This page intentionally left blank W. H. Freeman and Company New York The Quest for Insight F I F T H E D I T I O N PETER ATKINS Oxford University LORETTA JONES University of Northern Colorado C H E M I CA L P R I N C I P L E S PUBLISHER: Clancy Marshall SENIOR ACQUISITIONS EDITOR: Jessica Fiorillo SENIOR DEVELOPMENTAL EDITOR: Randi Rossignol MARKETING MANAGER: John Britch MEDIA AND SUPPLEMENTS EDITOR: Dave Quinn ASSISTANT EDITOR: Tony Petrites PHOTO EDITOR: Bianca Moscatelli COVER/TEXT DESIGNER: Blake Logan SENIOR PROJECT EDITOR: Georgia Lee Hadler COPY EDITOR: Margaret Comaskey ILLUSTRATION COORDINATOR: Bill Page ILLUSTRATIONS: Peter Atkins with Network Graphics PRODUCTION COORDINATOR: Paul Rohloff COMPOSITION: MPS Limited, A Macmillan Company PRINTING AND BINDING: Quebecor Library of Congress Control Number: 2009936820 ISBN-13: 978-1-4292-1955-6 ISBN-10: 1-4292-1955-6 ©2010, 2008, 2005, 2002 by P. W. Atkins and L. L. Jones All rights reserved Printed in the United States of America First printing W. H. Freeman and Company 41 Madison Avenue New York, NY 10010 Houndmills, Basingstoke RG21 6XS, England www.whfreeman.com CONTENTS IN BRIEF 1 ATOMS: THE QUANTUM WORLD 1 2 CHEMICAL BONDS 55 MAJOR TECHNIQUE 1: INFRARED SPECTROSCOPY 90 3 MOLECULAR SHAPE AND STRUCTURE 93 MAJOR TECHNIQUE 2: ULTRAVIOLET AND VISIBLE SPECTROSCOPY 130 4 THE PROPERTIES OF GASES 133 5 LIQUIDS AND SOLIDS 171 MAJOR TECHNIQUE 3: X-RAY DIFFRACTION 203 6 INORGANIC MATERIALS 205 7 THERMODYNAMICS: THE FIRST LAW 235 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS 287 9 PHYSICAL EQUILIBRIA 333 MAJOR TECHNIQUE 4: CHROMATOGRAPHY 381 10 CHEMICAL EQUILIBRIA 383 11 ACIDS AND BASES 423 12 AQUEOUS EQUILIBRIA 475 13 ELECTROCHEMISTRY 515 14 CHEMICAL KINETICS 561 MAJOR TECHNIQUE 5: COMPUTATION 610 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 611 16 THE ELEMENTS: THE d-BLOCK 667 17 NUCLEAR CHEMISTRY 705 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS 735 MAJOR TECHNIQUE 6: MASS SPECTROMETRY 758 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS 761 MAJOR TECHNIQUE 7: NUCLEAR MAGNETIC RESONANCE 791 FUNDAMENTALS F1 Introduction and Orientation, Matter and Energy, Elements and Atoms, Compounds, The Nomenclature of Compounds, Moles and Molar Masses, Determination of Chemical Formulas, Mixtures and Solutions, Chemical Equations, Aqueous Solutions and Precipitation, Acids and Bases, Redox Reactions, Reaction Stoichiometry, Limiting Reactants iii This page intentionally left blank CONTENTS Preface xv FUNDAMENTALS F1 INTRODUCTION AND ORIENTATION F1 Chemistry and Society F1 Chemistry: A Science at Three Levels F2 How Science Is Done F2 The Branches of Chemistry F4 Mastering Chemistry F4 A MATTER AND ENERGY F5 A.1 Physical Properties F5 A.2 Force F9 A.3 Energy F10 Exercises F13 B ELEMENTS AND ATOMS F15 B.1 Atoms F15 B.2 The Nuclear Model F16 B.3 Isotopes F17 B.4 The Organization of the Elements F18 Exercises F21 C COMPOUNDS F22 C.1 What Are Compounds? F22 C.2 Molecules and Molecular Compounds F23 C.3 Ions and Ionic Compounds F24 Exercises F28 D THE NOMENCLATURE OF COMPOUNDS F29 D.1 Names of Cations F29 D.2 Names of Anions F29 D.3 Names of Ionic Compounds F31 TOOLBOX D.1 HOW TO NAME IONIC COMPOUNDS F31 D.4 Names of Inorganic Molecular Compounds F32 TOOLBOX D.2 HOW TO NAME SIMPLE INORGANIC MOLECULAR COMPOUNDS F33 D.5 Names of Some Common Organic Compounds F35 Exercises F36 E MOLES AND MOLAR MASSES F37 E.1 The Mole F37 E.2 Molar Mass F39 Exercises F44 F DETERMINATION OF CHEMICAL FORMULAS F45 F.1 Mass Percentage Composition F46 F.2 Determining Empirical Formulas F47 F.3 Determining Molecular Formulas F49 Exercises F50 G MIXTURES AND SOLUTIONS F51 G.1 Classifying Mixtures F51 G.2 Separation Techniques F53 G.3 Concentration F54 G.4 Dilution F57 TOOLBOX G.1 HOW TO CALCULATE THE VOLUME OF STOCK SOLUTION REQUIRED FOR A GIVEN DILUTION F57 Exercises F58 H CHEMICAL EQUATIONS F60 H.1 Symbolizing Chemical Reactions F60 H.2 Balancing Chemical Equations F62 Exercises F64 I AQUEOUS SOLUTIONS AND PRECIPITATION F65 I.1 Electrolytes F65 I.2 Precipitation Reactions F67 I.3 Ionic and Net Ionic Equations F67 I.4 Putting Precipitation to Work F69 Exercises F70 J ACIDS AND BASES F72 J.1 Acids and Bases in Aqueous Solution F72 J.2 Strong and Weak Acids and Bases F74 J.3 Neutralization F75 Exercises F76 K REDOX REACTIONS F77 K.1 Oxidation and Reduction F78 K.2 Oxidation Numbers: Keeping Track of Electrons F79 TOOLBOX K.1 HOW TO ASSIGN OXIDATION NUMBERS F80 K.3 Oxidizing and Reducing Agents F81 K.4 Balancing Simple Redox Equations F83 Exercises F84 v L REACTION STOICHIOMETRY F85 L.1 Mole-to-Mole Predictions F86 L.2 Mass-to-Mass Predictions F86 TOOLBOX L.1 HOW TO CARRY OUT MASS-TO-MASS CALCULATIONS F87 L.3 Volumetric Analysis F89 TOOLBOX L.2 HOW TO INTERPRET A TITRATION F90 Exercises F93 M LIMITING REACTANTS F95 M.1 Reaction Yield F95 M.2 The Limits of Reaction F96 TOOLBOX M.1 HOW TO IDENTIFY THE LIMITING REACTANT F97 M.3 Combustion Analysis F100 Exercises F103 Chapter 1 ATOMS: THE QUANTUM WORLD INVESTIGATING ATOMS 1 1.1 The Nuclear Model of the Atom 2 1.2 The Characteristics of Electromagnetic Radiation 3 1.3 Atomic Spectra 6 QUANTUM THEORY 8 1.4 Radiation, Quanta, and Photons 8 1.5 The Wave–Particle Duality of Matter 13 1.6 The Uncertainty Principle 15 1.7 Wavefunctions and Energy Levels 17 THE HYDROGEN ATOM 22 1.8 The Principal Quantum Number 22 1.9 Atomic Orbitals 23 1.10 Electron Spin 30 1.11 The Electronic Structure of Hydrogen 30 Box 1.1 How Do We Know . . . That an Electron Has Spin? 31 MANY-ELECTRON ATOMS 32 1.12 Orbital Energies 32 1.13 The Building-Up Principle 33 TOOLBOX 1.1 HOW TO PREDICT THE GROUND-STATE ELECTRON CONFIGURATION OF AN ATOM 36 1.14 Electronic Structure and the Periodic Table 37 Box 1.2 The Development of the Periodic Table 38 THE PERIODICITY OF ATOMIC PROPERTIES 39 1.15 Atomic Radius 39 vi CONTENTS 1.16 Ionic Radius 40 1.17 Ionization Energy 42 1.18 Electron Affinity 44 1.19 The Inert-Pair Effect 46 1.20 Diagonal Relationships 46 1.21 The General Properties of the Elements 46 Exercises 49 Chapter 2 CHEMICAL BONDS IONIC BONDS 55 2.1 The Ions That Elements Form 56 2.2 Lewis Symbols 58 2.3 The Energetics of Ionic Bond Formation 58 2.4 Interactions Between Ions 59 COVALENT BONDS 63 2.5 Lewis Structures 63 2.6 Lewis Structures of Polyatomic Species 64 TOOLBOX 2.1 HOW TO WRITE THE LEWIS STRUCTURE OF A POLYATOMIC SPECIES 65 2.7 Resonance 67 2.8 Formal Charge 69 TOOLBOX 2.2 HOW TO USE FORMAL CHARGE TO DETERMINE THE MOST LIKELY LEWIS STRUCTURE 70 EXCEPTIONS TO THE OCTET RULE 71 2.9 Radicals and Biradicals 72 2.10 Expanded Valence Shells 72 Box 2.1 What Has This to Do with . . . Staying Alive? 73 2.11 The Unusual Structures of Some Group 13/III Compounds 75 IONIC VERSUS COVALENT BONDS 76 2.12 Correcting the Covalent Model: Electronegativity 76 2.13 Correcting the Ionic Model: Polarizability 78 THE STRENGTHS AND LENGTHS OF COVALENT BONDS 79 2.14 Bond Strengths 79 2.15 Variation in Bond Strength 80 2.16 Bond Lengths 81 Box 2.2 How Do We Know . . . the Length of a Chemical Bond? 83 Exercises 84 MAJOR TECHNIQUE 1: INFRARED SPECTROSCOPY 90 Chapter 3 MOLECULAR SHAPE AND STRUCTURE THE VSEPR MODEL 93 Box 3.1 Frontiers of Chemistry: Drugs by Design and Discovery 94 3.1 The Basic VSEPR Model 94 3.2 Molecules with Lone Pairs on the Central Atom 98 TOOLBOX 3.1 HOW TO USE THE VSEPR MODEL 100 3.3 Polar Molecules 101 VALENCE-BOND THEORY 104 3.4 Sigma and Pi Bonds 105 3.5 Electron Promotion and the Hybridization of Orbitals 107 3.6 Other Common Types of Hybridization 108 3.7 Characteristics of Multiple Bonds 111 MOLECULAR ORBITAL THEORY 113 3.8 The Limitations of Lewis’s Theory 113 Box 3.2 How Do We Know . . . That Electrons Are Not Paired? 114 3.9 Molecular Orbitals 115 3.10 Electron Configurations of Diatomic Molecules 116 Box 3.3 How Do We Know . . . the Energies of Molecular Orbitals? 117 TOOLBOX 3.2 HOW TO DETERMINE THE ELECTRON CONFIGURATION AND BOND ORDER OF A HOMONUCLEAR DIATOMIC SPECIES 118 3.11 Bonding in Heteronuclear Diatomic Molecules 120 3.12 Orbitals in Polyatomic Molecules 121 Exercises 124 MAJOR TECHNIQUE 2: ULTRAVIOLET AND VISIBLE SPECTROSCOPY 130 CONTENTS vii Chapter 4 THE PROPERTIES OF GASES THE NATURE OF GASES 134 4.1 Observing Gases 134 4.2 Pressure 134 4.3 Alternative Units of Pressure 136 THE GAS LAWS 138 4.4 The Experimental Observations 138 4.5 Applications of the Ideal Gas Law 141 TOOLBOX 4.1 HOW TO USE THE IDEAL GAS LAW 142 4.6 Gas Density 145 4.7 The Stoichiometry of Reacting Gases 147 4.8 Mixtures of Gases 148 MOLECULAR MOTION 152 4.9 Diffusion and Effusion 152 4.10 The Kinetic Model of Gases 153 4.11 The Maxwell Distribution of Speeds 157 Box 4.1 How Do We Know . . . the Distribution of Molecular Speeds? 158 REAL GASES 159 4.12 Deviations from Ideality 159 4.13 The Liquefaction of Gases 160 4.14 Equations of State of Real Gases 161 Exercises 163 Chapter 5 LIQUIDS AND SOLIDS INTERMOLECULAR FORCES 171 5.1 The Origin of Intermolecular Forces 172 5.2 Ion–Dipole Forces 172 5.3 Dipole–Dipole Forces 174 5.4 London Forces 175 5.5 Hydrogen Bonding 178 5.6 Repulsions 179 LIQUID STRUCTURE 179 5.7 Order in Liquids 180 5.8 Viscosity and Surface Tension 180 SOLID STRUCTURES 182 5.9 Classification of Solids 182 Box 5.1 How Do We Know . . . What a Surface Looks Like? 183 5.10 Molecular Solids 184 7.4 Heat 243 7.5 The Measurement of Heat 243 7.6 The First Law 247 7.7 A Molecular Interlude: The Origin of Internal Energy 251 ENTHALPY 252 7.8 Heat Transfers at Constant Pressure 252 7.9 Heat Capacities at Constant Volume and Constant Pressure 254 7.10 A Molecular Interlude: The Origin of the Heat Capacities of Gases 255 7.11 The Enthalpy of Physical Change 257 7.12 Heating Curves 259 Box 7.1 How Do We Know . . . the Shape of a Heating Curve? 260 THE ENTHALPY OF CHEMICAL CHANGE 261 7.13 Reaction Enthalpies 261 7.14 The Relation Between ⌬H and ⌬U 263 7.15 Standard Reaction Enthalpies 264 7.16 Combining Reaction Enthalpies: Hess’s Law 265 TOOLBOX 7.1 HOW TO USE HESS’S LAW 266 7.17 The Heat Output of Reactions 267 Box 7.2 What Has This to Do with . . . the Environment? 268 7.18 Standard Enthalpies of Formation 271 7.19 The Born–Haber Cycle 274 7.20 Bond Enthalpies 276 7.21 The Variation of Reaction Enthalpy with Temperature 278 Exercises 280 Chapter 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS ENTROPY 287 8.1 Spontaneous Change 287 8.2 Entropy and Disorder 288 8.3 Changes in Entropy 290 5.11 Network Solids 185 5.12 Metallic Solids 186 5.13 Unit Cells 188 5.14 Ionic Structures 191 THE IMPACT ON MATERIALS 194 5.15 Liquid Crystals 194 5.16 Ionic Liquids 195 Exercises 196 MAJOR TECHNIQUE 3: X-RAY DIFFRACTION 203 Chapter 6 INORGANIC MATERIALS METALLIC MATERIALS 205 6.1 The Properties of Metals 205 6.2 Alloys 207 6.3 Steel 208 6.4 Nonferrous Alloys 209 HARD MATERIALS 210 6.5 Diamond and Graphite 210 6.6 Calcium Carbonate 211 6.7 Silicates 212 6.8 Cement and Concrete 214 6.9 Borides, Carbides, and Nitrides 215 6.10 Glasses 216 6.11 Ceramics 217 MATERIALS FOR NEW TECHNOLOGIES 218 6.12 Bonding in the Solid State 218 6.13 Semiconductors 220 6.14 Superconductors 221 6.15 Luminescent Materials 223 6.16 Magnetic Materials 224 6.17 Composite Materials 225 NANOMATERIALS 226 6.18 The Nature and Uses of Nanomaterials 226 6.19 Nanotubes 227 6.20 Preparation of Nanomaterials 228 Exercises 231 Chapter 7 THERMODYNAMICS: THE FIRST LAW SYSTEMS, STATES, AND ENERGY 235 7.1 Systems 236 7.2 Work and Energy 236 7.3 Expansion Work 237 viii CONTENTS 8.4 Entropy Changes Accompanying Changes in Physical State 295 8.5 A Molecular Interpretation of Entropy 298 8.6 The Equivalence of Statistical and Thermodynamic Entropies 301 8.7 Standard Molar Entropies 303 Box 8.1 Frontiers of Chemistry: The Quest for Absolute Zero 304 8.8 Standard Reaction Entropies 307 GLOBAL CHANGES IN ENTROPY 308 8.9 The Surroundings 308 8.10 The Overall Change in Entropy 310 8.11 Equilibrium 314 GIBBS FREE ENERGY 315 8.12 Focusing on the System 315 8.13 Gibbs Free Energy of Reaction 318 8.14 The Gibbs Free Energy and Nonexpansion Work 321 8.15 The Effect of Temperature 323 8.16 Impact on Biology: Gibbs Free Energy Changes in Biological Systems 325 Exercises 326 Chapter 9 PHYSICAL EQUILIBRIA PHASES AND PHASE TRANSITIONS 333 9.1 Vapor Pressure 334 9.2 Volatility and Intermolecular Forces 335 9.3 The Variation of Vapor Pressure with Temperature 335 9.4 Boiling 338 9.5 Freezing and Melting 339 9.6 Phase Diagrams 340 9.7 Critical Properties 342 SOLUBILITY 344 9.8 The Limits of Solubility 344 9.9 The Like-Dissolves-Like Rule 345 9.10 Pressure and Gas Solubility: Henry’s Law 347 9.11 Temperature and Solubility 348 9.12 The Enthalpy of Solution 349 9.13 The Gibbs Free Energy of Solution 351 COLLIGATIVE PROPERTIES 352 9.14 Molality 352 TOOLBOX 9.1 HOW TO USE THE MOLALITY 353 9.15 Vapor-Pressure Lowering 356 9.16 Boiling-Point Elevation and Freezing-Point Depression 358 9.17 Osmosis 360 TOOLBOX 9.2 HOW TO USE COLLIGATIVE PROPERTIES TO DETERMINE MOLAR MASS 362 BINARY LIQUID MIXTURES 365 9.18 The Vapor Pressure of a Binary Liquid Mixture 365 9.19 Distillation 367 9.20 Azeotropes 368 THE IMPACT ON BIOLOGY AND MATERIALS 369 9.21 Colloids 370 9.22 Bio-based and Biomimetic Materials 371 Box 9.1 Frontiers of Chemistry: Drug Delivery 372 Exercises 373 MAJOR TECHNIQUE 4: CHROMATOGRAPHY 381 Chapter 10 CHEMICAL EQUILIBRIA REACTIONS AT EQUILIBRIUM 384 10.1 The Reversibility of Reactions 384 10.2 Equilibrium and the Law of Mass Action 385 10.3 The Thermodynamic Origin of Equilibrium Constants 390 10.4 The Extent of Reaction 395 10.5 The Direction of Reaction 396 EQUILIBRIUM CALCULATIONS 397 10.6 The Equilibrium Constant in Terms of Molar Concentrations of Gases 398 10.7 Alternative Forms of the Equilibrium Constant 400 10.8 Using Equilibrium Constants 401 TOOLBOX 10.1 HOW TO SET UP AND USE AN EQUILIBRIUM TABLE 401 THE RESPONSE OF EQUILIBRIA TO CHANGES IN CONDITIONS 405 10.9 Adding and Removing Reagents 405 10.10 Compressing a Reaction Mixture 408 CONTENTS ix AUTOPROTOLYSIS AND pH 464 11.18 Very Dilute Solutions of Strong Acids and Bases 464 11.19 Very Dilute Solutions of Weak Acids 466 Exercises 468 Chapter 12 AQUEOUS EQUILIBRIA MIXED SOLUTIONS AND BUFFERS 475 12.1 Buffer Action 476 12.2 Designing a Buffer 477 12.3 Buffer Capacity 482 TITRATIONS 483 12.4 Strong Acid–Strong Base Titrations 483 Box 12.1 What Has This to Do with . . . Staying Alive? 484 TOOLBOX 12.1 HOW TO CALCULATE THE pH DURING A STRONG ACID–STRONG BASE TITRATION 485 12.5 Strong Acid–Weak Base and Weak Acid–Strong Base Titrations 486 TOOLBOX 12.2 HOW TO CALCULATE THE pH DURING A TITRATION OF A WEAK ACID OR A WEAK BASE 490 12.6 Acid–Base Indicators 492 12.7 Stoichiometry of Polyprotic Acid Titrations 494 SOLUBILITY EQUILIBRIA 496 12.8 The Solubility Product 497 12.9 The Common-Ion Effect 499 12.10 Predicting Precipitation 501 12.11 Selective Precipitation 502 12.12 Dissolving Precipitates 504 12.13 Complex Ion Formation 505 12.14 Qualitative Analysis 507 Exercises 509 Chapter 13 ELECTROCHEMISTRY REPRESENTING REDOX REACTIONS 515 13.1 Half-Reactions 516 13.2 Balancing Redox Equations 516 TOOLBOX 13.1 HOW TO BALANCE COMPLICATED REDOX EQUATIONS 517 10.11 Temperature and Equilibrium 410 10.12 Catalysts and Haber’s Achievement 413 10.13 The Impact on Biology: Homeostasis 413 Exercises 414 Chapter 11 ACIDS AND BASES THE NATURE OF ACIDS AND BASES 423 11.1 Brønsted–Lowry Acids and Bases 423 11.2 Lewis Acids and Bases 426 11.3 Acidic, Basic, and Amphoteric Oxides 428 11.4 Proton Exchange Between Water Molecules 429 11.5 The pH Scale 431 11.6 The pOH of Solutions 434 WEAK ACIDS AND BASES 435 11.7 Acidity and Basicity Constants 435 11.8 The Conjugate Seesaw 438 11.9 Molecular Structure and Acid Strength 440 11.10 The Strengths of Oxoacids and Carboxylic Acids 442 THE pH OF SOLUTIONS OF WEAK ACIDS AND BASES 445 11.11 Solutions of Weak Acids 445 TOOLBOX 11.1 HOW TO CALCULATE THE pH OF A SOLUTION OF A WEAK ACID 445 11.12 Solutions of Weak Bases 448 TOOLBOX 11.2 HOW TO CALCULATE THE pH OF A SOLUTION OF A WEAK BASE 448 11.13 The pH of Salt Solutions 450 POLYPROTIC ACIDS AND BASES 454 11.14 The pH of a Polyprotic Acid Solution 455 11.15 Solutions of Salts of Polyprotic Acids 456 11.16 The Concentrations of Solute Species 457 TOOLBOX 11.3 HOW TO CALCULATE THE CONCENTRATIONS OF ALL SPECIES IN A POLYPROTIC ACID SOLUTION 458 11.17 Composition and pH 461 Box 11.1 What Has This to Do with . . . the Environment? 462 x CONTENTS GALVANIC CELLS 522 13.3 The Structure of Galvanic Cells 522 13.4 Cell Potential and Reaction Gibbs Free Energy 524 13.5 The Notation for Cells 526 TOOLBOX 13.2 HOW TO WRITE A CELL REACTION CORRESPONDING TO A CELL DIAGRAM 528 13.6 Standard Potentials 529 13.7 The Electrochemical Series 534 13.8 Standard Potentials and Equilibrium Constants 536 TOOLBOX 13.3 HOW TO CALCULATE EQUILIBRIUM CONSTANTS FROM ELECTROCHEMICAL DATA 537 13.9 The Nernst Equation 538 13.10 Ion-Selective Electrodes 541 ELECTROLYTIC CELLS 542 13.11 Electrolysis 542 13.12 The Products of Electrolysis 544 TOOLBOX 13.4 HOW TO PREDICT THE RESULT OF ELECTROLYSIS 545 THE IMPACT ON MATERIALS 547 13.13 Applications of Electrolysis 547 13.14 Corrosion 548 13.15 Practical Cells 550 Box 13.1 Frontiers of Chemistry: Fuel Cells 552 Exercises 553 Chapter 14 CHEMICAL KINETICS REACTION RATES 561 14.1 Concentration and Reaction Rate 561 Box 14.1 How Do We Know . . . What Happens to Atoms During a Reaction? 564 14.2 The Instantaneous Rate of Reaction 565 14.3 Rate Laws and Reaction Order 566 CONCENTRATION AND TIME 572 14.4 First-Order Integrated Rate Laws 572 14.5 Half-Lives for First-Order Reactions 576 14.6 Second-Order Integrated Rate Laws 578 REACTION MECHANISMS 580 14.7 Elementary Reactions 580 14.8 The Rate Laws of Elementary Reactions 581 14.9 Chain Reactions 585 14.10 Rates and Equilibrium 586 MODELS OF REACTIONS 587 14.11 The Effect of Temperature 587 14.12 Collision Theory 591 Box 14.2 How Do We Know . . . What Happens During a Molecular Collision? 593 14.13 Transition State Theory 594 ACCELERATING REACTIONS 595 14.14 Catalysis 595 14.15 Industrial Catalysts 597 Box14.3 What Has This to Do with . . . the Environment? 598 14.16 Living Catalysts: Enzymes 600 Exercises 602 MAJOR TECHNIQUE 5: COMPUTATION 610 Chapter 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS PERIODIC TRENDS 611 15.1 Atomic Properties 611 15.2 Bonding Trends 613 HYDROGEN 615 15.3 The Element 615 Box 15.1 What Has This to Do with . . . the Environment? 616 15.4 Compounds of Hydrogen 618 GROUP 1: THE ALKALI METALS 619 15.5 The Group 1 Elements 620 15.6 Compounds of Lithium, Sodium, and Potassium 622 GROUP 2: THE ALKALINE EARTH METALS 623 15.7 The Group 2 Elements 624 15.8 Compounds of Beryllium, Magnesium, and Calcium 625 GROUP 13/III: THE BORON FAMILY 628 15.9 The Group 13/III Elements 628 15.10 Group 13/III Oxides and Halides 630 15.11 Boranes and Borohydrides 632 GROUP 14/IV: THE CARBON FAMILY 633 15.12 The Group 14/IV Elements 633 CONTENTS xi THE ELECTRONIC STRUCTURES OF COMPLEXES 691 16.8 Crystal Field Theory 691 16.9 The Spectrochemical Series 693 16.10 The Colors of Complexes 696 16.11 Magnetic Properties of Complexes 697 16.12 Ligand Field Theory 698 Exercises 700 Chapter 17 NUCLEAR CHEMISTRY NUCLEAR DECAY 705 17.1 The Evidence for Spontaneous Nuclear Decay 706 17.2 Nuclear Reactions 707 17.3 The Pattern of Nuclear Stability 710 17.4 Predicting the Type of Nuclear Decay 712 17.5 Nucleosynthesis 712 Box 17.1 What Has This to Do with . . . Staying Alive? 714 NUCLEAR RADIATION 715 17.6 The Biological Effects of Radiation 715 Box 17.2 How Do We Know . . . How Radioactive a Material Is? 717 17.7 Measuring the Rate of Nuclear Decay 717 17.8 Uses of Radioisotopes 721 NUCLEAR ENERGY 721 17.9 Mass–Energy Conversion 722 17.10 Nuclear Fission 724 17.11 Nuclear Fusion 726 17.12 The Chemistry of Nuclear Power 728 Exercises 730 Chapter 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS ALIPHATIC HYDROCARBONS 735 18.1 Types of Aliphatic Hydrocarbons 736 TOOLBOX 18.1 HOW TO NAME ALIPHATIC HYDROCARBONS 738 18.2 Isomers 740 18.3 Properties of Alkanes 743 Box 15.2 Frontiers of Chemistry: Self-Assembling Materials 636 15.13 Oxides of Carbon and Silicon 637 15.14 Other Important Group 14/IV Compounds 639 GROUP 15/V: THE NITROGEN FAMILY 640 15.15 The Group 15/V Elements 641 15.16 Compounds with Hydrogen and the Halogens 642 15.17 Nitrogen Oxides and Oxoacids 644 15.18 Phosphorus Oxides and Oxoacids 646 GROUP 16/VI: THE OXYGEN FAMILY 647 15.19 The Group 16/VI Elements 648 15.20 Compounds with Hydrogen 650 15.21 Sulfur Oxides and Oxoacids 652 GROUP 17/VII: THE HALOGENS 654 15.22 The Group 17/VII Elements 654 15.23 Compounds of the Halogens 656 GROUP 18/VIII: THE NOBLE GASES 659 15.24 The Group 18/VIII Elements 659 15.25 Compounds of the Noble Gases 660 Exercises 661 Chapter 16 THE ELEMENTS: THE d-BLOCK THE d-BLOCK ELEMENTS AND THEIR COMPOUNDS 667 16.1 Trends in Physical Properties 668 16.2 Trends in Chemical Properties 669 SELECTED ELEMENTS: A SURVEY 671 16.3 Scandium Through Nickel 671 16.4 Groups 11 and 12 676 COORDINATION COMPOUNDS 680 16.5 Coordination Complexes 680 Box 16.1 What Has This to Do with . . . Staying Alive? 681 TOOLBOX 16.1 HOW TO NAME d-METAL COMPLEXES AND COORDINATION COMPOUNDS 683 16.6 The Shapes of Complexes 685 16.7 Isomers 686 Box 16.2 How Do We Know . . . That a Complex Is Optically Active? 689 xii CONTENTS CONTENTS xiii Box 19.1 Frontiers of Chemistry: Conducting Polymers 778 19.14 Carbohydrates 781 19.15 Nucleic Acids 782 Exercises 785 MAJOR TECHNIQUE 7: NUCLEAR MAGNETIC RESONANCE 791 Appendix 1 Symbols, Units, and Mathematical Techniques A1 1A Symbols A1 1B Units and Unit Conversions A3 1C Scientific Notation A5 1D Exponents and Logarithms A6 1E Equations and Graphs A7 1F Calculus A7 Appendix 2 Experimental Data A11 2A Thermodynamic Data at 25°C A11 2B Standard Potentials at 12°C A18 2C Ground-State Electron Configurations A20 2D The Elements A22 2E The Top 23 Chemicals by Industrial Production in the United States in 2008 A32 Appendix 3 Nomenclature A33 3A The Nomenclature of Polyatomic Ions A33 3B Common Names of Chemicals A34 3C Names of Some Common Cations with Variable Charge Numbers A34 Glossary B1 Answers C1 Self-Tests B C1 Odd-Numbered Exercises C10 Illustration Credits D1 Index E1 18.4 Alkane Substitution Reactions 744 18.5 Properties of Alkenes 745 18.6 Electrophilic Addition 746 AROMATIC COMPOUNDS 748 18.7 Nomenclature of Arenes 748 18.8 Electrophilic Substitution 749 IMPACT ON TECHNOLOGY: FUELS 751 18.9 Gasoline 751 18.10 Coal 752 Exercises 753 MAJOR TECHNIQUE 6: MASS SPECTROMETRY 758 Chapter 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS COMMON FUNCTIONAL GROUPS 761 19.1 Haloalkanes 762 19.2 Alcohols 762 19.3 Ethers 763 19.4 Phenols 764 19.5 Aldehydes and Ketones 764 19.6 Carboxylic Acids 765 19.7 Esters 766 19.8 Amines, Amino Acids, and Amides 767 TOOLBOX 19.1 HOW TO NAME SIMPLE COMPOUNDS WITH FUNCTIONAL GROUPS 769 THE IMPACT ON TECHNOLOGY 770 19.9 Addition Polymerization 770 19.10 Condensation Polymerization 772 19.11 Copolymers 775 19.12 Physical Properties of Polymers 775 THE IMPACT ON BIOLOGY 777 19.13 Proteins 777 LETTER FROM THE AUTHORS Dear Colleagues, It is with great pleasure that we offer the fifth edition of Chemical Principles: The Quest for Insight. The new edition is designed, like its predecessors, to encourage students to think and to develop a solid understanding of chemistry by first building a qualitative understanding and then showing how to express those qualitative concepts quantitatively. Because college students often have forgotten much of their high school chemistry, the book begins with a Fundamentals section that reviews the basic ideas of chemistry such as nomenclature, concentration, and stoichiometry. The main part of the book starts with an investigation of the structure of the atom, goes on to show how atomic properties determine the types of bonds that atoms form, and then investigates how the properties of molecules and ions contribute to the structure, reactions, and properties of bulk matter. We have updated much of the content and the format of the periodic table. We have also introduced a new materials chapter following the solid state chapter. This chapter serves as a review of the first five chapters and introduces students to the chemistry that is the basis of the exciting field of nanotechnology. In this chapter students also see how the chemical principles they are learning, even at an early stage in their course, apply to modern research and applications such as ceramic and magnetic materials and electronic components. In later chapters we investigate further properties of materials as new concepts are introduced. We have enhanced our approach to problem solving to help students develop the kinds of problem-solving skills that experts use. That is, we want students to learn to solve problems as chemists do. Consequently, in the worked examples we begin, where appropriate, with an Anticipate section that encourages students to estimate the answer and develop their powers of insight and judgment. Then we present a general Plan that encourages readers to collect their thoughts and establish an approach to the problem. After the fully worked out Solve section, we encourage students to reflect on their original anticipation in a brief Evaluate section. In addition, for a number of calculations we encourage students to organize their thinking by asking What should we assume? before proceeding. Almost all the worked examples are accompanied by graphic thumbnail interpretations of each step, which were introduced in the fourth edition as an entirely new way to help students make connections among the different levels of chemical description. The thumbnails have been developed further for this edition. We hope you will like the scattering of Thinking points throughout the text, which are intended to encourage and emphasize our underlying strategy: to get students to think as well as to learn. We have also generated a new art program for a great deal of the book, which we hope will enhance the learning experience by conveying insight into the molecular world. We are grateful for the feedback and support we have received from those who have used the previous four editions. The suggestions readers have given us have helped us to refine the book and make it more interesting and useful for students. We hope that you and your students find the book to be a refreshing and intriguing introduction to chemistry. Yours sincerely, Peter Atkins Loretta Jones PREFACE CHEMICAL PRINCIPLES This text is designed for a rigorous course in introductory chemistry. Its central theme is to challenge students to think and question while providing a sound foundation in the principles of chemistry. At the same time, students of all levels benefit from assistance in learning how to think, pose questions, and approach problems. To that end, Chemical Principles is organized in a logical way that builds understanding and offers students a wide array of pedagogical support. ATOMS-FIRST ORGANIZATION Chemical Principles presents the concepts of chemistry in a logical sequence that enhances student understanding. The atoms-first sequence starts with the behavior of atoms and molecules and builds to more complex properties and interactions. • Atoms and molecules come first (including discussions of quantum mechanics and molecular orbitals), providing the foundation for understanding bulk properties and models of gases, liquids, and solids. Chapter 1 has been reorganized in this edition to give readers a gentler introduction to atoms and their structure. • Next comes an exploration of thermodynamics and equilibrium, which builds on a conceptual understanding of entropy and free energy. This integrated presentation lays a common foundation for related concepts and provides a basis for the form of the equilibrium constant. • Kinetics then shows the dynamic nature of chemistry and the crucial role of insight and model building in identifying reaction mechanisms. PO4 3Ϫ 3Ϫ Ca2ϩ FIGURE 2.8 A micrograph of bone, which owes its rigidity to calcium phosphate. The overlay shows part of the crystal structure of calcium phosphate. Phosphate ions are polyatomic ions; however, as shown in the inset, they are nearly spherical and fit into crystal structures in much the same way as monatomic ions of charge Ϫ3. xv COVERING THE BASICS The Fundamentals sections, which precede Chapter 1, are identified by green-edged pages. These 13 minichapters provide a streamlined overview of the basics of chemistry. They can be used either to provide a useful, succinct review of basic material to which students can refer for extra help as they progress through the course, or as a concise, quick survey of material before starting on the main text. Diagnostic Test for the Fundamentals Sections. This test allows instructors to determine what their students understand and where they need additional support. Instructors can then make appropriate assignments from the Fundamentals sections. The test includes 5 to 10 problems for each Fundamentals section. The diagnostic test was created by Cynthia LaBrake at the University of Texas, Austin and can be found on the Instructor’s Resource CD ROM and on the Instructor pages of the Web site. FLEXIBLE MATH COVERAGE Optional Use of Calculus. The How do we do that? feature sets off derivations of key equations and encourages students to appreciate the power of mathematics. Almost all the calculus in the text is confined to this feature, so it can easily be avoided or emphasized as the instructor chooses. A selection of end-of-chapter exercises that make use of calculus are provided and marked with a . HOW DO WE DO THAT? We want to find the relation between the height, h, of the column of mercury in a barometer and the atmospheric pressure, P. Suppose the cross-sectional area of the cylindrical column is A. The volume of mercury in the column is the height of the cylinder times this area, V ϭ hA. The mass, m, of this volume of mercury is the product of mercury’s density, d, and the volume; so m ϭ dV ϭ dhA. The mercury is pulled down by the force of gravity; and the total force that its mass exerts at its base is the product of the mass and the acceleration of free fall (the acceleration due to gravity), g: F ϭ mg. Therefore, the pressure at the base of the column, the force divided by the area, is h Area, A Mass, m ϭ dhA Force, F ϭ mg From P ϭ F/A and F ϭ mg: P = F A = mg A = dhA g A = dhg #m #mg This equation shows that the pressure, P, exerted by a column of mercury is proportional to the height of the column. Mercury inside a tube sealed at one end and inverted in a pool of mercury will fall until the pressure exerted by the mercury balances the atmospheric pressure. Therefore, the height of the column can be used as a measure of atmospheric pressure. C xvi PREFACE EMPHASIS ON PROBLEM SOLVING • NEW! Anticipate/Plan/Solve/Evaluate Strategy. This problemsolving approach encourages students to anticipate or predict what a problem’s answer should be and to map out the solution before trying to solve the problem. Following the solution, the original anticipation is evaluated. The accompanying graphics provide the opportunity for visualizing and interpreting each step of the solution and the final result. • Self-Tests occur as pairs throughout the book. They enable students to test their understanding of the material covered in the preceding section or Worked Example. The answer to the first self-test is provided immediately and the answer to the second can be found at the back of the book. EXAMPLE 4.3 Using the combined gas law when one variable is changed Assume that, when you press in the piston of a bicycle pump, the volume inside the pump is decreased from about 100. cm3 to 20. cm3 before the air flows into the tire. Suppose that the compression is isothermal; estimate the final pressure of the compressed air in the pump, given an initial pressure of 1.00 atm. Anticipate The volume is reduced by a factor of 5, so we should expect a fivefold increase in pressure. PLAN Follow the second procedure in Toolbox 4.1. Only the pressure and volume change, so all other variables cancel, resulting in Boyle’s law. SOLVE 1 20 100 ? Pressure Volume PV ϭ constant (P2 ,V2) (P1,V1 ) Step 1 Rearrange P1V1/n1T1 ϭ P2V2/n2T2 to find P2 by multiplying both sides by n2T2/V2, and set n2 ϭ n1 (no change in the amount) and T2 ϭ T1 (no change in temperature): P2 = P1V1 n1T1 * n2T2 V2 ¡ P1V1 n1T1 * n1T1 V2 = P1 * V1 V2 1.00 atm 100 cm3 20 cm3 5.0 atm Step 2 Substitute the data: P2 = (1.00 atm) * 100 cm3 20 cm3 = 5.0 atm Evaluate The final pressure is higher by a factor of 5 (more precisely, 5.0), as expected. Self-Test 4.8A A sample of argon gas of volume 10.0 mL at 200. Torr is allowed to expand isothermally into an evacuated tube with a volume of 0.200 L. What is the final pressure of the argon in the tube? [Answer: 10.0 Torr] n2 ϭ n1 T2 ϭ T1 • Toolboxes show students how to tackle major types of calculations, demonstrating how to connect concepts to problem solving. They are designed as learning aids and handy summaries of key material. Each Toolbox is immediately followed by a related example. CUTTING EDGE CHEMISTRY FOR ALL STUDENTS Of special interest to Engineering students: • Liquid Crystals (Section 5.15) • Colloids (Section 9.21) • Applications of Electrolysis (Section 13.13) • Fuels (Section 18.9 and Box 7.2) • Polymerization and Polymers (Sections 19.9–19.12) • Corrosion (Section 13.14) • Fuel Cells (Box 13.1 Frontiers of Chemistry) • Industrial Catalysts (Section 14.15) • Self Assembling Materials (Box 15.2 Frontiers of Chemistry) • The whole of Chapter 6, Inorganic Materials Of special interest to Biology students: • Drugs by Design and Discovery (Box 3.1 Frontiers of Chemistry) • Gibbs Free Energy Changes in Biological Systems (Section 8.16) • Colloids (Section 9.21) • Bio-based and Biomimetic Materials (Section 9.22) • Homeostasis (Section 10.13) • Physiological Buffers (Box 12.1 What Has This to Do with . . . Staying Alive?) • Living Catalysts: Enzymes (Section 14.16) • Why We Need to Eat d-Metals (Box 16.1 What Has This to Do with . . . Staying Alive?) • Nuclear Medicine (Box 17.1 What Has This to Do with . . . Staying Alive?) • The Biological Effects of Radiation (Section 17.6) • Proteins (Section 19.13) • Carbohydrates (Section 19.14) • Nucleic Acids (Section 19.15) TOOLBOX 7.1 HOW TO USE HESS’S LAW CONCEPTUAL BASIS Because enthalpy is a state function, the enthalpy change of a system depends only on its initial and final states. Therefore, we can carry out a reaction in one step or, if that is not convenient, visualize it as the sum of several steps; the reaction enthalpy is the same in each case. PROCEDURE To use Hess’s law to find the enthalpy of a given reaction, we find a sequence of reactions with known reaction enthalpies that adds up to the reaction of interest. Step 1 Select one of the reactants in the overall reaction and write down a chemical equation in which it also appears as a reactant. Step 2 Select one of the products in the overall reaction and write down a chemical equation in which it also appears as a product. Add this equation to the equation written in step 1 and cancel species that appear on both sides of the equation. Step 3 Cancel unwanted species in the sum obtained in step 2 by adding an equation that has the same substance or substances on the opposite side of the arrow. Step 4 Once the sequence is complete, combine the standard reaction enthalpies. In each step, we may need to reverse the equation or multiply it by a factor. Recall from Eq. 16 that, if we want to reverse a chemical equation, we have to change the sign of the reaction enthalpy. If we multiply the stoichiometric coefficients by a factor, we must multiply the reaction enthalpy by the same factor. This procedure is illustrated in Example 7.9. The relative energies of the d-orbitals are different in complexes with different shapes. For example, in a tetrahedral complex, the three t2-orbitals point more directly at the ligands than the two e-orbitals do. As a result, in a tetrahedral complex, the t2-orbitals have a higher energy than the e-orbitals (Fig. 16.29). The ligand field splitting, ⌬T (where the T denotes tetrahedral), is generally smaller than in octahedral complexes, in part because there are fewer repelling ligands. Thinking point: Into what groups do you think the d-orbitals are split in a square-planar complex? • NEW! Thinking Points encourage students to speculate about the implications of what they are learning and to transfer their knowledge to new situations. Of special interest to Environmental Science students: • Green Chemistry promotes environmentally sound chemistry. Green chemistry passages in the text and green chemistry end-of-chapter exercises are accompanied by an icon. • Alternative Fuels (Box 7.2 What Has This to Do with . . . the Environment?) • Acid Rain and the Gene Pool (Box 11.1 What Has This to Do with . . . the Environment?) • Protecting the Ozone Layer (Box 14.3 What Has This to Do with . . . the Environment?) • The Greenhouse Effect (Box 15.1. What Has This to Do with . . . the Environment?) • Coal (Section 18.10) PREFACE xvii B A −6.50 −6.75 −7.00 ln[C3H8] Time (min) 50 1510 −6.56, 1.7 min −7.02, 13.3 min FIGURE 14.11 We can test for a firstorder reaction by plotting the natural logarithm of the reactant concentration against time. The graph is linear if the reaction is first order. The slope of the line, which is calculated here for the system in Example 14.4 by using the points A and B, is equal to the negative of the rate constant. Living Graph 14.11 • Living Graphs. Selected graphs in the text are available in interactive form on the Web site. Students can manipulate parameters and see cause and effect relationships. dense materials. Branched polymer chains cannot fit together as closely and form weaker, less dense materials (Fig. 19.15). A soft, lightweight body armor has been developed by creating arrays of long polyethylene chains that are closely aligned in the same direction, giving rise to very strong intermolecular forces. This body armor is reported to be 15 times stronger than steel, yet has such a low density that it floats on water. It is also soft and flexible, so it is comfortable to wear (Fig. 19.16). FIGURE 19.16 Recruits at the New York Police Academy are issued bullet-proof vests. The high-density polyethylene body armor protects law enforcement personnel without restricting movement because it is soft and flexible. • NEW! Chapter 6, Inorganic Materials. This new chapter reviews the first five chapters and introduces students to the chemistry that is the basis of the exciting new field of nanotechnology. In this chapter students also see how the chemical principles they are learning apply to cutting edge research and applications such as ceramic and magnetic materials and electronic components. MEDIA INTEGRATION Selected figures and exercises throughout the book are accompanied by media link icons that direct 6.11 Ceramics Many of the materials used in the most advanced technologies are based on a material characteristic of one of the oldest technologies: common clay. Most clays used commercially are oxides of silicon, aluminum, and magnesium. China clay contains primarily kaolinite, a form of aluminum aluminosilicate that can be obtained reasonably free of the iron impurities that make many clays look reddish brown, and so it is white. However, other clays contain the iron oxides that cause the orange color of terra cotta tiles and flower pots. The appearance of a flake of clay reflects its internal structure, which is something like an untidy stack of papers (Fig. 6.23). Sheets of tetrahedral silicate units or octahedral units of aluminum or magnesium oxides are separated by layers of water molecules that serve to bind the layers of the flake together. Each flake of clay is surrounded by a double layer of ions that separates the flakes by repelling the like charges on the other flakes. This repulsion allows the flakes to slide past one another and gives the clay the ability to flow in response to stress. As a result, clays can be easily molded. When clay is baked in a kiln, it forms the hard, tough ceramic materials used in firebricks, tiles, and pots as the water is driven out and strong chemical bonds form between the flakes. Large amounts of china clay, which is used to make ceramics such as porcelain and china, are applied in the coating of paper (such as this page) to give a smooth, nonabsorbent surface. Clay was the first substance to be made into a ceramic, an inorganic material that has been hardened by heating to a high temperature. Today a wide variety of compounds, often oxides, are used to create ceramics with specific properties. FIGURE 6.23 The layers of clay particles can be seen in this micrograph. Because the surfaces of these layers have like charges, they repel one another and easily slide past one another, making clay soft and malleable. students to Web-based resources. These integrated links to the companion Web site are designed to make the text more dynamic and interactive. Chemical Principles contains media links to: • Animations. Selected art in the text is supported by media. Students can view motion, three dimensions, and atomic and molecular interactions and learn to visualize like chemists—at a molecular level. To focus their attention, questions on each animation have been added in this edition. FIGURE 3.13 These contours indicate the amplitude of the sp3 hybrid orbital wavefunction in a plane that bisects it and passes through the nucleus. The colors indicate the variation of electron density in the orbital: regions of high electron density are red and regions of low electron density blue. Each sp3 hybrid orbital points toward the corner of a tetrahedron. Animation 3.13 (a) (b) (c) FIGURE 15.48 Sulfuric acid is a dehydrating agent. When concentrated sulfuric acid is poured on to sucrose (a), the sucrose, a carbohydrate, is dehydrated (b), leaving a frothy black mass of carbon (c). Lab Video 15.48 • Lab Videos. Video clips of many of the reactions described in the book are provided on the book’s Web site. • Tools. Tools on the book’s Web site allow the study of chemical calculations, graphing, and exploration of periodic properties from different points of view. xviii PREFACE FOR THE INSTRUCTOR Instructor’s Solutions Manual by Carl Hoeger, University of California, San Diego, Laurence Lavelle, University of California, Los Angeles, and Yinfa Ma, University of Missouri-Rolla ISBN: 1-4292-3892-5 The Instructor’s Solutions Manual contains full, worked-out solutions to all evennumbered exercises. Worked-out solutions for odd-numbered exercises can be found in the Student Study Guide and Solutions Manual. Test Bank by Robert Balahura, University of Guelph, and Mark Benvenuto, University of Detroit Mercy The Test Bank offers over 1400 multiple-choice, fill-in-the-blank, and essay questions, and is available exclusively on the Instructor’s Resource CD. Instructor’s Resource CD ISBN: 1-4292-5808-X To help instructors create their own Web sites and prepare dynamic lectures, the CD contains: • All the illustrations from the text in .jpg files and preformatted PowerPoint slides • All animations, lab videos, and living graphs from the Book Companion Site • All solutions to the end-of-chapter exercises, in editable Microsoft Word files • Diagnostic Test for the Fundamentals sections • The electronic Test Bank, which includes over 1400 multiple-choice, fill-inthe-blank, and essay questions Electronic Instructor Resources Instructors can access valuable teaching tools through www.whfreeman.com/ chemicalprinciples5e. These password-protected resources are designed to enhance lecture presentations, and include all the illustrations from the textbook (in .jpg and PowerPoint format), Lecture PowerPoint slides, Clicker Questions, and more. There’s also a Diagnostic Test for the Fundamentals sections, which allows instructors to determine what their students understand and where they need additional support. Instructors can then make appropriate assignments from the Fundamentals sections. This test includes 5 to 10 problems for each Fundamentals section. 16.98 cis-Platin is an anticancer drug with a structure that can be viewed on the Web site. (a) What is the formula and systematic name for the compound cis-Platin? (b) Draw any isomers that are possible for this compound. Label any isomers that are optically active. (c) What is the coordination geometry of the platinum atom? INSTRUCTOR AND STUDENT SUPPORT We believe a student needs to interact with a concept several times in a variety of scenarios in order to obtain a thorough understanding. With that in mind, W. H. Freeman and Company has developed the most comprehensive student learning package available. • End-of-Chapter Exercises. Selected exercises direct students to use media to solve problems. WebAssign Premium For instructors interested in online homework management, W. H. Freeman and WebAssign have partnered to deliver WebAssign Premium—a comprehensive and flexible suite of resources. Combining the most widely used online homework platform with a wealth of visualization and tutorial resources, WebAssign Premium extends and enhances the classroom experience for instructors and students by combining algorithmically generated versions of selected end-of-chapter questions with a fully interactive eBook at an affordable price. See below for more details, or visit www.webassign.net to sign up for a faculty demo account. LabPartner Chemistry W. H. Freeman’s latest offering in custom lab manuals provides instructors with a diverse and extensive database of experiments published by W. H. Freeman and Hayden-McNeil Publishing—all in an easy-to-use, searchable online system. With the click of a button, instructors can choose from a variety of traditional and inquiry-based labs. LabPartner Chemistry sorts labs in a number of ways, from topic, title, and author, to page count, estimated completion time, and prerequisite knowledge level. Add content on lab techniques and safety, reorder the labs to fit your syllabus, and include your original experiments with ease. Wrap it all up in an array of bindings, formats, and designs. It’s the next step in custom lab publishing—the perfect partner for your course. FOR THE STUDENT Student Study Guide and Solutions Manual by John Krenos and Joseph Potenza, Rutgers University, Laurence Lavelle, University of California, Los Angeles, Yinfa Ma, University of Missouri Rolla, and Carl Hoeger, University of California, San Diego ISBN: 1-4292-3135-1 The Student Study Guide and Solutions Manual provides students with a combined manual designed to help them to improve their problem-solving skills, avoid common mistakes, and understand key concepts. After a brief review of each section’s critical ideas, students are taken through worked-out examples, try-ityourself examples, and chapter quizzes, all structured to reinforce chapter objectives and build problem-solving techniques. The solutions manual includes detailed solutions to all odd-numbered exercises in the text. ACS Molecular Structure Model Set by Maruzen Company, Ltd. ISBN: 0-7167-4822-3 Molecular modeling helps students understand physical and chemical properties by providing a way to visualize the three-dimensional arrangement of atoms. This model set uses polyhedra to represent atoms, and plastic connectors to represent bonds (scaled to correct bond length). Plastic plates representing orbital lobes are included for indicating lone pairs of electrons, radicals, and multiple bonds—a feature unique to this set. Bridging to the Lab by Loretta Jones, University of Northern Colorado, and Roy Tasker, University of Western Sydney ISBN: 0-7167-4746-4 The Bridging to the Lab modules are computer-based laboratory simulations with engaging activities that emphasize experimental design and visualization of structures and processes at the molecular level. The modules are designed to help students connect chemical principles from lecture with their practical applications in the lab. Every module has a built-in accountability feature that PREFACE xix records section completion for use in setting grades and a workbook for recording student work. Used either as pre-laboratory preparation for related laboratory activities or to expose students to additional laboratory activities not available in their program, these modules motivate students to learn by proposing real-life problems in a virtual environment. Students make decisions on experimental design, observe reactions, record data, interpret these data, perform calculations, and draw conclusions from their results. Following a summary of the module, students test their understanding by applying what they have learned to new situations or by analyzing the effect of experimental errors. For more information, visit www.whfreeman.com/bridgingtothelab Chemistry Laboratory Student Notebook, Second Edition ISBN: 0-7167-3900-3 A convenient 8 ϫ 11, 3-hole-punched format contains 114 pages of graph paper, carbon included. The new edition adds tables and graphs that make the Notebook a handy reference as well. PREMIUM MULTIMEDIA RESOURCES The Chemical Principles Book Companion Site, which can be accessed at www.whfreeman.com/chemicalprinciples5e, also contains a plethora of Premium Student Resources. Students can unlock these resources with the click of a button, putting extensive concept and problem-solving support at their fingertips. Some of the resources available are: Toolbox Tutorials present major types of calculations, in an interactive format. They demonstrate the connections between concepts and problem solving and are designed as hands-on learning aids and handy summaries of key materials: ChemCasts replicate the face-to-face experience of watching an instructor work a problem. Using a virtual whiteboard, these video tutors show students the steps involved in solving key worked examples, while explaining the concepts along the way. They are easy to view on a computer screen or download to an iPod. ChemNews from Scientific American provides a streaming newsfeed of the latest articles from Scientific American. The multimedia-enhanced eBook contains the complete text with a wealth of helpful functions. All student multimedia, including the Toolbox Tutorials, ChemCasts, and ChemNews, are linked directly from the eBook pages. Students are thus able to access supporting resources when they need them—taking advantage of the “teachable moment” as they read. Customization functions include instructor and student notes, document linking, and editing capabilities. Online Learning Environments The above resources are available in two platforms. WebAssign Premium offers the most effective and widely used online homework system in the sciences, and is designed specifically for those instructors seeking graded homework management. The Student Companion Web site provides student-oriented support materials independent of any homework system. WEBASSIGN PREMIUM For instructors interested in online homework management, WebAssign Premium features a time-tested, secure online environment already used by millions of students worldwide. Featuring algorithmic problem generation and supported by a 1 ⁄2 xx PREFACE wealth of chemistry-specific learning tools, WebAssign Premium for Chemical Principles, Fifth Edition presents instructors with a powerful assignment manager and study environment. WebAssign Premium provides the following resources: • Algorithmically generated problems: Students receive homework problems containing unique values for computation, encouraging them to work out the problems on their own. • Complete access to the interactive eBook, from a live table of contents, as well as from relevant problem statements. • Links to Toolbox Tutorials, ChemCasts, and other interactive tools are provided as hints and feedback to ensure a clearer understanding of the problems and the concepts they reinforce. STUDENT COMPANION WEB SITE TheChemicalPrinciplesBookCompanionSite,www.whfreeman.com/chemicalprinciples5e, provides a range of tools for problem solving and chemical explorations. They include: • An interactive Periodic Table of the Elements • A calculator adapted for solving equilibrium calculations • Two- and three-dimensional curve plotters • “Living Graphs,” which allow the user to control the parameters • Animations that allow students to visualize chemical events on a molecular level • Diagnostic Test for the Fundamentals sections • Web-based Assessment. An excellent online quizzing bank of multiplechoice questions for each text chapter (not from the test bank). Students receive instant feedback and can take the quizzes multiple times. Instructors can go into a protected Web site to view results by quiz, student, or question, or can get weekly results via e-mail. Excellent for practice testing and/or homework. ACKNOWLEDGMENTS We are grateful to the many instructors, colleagues, and students who have contributed their expertise to this edition. We would like above all to thank those who carefully evaluated the fourth edition and commented on drafts of the fifth edition: PREFACE xxi Yiyan Bai, Houston Community College System Central Campus Maria Ballester, Nova Southeastern University Patricia D. Christie, Massachusetts Institute of Technology Henderson J. Cleaves, II, University of California, San Diego Ivan J. Dmochowski, University of Pennsylvania Ronald Drucker, City College of San Francisco Christian Ekberg, Chalmers University of Technology, Sweden Bryan Enderle, University of California, Davis David Erwin, Rose-Hulman Institute of Technology Justin Fermann, University of Massachusetts Regina F. Frey, Washington University P. Shiv Halasyamani, University of Houston Jameica Hill, Wofford College Alan Jircitano, Penn State, Erie Gert Latzel, Riemerling, Germany Nancy E. Lowmaster, Allegheny College Matthew L. Miller, South Dakota State University Clifford B. Murphy, Boston University Maureen Murphy, Huntingdon College Enrique Peacock-Lopez, Williams College LeRoy Peterson, Jr., Francis Marion University Tyler Rencher, Brigham Young University Michael Samide, Butler University Gordy Savela, Itasca Community College Lori Slavin, College of Saint Catherine Mike Solow, City College of San Francisco John E. Straub, Boston University Laura Stultz, Birmingham-Southern College Peter Summer, Lake Sumter Community College David W. Wright, Vanderbilt University Mamudu Yakubu, Elizabeth City State University Meishan Zhao, University of Chicago xxii PREFACE Thomas Albrecht-Schmidt, Auburn University Matthew Asplund, Brigham Young University Matthew P. Augustine, University of California, Davis David Baker, Delta College Alan L. Balch, University of California, Davis Mario Baur, University of California, Los Angeles Robert K. Bohn, University of Connecticut Paul Braterman, University of North Texas William R. Brennan, University of Pennsylvania Ken Brooks, New Mexico State University Julia R. Burdge, University of Akron Paul Charlesworth, Michigan Technological University Patricia D. Christie, Massachusetts Institute of Technology William Cleaver, University of Vermont David Dalton, Temple University J. M. D’Auria, Simon Fraser University James E. Davis, Harvard University Walter K. Dean, Lawrence Technological University Jimmie Doll, Brown University Ronald Drucker, City College of San Francisco Jetty Duffy-Matzner, State University of New York, Cortland Robert Eierman, University of Wisconsin Kevin L. Evans, Glenville State College Donald D. Fitts, University of Pennsylvania Lawrence Fong, City College of San Francisco Regina F. Frey, Washington University Dennis Gallo, Augustana College David Harris, University of California, Santa Barbara Sheryl Hemkin, Kenyon College Michael Henchman, Brandeis University Geoffrey Herring, University of British Columbia Timothy Hughbanks, Texas A&M University Paul Hunter, Michigan State University Keiko Jacobsen, Tulane University Robert C. Kerber, State University of New York, Stony Brook Robert Kolodny, Armstrong Atlantic State University Lynn Vogel Koplitz, Loyola University Petra van Koppen, University of California, Santa Barbara Mariusz Kozik, Canisius College Julie Ellefson Kuehn, William Rainey Harper College Cynthia LaBrake, University of Texas, Austin Brian B. Laird, University of Kansas Yinfa Ma, University of Missouri-Rolla Paul McCord, University of Texas, Austin Alison McCurdy, Harvey Mudd College Charles W. McLaughlin, University of Nebraska Patricia O’Hara, Amherst College Noel Owen, Brigham Young University Donald Parkhurst, The Walker School Montgomery Pettitt, University of Houston Joseph Potenza, Rutgers University Wallace Pringle, Wesleyan University Philip J. Reid, University of Washington Barbara Sawrey, University of California, San Diego George Schatz, Northwestern University Paula Jean Schlax, Bates College Carl Seliskar, University of Cincinnati Robert Sharp, University of Michigan, Ann Arbor Peter Sheridan, Colgate University Jay Shore, South Dakota State University Herb Silber, San Jose State University Lee G. Sobotka, Washington University Michael Sommer, Harvard University Nanette A. Stevens, Wake Forest University Tim Su, City College of San Francisco Sara Sutcliffe, University of Texas, Austin Larry Thompson, University of Minnesota, Duluth Dino Tinti, University of California, Davis Sidney Toby, Rutgers University David Vandenbout, University of Texas, Austin Deborah Walker, University of Texas, Austin Lindell Ward, Franklin College Thomas R. Webb, Auburn University Peter M. Weber, Brown University David D. Weis, Skidmore College Ken Whitmire, Rice University James Whitten, University of Massachusetts, Lowell Gang Wu, Queen’s University Zhiping Zheng, University of Arizona Marc Zimmer, Connecticut College Martin Zysmilich, Massachusetts Institute of Technology The contributions of the reviewers of the first, second, and third editions remain embedded in the text, so we also wish to renew our thanks to: Some contributed in substantial ways. Leroy Laverman, University of California at Santa Barbara, carefully reviewed the entire text and all the art, leading to considerable improvements. Roy Tasker, University of Western Sydney, contributed to the Web site for this book, designed related animations, and selected the icons for the animation media links. Michael Cann, University of Scranton, opened our eyes to the world of green chemistry in a way that has greatly enriched this book. We would also like to thank Nathan Barrows, Arizona State University, for contributing to the Self-Test answers. The supplements authors, especially John Krenos, Joseph Potenza, Laurence Lavelle, Yinfa Ma, and Carl Hoeger, have offered us PREFACE xxiii much useful advice. Laurence Lavelle, UCLA, and Danielle Scheuhler, Wagner College, provided careful checking of all the solutions. This book also benefited from suggestions made by Dennis Kohl, University of Texas at Austin, Randall Shirts, Brigham Young University, Catherine Murphy, University of South Carolina, Michael Sailor, University of California at San Diego, Matt Miller and Jay Shore, South Dakota State University, and Peter Garik, Rosina Georgiadis, Mort Hoffman, and Dan Dill, Boston University. We are grateful to the staff members at W. H. Freeman and Company, who understood our vision and helped to bring it to fruition. In particular, we would like to acknowledge Jessica Fiorillo, senior chemistry editor, who organized us and the entire project; Randi Rossignol, our developmental editor, who guided us toward important improvements in this edition; Georgia Lee Hadler, senior project editor, who once again took on the awesome task of overseeing the transformation of our files into paper; Margaret Comaskey, our copy editor, who organized and coordinated those files with great care; Bianca Moscatelli, who found exactly the right new photographs; and Dave Quinn, who directed the development and production of the substantial array of print and media supplements. We also thank Jenness Crawford for her help with the supplements and Anthony Petrites and Brittany Murphy for their help shepherding the manuscript into production. The authors could not have wished for a better or more committed team. This page intentionally left blank WELCOME to chemistry! You are about to embark on a remarkable journey that will take you to the center of science. Looking in one direction, toward physics, you will see how the principles of chemistry are based on the behavior of atoms and molecules. Looking in another direction, toward biology, you will see how chemists contribute to an understanding of that most awesome property of matter, life. Eventually, you will be able to look at an everyday object, see in your mind’s eye its composition in terms of atoms, and understand how that composition determines its properties. INTRODUCTION AND ORIENTATION Chemistry is the science of matter and the changes it can undergo. The world of chemistry therefore embraces everything material around us—the stones we stand on, the food we eat, the flesh we are made of, and the silicon in our computers. There is nothing material beyond the reach of chemistry, be it living or dead, vegetable or mineral, on Earth or in a distant star. Chemistry and Society Today’s chemistry is built on centuries of exploration and discovery. In the earliest days of civilization, when the Stone Age gave way to the Bronze Age and then to the Iron Age, people did not realize that they were doing chemistry when they changed the material they found as stones—we would now call them minerals—into metals (Fig. 1). The possession of metals gave them a new power over their environment, and treacherous nature became less brutal. Civilization emerged as skills in transforming materials grew: glass, jewels, coins, ceramics, and, inevitably, weapons became more varied and effective. Art, agriculture, and warfare became more sophisticated. None of this would have happened without chemistry. The development of steel accelerated the profound impact of chemistry on society. Better steel led to the Industrial Revolution, when muscles gave way to steam and giant enterprises could be contemplated. With improved transport and greater output from F1 F U N DA M E N TA L S FIGURE 1 Copper is easily extracted from its ores and was one of the first metals worked. The Bronze Age followed the discovery that adding some tin to copper made the metal harder and stronger. These four bronze swords date from 1250 to 850 BCE, the Late Bronze Age, and are from a collection in the Naturhistorisches Museum, Vienna, Austria. From bottom to top, they are a short sword, an antenna-type sword, a tongue-shaped sword, and a Liptau-type sword. F2 FUNDAMENTALS factories came more extensive trade, and the world became simultaneously a smaller but busier place. None of this would have happened without chemistry. With the twentieth century, and now the twenty-first, came enormous progress in the development of the chemical industry. Chemistry transformed agriculture. Synthetic fertilizers provided the means of feeding the enormous, growing population of the world. Chemistry transformed communication and transportation. Today chemistry provides advanced materials, such as polymers for fabrics, ultrapure silicon for computers, and glass for optical fibers. It is producing more efficient renewable fuels and the tough, light alloys that are needed for modern aircraft and space travel. Chemistry has transformed medicine, substantially extended life expectancy, and has provided the foundations of genetic engineering. The deep understanding of life that we are developing through molecular biology is currently one of the most vibrant areas of science. None of this progress would have been achieved without chemistry. However, the price of all these benefits has been high. The rapid growth of industry and agriculture, for instance, has stressed the Earth and damaged our inheritance. There is now widespread concern about the preservation of our extraordinary planet. It will be up to you and your contemporaries to draw on chemistry—in whatever career you choose—to build on what has already been achieved. Perhaps you will help to start a new phase of civilization based on new materials, just as semiconductors transformed society in the twentieth century. Perhaps you will help to reduce the harshness of the impact of progress on our environment. To do that, you will need chemistry. Chemistry: A Science at Three Levels Chemistry can be understood at three levels. At one level, chemistry is about matter and its transformations. This is the level at which we can actually see the changes, as when a fuel burns, a leaf changes color in the fall (Fig. 2), or magnesium burns brightly in air (Fig. 3). This level is the macroscopic level, the level dealing with the properties of large, visible objects. However, there is an underworld of change, a world that we cannot see directly. At this deeper microscopic level, chemistry interprets these phenomena in terms of the rearrangements of atoms (Fig. 4). The third level is the symbolic level, the expression of chemical phenomena in terms of chemical symbols and mathematical equations. This level ties the other two levels together. A chemist thinks at the microscopic level, conducts experiments at the macroscopic level, and represents both symbolically. We can map these three aspects of chemistry as a triangle (Fig. 5). As you read further in this text, you will find that sometimes the topics and explanations are close to one vertex of the triangle, sometimes to another. Because it is helpful in understanding chemistry to make connections among these levels, in the worked examples in this book you will find drawings of the molecular level as well as graphical interpretations of equations. As your understanding of chemistry grows so will your ability to travel easily within the triangle as you connect, for example, a laboratory observation to the symbols on a page and to mental images of atoms and molecules. How Science Is Done Scientists pursue ideas in an ill-defined but effective way often called the scientific method. There is no strict rule of procedure that leads you from a good idea to a Nobel prize or even to a publishable discovery. Some scientists are meticulously careful, others are highly creative. The best scientists are probably both careful and creative. Although there are various scientific methods in use, a typical approach consists of a series of steps (Fig. 6). The first step is often to collect data by making observations and measurements. These measurements are usually made on small samples of matter, representative pieces of the material that we want to study. Scientists are always on the lookout for patterns. When a pattern is observed in the data, it can be stated as a scientific law, a succinct summary of a wide range of observations. For example, water was found to have eight times the mass of oxygen as it has of hydrogen, regardless of the source of the water or the size of the sample. One FIGURE 2 Cold weather triggers chemical processes that reduce the amount of the green chlorophyll in leaves, allowing the colors of various other pigments to show. FIGURE 3 When magnesium burns in air, it gives off a lot of heat and light. The gray-white powdery product looks like smoke. Lab Video 3 FUNDAMENTALS HOW SCIENCE IS DONE F3 of the earliest laws of chemistry summarized those types of observations as the “law of constant composition,” which states that a compound has the same composition regardless of the source of the sample. Formulating a law is just one way, not the only way, of summarizing data. There are many properties of matter (such as superconductivity, the ability of a few cold solids to conduct electricity without any resistance) that are currently at the forefront of research but are not described by grand “laws” that embrace hundreds of different compounds. A major current puzzle, which might be resolved in the future either by finding the appropriate law or by detailed individual computation, is what determines the shapes of protein molecules such as those that govern almost every aspect of life, including serious diseases such as Alzheimer’s, Parkinson’s, and cancer. Once they have detected patterns, scientists may develop hypotheses, possible explanations of the laws—or the observations—in terms of more fundamental concepts. Observation requires careful attention to detail, but the development of a hypothesis requires insight, imagination, and creativity. In 1807, John Dalton interpreted experimental results to propose the hypothesis that matter consists of atoms. Although Dalton could not see individual atoms, he was able to imagine them and formulate his atomic hypothesis. Dalton’s hypothesis was a monumental insight that helped others understand the world in a new way. The process of scientific discovery never stops. With luck and application, you may acquire that kind of insight as you read through this text, and one day you may make your own extraordinary and significant hypotheses. After formulating a hypothesis, scientists design further experiments—carefully controlled tests—to verify it. Designing and conducting good experiments often requires ingenuity and sometimes good luck. If the results of repeated experiments— often in other laboratories and sometimes by skeptical coworkers—support the hypothesis, scientists may go on to formulate a theory, a formal explanation of a law. Quite often the theory is expressed mathematically. A theory originally envisioned as a qualitative concept, a concept expressed in words or pictures, is converted into a quantitative form, the same concept expressed in terms of mathematics. After a concept has been expressed quantitatively, it can be used to make numerical predictions and is subjected to rigorous experimental confirmation. You will have plenty of practice with the quantitative aspect of chemistry while working through this text. Magnesium Magnesium oxide Oxygen Magnesium Macroscopic Microscopic Symbolic Hypothesis Law Theory Hypothesis not supported Hypothesis supported Model Insight Sample Experiments Data Identify pattern Propose explanation Verify Interpret FIGURE 4 When a chemical reaction takes place, atoms exchange partners, as in Fig. 3 where magnesium and oxygen atoms form magnesium oxide. As a result, two forms of matter (left inset) are changed into another form of matter (right inset). Atoms are neither created nor destroyed in chemical reactions. FIGURE 6 A summary of the principal activities in a common version of the scientific method. The ideas proposed must be tested and possibly revised at each stage. FIGURE 5 This triangle illustrates the three modes of scientific inquiry used in chemistry: macroscopic, microscopic, and symbolic. Sometimes we work more at one corner than at the others, but it is important to be able to move from one approach to another inside the triangle. The postulates of Dalton’s atomic hypothesis are described in Section B. F4 FUNDAMENTALS Scientists commonly interpret a theory in terms of a model, a simplified version of the object of study that they can use to make predictions. Like hypotheses, theories and models must be subjected to experiment and revised if experimental results do not support them. For example, our current model of the atom has gone through many formulations and progressive revisions, starting from Dalton’s vision of an atom as an uncuttable solid sphere to our current much more detailed model, which is described in Chapter 1. One of the main goals of this text is to show you how to build models, turn them into a testable form, and then refine them in the light of additional evidence. The Branches of Chemistry Chemistry is more than test tubes and beakers. New technologies have transformed chemistry dramatically in the past 50 years, and new areas of research have emerged (Fig. 7). Traditionally, the field of chemistry has been organized into three main branches: organic chemistry, the study of compounds of carbon; inorganic chemistry, the study of all the other elements and their compounds; and physical chemistry, the study of the principles of chemistry. New regions of study have developed as information has been acquired in specialized areas or as a result of the use of particular techniques. It is the nature of a vigorously developing science that the distinctions between its branches are not clear-cut, but nevertheless we still speak of biochemistry, the study of the chemical compounds, reactions, and other processes in living systems; analytical chemistry, the study of techniques for identifying substances and measuring their amounts; theoretical chemistry, the study of molecular structure and properties in terms of mathematical models; computational chemistry, the computation of molecular properties; chemical engineering, the study and design of industrial chemical processes, including the fabrication of manufacturing plants and their operation; medicinal chemistry, the application of chemical principles to the development of pharmaceuticals; and biological chemistry, the application of chemical principles to biological structures and processes. Various interdisciplinary branches of knowledge with roots in chemistry have arisen, including: molecular biology, the study of the chemical and physical basis of biological function and diversity, especially in relation to genes and proteins; materials science, the study of the chemical structure and composition of materials; and nanotechnology, the study of matter at the nanometer level, where structures consisting of small number of atoms can be manipulated. A newly emerging concern of chemistry is sustainable development, the economical utilization and renewal of resources coupled with hazardous waste reduction and concern for the environment. This sensitive approach to the environment and our planetary inheritance is known colloquially as green chemistry. Where we think it is appropriate to draw your attention to this important development, we display the small icon shown here. All sciences, medicine, and many fields of commercial activity draw on chemistry. You can be confident that whatever career you choose in a scientific or technical field, it will make use of the concepts discussed in this text. Chemistry is truly central to science. Mastering Chemistry The following lettered sections summarize the basic information that you need to begin your chemistry course. You might already have a strong background in chemistry. FIGURE 7 Scientific research today often requires sophisticated equipment and computers. This chemist is using an Auger electron spectrometer to probe the surface of a crystal. The data collected will allow the chemist to determine which elements are present in the surface. FUNDAMENTALS A.1 PHYSICAL PROPERTIES F5 These green-bordered introductory pages will provide you with a summary of a number of basic concepts and techniques. Your instructor will advise you on how to use these sections to prepare yourself for the chapters in the text itself. If you have done little chemistry before, these pages are for you, too. They contain a brief but systematic summary of the basic concepts and calculations of chemistry that you should know before studying the chapters in the text. You can return to them as needed. If you need to review the mathematics required for chemistry, especially algebra and logarithms, Appendix 1 has a brief review of the important procedures. A MATTER AND ENERGY Whenever we touch, pour, or weigh something, we are working with matter. Chemistry is concerned with the properties of matter and particularly the conversion of one form of matter into another kind. But what is matter? Matter is in fact difficult to define precisely without drawing on advanced ideas from elementary particle physics, but a straightforward working definition is that matter is anything that has mass and takes up space. Thus, gold, water, and flesh are forms of matter; electromagnetic radiation (which includes light) and justice are not. One characteristic of science is that it uses common words from our everyday language but gives them a precise meaning. In everyday language, a “substance” is just another name for matter. However, in chemistry, a substance is a single, pure form of matter. Thus, gold and water are distinct substances. Flesh is a mixture of many different substances, and, in the technical sense used in chemistry, it is not a “substance.” Air is matter; but, being a mixture of several gases, it is not a single substance. Substances, and matter in general, come in different forms, called states of matter. The three most common states of matter are solid, liquid, and gas: A solid is a form of matter that retains its shape and does not flow. A liquid is a fluid form of matter that has a well-defined surface; it takes the shape of the part of the container it occupies. A gas is a fluid form of matter that fills any vessel containing it. The term vapor denotes the gaseous form of a substance that is normally a solid or liquid. Thus, we speak of ice (the solid form of water), liquid water, and water vapor (steam). Figure A.1 shows how the states of matter can be distinguished by the arrangements and motions of atoms and molecules. In a solid, such as ice or copper metal, the atoms are packed together closely, and the solid is rigid because the atoms cannot move past one another. However, the atoms in a solid are not motionless: they oscillate around their average locations, and the oscillation becomes more vigorous as the temperature is raised. The atoms (and molecules) of a liquid are packed together about as closely as they are in a solid, but they have enough energy to move past one another. As a result, a liquid, such as water or molten copper, flows in response to a force, such as gravity. In a gas, such as air (which is mostly nitrogen and oxygen) and water vapor, the molecules have achieved almost complete freedom from one another: they fly through empty space at close to the speed of sound, colliding when they meet and immediately flying off in another direction. A.1 Physical Properties Chemistry is concerned with the properties of matter, its distinguishing characteristics. A physical property of a substance is a characteristic that we can observe or measure without changing the identity of the substance. For example, a physical property of a sample of water is its mass; another is its temperature. Physical properties include characteristics such as melting point (the temperature at which a solid turns into a liquid), hardness, color, state of matter (solid, liquid, or gas), and density. A chemical property A.1 Physical Properties A.2 Force A.3 Energy (a) (b) (c) FIGURE A.1 A molecular representation of the three states of matter. In each case, the spheres represent particles that may be atoms, molecules, or ions. (a) In a solid, the particles are packed tightly together and held in place, but continue to oscillate. (b) In a liquid, the particles are in contact, but have enough energy to move past one another. (c) In a gas, the particles are far apart, move almost completely freely, and are in ceaseless random motion. F6 FUNDAMENTALS refers to the ability of a substance to be changed into another substance. For example, a chemical property of the gas hydrogen is that it reacts with (burns in) oxygen to produce water; a chemical property of the metal zinc is that it reacts with acids to produce hydrogen gas. When a substance undergoes a physical change, the identity of the substance does not change, only its physical properties are different. For example, when water freezes, the solid ice is still water. However, when a substance undergoes a chemical change, it is transformed into a different substance altogether. In this section we review some important physical properties of matter. Each physical quantity is represented by an italic or sloping Greek symbol (thus, m for mass, not m). The results of a measurement, the “value” of a physical quantity, is reported as a multiple of a unit, such as reporting a mass as 15 kilograms, which is understood to be 15 times the unit “1 kilogram.” Scientists have reached international agreement on the units to use when reporting measurements, so their results can be used with confidence and checked by people anywhere in the world. You will find most of the symbols used in this textbook together with their units in Appendix 1. A note on good practice: All units are denoted by Roman letters, such as m for meter and s for second, that distinguish them from the physical quantity to which they refer (such as l for length and t for time). The Système International (SI) is the internationally accepted form and elaboration of the metric system. It defines seven base units in terms of which all physical quantities can be expressed. At this stage all we need are: meter, m The meter, the unit of length kilogram, kg The kilogram, the unit of mass second, s The second, the unit of time All the units are defined in Appendix 1B. Each unit may be modified by a prefix. The full set is given in Appendix 1B; some common examples are: Prefix Symbol Factor Example centi- c 1/100 1 cm ϭ 1/100 m (1 centimeter) milli- m 1/1000 1 ms ϭ 1/1000 s (1 millisecond) kilo- k 1000 1 km ϭ 1000 m (1 kilometer) Units may be combined together into derived units to express a property more complicated than mass, length, or time. For example, volume, V, the amount of space occupied by a substance, is the product of three lengths; therefore, the derived unit of volume is (meter)3 , denoted m3 . Similarly, density, the mass of a sample divided by its volume, is a derived unit expressed in terms of the base unit for mass divided by the derived unit for volume—namely, kilogram/(meter)3 , denoted kg/m3 or, equivalently, kgиmϪ3 . A note on good practice: The SI convention is that a power, such as the 3 in cm3 , refers to the unit and its multiple. That is, cm3 should be interpreted as (cm)3 or 10Ϫ6 m3 not as c(m3 ), or 10Ϫ2 m3 . It is often necessary to convert measurements from another set of units into SI units. For example, we may need to convert a length measured in inches into centimeters. To convert these units, we use the relation 1 in. ϭ 2.54 cm, and in general, Relations between common units can be found in Table 5 of Appendix 1B. We use these relations to construct a conversion factor of the form Conversion factor = units required units given Units given = unit required FUNDAMENTALS A.1 PHYSICAL PROPERTIES F7 Then we use it as follows: Information required ϭ information given ϫ conversion factor When using a conversion factor, we treat the units just like algebraic quantities: they are multiplied or canceled in the normal way. EXAMPLE A.1 Converting units Suppose you are in a store—perhaps in Canada or Europe—where paint is sold only in liters. You know you need 1.7 qt of a particular paint. What is that volume in liters? Anticipate It is useful to remember that 1 L is slightly more than 1 qt, so we should expect a volume of slightly less than 1.7 L. PLAN Identify the relation between the two units from Table 5 of Appendix 1B: 1 qt ϭ 0.946 352 5 L Then set up the conversion factor from the units given (qt) to the units required (L). SOLVE Required Given ϫ ϭ Answers to all B self-tests are in the back of this book. Form the conversion factor as (units required)/(units given). Conversion factor = 0.946 352 5 L 1 qt Convert the measurement into the required units. Volume1L2 = 11.7 qt2 * 0.946 352 5 L 1 qt = 1.6 L Evaluate As expected, we need slightly less than 1.7 L. We have rounded the answer to two significant figures, as explained below. Self-Test A.1A Express the height of a person 6.00 ft tall in centimeters. [Answer: 183 cm] Self-Test A.1B Express the mass in ounces of a 250.-g package of breakfast cereal. It is often necessary to convert a unit that is raised to a power (including negative powers). In such cases, the conversion factor is raised to the same power. For example, to convert a density of 11 700 kgиm–3 into grams per centimeter cubed (gиcmϪ3 ), we use the two relations 1 kg ϭ 103 g and 1 cm ϭ 10Ϫ2 m as follows: = 11.7 g cm3 = 11.7 gиcm-3 = (11 700 kgиm-3 ) * 103 g 1 kg * 10-6 m3 1 cm3 Density (gиcm-3 ) = (11 700 kgиm-3 ) * 103 g 1 kg * a 1 cm 10-2 m b -3 F8 FUNDAMENTALS A note on good practice: Units are treated like algebraic quantities and are multiplied and canceled just like numbers. For example, in the second line of this calculation we used the relation Self-Test A.2A Express a density of 6.5 gиmmϪ3 in micrograms per nanometer cubed (␮gиnmϪ3 ). [Answer: 6.5 ϫ 10Ϫ12 ␮gиnmϪ3 ] Self-Test A.2B Express an acceleration of 9.81 mиsϪ2 in kilometers per hour squared. Properties can be classified according to their dependence on the size of a sample. An extensive property is a property that does depend on the size (“extent”) of the sample. More precisely, if a system is divided into parts and it is found that the property of the complete system has a value that is the sum of the values of the property of all the parts, then that property is extensive. If that is not the case, then the property is intensive. In short, an intensive property is independent of the size of the sample. Volume is an extensive property: 2 kg of water occupies twice the volume of 1 kg of water. Temperature is an intensive property, because we can take a sample of any size from a uniform bath of water and measure the same temperature (Fig. A.2). The importance of the distinction is that we identify different substances by their intensive properties. Thus, we might recognize a sample as water by noting its color, density (1.00 gиcmϪ3 ), melting point (0°C), boiling point (100°C), and the fact that it is a liquid. Some intensive properties are ratios of two extensive properties. For example, the density, d, mentioned above, is a ratio of the mass, m, of a sample divided by its volume, V: (1) The density of a substance is independent of the size of the sample because doubling the volume also doubles the mass; so the ratio of mass to volume remains the same. Density is therefore an intensive property. We have to be aware that most properties depend on the state of matter and the conditions, such as the temperature and pressure. For example, the density of water at 0°C is 1.00 gиcmϪ3 but at 100°C it is 0.96 gиcmϪ3 . The density of ice at 0°C is 0.92 gиcmϪ3 and the density of water vapor at 100°C and atmospheric pressure is nearly 2000 times less, at 0.59 gиLϪ1 . Water is unusual in expanding slightly when it freezes to ice, so ice is less dense than water at 0°C: most substances contract slightly and become more dense as they freeze. Units for physical quantities and temperature scales are discussed in Appendix 1B. Density = mass volume or d = m V a 1 cm 10-2 m b -3 = a 10-2 m 1 cm b 3 = 10-6 m3 1 cm3 FIGURE A.2 Mass is an extensive property, but temperature is intensive. These two samples of iron(II) sulfate solution were taken from the same wellmixed supply: they have different masses but the same temperature. EXAMPLE A.2 Calculating the volume of a sample What is the volume occupied by 5.0 g of solid silver, given the density listed in Appendix 2D? Anticipate In Appendix 2D, we see that most metals have densities in the range 5 to 20 gиcmϪ3 , with many close to 10 gиcmϪ3 . Therefore, we should expect a mass of 1 g to correspond to a volume of about 0.1 cm3 . For 5 g, we should expect an answer close to 0.5 cm3 . PLAN We rearrange Eq. 1 into V ϭ m/d, and then substitute the data. SOLVE The density of silver is listed in Appendix 2D as 10.50 gиcmϪ3 ; so the volume of 5.0 g of solid silver is 0.78 cm 5.0 g From V ϭ m/d, V = 5.0 g 10.50 gиcm-3 = 5.0 10.50 cm3 = 0.48 cm3 FIGURE A.3 The holes in these targets represent measurements that are (a) precise and accurate, (b) precise but inaccurate, (c) imprecise but accurate on average, and (d) both imprecise and inaccurate. FUNDAMENTALS A.2 FORCE F9 Evaluate The volume calculated, 0.48 cm3 , is close to what we expected. Self-Test A.3A The density of selenium is 4.79 gиcmϪ3 . What is the mass of 6.5 cm3 of selenium? [Answer: 31 g] Self-Test A.3B The density of helium gas at 0°C and 1.00 atm is 0.176 85 gиLϪ1 . What is the volume of a balloon containing 10.0 g of helium under the same conditions? All measured quantities have some uncertainty associated with them; in science it is important to convey the degree to which we are certain of not only the values we report but also the results of calculations using those values. Notice that in Example A.2 we wrote the result of dividing 5.0 by 10.50 as 0.48, not 0.47619. The number of digits reported in the result of a calculation must reflect the number of digits in the data provided. The number of significant figures in a numerical value is the number of digits that can be justified by the data. Thus, the measurement 5.0 g has two significant figures (2 sf) and 10.50 gиcmϪ3 has four (4 sf). The number of significant figures in the result of a calculation cannot exceed the number in the data (you can’t generate reliability on a calculator!), so in Example A.2 we limited the result to 2 sf, the lower number of significant figures in the data. The full rules for counting the number of significant figures and determining the number of significant figures in the result of a calculation are given in Appendix 1C, together with the rules for rounding numerical values. An ambiguity may arise when dealing with a whole number ending in a zero, because the number of significant figures in the number may be less than the number of digits. For example, 400 could have 1, 2, or 3 sf. To avoid ambiguity, in this book when all the digits in a number ending in zero are significant, the number is followed by a decimal point. Thus, the number 400. has 3 sf. When scientists measure the properties of a substance, they monitor and report the accuracy and precision of the data. To make sure of their data, scientists usually repeat their measurements several times. The precision of a measurement is reflected in the number of significant figures justified by the procedure and depends on how close repeated measurements are to one another. The accuracy of a series of measurements is the closeness of their average value to the true value. The illustration in Fig. A.3 distinguishes precision from accuracy. As the illustration suggests, even precise measurements can give inaccurate values. For instance, if there is an unnoticed speck of dust on the pan of a chemical balance that we are using to measure the mass of a sample of silver, then even though we might be justified in reporting our measurements to five significant figures (such as 5.0450 g), the reported mass of the sample will be inaccurate. More often than not, measurements are accompanied by two kinds of error. A systematic error is an error present in every one of a series of repeated measurements. An example is the effect of a speck of dust on a pan, which distorts the mass of each sample in the same direction (the speck makes each sample appear heavier than it is). A random error is an error that varies at random and can average to zero over a series of observations. An example is the effect of drafts of air from an open window moving a balance pan either up or down a little, decreasing or increasing the mass measurements randomly. Scientists attempt to minimize random error by making many observations and taking the average of the results. Systematic errors are much harder to identify. Thinking point: What are some means that scientists can use to identify and eliminate systematic errors? Physical properties are those that do not involve changing the identity of a substance. Chemical properties are those that involve changing the identity of a substance. Extensive properties depend on the mass of the sample; intensive properties do not. The precision of a measurement is an indication of how close together repeated measurements are; the accuracy of a measurement is its closeness to the true value. A.2 Force A force, F, is an influence that changes the state of motion of an object. For instance, we exert a force to open a door—to start the door swinging open—and we exert a force (a) (b) (c) (d) F10 FUNDAMENTALS on a ball when we hit it with a bat. According to Newton’s second law of motion, when an object experiences a force, it is accelerated. The acceleration, a, of the object, the rate of change of its velocity, is proportional to the force that it experiences: The constant of proportionality between the force and the acceleration it produces is the mass, m, of the object experiencing the force: Force ϭ mass ϫ acceleration, or F ϭ ma (2) This expression, in the form a ϭ F/m, tells us that a stronger force is required to accelerate a heavy object by a given amount than to accelerate a lighter object by the same amount. Velocity, the rate of change of position, has both magnitude and direction; so, when a force acts, it can change the magnitude alone, the direction alone, or both simultaneously (Fig. A.4). The magnitude of the velocity of an object—the rate of change of position regardless of the direction of the motion—is called its speed, v. When we accelerate a car in a straight line, we change its speed, but not its direction, by applying a force through the rotation of the wheels and their contact with the road. To stop a car, we apply a force that opposes the motion. However, a force can also act without changing the speed: if a body is forced to travel in a different direction at the same speed, it undergoes acceleration because velocity includes direction as well as magnitude. For example, when a ball bounces on the floor, the force exerted by the floor reverses the ball’s direction of travel without affecting its speed very much. Forces important in chemistry include the electrostatic forces of attraction and repulsion between charged particles and the weaker forces between molecules. Atomic nuclei exert forces on the electrons that surround them, and it takes energy to move those electrons from one place to another in a molecule. Rather than considering the forces directly, chemists normally focus on the energy needed to overcome them. One major exception, discussed in Major Technique 1, following Chapter 2, is in the vibrations of molecules, where atoms in bonds behave as though they are joined by springs that exert forces when the bonds are stretched and compressed. Acceleration, the rate of change of velocity, is proportional to applied force. A.3 Energy Some chemical changes give off a lot of energy (Fig. A.5); others absorb energy. An understanding of the role of energy is the key to understanding chemical phenomena and the structures of atoms and molecules. But just what is energy? The word energy is so common in everyday language that most people have a general sense of what it means; however, to get a technical answer to this question, we would have to delve into the theory of relativity, which is far beyond the scope of this book. In chemistry, we use a practical definition of energy as the capacity to do work, with work defined as motion against an opposing force, Energy ϭ force ϫ distance Thus, energy is needed to do the work of raising a weight a given height or the work of forcing an electric current through a circuit. The greater the energy of an object, the greater its capacity to do work. The SI unit for energy is the joule (J). As explained in Appendix 1B, 1 J ϭ 1 kgиm2 иsϪ2 Each beat of the human heart uses about 1 J of energy, and to raise this book (of mass close to 2.0 kg) from the floor to a tabletop about 0.97 m above the floor requires about 19 J (Fig. A.6). Because energy changes in chemical reactions tend to be of the order of thousands of joules for the amounts usually studied, it is more common in chemistry to use the kilojoule (kJ, where 1 kJ ϭ 103 J). A note on good practice: Names of units derived from the names of people are always lower case (as for joule, named for the scientist J. P. Joule), but their abbreviations are always uppercase (as in J for joule). Acceleration r force, or a r F FIGURE A.4 (a) When a force acts along the direction of travel, the speed (the magnitude of the velocity) changes, but the direction of motion does not. (b) The direction of travel can be changed without affecting the speed if the force is applied in an appropriate direction. Both changes in velocity correspond to acceleration. (a) (b) FIGURE A.5 When bromine is poured on red phosphorus, a chemical change takes place in which a lot of energy is released as heat and light. Lab Video A.5 The joule is named for James Joule, the nineteenth-century English scientist who made many contributions to the study of heat. FUNDAMENTALS A.3 ENERGY F11 There are three contributions to energy: kinetic energy, potential energy, and electromagnetic energy. Kinetic energy, Ek, is the energy that a body possesses due to its motion. For a body of mass m traveling at a speed v, the kinetic energy is (3)* A heavy body traveling rapidly has a high kinetic energy. A body at rest (stationary, v ϭ 0) has zero kinetic energy. Ek = 1 2 mv2 Potential energy is also commonly denoted V. A field is a region where a force acts. This formula applies only to objects close to the surface of the Earth. EXAMPLE A.3 Calculating kinetic energy How much energy does it take to accelerate a person and a bicycle of total mass 75 kg to 20. mph (8.9 mиsϪ1 ), starting from rest and ignoring friction and wind resistance? PLAN We need to decide how much energy must be supplied to reach the kinetic energy of the cyclist corresponding to the final speed. SOLVE 75 kg 3.0 kJ 8.9 m·sϪ1 EXAMPLE A.4 Calculating the gravitational potential energy Someone of mass 65 kg walks up a flight of stairs between two floors of a building that are separated by 3.0 m. What is the change in potential energy of the person? From = 3.0 * 103 kgиm2 иs-2 = 3.0 kJ Ek = 1 2 * (75 kg) * (8.9 mиs-1 )2 Ek = 1 2 mv2 , Evaluate We see that a minimum of 3.0 kJ is needed. More energy is needed to achieve that speed when friction and wind resistance are taken into account. Self-Test A.4A Calculate the kinetic energy of a ball of mass 0.050 kg traveling at 25 mиsϪ1 . [Answer: 16 J] Self-Test A.4B Calculate the kinetic energy of a 1.5-kg book just before it lands on your foot after falling off a table, when it is traveling at 3.0 mиsϪ1 . The potential energy, Ep, of an object is the energy that it possesses on account of its position in a field of force. There is no single formula for the potential energy of an object, because the potential energy depends on the nature of the forces that it experiences. However, two simple cases are important in chemistry: gravitational potential energy (for a particle in a gravitational field) and Coulomb potential energy (for a charged particle in an electrostatic field). A body of mass m at a height h above the surface of the Earth has a gravitational potential energy Ep ϭ mgh (4)* relative to its potential energy on the surface itself (Fig. A.7), where g is the acceleration of free fall (and, commonly, the “acceleration of gravity”). The value of g depends on where we are on the Earth, but in most typical locations g has close to its “standard value” of 9.81 mиsϪ2 , and we shall use this value in all calculations. Equation 4 shows that the greater the altitude of an object, the greater is its gravitational potential energy. For instance, when we raise this book from the floor to the table against the opposing force of gravity, we have done work on the book and its potential energy is increased. A note on good practice: You will sometimes see kinetic energy denoted KE and potential energy denoted PE. Modern practice is to denote all physical quantities by a single letter (accompanied, if necessary, by subscripts). CHEMISTRY CCHEMCHEMCHEMCHEMCHEMCHEMCHEMCHEMCHEM STSTRSTRISTRISTRISTRISTRISTRISTRISTRYYYYYYYYYCHEMISTRY 0.97 m 2.0 kg Potential energy 0 19 J FIGURE A.6 The energy required to raise the book that you are now reading from floor to tabletop is approximately 19 J. The same energy would be released if the book fell from tabletop to floor. FIGURE A.7 The potential energy of a mass m in a gravitational field is proportional to its height h above a point (here, the surface of the Earth), which is taken to correspond to zero potential energy. Mass, m Height,h Potential energy 0 mgh ()*(')'* k J A star next to an equation number signals that it appears in the list of Key Equations on the Web site for this book: www.whfreeman.com/ chemicalprinciples5e. F12 FUNDAMENTALS PLAN To calculate the change, we suppose that the potential energy of the person on the lower floor is zero, then calculate the potential energy at the height of the upper floor. SOLVE The potential energy of the person on the upper floor relative to that on the lower floor is FIGURE A.9 An electromagnetic field oscillates in time and space. The magnetic field (shown in blue) is perpendicular to the electric field (shown in red). The length of an arrow at any point represents the strength of the field at that point, and its orientation denotes its direction. Both fields are perpendicular to the direction of travel of the radiation. 0 Potentialenergy,Ep Separation, r FIGURE A.8 The variation of the Coulomb potential energy of two opposite charges (one represented by the red circle, the other by the green circle) with their separation. Notice that the potential energy decreases as the charges approach each other. Electric field Magnetic field From Ep ϭ mgh, = 1.9 * 103 kgиm2 иs-2 = 1.9 kJ Ep = (65 kg) * (9.81 mиs-2 ) * (3.0 m) 3.0 m ϩ1.9 kJ Self-Test A.5A What is the gravitational potential energy of this book (mass 1.5 kg) when it is on a table of height 0.82 m relative to its potential energy when it is on the floor? [Answer: 12 J] Self-Test A.5B How much energy has to be expended to raise a can of soda (mass 0.350 kg) to the top of the Sears Tower in Chicago (height 443 m)? The energy due to attractions and repulsions between electric charges is of great importance in chemistry, which deals with electrons, atomic nuclei, and ions, all of which are charged. The Coulomb potential energy of a particle of charge Q1 at a distance r from another particle of charge Q2 is proportional to the two charges and inversely proportional to the distance between them: (5)* In this expression, which applies when the two charges are separated by a vacuum, (epsilon zero) is a fundamental constant called the “vacuum permittivity”; its value is 8.854 ϫ 10Ϫ12 JϪ1 иC2 иmϪ1 . The Coulomb potential energy is obtained in joules when the charges are in coulombs (C, the SI unit of charge) and their separation is in meters (m). The charge on an electron is Ϫe, with e ϭ 1.602 ϫ 10Ϫ19 C, the “fundamental charge.” What does this equation tell us? The Coulomb potential energy approaches zero as the distance between two particles approaches infinity. If the particles have the same charge— if they are two electrons, for instance—then the numerator Q1Q2, and therefore Ep itself, is positive, and the potential energy rises (becomes more strongly positive) as the particles approach each other (r decreases). If the particles have opposite charges—an electron and an atomic nucleus, for instance—then the numerator, and therefore Ep, is negative and the potential energy decreases (in this case, becomes more negative) as the separation of the particles decreases (Fig. A.8). What we have termed “electromagnetic energy” is the energy of the electromagnetic field, such as the energy carried through space by radio waves, light waves, and x-rays (very high energy electromagnetic radiation). An electromagnetic field is generated by the acceleration of charged particles and consists of an oscillating electric field and an oscillating magnetic field (Fig. A.9). The crucial distinction is that an electric field affects charged particles whether they are still or moving, whereas a magnetic field affects only moving charged particles. The total energy, E, of a particle is the sum of its kinetic and potential energies: Total energy ϭ kinetic energy ϩ potential energy, or E ϭ Ek ϩ Ep (6)* A very important feature of the total energy of an object is that, provided there are no outside influences, it is constant. We summarize this observation by saying that energy is conserved. Kinetic energy and potential energy can change into each other, but their sum for a given object, whether as large as a planet or as tiny as an atom, is constant. ε0 Ep = Q1Q2 4␲ε0r FUNDAMENTALS EXERCISES F13 For instance, a ball thrown up into the air initially has high kinetic energy and zero potential energy. At the top of its flight, it has zero kinetic energy and high potential energy. However, as it returns to Earth, its kinetic energy rises and its potential energy approaches zero again. At each stage, its total energy is the same as it was when it was initially launched (Fig. A.10). When it strikes the Earth, the ball is no longer isolated, and its energy is dissipated as thermal motion, the chaotic, random motion of atoms and molecules. If we added up all the kinetic and potential energies, we would find that the total energy of the Earth had increased by exactly the same amount as that lost by the ball. No one has ever observed any exception to the law of conservation of energy, the observation that energy can be neither created nor destroyed. One region of the universe—an individual atom, for instance—can lose energy, but another region must gain that energy. Chemists often refer to two other kinds of energy. The term chemical energy is used to refer to the change in energy when a chemical reaction takes place, as in the combustion of a fuel. “Chemical energy” is not a special form of energy: it is simply a shorthand name for the sum of the potential and kinetic energies of the substances participating in the reaction, including the potential and kinetic energies of their electrons. The term thermal energy is another shorthand term. In this case it is shorthand for the sum of the potential and kinetic energies arising from the thermal motion of atoms, ions, and molecules. Kinetic energy results from motion, potential energy from position. An electromagnetic field carries energy through space; work is motion against an opposing force. Energy and mass are equivalent and can be interconverted; Einstein deduced that E ϭ mc2 , where c is the speed of light. A.1 Classify the following properties as chemical or physical: (a) objects made of silver become tarnished; (b) the red color of rubies is due to the presence of chromium ions; (c) the boiling point of ethanol is 78°C. A.2 A chemist investigates the density, melting point, and flammability of acetone, a component of fingernail polish remover. Which of these properties are physical properties and which are chemical properties? A.3 Identify all the physical properties and changes in the following statement: “The camp nurse measured the temperature of the injured camper and ignited a propane burner; when the water began to boil some of the water vapor condensed on the cold window.” A.4 Identify all the chemical properties and changes in the following statement: “Copper is a red-brown element obtained from copper sulfide ores by heating them in air, which forms copper oxide. Heating the copper oxide with carbon produces impure copper, which is purified by electrolysis.” A.5 In the containers below, the green spheres represent atoms of one element, the red spheres the atoms of a second element. In each case, the pictures show either a physical or chemical change; identify the type of change. EXERCISES FIGURE A.10 Kinetic energy (represented by the height of the light green bar) and potential energy (the dark blue-green bar) are interconvertible, but their sum (the total height of the bar) is a constant in the absence of external influences, such as air resistance. A ball thrown up from the ground loses kinetic energy as it slows, but gains potential energy. The reverse happens as it falls back to Earth. Potentialenergy,EpKineticenergy,Ek Totalenergy,E (a) (b) (c) ❑ 1 Identify properties as chemical or physical, intensive or extensive. ❑ 2 Use the density of a substance in calculations (Example A.1). ❑ 3 Calculate the kinetic energy of an object (Example A.2). ❑ 4 Calculate the gravitational potential energy of an object (Example A.3). ❑ 5 Distinguish the different forms of energy described in this section. SKILLS YOU SHOULD HAVE MASTERED F14 FUNDAMENTALS A.6 Which of the containers in Exercise A.5 shows a substance that could be a gas? A.7 State whether the following properties are extensive or intensive: (a) the temperature at which ice melts; (b) the color of nickel chloride; (c) the energy produced when gasoline burns; (d) the cost of gasoline. A.8 State whether the following properties are extensive or intensive: (a) the price of platinum; (b) the humidity of the atmosphere; (c) the air pressure in a tire; (d) the hardness of concrete. A.9 The following units may sound strange, but were actually used in ancient times. Suppose that they have been adopted into the SI system. Rewrite each value with the appropriate SI prefix. (a) 1000 grain; (b) 0.01 batman; (c) 1 ϫ 106 mutchkin. A.10 The following units may sound strange, but were actually used in ancient times. Suppose that they have been adopted into the SI system. Rewrite each value with the appropriate SI prefix. (a) 1 ϫ 1012 scantling; (b) 1 ϫ 10Ϫ15 palm; (c) 1 ϫ 10Ϫ9 catty. A.11 Express the volume in milliliters of a 1.00-cup sample of milk, given that 2 cups ϭ 1 pint, 2 pints ϭ 1 quart. A.12 The ångström unit (1 Å ϭ 10Ϫ10 m) is still widely used to report measurements of the dimensions of atoms and molecules. Express the following data in ångströms: (a) the radius of a sodium atom, 180 pm (2 sf); (b) the wavelength of yellow light, 550 nm (2 sf). (c) Write a (single) conversion factor between ångströms and nanometers. A.13 When a piece of unreactive metal of mass 112.32 g is dropped into a graduated cylinder containing 23.45 mL of water, the water level rises to 29.27 mL. What is the density of the metal (in grams per cubic centimeter)? A.14 When a piece of unreactive metal of mass 156.77 g is dropped into a graduated cylinder containing 30.21 mL of water, the water level rises to 48.95 mL. What is the density of the metal (in grams per cubic centimeter)? A.15 The density of diamond is 3.51 gиcmϪ3 . The international (but non-SI) unit for weighing diamonds is the “carat” (1 carat ϭ 200 mg exactly). What is the volume of a 0.750-carat diamond? A.16 Use data from Appendix D to calculate the volume of 1.00 ounce of gold. A.17 A flask weighs 43.50 g when it is empty and 105.50 g when filled with water. When the same flask is filled with another liquid, the mass is 96.75 g. What is the density of the second liquid? A.18 What volume (in cubic centimeters) of lead (of density 11.3 gиcmϪ3 ) has the same mass as 215 cm3 of a piece of redwood (of density 0.38 gиcmϪ3 )? A.19 Spacecraft are commonly clad with aluminum to provide shielding from radiation. Adequate shielding requires that the cladding provide 20. g of aluminum per square centimeter. Use data from Appendix D to calculate how thick the aluminum cladding must be to provide adequate shielding. A.20 Assume that the entire mass of an atom is concentrated in its nucleus, a sphere of radius 1.5 ϫ 10Ϫ5 pm. (a) If the mass of a carbon atom is 2.0 ϫ 10Ϫ23 g, what is the density of a carbon nucleus? The volume of a sphere of radius r is ␲r3 . (b) What would the radius of the Earth be if its matter were compressed to the same density as that of a carbon nucleus? (The Earth’s average radius is 6.4 ϫ 103 km, and its average density is 5.5 gиcmϪ3 .) A.21 To how many significant figures should the result of the following calculation be reported? A.22 To how many significant figures should the result of the following calculation be reported? A.23 Use the conversion factors in Appendix 1B and inside the back cover to express the following measurements in the designated units: (a) 4.82 nm to pm; (b) 1.83 mLиminϪ1 to mm3 иsϪ1 ; (c) 1.88 ng to kg; (d) 2.66 gиcmϪ3 to kgиmϪ3 ; (e) 0.044 gиLϪ1 to mgиcmϪ3 . A.24 Use the conversion factors in Appendix 1B and inside the back cover to express the following measurements in the designated units: (a) 36 L to m3 ; (b) 45 gиLϪ1 to mgиmLϪ1 ; (c) 1.54 mmиsϪ1 to nmи␮sϪ1 ; (d) 7.01 cmиsϪ1 to kmиhϪ1 ; (e) $3.50/gallon to peso/liter (assume 1 dollar Ϸ 13.1 peso). A.25 The density of a metal was measured by two different methods. In each case, calculate the density. Indicate which measurement is more precise. (a) The dimensions of a rectangular block of the metal were measured as 1.10 cm ϫ 0.531 cm ϫ 0.212 cm. Its mass was found to be 0.213 g. (b) The mass of a cylinder of water filled to the 19.65-mL mark was found to be 39.753 g. When a piece of the metal was immersed in the water, the level of the water rose to 20.37 mL and the mass of the cylinder with the metal was found to be 41.003 g. A.26 A chemist at Trustworthy Labs determined in a set of four experiments that the density of magnesium metal was 1.68 gиcmϪ3 , 1.67 gиcmϪ3 , 1.69 gиcmϪ3 , 1.69 gиcmϪ3 . A chemist at Righton Labs repeated the measurements but found the following values: 1.72 gиcmϪ3 , 1.63 gиcmϪ3 , 1.74 gиcmϪ3 , 1.86 gиcmϪ3 . The accepted value for its density is 1.74 gиcmϪ3 . Compare the precision and accuracy of the two chemists’ data. A.27 The reference points on a newly proposed temperature scale expressed in ºX are the freezing and boiling points of water, set equal to 50.ºX and 250.ºX, respectively. (a) Derive a formula for converting temperatures on the Celsius scale to the new scale. (b) Comfortable room temperature is 22ºC. What is that temperature in ºX? A.28 When Anders Celsius first proposed his scale, he took 100 as the freezing point of water and 0 as the boiling point. (a) To what temperature would 25ºC correspond on that proposed scale? (b) To what temperature would 98.6ºF correspond on the proposed scale? A.29 The maximum ground speed of a chicken is 14 kmиhϪ1 . Calculate the kinetic energy of a chicken of mass 4.2 kg crossing a road at its maximum speed. A.30 Mars orbits the Sun at 25 kmиsϪ1 . A spaceship attempting to land on Mars must match its orbital speed. If the mass of the spaceship is 3.6 ϫ 105 kg, what is its kinetic energy when its speed has matched that of Mars? A.31 A vehicle of mass 2.8 t slows from 100. kmиhϪ1 to 50. kmиhϪ1 as it enters a city. How much energy could have been recovered instead of being dissipated as heat? To what height, neglecting friction and other losses, could that energy have been used to drive the vehicle up a hill? A.32 What is the minimum energy that a football player must expend to kick a football of mass 0.51 kg over a goalpost of height 3.0 m? (604.01 + 0.53) * 321.81 * 0.001 80 3.530 * 10-3 0.082 06 * (273.15 + 1.2) 3.25 * 7.006 4 3 B.1 Atoms B.2 The Nuclear Model B.3 Isotopes B.4 The Organization of the Elements Appendix 2D lists the names and chemical symbols of the elements and gives the origins of their names. FIGURE B.1 Samples of common elements. Clockwise from the redbrown liquid bromine are the silvery liquid mercury and the solids iodine, cadmium, red phosphorus, and copper. B.1 Atoms The Greeks asked what would happen if they continued to cut matter into ever smaller pieces. Is there a point at which they would have to stop because the pieces no longer had the same properties as the whole or could they go on cutting forever? We now know that there is a point at which we have to stop. That is, matter consists of almost unimaginably tiny particles. The smallest particle of an element that can exist is called an atom. The story of the development of the modern model of the atom is an excellent illustration of how scientific models are developed and is continued in Chapter 1. The first convincing argument for atoms was made in 1807 by the English schoolteacher and chemist John Dalton (Fig. B.2). He made many measurements of the ratios of the masses of elements that combine together to form the substances we call “compounds” (see Section C) and found that the ratios formed patterns. For example, he found that, in every sample of water, there was 8 g of oxygen for every 1 g of hydrogen and that, in another compound of the two elements (hydrogen peroxide), FIGURE B.2 John Dalton (1766–1844), the English schoolteacher who used experimental measurements to argue that matter consists of atoms. The name atom comes from the Greek word for “not cuttable.” B ELEMENTS AND ATOMS Science is a quest for simplicity. Although the complexity of the world appears boundless, this complexity springs from an underlying simplicity that science attempts to discover. Chemistry’s contribution to this quest is to show how everything around us— mountains, trees, people, computers, brains, concrete, oceans—is in fact made up of a handful of simple entities. The ancient Greeks had much the same idea. They supposed that there were four elements—earth, air, fire, and water—that could produce all other substances when combined in the right proportions. Their concept of an element is similar to our own; but, on the basis of experiments, we now know that there are actually more than 100 elements, which—in various combinations—make up all the matter on Earth (Fig. B.1). B.1 ATOMS F15 FUNDAMENTALS A.33 It has been said in jest that the only exercise some people get is raising a fork to their lips. How much energy do we expend to raise a loaded fork of mass 40.0 g a height of 0.50 m 30 times in the course of a meal? A.34 Calculate the energy released when an electron is brought from infinity to a distance of 53 pm from a proton. (That distance is the most probable distance of an electron from the nucleus in a hydrogen atom.) The actual energy released when an electron and a proton form a hydrogen atom is 13.6 electronvolts (eV; 1 eV ϭ 1.602 ϫ 10Ϫ19 J). Account for the difference. A.35 The expression Ep ϭ mgh applies only close to the surface of the Earth. The general expression for the potential energy of a mass m at a distance R from the center of the Earth (of mass mE) is Ep ϭ ϪGmEm/R. Write R ϭ RE ϩ h, where RE is the radius of the Earth; and show that, when h ϽϽ RE, this general expression reduces to the special case, and find an expression for g. You will need the expansion (1 ϩ x)Ϫ1 ϭ 1 Ϫ x ϩ . . . . . A.36 The expression for the Coulomb potential energy is very similar to the expression for the general gravitational potential energy given in Exercise A.35. Is there an expression resembling Ep ϭ mgh for the change in potential energy when an electron a long way from a proton is moved through a small distance h? Find the expression of the form Ep ϭ egh, with an appropriate expression for g, using the same procedure as in Exercise A.35. there was 16 g of oxygen for every 1 g of hydrogen. These and related data led Dalton to develop his atomic hypothesis: 1 All the atoms of a given element are identical. 2 The atoms of different elements have different masses. 3 A compound is a specific combination of atoms of more than one element. 4 In a chemical reaction, atoms are neither created nor destroyed; they exchange partners to produce new substances. As we shall see in Section B.3, Dalton’s first assumption has to be modified because it is now known that the atoms of an element are not all exactly the same, for they can differ slightly in mass. Modern instrumentation provides much more direct evidence of atoms than was available to Dalton (Fig. B.3). There is no longer any doubt that atoms exist and that they are the units that make up the elements. In fact, chemists use the existence of atoms as the definition of an element: an element is a substance composed of only one kind of atom. By 2008, 112 elements had been discovered or created, but in some cases in only very small amounts. For instance, when element 110 was made, only two atoms were produced and they lasted less than a millisecond before disintegrating. All matter is made up of various combinations of the simple forms of matter called the chemical elements. An element is a substance that consists of only one kind of atom. B.2 The Nuclear Model We develop the modern model of an atom in Chapter 1. At this stage, all we need to know is that, according to the current nuclear model of the atom, an atom consists of a small positively charged nucleus, which is responsible for almost all its mass, surrounded by negatively charged electrons (denoted eϪ ). Compared with the size of the nucleus (about 10Ϫ14 m in diameter), the space occupied by the electrons is enormous (about 10Ϫ9 m in diameter; a hundred thousand times as great). If the nucleus of an atom were the size of a fly at the center of a baseball field, then the space occupied by the surrounding electrons would be about the size of the entire stadium (Fig. B.4). The positive charge of the nucleus exactly cancels the negative charge of the surrounding electrons. As a result, an atom is electrically neutral (uncharged). Because each electron has a single negative charge, for each electron in an atom there is a particle inside the nucleus having a single positive charge. These positively charged particles are called protons (denoted p); their properties are given in Table B.1. A proton is nearly 2000 times as heavy as an electron. The number of protons in an element’s atomic nucleus is called the atomic number, Z, of that element. For example, hydrogen has Z ϭ 1; and so we know that the nucleus of a hydrogen atom has one proton; helium has Z ϭ 2, and so its nucleus contains two protons. Henry Moseley, a young British scientist, was the first to determine atomic numbers unambiguously, shortly before he was killed in action in World War I. Moseley knew that when elements are bombarded with rapidly moving electrons they emit x-rays. He found that the properties of the x-rays emitted by an element depend on its atomic number; and, by studying the x-rays of many elements, he was able to determine the values of Z for them. Scientists have since determined the atomic numbers of all the known elements (see the list of elements inside the back cover). Technological advances in electronics early in the twentieth century led to the invention of the mass spectrometer, a device for determining the mass of an atom (Fig. B.5). Mass spectrometers are described more fully in Major Technique 6 after Chapter 18. Mass spectrometry has been used to determine the masses of the atoms of all the elements. We now know, for example, that the mass of a hydrogen atom is 1.67 ϫ 10–27 kg and that of a carbon atom is 1.99 ϫ 10–26 kg. Even the heaviest atoms have masses of only about 5 ϫ 10–25 kg. Once we know the mass of an individual atom, we can determine the number of those atoms in a given mass of element simply by dividing the mass of the sample by the mass of one atom. F16 FUNDAMENTALS FIGURE B.3 Individual atoms can be seen as bumps on the surface of a solid by the technique called scanning tunneling microscopy (STM). This image shows how information can be stored in individual atoms. The yellow spheres are silicon atoms arranged on a surface of gold and silicon atoms in an arrangement that can be read by an STM microscope. These tiny arrays can lead to very high density storage media. FIGURE B.4 Think of a fly at the center of this stadium: that is the relative size of the nucleus of an atom if the atom were magnified to the size of the stadium. FIGURE B.5 A mass spectrometer is used to measure the masses of atoms. Electrons emerge from the electron gun and are accelerated through a magnetic field by a potential difference. A pump is used to remove air. As the strength of the magnetic field is changed, the path of the accelerated ions moves from A to C. When the path is at B, the ion detector sends a signal to the recorder. The mass of the ion is proportional to the strength of the magnetic field needed to move the beam into position to strike the detector. ElectromagnetSample High potential difference ϩ Ϫ Ion detector Electron gun Ion beam Pump A B C ϭ FIGURE B.6 The mass spectrum of neon. The locations of the peaks on the x-axis tell us the relative masses of the atoms, and the intensities tell us the relative numbers of atoms having each mass. 20 21 22 Detectorsignal Mass N = 1.00 * 10-1 kg 1.99 * 10-26 kg = 5.03 * 1023 Evaluate As anticipated, the number of atoms, 5.03 ϫ 1023 , is very large. A note on good practice: Notice how we have converted the units that were given (grams, for the mass of this sample) into units that cancel (here, kilograms). It is often prudent to convert all units to SI base units. Self-Test B.1A The mass of an iron atom is 9.29 ϫ 10–26 kg. How many iron atoms are present in an iron magnet of mass 25.0 g? [Answer: 2.69 ϫ 1023 ] Self-Test B.1B A miner panning for gold in an Alaskan creek collects 12.3 g of the fine pieces of gold known as “gold dust.” The mass of one gold atom is 3.27 ϫ 10–25 kg. How many gold atoms has the miner collected? In the nuclear model of the atom, the positive charge and almost all of the mass is concentrated in the tiny nucleus, and the surrounding negatively charged electrons take up most of the space. The atomic number is the number of protons in the nucleus. B.3 Isotopes As happens so often in science, a new and more precise technique of measurement led to a major discovery. When scientists first used mass spectrometers they found—much to their surprise—that not all the atoms of a single element have the same mass. In a sample of perfectly pure neon, for example, most of the atoms have mass 3.32 ϫ 10–26 kg, which is about 20 times as great as the mass of a hydrogen atom. Some neon atoms, however, are found to be about 22 times as heavy as hydrogen. Others are about 21 times as heavy (Fig. B.6). All three types of atoms have the same atomic number; so they are definitely atoms of neon. The observation that atoms of a single element can have different masses helped scientists refine the nuclear model still further. They realized that an atomic nucleus must contain subatomic particles other than protons and proposed that it also contains electrically neutral particles called neutrons (denoted n). Because neutrons have no electric charge, their presence does not affect the nuclear charge or the number of electrons in the atom. However, they have approximately the same mass as protons, and so add substantially to the mass of the nucleus. Therefore, different numbers of neutrons in a nucleus give rise to atoms of different masses, even though the atoms belong to the same element. As we can see from Table B.1, neutrons and protons are very similar apart from their charge; they are jointly known as nucleons. B.3 ISOTOPES F17 FUNDAMENTALS 10.0 g EXAMPLE B.1 Calculating the number of atoms in a sample How many atoms are there in a sample of carbon of mass 10.0 g? Anticipate Because atoms are very tiny, we should expect a very large number. PLAN We need to divide the mass of the sample by the mass of one atom. SOLVE The mass of one carbon atom is 1.99 ϫ 10Ϫ26 kg (given in the text). From N ϭ (mass of sample)/(mass of one atom), $++%''& The total number of protons and neutrons in a nucleus is called the mass number, A, of the atom. A nucleus of mass number A is about A times as heavy as a hydrogen atom, which has a nucleus that consists of a single proton. Therefore, if we know that an atom is a certain number of times as heavy as a hydrogen atom, then we can infer the mass number of the atom. For example, because mass spectrometry shows that the three varieties of neon atoms are 20, 21, and 22 times as heavy as a hydrogen atom, we know that the mass numbers of the three types of neon atoms are 20, 21, and 22. Because for each of them Z ϭ 10, these neon atoms must contain 10, 11, and 12 neutrons, respectively (Fig. B.7). Atoms with the same atomic number (belonging to the same element) but with different mass numbers are called isotopes of the element. All isotopes of an element have exactly the same atomic number; hence they have the same number of protons and electrons. An isotope is named by writing its mass number after the name of the element, as in neon-20, neon-21, and neon-22. Its symbol is obtained by writing the mass number as a superscript to the left of the chemical symbol of the element, as in 20 Ne, 21 Ne, and 22 Ne. You will occasionally see the atomic number included as a subscript on the lower left, as in the symbol Ne used in Fig. B.7. Because isotopes of the same element have the same number of protons and the same number of electrons, they have essentially the same chemical and physical properties. However, the mass differences between isotopes of hydrogen are comparable to the masses of the atoms themselves, leading to noticeable differences in some physical properties and slight variations in some of their chemical properties. Hydrogen has three isotopes (Table B.2). The most common (1 H) has no neutrons; its nucleus is a lone proton. The other two isotopes are less common but nevertheless so important in chemistry and nuclear physics that they are given special names and symbols. The isotope with one neutron (2 H) is called deuterium (D) and the one with two neutrons (3 H) is called tritium (T). Self-Test B.2A How many protons, neutrons, and electrons are present in (a) an atom of nitrogen-15; (b) an atom of iron-56? [Answer: (a) 7, 8, 7; (b) 26, 30, 26] Self-Test B.2B How many protons, neutrons, and electrons are present in (a) an atom of oxygen-16; (b) an atom of uranium-236? Isotopes of an element have the same atomic number but different mass numbers. Their nuclei have the same number of protons but different numbers of neutrons. B.4 The Organization of the Elements There are 112 known elements, of which only 88 occur in significant quantities on Earth and are considered to be naturally occurring. At first sight the prospect of learning their 22 10 F18 FUNDAMENTALS The name isotope comes from the Greek words for “equal place.” FIGURE B.7 The nuclei of different isotopes of the same element have the same number of protons but different numbers of neutrons. These three diagrams show the composition of the nuclei of the three isotopes of neon. On this scale, the atom itself would be about 1 km in diameter. These diagrams make no attempt to show how the protons and neutrons are arranged inside the nucleus. Neon-20 (20 Ne)10 Neon-21 (21 Ne)10 Neon-22 (22 Ne)10 TABLE B.2 Some Isotopes of Common Elements Element Symbol Atomic number, Z Mass number, A Abundance, % hydrogen 1 H 1 1 99.985 deuterium 2 H or D 1 2 0.015 tritium 3 H or T 1 3 —* carbon-12 12 C 6 12 98.90 carbon-13 13 C 6 13 1.10 oxygen-16 16 O 8 16 99.76 *Radioactive, short-lived. Another, better, name for the mass number is nucleon number. TABLE B.1 Properties of Subatomic Particles Particle Symbol Charge* Mass, kg electron eϪ Ϫ1 9.109 ϫ 10Ϫ31 proton p ϩ1 1.673 ϫ 10Ϫ27 neutron n 0 1.675 ϫ 10Ϫ27 *Charges are given as multiples of the fundamental charge, which in SI units is 1.602 ϫ 10Ϫ19 C (see Appendix 1B). In some versions of the periodic table, the lanthanoids begin with lanthanum (element 57) and the actinoids begin with actinium (element 89). FIGURE B.8 The structure of the periodic table, showing the names of some regions and groups. The groups are the vertical columns, numbered 1 through 18. The periods are the horizontal rows, numbered 1 through 7 (Period 1 is the top row—hydrogen and helium—and is not numbered in the figure). The main-group elements are those in Groups 1, 2, and 13 through 18, together with hydrogen. Groups 1 and 2 make up the s block, 3–12 the d block, and 13–18 the p block. Periodnumbers Group numbers 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 1 2 2 3 3 4 4 5 5 6 6 7 7 8 9 10 11 12 1 Transition metals Lanthanoids (lanthanides) Actinoids (actinides) Halogens Noblegases Alkalineearthmetals Alkalimetals In some versions of the periodic table, you will see a different notation for groups, with the noble gases belonging to Group VIII, VIIIA, or VIIIB. These alternatives are given in the table printed inside the front cover. properties might seem overwhelming. The task is made much easier—and more interesting—by one of the most important discoveries in the history of chemistry. Chemists have found that when the elements are listed in order of their atomic number and arranged in rows of certain lengths, they form families that show regular trends in properties. The arrangement of elements that shows their family relationships is called the periodic table (it is printed inside the front cover of this book and repeated schematically in Fig. B.8). The vertical columns of the periodic table are called groups. These groups identify the principal families of elements. The taller columns (Groups 1, 2, and 13/III through 18/VIII) are called the main groups of the table. The horizontal rows are called periods and are numbered from the top down. The four rectangular regions of the periodic table are called blocks and, for reasons related to atomic structure (Section 1.13), are labeled s, p, d, and f. The members of the d block, with the exception of the elements in Group 12 (the zinc group) are called transition metals. As we shall see, these elements are transitional in character between the vigorously reactive metals in the s block and the less reactive metals on the left of the p block. The members of the f block, which is shown below the main table (to save space), are the inner transition metals. The upper row of this block, following lanthanum (element 57) in Period 6, consists of the lanthanoids (more commonly and traditionally, the “lanthanides”), and the lower row, following actinium (element 89) in Period 7, consists of the actinoids (more commonly, the “actinides”). Some of the main groups have special names that reflect the common properties of the elements in that group. The elements in Group 1 are called the alkali metals. All of them are soft, lustrous metals that melt at low temperatures. They all produce hydrogen when they come in contact with water (Fig. B.9)—lithium gently, but with increasing violence down the group. The elements calcium (Ca), strontium (Sr), and barium (Ba) in Group 2 are called the alkaline earth metals, but the name is often extended to all the members of the group. The Group 2 metals have many properties in common with the Group 1 metals, but their reactions are less vigorous. On the far right of the table, in Group 18/VIII, are the elements known as the noble gases. They are so called because they combine with very few elements—they are chemically aloof. In fact, until the 1960s, they were called the “inert gases” because they were thought not to combine with any elements at all. All the Group 18/VIII elements are colorless, odorless gases. Next to the noble gases are the halogens of Group 17/VII. Many of the properties of the halogens vary in a regular fashion from fluorine (F) through chlorine (Cl) and bromine (Br) to iodine (I). Fluorine, for instance, is a very pale yellow, almost colorless gas, chlorine a yellow-green gas, bromine a red-brown liquid, and iodine a purple-black solid (Fig. B.10). All the halogens occur as diatomic molecules in elemental form: F2, Cl2, Br2, and I2. B.4 THE ORGANIZATION OF THE ELEMENTS F19 FUNDAMENTALS The story of the discovery of periodic relationships by Dmitri Mendeleev can be found in Box 1.2 in Chapter 1. FIGURE B.9 The alkali metals react with water, producing gaseous hydrogen and heat. Potassium, as shown here, reacts vigorously, producing so much heat that the hydrogen produced is ignited. Lab Video B.9 At the head of the periodic table, standing alone, is hydrogen. Some tables place hydrogen in Group 1, others place it in Group 17/VII, and yet others place it in both groups. We treat it as a very special element and place it in none of the groups. Most of the elements are solid metals. Only two elements (mercury and bromine) are liquids at ordinary temperatures, and only 11 are gaseous. The elements are classified as metals, nonmetals, and metalloids: A metal conducts electricity, has a luster, and is malleable and ductile. A nonmetal does not conduct electricity and is neither malleable nor ductile. A metalloid has the appearance of a metal but can behave chemically like a metal or a nonmetal, depending on conditions. A “malleable” substance (from the Latin word for “hammer”) is one that can be hammered into thin sheets (Fig. B.11). A “ductile” substance (from the Latin word for “drawing out”) is one that can be drawn out into wires. Copper, for example, is a metal. It conducts electricity, has a luster when polished, and is malleable. It is so ductile that it is readily drawn out to form electrical wires. Sulfur, on the other hand, is a nonmetal. This brittle yellow solid does not conduct electricity, cannot be hammered into thin sheets, and cannot be drawn out into wires. The distinctions between metals and metalloids and between metalloids and nonmetals are not very precise (and not always made), but the metalloids are often taken to be the seven elements shown in Fig. B.12 on a diagonal band between the metals on the left and the nonmetals on the right. The periodic table is a very useful summary of the properties of the elements. Even if we have never heard of osmium (Os), we can glance at the periodic table and see that it is a metal because it lies to the left of the metalloids (all the d-block elements are metals). Similarly, even though chemists might not have investigated the reactions of radon (Rn)—it is a dangerously radioactive gas—we can expect it to resemble the other noble gases, particularly its immediate neighbor in Group 18/VIII, xenon (Xe), and to form very few compounds. As you work through this text and encounter a new element, it is F20 FUNDAMENTALS FIGURE B.10 The halogens are colored elements. From left to right, chlorine is a yellow-green gas, bromine is a red-brown liquid (its vapor fills the flask), and iodine is a dark purple-black solid (note the small crystals). FIGURE B.12 The location of the seven elements commonly regarded as metalloids: these elements have characteristics of both metals and nonmetals. Other elements, notably beryllium and bismuth, are sometimes included in the classification. Boron (B), although not resembling a metal in appearance, is included because it resembles silicon (Si) chemically. 1 2 2 3 3 4 4 5 5 6 6 7 7 8 9 10 11 12 13/III 14/IV 15/V 16/VI 17/VII 18/VIII Metal Metalloid Nonmetal B C Al Si P Ga Ge As Se Sn Sb Bi Po At Te I 1 FIGURE B.11 All metals can be deformed by hammering. Gold can be hammered into a sheet so thin that light can pass through it. Here, it is possible to see the light of a flame through the sheet of gold. EXERCISES F21 SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Describe the structure of an atom. ❑ 2 Find the number of atoms in a given mass of an element (Example B.1). ❑ 3 Find the numbers of neutrons, protons, and electrons in an isotope (Self-Test B.2). ❑ 4 Describe the organization of the periodic table and the characteristics of elements in different regions of the table. B.1 The mass of an atom of beryllium is 1.50 ϫ 10Ϫ26 kg. How many beryllium atoms are present in a beryllium film of mass 0.210 g used as a window on an x-ray tube? B.2 The mass of an atom of fluorine is 3.16 ϫ 10Ϫ26 kg. How many fluorine atoms are present in a 3.50-L tank of fluorine gas? The density of the fluorine gas in the tank is 0.777 gиLϪ1 . B.3 Give the number of protons, neutrons, and electrons in an atom of (a) boron-11; (b) 10 B; (c) phosphorus-31; (d) 238 U. B.4 Give the number of protons, neutrons, and electrons in an atom of (a) tritium, 3 H; (b) 69 Ga; (c) selenium-79; (d) 247 Cm. B.5 Identify the isotope that has atoms with (a) 117 neutrons, 77 protons, and 77 electrons; (b) 12 neutrons, 10 protons, and 10 electrons; (c) 28 neutrons, 23 protons, and 23 electrons. B.6 Identify the isotope that has atoms with (a) 106 neutrons, 76 protons, and 76 electrons; (b) 30 neutrons, 28 protons, and 28 electrons; (c) 21 neutrons, 20 protons, and 20 electrons. B.7 Complete the following table: Mass Element Symbol Protons Neutrons Electrons number 36 Cl 30 65 20 20 lanthanum 80 B.8 Complete the following table: Mass Element Symbol Protons Neutrons Electrons number osmium 190 120 Sn 74 184 30 25 B.9 (a) What characteristics do atoms of argon-40, potassium-40, and calcium-40 have in common? (b) In what ways are they different? (Consider the numbers and types of subatomic particles.) EXERCISES FUNDAMENTALS B.10 (a) What characteristics do atoms of manganese-55, iron-56, and nickel-58 have in common? (b) In what ways are they different? (Consider the numbers and types of subatomic particles.) B.11 Determine the fraction of the total mass of a 58 Fe atom that is due to (a) neutrons; (b) protons; (c) electrons. (d) What is the mass of neutrons in an automobile of mass 1.000 t? Assume that the total mass of the vehicle is due to 56 Fe. B.12 (a) Determine the total number of protons, neutrons, and electrons in one carbon tetrafluoride molecule, CF4, assuming that all atoms are the most common isotopes of that element. (b) What is the total mass of protons, of neutrons, and of electrons in one carbon tetrafluoride molecule? Calculate three masses. B.13 Name each of the following elements: (a) Sc; (b) Sr; (c) S; (d) Sb. List their group numbers in the periodic table. Identify each as a metal, a nonmetal, or a metalloid. B.14 Name each of the following elements: (a) P; (b) Pr; (c) Po; (d) Pd. List their group numbers in the periodic table, and identify each as a metal, a nonmetal, or a metalloid. B.15 Write the symbol of (a) strontium; (b) xenon; (c) silicon. Classify each as a metal, a nonmetal, or a metalloid. B.16 Write the symbol of (a) thallium; (b) europium; (c) cadmium. Classify each as a metal, a nonmetal, or a metalloid. B.17 List the names, symbols, and atomic numbers of the halogens. Identify the normal physical state of each. B.18 List the names, symbols, and atomic numbers of the alkali metals. Characterize their reactions with water and describe their trend in melting points. B.19 Identify the periodic table block to which each of the following elements belongs: (a) zirconium; (b) As; (c) Ta; (d) barium; (e) Si; (f) cobalt. B.20 State three physical properties that are typical of (a) metals; (b) nonmetals. B.21 Identify the element having atoms with 118 neutrons and mass number 200 and state its group number in the periodic table. Is this element a metal, a nonmetal, or a metalloid? B.22 Identify the element having atoms with 74 neutrons and mass number 127 and state its group number in the periodic table. Is this element a metal, a nonmetal, or a metalloid? a good idea to refer to the periodic table, identify the neighbors of the element, and try to predict its properties. The periodic table is an arrangement of the elements by atomic number that reflects their family relationships; members of the same group typically show a smooth trend in properties. F22 FUNDAMENTALS C COMPOUNDS The small number of elements that make up our world combine to produce matter in a seemingly limitless variety of forms. We have only to look at the vegetation, flesh, landscapes, fabrics, building materials, and other things around us to appreciate the wonderful variety of the material world. A part of chemistry is analysis: the discovery of which elements have combined together to form a substance. Another aspect of chemistry is synthesis: the process of combining elements to produce compounds or converting one compound into another. If the elements are the alphabet of chemistry, then the compounds are its plays, its poems, and its novels. C.1 What Are Compounds? A compound is an electrically neutral substance that consists of two or more different elements with their atoms present in a definite ratio. A binary compound consists of only two elements. For example, water is a binary compound of hydrogen and oxygen, with two hydrogen atoms for each oxygen atom. Whatever the source of the water, it has exactly the same composition; indeed, a substance with a different ratio of atoms would not be water. Hydrogen peroxide (H2O2), for instance, has one hydrogen atom for every oxygen atom. Compounds are classified as either organic or inorganic. Organic compounds contain the element carbon and usually hydrogen, too. There are millions of organic compounds, including fuels such as methane and propane, sugars such as glucose and sucrose, and most medicines. These compounds are called organic because it was once believed, incorrectly, that they could be formed only by living organisms. Inorganic compounds are all the other compounds; they include water, calcium sulfate, ammonia, silica, hydrochloric acid, and many, many more. In addition, some very simple carbon compounds, particularly carbon dioxide and the carbonates, which include chalk (calcium carbonate), are treated as inorganic compounds. Intermetallic compounds are inorganic compounds that are formed when the atoms of two metals bond in specific proportions. Examples are nitinol, NiTi, which is used in orthodontic wires, flexible eyeglass frames, and stents that increase blood flow in arteries; Ag3Sn, which is found in “silver” dental fillings; and FeCo, which is used in magnets. The elements in a compound are not just mixed together. Their atoms are actually joined, or bonded, to one another in a specific way due to a chemical change (see Section A). The result is a substance with chemical and physical properties different from those of the elements that form it. For example, when sulfur is ignited in air, it combines with oxygen from the air to form the compound sulfur dioxide. Solid yellow sulfur and odorless oxygen gas produce a colorless, pungent, and poisonous gas (Fig. C.1). Chemists have found that atoms can bond together to form molecules or can be present in compounds as ions: A molecule is a discrete group of atoms bonded together in a specific arrangement. An ion is a positively or negatively charged atom or molecule. A positively charged ion is called a cation, and a negatively charged ion is called an anion. For instance, a positively charged sodium atom is a cation and is denoted Naϩ ; a negatively charged chlorine atom is an anion and is denoted ClϪ . An example of a “polyatomic” (many-atom) cation is the ammonium ion, NH4 ϩ , and an example of a polyatomic anion is the carbonate ion, CO3 2Ϫ ; note that the latter has two negative charges. An ionic compound consists of ions in a ratio that results in overall electrical neutrality; a molecular compound consists of electrically neutral molecules. In general, binary compounds of two nonmetals are molecular, whereas binary compounds formed by a metal and a nonmetal are ionic. Water (H2O) is an example of a binary molecular compound, and sodium chloride (NaCl) is an example of a binary ionic compound. As we shall see, these two types of compounds have characteristic C.1 What Are Compounds? C.2 Molecules and Molecular Compounds C.3 Ions and Ionic Compounds Bonding is discussed in more detail in Chapters 2 and 3. The name ion comes from the Greek word for “go,” because charged particles go either toward or away from a charged electrode. The prefixes cat- and an- come from the Greek words for “down” and “up.” Oppositely charged ions travel in opposite directions in an electric field. FIGURE C.1 Elemental sulfur burns in air with a blue flame and produces the dense gas sulfur dioxide, a compound of sulfur and oxygen. FUNDAMENTALS C.2 MOLECULES AND MOLECULAR COMPOUNDS F23 properties, and knowing the type of compound that we are studying can be a source of insight into its properties. Compounds are combinations of elements in which the atoms of the different elements are present in a characteristic, constant ratio. A compound is classified as molecular if it consists of molecules and as ionic if it consists of ions. C.2 Molecules and Molecular Compounds The chemical formula of a compound represents its composition in terms of chemical symbols. Subscripts show the numbers of atoms of each element present in the smallest unit that is representative of the compound. For molecular compounds, it is common to give the molecular formula, a chemical formula that shows how many atoms of each type of element are present in a single molecule of the compound. For instance, the molecular formula for water is H2O: each molecule contains one O atom and two H atoms. The molecular formula for estrone, a female sex hormone, is C18H22O2, showing that a single molecule of estrone consists of 18 C atoms, 22 H atoms, and 2 O atoms. A molecule of a male sex hormone, testosterone, differs by only a few atoms: its molecular formula is C19H28O2. Think of the consequences of that tiny difference! Some elements also exist in molecular form. Except for the noble gases, all the elements that are gases at ordinary temperatures are found as diatomic molecules, molecules that consist of two atoms. For example, molecules of hydrogen gas contain two hydrogen atoms bonded together and are represented as H2. The most common form of oxygen consists of diatomic molecules and is known formally as dioxygen, O2. Solid sulfur exists as S8 molecules and phosphorus as P4 molecules. Nitrogen and all the halogens exist as diatomic molecules: N2, F2, Cl2, Br2, and I2. A structural formula indicates how the atoms are linked together, but not their actual three-dimensional arrangement in space. For instance, the molecular formula of methanol (wood spirit or wood alcohol) is CH4O, and its structural formula is shown in (1): each line represents a chemical bond (the link between two atoms) and each symbol an atom. Structural formulas contain more information than the chemical formula, but they are cumbersome. So chemists condense them and write, for instance, CH3OH to represent the structure of methanol. This “condensed” structural formula indicates the groupings of the atoms and summarizes the full structural formula. In most cases, symbols with subscripts represent atoms connected to the preceding element in the formula. A group of atoms attached to another atom in the molecule is set off with parentheses. For example, methylpropane (2) has a methyl group (¬CH3) attached to the central atom in a chain of three carbon atoms, and the condensed version of its structural formula is written CH3CH(CH3)CH3 or HC(CH3)3. The richness of organic chemistry arises in part from the fact that, although carbon atoms nearly always form four bonds, they can form chains and rings of almost limitless variety. Another source of its richness is that the carbon atoms can be linked together by different kinds of chemical bonds. In Chapter 2, we shall see that atoms can be joined by single bonds, indicated by a single line (C¬C); double bonds, represented by a double line (C“C); and triple bonds, represented by a triple line (C‚C). A carbon atom can form four single bonds, two double bonds, or any combination that results in four bonds, such as one single and one triple bond. Organic chemists have found a way to draw complex molecular structures in a very simple way, by not showing the C and H atoms explicitly. A line structure represents a chain of carbon atoms by a zigzag line, where each short line indicates a bond and the end of each line represents a carbon atom. Atoms other than C and H are shown by their symbols. Double bonds are represented by a double line and triple bonds by a triple line. Because carbon almost always forms four bonds in organic compounds, there is no need to show the C¬H bonds explicitly. We just fill in the correct number of hydrogen atoms mentally: compare the line structure of 2-chlorobutane, CH3CHClCH2CH3 (3a), with its structural form (3b). Line structures are particularly useful for complex molecules, such as testosterone (4). They are used occasionally in the early chapters of this text and are explained in more detail in Chapter 18. At this H C C C C H H H H H H H H 2 Methylpropane, CH3CH(CH3)CH3 H 3 2-Chlorobutane, CH3CHClCH2CH3 H Cl H C H C H H C H H C H H (b) Cl (a) H OC H H H 1 Methanol, CH3OH O 4 Testosterone, C19H28O2 OH F24 FUNDAMENTALS stage, you need only know that a line structure is a display of the “connectivity” of a molecule, a portrayal of which atom is linked to which and by how many bonds. Another important aspect of a molecular compound is its shape. The pictorial representations of molecules that most accurately show their shapes are images based on computation or software that represents atoms by spheres of various sizes. An example is the space-filling model of an ethanol molecule shown in Fig. C.2a. The atoms are represented by colored spheres (they are not the actual colors of the atoms) that fit into one another. The radii of the atoms are determined by calculation; because atoms do not have hard surfaces, the surface shown uses a chosen cut-off limit of electron density, usually 90 or 95%. Another representation of the same molecule, called a ball-andstick model, is shown in Fig. C.2b. Each ball represents the location of an atom, and the sticks represent the bonds. Although this kind of model does not represent the actual molecular shape as well as a space-filling model does, it shows bond lengths and angles more clearly. It is also easier to draw and interpret. Chemists use several other kinds of images to depict molecular structure. The tube structure is like a ball-and-stick structure without the balls (Fig. C.2c): different atoms are depicted by different colors at the ends of the tube that represents the link between them. Tube structures and line structures (recall 4) are useful for showing the structures of complicated molecules. More sophisticated than any of these representations are images that show the distribution of electrons in the molecule. The cloud in Fig. C.2d, for instance, indicates how the electrons are spread throughout an ethanol molecule: it is an example of a density isosurface and gives a very real sense of the shape of the molecule (but it is hard to interpret in terms of the location of the atoms). Figure C.2e shows the same diagram with the density isosurface made transparent and a tube structure inside, which helps to clarify the significance of the isosurface. Chemists also need to know the distribution of electric charge in a molecule, because that distribution affects its physical and chemical properties. To do so, they sometimes use an electrostatic potential surface (an “elpot” surface), in which the net electric potential is calculated at each point of the density isosurface and depicted by different colors, as in Fig. C.2f. A blue tint at a point indicates that the positive potential at that point due to the positively charged nuclei outweighs the negative potential due to the negatively charged electrons; a red tint indicates the opposite. Thinking point: Which type of molecular representation would you use to study bond lengths? Molecular volume? A molecular formula shows the composition of a molecule in terms of the numbers of atoms of each element present. Different styles of molecular models are used to emphasize different molecular characteristics. C.3 Ions and Ionic Compounds To imagine what ionic compounds look like, we have to visualize a huge number of cations and anions stacked together in a regular three-dimensional formation. The ions bond together by the attraction between their opposite charges. Each crystal of sodium chloride, for example, consists of an orderly array of a vast number of alternating Naϩ and ClϪ ions (Fig. C.3). When you take a pinch of salt, each crystal that you are picking up consists of more ions than there are stars in the visible universe. The nuclear model of the atom readily explains the existence of monatomic ions (single-atom ions). When an electron is removed from a neutral atom, the charge of the remaining electrons no longer fully cancels the positive charge of the nucleus (Fig. C.4). Because an electron has one unit of negative charge, each electron removed from a neutral atom leaves behind a cation with one additional unit of positive charge. For example, a sodium cation, Naϩ , is a sodium atom that has lost one electron. When a calcium atom loses two electrons, it becomes the doubly positively charged calcium ion, Ca2ϩ . Each electron gained by an atom increases the negative charge by one unit (Fig. C.5). So, when a fluorine atom gains an electron, it becomes the singly negatively FIGURE C.2 Representations of an ethanol molecule: (a) space-filling, (b) ball-and-stick, (c) tube, (d) density isosurface, (e) transparent density isosurface, (f) electrostatic potential (elpot) surface. (a) (b) (c) (d) (e) (f) ClϪ Naϩ FIGURE C.3 An ionic solid consists of an array of cations and anions stacked together. This illustration shows the arrangement of sodium cations (Naϩ ) and chlorine anions (chloride ions, ClϪ ) in a crystal of sodium chloride (common table salt). The faces of the crystal are where the stacks of ions come to an end. FUNDAMENTALS C.3 IONS AND IONIC COMPOUNDS F25 charged fluoride ion, FϪ . When an oxygen atom gains two electrons, it becomes the doubly charged oxide ion, O2Ϫ . When a nitrogen atom gains three electrons, it becomes the triply charged nitride ion, N3Ϫ . The periodic table can help us decide what type of ion an element forms and what charge to expect the ion to have. Fuller details will be given in Chapter 2, but we can begin to see the patterns. One major pattern is that metallic elements—those toward the left of the periodic table—typically form cations by electron loss. Nonmetallic elements—those toward the right of the table—typically form anions by gaining electrons. Thus, the alkali metals form cations, and the halogens form anions. Figure C.6 shows another pattern in the charges of monatomic cations. For elements in Groups 1 and 2, for instance, the charge of the ion is equal to the group number. Thus, cesium in Group 1 forms Csϩ ions; barium in Group 2 forms Ba2ϩ ions. Figure C.6 also shows that atoms of the d-block elements and some of the heavier metals of Groups 13/III and 14/IV can form cations with different charges. An iron atom, for instance, can lose two electrons to become Fe2ϩ or three electrons to become Fe3ϩ . Copper can lose either one electron to form Cuϩ or two electrons to become Cu2ϩ . Some of the anions present in compounds are listed in Fig. C.7. We see another pattern emerging: a main-group element on the right side of the table forms an anion with a negative charge equal to its distance from the noble-gas group. Oxygen is two groups away from the noble gases and forms the oxide ion, O2Ϫ ; phosphorus, which is three groups away, forms the phosphide ion, P3Ϫ . In general, if the group number of a main-group element is N (in the 1 to 18 system), the charge of the anions that it forms is N Ϫ 18. The pattern of ion formation by main-group elements can be summarized by a single rule: For atoms toward the left or right of the periodic table, atoms lose or gain electrons until they have the same number of electrons as the nearest noble-gas atom. Thus, a magnesium atom can lose two electrons and become Mg2ϩ , which has the same number of electrons as an atom of neon. A selenium atom can gain two electrons and become Se2Ϫ , which has the same number of electrons as a krypton atom. Metallic elements typically form cations, and nonmetallic elements typically form anions; the charge of a monatomic ion of a main group element is related to its group in the periodic table. FIGURE C.4 A neutral sodium atom (left) consists of a nucleus that contains 11 protons and is surrounded by 11 electrons. When 1 electron is lost, the remaining 10 electrons cancel only 10 of the proton charges, and the resulting ion (right) has one overall positive charge. eϪ 11 eϪ 10 eϪ Naϩ Na eϪ 10 eϪ FϪ 9 e F FIGURE C.5 A neutral fluorine atom (left) consists of a nucleus that contains 9 protons and is surrounded by 9 electrons. When the atom gains 1 electron, the 9 proton charges cancel all but 1 of the 10 electron charges, and the resulting ion (right) has one overall negative charge. FIGURE C.6 The typical cations formed by a selection of elements in the periodic table. The transition metals (Groups 3–11) form a wide variety of cations; we have shown only a few. 3 8 9 10 11 12 13/III 14/IV1 2 2 3 4 5 6 7 Li+ Na+ K+ Rb+ Cs+ Be2+ Mg2+ Ca2+ Sr2+ Ba2+ Ra2+ Fe2+ Fe3+ Cu+ Cu2+ Ag+ Au+ Au3+ H+ Zn2+ Cd2+ Hg 2+ Hg2+ 2 Al3+ Ga3+ In+ In3+ Tl+ Tl3+ Sn2+ Sn4+ Pb2+ Pb4+ F26 FUNDAMENTALS N 15 16 171 ؊3 Self-Test C.1A What ions are (a) iodine and (b) aluminum likely to form? [Answer: (a) IϪ ; (b) Al3ϩ ] Self-Test C.1B What ions are (a) potassium and (b) sulfur likely to form? Many ions are diatomic, meaning that they consist of two atoms bonded together, or polyatomic, meaning that they consist of three or more atoms bonded together. In each case, the ions have an overall positive or negative charge. For example, the cyanide ion, CNϪ , is diatomic, and the ammonium ion, NH4 ϩ , is polyatomic. The most common polyatomic anions are the oxoanions, polyatomic anions that contain oxygen. They include the carbonate, CO3 2Ϫ ; nitrate NO3 Ϫ ; phosphate, PO4 3Ϫ ; and sulfate, SO4 2Ϫ , anions. A carbonate ion (5), for example, has three O atoms bonded to a C atom and has two additional electrons. Similarly, a phosphate ion (6) consists of four O atoms bonded to a P atom, with three additional electrons. In Chapter 2, we shall see why we have drawn some of these structures with double bonds: for now, we take it as a way of making sure that each atom forms its correct number of bonds. The formulas of ionic compounds have a different meaning from those of molecular compounds. Each crystal of sodium chloride may have a different total number of cations and anions from any other crystal. We cannot simply specify the numbers of ions present as the formula of this ionic compound, because each crystal would have a different formula and the subscripts would be enormous numbers. However, the ratio of the number of cations to the number of anions is the same in all the crystals, and the chemical formula shows this ratio. In sodium chloride, there is one Naϩ ion for each ClϪ ion; so its formula is NaCl. Sodium chloride is an example of a binary ionic compound, a compound formed from the ions of two elements. Another binary ionic compound, CaCl2, is formed from Ca2ϩ and ClϪ ions in the ratio 1:2, which is required for electrical neutrality. 1 2 3 4 5 6 7 14/IV 15/V 16/VI 17/VII 18/VIII HϪ N3Ϫ O2Ϫ FϪ P3Ϫ S2Ϫ ClϪ Se2Ϫ BrϪ IϪ 5 Carbonate ion, CO3 2Ϫ 2Ϫ 6 Phosphate ion, PO4 3Ϫ 3Ϫ EXAMPLE C.1 Identifying the likely charge of a monatomic ion What ions are (a) nitrogen and (b) calcium likely to form? Anticipate Nitrogen is a nonmetal so we expect it to form an anion; calcium is a metal so we expect it to form a cation. PLAN Identify the group to which each element belongs and decide whether it is likely to lose or gain electrons in order to reach a nearby noble-gas electron count. Typically, a nonmetal forms an anion of charge N Ϫ 18 and a metal in Group 1 or 2 forms a cation of charge N, where N is the group number. SOLVE (a) Nitrogen (N) is in Group 15/V and a nonmetal. N ϭ 15; so N Ϫ 18 ϭ 15 Ϫ 18 ϭ Ϫ3; nitrogen forms N3Ϫ (b) Calcium (Ca) is in Group 2 and a metal. N ϭ 2, so calcium forms Ca2ϩ Ca 2 3 4 ؉2 FIGURE C.7 The typical monatomic anions formed by a selection of elements in the periodic table. Notice how the charge on each ion depends on its group number. Only the nonmetals form monatomic anions under common conditions. FUNDAMENTALS C.3 IONS AND IONIC COMPOUNDS F27 Clusters of ions, such as Na+ Cl– , do exist in the gas phase and in concentrated aqueous solutions, in which case they are commonly termed ion pairs rather than molecules. The formulas of compounds containing polyatomic ions follow similar rules. In sodium carbonate there are two Naϩ (sodium) ions per CO3 2Ϫ (carbonate) ion; so its formula is Na2CO3. When a subscript has to be added to a polyatomic ion, the ion is written within parentheses, as in (NH4)2SO4, where (NH4)2 means that there are two NH4 ϩ (ammonium) ions for each SO4 2Ϫ (sulfate) ion in ammonium sulfate. In each case, the ions combine in such a way that the positive and negative charges cancel: all compounds are electrically neutral overall. We do not usually speak of a “molecule” of an ionic compound. However, it is useful to be able to refer to a group of ions having the number of atoms given by the formula. This group of ions is called a formula unit. For example, the formula unit of sodium chloride, NaCl, consists of one Naϩ ion and one ClϪ ion; and the formula unit of ammonium sulfate, (NH4)2SO4, consists of two NH4 ϩ ions and one SO4 2Ϫ ion. We can often decide whether a substance is an ionic compound or a molecular compound by examining its formula. Binary molecular compounds are typically formed from two nonmetals (such as hydrogen and oxygen, the elements in water). Ionic compounds are typically formed from the combination of a metallic element with nonmetallic elements (such as the combination of potassium with sulfur and oxygen to form potassium sulfate, K2SO4). Ionic compounds typically contain one metallic element; the principal exceptions are compounds containing the ammonium ion, such as ammonium nitrate, which are ionic even though all the elements present are nonmetallic. Mg 2 3 4 MMMM؉2 Find the charge on the cation from the periodic table. Mg is in Group 2; so it forms ions with charge ϩ2. EXAMPLE C.2 Writing the likely formula of a binary ionic compound Write the formula of the binary ionic compound formed by magnesium and phosphorus. PLAN Identify the charges of the cation and anion, then choose numbers of each so that the total charge is zero. SOLVE Find the charge on the anion from the periodic table. P is in Group 15/V and forms ions with charge 15 Ϫ 18 ϭ Ϫ3. P 15 16 17 ؊3 Combine the ions so that their charges cancel. 3 Mg2ϩ ions have a charge of ϩ6. 2 P3Ϫ ions have a charge of Ϫ6. The formula is Mg3P2. Ϫ3 Ϫ3ϩ2 ϩ2 ϩ2 Self-Test C.2A Write the formula of the binary ionic compound formed by (a) barium and bromine; (b) aluminum and oxygen. [Answer: (a) BaBr2; (b) Al2O3] Self-Test C.2B Write the formula of the binary ionic compound formed by (a) lithium and nitrogen; (b) strontium and bromine. F28 FUNDAMENTALS The chemical formula of an ionic compound shows the ratio of the numbers of atoms of each element present in one formula unit. A formula unit of an ionic compound is a group of ions with the same number of atoms of each element as appears in its formula. SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Distinguish between molecules, ions, and atoms. ❑ 2 Identify compounds as organic or inorganic and as molecular or ionic. ❑ 3 Use various means of representing molecules. ❑ 4 Predict the anion or cation that a main-group element is likely to form (Example C.1). ❑ 5 Interpret chemical formulas in reference to the number of each type of atom present. ❑ 6 Predict the formulas of binary ionic compounds (Example C.2). EXERCISES C.1 Each of the containers pictured below holds either a mixture, a single compound, or a single element. The blue spheres represent atoms of one element, the green spheres the atoms of a second element. In each case, identify the type of contents. C.2 Each of the containers pictured below holds either a mixture, a single compound, or a single element. The blue spheres represent atoms of one element, the green spheres the atoms of a second element. In each case, identify the type of contents. C.3 The compound xanthophyll is a yellow compound found in bird feathers and flowers. Xanthophyll contains atoms of carbon, hydrogen, and oxygen in the ratio 20:28:1. Its molecules each have six oxygen atoms. Write the molecular formula of xanthophyll. C.4 Valinomycin is an antibiotic that has been used to treat tuberculosis. Valinomycin contains atoms of carbon, hydrogen, nitrogen, and oxygen in the ratio 9:15:1:3. Its molecules each have 18 oxygen atoms. Write the molecular formula of valinomycin. C.5 In the following ball-and-stick molecular structures, gray indicates carbon, red oxygen, white hydrogen, blue nitrogen, and green chlorine. Write the chemical formula of each structure. (a) (b) C.6 Write the chemical formula of each ball-and-stick structure. See Exercise C.5 for the color code. (a) (b) C.7 State whether each of the following elements is more likely to form a cation or an anion, and write the formula for the ion most likely to be formed: (a) cesium; (b) iodine; (c) selenium; (d) calcium. C.8 State whether each of the following elements is more likely to form a cation or an anion, and write the formula for the ion most likely to be formed: (a) tellurium; (b) barium; (c) rubidium; (d) bromine. C.9 How many protons, neutrons, and electrons are present in (a) 10 Be2+ ; (b) 17 O2Ϫ ; (c) 80 BrϪ ; (d) 75 As3Ϫ ? C.10 How many protons, neutrons, and electrons are present in (a) 64 Cu2ϩ ; (b) 138 La3ϩ ; (c) 12 C2Ϫ ; (d) 39 Kϩ ? C.11 Write the symbol of the ion that has (a) 9 protons, 10 neutrons, and 10 electrons; (b) 12 protons, 12 neutrons, and 10 electrons; (c) 52 protons, 76 neutrons, and 54 electrons; (d) 37 protons, 49 neutrons, and 36 electrons. C.12 Write the symbol of the ion that has (a) 11 protons, 13 neutrons, and 10 electrons; (b) 13 protons, 14 neutrons, and 10 electrons; (c) 34 protons, 45 neutrons, and 36 electrons; (d) 24 protons, 28 neutrons, and 22 electrons. C.13 Write the formula of a compound formed by combining (a) Al and Te; (b) Mg and O; (c) Na and S; (d) Rb and I. C.14 Write the formula of a compound formed by combining (a) Mg and N; (b) Ga and S; (c) Ba and Cl; (d) K and Se. C.15 A main-group element in Period 3 forms the following ionic compounds: EBr3 and E2O3. (a) To which group does the element E belong? (b) Write the name and symbol of element E. (a) (b) (a) (b) D.2 NAMES OF ANIONS F29 FUNDAMENTALS C.16 A main-group element in Period 3 forms the molecular compound H2E and the ionic compound Na2E. (a) To which group does the element E belong? (b) Write the name and symbol of element E. C.17 Determine the fraction of the total mass of a 48 Ti atom that is due to (a) neutrons; (b) protons; (c) electrons. (d) What is the mass of protons in a titanium bicycle frame of mass 30. kg? Assume the total mass of the bicycle frame is due to 48 Ti. Note: The masses of free protons and neutrons are slightly higher than the masses of these particles in atoms, so the answer is only an approximation. C.18 (a) Determine the total number of protons, neutrons, and electrons in one water molecule, H2O, assuming that only the most common isotopes, 1 H and 16 O, are present. (b) What are the total masses of protons, neutrons, and electrons in this water molecule? (c) What fraction of your own mass is due solely to the electrons in your body, assuming that you consist primarily of water made from this type of molecule? Note: The masses of free protons and neutrons are slightly higher than the masses of these particles in atoms; so the answer is only an approximation. C.19 The following compounds contain polyatomic ions. (a) Write the formula for the compound formed from sodium ions and hydrogen phosphite ions (HPO3 2Ϫ ). (b) Write the formula for ammonium carbonate, which is formed from ammonium ions (NH4 ϩ ) and carbonate ions (CO3 2Ϫ ). (c) The formula for magnesium sulfate is MgSO4; what is the charge of the cation in CuSO4? (d) The formula for potassium phosphate is K3PO4; what is the charge of the cation in Sn3(PO4)2? C.20 The following compounds contain polyatomic ions. (a) Write the formula for the compound formed from sodium ions and chromate ions (CrO4 2Ϫ ). (b) Write the formula for ammonium sulfite, which is formed from ammonium ions (NH4 ϩ ) and sulfite ions (SO3 2Ϫ ). (c) The formula for manganese(II) sulfate is MnSO4; what is the charge of the cation in Co2(SO4)3? (d) The formula for potassium hydrogen phosphate is K2HPO4; what is the charge of the cation in Pb3(PO4)4? C.21 Identify the following substances as elements, molecular compounds, or ionic compounds: (a) HCl; (b) S8; (c) CoS; (d) Ar; (e) CS2; (f) SrBr2. C.22 Identify the following substances as elements, molecular compounds, or ionic compounds: (a) NiO2; (b) NaF; (c) Xe; (d) P4; (e) NH3; (f) CO. D.1 Names of Cations D.2 Names of Anions D.3 Names of Ionic Compounds D.4 Names of Inorganic Molecular Compounds D.5 Names of Some Common Organic Compounds D THE NOMENCLATURE OF COMPOUNDS Many compounds were given informal, common names before their compositions were known. Common names include water, salt, sugar, ammonia, and quartz. A systematic name, on the other hand, reveals which elements are present and, in some cases, the arrangement of atoms. The systemic naming of compounds, which is called chemical nomenclature, follows the simple rules described in this section. D.1 Names of Cations The name of a monatomic cation is the same as the name of the element forming it, with the addition of the word ion, as in “sodium ion” for Naϩ . When an element can form more than one kind of cation, such as Cuϩ and Cu2ϩ from copper, we use the oxidation number, the charge of the cation, written as a Roman numeral in parentheses immediately following the name of the element. Thus, Cuϩ is a copper(I) ion and Cu2ϩ is a copper(II) ion. Similarly, Fe2ϩ is an iron(II) ion and Fe3ϩ is an iron(III) ion. As shown in Fig. C.6, most transition metals form more than one kind of ion; so unless we are given other information we need to include the oxidation number in the names of their compounds. Some older systems of nomenclature are still in use. For example, some cations were once denoted by the endings -ous and -ic for the ions with lower and higher charges, respectively. To make matters worse, these endings were in some cases added to the Latin form of the element’s name. Thus, iron(II) ions were called ferrous ions and iron(III) ions were called ferric ions (see Appendix 3C). We do not use this system in this text, but you will sometimes come across it and should be aware of it. The name of a monatomic cation is the name of the element plus the word ion; for elements that can form more than one type of cation, the oxidation number, a Roman numeral indicating the charge, is included. D.2 Names of Anions Monatomic anions, such as the ClϪ ions in sodium chloride and the O2Ϫ ions in quicklime (CaO), are named by adding the suffix -ide and the word ion to the first part of the name of the element (the “stem” of its name), as shown in Table D.1; thus, S2Ϫ is a sulfide ion and O2Ϫ is an oxide ion. There is usually no need to specify the charge, In chemical nomenclature, the oxidation number is sometimes called the Stock number for the German chemist Alfred Stock, who devised this numbering system. Oxidation numbers are discussed in more detail in Sections K and 2.8. nitrite ion, NO2 Ϫ nitrous acid, HNO2 nitrate ion, NO3 Ϫ nitric acid, HNO3 phosphate ion, PO4 3Ϫ phosphoric acid, H3PO4 hydrogen phosphate ion, HPO4 2Ϫ dihydrogen phosphate ion, H2PO4 Ϫ sulfite ion, SO3 2Ϫ sulfurous acid, H2SO3 hydrogen sulfite ion, HSO3 Ϫ sulfate ion, SO4 2Ϫ sulfuric acid, H2SO4 hydrogen sulfate ion, HSO4 Ϫ hypochlorite ion, ClOϪ hypochlorous acid, HClO chlorite ion, ClO2 Ϫ chlorous acid, HClO2 chlorate ion, ClO3 Ϫ chloric acid, HClO3 perchlorate ion, ClO4 Ϫ perchloric acid, HClO4 fluoride ion, FϪ hydrofluoric acid,* HF (hydrogen fluoride) chloride ion, ClϪ hydrochloric acid,* HCl (hydrogen chloride) bromide ion, BrϪ hydrobromic acid,* HBr (hydrogen bromide) iodide ion, IϪ hydroiodic acid,* HI (hydrogen iodide) oxide ion, O2Ϫ water, H2O hydroxide ion, OHϪ sulfide ion, S2Ϫ hydrosulfuric acid,* H2S hydrogen sulfide ion, HSϪ (hydrogen sulfide) cyanide ion, CNϪ hydrocyanic acid,* HCN (hydrogen cyanide) acetate ion, CH3CO2 Ϫ acetic acid, CH3COOH carbonate ion, CO3 2Ϫ carbonic acid, H2CO3 hydrogen carbonate (bicarbonate) ion, HCO3 Ϫ *The name of the aqueous solution of the compound. The name of the compound itself is in parentheses. Hypo comes from the Greek word for “under.” Per is the Latin word for “all over,” suggesting that the element’s ability to combine with oxygen is finally satisfied. TABLE D.1 Common Anions and Their Parent Acids Anion Parent acid Anion Parent acid because most elements that form monatomic anions form only one kind of ion. The ions formed by the halogens are collectively called halide ions and include fluoride (FϪ ), chloride (ClϪ ), bromide (BrϪ ), and iodide (IϪ ) ions. Polyatomic ions (see Section C) include the oxoanions, which are ions that contain oxygen (see Table D.1). If only one oxoanion of an element exists, its name is formed by adding the suffix -ate to the stem of the name of the element, as in the carbonate ion, CO3 2Ϫ . Some elements can form two types of oxoanions, with different numbers of oxygen atoms, so we need names that distinguish them. Nitrogen, for example, forms both NO2 Ϫ and NO3 Ϫ . In such cases, the ion with the larger number of oxygen atoms is given the suffix -ate, and that with the smaller number of oxygen atoms is given the suffix -ite. Thus, NO3 Ϫ is nitrate, and NO2 Ϫ is nitrite. The nitrate ion is an important source of nitrogen for plants and is included in some fertilizers (such as ammonium nitrate, NH4NO3). Some elements—particularly the halogens—form more than two kinds of oxoanions. The name of the oxoanion with the smallest number of oxygen atoms is formed by adding the prefix hypo- to the -ite form of the name, as in the hypochlorite ion, ClOϪ . The oxoanion with the most oxygen atoms is named with the prefix per- added to the -ate form of the name. An example is the perchlorate ion, ClO4 Ϫ . The rules for naming polyatomic ions are summarized in Appendix 3A and common examples are listed in Table D.1. Hydrogen is present in some anions. Two examples are HSϪ and HCO3 Ϫ . The names of these anions begin with “hydrogen.” Thus, HSϪ is the hydrogen sulfide ion, and HCO3 Ϫ is the hydrogen carbonate ion. You might also see the name of the ion written as a single word, as in hydrogencarbonate ion, which is the more modern style. In an older system of nomenclature, which is still quite widely used, an anion containing hydrogen is named with the prefix bi-, as in bicarbonate ion for HCO3 Ϫ . If two hydrogen atoms are present in an anion, as in H2PO4 Ϫ , then the ion is named as a dihydrogen anion, in this case as dihydrogen phosphate. Self-Test D.1A Write (a) the name of the IOϪ ion and (b) the formula of the hydrogen sulfite ion. [Answer: (a) Hypoiodite ion; (b) HSO3 Ϫ ] Self-Test D.1B Write (a) the name of the H2AsO4 Ϫ ion and (b) the formula of the chlorate ion. Names of monatomic anions end in -ide. Oxoanions are anions that contain oxygen. The suffix -ate indicates a greater number of oxygen atoms than the F30 FUNDAMENTALS TABLE D.2 Prefixes Used for Naming Compounds Prefix Meaning Prefix Meaning mono- 1 di- 2 tri- 3 tetra- 4 penta- 5 hexa- 6 TOOLBOX D.1 HOW TO NAME IONIC COMPOUNDS CONCEPTUAL BASIS The aim of chemical nomenclature is to be simple but unambiguous. Ionic and molecular compounds use different procedures; so it is important first to identify the type of compound. To name an ionic compound, we name the ions present and then combine the names of the ions. PROCEDURE Step 1 Identify the cation and the anion (see Table D.1 or Appendix 3A, if necessary). To determine the oxidation number of the cation, decide what cation charge is required to cancel the total negative charge of the anions. Step 2 Name the cation. If the metal can have more than one oxidation number (most transition metals and some metals in Groups 12 through 15/V), give its charge as a Roman numeral. Step 3 Name the anion. If the anion is monatomic, change the ending of the element’s name to -ide. For an oxoanion: (a) For elements that form two oxoanions, give the ion with the larger number of oxygen atoms the suffix -ate and that with the smaller number of oxygen atoms the suffix -ite. (b) For elements that form a series of four oxoanions, add the prefix hypo- to the name of the oxoanion with the smallest number of oxygen atoms. Add the prefix per- to the oxoanion with the highest number of oxygen atoms. For other polyatomic anions, find the name of the ion in Table D.1 or Appendix 3A. If hydrogen is present, add “hydrogen” to the name of the anion. If two hydrogen atoms are present, add “dihydrogen” to the name of the anion. Step 4 If water molecules appear in the formula, the compound is a hydrate. Add the word hydrate with a Greek prefix corresponding to the number in front of H2O. For examples of how these rules are applied, see Example D.1. suffix -ite within the same series of oxoanions. In series of three or more related oxoanions the prefix per- indicates the maximum number of oxygen atoms; the prefix hypo- indicates the least number of oxygen atoms. D.3 Names of Ionic Compounds An ionic compound is named with the cation name first, followed by the name of the anion; the word ion is omitted in each case. The oxidation number of the cation is given if more than one charge is possible. However, if the cation comes from an element that exists in only one charge state (as listed in Fig. C.6), then the oxidation number is omitted. Typical names include potassium chloride (KCl), a compound containing Kϩ and ClϪ ions; and ammonium nitrate (NH4NO3), which contains NH4 ϩ and NO3 Ϫ ions. The cobalt chloride that contains Co2ϩ ions (CoCl2) is called cobalt(II) chloride; CoCl3 contains Co3ϩ ions and is called cobalt(III) chloride. Notice that the number of chloride ions is determined by the need for charge balance. Some ionic compounds form crystals that incorporate a definite proportion of molecules of water as well as the ions of the compound itself. These compounds are called hydrates. For example, copper(II) sulfate normally exists as blue crystals of composition CuSO4 .5H2O. The raised dot in this formula separates the waters of hydration from the rest of the formula and the number before the H2O indicates how many water molecules are present in each formula unit. Hydrates are named by first giving the name of the compound, then adding the word hydrate with a Greek prefix indicating how many molecules of water are found in each formula unit (Table D.2). For example, the name of CuSO4 .5H2O, the common blue form of this compound, is copper(II) sulfate pentahydrate. When this compound is heated, the water of hydration is lost and the blue crystals crumble to a white powder (Fig. D.1). The white powder is CuSO4 itself. When we wish to emphasize that the compound has lost its water of hydration, we call it anhydrous. Thus, CuSO4 is anhydrous copper(II) sulfate. The distinction can be important: if you buy sodium sulfate decahydrate, Na2SO4и10H2O, instead of its anhydrous form, Na2SO4, you are buying a lot of water! hepta- 7 octa- 8 nona- 9 deca- 10 undeca- 11 dodeca- 12 FIGURE D.1 Blue crystals of copper(II) sulfate pentahydrate (CuSO4·5H2O) lose water above 150°C and form the white anhydrous powder (CuSO4) seen in this petri dish. The color is restored when water is added; and, in fact, anhydrous copper sulfate has such a strong attraction for water that it is usually colored a very pale blue from reaction with the water in air. Lab Video D.1 Step 3 Name the anion and combine the names of the ions with the cation first. chromium(III) chloride barium perchlorate Step 4 If H2O is present, add hydrate with a Greek prefix. chromium(III) chloride hexahydrate Self-Test D.2A Name the compounds (a) NiCl2и2H2O; (b) AlF3; (c) Mn(IO2)2. [Answer: (a) Nickel(II) chloride dihydrate; (b) aluminum fluoride; (c) manganese(II) iodite] Self-Test D.2B Name the compounds (a) AuCl3; (b) CaS; (c) Mn2O3. Ionic compounds are named by starting with the name of the cation (with its oxidation number if more than one charge is possible), followed by the name of the anion; hydrates are named by adding the word hydrate, preceded by a Greek prefix indicating the number of water molecules in the formula unit. D.4 Names of Inorganic Molecular Compounds Many simple inorganic molecular compounds are named by using the Greek prefixes in Table D.2 to indicate the number of each type of atom present. Usually, we do not use a prefix if only one atom of an element is present; for example, NO2 is nitrogen dioxide. An important exception to this rule is carbon monoxide, CO. When naming common binary molecular compounds—molecular compounds built from two elements—name the element that occurs further to the right in the periodic table second, with its ending changed to -ide: phosphorus trichloride, PCl3 dinitrogen oxide, N2O sulfur hexafluoride, SF6 dinitrogen pentoxide, N2O5 Some exceptions to these rules are the phosphorus oxides and compounds that are generally known by their common names. The phosphorus oxides are distinguished by the oxidation number of phosphorus, which is written as though phosphorus were a metal and the oxygen present as O2Ϫ . Thus, P4O6 is named phosphorus(III) oxide as though it were (P3ϩ )4(O2Ϫ )6, and P4O10 is named phosphorus(V) oxide as though it were (P5ϩ )4(O2Ϫ )10. These compounds, though, are molecular. Some binary molecular compounds, such as NH3 and H2O, have widely used common names (Table D.3). In both the names and the molecular formulas of compounds formed between hydrogen and nonmetals in Groups 16/VI or 17/VII hydrogen is written first: for example, the formula for hydrogen chloride is HCl and that for hydrogen sulfide is H2S. Note that, when these compounds are dissolved in water, most act as acids and are named as acids. Binary acids are named by adding the prefix hydro- and changing the ending of the name of the second element to -ic acid, as in hydrochloric acid for HCl in water and hydrosulfuric acid for H2S in water. An aqueous solution, a solution in water, is indicated by (aq) after the formula. Thus, HCl, the compound itself, is hydrogen chloride, and HCl(aq), its aqueous solution, is hydrochloric acid. TABLE D.3 Common Names for Some Simple Molecular Compounds Formula* Common name NH3 ammonia N2H4 hydrazine NH2OH hydroxylamine PH3 phosphine NO nitric oxide N2O nitrous oxide C2H4 ethylene C2H2 acetylene *For historical reasons, the molecular formulas of binary hydrogen compounds of Group 15/V elements are written with the Group 15/V element first. F32 FUNDAMENTALS Step 1 Identify the cation and anion. Step 2 Name the cation, giving the charge of the transition-metal cation as a Roman numeral. Note that in (a) there are three ClϪ ions; so the charge on Cr must be ϩ3. (a) CrCl3 и 6H2O: Cr3ϩ , ClϪ (b) Ba(ClO4)2: Ba2ϩ , ClO4 Ϫ chromium(III) barium EXAMPLE D.1 Naming ionic inorganic compounds Name (a) CrCl3 и 6H2O and (b) Ba(ClO4)2. PLAN Use the rules in Toolbox D.1. SOLVE FUNDAMENTALS D.4 NAMES OF INORGANIC MOLECULAR COMPOUNDS F33 An oxoacid is an acidic molecular compound that contains oxygen. Oxoacids are the parents of the oxoanions in the sense that an oxoanion is formed by removing one or more hydrogen ions from an oxoacid molecule (see Table D.1). In general, -ic oxoacids are the parents of -ate oxoanions and -ous oxoacids are the parents of -ite oxoanions. For example, H2SO4, sulfuric acid, is the parent acid of the sulfate ion, SO4 2Ϫ . Similarly, the parent acid of the sulfite ion, SO3 2Ϫ , is the molecular compound H2SO3, sulfurous acid. TOOLBOX D.2 HOW TO NAME SIMPLE INORGANIC MOLECULAR COMPOUNDS CONCEPTUAL BASIS The aim of chemical nomenclature is to be simple but unambiguous. A systematic name specifies the elements present in the molecule and the numbers of atoms of each element. PROCEDURE Determine the type of compound and then apply the corresponding rules. Binary molecular compounds other than acids The compound is generally not an acid if its formula does not begin with H. Step 1 Write the name of the first element, followed by the name of the second, with its ending changed to -ide. Step 2 Add Greek prefixes to indicate the number of atoms of each element. “Mono-” is usually omitted. See Example D.2(a) and (b). Acids An inorganic acid has a formula that typically begins with H; oxoacids have formulas that begin with H and end in O. We distinguish between binary hydrides, such as HX, which are not named as acids, and their aqueous solutions, HX(aq), which are. Step 1 If the compound is a binary acid in solution, add “hydro . . . ic acid” to the root of the element’s name. See Example D.2(c). Step 2 If the compound is an oxoacid, derive the name of the acid from the name of the polyatomic ion that it produces, as in Toolbox D.1. In general, -ate ions come from -ic acids -ite ions come from -ous acids Retain any prefix, such as hypo- or per-. See Example D.2(d). EXAMPLE D.2 Naming inorganic molecular compounds Give the systematic names of (a) N2O4, (b) ClO2, (c) HI(aq), and (d) HNO2. PLAN Proceed as in Toolbox D.2. SOLVE (a) The molecule N2O4 has two nitrogen atoms and four oxygen atoms. Dinitrogen tetroxide (b) A ClO2 molecule has one chlorine atom and two oxygen atoms. Chlorine dioxide (c) HI(aq) is a binary acid formed when hydrogen iodide dissolves in water. Hydroiodic acid (The molecular compound HI is hydrogen iodide.) EXAMPLE D.3 Writing the formula of a binary compound from its name Write the formulas of (a) cobalt(II) chloride hexahydrate; (b) diboron trisulfide. PLAN First check to see whether the compounds are ionic or molecular. Many compounds that contain a metal are ionic. Write the symbol of the metal first, followed by the symbol of the nonmetal. The charges on the ions are determined as shown in Examples C.1 and C.2. Subscripts are chosen to balance charges. Compounds of two nonmetals are normally molecular. Write their formulas by listing the symbols of the elements in the same order as in the name, with subscripts corresponding to the Greek prefixes used. SOLVE Self-Test D.3A Name (a) HCN(aq); (b) BCl3; (c) IF5. [Answer: (a) Hydrocyanic acid; (b) boron trichloride; (c) iodine pentafluoride] Self-Test D.3B Name (a) PCl3; (b) SO3; (c) HBr(aq). Self-Test D.4A Write the formulas for (a) vanadium(V) oxide; (b) calcium carbide; (c) germanium tetrafluoride; (d) dinitrogen trioxide. [Answer: (a) V2O5; (b) Ca2C; (c) GeF4; (d) N2O3] Self-Test D.4B Write the formulas for (a) cesium sulfide tetrahydrate; (b) manganese(VII) oxide; (c) hydrogen cyanide (a poisonous gas); (d) disulfur dichloride. (d) HNO2 is an oxoacid, the parent acid of the nitrite ion, NO2 Ϫ . Nitrous acid F34 FUNDAMENTALS (a) Determine if the compound is ionic or molecular. Metal and nonmetal, so ionic. Determine the charge on the cation. The II in cobalt(II) indicates a ϩ2 charge, so Co2ϩ . Determine the charge on the anion. Cl is in Group 17/VII, so has the charge 17 Ϫ 18 ϭ Ϫ1, so ClϪ . Balance charges. 2 ClϪ ions are required for each Co2ϩ ion, so CoCl2. Add waters of hydration. Hexahydrate, so 6 water molecules are attached: CoCl2 и 6H2O. (b) Determine if the compound is ionic or molecular. Two nonmetals, so molecular. Convert Greek prefixes into subscripts. di ϭ 2; tri ϭ 3, so B2S3. FUNDAMENTALS D.5 NAMES OF SOME COMMON ORGANIC COMPOUNDS F35 1 Methane, CH4 2 Ethane, C2H6 3 Benzene, C6H6 4 Ethanol, CH3CH2OH 5 Methanol, CH3OH 6 Carboxyl group, COOH 7 Acetic acid, CH3COOH 8 Formic acid, HCOOH Binary molecular compounds are named by using Greek prefixes to indicate the number of atoms of each element present; the element named second has its ending changed to -ide. D.5 Names of Some Common Organic Compounds There are millions of organic compounds; many consist of highly intricate molecules, so their names can be very complicated. You could, for example, find yourself asking for ␣-D-glucopyranosyl(1→2)-␤-D-fructofuranose when all you wanted was sucrose (sugar). However, for most of this text, we will need to know only a few simple organic compounds, and this section will introduce some of them. Chapters 18 and 19 present a more complete introduction to the nomenclature of organic compounds. At this stage it is helpful to know that compounds of hydrogen and carbon are called hydrocarbons. They include methane, CH4 (1); ethane, C2H6 (2); and benzene, C6H6 (3). Hydrocarbons that have no carbon¬carbon multiple bonds are called alkanes. Thus, methane and ethane are both alkanes. The unbranched alkanes with up to 12 carbon atoms are listed in Table D.4. Notice that Greek prefixes are used to name all the alkanes with five or more carbon atoms. Hydrocarbons with double bonds are called alkenes. Ethene, CH2“CH2, is the simplest example of an alkene. It used to be (and still widely is) called ethylene. Benzene is a hydrocarbon with double bonds, and it has such distinctive properties that it is regarded as the parent hydrocarbon of a separate class of compounds called aromatic compounds. The hexagonal benzene ring is exceptionally stable and can be found in many important compounds. Specific groups of atoms derived from hydrocarbons, such as ¬CH3, methyl, and ¬CH2CH3, ethyl, are named by replacing the ending of the parent hydrocarbon’s name by -yl. The hydrocarbons are the basic framework for all organic compounds. Different classes of organic compounds have one or more of the hydrogen atoms replaced by other atoms or groups of atoms (see Chapter 19 for a more comprehensive list). All we need to be aware of at this stage are the three classes of compounds known as alcohols, carboxylic acids, and haloalkanes: An alcohol is a type of organic compound that contains an ¬OH group. Ethanol, CH3CH2OH (4), the “alcohol” of beer and wine, is an ethane molecule in which one H atom has been replaced by an ¬OH group, and CH3OH (5) is the toxic alcohol called methanol, or wood alcohol. A carboxylic acid is a compound that contains the carboxyl group, ¬COOH (6). The most common example is acetic acid, CH3COOH (7), the acid that gives vinegar its sharp taste. Formic acid, HCOOH (8), is the acid of ant venom. A haloalkane is an alkane in which one or more H atoms have been replaced by halogen atoms. TABLE D.4 Alkane Nomenclature Number of carbon atoms Formula Name of alkane Name of alkyl group 1 CH4 methane methyl 2 CH3CH3 ethane ethyl 3 CH3CH2CH3 propane propyl 4 CH3(CH2)2CH3 butane butyl 5 CH3(CH2)3CH3 pentane pentyl 6 CH3(CH2)4CH3 hexane hexyl 7 CH3(CH2)5CH3 heptane heptyl 8 CH3(CH2)6CH3 octane octyl 9 CH3(CH2)7CH3 nonane nonyl 10 CH3(CH2)8CH3 decane decyl 11 CH3(CH2)9CH3 undecane undecyl 12 CH3(CH2)10CH3 dodecane dodecyl 10 Trichloromethane, CHCl3 ❑ 1 Name ions, binary inorganic compounds, oxoacids, compounds with common polyatomic ions, and hydrates, and write their formulas (Toolboxes D.1 and D.2, Self-Test D.1, and Examples D.1, D.2, and D.3). ❑ 2 Name simple hydrocarbons and substituted methane (Section D.5). ❑ 3 Identify alcohols and carboxylic acids from their formulas (Self-Test D.5). SKILLS YOU SHOULD HAVE MASTERED D.1 Write the formula of (a) manganese(II) chloride; (b) calcium phosphate; (c) aluminum sulfite; (d) magnesium nitride. D.2 Write the formula of (a) barium hydroxide; (b) cobalt(II) phosphite; (c) manganese(II) bromide; (d) chromium(III) sulfide. D.3 Name the following ionic compounds. Write both the old and the modern names wherever appropriate. (a) Ca3(PO4)2, the major inorganic component of bones; (b) SnS2; (c) V2O5; (d) Cu2O. D.4 The following ionic compounds are commonly found in laboratories. Write the modern name of (a) NaHCO3 (baking soda); (b) Hg2Cl2 (calomel): (c) NaOH (lye); (d) ZnO (calamine). D.5 Write the formula of (a) titanium dioxide; (b) silicon tetrachloride; (c) carbon disulfide; (d) sulfur tetrafluoride; (e) lithium sulfide; (f) antimony pentafluoride; (g) dinitrogen pentoxide; (h) iodine heptafluoride. D.6 Write the formula of (a) dinitrogen pentoxide: (b) hydrogen iodide; (c) oxygen difluoride; (d) phosphorus trichloride; (e) sulfur trioxide; (f) carbon tetrabromide; (g) bromine trifluoride. D.7 Name each of the following binary molecular compounds: (a) SF6; (b) N2O5; (c) NI3; (d) XeF4; (e) AsBr3; (f) ClO2. D.8 The following compounds are often found in chemical laboratories. Name each compound: (a) SiO2 (silica); (b) SiC (carborundum); (c) N2O (a general anesthetic); (d) P4O10 (a drying agent for organic solvents); (e) CS2 (a solvent); (f) SO2 (a bleaching agent); (g) NH3 (a common reagent). D.9 The following aqueous solutions are common laboratory acids. What are their names? (a) HCl(aq); (b) H2SO4(aq); (c) HNO3(aq); (d) CH3COOH(aq); (e) H2SO3(aq); (f) H3PO4(aq). D.10 The following acids are used in chemical laboratories, although they are less common than those in Exercise D.9. Write the formula of (a) perchloric acid; (b) hypochlorous acid; (c) hypoiodous acid; (d) hydrofluoric acid; (e) phosphorous acid; (f) periodic acid. D.11 Write the formula for the ionic compound formed from (a) zinc and fluoride ions; (b) barium and nitrate ions; (c) silver and iodide ions; (d) lithium and nitride ions; (e) chromium(III) and sulfide ions. D.12 Write the formula for the ionic compound formed from (a) calcium and bromide ions; (b) ammonium and phosphite ions; (c) cesium and oxide ions; (d) gallium and sulfide ions; (e) lithium and nitride ions. D.13 (a) Write the formula for and name the compound formed when the element in Group 2, Period 6 of the periodic table combines with the element in Group 17/VII, Period 3. (b) Is the compound molecular or ionic? D.14 (a) Write the formula for and name the compound formed when the element in Group 1, Period 5 of the periodic table combines with the element in Group 16/VI, Period 4. (b) Is the compound molecular or ionic? D.15 Name each of the following compounds: (a) Na2SO3; (b) Fe2O3; (c) FeO; (d) Mg(OH)2; (e) NiSO4и6H2O; (f) PCl5; (g) Cr(H2PO4)3; (h) As2O3; (i) RuCl2. D.16 Name each of the following compounds: (a) CrBr2и6H2O; (b) Co(NO3)3и6H2O; (c) InCl3; (d) BrF; (e) CrO3; (f) Cd(NO2)2; (g) Ca(ClO3)2; (h) Ni(ClO2)2; (i) V2O5. D.17 Each of the following compounds has an incorrect name. Correct each of the mistakes. (a) CuCO3, copper(I) carbonate; (b) K2SO3, potassium sulfate; (c) LiCl, lithium chlorine. D.18 Each of the following compounds has an incorrect formula. Correct each of the mistakes. (a) sodium sulfate, NaSO4; (b) magnesium chlorite, Mg(ClO)2; (c) phosphorus(V) oxide, P2O10. EXERCISES F36 FUNDAMENTALS Haloalkanes include chloromethane, CH3Cl (9), and trichloromethane, CHCl3 (10). The latter compound has the common name chloroform and was an early anesthetic. Notice that the names are formed by shortening the name of the halogen to fluoro-, chloro-, bromo-, or iodo- and adding a Greek prefix indicating the number of halogen atoms. Self-Test D.5 A(a) Name CH2BrCl. (b) What type of compound is CH3CH(OH)CH3? [Answer: (a) Bromochloromethane; (b) alcohol] Self-Test D.5B (a) Name CH3CH2CH2CH2CH3. (b) What type of compound is CH3CH2COOH? The names of organic compounds are based on the names of the parent hydrocarbons; alcohols contain ¬OH groups, carboxylic acids contain ¬COOH groups, and haloalkanes contain halogen atoms. 9 Chloromethane, CH3Cl FUNDAMENTALS E.1 THE MOLE F37 D.19 Name each of the following organic compounds: (a) CH3CH2CH2CH2CH2CH2CH3; (b) CH3CH2CH3; (c) CH3CH2CH2CH2CH3; (d) CH3CH2CH2CH3. D.20 Name each of the following organic compounds: (a) CH4; (b) CH3F; (c) CH3Br; (d) CH3I. D.21 You come across some old bottles in a storeroom that are labeled (a) cobaltic oxide monohydrate, (b) cobaltous hydroxide. Using Appendix 3C as a guide, write their modern names and chemical formulas. D.22 The formal rules of chemical nomenclature result in a certain compound used for electronic components being called barium titanate(IV), in which the oxidation state of titanium is ϩ4. See if you can work out its likely chemical formula. When you have identified the rules for naming oxoanions, suggest a formal name for H2SO4. D.23 A main-group element E in Period 3 forms the molecular compound EH4 and the ionic compound Na4E. Identify element E and write the names of the compounds described. D.24 A main-group element E in Period 5 forms the ionic compounds EBr2 and EO. Identify element E and write the names of the compounds described. D.25 The names of some compounds of hydrogen are exceptions to the usual rules of nomenclature. Look up the following compounds, write their names, and identify them as ionic or molecular: (a) LiAlH4; (b) NaH. D.26 The names of some compounds of oxygen are exceptions to the usual rules of nomenclature. Look up the following compounds, write their names, and identify them as ionic or molecular: (a) KO2; (b) Na2O2; (c) CsO3. D.27 Name each of the following compounds, using analogous compounds with phosphorus and sulfur as a guide: (a) H2SeO4; (b) Na3AsO4; (c) CaTeO3; (d) Ba3(AsO4)2; (e) H3SbO4; (f) Ni2(SeO4)3. D.28 Name each of the following compounds, using analogous compounds with phosphorus and sulfur as a guide: (a) AsH3; (b) H2Se; (c) Cu2TeO4; (d) Ca3(AsO3)2; (e) NaH2SbO4; (f) BaSeO3. D.29 What type of organic compound is (a) CH3CH2CH2OH; (b) CH3CH2CH2CH2COOH; (c) CH3F? D.30 What type of organic compound is (a) CH3CH2CH3; (b) CH3CH2Br; (c) CH3CH2COOH? E MOLES AND MOLAR MASSES Astronomically large numbers of molecules are present even in a tiny sample: even 1 mL of water contains 3 ϫ 1023 H2O molecules, more molecules than there are stars in the visible universe. How can we find out the numbers present and how do we report them? It is difficult to imagine and inconvenient to refer to large numbers such as 3 ϫ 1023 molecules, just as wholesalers find it inconvenient to report individual items instead of dozens (12) or gross (144). To keep track of the enormous numbers of atoms, ions, or molecules in a sample, we need an efficient way of reporting them. E.1 The Mole Chemists report numbers of atoms, ions, and molecules in terms of a unit called a “mole.” A mole is the analog of the wholesaler’s “dozen.” A “dozen” could be defined as the number of soda cans in a “twelve pack” carton supplied by a wholesaler. Even if you could not open the carton to count the number of cans inside, you could find out how many cans are in a dozen by weighing the carton and dividing the mass of the carton by the mass of one can. A similar approach is used to define the mole (abbreviated mol): 1 mole of objects contains the same number of objects as there are atoms in exactly 12 g of carbon-12. To see what we mean by 1 mol, we could weigh out 12 g of carbon-12 (Fig. E.1). But how can we tell how many atoms are present? Because counting atoms directly is impractical, we use an indirect route based on the mass of one atom. The mass of a carbon-12 atom has been found by mass spectrometry to be 1.992 65 ϫ 10Ϫ23 g. It follows that the number of atoms in exactly 12 g of carbon-12 is Because the mole is equal to this number, we can apply the definition to any object, not just carbon atoms (Fig. E.2): 1 mol of objects means 6.0221 ϫ 1023 of those objects. Number of C atoms = 12 g [exactly] 1.992 65 * 10-23 g = 6.0221 * 1023 E.1 The Mole E.2 Molar Mass The name mole comes from the Latin word for “massive heap.” Coincidentally, the animal of the same name makes massive heaps of soil on lawns. 12 g of carbon-12 FIGURE E.1 The definition of the mole: if we measure out exactly 12 g of carbon-12, then we have exactly 1 mol of carbon-12 atoms. There will be exactly an Avogadro’s number of atoms in the pile. mass of sample mass of one C atom (++++)++++* $++%++& F38 FUNDAMENTALS FIGURE E.2 Each sample consists of 1 mol of atoms of the element. Clockwise from the upper right are 32 g of sulfur, 201 g of mercury, 207 g of lead, 64 g of copper, and 12 g of carbon. Therefore, 1 mol of atoms of any element, 1 mol of ions, and 1 mol of molecules each contain 6.0221 ϫ 1023 atoms, ions, and molecules, respectively. Just as 1 g and 1 m are units for physical properties, so too is the unit 1 mol. The mole is the unit for the physical property formally called the amount of substance, n. However, that name has found little favor among chemists, who colloquially refer to n as “the number of moles.” A compromise, which is gaining acceptance, is to refer to n as the “chemical amount” or simply “amount” of entities present in a sample. Thus, 1.0000 mol of hydrogen atoms (6.0221 ϫ 10 23 hydrogen atoms), which is written 1.0000 mol H, is the chemical amount of hydrogen atoms in the sample. Take the advice of your instructor on whether to use the formal term. Like any SI unit, the mole can be used with prefixes. For example, 1 mmol ϭ 10Ϫ3 mol and 1 ␮mol ϭ 10Ϫ6 mol. Chemists encounter such small quantities when dealing with rare or expensive natural products and pharmaceuticals. The number of objects per mole, 6.0221 ϫ 1023 molϪ1 , is called Avogadro’s constant, NA, in honor of the nineteenth-century Italian scientist Amedeo Avogadro (Fig. E.3),who helped to establish the existence of atoms. Avogadro’s constant is used to convert between the chemical amount (the number of moles) and the number of atoms, ions, or molecules in that amount: Number of objects ϭ amount in moles ϫ number of objects per mole ϭ amount in moles ϫ Avogadro’s constant If we denote the number of objects by N and the amount of substance (in moles) by n, this relation is written N ϭ nNA (1)* A note on good practice: Avogadro’s constant is a constant with units, not a pure number. You will often hear people referring to Avogadro’s number: this is the pure number 6.0221 ϫ 1023 . To be unambiguous when using moles, we must be specific about which entities (that is, which atoms, molecules, formula units, or ions) we mean. For example, hydrogen occurs naturally as a gas, with each molecule built from two atoms, which is why it is denoted H2. We write 1 mol H if we mean hydrogen atoms or 1 mol H2 if we mean hydrogen molecules. Note that 1 mol H2 corresponds to 2 mol H. EXAMPLE E.1 Converting number of atoms into an amount in moles Nanotechnology researchers have developed a hydrogen storage device capable of storing 1.29 ϫ 1024 hydrogen atoms. What is the chemical amount (in moles) of hydrogen atoms that can be stored in the device? FIGURE E.3 Lorenzo Romano Amedeo Carlo Avogadro, Count of Quaregna and Cerreto (1776–1856). FUNDAMENTALS E.2 MOLAR MASS F39 ϭ ϫ 1 mol 2.14 mol 1.29 ϫ 1024 6.022 ϫ 1023 Evaluate There is indeed more than 1 mol of hydrogen atoms present in the device, as we anticipated. Self-Test E.1A A sample of a drug extracted from a fruit used by the Achuar Jivaro people of Peru to treat fungal infections is found to contain 2.58 ϫ 1024 oxygen atoms. What is the chemical amount (in moles) of O atoms in the sample? [Answer: 4.28 mol O] Self-Test E.1B A small cup of coffee contains 3.14 mol H2O. What is the number of H atoms present in the coffee? The amounts of atoms, ions, or molecules in a sample are expressed in moles, and Avogadro’s constant, NA, is used to convert between numbers of these particles and the numbers of moles. E.2 Molar Mass How can we determine the amount of substance present if we can’t count the atoms directly? We can find the amount of substance if we know the mass of the sample and the molar mass, M, the mass per mole of particles: The molar mass of an element is the mass per mole of its atoms. The molar mass of a molecular compound is the mass per mole of its molecules. The molar mass of an ionic compound is the mass per mole of its formula units. The units of molar mass in each case are grams per mole (gиmol–1 ). The mass of a sample is the amount (in moles) multiplied by the mass per mole (the molar mass), Mass of sample ϭ amount in moles ϫ mass per mole Therefore, if we denote the total mass of the sample by m, we can write m ϭ nM (2)* It follows that n ϭ m/M. That is, to find the amount in moles, n, we divide the total mass, m, of the sample by the molar mass of the species present. EXAMPLE E.2 Calculating the amount of atoms in a sample Calculate (a) the amount and (b) the number of F atoms in 22.5 g of fluorine. The molar mass of fluorine atoms is 19.00 gиmolϪ1 , or, more specifically, 19.00 gи(mol F)Ϫ1 . Anticipate Because the mass of fluorine present in the sample is greater than the mass of 1 mol F atoms, we should expect to find that more than 1 mol F is present. Anticipate Because the number of atoms in the sample is greater than 6 ϫ 1023 , we anticipate that more than 1 mol of hydrogen atoms is present. PLAN Rearrange Eq. 1 into n = N/NA and then substitute the data. SOLVE From n ϭ N/NA, n = 1.29 * 1024 H 6.0221 * 1023 mol-1 = 2.14 mol H F40 FUNDAMENTALS Evaluate As expected, more than 1 mol F is present. A note on good practice: To avoid ambiguity, specify the entities (in this case, fluorine atoms, F, not F2 molecules) in the units of the calculation. (b) To calculate the actual number, N, of atoms in the sample, we multiply the amount (in moles) by Avogadro’s constant: ϭ ϫ 1 mol 1.18 mol 22.5 g 19.00 g ϭ 1 mol1.18 mol 6.11 ϫ 1023 6.022 ϫ 1023 ϫ PLAN To find the amount in moles, divide the total mass of the sample by the molar mass. SOLVE That is, the sample contains 7.11 ϫ 1023 fluorine atoms. Self-Test E.2A The mass of a copper coin is 3.20 g. Suppose it were pure copper. (a) How many moles of Cu atoms would the coin contain, given a molar mass of Cu of 63.55 gиmolϪ1 ? (b) How many Cu atoms are present? [Answer: 0.0504 mol Cu; 3.03 ϫ 1022 Cu atoms] Self-Test E.2B In one day, 5.4 kg of aluminum was collected from a recycling bin. (a) How many moles of Al atoms did the bin contain, given that the molar mass of Al is 26.98 gиmolϪ1 ? (b) How many Al atoms were collected? The molar masses of elements are determined by using mass spectrometry to measure the masses of the individual isotopes and their abundances. The mass per mole of atoms is the mass of an individual atom multiplied by Avogadro’s constant (the number of atoms per mole): M ϭ matomNA (3a) The greater the mass of an individual atom, the greater the molar mass of the substance. However, most elements exist in nature as a mixture of isotopes. We saw in Section B, for instance, that neon exists as three isotopes, each with a different mass. In chemistry, we almost always deal with natural samples of elements, which have the natural abundance of isotopes. So, we need the average molar mass, the molar mass calculated by taking into account the masses of the isotopes and their relative abundances in typical samples: M ϭ matom, averageNA (3b) All molar masses quoted in this text refer to these average values. Their values are given in Appendix 2D. They are also included in the periodic table inside the front cover and in the alphabetical list of elements inside the back cover. (a) From n ϭ m/M, = 1.18 mol F n(F) = 22.5 g 19.00 gи(mol F)-1 = 22.5 19.00 mol F From N ϭ nNA, = 7.11 * 1023 F N = (1.18 mol F) * (6.022 * 1023 mol-1 ) E.2 MOLAR MASS F41 FUNDAMENTALS Evaluate As expected, the molar mass is close to 35 gиmolϪ1 . Self-Test E.3A In a typical sample of magnesium, 78.99% is magnesium-24 (with atomic mass 3.983 ϫ 10Ϫ23 g), 10.00% is magnesium-25 (4.149 ϫ 10Ϫ23 g), and 11.01% is magnesium-26 (4.315 ϫ 10Ϫ23 g). Calculate the molar mass of a typical sample of magnesium, given the atomic masses (in parentheses). [Answer: 24.31 gиmolϪ1 ] Self-Test E.3B Calculate the molar mass of copper, given that a natural sample typically consists of 69.17% copper-63, which has a molar mass of 62.94 gиmolϪ1 , and 30.83% copper-65, which has a molar mass of 64.93 gиmolϪ1 . EXAMPLE E.3 Evaluating an average molar mass Chlorine has two naturally occurring isotopes: chlorine-35 and chlorine-37. The mass of an atom of chlorine-35 is 5.807 ϫ 10Ϫ23 g and that of an atom of chlorine-37 is 6.139 ϫ 10Ϫ23 g. In a typical natural sample of chlorine, 75.77% of the sample is chlorine-35 and 24.23% is chlorine-37. What is the molar mass of a typical sample of chlorine? Anticipate Because the more abundant isotope is chlorine-35, we should expect to find that the molar mass of a typical sample will be close to 35 gиmolϪ1 . PLAN First calculate the average atomic mass of the isotopes by adding together the individual masses, each multiplied by the fraction that represents its abundance. Then obtain the molar mass, the mass per mole of atoms, by multiplying the average atomic mass by Avogadro’s constant. SOLVE The fraction (f) of chlorine-35 atoms in the sample is 75.77/100 ϭ 0.7577, and the fraction of chlorine-37 is 24.23/100 ϭ 0.2423. The average mass of an atom of chlorine in a natural sample is ϭ ϩ35Cl Cl 37 Cl From * (6.139 * 10-23 g) = 5.887 * 10-23 g matom, average = 0.7577 * (5.807 * 10-23 g) + 0.2423 + fchlorine-37 * mchlorine-37, matom, average = fchlorine-35 * mchlorine-35 It follows from Eq. 3b that the molar mass of a typical sample of chlorine atoms is ϫCl 6.011 ϫ 1023 1 mol From M ϭ matom, averageNA, M ϭ (5.887 ϫ 10Ϫ23 g) ϫ (6.022 ϫ 1023 molϪ1 ) ϭ 35.45 gиmolϪ1 To calculate the molar masses of compounds, we use the molar masses of the elements present: the molar mass of a compound is the sum of the molar masses of the elements that make up the molecule or the formula unit. We need only note how many times each atom or ion appears in the molecular formula or the formula unit of the ionic compound. For example, 1 mol of the ionic compound Al2(SO4)3 contains 2 mol Al, 3 mol S, and 12 mol O. Therefore, the molar mass of Al2(SO4)3 is = 342.14 gиmol-1 = 2(26.98 gиmol-1 ) + 3(32.06 gиmol-1 ) + 12(16.00 gиmol-1 ) M(Al2(SO4)3) = 2M(Al) + 3M(S) + 12M(O) For the most authoritative and up-todate listing of atomic weights, see the IUPAC link on the Web site for this text. (a) Equal masses (b) Equal amounts FIGURE E.4 (a) The two samples have the same mass but, because the atoms on the right are lighter than those on the left, more of them are required to balance the sample on the left. (b) The two samples contain the same number of atoms but, because the atoms on the right are lighter than those on the left, the mass of the sample on the right is the smaller of the two. Equal amounts (equal numbers of moles) of atoms do not necessarily have the same mass. EXAMPLE E.4 Calculating the mass of a sample corresponding to a given amount in moles Suppose we are preparing a solution of potassium permanganate, KMnO4, and need about 0.10 mol of the compound (that is, 0.10 mol KMnO4). How many grams of the compound do we need? Self-Test E.4A Calculate the molar mass of (a) ethanol, C2H5OH; (b) copper(II) sulfate pentahydrate. [Answer: (a) 46.07 gиmolϪ1 ; (b) 249.69 gиmolϪ1 ] Self-Test E.4B Calculate the molar mass of (a) phenol, C6H5OH; (b) sodium carbonate decahydrate. Two terms used throughout the chemical literature are atomic weight and molecular weight: The atomic weight of an element is the numerical value of its molar mass. The molecular weight of a molecular compound or the formula weight of an ionic compound is the numerical value of its molar mass. For instance, the atomic weight of hydrogen (molar mass 1.0079 gиmolϪ1 ) is 1.0079, the molecular weight of water (molar mass 18.02 gиmolϪ1 ) is 18.02, and the formula weight of sodium chloride (molar mass 58.44 gиmolϪ1 ) is 58.44. These three terms are traditional and deeply ingrained in chemical conversations, even though the numbers are not “weights.” The mass of an object is a measure of the quantity of matter that it contains, whereas the weight of an object is a measure of the gravitational pull that it experiences. Mass and weight are proportional to each other, but they are not identical. An astronaut would have the same mass (contain the same quantity of matter) but different weights on Earth and on Mars. A final point to keep in mind is that the “atomic weight” of an element allows us to make a good estimate of the numbers of protons and neutrons in its nuclei, because each proton and each neutron contribute close to one unit of mass to the atomic weight. Thus, we know that carbon, atomic weight 12.01, contains a total of 12 protons and neutrons. The atomic weight, however, is not exactly the mass number, because the mass of a nucleus is not exactly the sum of the masses of its protons and neutrons, and atomic weights (that is, molar masses) are averages that take into account the isotopic composition of typical samples of the element. Once the molar mass of a compound has been calculated, we can use the same technique used for elements to determine how many moles of molecules or formula units are in a sample of a given mass. Self-Test E.5A Calculate the amount of urea molecules, OC(NH2)2, in 2.3 ϫ 105 g of urea, which is used in facial creams and, on a bigger scale, as an agricultural fertilizer. [Answer: 3.8 ϫ 103 mol] Self-Test E.5B Calculate the amount of Ca(OH)2 formula units in 1.00 kg of slaked lime (calcium hydroxide), which is used to adjust the acidity of soils. Molar mass is important when we need to know the number of atoms in a sample. It would be impossible to count out 6 ϫ 1023 atoms of an element, but it is easy to measure out a mass equal to the molar mass of the element in grams. Each of the samples shown in Fig. E.2 was obtained in this way: each sample contains the same number of atoms of the element (6.022 ϫ 1023 ), but the masses vary because the masses of the atoms are different (Fig. E.4).The same rule applies to compounds. Because the molar mass of sodium chloride is 58.44 gиmol–1 , if we measure out 58.44 g of sodium chloride, we obtain a sample that contains 1.000 mol NaCl formula units (Fig. E.5). In practice, chemists rarely try to measure out an exact mass. Instead, they estimate the mass required and spoon out that mass approximately. Then they measure the mass of the sample precisely and convert it into an amount in moles (by using Eq. 2, n ϭ m/M) to find the precise amount that they have obtained. F42 FUNDAMENTALS SKILLS YOU SHOULD HAVE MASTERED F43 FUNDAMENTALS PLAN To find the mass of a stated amount of compound, we multiply the amount by the molar mass of the compound. SOLVE To find the mass of KMnO4 that corresponds to 0.10 mol KMnO4, we note that, because the molar mass of the compound is 158.04 gиmolϪ1 , FIGURE E.5 Each sample contains 1 mol of formula units of an ionic compound. From left to right are 58 g of sodium chloride (NaCl), 100 g of calcium carbonate (CaCO3), 278 g of iron(II) sulfate heptahydrate (FeSO4и7H2O), and 78 g of sodium peroxide (Na2O2). ϫ ϭ 0.10 mol 158.04 g 16 g 1 mol From m ϭ nM, m ϭ (0.10 mol) ϫ (158.04 gиmolϪ1 ) ϭ 16 g So, we need to measure out about 16 g of KMnO4. If, when we weigh the sample, we find that its actual mass is 14.87 g, the amount of KMnO4 that we actually weighed out is ϫ ϭ 158.04 g 14.87 g 1 mol 0.09409 mol From n ϭ m/M, = 0.094 09 mol KMnO4 n(KMnO4) = 14.87 g 158.04 gи(mol KMnO4)-1 Self-Test E.6A What mass of anhydrous sodium hydrogen sulfate should you weigh out to obtain about 0.20 mol NaHSO4? [Answer: About 24 g] Self-Test E.6B What mass of acetic acid should you weigh out to obtain 1.5 mol CH3COOH? The molar mass of a compound, the mass per mole of its molecules or formula units, is used to convert between the mass of a sample and the amount of molecules or formula units that it contains. ❑ 1 Use Avogadro’s constant to convert between amount in moles and the number of atoms, molecules, or ions in a sample (Examples E.1 and E.2). ❑ 2 Calculate the molar mass of an element, given its isotopic composition (Example E.3). ❑ 3 Calculate the molar mass of a compound, given its chemical formula. ❑ 4 Convert between mass and amount in moles by using the molar mass (Example E.4). SKILLS YOU SHOULD HAVE MASTERED E.1 The field of nanotechnology offers some intriguing possibilities, such as the creation of fibers one atom wide. Suppose you were able to string together 1.00 mol Ag atoms, each of radius 144 pm, into one of these fibers by encapsulating them in carbon nanotubes (see Chapter 6). How long would the fiber extend? E.2 If you won 1 mol of dollars in a lottery the day you were born, and spent 1 billion dollars a second for the rest of your life, what percentage of the prize money would remain, if any, when you decide to retire from spending at 90 years of age? E.3 In a nanotechnology lab you might have the capability to manipulate individual atoms. The atoms on the left are bromine atoms (molar mass 80 gиmolϪ1 ), those on the right are atoms of calcium (molar mass 40 gиmolϪ1 ). How many calcium atoms would have to be added to the pan on the right for the masses on the two pans to be equal? E.4 In a nanotechnology lab you might have the capability to manipulate individual atoms. The atoms on the left are aluminum atoms (molar mass 27 gиmolϪ1 ), those on the right are atoms of beryllium (molar mass 9 gиmolϪ1 ). How many beryllium atoms would have to be added to the pan on the right for the masses on the two pans to be equal? E.5 (a) The approximate population of Earth is 6.0 billion people. How many moles of people inhabit Earth? (b) If all people were pea pickers, then how long would it take for the entire population of Earth to pick 1 mol of peas at the rate of one pea per second, working 24 hours per day, 365 days per year? E.6 (a) One thousand tonnes (1000 t, 1 t ϭ 103 kg) of sand contains about a trillion (1012 ) grains of sand. How many tonnes of sand are needed to provide 1 mol of grains of sand? (b) Assuming the volume of a grain of sand is 1 mm3 and the land area of the continental United States is 3.6 ϫ 106 mi2 , how deep would the sand pile over the United States be if this area were evenly covered with 1 mol of grains of sand? E.7 Epsom salts consist of magnesium sulfate heptahydrate. Write its formula. (a) How many atoms of oxygen are in 5.15 g of Epsom salts? (b) How many formula units of the compound are present in 5.15 g? (c) How many moles of water molecules are in 5.15 g of Epsom salts? E.8 Copper metal can be extracted from a copper(II) sulfate solution by electrolysis (as described in Chapter 13). If 45.20 g of copper(II) sulfate pentahydrate, CuSO4и5H2O, is dissolved in 100mL of water and all the copper is electroplated out, what mass of copper would be obtained? E.9 The nuclear power industry extracts 6 Li but not 7 Li from natural samples of lithium. As a result, the molar mass of commercial samples of lithium is increasing. The current abundances of the two isotopes are 7.42% and 92.58%, respectively, and the masses of their atoms are 9.988 ϫ 1024 g and 1.165 ϫ 1023 g, respectively. (a) What is the current molar mass of a natural sample of lithium? (b) What will the molar mass be when the abundance of 6 Li is reduced to 5.67%? E.10 Calculate the molar mass of sulfur in a sample that consists of 95.0% 32 S (molar mass 31.97 gиmolϪ1 ), 0.8% 33 S (molar mass 32.97 gиmolϪ1 ), and 4.2% 34 S (molar mass 33.97 gиmolϪ1 ). E.11 The molar mass of boron atoms in a natural sample is 10.81 gиmolϪ1 . The sample is known to consist of 10 B (molar mass 10.013 gиmolϪ1 ) and 11 B (molar mass 11.093 gиmolϪ1 ). What are the percentage abundances of the two isotopes? E.12 Calculate the molar mass of the noble gas krypton in a natural sample, which is 0.3% 78 Kr (molar mass 77.92 gиmolϪ1 ), 2.3% 80 Kr (molar mass 79.91 gиmolϪ1 ), 11.6% 82 Kr (molar mass 81.91 gиmolϪ1 ), 11.5% 83 Kr (molar mass 82.92 gиmolϪ1 ), 56.9% 84 Kr (molar mass 83.91 gиmolϪ1 ), and 17.4% 86 Kr (molar mass 85.91 gиmolϪ1 ). E.13 Which sample in each of the following pairs contains the greater number of moles of atoms? (a) 75 g of indium or 80 g of tellurium; (b) 15.0 g of P or 15.0 g of S; (c) 7.36 ϫ 1027 atoms of Ru or 7.36 ϫ 1027 atoms of Fe. E.14 Calculate the mass, in micrograms, of (a) 3.27 ϫ 1016 Hg atoms; (b) 963 nmol Hf atoms; (c) 5.50 ␮mol Gd atoms; (d) 6.02 ϫ 1025 Sb atoms. E.15 A report stated that the Sudbury Neutrino Observatory in Sudbury, Canada, uses 1.00 ϫ 103 tonne (1 t ϭ 103 kg) of heavy water, D2O, in a spherical tank of diameter 12 m to detect subatomic particles called neutrinos. The density of normal water (H2O) at the temperature of the tank is 1.00 gиcmϪ3 . (a) Using a molar mass for deuterium of 2.014 gиmolϪ1 , calculate the molar mass of D2O. (b) Assuming that the volume occupied by a D2O molecule is the same as that occupied by an H2O molecule, calculate the density of heavy water. (c) Calculate the volume of the tank in cubic meters from your density data and the given mass of the heavy water then compare this volume with the volume of the tank calculated from its reported diameter. (d) Is the reported mass of heavy water accurate? (e) Is the assumption you made in part (b) reasonable? Explain your reasoning. (The volume of a sphere of radius r is .) E.16 A chemist orders 1.000 kg of D2O from an isotope supplier, who claims that the compound is 98% pure (that is, it contains no more than 2% H2O by mass). To check this claim, the chemist measures the density of the D2O and finds it to be 1.10 gиcmϪ3 . The density of normal water (H2O) at the temperature of the test is 1.00 gиcmϪ3 . Is the D2O as pure as advertised? (Molar mass of deuterium is 2.014 gиmolϪ1 .) E.17 Calculate the amount (in moles) and the number of molecules and formula units (or atoms, if indicated) in (a) 10.0 g of alumina, Al2O3; (b) 25.92 mg of hydrogen fluoride, HF; (c) 1.55 mg of hydrogen peroxide, H2O2; (d) 1.25 kg of glucose, C6H12O6; (e) 4.37 g of nitrogen as N atoms and as N2 molecules. E.18 Convert each of the following masses into amount (in moles) and into number of molecules (and atoms, if indicated). (a) 2.40 kg of H2O; (b) 49 kg of benzene (C6H6); (c) 260.0 g of phosphorus, as P atoms and as P4 molecules; (d) 5.0 g of CO2; (e) 5.0 g of NO2. V = 4 3␲r3 EXERCISES F44 FUNDAMENTALS EXERCISES F45 FUNDAMENTALS E.19 Calculate the amount (in moles) of (a) Cu2ϩ ions in 3.00 g of CuBr2; (b) SO3 molecules in 7.00 ϫ 102 mg of SO3; (c) FϪ ions in 25.2 kg of UF6; (d) H2O in 2.00 g of Na2CO3и10H2O. E.20 Calculate the amount (in moles) of (a) CNϪ in 4.00 g of NaCN; (b) O atoms in 4.00 ϫ 102 ng of H2O; (c) CaSO4 in 4.00 kg of CaSO4; (d) H2O in 4.00 mg of Al2(SO4)3и8H2O. E.21 (a) Determine the number of KNO3 formula units in 0.750 mol KNO3. (b) What is the mass (in milligrams) of 2.39 ϫ 1020 formula units of Ag2SO4? (c) Estimate the number of NaHCO2 formula units in 3.429 g of NaHCO2, sodium formate, which is used in dyeing and printing fabrics. E.22 (a) How many CaH2 formula units are present in 5.294 g of CaH2? (b) Determine the mass of 6.25 ϫ 1024 formula units of NaBF4, sodium tetrafluoroborate. (c) Calculate the amount (in moles) of 9.54 ϫ 1021 formula units of CeI3, cerium(III) iodide, a bright yellow, water-soluble solid. E.23 (a) Calculate the mass, in grams, of one water molecule. (b) Determine the number of H2O molecules in 1.00 kg of water. E.24 Octane, C8H18, is typical of the molecules found in gasoline. (a) Calculate the mass of one octane molecule. (b) Determine the number of C8H18 molecules in 1.00 mL of octane, the mass of which is 0.82 g. E.25 A chemist measured out 8.61 g of copper(II) chloride tetrahydrate, CuCl2и4H2O. (a) How many moles of CuCl2и4H2O were measured out? (b) How many moles of ClϪ ions are present in the sample? (c) How many H2O molecules are present in the sample? (d) What fraction of the total mass of the sample was due to oxygen? E.26 Anhydrous copper(II) sulfate is difficult to dry completely. What mass of copper(II) sulfate would remain after removing 90% of the water from 250. g of CuSO4и5H2O? E.27 Suppose you had bought 2.5 kg of Na2CO3и10H2O for $175, instead of 2.5 kg of Na2CO3 for $195. (a) How much water did you buy and how much did you pay per liter of water? (The mass of 1 L of water is 1 kg.) (b) What would have been a fair price for the hydrated compound, valuing water at zero cost? E.28 A chemist wants to extract the gold from 57.75 g of gold(III) chloride dihydrate, AuCl3и2H2O, by electrolysis of an aqueous solution (this technique is described in Chapter 13). What mass of gold could be obtained from the sample? E.29 The king of Zirconia is naturally fond of the element zirconium and has established an independent definition of the mole based on zirconium. The mass of one zirconium-90 atom is 1.4929 ϫ 10Ϫ22 g. If zirconium were the standard used for molar mass (instead of carbon-12), 1 mol would be defined as the amount of substance that contains the same number of entities as there are atoms in exactly 90 g of zirconium-90. In that case, what would be (a) the molar mass of carbon-12; (b) the (average) molar mass of gold? E.30 The isotope silicon-28 has been proposed as a new standard for the molar masses of elements because it can be prepared to a very high degree of purity. The mass of one silicon-28 atom is 4.64567 ϫ 10Ϫ23 g. If silicon were the standard used for molar mass (instead of carbon-12), 1 mol would be defined as the amount of substance that contains the same number of entities as there are atoms in exactly 28 g of silicon-28. In that case, what would be (a) the molar mass of carbon-12; (b) the (average) molar mass of chlorine? E.31 The density of sodium borohydride is 1.074 gиcmϪ3 . If 3.93 g of sodium borohydride contains 2.50 ϫ 1023 H atoms, how many moles of H atoms are present in 28.0 cm3 of sodium borohydride? E.32 Chloroform is produced industrially from dichloroethane (C2H4Cl2). Chloroform consists of molecules containing five atoms each and, at 20°C, has a density of 1.492 gиcmϪ3 . Given that 0.250 mol of chloroform molecules occupies 20.0 mL, what mass (in grams) of dichloroethane contains the same number of atoms as 36.8 g of chloroform? E.33 The decay of teeth can be slowed by the use of fluoridated toothpaste. The fluoride ions convert the hydroxyapatite, Ca5(PO4)3OH, in tooth enamel into fluorapatite, Ca5(PO4)3F. If all the hydroxyapatite is converted into fluorapatite, by what percentage does this conversion increase the mass of the enamel? E.34 The antibiotic tetracycline has the formula C22H24N2O8. Safe dosage of the drug is 0.24 ␮mol/kg/day. If a child weighing 45 lb is administered tetracycline in four equally divided doses per day, what mass of tetracycline should be present in each dose? F DETERMINATION OF CHEMICAL FORMULAS One way that scientists discover new drugs is by studying the properties of compounds found in plants or other materials that have been used as medicines for centuries (Fig. F.1). Once chemists have extracted a biologically active compound from a natural product, they try to identify its molecular structure so that it can be improved or manufactured in greater quantities. This section focuses on the first step in identifying the molecular structure, the determination of the “empirical formula” and the “molecular formula” of the compound. First, consider the empirical formula: The empirical formula shows the relative numbers of atoms of each element present in the compound. For example, the empirical formula of glucose, which is CH2O, tells us that carbon, hydrogen, and oxygen atoms are present in the ratio 1:2:1. The elements are present in these proportions regardless of the size of the sample. After the empirical formula has been determined, the next step is to determine the molecular formula (Section C): The molecular formula shows the actual numbers of atoms of each element in a molecule. F.1 Mass Percentage Composition F.2 Determining Empirical Formulas F.3 Determining Molecular Formulas 1 ␣-D-Glucose, C6H12O6 FIGURE F.1 The research vessel Alpha Helix is used by chemists at the University of Illinois at UrbanaChampaign to search for marine organisms that contain compounds of medicinal value. Compounds found to have antifungal or antiviral properties are then subjected to the kinds of analyses described in this section. 2 Formaldehyde, CH2O EXAMPLE F.1 Calculating the mass percentage of an element in a compound Suppose we are generating hydrogen from water to use as a fuel and need to know the mass of hydrogen that a given mass of water can provide. What is the mass percentage of hydrogen in water? Anticipate Even though there are two hydrogen atoms in each H2O molecule, because hydrogen atoms are much lighter than oxygen atoms, they contribute only a small mass to each molecule and we should therefore expect only a small mass percentage contribution. PLAN To calculate the mass percentage of hydrogen in water, find the mass of H atoms in 1 mol H2O molecules by noting that there are 2 mol H in 1 mol H2O, dividing that mass by the mass of 1 mol H2O, and multiplying by 100%. The molecular formula for glucose, which is C6H12O6, tells us that each glucose molecule consists of 6 carbon atoms, 12 hydrogen atoms, and 6 oxygen atoms (1, which shows one common configuration of the glucose molecule). In contrast, the empirical formula gives only the ratios of the numbers of atoms of each element. Therefore, different compounds with different molecular formulas can have the same empirical formula. For example, formaldehyde, CH2O (2, the preservative in formalin solution), acetic acid, C2H4O2 (the acid in vinegar), and lactic acid, C3H6O3 (the acid in sour milk), all have the same empirical formula (CH2O) as that of glucose, but are different compounds with different properties. F.1 Mass Percentage Composition To determine the empirical formula of a compound, we begin by measuring the mass of each element present in a sample. The result is usually reported as the mass percentage composition—that is, the mass of each element expressed as a percentage of the total mass: (1)* Because the mass percentage composition is independent of the size of the sample—in the language of Section A, it is an intensive property—every sample of the substance has that same composition. A principal technique for determining the mass percentage composition of an unknown organic compound is “combustion analysis,” which is described in Section M. Self-Test F.1A For centuries, the Australian Aborigines have used the leaves of the eucalyptus tree to alleviate sore throats and other pains. The primary active ingredient has been identified and named eucalyptol. An analysis of a sample of eucalyptol of total mass 3.16 g gave its composition as 2.46 g of carbon, 0.373 g of hydrogen, and 0.329 g of oxygen. Determine the mass percentages of carbon, hydrogen, and oxygen in eucalyptol. [Answer: 77.8% C, 11.8% H, 10.4% O] Self-Test F.1B The compound ␣-pinene, a natural antiseptic found in the resin of the piñon tree, has been used since ancient times by Zuni healers. A 7.50-g sample of ␣-pinene contains 6.61 g of carbon and 0.89 g of hydrogen. What are the mass percentages of carbon and hydrogen in ␣-pinene? If the chemical formula of a compound is already known, its mass percentage composition can be obtained from the formula. Mass percentage of element = mass of element in the sample total mass of sample * 100% F46 FUNDAMENTALS F.2 DETERMINING EMPIRICAL FORMULAS F47 FUNDAMENTALS SOLVE From mass percentage of = 11.19% Mass percentage of H = (2 mol) * (1.0079 gиmol-1 ) (1 mol) * (18.02 gиmol-1 ) * 100% H = mass of H atoms mass of H2O molecules * 100%, ϩ 1.0079 g 1.0079 g 18.02 g H H H2O Evaluate As expected, the mass percentage of hydrogen in water, 11.19%, is quite small. Self-Test F.2A Calculate the mass percentage of Cl in NaCl. [Answer: 60.66%] Self-Test F.2B Calculate the mass percentage of Ag in AgNO3. Mass percentage composition is found by calculating the fraction of the total mass contributed by each element present in a compound and expressing the fraction as a percentage. F.2 Determining Empirical Formulas Recall that an empirical formula gives the relative numbers of atoms of each element in the compound. To convert the mass percentages into an empirical formula, we must convert the mass percentage of each type of atom into the relative number of atoms of that element. The simplest procedure is to imagine that we have a sample with a mass of exactly 100 g. In this case the mass percentage composition gives the mass in grams of each element. Then we use the molar mass of each element to convert these masses into amounts in moles and go on to find the relative numbers of moles of each type of atom. EXAMPLE F.2 Determining the elemental composition from mass percentage composition Suppose that an analytical laboratory reported a composition of 40.9% carbon, 4.58% hydrogen, and 54.5% oxygen for a sample of vitamin C. In what atom ratios are the elements present in vitamin C? PLAN We consider a sample of exactly 100 g, then convert the masses into amounts in moles by dividing the mass percentage for each element by the element’s molar mass. We denote the amount of a substance J by n(J). SOLVE The mass of carbon in a sample of vitamin C of mass 100 g is 40.9 g. Because the molar mass of carbon is 12.01 gиmol–1 , From n ϭ m/M, n(C) = 40.9 g 12.01 gи(mol C)-1 = 3.41 mol C ϫ ϭ 12.01 g 40.9 g 1 mol C C 3.41 mol Likewise, from the mass percentages of hydrogen and oxygen, we find n(H) ϭ 4.54 mol H and n(O) ϭ 3.41 mol O It follows that, in any sample of vitamin C, the atoms are present in the ratio 3.41 C : 4.54 H : 3.41 O Self-Test F.3A Pyrophosphoric acid has the composition 2.27% H, 34.81% P, and 62.93% O. Find the relative amounts of H, P, and O atoms present in pyrophosphoric acid. [Answer: 100 g contains 2.25 mol H, 1.12 mol P, and 3.93 mol O; 2.25 H : 1.12 P : 3.93 O] Self-Test F.3B Use the information in Self-Test F.1A to find the relative amounts of C, H, and O atoms present in eucalyptol. To find the empirical formula of vitamin C from the data in Example F.1 we must express the ratios of numbers of atoms as the simplest whole numbers. First, we divide each number by the smallest value (3.41), which gives a ratio of 1.00:1.33:1.00. Molecules contain only whole numbers of atoms, and one of these numbers is still not a whole number. Hence, we must multiply each number by the correct factor so that all numbers can be rounded off to whole numbers. Because 1.33 is 4 ⁄3 (within experimental error), we multiply all three numbers by 3 to obtain 3.00:3.99:3.00, or approximately 3:4:3. Now we know that the empirical formula of vitamin C is C3H4O3. The calculated values are not exact, because they are derived from experimental data, which are subject to experimental error. EXAMPLE F.3 Determining the empirical formula from mass percentage composition The mass percentage composition of a compound that assists in the coagulation of blood is 76.71% C, 7.02% H, and 16.27% N. Determine the empirical formula of the compound. PLAN Divide each mass percentage by the molar mass of the corresponding element to obtain the number of moles of that element found in exactly 100 g of the compound. Divide the number of moles of each element by the smallest number of moles. If fractional numbers result, then multiply by the factor that gives the smallest whole numbers of moles. SOLVE The mass of each element X, m(X), in exactly 100 g of the compound is equal to its mass percentage in grams. m(C) ϭ 76.71 g m(H) ϭ 7.02 g m(N) ϭ 16.27 g 76.71 g 16.27 g 7.02 g H C N 6.387 mol 6.96 mol 1.161 mol C N H Convert each mass to an amount, n(J), in moles by using the molar mass, M(J), of the element, n(J) ϭ m(J)/M(J). n(N) = 16.27 g 14.01 gи(mol N)-1 = 1.161 mol N n(H) = 7.02 g 1.0079 gи(mol H)-1 = 6.96 mol H n(C) = 76.71 g 12.01 gи(mol C)-1 = 6.387 mol C F48 FUNDAMENTALS 5.501 5.99 1 C N H Divide each amount by the smallest amount (1.161 mol). Carbon: Hydrogen: Nitrogen: 1.161 mol 1.161 mol = 1.000 6.96 mol 1.161 mol = 5.99 6.387 mol 1.161 mol = 5.501 F.3 DETERMINING MOLECULAR FORMULAS F49 FUNDAMENTALS A note on good practice: Note that the number of significant figures in the data controls the number of significant figures in the calculated amounts. Because 5.501 is approximately 11 ⁄2, we multiply all the numbers by 2 to get the ratios 11.00:12.0:2.000. The empirical formula is therefore C11H12N2. Self-Test F4.A Use the molar composition of eucalyptol calculated in Self-Test F.3B to determine its empirical formula. [Answer: C10H18O] Self-Test F.4B The mass percentage composition of the compound thionyl difluoride is 18.59% O, 37.25% S, and 44.16% F. Calculate its empirical formula. The empirical formula of a compound is determined from the mass percentage composition and the molar masses of the elements present. F.3 Determining Molecular Formulas We have determined that the empirical formula of vitamin C is C3H4O3. However, the empirical formula tells us only that the C, H, and O atoms are present in the sample in the ratio 3:4:3, not the number of each type of atom in a molecule. The molecular formula could be C3H4O3, C6H8O6, C9H12O9, or any other whole-number multiple of the empirical formula. To find the molecular formula of a compound, we need one more piece of information—its molar mass. Then all we have to do is to calculate how many empirical formula units are needed to account for the molar mass. One of the best ways of determining the molar mass of an organic compound is by mass spectrometry. We saw this technique applied to atoms in Section B. It can be applied to molecules, too; and, although there are important changes of detail (see Major Technique 6, following Chapter 18), the technique is essentially the same. EXAMPLE F.4 Determining the molecular formula from the empirical formula Mass spectrometry has been used to show that the molar mass of vitamin C is 176.12 gиmolϪ1 . Given its empirical formula of C3H4O3, what is the molecular formula of vitamin C? PLAN To find the number of formula units needed to account for the observed molar mass of a compound, divide the molar mass of the compound by the molar mass of the empirical formula unit. SOLVE The molar mass of a C3H4O3 formula unit is = 88.06 gиmol-1 + 3 * (16.00 gиmol-1 ) Molar mass of C3H4O3 = 3 * (12.01 gиmol-1 ) + 4 * (1.008 gиmol-1 ) Dividing the molar mass of the compound by the molar mass of the empirical formula unit yields the factor by which we must multiply the coefficients in the empirical formula to obtain the molecular formula: We conclude that the molecular formula of vitamin C is 2 ϫ (C3H4O3), or C6H8O6. Molar mass of compound Molar mass of empirical formula unit = 176.14 gиmol-1 88.06 gиmol-1 = 2.000 Self-Test F.5A The molar mass of styrene, which is used in the manufacture of the plastic polystyrene, is 104 gиmolϪ1 , and its empirical formula is CH. Deduce its molecular formula. [Answer: C8H8] Self-Test F.5B The molar mass of oxalic acid, an acid present in rhubarb, is 90.0 gиmolϪ1 , and its empirical formula is CHO2. What is its molecular formula? The molecular formula of a compound is found by determining how many empirical formula units are needed to account for the measured molar mass of the compound. ❑ 1 Calculate the mass percentage of an element in a compound from a formula (Example F.1). ❑ 2 Calculate the empirical formula of a compound from its mass percentage composition (Example F.3). ❑ 3 Determine the molecular formula of a compound from its empirical formula and its molar mass (Example F.4). SKILLS YOU SHOULD HAVE MASTERED F.1 Citral is a fragrant component of lemon oil that is used in colognes. It has the molecular structure shown. Calculate the mass percentage composition of citral (gray ϭ C, white ϭ H, red ϭ O). F.2 The compound mainly responsible for the odor of musk produced by musk deer is muscone, which has the molecular structure shown. Calculate the mass percentage composition of muscone (gray ϭ C, white ϭ H, red ϭ O). F.3 What is the mass percentage composition of L-carnitine, C7H15NO3, a compound that is taken as a dietary supplement to reduce muscle fatigue? F.4 What is the mass percentage composition of sucralose, C12H19Cl3O8, a chlorinated derivative of sucrose (table sugar) that has an enhanced sweetness and is used as an artificial sweetener? F.5 A metal M forms an oxide with the formula M2O, for which the mass percentage of the metal is 88.8%. (a) What is the molar mass of the metal? (b) Write the name of the compound. F.6 A metal M forms an oxide with the formula M2O3, for which the mass percentage of the metal is 69.9%. (a) What is the identity of the metal? (b) Write the name of the compound. F.7 Determine the empirical formulas from the following analyses. (a) The mass percentage composition of cryolite, a compound used in the production of aluminum, is 32.79% Na, 13.02% Al, and 54.19% F. (b) A compound used to generate O2 gas in the laboratory has mass percentage composition 31.91% K and 28.93% Cl, the remainder being oxygen. (c) A fertilizer is found to have the following mass percentage composition: 12.2% N, 5.26% H, 26.9% P, and 55.6% O. F.8 Determine the empirical formula of each of the following compounds from the data given. (a) Talc (used in talcum powder) has mass composition 19.2% Mg, 29.6% Si, 42.2% O, and 9.0% H. (b) Saccharin, a sweetening agent, has mass composition 45.89% C, 2.75% H, 7.65% N, 26.20% O, and 17.50% S. (c) Salicylic acid, used in the synthesis of aspirin, has mass composition 60.87% C, 4.38% H, and 34.75% O. F.9 In an experiment, 4.14 g of phosphorus combined with chlorine to produce 27.8 g of a white solid compound. (a) What is the empirical formula of the compound? (b) Assuming that the empirical and molecular formulas of the compound are the same, what is its name? F.10 A chemist found that 4.69 g of sulfur combined with fluorine to produce 15.81 g of a gas. (a) What is the empirical formula of the gas? (b) Assuming that the empirical and molecular formulas of the compound are the same, what is its name? F.11 Diazepam, a drug used to treat anxiety, is 67.49% C, 4.60% H, 12.45% Cl, 9.84% N, and 5.62% O. What is the empirical formula of the compound? F.12 The compound fluoxetine is sold as Prozac when combined with HCl. Fluoxetine has the composition 66.01% C, 5.87% H, 18.43% F, 4.53% N, and 5.17% O. What is the empirical formula of fluoxetine? EXERCISES F50 FUNDAMENTALS G.1 CLASSIFYING MIXTURES F51 FUNDAMENTALS F.13 Osmium forms a molecular compound with mass percentage composition 15.89% C, 21.18% O, and 62.93% Os. (a) What is the empirical formula of this compound? (b) From the mass spectrum of the compound, the molecule was determined to have a molar mass of 907 gиmolϪ1 . What is its molecular formula? F.14 Paclitaxel, which is extracted from the Pacific yew tree Taxus brevifolia, has antitumor activity for ovarian and breast cancer. It is sold under the trade name Taxol. On analysis, its mass percentage composition is 66.11% C, 6.02% H, and 1.64% N, with the balance being oxygen. What is the empirical formula of paclitaxel? F.15 Caffeine, a stimulant in coffee and tea, has a molar mass of 194.19 gиmolϪ1 and a mass percentage composition of 49.48% C, 5.19% H, 28.85% N, and 16.48% O. What is the molecular formula of caffeine? F.16 A sample of a pungent compound was extracted from skunk spray. Upon analysis the 2.00-mg sample was found to have the following composition: 1.09 mg C, 0.183 mg H, and 0.727 mg S. The molar mass of the compound was found to be 88.17 gиmolϪ1 . What is the molecular formula of this compound? F.17 In 1978, scientists extracted a compound with antitumor and antiviral properties from marine animals in the Caribbean Sea. A sample of the compound didemnin-A of mass 1.78 mg was analyzed and found to have the following composition: 1.11 mg C, 0.148 mg H, 0.159 mg N, and 0.363 mg O. The molar mass of didemnin-A was found to be 942 gиmolϪ1 . What is the molecular formula of didemnin-A? F.18 A sample of the fungicide chloranil of mass 1.50 mg was found to have the following composition: 0.440 mg C, 0.865 mg Cl, and 0.195 mg O. The molar mass of chloranil is 245.88 gиmolϪ1 . What is the molecular formula of chloranil? F.19 The CO2 produced by the combustion of hydrocarbons contributes to global warming. Rank the following fuels according to increasing mass percentage of carbon: (a) ethene, C2H4; (b) propanol, C3H7OH; (c) heptane, C7H16. F.20 Dolomite is a mixed carbonate of calcium and magnesium. Calcium and magnesium carbonates both decompose on heating to produce the metal oxides (MgO and CaO) and carbon dioxide (CO2). If 4.84 g of residue consisting of MgO and CaO remains when 9.66 g of dolomite is heated until decomposition is complete, what percentage by mass of the original sample was MgCO3? F.21 In the following ball-and-stick molecular structures, gray indicates carbon, white hydrogen, blue nitrogen, and green chlorine. Write the empirical and molecular formulas of each structure. Hint: It may be easier to write the molecular formula first. (a) (b) F.22 Write the empirical and molecular formulas of each balland-stick structure. Gray indicates carbon, white hydrogen, red oxygen, and green chlorine. Hint: It may be easier to write the molecular formula first. (a) (b) F.23 A mixture of NaNO3 and Na2SO4 of mass 5.37 g contains 1.61 g of sodium. What is the percentage by mass of NaNO3 in the mixture? F.24 A mixture of KBr and K2S of mass 8.02 g contains 4.50 g of potassium. What is the percentage by mass of KBr in the mixture? G MIXTURES AND SOLUTIONS So far, we have discussed only pure substances. However, most materials are neither pure elements nor pure compounds, and so they are not “substances” in the technical sense of the term (Section A); they are mixtures of these simpler substances, with one substance mingled with another. For example, air, blood, and seawater are mixtures. A medicine, such as a cough syrup, is often a mixture of various ingredients that has been formulated to achieve an overall biological effect. Much the same can be said of a perfume. Chemists need to be able to specify the composition of mixtures quantitatively. For example, a chemist may need to monitor a pollutant, administer a dosage, or transfer a known amount of a solute. In this section we examine the properties and types of mixtures as well as how to use the “molar concentration” of a dissolved substance to analyze solutions quantitatively. G.1 Classifying Mixtures A compound has a fixed composition, whereas the composition of a mixture may be varied. There are always two H atoms for each O atom in a sample of the compound water, but sugar and sand, for instance, can be mixed in any proportions. Because the G.1 Classifying Mixtures G.2 Separation Techniques G.3 Concentration G.4 Dilution components of a mixture are merely mingled with one another, they retain their own chemical properties in the mixture. In contrast, a compound has chemical properties that differ from those of its component elements. The formation of a mixture is a physical change, whereas the formation of a compound requires a chemical change. The differences between mixtures and compounds are summarized in Table G.1. Some mixtures have component particles that are so large we can see them with an optical microscope or even the unaided eye (Fig. G.1). Such a patchwork of different substances is called a heterogeneous mixture. Many of the rocks that form the landscape are heterogeneous mixtures of crystals of different minerals. Milk, which looks like a pure substance, is in fact a heterogeneous mixture: through a microscope, we can see the individual globules of butterfat floating in a liquid that is largely water. Human bodies are heterogeneous mixtures of thousands of compounds. In some mixtures, the molecules or ions of the components are so well mixed that the composition is the same throughout, no matter how small the sample. Such a mixture is called a homogeneous mixture (Fig. G.2). For example, syrup is a homogeneous mixture of sugar and water. The molecules of sugar are dispersed and mixed so thoroughly with the water that we cannot see separate regions or particles. Even when using a microscope, we cannot distinguish between a pure substance and a homogeneous mixture. TABLE G.1 Differences Between Mixtures and Compounds Mixture Compound components can be separated by using components cannot be separated by using physical techniques physical techniques composition is variable composition is fixed properties are related to those of its properties are unlike those of its components components (a) (b) (c) FIGURE G.1 This piece of granite is a heterogeneous mixture of several substances. FIGURE G.2 Three examples of homogeneous mixtures. (a) Air is a homogeneous mixture of many gases, including the nitrogen, oxygen, and argon depicted here. (b) Table salt dissolved in water consists of sodium ions and chloride ions among water molecules. (c) Many alloys are solid homogeneous mixtures of two or more metals. The insets show that the mixing is uniform at the molecular level. Solvent Solute Solution Solute FIGURE G.3 Solutions are homogeneous mixtures in which one substance, the solvent (here water), is usually in large excess. A dissolved substance is called a solute. The inset shows only the solute particles. F52 FUNDAMENTALS A homogeneous mixture is also called a solution. Many of the materials around us are solutions. Root beer is a solution consisting mostly of water, along with sugar, plant extracts, and various additives. Filtered seawater is a solution of common table salt (sodium chloride) and many other substances in water. Although a solution looks uniform in composition, the components that form it retain their identities. Forming a solution is a physical change, not a chemical change. When we use the everyday term dissolving, we mean the process of producing a solution. Usually the component of the solution present in the larger amount (water in these examples) is called the solvent, and any dissolved substance is a solute (Fig. G.3). However, if we want to emphasize the role of one of the substances as the one that the others are “dissolved in,” we may identify that substance as the solvent. For example, in a thick syrup, the sugar may be present in a much greater amount than the water, but water is considered the solvent. Normally, the solvent determines the physical state of the solution (whether it is a solid, a liquid, or a gas). Crystallization takes place when the solute slowly comes out of solution as crystals, perhaps as the solvent evaporates. For example, salt crystals that form when water evaporates line the shores of the Great Salt Lake in Utah. In precipitation, a solute G.2 SEPARATION TECHNIQUES F53 comes out of solution so rapidly that a single crystal does not have time to form. Instead, the solute forms a finely divided powder called a precipitate. Precipitation is often almost instantaneous (Fig. G.4). Beverages and seawater are examples of aqueous solutions, solutions in which the solvent is water. Aqueous solutions are very common in everyday life and in chemical laboratories; for that reason, most of the solutions mentioned in this text are aqueous. Nonaqueous solutions are solutions in which the solvent is not water. Although they are less common than aqueous solutions, nonaqueous solutions have important uses. In “dry cleaning,” the grease and dirt on fabrics are dissolved in a nonaqueous liquid solvent such as tetrachloroethene, C2Cl4. There are also solid solutions, in which the solvent is a solid. An example is a common form of brass that can be regarded as a solution of zinc in copper. Although gaseous solutions exist, they are normally referred to as gaseous mixtures. The atmosphere could be regarded as a vast gaseous solution of various substances in nitrogen, its major component, but it is normally termed a gaseous mixture. In mixtures, the properties of the constituents are retained; they differ from compounds, as summarized in Table G.1. Mixtures are classified as homogeneous or heterogeneous; solutions are homogeneous mixtures of two or more substances and can be solid, liquid, or gaseous. G.2 Separation Techniques Natural products, such as enzymes and vitamins, are almost invariably extracted from mixtures. To analyze the composition of any sample that we suspect is a mixture, we first separate its components by physical means and then identify each individual substance present (Fig. G.5). Common physical separation techniques include decanting, filtration, chromatography, and distillation. Decanting makes use of differences in density. One liquid floats on another liquid or lies above a solid and is poured off. Filtration is used to separate substances when there is a difference in solubility (the ability to dissolve in a particular solvent). The sample is stirred with a liquid and then poured through a fine mesh, the filter. Components of the mixture that have dissolved in the liquid pass through the filter, whereas solid components that do not dissolve are captured by the filter. The technique can be used to separate sugar from sand because sugar is soluble in water but sand is not. Filtration is a common first stage in the treatment of domestic water supplies. A related technique, one of the most sensitive techniques available for separating a mixture, is chromatography, which relies on the different abilities of substances to adsorb, or stick, to surfaces (Fig. G.6). Chromatography is discussed in detail in Major Technique 5, following Chapter 8. Compounds Elements Physical techniques Chemical techniques Substances Changes of state Mixtures Matter Gas Liquid Solid Heterogeneous Homogeneous (solutions) FIGURE G.5 The hierarchy of materials: matter, whether solid, liquid, or gas, consists of either mixtures or substances; substances consist of either compounds or elements. Physical techniques are used to separate mixtures into pure substances. Chemical techniques are used to separate compounds into elements. FIGURE G.4 Precipitation occurs when an insoluble substance is formed. Here lead(II) iodide, PbI2, which is an insoluble yellow solid, precipitates when we mix solutions of lead(II) nitrate, Pb(NO3)2, and potassium iodide, KI. Lab Video G.4 Distillation makes use of differences in boiling points to separate mixtures. When a solution is distilled, the components of the mixture boil away at different temperatures and condense in a cooled tube called a condenser (Fig. G.7). Distillation can be used to remove water (which boils at 100°C) from table salt (sodium chloride), which does not even melt until 801°C; the solid salt is left behind when the water evaporates. Mixtures are separated by making use of the differences in physical properties of the components; common techniques based on physical differences include decanting, filtration, chromatography, and distillation. G.3 Concentration In Section F we saw that the composition of a compound could be expressed in terms of the mass percentage of each element. Similarly, we can express the composition of a mixture as the mass percentage of each component, the mass of each component in a total of 100 grams of the mixture. For example, if we were to dissolve 15 g NaCl in 60. g water, the total mass of the mixture is 75 g and the percentage of NaCl in the solution is (15 g/75 g) ϫ 100% ϭ 20.% NaCl. If we made up a sample containing 30. g of that solution, that sample would have the same composition, 20.% NaCl by mass, and would therefore contain 6.0 g NaCl. In chemistry it is often important to know the amount of solute in a given volume of solution. The molar concentration, c, of a solute in a solution, which is widely but unofficially called the “molarity” of the solute, is the amount of solute molecules or formula units (in moles) present in a given volume of the solution (in liters): (1) The units of molarity are moles per liter (molиLϪ1 ), often denoted M: 1 M ϭ 1 molиLϪ1 The symbol M is often read “molar”; it is not an SI unit. Note that 1 molиL–1 is the same as 1 mmolиmL–1 . Chemists working with very low concentrations of solutes also report molar concentrations as millimoles per liter (mmolиL–1 ) and micromoles per liter (␮molиLϪ1 ). Molarity = amount of solute (in moles) volume of solution (in liters) or c = n V FIGURE G.6 In paper chromatography, the components of a mixture are separated by washing them along a paper—the support—with a solvent. A primitive form of the technique is shown here. On the left is a dry filter paper to which a drop of green food coloring was applied. Solvent was then poured on to the center of the filter paper. The blue and yellow dyes that were combined to make the green color begin to separate. The filter paper on the right was allowed to dry after the solvent had spread out to the edges of the paper, carrying the two dyes to different distances as it spread. The dried support showing the separated components of a mixture is called a chromatogram. FIGURE G.7 The technique of distillation, which is used to separate a low-boiling liquid from a dissolved solid or a liquid with a much higher boiling point. When the solution is heated, the low-boiling liquid boils off, condenses in the water-jacketed tube (the condenser), and is collected as the distillate. Water out Water in Condenser Thermometer Distillate Solution Heat Volatile solvent Nonvolatile solute The first known distillation apparatus, assembled in the first century CE, is attributed to Mary the Jewess, an alchemist who lived in the Middle East. The formal name for molarity is the “amount of substance concentration.” EXAMPLE G.1 Calculating the molarity of a solute Suppose we dissolved 10.0 g of cane sugar in enough water to make 200. mL of solution, which we might do (with less precision) if we were making a glass of lemonade. Cane sugar is sucrose (C12H22O11, molar mass ϭ 342 gиmolϪ1 ). What is the molarity of sucrose in the solution? Anticipate The mass of sugar is only about 3% of the mass of 1 mole of sugar; therefore, although only 0.200 L is being prepared, we should expect a small concentration. PLAN The definition of molar concentration (molarity) is c ϭ n/V; we first need to convert the mass of solute to an amount in moles (by using n ϭ m/M) and then substitute that amount into this expression for c. #mol L F54 FUNDAMENTALS " G.3 CONCENTRATION F55 FUNDAMENTALS SOLVE Evaluate The molar concentration, which we report as 0.146 M C12H22O11(aq), is small, as expected. A note on good practice: Note that we refer to the molarity of the solute, not the molarity of the solution. Self-Test G.1A If instead of 10.0 g, we were to dissolve 20.0 g of cane sugar in the same volume of solution, what would be the molarity of the sugar? [Answer: 0.292 M C12H22O11(aq)] Self-Test G.1B What is the molarity of sodium sulfate in a solution prepared by dissolving 15.5 g of sodium sulfate in enough water to make 350. mL of solution? Because molarity is defined in terms of the volume of the solution, not the volume of solvent used to prepare the solution, the volume must be measured after the solutes have been added. The usual way to prepare an aqueous solution of a solid substance of given molarity is to transfer a known mass of the solid into a volumetric flask, a flask calibrated to contain a specified volume, dissolve it in a little water, fill the flask up to the mark with water, and then mix the solution thoroughly by tipping the flask end over end (Fig. G.8). To use the molarity of a solution to calculate the amount of solute in a given volume of solution, we use Eq. 1 rearranged into (2) where c is the molarity, V is the volume, and n is the amount. Because we can convert moles into mass by using the molar mass of the solute, we can also use this formula to estimate the mass of solute needed to make up a given volume of solution of known concentration. n = c * V 29.2 mmol 200 mL 10.0 g 1 mol 342 g ϫ 0.0380 mmol ϫ ϭ 9.50 mmol 1 L250 mL EXAMPLE G.2 Determining the mass of solute required for a given concentration Suppose we were asked to prepare 250. mL of a solution that was approximately 0.0380 M CuSO4(aq) from solid copper(II) sulfate pentahydrate, CuSO4и5H2O. What mass of the solid do we need? PLAN Find the amount of solute from the relation n ϭ cV, then convert moles of solute to grams by using m ϭ nM. SOLVE First we need to know the amount of CuSO4 in 250. mL (0.250 L) of solution: FIGURE G.8 The steps in making up a solution of known molarity. A known mass of the solute is dispensed into a volumetric flask (top). Some water is added to dissolve it (center). Finally, water is added up to the mark on the stem of the flask (bottom). The bottom of the solution’s meniscus (the curved top surface of the liquid) should be level with the mark. nϭm/M V ()* mol molиLϪ1 L # # # (++)++* From c ϭ n/V and n ϭ m/m, = 10.0 g (342 gиmol-1 ) * (0.200 L) = 0.146 molиL-1 c = (10.0 g)/(342 gиmol-1 ) 0.200 L From n ϭ cV, n(CuSO4) ϭ (0.0380 molиL–1 ) ϫ (0.250 L) ϭ 0.0380 ϫ 0.250 mol ϭ 0.009 50 mol EXAMPLE G.3 Calculating the volume of solution that contains a given amount of solute Suppose we want to measure out 0.760 mmol CH3COOH, acetic acid, an acid found in vinegar and often used in the laboratory, and we have available 0.0380 M CH3COOH(aq). What volume of solution should we use? PLAN Noting that c ϭ n/V can be rearranged into V ϭ n/c, to find the volume we divide the amount of solute by its molarity, as in Eq. 3. It is best first to convert the units of amount from millimole (mmol) to mole (mol). SOLVE Because 1 mol CuSO4и5H2O contains 1 mol CuSO4, the amount of CuSO4и5H2O we need to supply is the same as the amount of CuSO4 needed to prepare the solution. That is, n(CuSO4и5H2O) ϭ n(CuSO4) ϭ 0.009 50 mol Then, because the molar mass of copper(II) sulfate pentahydrate is 249.6 gиmol–1 , we calculate the mass of the pentahydrate that we need to supply as follows. ϫ ϭ 9.50 mmol 2.37 g 249.6 g 1 mol We conclude that we need about 2.37 g of copper(II) sulfate pentahydrate. In practice, we might find that we had measured out 2.403 g, in which case the molarity would be 0.0385 M CuSO4(aq). Self-Test G.2A Calculate the mass of glucose needed to prepare 150. mL of 0.442 M C6H12O6(aq). [Answer: 11.9 g] Self-Test G.2B Calculate the mass of oxalic acid needed to prepare 50.00 mL of 0.125 M C2H2O4(aq). The molarity is also used to calculate the volume of solution, V, that contains a given amount of solute. For this type of calculation, we rearrange Eq. 1 into (3) and then substitute the data. V L = n mol c molиL- 1 380 mmol ϫ ϭ 1 L 0.760 mmol 20.0 mL We should therefore transfer 20.0 mL of the acetic acid solution into a flask by using a buret or a pipet (Fig. G.9). The flask will then contain 0.760 mmol CH3COOH. Self-Test G.3A What volume of 1.25 ϫ 10–3 M C6H12O6(aq) contains 1.44 ␮mol of glucose molecules? [Answer: 1.15 mL] # # # F56 FUNDAMENTALS From m ϭ nM, m(CuSO4и5H2O) ϭ (0.009 50 mol) ϫ (249.6 gиmol–1 ) ϭ 2.37 g From V ϭ n/c, V = 0.760 * 10-3 mol 0.0380 molиL-1 = 0.0200 L FIGURE G.9 A buret is calibrated so that the volume of liquid delivered can be measured. G.4 DILUTION F57 FUNDAMENTALS Self-Test G.3B What volume of 0.358 M HCl(aq) contains 2.55 mmol HCl? The molarity (molar concentration) of a solute in a solution is the amount of solute in moles divided by the volume of the solution in liters. G.4 Dilution A common space-saving practice in chemistry is to store a solution in a concentrated form called a stock solution and then to dilute it, or reduce its concentration, to whatever concentration is needed. Chemists use solutions and techniques such as dilution when they need very precise control over the amounts of the substances that they are handling, especially very small quantities of substances. For example, pipetting 25.0 mL of 1.50 ϫ 10Ϫ3 M NaOH(aq) corresponds to transferring only 37.5 ␮mol NaOH or 1.50 mg of the compound. A mass this small would be difficult to weigh out accurately. To dilute a stock solution to a desired concentration, we use a pipet to transfer the appropriate volume of stock solution to a volumetric flask. Then we add enough solvent to increase the volume of the solution to its final value. Toolbox G.1 shows how to calculate the initial volume of stock solution required for a given volume of diluted solution. TOOLBOX G.1 HOW TO CALCULATE THE VOLUME OF STOCK SOLUTION REQUIRED FOR A GIVEN DILUTION CONCEPTUAL BASIS This procedure is based on a simple idea: although we may add more solvent to a given volume of solution, we change only the concentration, not the amount of solute (Fig. G.10). After dilution, the same amount of solute simply occupies a larger volume of solution. PROCEDURE The procedure has two steps: Step 1 Calculate the amount of solute, n, in the final, dilute solution of volume Vfinal. (This is the amount of solute to be transferred into the volumetric flask.) n ϭ cfinalVfinal Step 2 Calculate the volume, Vinitial, of the initial stock solution of molarity, cinitial, that contains this amount of solute. (This is the volume of stock solution that contains the amount of solute calculated in step 1.) (4a)* This procedure is illustrated in Example G.4. Because the amount of solute, n, is the same in these two expressions, they can be combined into and rearranged into an easily remembered form. cinitialVinitial ϭ cfinalVfinal (4b)* In Eq. 4b, the amount of solute in the final solution (the product on the right) is the same as the amount of solute in the initial volume of solution (the product on the left), nfinal ϭ ninitial. Vinitial = cfinal Vfinal cinitial Vinitial = n cinitial EXAMPLE G.4 Calculating the volume of stock solution to dilute We need to prepare 250. mL of 1.25 ϫ 10Ϫ3 M NaOH(aq) and will use a 0.0380 M NaOH(aq) stock solution. How much stock solution do we need? Anticipate Because the stock solution is about 30 times more concentrated than the diluted solution, we should expect to use about 1/30 of 250. mL, or just over 8 mL. PLAN We proceed as in Toolbox G.1. SOLVE ϫ ϭ 1 L0.250 L 0.312 mmol 1.25 mmol Step 1 From n ϭ cfinalVfinal, n ϭ (1.25 ϫ 10–3 molиL–1 ) ϫ (0.250 L) ϭ (1.25 ϫ 10Ϫ3 ϫ 0.250) mol Before dilution After dilution FIGURE G.10 When a solution is diluted, the same number of solute molecules occupy a larger volume. Therefore, the same volume (as depicted by the cube) will contain fewer molecules than in the concentrated solution. 38.0 mmol ϫ ϭ 0.312 mmol 8.22 mL 1000 mL Evaluate The volume of stock solution required is 8.22 mL, close to the expected value. This volume should be measured into a 250.-mL volumetric flask (by using a buret) and water should then be added up to the mark (Fig. G.11). A note on good practice: Note how, to minimize rounding errors, we carry out the calculation in a single step. However, to help guide you through the calculation, we shall often give intermediate numerical results in the examples. Self-Test G.4A Calculate the volume of 0.0155 M HCl(aq) that we should use to prepare 100. mL of 5.23 ϫ 10Ϫ4 M HCl(aq). [Answer: 3.37 mL] Self-Test G.4B Calculate the volume of 0.152 M C6H12O6(aq) that should be used to prepare 25.00 mL of 1.59 ϫ 10Ϫ5 M C6H12O6(aq). When a solution is diluted to a larger volume, the total amount of solute in the solution does not change, but the concentration of solute is reduced. Transfer Add solvent FIGURE G.11 The steps in dilution. A small sample of the original solution is transferred to a volumetric flask, and then solvent is added up to the mark. ❑ 1 Distinguish between heterogeneous and homogeneous mixtures and describe methods of separation (Sections G.1 and G.2). ❑ 2 Calculate the molarity of a solute in a solution, volume of solution, and mass of solute, given the other two quantities (Examples G.1–G.3). ❑ 3 Determine the volume of stock solution needed to prepare a dilute solution of a given molarity (Toolbox G.1 and Example G.4). SKILLS YOU SHOULD HAVE MASTERED G.1 Indicate whether each statement is true or false. If false, explain what is wrong with the statement: (a) The components of a compound can be separated from each other by physical means. (b) The composition of a solution can be varied. (c) The properties of a compound are the same as those of the elements that compose it. G.2 Indicate whether each statement is true or false. If false, explain what is wrong with the statement: (a) A nonaqueous solution is one in which the solvent is water. (b) Decanting makes use of differences in boiling points to separate the components of a mixture. (c) In chromatography the components of a mixture are separated according to their ability to adsorb onto a surface. G.3 Identify the following mixtures as homogeneous or heterogeneous, and suggest a technique for separating their components: (a) oil and vinegar; (b) chalk and table salt; (c) salt water. G.4 Identify the following mixtures as homogeneous or heterogeneous, and suggest a technique for separating their components: (a) lemonade; (b) salad oil and vinegar; (c) salt and ground pepper. EXERCISES F58 FUNDAMENTALS Step 2 From Vinitial ϭ n/cinitial, Vinitial = (1.25 * 10-3 * 0.250) mol 0.0380 molиL-1 = 8.22 * 10-3 L EXERCISES F59 FUNDAMENTALS G.5 You need to prepare 510. g of an aqueous solution containing 5.45% K2NO3 by mass. Describe how you would prepare the solution and what mass of each component you would use. G.6 You need to prepare a sample containing 0.872 g of CuSO4 from a solution that is 6.75% CuSO4 by mass. What mass of solution do you need? G.7 A chemist studying the properties of photographic emulsions needed to prepare 500.0 mL of 0.179 M AgNO3(aq). What mass of silver nitrate must be placed into a 500.0-mL volumetric flask, dissolved, and diluted to the mark with water? G.8 (a) A chemist prepares a solution by dissolving 3.750 g of NaNO3 in enough water to make 500.0 mL of solution. What molar concentration of sodium nitrate should appear on the label? (b) If the chemist mistakenly uses a 250.0-mL volumetric flask instead of the 500.0-mL flask in part (a), what molar concentration of sodium nitrate will the chemist actually prepare? G.9 A student prepared a solution of sodium carbonate by adding 2.111 g of the solid to a 250.0-mL volumetric flask and adding water to the mark. Some of this solution was transferred to a buret. What volume of solution should the student transfer into a flask to obtain (a) 2.15 mmol Naϩ ; (b) 4.98 mmol CO3 2Ϫ ; (c) 50.0 mg Na2CO3? G.10 A student investigating the properties of solutions containing carbonate ions prepared a solution containing 8.124 g of Na2CO3 in a flask of volume 250.0 mL. Some of the solution was transferred to a buret. What volume of solution should be dispensed from the buret to provide (a) 5.124 mmol Na2CO3; (b) 8.726 mmol Naϩ ? G.11 Explain how you would prepare 0.010 M KMnO4(aq) by starting with (a) solid KMnO4; (b) 0.050 M KMnO4(aq). G.12 (a) A sample of 1.345 M K2SO4(aq) of volume 12.56 mL is diluted to 250.0 mL. What is the molar concentration of K2SO4 in the diluted solution? (b) A sample of 0.366 M HCl(aq) of volume 25.00 mL is drawn from a reagent bottle with a pipet. The sample is transferred to a flask of volume 125.00 mL and diluted to the mark with water. What is the molar concentration of the dilute hydrochloric acid solution? G.13 (a) What volume of 0.778 M Na2CO3(aq) should be diluted to 150.0 mL with water to reduce its concentration to 0.0234 M Na2CO3(aq)? (b) An experiment requires the use of 60.0 mL of 0.50 M NaOH(aq). The stockroom assistant can only find a reagent bottle of 2.5 M NaOH(aq). How can the 0.50 M NaOH(aq) be prepared? G.14 A chemist dissolves 0.033 g of CuSO4и5H2O in water and dilutes the solution to the mark in a 250.0-mL volumetric flask. A 2.00-mL sample of this solution is then transferred to a second 250.0-mL volumetric flask and diluted. (a) What is the molarity of CuSO4 in the final solution? (b) To prepare the final 250.0-mL solution directly, what mass of CuSO4и5H2O would need to be weighed out? G.15 (a) Determine the mass of anhydrous copper(II) sulfate that must be used to prepare 250 mL of 0.20 M CuSO4(aq). (b) Determine the mass of CuSO4и5H2O that must be used to prepare 250 mL of 0.20 M CuSO4(aq). G.16 The ammonia solution that is purchased for a stockroom has a molarity of 15.0 molиLϪ1 . (a) Determine the volume of 15.0 M NH3(aq) that must be diluted to 500. mL to prepare 1.25 M NH3(aq). (b) An experiment requires 0.32 M NH3(aq). The stockroom manager estimates that 12.0 L of the base is needed. What volume of 15.0 M NH3(aq) must be used for the preparation? G.17 A solution is prepared by dissolving 0.500 g of KCl, 0.500 g of K2S, and 0.500 g of K3PO4 in 500. mL of water. What is the concentration in the final solution of (a) potassium ions; (b) sulfide ions? G.18 To prepare a very dilute solution, it is advisable to perform successive dilutions of a single prepared reagent solution, rather than to weigh out a very small mass or to measure a very small volume of stock chemical. A solution was prepared by transferring 0.661 g of K2Cr2O7 to a 250.0-mL volumetric flask and adding water to the mark. A sample of this solution of volume 1.000 mL was transferred to a 500.0-mL volumetric flask and diluted to the mark with water. Then 10.0 mL of the diluted solution was transferred to a 250.0-mL flask and diluted to the mark with water. (a) What is the final concentration of K2Cr2O7 in solution? (b) What mass of K2Cr2O7 is in this final solution? (The answer to the last question gives the amount that would have had to have been weighed out if the solution had been prepared directly.) G.19 What mass (in grams) of anhydrous solute is needed to prepare each of the following solutions? (a) 1.00 L of 0.125 M K2SO4(aq); (b) 375 mL of 0.015 M NaF(aq); (c) 500. mL of 0.35 M C12H22O11(aq). G.20 Describe the preparation of each of the following solutions, starting with the anhydrous solute and water and using the indicated size of volumetric flask: (a) 75.0 mL of 5.0 M NaOH(aq); (b) 5.0 L of 0.21 M BaCl2(aq); (c) 300. mL of 0.0340 M AgNO3(aq). G.21 In medicine it is sometimes necessary to prepare solutions with a specific concentration of a given ion. A lab technician has made up a 100.0-mL solution containing 0.50 g of NaCl and 0.30 g of KCl, as well as glucose and other sugars. What is the concentration of chloride ions in the solution? G.22 When a 1.850-g sample of iron ore is treated with 50.0 mL of hydrochloric acid the iron dissolves in the acid to form a solution of FeCl3. The FeCl3 solution is diluted to 100.0 mL and the concentration of Fe3+ ions is determined by spectrometry to be 0.103 molиLϪ1 . What is the mass percentage of iron in the ore? G.23 Practitioners of the branch of alternative medicine known as homeopathy claim that very dilute solutions of substances can have an effect. Is the claim plausible? To explore this question, suppose that you prepare a solution of a supposedly active substance, X, with a molarity of 0.10 molиLϪ1 . Then you dilute 10. mL of that solution by doubling the volume, doubling it again, and so on, for 90 doublings in all. How many molecules of X will be present in 10. mL of the final solution? Comment on the possible health benefits of the solution. G.24 Refer to Exercise G.23. How many successive tenfold dilutions of the original solution will result in one molecule of X being left in 10 mL of solution? G.25 Concentrated hydrochloric acid is 37.50% HCl by mass and has a density of 1.205 gиcmϪ3 . What volume (in milliliters) of concentrated hydrochloric acid must be used to prepare 10.0 L of 0.7436 M HCl(aq)? G.26 You need 500. mL of 0.10 M AgNO3(aq). You have on hand 100. mL of 0.30 M AgNO3(aq), 1.00 L of 0.050 M AgNO3(aq), and lots of distilled water. Describe how you would prepare the desired solution and what volume of each solution you would use. G.27 The concentration of toxic chemicals in the environment is often measured in parts per million (ppm) or even parts per billion (ppb). A solution in which the concentration of the solute is 3 ppb by mass has 3 g of the solute for every billion grams (1000 t) of the solution. The World Health Organization has set the acceptable standard for lead in drinking water at 10 ppb. You need to analyze some tap water for lead concentration, but your equipment is able to detect lead in concentrations only as low as 1 ϫ 10–8 molиLϪ1 . Is your equipment satisfactory? You can assume that in such dilute solutions the density of the solution is 1.00 gиcmϪ3 . Explain your reasoning. G.28 Refer to Exercise G.27. In 1992 the tap water in one-third of the homes in Chicago was found to have a lead concentration of about 10 ppb. If you lived in one of these homes and drank 2 L of tap water at home each day, what is the total mass of lead you would have ingested per year? F60 FUNDAMENTALS H CHEMICAL EQUATIONS The growth of a child, the production of polymers from petroleum, and the digestion of food are all the outcome of chemical reactions, processes by which one or more substances are converted into other substances. This type of process is a chemical change. The starting materials are called the reactants and the substances formed are called the products. The chemicals available in a laboratory are called reagents. Only when a reagent is being used in a particular reaction is it called a reactant. This section reviews a number of very important aspects of chemical reactions. For instance, we see how to express the outcome of a chemical reaction in terms of symbols: this procedure is an absolutely fundamental part of the language of chemistry and you will encounter it at every stage of your studies. Chemists have also identified a number of patterns that can be used to classify chemical reactions into different types. Once patterns have been identified a subject becomes not only more systematic but also much easier to learn. H.1 Symbolizing Chemical Reactions A chemical reaction is symbolized by an arrow: For example, sodium is a soft, shiny metal that reacts vigorously with water. When we drop a small lump of sodium metal into a container of water, hydrogen gas forms rapidly and sodium hydroxide is produced in solution (Fig. H.1). We could describe this reaction in words: We can summarize this statement by using chemical formulas: Na + H2O ¡ NaOH + H2 Sodium + water ¡ sodium hydroxide + hydrogen Reactants ¡ products H.1 Symbolizing Chemical Reactions H.2 Balancing Chemical Equations H2 Naϩ OHϪ Na FIGURE H.1 When a small piece of sodium is dropped into water, a vigorous reaction takes place. Hydrogen gas and sodium hydroxide are formed, and the heat released is enough to melt the sodium into a sphere. The pink color is due to the presence of a dye that changes color in the presence of sodium hydroxide. The (balanced) chemical equation on the next page shows that when two sodium atoms give rise to two sodium ions, two water molecules give rise to one hydrogen molecule (which escapes as a gas) and two hydroxide ions. There is a rearrangement of partners, not a creation or annihilation of atoms. The unreacted water molecules are not shown in the inset on the right. H.1 SYMBOLIZING CHEMICAL REACTIONS F61 FUNDAMENTALS This expression is called a skeletal equation because it shows the bare bones of the reaction (the identities of the reactants and products) in terms of chemical formulas. A skeletal equation is a qualitative summary of a chemical reaction. To summarize reactions quantitatively, we note that atoms are neither created nor destroyed in a chemical reaction: they simply change their partners. The principal evidence for this conclusion is that there is no overall change in mass when a reaction takes place in a sealed container. The observation that the total mass is constant during a chemical reaction is called the law of conservation of mass. Because atoms are neither created nor destroyed, chemists regard each elemental symbol as representing one atom of the element. Subscripts in a formula tell us how many atoms of that element are present in one molecule or formula unit (Section C). The formulas are then multiplied by factors that result in the same numbers of atoms of each element on both sides of the arrow. The resulting expression is said to be balanced and is called a chemical equation. For example, there are two H atoms on the left of the preceding skeletal equation but three H atoms on the right. So, we rewrite the expression as Now there are four H atoms, two Na atoms, and two O atoms on each side, and the equation conforms to the law of conservation of mass. The number multiplying an entire chemical formula in a chemical equation (for example, the 2 multiplying H2O) is called the stoichiometric coefficient of the substance. A coefficient of 1 (as for H2) is not written explicitly. A chemical equation typically also shows the physical state of each reactant and product by using a state symbol: (s): solid (l): liquid (g): gas (aq): aqueous solution For the reaction between solid sodium and liquid water, the complete, balanced chemical equation is therefore When we want to show that a reaction requires a high temperature, we write the Greek letter ⌬ (delta) over the arrow. For example, the conversion of limestone into quicklime takes place at about 800ЊC, and we write Sometimes a catalyst, a substance that increases the rate of a reaction but is not itself consumed in the reaction, is added. For example, vanadium pentoxide, V2O5, is a catalyst in one step of the industrial process for the production of sulfuric acid. The presence of a catalyst is indicated by writing the formula of the catalyst above the reaction arrow: Now we come to an important interpretation of a chemical equation. First, we note that the equation for the reaction of sodium with water tells us that • when any 2 atoms of sodium react with 2 molecules of water, they produce 2 formula units of NaOH and one molecule of hydrogen. We can multiply through by Avogadro’s number (Section E) and conclude that • when 2 moles of Na atoms react with 2 moles of H2O molecules, they produce 2 moles of NaOH formula units and 1 mole of H2 molecules. In other words, the stoichiometric coefficients multiplying the chemical formulas in any balanced chemical equation tell us the relative number of moles of each substance that reacts or is produced in the reaction. A balanced chemical equation symbolizes both the qualitative and the quantitative changes that take place in a chemical reaction. The stoichiometric coefficients tell us the relative numbers of moles of reactants and products taking part in the reaction. 2 SO2(g) + O2(g) V2O5 ¡ 2 SO3(g) CaCO3(s) ¡ CaO(s) + CO2(g) 2 Na(s) + 2 H2O(l) ¡ 2 NaOH(aq) + H2(g) 2 Na + 2 H2O ¡ 2 NaOH + H2 The somewhat awkward word stoichiometric is derived from the Greek words for “element” and “measure.” ⌬ F62 FUNDAMENTALS H.2 Balancing Chemical Equations In some cases, the stoichiometric coefficients needed to balance an equation are easy to determine. For example, let’s consider the reaction in which hydrogen and oxygen gases combine to form water. We start by summarizing the qualitative information as a skeletal equation: ƽ We use the international Hazard! road sign ƽ to warn that a skeletal equation is not balanced. Then we balance hydrogen and oxygen atoms: There are four H atoms and two O atoms on each side of the arrow. At this stage, we insert the state symbols: Figure H.2 is a molecular-level representation of this reaction. An equation must never be balanced by changing the subscripts in the chemical formulas. That change would imply that different substances were taking part in the reaction. For example, changing H2O to H2O2 in the skeletal equation and writing certainly results in a balanced equation. However, it is a summary of a different reaction— the formation of hydrogen peroxide (H2O2) from its elements. Nor should we write Although this equation is balanced, it summarizes the reaction between hydrogen molecules and oxygen atoms, not the oxygen molecules that are the actual starting materials. Although normally the coefficients in a balanced chemical equation are the smallest possible whole numbers, a chemical equation can be multiplied through by a factor and still be a valid equation. At times it is convenient to use fractional coefficients; for example, we could write if we want the equation to correspond to the consumption of 1 mol H2. Sometimes we need to construct a balanced chemical equation from a verbal description of a reaction. For example, methane, CH4, is the principal ingredient of natural gas (Fig. H.3). It burns in oxygen to form carbon dioxide and water, both formed initially as gases. To write the balanced equation for the reaction reported as “methane burns in oxygen to form carbon dioxide and water,” we first write the skeletal equation: ƽ Then we balance the equation. A good strategy is to balance one element at a time, starting with one that appears in the fewest formulas, such as carbon and hydrogen. Then specify the states. If under the conditions of the experiment water is produced as a vapor, we write CH4(g) + 2 O2(g) ¡ CO2(g) + 2 H2O(g) CH4 + O2 ¡ CO2 + H2O H2(g) + 1 2 O2(g) ¡ H2O(l) H2 + O ¡ H2O H2 + O2 ¡ H2O2 2 H2(g) + O2(g) ¡ 2 H2O(l) 2 H2 + O2 ¡ 2 H2O H2 + O2 ¡ H2O FIGURE H.2 A representation of the reaction between hydrogen and oxygen, with the production of water. No atoms are created or destroyed; they simply change partners. For every two hydrogen molecules that react (background, shown in white), one oxygen molecule (shown in red) is consumed and two water molecules are formed (foreground). Reactants Products FIGURE H.3 When methane burns, it forms carbon dioxide and water. The blue color is due to the presence of C2 molecules in the flame. If the oxygen supply is inadequate, these carbon molecules can stick together and form soot, thereby producing a smoky flame. Note that one carbon dioxide molecule and two water molecules are produced for each methane molecule that is consumed. The two hydrogen atoms in each water molecule do not necessarily come from the same methane molecule: the illustration depicts the overall outcome, not the specific outcome of the reaction of one molecule. The excess oxygen remains unreacted. H.2 BALANCING CHEMICAL EQUATIONS F63 FUNDAMENTALS EXAMPLE H.1 Writing and balancing a chemical equation Write and balance the chemical equation for the combustion of liquid hexane, C6H14, to gaseous carbon dioxide gas and gaseous water. Anticipate Combustion refers to burning in air, specifically to reaction with molecular oxygen. Because hexane contains six C atoms and 14 H atoms, we can expect each molecule to give rise to six CO2 molecules and seven H2O molecules, so the balanced equation will be of the form C6H14 ϩ ? O2 : 6 CO2 ϩ 7 H2O or a multiple of it. PLAN First write the skeletal equation, using the rules in Section D if necessary. Balance first the element that occurs in the fewest formulas. Verify that the coefficients are the smallest whole numbers. Specify the states of each reactant and product. SOLVE Write the skeletal equation. ƽ Balance carbon and hydrogen. ƽ Next balance oxygen. In this case, a fractional stoichiometric coefficient is needed. Multiply by 2 to clear the fraction. Add the physical states. Evaluate As we anticipated, the balanced equation, 2 C6H14(g) ϩ 19 O2(g) : 12 CO2(g) ϩ 14 H2O(g), is a multiple (in fact, by a factor of 2) of an equation of the form C6H14 ϩ ? O2 : 6 CO2 ϩ 7 H2O. Self-Test H.1A When aluminum is melted and heated with solid barium oxide, a vigorous reaction takes place, and elemental molten barium and solid aluminum oxide are formed. Write the balanced chemical equation for the reaction. [Answer: 2 Al(l) ϩ 3 BaO(s) : ⌬ Al2O3(s) ϩ 3 Ba(l)] Self-Test H.1B Write the balanced chemical equation for the reaction of solid magnesium nitride with aqueous sulfuric acid to form aqueous magnesium sulfate and aqueous ammonium sulfate. A chemical equation expresses a chemical reaction in terms of chemical formulas; the stoichiometric coefficients are chosen to show that atoms are neither created nor destroyed in the reaction. 2 C6H14(g) + 19 O2(g) ¡ 12 CO2(g) + 14 H2O(g) 2 C6H14 + 19 O2 ¡ 12 CO2 + 14 H2O C6H14 + 19 2 O2 ¡ 6 CO2 + 7 H2O C6H14 + O2 ¡ 6 CO2 + 7 H2O C6H14 + O2 ¡ CO2 + H2O F64 FUNDAMENTALS SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Explain the role of stoichiometric coefficients (Section H.1). ❑ 2 Write, balance, and label a chemical equation on the basis of information given in sentence form (Example H.1). EXERCISES H.1 It appears that balancing the chemical equation Cu ϩ SO2 : CuO ϩ S would be simple if we could just add another O to the product side: Cu ϩ SO2 : CuO ϩ S ϩ O. (a) Why is that balancing procedure not allowed? (b) Balance the equation correctly. H.2 Indicate which of the following are conserved in a chemical reaction: (a) mass; (b) number of atoms; (c) number of molecules; (d) number of electrons. H.3 The first box below represents the reactants for a chemical reaction and the second box the products that form if all the reactant molecules shown react. Using the key below, write a balanced equation for the reaction. Assume that if two atoms are touching, they are bonded together. Key: • oxygen; hydrogen; ♦ silicon. H.4 The first box below represents the reactants for a chemical reaction and the second box the products that form if all the reactant molecules shown react. Using the key below, write a balanced equation for the reaction using the smallest wholenumber coefficients. Assume that if two atoms are touching, they are bonded together. Key: • oxygen; hydrogen; ■ nitrogen. H.5 Balance the following skeletal chemical equations: (a) NaBH4(s) ϩ H2O(l) : NaBO2(aq) ϩ H2(g) (b) Mg(N3)2(s) ϩ H2O(l) : Mg(OH)2(aq) ϩ HN3(aq) (c) NaCl(aq) ϩ SO3(g) ϩ H2O(l) : Na2SO4(aq) ϩ HCl(aq) (d) Fe2P(s) ϩ S(s) : P4S10(s) ϩ FeS(s) H.6 Balance the following skeletal chemical equations: (a) KClO3(s) ϩ C6H12O6(s) ⌬ : KCl(s) ϩ CO2(g) ϩ H2O(g) (b) P2S5(s) ϩ PCl5(s) : PSCl3(g) (c) (in ether) LiBH4 ϩ BF3 : B2H6 ϩ LiBF4 (d) Ca3(PO4)2(s) ϩ SiO2(s) ϩ C(s) ⌬ : CaSiO3(l) ϩ CO(g) + P4(g) H.7 Write a balanced chemical equation for each of the following reactions. (a) Calcium metal reacts with water to produce hydrogen gas and aqueous calcium hydroxide. (b) The reaction of solid sodium oxide, Na2O, and water produces aqueous sodium hydroxide. (c) Hot solid magnesium metal reacts in a nitrogen atmosphere to produce solid magnesium nitride, Mg3N2. (d) The reaction of ammonia gas with oxygen gas at high temperatures in the presence of a copper metal catalyst produces the gases water and nitrogen dioxide. H.8 Write a balanced chemical equation for each of the following reactions. (a) In the first step of recovering copper metal from ores containing CuFeS2 the ore is heated in air. During this “roasting” process, molecular oxygen reacts with the CuFeS2 to produce solid copper(II) sulfide, iron(II) oxide, and sulfur dioxide gas. (b) The diamond-like abrasive silicon carbide, SiC, is made by reacting solid silicon dioxide with elemental carbon at 2000ЊC to produce solid silicon carbide and carbon monoxide gas. (c) The reaction of elemental hydrogen and nitrogen gases is used for the commercial production of gaseous ammonia in the Haber process. (d) Under acidic conditions oxygen gas can react with aqueous hydrobromic acid to form liquid water and liquid bromine. H.9 In one stage in the commercial production of iron metal in a blast furnace, the iron(III) oxide, Fe2O3, reacts with carbon monoxide to form solid Fe3O4 and carbon dioxide gas. In a second stage, the Fe3O4 reacts further with carbon monoxide to produce solid elemental iron and carbon dioxide. Write the balanced equation for each stage in the process. H.10 The bacteria-catalyzed oxidation of ammonia in waste water takes place in two steps. In the first step aqueous ammonia reacts with oxygen gas to form aqueous nitrous acid and water. In the second step the nitrous acid reacts with additional oxygen to form aqueous nitric acid. Write the balanced equation for each stage in the process. H.11 When nitrogen and oxygen gases react in the cylinder of an automobile engine, nitric oxide gas, NO, is formed. After it escapes into the atmosphere with the other exhaust gases, the nitric oxide reacts with oxygen to produce nitrogen dioxide gas, one of the precursors of acid rain. Write the two balanced equations for the reactions leading to the formation of nitrogen dioxide. H.12 The reaction of boron trifluoride, BF3(g), with sodium borohydride, NaBH4(s), leads to the formation of sodium tetrafluoroborate, NaBF4(s), and diborane gas, B2H6(g). The diborane reacts with the oxygen in air, forming boron oxide, B2O3(s), and water. Write the two balanced equations leading to the formation of boron oxide. H.13 Hydrofluoric acid is used to etch grooves in glass because it reacts with the silica, SiO2(s), in glass. The products of the reaction are aqueous silicon tetrafluoride and water. Write a balanced equation for the reaction. H.14 The compound Sb4O5Cl2(s), which has been investigated because of its interesting electrical properties, can be prepared by warming a mixture of antimony(III) oxide and antimony(III) chloride, both of which are solids. Write a balanced equation for the reaction. H.15 Write a balanced equation for the complete combustion (reaction with oxygen gas) of liquid heptane, C7H16, a component typical of the hydrocarbons in gasoline, to carbon dioxide gas and water vapor. ~ ~ FUNDAMENTALS I.1 ELECTROLYTES F65 H.16 Write a balanced equation for the incomplete combustion (reaction with oxygen gas) of liquid heptane, C7H16, to carbon monoxide gas and water vapor. H.17 Aspartame, C14H18N2O5, is a solid used as an artificial sweetener. Write the balanced equation for its combustion to carbon dioxide gas, liquid water, and nitrogen gas. H.18 Dimethazan, C11H17N5O2, is a solid antidepressant drug. Write the balanced equation for its combustion to carbon dioxide gas, liquid water, and nitrogen gas. H.19 The psychoactive drug sold as methamphetamine (“speed”), C10H15N, undergoes a series of reactions in the body; the net result of these reactions is the oxidation of solid methamphetamine by oxygen gas to produce carbon dioxide gas, liquid water, and an aqueous solution of urea, CH4N2O. Write the balanced equation for this net reaction. H.20 The psychoactive street drug sold as MDMA (“Ecstacy”), C11H15NO2, undergoes a series of reactions in the body; the net result of these reactions is the oxidation of aqueous MDMA by oxygen gas to produce carbon dioxide gas, liquid water, and an aqueous solution of urea, CH4N2O. Write the balanced equation for this net reaction. H.21 Sodium thiosulfate, which as the pentahydrate Na2S2O3и5H2O forms the large white crystals used as “photographer’s hypo,” can be prepared by bubbling oxygen through a solution of sodium polysulfide, Na2S5, in alcohol and adding water. Sulfur dioxide gas is formed as a by-product. Sodium polysulfide is made by the action of hydrogen sulfide gas on a solution of sodium sulfide, Na2S, in alcohol, which, in turn, is made by the reaction of hydrogen sulfide gas, H2S, with solid sodium hydroxide. Write the three chemical equations that show how hypo is prepared from hydrogen sulfide and sodium hydroxide. Use (alc) to indicate the state of species dissolved in alcohol. H.22 The first stage in the production of nitric acid by the Ostwald process is the reaction of ammonia gas with oxygen gas, producing nitric oxide gas, NO, and liquid water. The nitric oxide further reacts with oxygen to produce nitrogen dioxide gas, which, when dissolved in water, produces nitric acid and nitric oxide. Write the three balanced equations that lead to the production of nitric acid. H.23 Phosphorus and oxygen react to form two different phosphorus oxides. The mass percentage of phosphorus in one of these oxides is 43.64%; in the other, it is 56.34%. (a) Write the empirical formula of each phosphorus oxide. (b) The molar mass of the former oxide is 283.33 gиmolϪ1 and that of the latter is 219.88 gиmolϪ1 . Determine the molecular formula and name of each oxide. (c) Write a balanced chemical equation for the formation of each oxide. H.24 One step in the refining of titanium metal is the reaction of FeTiO3 with chlorine gas and carbon. Balance the equation for the reaction: FeTiO3(s) ϩ Cl2(g) ϩ C(s) : TiCl4(l) ϩ FeCl3(s) ϩ CO(g). I AQUEOUS SOLUTIONS AND PRECIPITATION When we mix two solutions the result is often simply a new solution that contains both solutes. However, in some cases the solutes can react with each other. For instance, when we mix a colorless aqueous solution of silver nitrate with a clear yellow aqueous solution of potassium chromate, a powdery red solid forms, indicating that a chemical reaction has occurred (Fig. I.1). This section and the next two introduce three of the main types of chemical reactions: precipitation reactions, acid–base reactions, and redox reactions, all of which are discussed in more depth in later chapters. (The fourth type of reaction discussed in this text, Lewis acid–base reactions, is introduced in Section 11.2.) Many chemical reactions take place in solution, particularly in water; therefore, in this section we begin by considering the nature of aqueous solutions. I.1 Electrolytes A soluble substance is one that dissolves to a significant extent in a specified solvent. When we refer simply to solubility without mentioning the solvent, we mean “soluble in water.” An insoluble substance is one that does not dissolve significantly in a specified solvent; substances are often regarded as “insoluble” if they do not dissolve to more than about 0.1 molиLϪ1 . Unless otherwise specified in this text, we use the term insoluble to mean “insoluble in water.” For instance, calcium carbonate, CaCO3, which makes up limestone and chalk, dissolves to form a solution that contains only 0.01gиLϪ1 (corresponding in this case to 1 ϫ 10Ϫ4 molиLϪ1 ), and we regard CaCO3 as insoluble. This insolubility is important for landscapes: chalk hills and limestone buildings do not wash away in natural rainwater. A solute may be present as ions or as molecules. We can find out if the solute is present as ions by noting whether the solution conducts an electric current. Because a current is a flow of electric charge, only solutions that contain ions conduct electricity. I.1 Electrolytes I.2 Precipitation Reactions I.3 Ionic and Net Ionic Equations I.4 Putting Precipitation to Work FIGURE I.1 When a solution of yellow K2CrO4 is mixed with a colorless solution of AgNO3 a red precipitate of silver chromate, Ag2CrO4, forms. F66 FUNDAMENTALS NaClcrystal Naϩ ClϪ Water Naϩ ClϪ Methanol molecule FIGURE I.3 In a nonelectrolyte solution, the solute remains as a molecule and does not break up into ions. Methanol, CH3OH, is a nonelectrolyte and is present as intact molecules when it is dissolved in water. The inset shows the methanol molecule alone. The term electrolyte is also used in some contexts to denote a medium, such as a liquid solution or a porous solid, that can conduct electricity by the migration of ions. 1 Acetone, C3H6O 2 ␣-D-Glucose, C6H12O6 There is such a tiny concentration of ions in pure water (about 10Ϫ7 molиLϪ1 ) that pure water itself does not conduct electricity significantly. An electrolyte is a substance that, in solution, is present as ions. Ionic solids that are soluble in water are electrolytes because the ions become free to move when water molecules separate the ions (Fig. I.2). Some electrolytes, such as acids, exist as molecules that form ions only when they dissolve. The term electrolyte solution is commonly used to emphasize that the medium is in fact a solution. A nonelectrolyte is a substance that does not form ions in solution; it dissolves to give a nonelectrolyte solution. Aqueous solutions of acetone (1) and glucose (2) are nonelectrolyte solutions. Except for acids, most organic compounds that dissolve in water form nonelectrolyte solutions. If we could see the individual molecules in a nonelectrolyte solution, we would see the intact solute molecules dispersed among the solvent molecules (Fig. I.3). A strong electrolyte is a substance that is present almost entirely as ions in solution. Three types of solutes are strong electrolytes: strong acids and strong bases, which will be described in more detail in Section J, and soluble ionic compounds. Hydrogen chloride is a strong electrolyte; so are sodium hydroxide and the salt sodium chloride. A weak electrolyte is a substance that is incompletely ionized in solution; in other words, most of the molecules remain intact. Acetic acid is a weak electrolyte: in aqueous solution at normal concentrations, only a small fraction of CH3COOH molecules separate into hydrogen ions, Hϩ , and acetate ions, CH3CO2 Ϫ . One way to distinguish strong and weak electrolytes is to measure the abilities of their solutions to conduct electricity: for the same molar concentration of solute, a solution of strong electrolyte is a better conductor than a solution of a weak electrolyte (Fig. I.4). Self-Test I.1A Identify each of the following substances as an electrolyte or a nonelectrolyte and predict which will conduct electricity when dissolved in water: (a) NaOH; (b) Br2. [Answer: (a) Ionic compound, so a strong electrolyte, conducts electricity; (b) molecular compound and not an acid, so a nonelectrolyte, does not conduct electricity] Self-Test I.1B Identify each of the following substances as an electrolyte or a nonelectrolyte and predict which will conduct electricity when dissolved in water: (a) ethanol, CH3CH2OH(aq); (b) Pb(NO3)2(aq). The solute in an aqueous strong electrolyte solution is present as ions that can conduct electricity through the solution. The solutes in nonelectrolyte solutions are present as molecules. Only a small fraction of the solute molecules in weak electrolyte solutions are present as ions. FIGURE I.2 Sodium chloride consists of sodium ions and chloride ions. When sodium chloride comes in contact with water (left), the ions are separated by the water molecules, and they spread throughout the solvent (right). The solution consists of water, sodium ions, and chloride ions. There are no NaCl molecules present. In the insets water molecules are represented by the blue background. Animation I.2 I.3 IONIC AND NET IONIC EQUATIONS F67 (a) (c)(b) I.2 Precipitation Reactions Some ionic compounds are soluble, others are not. Consider what happens when we pour a solution of sodium chloride (a strong electrolyte) into a solution of silver nitrate (another strong electrolyte). A solution of sodium chloride contains Naϩ cations and ClϪ anions. Similarly, a solution of silver nitrate, AgNO3, contains Agϩ cations and NO3 Ϫ anions. When we mix these two aqueous solutions, a white precipitate, a cloudy, finely divided solid deposit, forms immediately. Analysis shows that the precipitate is silver chloride, AgCl, an insoluble white solid. The colorless solution remaining above the precipitate contains dissolved Naϩ cations and NO3 Ϫ anions. These ions remain in solution because sodium nitrate, NaNO3, is soluble in water. In a precipitation reaction, an insoluble solid product forms when we mix two electrolyte solutions. When an insoluble substance is formed in water, it immediately precipitates. In the chemical equation for a precipitation reaction, we use (aq) to indicate substances that are dissolved in water and (s) to indicate the solid that has precipitated: A precipitation reaction takes place when solutions of two electrolytes are mixed and react to form an insoluble solid. I.3 Ionic and Net Ionic Equations A complete ionic equation for a precipitation reaction shows all the species as they actually exist in solution; because dissolved ionic compounds exist as separate aqueous ions, the ions are shown separately. For example, the complete ionic equation for the silver chloride precipitation reaction shown in Fig. I.5 is Because the Naϩ and NO3 Ϫ ions appear as both reactants and products, they play no direct role in the reaction. They are spectator ions, ions that are present while the reaction takes place but do not participate in it, like spectators at a sports event. Because spectator ions remain unchanged, we can simplify the chemical equation by canceling them on each side of the arrow in the ionic equation: Canceling the spectator ions leaves the net ionic equation for the reaction, the chemical equation that displays only the net change taking place in the reaction: Ag+ (aq) + Cl(aq) ¡ AgCl(s) AgCl(s) + Na+ (aq) + NO3 - (aq) Ag+ (aq) + NO3 (aq) + Na+ (aq) + Cl(aq) ¡ AgCl(s) + Na+ (aq) + NO3 - (aq) Ag+ (aq) + NO3 (aq) + Na+ (aq) + Cl(aq) ¡ AgNO3(aq) + NaCl(aq) ¡ AgCl(s) + NaNO3(aq) Lab Video I.4 FIGURE I.4 (a) Pure water is a poor conductor of electricity, as shown by the very dim glow of the bulb in the circuit on the left. (b) When ions are present, as in this weak electrolyte solution, the solution has a low ability to conduct electricity. That ability is significant when the solute is a strong electrolyte (c), even when the solute concentration is the same in each instance. F68 FUNDAMENTALS (a) Complete ionic reaction Net ionic reaction (b) FIGURE I.5 (a) Silver chloride precipitates immediately when sodium chloride solution is added to a solution of silver nitrate. (b) If we imagine the removal of the spectator ions from the complete ionic reaction (top), we can focus on the essential process, the net ionic reaction (bottom). The net ionic equation shows that Agϩ ions combine with ClϪ ions to precipitate as solid silver chloride, AgCl (see Fig. I.5). A net ionic equation focuses our attention on the change that results from the chemical reaction. EXAMPLE I.1 Writing a net ionic equation When concentrated aqueous solutions of barium nitrate, Ba(NO3)2, and ammonium iodate, NH4IO3, are mixed, insoluble barium iodate, Ba(IO3)2, forms. The chemical equation for the precipitation reaction is Write the net ionic equation for the reaction. Anticipate Nitrate ions and ammonium ions occur in solution on both sides of the equation, so we can expect them to cancel and the ionic equation to involve only iodate ions and barium ions. PLAN First, write and balance the complete ionic equation, showing all the dissolved ions as they actually exist in solution, as separate, charged ions. Insoluble solids are shown as complete compounds. Next, cancel the spectator ions, the ions that appear as aqueous ions on both sides of the arrow. SOLVE The complete ionic equation, which shows all the dissolved ions, both those that react and the spectator ions, is We cancel the spectator ions, NH4 ϩ and NO3 Ϫ : and obtain the net ionic equation: Ba2+ (aq) + 2 IO3 (aq) ¡ Ba(IO3)2(s) Ba(IO3)2(s) + 2 NH4 + (aq) + 2 NO3 - (aq) Ba2+ (aq) + 2 NO3 (aq) + 2 NH4 + (aq) + 2 IO3 (aq) ¡ Ba(IO3)2(s) + 2 NH4 + (aq) + 2 NO3 - (aq) Ba2+ (aq) + 2 NO3 (aq) + 2 NH4 + (aq) + 2 IO3 (aq) ¡ Ba(IO3)2(s) + 2 NH4NO3(aq)Ba(NO3)2(aq) + 2 NH4IO3(aq) ¡ I.4 PUTTING PRECIPITATION TO WORK F69 FUNDAMENTALS FIGURE I.6 A step in a gravimetric analysis. To determine how much of a particular type of ion was present in a solution, the ion was precipitated and the precipitate is being filtered. The filter paper, which has a known mass, will then be dried and weighed, thereby allowing the mass of the precipitate to be determined. Section 12.14 describes the use of precipitates in qualitative analysis in more detail. You will find an example of how to use this technique in Section L. Evaluate As we anticipated, the NH4 ϩ and NO3 Ϫ ions do not appear in the net ionic equation. Self-Test I.2A Write the net ionic equation for the reaction in Fig. I.1, in which aqueous solutions of colorless silver nitrate and yellow potassium chromate react to give a precipitate of red silver chromate. [Answer: 2 Agϩ (aq) ϩ CrO4 2Ϫ (aq) : Ag2CrO4(s)] Self-Test I.2B The mercury(I) ion, Hg2 2ϩ , consists of two Hgϩ ions joined together. Write the net ionic equation for the reaction in which colorless aqueous solutions of mercury(I) nitrate, Hg2(NO3)2, and potassium phosphate, K3PO4, react to give a white precipitate of mercury(I) phosphate. A complete ionic equation expresses a reaction in terms of the ions that are present in solution; a net ionic equation is the chemical equation that remains after the cancellation of the spectator ions. I.4 Putting Precipitation to Work Precipitation reactions have many applications in chemistry. One is to make compounds by mixing two solutions that form a precipitate of the desired insoluble compound when they are mixed. Then we can separate the insoluble compound from the reaction mixture by filtration. Precipitation reactions are also used in chemical analysis. In qualitative analysis—the identification of the substances present in a sample—the formation of a precipitate is used to confirm the identity of certain ions. In quantitative analysis, the aim is to determine the amount of each substance or element present. In particular, in gravimetric analysis, the amount of substance present is determined by measurements of mass. In this application, an insoluble compound is precipitated, the precipitate is filtered off and weighed, and from its mass the amount of a substance in one of the original solutions is calculated (Fig. I.6). Gravimetric analysis can be used in environmental monitoring to find out how much of a heavy metal ion, such as lead or mercury, is in a sample of water. Table I.1 summarizes the solubility patterns of common ionic compounds in water. Notice that all nitrates and all common compounds of the Group 1 metals are soluble; so they make useful starting solutions for precipitation reactions. Any spectator ions can be used, provided that they remain in solution and do not otherwise react. For example, Table I.1 shows that mercury(I) iodide, Hg2I2, is insoluble. It is formed as a precipitate when solutions containing Hg2 2ϩ ions and IϪ ions are mixed: Because the spectator ions are not shown, the net ionic equation will be the same when any soluble mercury(I) compound is mixed with any soluble iodide. Hg2 2+ (aq) + 2 I(aq) ¡ Hg2I2(s) TABLE I.1 Solubility Rules for Inorganic Compounds Soluble compounds Insoluble compounds compounds of Group 1 elements ammonium (NH4 ϩ ) compounds chlorides (ClϪ ), bromides (BrϪ ), and iodides (IϪ ), except those of Agϩ , Hg2 2ϩ , and Pb2ϩ * nitrates (NO3 Ϫ ), acetates (CH3CO2 Ϫ ), chlorates (ClO3 Ϫ ), and perchlorates (ClO4 Ϫ ) sulfates (SO4 2Ϫ ), except those of Ca2ϩ , Sr2ϩ , Ba2ϩ , Pb2ϩ , Hg2 2ϩ , and Agϩ† carbonates (CO3 2Ϫ ), chromates (CrO4 2Ϫ ), oxalates (C2O4 2Ϫ ), and phosphates (PO4 3Ϫ ), except those of the Group 1 elements and NH4 ϩ sulfides (S2Ϫ ), except those of the Group 1 and 2 elements and NH4 ϩ hydroxides (OHϪ ) and oxides (O2Ϫ ), except those of the Group 1 elements and Group 2 elements below Period 2‡ *PbCl2 is slightly soluble. † Ag2SO4 is slightly soluble. ‡ Ca(OH)2 and Sr(OH)2 are sparingly (slightly) soluble; Mg(OH)2 is only very slightly soluble. F70 FUNDAMENTALS EXAMPLE I.2 Predicting the outcome of a precipitation reaction Predict the precipitate likely to be formed, if any, when aqueous solutions of sodium phosphate and lead(II) nitrate are mixed. Write the net ionic equation for the reaction. PLAN Decide which ions are present in the mixed solutions and consider all possible combinations. Use the solubility rules in Table I.1 to decide which combination corresponds to an insoluble compound and write the net ionic equation to match. SOLVE The mixed solution will contain Naϩ , PO4 3Ϫ , Pb2ϩ , and NO3 Ϫ ions. All nitrates and all compounds of Group 1 metals are soluble, but phosphates of other elements are generally insoluble. Hence, we can predict that Pb2ϩ and PO4 3Ϫ ions will form an insoluble compound and that lead(II) phosphate, Pb3(PO4)2, will precipitate. Now write the net ionic equation. The Naϩ and NO3 Ϫ ions are spectators, and so they are omitted. Self-Test I.3A Predict the identity of the precipitate that forms, if any, when aqueous solutions of ammonium sulfide and copper(II) sulfate are mixed, and write the net ionic equation for the reaction. [Answer: Copper(II) sulfide; Cu2ϩ (aq) ϩ S2Ϫ (aq) : CuS(s)] Self-Test I.3B Suggest two solutions that can be mixed to prepare strontium sulfate, and write the net ionic equation for the reaction. The solubility rules in Table I.1 are used to predict the outcomes of precipitation reactions. 3 Pb2+ (aq) + 2 PO4 3(aq) ¡ Pb3(PO4)2(s) SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Identify electrolytes or nonelectrolytes on the basis of the formulas of the solutes (Self-Test I.1). ❑ 2 Construct balanced complete ionic and net ionic equations for reactions involving ions (Example I.1). ❑ 3 Use the solubility rules to select appropriate solutions that, when mixed, will produce a desired precipitate (Section I.4). ❑ 4 Identify any precipitate that may form on mixing two given solutions (Example I.2). EXERCISES I.1 The beaker on the left pictured below contains 0.50 M CaCl2(aq)and the beaker on the right contains 0.50 M Na2SO4(aq). Suppose the contents of the two beakers are mixed. Draw a picture of the resulting products. I.2 The beaker on the left pictured below contains 0.50 M Hg2(NO3)2(aq) and the beaker on the right contains 0.50 M K3PO4(aq). Suppose the contents of the two beakers are mixed. Draw a picture of the resulting products. I.3 How would you use the solubility rules in Table I.1 to separate the following pairs of ions? In each case indicate what reagent you would add and write the net ionic equation for the precipitation reaction: (a) lead(II) and copper(II) ions; (b) ammonium and magnesium ions. I.4 How would you use the solubility rules in Table I.1 to separate the following pairs of ions? In each case indicate what reagent you would add and write the net ionic equation for the precipitation reaction: (a) barium and mercury(I) ions; (b) silver and zinc ions. I.5 Classify each of the following substances as a strong electrolyte or a nonelectrolyte: (a) CH3OH; (b) BaCl2; (c) KF. I.6 Classify each of the following substances as a strong electrolyte, a weak electrolyte, or a nonelectrolyte: (a) H2SO4; (b) KOH; (c) CH3CH2CH2COOH. EXERCISES F71 FUNDAMENTALS I.7 Use the information in Table I.1 to classify each of the following ionic compounds as soluble or insoluble in water: (a) potassium phosphate, K3PO4; (b) lead(II) chloride, PbCl2; (c) cadmium sulfide, CdS; (d) barium sulfate, BaSO4. I.8 Use the information in Table I.1 to classify each of the following ionic compounds as soluble or insoluble in water: (a) cadmium nitrate, Cd(NO3)2; (b) copper(II) acetate, Cu(CH3CO2)2; (c) cobalt(III) hydroxide, Co(OH)3; (d) silver bromide, AgBr. I.9 What are the principal solute species present in an aqueous solution of (a) NaI; (b) Ag2CO3; (c) (NH4)3PO4; (d) FeSO4? I.10 What are the principal solute species present in an aqueous solution of (a) CoCO3; (b) LiNO3; (c) K2CrO4; (d) Hg2Cl2? I.11 (a) When aqueous solutions of iron(III) sulfate and sodium hydroxide were mixed, a precipitate formed. Write the formula of the precipitate. (b) Does a precipitate form when aqueous solutions of silver nitrate, AgNO3, and potassium carbonate are mixed? If so, write the formula of the precipitate. (c) If aqueous solutions of lead(II) nitrate and sodium acetate are mixed, does a precipitate form? If so, write the formula of the precipitate. I.12 (a) Solid calcium nitrate and solid sodium carbonate were mixed, placed in water, and stirred. What is observed? If a precipitate is present, write its formula. (b) Solid nickel(II) sulfate and solid copper(II) chloride were placed in water, and the mixture was stirred. Is the formation of a precipitate expected? If so, write the formula of the precipitate. (c) Aqueous solutions of sodium phosphate and barium chloride are mixed. What is observed? If a precipitate is present, write its formula. I.13 When the solution in Beaker 1 is mixed with the solution in Beaker 2, a precipitate forms. Using the following table, write the net ionic equation describing the formation of the precipitate, and then identify the spectator ions. Beaker 1 Beaker 2 (a) FeCl2(aq) Na2S(aq) (b) Pb(NO3)2(aq) KI(aq) (c) Ca(NO3)2(aq) K2SO4(aq) (d) Na2CrO4(aq) Pb(NO3)2(aq) (e) Hg2(NO3)2(aq) K2SO4(aq) I.14 The contents of Beaker 1 are mixed with those of Beaker 2. If a reaction takes place, write the net ionic equation and indicate the spectator ions. Beaker 1 Beaker 2 (a) K2SO4(aq) AgNO3(aq) (b) H3PO4(aq) SrBr2(aq) (c) Na2S(aq) NH4NO3(aq) (d) CdSO4(aq) (NH4)2CO3(aq) (e) H2SO4(aq) Hg2Cl2(aq) I.15 Each of the following procedures results in the formation of a precipitate. For each reaction, write the chemical equations describing the formation of the precipitate: the overall equation, the complete ionic equation, and the net ionic equation. Identify the spectator ions. (a) (NH4)2CrO4(aq) is mixed with BaCl2(aq). (b) CuSO4(aq) is mixed with Na2S(aq). (c) FeCl2(aq) is mixed with (NH4)3PO4(aq). (d) Potassium oxalate, K2C2O4(aq), is mixed with Ca(NO3)2(aq). (e) NiSO4(aq) is mixed with Ba(NO3)2(aq). I.16 Each of the following procedures results in the formation of a precipitate. For each reaction, write the chemical equations describing the formation of the precipitate: the overall equation, the complete ionic equation, and the net ionic equation. Identify the spectator ions. (a) AgNO3(aq) is mixed with Na2CO3(aq). (b) Pb(NO3)2(aq) is mixed with KI(aq). (c) Ba(OH)2(aq) is mixed with H2SO4(aq). (d) (NH4)2S(aq) is mixed with Cd(NO3)2(aq). (e) KOH(aq) is mixed with CuCl2(aq). I.17 Write the balanced overall, complete ionic, and net ionic equations corresponding to each of the following reactions: (a) Ba(CH3CO2)2(aq) ϩ Li2CO3(aq) : BaCO3(s) ϩ LiCH3CO2(aq) (b) NH4Cl(aq) ϩ Hg2(NO3)2(aq) : NH4NO3(aq) ϩ Hg2Cl2(s) (c) Cu(NO3)2(aq) ϩ Ba(OH)2(aq) : Cu(OH)2(s) ϩ Ba(NO3)2(aq) I.18 Write the balanced overall, complete ionic, and net ionic equations corresponding to each of the following reactions: (a) BaCl2(aq) ϩ K3PO4(aq) : Ba3(PO4)2(s) ϩ KCl(aq) (b) KCl(aq) ϩ Hg2(NO3)2(aq) : Hg2Cl2(s) ϩ KNO3(aq) (c) K2C2O4(aq) ϩ Fe(CH3CO2)3(aq) : Fe2(C2O4)3(s) ϩ KCH3CO2(aq) I.19 For each of the following reactions, suggest two soluble ionic compounds that, when mixed together in water, result in the net ionic equation given: (a) 2 Agϩ (aq) ϩ CrO4 2Ϫ (aq) : Ag2CrO4(s) (b) Ca2ϩ (aq) ϩ CO3 2Ϫ (aq) : CaCO3(s), the reaction responsible for the deposition of chalk hills and sea urchin spines (c) Cd2ϩ (aq) ϩ S2Ϫ (aq) : CdS(s), a yellow substance used to color glass I.20 For each of the following reactions, suggest two soluble ionic compounds that, when mixed together in water, result in the net ionic equation given: (a) 2 Agϩ (aq) ϩ CO3 2Ϫ (aq) : Ag2CO3(s) (b) Mg2ϩ (aq) ϩ 2 OHϪ (aq) : Mg(OH)2(s), the suspension present in milk of magnesia (c) 3 Ca2ϩ (aq) ϩ 2 PO4 3Ϫ (aq) : Ca3(PO4)2(s), gypsum, a component of concrete I.21 Write the net ionic equation for the formation of each of the following insoluble compounds in aqueous solution: (a) silver sulfate, Ag2SO4; (b) mercury(II) sulfide, HgS, used as an electrolyte in some primary batteries; (c) calcium phosphate, Ca3(PO4)2, a component of bones and teeth. (d) Select two soluble ionic compounds that, when mixed in solution, form each of the insoluble compounds in parts (a), (b), and (c). Identify the spectator ions. I.22 Write the net ionic equation for the formation of each of the following insoluble compounds in aqueous solution: (a) lead(II) chromate, PbCrO4, the yellow pigment that has been used for centuries in oil paints; (b) aluminum phosphate, AlPO4, used in cements and as an antacid; (c) iron(II) hydroxide, Fe(OH)2; (d) Select two soluble ionic compounds that, when mixed in F72 FUNDAMENTALS solution, form each of the insoluble compounds in parts (a), (b), and (c). Identify the spectator ions. I.23 You are given a solution and asked to analyze it for the cations Agϩ , Ca2ϩ , and Zn2ϩ . You add hydrochloric acid, and a white precipitate forms. You filter out the solid and add sulfuric acid to the solution. Nothing appears to happen. Then you add hydrogen sulfide. A black precipitate forms. Which ions should you report as present in your solution? I.24 You are given a solution and asked to analyze it for the cations Agϩ , Ca2ϩ , and Hg2ϩ . You add hydrochloric acid. Nothing appears to happen. You then add dilute sulfuric acid, and a white precipitate forms. You filter out the solid and add hydrogen sulfide to the solution that remains. A black precipitate forms. Which ions should you report as present in your solution? I.25 Suppose that 40.0 mL of 0.100 M NaOH(aq) is added to 10.0 mL of 0.200 M Cu(NO3)2(aq). (a) Write the chemical equation for the precipitation reaction, the complete ionic equation, and the net ionic equation. (b) What is the molarity of Naϩ ions in the final solution? I.26 Suppose that 2.50 g of solid (NH4)3(PO4) is added to 50.0 mL of 0.125 M CaCl2(aq). (a) Write the chemical equation for the precipitation reaction and the net ionic equation. (b) What is the molarity of each spectator ion after reaction is complete? Assume a final volume of 70.0 mL. I.27 Suppose that 5.20 g of solid potassium chromate is added to 75.0 mL of 0.250 M Mg(NO3)2(aq). (a) What is the initial molarity of potassium chromate in the solution? (b) What mass of potassium is present in solution? (c) Write the formula for the precipitate that forms. Assume a final volume of 75.0 mL. J ACIDS AND BASES Early chemists applied the term acid to substances that had a sharp or sour taste. Vinegar, for instance, contains acetic acid, CH3COOH. Aqueous solutions of substances that they called bases or alkalis were recognized by their soapy feel. Fortunately, there are less hazardous ways of recognizing acids and bases. For instance, acids and bases change the color of certain dyes known as indicators (Fig. J.1). One of the best-known indicators is litmus, a vegetable dye obtained from a lichen. Aqueous solutions of acids turn litmus red; aqueous solutions of bases turn it blue. Later (in Chapter 12), we shall see that the electronic instrument known as a “pH meter” provides a rapid way of identifying a solution as acidic or basic: a pH lower than 7 (pH Ͻ 7) denotes an acidic solution a pH higher than 7 (pH Ͼ 7) denotes a basic solution J.1 Acids and Bases in Aqueous Solution Chemists debated the concepts of acid and base for many years before precise definitions emerged. Among the first useful definitions was the one proposed by the Swedish chemist Svante Arrhenius in about 1884: An acid is a compound that contains hydrogen and reacts with water to form hydrogen ions. A base is a compound that produces hydroxide ions in water. J.1 Acids and Bases in Aqueous Solution J.2 Strong and Weak Acids and Bases J.3 Neutralization FIGURE J.1 The acidities of various household products can be demonstrated by adding an indicator (an extract of red cabbage, in this case) and noting the resulting color. Red indicates an acidic solution, blue basic. From left to right, the household products are stomach acid, lemon-lime soda, tap water, detergent, and a solution of lye. The yellow seen in the lye solution is a sign that the lye is so basic that it has destroyed some of the dye. J.1 ACIDS AND BASES IN AQUEOUS SOLUTION F73 FUNDAMENTALS These compounds are called Arrhenius acids and bases. For instance, HCl is an Arrhenius acid, because it releases a hydrogen ion, Hϩ (a proton), when it dissolves in water; CH4 is not an Arrhenius acid, because it does not release hydrogen ions in water. Sodium hydroxide is an Arrhenius base, because OHϪ ions go into solution when it dissolves; ammonia is an Arrhenius base, because it produces OHϪ ions by reacting with water: (1) Sodium metal, although it produces OHϪ ions when it reacts with water, is not an Arrhenius base, because it is an element, not a compound, as the definition requires. The problem with the Arrhenius definitions is that they are specific to one particular solvent, water. When chemists studied nonaqueous solvents, such as liquid ammonia, they found that a number of substances showed the same pattern of acid–base behavior. A major advance in our understanding of what it means to be an acid or a base came in 1923, when two chemists working independently, Thomas Lowry in England and Johannes Brønsted in Denmark, came up with the same idea. Their insight was to realize that the key process responsible for the properties of acids and bases was the transfer of a proton (a hydrogen ion) from one substance to another. The Brønsted–Lowry definition of acids and bases is as follows: An acid is a proton donor. A base is a proton acceptor. We call such substances “Brønsted acids and bases” or just plain “acids and bases” because the Brønsted–Lowry definition is the one commonly accepted today and the one used throughout this text. First consider acids. When a molecule of an acid dissolves in water, it donates a hydrogen ion, H+ , to one of the water molecules and forms a hydronium ion, H3Oϩ (1). For example, when hydrogen chloride, HCl, dissolves in water, it releases a hydrogen ion to water, and the resulting solution consists of hydronium ions and chloride ions: Notice that because H2O accepts the hydrogen ion to form H3Oϩ , water is acting as a Brønsted base. Hydrogen chloride, HCl, and nitric acid, HNO3, are Brønsted acids. The molecules of both compounds contain hydrogen atoms that they can donate as protons to other substances. Both compounds form hydronium ions in water. Methane, CH4, is not a Brønsted acid under ordinary conditions. Although it contains hydrogen, it does not normally release hydrogen ions to other substances. Acetic acid, CH3COOH, releases one hydrogen ion (from the hydrogen atom of the carboxyl group, ¬COOH (2)) to water and any other Brønsted bases present in the solution. Like HCl and HNO3, acetic acid is a monoprotic acid, an acid that can donate only one proton from each molecule. Sulfuric acid, H2SO4, can release both its hydrogen atoms as ions—the first one much more readily than the second—and so it is an example of a polyprotic acid, an acid that can donate more than one proton from each molecule. The acidic hydrogen atom in a compound is the hydrogen atom that can be released as a proton. It is often written as the first element in a molecular formula, as in HCl and HNO3. However, for organic acids, such as acetic acid, it is more informative to write the formulas to show the carboxyl group, ¬COOH, explicitly, thereby making it easier to remember that the H atom in this group of atoms is the acidic one. Thus, we can immediately recognize from their formulas that HCl, H2CO3 (carbonic acid), H2SO4 (sulfuric acid), and C6H5COOH (benzoic acid) are acids in water but that CH4, NH3 (ammonia) and CH3CO2 Ϫ (the acetate ion) are not. The common oxoacids, acids containing oxygen, were introduced in Section D and are listed in Table D.1. Now consider bases, species that accept protons. First, we can see that hydroxide ions are bases, because they accept protons from acids to form molecules of water: OH(aq) + CH3COOH(aq) ¡ H2O(l) + CH3CO2 - (aq) HCl(aq) + H2O(l) ¡ H3O+ (aq) + Cl- (aq) NH3(aq) + H2O(l) ¡ NH4 + (aq) + OH- (aq) Acids and bases are described in more detail in Chapter 11. ϩ 1 Hydronium ion, H3Oϩ 2 Carboxyl group, COOH F74 FUNDAMENTALS Ammonia is a base because, as we see from Eq. 1, it accepts protons from water and forms NH4 ϩ ions. Notice that because water donates a hydrogen ion it is acting as a Brønsted acid in that reaction. A note on good practice: In the Arrhenius system, sodium hydroxide is a base; however, from the Brønsted point of view it simply provides the base OHϪ . Chemists commonly slip into using the Arrhenius definition. Self-Test J.1A Which of the following compounds are Brønsted acids or bases in water? (a) HNO3; (b) C6H6; (c) KOH; (d) C3H5COOH. [Answer: (a) and (d) are acids; (b) is neither an acid nor a base; (c) supplies the base OHϪ ] Self-Test J.1B Which of the following compounds are Brønsted acids or bases in water? (a) KCl; (b) HClO; (c) HF; (d) Ca(OH)2. Acids are molecules or ions that are proton donors. Bases are molecules or ions that are proton acceptors. J.2 Strong and Weak Acids and Bases We saw in Section I.1 that electrolytes are classified as strong or weak according to the extent to which they are present as ions in solution. We classify acids and bases in a similar fashion. In these definitions the term deprotonation means loss of a proton and protonation means the gain of a proton: A strong acid is completely deprotonated in solution. A weak acid is incompletely deprotonated in solution. A strong base is completely protonated in solution. A weak base is incompletely protonated in solution. By “completely deprotonated” we mean that each acid molecule or ion has lost the proton of its acidic hydrogen atom by transferring it as a hydrogen ion to a solvent molecule. “Completely protonated” means that each base molecule or ion has acquired a proton. By “incompletely deprotonated” or “incompletely protonated,” we mean that only a fraction (usually a very tiny fraction) of the acid molecules or ions have lost acidic hydrogen atoms as protons or only a tiny fraction of the base molecules or ions have acquired protons. To understand the distinction between strong and weak acids, we compare two acids. Hydrogen chloride is a strong acid in water. A solution of hydrogen chloride and water, which we call hydrochloric acid, contains hydronium ions, chloride ions, and virtually no HCl molecules. This reaction goes to completion: Acetic acid, on the other hand, is a weak acid in water. Only a small fraction of its molecules undergo deprotonation in this reaction: Therefore, the solute consists principally of CH3COOH molecules (Fig. J.2). In fact, 0.1 M CH3COOH(aq) contains only about one CH3CO2 Ϫ ion for every hundred acetic acid molecules used to make a solution. Table J.1 lists all the common strong acids in water. They include three acids that are often found as reagents in laboratories—hydrochloric acid, nitric acid, and sulfuric acid (with respect to the loss of one proton from each H2SO4 molecule). Most acids are weak in water. All carboxylic acids are weak in water. Now consider strong and weak bases. The common strong bases are oxide ions and hydroxide ions, which are provided by the alkali metal and alkaline earth metal oxides and hydroxides, such as calcium oxide (see Table J.1). As we have seen, chemists CH3COOH(aq) + H2O(l) ¡ H3O+ (aq) + CH3CO2 - (aq) HCl(g) + H2O(l) ¡ H3O+ (aq) + Cl- (aq) The terms ionized and dissociated are commonly used instead of “deprotonated.” CH3COOH CH3CO2 Ϫ H3Oϩ FIGURE J.2 Acetic acid, like all carboxylic acids, is a weak acid in water. This classification means that most of it remains as acetic acid molecules, CH3COOH; however, a small proportion of these molecules donate a hydrogen ion to a water molecule to form hydronium ions, H3Oϩ , and acetate ions, CH3CO2 Ϫ . J.3 NEUTRALIZATION F75 FUNDAMENTALS TABLE J.1 The Strong Acids and Bases in Water Strong acids Strong bases hydrobromic acid, HBr(aq) Group 1 hydroxides hydrochloric acid, HCl(aq) alkaline earth metal hydroxides* hydroiodic acid, HI(aq) Group 1 and Group 2 oxides nitric acid, HNO3 perchloric acid, HClO4 chloric acid, HClO3 sulfuric acid, H2SO4 (to HSO4 Ϫ ) *Ca(OH)2, Sr(OH)2, Ba(OH)2. often refer to these oxides and hydroxides as “strong bases.” When an oxide dissolves in water, the oxide ions, O2Ϫ , accept protons to form hydroxide ions: Hydroxide ions, such as those provided by sodium hydroxide and calcium hydroxide, are also strong bases in water: Even though a hydroxide ion is a strong base and is protonated in water, it effectively survives, because the H2O molecule that donates a proton to OHϪ becomes a hydroxide ion itself and takes its place! All other common bases are weak in water. For example, ammonia is a weak base in water. In its aqueous solutions, it exists almost entirely as NH3 molecules, with just a small proportion—usually fewer than one in a hundred molecules at normal concentrations—of NH4 ϩ cations and OHϪ anions. Other common weak bases are the amines, the pungent compounds that are derived from ammonia by replacement of one or more of its hydrogen atoms by an organic group. For example, the replacement of one hydrogen atom in NH3 by a methyl group, ¬CH3 (3), results in methylamine, CH3NH2 (4). The replacement of all three hydrogen atoms in NH3 by methyl groups results in trimethylamine, (CH3)3N (5), a substance found in decomposing fish and on unwashed dogs. Strong acids (the acids listed in Table J.1) are completely deprotonated in solution; weak acids (most other acids) are not. Strong bases (the metal oxides and hydroxides listed in Table J.1) are completely protonated in solution. Weak bases (ammonia and its organic derivatives, the amines) are only partially protonated in solution. J.3 Neutralization The reaction between an acid and a base is called a neutralization reaction, and the ionic compound produced in the reaction is called a salt. The general form of a neutralization reaction of a strong acid and a metal hydroxide that provides the hydroxide ion, a strong base, in water is The name salt is taken from ordinary table salt, sodium chloride, the ionic product of the reaction between hydrochloric acid and sodium hydroxide: In the neutralization reaction between an acid and a metal hydroxide, the cation of the salt is provided by the metal hydroxide, such as NaOH, and the anion is provided by the acid. Another example is the reaction between nitric acid and barium hydroxide: The barium nitrate remains in solution as Ba2ϩ and NO3 Ϫ ions. 2 HNO3(aq) + Ba(OH)2(aq) ¡ Ba(NO3)2(aq) + 2 H2O(l) HCl(aq) + NaOH(aq) ¡ NaCl(aq) + H2O(l) Acid + metal hydroxide ¡ salt + water H2O(l) + OH(aq) ¡ OH(aq) + H2O(l) O2(aq) + H2O(l) ¡ 2 OH- (aq) 3 Methyl group, CH3 4 Methylamine, CH3NH2 5 Trimethylamine, (CH3)3N F76 FUNDAMENTALS We saw in Section I that the net chemical change in a precipitation reaction is clarified by writing its net ionic equation. The same is true of neutralization reactions. First, we write the complete ionic equation for the neutralization reaction between nitric acid and barium hydroxide in water: The ions common to both sides now cancel, and the net ionic equation of this reaction is therefore which simplifies to The net outcome of any neutralization reaction between a strong acid and a strong base in water is the formation of water from hydrogen ions and hydroxide ions. When we write the net ionic equation for the neutralization of a weak acid or a weak base, we use the molecular form of the weak acid or base, because molecules are the dominant species in solution. For example, we write the net ionic equation for the reaction of the weak acid HCN with the strong base NaOH in water (Fig. J.3) as Similarly, the net ionic equation for the reaction of the weak base ammonia with the strong acid HCl in water is Self-Test J.2A What acid and base solutions could you use to prepare rubidium nitrate? Write the chemical equation for the neutralization. [Answer: HNO3(aq) ϩ RbOH(aq) : RbNO3(aq) ϩ H2O(l)] Self-Test J.2B Write the chemical equation for a neutralization reaction in which calcium phosphate is produced. In a neutralization reaction in water, an acid reacts with a base to produce a salt (and water if the base is strong); the net outcome of the reaction between solutions of a strong acid and a metal hydroxide is the formation of water from hydrogen ions and hydroxide ions. NH3(aq) + H+ (aq) ¡ NH4 + (aq) HCN(aq) + OH(aq) ¡ H2O(l) + CN- (aq) H+ (aq) + OH(aq) ¡ H2O(l) 2 H+ (aq) + 2 OH(aq) ¡ 2 H2O(l) Ba2+ (aq) + 2 NO3 (aq) + 2 H2O(l) 2 H+ (aq) + 2 NO3 (aq) + Ba2+ (aq) + 2 OH(aq) ¡ Ba2+ (aq) + 2 NO3 (aq) + 2 H2O(l) 2 H+ (aq) + 2 NO3 (aq) + Ba2+ (aq) + 2 OH(aq) ¡ H2O HCN OHϪ CNϪ FIGURE J.3 The net ionic equation for the neutralization of HCN, a weak acid, by the strong base, NaOH, tells us that the hydroxide ion extracts a hydrogen ion from an acid molecule. ❑ 1 Describe the chemical properties of acids and bases (Section J.1). ❑ 2 Classify substances as acids or bases (Self-Test J.1). ❑ 3 Identify common strong acids and bases (Table J.1). ❑ 4 Predict the outcome of neutralization reactions and write their chemical equations (Self-Test J.2). SKILLS YOU SHOULD HAVE MASTERED Although hydrogen ions are always attached to water molecules as hydronium ions, H3Oϩ , or more complex species, we write them here as Hϩ for simplicity. The (aq) should be taken to imply that the hydrogen ion is actually present as the hydronium ion. J.1 Identify each compound as either a Brønsted acid or a Brønsted base: (a) NH3; (b) HBr; (c) KOH; (d) H2SO3; (e) Ca(OH)2. J.2 Classify each compound as either a Brønsted acid or a Brønsted base: (a) H2SeO4; (b) CH3CH2NH2, a derivative of ammonia; (c) HCOOH; (d) CsOH; (e) HIO4. J.3 Complete the overall equation, and write the complete ionic equation and the net ionic equation for each of the following acid–base reactions. If the substance is a weak acid or base, leave it in its molecular form in the equations. (a) HF(aq) ϩ NaOH(aq) : (b) (CH3)3N(aq) ϩ HNO3(aq) : (c) LiOH(aq) ϩ HI(aq) : EXERCISES EXERCISES F77 FUNDAMENTALS J.4 Complete the overall equation, and write the complete ionic equation and the net ionic equation for each of the following acid–base reactions. If the substance is a weak acid or base, leave it in its molecular form in the equations. (a) H3PO4(aq) ϩ KOH(aq) : (Phosphoric acid, H3PO4, is a triprotic acid. Write the equation for complete reaction with KOH.) (b) Ba(OH)2(aq) ϩ CH3COOH(aq) : (c) Mg(OH)2(s) ϩ HClO3(aq) : J.5 Select an acid and a base for a neutralization reaction that results in the formation of (a) potassium bromide; (b) zinc nitrite; (c) calcium cyanide, Ca(CN)2; (d) potassium phosphate. Write the balanced equation for each reaction. J.6 Identify the salt that is produced from the acid–base neutralization reaction between (a) potassium hydroxide and acetic acid, CH3COOH; (b) ammonia and phosphoric acid; (c) calcium hydroxide and bromous acid; (d) sodium hydroxide and hydrosulfuric acid, H2S (both H atoms react). Write the complete ionic equation for each reaction. J.7 Identify the acid and the base in each of the following reactions: (a) CH3NH2(aq) ϩ H3Oϩ (aq) : CH3NH3 ϩ (aq) ϩ H2O(l) (b) CH3NH2(aq) ϩ CH3COOH(aq) : CH3NH3 ϩ (aq) ϩ CH3CO2 Ϫ (aq) (c) 2 HI(aq) ϩ CaO(s) : CaI2(aq) ϩ H2O(l) J.8 Identify the acid and the base in each of the following reactions: (a) HBrO3(aq) ϩ NaHCO3(aq) : H2CO3(aq) ϩ NaBrO3(aq) (b) (CH3)3N(aq) ϩ HCl(aq) : (CH3)3NHϩ (aq) ϩ ClϪ (aq) (c) O2Ϫ (aq) ϩ H2O(l) : 2 OHϪ (aq) J.9 You are asked to identify compound X, which was extracted from a plant seized by customs inspectors. You run a number of tests and collect the following data. Compound X is a white, crystalline solid. An aqueous solution of X turns litmus red and conducts electricity poorly, even when X is present at appreciable concentrations. When you add sodium hydroxide to the solution a reaction takes place. A solution of the products of the reaction conducts electricity well. An elemental analysis of X shows that the mass percentage composition of the compound is 26.68% C and 2.239% H, with the remainder being oxygen. A mass spectrum of X yields a molar mass of 90.0 gиmolϪ1 . (a) Write the empirical formula of X. (b) Write the molecular formula of X. (c) Write the balanced chemical equation and the net ionic equation for the reaction of X with sodium hydroxide. (Assume that X has two acidic hydrogen atoms.) J.10 (a) White phosphorus, which has the formula P4, burns in air to form compound A, in which the mass percentage of phosphorus is 43.64%, with the remainder oxygen. The mass spectrum of A yields a molar mass of 283.9 gиmolϪ1 . Write the molecular formula of compound A. (b) Compound A reacts with water to form compound B, which turns litmus red and has a mass percentage composition of 3.087% H and 31.60% P, with the remainder oxygen. The mass spectrum of compound B yields a molar mass of 97.99 gиmolϪ1 . Write the molecular formula of compound B. (c) Compound B reacts with an aqueous solution of calcium hydroxide to form compound C, a white precipitate. Write balanced chemical equations for the reactions in parts (a), (b), and (c). J.11 In each of the following salts, either the cation or the anion is a weak acid or a weak base. Write the chemical equation for the proton transfer reaction of this cation or anion with water: (a) NaC6H5O; (b) KClO; (c) C5H5NHCl; (d) NH4Br. J.12 C6H5NH3Cl is a chloride salt with an acidic cation. (a) If 50.0 g of C6H5NH3Cl is dissolved in water to make 150.0 mL of solution, what is the initial molarity of the cation? (b) Write the chemical equation for the proton transfer reaction of the cation with water. Identify the acid and the base in this reaction. J.13 The anion in Na3AsO4 is a weak base that can accept more than one proton. (a) Write the chemical equations for the sequential proton transfer reactions of the anion with water. Identify the acid and the base in each reaction. (b) If 35.0 g of Na3AsO4 is dissolved in water to make 250.0 mL of solution, how many moles of sodium cations are in the solution? J.14 The anion in potassium sulfite, K2SO3, is a weak base that can accept more than one proton. (a) Write the chemical equations for the sequential proton transfer reactions of the anion with water. Identify the acid and the base in each reaction. (b) If 0.054 g of K2SO3 is dissolved in water to make 200.0 mL of solution, what amount (in moles) of potassium cations are in the solution? J.15 The oxides of nonmetallic elements are called acidic oxides because they form acidic solutions in water. Write the balanced chemical equations for the reaction of one mole of each acidic oxide with one mole of water molecules to form an oxoacid and name the acid formed: (a) CO2; (b) SO3. J.16 The oxides of metallic elements are called basic oxides because they form basic solutions in water. Write the balanced chemical equations for the reaction of 1 mol of each basic oxide with 1 mol of water molecules to form a metal hydroxide: (a) BaO; (b) Li2O. K REDOX REACTIONS Redox reactions constitute the third of the three major classes of chemical reactions treated here. The variety of these reactions is remarkable. Many common reactions, such as combustion, corrosion, photosynthesis, the metabolism of food, and the extraction of metals from their ores, appear to be completely different. However, when we consider these changes at the molecular level with a chemist’s eye, we can see that they are all examples of a single type of process. K.1 Oxidation and Reduction K.2 Oxidation Numbers: Keeping Track of Electrons K.3 Oxidizing and Reducing Agents K.4 Balancing Simple Redox Equations F78 FUNDAMENTALS K.1 Oxidation and Reduction Let’s examine some of these redox reactions and look for their common characteristic. First, consider the reaction between magnesium and oxygen, which produces magnesium oxide (Fig. K.1); this reaction is used in fireworks to produce white sparks. It is also used, less agreeably, in tracer ammunition and incendiary devices. The reaction of magnesium and oxygen is a classic example of an oxidation reaction, in the original sense of the term, “reaction with oxygen.” In the course of the reaction, the Mg atoms in the solid magnesium lose electrons to form Mg2ϩ ions, and the O atoms in the molecular oxygen gain electrons to form O2– ions: 2 Mg(s) ϩ O2(g) 2 Mg2ϩ (s) ϩ 2 O2Ϫ (s), as 2 MgO(s) A similar reaction takes place when magnesium reacts with chlorine to produce magnesium chloride: Mg(s) ϩ Cl2(g) Mg2ϩ (s) ϩ 2 ClϪ (s), as MgCl2(s) Because the pattern of reaction is the same, the second reaction is also regarded as an “oxidation” of magnesium even though no oxygen takes part. In each case, the common feature is the loss of electrons from magnesium and their transfer to another reactant. The loss of electrons from one species to another is now recognized as the essential event in an oxidation, and chemists now define oxidation as the loss of electrons, regardless of the species to which the electrons migrate. We can often recognize loss of electrons by noting the increase in the charge of a species. This rule also applies to anions, as in the oxidation of bromide ions (charge –1) to bromine (charge 0) in a reaction such as the one used commercially to make bromine (Fig. K.2): 2 NaBr(s) ϩ Cl2(g) 2 NaCl(s) ϩ Br2(l) Here, the bromide ion (as sodium bromide) is oxidized to bromine by the chlorine gas. The name reduction originally referred to the extraction of a metal from its oxide, often by reaction with hydrogen, carbon, or carbon monoxide. One example is the reduction of iron(III) oxide by carbon monoxide in the manufacture of steel: Fe2O3(s) ϩ 3 CO(g) 2 Fe(l) ϩ 3 CO2(g) In this reaction, an oxide of an element is converted into the free element, the reverse of oxidation. In the reduction of iron(III) oxide, Fe3ϩ ions present in Fe2O3 are converted into uncharged Fe atoms when they gain electrons to neutralize their positive charges. That turns out to be the pattern common to all reductions: in a reduction, an atom gains electrons from another species. Whenever the charge on a species is decreased (as from Fe3ϩ to Fe), we say that reduction has taken place. The same rule applies if the charge is negative. For example, when chlorine is converted into chloride ions in the reaction 2 NaBr(s) ϩ Cl2(g) 2 NaCl(s) ϩ Br2(l) the charge decreases from 0 (in Cl2) to Ϫ1 (in ClϪ ), and we conclude that in this reaction chlorine has been reduced. Self-Test K.1A Identify the species that have been oxidized or reduced in the reaction 3 Agϩ (aq) ϩ Al(s) : 3 Ag(s) ϩ Al3ϩ (aq). [Answer: Al(s) is oxidized, Agϩ (aq) is reduced] Self-Test K.1B Identify the species that have been oxidized or reduced in the reaction 2 Cuϩ (aq) ϩ I2(s) : 2 Cu2ϩ (aq) ϩ 2 IϪ (aq). We have seen that oxidation is electron loss and reduction is electron gain. Electrons are real particles and cannot just be “lost.” Therefore, whenever a species is oxidized, another species must be reduced. Oxidation or reduction taken separately is like one ¡ ¡ ¡ ¡ ¡ FIGURE K.2 When chlorine is bubbled through a solution of bromide ions, it oxidizes the ions to bromine, which colors the solution reddish brown. FIGURE K.1 An example of an oxidation reaction: magnesium burning brightly in air. Magnesium is so easily oxidized that it also burns brightly in water and carbon dioxide; consequently, magnesium fires are very difficult to extinguish. Lab Video K.1 FUNDAMENTALS K.2 OXIDATION NUMBERS: KEEPING TRACK OF ELECTRONS F79 hand clapping: one transfer must occur in conjunction with the other for reaction to take place. For instance, in the reaction between chlorine and sodium bromide, the bromide ions are oxidized and the chlorine molecules are reduced. Because oxidation is always accompanied by reduction, chemists speak of redox reactions, oxidation–reduction reactions, rather than simply oxidation reactions or reduction reactions. Oxidation is electron loss; reduction is electron gain. Oxidation and reduction occur together in redox reactions. K.2 Oxidation Numbers: Keeping Track of Electrons We recognize redox reactions by noting whether electrons have migrated from one species to another. The loss or gain of electrons is easy to identify for monatomic ions, because we can monitor the charges of the species. Thus, when BrϪ ions are converted into bromine atoms (which go on to form Br2 molecules), we know that each Br– ion must have lost an electron and hence that it has been oxidized. When O2 forms oxide ions, O2Ϫ , we know that each oxygen atom must have gained two electrons and therefore that it has been reduced. The difficulty arises when the transfer of electrons is accompanied by the transfer of atoms. For example, is chlorine gas, Cl2, oxidized or reduced when it is converted into hypochlorite ions, ClOϪ ? Chemists have found a way to keep track of electrons by assigning an “oxidation number” to each element. The oxidation number, Nox, is defined so that Oxidation corresponds to an increase in oxidation number. Reduction corresponds to a decrease in oxidation number. A redox reaction, therefore, is any reaction in which there are changes in oxidation numbers. The oxidation number of the element as a monatomic ion is the same as its charge. For example, the oxidation number of magnesium is ϩ2 when it is present as Mg2ϩ ions, and the oxidation number of chlorine is Ϫ1 when it is present as ClϪ ions. The oxidation number of the elemental form of an element is 0; so magnesium metal has oxidation number 0 and chlorine in the form of Cl2 molecules also has oxidation number 0. When magnesium combines with chlorine, the oxidation numbers change as follows: 0 2(0) ϩ2 2(Ϫ1) Mg(s) ϩ Cl2(g) MgCl2(s) We see that magnesium has been oxidized and chlorine has been reduced. Similarly, in the reaction between sodium bromide and chlorine, 2(ϩ1 Ϫ1) 2(0) 2(ϩ1 Ϫ1) 2(0) 2 NaBr(s) ϩ Cl2(g) 2 NaCl(s) ϩ Br2(l) In this reaction, bromine has been oxidized and chlorine has been reduced, but the sodium ions remain unchanged as Naϩ . When an element is part of a compound or a polyatomic ion, we assign its oxidation number by using the procedure in Toolbox K.1. A note on good practice: You will hear chemists speaking of both “oxidation number” and “oxidation state.” An oxidation number is the number assigned according to the rules in Toolbox K.1. An oxidation state is the actual condition of a species with a specified oxidation number. Thus, an element has a certain oxidation number and is in the corresponding oxidation state. For example, Mg2ϩ is the ϩ2 oxidation state of magnesium; and, in that state, magnesium has oxidation number ϩ2. ¡ ¡ The concept of oxidation number was first introduced in Section D. TOOLBOX K.1 HOW TO ASSIGN OXIDATION NUMBERS CONCEPTUAL BASIS To assign an oxidation number, we imagine that each atom in a molecule, formula unit, or polyatomic ion is present in ionic form (which it might not be). The oxidation number is then taken to be the charge on each “ion.” The “anion” is usually oxygen as O2Ϫ or the element farthest to the right in the periodic table (actually, the most electronegative element; see Section 2.12). We then assign to the other atoms charges that balance the charge on the “anions.” PROCEDURE To assign an oxidation number Nox(E) to an element E, we start with two simple rules: 1 The oxidation number of an element uncombined with other elements is 0. 2 The sum of the oxidation numbers of all the atoms in a species is equal to its total charge. The oxidation numbers of elements in most of the compounds in this text are assigned by using these two rules along with the following specific values: • The oxidation number of hydrogen is ϩ1 in combination with nonmetals and Ϫ1 in combination with metals. • The oxidation number of elements in Groups 1 and 2 is equal to their group number. • The oxidation number of all the halogens is Ϫ1 unless the halogen is in combination with oxygen or another halogen higher in the group. The oxidation number of fluorine is Ϫ1 in all its compounds. • The oxidation number of oxygen is Ϫ2 in most of its compounds. Exceptions are its compounds with fluorine (in which case, the previous statement takes precedence) and its occurrence as peroxides (O2 2Ϫ ), superoxides (O2 Ϫ ), and ozonides (O3 Ϫ ). This procedure is illustrated in Example K.1. EXAMPLE K.1 Assigning oxidation numbers Is the conversion of SO2 to SO4 2Ϫ oxidation or reduction? Anticipate Even though the product has acquired a negative charge, suggesting reduction, it has also acquired two more O atoms, so we can anticipate that overall the conversion is an oxidation. PLAN The process is oxidation if the oxidation number of sulfur increases, reduction if it decreases. We need to assign the oxidation numbers of sulfur in SO2 and SO4 2Ϫ , then compare them. In each case, we represent the oxidation number of sulfur by Nox(S) and solve for Nox(S) after using the rules in Toolbox K.1. The oxidation number of oxygen is Ϫ2 in both compounds. SOLVE SO2: By rule 2, the sum of oxidation numbers of the atoms in the compound must be 0: Ϫ2 ϩ4 Ϫ2 F80 FUNDAMENTALS Nox(S) ϩ 2Nox(O) ϭ 0 Nox(S) ϩ [2 ϫ (Ϫ2)] ϭ 0 S 2 O zero charge on neutral molecule Therefore, the oxidation number of sulfur in SO2 is ϩ4. SO4 2Ϫ : By rule 2, the sum of oxidation numbers of the atoms in the ion is Ϫ2; so ϩ6 Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2 Nox(S) ϩ 4Nox(O)ϭ Ϫ2 Nox(S) ϩ [4 ϫ (Ϫ2)] ϭ Ϫ2 S 4 O total charge on ion FUNDAMENTALS K.3 OXIDIZING AND REDUCING AGENTS F81 Therefore, the oxidation number of sulfur in SO4 2Ϫ is ϩ6. Evaluate We conclude that sulfur is more highly oxidized in the sulfate ion than in sulfur dioxide. Therefore, as we suspected, the conversion of SO2 to SO4 2Ϫ is an oxidation. Self-Test K.2A Find the oxidation numbers of sulfur, phosphorus, and chlorine in (a) H2S; (b) P4O6; (c) ClOϪ . [Answer: (a) Ϫ2; (b) ϩ3; (c) ϩ1] Self-Test K.2B Find the oxidation numbers of sulfur, nitrogen, and chlorine in (a) SO3 2Ϫ ; (b) NO2 Ϫ ; (c) HClO3. Oxidation increases the oxidation number of an element; reduction decreases the oxidation number. Oxidation numbers are assigned by using the rules in Toolbox K.1. K.3 Oxidizing and Reducing Agents The species that causes oxidation is called the oxidizing agent (or “oxidant”). When an oxidizing agent acts, it accepts the electrons released by the species being oxidized. In other words, the oxidizing agent contains an element that undergoes a decrease in oxidation number (Fig. K.3). That is, • The oxidizing agent in a redox reaction is the species that causes oxidation and in the process gets reduced. For instance, oxygen removes electrons from magnesium. Because oxygen accepts those electrons, its oxidation number decreases from 0 to –2 (a reduction). Oxygen is therefore the oxidizing agent in this reaction. Oxidizing agents can be elements, ions, or compounds. The species that brings about reduction is called the reducing agent (or “reductant”). Because the reducing agent supplies electrons to the species being reduced, the reducing agent loses electrons. That is, the reducing agent contains an element that undergoes an increase in oxidation number (Fig. K.4). In other words, • The reducing agent in a redox reaction is the species that causes reduction and in the process gets oxidized. For example, when magnesium metal supplies electrons to oxygen (reducing the oxygen atoms), the magnesium atoms lose electrons and the oxidation number of magnesium increases from 0 to ϩ2 (an oxidation). It is the reducing agent in the reaction of magnesium and oxygen. To identify the oxidizing and reducing agents in a redox reaction, we compare the oxidation numbers of the elements before and after the reaction to see which have changed. The reactant that contains an element that is reduced in the reaction is the oxidizing agent, and the reactant that contains an element that is oxidized is the reducing agent. For example, when a piece of zinc metal is placed in a copper(II) solution (Fig. K.5), the reaction is 0 ϩ2 ϩ2 0 Zn(s) ϩ Cu2ϩ (aq) Zn2ϩ (aq) ϩ Cu(s) The oxidation number of zinc changes from 0 to ϩ2 (an oxidation), whereas that of copper decreases from ϩ2 to 0 (a reduction). Therefore, because zinc is oxidized, zinc metal is the reducing agent in this reaction. Conversely, because copper is reduced, copper(II) ions are the oxidizing agent. ¡ eϪ Oxidation number Oxidizing agent Oxidized species FIGURE K.3 The oxidizing agent (bottom) is the species containing the element that undergoes a decrease in oxidation number. Here we see how the oxidation number of the species on the top is driven upward as the oxidizing agent gains electrons. eϪ Oxidation number Reducing agent Reduced species FIGURE K.4 The reducing agent (bottom) is the species containing the element that undergoes an increase in oxidation number. Here we see how the oxidation number of the species on the top is driven downward as it gains the electrons lost by the reducing agent. EXAMPLE K.2 Identifying oxidizing agents and reducing agents Identify the oxidizing agent and the reducing agent in the following reaction: Cr2O7 2Ϫ (aq) ϩ 6 Fe2ϩ (aq) ϩ 14 Hϩ (aq) 6 Fe3ϩ (aq) ϩ 2 Cr3ϩ (aq) ϩ 7 H2O(l)¡ FIGURE K.5 When a strip of zinc is placed in a solution that contains Cu2ϩ ions, the blue solution slowly becomes colorless and copper metal is deposited on the zinc. The inset shows that, in this redox reaction, the zinc metal is reducing the Cu2ϩ ions to copper metal and the Cu2ϩ ions are oxidizing the zinc metal to Zn2ϩ ions. Zn2ϩ Cu2ϩ Deposited copper Copper(II) sulfate solution Zinc strip Anticipate Because the charge on the iron cation has increased, it is being oxidized and we should expect it to be the reducing agent. Another clue is that a species with many O atoms can be suspected to act as an oxidizing agent, so we should expect the dichromate ion (Cr2O7 2Ϫ ) to be the oxidizing agent. PLAN First, determine the oxidation numbers of the elements taking part in the reaction. The oxidizing agent is the species that contains an element that is reduced. Similarly, the reducing agent is the species that contains an element that is oxidized. SOLVE The oxidation numbers of H and O have not changed, and so we concentrate on Cr and Fe. Determine the oxidation numbers of chromium. As a reactant (in Cr2O7 2Ϫ ): let the oxidation number of Cr be Nox(Cr), then 2Nox(Cr) ϩ [7 ϫ (–2)] ϭ Ϫ2, or 2Nox(Cr) Ϫ 14 ϭ Ϫ2 Cr2O7 2Ϫ Cr2O7 2Ϫ Cr2O7 2Ϫ The oxidation number of Cr in Cr2O7 2Ϫ is ϩ6. As a product (as Cr3ϩ ): the oxidation number is ϩ3. ϩ6 ϩ6 Ϫ2 Ϫ2Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2Ϫ2 ϩ6 ϩ3 Ϫ2 3ϩ Cr Cr F82 FUNDAMENTALS Decide whether Cr is oxidized or reduced. ϩ6 ϩ3 Because Cr2O7 2Ϫ : 2 Cr3ϩ , the oxidation number of Cr decreases from ϩ6 to ϩ3, so Cr is reduced and the dichromate ion is the oxidizing agent. ϩ3 ϩ2 Fe Fe Determine the oxidation numbers of iron. In Fe2ϩ (reactant): the oxidation number is ϩ2. In Fe3ϩ (product): the oxidation number is ϩ3. Decide whether Fe is oxidized or reduced. The oxidation number of Fe increases from ϩ2 to ϩ3, so Fe is oxidized. Therefore, the Fe2ϩ ion is the reducing agent. Evaluate As we anticipated, the dichromate ion is the oxidizing agent and Fe2ϩ is the reducing agent. The dichromate ion in acidic solution is a common laboratory oxidizing agent. FUNDAMENTALS K.4 BALANCING SIMPLE REDOX EQUATIONS F83 Self-Test K.3A In the Claus process for the recovery of sulfur from natural gas and petroleum, hydrogen sulfide reacts with sulfur dioxide to form elemental sulfur and water: 2 H2S(g) ϩ SO2(g) : 3 S(s) ϩ 2 H2O(l). Identify the oxidizing agent and the reducing agent. [Answer: SO2 is the oxidizing agent, H2S is the reducing agent] Self-Test K.3B When sulfuric acid reacts with sodium iodide, sodium iodate and sulfur dioxide are produced. Identify the oxidizing and reducing agents in this reaction. Oxidation is brought about by an oxidizing agent, a species that contains an element that undergoes reduction. Reduction is brought about by a reducing agent, a species that contains an element that undergoes oxidation. K.4 Balancing Simple Redox Equations Because electrons can be neither lost nor created in a chemical reaction, all the electrons lost by the species being oxidized must be transferred to the species being reduced. Because electrons are charged, the total charge of the reactants must be the same as the total charge of the products. Therefore, when balancing the chemical equation for a redox reaction, we have to balance the charges as well as the atoms. For example, consider the net ionic equation for the oxidation of copper metal to copper(II) ions by silver ions (Fig. K.6): Cu(s) ϩ Agϩ (aq) Cu2ϩ (aq) ϩ Ag(s) ƽ At first glance, the equation appears to be balanced, because it has the same number of each kind of atom on each side. However, the total charge of the products is different from that of the reactants. Each copper atom has lost two electrons, whereas each silver atom has gained only one. To balance the electrons, we have to balance the charge. Therefore, we need to write Cu(s) ϩ 2 Agϩ (aq) Cu2ϩ (aq) ϩ 2 Ag(s) Self-Test K.4A When tin metal is placed in contact with a solution of Fe3ϩ ions, it reduces the iron to iron(II) and is itself oxidized to tin(II) ions. Write the net ionic equation for the reaction. [Answer: Sn(s) ϩ 2 Fe3ϩ (aq) : Sn2ϩ (aq) ϩ 2 Fe2ϩ (aq)] Self-Test K.4B In aqueous solution, cerium(IV) ions oxidize iodide ions to solid diatomic iodine and are themselves reduced to cerium(III) ions. Write the net ionic equation for the reaction. Some redox reactions, particularly those involving oxoanions, have complex chemical equations that require special balancing procedures. We meet examples and see how to balance them in Chapter 13. When balancing the chemical equation for a redox reaction involving ions, the total charge on each side must be balanced. ¡ ¡ (a) (b) FIGURE K.6 (a) A silver nitrate solution is colorless. (b) Some time after the insertion of a copper wire, the solution shows the blue color of the copper(II) ion and the formation of crystals of silver metal on the surface of the wire. Animation K.6 ❑ 1 Determine the oxidation number of an element (Toolbox K.1 and Example K.1). ❑ 2 Identify the oxidizing and reducing agents in a reaction (Example K.2). ❑ 3 Write and balance chemical equations for simple redox reactions (Self-Test K.4). EXERCISES K.1 Write a balanced equation for each of the following skeletal redox reactions: (a) NO2(g) ϩ O3(g) : N2O5(g) ϩ O2(g) (b) S8(s) ϩ Na(s) : Na2S(s) (c) Cr2ϩ (aq) ϩ Sn4ϩ (aq) : Cr3ϩ (aq) ϩ Sn2ϩ (aq) (d) As(s) ϩ Cl2(g) : AsCl3(l) K.2 Write a balanced equation for each of the following skeletal redox equations: (a) Hg2ϩ (aq) ϩ Fe(s) : Hg2 2ϩ (aq) ϩ Fe3ϩ (aq) (b) Pt4ϩ (aq) ϩ H2(g) : Pt2ϩ (aq) ϩ Hϩ (aq) (c) Al(s) ϩ Fe2O3(s) : Fe(s) ϩ Al2O3(s) (d) La(s) ϩ Br2(l) : LaBr3(s) K.3 Write a balanced equation for each of the following redox reactions: (a) Displacement of copper(II) ion from solution by magnesium metal: Mg(s) ϩ Cu2ϩ (aq) : Mg2ϩ (aq) ϩ Cu(s) (b) Formation of iron(III) ion in the following reaction: Fe2ϩ (aq) ϩ Ce4ϩ (aq) : Fe3ϩ (aq) ϩ Ce3ϩ (aq) (c) Synthesis of hydrogen chloride from its elements: H2(g) ϩ Cl2(g) : HCl(g) (d) Formation of rust (a simplified equation): Fe(s) ϩ O2(g) : Fe2O3(s) K.4 Determine the oxidation number of the italicized element in each of the following compounds: (a) SOCl2; (b) SeO3; (c) N2O5; (d) NO2; (e) HBrO2; (f) XeF2. K.5 Determine the oxidation number of the italicized element in each of the following compounds: (a) H4SiO4; (b) SnO2; (c) N2H4; (d) P4O10; (e) S2Cl2; (f) P4. K.6 Determine the oxidation number of the italicized element in each of the following ions: (a) AsO4 3Ϫ ; (b) N2O2 2Ϫ ; (c) S2O4 2Ϫ ; (d) TiF6 2Ϫ ; (e) IF6 ϩ . K.7 Determine the oxidation number of the italicized element in each of the following ions: (a) Zn(OH)4 2Ϫ ; (b) PdCl4 2Ϫ ; (c) UO2 2ϩ ; (d) SiF6 2Ϫ ; (e) IOϪ . K.8 Some compounds of hydrogen and oxygen are exceptions to the common observation that H has oxidation number ϩ1 and O has oxidation number Ϫ2. Assuming that each metal has the oxidation number of its most common ion, find the oxidation numbers of H and O in each of the following compounds: (a) KO2; (b) LiAlH4; (c) Na2O2; (d) NaH; (e) KO3. K.9 For each of the following redox reactions, identify the substance oxidized and the substance reduced by the change in oxidation numbers. (a) CH3OH(aq) ϩ O2(g) : HCOOH(aq) ϩ H2O(l) (b) 2 MoCl5(s) ϩ 5 Na2S(s) : 2 MoS2(s) ϩ 10 NaCl(s) ϩ S(s) (c) 3 Tlϩ (aq) : 2 Tl(s) ϩ Tl3ϩ (aq) K.10 In each of the following reactions, use oxidation numbers to identify the substance oxidized and the substance reduced. (a) Production of iodine from seawater: Cl2(g) ϩ 2 IϪ (aq) : I2(aq) ϩ 2 ClϪ (aq) (b) Reaction to prepare bleach: Cl2(g) ϩ 2 NaOH(aq) : NaCl(aq) ϩ NaOCl(aq) ϩ H2O(l) (c) Reaction that destroys ozone in the stratosphere: NO(g) ϩ O3(g) : NO2(g) ϩ O2(g) K.11 Which do you expect to be the stronger oxidizing agent? Explain your reasoning. (a) Cl2 or ClϪ ; (b) N2O5 or N2O. K.12 Which do you expect to be the stronger oxidizing agent? Explain your reasoning. (a) NaClO2 or NaClO; (b) Cr2O7 2Ϫ or Cr3ϩ . K.13 Identify the oxidizing agent and the reducing agent in each of the following reactions: (a) Zn(s) ϩ 2 HCl(aq) : ZnCl2(aq) ϩ H2(g), a simple means of preparing H2 gas in the laboratory (b) 2 H2S(g) ϩ SO2(g) : 3 S(s) ϩ 2 H2O(l), a reaction used to produce sulfur from hydrogen sulfide, the “sour gas” in natural gas (c) B2O3(s) ϩ 3 Mg(s) : 2 B(s) ϩ 3 MgO(s), a preparation of elemental boron K.14 Identify the oxidizing agent and the reducing agent in each of the following reactions: (a) 2 Al(l) ϩ Cr2O3(s) Al2O3(s) ϩ 2 Cr(l), an example of a thermite reaction used to obtain some metals from their ores (b) 6 Li(s) ϩ N2(g) : 2 Li3N(s), a reaction that shows the similarity of lithium and magnesium (c) 2 Ca3(PO4)2(s) ϩ 6 SiO2(s) ϩ 10 C(s) : P4(g) ϩ 6 CaSiO3(s) ϩ 10 CO(g), a reaction for the preparation of elemental phosphorus. K.15 For each of the following incomplete reactions, would you choose an oxidizing agent or a reducing agent to make the conversion? (a) ClO4 Ϫ (aq) : ClO2(g) (b) SO4 2Ϫ (aq) : SO2(g) K.16 For each of the following incomplete reactions, would you choose an oxidizing agent or a reducing agent to make the conversion? (a) H3PO3(aq) : P4O10(s) (b) CH3CH2OH (ethanol) : CH3CH2COOH (acetic acid) K.17 The Sabatier process has been used to remove CO2 from artificial atmospheres, such as those in submarines and spacecraft. An advantage is that it produces methane, CH4, which can be burned as a fuel, and water, which can be reused. Balance the equation for the process and identify the type of reaction: CO2(g) ϩ H2(g) : CH4(g) ϩ H2O(l). K.18 The industrial production of sodium metal and chlorine gas makes use of the Downs process, in which molten sodium chloride is electrolyzed (Chapter 13). Write a balanced equation for the production of the two elements from molten sodium chloride. Which element is produced by oxidation and which by reduction? K.19 Identify the oxidizing agent and the reducing agent for each of the following reactions: ¡ ¢ SKILLS YOU SHOULD HAVE MASTERED F84 FUNDAMENTALS FUNDAMENTALS EXERCISES F85 (a) Production of tungsten metal from its oxide: WO3(s) ϩ 3 H2(g) : W(s) ϩ 3 H2O(l) (b) Generation of hydrogen gas in the laboratory: Mg(s) ϩ 2 HCl(aq) : H2(g) ϩ MgCl2(aq) (c) Production of metallic tin from tin(IV) oxide: SnO2(s) ϩ 2 C(s) Sn(l) ϩ 2 CO(g) (d) A reaction used to propel rockets: 2 N2H4(g) ϩ N2O4(g) : 3 N2(g) ϩ 4 H2O(g) K.20 Classify each of the following reactions as precipitation, acid–base neutralization, or redox. If a precipitation reaction, write a net ionic equation; if a neutralization reaction, identify the acid and the base; if a redox reaction, identify the oxidizing agent and the reducing agent. (a) Reaction used to measure the concentration of carbon monoxide in a gas stream: 5 CO(g) ϩ I2O5(s) : I2(s) ϩ 5 CO2(g) (b) Test for the amount of iodine in a sample: I2(aq) ϩ 2 S2O3 2– (aq) : 2 IϪ (aq) ϩ S4O6 2Ϫ (aq) (c) Test for bromide ions in solution: AgNO3(aq) ϩ BrϪ (aq) : AgBr(s) ϩ NO3 Ϫ (aq) (d) Heating of uranium tetrafluoride with magnesium, one stage in the purification of uranium metal: UF4(g) ϩ 2 Mg(s) U(s) ϩ 2 MgF2(s) K.21 Nitrogen in the air of spaceships is gradually lost through leakage and must be replaced. One method is to store the nitrogen in the form of hydrazine, N2H4(l), from which nitrogen is readily obtained by heating. The ammonia also produced can be processed further to obtain even more nitrogen: N2H4(l) : NH3(g) ϩ N2(g). (a) Balance the equation. (b) Give the oxidation number of nitrogen in each compound. (c) Identify the oxidizing and reducing agent. (d) Given that 28 g of nitrogen gas occupies 24 L at room temperature and pressure, what volume of nitrogen gas can be obtained from 1.0 L of hydrazine? (The density of hydrazine is 1.004 gиcmϪ3 at room temperature.) K.22 (a) Determine and tabulate the maximum (most positive) and minimum (most negative) oxidation numbers of the elements in the first seven main groups. Hint: Maximum oxidation numbers are often found in the oxoanion with the most oxygen atoms. For minimum oxidation numbers, consult Fig. C.7. (b) Describe any patterns you see in the data. K.23 A mixture of 5.00 g of Cr(NO3)2 and 6.00 g of CuSO4 is dissolved in sufficient water to make 250.0 mL of solution, where the cations react. In the reaction, copper metal is formed and each chromium ion loses one electron. (a) Write the net ionic equation. (b) What is the number of electrons transferred in the balanced equation written with the smallest whole-number coefficients? (c) What are the molar concentrations of the two anions in the final solution? K.24 Silver tarnish is Ag2S. (a) When silver metal is tarnished, is it oxidized or reduced? Answer this question by considering the oxidation numbers. (b) If a bar of silver is covered with 5.0 g of tarnish, what amount (in moles) of silver atoms was either oxidized or reduced? (c) What amount (in moles) of electrons was transferred in part (b)? K.25 The following redox reactions are important in the refining of certain elements. Balance the equations and in each case, write the name of the source compound of the element (in bold face) and the oxidation state in that compound of the element that is being extracted: (a) SiCl4(l) ϩ H2(g) : Si(s) ϩ HCl(g) (b) SnO2(s) ϩ C(s) Sn(l) ϩ CO2 (c) V2O5(s) ϩ Ca(l) V(s) ϩ CaO(s) (d) B2O3(s) ϩ Mg(s) : B(s) ϩ MgO(s) K.26 Balance the following equations and identify the oxidizing and reducing agents in each: (a) CO(g) ϩ H2O(g) : CO2(g) ϩ H2(g) (b) ClO2(g) ϩ O3(g) : Cl2O6(l) ϩ O2(g) (c) Cl2(g) ϩ F2(g) : ClF3(g) K.27 Balance the following equations and identify the oxidizing and reducing agents in each: (a) Cl2(g) ϩ H2O(l) : HClO(aq) ϩ HCl(aq) (b) NaClO3(aq) ϩ SO2(g) ϩ H2SO4(aq, dilute) : NaHSO4(aq) ϩ ClO2(g) (c) CuI(aq) : Cu(s) ϩ I2(s) ¡ ¢ ¬¡ 1200°C ¡ ¢ ¡ ¢ L REACTION STOICHIOMETRY Chemistry is a part of the physical sciences, which means that it uses quantitative procedures as well as qualitative concepts. One of the most basic quantitative procedures in chemistry is the prediction of the masses of substances and volumes of solutions that are involved in chemical reactions. We develop these procedures here and will encounter them again throughout the text. Sometimes we need to know how much product to expect from a reaction, or how much reactant we need to make a desired amount of product. To do this kind of calculation, we need the quantitative aspect of chemical reactions called reaction stoichiometry. The key to reaction stoichiometry is the balanced chemical equation. Recall from Section H that a stoichiometric coefficient in a chemical equation tells us the relative amount (number of moles) of a substance that reacts or is produced. Thus, the stoichiometric coefficients in N2(g) ϩ 3 H2(g) 2 NH3(g) tell us that, if 1 mol N2 reacts, then 3 mol H2 will be consumed and 2 mol NH3 will be produced. We summarize this information by writing 1 mol N2 3 mol H2 1 mol N2 2 mol NH3ϴϴ ¡ L.1 Mole-to-Mole Predictions L.2 Mass-to-Mass Predictions L.3 Volumetric Analysis Stoichiometric coefficients are exact numbers; therefore, they do not limit the significant figures of stoichiometric calculations (see Appendix 1C). FIGURE L.1 A technician studies a lightweight, efficient hydrogen–oxygen fuel cell of the type used in the space shuttle. The three fuel cells on the space shuttle provide life-support electricity and drinking water. Because they have no moving parts they have a long working life. 1 Moles of A Moles of B Reaction stoichiometry Mole ratio F86 FUNDAMENTALS The sign is read “is chemically equivalent to,” and these expressions are called stoichiometric relations. The term chemically equivalent refers to a specific chemical reaction, and in general different reactions give rise to different stoichiometric relations. L.1 Mole-to-Mole Predictions Stoichiometry has important practical applications, such as predicting how much product can be formed in a reaction. For example, in the space shuttle fuel cell, oxygen reacts with hydrogen to produce water, which is used for life support (Fig. L.1). Let’s look at the calculation space shuttle engineers would have to do to find out how much water is formed when 0.25 mol O2 reacts with hydrogen gas. First, we write the chemical equation for the reaction: 2 H2(g) ϩ O2(g) 2 H2O(l) Then we summarize the information that 1 mol O2 reacts to form 2 mol H2O by writing the stoichiometric relation between oxygen (the given substance) and water (the required substance): 1 mol O2 2 mol H2O Next, we use the stoichiometric relation to set up a conversion factor relating the given substance to the required substance: This ratio, which is commonly called the mole ratio for the reaction, allows us to relate the amount of O2 molecules consumed to the amount of H2O molecules produced. We use it in the same way that we use a conversion factor when we are converting units, as illustrated in Section A: Note that the unit mol and the species (in this case, O2 molecules) cancel. The general strategy for this type of calculation is summarized in diagram (1). Self-Test L.1A What amount of NH3 can be produced from 2.0 mol H2 in the reaction N2(g) ϩ 3 H2(g) 2 NH3(g)? [Answer: 1.3 mol NH3] Self-Test L.1B What amount of Fe atoms can be extracted from 25 mol Fe2O3? The balanced chemical equation for a reaction is used to set up the mole ratio, a factor that is used to convert the amount of one substance into the amount of another. L.2 Mass-to-Mass Predictions To find out the mass of a product that can be formed from a known mass of a reactant, we first convert the grams of reactant into moles, use the mole ratio from the balanced equation, and then convert the moles of product formed into grams. Essentially, we go through three steps: ¡ = 0.50 mol H2O Amount of H2O produced (mol) = (0.25 mol O2) * 2 mol H2O 1 mol O2 Substance required Substance given = 2 mol H2O 1 mol O2 ϴ ¡ ϴ Mass (g) of reactant Mass (g) of product Molar mass Molar mass of the reactant of the product Amount (mol) of reactant Amount (mol) of product Mole ratio for the reaction q q æ 9999 L.2 MASS-TO-MASS PREDICTIONS F87 FUNDAMENTALS For example, in Section L.1 we saw that 0.50 mol H2O can be produced from 0.25 mol O2. If we want to know the mass of water that can be produced, we use the molar mass of water to convert this amount to mass by using m ϭ nM: Mass of H2O produced (g) = 0.50 mol H2O * 18.02 gи(mol H2O)-1 = 9.0 g TOOLBOX L.1 HOW TO CARRY OUT MASS-TO-MASS CALCULATIONS CONCEPTUAL BASIS A chemical equation tells us the relations between the amounts (in moles) of each reactant and product. By using the molar masses as conversion factors, we can express these relations in terms of masses. PROCEDURE The general procedure for mass-to-mass calculations, summarized in diagram (2), requires that first we write the balanced chemical equation for the reaction. Then we perform the following calculations: Step 1 Convert the given mass of one substance (A) in grams into amount in moles by using its molar mass. If necessary, first convert the units of mass to grams (use 1 kg ϭ 103 g, 1 mg ϭ 10Ϫ3 g). Step 2 Use the mole ratio derived from the stoichiometric coefficients in the balanced chemical equation to convert from the amount of one substance (A) into the amount in moles of the other substance (B). For aA : bB or aA ϩ bB : cC, use Step 3 Convert from amount in moles of the second substance to mass (in grams) by using its molar mass. mB ϭ nBMB This procedure is illustrated in Example L.1. nB = nA * b mol B a mol A 2 Molar mass of A Molar mass of B Mass of A Mass of B Moles of A Moles of B Reaction stoichiometry Mole ratio nA = mA MA EXAMPLE L.1 Calculating the mass of product that can be obtained from a given mass of reactant (a) What mass of iron(III) oxide, Fe2O3, present in iron ore is required to produce 10.0 g of iron when it is reduced by carbon monoxide gas to metallic iron and carbon dioxide gas in a blast furnace? (b) The carbon dioxide produced as a by-product must also be monitored to protect the environment. What mass of carbon dioxide is released when 10.0 g of iron is produced? Anticipate Because not all the matter in Fe2O3 is iron, expect to use more than 10.0 g of the ore to obtain 10.0 g of iron. To answer part (b) we have to do the calculation. PLAN Follow the steps in Toolbox L.1. SOLVE The chemical equation is Fe2O3(s) ϩ 3 CO(g) 2 Fe(s) ϩ 3 CO2(g) which implies that 2 mol Fe 1 mol Fe2O3 and 2 mol Fe 3 mol CO2 (a) The molar mass of iron is 55.85 gиmolϪ1 and that of iron(III) oxide is 159.69 gиmol–1 . ϴϴ ¡ Step 1 Convert from mass into amount of product by using its molar mass (n ϭ m/M). = 10 55.85 mol Fe Amount of Fe (mol) = 10.0 g 55.85 gи(mol Fe)-1 ϫ ϭ 55.85 g 10.0 g 1 mol Fe 0.179 mol ϫ ϭ 1 mol Fe2O3 Fe 0.179 mol 0.0895 mol 2 mol Step 2 Calculate the amount of reactant by using the mole ratio. = 10 55.85 * 2 mol Fe2O3 * 1 mol Fe2O3 2 mol Fe Amount of Fe2O3 (mol) = 10 55.85 mol Fe ϫ ϭ 0.0895 mol 1 mol 14.3 g 159.69 gStep 3 Convert from amount into mass of reactant by using its molar mass (n ϭ m/M). = 10 * 159.69 55.85 * 2 g = 14.3 g * 159.69 gи(molFe2O3)-1 Mass of Fe2O3 (g) = 10 55.85 * 2 mol Fe2O3 (b) The molar mass of carbon dioxide is 44.01 gиmolϪ1 . ϫ ϭ 1 mol ϫ 2 mol 3 mol CO2 ϫ 1 mol Fe 10.0 g 11.8 g 55.85 g 44.01 g Step 1 Convert from mass into amount of product by using its molar mass (n ϭ m/M). First, find the amount of Fe produced, as above. = 10 55.85 mol FeAmount of Fe (mol) = 10.0 g 55.85 gи(mol Fe)-1 F88 FUNDAMENTALS Step 2 Calculate the amount of the product of interest by using the mole ratio. = 10 * 3 55.85 * 2 mol CO2 Amount of CO2 (mol) = 10 55.85 mol Fe * 3 mol CO2 2 mol Fe Step 3 Use molar mass to convert from amount into mass (m ϭ nM). = 10 * 3 * 44.01 55.85 * 2 g = 11.8 g Mass of CO2 (g) = 10 * 3 55.85 * 2 mol CO2 * 44.01 gи(mol CO2)-1 Evaluate As we anticipated, more than 10 g of the ore is needed to obtain 10 g of iron. A note on good practice: Note that although, as usual, we have left the numerical calculation to a single, final step, the same is not true for the units: canceling units does not introduce rounding errors and clarifies each step. Self-Test L.2A Calculate the mass of potassium metal needed to react with 0.450 g of hydrogen gas to produce solid potassium hydride, KH. [Answer: 17.5 g] Self-Test L.2B Carbon dioxide can be removed from power plant exhaust gases by combining it with an aqueous slurry of calcium silicate: 2 CO2(g) ϩ H2O(l) ϩ CaSiO3(s) : SiO2(s) ϩ Ca(HCO3)2(aq). What mass of CaSiO3 (having molar mass 116.17 g и molϪ1 ) is needed to react completely with 0.300 kg of carbon dioxide? FUNDAMENTALS L.3 VOLUMETRIC ANALYSIS F89 In a mass-to-mass calculation, convert the given mass into amount in moles, apply the mole-to-mole conversion factor to obtain the amount required, and finally convert amount in moles into mass of the unknown substance. L.3 Volumetric Analysis A common laboratory technique for determining the concentration of a solute is titration (Fig. L.2). Titrations are usually either acid–base titrations, in which an acid reacts with a base, or redox titrations, in which the reaction is between a reducing agent and an oxidizing agent. Titrations are widely used to monitor water purity and blood composition and for quality control in the food industry. In a titration, the volume of one solution is known, and we measure the volume of the other solution required for complete reaction. The solution being analyzed is called the analyte, and a known volume is transferred into a flask, usually with a pipet. Then a solution containing a known concentration of reactant is measured into the flask from a buret until all the analyte has reacted. The solution in the buret is called the titrant, and the difference between the initial and final volume readings of the buret tells us the volume of titrant that has drained into the flask. The determination of concentration or amount by measuring volume is called volumetric analysis. In an acid–base titration, the analyte is a solution of a base and the titrant is a solution of an acid or vice versa. An indicator, a water-soluble dye (Section J), is used to detect the stoichiometric point, the stage at which the volume of titrant added is exactly that required by the stoichiometric relation between titrant and analyte. For example, if we titrate hydrochloric acid containing a few drops of the indicator phenolphthalein, the solution is initially colorless. After the stoichiometric point, when excess base is present, the solution in the flask is basic and the indicator is pink. Because the indicator color change is sudden, it is easy to detect the stoichiometric point (Fig. L.3). Toolbox L.2 shows how to interpret a titration; the procedure is summarized in diagram (3), where A is the solute in the titrant and B is the solute in the analyte. The stoichiometric point is also called the equivalence point. FIGURE L.2 The apparatus typically used for a titration: magnetic stirrer; flask containing the analyte; clamp; buret containing the titrant—in this case, potassium hydroxide. FIGURE L.3 An acid–base titration at the stoichiometric point. The indicator is phenolphthalein. 3 Molarity of A solution Molarity of B solution Volume of A solution Volume of B solution Moles of A Moles of B Reaction stoichiometry Mole ratio EXAMPLE L.2 Determining the molarity of an acid by titration Suppose that 25.00 mL of a solution of oxalic acid, H2C2O4 (4), which has two acidic protons, is titrated with 0.100 M NaOH(aq) and that the stoichiometric point for reaction with both protons is reached when 38.0 mL of the solution of base is added. Find the molarity of the oxalic acid solution. Anticipate If the acid were monoprotic, then because more than 25 mL of the alkali is needed to neutralize it, the molarity of the acid must be greater than the molarity of the base. However, the acid is in fact diprotic, so because each molecule of acid provides two acidic protons, its molarity would be half that of a monoprotic acid, so we can expect a molarity close to M M. PLAN Proceed as in Toolbox L.2. SOLVE L 0.081 2 * 1.5 * 0.1 4 Oxalic acid, (COOH)2 3.80 mmol NaOH 38.0 mLStep 1 Find the amount of NaOH added. = 38.0 * 10-3 * 0.100 mol NaOH nNaOH = (38.0 * 10-3 L) * 0.100 (mol NaOH)иL-1 F90 FUNDAMENTALS TOOLBOX L.2 HOW TO INTERPRET A TITRATION CONCEPTUAL BASIS In a titration one reactant (the titrant) is added gradually in solution to another (the analyte). The goal is to determine the molarity of the reactant in the analyte or its mass. We use the molarity of the titrant to find the amount of reacting titrant species in the volume of titrant supplied. PROCEDURE Step 1 Calculate the amount (ntitrant, in moles) of titrant species added from the volume of titrant (Vtitrant,) and its molarity (ctitrant). mol titrant (mol titrant)иL Ϫ1 L ntitrant ϭ ctitrant ϫ Vtitrant Step 2 Calculate the amount of analyte: (a) Write the chemical equation for the reaction, (b) identify the mole ratio between the titrant species and the analyte species, and (c) use it to convert the amount of titrant into amount of analyte (nanalyte). nanalyte ϭ ntitrant ϫ mole ratio Step 3 Calculate the initial molarity of the analyte (canalyte) by dividing the amount of analyte species by the initial volume, vanalyte, of the analyte. mol analyte L This procedure is illustrated in Example L.2. If the mass of the analyte is required, instead of step 3, use the molar mass of the analyte to convert moles into grams. This procedure is demonstrated in Example L.3. A note on good practice. Because we need to keep track of the substances, we must be sure to indicate the exact species and concentration units, by writing, for example, 1.0 (mol HCl)иL–1 or 1.0 M HCl(aq). = nanalyte Vanalyte canalyte (mol analyte)иLϪ1 $'%'& $'%'& $'%'& $'%'& $'%'& $'%'& ϫ ϭ 1 mol H2C2O4 H2C2O4 2 mol NaOH NaOH 3.80 mmol 1.90 mmol Step 2 (a) Write the chemical equation. (b) Identify the mole ratio. (c) Calculate the amount of acid present. (a) H2C2O4(aq) ϩ 2 NaOH(aq) : Na2C2O4(aq) ϩ 2 H2O(l) (b) 2 mol NaOH 1 mol H2C2O4 (c) = 1 2 * 38.0 * 10-3 * 0.100 mol H2C2O4 * 1 mol H2C2O4 2 mol NaOH n(H2C2O4) = (38.0 * 10-3 * 0.100 mol NaOH) ϴ FUNDAMENTALS L.3 VOLUMETRIC ANALYSIS F91 Evaluate The solution is 0.0760 M H2C2O4(aq). As we expected, the acid is less concentrated than the base and has a molarity close to 0.08 M. Self-Test L.3A A student used a sample of hydrochloric acid that was known to contain 0.020 mol of hydrogen chloride in 500.0 mL of solution to titrate 25.0 mL of a solution of calcium hydroxide. The stoichiometric point was reached when 15.1 mL of acid had been added. What was the molarity of the calcium hydroxide solution? [Answer: 0.012 M Ca(OH)2(aq)] Self-Test L.3B Many abandoned mines have exposed nearby communities to the problem of acid mine drainage. Certain minerals, such as pyrite (FeS2), decompose when exposed to air, forming solutions of sulfuric acid. The acidic mine water then drains into lakes and creeks, killing fish and other animals. At a mine in Colorado, a 16.45-mL sample of mine water was completely neutralized with 25.00 mL of 0.255 M KOH(aq). What is the molar concentration of H2SO4 in the water? 1.90 mmol 25 mL ϭ 0.0760 M Step 3 Calculate the molarity of the acid. = 0.0760 (mol H2C2O4)иL-1 c(H2C2O4) = 1 2 * 38.0 * 10-3 * 0.100 mol H2C2O4 25.00 * 10-3 L EXAMPLE L.3 Determining the purity of a sample by means of a redox titration The iron content of ores can be determined by titrating a sample with a solution of potassium permanganate, KMnO4. The ore is first dissolved in hydrochloric acid, going into solution as iron(II) ions, which then react with MnO4 Ϫ ions: 5 Fe2ϩ (aq) ϩ MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) 5 Fe3ϩ (aq) ϩ Mn2ϩ (aq) ϩ 4 H2O(l) The stoichiometric point is reached when all the Fe2ϩ has reacted and is detected when the purple color of the permanganate ion persists. A sample of ore of mass 0.202 g was dissolved in hydrochloric acid, and the resulting solution needed 16.7 mL of 0.0108 M KMnO4(aq) to reach the stoichiometric point. (a) What mass of iron(II) ions is present? (b) What is the mass percentage of iron in the ore sample? Anticipate The mass of iron present must be less than the mass of ore used in the titration. PLAN (a) To obtain the amount of iron(II) in the analyte, we use the volume and concentration of the titrant. We follow the first two steps of the procedure in Toolbox L.2. Then we convert moles of Fe2ϩ ions into mass by using the molar mass of Fe2ϩ : because the mass of electrons is so small, we use the molar mass of elemental iron for the molar mass of iron(II) ions. (b) To find the mass percentage, divide the mass of iron by the mass of the ore sample and multiply by 100%. SOLVE (a) Find the mass of iron present in the sample. From the chemical equation, the stoichiometric relation between the iron and the permanganate ions is 5 mol Fe2ϩ 1 mol MnO4 Ϫ We can set up the mass calculation as follows: ϴ ¡ 16.7 mL 0.180 mmol MnO4 Ϫ Find the amount of MnO4 Ϫ added from n ϭ cV, = (1.67 * 10-2 * 0.0108) mol MnO4 - n(MnO4 ) = 0.0108 mol MnO4 - 1 L * (1.67 * 10-2 L) ϫ ϭ 5 mol Fe2ϩ Fe2ϩ 1 mol MnO4 Ϫ MnO4 Ϫ 0.180 mmol 0.902 mmol Find the amount of Fe2ϩ present from the mole ratio for the reaction, = 1.67 * 10-2 * 0.0108 * 5 mol Fe2+ * 5 mol Fe2+ 1 mol MnO4 - n(Fe2+ ) = (1.67 * 10-2 * 0.0108) mol MnO4 - ϫ ϭ 1 mol 0.902 mmol 50.4 mg 55.85 g (a) Find the mass of iron from m ϭ nM. = 0.0504 g * 55.85 gи(mol Fe2+ )-1 m(Fe) = (1.67 * 10-2 * 0.0108 * 5 mol Fe2+ ) ϫ100% ϭ 202 mg 50.4 mg 25.0% (b) Calculate the mass percentage of iron in the ore; from mass percentage ϭ {(mass of iron)/(mass of sample)} ϫ 100%, Mass percentage of iron = 0.0504 g 0.202 g * 100% = 25.0% Evaluate The sample contains 0.0504 g of iron (as we anticipated, that is necessarily smaller than the mass of ore) and is 25.0% iron by mass. Self-Test L.4A A sample of clay of mass 20.750 g for use in making ceramics was analyzed to determine its iron content. The clay was washed with hydrochloric acid, and the iron converted into iron(II) ions. The resulting solution was titrated with cerium(IV) sulfate solution: Fe2ϩ (aq) ϩ Ce4ϩ (aq) Fe3ϩ (aq) ϩ Ce3ϩ (aq) In the titration, 13.45 mL of 1.340 M Ce2SO4(aq) was needed to reach the stoichiometric point. What is the mass percentage of iron in the clay? [Answer: 4.85%] Self-Test L.4B The amount of arsenic(III) oxide in a mineral can be determined by dissolving the mineral in acid and titrating it with potassium permanganate: 24 Hϩ (aq) ϩ 5 As4O6(s) ϩ 8 MnO4 Ϫ (aq) ϩ 18 H2O(l) 8 Mn2ϩ (aq) ϩ 20 H3AsO4(aq) A sample of industrial waste was analyzed for the presence of arsenic(III) oxide by titration with 0.0100 M KMnO4. It took 28.15 mL of the titrant to reach the stoichiometric point. What mass of arsenic(III) oxide did the sample contain? The stoichiometric relation between analyte and titrant species, together with the molarity of the titrant, is used in titrations to determine the molarity of the analyte. ¡ ¡ F92 FUNDAMENTALS ❑ 1 Carry out stoichiometric calculations for any two species taking part in a chemical reaction (Toolbox L.1 and Example L.1). ❑ 2 Calculate the molar concentration (molarity) of a solute from titration data (Toolbox L.2 and Example L.2). ❑ 3 Calculate the mass of a solute from titration data (Toolbox L.2 and Example L.3). SKILLS YOU SHOULD HAVE MASTERED FUNDAMENTALS EXERCISES F93 EXERCISES can react as bases: CaCO3(s) ϩ 2 HCl(aq) : CaCl2(aq) ϩ CO2(g) ϩ H2O(l). A popular antacid tablet contains 400. mg of CaCO3 and 150. mg of Mg(OH)2. What mass of HCl can it neutralize? L.10 You have used up all the antacid tablets, so you decide to use sodium bicarbonate as an antacid, because it can act as a base: NaHCO3(s) ϩ HCl(aq) : NaCl(aq) ϩ H2O(l) ϩ CO2(g). What mass of NaHCO3 will you need to neutralize the same mass of acid neutralized by the antacid tablet in Exercise L.9? L.11 A solution of sodium hydroxide of volume 15.00 mL was titrated to the stoichiometric point with 17.40 mL of 0.234 M HCl(aq). (a) What is the initial molarity of NaOH in the solution? (b) Calculate the mass of NaOH in the solution. L.12 A solution of oxalic acid, H2C2O4 (with two acidic protons), of volume 25.17 mL was titrated to the stoichiometric point with 26.72 mL of 0.327 M NaOH(aq). (a) What is the molarity of the oxalic acid? (b) Determine the mass of oxalic acid in the solution. L.13 A sample of barium hydroxide of mass 9.670 g was dissolved and diluted to the mark in a 250.0-mL volumetric flask. It was found that 11.56 mL of this solution was needed to reach the stoichiometric point in a titration of 25.0 mL of a nitric acid solution. (a) Calculate the molarity of the HNO3 solution. (b) What mass of HNO3 is in the initial sample? L.14 Suppose that 10.0 mL of 3.0 M KOH(aq) is transferred to a 250.0-mL volumetric flask and diluted to the mark. It was found that 38.5 mL of this diluted solution was needed to reach the stoichiometric point in a titration of 10.0 mL of a phosphoric acid solution according to the reaction 3 KOH(aq) ϩ H3PO4(aq) : K3PO4(aq) ϩ 3 H2O(l). (a) Calculate the molarity of H3PO4 in the solution. (b) What mass of H3PO4 is in the initial sample? L.15 In a titration, 3.25 g of an acid, HX, requires 68.8 mL of 0.750 M NaOH(aq) for complete reaction. What is the molar mass of the acid? L.16 Suppose that 14.56 mL of 0.115 M NaOH(aq) was required to titrate 0.2037 g of an unknown acid, HX. What is the molar mass of the acid? L.17 Excess NaI was added to 50.0 mL of aqueous AgNO3 solution, and 1.76 g of AgI precipitate was formed. What was the molar concentration of AgNO3 in the original solution? L.18 An excess of AgNO3 reacts with 25.0 mL of 5.0 M K2CrO4(aq) to form a precipitate. What is the precipitate, and what mass of precipitate is formed? L.19 A solution of hydrochloric acid was prepared by measuring 10.00 mL of the concentrated acid into a 1.000-L volumetric flask and adding water up to the mark. Another solution was prepared by adding 0.832 g of anhydrous sodium carbonate to a 100.0-mL volumetric flask and adding water up to the mark. Then, 25.00 mL of the carbonate solution was pipetted into a flask and titrated with the diluted acid. The stoichiometric point was reached after 31.25 mL of acid had been added. (a) Write a balanced equation for the reaction of HCl(aq) with Na2CO3(aq). (b) What is the molarity of the original concentrated hydrochloric acid? L.20 A tablet of vitamin C was analyzed to determine whether it did in fact contain, as the manufacturer claimed, 1.0 g of the L.1 Compounds that can be used to store hydrogen in vehicles are being actively sought. One reaction being studied for hydrogen storage is Li3N(s) ϩ 2 H2(g) : LiNH2(s) ϩ 2 LiH(s) (a) How many moles of H2 are needed to react with 1.5 mg of Li3N? (b) Calculate the mass of Li3N that will produce 0.650 mol LiH. L.2 In research on the synthesis of superconductors the reaction Tl2O3(l) ϩ 2 BaO(s) ϩ 3 CaO(s) ϩ 4 CuO(s): Tl2Ba2Ca3Cu4O12(s) is being studied: (a) How many moles of BaO are needed to react with 4.0 g of CaO? (b) Calculate the mass of CuO required to produce 0.10 mol of product. L.3 The solid fuel in the booster stage of the space shuttle is a mixture of ammonium perchlorate and aluminum powder. On ignition, the reaction that takes place is 6 NH4ClO4(s) ϩ 10 Al(s) : 5 Al2O3(s) ϩ 3 N2(g) ϩ 6 HCl(g) ϩ 9 H2O(g). (a) What mass of aluminum should be mixed with 1.325 kg of NH4ClO4 for this reaction? (b) Determine the mass of Al2O3 (alumina, a finely divided white powder that is produced as billows of white smoke) formed in the reaction of 3.500 ϫ 103 kg of aluminum. L.4 The compound diborane, B2H6, was at one time considered for use as a rocket fuel. Its combustion reaction is B2H6(g) ϩ 3 O2(l) : 2 HBO2(g) ϩ 2 H2O(l) The fact that HBO2, a reactive compound, was produced rather than the relatively inert B2O3 was a factor in the discontinuation of the investigation of diborane as a fuel. (a) What mass of liquid oxygen (LOX) would be needed to burn 257 g of B2H6? (b) Determine the mass of HBO2 produced from the combustion of 106 g of B2H6. L.5 The camel stores the fat tristearin, C57H110O6, in its hump. As well as being a source of energy, the fat is also a source of water because, when it is used, the reaction 2 C57H110O6(s) ϩ 163 O2(g) : 114 CO2(g) ϩ 110 H2O(l) takes place. (a) What mass of water is available from 1.00 pound (454 g) of this fat? (b) What mass of oxygen is needed to oxidize this amount of tristearin? L.6 Potassium superoxide, KO2, is utilized in a closed-system breathing apparatus to remove carbon dioxide and water from exhaled air. The removal of water generates oxygen for breathing by the reaction 4 KO2(s) ϩ 2 H2O(l) : 3 O2(g) ϩ 4 KOH(s). The potassium hydroxide removes carbon dioxide from the apparatus by the reaction KOH(s) ϩ CO2(g) : KHCO3(s). (a) What mass of potassium superoxide generates 85.0 g of O2? (b) What mass of CO2 can be removed from the apparatus by 67.0 g of KO2? L.7 When a hydrocarbon burns, water is produced as well as carbon dioxide. The density of gasoline is 0.79 gиmLϪ1 . Assume gasoline to be represented by octane, C8H18, for which the combustion reaction is 2 C8H18(l) ϩ 25 O2(g) : 16 CO2(g) ϩ 18 H2O(l). Calculate the mass of water produced from the combustion of 1.0 gallon (3.8 L) of gasoline. L.8 The density of oak is 0.72 gиcmϪ3 . Assuming oak to have the empirical formula CH2O, calculate the mass of water produced when a log of dimensions 12 cm ϫ 14 cm ϫ 25 cm is completely burned to CO2(g) and H2O(l). L.9 The stomach uses HCl to digest food. However, excess stomach acid can cause problems and must sometimes be neutralized by chewing antacid tablets containing a base such as Mg(OH)2. Carbonates such as CaCO3 are also used, because they vitamin. One tablet was dissolved in water to form 100.00 mL of solution, and 10.0 mL of that solution was titrated with iodine (as potassium triiodide). It required 10.1 mL of 0.0521 M I3 Ϫ (aq) to reach the stoichiometric point in the titration. Given that 1 mol I3 Ϫ reacts with 1 mol vitamin C in the reaction, is the manufacturer’s claim correct? The molar mass of vitamin C is 176 gиmolϪ1 . L.21 Iodine is a common oxidizing agent, often used as the triiodide ion, I3 Ϫ . Suppose that in the presence of HCl(aq), 25.00 mL of 0.120 M aqueous triiodide solution reacts completely with 30.00 mL of a solution containing 19.0 gиLϪ1 of an ionic compound containing tin and chlorine. The products are iodide ions and another compound of tin and chlorine. The reactant compound is 62.6% tin by mass. Write a balanced equation for the reaction. L.22 A forensic laboratory is analyzing a mixture of the two solids calcium chloride dihydrate, CaCl2и2H2O, and potassium chloride, KCl. The mixture is heated to drive off the water of hydration: CaCl2 :⌬ 2H2O(s) CaCl2(s) ϩ 2 H2O(g). A sample of the mixture weighed 2.543 g before heating. After heating, the resulting mixture of anhydrous CaCl2 and KCl weighed 2.312 g. Calculate the mass percentage of each compound in the original sample. L.23 Thiosulfate ions (S2O3 2Ϫ ) “disproportionate” in acidic solution to give solid sulfur (S) and hydrogen sulfite ion (HSO3 Ϫ ): 2 S2O3 2Ϫ (aq) ϩ 2 H3Oϩ (aq) : 2 HSO3 Ϫ (aq) ϩ 2 H2O(l) ϩ 2 S(s) (a) A disproportionation reaction is a type of oxidation–reduction reaction. Which species is oxidized and which is reduced? (b) If 10.1 mL of 55.0% HSO3 Ϫ by mass is obtained in the reaction, what mass of S2O3 2Ϫ was present initially, assuming the reaction went to completion? The density of the HSO3 Ϫ solution is 1.45 gиcmϪ3 . L.24 Suppose that 25.0 mL of 0.50 M K2CrO4(aq) reacts with 15.0 mL of AgNO3(aq) completely. What mass of NaCl is needed to react completely with 45.0 mL of the same AgNO3 solution? L.25 The compound XCl2(NH3)2 can be formed by reacting XCl4 with NH3. Suppose that 3.571 g of XCl4 reacts with excess NH3 to give Cl2 and 3.180 g of XCl2(NH3)2. What is the element X? L.26 The reduction of iron(III) oxide to iron metal in a blast furnace is another source of atmospheric carbon dioxide. The reduction takes place in these two steps: 2 C(s) ϩ O2(g) 2 CO(g) Fe2O3(s) ϩ 3 CO(g) 2 Fe(l) ϩ 3 CO2(g) Assume that all the CO generated in the first step reacts in the second. (a) How many C atoms are needed to react with 600. Fe2O3 formula units? (b) What is the maximum volume of carbon dioxide (taken to have a density of 1.25 gиLϪ1 ) that can be generated in the production of 1.0 t of iron (1 t ϭ 103 kg)? (c) Assuming a 67.9% yield, what volume of carbon dioxide is released to the atmosphere in the production of 1.0 t of iron? (d) How many kilograms of O2 are required for the production of 5.00 kg of Fe? L.27 Barium bromide, BaBrx, can be converted into BaCl2 by treatment with chlorine. It is found that 3.25 g of BaBrx reacts completely with an excess of chlorine to yield 2.27 g of BaCl2. Determine the value of x and write the balanced chemical equation for the production of BaCl2 from BaBrx. L.28 Sulfur is an undesirable impurity in coal and petroleum fuels. The mass percentage of sulfur in a fuel can be determined by burning the fuel in oxygen and dissolving the SO3 produced in water to form aqueous sulfuric acid. In one experiment, 8.54 g of a fuel was burned, and the resulting sulfuric acid was titrated with 17.54 mL of 0.100 M NaOH(aq). (a) Determine the amount (in moles) of H2SO4 that was produced. (b) What is the mass percentage of sulfur in the fuel? L.29 Sodium bromide, NaBr, which is used to produce AgBr for use in photographic film, can itself be prepared as follows. Fe ϩ Br2 FeBr2 FeBr2 ϩ Br2 Fe3Br8 Fe3Br8 ϩ Na2CO3 NaBr ϩ CO2 ϩ Fe3O4 How much iron, in kilograms, is needed to produce 2.50 t of NaBr? Note that these equations must first be balanced! L.30 Silver nitrate is an expensive laboratory reagent that is often used for quantitative analysis of chloride ion. A student preparing to conduct a particular analysis needs 100.0 mL of 0.0750 M AgNO3(aq), but finds only about 60 mL of 0.0500 M AgNO3(aq). Instead of making up a fresh solution of the exact concentration desired (0.0750 M), the student decides to pipet 50.0 mL of the existing solution into a 100.0-mL flask, then add enough pure solid AgNO3 to make up the difference and enough water to bring the volume of the resulting solution to exactly 100.0 mL. What mass of solid AgNO3 must be added in the second step? L.31 (a) How would you prepare 1.00 L of 0.50 M HNO3(aq) from “concentrated” (16 M) HNO3(aq)? (b) How many milliliters of 0.20 M NaOH(aq) could be neutralized by 100. mL of the diluted solution? L.32 You have been given a sample of an unknown diprotic acid. (a) Analysis of the acid shows that a 10.0-g sample contains 0.224 g of hydrogen, 2.67 g of carbon, and the rest oxygen. Determine the empirical formula of the acid. (b) A 0.0900-g sample of your unknown acid is dissolved in 30.0 mL of water and titrated to the endpoint with 50.0 mL of 0.040 M NaOH(aq). Determine the molecular formula of the acid. (c) Write a balanced chemical equation for the neutralization of the unknown acid with NaOH(aq). L.33 A 1.50-g sample of metallic tin was placed in a 26.45-g crucible and heated until all the tin had reacted with the oxygen in air to form an oxide. The crucible and product together were found to weigh 28.35 g. (a) What is the empirical formula of the oxide? (b) Write the name of the oxide. L.34 A 1.27-g sample of metallic copper was placed in a 26.32-g crucible and heated until all the copper had reacted with the oxygen in air to form an oxide. The crucible and product together were found to weigh 27.75 g. (a) What is the empirical formula of the oxide? (b) Write the name of the oxide. L.35 A chemist is titrating a solution of KOH of unknown concentration with 0.0101 M HCl(aq); a number of events occur during the titration. Which of the following events will affect the reported concentration? If there is an effect, indicate whether the reported KOH concentration will be too high or too low. ¡ ¡ ¡ ¡ ¡ F94 FUNDAMENTALS FUNDAMENTALS M.1 REACTION YIELD F95 (a) The flask used for the KOH solution was not dried and so contains a small amount of distilled water. (b) The buret used for the HCl solution was not dried and so contains a small amount of distilled water. (c) The walls of the buret were slightly oily and some water droplets stick to the sides as the level falls. (d) The chemist misread the concentration of HCl as 0.0110 M HCl(aq). L.36 A chemist is determining the mass percentage of iron in a sample of ore, using the method in Example L.3. After dissolving the ore in hydrochloric acid, it is discovered that some of the solid does not dissolve. Which of the following additional pieces of information will the chemist need to determine the mass percentage of iron in the ore? (a) The mass of the insoluble solid. (b) The percentage of the mass of the ore sample represented by the insoluble solid. (c) The identity of the insoluble solid. (d) Knowledge that the insoluble solid does not contain any iron. (e) None of these pieces of information are necessary. M LIMITING REACTANTS Stoichiometric calculations of the amount of product formed in a reaction are based on an ideal view of the world. They suppose, for instance, that all the reactants react exactly as described in the chemical equation. In practice, that might not be so. Some of the starting materials may be consumed in a competing reaction, a reaction taking place at the same time as the one in which we are interested and using some of the same reactants. Another possibility is that the reaction might not be complete at the time we make our measurements. A third possibility—of major importance in chemistry and covered in several chapters of this text—is that many reactions do not go to completion. They appear to stop once a certain proportion of the reactants has been consumed. Therefore, the actual amount of product may be less than what we would calculate from the reaction stoichiometry. M.1 Reaction Yield The theoretical yield of a reaction is the maximum quantity (amount, mass, or volume) of product that can be obtained from a given quantity of reactant. The quantities of products calculated from a given mass of reactant in Section L were all theoretical yields. The percentage yield is the fraction of the theoretical yield actually produced, expressed as a percentage: (1)*Percentage yield = actual yield theoretical yield * 100% M.1 Reaction Yield M.2 The Limits of Reaction M.3 Combustion Analysis EXAMPLE M.1 Calculating the percentage yield of a product Incomplete combustion of the fuel in a poorly tuned engine can produce toxic carbon monoxide along with the usual carbon dioxide and water. In a test of an off-road motorcycle engine, 1.00 L of octane (of mass 702 g) is burned and it was found that 1.84 kg of carbon dioxide is produced. What is the percentage yield of carbon dioxide? Anticipate Apart from knowing that the percentage yield cannot exceed 100%, it is not possible to anticipate the actual value in this case. PLAN Begin by writing the chemical equation for the desired reaction. Then calculate the theoretical yield (in grams) of product by using the procedure in Toolbox L.1. To avoid rounding errors, do all the numerical work at the end of the calculation. To obtain the percentage yield, divide the actual mass produced by the theoretical mass of product and multiply by 100%. SOLVE The molar mass of C8H18 is 114.2 gиmolϪ1 and the molar mass of CO2 is 44.01 gиmolϪ1 . The chemical equation is 2 C8H18(l) + 25 O2(g) ¡ 16 CO2(g) + 18 H2O(l) ϫ ϭ 1 mol ϫ 2 mol 16 mol CO2 CO2 C8H18 C8H18 C8H18 ϫ 1 mol 702 g 2.16 kg 114.2 g 44.01 g CO2 Calculate the theoretical yield of CO2 for the combustion of 702 g of octane. = 2.16 * 103 g (or 2.16 kg) * 44.01 gи(mol CO2)-1 m(CO2) = 702 g 114.2 gи(molC8H18)-1 * 16 mol CO2 2 mol C8H18 Evaluate The theoretical yield of 2.16 kg corresponds to about 8 kg of CO2 per gallon of fuel. Although there are concerns about rising levels of CO2, that the percentage yield of CO2 is only 85.2% of the theroetical yield in this case is not a step in the right direction! It means that the fuel is being used inefficiently and that a lot of undesirable CO is being produced. Self-Test M.1A When 24.0 g of potassium nitrate was heated with lead, 13.8 g of potassium nitrite was formed in the reaction Pb(s) ϩ KNO3(s) : PbO(s) ϩ KNO2(s). Calculate the percentage yield of potassium nitrite. [Answer: 68.3%] Self-Test M.1B Reduction of 15 kg of iron(III) oxide in a blast furnace produced 8.8 kg of iron. What is the percentage yield of iron? The theoretical yield of a product is the maximum quantity that can be expected on the basis of the stoichiometry of a chemical equation. The percentage yield is the percentage of the theoretical yield actually achieved. M.2 The Limits of Reaction The limiting reactant in a reaction is the reactant that governs the maximum yield of product. A limiting reactant is like a part in short supply in a motorcycle factory. Suppose there are eight wheels and seven motorcycle frames. Because each frame requires two wheels, there are enough wheels for only four motorcycles, so the wheels play the role of the limiting reactant. When all the wheels have been used, three frames remain unused, because they were present in excess. In some cases, we must determine by calculation which is the limiting reactant. For example, from the equation we see that, in the synthesis of ammonia, 1 mol N2 ϴ 3 mol H2. To decide which reactant is the limiting one, we compare the number of moles of each reactant supplied with the stoichiometric coefficients. For example, suppose we had available 1 mol N2 but only 2 mol H2. Because this amount of hydrogen is less than is required by the stoichiometric relation, hydrogen would be the limiting reactant. Once we have identified the limiting reactant, we can calculate the amount of product that can be formed. We can also calculate the amount of excess reactant that remains at the end of the reaction. N2(g) + 3 H2(g) ¡ 2 NH3(g) ϫ 100% 2.16 kg 1.84 kg ϭ 85.2% Calculate the percentage yield of carbon dioxide from the fact that only 1.84 kg was produced. Percentage yield of CO2 = 1.84 kg 2.16 kg * 100% = 85.2% F96 FUNDAMENTALS M.2 THE LIMITS OF REACTION F97 FUNDAMENTALS TOOLBOX M.1 HOW TO IDENTIFY THE LIMITING REACTANT CONCEPTUAL BASIS The limiting reactant is the reactant that will be completely used up. All other reactants are in excess. Because the limiting reactant is the one that limits the amounts of products that can be formed, the theoretical yield is calculated from the amount of the limiting reactant. PROCEDURE There are two ways of determining which reactant is the limiting one. Method 1 In this approach, we use the mole ratio from the chemical equation to determine whether there is enough of one reactant to react with another. Step 1 Convert the mass of each reactant into an amount in moles, if necessary, by using the molar masses of the substances. Step 2 Choose one of the reactants and use the stoichiometric relation to calculate the theoretical amount of the second reactant needed for complete reaction with the first. Step 3 If the actual amount of the second reactant is greater than the amount needed (the value calculated in step 2), then the second reactant is present in excess; in this case, the first reactant is the limiting reactant. If the actual amount of the second reactant is less than that calculated, then all of it will react; so it is the limiting reactant and the first reactant is in excess. This method is used in Example M.2. Method 2 Calculate the theoretical molar yield of one of the products for each reactant separately, by using the procedure in Toolbox L.1. This method is a good one to use when there are more than two reactants. The reactant that would produce the smallest amount of product is the limiting reactant. Step 1 Convert the mass of each reactant into an amount in moles, if necessary, by using the molar masses of the substances. Step 2 Select one of the products. For each reactant, calculate how many moles of the product it can form. Step 3 The reactant that can produce the least product is the limiting reactant. This method is used in Example M.3. EXAMPLE M.2 Identifying the limiting reactant Calcium carbide, CaC2, reacts with water to form calcium hydroxide and the flammable gas ethyne (acetylene). This reaction was once used for lamps on bicycles, because the reactants are easily transported. (a) Which is the limiting reactant when 100. g of water reacts with 100. g of calcium carbide? (b) What mass of ethyne can be produced? (c) What mass of excess reactant remains after reaction is complete? Assume that the calcium carbide is pure and that all the ethyne produced is collected. The chemical equation is Anticipate Because the molar mass of CaC2 is so much greater than that of H2O, we might suspect that there is a small amount of it present and therefore that it will be the limiting reactant. On the other hand, the mole ratio for the reaction indicates that the amount of H2O required is twice that of the CaC2, so we have to be cautious about that prediction. PLAN We follow the procedure in Method 1 of Toolbox M.1. Molar masses are calculated by using the information in the periodic table inside the front cover or the alphabetical list of elements inside the back cover. SOLVE CaC2(s) + 2 H2O(l) ¡ Ca(OH)2(aq) + C2H2(g) ϫ ϭ 1.56 mol 100 g 64.10 g 1 mol CaC2 ϫ ϭ 5.55 mol18.02 g 1 mol H2O 100 g (a) First calculate the molar masses. calcium carbide: 64.10 gиmolϪ1 ; water: 18.02 gиmolϪ1 Step 1 Calculate the amount of each reactant. = 100. 18.02 mol H2O = 5.55 mol H2O n(H2O) = 100. g 18.02 gи(mol H2O)-1 = 100. 64.10 mol CaC2 = 1.56 mol CaC2 n(CaC2) = 100. g 64.10 gи(mol CaC2)-1 = 40.6 g m(CaC2) = a 100. 64.10 mol CaC2b * 1 mol C2H4 1 mol CaC2 * 26.04 gи(mol C2H4)-1 ϫ ϭ CaC2 H2O 1.56 mol 3.12 mol 1 mol 2 mol 100 g CaC2 3.12 mol 5.55 mol Supplied: Requires: Step 2 Write the stoichiometric relation and calculate the amount of H2O that is needed to react with the available amount of CaC2. = 3.12 mol H2O n(H2O) = a 100. 64.10 mol CaC2b * 2 mol H2O 1 mol CaC2 1 mol CaC2 ϴ 2 mol H2O Step 3 Determine which reactant is the limiting reactant. Because 3.12 mol H2O is required and 5.55 mol H2O is supplied, all the calcium carbide can react; so the calcium carbide is the limiting reactant and water is present in excess. (b) Because C2H2 is the limiting reactant and 1 mol CaC2 ϴ 1 mol C2H2, the mass of ethyne (of molar mass 26.04 gиmolϪ1 ) that can be produced is (c) The reactant in excess is water. Because 5.55 mol H2O was supplied and 3.12 mol H2O was consumed, the amount of H2O remaining is 5.55 Ϫ 3.12 mol ϭ 2.43 mol. Therefore, the mass of the excess reactant remaining at the end of the reaction is Mass of H2O remaining ϭ (2.43 mol) ϫ (18.02 gиmolϪ1 ) ϭ 43.8 g F98 FUNDAMENTALS Evaluate The CaC2 is the limiting reactant (as we anticipated), 40.6 g of ethyne can be produced, and 43.8 g of water remains unreacted. Self-Test M.2A (a) Identify the limiting reactant in the reaction 6 Na(l) ϩ Al2O3(s) : 2 Al(l) ϩ 3 Na2O(s) when 5.52 g of sodium is heated with 5.10 g of Al2O3. (b) What mass of aluminum can be produced? (c) What mass of excess reactant remains at the end of the reaction? [Answer: (a) Sodium; (b) 2.16 g Al; (c) 1.02 g Al2O3] Self-Test M.2B (a) What is the limiting reactant for the preparation of urea from ammonia in the reaction 2 NH3(g) ϩ CO2(g) : OC(NH2)2(s) ϩ H2O(l) when 14.5 kg of ammonia is available to react with 22.1 kg of carbon dioxide? (b) What mass of urea can be produced? (c) What mass of excess reactant remains at the end of the reaction? EXAMPLE M.3 Calculating the percentage yield from a limiting reactant An important step in the refining of aluminum metal is the manufacture of cryolite, Na3AlF6, from ammonium fluoride, sodium aluminate, and sodium hydroxide in aqueous solution: Unfortunately, by-products can form, reducing the yield. In a laboratory investigation of the process, 100.0 g of NH4F was mixed with 82.6 g of Na[Al(OH)4] and 80.0 g of NaOH. The mass of Na3AlF6 produced was 75.0 g. What was the percentage yield of the reaction? Anticipate Apart from knowing that the percentage yield cannot exceed 100%, it is not possible to anticipate the actual value in this case. Na3AlF6(s) + 6 NH3(aq) + 6 H2O(l) 6 NH4F(aq) + Na[Al(OH)4](aq) + 2 NaOH(aq) ¡ M.2 THE LIMITS OF REACTION F99 FUNDAMENTALS PLAN First, the limiting reactant must be identified (Toolbox M.1). This limiting reactant determines the theoretical yield of the reaction, and so we use it to calculate the theoretical amount of product by Method 2 in Toolbox L.1. The percentage yield is the ratio of the mass produced to the theoretical mass times 100%. SOLVE NaOH NH4F Na[Al(OH)4] Na3[AlF6] 1 mol m ϫ ϭ Find the molar masses. Reactants: NH4F: 37.04 gиmolϪ1 Na[Al(OH)4]: 118.00 gиmolϪ1 NaOH: 80.00 gиmolϪ1 Product: Na3AlF6: 209.95 gиmolϪ1 Step 1 Calculate the amount of each reactant from n ϭ m/M. n(NaOH) = 80.0 g 40.00 gи(mol NaOH)-1 = 2.00 mol NaOH = 0.700 mol Na[Al(OH)4] n(Na[Al(OH)4]) = 82.6 g 118.00 gи(mol Na[Al(OH)4])-1 n(NH4F) = 100.0 g 37.04 gи(mol NH4F)-1 = 2.700 mol NH4F ϫ ϭ 1 mol Na3[AIF6] 6 molNH4F 2.700 mol 0.450 mol ϫ ϭ 1 mol Na3[AlF6] Na[Al(OH)4] 1 mol 0.700 mol 0.700 mol Step 2 Write the mole ratios for the reaction. 2 mol NaOH ϴ 1 mol Na3AlF6 1 mol Na[Al(OH)4] ϴ 1 mol Na3AlF6;6 mol NH4F ϴ 1 mol Na3AlF6; Step 3 Identify as limiting reactant the reactant that can produce the least product. From NH4F: From Na[Al(OH)4]: = 0.700 mol Na3AlF6 * 1 mol Na3AlF6 1 mol Na[Al(OH)4] n(Na3AlF6) = 0.700 mol Na[Al(OH)4] = 0.450 mol Na3AlF6 n(Na3AlF6) = 2.700 mol NH4F * 1 mol Na3AlF6 6 mol NH4F From NaOH: NH4F can produce only 0.450 mol Na3AlF6. Therefore, it is the limiting reactant. = 1.00 mol Na3AlF6 n(Na3AlF6) = 2.00 mol NaOH * 1 mol Na3AlF6 2 mol NaOH ϫ ϭ 1 mol Na3[AlF6] NaOH 2 mol 2.00 mol 1.00 mol ϫ ϭ 1 mol 0.450 mol 94.5 g 209.95 g ϫ 100% 94.5 g 75.0 g ϭ 79.4% Calculate the percentage yield from Eq. 1. Evaluate As expected, the yield (79.4%) is less than 100% on account of the formation of unwanted by-products. Self-Test M.3A In the synthesis of ammonia, what is the percentage yield of ammonia when 100. kg of hydrogen reacts with 800. kg of nitrogen to produce 400. kg of ammonia? [Answer: 71.0%] Self-Test M.3B Suppose that 28 g of NO2 and 18 g of water are allowed to react to produce nitric acid and nitrogen monoxide. If 22 g of nitric acid are produced in the reaction, what is the percentage yield? The limiting reactant in a reaction is the reactant supplied in an amount smaller than that required by the stoichiometric relation between the reactants. M.3 Combustion Analysis In Section F, we saw that one technique used in modern chemical laboratories to determine the empirical formulas of organic compounds is combustion analysis. We are now in a position to understand the basis of the technique, because it makes use of the concept of limiting reactant. The sample is ignited and allowed to burn in a tube while a plentiful supply of oxygen passes through (Fig. M.1). The use of excess oxygen ensures that the sample is the limiting reactant. All the hydrogen in the compound is converted into water and all the carbon is converted into carbon dioxide. In the modern version of the technique, the product gases are separated chromatographically and their relative Percentage yield of Na3AlF6 = 75.0 g 94.5 g * 100% = 79.4% F100 FUNDAMENTALS Calculate the theoretical yield as mass of Na3AlF6 from m ϭ nM. m(Na3AlF6) = 0.450 mol * 209.95 gиmol-1 = 94.5 g Detector Gas chromatograph Sample He and O2 Ceramic crucible WO3 catalyst Cu catalyst N2 CO2 H2O FIGURE M.1 The apparatus used for a combustion analysis. An oxygen–helium mixture is passed over the ceramic crucible containing the sample, which is oxidized. Product gases are passed through two filters. The WO3 catalyst ensures that any CO produced is oxidized to CO2; the Cu removes the excess oxygen. The masses of nitrogen, carbon dioxide, and water produced are obtained by separating the product gases and measuring their thermal conductivities. M.3 COMBUSTION ANALYSIS F101 FUNDAMENTALS amounts determined by measuring the thermal conductivity (the ability to conduct heat) of the gas streaming from the apparatus. Let’s see how to determine an empirical formula by analyzing the data, which are the initial mass of the compound and the masses of the water and carbon dioxide produced in the combustion of the compound. In the presence of excess oxygen, each carbon atom in the compound ends up in one molecule of carbon dioxide. Therefore, we can write or, more briefly, 1 mol C ϴ 1 mol CO2. Hence, by measuring the mass of carbon dioxide produced and converting that mass into amount of C atoms, we can find the number of moles of C atoms in the original sample. Similarly, in the presence of excess oxygen, each hydrogen atom in a compound contributes to a water molecule when the compound burns. We can infer that or, more briefly, 2 mol H ϴ 1 mol H2O. Therefore, if we measure the mass of water produced when the compound burns in plenty of oxygen, we can find the amount of H atoms (in moles) in the sample. Many organic compounds also contain oxygen. Provided the compound contains only carbon, hydrogen, and oxygen, we can calculate the mass of oxygen originally present by subtracting the masses of carbon and hydrogen in the sample from the original mass of the sample. That mass of oxygen can be converted into amount of O atoms (in moles) by using the molar mass of oxygen atoms (16.00 gиmolϪ1 ). We can then calculate the empirical formula. 2 mol H in sample ϴ 1 mol H2O as product 1 mol C in sample ϴ 1 mol CO2 as product EXAMPLE M.4 Determining an empirical formula by combustion analysis A combustion analysis was carried out on 1.621 g of a newly synthesized compound, which was known to contain only C, H, and O. The masses of water and carbon dioxide produced were 1.902 g and 3.095 g, respectively. What is the empirical formula of the compound? Anticipate Only if we had carried out the synthesis with a specific product in mind could we anticipate the empirical formula. PLAN We use the stoichiometric relations given earlier to find the amounts of carbon and hydrogen atoms in the sample and then convert those moles into masses. The mass of oxygen in the sample is obtained by subtracting the total mass of carbon and hydrogen from the mass of the original sample. It is then converted into the number of moles of O atoms. Finally, the relative numbers of atoms are expressed as an empirical formula. SOLVE The molar masses that we need are The mole ratio for the production of CO2 is 1 mol C ϴ 1 mol CO2 and for the production of H2O is 1 mol H2O ϴ 2 mol H. C: 12.01 gиmol-1 ; H2O: 18.02 gиmol-1 CO2: 44.01 gиmol-1 ; H: 1.008 gиmol-1 ; ϫ ϭ 1 mol ϫ 1 mol 1 mol ϫ 1 mol 3.095 g 844.6 mg 44.01 g 12.01 g Convert mass of CO2 produced into amount of C in the sample. (= 0.0703 mol C) n(C) = 3.095 g 44.01 gи(mol CO2)-1 * 1 mol C 1 mol CO2 = 3.095 44.01 mol C ϫ ϭ 1 mol ϫ 1 mol 2 mol ϫ 1 mol 1.902 g 212.8 mg 18.02 g 1.008 g Calculate the mass of carbon in the sample from m ϭ nM. m(C) = a 3.095 44.01 mol Cb * 12.01 gи(mol C)-1 = 0.8446 g Convert mass of H2O produced into amount of H in the sample. (= 0.2111 mol H) = 1.902 * 2 18.02 mol H n(H) = 1.902 g 18.02 gи(mol H2O)-1 * 2 mol H 1 mol H2O Calculate the mass of H in the sample. m(H) = a 1.902 * 2 18.02 mol Hb * 1.008 gи(mol H)-1 = 0.2128 g Find the total mass of C and H. 0.8446 g + 0.2128 g = 1.0574 g Calculate the mass of oxygen in the sample from the difference between sample mass and the masses of C and H. m(O) = 1.621 g - 1.0574 g = 0.564 g F102 FUNDAMENTALS ϫ ϭ 1 mol 16.00 g 35.2 mmol 0.564 g Convert mass of oxygen into amount of O atoms. n(O) = 0.564 g 16.00 gи(mol O)-1 = 0.0352 mol O 0.07032 0.2111 0.0352 Write the ratios of the amount of each element in the sample. This ratio is the same as the relative numbers of atoms. C:H:O ϭ 0.070 32 : 0.2111 : 0.0352 Divide by the smallest number (0.0352). C:H:O ϭ 2.00 : 6.00 : 1.00 Evaluate We conclude that the empirical formula of the new compound is C2H6O. Self-Test M.4A When 0.528 g of sucrose (a compound of carbon, hydrogen, and oxygen) is burned, 0.306 g of water and 0.815 g of carbon dioxide are formed. Deduce the empirical formula of sucrose. [Answer: C12H22O11] EXERCISES F103 FUNDAMENTALS Self-Test M.4B When 0.236 g of aspirin is burned in oxygen, 0.519 g of carbon dioxide and 0.0945 g of water are formed. Deduce the empirical formula of aspirin. In a combustion analysis, the amounts of C, H, and O atoms in a sample of a compound, and thus its empirical formula, are determined from the masses of carbon dioxide and water produced when the compound burns in excess oxygen. SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Calculate the theoretical and percentage yields of the products of a reaction, given the mass of starting material (Example M.1). ❑ 2 Identify the limiting reactant of a reaction and use the limiting reactant to calculate the yield of a product and the amount of excess reactant remaining after reaction is complete (Toolbox M.1 and Example M.2). ❑ 3 Determine the empirical formula of an organic compound containing carbon, hydrogen, and oxygen by combustion analysis (Example M.3). EXERCISES M.1 When limestone, which is principally CaCO3, is heated, carbon dioxide and quicklime, CaO, are produced by the reaction CaCO3(s) :⌬ CaO(s) ϩ CO2(g). If 17.5 g of CO2 is produced from the thermal decomposition of 42.73 g of CaCO3, what is the percentage yield of the reaction? M.2 Phosphorus trichloride, PCl3, is produced from the reaction of white phosphorus, P4, and chlorine: P4(s) ϩ 6 Cl2(g) : 4 PCl3(g). A sample of PCl3 of mass 203.2 g was collected from the reaction of 51.24 g of P4 with excess chlorine. What is the percentage yield of the reaction? M.3 Solid boron can be extracted from solid boron oxide by reaction with magnesium metal at a high temperature. A second product is solid magnesium oxide. (a) Write a balanced equation for the reaction. (b) If 125 kg of boron oxide is heated with 125 kg of magnesium, what mass of boron can be produced? M.4 The antiperspirant aluminum chloride is made by reacting solid aluminum oxide, solid carbon, and chlorine gas. Carbon monoxide gas is also produced in the reaction. (a) Write a balanced equation for the reaction. (b) If 185 kg of aluminum oxide is heated with 25 kg of carbon and 100 kg of chlorine, how much aluminum chloride can be produced? M.5 Polychlorinated biphenyls (PCBs) were once widely used industrial chemicals but were found to pose a risk to health and the environment. PCBs contain only carbon, hydrogen, and chlorine. Aroclor 1254 is the trade name for a PCB with molar mass 360.88 gиmolϪ1 . Combustion of 1.52 g of Aroclor 1254 produced 2.224 g of CO2, and combustion of 2.53 g produced 0.2530 g of H2O. How many chlorine atoms does an Aroclor 1254 molecule contain? M.6 Slaked lime, Ca(OH)2, is formed from quicklime, CaO, by the addition of water: CaO(s) ϩ H2O(l) : Ca(OH)2(s). What mass of slaked lime can be produced from a mixture of 25.0 g of CaO and 12.0 g of H2O? M.7 A reaction vessel contains 5.77 g of white phosphorus and 5.77 g of oxygen. The first reaction to take place is the formation of phosphorus(III) oxide, P4O6: P4(s) ϩ 3 O2(g) : P4O6(s). If enough oxygen is present, the oxygen can react further with this oxide to produce phosphorus(V) oxide, P4O10: P4O6(s) ϩ 2 O2(g) : P4O10(s). (a) What is the limiting reactant for the formation of P4O10? (b) What mass of P4O10 is produced? (c) How many grams of the excess reactant remain in the reaction vessel? M.8 A mixture of 9.125 g of iron(II) oxide and 8.625 g of aluminum metal is placed in a crucible and heated in a hightemperature oven, where a reduction of the oxide takes place: 3 FeO(s) ϩ 2 Al(l) : 3 Fe(l) ϩ Al2O3(s). (a) What is the limiting reactant? (b) Determine the maximum amount of iron (in moles of Fe) that can be produced. (c) Calculate the mass of excess reactant remaining in the crucible. M.9 Copper(II) nitrate reacts with sodium hydroxide to produce a precipitate of light blue copper(II) hydroxide. (a) Write the net ionic equation for the reaction. (b) Calculate the maximum mass of copper(II) hydroxide that can be formed if 2.00 g of sodium hydroxide is added to 80.0 mL of 0.500 M Cu(NO3)2(aq). M.10 In the reaction of hydrogen gas (H2) and oxygen gas (O2) to form water vapor, which is the limiting reactant in each situation? What is the maximum quantity of water vapor that can be produced in each case? Report your answer using the units in parentheses. (a) 1.0 g of hydrogen gas and 0.25 mol O2(g) (in moles of H2O); (b) 100 H2 molecules and 40 O2 molecules (in H2O molecules). M.11 The stimulant in coffee and tea is caffeine, a substance of molar mass 194 gиmolϪ1 . When 0.376 g of caffeine was burned, 0.682 g of carbon dioxide, 0.174 g of water, and 0.110 g of nitrogen were formed. Determine the empirical and molecular formulas of caffeine, and write the equation for its combustion. M.12 Nicotine, the stimulant in tobacco, causes a very complex set of physiological effects in the body. It is known to have a molar mass of 162 gиmolϪ1 . When a sample of mass 0.385 g was burned, 1.072 g of carbon dioxide, 0.307 g of water, and 0.068 g of nitrogen were produced. What are the empirical and molecular formulas of nicotine? Write the equation for its combustion. M.13 A compound found in the nucleus of a human cell was found to be composed of carbon, hydrogen, oxygen, and nitrogen. A combustion analysis of 1.35 g of the compound produced 2.20 g of CO2 and 0.901 g of H2O. When a separate 0.500-g sample of the compound was analyzed for nitrogen, 0.130 g of N2 was produced. What is the empirical formula of the compound? M.14 A compound produced as a by-product in an industrial synthesis of polymers was found to contain carbon, hydrogen, and iodine. A combustion analysis of 1.70 g of the compound produced 1.32 g of CO2 and 0.631 g of H2O. The mass percentage of iodine in the compound was determined by converting the iodine in a 0.850-g sample of the compound into 1.15 g of lead(II) iodide. What is the empirical formula of the compound? Could the compound also contain oxygen? Explain your answer. M.15 When aqueous solutions of calcium nitrate and phosphoric acid are mixed, a white solid precipitates. (a) What is the formula of the solid? (b) How many grams of the solid can be formed from 206 g of calcium nitrate and 150. g of phosphoric acid? M.16 Small amounts of chlorine gas can be generated in the laboratory from the reaction of manganese(IV) oxide with hydrochloric acid: 4 HCl(aq) ϩ MnO2(s) : 2 H2O(l) ϩ MnCl2(s) ϩ Cl2(g). (a) What mass of Cl2 can be produced from 42.7 g of MnO2 with an excess of HCl(aq)? (b) What volume of chlorine gas (of density 3.17 gиLϪ1 ) will be produced from the reaction of 300. mL of 0.100 M HCl(aq) with an excess of MnO2? (c) Suppose only 150. mL of chlorine was produced in the reaction in part (b). What is the percentage yield of the reaction? M.17 In addition to determining elemental composition of pure unknown compounds, combustion analysis can be used to determine the purity of known compounds. A sample of 2-naphthol, C10H7OH, which is used to prepare antioxidants to incorporate into synthetic rubber, was found to be contaminated with a small amount of LiBr. The combustion analysis of this sample gave the following results: 77.48% C and 5.20% H. Assuming that the only species present are 2-naphthol and LiBr, calculate the percentage purity by mass of the sample. M.18 An organic compound with the formula C14H20O2N was recrystallized from 1,1,2,2-tetrachloroethane, C2H2Cl4. A combustion analysis of the compound gave the following data: 68.50% C, 8.18% H by mass. Because the data were considerably different from that expected for pure C14H20O2N, the sample was examined and found to contain a significant amount of 1,1,2,2tetrachloroethane. Assuming that only these two compounds are present, what is the percentage purity by mass of the C14H20O2N? M.19 Tu-jin-pi is a root bark used in traditional Chinese medicines for the treatment of “athlete’s foot.” One of the active ingredients in tu-jin-pi is pseudolaric acid A, which is known to contain carbon, hydrogen, and oxygen. A chemist wanting to determine the molecular formula of pseudolaric acid A burned 1.000 g of the compound in an elemental analyzer. The products of the combustion were 2.492 g of CO2 and 0.6495 g of H2O. (a) Determine the empirical formula of the compound. (b) The molar mass was found to be 388.46 gиmolϪ1 . What is the molecular formula of pseudolaric acid A? M.20 A folk medicine used in the Anhui province of China to treat acute dysentery is cha-tiao-qi, a preparation of the leaves of Acer ginnala. Reaction of one of the active ingredients in cha-tiao-qi with water yields gallic acid, a powerful antidysenteric agent. Gallic acid is known to contain carbon, hydrogen, and oxygen. A chemist wanting to determine the molecular formula of gallic acid burned 1.000 g of the compound in an elemental analyzer. The products of the combustion were 1.811 g of CO2 and 0.3172 g of H2O. (a) Determine the empirical formula of the compound. (b) The molar mass was found to be 170.12 gиmolϪ1 . What is the molecular formula of gallic acid? M.21 An industrial by-product consists of C, H, O, and Cl. When 0.100 g of the compound was analyzed by combustion analysis, 0.0682 g of CO2 and 0.0140 g of H2O were produced. The mass percentage of Cl in the compound was found to be 55.0%. What are the empirical and molecular formulas of the compound? M.22 A mixture of 4.94 g of 85.0% pure phosphine, PH3, and 0.110 kg of CuSO4и5H2O (of molar mass 249.68 gиmolϪ1 ) is placed in a reaction vessel. (a) Balance the chemical equation for the reaction that takes place, given the skeletal form CuSO4и5H2O(s) ϩ PH3(g) : Cu3P2(s) ϩ H2SO4(aq) ϩ H2O(l). (b) Name each reactant and product. (c) Determine the limiting reactant. (d) Calculate the mass (in grams) of Cu3P2 (of molar mass 252.56 gиmolϪ1 ) produced, given that the percentage yield of the reaction is 6.31%. M.23 The acid HA (where A stands for an unknown group of atoms) has molar mass 231 gиmolϪ1 . HA reacts with the base XOH (molar mass 125 gиmolϪ1 ) to produce H2O and the salt XA. In one experiment, 2.45 g of HA react with 1.50 g of XOH to form 2.91 g of XA. What is the percentage yield of the reaction? M.24 The acid H2AЈ (where AЈ stands for an unknown group of atoms) has molar mass 168 gиmolϪ1 . H2AЈ reacts with the base XOH (molar mass 125 gиmolϪ1 ) to produce H2O and the salt X2AЈ. In one experiment, 1.20 g of H2AЈ react with 1.00 g of XOH to form 0.985 g of X2AЈ. What is the percentage yield of the reaction? M.25 Aluminum metal reacts with chlorine gas to produce aluminum chloride. In one preparation, 255 g of aluminum is placed in a container holding 535 g of chlorine gas. After reaction ceases, it is found that 300. g of aluminum chloride has been produced. (a) Write the balanced equation for the reaction. (b) What mass of aluminum chloride can be produced by these reactants? (c) What is the percentage yield of aluminum chloride? F104 FUNDAMENTALS 1 What Are the Key Ideas? Matter is composed of atoms. The structures of atoms can be understood in terms of the theory of matter known as quantum mechanics, in which the properties of particles and waves merge together. Why Do We Need to Know This Material? Atoms are the fundamental building blocks of matter. They are the currency of chemistry in the sense that almost all the explanations of chemical phenomena are expressed in terms of atoms. This chapter explores the periodic variation of atomic properties and shows how quantum mechanics is used to account for the structures and therefore the properties of atoms. This material is in fact the foundation for almost all explanations in chemistry. What Do We Need to Know Already? We need to be familiar with the nuclear model of the atom and the general layout of the periodic table (Fundamentals Section B). We also need the concepts of kinetic and potential energy (Section A). W e need insight to think like a chemist. Chemical insight means that, when we look at an everyday object or a sample of a chemical, we can imagine the atoms that make it up. Not only that, we need to be able to plunge, in our mind’s eye, deep into the center of matter and imagine the internal structure of atoms. To visualize this structure and how it relates to the chemical properties of elements, we need to understand the electronic structure of an atom, the description of how its electrons are arranged around the nucleus. As soon as we start this journey into the atom, we encounter an extraordinary feature of our world. In the early twentieth century scientists expected to be able to use classical mechanics, the laws of motion proposed by Newton in the seventeenth century, to describe the structure of atoms (Section B). After all, classical mechanics had been tremendously successful for describing the motion of visible objects such as balls and planets. However, it soon became clear that classical mechanics fails when applied to electrons in atoms. New laws, which came to be known as quantum mechanics, had to be developed. This chapter builds an understanding of atomic structure in four steps. First, we review the experiments that led to our current nuclear model of the atom and see how spectroscopy reveals information about the arrangement of electrons around the nucleus. Then we describe the experiments that led to the replacement of classical mechanics by quantum mechanics, introduce some of its central features, and illustrate them by considering a very simple system. Next, we apply those ideas to the simplest atom of all, the hydrogen atom. Finally, we extend these concepts to the atoms of all the elements and see the foundations of the periodic table. INVESTIGATING ATOMS Dalton pictured atoms as featureless spheres, like billiard balls. Today, we know that atoms have an internal structure: they are built from even smaller subatomic particles. In this book, we deal with the three major subatomic particles: the electron, the proton, and the neutron. By investigating the internal structure of atoms, we can come to see how one element differs from another and see how their properties are related to the structures of their atoms. INVESTIGATING ATOMS 1.1 The Nuclear Model of the Atom 1.2 The Characteristics of Electromagnetic Radiation 1.3 Atomic Spectra QUANTUM THEORY 1.4 Radiation, Quanta, and Photons 1.5 The Wave–Particle Duality of Matter 1.6 The Uncertainty Principle 1.7 Wavefunctions and Energy Levels THE HYDROGEN ATOM 1.8 The Principal Quantum Number 1.9 Atomic Orbitals 1.10 Electron Spin 1.11 The Electronic Structure of Hydrogen MANY-ELECTRON ATOMS 1.12 Orbital Energies 1.13 The Building-Up Principle 1.14 Electronic Structure and the Periodic Table THE PERIODICITY OF ATOMIC PROPERTIES 1.15 Atomic Radius 1.16 Ionic Radius 1.17 Ionization Energy 1.18 Electron Affinity 1.19 The Inert-Pair Effect 1.20 Diagonal Relationships 1.21 The General Properties of the Elements 1 Chapter 1 ATOMS: THE QUANTUM WORLD 1.1 The Nuclear Model of the Atom The earliest experimental evidence for the internal structure of atoms was the discovery in 1897 of the first subatomic particle, the electron. The British physicist J. J. Thomson (Fig. 1.1) was investigating “cathode rays,” the rays that are emitted when a high potential difference (a high voltage) is applied between two metal contacts called electrodes in an evacuated glass tube (Fig. 1.2). Thomson showed that cathode rays are streams of negatively charged particles. They came from inside the atoms that made up the negatively charged electrode, which is called the cathode. Thomson found that the charged particles, which came to be called “electrons,” were the same regardless of the metal he used for the cathode. He concluded that they are part of the makeup of all atoms. Thomson was able to measure the value of e/me, the ratio of the magnitude of the electron’s charge e to its mass me. However, the values of e and me themselves were not known until later workers, most notably the American physicist Robert Millikan, carried out experiments that enabled them to determine the value of e. Millikan designed an ingenious apparatus in which he could observe tiny electrically charged oil droplets (Fig. 1.3). From the strength of the electric field required to overcome the pull of gravity on the droplets, he determined the values of the charges on the particles. Because each oil droplet contained more than one additional electron, he took the charge on one electron to be the smallest increment of charge between droplets. The modern value, which is obtained in a much more sophisticated way, is e ϭ 1.602 ϫ 10Ϫ19 C. A charge of Ϫe is considered to be “one unit” of negative charge, and e itself, which is called the fundamental charge, is taken to be “one unit” of positive charge. The mass of the electron was calculated by combining this charge with the value of e/me measured by Thomson; its modern value is 9.109 ϫ 10Ϫ31 kg. Although electrons have a negative charge, atoms overall have zero charge. Therefore, an atom must contain enough positive charge to cancel the negative charge. But where was the positive charge? Thomson suggested a model of an atom as a blob of a positively charged, jellylike material, with the electrons suspended in it like raisins in pudding. However, this model was overthrown in 1908 by another experimental observation. Ernest Rutherford (Fig. 1.4) knew that some elements, including radon, emit 2 CHAPTER 1 ATOMS: THE QUANTUM WORLD FIGURE 1.1 Joseph John Thomson (1856–1949), with the apparatus that he used to discover the electron. ϩ Ϫ Magnet Screen Electron beam Electron source FIGURE 1.2 The apparatus used by Thomson to investigate the properties of electrons. An electric field is set up between the two plates and a magnetic field is applied perpendicular to the electric field. ϩ Ϫ Oil spray Microscope Electric force Gravitational force FIGURE 1.3 A schematic diagram of Millikan’s oil-drop experiment. Oil is sprayed as a fine mist into a chamber containing a charged gas, and the location of an oil droplet is monitored by using a microscope. Charged particles (ions) are generated in the gas by exposing it to x-rays. The fall of the charged droplet is balanced by the electric field. Recall that C stands for coulomb, the SI unit of electric charge (Section A). streams of positively charged particles, which he called ␣ particles (alpha particles). He asked two of his students, Hans Geiger and Ernest Marsden, to shoot ␣ particles toward a piece of platinum foil only a few atoms thick (Fig. 1.5). If atoms were indeed like blobs of positively charged jelly, then all the ␣ particles would easily pass through the diffuse positive charge of the foil, with only occasional slight deflections in their paths. Geiger and Marsden’s observations astonished everyone. Although almost all the ␣ particles did pass through and were deflected only very slightly, about 1 in 20 000 was deflected through more than 90Њ, and a few ␣ particles bounced straight back in the direction from which they had come. “It was almost as incredible,” said Rutherford, “as if you had fired a 15-inch shell at a piece of tissue paper and it had come back and hit you.” The results of the Geiger–Marsden experiment suggested the nuclear model of the atom, in which there is a dense pointlike center of positive charge, the nucleus, surrounded by a large volume of mostly empty space in which the electrons are located. Rutherford reasoned that when a positively charged ␣ particle scored a direct hit on one of the minute but heavy platinum nuclei, the ␣ particle was strongly repelled by the positive charge of the nucleus and deflected through a large angle, like a tennis ball bouncing off a stationary cannonball (Fig. 1.6). Later work showed that the nucleus of an atom contains particles called protons, each of which has a charge of ϩe, that are responsible for the positive charge, and neutrons, which are uncharged particles. The number of protons in the nucleus is different for each element and is called the atomic number, Z, of the element (Section B). The total charge on an atomic nucleus of atomic number Z is ϩZe and, for the atoms to be electrically neutral, there must be Z electrons around it. In the nuclear model of the atom, all the positive charge and almost all the mass is concentrated in the tiny nucleus, and the negatively charged electrons surround the nucleus. The atomic number is the number of protons in the nucleus. 1.2 The Characteristics of Electromagnetic Radiation The question that scientists struggled with for years is how those Z electrons are arranged around the nucleus. To investigate the internal structures of objects as small as atoms, scientists observe them indirectly through the properties of the light the atoms emit when stimulated by heat or an electric discharge. The analysis of the light emitted or absorbed by substances is a hugely important branch of chemistry called spectroscopy. We shall see how atomic spectroscopy—spectroscopy applied to atoms— allowed scientists to propose a model of the electronic structure of atoms and to test their model against experiment. To do so, we need to understand the nature of light. Light is a form of electromagnetic radiation, which consists of oscillating (time-varying) electric and magnetic fields that travel through empty space at about 3 ϫ 108 mиsϪ1 , or at just over 670 million miles per hour. This speed is denoted c and called the “speed of light.” Visible light, radio waves, microwaves, and x-rays are all 1.2 THE CHARACTERISTICS OF ELECTROMAGNETIC RADIATION 3 FIGURE 1.4 Ernest Rutherford (1871–1937), who was responsible for many discoveries about the structure of the atom and its nucleus. Fluorescent screen Platinum foil 1 in 20,000 Scintillations ␣ particles FIGURE 1.5 Part of the experimental arrangement used by Geiger and Marsden. The ␣ particles came from a sample of the radioactive gas radon. They were directed through a hole into a cylindrical chamber with a zinc sulfide coating on the inside. The ␣ particles struck the platinum foil mounted inside the cylinder, and their deflections were measured by observing flashes of light (scintillations) where they struck the screen. About 1 in 20 000 ␣ particles was deflected through very large angles; most went through the thin foil with almost no deflection. ␣ particles Platinum atoms Nucleus FIGURE 1.6 Rutherford’s model of the atom explains why most ␣ particles pass almost straight through the platinum foil, whereas a very few—those scoring a direct hit on the nucleus—undergo very large deflections. Most of the atom is nearly empty space thinly populated by the atom’s electrons. The nuclei are much smaller relative to their atoms than shown here. types of electromagnetic radiation. All these forms of radiation transfer energy from one region of space to another. The warmth we feel from the Sun is carried to us through space as electromagnetic radiation. As a light ray passes an electron, its electric field pushes the electron first in one direction and then in the opposite direction, over and over again. That is, the field oscillates in both direction and strength (Fig. 1.7). The number of cycles (complete reversals of direction away from and back to the initial strength and direction) per second is called the frequency, ␯ (the Greek letter nu), of the radiation. The unit of frequency, 1 hertz (1 Hz), is defined as 1 cycle per second: 1 Hz ϭ 1 sϪ1 Electromagnetic radiation of frequency 1 Hz pushes a charge in one direction, then the opposite direction, and returns to the original direction once per second. The frequency of electromagnetic radiation that we see as visible light is close to 1015 Hz, and so its electric field returns to its initial direction about a thousand trillion (1015 ) times a second as it travels past a given point. An instantaneous snapshot of a wave of electromagnetic radiation spread through space would look like Fig. 1.7. The wave is characterized by its amplitude and wavelength. The amplitude is the height of the wave above the center line. The square of the amplitude determines the intensity, or brightness, of the radiation. The wavelength, ␭ (the Greek letter lambda), is the peak-to-peak distance. The wavelengths of visible light are close to 500 nm. Although 500 nm is only half of one-thousandth of a millimeter (so you might just be able to imagine it), it is much longer than the diameters of atoms, which are typically close to 0.2 nm. Different wavelengths of electromagnetic radiation correspond to different regions of the spectrum (see Table 1.1). Our eyes detect electromagnetic radiation with wavelengths in the range from 700 nm (red light) to 400 nm (violet light). Radiation in this range is called visible light, and the frequency of visible light determines its color. White light is a mixture of all wavelengths of visible light. The radiation from the Sun consists of white light and radiation of shorter and longer wavelengths called, respectively, ultraviolet and infrared radiation. Now imagine the wave in Fig. 1.7 zooming along at its actual speed, the speed of light, c. If the wavelength of the light is very short, very many complete oscillations pass a given point in a second (Fig. 1.8a). If the wavelength is long, fewer complete oscillations pass the point in a second (Fig. 1.8b). A short wavelength therefore corresponds to high-frequency radiation and a long wavelength corresponds to lowfrequency radiation. The precise relation is Wavelength ϫ frequency ϭ speed of light, or ␭n ϭ c (1)* 4 CHAPTER 1 ATOMS: THE QUANTUM WORLD Wavelength ␭ Amplitude FIGURE 1.7 The electric field of electromagnetic radiation oscillates in space and time. This diagram represents a “snapshot” of an electromagnetic wave at a given instant. The length of an arrow at any point represents the strength of the force that the field exerts on a charged particle at that point. The distance between the peaks is the wavelength of the radiation, and the height of the wave above the center line is the amplitude. TABLE 1.1 Color, Frequency, and Wavelength of Electromagnetic Radiation Frequency Wavelength Energy per Radiation type (1014 Hz) (nm, 2 sf)* photon (10؊19 J) x-rays and g-rays Ն103 Յ3 Ն103 ultraviolet 8.6 350 5.7 visible light violet 7.1 420 4.7 blue 6.4 470 4.2 green 5.7 530 3.8 yellow 5.2 580 3.4 orange 4.8 620 3.2 red 4.3 700 2.8 infrared 3.0 1000 2.0 microwaves and radio waves Յ10Ϫ3 Ն3 ϫ 106 Յ10Ϫ3 *The abbreviation sf denotes the number of significant figures in the data. The frequencies, wavelengths, and energies are typical values; they should not be regarded as precise. A star next to an equation number signals that it appears in the list of Key Equations on the Web site for this book: www.freeman.com/ chemicalprinciples5e. EXAMPLE 1.1 Calculating the wavelength of light of a known frequency Which has the longer wavelength, red light of frequency 4.3 ϫ 1014 Hz or blue light of frequency 6.4 ϫ 1014 Hz? Anticipate Because long-wavelength waves result in fewer oscillations as they pass a given point, we associate long wavelength with low frequency. Therefore, because red light has a lower frequency than blue light, we should expect it to have the longer wavelength. PLAN Use Eq. 1 to convert from frequency to wavelength. SOLVE 1.2 THE CHARACTERISTICS OF ELECTROMAGNETIC RADIATION 5 (a) (b) FIGURE 1.8 (a) Short-wavelength radiation: the vertical line shows how the electric field changes markedly at five successive instants, from top to bottom. (b) For the same five instants, the electric field of the long-wavelength radiation changes much less. The horizontal arrows in the uppermost images show that in each case the wave has traveled the same distance. Shortwavelength radiation has a high frequency, whereas long-wavelength radiation has a low frequency. 700 nm 470 nm Hz Evaluate As predicted, red light has a longer wavelength (700 nm) than blue light (470 nm). A note on good practice: It is a good idea to test your understanding with the self-tests that follow each worked example. Answers to the B self-tests can be found at the back of this book. Self-Test 1.1A Calculate the wavelengths of the light from traffic signals as they change. Assume that the lights emit the following frequencies: green, 5.75 ϫ 1014 Hz; yellow, 5.15 ϫ 1014 Hz; red, 4.27 ϫ 1014 Hz. [Answer: Green, 521 nm; yellow, 582 nm; red, 702 nm] Self-Test 1.1B What is the wavelength of the signal from a radio station transmitting at 98.4 MHz? For red light: from ␭␯ ϭ c written as ␭ ϭ c/␯, l = 2.998 * 108 mиs-1 4.3 * 1014 s-1 = 2.998 * 108 4.3 * 1014 m = 7.0 * 10-7 m For blue light: from ␭␯ ϭ c written as ␭ ϭ c/␯, l = 2.998 * 108 mиs-1 6.4 * 1014 s-1 = 2.998 * 108 6.4 * 1014 m = 4.7 * 10-7 m Hz c $++%++& c $++%++& Answer to all B self-tests are in the back of this book. # # As far as we know, there is neither an upper limit nor a lower limit to the wavelength of electromagnetic radiation (Fig. 1.9). Ultraviolet radiation is radiation at higher frequency than violet light; its wavelength is less than about 400 nm. This component of solar radiation is responsible for sunburn and tanning, but would destroy all living things on Earth if it were not largely prevented from reaching the surface of the Earth by the ozone layer. Infrared radiation, the radiation we experience as heat, has a lower frequency and longer wavelength than red light; its wavelength is greater than about 800 nm. Microwaves, which are used in radar and microwave ovens, have even longer wavelengths, in the millimeter-to-centimeter range. The color of light depends on its frequency and wavelength; long-wavelength radiation has a lower frequency than short-wavelength radiation. 1.3 Atomic Spectra Now that we know some of the properties of electromagnetic radiation, we can begin to see how it provides information about atomic structure. In this section we focus on the hydrogen atom, as it contains only a single electron. When an electric current is passed through a low-pressure sample of hydrogen gas, the sample emits light. The electric current, which is like a storm of electrons, breaks up the H2 molecules and excites the free hydrogen atoms to higher energies. These excited atoms quickly discard their excess energy by giving off electromagnetic radiation; then they combine to form H2 molecules again. When white light is passed through a prism, a continuous spectrum of light results because white light consists of all wavelengths of visible radiation (Fig. 1.10a). However, when the light emitted by excited hydrogen atoms is passed through a prism, the radiation is found to consist of a number of components, or spectral lines (Fig. 1.10b). The brightest line (at 656 nm) is red, and the excited atoms in the gas glow with this red light. Excited hydrogen atoms also emit ultraviolet and infrared radiation, which are invisible to the eye but can be detected electronically and photographically. The first person to identify a pattern in the lines of the visible region of the spectrum was Johann Balmer, a Swiss schoolteacher. In 1885, he noticed that the wavelengths of all the lines then known could be generated by the expression Shortly after, the Swedish spectroscopist Johannes Rydberg suggested a form of this expression that was to prove much more revealing: 1 l r 1 22 - 1 n2 n = 3,4, p l r n2 n2 - 4 n = 3,4, p 6 CHAPTER 1 ATOMS: THE QUANTUM WORLD Modern theories suggest that our concept of space breaks down on a scale of 10Ϫ34 m, so that may constitute a lower bound to the wavelength of electromagnetic radiation. 700 620 580 530 470 420 Red Orange Yellow Green Blue Violet 10 cm 1 mm 100 nm 1 pm 0.1 pm Radio Microwave Infrared Visible Ultraviolet x-ray Cosmic ray (nm)␭ ␥-ray 1 ␮m FIGURE 1.9 The electromagnetic spectrum and the names of its regions. The region we call “visible light” occupies a very narrow range of wavelengths. The regions are not drawn to scale. The components of different frequency or wavelength are called lines because, in the early spectroscopic experiments, the radiation from the sample was passed through a slit and then through a prism; the image of the slit was then focused on a photographic plate, where it appeared as a line. Infrared Visible Ultraviolet Balmer series Lyman series 954.6 656.3 486.1 434.0 410.2 121.6 102.6 97.3 Wavelength (nm) (b) (a) Infrared radiation Ultraviolet radiation FIGURE 1.10 (a) The infrared, visible, and ultraviolet spectrum. (b) The complete spectrum of atomic hydrogen. The spectral lines have been assigned to various groups called series, two of which are shown with their names. This expression is easily extended to account for other series of lines which soon came to be discovered, simply by replacing 22 by 32 , 42 , and so on. The modern form of the more general expression is often written in terms of the frequency ␯ ϭ c/␭ as (2) Here R is an empirical (experimentally determined) constant now known as the Rydberg constant; its value is 3.29 ϫ 1015 Hz. The Balmer series is the set of lines with n1 ϭ 2 (and n2 ϭ 3, 4, . . . ). The Lyman series, a set of lines in the ultraviolet region of the spectrum, has n1 ϭ 1 (and n2 ϭ 2, 3, . . . ). EXAMPLE 1.2 Identifying a line in the hydrogen spectrum Calculate the wavelength of the radiation emitted by a hydrogen atom for n1 ϭ 2 and n2 ϭ 3. Identify the spectral line in Fig. 1.10b. PLAN The frequency is given by Eq. 2. Convert frequency into wavelength by using Eq. 1. The wavelength should match one of the lines in the Balmer series in Fig. 1.10b. SOLVE n = R b 1 n2 1 - 1 n2 2 r n1 = 1,2, p , n2 = n1 + 1, n1 + 2, p 1.3 ATOMIC SPECTRA 7 From Eq. 2 with n1 ϭ 2 and n2 ϭ 3, n = R b 1 22 - 1 32 r = 5 36 R Energy 1 2 3 h␯5hRR /36 hR /9 hR /4 From ␭␯ ϭ c, l = c n = c (5R/36) = 36c 5R Now substitute the data: l = 36 * (2.998 * 108 mиs-1 ) 5 * (3.29 * 1015 s-1 ) = 6.57 * 10-7 m Evaluate This wavelength, 657 nm, corresponds to the red line in the Balmer series of lines in the spectrum. Self-Test 1.2A Repeat the calculation for n1 ϭ 2 and n2 ϭ 4 and identify the spectral line in Fig. 1.10b. [Answer: 486 nm; blue line] Self-Test 1.2B Repeat the calculation for n1 ϭ 2 and n2 ϭ 5 to and identify the spectral line in Fig. 1.10b. If we pass white light through a vapor composed of the atoms of an element, we see its absorption spectrum, a series of dark lines on an otherwise continuous spectrum (Fig. 1.11). The absorption lines have the same frequencies as the lines in the emission spectrum and suggest that an atom can absorb radiation only of those same frequencies. Absorption spectra are used by astronomers to identify elements in the outer layers of stars. We can begin to understand the presence of spectral lines if we suppose that an electron can exist with only certain energies when it is part of a hydrogen atom, and 657 nm c R $''''%''''& $'''%'''& that a line in an emission spectrum arises from a transition between two of the allowed energies. The presence of spectral lines of specific frequencies suggests that the energy of an electron in an atom is restricted to a series of discrete values, called energy levels. The difference in the energies of two levels is carried away by the electromagnetic radiation emitted by the atom. If that is the case, then Rydberg’s formula begins to suggest that the permitted energies are proportional to R/n2 , for then the difference in energy of the two states involved in the transition would be given by an expression that resembled the right-hand side of Rydberg’s formula. But why should the frequency of the emitted radiation be proportional to that energy difference? Furthermore, why does the Rydberg constant have the value that is observed? The observation of discrete spectral lines suggests that an electron in an atom can have only certain energies. QUANTUM THEORY Toward the end of the nineteenth century, scientists became increasingly perplexed as they gathered more information about electromagnetic radiation that could not be explained by classical mechanics, and the lines in the spectrum of hydrogen remained deeply puzzling. Then, from 1900 on, a series of imaginative suggestions were made, and by 1927 the puzzles had been resolved, only to be replaced by new and even more intriguing puzzles. In this part of the chapter we describe these other puzzles and their resolution in terms of quantum mechanics. We shall then see some of the peculiar, revolutionary results from quantum mechanics that will help us to understand atomic structure, beginning with the hydrogen atom. 1.4 Radiation, Quanta, and Photons Important clues to the nature of electromagnetic radiation came from observations of objects as they are heated. At high temperatures an object begins to glow—the phenomenon of incandescence. As the object is heated to higher temperatures it glows more brightly and the color of light it gives off changes from red through orange and yellow toward white. Those are qualitative observations. To understand what the color changes mean, scientists had to study the effect quantitatively. They measured the intensity of radiation at each wavelength and repeated the measurements at a variety of different temperatures. These experiments caused one of the greatest revolutions that has ever occurred in science. Figure 1.12 shows some of the experimental results. The “hot object” is known as a black body (even though it might be glowing white hot!). The name signifies that the object does not favor one wavelength over another in the sense of absorbing a particular wavelength preferentially or emitting one preferentially. The curves in Fig. 1.12 show the intensity of black-body radiation, the radiation emitted at different wavelengths by a heated black body, for a series of temperatures. Notice that as the temperature rises, the maximum intensity of the radiation emitted occurs at shorter and shorter wavelengths. Thinking point: Why does a heated metal object first glow red hot and then white hot? 8 CHAPTER 1 ATOMS: THE QUANTUM WORLD FIGURE 1.11 When white light shines through a vapor, radiation is absorbed by the atoms at frequencies that correspond to their excitation energies. In this small section of the spectrum of the Sun, it is possible to identify which atoms in its outer layers are absorbing the radiation from the incandescence below. Many of the lines have been ascribed to hydrogen, showing that hydrogen is present in the cooler outer layers of the Sun. 200 150 100 50 0 2 4 6 8 100 1000 K 950 K 900 K 850 K 800 K Wavelength (μm) Energydensity(J⋅m−4 ) FIGURE 1.12 The intensity of radiation emitted by a heated black body as a function of wavelength. As the temperature increases, the total energy emitted (the area under the curve) increases sharply, and the maximum intensity of emission moves to shorter wavelengths. (To obtain the energy in a volume V and at wavelengths ␭ and ␭ ϩ ⌬␭, multiply the energy density by V and ⌬␭.) Ultraviolet x-rays γ rays Infrared and radio spectrum 400 450 500 550 600 Wavelength, l(nm) 650 700 750 Two crucial pieces of experimental information about black-body radiation were discovered in the late nineteenth century. In 1879, Josef Stefan investigated the increasing brightness of a black body as it is heated and discovered that the total intensity of radiation emitted over all wavelengths increases as the fourth power of the absolute temperature (Fig. 1.13). This quantitative relation is now called the Stefan–Boltzmann law and is usually written Total intensity ϭ constant ϫ T4 (3a) The experimental value of the constant is 5.67 ϫ 10Ϫ8 WиmϪ2 иKϪ4 , where W denotes watts (1 W ϭ 1 JиsϪ1 ). A few years later, in 1893, Wilhelm Wien examined the shift in color of black-body radiation as the temperature increases and discovered that the wavelength corresponding to the maximum in the intensity, ␭max, is inversely proportional to the absolute temperature, ␭max 1/T (that is, as T increases the wavelength decreases), and therefore that ␭max ϫ T is a constant (Fig. 1.14). This quantitative result is now called Wien’s law and is normally written T␭max ϭ constant (3b) The empirical (experimental) value of the constant in this expression is 2.9 Kиmm. r 1.4 RADIATION, QUANTA, AND PHOTONS 9 6 4 2 0 Intensity(104W.m−2 ) 0 200 400 600 800 1000 Temperature (K) FIGURE 1.13 The total intensity of radiation emitted by a heated black body increases as the fourth power of the temperature, so a body at 1000 K emits more than 120 times as much energy as is emitted by the same body at 300 K. 0 0.005 0.01 3 2 1 0 Wavelengthofmaximum,lmax(10−5 m) 1/Temperature, 1/T (K−1 ) (100K) (200K) (400K) FIGURE 1.14 As the temperature is raised (1/T decreases), the wavelength of maximum emission shifts to smaller values. From T ϭ constant/␭max, T = 2.9 * 10-3 mиK 4.90 * 10-7 m = 2.9 * 10-3 4.90 * 10-7 K = 5.9 * 103 K Evaluate The surface temperature of the Sun is about 5900 K, in accord with our expectation. Self-Test 1.3A In 1965, electromagnetic radiation with a maximum at 1.05 mm (in the microwave region) was discovered to pervade the universe. What is the temperature of “empty” space? [Answer: 2.76 K] Self-Test 1.3B A red giant is a late stage in the evolution of a star. The average wavelength maximum at 700. nm shows that a red giant cools as it dies. What is the surface temperature of a red giant? For nineteenth-century scientists, the obvious way to account for the laws of blackbody radiation was to use classical physics to derive its characteristics. However, much to their dismay, they found that the characteristics they deduced did not match their observations. Worst of all was the ultraviolet catastrophe: classical physics predicted that any hot body should emit intense ultraviolet radiation and even x-rays and ␥-rays! According to classical physics, a hot object would devastate the countryside with highfrequency radiation. Even a human body at 37ЊC would glow in the dark. There would, in fact, be no darkness. 490 nm 6000 K The name of the Stefan–Boltzmann law recognizes Ludwig Boltzmann’s theoretical contribution. 2.9 mm 490 nm $++%++& $'''%'''& EXAMPLE 1.3 Determining temperature from black-body radiation A star can be regarded as a black body, so we can use the properties of black-body radiation to measure its temperature. The maximum intensity of solar radiation occurs at 490. nm. What is the temperature of the surface of the Sun? Anticipate We should be aware that objects glowing white hot are at temperatures of several thousand degrees. PLAN Use Wien’s law in the form T ϭ constant/␭max. SOLVE The suggestion that resolved the problem came in 1900 from the German physicist Max Planck. He proposed that the exchange of energy between matter and radiation occurs in quanta, or packets, of energy. Planck focused his attention on the hot, rapidly oscillating electrons and atoms of the black body. His central idea was that a charged particle oscillating at a frequency n can exchange energy with its surroundings by generating or absorbing electromagnetic radiation only in discrete packets of energy E ϭ hn (4)* The constant h, now called Planck’s constant, has the value 6.626 ϫ 10Ϫ34 Jиs. If the oscillating atom releases an energy E into the surroundings, then radiation of frequency ␯ ϭ E/h will be detected. Planck’s hypothesis implies that radiation of frequency ␯ can be generated only if an oscillator of that frequency has acquired the minimum energy required to start oscillating. At low temperatures, there is not enough energy available to stimulate oscillations at very high frequencies, and so the object cannot generate high-frequency, ultraviolet radiation. As a result, the intensity curves in Fig. 1.12 die away at high frequencies (short wavelengths) and the ultraviolet catastrophe is avoided. In contrast, in classical physics it was assumed that an oscillator could oscillate with any energy and therefore, even at low temperatures, high-frequency oscillators could contribute to the emitted radiation. Planck’s hypothesis is quantitatively successful, too, because not only was he able to use his proposal to derive the Stefan–Boltzmann and Wien laws but he was also able to calculate the variation of intensity with wavelength and to obtain a curve that matched the experimental curve almost exactly. To achieve this successful theory, Planck had discarded classical physics, which puts no restriction on how small an amount of energy may be transferred from one object to another. He had proposed instead that energy is transferred in discrete packets. To justify such a dramatic revolution, more evidence was needed. That evidence came from the photoelectric effect, the ejection of electrons from a metal when its surface is exposed to ultraviolet radiation (Fig. 1.15). The experimental observations were as follows: 1 No electrons are ejected unless the radiation has a frequency above a certain threshold value characteristic of the metal. 2 Electrons are ejected immediately, however low the intensity of the radiation. 3 The kinetic energy of the ejected electrons increases linearly with the frequency of the incident radiation. A note on good practice: We say that a property y varies linearly with x if the relation between y and x can be written y ϭ b ϩ mx, where b and m are constants. When y ϭ mx (that is, when b ϭ 0), we say that y is proportional to x. See Appendix 1E. Albert Einstein found an explanation of these observations and, in the process, profoundly changed our conception of the electromagnetic field. He proposed that electromagnetic radiation consists of particles, which were later called photons. Each photon can be regarded as a packet of energy, and the energy of a single photon is related to the frequency of the radiation by Eq. 4 (E ϭ h␯). For example, ultraviolet photons are more energetic than photons of visible light, which has lower frequencies. According to this photon model of electromagnetic radiation, we can visualize a beam of red light as a stream of photons, each having the same energy, yellow light as a stream of photons, each of higher energy, and green light as a stream of photons, each of higher energy still. It is important to note that the intensity of radiation is an indication of the number of photons present, whereas E ϭ h␯ is a measure of the energy of each individual photon. 10 CHAPTER 1 ATOMS: THE QUANTUM WORLD The word quantum comes from the Latin for amount—literally, “How much?” In fact, Planck struggled for years to keep classical mechanics alive, believing that his introduction of the quantum was just a mathematical trick. Einstein is often credited with establishing the physical reality of quantizaton. Metal Ultraviolet radiation source Electrons FIGURE 1.15 When a metal is illuminated with ultraviolet radiation, electrons are ejected, provided the frequency is above a threshold frequency that is characteristic of the metal. EXAMPLE 1.4 Calculating the energy of a photon What is (a) the energy of a single photon of blue light of frequency 6.4 ϫ 1014 Hz; (b) the energy per mole of photons of the same frequency? PLAN (a) Use Eq. 4 to find the energy of light of a given frequency. (b) Multiply the energy of one photon by the number of photons per mole, which is Avogadro’s constant (Section E). 1.4 RADIATION, QUANTA, AND PHOTONS 11 Energy Energy brought by photon, h␯ Kinetic energy of electron, Energy needed to remove electron, ⌽ mev21 2 FIGURE 1.16 In the photoelectric effect, a photon with energy hn strikes the surface of a metal and its energy is absorbed by an electron. If the energy of the photon is greater than the work function, ⌽, of the metal, the electron absorbs enough energy to break away from the metal. The kinetic energy of the ejected electron is the difference between the energy of the photon and the work function: mev2 ϭ h␯ Ϫ ⌽.1 2 (a) From E(1 photon) ϭ h␯, E(1 photon) ϭ (6.626 ϫ 10Ϫ34 Jиs) ϫ (6.4 ϫ 1014 Hz) ϭ 4.2 ϫ 10Ϫ19 J (b) From E(per mole of photons) ϭ NAE, To derive the energy in part (a), we have used 1 Hz ϭ 1 sϪ1 , so Jиs ϫ Hz ϭ Jиs ϫ sϪ1 ϭ J. Self-Test 1.4A What is the energy of a photon of yellow light of frequency 5.2 ϫ 1014 Hz? [Answer: 3.4 ϫ 10Ϫ19 J] Self-Test 1.4B What is the energy of a photon of orange light of frequency 4.8 ϫ 1014 Hz? The characteristics of the photoelectric effect are easy to explain if we visualize electromagnetic radiation as consisting of a stream of photons. If the incident radiation has frequency ␯, it consists of photons of energy h␯. These particles collide with the electrons in the metal. The energy required to remove an electron from the surface of a metal is called the work function of the metal and denoted ⌽ (uppercase phi). If the energy of a photon is less than the energy required to remove an electron from the metal, then an electron will not be ejected, regardless of the intensity of the radiation (the rate at which the photons arrive). However, if the energy of the photon, h␯, is greater than ⌽, then an electron is ejected with a kinetic energy, equal to the difference between the energy of the incoming photon and the work function: Ek ϭ h␯ Ϫ ⌽ (Fig. 1.16). It follows that ⌽ (5) What does this equation tell us? Because the kinetic energy of the ejected electrons varies linearly with frequency, a plot of the kinetic energy against the frequency of the supplied radiation should look like the graph in Fig. 1.17, a straight line of slope h, the same for all metals, and have an extrapolated intercept with the vertical axis at Ϫ⌽, different for each metal. The intercept with the horizontal axis (corresponding to zero kinetic energy of the ejected electron) is at ⌽/h in each case. We can now interpret the experimental observations of the photoelectric effect in light of Einstein’s theory: 1 An electron can be driven out of the metal only if it receives from the photon during the collision at least a certain minimum energy equal to the work function, ⌽. Therefore, the frequency of the radiation must have a certain minimum value if electrons are to be ejected. This minimum frequency depends on the work function and hence on the identity of the metal (as shown in Fig. 1.17). 2 Provided a photon has enough energy, a collision results in the immediate ejection of an electron. 3 The kinetic energy of the electron ejected from the metal increases linearly with the frequency of the incident radiation according to Eq. 5. -hn=1 2mev2 Ek = 1 2mev2 , = 2.5 * 105 J mol-1 , or 250 kJ mol-1 E(per mole of photons) = (6.022 * 1023 mol-1 ) * (4.2 * 10-19 J) Kinetic energy Energy Energy required of ejected supplied to eject photon electron by photon ()* " " SOLVE EXAMPLE 1.5 Analyzing the photoelectric effect The speed of an electron emitted from the surface of a sample of potassium by a photon is 668 kmиsϪ1 . (a) What is the kinetic energy of the ejected electron? (b) What is the wavelength of the radiation that caused photoejection of the electron? (c) What is the longest wavelength of electromagnetic radiation that could eject electrons from potassium? The work function of potassium is 2.29 eV. 12 CHAPTER 1 ATOMS: THE QUANTUM WORLD Frequency of incident radiation, ␯ Kineticenergyofejectedelectron,EK Rb K Na 5.051014 Hz(593nm) 5.441014 Hz(551nm) 5.561014 Hz(539nm) Slope = h ⌽/h −⌽ FIGURE 1.17 When photons strike a metal, no electrons are ejected unless the incident radiation has a frequency above a value characteristic of the metal. The kinetic energy of the ejected electrons varies linearly with the frequency of the incident radiation. The inset shows the relation of the slope and the two intercepts to the parameters in Eq. 5. (a) From = 2.03 * 10-19 J Ek = 1 2 * (9.109 * 10-31 kg) * (6.68 * 105 mиs-1 )2 Ek = 1 2mv2 , (b) Convert the work function from electronvolts to joules. 2.29 eV * 1.602 * 10-19 J 1 eV = 3.67 * 10-19 J From 1 2mev2 = hn - ⌽, hn = ⌽ + 1 2mev2 = ⌽ + Ek, so n = 5.70 * 10-19 J h hn = 3.67 * 10-19 J + 2.03 * 10-19 J = 5.70 * 10-19 J ⌽ Ek h␯ Now use ␭ ϭ c/␯: = 3.49 * 10-7 m or 349 nm l = (3.00 * 108 mиs-1 ) * (6.626 * 10-34 Jиs) 5.70 * 10-19 J PLAN (a) Find the kinetic energy of the ejected electron from To use SI base units (which is often sensible in calculations), first convert the speed to meters per second. (b) The energy of the ejected electron is equal to the difference in energy of the incident radiation and the work function (Eq. 5). The photon needs to provide enough energy to eject the electron from the surface (the work function) as well as to cause it to move at 668 kmиsϪ1 . Convert the value of the work function into joules and use Eq. 5 to determine the value of h␯ for the photon. Then use l␯ ϭ c to convert that energy to wavelength. Conversion factors and fundamental constants can be found inside the back cover of the book. (c) The longest wavelength of radiation that can eject electrons from a substance is the wavelength that results in the ejected electron having zero kinetic energy. SOLVE Ek = 1 2mev2 . Self-Test 1.5A The work function of zinc is 3.63 eV. What is the longest wavelength of electromagnetic radiation that could eject electrons from zinc? [Answer: 342 nm] Self-Test 1.5B The speed of an electron that is emitted from the surface of a sample of zinc by a photon is 785 kmиsϪ1 . (a) What is the kinetic energy of the ejected electron? (b) The work function of zinc is 3.63 eV. What is the wavelength of the radiation that caused photoejection of the electron? The existence of photons and the relation between the energy and frequency of a photon helps to answer one of the questions posed by the spectrum of atomic hydrogen. At the end of Section 1.3 we started to form the view that a spectral line arises from a transition between two energy levels. Now we can see that if the energy difference is carried away as a photon, then the frequency of an individual line in a spectrum is related to the energy difference between two energy levels involved in the transition (Fig. 1.18): (6)* This relation is called the Bohr frequency condition. If the energies on the right of this expression are each proportional to hR /n2 , then we have accounted for Rydberg’s formula. We still have to explain why the energies have this form, but we have made progress. Studies of black-body radiation led to Planck’s hypothesis of the quantization of electromagnetic radiation. The photoelectric effect provides evidence of the particulate nature of electromagnetic radiation. 1.5 The Wave–Particle Duality of Matter The photoelectric effect strongly supports the view that electromagnetic radiation consists of photons that behave like particles. However, there is plenty of evidence to show that electromagnetic radiation behaves like waves! The most compelling evidence is the observation of diffraction, the pattern of high and low intensities generated by an object in the path of a ray of light (Fig. 1.19). A diffraction pattern results when the peaks and troughs of waves traveling along one path interfere with the peaks and troughs of waves traveling along another path. If the peaks coincide, the amplitude of the wave (its height) is enhanced; we call this enhancement constructive interference (Fig. 1.20a). If the peaks of one wave coincide with the troughs of another wave, the amplitude of the wave is diminished by destructive interference (Fig. 1.20b). This effect is the basis of a number of useful techniques for studying matter. For example, x-ray diffraction is one of the most important tools for studying the structures of molecules (see Major Technique 4, following Chapter 5). You can appreciate why scientists were puzzled! The results of some experiments (the photoelectric effect) compelled them to the view that electromagnetic radiation is particlelike. The results of other experiments (diffraction) compelled them equally hn = Eupper - Elower = 5.42 * 10-7 m or 542 nm l = (3.00 * 108 mиs-1 ) * (6.626 * 10-34 Jиs) 3.67 * 10-19 J 1.5 THE WAVE–PARTICLE DUALITY OF MATTER 13 (c) To find the longest wavelength of radiation able to eject an electron, set Ek ϭ 0 in Eq. 5, so h␯ ϭ ⌽, and therefore ␭ ϭ ch/⌽. ⌽ Ek = 0 h␯ Energy A B FIGURE 1.18 When an atom undergoes a transition from a state of higher energy to one of lower energy, it loses energy that is carried away as a photon. The greater the energy difference, the higher the frequency (and the shorter the wavelength) of the radiation emitted. Compare the high frequency of the emission during a transition from state A to that from state B. Screen Diffractionpattern Incident light Constructive interference (a) (b) FIGURE 1.19 In this illustration, the peaks of the waves of electromagnetic radiation are represented by orange lines. When radiation coming from the left (the vertical lines) passes through a pair of closely spaced slits, circular waves are generated at each slit. These waves interfere with each other. Where they interfere constructively (as indicated by the positions of the dotted lines), a bright line is seen on the screen behind the slits; where the interference is destructive, the screen is dark. FIGURE 1.20 (a) Constructive interference. The two component waves (left) are “in phase” in the sense that their peaks and troughs coincide. The resultant (right) has an amplitude that is the sum of the amplitudes of the components. The wavelength of the radiation is not changed by interference, only the amplitude is changed. (b) Destructive interference. The two component waves are “out of phase” in the sense that the troughs of one coincide with the peaks of the other. The amplitude of the resultant is much lower than in the case of constructive interference of either component. firmly to the view that electromagnetic radiation is wavelike. Thus we are brought to the heart of modern physics. Experiments oblige us to accept the wave-particle duality of electromagnetic radiation, in which the concepts of waves and particles blend together. In the wave model, the intensity of the radiation is proportional to the square of the amplitude of the wave. In the particle model, intensity is proportional to the number of photons present at each instant. If electromagnetic radiation, which for a long time had been regarded as wavelike, has a dual character, could it be that matter, which since Dalton’s day had been regarded as consisting of particles, also has wavelike properties? In 1925, the French scientist Louis de Broglie proposed that all particles should be regarded as having wavelike properties. He went on to suggest that the wavelength associated with the “matter wave” is inversely proportional to the particle’s mass, m, and speed, v, and that (7a) The product of mass and speed is called the linear momentum, p, of a particle, and so this expression is more simply written as the de Broglie relation: (7b)* EXAMPLE 1.6 Calculating the wavelength of a particle In order to appreciate why the wavelike properties of particles had not been noticed, calculate the wavelength of a particle of mass 1 g traveling at 1 mиsϪ1 . Anticipate Because the particle is much heavier than any subatomic particle, we should expect a very short wavelength. PLAN Use Eq. 7a to find the wavelength of a particle of known mass. SOLVE l = h p l = h mv 14 CHAPTER 1 ATOMS: THE QUANTUM WORLD From ␭ ϭ h/mv, Evaluate As expected, this wavelength is very—in fact, undetectably—small; the same is true for any macroscopic (visible) object traveling at normal speeds. A note on good practice: Notice how, in the calculations, we kept all the units, writing them separately, and then canceling and multiplying them like ordinary numbers. We did not simply “guess” that the wavelength would turn out in meters. This procedure helps you to detect errors and ensures that your answer has the correct units. Self-Test 1.6A Calculate the wavelength of an electron traveling at 1/1000 the speed of light (see the inside back cover of this book for the mass of an electron). [Answer: 2.43 nm] Self-Test 1.6B Calculate the wavelength of a rifle bullet of mass 5.0 g traveling at twice the speed of sound (the speed of sound is 331 mиsϪ1 ). The wavelike character of electrons was confirmed by showing that they could be diffracted. The experiment was first performed in 1925 by two American scientists, Clinton Davisson and Lester Germer, who directed a beam of fast electrons at a single = 7 * 10-31 m = 6.626 * 10-34 1 * 10-3 kgиm2 иs-2 иs kgиmиs-1 l = 6.626 * 10-34 Jиs (1 * 10-3 kg) * (1 mиs-1 ) crystal of nickel. The regular array of atoms in the crystal, with centers separated by 250 pm, acts as a grid that diffracts waves; and a diffraction pattern was observed (Fig. 1.21). Since then, some molecules have been shown to undergo diffraction, and there is no doubt that particles have a wavelike character. Indeed, electron diffraction is now an important technique for determining the structures of molecules and exploring the structures of solid surfaces. Electrons (and matter in general) have both wavelike and particlelike properties. 1.6 The Uncertainty Principle The discovery of wave–particle duality not only changes our understanding of electromagnetic radiation and matter, but also sweeps away the foundations of classical physics. In classical mechanics, a particle has a definite trajectory, or path on which location and linear momentum are specified at each instant. However, we cannot specify the precise location of a particle if it behaves like a wave: think of a wave in a guitar string, which is spread out all along the string, not localized at a precise point. A particle with a precise linear momentum has a precise wavelength; but, because it is meaningless to speak of the location of a wave, it follows that we cannot specify the location of a particle that has a precise linear momentum. Duality means that the electron in a hydrogen atom cannot be described as orbiting the nucleus with a definite trajectory. The popular picture of an electron in orbit around the nucleus is just plain wrong. The difficulty will not go away. Wave–particle duality denies the possibility of specifying the location if the linear momentum is known, and so we cannot specify the trajectory of particles. If we know that a particle is here at one instant, we can say nothing about where it will be an instant later! The impossibility of knowing the precise position if the linear momentum is known precisely is an aspect of the complementarity of location and momentum—if one property is known the other cannot be known simultaneously. The Heisenberg uncertainty principle, which was formulated by the German scientist Werner Heisenberg in 1927, expresses this complementarity quantitatively. It states that, if the location of a particle is known to within an uncertainty ⌬x, then the linear momentum, p, parallel to the x-axis can be known simultaneously only to within an uncertainty ⌬p, where (8)* The symbol U, which is read “h bar,” means h/2␲, a useful combination that is found widely in quantum mechanics. What does this equation tell us? The product of the uncertainties in two simultaneous measurements cannot be less than a certain constant value. Therefore, if the uncertainty in position is very small (⌬x very small), then the uncertainty in linear momentum must be large, and vice versa (Fig. 1.22). The uncertainty principle has negligible practical consequences for macroscopic objects, but it is of profound importance for subatomic particles such as the electrons in atoms. EXAMPLE 1.7 Using the uncertainty principle Estimate the minimum uncertainty in (a) the position of a marble of mass 1.0 g given that its speed is known to within Ϯ1.0 mmиsϪ1 and (b) the speed of an electron confined to within the diameter of a typical atom (200. pm). Anticipate We should expect the uncertainty in the position of an object as heavy as a marble to be very small but the uncertainty in the speed of an electron, which has a very small mass and is confined to a small region, to be very large. PLAN (a) The uncertainty ⌬p is equal to m⌬v, where ⌬v is the uncertainty in the speed; we use Eq. 8 to estimate the minimum uncertainty in position, ⌬x, along the direction of the ¢p¢x Ú 1 2 U 1.6 THE UNCERTAINTY PRINCIPLE 15 FIGURE 1.21 Davisson and Germer showed that electrons produce a diffraction pattern when reflected from a crystal. G. P. Thomson, working in Aberdeen, Scotland, showed that they also produce a diffraction pattern when they pass through a very thin gold foil. The latter is shown here. G. P. Thomson was the son of J. J. Thomson, who identified the electron (Section 1.1). Both received Nobel prizes: J. J. for showing that the electron is a particle and G. P. for showing that it is a wave. (a) (b) FIGURE 1.22 A representation of the uncertainty principle. (a) The location of the particle is ill defined, and so the momentum of the particle (represented by the arrow) can be specified reasonably precisely. (b) The location of the particle is well defined, and so the momentum cannot be specified very precisely. travel of the marble from (the minimum value of the product of uncertainties). (b) We assume ⌬x to be the diameter of the atom and use Eq. 8 to estimate ⌬p; by using the mass of the electron inside the back cover, we find ⌬v from ⌬p ϭ m⌬v. SOLVE (a) First we convert mass and speed into SI base units. The mass, m, is 1.0 ϫ 10Ϫ3 kg, and the uncertainty in the speed, ⌬v, is 2 ϫ (1.0 ϫ 10 Ϫ3 mиsϪ1 ). The minimum uncertainty in position, ⌬x, is then: ¢p¢x = 1 2 U 16 CHAPTER 1 ATOMS: THE QUANTUM WORLD From and ⌬p ϭ m⌬v,¢p¢x = 1 2 U m¢v¢x = U 2 or ¢x = U 2m¢v Evaluate As expected, this uncertainty is very small. A note on good practice: Notice that to manipulate the units we have expressed derived units (J in this case) in terms of base units. Notice too that we are using the more precise values of the fundamental constants given inside the back cover (rather than the less precise values quoted in the text) to ensure reliable results. (b) The mass of the electron is given inside the back cover; the diameter of the atom is 200. ϫ 10Ϫ12 m, or 2.00 ϫ 10Ϫ10 m. The uncertainty in the speed, ⌬v, is equal to ⌬p/m: = 2.6 * 10-29 kgиm2 иs-2 иs kgиmиs-1 = 2.6 * 10-29 m = 1.054 57 * 10-34 2 * 1.0 * 10-3 * 2.0 * 10-3 Jиs kgиmиs-1 ¢x = 1.054 57 * 10-34 Jиs 2 * (1.0 * 10-3 kg) * (2.0 * 10-3 mиs-1 ) From ⌬x ϭ /2m⌬v,U 1.0 g 2.0 mmиsϪ1 From and ⌬p ϭ m⌬v,¢p¢x = 1 2 U ¢v = ¢p m = ¢p=U/2¢x U 2m¢x From ⌬x ϭ U/2m⌬v, Evaluate As predicted, the uncertainty in the speed of the electron is very large, nearly Ϯ150 kmиsϪ1 . = 2.89 * 105 kgиm2 иs-2 иs kgиm = 2.89 * 105 mиs-1 = 1.054 57 * 10-34 2 * 9.109 39 * 10-31 * 2.0 * 10-10 Jиs kgиm ¢v = 1.054 57 * 10-34 Jиs 2 * (9.109 39 * 10-31 kg) * (2.00 * 10-10 m) me 200. pm J $+%+& # ('')''* ('')''* (''')'''* ('')''* Self-Test 1.7A A proton is accelerated in a cyclotron to a very high speed that is known to within 3.0 ϫ 102 kmиsϪ1 . What is the minimum uncertainty in its position? [Answer: 0.11 pm] Self-Test 1.7B The police are monitoring an automobile of mass 2.0 t (1 t ϭ 103 kg) speeding along a highway. They are certain of the location of the vehicle only to within 1 m. What is the minimum uncertainty in the speed of the vehicle? The location and momentum of a particle are complementary; that is, the location and the momentum cannot both be known simultaneously with arbitrary precision. The quantitative relation between the precision of each measurement is described by the Heisenberg uncertainty principle. 1.7 Wavefunctions and Energy Levels If they were to account for the spectrum of atomic hydrogen and then atoms of the other elements, scientists of the early twentieth century had to revise the nineteenthcentury description of matter to take into account wave–particle duality. One of the first people to formulate a successful theory (in 1927) was the Austrian scientist Erwin Schrödinger (Fig. 1.23), who introduced a central concept of quantum theory. We shall illustrate the concept with a simple example (a particle trapped in a box) that reveals a number of important aspects of his approach. At the end of this section we shall be ready to move on to the hydrogen atom and see how the concepts apply to it and answer the remaining questions about its spectrum. Because particles have wavelike properties, we cannot expect them to behave like pointlike objects moving along precise trajectories. Schrödinger’s approach was to replace the precise trajectory of a particle by a wavefunction, ␺ (the Greek letter psi), a mathematical function with values that vary with position. Some wavefunctions are very simple: shortly we shall meet one that is simply sin x; when we get to the hydrogen atom, we shall meet one that is like eϪx . The German physicist Max Born suggested how the wavefunction should be interpreted physically. The Born interpretation of the wavefunction is that the probability of finding the particle in a region is proportional to the value of ␺2 (Fig. 1.24). To be precise, ␺2 is a probability density, the probability that the particle will be found in a small region divided by the volume of the region. “Probability density” is the analog of the more familiar “mass density,” the mass of a region divided by the volume of the region. To calculate the mass of a region, we multiply its mass density by the volume of the region. Likewise, to calculate the probability that a particle is in a region, we multiply the probability density by the volume of the region. For instance, if ␺2 ϭ 0.1 pmϪ3 at a point, then the probability of finding the particle in a region of volume 2 pm3 located at that point would be (0.1 pmϪ3 ) ϫ (2 pm3 ) ϭ 0.2, or 1 chance in 5. Wherever ␺2 is large, the particle has a high probability density; wherever ␺2 is small, the particle has only a low probability density. A note on good practice: Distinguish between probability and probability density: the former is unitless and lies between 0 (certainly not there) and 1 (certainly there), but the latter has the dimensions of 1/volume. To go from probability density to probability, multiply it by the volume of interest. Because the square of any number is positive, we don’t have to worry about ␺ having a negative sign in some regions of space (as a function such as sin x has): probability density is never negative. Wherever ␺, and hence ␺2 , is zero, the particle has zero probability density. A location where ␺ passes through zero (not just reaching zero) is called a node of the wavefunction; so we can say that a particle has zero probability density wherever the wavefunction has nodes. To calculate the wavefunction for any particle we use Schrödinger’s great contribution, the Schrödinger equation. Although we shall not use the equation directly (we shall need to know only the form of some of its solutions, not how those solutions are found), 1.7 WAVEFUNCTIONS AND ENERGY LEVELS 17 FIGURE 1.23 Erwin Schrödinger (1887–1961). x ␺ 2␺ or2 ␺␺ FIGURE 1.24 The Born interpretation of the wavefunction. The probability density (the blue line) is given by the square of the wavefunction and depicted by the density of shading in the band beneath. Note that the probability density is zero at a node. A node is a point where the wavefunction (the orange line) passes through zero, not merely approaches zero. As you go on in quantum mechanics, you will see that wavefunctions may be “complex” in the technical sense of involving i ϭ . We ignore that possibility here. 2(-1) Note the “passes through”; merely becoming zero is not enough to be considered a node. it is appropriate at least to see what it looks like. For a particle of mass m moving in one dimension in a region where the potential energy is V(x) the equation is (9a) The term d2 ␺/dx2 can be thought of as a measure of how sharply the wavefunction is curved. The left-hand side of the Schrödinger equation is commonly written H␺, where H is called the hamiltonian for the system; then the equation takes the deceptively simple form H␺ ϭ E␺ (9b) The Schrödinger equation is used to calculate both the wavefunction ␺ and the corresponding energy E. To understand what is involved, we shall consider one of the simplest systems, a single particle of mass m confined in a one-dimensional box between two rigid walls a distance L apart, a so-called particle in a box (Fig. 1.25). The equation can be solved quite easily for this system (as we show below). The idea to keep in mind is that only certain wavelengths can exist in the box, just as a stretched string can support only certain wavelengths. Think of a guitar string: because it is tied down at each end, it can support only shapes like the ones shown in Fig. 1.25. The shapes of the wavefunctions for the particle in the box are the same as the displacements of a vibrating string. Their mathematical form is (10) The integer n labels the wavefunctions and is called a “quantum number.” In general, a quantum number is an integer (or, in some cases, Section 1.10, a half-integer) that labels a wavefunction, specifies a state, and can be used to calculate the value of a property of the system. For example, we can use n to find an expression for the energy corresponding to each wavefunction. cn(x) = a 2 L b 1/2 sin a n␲x L b n = 1, 2, Á d2 c dx2 + V(x)c = Ec- U2 2m 18 CHAPTER 1 ATOMS: THE QUANTUM WORLD HOW DO WE DO THAT (LEVEL 1)? The kinetic energy of a particle of mass m is related to its speed, v, by Ek ϭ We can relate this energy to the wavelength of the particle by noting that the linear momentum is p ϭ mv and then using the de Broglie relation (Eq. 7): We assume that the potential energy of the particle is zero everywhere inside the box, and so the total energy, E, is given by the expression for Ek alone. At this point, we recognize that (like a guitar string) only whole-number multiples of half-wavelengths can fit into the box (see Fig. 1.25; the waves have one bulge, two bulges, three bulges, and so forth, with each “bulge” a half-wavelength). That is, the wavelengths possible for a particle in a box of length L must meet the condition that: Therefore, the allowed wavelengths are When this expression for l is inserted into the expression for the energy, we obtain En = h2 2ml2 = h2 2m(2L/n)2 = n2 h2 8mL2 l = 2L/n, with n = 1, 2, Á L = 1 2 l, l, 3 2 l, Á = n * 1 2 l, with n = 1, 2, Á Ek = 1 2 mv2 = 1 2 (mv)2 m = p2 2m = (h/l)2 2m = h2 2ml2 1 2mv2 . The Schrödinger equation is a “differential equation,” an equation that relates the “derivatives” of a function (in this case, a second derivative of ␺, d2 ␺/dx2 ) to the value of the function at each point. Derivatives are reviewed in Appendix 1F. Energy 0 1 2 3 4 5 6 n 0 L x FIGURE 1.25 The arrangement known as “a particle in a box,” in which a particle of mass m is confined between two impenetrable walls a distance L apart. The first six wavefunctions and their energies are shown. The numbers on the left are values of the quantum number n. Note that there is a zero-point energy because n cannot be zero. Living Graph 1.25 1.7 WAVEFUNCTIONS AND ENERGY LEVELS 19 HOW DO WE DO THAT (LEVEL 2)? The more sophisticated—and more general—way of finding the energy levels of a particle in a box is to use calculus to solve the Schrödinger equation. First, we note that the potential energy of the particle is zero everywhere inside the box; so V(x) ϭ 0, and the equation that we have to solve is Differential equations are commonly solved by recognizing that they have a particular form and then verifying that that form is a solution by substituting it into the original equation. An equation like this one has solutions of the form with A, B, and k constants. To verify that this is a solution, we substitute it into the differential equation and use d(sin kx)/dx ϭ k cos kx and d(cos kx)/dx ϭ Ϫk sin kx: This expression has the same form as the Schrödinger equation, and is exactly the same if k2 ϭ 2mE/U2 . It follows that Our next task is to find the constants A, B, and k that appear in ␺(x) and E. One criterion for the acceptability of a wavefunction is that, like a guitar string, it varies smoothly. Like a guitar string, a wavefunction cannot drop from a nonzero value just inside the container to zero in the walls: to be continuous, ␺ must be zero at the walls. Therefore, for a box of length L, ␺(x) must be zero at the edges of the box, at x ϭ 0 and x ϭ L. We call these constraints “boundary conditions.” If we set x ϭ 0 and use sin 0 ϭ 0 and cos 0 ϭ 1 in ␺(x) ϭ A sin kx ϩ B cos kx, we find ␺(0) ϭ B. However, ␺(0) ϭ 0; so B ϭ 0 and the wavefunction is This expression already resembles that in Eq. 10. To find the value of k, we use the second boundary condition, that ␺(L) ϭ 0; that is, Setting A ϭ 0 is unacceptable, because then ␺(x) would be zero everywhere, which would mean that the particle would be nowhere. Therefore, to guarantee that ␺(L) ϭ 0, we use the relation sin n␲ ϭ 0 with n ϭ 1, 2, . . . , and set kL ϭ n␲. We now have and, by substituting k ϭ n␲/L into the expression for E, arrive at exactly as we found in level 1. We see that the quantization of energy stems directly from the imposition of boundary conditions on the wavefunction. To find the one remaining constant, A, we use the fact that the probability of finding the particle in a region of length dx at x is ␺(x)2 dx, and therefore the total probability of finding the particle between x ϭ 0 and x ϭ L is the sum (integral) of these probabilities. Because that total probability must be equal to 1 (the particle must be somewhere in the box), we “normalize” the wavefunction; that is, we set the integral equal to 1: 1 L 0 c(x) 2 dx = A 2 1 L 0 sin 2 a n␲x L bdx = 1 E = k2 h2 8␲2 m = (n␲/L)2 h2 8␲2 m = n2 h2 8mL2 c(x) = A sin a n␲x L b n = 1, 2, Á c(L) = A sin kL = 0 c(x) = A sin kx E = k2 U2 2m = k2 (h/2␲)2 2m = k2 h2 8␲2 m = -k2 c = -k2 A sin kx - k2 B cos kx = -k2 (A sin kx + B cos kx) d2 c dx2 = d2 dx2 (A sin kx + B cos kx) = d dx (kA cos kx - kB sin kx) c(x) = A sin kx + B cos kx - U2 2m d2 c dx2 = Ec By convention, sin2 x means (sin x)2 . The integral evaluates to L/2; so A2 L/2 ϭ 1. Therefore, A ϭ (2/L)1/2 and the final form of the wavefunction is that given in Eq. 10. We have established that the allowed energies of a particle of mass m in a onedimensional box of length L are (11) What does this equation tell us? Because the mass, m, of the particle appears in the denominator, for a given length of box, the energy levels lie at lower values for heavy particles than for light particles. Because the length of the box appears in the denominator (as L2 ), as the walls become more confining (L smaller), the energy levels are squeezed upward. A striking implication of Eq. 11 is that because n can take only integral values, the energy of the particle is quantized, meaning that it is restricted to a series of discrete values, called energy levels. According to classical mechanics, an object can have any total energy—high, low, and anything in between. For example, a particle in a box could bounce from wall to wall with any speed and hence any kinetic energy. According to quantum mechanics, however, because only certain wavelengths fit into the box and each wavelength corresponds to a different energy, energy is quantized. The difference between the classical and quantum descriptions of energy is like the difference between the bulk and molecular descriptions of water: when we pour water from a bucket, the water seems to be a continuous fluid that can be transferred in any amount, no matter how small; however, the smallest amount of water that we can transfer is one H2O molecule, one “quantum” of water. As we saw in the derivation of Eq. 11, energy quantization stems from the boundary conditions on the wavefunction, the constraints that the wavefunction must satisfy at different points of space (such as fitting into a container correctly). Because an electron in an atom has a wavefunction that must satisfy certain constraints in three dimensions, only some solutions of the Schrödinger equation and their corresponding energies are acceptable. We can begin to see the origin of the quantized energy levels of an atom. We can use Eq. 11 to calculate the energy separation between two neighboring levels with quantum numbers n and n ϩ 1: (12) We see that, as L (the length of the box) or m (the mass of the particle) increases, the separation between neighboring energy levels decreases (Fig. 1.26). That is why no one noticed that energy is quantized until they investigated very small systems such as an electron in a hydrogen atom: the separation between levels is so small for ordinary particles in ordinary-sized vessels that it is completely undetectable. We can, in fact, ignore the quantization of the motion of the atoms of a gas in a typical flask. EXAMPLE 1.8 Calculating the energies of a particle in a box Very simple expressions can often be used to estimate the order of magnitude of a property without doing a detailed calculation. For example, treat a hydrogen atom as a one-dimensional box of length 150. pm (the approximate diameter of the atom) containing an electron and predict the wavelength of the radiation emitted when the electron falls to the lowest energy level from the next higher energy level. PLAN The lowest energy level has n ϭ 1, and so we can use Eq. 12 with n ϭ 1 and m ϭ me, the mass of the electron. The energy difference is carried away as a photon of radiation; so we set the energy difference equal to h␯ and express ␯ in terms of the corresponding wavelength by using Eq. 1 (␭ ϭ c/␯). En+1 - En = (n + 1)2 h2 8mL2 - n2 h2 8mL2 = (2n + 1) h2 8mL2 En = n2 h2 8mL2 n = 1, 2, Á 20 CHAPTER 1 ATOMS: THE QUANTUM WORLD Energy 0 1 2 3 4 5 6 n FIGURE 1.26 As the length of the box increases (compare boxes on left and right), the energy levels fall and move closer together. SOLVE The mass of the electron is found inside the back cover. 1.7 WAVEFUNCTIONS AND ENERGY LEVELS 21 From Eq. 12 with n ϭ 1, 2n ϩ 1 ϭ 3, E2 - E1 = 3h2 8meL2 Energy 1 2 3 4 5 h␯ From E2 Ϫ E1 ϭ h␯, hn = 3h2 8meL2 , so n = 3h 8meL2 From ␭ ϭ c/␯, l = c (3h/8meL2 ) = 8mecL2 3h Now substitute the data: A note on good practice: Note once again how the complicated collection of units is treated: arriving at the correct units for the answer is a sign that you have set up the equation correctly. As usual, it is good practice to go as far as possible symbolically and then to insert numerical values at the last possible stage. Evaluate This wavelength corresponds to 24.7 nm. The experimental value for the actual transition in a hydrogen atom is 122 nm. Although there is a big discrepancy, an atom does not have the hard boundaries that confine a particle in a box, and is threedimensional. The fact that the predicted wavelength has nearly the same order of magnitude as the actual value suggests that a quantum theory of the atom, based on a more realistic three-dimensional model, should give good agreement. Self-Test 1.8A Use the same model for helium but suppose that the box is 100. pm long, because the atom is smaller. Estimate the wavelength of the same transition. [Answer: 11.0 nm] Self-Test 1.8B Use the same model for hydrogen and estimate the wavelength for the transition from the n ϭ 3 energy level to the n ϭ 2 level. Another surprising implication of Eq. 11 is that a particle in a container cannot have zero energy. Because the lowest value of n is 1 (corresponding to a wave of one-half wavelength fitting into the box), the lowest energy is E1 ϭ h2 /8mL2 . This lowest possible energy is called the zero-point energy. The existence of a zero-point energy means that, according to quantum mechanics, a particle can never be perfectly still when it is confined between two walls: it must always possess an energy—in this case, a kinetic energy—of at least h2 /8mL2 . This result is consistent with the uncertainty principle. When a particle is confined between two walls, the uncertainty in its position cannot = 2.47 * 10-8 m = 8 * 9.109 39 * 10-31 * 2.998 * 108 * (1.50 * 10-10 )2 3 * 6.626 * 10-34 kgиmиs-1 иm2 kgиm2 иs-2 иs l = 8 * (9.109 39 * 10-31 kg) * (2.998 * 108 mиs-1 ) * (1.50 * 10-10 m)2 3 * (6.626 * 10-34 Jиs) J $++%++& me $+++%+++& c $+++%+++& Lϭ150 pm $+++%+++& h $++%++& be larger than the distance between the two walls. Because the position is not completely uncertain, the linear momentum must be uncertain, too, and so we cannot say that the particle is completely still. The particle must therefore have some kinetic energy. The zero-point energy is a purely quantum mechanical phenomenon and is very small for macroscopic systems. For example, a billiard ball on a pool table has a completely negligible zero-point energy of about 10Ϫ67 J. Finally, the shapes of the wavefunctions of a particle in a box also reveal some interesting information. Let’s look at the two lowest energy wavefunctions, corresponding to n ϭ 1 and n ϭ 2. Figure 1.27 shows, by the density of shading, the likelihood of finding a particle: we see that when a particle is described by the wavefunction ␺1 (and has energy h2 /8mL2 ), then it is most likely to be found in the center of the box. Conversely, if the particle is described by the wavefunction ␺2 (and has energy h2 /2mL2 ), then it is most likely to be found in regions between the center and the walls and is unlikely to be found in the middle of the box. Remember that the wavefunction itself does not have any direct physical significance: we have to take the square of ␺ before we can interpret it in terms of the probability of finding a particle somewhere. The probability density for a particle at a location is proportional to the square of the wavefunction at that point; the wavefunction is found by solving the Schrödinger equation for the particle. When the equation is solved subject to the appropriate boundary conditions, it is found that the particle can possess only certain discrete energies. THE HYDROGEN ATOM We are now ready to build a quantum mechanical model of a hydrogen atom. Our task is to combine our knowledge that an electron has wavelike properties and is described by a wavefunction with the nuclear model of the atom, and explain the ladder of energy levels suggested by spectroscopy. 1.8 The Principal Quantum Number An electron in an atom is like a particle in a box, in the sense that it is confined within the atom by the pull of the nucleus. We can therefore expect the electron’s wavefunctions to obey certain boundary conditions, like the constraints we encountered when fitting a wave between the walls of a container. As we saw for a particle in a box, these constraints result in the quantization of energy and the existence of discrete energy levels. Even at this early stage, we can expect the electron to be confined to certain energies, just as the spectroscopic observations require. Thinking point: How many quantum numbers do you think will be needed to specify the wavefunction of an electron in a hydrogen atom? To find the wavefunctions and energy levels of an electron in a hydrogen atom, we must solve the appropriate Schrödinger equation. To set up this equation, which resembles the equation in Eq. 9 but allows for motion in three dimensions, we use the expression for the potential energy of an electron of charge Ϫe at a distance r from a nucleus of charge ϩe. As we saw in Section A, this “Coulomb” potential energy is (13) Solving the Schrödinger equation for a particle with this potential energy is difficult, but Schrödinger himself achieved it in 1927. He found that the allowed energy levels for an electron in a hydrogen atom are (14a) These energy levels have exactly the form suggested spectroscopically, but now we also have an expression for R in terms of more fundamental constants. When the En = - hR n2 R = mee4 8h3 ε0 2 n = 1, 2, Á V(r) = (-e)(+e) 4␲ε0r = - e2 4␲ε0 r 22 CHAPTER 1 ATOMS: THE QUANTUM WORLD x ␺ 2 ␺ 0 n = 2 n = 1 L FIGURE 1.27 The two lowest energy wavefunctions (␺, orange) for a particle in a box and the corresponding probability densities (␺2 , blue). The probability densities are also shown by the density of shading of the bands beneath each wavefunction. fundamental constants are inserted into the expression for R, the value obtained is 3.29 ϫ 1015 Hz, the same as the experimental value of the Rydberg constant. This agreement is a triumph for Schrödinger’s theory and for quantum mechanics; it is easy to understand the thrill that Schrödinger must have felt when he arrived at this result. A very similar expression applies to other one-electron ions, such as Heϩ and even C5ϩ , with atomic number Z: (14b)* What does this equation tell us? All the energies are negative, meaning that the electron has a lower energy in the atom than when it is far from the nucleus. Because Z appears in the numerator, we see that the greater the value of the nuclear charge the more tightly the electron is bound to a nucleus. That n appears in the denominator shows that as n increases, the energy becomes less negative. The dependence of the energy on Z2 rather than on Z itself arises from two factors: first, a nucleus of atomic number Z and charge Ze gives rise to a field that is Z times stronger than that of a single proton; second, the electron is drawn in by the higher charge and is Z times closer to the nucleus than it is in hydrogen. Figure 1.28 shows the energy levels calculated from Eq. 14a. We see that they come closer together as n increases. Each level is labeled by the integer n, which is called the principal quantum number, from n ϭ 1 for the first (lowest, most negative) level, n ϭ 2 for the second, continuing to infinity. The lowest energy possible for an electron in a hydrogen atom, ϪhR , is obtained when n ϭ 1. This lowest energy state is called the ground state of the atom. A hydrogen atom is normally found in its ground state, with its electron in the level with n ϭ 1. When the bound electron is excited by absorbing a photon, its energy climbs up the ladder of levels as n increases. It reaches the top of the ladder, corresponding to E ϭ 0 and freedom, when n reaches infinity. At that point, the electron has left the atom. This process is called ionization. The difference in energy between the ground state and the ionized state is the energy required to remove an electron from the neutral atom in its ground state. The “ionization energy” itself, which we discuss in more detail in Section 1.17, is the minimum energy needed to achieve ionization, with the electron removed from the orbital with n ϭ 1 to a final state in which it has zero energy: in this final state it is free of the nucleus and has zero kinetic energy. The energy levels of a hydrogen atom are defined by the principal quantum number, n ‫؍‬ 1, 2, . . . , and form a converging series, as shown in Fig. 1.28. 1.9 Atomic Orbitals We have found the energies and now need to find the corresponding wavefunctions. Knowing the form of the wavefunctions allows us to go beyond the information provided by spectroscopy and determine not only the allowed energies of the electron in a hydrogen atom but also how the electron is distributed around the nucleus. The wavefunctions of electrons in atoms are called atomic orbitals. The name was chosen to suggest something less definite than an “orbit” of an electron around a nucleus and to take into account the wave nature of the electron. The mathematical expressions for atomic orbitals—which are obtained as solutions of the Schrödinger equation—are more complicated than the sine functions for the particle in a box, but their essential features are straightforward. Moreover, we must never lose sight of their interpretation, that the square of a wavefunction tells us the probability density of an electron at each point. To visualize this probability density, imagine a cloud centered on the nucleus. The density of the cloud at each point represents the probability of finding an electron there. Denser regions of the cloud therefore represent locations where the electron is more likely to be found. To interpret the information in each atomic orbital, we need a way to identify the location of each point around a nucleus. It is most convenient to describe these En = - Z2 hR n2 n = 1, 2, Á 1.9 ATOMIC ORBITALS 23 Energy 0 ϪhR Lyman Balmer 1 2 3 4 1 9 Ϫ hR Ϫ hR1 4 FIGURE 1.28 The permitted energy levels of a hydrogen atom as calculated from Eq. 14. The levels are labeled with the quantum number n, which ranges from 1 (for the lowest state) to infinity (for the separated proton and electron). The ionization energy is discussed further in Section 1.17. locations in terms of spherical polar coordinates, in which each point is labeled with three coordinates: • r, the distance from the center of the atom; • u (theta), the angle from the positive z-axis (the “north pole”), which can be thought of as playing the role of the geographical “latitude”; and • f (phi), the angle about the z-axis, the geographical “longitude.” These coordinates are shown in Fig. 1.29. Each wavefunction, which in general varies from point to point, can be written as a function of the coordinates, ␺(r, u, f). It turns out, however, that all the wavefunctions can be written as the product of a function that depends only on r and another function that depends only on the angles u and f. That is, (15)* The function R(r) is called the radial wavefunction; it tells us how the wavefunction varies as we move away from the nucleus in any direction. The function Y(u,f) is called the angular wavefunction; it tells us how the wavefunction varies as the angles u and f change. For example, the wavefunction corresponding to the ground state of the hydrogen atom (n ϭ 1) is The quantity a0 is called the Bohr radius; when the values of the fundamental constants are inserted, we find a0 ϭ 52.9 pm. What does this equation tell us? For this wavefunction, the angular wavefunction Y is a constant, 1/2␲1/2 , independent of the angles, which means that the wavefunction is the same in all directions. The radial wavefunction R(r) decays exponentially toward zero as r increases, which means that the probability density is highest close to the nucleus (e0 ϭ 1). The Bohr radius tells us how sharply the wavefunction falls away with distance: when r ϭ a0, ␺ has fallen to 1/e (37%) of its value at the nucleus. All the higher energy levels have more than one wavefunction for each energy level. One of the wavefunctions for the next higher energy level, with n ϭ 2 and , is What does this equation tell us? This wavefunction also falls exponentially toward zero as r increases. Notice, though, that the exponential function is multiplied by the factor r, so ␺ is zero at the nucleus (at r ϭ 0) as well as far away from it. We discuss the angular dependence shortly. The expressions for a number of other atomic orbitals are shown in Table 1.2a (for R) and Table 1.2b (for Y). To understand these tables, we need to know, as we describe in more detail immediately below, that each wavefunction is labeled by three quantum numbers: n is related to the size and energy of the orbital, l is related to its shape, and ml is related to its orientation in space. When the Schrödinger equation is solved in detail, it turns out that three quantum numbers are needed to label each wavefunction (because the atom is three-dimensional). The three quantum numbers are designated n, l, and ml. More surprisingly, it also turns out that, for a hydrogen atom, wavefunctions with the same value of n all have the same energy regardless of the values of the other two quantum numbers. We have already encountered n, the principal quantum number, which specifies the energy of the orbital in a one-electron atom (through Eq. 14). In a one-electron = 1 4 a 1 2␲a0 5 b 1/2 re-r/2a0 sin u cos f c(r, u, f) = 1 226 1 a0 5/2 re-r/2a0 * a 3 4␲ b 1/2 sin u cos f E2 = -1 4 hR a0 = 4␲ε0U2 mee2 c(r, u, f) = 2e-r/a0 a0 3/2 * 1 2␲1/2 = e-r/a0 (␲a0 3 )1/2 c(r, u,f) = R(r)Y(u,f) 24 CHAPTER 1 ATOMS: THE QUANTUM WORLD z x y r ␪ ␾ FIGURE 1.29 The spherical polar coordinates: r is the radius, which gives the distance from the center, u is the colatitude, which gives the angle from the z-axis, and f, the “longitude,” is the azimuth, which gives the angle from the x-axis. R(r) $%& Y(u, f) $%& R(r) $+++%+++& Y(u, f) $+++%+++& Geographical latitudes are measured from the equator, not the north pole. The technical name for u is the colatitude. In an early model of the hydrogen atom proposed by Niels Bohr, the electron traveled in a circular orbit of radius a0 around the nucleus. The uncertainty principle rules out this model. atom, all atomic orbitals with the same value of the principal quantum number n have the same energy and are said to belong to the same shell of the atom. The name “shell” reflects the fact that as n increases, the region of greatest probability density is like a nearly hollow shell of increasing radius. The higher the number of the shell, the further away from the nucleus are the electrons in that shell. The second quantum number needed to specify an orbital is l, the orbital angular momentum quantum number. This quantum number can take the values There are n different values of l for a given value of n. For instance, when n ϭ 3, l can have any of the three values 0, 1, and 2. The orbitals of a shell with principal quantum number n therefore fall into n subshells, groups of orbitals that have the same value of l. There is only one subshell in the n ϭ 1 level (l ϭ 0), two in the n ϭ 2 level (l ϭ 0 and 1), three in the n ϭ 3 level (l ϭ 0, 1, and 2), and so on. All orbitals with l ϭ 0 are called s-orbitals, those with l ϭ 1 are called p-orbitals, those with l ϭ 2 are called d-orbitals, and those with l ϭ 3 are called f-orbitals: Value of l 0 1 2 3 Orbital type s p d f Although higher values of l (corresponding to g-, h-, . . . orbitals) are possible, the lower values of l (0, 1, 2, and 3) are the only ones that chemists need in practice. Just as the value of n can be used to calculate the energy of an electron, the value of l can be used to calculate another physical property. As its name suggests, l tells us the orbital angular momentum of the electron, a measure of the rate at which (in classical terms) the electron “circulates” round the nucleus: Orbital angular momentum ϭ {l(l ϩ 1)}1/2 (16)*U l = 0, 1, 2, Á , n - 1 1.9 ATOMIC ORBITALS 25 TABLE 1.2 Hydrogenlike Wavefunctions* (Atomic Orbitals), ‫؍‬ RY (a) Radial wavefunctions (b) Angular wavefunctions n l Rnl(r) l “ml”† (u, f) 1 0 0 0 2 0 1 x 1 y 3 0 z 1 2 xy 2 yz zx x2 Ϫ y2 z2 *Note: In each case, a0 ϭ 4␲ε0 2 /mee2 , or close to 52.9 pm; for hydrogen itself, Z ϭ 1. † In all cases except ml ϭ 0, the orbitals are sums and differences of orbitals with specific values of ml. a 5 16␲ b 1/2 (3 cos2 u - 1) a 15 16␲ b 1/2 sin2 u cos 2f a 15 4␲ b 1/2 cos u sin u cos f a 15 4␲ b 1/2 cos u sin u sin f 4 81230 a Z a0 b 3/2 a Zr a0 b 2 e-Zr/3a0 a 15 16␲ b 1/2 sin2 u sin 2f 2 926 a Z a0 b 3/2 a2 - Zr 3a0 be-Zr/3a0 a 3 4␲ b 1/2 cosu+ 2Z2 r2 9a0 2 b e-Zr/3a0 2 923 a Z a0 b 3/2 a3 - 2Zr a0 a 3 4␲ b 1/2 sinu sinf 1 226 a Z a0 b 3/2 a Zr a0 be-Zr/2a0 a 3 4␲ b 1/2 sinu cosf 1 222 a Z a0 b 3/2 a2 - Zr a0 be-Zr/2a0 a 1 4␲ b 1/2 2a Z a0 b 3/2 e-Zr/a0 Yl, ml c The labels come from the fact that spectroscopic lines were once classified as sharp, principal, diffuse, and fundamental. 26 CHAPTER 1 ATOMS: THE QUANTUM WORLD An electron in an s-orbital (an “s-electron”), for which l ϭ 0, has zero orbital angular momentum. That means that we should imagine it not as circulating around the nucleus but simply as distributed evenly around it. An electron in a p-orbital (l ϭ 1) has nonzero orbital angular momentum (of magnitude 21/2 ; so it can be thought of as circulating around the nucleus. An electron in a d-orbital (l ϭ 2) has a higher orbital angular momentum (61/2 ), one in an f-orbital (l ϭ 3) has an even higher angular momentum (121/2 ), and so on. An important feature of the hydrogen atom is that, as we have remarked, all the orbitals of a given shell have the same energy, regardless of the value of their orbital angular momentum (we see from Eq.14 that l does not appear in the expression for the energy). We say that the orbitals of a shell in a hydrogen atom are degenerate, which means that they all have the same energy. This degeneracy is true only of the hydrogen atom and one-electron ions (such as Heϩ and C5ϩ ). The third quantum number required to specify an orbital is ml, the magnetic quantum number, which distinguishes the individual orbitals within a subshell. This quantum number can take the values ml ϭ l, l Ϫ 1, . . ., Ϫl There are 2l ϩ 1 different values of ml for a given value of l and therefore 2l ϩ 1 orbitals in a subshell of quantum number l. For example, when l ϭ 1, ml ϭ ϩ1, 0, Ϫ1; so there are three p-orbitals in a given shell. Alternatively, we can say that a subshell with l ϭ 1 consists of three orbitals. A note on good practice: Always write the ϩ sign explicitly for positive values of ml. The magnetic quantum number tells us the orientation of the orbital motion of the electron. Specifically, it tells us that the orbital angular momentum around an arbitrary axis is equal to ml , the rest of the orbital motion (to make up the full amount of {l(l ϩ 1)}1/2 ) being around other axes. For instance, if ml ϭ ϩ1, then the orbital angular momentum of the electron around the arbitrary axis is ϩ , whereas, if ml ϭ Ϫ1, then the orbital angular momentum of the electron around the same arbitrary axis is Ϫ . The difference in sign simply means that the direction of motion is opposite, the electron in one state circulating clockwise and an electron in the other state circulating counterclockwise. If ml ϭ 0, then the electron is not circulating around the selected axis, but rather is evenly distributed around it. The hierarchy of shells, subshells, and orbitals is summarized in Fig. 1.30 and Table 1.3. Each possible combination of the three quantum numbers specifies an individual orbital. For example, an electron in the ground state of a hydrogen atom has the specification n ϭ 1, l ϭ 0, ml ϭ 0. Because l ϭ 0, the ground-state wavefunction is an example of an s-orbital and is denoted 1s. Each shell has one s-orbital, and the s-orbital in the shell with quantum number n is called an ns-orbital. All s-orbitals are independent of the angles u and f, so we say that they are spherically symmetrical (Fig. 1.31). The probability density of an electron at the point (r, u, f) when it is in a 1s-orbital is given by the square of the corresponding wavefunction (which was given earlier, but can also be constructed as RY from the entries for R and Y in Tables 1.2a and 1.2b): (17)c2 (r, u, f) = e-2r/a0 ␲a3 0 U U U U U U U l = 2 d l = 1 p l = 0 s ϩ10 0 Ϫ1 ϩ1 ϩ20Ϫ1Ϫ2 Shell Subshell O rbital 3s 3p 3d ml ml ml l = 1 p l = 0 s ϩ10 0 Ϫ1 2s 2p ml ml l = 0 s 0 1s ml n = 3 n = 2 n = 1 FIGURE 1.30 A summary of the arrangement of shells, subshells, and orbitals in an atom and the corresponding quantum numbers. Note that the quantum number ml is an alternative label for the individual orbitals: in chemistry, it is more common to use x, y, and z instead, as shown in Figs. 1.36 through 1.38. TABLE 1.3 Quantum Numbers for Electrons in Atoms Name Symbol Values Specifies Indicates principal n 1, 2, . . . shell size orbital angular l 0, 1, . . ., n Ϫ 1 subshell: shape momentum* l ϭ 0, 1, 2, 3, 4, . . . s, p, d, f, g, . . . magnetic ml l, l Ϫ 1, . . . , Ϫl orbitals of subshell orientation spin magnetic ms spin state spin direction *Also called the azimuthal quantum number. +1 2, -1 2 Probability density Electron cloud FIGURE 1.31 The three-dimensional electron cloud corresponding to an electron in a 1s-orbital of hydrogen. The density of shading represents the probability of finding the electron at any point. The superimposed graph shows how the probability varies with the distance of the point from the nucleus along any radius. In this case, the probability density is independent of angle, and for simplicity is commonly written simply ␺2 (r). In principle, the cloud representing the probability density never thins to exactly zero, no matter how large the value of r. So we could think of an atom as being bigger than the Earth! However, there is virtually no chance of finding an electron farther from the nucleus than about 250 pm, and so atoms are in fact very small. As we can see from the high density of the cloud at the nucleus, an electron in an s-orbital has a nonzero probability of being found right at the nucleus: because l ϭ 0, there is no orbital angular momentum to fling the electron away from the nucleus. Thinking point: How do you think a 1s-orbital in Heϩ will differ from the same orbital in H? 1.9 ATOMIC ORBITALS 27 Suppose the electron is in a 1s-orbital of a hydrogen atom. What is the probability of finding the electron in a small region a distance a0 from the nucleus relative to the probability of finding it in the same small region located right at the nucleus? Anticipate We should expect a lower probability because the wavefunction decays exponentially with distance from the nucleus. PLAN The probability density is independent of angle when l ϭ 0. We need to compare the probability densities at the two locations. To do that, we take the ratio of the squares of the wavefunction at the two locations. SOLVE EXAMPLE 1.9 Calculating the probability of finding an electron at a certain location The ratio of the probability that the electron is found at the nucleus or at r ϭ a0 is: Probability density at r = a0 Probability density at r = 0 = c2 (a0) c2 (0) From c2 (a0) c2 (0) = (1/␲a 3 0 )e-2a0 /a0 (1/␲a3 0)e0 = e-2 = 0.14 c2 (r, u, f) = (1/␲a0 3 )e-2r/a0 , Evaluate As expected, the probability of finding the electron in a small region at a distance a0 from the nucleus is lower than at the nucleus itself: the probability is only 14% of that of finding the electron in a region of the same volume located at the nucleus. r ␺ a0 2 eϪ2 $%& 1 0 10 20 0.6 0.5 0.4 0.3 0.2 0.1 0 Radius, r/a0 Radialdistributionfunction,4πr2 y2 a0 1s 2s 3s FIGURE 1.32 The radial distribution function tells us the probability density for finding an electron at a given radius summed over all directions. The graph shows the radial distribution function for the 1s-, 2s-, and 3s-orbitals in hydrogen. Note how the most probable radius (corresponding to the greatest maximum) increases as n increases. Self-Test 1.9A Calculate the same ratio but for the more distant point at r ϭ 2a0, twice as far from the nucleus. [Answer: 0.018] Self-Test 1.9B Calculate the same ratio but for a point at 3a0 from the nucleus. The value of ␺2 lets us predict the probability of finding the electron in a given region at a distance r from the nucleus; but suppose we want to know the total probability of finding the electron at a distance r regardless of the direction. To calculate this probability we use the radial distribution function, P. Specifically, the probability that the electron will be found anywhere in a thin shell of radius r and thickness ␦r is given by P(r)␦r (Fig. 1.32), with P(r) ϭ r2 R2 (r) (18a) # 28 CHAPTER 1 ATOMS: THE QUANTUM WORLD For s-orbitals, ␺ ϭ RY ϭ R/2␲1/2 , so R2 ϭ 4␲␺2 , and this expression is then the same as P(r) ϭ 4␲r2 ␺2 (r) (18b)* and this expression is the form that you will normally see used; however, it applies only to s-orbitals, whereas Eq. 18a applies to any kind of orbital. It is important to distinguish the radial distribution function from the wavefunction and its square, the probability density: • The wavefunction itself tells us, through ␺2 (r, u, f)␦V, the probability of finding the electron in the small volume ␦V at a particular location specified by r, u, and f. • The radial distribution function tells us, through P(r)␦r, the probability of finding the electron in the range of radii ␦r, at a particular value of the radius, summed over all values of u and f. The radial distribution function for the population of the Earth, for instance, is zero up to about 6400 km from the center of the Earth, rises sharply, and then falls back to almost zero (the “almost” takes into account the small number of people who are on mountains or flying in airplanes). Note that for all orbitals, not just s-orbitals, P is zero at the nucleus, simply because the region in which we are looking for the electron has shrunk to zero size. (The probability density for an s-orbital is nonzero at the nucleus, but here we are multiplying it by a volume, 4␲r2 ␦r, that becomes zero at the nucleus, at r ϭ 0.) As r increases, the value of 4␲r2 increases (the shell is getting bigger), but, for a 1s-orbital, the square of the wavefunction, ␺2 , falls toward zero as r increases; as a result, the product of 4␲r2 and ␺2 starts off at zero, goes through a maximum, and then declines to zero. The value of P is a maximum at a0, the Bohr radius. Therefore, the Bohr radius corresponds to the radius at which an electron in a 1s-orbital is most likely to be found. Instead of drawing the s-orbital as a cloud, chemists usually draw its boundary surface, a smooth surface that encloses most of the cloud. However, although the boundary surface is easier to draw, it does not give the best picture of an atom; an atom has fuzzy edges and is not as smooth as the boundary surface might suggest. Despite this limitation, the boundary surface is useful, because an electron is likely to be found only inside the boundary surface of the orbital. An s-orbital has a spherical boundary surface (Fig. 1.33), because the electron cloud is spherical. s-Orbitals with higher energies have spherical boundary surfaces of greater diameter. They also have a more complicated radial variation, with nodes at locations that can be found by examining the wavefunctions (Fig. 1.34). 2.0 1.5 1.0 0.5 0 Radius, r/a0 Radialwavefunction,Ra0 3/2 0 5 10 15 1s FIGURE 1.34 The radial wavefunctions of the first three s-orbitals of a hydrogen atom. Note that the number of radial nodes increases (as n Ϫ 1), as does the average distance of the electron from the nucleus (compare with Fig. 1.32). Because the probability density is given by ␺2 , all s-orbitals correspond to a nonzero probability density at the nucleus. 1s 3s2s FIGURE 1.33 The three s-orbitals of lowest energy. The simplest way of drawing an atomic orbital is as a boundary surface, a surface within which there is a high probability (typically 90%) of finding the electron. We shall use blue to denote s-orbitals, but that color is only an aid to their identification. The shading within the boundary surfaces is an approximate indication of the electron density at each point. The darker the shading, the higher the probability of finding the electron at that distance from the nucleus. Animation 1.33 Living Graph 1.34 Radius, r/a0 0.6 0.8 0.4 0.2 0 −0.2 Radialwavefunction,Ra0 3/2 0 5 10 15 2s Radius, r/a0 0.4 0.3 0.2 0.1 0 −0.1 0 5 10 15 20 Radialwavefunction,Ra0 3/2 3s The boundary surface of a p-orbital has two lobes (Fig. 1.35). These lobes are marked ϩ and Ϫ to signify that the wavefunction has different signs in the two regions. For instance, the 2p-orbital discussed earlier is proportional to sin u cos f, and as f increases from 0 to 2␲ as we travel around the “equator” of the atom, cos f changes from ϩ1 through 0 (at f ϭ ␲/2) to Ϫ1 (at ␲) and then through zero and back to ϩ1 again. Thus, in one hemisphere the wavefunction is positive and in the other it is negative, as depicted on the boundary surface in Fig. 1.35. The two lobes of a p-orbital are separated by a planar region called a nodal plane, which cuts through the nucleus and on which ␺ ϭ 0. A p-electron, an electron in a p-orbital, will never be found on the nodal plane. Nor will it be found at the nucleus on account of the factor r in the wavefunction. This difference from s-orbitals stems from the fact that an electron in a p-orbital has nonzero orbital angular momentum that flings it away from the nucleus. There are three p-orbitals in each subshell, corresponding to the quantum numbers ml ϭ ϩ1, 0, Ϫ1. However, chemists commonly refer to the orbitals according to the axes along which the lobes lie; hence, we refer to px, py, and pz orbitals (Fig. 1.36). A subshell with l ϭ 2 consists of five d-orbitals. Each d-orbital has four lobes, except for the orbital designated , which has a more complicated shape (Fig. 1.37). A subshell with l ϭ 3 consists of seven f-orbitals with even more complicated shapes (Fig. 1.38). The total number of orbitals in a shell with principal quantum number n is n2 . To confirm this rule, we need to recall that l has n integer values from 0 to n Ϫ 1 and that the number of orbitals in a subshell for a given value of l is 2l ϩ 1. For instance, for n ϭ 4, there are four subshells with l ϭ 0, 1, 2, and 3, consisting of one s-orbital, three p-orbitals, five d-orbitals, and seven f-orbitals, respectively. There are therefore 1 ϩ 3 ϩ 5 ϩ 7 ϭ 16, or 42 , orbitals in the shell with n ϭ 4 (Fig. 1.39). The location of an electron in an atom is described by a wavefunction known as an atomic orbital; atomic orbitals are designated by the quantum numbers n, l, and ml and fall into shells and subshells as summarized in Fig. 1.30. dz2 Radius, r/a0 Radialwavefunction,Ra0 15 0.15 0.1 0.05 0 0 5 10 − + Nodal plane − + FIGURE 1.35 The boundary surface and the radial variation of a 2p-orbital along the (vertical) z-axis. All p-orbitals have boundary surfaces with similar shapes, including one nodal plane. Note that the orbital has opposite signs (as depicted by the depth of color) on each side of the nodal plane. There is no direct relation between the values of ml and the x, y, z designation of the orbitals: the orbitals labeled with the axes are combinations of the orbitals labeled with the quantum number ml. x y z dz2 dx2 Ϫy2 dxy dyzdzx FIGURE 1.37 The boundary surface of a d-orbital is more complicated than that of an s- or a p-orbital. There are, in fact, five d-orbitals of a given energy; four of them have four lobes, one is slightly different. In each case, an electron that occupies a d-orbital will not be found at the nucleus. We shall use orange to indicate d-orbitals: dark and light shades denote different signs of the wavefunction. x y z Nodal plane px py pz FIGURE 1.36 There are three p-orbitals of a given energy, and they lie along three perpendicular axes. We shall use yellow to indicate p-orbitals: dark and light shades denote different signs of the wavefunction. Animation 1.36 Animation 1.37 1.10 Electron Spin Schrödinger’s calculation of the energies of the hydrogen orbitals was a milestone in the development of modern atomic theory. Yet the observed spectral lines did not have exactly the frequencies he predicted. In 1925 (before Schrödinger’s work but after Bohr had developed an earlier model of the atom), two Dutch–American physicists, Samuel Goudsmit and George Uhlenbeck, proposed an explanation for the tiny deviations that had been observed. They suggested that an electron behaves in some respects like a spinning sphere, something like a planet rotating on its axis. This property is called spin. Schrödinger’s theory did not account for spin, but it emerged naturally when the British physicist Paul Dirac found a way (in 1928) to combine Einstein’s theory of relativity with Schrödinger’s approach. According to quantum mechanics, an electron has two spin states, represented by the arrows (up) and (down) or the Greek letters ␣ (alpha) and ␤ (beta).We can think of an electron as being able to spin counterclockwise at a certain rate (the state) or clockwise at exactly the same rate (the state). These two spin states are distinguished by a fourth quantum number, the spin magnetic quantum number, ms. This quantum number can have only two values: ϩ indicates an electron and Ϫ indicates a electron (Fig. 1.40). Box 1.1 describes an experiment that confirmed these properties of electron spin. An electron has the property of spin; the spin is described by the quantum number ms, which may have one of two values. 1.11 The Electronic Structure of Hydrogen Let’s review what we now know about the hydrogen atom by imagining first its ground state and then what happens to its electron as the atom acquires energy. Initially, the electron is in the lowest energy level, the ground state of the atom, with n ϭ 1. The only orbital with this energy is the 1s-orbital; we say that the electron occupies a 1s-orbital or that it is a “1s-electron.” The electron in the ground state of a hydrogen atom is described by the following values of the four quantum numbers: n ϭ 1 l ϭ 0 ml ϭ 0 ms ϭ ϩ or Ϫ The electron can have either spin state. 1 2 1 2 c1 2 c1 2 c c c c y3 − 3yx2 x3 − 3xy25yz2 − yr2 xyzzx2 − zy25xz2 − xr25z3 − 3zr2 x y zFIGURE 1.38 The seven f-orbitals (l ϭ 3) of a shell have a very complex appearance. Their detailed form will not be used again in this text. However, their existence is important for understanding the periodic table, the presence of the lanthanoids and actinoids, and the properties of the later d-block elements. A darker color denotes a positive lobe, a lighter color a negative lobe. ϩ1 ϩ20Ϫ1Ϫ2 ϩ1 ϩ2 ϩ30Ϫ1Ϫ2Ϫ3 0 ϩ10Ϫ1 4s 4p 4d 4f 16 FIGURE 1.39 There are 16 orbitals in the shell with n ϭ 4, each of which can hold two electrons (see Section 1.13), for a total of 32 electrons. ms = Ϫ1 /2 ms = ϩ1 /2 FIGURE 1.40 The two spin states of an electron can be represented as clockwise or counterclockwise rotation around an axis passing through the electron. The two states are identified by the quantum number ms and depicted by the arrows shown on the right. The magnitude of the spin angular momentum of an electron is described by the quantum number s ϭ (the analog of l, but with an unchangeable value). Only the orientation of its spin is variable and specified by the quantum number ms (the analog of ml). 1 2 When the atom acquires enough energy (by absorbing a photon of radiation, for instance) for its electron to reach the shell with n ϭ 2, it can occupy any of the four orbitals in that shell. There are one 2s- and three 2p-orbitals in this shell; in hydrogen, they all have the same energy. When an electron is described by one of these wavefunctions, we say that it “occupies a 2s-orbital” or one of the 2p-orbitals or that it is “a 2sor 2p-electron.” The average distance of an electron from the nucleus when it occupies any of the orbitals in the shell with n ϭ 2 is greater than when n ϭ 1, and so we can think of the atom as swelling up as it is excited energetically. When the atom acquires even more energy, the electron moves into the shell with n ϭ 3; the atom is now even larger. In this shell, the electron can occupy any of nine orbitals (one 3s-, three 3p-, and five 3d-orbitals). More energy moves the electron still farther from the nucleus to the n ϭ 4 shell, where sixteen orbitals are available (one 4s-, three 4p-, five 4d-, and seven 4f-orbitals). Eventually, enough energy is absorbed so that the electron can escape the pull of the nucleus and leaves the atom. Self-Test 1.10A The three quantum numbers for an electron in a hydrogen atom in a certain state are n ϭ 4, l ϭ 2, and ml ϭ Ϫ1. In what type of orbital is the electron located? [Answer: 4d] Self-Test 1.10B The three quantum numbers for an electron in a hydrogen atom in a certain state are n ϭ 3, l ϭ 1, and ml ϭ Ϫ1. In what type of orbital is the electron located? The state of an electron in a hydrogen atom is defined by the four quantum numbers n, l, ml, and ms; as the value of n increases, the size of the atom increases. 1.11 THE ELECTRONIC STRUCTURE OF HYDROGEN 31 Electron spin was first detected experimentally by two German scientists, Otto Stern and Walter Gerlach, in 1920. Because a moving electric charge generates a magnetic field, they predicted that a spinning electron should behave like a tiny bar magnet. In their experiment (see the illustration), Stern and Gerlach removed all the air from a container and set up a highly nonuniform magnetic field across it. They then shot a narrow stream of silver atoms through the container toward a detector. As explained in Section 1.13, a silver atom has one unpaired electron, with its remaining 46 electrons paired. The atom therefore behaves like a single unpaired electron riding on a heavy platform, the rest of the atom. A schematic representation of the apparatus used by Stern and Gerlach. In the experiment, a stream of atoms splits into two as it passes between the poles of a magnet. The atoms in one stream have an odd electron, and those in the other an odd electron. c c HOW DO WE KNOW . . . THAT AN ELECTRON HAS SPIN?BOX 1.1 Magnet Collection plate Atom beam If a spinning electron behaved like a spinning ball, the axis of spin could point in any direction. The electron would behave like a bar magnet that could have any orientation relative to the applied magnetic field. In that case, a broad band of silver atoms should appear at the detector, because the field would push the silver atoms by different amounts according to the orientation of the spin. Indeed, that is exactly what Stern and Gerlach observed when they first carried out the experiment. However, the first results were misleading. The experiment is difficult because the atoms collide with one another in the beam. An atom moving in one direction might easily be knocked by its neighbors into a different direction. When Stern and Gerlach repeated their experiment, they used a much less dense beam of atoms, thereby reducing the number of collisions between the atoms. They now saw only two narrow bands. One band consisted of atoms flying through the magnetic field with one orientation of their spin; the other band consisted of the atoms with opposite spin. The two narrow bands confirmed not only that an electron has spin but also that it can have only two orientations. Electron spin is the basis of the experimental technique called electron paramagnetic resonance (EPR), which is used to study the structures and motions of molecules and ions that have unpaired electrons. This technique is based on detecting the energy needed to flip an electron between its two spin orientations. Like Stern and Gerlach’s experiment, it works only with ions or molecules that have an unpaired electron. MANY-ELECTRON ATOMS A neutral atom other than a hydrogen atom has more than one electron and is known as a many-electron atom. In the next three sections, we build on what we have learned about the hydrogen atom to see how the presence of more than one electron affects the energies of atomic orbitals. The resulting electronic structures are the key to the periodic properties of the elements and the abilities of atoms to form chemical bonds. This material therefore underlies almost every aspect of chemistry. 1.12 Orbital Energies The electrons in a many-electron atom occupy orbitals like those of hydrogen. However, the energies of these orbitals are not the same as those for a hydrogen atom. The nucleus of a many-electron atom is more highly charged than the hydrogen nucleus, and the greater charge attracts electrons more strongly and hence lowers their energy. However, the electrons also repel one another; this repulsion opposes the nuclear attraction and raises the energies of the orbitals. In a helium atom, for instance, with two electrons, the charge of the nucleus is ϩ2e and the total potential energy is given by three terms: Attraction of Attraction of Repulsion electron 1 to electron 2 to between the the nucleus the nucleus two electrons (19) where r1 is the distance of electron 1 from the nucleus, r2 is the distance of electron 2 from the nucleus, and r12 is the distance between the two electrons. The two terms with negative signs (indicating that the potential energy falls as r1 or r2 decreases when either electron gets closer to the nucleus) represent the attractions between the nucleus and the two electrons. The term with a positive sign (indicating an increase in energy as r12 decreases) represents the repulsion between the two electrons. The Schrödinger equation based on this potential energy is impossibly difficult to solve exactly, but highly accurate numerical solutions can be obtained by using computers. The hydrogen atom, with one electron, has no electron–electron repulsions and all the orbitals of a given shell are degenerate. For instance, the 2s-orbital and all three 2p-orbitals have the same energy. In many-electron atoms, however, the results of spectroscopic experiments and calculations show that electron–electron repulsions cause the energy of a 2p-orbital to be higher than that of a 2s-orbital. Similarly, in the n ϭ 3 shell, the three 3p-orbitals lie higher than the 3s-orbital, and the five 3d-orbitals lie higher still (Fig. 1.41). How can we explain these energy differences? As well as being attracted to the nucleus, each electron in a many-electron atom is repelled by the other electrons present. As a result, it is less tightly bound to the nucleus than it would be if those other electrons were absent. We say that each electron is shielded from the full attraction of the nucleus by the other electrons in the atom. The shielding effectively reduces the pull of the nucleus on an electron. The effective nuclear charge, Zeffe, experienced by the electron is always less than the actual nuclear charge, Ze, because the electron–electron repulsions work against the pull of the nucleus. A very approximate form of the energy of an electron in a many-electron atom is a version of Eq. 14b in which the true atomic number is replaced by the effective atomic number: (20) Note that the other electrons do not “block” the influence of the nucleus; they simply provide additional repulsive coulombic interactions that partly counteract the pull of the nucleus. For example, the pull of the nucleus on an electron in the helium atom is less than its charge of ϩ2e would exert but greater than the net charge of ϩe that we would expect if each electron balanced one positive charge exactly. En = - Z2 effhR n2 V = - 2e2 4␲ε0r1 - 2e2 4␲ε0r2 + e2 4␲ε0r12 32 CHAPTER 1 ATOMS: THE QUANTUM WORLD ⎫⎪ ⎪ ⎬ ⎪ ⎭ ⎫ ⎪ ⎪ ⎬ ⎪ ⎭ ⎫ ⎪ ⎬ ⎪ ⎭ Along with code breakers, weather forecasters, and molecular biologists, chemists are now among the heaviest users of computers, which they use to calculate the detailed electronic structures of atoms and molecules (see Major Technique 5, following Chapter 14). Energy 1s 2s 2p 3p 3d 3s 4s 0 After Z = 20 FIGURE 1.41 The relative energies of the shells, subshells, and orbitals in a many-electron atom. Each of the boxes can hold at most two electrons. Note the change in the order of energies of the 3d- and 4s-orbitals after Z ϭ 20. A many-electron atom is also called a polyelectron atom. An s-electron of any shell can be found very close to the nucleus (remember that ␺2 for an s-orbital is nonzero at the nucleus), and so we say that it can penetrate through the inner shells. A p-electron penetrates much less because its orbital angular momentum prevents it from approaching close to the nucleus (Fig. 1.42). We have seen that its wavefunction vanishes at the nucleus, and so there is zero probability density for finding a p-electron there. Because a p-electron penetrates less than an s-electron through the inner shells of the atom, it is more effectively shielded from the nucleus and hence experiences a smaller effective nuclear charge than an s-electron does. In other words, an s-electron is bound more tightly than a p-electron and has a slightly lower (more negative) energy. A d-electron is bound less tightly than a p-electron of the same shell because its orbital angular momentum is higher and it is therefore even less able to approach the nucleus closely. That is, d-electrons are higher in energy than p-electrons of the same shell, which are in turn higher in energy than s-electrons of that shell. The effects of penetration and shielding can be large. A 4s-electron generally has a much lower energy than that of a 4p- or 4d-electron; it may even have lower energy than that of a 3d-electron of the same atom (see Fig. 1.41). The precise ordering of orbitals depends on the number of electrons in the atom, as we shall see in the next section. In a many-electron atom, because of the effects of penetration and shielding, the order of energies of orbitals in a given shell is s Ͻ p Ͻ d Ͻ f. 1.13 The Building-Up Principle The electronic structure of an atom determines its chemical properties, and so we need to be able to describe that structure. To do so, we write the electron configuration of the atom—a list of all its occupied orbitals, with the numbers of electrons that each one contains. In the ground state of a many-electron atom, the electrons occupy atomic orbitals in such a way that the total energy of the atom is a minimum. At first sight, we might expect an atom to have its lowest energy when all its electrons are in the lowest energy orbital (the 1s-orbital), but except for hydrogen and helium, which have no more than two electrons, that can never happen. In 1925, the Austrian scientist Wolfgang Pauli discovered a general and very fundamental rule about electrons and orbitals that is now known as the Pauli exclusion principle: No more than two electrons may occupy any given orbital. When two electrons do occupy one orbital, their spins must be paired. The spins of two electrons are said to be paired if one is and the other (Fig. 1.43). Paired spins are denoted , and electrons with paired spins have spin magnetic quantum numbers of opposite sign. Because an atomic orbital is designated by three quantum numbers (n, l, and ml) and the two spin states are specified by a fourth quantum number, ms, another way of expressing the Pauli exclusion principle for atoms is No two electrons in an atom can have the same set of four quantum numbers. The exclusion principle implies that each atomic orbital can hold no more than two electrons. The hydrogen atom in its ground state has one electron in the 1s-orbital. To show this structure, we place a single arrow in the 1s-orbital in a “box diagram,” which shows each orbital as a box that can be occupied by no more than two electrons (see diagram 1, which is a fragment of Fig. 1.41). We then report its configuration as 1s1 (“one s one”). In the ground state of a helium (He) atom (Z ϭ 2), both electrons are in a 1s-orbital, which is reported as 1s2 (“one s two”). As we see in (2), the two electrons are paired. At this point, the 1s-orbital and the shell with n ϭ 1 are fully occupied. We say that the helium atom has a closed shell, a shell containing the maximum number of electrons allowed by the exclusion principle. A note on good practice: When a single electron occupies an orbital we write 1s1 , for instance, not simply 1s. Lithium (Z ϭ 3) has three electrons. Two electrons occupy the 1s-orbital and complete the n ϭ 1 shell. The third electron must occupy the next available orbital up the ladder cc cc 1.13 THE BUILDING-UP PRINCIPLE 33 1s 2s 3s 0.1 0.2 0.3 0.4 0.5 0.6 0 Radialdistributionfunction,P(r)a0 2p 3p 0.1 0 3d 0.1 0 10 20 30 0 Radius, r/a0 0.2 0.2 FIGURE 1.42 The radial distribution functions for s-, p-, and d-orbitals in the first three shells of a hydrogen atom. Note that the probability maxima for orbitals of the same shell are close to each other; however, note that an electron in an ns-orbital has a higher probability of being found close to the nucleus than does an electron in an np-orbital or an nd-orbital. 1 H 1s1 1s 2 He 1s2 1s H 1s 2s 3p 4p 5p 6p 7p 3s 4s 5s 6s 7s 2p Start 5f 4f 3d 4d 5d 6d [He] [Ne] [Ar] [Kr] [Xe] [Rn] s-block f-block d-block p-block He Ne Ar Kr Xe Rn 2 10 614 FIGURE 1.44 The names of the blocks of the periodic table indicate the last subshell being occupied according to the building-up principle. The numbers of electrons that each type of orbital can accommodate are shown by the numbers across the bottom of the table. The colors of the blocks match the colors that we are using for the corresponding orbitals. of energy levels, the 2s-orbital (see Fig. 1.41). The ground state of a lithium (Li) atom is therefore 1s2 2s1 (3). We can think of this atom as consisting of a core, the electrons in filled orbitals, and the valence electrons. In the case of lithium the core is made up of the inner heliumlike closed shell, the 1s2 core, which we denote [He]. The core is surrounded by an outer shell containing a higher-energy electron. Therefore, the electron configuration of lithium is [He]2s1 . Electrons in the outermost shell are called valence electrons. In general, only valence electrons can be lost in chemical reactions, because core electrons (those in lower-energy orbitals) are too tightly bound. Thus, lithium loses only one electron when it forms compounds; it forms Liϩ ions, rather than Li2ϩ or Li3ϩ ions. The element with Z ϭ 4 is beryllium (Be), with four electrons. The first three electrons form the configuration 1s2 2s1 , like lithium. The fourth electron pairs with the 2selectron, giving the configuration 1s2 2s2 , or more simply [He]2s2 (4). A beryllium atom therefore has a heliumlike core surrounded by a valence shell of two paired electrons. Like lithium—and for the same reason—a Be atom can lose only its valence electrons in chemical reactions. Thus, it loses both 2s-electrons to form a Be2ϩ ion. Boron (Z ϭ 5) has five electrons. Two enter the 1s-orbital and complete the n ϭ 1 shell. Two enter the 2s-orbital. The fifth electron occupies an orbital of the next available subshell, which Fig. 1.41 shows is a 2p-orbital. This arrangement of electrons is reported as the configuration 1s2 2s2 2p1 or [He]2s2 2p1 (5), showing that boron has three valence electrons around a heliumlike core. We need to make another decision at carbon (Z ϭ 6): does the sixth electron join the one already in the 2p-orbital or does it enter a different 2p-orbital? (Remember, there are three p-orbitals in the subshell, all of the same energy.) To answer this question, we note that electrons are farther from each other and repel each other less when they occupy different p-orbitals than when they occupy the same orbital. So the sixth electron goes into an empty 2p-orbital, and the ground state of carbon is 1s2 2s2 2px 1 2py 1 (6). We write out the individual orbitals like this only when we need to emphasize that electrons occupy different orbitals within a subshell. In most cases, we can write the shorter form, [He]2s2 2p2 . Note that in the orbital diagram we have drawn the two 2p-electrons with parallel spins ( ), indicating that they have the same spin magnetic quantum numbers. For reasons based in quantum mechanics, electrons with parallel spins tend to avoid each other. Therefore, this arrangement has slightly lower energy than that of a paired arrangement. However, it is allowed only when the electrons occupy different orbitals. The procedure that we have been using is called the building-up principle. It can be summarized by two rules. To predict the ground-state configuration of a neutral atom of an element with atomic number Z with its Z electrons: 1 Add Z electrons, one after the other, to the orbitals in the order shown in Fig. 1.44 but with no more than two electrons in any one orbital. 2 If more than one orbital in a subshell is available, add electrons with parallel spins to different orbitals of that subshell rather than pairing two electrons in one of the orbitals. cc 34 CHAPTER 1 ATOMS: THE QUANTUM WORLD The outermost electrons are used in the formation of chemical bonds (Chapter 2), and the theory of bond formation is called valence theory; hence the name of these electrons. 3 Li 1s22s1, [He]2s1 2s 1s 4 Be 1s2 2s2 , [He]2s2 2s 1s 5 B 1s2 2s2 2p1 , [He]2s2 2p1 2p 2s 1s 6 C 1s2 2s2 2p2 , [He]2s2 2p2 2p 2s 1s The building-up principle is also commonly called the Aufbau principle, from the German word for “building up.” (a) (b) FIGURE 1.43 (a) Two electrons are said to be paired if they have opposite spins (one clockwise, the other counterclockwise). (b) Two electrons are classified as having parallel spins if their spins are in the same direction; in this case, both .c The first rule takes into account the Pauli exclusion principle. The second rule is called Hund’s rule, for the German spectroscopist Friedrich Hund, who first proposed it. This procedure gives the configuration of the atom that corresponds to the lowest total energy, which maximizes the attraction of the electrons to the nucleus and minimizes their repulsion by one another. An atom with electrons in energy states higher than predicted by the building-up principle is said to be in an excited state. For example, the electron configuration [He]2s1 2p3 represents an excited state of a carbon atom. An excited state is unstable and emits a photon as the electron returns to an orbital that restores the atom to a lower energy. In general, we can think of an atom of any element as having a noble-gas core surrounded by a number of electrons in the valence shell, the outermost occupied shell. The valence shell is the occupied shell with the largest value of n. The underlying organization of the periodic table described in Section B now begins to unfold. All the atoms of the main-group elements in a given period have a valence shell with the same principal quantum number, which is equal to the period number. For example, the valence shell of elements in Period 2 (from lithium to neon) is the shell with n ϭ 2. Thus all the atoms in a given period have the same type of core and valence electrons with the same principal quantum number. For example, the atoms of Period 2 elements all have a heliumlike 1s2 core, and those of Period 3 elements have a neonlike 1s2 2s2 2p6 core, denoted [Ne]. All the atoms of a given group (in the main groups, particularly) have analogous valence electron configurations that differ only in the value of n. For instance, all the members of Group 1 have the valence configuration ns1 ; and all the members of Group 14/IV have the valence configuration ns2 np2 . These similar electron configurations give the elements in a group similar chemical properties, as illustrated in Section B. With these points in mind, let’s continue building up the electron configurations across Period 2. Nitrogen has Z ϭ 7 and one more electron than carbon, giving [He]2s2 2p3 . Each p-electron occupies a different orbital, and the three have parallel spins (7). Oxygen has Z ϭ 8 and one more electron than nitrogen; therefore, its configuration is [He]2s2 2p4 (8) and two of its 2p-electrons are paired. Similarly, fluorine, with Z ϭ 9 and one more electron than oxygen, has the configuration [He]2s2 2p5 (9), with only one unpaired electron. Neon, with Z ϭ 10, has one more electron than fluorine. This electron completes the 2p-subshell, giving [He]2s2 2p6 (10). According to Figs. 1.41 and 1.44, the next electron enters the 3s-orbital, the lowest-energy orbital of the next shell. The configuration of sodium is therefore [He]2s2 2p6 3s1 , or more briefly, [Ne]3s1 , where [Ne] denotes the neonlike core. Self-Test 1.11A Predict the ground-state configuration of a magnesium atom. [Answer: 1s2 2s2 2p6 3s2 , or [Ne]3s2 ] Self-Test 1.11B Predict the ground-state configuration of an aluminum atom. The s- and p-orbitals of the shell with n ϭ 3 are full by the time we get to argon, [Ne]3s2 3p6 , which is a colorless, odorless, unreactive gas resembling neon. Argon completes the third period. From Fig. 1.41, we see that the energy of the 4s-orbital is slightly lower than that of the 3d-orbitals. As a result, instead of electrons entering the 3d-orbitals, the fourth period now begins by filling the 4s-orbitals (see Fig. 1.41). Hence, the next two electron configurations are [Ar]4s1 for potassium and [Ar]4s2 for calcium, where [Ar] denotes the argonlike core, 1s2 2s2 2p6 3s2 3p6 . At this point, however, the 3dorbitals begin to be occupied, and there is a change in the rhythm of the periodic table. According to the pattern of increasing energy of the orbitals (see Fig. 1.41), the next 10 electrons (for scandium, with Z ϭ 21, through zinc, with Z ϭ 30) enter the 3d-orbitals. The ground-state electron configuration of scandium, for example, is [Ar]3d1 4s2 , and that of its neighbor titanium is [Ar]3d2 4s2 . Note that, beginning at scandium, we write the 4s-electrons after the 3d-electrons: once they contain electrons, the 3d-orbitals lie lower in energy than the 4s-orbital (recall Fig. 1.41; the same relation holds true for nd- and (n ϩ 1)s-orbitals in subsequent periods). Successive electrons are added to the d-orbitals as Z increases. However, there are two exceptions: the experimental electron configuration of chromium is [Ar]3d5 4s1 instead of [Ar]3d4 4s2 , and that of copper is 1.13 THE BUILDING-UP PRINCIPLE 35 7 N 1s2 2s2 2p3 , [He]2s2 2p3 2p 2s 1s 8 O 1s2 2s2 2p4 , [He]2s2 2p4 2p 2s 1s 9 F 1s2 2s2 2p5 , [He]2s2 2p5 2p 2s 1s 10 Ne 1s2 2s2 2p6 , [He]2s2 2p6 2p 2s 1s 36 CHAPTER 1 ATOMS: THE QUANTUM WORLD TOOLBOX 1.1 HOW TO PREDICT THE GROUND-STATE ELECTRON CONFIGURATION OF AN ATOM CONCEPTUAL BASIS Electrons occupy orbitals in such a way as to minimize the total energy of an atom by maximizing attractions and minimizing repulsions in accord with the Pauli exclusion principle and Hund’s rule. PROCEDURE We use the following rules of the building-up principle to assign a ground-state configuration to a neutral atom of an element with atomic number Z: 1 Add Z electrons, one after the other, to the orbitals in the order shown in Figs. 1.41 and 1.44 but with no more than two electrons in any one orbital (the Pauli exclusion principle). 2 If more than one orbital in a subshell is available, add electrons to different orbitals of the subshell before doubly occupying any of them (Hund’s rule). 3 Write the labels of the orbitals in order of increasing energy, with a superscript that gives the number of electrons in that orbital. The configuration of a filled shell is represented by the symbol of the noble gas having that configuration, as in [He] for 1s2 . 4 When drawing a box diagram, show the electrons in different orbitals of the same subshell with parallel spins; electrons sharing an orbital have paired spins. In most cases this procedure gives the ground-state electron configuration of an atom, the arrangement with the lowest energy. Any arrangement other than the ground state corresponds to an excited state of the atom. Note that we can use the structure of the periodic table to predict the electron configurations of most elements once we realize which orbitals are being filled in each block of the periodic table (see Fig. 1.44). A useful shortcut for atoms of elements with large numbers of electrons is to write the valence electron configuration from the group number, which gives the number of valence electrons in the ground state of the atom, and the period number, which gives the value of the principal quantum number of the valence shell. The core consists of the preceding noble-gas configuration together with any completed d- and f-subshells. Example 1.10 shows how these rules are applied. [Ar]3d10 4s1 instead of [Ar]3d9 4s2 . This apparent discrepancy occurs because the halfcomplete subshell configuration d5 and the complete subshell configuration d10 turn out to have a lower energy than simple theory suggests. As a result, a lower total energy may be achieved if an electron enters a 3d-orbital instead of the expected 4s-orbital, if that arrangement completes a half-subshell or a full subshell. Other exceptions to the building-up principle can be found in the complete listing of electron configurations in Appendix 2C and in the periodic table inside the front cover. As we can anticipate from the structure of the periodic table (see Fig. 1.44), electrons occupy 4p-orbitals once the 3d-orbitals are full. The configuration of germanium, [Ar]3d10 4s2 4p2 , for example, is obtained by adding two electrons to the 4p-orbitals outside the completed 3d-subshell. Arsenic has one more electron and the configuration [Ar]3d10 4s2 4p3 . The fourth period of the table contains 18 elements, because the 4s- and 4p-orbitals together can accommodate a total of 8 electrons and the 3d-orbitals can accommodate 10. Period 4 is the first long period of the periodic table. Next in line for occupation at the beginning of Period 5 is the 5s-orbital, followed by the 4d-orbitals. As in Period 4, the energy of the 4d-orbitals falls below that of the 5s-orbital after 2 electrons have been accommodated in the 5s-orbital. A similar effect is seen in Period 6, but now another set of inner orbitals, the 4f-orbitals, begins to be occupied. Cerium, for example, has the configuration [Xe]4f1 5d1 6s2 . Electrons then continue to occupy the seven 4f-orbitals, which are complete after 14 electrons have been added, at ytterbium, [Xe]4f14 6s2 . Next, the 5d-orbitals are occupied. The 6p-orbitals are occupied only after the 6s-, 4f-, and 5d-orbitals are filled at mercury; thallium, for example, has the configuration [Xe]4f14 5d10 6s2 6p1 . You may notice in Appendix 2C that there are several apparent disruptions in the order in which the 4f orbitals are filled. The apparent exceptions result because the 4f and 5d orbitals are very close in energy. In fact, closely spaced energy levels account for the fact that about 25% of the elements have electron configurations that deviate in some way from these rules. However, for the majority of elements they are useful guidelines and a good starting point for them all; Toolbox 1.1 outlines a procedure for writing the electron configuration of a heavy element. 1.14 ELECTRONIC STRUCTURE AND THE PERIODIC TABLE 37 EXAMPLE 1.10 Predicting the ground-state electron configuration of a heavy atom Predict the ground-state electron configuration of (a) a vanadium atom and (b) a lead atom. Anticipate Because vanadium is a member of the d-block, we should expect its atoms to have a partially filled set of d-orbitals. Because lead is in the same group as carbon, we should expect the configuration of its valence electrons to be similar to that of carbon (s2 p2 ). PLAN Follow the procedure in Toolbox 1.1. SOLVE (a) Vanadium is in Period 4, and so it has an argon core. Add two electrons to the 4s-orbital, and the last three electrons to three separate 3d-orbitals. [Ar]3d3 4s2 2 3 4 5 VTiScK Ca Ar s 1 s 2 d 1 s 2 d 2 s 2 d 3 s 2 (b) Lead belongs to Group 14/IV and Period 6. It therefore has four electrons in its valence shell, two in a 6s-orbital and two in different 6p-orbitals. The atom has complete 5d- and 4f-subshells, and the preceding noble gas is xenon. [Xe]4f14 5d10 6s2 6p2 C Si Ge Sn Pb Evaluate As expected, vanadium has an incomplete set of d-electrons and the valence-shell configuration of lead is analogous to that of carbon. Self-Test 1.12A Write the ground-state configuration of a bismuth atom. [Answer: [Xe]4f14 5d10 6s2 6p3 ] Self-Test 1.12B Write the ground-state configuration of an arsenic atom. We account for the ground-state electron configuration of an atom by using the building-up principle in conjunction with Fig. 1.41, the Pauli exclusion principle, and Hund’s rule. 1.14 Electronic Structure and the Periodic Table The periodic table (Section B) was formulated long before the structures of atoms were known, by noting trends in experimental data, but the reason for the periodicity of the elements remained a mystery (Box 1.2). Now, however, we can understand the organization of the periodic table in terms of the electron configurations of the elements. The table is divided into s-, p-, d-, and f-blocks, named for the last subshell that is occupied according to the building-up principle (as shown in Fig. 1.44). Two elements are exceptions. Because it has two 1s-electrons, we would place helium in the s block, but it is shown in the p-block because of its properties. It is a gas with properties matching those of the noble gases in Group 18/VIII, rather than the reactive metals in Group 2. Its place in Group 18/VIII is justified because it has a filled valence shell, like all the other Group 18/VIII elements. Hydrogen occupies a unique position in the periodic table. It has one s-electron, and so it belongs in Group 1; but it is also one electron short of a noble-gas configuration, and so it can act like a member of Group 17/VII. Because hydrogen has such a unique character, we do not ascribe it to any group; however, you will often see it placed in Group 1 or Group 17/VII, and sometimes in both. Thinking point: What are the arguments for and against including He in Group 2, above beryllium? The periodic table is one of the most notable achievements in chemistry because it helps to organize what would otherwise be a bewildering array of properties of the elements. However, the fact that its structure corresponds to the electronic structure of atoms was unknown to its discoverers. The periodic table was developed solely from a consideration of physical and chemical properties of the elements. THE DEVELOPMENT OF THE PERIODIC TABLEBOX 1.2 Mendeleev’s Predictions for Eka-Silicon (Germanium) Property Eka-silicon, E Germanium, Ge molar mass 72 gиmolϪ1 72.59 gиmolϪ1 density 5.5 gиcmϪ3 5.32 gиcmϪ3 melting point high 937°C appearance dark gray gray-white oxide EO2; white solid; amphoteric; density 4.7 gиcmϪ3 GeO2; white solid; amphoteric; density 4.23 gиcmϪ3 chloride ECl4; boils below 100°C; density 1.9 gиcmϪ3 GeCl4; boils at 84°C; density 1.84 gиcmϪ3 Dmitri Ivanovich Mendeleev (1834–1907). of whom left with copies of Avogadro’s paper. In 1869, Meyer and Mendeleev discovered independently that the elements fell into families with similar properties when they were arranged in order of increasing atomic mass. Mendeleev called this observation the periodic law. Mendeleev’s chemical insight led him to leave gaps for elements that would be needed to complete the pattern but were unknown at the time. When they were discovered later, he turned out (in most cases) to be strikingly correct. For example, his pattern required an element that he named “eka-silicon” below silicon and between gallium and arsenic. He predicted that the element would have a relative atomic mass of 72 (taking the mass of hydrogen as 1) and properties similar to those of silicon. This prediction spurred the German chemist Clemens Winkler in 1886 to search for eka-silicon, which he eventually discovered and named germanium. It has a relative atomic mass of 72.59 and properties similar to those of silicon, as shown in the accompanying table. One problem with Mendeleev’s table was that some elements seemed to be out of place. For example, when argon was isolated, it did not seem to have the correct mass for its location. Its relative atomic mass of 40 is the same as that of calcium, but argon is an inert gas and calcium a reactive metal. Such anomalies led scientists to question the use of relative atomic mass as the basis for organizing the elements. When Henry Moseley examined x-ray spectra of the elements in the early twentieth century, he realized that he could infer the atomic number itself. It was soon discovered that elements fall into the uniformly repeating pattern of the periodic table if they are organized according to atomic number, rather than atomic mass. Related Exercises: 1.113 and 1.116. In 1860, the Congress of Karlsruhe brought together many prominent chemists in an attempt to resolve issues such as the existence of atoms and the correct atomic masses. One of the new ideas presented was Avogadro’s principle—that the numbers of molecules in samples of different gases of equal volume, pressure, and temperature are the same (see Section 4.4). This principle allowed the relative atomic masses of the gases to be determined. Two scientists attending the congress were the German Lothar Meyer and the Russian Dmitri Mendeleev, both The s- and p-blocks form the main groups of the periodic table. The similar valenceshell electron configurations for the elements in the same main group are the reason for the similar properties of these elements. The group number tells us how many valence-shell electrons are present. In the s-block, the group number (1 or 2) is the same as the number of valence electrons. This relation is also true for all main groups when the Roman numerals (I–VIII) are used to label the groups. However, when the group labels 1–18 are used, in the p-block we subtract 10 from the group number to find the number of valence electrons. For example, fluorine in Group 17/VII has seven valence electrons. Each new period corresponds to the occupation of a shell with a higher principal quantum number. This correspondence explains the different lengths of the periods. Period 1 consists of only two elements, H and He, in which the single 1s-orbital of the n ϭ 1 shell is being filled with its two electrons. Period 2 consists of the eight elements Li through Ne, in which the one 2s- and three 2p-orbitals are being filled with eight more electrons. In Period 3 (Na through Ar), the 3s- and 3p-orbitals are being occupied by eight additional electrons. In Period 4, not only are the eight electrons of the 4s- and 4p-orbitals being added, but so are the ten electrons of the 3d-orbitals. Hence there are 1.15 ATOMIC RADIUS 39 eighteen elements in Period 4. Period 5 elements add another 18 electrons as the 5s-, 4d-, and 5p-orbitals are filled. In Period 6, a total of 32 electrons are added, because 14 electrons are also being added to the seven 4f-orbitals. The f-block elements have very similar chemical properties, because their electron configurations differ only in the population of inner f-orbitals, and electrons in these orbitals do not participate much in bond formation. The blocks of the periodic table are named for the last orbital to be occupied according to the building-up principle. The periods are numbered according to the principal quantum number of the valence shell. THE PERIODICITY OF ATOMIC PROPERTIES The periodic table can be used to predict a wide range of properties, many of which are crucial for understanding chemistry. The variation of effective nuclear charge through the periodic table plays an important role in the explanation of periodic trends. Figure 1.45 shows the variation for the first three periods. The effective charge increases from left to right across a period and falls back sharply on going to the next period. Thinking point: Before reading further, predict how the effective nuclear charge might affect some atomic properties, such as the size of an atom or the ease with which an outer electron can be removed. 1.15 Atomic Radius Electron clouds do not have sharp boundaries, and so we cannot measure the exact radius of an atom. However, when atoms pack together in solids and bond together to form molecules, their centers are found at definite distances from one another. The atomic radius of an element is defined as half the distance between the centers of neighboring atoms (11). If the element is a metal, its atomic radius is taken to be half the distance between the centers of neighboring atoms in a solid sample. For instance, because the distance between neighboring nuclei in solid copper is 256 pm, the atomic radius of copper is 128 pm. If the element is a nonmetal or a metalloid, we use half the distance between the nuclei of atoms joined by a chemical bond; this radius is also called the covalent radius of the element, for reasons that will become clear in Chapter 2. For instance, the distance between the nuclei in a Cl2 molecule is 198 pm, and so the covalent radius of chlorine is 99 pm. If the element is a noble gas, we use the van der Waals radius, which is half the distance between the centers of neighboring atoms in a sample of the solidified gas. The atomic radii of the noble gases listed in Appendix 2D are all van der Waals radii. Because the atoms in a sample of a noble gas are not chemically bonded together, van der Waals radii are generally much larger than covalent radii and are best not included in the discussion of trends. Effectivenuclearcharge,Zeff 1 2 4 5 6 7 Atomic number, Z 1 3 5 7 9 13 1511 17 3 He Li Be B C N O F Ne Na Mg Al Si P S Cl Ar FIGURE 1.45 The variation of the effective nuclear charge for the outermost valence electron with atomic number. Notice that the effective nuclear charge increases from left to right across a period but drops when the outer electrons occupy a new shell. (The effective nuclear charge is actually Zeffe, but Zeff itself is commonly referred to as the charge.) 11 Atomic radius 2r Figure 1.46 shows some atomic radii, and Fig. 1.47 shows the variation in atomic radius with atomic number. Note the periodic, sawtooth pattern in the latter plot. A feature to note is that: Atomic radius generally decreases from left to right across a period and increases down a group. The increase down a group, such as that from Li to Cs, makes sense: with each new period, the outermost electrons occupy shells with increasing principal quantum number and therefore lie farther from the nucleus. The decrease across a period, such as that from Li to Ne, is surprising at first, because the number of electrons is increasing along with the number of protons. The explanation is that the new electrons are in the same shell of the atom and about as close to the nucleus as other electrons in the same shell. However, because they are spread out, the electrons do not shield one another well from the nuclear charge; so the effective nuclear charge increases across the period. The increasing effective nuclear charge draws the electrons in, and, as a result, the atom is more compact and we see a diagonal trend for atomic radii to increase from the upper right of the periodic table to the lower left. Atomic radii generally decrease from left to right across a period as the effective atomic number increases, and they increase down a group as successive shells are occupied. 1.16 Ionic Radius The radii of ions differ markedly from the radii of their parent atoms. As described in Section C, in an ionic solid each ion is surrounded by ions with the opposite charge. The ionic radius of an element is its share of the distance between neighboring ions in an ionic solid (12). The distance between the centers of a neighboring cation and anion is 40 CHAPTER 1 ATOMS: THE QUANTUM WORLD Ne Ar Kr Xe Rn Li Be B C N O F Na Mg Al Si P S Cl K Ca In Rb Cs Sr Ba Ga Tl Ge Sn Pb As Sb Bi Se Te Po Br I At 152 113 88 77 75 66 58 154 160 143 117 110 104 99 227 197 122 122 121 117 114 248 215 163 141 141 137 133 265 217 170 175 155 167 1 2 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 2 3 4 5 6 FIGURE 1.46 The atomic radii (in picometers) of the main-group elements. The radii decrease from left to right in a period and increase down a group. The colors used here and in subsequent charts represent the general magnitude of the property. Atomic radii, including those of the d-block elements, are listed in Appendix 2D. Li Cl Br Atomic number Atomicradius(pm) 100 200 300 I Po F Na K Rb Cs FIGURE 1.47 The periodic variation in the atomic radii of the elements. The decrease across a period can be explained in terms of the effect of increasing effective nuclear charge; the increase down a group by the occupation of shells with increasing principal quantum number. 12 Ionic radius ranion ϩ rcation ϩϪ 1.16 IONIC RADIUS 41 the sum of the two ionic radii. In practice, we take the radius of the oxide ion to be 140. pm and calculate the radii of other ions on the basis of that value. For example, because the distance between the centers of neighboring Mg2ϩ and O2Ϫ ions in magnesium oxide is 212 pm, the radius of the Mg2ϩ ion is reported as 212 pm Ϫ 140 pm ϭ 72 pm. Figure 1.48 illustrates the trends in ionic radii, and Fig. 1.49 shows the relative sizes of some ions and their parent atoms. All cations are smaller than their parent atoms, because the atom loses one or more electrons to form the cation and exposes its core, which is generally much smaller than the parent atom. For example, the atomic radius of Li, with the configuration 1s2 2s1 , is 152 pm, but the ionic radius of Liϩ , the bare heliumlike 1s2 core of the parent atom, is only 76 pm. This size difference is comparable to that between a cherry and its pit. Atoms in the same main group tend to form ions with the same charge. Like atomic radii, the radii of these ions increase down each group because electrons are occupying shells with higher principal quantum numbers. Figure 1.49 shows that anions are larger than their parent atoms. The reason can be traced to the increased number of electrons in the valence shell of the anion and the repulsive effects exerted by electrons on one another. The variation in the radii of anions shows the same diagonal trend as that for atoms and cations, with the smallest at the upper right of the periodic table, close to fluorine. Atoms and ions with the same number of electrons are called isoelectronic. For example, Naϩ , FϪ , and Mg2ϩ are isoelectronic. All three ions have the same electron configuration, [He]2s2 2p6 , but their radii differ because they have different nuclear charges (see Fig. 1.48). The Mg2ϩ ion has the largest nuclear charge; so it has the strongest attraction for the electrons and therefore the smallest radius. The FϪ ion has the lowest nuclear charge of the three isoelectronic ions and, as a result, it has the largest radius. 1 2 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 2 3 4 5 6 Ne Ar Kr Xe Rn Liϩ Be2ϩ B3ϩ C N3Ϫ O2Ϫ FϪ Naϩ Mg2ϩ Al3ϩ Si P3Ϫ S2Ϫ ClϪ Kϩ Ca2ϩ In3ϩ Rbϩ Csϩ Sr2ϩ Ba2ϩ Ga3ϩ Tl3ϩ Ge Sn Pb As3Ϫ Sb Bi Se2Ϫ Te2Ϫ Po BrϪ IϪ At 76 45 23 171 140 133 102 72 54 212 184 181 138 100 80 222 198 196 152 118 62 221 220 167 135 89 FIGURE 1.48 The ionic radii (in picometers) of the ions of the maingroup elements. Note that cations are typically smaller than anions—in some cases, very much smaller. Liϩ Be2ϩ O2Ϫ FϪ Naϩ Mg2ϩ S2Ϫ ClϪ Na Li O S Be Mg F Cl FIGURE 1.49 The relative sizes of some cations and anions compared with their parent atoms. Note that cations (pink) are smaller than their parent atoms (gray), whereas anions (green) are larger. EXAMPLE 1.11 Deciding the relative sizes of ions Arrange each of the following pairs of ions in order of increasing ionic radius: (a) Mg2ϩ and Ca2ϩ ; (b) O2Ϫ and FϪ . PLAN The smaller member of a pair of isoelectronic ions in the same period will be an ion of an element that lies farther to the right in a period, because that ion has the greater effective nuclear charge. If the two ions are in the same group, the smaller ion will be the one that lies higher in the group, because its outermost electrons are closer to the nucleus. SOLVE (a) Mg lies above Ca in Group 2. Mg2ϩ has the smaller ionic radius. Ca 2 3 4 Mg pp72 pm pmpm100 pm 2؉ 2؉ 42 CHAPTER 1 ATOMS: THE QUANTUM WORLD (b) FϪ lies to the right of O in Period 2. FϪ has the smaller ionic radius. 2؊ ؊ 15 16 17 O F 133 pm140 pm Evaluate Appendix 2C shows that the actual values are (a) 72 pm for Mg2ϩ and 100 pm for Ca2ϩ ; (b) 133 pm for FϪ and 140 pm for O2Ϫ . Self-Test 1.13A Arrange each of the following pairs of ions in order of increasing ionic radius: (a) Mg2ϩ and Al3ϩ ; (b) O2Ϫ and S2Ϫ . [Answer: (a) r(Al3ϩ ) Ͻ r(Mg2ϩ ); (b) r(O2Ϫ ) Ͻ r(S2Ϫ )] Self-Test 1.13B Arrange each of the following pairs of ions in order of increasing ionic radius: (a) Ca2ϩ and Kϩ ; (b) S2Ϫ and ClϪ . Ionic radii generally increase down a group and decrease from left to right across a period. Cations are smaller than their parent atoms and anions are larger. 1.17 Ionization Energy We shall see in Chapter 2 that the formation of a bond in an ionic compound depends on the removal of one or more electrons from one atom and their transfer to another atom. The energy needed to remove electrons from atoms is therefore of central importance for understanding their chemical properties. The ionization energy, I, is the minimum energy needed to remove an electron from an atom in the gas phase: X(g) Xϩ (g) ϩ eϪ (g) I ϭ E(Xϩ ) Ϫ E(X) (21)* The ionization energy is normally expressed in electronvolts (eV) for a single atom or in kilojoules per mole of atoms (kJ·molϪ1 ). The first ionization energy, I1, is the minimum energy needed to remove an electron from a neutral atom in the gas phase. For example, for copper, Cu(g) Cuϩ (g) ϩ eϪ (g) energy required ϭ I1 (7.73 eV, 746 kJ·molϪ1 ) The second ionization energy, I2, of an element is the minimum energy needed to remove an electron from a singly charged gas-phase cation. For copper, Cuϩ (g) Cu2ϩ (g) ϩ eϪ (g) energy required ϭ I2 (20.29 eV, 1958 kJ·molϪ1 ) Because ionization energy is a measure of how difficult it is to remove an electron, elements with low ionization energies can be expected to form cations readily and to conduct electricity (which requires that some electrons be free to move) in their solid forms. Elements with high ionization energies are unlikely to form cations and are unlikely to conduct electricity. Thinking point: Why is the second ionization energy of an atom always higher than its first ionization energy? As we can see in Fig. 1.50: First ionization energies typically decrease down a group. First ionization energies generally increase across a period. The decrease down a group can be explained by the finding that, in successive periods, the outermost electron occupies a shell that is farther from the nucleus and is therefore less tightly bound. Therefore, it takes less energy to remove an electron from a cesium atom, for instance, than from a sodium atom. With few exceptions, the first ionization energy rises from left to right across a period (Fig. 1.51). This trend can be traced to the increase in effective nuclear charge ¡ ¡ ¡By referring to the minimum energy we do not have to worry about the kinetic energy of the electron: it is stationary. Ionization can be achieved by using a higher energy, but then the electron would carry away the excess energy as kinetic energy. 1.17 IONIZATION ENERGY 43 Ne Ar Kr Xe Rn Li Be B C N O F Na Mg Al Si P S Cl K Ca InRb Cs Sr Ba Ga Tl Ge Sn Pb As Sb Bi Se Te Po Br I At 1 2 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 2 3 4 5 6 H He 1310 519 900 799 1090 1400 1310 1680 494 736 577 786 1011 1000 1255 2080 418 590 577 784 947 941 1140 1350 402 548 556 707 834 870 1008 1170 376 502 590 716 703 812 1037 1036 1520 2370 FIGURE 1.50 The first ionization energies of the main-group elements, in kilojoules per mole. In general, low values are found at the lower left of the table and high values are found at the upper right. across a period. The small departures from this trend can be traced to repulsions between electrons, particularly electrons occupying the same orbital. For example, the ionization energy of oxygen is slightly lower than that of nitrogen because in a nitrogen atom each p-orbital has one electron, but in oxygen the eighth electron is paired with an electron already occupying an orbital. The repulsion between the two electrons in the same orbital raises their energy and makes one of them easier to remove from the atom than if the two electrons had been in different orbitals. Figure 1.52 shows that the second ionization energy of an element is always higher than its first ionization energy. It takes more energy to remove an electron from a positively charged ion than from a neutral atom. For the Group 1 elements, the second ionization energy is considerably larger than the first; but, in Group 2, the two ionization energies have similar values. This difference makes sense, because the Group 1 elements have an ns1 valence-shell electron configuration. Although the removal of the first electron requires only a small energy, the second electron must come from the noble-gas core. The core electrons have lower principal quantum numbers and are much closer to the nucleus. They are strongly attracted to it and a lot of energy is needed to remove them. He Ne Ar Kr Xe Rn Lanthanides Actinides H Ionizationenergy Atomic number FIGURE 1.51 The periodic variation of the first ionization energies of the elements. 519 900 799 494 418 7300 1760 14 800 25 000 2420 3660 4560 3070 Li Be B Na K First Second Third Fourth FIGURE 1.52 The successive ionization energies of a selection of main-group elements. Note the great increase in energy required to remove an electron from an inner shell. In each case, the blue outline denotes ionization from the valence shell. 44 CHAPTER 1 ATOMS: THE QUANTUM WORLD Metal block Cation Electron sea FIGURE 1.53 A block of metal consists of an array of cations (the spheres) surrounded by a sea of electrons. The charge of the electron sea cancels the charges of the cations. The electrons of the sea are mobile and can move past the cations quite easily and hence conduct an electric current. Self-Test 1.14A Account for the slight decrease in first ionization energy between beryllium and boron. [Answer: Boron loses an electron from a higher-energy subshell than beryllium does.] Self-Test 1.14B Account for the large decrease in third ionization energy between beryllium and boron. The low ionization energies of elements at the lower left of the periodic table account for their metallic character. A block of metal consists of a collection of cations of the element surrounded by a sea of valence electrons that the atoms have lost (Fig. 1.53). Only elements with low ionization energies—the members of the s-block, the d-block, the f-block, and the lower left of the p-block—can form metallic solids, because only they can lose electrons easily. The elements at the upper right of the periodic table have high ionization energies; so they do not readily lose electrons and are therefore not metals. Note that our knowledge of electronic structure has helped us to understand a major feature of the periodic table—in this case, why the metals are found toward the lower left and the nonmetals are found toward the upper right. The first ionization energy is highest for elements close to helium and is lowest for elements close to cesium. Second ionization energies are higher than first ionization energies (of the same element) and very much higher if the electron is to be removed from a closed shell. Metals are found toward the lower left of the periodic table because these elements have low ionization energies and can readily lose their electrons. 1.18 Electron Affinity To predict some chemical properties, we need to know how the energy changes when an electron attaches to an atom. The electron affinity, Eea, of an element is the energy released when an electron is added to a gas-phase atom. A positive electron affinity means that energy is released when an electron attaches to an atom. A negative electron affinity means that energy must be supplied to push an electron onto an atom. This convention matches the everyday meaning of the term “affinity.” More formally, the electron affinity of an element X is defined as X(g) ϩ eϪ (g) XϪ (g) Eea(X) ϭ E(X) Ϫ E(XϪ ) (22)* where E(X) is the energy of a gas-phase X atom and E(XϪ ) is the energy of the gas-phase anion. For instance, the electron affinity of chlorine is the energy released in the process Cl(g) ϩ eϪ (g) ClϪ (g) energy released ϭ Eea (3.62 eV, 349 kJиmolϪ1 ) Because the electron has a lower energy when it occupies one of the atom’s orbitals, the difference E(Cl) Ϫ E(ClϪ ) is positive and the electron affinity of chlorine is positive. Like ionization energies, electron affinities are reported either in electronvolts for a single atom or in joules per mole of atoms. Figure 1.54 shows the variation in electron affinity in the main groups of the periodic table. It is much less periodic than variations in radius and ionization energy. However, one broad trend is clearly visible: with the exception of the noble gases, Electron affinities are highest toward the right of the periodic table. This trend is particularly true in the upper right, close to oxygen, sulfur, and the halogens. In these atoms, the incoming electron occupies a p-orbital close to a nucleus with a high effective charge and can experience its attraction quite strongly. The noble gases have negative electron affinities because any electron added to them must occupy an orbital outside a closed shell and far from the nucleus: this process requires energy, and so the electron affinity is negative. Once an electron has entered the single vacancy in the valence shell of a Group 17/VII atom, the shell is complete and any additional electron would have to begin a new shell. In that shell, it not only would be farther from the nucleus but would also feel the repulsion of the negative charge already present. As a result, the second electron ¡ ¡ Animation 1.53 In some books, you will see electron affinity defined with an opposite-sign convention. Those values are actually the electron-gain enthalpies (Chapter 7). 1.18 ELECTRON AFFINITY 45 affinity of fluorine is strongly negative, meaning that a lot of energy has to be expended to form F2Ϫ from FϪ . Ionic compounds of the halogens are therefore built from singly charged ions such as FϪ and never from doubly charged ions such as F2Ϫ . A Group 16/VI atom, such as O or S, has two vacancies in its valence-shell p-orbitals and can accommodate two additional electrons. The first electron affinity is positive because energy is released when an electron attaches to O or S. However, attachment of the second electron requires energy because of the repulsion by the negative charge already present in OϪ or SϪ . Unlike that of a halide ion, however, the valence shell of the OϪ anion has only seven electrons and thus can accommodate an additional electron. Therefore, we expect that less energy will be needed to make O2Ϫ from OϪ than to make F2Ϫ from FϪ , where no such vacancy exists. In fact, 141 kJ·molϪ1 is released when the first electron adds to the neutral atom to form OϪ , but 844 kJ·molϪ1 must be supplied to add a second electron to form O2Ϫ ; so the total energy required to make O2Ϫ from O is ϩ703 kJ·molϪ1 . As we shall see in Chapter 2, this energy can be achieved in chemical reactions, and O2Ϫ ions are common in metal oxides. Ne Ar Kr Xe Rn Li Be B C N O F Na Mg Al Si P S Cl K Ca InRb Cs Sr Ba Ga Tl Ge Sn Pb As Sb Bi Se Te Po Br I At 1 2 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 2 3 4 5 6 H He ϩ73 ϩ60 Յ0 ϩ27 ϩ122 Ϫ7 ϩ141 Ϫ844 ϩ328 Ͻ0 ϩ53 Յ0 ϩ43 ϩ134 ϩ72 ϩ200, Ϫ532 ϩ349 Ͻ0 ϩ48 ϩ2 ϩ29 ϩ78 ϩ195 ϩ325 Ͻ0 ϩ47 ϩ5 ϩ29 ϩ116 ϩ116 ϩ103 ϩ190 ϩ295 Ͻ0 ϩ46 ϩ14 ϩ19 ϩ35 ϩ91 ϩ174 ϩ270 Ͻ0 Ͻ0 FIGURE 1.54 The variation in electron affinity in kilojoules per mole of the main-group elements. Where two values are given, the first refers to the formation of a singly charged anion and the second is the additional energy needed to produce a doubly charged anion. The negative signs of the second values indicate that energy is required to add an electron to a singly charged anion. The variation is less systematic than that for ionization energy, but high values tend to be found close to fluorine (but not for the noble gases). FIGURE 1.55 The energy changes taking place when an electron is added to a carbon atom and a nitrogen atom. (a) A carbon atom can accommodate an additional electron in an empty p-orbital. (b) When an electron is added to a nitrogen atom it must pair with an electron in a p-orbital. The incoming electron experiences so much repulsion from those already present in the nitrogen atom that the electron affinity of nitrogen is less than that of carbon and is in fact negative. Energy Before After Before After (a) Carbon (b) Nitrogen 0 EXAMPLE 1.12 Predicting trends in electron affinity The electron affinity of carbon is greater than that of nitrogen; indeed, the latter is negative. Suggest a reason for this observation. PLAN When a periodic trend is different from what is expected, we examine the electron configurations of all the species to look for clues to the observed behavior. SOLVE We expect more energy to be released when an electron enters the N atom, because an N atom is smaller than a C atom and its nucleus is more highly charged: the effective nuclear charges for the outermost electrons of the neutral atoms are 3.8 for N and 3.1 for C. However, the opposite is observed, and so we must also consider the effective nuclear charges experienced by the valence electrons in the anions (Fig. 1.55). When CϪ forms from C, the additional electron occupies an empty 2p-orbital (see 6). The incoming electron is well separated from the other p-electrons, and so it experiences an effective nuclear charge close to 3.1. When NϪ forms from N, the additional electron must occupy a 2p-orbital that is already half full (see 7). The effective nuclear charge experienced by this electron is therefore much less than 3.8; so energy is required to form NϪ , and the electron affinity of nitrogen is lower than that of carbon. Self-Test 1.15A Account for the large decrease in electron affinity between lithium and beryllium. [Answer: The additional electron enters a 2s-orbital in Li but a 2p-orbital in Be, and a 2s-electron is more tightly bound than a 2p-electron.] Self-Test 1.15B Account for the large decrease in electron affinity between fluorine and neon. Elements with the highest electron affinities are those in Groups 16/VI and 17/VII. 46 CHAPTER 1 ATOMS: THE QUANTUM WORLD FIGURE 1.56 When tin(II) oxide is heated in air, it becomes incandescent as it reacts to form tin(IV) oxide. Even without being heated, it smolders and can ignite. Cd Hg Zn Ga Ge As Se Al Si Sb3+ Sb5+ Sn2+ Sn4+ In+ In3+ Bi3+ Bi5+ Pb2+ Pb4+ Tl+ Tl3+ P S FIGURE 1.57 The typical ions formed by the heavy elements in Groups 13/III through 15/V show the influence of the inert pair—the tendency to form compounds in which the oxidation numbers differ by 2. 13/III 14/IV 15/V16/VI 17/VII 18/VIII 1 2 2 3 4 5 6 7 Li Be B C N Mg Al SiNa P K Ca Ga Ge As FIGURE 1.58 The pairs of elements represented by similarly colored boxes show a strong diagonal relationship to each other. 1.19 The Inert-Pair Effect Although both aluminum and indium are in Group 13/III, aluminum forms Al3ϩ ions, whereas indium forms both In3ϩ and Inϩ ions. The tendency to form ions two units lower in charge than expected from the group number is called the inert-pair effect. Another example of the inert-pair effect is found in Group 14/IV: tin forms tin(IV) oxide when heated in air, but the heavier lead atom loses only its two p-electrons and forms lead(II) oxide. Tin(II) oxide can be prepared, but it is readily oxidized to tin(IV) oxide (Fig. 1.56). Lead exhibits the inert-pair effect more strongly than tin. The inert-pair effect is due in part to the relative energies of the valence p- and s-electrons. In the later periods of the periodic table, valence s-electrons are very low in energy because of their good penetration and the low shielding ability of the delectrons. The valence s-electrons may therefore remain attached to the atom during ion formation. The inert-pair effect is most pronounced among the heaviest members of a group, where the difference in energy between s- and p-electrons is greatest (Fig. 1.57). Even so, the pair of s-electrons can be removed from the atom under sufficiently vigorous conditions. An inert pair would be better called a “lazy pair” of electrons. The inert-pair effect is the tendency to form ions two units lower in charge than expected from the group number; it is most pronounced for heavy elements in the p-block. 1.20 Diagonal Relationships A diagonal relationship is a similarity in properties between diagonal neighbors in the main groups of the periodic table (Fig. 1.58). A part of the reason for this similarity can be seen in Figs. 1.46 and 1.50 by concentrating on the colors that show the general trends in atomic radius and ionization energy. The colored bands of similar values lie in diagonal stripes across the table. Because these characteristics affect the chemical properties of an element, it is not surprising to find that the elements within a diagonal band show similar chemical properties (Fig. 1.59). Diagonal relationships are helpful for making predictions about the properties of elements and their compounds. The diagonal band of metalloids dividing the metals from the nonmetals is one example of a diagonal relationship (Section B). So is the chemical similarity of lithium and magnesium and of beryllium and aluminum. For example, both lithium and magnesium react directly with nitrogen to form nitrides. Like aluminum, beryllium reacts with both acids and bases. We shall see many examples of this diagonal similarity when we look at the main-group elements in detail in Chapter 15. Diagonally related pairs of elements often show similar chemical properties. 1.21 The General Properties of the Elements We are now at the point where we can begin to predict, in at least a general way, the properties of elements. For example, an s-block element has a low ionization energy, which means that its outermost electrons can easily be lost. An s-block element is therefore likely to be a reactive metal with all the characteristics that the name “metal” implies (Table 1.4, Fig. 1.60). Because ionization energies are lowest at the bottom of each group and the elements there lose their valence electrons most easily, cesium and barium react most vigorously of all s-block elements and have to be stored out of contact with air and water. Elements on the left of the p-block, especially the heavier elements, have ionization energies that are low enough for these elements to have some of the metallic properties of the members of the s-block. However, the ionization energies of the p-block metals are quite high, and they are less reactive than those in the s-block (Fig. 1.61). Elements at the right of the p-block (with the exception of the noble gases) have characteristically high electron affinities: they tend to gain electrons to complete closed 1.21 THE GENERAL PROPERTIES OF THE ELEMENTS 47 shells. Except for the metalloids tellurium and polonium, the members of Groups 16/VI and 17/VII are nonmetals (Fig. 1.62). They typically form molecular compounds with one another. All d-block elements are metals (Fig. 1.63). Their properties are transitional between the s- and the p-block elements, which (with the exception of the members of Group 12) accounts for their alternative name, the “transition metals.” Because transition metals in the same period differ mainly in the number of d-electrons, and these electrons are in inner shells, their properties are very similar. When a d-metal atom loses electrons to form a cation, it first loses its outer s-electrons. However, most transition metals form ions with different oxidation states, because the d-electrons have similar energies and a variable number can be lost when they form compounds. Iron, for instance, forms Fe2ϩ and Fe3ϩ ; copper forms Cuϩ and Cu2ϩ . Although copper is like potassium in having a single outermost s-electron, potassium forms only Kϩ . The reason for this difference can be understood by comparing their second ionization energies, which are 1958 kJ·molϪ1 for copper and 3051 kJ·molϪ1 for potassium. To form Cu2ϩ , an electron is removed from the d-subshell of [Ar]3d10 ; but, to form K2ϩ , the electron would have to be removed from potassium’s argonlike core. The availability of d-orbitals and the similarity of the atomic radii of the d-block metals have a significant impact on many areas of our lives. The availability of d-orbitals is in large measure responsible for the action of transition metals and their compounds as catalysts (substances that accelerate reactions but are not themselves consumed) throughout the chemical industry. Thus, iron is used in the manufacture of ammonia, nickel in the conversion of vegetable oils into shortening, platinum in the manufacture of nitric acid, vanadium(V) oxide in the manufacture of sulfuric acid, and titanium compounds in the manufacture of polyethylene. The ability to form ions FIGURE 1.59 Boron (top) and silicon (bottom) have a diagonal relationship. Both are brittle solids with high melting points. They also show a number of chemical similarities. TABLE 1.4 Characteristics of Metals and Nonmetals Metals Nonmetals Physical properties good conductors of electricity poor conductors of electricity malleable not malleable ductile not ductile lustrous not lustrous typically: solid; high melting point; typically: solid, liquid, or gas; low melting good conductors of heat point; poor conductors of heat Chemical properties react with acids do not react with acids form basic oxides (which react with acids) form acidic oxides (which react with bases) form cations form anions form ionic halides form covalent halides FIGURE 1.60 All the alkali metals are soft, reactive, silvery metals. Sodium is kept under mineral oil to protect it from air, and a freshly cut surface soon becomes covered with the oxide. Variable valence is discussed further in Section 2.1. Lab Video 1.60 FIGURE 1.61 The Group 14/IV elements. From left to right: carbon (as graphite), silicon, germanium, tin, and lead. ❑ 1 Describe the experiments that led to the formulation of the nuclear model of the atom (Section 1.1). ❑ 2 Calculate the wavelength or frequency of light from the relation ln ϭ c (Example 1.1). ❑ 3 Use Wien’s law to estimate a temperature (Example 1.3). ❑ 4 Use the relation E ϭ hn to calculate the energy, frequency, or number of photons emitted from a light source (Examples 1.4 and 1.5). ❑ 5 Estimate the wavelength of a particle (Example 1.6). ❑ 6 Estimate the uncertainty in the location or speed of a particle (Example 1.7). ❑ 7 Calculate the energies and describe the wavefunctions of a particle in a box (Example 1.8). ❑ 8 Explain the origin of the lines in the spectrum of an element and correlate them with specific energy transitions (Example 1.2). ❑ 9 Assess the relative probability of finding an electron at a given distance from the nucleus of an atom (Example 1.9). ❑ 10 Name and explain the relation of each of the four quantum numbers to the properties and relative energies of atomic orbitals (Sections 1.8–1.11). ❑ 11 Describe the factors affecting the energy of an electron in a many-electron atom (Section 1.12). ❑ 12 Write the ground-state electron configuration for an element (Toolbox 1.1 and Example 1.10). ❑ 13 Account for periodic trends in atomic radii, ionization energies, and electron affinities (Examples 1.11 and 1.12). SKILLS YOU SHOULD HAVE MASTERED 48 CHAPTER 1 ATOMS: THE QUANTUM WORLD with different charges is important for facilitating the very subtle changes that take place in organisms. For instance, iron is present as iron(II) in hemoglobin, the oxygentransport protein in mammalian blood; copper is present in the proteins responsible for electron transport; and manganese is present in the proteins responsible for photosynthesis. The similarity of their atomic radii is largely responsible for the ability of transition metals to form the mixtures known as alloys, especially the wide variety of steels that make modern construction and engineering possible. Difficulties in separating and isolating the lanthanoids delayed their widespread use in technology. However, today they are studied intensely, because superconducting materials often contain lanthanoids. All the actinoids are radioactive. None of the elements following plutonium occurs naturally on Earth in any significant amount. Because they can be made only in nuclear reactors or particle accelerators, they are available only in small quantities. All elements in the s-block are reactive metals that form basic oxides. The p-block elements tend to gain electrons to complete closed shells; they range from metals through metalloids to nonmetals. All d-block elements are metals with properties between those of s-block and p-block metals. Many d-block elements form cations in more than one oxidation state. FIGURE 1.62 The Group 16/VI elements. From left to right: oxygen, sulfur, selenium, and tellurium. Note the trend from nonmetal to metalloid. FIGURE 1.63 The elements in the first row of the d-block. Top row (left to right): scandium, titanium, vanadium, chromium, and manganese. Bottom row: iron, cobalt, nickel, copper, and zinc. EXERCISES 49 Exercises labeled require calculus. Observing Atoms 1.1 At the time that J. J. Thomson conducted his experiments on cathode rays, the nature of the electron was in doubt. Some considered it to be a form of radiation, like light; others believed the electron to be a particle. Some of the observations made on cathode rays were used to advance one view or the other. Explain how each of the following properties of cathode rays supports either the wave or the particle model of the electron. (a) They pass through metal foils. (b) They travel at speeds slower than that of light. (c) If an object is placed in their path, they cast a shadow. (d) Their path is deflected when they are passed between electrically charged plates. 1.2 J. J. Thomson originally referred to the rays produced in his apparatus (Fig. B.5) as “canal rays.” The canal ray is deflected within the region between the poles of a magnet and strikes the phosphor screen. The ratio Q/m (where Q is the charge and m the mass) of the particles making up the canal rays is found to be 2.410 ϫ 107 C·kgϪ1 . The cathode and anode of the apparatus are made of lithium, and the tube contains helium. Use the information inside the back cover to identify the particles (and their charge) that make up the canal rays. Explain your reasoning. 1.3 Arrange the following types of photons of electromagnetic radiation in order of increasing energy: ␥-rays, visible light, ultraviolet radiation, microwaves, x-rays. 1.4 Arrange the following types of photons of electromagnetic radiation in order of increasing frequency: visible light, radio waves, ultraviolet radiation, infrared radiation. 1.5 A college student recently had a busy day. Each of the student’s activities on that day (reading, having a dental x-ray, making popcorn in a microwave oven, and getting a suntan) involved radiation from a different part of the electromagnetic spectrum. Complete the following table and match each type of radiation to the appropriate event: Frequency Wavelength Energy of photon Event 8.7 ϫ 1014 Hz 3.3 ϫ 10Ϫ19 J 300 MHz 2.5 nm 1.6 A college student used a variety of types of electromagnetic radiation when going to a restaurant for lunch (watching a red traffic light change, listening to the car radio, being struck by a stray gamma ray from outer space while entering the restaurant, and taking food from a serving table heated with an infrared lamp). Complete the following table and match each type of radiation to the appropriate event: Frequency Wavelength Energy of photon Event 2.7 ϫ 10Ϫ19 J 999 nm 5 ϫ 1019 Hz 155 cm Atomic Spectra 1.7 Use the Rydberg formula for atomic hydrogen to calculate the wavelength for the transition from n ϭ 4 to n ϭ 2. (b) What is the name given to the spectroscopic series to which this transition belongs? (c) Use Table 1.1 to determine the region of the spectrum in which the transition takes place. If the change takes place in the visible region of the spectrum, what color will be emitted? 1.8 (a) Use the Rydberg formula for atomic hydrogen to calculate the wavelength for the transition from n ϭ 5 to n ϭ 1. (b) What is the name given to the spectroscopic series to which this transition belongs? (c) Use Table 1.1 to determine the region of the spectrum in which the transition takes place. If the change takes place in the visible region of the spectrum, what color will be emitted? 1.9 In the spectrum of atomic hydrogen, several lines are generally classified together as belonging to a series (for example, Balmer series, Lyman series, Paschen series), as shown in Fig. 1.28. What is common to the lines within a series that makes grouping them together logical? 1.10 In the spectrum of atomic hydrogen, a violet line is observed at 434 nm. Determine the beginning and ending energy levels of the electron during the emission of energy that leads to this spectral line. 1.11 The energy levels of hydrogenlike one-electron ions of atomic number Z differ from those of hydrogen by a factor of Z2 . Predict the wavelength of the 2s : 1s transition in Heϩ . 1.12 Some lasers work by exciting atoms of one element and letting these excited atoms collide with atoms of another element and transfer their excitation energy to those atoms. The transfer is most efficient when the separation of energy levels matches in the two species. Given the information in Exercise 1.11, are there any transitions of Heϩ (including transitions from its excited states) that could be excited by collision with an excited hydrogen atom with the configuration 2s1 ? Quantum Theory 1.13 Consider the following statements about electromagnetic radiation and decide whether they are true or false. If they are false, correct them. (a) The total intensity of radiation emitted from a black body at absolute temperature T is directly proportional to the temperature. (b) As the temperature of a black body increases, the wavelength at which the maximum intensity is found decreases. (c) Photons of radio-frequency radiation are higher in energy than photons of ultraviolet radiation. 1.14 Consider the following statements about electromagnetic radiation and decide whether they are true or false. If they are false, correct them. (a) Photons of ultraviolet radiation have less energy than photons of infrared radiation. (b) The kinetic energy of an electron ejected from a metal surface when the metal is irradiated with ultraviolet radiation is independent of the frequency of the radiation. (c) The energy of a photon is inversely proportional to the wavelength of the radiation. 1.15 The temperature of molten iron can be estimated by using Wien’s law. If the melting point of iron is 1540°C, what will be the wavelength (in nanometers) corresponding to maximum intensity when a piece of iron melts? EXERCISES C 50 CHAPTER 1 ATOMS: THE QUANTUM WORLD 1.16 An astronomer discovers a new red star and finds that the maximum intensity is at ␭ ϭ 572 nm. What is the temperature of the surface of the star? 1.17 The ␥-ray photons emitted by the nuclear decay of a technetium-99 atom used in radiopharmaceuticals have an energy of 140.511 keV. Calculate the wavelength of these ␥-rays. 1.18 A mixture of argon and mercury vapor used in blue advertising signs emits light of wavelength 470 nm. Calculate the energy change resulting from the emission of 1.00 mol of photons at this wavelength. 1.19 Sodium vapor lamps, used for public lighting, emit yellow light of wavelength 589 nm. How much energy is emitted by (a) an excited sodium atom when it generates a photon; (b) 5.00 mg of sodium atoms emitting light at this wavelength; (c) 1.00 mol of sodium atoms emitting light at this wavelength? 1.20 When an electron beam strikes a block of copper, x-rays with a frequency of 1.2 ϫ 1017 Hz are emitted. How much energy is emitted at this wavelength by (a) an excited copper atom when it generates an x-ray photon; (b) 2.00 mol of excited copper atoms; (c) 2.00 g of copper atoms? 1.21 A lamp rated at 32 W (1 W ϭ 1 J·sϪ1 ) emits violet light of wavelength 420 nm. How many photons of violet light can the lamp generate in 2.0 s? 1.22 A lamp rated at 40 W (1 W ϭ 1 J·sϪ1 ) emits blue light of wavelength 470 nm. How many photons of blue light can the lamp generate in 2.0 s? 1.23 The velocity of an electron that is emitted from a metallic surface by a photon is 3.6 ϫ 103 km·sϪ1 . (a) What is the wavelength of the ejected electron? (b) No electrons are emitted from the surface of the metal until the frequency of the radiation reaches 2.50 ϫ 1016 Hz. How much energy is required to remove the electron from the metal surface? (c) What is the wavelength of the radiation that caused photoejection of the electron? (d) What kind of electromagnetic radiation was used? 1.24 The work function for chromium metal is 4.37 eV. What wavelength of radiation must be used to eject electrons with a velocity of 1.5 ϫ 103 km·sϪ1 ? 1.25 A baseball must weigh between 5.00 and 5.25 ounces (1 ounce ϭ 28.3 g). What is the wavelength of a 5.15-ounce baseball thrown at 92 mph? 1.26 A certain automobile of mass 1645 kg travels on a German autobahn at 162 km·hϪ1 . What is the wavelength of the automobile? 1.27 What is the velocity of a neutron of wavelength 100. pm? 1.28 The average speed of a helium atom at 25°C is 1.23 ϫ 103 m·sϪ1 . What is the average wavelength of a helium atom at this temperature? 1.29 What is the minimum uncertainty in the speed of an electron confined to within the diameter of a lead atom, which has a diameter of 350. pm? 1.30 What is the minimum uncertainty in the position of a hydrogen atom in a particle accelerator given that its speed is known to within Ϯ5.0 mиsϪ1 ? Wavefunctions 1.31 The energy levels of a particle of mass m in a twodimensional square box of side L are given by (n1 2 ϩ n2 2 )h2 /8mL2 . Are any of the levels degenerate? If so, find the values of the quantum numbers n1 and n2 for which these degeneracies arise for the first three cases. 1.32 Refer to Exercise 1.31. If one side of the box is twice that of the other, the energy levels are given by (n1 2 /L1 2 ϩ n2 2 /L2 2 ) ϫ h2 /8m. Are degeneracies allowed? If so, which are the degenerate states of the lowest level that shows degeneracy? 1.33 (a) Using the particle-in-the-box model for the hydrogen atom and treating the atom as an electron in a one-dimensional box of length 150. pm, predict the wavelength of radiation emitted when the electron falls from the level with n ϭ 3 to that with n ϭ 2. (b) Repeat the calculation for the transition from n ϭ 4 to n ϭ 2. 1.34 (a) What is the highest energy photon that can be absorbed by a ground-state hydrogen atom without causing ionization? (b) What is the wavelength of this radiation? (c) To what region of the electromagnetic spectrum does this photon belong? 1.35 (a) Use the Living Graphs on the Web site for this book to plot the particle-in-a-box wavefunction for n ϭ 2 and L ϭ 1 m. (b) How many nodes does the wavefunction have? Where do these nodes occur? (c) Repeat parts (a) and (b) for n ϭ 3. (d) What general conclusion can you draw about the relation between n and the number of nodes present in a wavefunction? (e) Convert the n ϭ 2 plot to a probability density distribution: at what values of x is it most likely to find the particle? (f) Repeat part (e) for n ϭ 3. 1.36 Verify the conclusion in part (d) of Exercise 1.35 by plotting the wavefunction for n ϭ 4 and determining the number of nodes. 1.37 The wavefunction for a particle in a one-dimensional box is given in Eq. 9. (a) Confirm that the probability of finding the particle in the left half of the box is regardless of the value of n. (b) Does the probability of finding the particle in the left-hand onethird of the box depend on n? If so, find the probability. Hint: The indefinite integral of sin2 ax is . 1.38 The Humphreys series is a set of spectral lines in the emission spectrum of atomic hydrogen that ends in the fifth excited state. If an atom emits a photon of radiation of wavelength 5910 nm, to which spectral line in the Humphreys series does that photon correspond (i.e., the lowest-energy spectral line, the second-lowestenergy spectral line, the third-lowest-energy spectral line, etc.)? Justify your answer with a calculation. Models of Atoms 1.39 Evaluate the probability of finding an electron in a small region of a hydrogen 1s-orbital at a distance 0.55a0 from the nucleus relative to finding it in the same small region located at the nucleus. 1.40 Evaluate the probability of finding an electron in a small region of a hydrogen 1s-orbital at a distance 0.65a0 from the nucleus relative to finding it in the same small region located at the nucleus. 1.41 Show that the electron distribution is spherically symmetrical for an atom in which an electron occupies each of the three p-orbitals of a given shell. 1.42 Show that, if the radial distribution function is defined as P ϭ r2 R2 , then the expression for P for an s-orbital is P ϭ 4␲r2 ␺2 . 1.43 What is the probability of finding an electron anywhere in a sphere of radius (a) a0 or (b) 2a0 in the ground state of a hydrogen atom? 1 2 x - (1/4a) sin(2ax) + constant 1 2 C C EXERCISES 51 1.44 At what distance from the nucleus is the electron most likely to be found if it occupies (a) a 3d-orbital or (b) a 4s-orbital in a hydrogen atom? 1.45 (a) Sketch the shape of the boundary surfaces corresponding to 1s-, 2p-, and 3d-orbitals. (b) What is meant by a node? (c) How many radial nodes and angular nodal surfaces does each orbital have? (d) Predict the number of nodal planes expected for a 4f-orbital. 1.46 Locate the positions of the radial nodes of (a) a 3s-orbital; (b) a 4d-orbital. 1.47 Describe the orientation of the lobes of the px-, py-, and pz-orbitals with respect to the reference Cartesian axes. 1.48 Describe the difference in orientation of the dxy- and the -orbitals with respect to the reference Cartesian axes. You may wish to refer to the animation of the atomic orbitals found on the Web site for this text. 1.49 How many orbitals are in subshells with l equal to (a) 0; (b) 2; (c) 1; (d) 3? 1.50 (a) How many subshells are there for principal quantum number n ϭ 5? (b) Identify the subshells in the form 5s, etc. (c) How many orbitals are there in the shell with n ϭ 5? 1.51 (a) How many values of the quantum number l are possible when n ϭ 7? (b) How many values of ml are allowed for an electron in a 6d-subshell? (c) How many values of ml are allowed for an electron in a 3p-subshell? (d) How many subshells are there in the shell with n ϭ 4? 1.52 (a) How many values of the quantum number l are possible when n ϭ 6? (b) How many values of ml are allowed for an electron in a 5f-subshell? (c) How many values of ml are allowed for an electron in a 2s-subshell? (d) How many subshells are there in the shell with n ϭ 3? 1.53 What are the principal and orbital angular momentum quantum numbers for each of the following orbitals: (a) 6p; (b) 3d; (c) 2p; (d) 5f? 1.54 What are the principal and orbital angular momentum quantum numbers for each of the following orbitals: (a) 2s; (b) 6f; (c) 4d; (d) 5p? 1.55 For each orbital listed in Exercise 1.53, give the possible values for the magnetic quantum number. 1.56 For each orbital listed in Exercise 1.54, give the possible values for the magnetic quantum number. 1.57 How many electrons can occupy (a) the 4p-orbitals? (b) the 3d-orbitals? (c) the 1s-orbital? (d) the 4f-orbitals? 1.58 How many electrons can occupy a subshell with l ϭ (a) 0; (b) 1; (c) 2; (d) 3? 1.59 Write the subshell notation (3d, for instance) and the number of orbitals having the following quantum numbers: (a) n ϭ 5, l ϭ 2; (b) n ϭ 1, l ϭ 0; (c) n ϭ 6, l ϭ 3; (d) n ϭ 2, l ϭ 1. 1.60 Write the subshell notation (3d, for instance) and the number of electrons that can have the following quantum numbers if all the orbitals of that subshell are filled: (a) n ϭ 4, l ϭ 1; (b) n ϭ 5, l ϭ 0; (c) n ϭ 6, l ϭ 2; (d) n ϭ 7, l ϭ 3. 1.61 How many electrons can have the following quantum numbers in an atom: (a) n ϭ 2, l ϭ 1; (b) n ϭ 4, l ϭ 2, ml ϭ Ϫ2; (c) n ϭ 2; (d) n ϭ 3, l ϭ 2, ml ϭ ϩ1? 1.62 How many electrons can have the following quantum numbers in an atom: (a) n ϭ 3, l ϭ 1; (b) n ϭ 5, l ϭ 3, ml ϭ Ϫ1; (c) n ϭ 2, l ϭ 1, ml ϭ 0; (d) n ϭ 7? 1.63 Which of the following subshells cannot exist in an atom: (a) 2d; (b) 4d; (c) 4g; (d) 6f? 1.64 Which of the following subshells cannot exist in an atom: (a) 4f; (b) 3f; (c) 5g; (d) 6h? The Structures of Many-Electron Atoms 1.65 (a) Write an expression for the total coulombic potential energy for a lithium atom. (b) What does each individual term represent? 1.66 (a) Write an expression for the total coulombic potential energy for a beryllium atom. (b) If Z denotes the number of electrons present in an atom, write a general expression to represent the total number of terms that will be present in the total coulombic potential energy equation. 1.67 Which of the following statements are true for many-electron atoms? If false, explain why. (a) The effective nuclear charge Zeff is independent of the number of electrons present in an atom. (b) Electrons in an s-orbital are more effective than those in other orbitals at shielding other electrons from the nuclear charge because an electron in an s-orbital can penetrate to the nucleus of the atom. (c) Electrons having l ϭ 2 are better at shielding than electrons having l ϭ 1. (d) Zeff for an electron in a p-orbital is lower than for an electron in an s-orbital in the same shell. 1.68 For the electrons on a carbon atom in the ground state, decide which of the following statements are true. If false, explain why. (a) Zeff for an electron in a 1s-orbital is the same as Zeff for an electron in a 2s-orbital. (b) Zeff for an electron in a 2s-orbital is the same as Zeff for an electron in a 2p-orbital. (c) An electron in the 2s-orbital has the same energy as an electron in the 2p-orbital. (d) The electrons in the 2p-orbitals have spin quantum numbers ms of opposite sign. (e) The electrons in the 2s-orbital have the same value of the quantum number ms. 1.69 Determine whether each of the following electron configurations represents the ground state or an excited state of the atom given. 1.70 Each of the following valence-shell configurations is possible for a neutral atom of a certain element. What is the element and which configuration represents the ground state? 1.71 Of the following sets of four quantum numbers {n, l, ml, ms}, identify the ones that are forbidden for an electron in an atom and explain why they are invalid: (a) (b) (c) {4, 4, -1, +1 2}.{5, 0, -1, +1 2};{4, 2, -1, +1 2}; dx2 -y2 C Ó 1s Ó 2s Ó 2p Ó 1s a 2s a 2p C Be Ó 1s Ó 2s a A a 2p Ó ÓÓ 1s 2s a a 2p N O Ó 4s a 4p a 4s a A a a 4p Ó 4s Ó 4p Ó 4s a a 4p (a) (c) (a) (c) (d) (b) (d) (b) 52 CHAPTER 1 ATOMS: THE QUANTUM WORLD 1.72 Of the following sets of four quantum numbers {n, l, ml, ms}, identify the ones that are forbidden for an electron in an atom and explain why they are invalid: (a) 1.73 What is the ground-state electron configuration expected for each of the following elements: (a) silver; (b) beryllium; (c) antimony; (d) gallium; (e) tungsten; (f) iodine? 1.74 What is the ground-state electron configuration expected for each of the following elements: (a) arsenic; (b) strontium; (c) tin; (d) platinum; (e) osmium; (f) molybdenum? 1.75 Which elements are predicted to have the following groundstate electron configurations: (a) [Kr]4d10 5s2 5p4 ; (b) [Ar]3d3 4s2 ; (c) [He]2s2 2p2 ; (d) [Rn]7s2 6d2 ? 1.76 Which elements are predicted to have the following groundstate electron configurations: (a) [Ar]3d10 4s2 4p1 ; (b) [Ne]3s1 ; (c) [Kr]5s2 ; (d) [Xe]4f7 6s2 ? 1.77 For each of the following ground-state atoms, predict the type of orbital (1s, 2p, 3d, 4f, etc.) from which an electron will be removed to form the ϩ1 ion: (a) Ge; (b) Mn; (c) Ba; (d) Au. 1.78 For each of the following ground-state atoms, predict the type of orbital (1s, 2p, 3d, 4f, etc.) from which an electron will be removed to form the ϩ1 ion: (a) Zn; (b) Cl; (c) Al; (d) Cu. 1.79 Predict the number of valence electrons present in each of the following atoms (include the outermost d-electrons: (a) N; (b) Ag; (c) Nb; (d) W. 1.80 Predict the number of valence electrons present in each of the following atoms (include the outermost d-electrons): (a) Bi; (b) Ba; (c) Mn; (d) Zn. 1.81 How many unpaired electrons are predicted for the groundstate configuration of each of the following atoms: (a) Bi; (b) Si; (c) Ta; (d) Ni? 1.82 How many unpaired electrons are predicted for the groundstate configuration of each of the following atoms: (a) Pb; (b) Ir; (c) Y; (d) Cd? 1.83 The elements Ga, Ge, As, Se, and Br lie in the same period in the periodic table. Write the electron configuration expected for the ground-state atoms of these elements and predict how many unpaired electrons, if any, each atom has. 1.84 The elements N, P, As, Sb, and Bi belong to the same group in the periodic table. Write the electron configuration expected for the ground-state atoms of these elements and predict how many unpaired electrons, if any, each atom has. 1.85 Give the notation for the valence-shell configuration (including the outermost d-electrons) of (a) the alkali metals; (b) Group 15/V elements; (c) Group 5 transition metals; (d) “coinage” metals (Cu, Ag, Au). 1.86 Give the notation for the valence-shell configuration (including the outermost d-electrons) of (a) the halogens; (b) the chalcogens (the Group 16/VI elements); (c) the transition metals in Group 5; (d) the Group 14/IV elements. The Periodicity of Atomic Properties 1.87 Arrange the elements in each of the following sets in order of decreasing atomic radius: (a) sulfur, chlorine, silicon; (b) cobalt, titanium, chromium; (c) zinc, mercury, cadmium; (d) antimony, bismuth, phosphorus. 1.88 Arrange the elements in each of the following sets in order of decreasing atomic radius: (a) bromine, chlorine, iodine; (b) gallium, selenium, arsenic; (c) calcium, potassium, zinc; (d) barium, calcium, strontium. 1.89 Place the following ions in order of increasing ionic radius: S2Ϫ , ClϪ , P3Ϫ . 1.90 Which ion of each of the following pairs has the larger radius: (a) Ca2ϩ , Ba2ϩ ; (b) As3Ϫ , Se2Ϫ ; (c) Sn2ϩ , Sn4ϩ ? 1.91 Which member of each pair has the smaller first ionization energy: (a) Ca or Mg; (b) Mg or Na; (c) Al or Na? 1.92 Which member of each pair is likely to have the smaller second ionization energy: (a) Ca or Mg; (b) Mg or Na; (c) Al or Na? 1.93 Place each of the following sets of elements in order of decreasing ionization energy. Explain your choices. (a) Selenium, oxygen, tellurium; (b) gold, tantalum, osmium; (c) lead, barium, cesium. 1.94 (a) Generally, the first ionization energies for elements in the same period increase on going to higher atomic number. Why? (b) Examine the data for the p-block elements given in Fig. 1.50. Note any exceptions to the rule given in part (a). How are these exceptions explained? 1.95 Which element of each of the following pairs has the higher electron affinity: (a) oxygen or fluorine; (b) nitrogen or carbon; (c) chlorine or bromine; (d) lithium or sodium? 1.96 Which element of each of the following pairs has the higher electron affinity: (a) aluminum or indium; (b) bismuth or antimony; (c) silicon or lead? 1.97 (a) What is the inert-pair effect? (b) Why is the inert-pair effect observed only for heavy elements? 1.98 Identify which of the following elements experience the inertpair effect and write the formulas for the ions that they form: (a) Sb; (b) As; (c) Tl; (d) Ba. 1.99 (a) What is a diagonal relationship? (b) How does it arise? (c) Give two examples to illustrate the concept. 1.100 Use Appendix 2D to find the values for the atomic radii of germanium and antimony as well as the ionic radii for Ge2ϩ and Sb3ϩ . What do these values suggest about the chemical properties of these two ions? 1.101 Which of the following pairs of elements exhibit a diagonal relationship: (a) Li and Mg; (b) Ca and Al; (c) F and S? 1.102 Which of the following pairs of elements do not exhibit a diagonal relationship: (a) Be and Al; (b) As and Sn; (c) Ga and Sn? 1.103 Why are s-block metals more reactive than p-block metals? 1.104 Which of the following elements are transition metals: (a) radium; (b) radon; (c) hafnium; (d) niobium? 1.105 Identify the following elements as metals, nonmetals, or metalloids: (a) lead; (b) sulfur; (c) zinc; (d) silicon; (e) antimony; (f) cadmium. 1.106 Identify the following elements as metals, nonmetals, or metalloids: (a) aluminum; (b) carbon; (c) germanium; (d) arsenic; (e) selenium; (f) tellurium. {2, 2, -1, +1 2}; (b) {6, 6, 0, +1 2}; (c) {5, 4, +5, +1 2} EXERCISES 53 Integrated Exercises 1.107 Photoelectron spectroscopy (PES, see Section 1.4 and Box 3.3) can be used to determine the energies of atomic orbitals by measuring the energies required to remove electrons from them. The following peaks were observed in the PES spectra for two elements. Identify the elements, write their electron configurations, and explain your reasoning: (a) 7.30 MJиmolϪ1 and 0.52 MJиmolϪ1 (b) 11.5 MJиmolϪ1 and 0.90 MJиmolϪ1 1.108 The following peaks were observed in the PES spectra for two elements (see Exercise 1.107). Identify the elements, write their electron configurations, and explain your reasoning: (a) 21 MJиmolϪ1 , 2.4 MJиmolϪ1 , and 0.80 MJиmolϪ1 (b) 29 MJиmolϪ1 , 4.6 MJиmolϪ1 , and 1.10 MJиmolϪ1 1.109 Infrared spectroscopy is an important tool for studying vibrations of molecules. Just as an atom can absorb a photon of suitable energy to move an electron from one electronic state to another, a molecule can absorb a photon of electromagnetic radiation in the infrared region to move from one vibrational energy level to another. In infrared spectroscopy, it is common to express energy in terms of ␯/c, with the units cmϪ1 (read as reciprocal centimeters). (a) If an absorption occurs in the infrared spectrum at 3600 cmϪ1 , what is the frequency of radiation that corresponds to that absorption? (b) What is the energy, in joules (J), of that absorption? (c) How much energy would be absorbed by 1.00 mol of molecules absorbing at 3600 cmϪ1 ? 1.110 Diffraction of electromagnetic radiation by atoms and molecules occurs when the wavelength of the electromagnetic radiation is similar to the size of the particle that causes the diffraction—in this case, atoms or molecules. (a) Using 2.0 ϫ 102 pm as the diameter of an atom, decide what type(s) of electromagnetic radiation would give rise to diffraction when passed through a sample of atoms or molecules. Beams of electrons and neutrons can also be used in diffraction experiments because of their high speeds and the de Broglie relation. Calculate the speed of (b) an electron and (c) a neutron that would be necessary to generate wavelengths comparable to the diameter of an atom. 1.111 Ionization energies usually increase on going from left to right across the periodic table. The ionization energy for oxygen, however, is lower than that of either nitrogen or fluorine. Explain this anomaly. 1.112 Thallium is the heaviest member of Group 13/III. Aluminum is also a member of that group, and its chemical properties are dominated by the ϩ3 oxidation state. Thallium, however, is found most usually in the ϩ1 oxidation state. Examine this difference by plotting the first, second, and third ionization energies for the Group 13/III elements against atomic number (see Appendix 2D or the periodic-table data found on the Web site for this text). Explain the trends you observe. 1.113 The German physicist Lothar Meyer observed a periodicity in the physical properties of the elements at about the same time that Mendeleev was working on their chemical properties. Some of Meyer’s observations can be reproduced by examining the molar volume for the solid element as a function of atomic number. Calculate the molar volumes for the elements in Periods 2 and 3 from the densities of the elements found in Appendix 2D and the following solid densities (g·cmϪ3 ): nitrogen, 0.88; fluorine, 1.11; neon, 1.21. Plot your results as a function of atomic number and describe any variations that you observe. 1.114 In the spectroscopic technique known as photoelectron spectroscopy (PES), ultraviolet radiation is directed at an atom or a molecule. Electrons are ejected from the valence shell, and their kinetic energies are measured. Because the energy of the incoming ultraviolet photon is known and the kinetic energy of the outgoing electron is measured, the ionization energy, I, can be deduced from the fact that the total energy is conserved. (a) Show that the speed v of the ejected electron and the frequency n of the incoming radiation are related by (b) Use this relation to calculate the ionization energy of a rubidium atom, given that radiation of wavelength 58.4 nm produces electrons with a speed of 2450 km·sϪ1 ; recall that 1 J ϭ 1 kg·m2 ·sϪ2 . 1.115 In the heavier transition-metal elements, especially the lanthanoids and actinoids, there are numerous exceptions to the regular order of orbital occupation predicted by the building-up principle. Suggest why more exceptions would be noted for these elements. 1.116 Modern periodic tables sometimes differ in which elements are placed immediately to the right of barium and radium. In some cases, the elements are lanthanum and actinium, whereas others place lutetium and lawrencium there. Why? Justify each selection. 1.117 Wavefunctions corresponding to states of different energy of a particle in a box are mutually “orthogonal” in the sense that, if the two wavefunctions are multiplied together and then integrated over the length of the box, then the outcome is zero. (a) Confirm that the wavefunctions for n ϭ 1 and n ϭ 2 are orthogonal. (b) Demonstrate, without doing a calculation, that all wavefunctions with even n are orthogonal to all wavefunctions with odd n. Hint: Think about the area under the product of any two such functions. 1.118 Wavefunctions are “normalized” to 1. This term means that the total probability of finding an electron in the system is 1. Verify this statement for a particle-in-the-box wavefunction (Eq. 10). 1.119 The intensity of a transition between the states n and nЈ of a particle in a box is proportional to the square of the integral I, where (a) Can there be a transition between states with quantum numbers 3 and 1? (b) Consider the transition between states with quantum numbers 2 and 1. Does the intensity decrease or increase as the box lengthens? 1.120 Millikan measured the charge of the electron in electrostatic units, esu. The data that he collected included the following series of charges found on oil drops: 9.60 ϫ 10Ϫ10 esu, 1.92 ϫ 10Ϫ9 esu, 2.40 ϫ 10Ϫ9 esu, 2.88 ϫ 10Ϫ9 esu, and 4.80 ϫ 10Ϫ9 esu. (a) From this series find the likely charge on the electron in electrostatic units. (b) Predict the number of electrons on an oil drop with the charge 6.72 ϫ 10Ϫ9 esu. 1.121 Atomic orbitals may be combined to form molecular orbitals. In such orbitals, there is a nonzero probability of finding Inn¿ = L L 0 cncn¿dx hn = I + 1 2 mev2 C C C 54 CHAPTER 1 ATOMS: THE QUANTUM WORLD an electron on any of the atoms that contribute to that molecular orbital. Consider an electron that is confined in a molecular orbital that extends over two adjacent carbon atoms. The electron can move freely between the two atoms. The C–C distance is 139 pm. (a) Using the one-dimensional particle-in-the-box model, calculate the energy required to promote an electron from the n ϭ 1 to the n ϭ 2 level, assuming that the length of the box is determined by the distance between two carbon atoms. (b) To what wavelength of radiation does this correspond? (c) Repeat the calculation for a linear chain of 1000 carbon atoms. (d) What can you conclude about the energy separation between energy levels as the size of the atom chain increases? 1.122 The energy required to break a C–C bond in a molecule is 348 kJ·molϪ1 . Will visible light be able to break this bond? If yes, what is the color of that light? If not, what type of electromagnetic radiation will be suitable? 1.123 Apparent anomalies in the filling of electron orbitals in atoms occur in chromium and copper. In these elements an electron expected to occupy an s-orbital occupies a d-orbital instead. (a) Explain why these anomalies occur. (b) Similar anomalies are known to occur in seven other elements. Using Appendix 2C, identify those elements and indicate for which ones the explanation used to rationalize the chromium and copper electron configurations is valid. (c) Explain why there are no elements in which electrons fill (n ϩ 1)s-orbitals instead of np-orbitals. 1.124 The electron in a hydrogen atom is excited to a 4d-orbital. Calculate the energy of the photon released if the electron were then to move to each of the following orbitals: (a) 1s; (b) 2p; (c) 2s; (d) 4s. (e) If the outermost electron in a potassium atom were excited to a 4d-orbital and then fell to the same orbitals, describe qualitatively how the emission spectrum would differ from that of hydrogen (do not do any calculations). Explain your answer. 1.125 The following properties are observed for an unknown element. Identify the element from its properties. (a) The neutral atom has two unpaired electrons. (b) One of the valence electrons in the ground state atom has ml ϭ ϩ1. (c) The most common oxidation state is ϩ4. (d) If an electron in a hydrogen atom were excited to the same principal quantum level, n, as the valence electrons in an atom of this element, and fell to the n Ϫ 1 quantum level, the photon emitted would have an energy of 4.9 ϫ 10Ϫ20 J. 1.126 The electron affinity of thulium has been measured by laser photodetachment electron spectroscopy. In this technique a gaseous beam of the anions of an element is bombarded with photons from a laser. The photons eject electrons from some of the anions and the energies of the ejected electrons are detected. The photons had a wavelength of 1064 nm and the ejected electrons had an energy of 0.137 eV. Although the analysis is somewhat more complicated, we can obtain a rough estimate of the electron affinity as the difference in energy between the photons and the energy of the ejected electrons. What is the electron affinity of thulium in kJиmolϪ1 ? 1.127 Francium is thought to be the most reactive of the alkali metals. Because it is radioactive and available in only very small amounts it is difficult to study. However, we can predict its properties based on its location in Group 1 of the periodic table. Estimate the following properties of francium: (a) atomic radius; (b) ionic radius of the ϩ1 cation; (c) ionization energy. 1.128 Below is pictured the reaction between an atom of magnesium and an atom of oxygen. Identify each element and the ions formed and explain your reasoning. 1.129 Below is pictured the reaction between an atom of sodium and an atom of chlorine. Identify each element and the ions formed and explain your reasoning. 1.130 This plot shows the radial distribution function of the 3s- and 3p-orbitals of a hydrogen atom. Identify each curve and explain how you made your decision. Chemistry Connections 1.131 Green chemistry methods, which use nontoxic chemicals, are replacing elemental chlorine for the bleaching of paper pulp. Chlorine causes problems because it is a strong oxidizing agent that reacts with organic compounds to form toxic by-products such as furan and dioxins. (a) Write the electron configuration of a chlorine atom in its ground state. How many unpaired electrons are present in the atom? Write the electron configuration you expect a chloride ion to have. The electron configuration of the chloride ion is identical to that of a neutral atom of what other element? (b) When a chlorine atom is excited by heat or light, one of its valence electrons may be promoted to a higher energy level. Predict the most likely electron configuration for the lowest possible excited state for an excited chlorine atom. (c) Estimate the wavelength (in nm) of the energy that needs to be absorbed for the electron to reach the excited state in part (b). To make this estimate, use Eq. 20 and take the effective nuclear charge from Fig. 1.45. (d) What is the value of the energy required in part (c) in kilojoules per mole and electronvolts? (e) The proportion of 37 Cl in a typical sample is 75.77%, with the remainder being 35 Cl. What would the molar mass of a sample of chlorine atoms be if the proportion of 37 Cl were reduced to half its current value? The mass of an atom of 35 Cl is 5.807 ϫ 10Ϫ23 g and that of an atom of 37 Cl is 6.139 ϫ 10Ϫ23 g. (f) What are the oxidation numbers of chlorine in the bleaching agents ClO2 and NaClO? (g) What are the oxidation numbers of chlorine in the oxidizing agents KClO3 and NaClO4? (h) Write the names of the compounds in parts (f) and (g). Radialdistribution function Radius a b A B C D A B C D 55 What Are the Key Ideas? Bond formation is accompanied by a lowering of energy. The energy lowering is due to the attractions between oppositely charged ions or between nuclei and shared electron pairs. The electron configurations of individual atoms control how the atoms combine with one another. Why Do We Need to Know This Material? The existence of compounds is central to the science of chemistry; and by seeing how bonds form between atoms, we come to see how chemists design new materials. Research into artificial blood, new pharmaceuticals, agricultural chemicals, and the polymers used in materials such as compact discs, cell phones, and synthetic fibers is based on an understanding of how atoms link together. What DoWe Need to KnowAlready? This chapter assumes that we know about atomic structure and electron configurations (Chapter 1), the basic features of energy, and the nature of the Coulomb interaction between charges (Section A). It is also helpful to be familiar with the nomenclature of compounds (Section D) and oxidation numbers (Section K). A chemical bond is the link between atoms. When a chemical bond forms between two atoms the resulting arrangement of the two nuclei and their electrons has a lower energy than the total energy of the separate atoms. If the lowest energy can be achieved by the complete transfer of one or more electrons from each atom of one element to those of another, then ions form and the compound is held together by the electrostatic attraction between them. This attraction is called an ionic bond. Sodium and chlorine atoms, for example, bond together as ions because solid sodium chloride, which consists of Naϩ and ClϪ ions, has a lower energy than a collection of widely separated sodium and chlorine atoms. If the lowest energy can be achieved by sharing electrons, then the atoms link through a covalent bond and discrete molecules are formed. Hydrogen and nitrogen atoms bond together as molecules of ammonia, NH3, for example, because a gas consisting of NH3 molecules has a lower energy than a gas consisting of the same number of widely separated nitrogen and hydrogen atoms. A third type of bond is the metallic bond, in which large numbers of cations are held together by a sea of electrons. For example, a piece of copper consists of a stack of copper ions held together by a sea of electrons, each of which comes from one of the atoms in the sample (recall Fig. 1.53). We consider the metallic bond in more detail in Chapters 5 and 6. In this chapter we examine ionic and covalent bonds. The changes in energy responsible for the formation of bonds occur when the valence electrons of atoms, the electrons in the outermost shells, move to new locations. Therefore, bond formation depends on the electronic structures of atoms discussed in Chapter 1. IONIC BONDS The ionic model, the description of bonding in terms of ions, is particularly appropriate for describing binary compounds formed from a metallic element, especially an s-block metal, and a nonmetallic element. An ionic solid is an assembly of cations and anions stacked together in a regular array. In sodium chloride, sodium ions alternate with chloride ions, and large numbers of oppositely charged ions are lined up in all three dimensions (Fig. 2.1). Ionic solids are examples of crystalline solids, or solids that consist of atoms, molecules, or ions stacked together in a regular pattern. We explore these patterns in Chapter 5; here we concentrate on the changes in the valence electrons that accompany the formation of ions and the energetics of the formation of ionic solids. IONIC BONDS 2.1 The Ions That Elements Form 2.2 Lewis Symbols 2.3 The Energetics of Ionic Bond Formation 2.4 Interactions Between Ions COVALENT BONDS 2.5 Lewis Structures 2.6 Lewis Structures of Polyatomic Species 2.7 Resonance 2.8 Formal Charge EXCEPTIONS TO THE OCTET RULE 2.9 Radicals and Biradicals 2.10 Expanded Valence Shells 2.11 The Unusual Structures of Some Group 13/III Compounds IONIC VERSUS COVALENT BONDS 2.12 Correcting the Covalent Model: Electronegativity 2.13 Correcting the Ionic Model: Polarizability THE STRENGTHS AND LENGTHS OF COVALENT BONDS 2.14 Bond Strengths 2.15 Variation in Bond Strength 2.16 Bond Lengths 55 Chapter 2 CHEMICAL BONDS 2.1 The Ions That Elements Form When an atom of a metallic element in the s-block forms a cation, it loses electrons down to its noble-gas core (Fig. 2.2). In general, that core has an ns2 np6 outer electron configuration, which is called an octet of electrons. For example, sodium ([Ne]3s1 ) loses its 3s-electron to form Naϩ , which has the same electron configuration as neon, [Ne] or 1s2 2s2 2p6 . The Naϩ ions cannot lose more electrons in a chemical reaction, because the ionization energies of core electrons are too high. Hydrogen loses an electron to form a bare proton. Lithium ([He]2s1 ) and beryllium ([He]2s2 ) lose their s-electrons, leaving a heliumlike duplet, a pair of electrons with the configuration 1s2 , when they become Liϩ and Be2ϩ . Some typical electron configurations of atoms and the ions they form are shown in Table 2.1. When the atoms of metals on the left of the p-block in Periods 2 and 3 lose their valence electrons, they form ions with the electron configuration of the preceding noble gas. Aluminum, [Ne]3s2 3p1 , for instance, forms Al3ϩ with the same configuration as neon. However, when the metallic p-block elements in Period 4 and later periods lose their s- and p-electrons, they leave a noble-gas core surrounded by an additional, complete subshell of d-electrons. For instance, gallium forms the ion Ga3ϩ with the configuration [Ar]3d10 . The d-electrons of the p-block atoms are gripped tightly by the nucleus and, in most cases, cannot be lost. In the d-block, when occupied by electrons, the (n Ϫ 1)d-orbitals lie below the nsorbitals in energy. Therefore, the ns-electrons are lost first, followed by a variable number of (n Ϫ 1)d-electrons. For example, to obtain the configuration of the Fe3ϩ ion, we start from the configuration of the Fe atom, which is [Ar]3d6 4s2 , and remove three electrons from it. The first two electrons removed are 4s-electrons. The third electron comes from the 3d-subshell, giving [Ar]3d5 . Many metallic elements, such as those in the p- and d-blocks, have atoms that can lose a variable number of electrons. As we saw in Section 1.18, the inert-pair effect implies that the elements listed in Fig. 1.52 can lose either their valence p-electrons alone or all their valence p- and s-electrons. These elements and the d-block metals can form different compounds, such as tin(II) oxide, SnO, and tin(IV) oxide, SnO2, for tin. The ability of an element to form ions with different charges is called variable valence. 56 CHAPTER 2 CHEMICAL BONDS 13/III 14/IV1 2 2 3 4 5 6 7 Li Na K Rb Cs Fr Be Mg Ca Sr Ba Ra Al Ga In Tl Sn Pb Ne Ar Kr Xe Rn BHe FIGURE 2.2 When a main-group metal atom forms a cation, it loses its valence s- and p-electrons and acquires the electron configuration of the preceding noble-gas atom. The heavier atoms in Groups 13/III and 14/IV retain their complete subshells of d-electrons. Formulas of some common cations are shown in Fig. C.6. TABLE 2.1 Some Typical Electron Configurations of Atoms and the Ions They Form Atom Configuration Ion Configuration Li [He]2s1 Liϩ [He] (1s2 ) Be [He]2s2 Be2ϩ [He] Na [Ne]3s1 Naϩ [Ne] ([He]2s2 2p6 ) Mg [Ne]3s2 Mg2ϩ [Ne] Al [Ne]3s2 3p1 Al3ϩ [Ne] N [He]2s2 2p3 N3– [Ne] ([He]2s2 2p6 ) O [He]2s2 2p4 O2– [Ne] F [He]2s2 2p5 F– [Ne] S [Ne]3s2 3p4 S2– [Ar] ([Ne]3s2 3p6 ) Cl [Ne]3s2 3p5 Cl– [Ar] EXAMPLE 2.1 Writing the electron configurations of cations Write the electron configurations of (a) Inϩ and (b) In3ϩ . Anticipate Because In is in Group 13, with the “generic” electron configuration [core]s2 p1 , we can expect successive loss of the p-electron and then the two s-electrons to give the configurations [core]s2 and [core], respectively. PLAN Determine the configuration of the neutral atom from its position in the periodic table. Remove electrons from the valence-shell p-orbitals first, then from the s-orbitals, and finally, if necessary, from the d-orbitals in the next-lower shell, until the number of electrons removed equals the charge on the ion. Naϩ ClϪ FIGURE 2.1 This tiny fragment of sodium chloride is an example of an ionic solid. The sodium ions are represented by pale red spheres and the chloride ions by green spheres. An ionic solid consists of an array of enormous numbers of cations and anions stacked together to give the lowest energy arrangement. The pattern shown here is repeated throughout the crystal. Animation 2.1 Evaluate As we anticipated from the location of the element in the periodic table, the two configurations have the form [core]s2 (as in [Kr]4d10 5s2 ) and [core] (as in [Kr]4d10 ). Self-Test 2.1A Write the electron configurations of (a) the copper(I) ion and (b) the copper(II) ion. [Answer: (a) [Ar]3d10 , [Ar]3d9 ] Self-Test 2.1B Write the electron configurations of (a) the manganese(II) ion and (b) the lead(IV) ion. Nonmetals rarely lose electrons in chemical reactions because their ionization energies are too high. However, a nonmetal atom can acquire enough electrons to complete its valence shell and form an anion with an octet corresponding to the configuration of the next noble gas (1s2 in the case of the hydride ion, HϪ ), Fig. 2.3. It does not gain more electrons, because any additional electrons would have to be accommodated in a higher-energy shell. To form a monatomic anion, we add enough electrons to complete the valence shell. For example, nitrogen has five valence electrons (1); so three more electrons are needed to reach a noble-gas configuration, that of neon. Therefore, the nitride ion will be N3Ϫ (2). Notice that in each case the ion has the electron configuration of the next noble gas. Self-Test 2.2A Predict the chemical formula and electron configuration of the phosphide ion. [Answer: P3Ϫ , [Ne]3s2 3p6 ] Self-Test 2.2B Predict the chemical formula and electron configuration of the iodide ion. To predict the electron configuration of a monatomic cation, remove outermost electrons in the order np, ns, and (n – 1)d; for a monatomic anion, add electrons until the next noble-gas configuration has been reached. The transfer of electrons results in the formation of an octet (or duplet) of electrons in the valence shell on each of the atoms: metals achieve an octet (or duplet) by electron loss and nonmetals achieve it by electron gain. 2.1 THE IONS THAT ELEMENTS FORM 57 15/V14/IV 16/VI 17/VII 18/VIII 2 1 3 4 5 6 N H P As Sb Po C Si Ge Bi O S Se Te At F Cl Br I Ne Ar Kr Xe Rn He FIGURE 2.3 When nonmetal atoms acquire electrons and form anions, they do so until they have reached the electron configuration of the next noble gas. SOLVE Determine the configuration of the neutral atom. Indium is in Group 13/III, Period 5. Its ground-state configuration is therefore [Kr]4d10 5s2 5p1 . 5p 5s 4d (a) Remove the outermost electron. Inϩ is [Kr]4d10 5s2 5p 5s 4d (b) Remove the next two electrons. In3ϩ is [Kr]4d10 5p 5s 4d 2s 1 N [He]2s22p3 2p 2s 2 N3− [He]2s2 2p6 2p The formulas of some common anions are shown in Fig. C.7. 2.2 Lewis Symbols Many of our basic ideas about the chemical bond were proposed by G. N. Lewis in the early years of the twentieth century. Lewis devised a simple way to keep track of valence electrons when atoms form ionic bonds. He represented each valence electron as a dot and arranged the dots around the symbol of the element. A single dot represents an electron alone in an orbital; a pair of dots represents two paired electrons sharing an orbital. Examples of the Lewis symbols of atoms are The Lewis symbol for nitrogen, for example, represents the valence electron configuration 2s2 2px 1 2py 1 2pz 1 (see 1), with two electrons paired in a 2s-orbital and three unpaired electrons in different 2p-orbitals. The Lewis symbol is a visual summary of the valence-shell electron configuration of an atom and allows us to see what happens to the electrons when an ion forms. To work out the formula of an ionic compound by using Lewis symbols: • Represent the cation by removing the dots from the symbol for the metal atom. • Represent the anion by transferring those dots to the Lewis symbol for the nonmetal atom to complete its valence shell. • It might then be necessary to adjust the numbers of atoms of each kind so that all the dots removed from the metal atom symbols are accommodated by the nonmetal atom symbols. • Write the charge of each ion as a superscript in the normal way, using brackets to indicate that the charge is the overall charge of the ion. A simple example is the formula of calcium chloride. The calcium atom loses its two valence electrons when it forms the Ca2ϩ ion. Because each chlorine atom has one vacancy, two are required to accommodate the two electrons lost: The ratio of two chloride ions for each calcium ion results in the formula CaCl2. However, note that this is an empirical formula (Section E). There are no CaCl2 molecules. Crystals of CaCl2 contain huge numbers of these ions in three-dimensional arrays. Formulas of compounds consisting of the monatomic ions of main-group elements can be predicted by assuming that cations have lost all their valence electrons and anions have gained electrons in their valence shells until each ion has an octet of electrons, or a duplet in the case of H, Li, and Be. 2.3 The Energetics of Ionic Bond Formation To understand why a crystal of sodium chloride, an ionic compound, has a lower energy than widely separated sodium and chlorine atoms, we picture the formation of the solid as taking place in three steps: sodium atoms release electrons, these electrons attach to chlorine atoms, and then the resulting cations and anions clump together as a crystal. Chemists often analyze complex processes by breaking them down into simpler steps, which can be hypothetical steps such as these. Sodium is in Group 1 of the periodic table and can be expected to form a ϩ1 ion. However, the valence electron is tightly held by the effective nuclear charge—it does not just fall off. In fact, the ionization energy of sodium is 494 kJиmolϪ1 (see Fig. 1.51), and so we must supply that much energy to form the cations: Na(g) Naϩ (g) ϩ eϪ (g) energy required ϭ 494 kJиmolϪ1 ¡ Cl ϩ ϩCa Cl Cl Ca 2ϩϪ Cl Ϫ a a Å Å z a Å Å z a Å Å a a Å Å a∫B H z He å å N O Cl K Mg z z z Å Å z z Å Å za z a 58 CHAPTER 2 CHEMICAL BONDS The electron affinity of chlorine atoms is ϩ349 kJиmolϪ1 (see Fig. 1.54), and so we know that 349 kJиmolϪ1 of energy is released when electrons attach to chlorine atoms to form anions: Cl(g) ϩ eϪ (g) ClϪ (g) energy released ϭ 349 kJиmolϪ1 At this stage, the net change in energy (energy required - energy released) is 494 - 349 kJиmolϪ1 ϭ ϩ145 kJиmolϪ1 , an increase in energy. A gas of widely separated Naϩ and ClϪ ions has a higher energy than a gas of neutral Na and Cl atoms. Now consider what happens when gaseous Naϩ and ClϪ ions come together to form a crystalline solid. Their mutual attraction releases a lot of energy, and experimentally it is found that Naϩ (g) ϩ ClϪ (g) NaCl(s) energy released ϭ 787 kJиmolϪ1 Therefore, the net change in energy for the overall process Na(g) ϩ ClϪ (g) NaCl(s) is 145 Ϫ 787 kJиmolϪ1 ϭ Ϫ642 kJиmolϪ1 (Fig. 2.4), a huge decrease in energy. We conclude that a solid composed of Naϩ and ClϪ ions has a lower energy than does a collection of widely separated Na and Cl atoms. We can now begin to understand the formation of ionic bonds and learn when to expect them. There is a net lowering of energy below that of the individual atoms, provided the net attraction between ions is greater than the energy needed to make them. The major contribution to the energy requirement is normally the ionization energy of the element that forms the cation. Although some of this energy may be recovered from the electron affinity of the nonmetal when the anion is formed, in some cases energy is also needed to make the anion. For instance, we saw in Section 1.17 that the formation of an O2Ϫ ion from an O atom requires 703 kJиmolϪ1 and adds to the energy that must be recovered from the interactions between ions. Typically, only metallic elements have ionization energies that are low enough for the formation of ionic bonds to be energetically feasible. The energy required for the formation of ionic bonds is supplied largely by the attraction between oppositely charged ions. 2.4 Interactions Between Ions We have seen that a key contribution to the formation of ionic bonds is the strength of the interaction between ions in a solid: it must be strong enough to overcome the energy investment needed to make the ions. However, a very important point to note is that an ionic solid is not held together by bonds between specific pairs of ions: all the cations interact to a greater or lesser extent with all the anions, all the cations repel each other, and all the anions repel each other. An ionic bond is a “global” characteristic of the entire crystal, a net lowering of energy of the entire crystal. By assessing this interaction quantitatively we can see what determines the lattice energy of the solid, the difference in energy between the ions packed together in a solid and the ions widely separated as a gas. High lattice energy indicates that the ions interact strongly with one another to give a tightly bonded solid. The strong electrostatic interactions between charged ions account for the typical properties of ionic solids, such as their high melting points and their brittleness. A high temperature is required before the ions are able to move past one another to form a liquid. Ionic solids are brittle because of the same strong attractions and repulsions. We cannot just push a block of ions in one region of the crystal past the ions in a neighboring region: when we strike an ionic solid, ions with like charges come into contact and repel one another. The resulting repulsions cause it to shatter into fragments (Fig. 2.5). ¡ ¡ ¡ 2.4 INTERACTIONS BETWEEN IONS 59 Energy NaCl 145 kJиmolϪ1 787 kJиmolϪ1 Naϩ Na Cl ClϪ FIGURE 2.4 Considerable energy is needed to produce cations and anions from neutral atoms: the ionization energy of the metal atoms is only partly recovered from the electron affinity of the nonmetal atoms. The overall lowering of energy that drags the ionic solid into existence arises from the strong attraction between cations and anions that occurs in the solid. In Chapter 7, we discuss the actual chemical reaction between Na(s) and Cl2(g): this illustration is for the energies of Na(g) and Cl(g) relative to the energy of NaCl(s). A positive electron affinity signifies a release of energy when an electron attaches to a gas-phase atom or ion (Section 1.18). Our starting point for understanding the interaction between ions in a solid is the expression for the Coulomb potential energy of the interaction of two individual ions (Section B): (1)* In this expression, e is the fundamental charge (the absolute value of the charge of an electron), z1 and z2 are the charge numbers of the two ions, r12 is the distance between the centers of the ions, and (“epsilon zero”) is the vacuum permittivity (see inside the back cover for the value of this fundamental constant). A note on good practice: The charge number, z, is positive for cations and negative for anions and the charge of an ion is ze. However, chemists almost always refer to z itself as the charge, and speak of a charge of ϩ1, Ϫ1, and so on. Each ion in a solid experiences attractions from all the other oppositely charged ions and repulsions from all the other like-charged ions. The total potential energy is the sum of all these contributions. Each cation is surrounded by anions, and there is a large negative (energy-lowering) contribution from the attraction of the opposite charges. Beyond those nearest neighbors, there are cations that contribute a positive (repulsive, energy-raising) term to the total potential energy of the central cation. There is also a negative contribution from the anions beyond those cations, a positive contribution from the cations beyond them, and so on, to the edge of the solid. These repulsions and attractions become progressively weaker as the distance from the central ion increases, but because the nearest neighbors of an ion give rise to a strong attraction, the net outcome of all these contributions is a lowering of energy. Our task is to assess how far the energy is lowered by using the Coulomb potential energy expression in Eq. 1. ε0 Ep,12 = (z1e) * (z2e) 4␲ε0r12 = z1z2e2 4␲ε0r12 60 CHAPTER 2 CHEMICAL BONDS FIGURE 2.5 This sequence of images illustrates why ionic solids are brittle. (a) The original solid consists of an orderly array of cations and anions. (b) A hammer blow can push ions with like charges into adjacent positions; this proximity of like charges raises strong repulsive forces (as depicted by the double-headed arrows). (c) As the result of these repulsive forces, the solid breaks apart into fragments. (d) The smooth faces of this calcite crystal result from the regular arrangement of the calcium and carbonate ions. (e) The blow of a hammer has shattered the crystal, leaving flat, regular surfaces consisting of planes of ions. Compare this image with the result of striking a metallic crystal (Fig. 6.2). HOW DO WE DO THAT? To calculate the electrostatic potential energy of an ionic solid we start with a simple model: a single line of uniformly spaced alternating cations and anions, with d the distance between their centers, the sum of the ionic radii (Fig. 2.6). If the charge numbers of the ions have the same absolute value (ϩ1 and Ϫ1, or ϩ2 and Ϫ2, for instance), then z1 ϭ ϩz, (a) (b) (c) (d) (e) Ϫzϩz d FIGURE 2.6 The arrangement used to calculate the potential energy of an ion in a line of alternating cations (red spheres) and anions (green spheres). We concentrate on one ion, the “central” ion denoted by the vertical dotted line. z2 ϭ Ϫz, and z1z2 ϭ Ϫz2 . The potential energy of the central ion is calculated by summing all the Coulomb potential energy terms, with negative terms representing attractions to oppositely charged ions and positive terms representing repulsions from like-charged ions. For the interaction arising from ions extending in a line to the right of the central ion, the total potential energy of the central ion is In the last step, we have used the relation . Next, we multiply Ep by 2 to obtain the total energy arising from interactions with ions on each side of the ion. We then multiply by Avogadro’s constant, NA, to obtain the potential energy per mole of ions. At this point, we know the total potential energy per mole of ions of one kind (cations, for instance) is The same expression applies to the energy per mole of the anions present: However, we cannot simply add the two expressions together to get the total potential energy, for in doing so we would count each interaction (Jack with Jill, Jill with Jack) twice. Therefore, the total energy per mole of pairs of ions is half this sum, which is with d ϭ rcation ϩ ranion the distance between the centers of neighboring ions. We have found that the molar potential energy of a one-dimensional crystal in which cations and anions alternate along a line has the form (2) with A ϭ 2 ln 2 (or 1.386) for this model system. What does this equation tell us? Because the potential energy is negative, there is a net lowering of energy, which means that the attraction between opposite charges overcomes the repulsion between like charges. The potential energy is strongly negative when the ions are highly charged (large values of z) and the separation between them is small (small values of d), which is the case when the ions themselves are small. The calculation that led to Eq. 2 can be extended to more realistic three-dimensional arrays of ions with different charges. The result has the same form but with different values of A and |z1z2| (that is, the absolute value of z1z2, its value without the negative sign) in place of z2 . The factor A is a numerical coefficient called the Madelung constant; its value depends on how the ions are arranged about one another (Table 2.2). In all cases, the energy lowering that occurs when an ionic solid forms is greatest for small, highly charged ions. For example, there is a strong interaction between the Mg2+ and the O2– ions in magnesium oxide, MgO, because the ions have high charges and small radii. This strong interaction is one reason why magnesium oxide survives at such high temperatures that it can be used for furnace linings. It is an example of a “refractory” material, a substance that can withstand high temperatures. Ep = -A * NAz2 e2 4␲ε0d Ep = 1 2 {Ep(cations) + Ep(anions)} = -2 ln2 * NAz2 e2 4␲ε0d Ep(anions) = -2 ln2 * NAz2 e2 4␲ε0d Ep(cations) = -2 ln2 * NAz2 e2 4␲ε0d 1 - 1 2 + 1 3 - 1 4 + . . . = ln2 = - z2 e2 4␲ε0d a1 - 1 2 + 1 3 - 1 4 + Áb = - z2 e2 4␲ε0d * ln2 Ep = e2 4␲ε0 * a - z2 d + z2 2d - z2 3d + Áb 2.4 INTERACTIONS BETWEEN IONS 61 TABLE 2.2 Madelung Constants Structural type* A cesium chloride 1.763 fluorite 2.519 rock salt 1.748 rutile 2.408 *For information about these structures, see Chapter 5. The potential energy in Eq. 2 becomes more and more negative as the separation d decreases. However, a collection of ions does not collapse to a point because repulsive effects between neighbors become important as soon as they come into contact, and the energy quickly rises again. To take the repulsion effects between close neighbors in an ionic solid into account it is commonly supposed that the repulsive contribution to the potential energy rises exponentially with decreasing separation and therefore has the form Ep* eϪd/d* with d* a constant (it is commonly taken to be 34.5 pm). The total potential energy is the sum of Ep and Ep* and passes through a minimum as the ion separation decreases and then rises sharply again (Fig. 2.7). The energy at the minimum is given by the Born–Mayer equation (which we do not derive here): (3)* What does this equation tell us? As before, the negative sign of this potential energy tells us that the ions have a lower potential energy when they are present as a solid rather than widely separated as a gas. The greatest stabilization is expected when the ions are highly charged (so |z1z2| is large) and small (so d is small, but not smaller than d*). We can now see why nature has adopted an ionic solid, calcium phosphate, for our skeletons: the doubly charged small Ca2ϩ ions and the triply charged PO4 3Ϫ ions attract one another very strongly and clump together tightly to form a rigid, insoluble solid (Fig. 2.8). Ionic solids typically have high melting points and are brittle. The coulombic interaction between ions in a solid is large when the ions are small and highly charged. Ep,min = -A * NA|z1z2|e2 4␲ε0d a1 - d* d b r 62 CHAPTER 2 CHEMICAL BONDS EXAMPLE 2.2 Estimating the relative lattice energies of solids The ionic solids NaCl and KCl form the same type of crystal structure. In which solid are the ions bound together more strongly by coulombic interactions? Anticipate Because sodium lies above potassium in the same group, we anticipate that the ionic radius of sodium is less than that of potassium and, therefore, that NaCl is more strongly bonded than KCl. PLAN Compare the radii of the ions (Fig. 1.48), for they determine the size of the separation d. SOLVE Naϩ ClϪ ClϪ Kϩ We compare the radii: The radius of Naϩ is 102 pm and that of Kϩ is 138 pm; the radius of ClϪ is 181 pm. Evaluate As we anticipated, the ions in NaCl should be bound together more strongly than those in KCl because the Naϩ ion has a smaller radius than the Kϩ ion and so d is smaller in NaCl than in KCl. Self-Test 2.3A The ionic solids CaO and KCl crystallize to form structures of the same type. In which compound are the interactions between the ions stronger? [Answer: CaO, higher charges and smaller radii] Self-Test 2.3B The ionic solids KBr and KCl crystallize to form structures of the same type. In which compound are the interactions between ions stronger? 0 0 Lattice parameter, d Totalpotentialenergy EP,min FIGURE 2.7 The potential energy of an ionic solid, taking into account the coulombic interaction of the ions and the exponential increase in their repulsion when they are in contact. The minimum potential energy is given by the Born–Mayer equation, Eq. 3. COVALENT BONDS Because nonmetals do not form monatomic cations, the nature of bonds between atoms of nonmetals puzzled scientists until 1916, when Lewis published his explanation. With brilliant insight, and before anyone knew about quantum mechanics or orbitals, Lewis proposed that a covalent bond is a pair of electrons shared between two atoms (3). The rest of this chapter and the next develop Lewis’s vision of the covalent bond. In this chapter, we consider the types, numbers, and properties of bonds that can be formed by sharing pairs of electrons. In Chapter 3, we see how to understand Lewis’s concept in terms of orbitals. 2.5 Lewis Structures When ionic bonds form, the atoms of one element lose electrons and the atoms of the second element gain them until both types of atoms have reached a noble-gas configuration. The same idea can be extended to covalent bonds. However, when a covalent bond forms, atoms share electrons until they reach a noble-gas configuration. Lewis called this principle the octet rule: In covalent bond formation, atoms go as far as possible toward completing their octets by sharing electron pairs. For example, nitrogen has five valence electrons and needs three more electrons to complete its octet. Chlorine has seven valence electrons and needs one more electron to complete its octet. Argon already has a complete octet and has no tendency to share any more electrons. Hydrogen needs one more electron to reach its helium-like duplet. Because hydrogen completes its duplet by sharing one pair of electrons, we say that it has “a valence of 1” in all its compounds. In general, the valence of an element is the number of bonds that its atoms can form. We can extend the Lewis symbols introduced in Section 2.2 to describe covalent bonding by using a line (∫) to represent a shared pair of electrons. For example, the hydrogen molecule formed when two Hи atoms share an electron pair (H a H) is represented by the symbol H∫H. A fluorine atom has seven valence electrons and needs one more to complete its octet. It can achieve an octet by accepting a share in an electron supplied by another atom, such as another fluorine atom: The circles drawn around each F atom show how each one gets an octet by sharing one electron pair. The valence of fluorine is therefore 1, the same as that of hydrogen. As well as a bonding pair of electrons, a fluorine molecule also possesses lone pairs of electrons; that is, pairs of valence electrons that do not take part in bonding. The lone pairs on one F atom repel the lone pairs on the other F atom, and this repulsion is F F F Fϩ , orå Å Å å Å Å å Å Å z å Å Å z ∫B F ¬ F (H z) (å Ar å) ¥ ¥ (åCl z) ¥ ¥ (å N z) z z 2.5 LEWIS STRUCTURES 63 3 Shared electron pair PO4 3Ϫ 3Ϫ Ca2ϩ FIGURE 2.8 A micrograph of bone, which owes its rigidity to calcium phosphate. The overlay shows part of the crystal structure of calcium phosphate. Phosphate ions are polyatomic ions; however, as shown in the inset, they are nearly spherical and fit into crystal structures in much the same way as monatomic ions of charge Ϫ3. almost enough to overcome the favorable attractions of the bonding pair that holds the atoms together. This repulsion is one of the reasons why fluorine gas is so reactive: the atoms are bound together as F2 molecules only very weakly. Among the common diatomic molecules, only H2 has no lone pairs. The Lewis structure of a molecule shows atoms by their chemical symbols, covalent bonds by lines, and lone pairs by pairs of dots. For example, the Lewis structure of HF is .We shall see that Lewis structures are a great help in understanding the properties of molecules, including their shapes and the reactions that they can undergo. Self-Test 2.4A Write the Lewis structure for the “interhalogen” compound chlorine monofluoride, ClF, and state how many lone pairs each atom possesses in the compound. [Answer: ; three on each atom] Self-Test 2.4B Write the Lewis structure for the compound HBr and state how many lone pairs each atom in the compound possesses. Nonmetal atoms share electrons until each has completed its octet (or duplet); a Lewis structure shows the arrangement of electrons as lines (bonding pairs) and dots (lone pairs). 2.6 Lewis Structures of Polyatomic Species Each atom in a polyatomic molecule completes its octet (or duplet for hydrogen) by sharing pairs of electrons with its immediate neighbors. Each shared pair counts as one covalent bond and is represented by a line between the two atoms. A Lewis structure does not in general portray the three-dimensional shape of a polyatomic molecule; it simply displays which atoms are bonded together and which atoms have lone pairs. Let’s construct the Lewis structure for the simplest organic molecule, the hydrocarbon methane, CH4. First, we count the valence electrons available from all the atoms in the molecule. For methane, the Lewis symbols of the atoms are and so there are eight valence electrons. The next step is to arrange the dots representing the electrons so that the C atom has an octet and each H atom has a duplet. We draw the arrangement shown on the left in (4); the Lewis structure of methane is then drawn as shown on the right in (4). Because the carbon atom is linked by four bonds to other atoms, we say that carbon is tetravalent: it has a valence of 4. We emphasize once again that a Lewis structure does not in general show the shape of the molecule, just the pattern of bonds, its “connectivity.” In Chapter 3, we shall see that the three-dimensional arrangement of bonds in a methane molecule is in fact tetrahedral. The general procedure for constructing the Lewis structure of any molecule or ion is set out in Toolbox 2.1 at the end of this section, but the following information is essential for applying those rules. A single shared pair of electrons is called a single bond. Two electron pairs shared between two atoms constitute a double bond, and three shared electron pairs constitute a triple bond. A double bond, such as Ca a O, is written C¢O in a Lewis structure. Similarly, a triple bond, such as Ca a a C, is written CΩC. Double and triple bonds are collectively called multiple bonds. The bond order is the number of bonds that link a specific pair of atoms. The bond order in H2 is 1; in the group C¢O, it is 2; and for CΩC in a molecule such as ethyne, C2H2, the bond order is 3. To write a Lewis structure, we need to know which atoms are linked together in a molecule. A “terminal” atom is bonded to only one other atom; an H atom in methane is an example. Except in the strange compounds called the boranes (Section 15.11), an H atom is always a terminal atom. A “central” atom is bonded to at least two other atoms. Two examples are the O atom in a water molecule, HOH, and the C atom in methane. The arrangement of atoms in a molecule and the identity of the central atom are often known in advance (for instance, it is easy to remember the arrangements of H H H HC z za zzzz Cl¬F å Å Å å Å Å H¬F å Å Å 64 CHAPTER 2 CHEMICAL BONDS It is sometimes necessary to write a Lewis structure at the end of a sentence or clause: be careful to distinguish electron dots from periods and colons! C H H HH C H H HH 4 Methane, CH4 atoms in CH4, NH3, and H2O). If there is doubt, a good rule of thumb for molecules other than compounds of hydrogen is to choose as the central atom the element with the lowest ionization energy. This arrangement often results in the lowest energy because an atom in the central position shares more of its electrons than does a terminal atom. Atoms with higher ionization energies are more reluctant to share and are more likely to hold on to their electrons as lone pairs. Another rule of thumb for predicting the structure of a molecule is to arrange the atoms symmetrically around the central atom. For instance, SO2 is OSO, not SOO. One common exception to this rule is dinitrogen monoxide, N2O (nitrous oxide), which has atoms in the asymmetrical arrangement NNO. Another clue for writing the correct arrangement of atoms is that, in simple chemical formulas, the central atom is often written first, followed by the atoms attached to it. For example, in the compound with the chemical formula OF2, the arrangement of the atoms is actually FOF, not OFF; and, in SF6, the S atom is surrounded by six F atoms. Acids are exceptions to this rule, because the H atoms are written first, as in H2S, which has the arrangement HSH. If the compound is an oxoacid, then the acidic hydrogen atoms are attached to oxygen atoms, which in turn are attached to the central atom. For example, the arrangement of atoms in sulfuric acid, H2SO4, is (HO)2SO2 (5), and that in hypochlorous acid, with the formula HClO, is actually HOCl. Finally, the same general procedure is used to determine the Lewis structures of polyatomic ions, except that we add or subtract electrons to account for the charge on the ion. We count the electrons available for bonds and lone pairs, arrange the atoms in the appropriate order, and then construct the Lewis structure. As for neutral molecules, it is essential to know the general arrangement of atoms in the ion. For oxoanions, it is usually the case that (except for H) the atom written first in the chemical formula is the central atom. In CO3 2– , for instance, the C atom is surrounded by three O atoms. Each atom provides the number of dots (electrons) equal to the number of electrons in its valence shell, but we have to adjust the total number of dots to represent the overall charge. For a cation, we subtract one dot for each positive charge. For an anion, we add one dot for each negative charge. The cation and the anion must be treated separately: they are individual ions and are not linked by shared pairs. The Lewis structure of ammonium carbonate, (NH4)2CO3, for instance, is written as three bracketed ions (6). 2.6 LEWIS STRUCTURES OF POLYATOMIC SPECIES 65 O O O O H S H 5 O O C 6 O H H + H H N H H H H N 2− + TOOLBOX 2.1 HOW TO WRITE THE LEWIS STRUCTURE OF A POLYATOMIC SPECIES CONCEPTUAL BASIS We look for ways of using all the valence electrons to complete the octets (or duplets). PROCEDURE Step 1 Count the number of valence electrons on each atom; for ions adjust the number of electrons to account for the charge. Divide the total number of valence electrons in the molecule by 2 to obtain the number of electron pairs. Step 2 Write down the most likely arrangements of atoms by using common patterns and the clues indicated in the text. Step 3 Place one electron pair between each pair of bonded atoms. Step 4 Complete the octet (or duplet, in the case of H) of each atom by placing any remaining electron pairs around the atoms. If there are not enough electron pairs, form multiple bonds. Step 5 Represent each bonded electron pair by a line. To check on the validity of a Lewis structure, verify that each atom has an octet or a duplet. As we shall see in Section 2.10, a common exception to this rule arises when the central atom is an atom of an element in Period 3 or higher. Such an atom can accommodate more than eight electrons in its valence shell. Consequently, the most stable Lewis structure may be one in which the central atom has more than eight electrons. This procedure is illustrated in Examples 2.3 and 2.4. In Section 2.12, when we have met the concept of electronegativity, we shall see that another and more common way to express this rule is to say that the central atom is usually the element with lowest electronegativity. EXAMPLE 2.3 Writing the Lewis structure of a molecule or an ion Write the Lewis structures of (a) water, H2O; (b) methanal, H2CO; and (c) the chlorite ion, ClO2 Ϫ . Use the rules in Toolbox 2.1; note that we must add one electron for the negative charge of ClO2 Ϫ . Anticipate It is hard to anticipate Lewis structures when you are starting out in your studies, but as you gain experience, you will be able to write them down without going through the systematic procedure used here. PLAN Go through the steps set out in the Toolbox. 66 CHAPTER 2 CHEMICAL BONDS SOLVE (a) H2O (b) H2CO (c) ClO2 Ϫ Step 1 Count the valence electrons and 1 ϩ 1 ϩ 6 ϭ 8 1 ϩ 1 ϩ 4 ϩ 6 ϭ 12 7 ϩ 6 ϩ 6 ϩ 1 ϭ 20 adjust the number for charges on ions. Count the electron pairs. 4 6 10 Step 2 Arrange the atoms. Step 3 Connect the atoms with bonding electron pairs. Count electron pairs not yet located. Step 4 Complete the octets. Step 5 Represent the bonds. O ¬Cl ¬Oå ¥ ¥ å ¥ ¥ ¥ ¥ Ϫ O© ¥ ¥ H C H ˚ ˚ H ¬ O ¬ H ¥ ¥ O Cl Oå åå ¥ ¥ å ¥ ¥ ¥ ¥ Ϫ H C H Oå å ¥ ¥ ¥ ¥ H å O å H ¥ ¥ (8)å å å å å å å å(3)å å å(2)å å O Cl Oå åH C H Oå ¥ ¥ H å O å H O Cl OH C H O H O H Self-Test 2.5A Write a Lewis structure for the cyanate ion, CNOϪ (the C atom is in the center). [Answer: ] Self-Test 2.5B Write a Lewis structure for NH3. N ¥ ¥ © © ¥ ¥ Ϫ OC SOLVE CH3COOH Step 1 Count the valence electrons to determine : : : : : : : : : : : : the number of electron pairs: 4 ϩ (3 ϫ 1) ϩ 4 ϩ 6 ϩ 6 ϩ 1 ϭ 24, 12 pairs EXAMPLE 2.4 Writing Lewis structures for molecules with more than one “central” atom Write the Lewis structure for acetic acid, CH3COOH, the carboxylic acid in vinegar that forms when the ethanol in wine is oxidized. In the ∫COOH group, both O atoms are attached to the same C atom, and one of them is bonded to the final H atom. The two C atoms are bonded to each other. Anticipate The formula of acetic acid suggests that the molecule consists of a CH3ß group and a ∫COOH group. We can anticipate that the CH3ß group, by analogy with methane, will consist of a C atom joined to three H atoms by single bonds. PLAN Apply the procedure in Toolbox 2.1. Step 2 Arrange atoms (linked atoms are indicated by the rectangles). 2.7 RESONANCE 67 H C CH H O O H Step 3 Connect the atoms with bonding electron pairs. Count electron pairs not yet located. Step 4 Complete the octets. Step 5 Represent the bonds. C H H H C O O H © ˚ ˚ ˚ ¬ ¬ ¬å å å Å H O O H H H å CC å åå åå Å ÅÅ Å Å Å å å å å å (5 pairs) H O O H H H å CC å å Å Å Å Å Self-Test 2.6A Write a Lewis structure for the urea molecule, (NH2)2CO. [Answer: See (7).] Self-Test 2.6B Write a Lewis structure for hydrazine, H2NNH2. The Lewis structure of a polyatomic species is obtained when all the valence electrons are used to complete the octets (or duplets) of the atoms present by forming single or multiple bonds and leaving some electrons as lone pairs. 2.7 Resonance Some molecules are not represented adequately by a single Lewis structure. For example, consider the nitrate ion, NO3 Ϫ , which, as potassium nitrate, is used in fireworks and fertilizers. The three Lewis structures shown in (8) differ only in the position of the double bond. All are valid structures and have exactly the same energy. If one of the pictured structures were correct, we would expect the nitrate ion to have two long single bonds and one short double bond because a double bond between two atoms is shorter than a single bond between the same types of atoms. However, detailed measurements have shown that the bond lengths in a nitrate ion are all the same. At 124 pm, they are longer than a typical N¢O double bond (120 pm) but shorter than a typical N∫O single bond (140 pm). The bond order in the nitrate ion lies between 1 (a single bond) and 2 (a double bond). Thinking point: How do you think lengths as short as 120 pm could be measured? (For an answer, see Box 2.2.) Because all three bonds are identical, a better model of the nitrate ion is a blend of all three Lewis structures with each bond intermediate in properties between a single and a double bond. This blending of structures, which is called resonance, is depicted in (9) by double-headed arrows. The blended structure is a resonance hybrid of the Bond length, the distance between the centers of bonded atoms, is discussed in more detail in Section 2.16. 7 Urea, (NH2)2CO O H H C H HNN contributing Lewis structures. A molecule does not flicker between different structures: a resonance hybrid is a blend of structures, just as a mule is a blend of a horse and a donkey, not a creature that flickers between the two. Electrons that are shown in different positions in a set of resonance structures are said to be delocalized. Delocalization means that a shared electron pair is distributed over several pairs of atoms and cannot be identified with just one pair of atoms. As well as delocalizing electrons over the atoms, resonance also lowers the energy below that of any single contributing structure and helps to stabilize the molecule. This lowering of energy occurs for quantum mechanical reasons. Broadly speaking, the wavefunction that describes the resonance structure is a more accurate description of the electronic structure of the molecule than the wavefunction for any single structure alone, and the more accurate the wavefunction, the lower the corresponding energy. The following points will help you to write appropriate resonance structures and to predict which are more important: • In each contributing structure, the nuclei are in the same positions; only the locations of lone pairs and bonding pairs are changed. • Structures with the same energy (so called “equivalent structures”) contribute equally to the resonance. • Low-energy structures contribute more to the resonance mixture than high-energy structures. For example, although we might be able to write the two hypothetical structures NNO and NON for the dinitrogen oxide (nitrous oxide) molecule, there is no resonance between them, because the atoms lie in different locations. 68 CHAPTER 2 CHEMICAL BONDS 8 O N − OO N − OO O N − O O O 9 Nitrate ion, NO3 Ϫ bıB bıB O N − OO N − OO O N − O O O Count the valence electrons. Oxygen is a member of Group 16/VI; so each atom has six valence electrons: 6 ϩ 6 ϩ 6 ϭ 18 electrons. Draw a Lewis structure for the molecule. Draw a second Lewis structure by exchanging the bonds. Draw the resonance hybrid as the two resonance structures connected with a double-headed arrow. O¬ O £ O $$ $ $ $ $ O£ O ¬ O $$ $ $ $ $· O £ O ¬ O $$ $ $ $ $ O¬O£O $$ $ $ $ $ EXAMPLE 2.5 Writing a resonance structure Stratospheric ozone, O3, protects life on Earth from harmful ultraviolet radiation from the Sun. Suggest two Lewis structures that contribute equally to the resonance structure for the O3 molecule. Experimental data show that the two bond lengths are the same. PLAN Write a Lewis structure for the molecule by using the method outlined in Toolbox 2.1. Decide whether there is another equivalent structure that results from the interchange of a single bond and a double or triple bond. Write the actual structure as a resonance hybrid of these Lewis structures. SOLVE Self-Test 2.7A Write Lewis structures contributing to the resonance hybrid for the acetate ion, CH3CO2 Ϫ . The structure of CH3COOH is described in Example 2.4; the acetate ion has a similar structure, except that it has lost the final H atom while keeping both electrons from the OH bond. [Answer: See (10).] C H H H C O b∫B Oෆ͉ Ϫ C H H H C O Oෆ͉ Ϫ 10 Acetate ion, CH3CO2 Ϫ Self-Test 2.7B Write Lewis structures contributing to the resonance hybrid for the nitrite ion, NO2 Ϫ . Benzene, C6H6, is another molecule best described as a resonance hybrid. It consists of a planar hexagonal ring of six carbon atoms, each one having a hydrogen atom attached to it. One Lewis structure that contributes to the resonance hybrid is shown in (11); it is called a Kekulé structure. The structure is normally written as a line structure (see Section C), a simple hexagon with alternating single and double lines (12). The difficulty with a single Kekulé structure is that it does not fit all the experimental evidence: • Reactivity Benzene does not undergo reactions typical of compounds with double bonds. For example, when a solution of red-brown bromine is mixed with an alkene such as 1hexene, CH2∞CHCH2CH2CH2CH3, the color due to bromine is lost as the Br2 molecule reacts with the molecule at the double bond to produce CH2Br∫CHBrCH2CH2CH2CH3 (Fig. 2.9). However, benzene does not react with liquid bromine. • Bond lengths All the carbon–carbon bonds in benzene are the same length. A Kekulé structure suggests that benzene should have two different bond lengths: three longer single bonds (154 pm) and three shorter double bonds (134 pm). Instead, all the bonds are found experimentally to have the same intermediate length (139 pm). • Structural evidence Only one 1,2-dichlorobenzene (in which the chlorine atoms are attached to two adjacent carbon atoms) exists. If the Kekulé structure were correct, there would be two distinct 1,2-dichlorobenzenes (13), one in which the carbon atoms are joined by a single bond and one with a double bond. In fact, only one 1,2-dichlorobenzene is known. We can use the concept of resonance to explain these characteristics of the benzene molecule. There are two Kekulé structures with exactly the same energy: they differ only in the positions of the double bonds. As a result of resonance between these two equivalent structures (14), the electrons shared in the C∞C double bonds are delocalized over the whole molecule, thereby giving each bond a length intermediate between that of a single and that of a double bond. Resonance makes all six C∫C bonds identical; this equivalence is implied by representing the double bonds in the resonance hybrid with a circle (15). We can see from (16) why there can be only one 1,2dichlorobenzene. Finally, as we have remarked, an important consequence of resonance is that it stabilizes a molecule by lowering its total energy. This stabilization makes benzene less reactive than expected for a molecule with three carbon–carbon double bonds. Resonance is a blending of structures with the same arrangement of atoms but different arrangements of electrons. It spreads multiple bond character over a molecule and results in a lower energy. 2.8 Formal Charge Nonequivalent Lewis structures—Lewis structures that do not correspond to the same energy—do not in general make the same contribution to a resonance structure. One way to decide which structures are likely to make the major contribution is to compare the number of valence electrons distributed around each atom in a structure with the FIGURE 2.9 When bromine dissolved in a solvent (the brown liquid) is mixed with an alkene (the colorless liquid), the bromine atoms add to the alkene molecule at the double bond, resulting in colorless products. C CC C C C H H H H H H 11 Kekulé structure 12 Kekulé structure, stick form Cl Cl Cl Cl 13 Dichlorobenzene, C6H4Cl2 The German chemist Friedrich Kekulé first proposed (in 1865) that benzene has a cyclic structure with alternating single and double bonds. Other arrangements may be drawn, but they differ from the one shown only by a rotation of the molecule. 14 Benzene resonance structure bB 15 Benzene, C6H6 Cl Cl 16 1,2-Dichlorobenzene, C6H4Cl2 2.8 FORMAL CHARGE 69 number of valence electrons on the free atoms. The smaller these differences for a structure, the lower is its energy and the greater is its contribution to a resonance hybrid. A measure of the redistribution of electrons is the formal charge on an atom in a given Lewis structure, the charge it would have if the bonding were perfectly covalent in the sense that the atom had exactly a half-share in the bonding electrons. That is, the formal charge takes into account the number of electrons that an atom can be regarded as “owning” in a molecule. It “owns” all its lone pairs and half of each shared bonding pair. The difference between this number and the number of valence electrons in the free atom is the formal charge: (4)* where V is the number of valence electrons in the free atom, L is the number of electrons present on the bonded atom as lone pairs, and B is the number of bonding electrons on the atom. If the atom has more electrons in the molecule than when it is a free, neutral atom, then the atom has a negative formal charge, like a monatomic anion. If the assignment of electrons leaves the atom with fewer electrons than when it is free, then the atom has a positive formal charge, as if it were a monatomic cation. Formal charge can be used to predict the most favorable arrangement of atoms in a molecule and the most likely Lewis structure for that arrangement: A Lewis structure in which the formal charges of the individual atoms are closest to zero typically represents the lowest energy arrangement of the atoms and electrons. A low formal charge indicates that an atom has undergone the least redistribution of electrons relative to the free atom. The structure with formal charges closest to zero typically has the lowest energy of all possible structures. For example, the formal charge rule suggests that the structure OCO is more likely for carbon dioxide than COO, as shown in (17). Similarly, it also suggests that the structure NNO is more likely than NON for dinitrogen monoxide, as shown in (18). Formal charge = V - (L + 1 2B) 70 CHAPTER 2 CHEMICAL BONDS O OC CO O 0 0 0 0 +2 −2 17 18 +1−1 −1 N ON NN O 0 +2 −1 TOOLBOX 2.2 HOW TO USE FORMAL CHARGE TO DETERMINE THE MOST LIKELY LEWIS STRUCTURE CONCEPTUAL BASIS To assign a formal charge, we establish the “ownership” of the valence electrons of an atom in a molecule and compare that ownership with the free atom. An atom owns one electron of each bonding pair attached to it and owns its lone pairs completely. The most plausible Lewis structure will be the one in which the formal charges of the atoms are lowest. PROCEDURE Step 1 Decide on the number of valence electrons (V) possessed by each free atom by noting the number of its group in the periodic table. Step 2 Draw the Lewis structures. Step 3 For each bonded atom, count each electron in its lone pairs (L), plus one electron from each of its bonding pairs (B). Step 4 For each bonded atom, subtract the total number of electrons it “owns” from V, as in Eq. 4. Each equivalent atom (the same element, the same number of bonds and lone pairs) has the same formal charge. A check on the calculated formal charges is that their sum is equal to the overall charge of the molecule or ion. For an electrically neutral molecule, the sum of the formal charges is zero. Compare the formal charges of each possible structure. The structure with the lowest formal charges represents the least disturbance of the electronic structures of the atoms and is the most plausible (lowest energy) structure. This procedure is illustrated in Example 2.6. EXAMPLE 2.6 Selecting the most likely atom arrangement One test for the presence of iron(III) ions in solution is to add a solution of potassium thiocyanate, KSCN; a blood-red color indicates that a compound of iron and the thiocyanate ion has formed. Write three Lewis structures with different atomic arrangements for the thiocyanate ion and select the most likely structure by identifying the structure with formal charges closest to zero. For simplicity, consider only structures with double bonds between neighboring atoms. Anticipate The element with the lowest ionization energy (after you have read Section 2.12, you will find it is more appropriate to think “lowest electronegativity”) of the three is carbon, so we should expect it to be the central atom and for the structure to be NCSϪ . PLAN We proceed as set out in Toolbox 2.2. SOLVE NCS؊ CNS؊ CSN؊ Step 1 Count the valence C: 4, N: 5, S: 6 C: 4, N: 5, S: 6 C: 4, N: 5, S: 6 electrons V and, for ions, Charge: 1 Charge: 1 Charge: 1 adjust for the charge. Total: 16 Total: 16 Total: 16 electrons electrons electrons Step 2 Draw Lewis structures. Step 3 Assign electron ownership, L ϩ B. Step 4 Find formal charge, V – (L ϩ B). Evaluate The individual formal charges are closest to zero in the first column; the atom arrangement NCSϪ is therefore the most likely one, as we anticipated. Self-Test 2.8A Suggest a likely structure for the poisonous gas phosgene, COCl2. Write its Lewis structure and formal charges. [Answer: See (19).] Self-Test 2.8B Suggest a likely structure for the oxygen difluoride molecule. Write its Lewis structure and formal charges. Although formal charge and oxidation number (Section K of Fundamentals) both give us information about the number of electrons around an atom in a compound, they are determined by different methods and often have different values: • Formal charge exaggerates the covalent character of bonds by assuming that the electrons are shared equally. • Oxidation number exaggerates the ionic character of bonds. It represents the atoms as ions, and all the electrons in a bond are assigned to the atom with the lower ionization energy (in Section 2.12, we shall see that this is the more electronegative atom). Thus, although the formal charge of C in structure 17 for CO2 is 0, its oxidation number is ϩ4 because all the bonding electrons are assigned to the oxygen atoms to give a structure that could be represented O2Ϫ C4ϩ O2Ϫ . Formal charges depend on the particular Lewis structure we write; oxidation numbers do not. The formal charge gives an indication of the extent to which atoms have gained or lost electrons in the process of covalent bond formation; atom arrangements and Lewis structures with the lowest formal charges are likely to have the lowest energy. EXCEPTIONS TO THE OCTET RULE The octet rule accounts for the valences of many of the elements and the structures of many compounds. Carbon, nitrogen, oxygen, and fluorine obey the octet rule rigorously, provided there are enough electrons to go around. However, some compounds have an odd number of electrons. In addition, an atom of phosphorus, sulfur, chlorine, or another nonmetal in Period 3 and subsequent periods can accommodate more than eight electrons in its valence shell. The following two sections show how to recognize exceptions to the octet rule. 1 2 C £ S £ N $ $ $ $ Ϫ2 ϩ2 Ϫ1 C £ N £ S $ $ $ $ Ϫ2 ϩ1 0 N £ C £ S $ $ $ $ Ϫ1 0 0 1 2 C £ S £ N $ $ $ $ 6 4 6 C £ N £ S $ $ $ $ 6 4 6 N £ C £ S $ $ $ $ 6 4 6 C £ S £ N $ $ $ $C £ N £ S $ $ $ $N £ C £ S $ $ $ $ 2.8 FORMAL CHARGE 71 O 00 0 0 19 Phosgene, COCl2 Cl ClC 2.9 Radicals and Biradicals Some species have an odd number of valence electrons, and so at least one of their atoms cannot have an octet. Species having electrons with unpaired spins are called radicals. They are generally highly reactive. One example is the methyl radical, иCH3, which is so reactive that it cannot be stored. It occurs in the flames of burning hydrocarbon fuels. The single unpaired electron is indicated by the dot on the C atom in иCH3. Radicals are of crucial importance for the chemical reactions that take place in the upper atmosphere, where they contribute to the formation and decomposition of ozone. Radicals also play a role in our daily lives, sometimes a destructive one. They are responsible for the rancidity of foods and the degradation of plastics in sunlight. Damage from radicals can be delayed by an additive called an antioxidant, which reacts rapidly with radicals before the radicals have a chance to do their damage. Human aging is believed to be partly due to the action of radicals, and antioxidants such as vitamins C and E may delay the process (see Box 2.1). The nitric oxide molecule, NO, has an unpaired electron and plays an important role as a neurotransmitter. Because it is a radical, NO is very reactive and can be eliminated within a few seconds. Because it is small, the NO molecule can move easily throughout the body. These properties allow NO to play several roles, including controlling the supply of blood to various organs. A biradical is a molecule with two unpaired electrons. The unpaired electrons are usually on different atoms, as depicted in (20). In that biradical, one unpaired electron is on one carbon atom of the chain and the second is on another carbon atom several bonds away. In some cases, though, both electrons are on the same atom. One of the most important examples is the oxygen atom itself. Its electron configuration is [He]2s2 2px 2 2py 1 2pz 1 and its Lewis symbol is . The O atom has two unpaired electrons, and so it can be regarded as a special type of biradical. However, there is a difference: whereas in a normal biradical the relative orientations of the two electron spins are random, in an O atom they are locked together in a parallel arrangement. Self-Test 2.9A Write a Lewis structure for the hydrogenperoxyl radical, HOOи, which plays an important role in atmospheric chemistry and which, in the body, has been implicated in the degeneration of neurons. [Answer: See (21).] Self-Test 2.9B Write a Lewis structure for NO2. A radical is a species with an unpaired electron; a biradical has two unpaired electrons on either the same or different atoms. 2.10 Expanded Valence Shells The octet rule tells us that eight electrons fill the outer shell of an atom to give a noblegas ns2 np6 valence-shell configuration. However, when the central atom in a molecule has empty d-orbitals, it may be able to accommodate 10, 12, or even more electrons. The electrons in such an expanded valence shell may be present as lone pairs or may be used by the central atom to form additional bonds. A note on good practice: Although “expanded valence shell” is the logically precise term, most chemists still use the term expanded octet. Because the additional electrons must be accommodated in valence orbitals, only nonmetal atoms in Period 3 or later periods can expand their valence shells. Atoms of these elements have empty d-orbitals in the valence shell. Another factor—possibly the main factor—in determining whether more atoms than allowed by the octet rule can bond to a central atom is the size of that atom. A P atom is big enough for as many as six Cl atoms to fit comfortably around it, and PCl5 (which in the solid is PCl4 ϩ PCl6 Ϫ ) is a common laboratory chemical. An N atom, though, is too small, and NCl5 is unknown. A compound that contains an atom with more atoms attached to it than is permitted by the octet rule is called a hypervalent compound. O $ $ # # 72 CHAPTER 2 CHEMICAL BONDS The older, still widely used term for radicals is free radicals. The role of radicals in the depletion of stratospheric ozone is developed further in Box 14.3. C H H C H H C H H C H H C H H 20 A biradical H O O 21 Hydrogenperoxyl, HO2 . Elements that can expand their valence shells commonly show variable covalence, the ability to form different numbers of covalent bonds. Elements that have variable covalence can form one number of bonds in some compounds and a different number in others. Phosphorus is an example. It reacts directly with a limited supply of chlorine to form the toxic, colorless liquid phosphorus trichloride: The Lewis structure of the PCl3 molecule is shown in (22), and we see that it obeys the octet rule. However, when phosphorus trichloride reacts with more chlorine (Fig. 2.10), phosphorus pentachloride, a pale yellow crystalline solid, is produced: PCl3(l) + Cl2(g) ¡ PCl5(s) P4(s) + 6Cl2(g) ¡ 4 PCl3(l) 2.10 EXPANDED VALENCE SHELLS 73 Chemical Self-Preservation In nearly every pharmacy, supermarket, and health food store, you can find bottles of antioxidants and antioxidant-rich natural products, such as fish oils, Gingko biloba leaves, and wheat grass. These dietary supplements are intended to help the body control its population of radicals and, as a result, slow aging and degenerative diseases such as heart failure and cancer. Radicals occur naturally in the body, partly as a by-product of metabolism. They serve many useful functions but can cause trouble if they are not eliminated when they are no longer needed. They often contain oxygen atoms and oxidize the lipid (fat) molecules that make up cell membranes and other vital tissues. This oxidation changes the structures of the lipid molecules and hence affects the function of the membranes. Cell membranes damaged in this way may not be able to protect cells against disease, and heart and nerve cells may lose their function. Recent evidence suggests that radical damage to living cells is the main factor in the aging process. When the nucleic acids such as DNA and RNA are attacked by radicals, they cannot replicate properly. These alterations result in defective cells with diminished function and a lessened ability to protect themselves against diseases such as cancer. The body maintains an antioxidant network consisting of vitamins A, C, and E, antioxidant enzymes, and a group of related compounds called coenzyme Q, for which the general formula is shown below. The n represents the number of times that a particular group is repeated; it can be 6, 8, or 10. Antioxidants are molecules that are easily oxidized, so they react readily with radicals before the radicals can react with other compounds in the body. Many common foods, such as green leafy vegetables, orange juice, and chocolate, contain antioxidants, as do coffee and tea. WHAT HAS THIS TO DO WITH . . . STAYING ALIVE?BOX 2.1 Leaves of the Gingko biloba tree, which originated in China. Extracts of these leaves are thought to have antioxidant properties. Some also believe that the extracts improve thinking ability by increasing oxygen flow to the brain. Molecular structure of coenzyme Q, an antioxidant used by the body to control the level of radicals. Harmful environmental conditions, such as ultraviolet radiation, ozone in the air we breathe, poor nutrition, and tobacco smoke can cause oxidative stress, a condition in which the concentration of radicals has become so high that the body’s natural antioxidant network cannot cope. Premature aging of skin that has been overexposed to sunlight and lung cancer in smokers are two possible results. Herbal medicines containing certain phytochemicals, chemicals derived from plant sources and fish oils, are being investigated as antioxidants that can supplement the diet to protect against damage from free radicals. These same chemicals are also being studied for their ability to prolong life beyond the currently expected lifespan. Related Exercises: 2.56, 2.57, and 2.107 For Further Reading: D. Harman, “The aging process,” Proceedings of the National Academy of Sciences, 78 (2004), 7124. C. Goldberg, “The quest for immortality: Science at the frontiers of aging,” Science News, 162 (August 31, 2002), 143. A. Scalbert, I. T. Johnson, and M. Saltmarsh, “Polyphenols: antioxidants and beyond,” American Journal of Clinical Nutrition, 81, 215S–217S (2005). P Cl Cl Cl 22 Phosphorus trichloride, PCl3 O O O O CH C(CH3)CH2 units (n = 6, 8, 10)CH2n ... ... Phosphorus pentachloride is an ionic solid consisting of PCl4 ϩ cations and PCl6 Ϫ anions; but at 160°C, it vaporizes to a gas of PCl5 molecules. The Lewis structures of the polyatomic ions and the molecule are shown in (23) and (24). In the anion, the P atom has expanded its valence shell to 12 electrons, by making use of two of its 3d-orbitals. In PCl5, the P atom has expanded its valence shell to 10 electrons by using one 3d-orbital. Phosphorus pentachloride is therefore an example of a hypervalent compound in both its solid and its gaseous forms. EXAMPLE 2.7 Writing a Lewis structure with an expanded valence shell The fluoride SF4 forms when a mixture of fluorine and nitrogen gases is passed over a film of sulfur at 275°C in the absence of oxygen and moisture. Write the Lewis structure of sulfur tetrafluoride and give the number of electrons in the expanded valence shell. Anticipate Sulfur, in Group 16/VI, has six valence electrons; if each fluorine atom provides one electron for the bond it forms, we can expect there to be 4 ϩ 6 ϭ 10 electrons around the S atom. PLAN Elements in Period 3 and higher have empty 3d-orbitals available, and so can expand their valence shells to accept additional electrons. After assigning all the valence electrons to bonds and lone pairs to give each atom an octet, assign any remaining electrons to the central atom. SOLVE 74 CHAPTER 2 CHEMICAL BONDS FIGURE 2.10 Phosphorus trichloride is a colorless liquid. When it reacts with chlorine (the pale yellow-green gas in the flask), it forms the very pale yellow solid phosphorus pentachloride (at the bottom of the flask). P Cl Cl ClCl Cl 24 Phosphorus pentachloride, PCl5 P Cl Cl Cl Cl P Cl Cl Cl Cl Cl Cl ϩ Ϫ (b) PCl6 − (a) PCl4 + 23 Phosphorus pentachloride, PCl5(s) Count the number of valence electrons. 6 from sulfur 7 from each fluorine atom ( F#) $ $ $ (# S#) $ $ y y y y y y y y y y y y y y y y y F F FF S¬ ¬ œ ç 15 16 17 S F 2s22p5 3s23p4 Evaluate As expected, in this structure sulfur has 10 electrons in its expanded valence shell. Self-Test 2.10A Write the Lewis structure for xenon tetrafluoride, XeF4, and give the number of electrons in the expanded valence shell. [Answer: See (25); 12 electrons.] Self-Test 2.10B Write the Lewis structure for the I3 Ϫ ion and give the number of electrons in the expanded valence shell. When different resonance structures are possible, some giving the central atom in a compound an octet and some an expanded valence shell, the dominant resonance structure is likely to be the one with the lowest formal charges. However, there are many exceptions and the selection of the best structure often depends on a careful analysis of experimental data. F F F F 25 Xenon tetrafluoride, XeF4 Xe Find the number of electron pairs. There are 6 ϩ (4 ϫ 7) ϭ 34 electrons, or 17 electron pairs. Construct the Lewis structure. Give each F atom 3 lone pairs and 1 bonding pair shared with the central S atom; place the 2 extra electrons on the S atom. EXAMPLE 2.8 Selecting the dominant resonance structure for a molecule The sulfate ion, SO4 2Ϫ , is present in a number of important minerals, including gypsum (CaSO4и2H2O), which is used in cement, and Epsom salts (MgSO4и7H2O), which is used as a purgative. Determine the dominant resonance structure of a sulfate ion from the three shown in (26a–26c) by calculating the formal charges on the atoms in each structure. Anticipate As you gain experience, you will be able to recognize the most favorable structure from the patterns of bonds and lone pairs, but until then the only way forward is to calculate the formal charges. PLAN Follow the procedure in Toolbox 2.2. We need do only one calculation for equivalent atoms, such as the oxygen atoms in the first diagram, because they all have the same arrangement of electrons and hence the same formal charge. SOLVE Draw up the following table, in accord with Toolbox 2.2. 2.11 THE UNUSUAL STRUCTURES OF SOME GROUP 13/III COMPOUNDS 75 O O O O S ෆ͉2Ϫ 26a ෆ͉2Ϫ 26c O O O O S P O O O O 27 ෆ͉3Ϫ P O O O O ෆ͉3Ϫ O ¬ S ¬ O $ $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ Ϫ1 ϩ2 Ϫ1 Ϫ1 Ϫ1 ¬ ෆ͉ 2Ϫ O ¬ S ¬ O $ $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ 7 4 ෆ͉ 2Ϫ O ¬ S ¬ O $ $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉ 2Ϫ O £ S ¬ O $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ Ϫ1 ϩ1 0 Ϫ1 Ϫ1 ¬ ෆ͉ 2Ϫ O£S¬O $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ 7 5 6 ෆ͉ 2Ϫ O £ S ¬ O $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉ 2Ϫ O £ S £ O $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉2ϪϪ1 0 0 0 ¬ Ϫ1 O £ S £O $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ 7 6 6 ෆ͉ 2Ϫ O£ S£ O $ $ $ $ $ $ $ O ˚ $$ $ O ˚ ෆ͉ 2ϪStep 2 Draw the Lewis structure. Step 3 Assign electron ownership, (L ϩ B). Step 4 Find the formal charge, V Ϫ (L ϩ B).1 2 1 2 26a 26b 26c Step 1 Count the valence O: 6 S: 6 electrons (V). Total: 30 electrons plus two electrons from the charge of Ϫ2, for a total of 16 pairs of electrons. Evaluate The individual formal charges are closest to zero in structure (26c); so the structure with two double bonds is likely to make the biggest contribution to the resonance hybrid, even though the valence shell on the S atom has expanded to hold 12 electrons. Note this pattern for future reference. Also note that the formal charges of the atoms add up to the overall charge of the ion in each case. Self-Test 2.11A Calculate the formal charges for the two Lewis structures of the phosphate ion shown in (27). [Answer: See (28).] Self-Test 2.11B Calculate the formal charges for the three oxygen atoms in one of the Lewis structures of the ozone resonance structure (Example 2.5). 2.11 The Unusual Structures of Some Group 13/III Compounds An unusual feature of the Lewis structure of the colorless gas boron trifluoride, BF3 (29), is that the boron atom has an incomplete octet: its valence shell consists of only six electrons. We might expect the boron atom to complete its octet by sharing more F B F F 29 Boron trifluoride, BF3 ෆ͉2Ϫ 26b O O O O S P −1 −1 −1 0 +1 0 −1 OO O −1 O 28 P −1 −1 OO O O ෆ͉3Ϫ ෆ͉3Ϫ electrons with fluorine, as depicted in (30), but fluorine has such a high ionization energy that it is unlikely to exist with a positive formal charge. Experimental evidence, such as the short BßF bond lengths, suggests that the true structure of BF3 is a resonance hybrid of both types of Lewis structures, with the singly bonded structure making the major contribution. The boron atom in BF3 can complete its octet if an additional atom or ion with a lone pair of electrons forms a bond by providing both electrons. A bond in which both electrons come from one of the atoms is called a coordinate covalent bond. For example, the tetrafluoroborate anion, BF4 Ϫ (31), forms when boron trifluoride is passed over a metal fluoride. In this anion, the formation of a coordinate covalent bond with a fluoride ion gives the B atom an octet. Another example of a coordinate covalent bond is that formed when boron trifluoride reacts with ammonia: BF3(g) ϩ NH3(g) NH3BF3(s) The Lewis structure of the product, a white molecular solid, is shown in (32). In this reaction, the lone pair on the nitrogen atom of ammonia, H3N:, can be regarded as completing boron’s octet in BF3 by forming a coordinate covalent bond. Boron trichloride, a colorless, reactive gas of BCl3 molecules, behaves chemically like BF3. However, the trichloride of aluminum, which is in the same group as boron, forms dimers, linked pairs of molecules. Aluminum chloride is a volatile white solid that vaporizes at 180°C to a gas of Al2Cl6 molecules. These molecules survive in the gas up to about 200°C and only then fall apart into AlCl3 molecules. The Al2Cl6 molecule exists because a Cl atom in one AlCl3 molecule uses one of its lone pairs to form a coordinate covalent bond to the Al atom in a neighboring AlCl3 molecule (33). This arrangement can occur in aluminum chloride but not boron trichloride because the atomic radius of Al is bigger than that of B. Compounds of boron and aluminum may have unusual Lewis structures in which boron and aluminum have incomplete octets or halogen atoms act as bridges. IONIC VERSUS COVALENT BONDS Ionic and covalent bonding are two extreme models of the chemical bond. Most actual bonds lie somewhere between purely ionic and purely covalent. When we describe bonds between nonmetals, covalent bonding is a good model. When a metal and nonmetal are present in a simple compound, ionic bonding is a good model. However, the bonds in many compounds seem to have properties between the two extreme models of bonding. Can we describe these bonds more accurately by improving the two basic models? 2.12 Correcting the Covalent Model: Electronegativity All bonds can be viewed as resonance hybrids of purely covalent and purely ionic structures. For example, the structure of a Cl2 molecule can be described as In this case, the ionic structures make only a small contribution to the resonance hybrid, and we regard the bond as almost purely covalent. Moreover, the two ionic structures have the same energy and make equal contributions to the hybrid; so the average charge on each atom is zero. However, in a molecule composed of different elements, such as HCl, the resonance has unequal contributions from the two ionic structures. The lower-energy ionic structure is . Because the chlorine atom has a greater attraction for electrons than does the hydrogen atom, the structure with the negative charge on the Cl atom makes H ϩ Cl Ϫ$ $ $ $ H¬Cl $ $ $ H Ϫ Cl Ϫ$ $ $ $ H ϩ Cl ϩ$ $ $ bB bB Cl¬Cl $ $ $ $ $ $ Cl Ϫ$ $ $ $ Cl Ϫ$ $ $ $ Cl ϩ$ $ $Cl ϩ$ $ $ bB bB ¡ 76 CHAPTER 2 CHEMICAL BONDS 31 Tetrafluoroborate, BF4 Ϫ F B F F F ෆ͉Ϫ 32 NH3BF3 NH B F F F H H ClCl Cl Cl Cl Cl Al Al œ œ œ ç ç ç œ ç 33 Aluminum chloride, Al2Cl6 F B F F 30 Boron trifluoride, BF3 a bigger contribution than . As a result, there is a small net negative charge on the Cl atom and a small net positive charge on the H atom. Here we see the limitations of using formal charge alone to determine the distribution of electrons in a structure. The formal charge on each atom in HCl is zero. The charges on the atoms in HCl are called partial charges. We show the partial charges on the atoms by writing ␦ϩ H∫Cl␦Ϫ . A bond in which ionic contributions to the resonance result in partial charges is called a polar covalent bond. All bonds between atoms of different elements are polar to some extent. The bonds in homonuclear (same element) diatomic molecules and ions are nonpolar. The two atoms in a polar covalent bond form an electric dipole, a partial positive charge next to an equal but opposite partial negative charge. In the original convention, a dipole was represented by an arrow that points toward the negative partial charge (34a); in the modern convention, the arrow points toward the positive partial charge (34b). Clearly, it is important to know which convention is being used! In this text, we use the modern convention. The size of an electric dipole—which is a measure of the magnitude of the partial charges and their separation—is reported as the electric dipole moment, ␮ (the Greek letter mu), in units called debye (D). The debye is defined so that a single negative charge (an electron) separated by 100. pm from a single positive charge (a proton) has a dipole moment of 4.80 D. The dipole moment associated with a Cl∫H bond is about 1.1 D. We can think of this dipole as arising from a partial charge of about 23% of an electron’s charge on the Cl atom and an equivalent positive charge on the H atom. A covalent bond is polar if one atom has a greater attraction for electrons than the other atom, because then the electron pair is more likely to be drawn closer to the former atom. In 1932, the American chemist Linus Pauling proposed a quantitative measure of electron distribution in bonds. The electron-pulling power of an atom when it is part of a molecule is called its electronegativity. Electronegativities are denoted ␹ (the Greek letter chi, pronounced “kye”). An atom of the element with the higher electronegativity has a stronger pulling power on electrons and tends to pull them away from the atom of the element with lower electronegativity (Fig. 2.11). Pauling based his scale on the dissociation energies, D, of the A∫A, B∫B, and A∫B bonds, measured in electronvolts. He defined the difference in electronegativity of the two elements A and B as (5) He then assigned individual values of electronegativities that were consistent with this expression. A simpler way of setting up a scale of electronegativities was devised by another American chemist, Robert Mulliken. In his approach, the electronegativity is the average of the ionization energy and electron affinity of the element (both expressed in electronvolts): ␹ ϭ (I ϩ Ea) (6) An atom gives up an electron reluctantly if the ionization energy is high. If the electron affinity is high, attaching electrons to an atom is energetically favorable. Elements with both these properties are reluctant to lose their electrons and tend to gain them; hence, they are classified as highly electronegative. Conversely, if the ionization energy and the electron affinity are both low, then it takes very little energy for the element to give up its electrons and it has little tendency to gain more; hence, the electronegativity is low. Figure 2.12 shows the variation in electronegativity for the main-group elements of the periodic table. Because ionization energies and electron affinities are highest at the top right of the periodic table (close to fluorine, with the exception of the noble gases), it is not surprising to find that nitrogen, oxygen, bromine, chlorine, and fluorine are the elements with the highest electronegativities. When the two atoms in a bond have only a small electronegativity difference, the partial charges are very small. As the difference in electronegativities increases, so do the partial charges. If the electronegativities are very different, then one atom can 1 2 |xA - xB| = {D(A - B) - 1 2[D(A - A) + D(B - B)]}1/2 H Ϫ $ Cl ϩ$ $ $ 2.12 CORRECTING THE COVALENT MODEL: ELECTRONEGATIVITY 77 The debye is named for the Dutch chemist Peter Debye, who carried out important studies of dipole moments. The SI unit of dipole moment is 1 Cиm (1 coulomb meter). It is the dipole moment of a charge of 1 C separated from a charge of Ϫ1 C by a distance of 1 m; 1 D ϭ 3.336 ϫ 10Ϫ30 Cиm. Dissociation energies, a measure of the strengths of bonds, are discussed in Section 2.14. A B FIGURE 2.11 The electronegativity of an element is its electron-pulling power when it is part of a compound. (a) An atom with a high electronegativity (B) has a strong pulling power on the electrons (as represented by the larger arrow) that it shares with its neighbor, A. (b) The outcome of the tug-of-war is that the more electronegative atom has a greater share in the electron pair of the covalent bond. Electron density is symbolized by the green cloud in each image. ␦Ϫ ␦ϩ (a) (b) ␦Ϫ ␦ϩ 34 (a) A B acquire the lion’s share of the electron pair, and the corresponding ionic structure makes a large contribution to the resonance. Because it has largely robbed the other atom of its share of the electrons, the highly electronegative element resembles an anion and the other atom resembles a cation. We say that such a bond has considerable ionic character. If the difference in electronegativity is large, as in NaCl or KF, the ionic contribution dominates the covalent contribution, and it is better to regard the bond as ionic. There is no sharp dividing line between ionic and covalent bonding. However, a good rule of thumb is that an electronegativity difference of about 2 means that there is so much ionic character present that the bond is best regarded as ionic (Fig. 2.13). For electronegativity differences smaller than about 1.5, a covalent description of the bond is probably reasonable. For example, the electronegativities of carbon and oxygen are 2.6 and 3.4, an electronegativity difference of 0.8, and C∫O bonds are best regarded as polar covalent. However, the electronegativity of calcium is 1.3, and Ca∫O bonds, with an electronegativity difference of 2.1, are considered ionic. Self-Test 2.12A In which of the following compounds do the bonds have greater ionic character: (a) P4O10 or (b) PCl3? [Answer: (a)] Self-Test 2.12B In which of the following compounds do the bonds have greater ionic character: (a) CO2 or (b) NO2? Electronegativity is a measure of the pulling power of an atom on the electrons in a bond. A polar covalent bond is a bond between two atoms with partial electric charges arising from their difference in electronegativity. The presence of partial charges gives rise to an electric dipole moment. 2.13 Correcting the Ionic Model: Polarizability All ionic bonds have some covalent character. To see how covalent character can arise, consider a monatomic anion (such as ClϪ ) next to a cation (such as Naϩ ). As the cation’s positive charge pulls on the anion’s electrons, the spherical electron cloud of the anion becomes distorted in the direction of the cation. We can think of this distortion as the tendency of an electron pair to move into the region between the two nuclei and to form a covalent bond (Fig. 2.14). Ionic bonds acquire more covalent character as the distortion of the electron cloud on the anion increases. Atoms and ions that readily undergo a large distortion are said to be highly polarizable. An anion can be expected to be highly polarizable if it is large, such as an iodide ion, IϪ . In such a large, highly polarizable ion, the ion’s nucleus exerts only weak control over its outermost electrons because they are so far away. As a result, the electron cloud of the large anion is easily distorted. Cations, which have fewer electrons than their parent atoms, are not significantly polarizable because the remaining electrons are held so tightly. 78 CHAPTER 2 CHEMICAL BONDS Ne Ar Kr Xe Rn Li 1.0 Be 1.6 B 2.0 C 2.6 N 3.0 O 3.4 F 4.0 Na 0.93 Mg 1.3 Al 1.6 Si 1.9 P 2.2 S 2.6 Cl 3.2 K 0.82 Ca 1.3 In 1.8 Rb 0.82 Cs 0.79 Sr 0.95 Ba 0.89 Ga 1.6 Tl 2.0 Ge 2.0 Sn 2.0 Pb 2.3 As 2.2 Sb 2.1 Bi 2.0 Se 2.6 Te 2.1 Po 2.0 Br 3.0 I 2.7 At 1 2 13/III 14/IV 15/V 16/VI 17/VII 18/VIII 2 3 4 5 6 H 2.2 He FIGURE 2.12 Variation in the electronegativity of the main-group elements (with the exception of the noble gases). Electronegativity tends to be high toward the upper-right corner of the periodic table and low on the lower left. Elements with low electronegativities (such as the s-block metals) are often called electropositive. These Pauling values are used throughout the text. 0 25 50 75 100 Percentageioniccharacter 0 1 2 3 4 HI HBr HCl HF LiI LiBr LiClKI KBr KCl CsCl CsF KF LiF Electronegativity difference, Δ␹ FIGURE 2.13 The dependence of the percentage ionic character of the bond on the difference in electronegativity, ⌬␹, between two bonded atoms for a number of halides. Atoms and ions that can cause large distortions are said to have a high polarizing power. A cation can be expected to have a strong polarizing power if it is small and highly charged, such as an Al3ϩ cation. A small radius means that the center of charge of a highly charged cation can get very close to the anion, where it can exert a strong pull on the anion’s electrons. Compounds composed of a small, highly charged cation and a large, polarizable anion tend to have bonds with considerable covalent character. Cations become smaller, more highly charged, and hence more strongly polarizing, from left to right across a period. Thus, Be2ϩ is more strongly polarizing than Liϩ , and Mg2ϩ is more strongly polarizing than Naϩ . On the other hand, cations become larger and hence less strongly polarizing down a group. Thus, Naϩ is less strongly polarizing than Liϩ , and Mg2ϩ is less strongly polarizing than Be2ϩ . Now we can see that, because polarizing power increases from Liϩ to Be2ϩ but decreases from Be2ϩ to Mg2ϩ , it follows that the polarizing power of the diagonal neighbors Liϩ and Mg2ϩ should be similar. We can expect such similarities in the properties of other diagonally related neighbors. These diagonal similarities underlie the diagonal relationships in the periodic table introduced in Section 1.20 and illustrated in Fig. 1.58. Self-Test 2.13A In which of the compounds NaBr and MgBr2 do the bonds have greater covalent character? [Answer: MgBr2] Self-Test 2.13B In which of the compounds CaS and CaO do the bonds have greater covalent character? Compounds composed of highly polarizing cations and highly polarizable anions have significant covalent character in their bonding. THE STRENGTHS AND LENGTHS OF COVALENT BONDS The characteristics of a covalent bond between two atoms are due mainly to the properties of the atoms themselves and vary only a little with the identities of the other atoms present in a molecule. Consequently, we can predict some characteristics of a bond with reasonable certainty once we know the identities of the two bonded atoms. For instance, provided the bond order is the same, the length and strength of an AßB bond are approximately the same regardless of the molecule in which it is found. Thus, to understand the properties of a large molecule, such as how DNA replicates in our cells and transmits genetic information, we can study the character of C¢O and NßH bonds in much simpler compounds, such as formaldehyde, H2C¢O, and ammonia, NH3. 2.14 Bond Strengths The strength of a chemical bond is measured by its dissociation energy, D, the energy required to separate the bonded atoms. On a plot of the potential energy of a diatomic molecule as a function of the internuclear distance, the dissociation energy is the distance between the bottom of the energy well and the energy of the separated atoms (Fig. 2.15). The bond breaking is homolytic, which means that each atom retains one of the electrons from the bond. An example is HßCl(g) иH(g) ϩ иCl(g) A high dissociation energy indicates a deep potential energy well and therefore a strong bond that requires a lot of energy to break. The strongest known bond between two nonmetal atoms is the triple bond in carbon monoxide, for which the dissociation energy is 1062 kJиmolϪ1 . One of the weakest bonds is that between the iodine atoms in molecular iodine, for which the dissociation energy is only 139 kJиmolϪ1 . The strength of a bond between two atoms is measured by its dissociation energy: the greater the dissociation energy, the stronger the bond. ¡ 2.14 BOND STRENGTHS 79 Polarizing cation Polarizable anion Distorted electron cloud FIGURE 2.14 When a small, highly charged cation is close to a large anion, the electron cloud of the anion is distorted in the process we call polarization. The green sphere represents the shape of anion in the absence of a cation. The gray shadow shows how the shape of the sphere is distorted by the positive charge of the cation. Internuclear distance Energy 0 Strong bond Weak bond D FIGURE 2.15 The variation of the energy of a diatomic molecule with internuclear separation for weak and strong bonds. The dissociation energy is a measure of the depth of the well. (In practice, we have to take into account the small zero-point energy of the vibrating molecule, and so the dissociation energy is slightly less than the depth of the well.) 2.15 Variation in Bond Strength Tables 2.3 and 2.4 list a selection of typical dissociation energies. The values given in Table 2.4 are average dissociation energies for a number of different molecules. For instance, the strength quoted for a CßO single bond is the average strength of such bonds in a selection of organic molecules, such as methanol (CH3ßOH), ethanol (CH3CH2ßOH), and dimethyl ether (CH3ßOßCH3). The values should therefore be regarded as typical rather than as accurate values for a particular molecule. The trends in bond strengths shown in Table 2.3 are explained in part by the Lewis structures for the molecules. Consider, for example, the diatomic molecules of nitrogen, oxygen, and fluorine (Fig. 2.16). Note the decline in bond strength as the bond order decreases—from 3 in N2 to 1 in F2. The triple bond in nitrogen is the origin of the inertness mentioned at the beginning of the chapter. A multiple bond is almost always stronger than a single bond because more electrons bind the multiply bonded atoms. A triple bond between two atoms is always stronger than a double bond between the same two atoms, and a double bond is always stronger than a single bond between the same two atoms. However, a double bond between two carbon atoms is not twice as strong as a single bond, and a triple bond is a lot less than three times as strong. For example, we see that the average dissociation energy of a C¢C double bond is 612 kJиmolϪ1 , whereas it takes 696 kJиmolϪ1 to break two CßC single bonds; similarly, the average dissociation energy of a CΩC triple bond is 837 kJиmolϪ1 , but it takes 1044 kJиmol–1 to break three CßC single bonds (Fig. 2.17). The origin of these differences is in part the repulsions between the electron pairs in a multiple bond, so each pair is not quite as effective at bonding as a pair of electrons in a single bond. Another contributing factor is that, as will be described in Section 3.4, the electrons in double and triple bonds are not as concentrated between the two atoms as they are in a single bond. The values in Table 2.4 show how resonance affects the strengths of bonds. For example, the strength of a carbon–carbon bond in benzene is intermediate between that of a single and that of a double bond. Resonance spreads multiple bond character over the bonds between atoms: as a result, what were single bonds are strengthened and what were double bonds are weakened. The net effect overall is a stabilization of the molecule. The presence of lone pairs may influence the strengths of bonds. Lone pairs repel each other; and, if they are on neighboring atoms, that repulsion can weaken the bond. This repulsion between lone pairs helps to explain why the bond in F2 is weaker than the bond in H2, because the latter molecule has no lone pairs. 80 CHAPTER 2 CHEMICAL BONDS We shall not distinguish between the average dissociation energy and the average dissociation enthalpy, a concept to be introduced in Section 7.20. The two quantities differ by only a few kilojoules per mole. TABLE 2.3 Bond Dissociation Energies of Diatomic Molecules (kJ·mol؊1 ) Bond dissociation Molecule energy H2 424 N2 932 O2 484 CO 1062 F2 146 Cl2 230 Br2 181 I2 139 HF 543 HCl 419 HBr 354 HI 287 TABLE 2.4 Average Bond Dissociation Energies (kJ·mol؊1 ) Bond Average bond dissociation energy Bond Average bond dissociation energy CßH 412 CßI 238 CßC 348 NßH 388 C¢C 612 NßN 163 CU∫LC* 518 N¢N 409 CΩC 837 NßO 210 CßO 360 N¢O 630 C¢O 743 NßF 195 CßN 305 NßCl 381 CßF 484 OßH 463 CßCl 338 OßO 157 CßBr 276 *In benzene. 932 484 146 15/V 16/VI 17/VII N2 O2 F2 FIGURE 2.16 The bond dissociation energies, in kilojoules per mole of N2, O2, and F2 molecules. Note how the bonds weaken in the change from a triple bond in N2 to a single bond in F2. C C C C 348 612 837 C C C C C C 1044 696 348 C C FIGURE 2.17 The strengths (in kilojoules per mole) of single and multiple bonds between two carbon atoms. Note that, for bonds between carbon atoms, a double bond is less than twice as strong as a single bond and a triple bond is less than three times as strong as a single bond, as shown by the fourth column. 2.16 BOND LENGTHS 81 FIGURE 2.18 The bond dissociation energies of the hydrogen halide molecules in kilojoules per mole of molecules. Note how the bond weakens as the halogen atom becomes larger. 35 H2N HO OH O O O O O O P P P O− O− O− O−N N N O N 2 3 4 5 6 7 13/III 14/IV 15/V 16/VI 17/VII 18/VIII1 2 Li Na K Rb Cs Be Mg Ca Sr Ba RaFr B Al Ga In Tl Bi Po At Ne Ar Kr Xe Rn I 14/IV 15/V 16/VI 17/VII 8 B A G n T N A K X I 14/IV 15/V 16/VI 17/VII 8 B A G n T N A K X I 14/IV 15/V 16/VI 17/VII B A a n T N A K X I / V 5/V 6/V 7/V B l a n l N A K X I 1 B l a n l N A K X I 1 B l a n l N A K X I 1 l a n l N A K X I 1 a N A K X I 1 N A K X I N A CH NH OH HF SiH PH SH HCl GeH AsH SeH HBr SnH SbH TeH HI PbH 412 388 463 543 318 322 338 419 289 297 312 354 253 257 267 287 205 FIGURE 2.19 The dissociation energies for bonds between hydrogen and the p-block elements. The bond strength decreases down each group as the atoms increase in size. Trends in bond strengths correlate with trends in atomic radii. If the nuclei of the bonded atoms cannot get very close to the electron pair lying between them, the two atoms will be only weakly bonded together. For example, the bond strengths of the hydrogen halides decrease from HF to HI, as shown in Fig. 2.18. The strength of the bond between hydrogen and a Group 14/IV element also decreases down the group (Fig. 2.19). This weakening of the bond correlates with a decrease in the stability of the hydrides down the group. Methane, CH4, can be kept indefinitely in air at room temperature. Silane, SiH4, bursts into flame on contact with air. Stannane, SnH4, decomposes into tin and hydrogen. Plumbane, PbH4, has never been prepared, except perhaps in trace amounts. The relative strengths of bonds are important for understanding the way that energy is used in bodies to power our brains and muscles. For instance, adenosine triphosphate, ATP (35), is found in every living cell. The triphosphate part of this molecule is a chain of three phosphate groups. One of the phosphate groups is removed in a reaction with water. The PßO bond in ATP requires only 276 kJиmolϪ1 to break and the new PßO bond formed in H2PO4 Ϫ releases 350 kJиmolϪ1 when it forms. As a result, the conversion of ATP to adenosine diphosphate, ADP, in the reaction (where the wiggly line indicates the rest of the molecule) can release energy that is used to power energy-demanding processes in cells. Closely related to the strength of a bond is its stiffness (its resistance to stretching and compressing), with strong bonds typically being stiffer than weak bonds. The stiffness of bonds is studied by infrared (IR) spectroscopy, as described in Major Technique 1, which follows this chapter, and is used to identify compounds. The bond strength increases as the multiplicity of a bond increases, decreases as the number of lone pairs on neighboring atoms increases, and decreases as the atomic radii increase. Bonds are strengthened by resonance. 2.16 Bond Lengths A bond length is the distance between the centers of two atoms joined by a covalent bond. It corresponds to the internuclear distance at the potential energy minimum for the two atoms (see Fig. 2.15). Bond lengths affect the overall size and shape of a molecule. O O O O OϪ OϪ OϪ PP H2PO4 Ϫ(aq)ϩ O O O O O OP OϪ OϪ OϪ OϪ P H2OP ϩ ∫B 82 CHAPTER 2 CHEMICAL BONDS TABLE 2.5 Average and Actual Bond Lengths Bond Average bond length (pm) Molecule Bond length (pm) CßH 109 H2 74 CßC 154 N2 110 C¢C 134 O2 121 CU∫LC* 139 F2 142 CΩC 120 Cl2 199 CßO 143 Br2 228 C¢O 112 I2 268 OßH 96 NßH 101 NßO 140 N¢O 120 *In benzene. 13/III 17/VII Ne Ar Kr Xe Rn Li Be C N O Na Mg Al 118 Si 111 P 110 S 102 Cl 98 K Ca In 144 Rb Cs Sr Ba Ga 126 Tl Ge 122 Sn 141 Pb As 121 Sb 138 Bi Se 117 Te 137 Po Br 114 I 134 At 1 2 14/IV 15/V 16/VI 18/VIII 2 3 4 5 6 H 37 He 60 67 B 88 58 F 77 75 60 55 66 60 The transmission of hereditary information in DNA, for instance, depends on bond lengths because the two strands of the double helix must fit together like pieces of a jigsaw puzzle (Section 19.15). Bond lengths are also crucial to the action of enzymes because only a molecule of the right size and shape will fit into the active site of the enzyme molecule (Section 14.16). As we see from Table 2.5, the lengths of bonds between Period 2 elements typically lie in the range from 100 pm to 150 pm. Bond lengths are determined experimentally by using either spectroscopy or x-ray diffraction (Box 2.2). Bonds between heavy atoms tend to be longer than those between light atoms because heavier atoms have larger radii than lighter ones (Fig. 2.20). Multiple bonds are shorter than single bonds between the same two elements because the additional bonding electrons attract the nuclei more strongly and pull the atoms closer together: compare the lengths of the various carbon–carbon bonds in Table 2.5. We can also see the averaging effect of resonance: the length of the carbon–carbon bond in benzene is intermediate between the lengths of the single and double bonds of a Kekulé structure (but closer to that of a double bond). For bonds between atoms of the same two elements, the stronger the bond, the shorter it is. Thus, a CΩC triple bond is both stronger and shorter than a C¢C double bond. Similarly, a C¢O double bond is both stronger and shorter than a CßO single bond. Each atom makes a characteristic contribution, called its covalent radius, to the length of a bond (Fig. 2.21). A bond length is approximately the sum of the covalent radii of the two atoms (36). The OßH bond length in ethanol, for example, is the sum of the covalent radii of H and O, 37 ϩ 74 pm ϭ 111 pm. We also see from Fig. 2.21 that the covalent radius of an atom taking part in a multiple bond is smaller than that for a single bond of the same atom.36 Covalent radii rA rB A B Bond length F F Cl Cl I I 142 199 268 Br Br 228 18/VIII16/VI 17/VII FIGURE 2.20 Bond lengths (in picometers) of the diatomic halogen molecules. Notice how the bond length increases down the group as the atomic radii become larger. FIGURE 2.21 Covalent radii of hydrogen and the p-block elements (in picometers). Where more than one value is given, the values refer to single, double, and triple bonds. Covalent radii tend to become smaller toward fluorine. A bond length is approximately the sum of the covalent radii of the two participating atoms. 2.16 BOND LENGTHS 83 Covalent radii typically decrease from left to right across a period. The reason is the same as for atomic radii (Section 1.15): the increasing effective nuclear charge draws in the electrons and makes the atom more compact. Like atomic radii, covalent radii increase down a group because, in successive periods, the valence electrons occupy shells that are more distant from the nucleus and are better shielded by the inner core of electrons. The covalent radius of an atom is the contribution it makes to the length of a covalent bond; covalent radii are added together to estimate the lengths of bonds in molecules. Because a chemical bond is only about 10Ϫ10 m long, special techniques have to be used to measure its length. There are two principal techniques: one for solids and the other for gases. The technique used for solids, x-ray diffraction, is described in Major Technique 3, following Chapter 5. Microwave spectroscopy, discussed here, is used to determine bond lengths in gas-phase molecules. This branch of spectroscopy makes use of the ability of rotating molecules to absorb microwave radiation, which has a wavelength close to 1 cm. According to classical physics, a solid body such as a ball can rotate with any energy. According to quantum mechanics, however, rotational energy is quantized, and a body can rotate only with certain energies—that is, only at certain speeds. Let’s see what that means for a diatomic molecule AB, with atomic masses mA and mB and bond length R. The molecule can rotate only with the following energies: where ␮ ϭ mAmB/(mA ϩ mB), h is Planck’s constant, and J is a quantum number. These energy levels are shown in the illustration for two kinds of molecules, one with heavy atoms and a long bond (such as ICl) and the other with light atoms and a short bond (such as HF). We see that the energy levels are much closer together for the heavier molecule than for the lighter molecule. The minimum energy needed to excite a molecule into rotation from rest (corresponding to J ϭ 0 and E ϭ 0) is Perhaps surprisingly, less energy is needed to excite a large heavy molecule than a small light molecule. The energy needed to excite a molecule from the general state J to the next higher level, J ϩ 1, is Because the energy needed to change the rotational state of a molecule depends on the masses of its atoms and the bond length, we can calculate the bond length if we can measure that energy. Photons corresponding to microwave radiation can supply ¢E = EJ+1 - EJ = h2 4␲2 mR2 * (J + 1) ¢E = E1 - E0 = h2 4␲2 mR2 EJ = h2 8␲2 mR2 * J(J + 1) J = 0,1,2, Á HOW DO WE KNOW . . . THE LENGTH OF A CHEMICAL BOND?BOX 2.2 the energy needed to excite the molecule to higher rotational energies. Therefore, to determine a bond length, a beam of microwave radiation is passed through a gaseous sample, its frequency is varied, and the frequencies, ␯ (nu), that result in a strong absorption are determined. The energy of the photons corresponding to this frequency is h␯, and this value can be set equal to the expression for the energy difference given above. The resulting expression is then solved for the value of R, the bond length. The technique as we have described it works only for polar molecules, because only they can interact with microwave radiation. However, modifications of this spectroscopic method can be used to investigate nonpolar molecules, too. A major limitation of the technique is that only the spectra of simple molecules can be interpreted. For complex molecules, solid samples are used in conjunction with x-ray diffraction (see Major Technique 3). 0 1 2 3 4 5 6 7 8 9 10 11 J (a) (b) Energy The rotational energy levels of (a) a heavy diatomic molecule and (b) a light diatomic molecule. Note that the energy levels are closer together for the heavy diatomic molecule. Microwaves are absorbed when transitions take place between neighboring energy levels. Electron Configurations of Ions 2.1 Give the number of valence electrons for each of the following elements: (a) Sb; (b) Si; (c) Mn; (d) B. 2.2 Give the number of valence electrons for each of the following elements: (a) Br; (b) Rh; (c) Nb; (d) Te. 2.3 Give the ground-state electron configuration expected for each of the following ions: (a) S2Ϫ ; (b) As3ϩ ; (c) Ru3ϩ ; (d) Ge2ϩ . 2.4 Give the ground-state electron configuration expected for each of the following ions: (a) BrϪ ; (b) Rh3ϩ ; (c) Nb3ϩ ; (d) Te2Ϫ . 2.5 Give the ground-state electron configuration expected for each of the following ions: (a) Cuϩ ; (b) Bi3ϩ ; (c) Ga3ϩ ; (d) Tl3ϩ . 2.6 Give the ground-state electron configuration expected for each of the following ions: (a) Al3ϩ ; (b) Tc4ϩ ; (c) Ra2ϩ ; (d) IϪ . 2.7 The following species have the same number of electrons: Cd, Inϩ , and Sn2ϩ . (a) Write the electron configurations for each species. Are they the same or different? Explain. (b) How many unpaired electrons, if any, are present in each species? (c) What neutral atom, if any, has the same electron configuration as that of In3ϩ ? 2.8 The following species have the same number of electrons: Ca, Ti2ϩ , and V3ϩ . (a) Write the electron configurations for each ion. Are they the same or different? Explain. (b) How many unpaired electrons, if any, are present in each species? (c) What neutral atom, if any, has the same electron configuration as that of Ti3ϩ ? 2.9 Which M2ϩ ions (where M is a metal) are predicted to have the following ground-state electron configurations: (a) [Ar]3d7 ; (b) [Ar]3d6 ; (c) [Kr]4d4 ; (d) [Kr]4d3 ? 2.10 Which E3ϩ (where E is an element) ions are predicted to have the following ground-state electron configurations: (a) [Xe]4f14 5d8 ; (b) [Xe]4f14 5d5 ; (c) [Kr]4d10 5s2 5p2 ; (d) [Ar]3d10 4s2 ? 2.11 Which M3ϩ ions (where M is a metal) are predicted to have the following ground-state electron configurations: (a) [Ar]3d6 ; (b) [Ar]3d5 ; (c) [Kr]4d5 ; (d) [Kr]4d3 ? 2.12 Which M2ϩ ions (where M is a metal) are predicted to have the following ground-state electron configurations: (a) [Ar]3d7 ; (b) [Kr]4d7 ; (c) [Kr]4d10 5s2 ; (d) [Xe]4f14 5d10 ? 2.13 For each of the following ground-state atoms, predict the type of orbital (1s, 2p, 3d, 4f, etc.) from which an electron will need to be removed to form the ϩ1 ions: (a) Zn; (b) Cl; (c) Al; (d) Cu. 2.14 For each of the following ground-state ions, predict the type of orbital (1s, 2p, 3d, 4f, etc.) from which an electron will need to be removed to form the ions of one greater positive charge: (a) Ti3ϩ ; (b) Inϩ ; (c) Te2Ϫ ; (d) Agϩ . 2.15 Write the most likely charge for the ions formed by each of the following elements: (a) S; (b) Te; (c) Rb; (d) Ga; (e) Cd. 2.16 Write the most likely charge for the ions formed by each of the following elements: (a) Ba; (b) Bi; (c) Br; (d) Zn; (e) Al. 2.17 Predict the number of valence electrons present for each of the following ions: (a) Mn4ϩ ; (b) Rh3ϩ ; (c) Co3ϩ ; (d) P3ϩ . 2.18 Predict the number of valence electrons present for each of the following ions: (a) Inϩ ; (b) Tc2ϩ ; (c) Ta2ϩ ; (d) Reϩ . 2.19 Give the ground-state electron configuration and number of unpaired electrons expected for each of the following ions: (a) Sb3ϩ ; (b) Sn4ϩ ; (c) W2ϩ ; (d) BrϪ ; (e) Ni2ϩ . 2.20 Give the ground-state electron configuration and number of unpaired electrons expected for each of the following ions: (a) Sn2ϩ ; (b) Cr3ϩ ; (c) Ba2ϩ ; (d) P3Ϫ . 2.21 Give the ground-state electron configuration and number of unpaired electrons expected for each of the following ions: (a) Ca2ϩ ; (b) Inϩ ; (c) Te2Ϫ ; (d) Agϩ . 2.22 Give the ground-state electron configuration and number of unpaired electrons expected for each of the following ions: (a) Fe3ϩ ; (b) Bi3ϩ ; (c) Si4ϩ ; (d) IϪ . 2.23 Chlorine can exist in both positive and negative oxidation states. What is the maximum (a) positive and (b) negative oxidation number that chlorine can have? (c) Write the electron configuration for each of these states. (d) Explain how you arrived at these values. 2.24 Sulfur can exist in both positive and negative oxidation states. What is the maximum (a) positive and (b) negative oxidation number that sulfur can have? (c) Write the electron configuration for each of these states. (d) Explain how you arrived at these values. 2.25 On the basis of the expected charges on the monatomic ions, give the chemical formula of each of the following compounds: (a) magnesium arsenide; (b) indium(III) sulfide; (c) aluminum hydride; (d) hydrogen telluride; (e) bismuth(III) fluoride. 2.26 On the basis of the expected charges on the monatomic ions, give the chemical formula of each of the following compounds: (a) manganese(II) telluride; (b) barium arsenide; (c) silicon nitride; (d) lithium bismuthide; (e) zirconium(IV) chloride. EXERCISES 84 CHAPTER 2 CHEMICAL BONDS SKILLS YOU SHOULD HAVE MASTERED ❑ 1 Write the electron configuration for an ion (Example 2.1 and Self-Test 2.2). ❑ 2 Compare the relative lattice energies of two ionic compounds (Example 2.2). ❑ 3 Draw the Lewis structures of molecules and ions (Toolbox 2.1 and Examples 2.3, 2.4, and 2.7). ❑ 4 Write the resonance structures for a molecule (Example 2.5). ❑ 5 Use formal charge calculations to evaluate alternative Lewis structures (Toolbox 2.2 and Examples 2.6 and 2.8). ❑ 6 Predict which of two bonds has greater ionic or covalent character (Self-Tests 2.12 and 2.13). ❑ 7 Predict and explain periodic trends in the polarizability of anions and the polarizing power of cations (Section 2.13). ❑ 8 Predict and explain relative bond strengths and lengths (Sections 2.14Ϫ2.16). 2.27 On the basis of the expected charges of the monatomic ions, give the chemical formula of each of the following compounds: (a) thallium(III) chloride; (b) aluminum sulfide; (c) manganese(IV) oxide. 2.28 On the basis of the expected charges of the monatomic ions, give the chemical formula of each of the following compounds: (a) chromium(III) oxide; (b) manganese(II) chloride; (c) lithium nitride. Ionic Bonds 2.29 Use data in Appendix 2D to predict which of the following pairs of ions would have the greatest coulombic attraction in a solid compound: (a) Kϩ , O2Ϫ ; (b) Ga3ϩ , O2Ϫ ; (c) Ca2ϩ , O2Ϫ . 2.30 Use data from Appendix 2D to predict which of the following pairs of ions would have the greatest coulombic attraction in a solid compound: (a) Mg2ϩ , S2Ϫ ; (b) Mg2ϩ , Se2Ϫ ; (c) Mg2ϩ , O2Ϫ . 2.31 Explain why the lattice energy of lithium chloride (861 kJиmolϪ1 ) is greater than that of rubidium chloride (695 kJиmolϪ1 ), given that they have similar arrangements of ions in the crystal lattice. See Appendix 2D. 2.32 Explain why the lattice energy of silver bromide (903 kJиmolϪ1 ) is greater than that of silver iodide (887 kJиmolϪ1 ), given that they have similar arrangements of ions in the crystal lattice. See Appendix 2D. Covalent Bonds 2.33 Write the Lewis structure of (a) CCl4; (b) COCl2; (c) ONF; (d) NF3. 2.34 Write the Lewis structure of (a) OCl2; (b) PBr3; (c) GeH4; (d) GaCl3. 2.35 Write the Lewis structure of (a) tetrahydridoborate ion, BH4 Ϫ ; (b) hypobromite ion, BrOϪ ; (c) amide ion, NH2 Ϫ . 2.36 Write the Lewis structure of (a) nitronium ion, ONOϩ ; (b) chlorite ion, ClO2 Ϫ ; (c) peroxide ion, O2 2Ϫ ; (d) formate ion, HCO2 Ϫ . 2.37 Write the complete Lewis structure for each of the following compounds: (a) formaldehyde, HCHO, which as its aqueous solution “formalin” is used to preserve biological specimens; (b) methanol, CH3OH, the toxic compound also called wood alcohol; (c) glycine, H2C(NH2)COOH, the simplest of the amino acids, the building blocks of proteins. 2.38 Write the Lewis structure of each of the following organic compounds: (a) ethanol, CH3CH2OH, which is also called ethyl alcohol or grain alcohol; (b) methylamine, CH3NH2, a putrid-smelling substance formed when flesh decays; (c) formic acid, HCOOH, a component of the venom injected by ants. 2.39 Write the Lewis structure for each of the following compounds: (a) methanethiol, CH3SH, one of the compounds found in bad breath and some cheeses; (b) carbon disulfide, CS2, which is used to make rayon; (c) dichloromethane, CH2Cl2, a common solvent. 2.40 Write the Lewis structure for each of the following compounds: (a) urea, OC(NH2)2, a compound formed in the body when proteins are metabolized; (b) phosgene, Cl2CO, a deadly gas once used in warfare; (c) nitrosyl fluoride, FNO, an oxidizing EXERCISES 85 agent used in rocket fuel (the atoms are attached in the order shown). 2.41 The following Lewis structure was drawn for a Period 3 element. Identify the element. 2.42 The following Lewis structure was drawn for a Period 3 element. Identify the element. 2.43 Write the complete Lewis structure for each of the following compounds: (a) ammonium chloride; (b) potassium phosphide; (c) sodium hypochlorite. 2.44 Write the complete Lewis structure for each of the following compounds: (a) calcium cyanide; (b) potassium sulfate; (c) ammonium iodate. 2.45 Anthracene has the formula C14H10. It is similar to benzene but has 3 six-membered rings that share common C∫C bonds, as shown below. Complete the structure by drawing in multiple bonds to satisfy the octet rule at each carbon atom. Resonance structures are possible. Draw as many as you can find. 2.46 Write the Lewis structures that contribute to the resonance hybrid of the guanadinium ion, C(NH2)3 ϩ . 2.47 Draw the Lewis structures that contribute to the resonance hybrid of nitryl chloride, ClNO2 (N is the central atom). 2.48 Do H∫CΩN and H∫NΩC form a pair of resonance structures? Explain your answer. 2.49 Draw the Lewis structure and determine the formal charge on each atom in (a) NOϩ ; (b) N2; (c) CO; (d) C2 2Ϫ ; (e) CNϪ . 2.50 Using only Lewis structures that obey the octet rule, draw the Lewis structures and determine the formal charge on each atom in (a) CH3 Ϫ ; (b) BrO2 Ϫ ; (c) PO3 3Ϫ . 2.51 Determine the formal charge on each atom in the following molecules. Identify the structure of lower energy in each pair. (a) (b) (c) ¬ ¬ ¬ ¬ ˚ ˚ ˚ ˚ ˚ ˚ HHH HHH H H H H C C C C C C C C C C C C C C $ $ $ $ $ Cl $ $ $O $ $ Cl O E $ $ $ $ $ Cl $ $ $ $Cl $ $ Cl O E O©Cl¬O $ $ $ $ $ $ $ ƒ O ˚ H O¬Cl¬O $ $ $ $ $ $ $ $ $ ˚ O ˚ H O©C©S $ $ $ $ O¬C $ $ $ $ H¬C $$ $ S N H¬C ©N 86 CHAPTER 2 CHEMICAL BONDS 2.54 Which of the following species are radicals? (a) ClO2; (b) Cl2O; (c) BF4 Ϫ ; (d) BrO. 2.55 Write the Lewis structure, including typical contributions to the resonance structure (where appropriate, allow for the possibility of octet expansion, including double bonds in different positions), for (a) sulfite ion; (b) hydrogen sulfite ion; (c) perchlorate ion; (d) nitrite ion. 2.56 Write the Lewis structure, including typical contributions to the resonance structure (where appropriate, allow for the possibility of octet expansion), for (a) hydrogen phosphate ion; (b) bromite ion; (c) perchlorate ion; (d) arsenate ion. 2.57 Write the Lewis structure of each of the following reactive species, all of which are found to contribute to the destruction of the ozone layer, and indicate which are radicals: (a) chlorine monoxide, ClO; (b) dichloroperoxide, Cl∫O∫O∫Cl; (c) chlorine nitrate, ClONO2 (the central O atom is attached to the Cl atom and to the N atom of the NO2 group). 2.58 Write the Lewis structure of each of the following species and indicate which are radicals: (a) the superoxide ion, O2 Ϫ ; (b) the methoxy group, CH3O; (c) XeO4; (d) HXeO4 Ϫ . 2.59 Determine the numbers of electron pairs (both bonding and lone pairs) on the iodine atom in (a) ICl2 ϩ ; (b) ICl4 Ϫ ; (c) ICl3; (d) ICl5. 2.60 Determine the numbers of electron pairs (both bonding and lone pairs) on the phosphorus atom in (a) PCl3; (b) PCl5; (c) PCl4 ϩ ; (d) PCl6 Ϫ . 2.61 Write the Lewis structure for each of the following molecules or ions and give the number of electrons about the central atom: (a) SF6; (b) XeF2; (c) AsF6 Ϫ ; (d) TeCl4. 2.62 Write the Lewis structure for each of the following molecules or ions and give the number of electrons about the central atom: (a) SiF6 2Ϫ ; (b) IF7; (c) ClF3; (d) BrF2 ϩ . 2.63 Write the Lewis structure and state the number of lone pairs on xenon, the central atom of each of the following compounds: (a) XeOF2; (b) XeF4; (c) XeOF4. 2.64 Write the Lewis structure and state the number of lone pairs on the central atom of each of the following compounds: (a) IF3; (b) AsF3; (c) OF2. 2.65 In each of these ions and compounds, an atom violates the octet rule. Identify the atom and explain the deviation from the octet rule: (a) BeCl2; (b) ClO2. 2.67 Two contributions to the resonance structure are shown below for each species. Determine the formal charge on each atom and then, if possible, identify the Lewis structure of lower energy for each species. (a) (b) 2.68 Two Lewis structures are shown below for each species. Determine the formal charge on each atom and then, if appropriate, identify the Lewis structure of lower energy for each species. (a) (b) 2.69 Select from each of the following pairs of Lewis structures the one that is likely to make the dominant contribution to a resonance hybrid. Explain your selection. (a) (b) 2.70 Select from each of the following pairs of Lewis structures the one that is likely to make the dominant contribution to a resonance hybrid. Explain your selection. (a) (b) O©C©O $ $ $ $ O¬C O$ $ $ $ ¬¬¬ F ¬ Xe ¬ F $ $ $ $ $ $ F ¬ Xe © F $ $ $ $ $ $2 @ $2 @ $ $ $ $ $ $ $ O $$$ OS O $ $$ $O $$$ OS O $ $$ O $$ OS $ $$ O $$ $ OS ෆ͉ Ϫ H $ $ $ $ $ $ $ O $$ O $ $ O S Oෆ͉ Ϫ H $ $ $ $ $ $ O $$ O $ $ O S O ෆ͉ Ϫ H $ $ $ $ O $ $$ O $ $ O S ෆ͉ Ϫ $ $ $ $ O $ $O H $ $ O S O¬As ¬O $ $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉3Ϫ O¬As ¬O $$ $ $ $ $ $ $ $ $ O $$$O ˚ ෆ͉3Ϫ O©As ©O $ $ $ $ $ $ O $ $ O ෆ͉3Ϫ © ©© N ©C © N $ $ $ $ ෆ͉2Ϫ N C ¬ N$ $ෆ͉2Ϫ O©I ©O $ $ $ $ $ $ $ O $ $ O ˚ ෆ͉ Ϫ © O©I ©O $ $ $ $ $ $ $ $ O $ $ O ˚ ෆ͉ Ϫ ˚ O¬I ¬O $ $ $ $ $ $ $ $ $ $ O $ $ O ˚ ෆ͉ Ϫ ˚ ©© Ionic Versus Covalent Bonds 2.71 Place the following elements in order of increasing electronegativity: antimony, tin, selenium, indium. 2.72 Place the following elements in order of increasing electronegativity: oxygen, carbon, nitrogen, fluorine, silicon, phosphorus, sulfur. 2.73 Just as some elements are electronegative, others can be electropositive, a term meaning that the element will readily give up electrons. Elements that are least electronegative are the most electropositive. What trend exists among the alkali metals and the alkaline earth metals with respect to their electropositive character? 2.74 Compare the electronegativites of the following Group 3 elements with those of the Group 2 elements in Periods 4, 5, and 6: Sc, 1.36; Y, 1.22; La 1.10. (a) Which group contains O©P ¬O $ $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉3Ϫ O©P ©O $ $ $ $ $ $ $ O ˚ $ $ $ O ˚ ෆ͉3Ϫ $ $ N © N ©O $ $ $ $ N N ¬O $ $©¬ 2.52 Determine the formal charge on each atom in the following ions. Identify the structure of lowest energy in each case. (a) (b) (c) Exceptions to the Octet Rule 2.53 Which of the following species are radicals? (a) NO2 Ϫ ; (b) CH3; (c) OH; (d) CH2O. 2.66 In each of these ions and compounds, an atom violates the octet rule. Identify the atom and explain the deviation from the octet rule: (a) BrF3; (b) BH3. the more electronegative elements? (b) Which element is the most electronegative? (c) Which is the most electropositive (see Exercise 2.73). 2.75 For each pair, determine which compound has bonds with greater ionic character: (a) HCl or HI; (b) CH4 or CF4; (c) CO2 or CS2. 2.76 For each pair, determine which compound has bonds with greater ionic character: (a) PH3 or NH3; (b) SO2 or NO2; (c) SF6 or IF5. 2.77 Compounds having bonds with a high covalent character tend to be less soluble in water than similar compounds that have low covalent character. Use electronegativities to predict which of the following compounds is the more soluble in water: (a) AlCl3 or KCl; (b) MgO or BaO. 2.78 Use electronegativities to predict which of the following compounds is the more soluble in water (see Exercise 2.77): (a) LiI or MgI2; (b) CaS or CaO. 2.79 Arrange the cations Rbϩ , Be2ϩ , and Sr2ϩ in order of increasing polarizing power. Give an explanation of your arrangement. 2.80 Arrange the cations Kϩ , Mg2ϩ , Al3ϩ , and Csϩ in order of increasing polarizing power. Give an explanation of your arrangement. 2.81 Arrange the anions ClϪ , BrϪ , N3Ϫ , and O2Ϫ in order of increasing polarizability and give reasons for your decisions. 2.82 Arrange the anions N3Ϫ , P3Ϫ , IϪ , and AtϪ in order of increasing polarizability and give reasons for your decisions. The Strengths and Lengths of Covalent Bonds 2.83 Place the following molecules or ions in order of decreasing bond length: (a) the CO bond in CO, CO2, CO3 2Ϫ ; (b) the SO bond in SO2, SO3, SO3 2Ϫ ; (c) the CN bond in HCN, CH2NH, CH3NH2. Explain your reasoning. 2.84 Place the following molecules or ions in order of decreasing bond order: (a) NO bond in NO, NO2, NO3 Ϫ ; (b) CC bond in C2H2, C2H4, C2H6; (c) CO bond in CH3OH, CH2O, CH3OCH3. Explain your reasoning. 2.85 Use the information in Fig. 2.21 to estimate the bond length of (a) the NN bond in hydrazine, H2NNH2; (b) the CO bond in CO2; (c) the CO and CN bonds in urea, OC(NH2)2; (d) the NN bond in nitrogen hydride, HNNH. 2.86 Use the information in Fig. 2.21 to estimate the indicated bond length of (a) the CO bond in formaldehyde, H2CO; (b) the CO bond in dimethyl ether, CH3OCH3; (c) the CO bond in methanol, CH3OH; (d) the CS bond in methanethiol, CH3SH. 2.87 Use the covalent radii in Fig. 2.21 to calculate the bond lengths in the following molecules. Account for the trends in your calculated values: (a) CF4; (b) SiF4; (c) SnF4. 2.88 Which do you predict to have the strongest CN bond: (a) NHCH2, (b) NH2CH3, or (c) HCN? Explain. Integrated Exercises 2.89 Write the Lewis structure, including resonance structures where appropriate, for (a) the oxalate ion, C2O4 2Ϫ (there is a C∫C bond with two oxygen atoms attached to each carbon atom); (b) BrOϩ ; (c) the acetylide ion, C2 2Ϫ . Assign formal charges to each atom. EXERCISES 87 2.90 Write three Lewis structures that follow the octet rule (including the most important structure) for the isocyanate ion, CNOϪ . State which of the three Lewis structures is the most important and explain why it is probably the most important. 2.91 Draw resonance structures for the trimethylenemethane anion C(CH2)3 2Ϫ in which a central carbon atom is attached to three CH2 groups (CH2 groups are referred to as methylene). 2.92 Show how resonance can occur in the following organic ions: (a) acetate ion, CH3CO2 Ϫ ; (b) enolate ion, CH2COCH3 Ϫ , which has one resonance structure with a C≈C double bond and an ∫OϪ group on the central carbon atom; (c) allyl cation, CH2CHCH2 ϩ ; (d) amidate ion, CH3CONHϪ (the O and the N atoms are both bonded to the second C atom). 2.93 White phosphorus is composed of tetrahedral molecules of P4 in which each P atom is connected to three other P atoms. Draw the Lewis structure for this molecule. Does it obey the octet rule? 2.94 The cyclopentadienide ion, C5H5 Ϫ , is a common organic anion that forms very stable complexes with metal cations. The anion is derived by removing a proton from cyclopentadiene, C5H6, with strong base. The molecule has a five-membered ring of carbon atoms, with four carbon atoms attached to only one proton and one carbon atom bonded to two. Draw the Lewis structure of cyclopentadiene. Are resonance forms possible for this molecule? The ion C5H5 Ϫ consists of a planar five-membered ring of carbon atoms, with one hydrogen atom attached to each carbon atom. Draw the Lewis structure for C5H5 Ϫ . How many resonance structures can you draw for this anion? 2.95 In 1999, Karl Christe synthesized and characterized a salt that contained the N5 ϩ cation, in which the five N atoms are connected in a long chain. This cation is the first all-nitrogen species to be isolated in more than 100 years. Draw the most important Lewis structure for this ion, including all equivalent resonance structures. Calculate the formal charges on all atoms. 2.96 Draw the most important Lewis structure for each of the following ring molecules (which have been drawn without showing the locations of the double bonds). Show all lone pairs and nonzero formal charges. If there are equivalent resonance forms, draw them. 2.97 An important principle in chemistry is the isolobal analogy. This very simple principle states that chemical fragments with similar valence orbital structures can replace one another in molecules. For example, and are isolobal fragments, each having three electrons with which to form bonds in addition to the bond to H. An isolobal series of molecules would be HCCH, HCSiH, HSiSiH. Similarly, a lone pair of electrons can be used to replace a bond so that is isolobalN # # # $ Si ¬ H # # # # # # C H C C HC HC NH ˚ ˚ CH2 CH2 N NH HC HC CH NH N CH2 CH2 C ¬ ˚ NH2 O N C C NN C ¬ ¬ OH ˚ OH OH (a) (b) (c) (d) with with the lone pair taking the place of the C∫H bond. The isolobal set here is HCCH, HCN, NN. (a) Draw the Lewis structures for the molecules HCCH, HCSiH, HSiSiH, HCN, and NN. (b) Using the isolobal principle, draw Lewis structures for molecules based on the structure of benzene, C6H6, in which one or more CH groups are replaced with N atoms. C ¬ H # # # 88 CHAPTER 2 CHEMICAL BONDS 2.98 The framework for the tropylium cation, C7H7 ϩ , is a sevenmembered ring of carbon atoms with a hydrogen atom attached to each carbon atom. Complete the structural drawing by adding the multiple bonds as appropriate. Resonance structures are possible. Draw as many as you can find. Determine the C∫C bond order. 2.99 Quinone, C6H4O2, is an organic molecule with the structure shown below; it can be reduced to the anion C6H4O2 2Ϫ . (a) Draw the Lewis structure of the reduced product. (b) On the basis of formal charges derived from the Lewis structure, predict which atoms in the molecule are most negatively charged. (c) If two protons are added to the reduced product, where are they most likely to bond? 2.100 In air, the NO radical can react with O2. What is the most likely product of the reaction? Answer this question by drawing Lewis structures of the reactants and products. 2.101 The atomic numbers (Z), electronic configurations, and numbers of unpaired electrons for five ions are listed in the following table. Assume that all unpaired electrons have parallel spins. Indicate the element symbol, charge, and energy state (that is, ground state or excited state) for each of the five cases. No. of unpaired Energy Z Configuration electrons Element Charge state 26 [Ar]3d6 4 52 [Kr]4d10 5s2 2 5p5 6s1 16 [Ne]3s2 3p6 0 39 [Kr]4d1 1 30 [Ar]4s2 3d8 2 2.102 The atomic numbers (Z), electronic configurations, and numbers of unpaired electrons for five ions are listed in the following table. Assume that all unpaired electrons have parallel spins. Indicate the element symbol, charge, and energy state (that is, ground state, excited state, etc.) for each of the five cases. No. of unpaired Energy Z Configuration electrons Element Charge state 38 [Kr]5p1 1 45 [Kr]4d7 3 43 [Kr]4d5 5s1 6 8 [Ne] 0 21 [Ar]3d1 4s1 2 C C C C C C O O H H H H H H H H H H H C C C CC C C ෆ͉ϩ 2.103 Draw the most important Lewis structure for each of the following molecules. Show all lone pairs and formal charges. Draw all equivalent resonance forms: (a) HONCO; (b) H2CSO; (c) H2CNN; (d) ONCN. 2.104 Determine the formal charges for the atoms in (a) CNϪ ; (b) CNOϪ ; (c) N3 Ϫ . 2.105 (a) Confirm that lattice energies are inversely proportional to the distance between the ions in MX (M ϭ alkali metal, X ϭ halide ion) by plotting the lattice energies of KF, KCl, and KI against the internuclear distances dMϪX. The lattice energies of KF, KCl, and KI are 826, 717, and 645 kJиmolϪ1 , respectively. Use the ionic radii found in Appendix 2D to calculate dMϪX. How good is the correlation? You should use a standard graphing program to make the plot that will generate an equation for the line and calculate a correlation coefficient for the fit (see the Web site for this book). (b) Estimate the lattice energy of KBr from your graph. (c) Find an experimental value for the lattice energy of KBr in the chemical literature and compare that value with the value that you calculated in part (b). How well do they agree? 2.106 (a) Explore whether the lattice energies of the alkali metal iodides are inversely proportional to the distances between the ions in MI (M ϭ alkali metal) by plotting the lattice energies given below against the internuclear distances dMϪI. Alkali metal iodide Lattice energy (kJиmolϪ1 ) LiI 759 NaI 700 KI 645 RbI 632 CsI 601 Use the ionic radii found in Appendix 2D to calculate dMϪX. How good is the correlation? Is a better fit obtained by plotting the lattice energies against (1 Ϫ d*/d)/d, as suggested by the Born–Meyer equation? You should use a standard graphing program to make the plot that will generate an equation for the line and calculate a correlation coefficient for the fit (see the Web site for this book). (b) From the ionic radii given in Appendix 2D and the plot given in part (a), estimate the lattice energy for silver iodide. (c) Compare your results from part (b) with the experimentally determined value of 886 kJиmolϪ1 . If they do not agree, provide an explanation for the deviation. 2.107 A common biologically active radical is the pentadienyl radical, RCHCHCHCHCHRЈ, where the carbons form a long chain, with R and RЈ, which can be a number of different organic groups, at each end. Draw three resonance structures for this compound that maintain carbon’s valence of four. 2.108 Predict the qualitative molecular potential energy curves for the NN bond by making rough sketches on one graph for N2H4, N2, and N3 Ϫ . Explain why the energy of the lowest point on each curve is not the same. 2.109 Thallium and oxygen form two compounds with the following characteristics: Compound I Compound II Mass percentage Tl 89.49% 96.23% Melting point 717°C 300°C (a) Determine the chemical formulas of the two compounds. (b) Determine the oxidation number of thallium in each compound. (c) Assume that the compounds are ionic and write the electron configuration for each thallium ion. (d) Use the melting points to decide which compound has more covalent character in its bonds. Is your finding consistent with what you would predict from the polarizing abilities of the two cations? 2.110 How close are the Mulliken and Pauling electronegativity scales? (a) Use Eq. 6 to calculate the Mulliken electronegativities of C, N, O, and F. Use the values in kJиmolϪ1 from Figs. 1.50 and 1.54 and divide each value by 230 kJиmolϪ1 for this comparison. (b) Plot both sets of electronegativities as a function of atomic number on the same graph. (c) Which scale is more periodic (depends more consistently on position in the periodic table)? 2.111 The perchlorate ion, ClO4 Ϫ , is described by resonance structures. (a) Draw the Lewis structures that contribute to the resonance hybrid and identify the most plausible Lewis structures by using formal charge arguments. (b) The average length of a single Cl∫O bond is 172 pm and that of a double Cl¢O bond can be estimated at 140 pm. The Cl∫O bond length in the perchlorate ion is found experimentally to be 144 pm for all four bonds. Identify the most plausible Lewis structures of the perchlorate ion from these experimental data. (c) What is the oxidation number of chlorine in the perchlorate ion? Identify the most plausible Lewis structure by using the oxidation number, assuming that lone pairs belong to the atom to which they are attached but that all electrons shared in a bond belong to the atom of the more negative element. (d) Are these three approaches consistent? Explain why or why not. 2.112 Predict which bond will absorb light of shorter wavelength and explain why: C∫H or C∫Cl. Refer to Major Technique 1, which follows these exercises. 2.113 Infrared spectra show absorption due to CßH bond stretching at 3.38 ␮m for a methyl (∫CH3) group and at 3.1 ␮m for an alkyne (∫CΩC∫H) group. Which C∫H bond is stiffer (has the larger force constant k), assuming that the vibrating atoms have the same effective mass? Refer to Major Technique 1, which follows these exercises. 2.114 Vibrational spectra are often so complicated that assignment of a particular absorption to a given bond is difficult. One way to confirm that an assignment is correct is to carry out selective isotopic substitution. For example, we can replace a hydrogen atom with a deuterium atom. If an iron-hydride (Fe∫H) stretch occurs at 1950 cmϪ1 , at what energy will this stretch occur, approximately, for a compound that has deuterium in place of the hydrogen? Refer to Major Technique 1, which follows these exercises. 2.115 Certain gases, called greenhouse gases, contribute to global warming by absorbing infrared radiation. Only molecules with dipole moments or nonpolar molecules that undergo distortions that create momentary dipoles (such as CO2, see Figure 2 in Major Technique 1, which follows these exercises) can absorb infrared radiation. Which of the following gases, all of which occur naturally in air, can function as greenhouse gases? (a) CO; (b) O2; (b) O3; (d) SO2; (e) N2O; (f) Ar. 2.116 One of the following compounds does not exist. Use Lewis structures to identify that compound. (a) C2H2; (b) C2H4; (c) C2H6; (d) C2H8. 2.117 Ozone in the stratosphere protects us from harmful radiation by absorbing ultraviolet radiation from the Sun. Compare the bond lengths in the ozone molecule and the oxygen molecule. (a) Are there one or two different bond lengths in ozone? (b) Which molecule has the longer bonds? 2.118 In the solid state, sulfur is sometimes found in rings of six atoms. (a) Draw a valid Lewis structure for S6. (b) Is resonance possible in S6? If so, draw one of the resonance structures. 2.119 Structural isomers are molecules that have the same formula but in which the atoms are connected in a different order. Two isomers of disulfur difluoride, S2F2, are known. In each the two S atoms are bonded to each other. In one isomer each of the S atoms is bonded to an F atom. In the other isomer, both F atoms are attached to one of the S atoms. (a) In each isomer the S∫S bond length is approximately 190 pm. Are the S∫S bonds in these isomers single bonds or do they have some double bond character? (b) Draw two resonance structures for each isomer. (c) Determine for each isomer which structure is favored by formal charge considerations. Are your conclusions consistent with the S∫S bond lengths in the compounds? 2.120 Ionic compounds typically have higher boiling points and lower vapor pressures than covalent compounds. Predict which compound in the following pairs has the lower vapor pressure at room temperature: (a) Cl2O or Na2O; (b) InCl3 or SbCl3; (c) LiH or HCl; (d) MgCl2 or PCl3. Chemistry Connections 2.121 The nitrogen oxides are common pollutants generated by internal combustion engines and power plants. They not only contribute to the respiratory distress caused by smog, but if they reach the stratosphere, can also threaten the ozone layer that protects Earth from harmful radiation. (a) The bond energy in NO is 632 kJиmolϪ1 and that of each N∫O bond in NO2 is 469 kJиmolϪ1 . Using Lewis structures and the average bond energies in Table 2.4, explain the difference in bond energies between the two molecules and the fact that the bond energies of the two bonds in NO2 are the same. (b) The bond length in NO is 115 pm. Use Fig. 2.21 to predict the length of a single bond and a double bond between nitrogen and oxygen. Use Table 2.5 to estimate the length of a triple bond between nitrogen and oxygen. Predict the bond order in NO from its bond length and explain any difference from the calculated values. (c) When the NO in smog reacts with NO2 a bond forms between the two N atoms. Draw the Lewis structure of each reactant and the product and indicate the formal charge on each atom. (d) The NO2 in smog also reacts with NO3 to form a product with an O atom between the two N atoms. Draw the Lewis structure of the most likely product and indicate the formal charge on each atom. (e) Write the balanced chemical equation for the reaction of the product from part (d) with water to produce an acid. The acid produced acts as a secondary pollutant in the environment. Name the acid. (f) If 4.05 g of the product from part (d) reacts with water as in part (e) to produce 1.00 L of acidic solution, what will be the concentration of the acid? (g) Determine the oxidation number of nitrogen in NO, NO2, and the products in parts (c) and (d). Which of these compounds would you expect to be the most potent oxidizing agent? EXERCISES 89 When we feel the warmth of the Sun on our faces, we are responding to infrared radiation that has traveled nearly 150 million kilometers through space. That radiation stimulates the molecules in our skin to vibrate, and specially adapted nerve cells detect the vibration and interpret it as “warmth.” The same type of radiation is used to identify molecules in samples and to determine the stiffness of bonds in molecules. The Technique Infrared radiation is electromagnetic radiation with longer wavelengths (lower frequencies) than red light; a typical wavelength is about 1000 nm. A wavelength of 1000 nm corresponds to a frequency of about 3 ϫ 1014 Hz, which is comparable to the frequency at which molecules vibrate. Therefore, molecules can absorb infrared radiation and become vibrationally excited, which means they begin to vibrate. Any bond between two atoms vibrates as the atoms move closer to each other and away again. This type of motion is called a “stretching” mode. Polyatomic molecules can also undergo “bending” vibrations in which bond angles periodically increase and decrease. The frequency at which a molecule vibrates depends on the masses of its atoms and the stiffness of its bonds: a molecule made up of light atoms joined by stiff bonds has a higher vibrational frequency than one made up of heavy atoms joined by loose bonds. The former molecule will therefore absorb higher frequency radiation than the latter. Bending motions of molecules tend to be less stiff than stretching motions; so bending vibrations typically absorb at lower frequencies than do stretching vibrations. The stiffness of a bond is measured by its force constant, k. This constant is the same as that in Hooke’s law for the restoring force of a spring: Hooke observed that the restoring force is proportional to the displacement of the spring from its resting position, and wrote Force ϭ Ϫk ϫ displacement A stiff bond (like a stiff spring) experiences a strong restoring force, even for quite small displacements, and so in this case k is large. A loose bond (like a weak spring) experiences only a weak restoring force, even for quite large displacements, so its associated k is small. In general, the force constant is larger for stretching displacements of molecules than for bending motions. The stiffness of a bond should not be confused with its strength, which is the energy required to break the bond. Typically, though, the stiffness of a bond increases with the strength of the bond (Fig. 1). The vibrational frequency, ␯ (nu), of a bond between two atoms A and B of masses mA and mB is given by the expression The quantity ␮ (mu) is called the effective mass of the molecular vibration (some people call it the “reduced mass”). As we n = 1 2␲A k m m = mAmB mA + mB INFRARED SPECTROSCOPYMAJOR TECHNIQUE 1 anticipated, the frequency is higher for stiff bonds (large k) and low atomic masses (low ␮). We see that by measuring the vibrational frequency of a molecule, which involves measuring the frequency (or wavelength) at which it absorbs infrared radiation, we can measure the stiffness of its bond. In practice, the vibrational absorption spectrum of a molecule is measured by using an infrared spectrometer. The source of infrared radiation is a hot filament, and the wavelength is selected by diffracting the radiation from a grating. Constructive interference* results in intense radiation in a given direction for a given angle of the grating; and, as that angle is changed, radiation of varying wavelength is passed through the sample. The beam is divided, one beam passing through the sample and the other beam passing through a blank; the intensities of the two beams are then compared at the detector and the reduction in intensity due to absorption by the sample is monitored. The result is a spectrum in which dips occur at the wavelengths of radiation absorbed by the sample. Normal Modes and Polyatomic Molecules A nonlinear molecule consisting of N atoms can vibrate in 3N Ϫ 6 different ways, and a linear molecule can vibrate in 3N Ϫ 5 different ways. The number of ways in which a molecule can vibrate increases rapidly with the number of atoms: a water molecule, with N ϭ 3, can vibrate in 3 ways, but a benzene molecule, with N ϭ 12, can vibrate in 30 different ways. Some of the vibrations of benzene correspond to expansion and contraction of the ring, others to its elongation, and still others to flexing and bending. Each way in which a molecule can vibrate is called a normal mode, and so we say that benzene has 30 normal modes of vibration. Each normal mode has a frequency that depends in a complicated way on the masses of the atoms that Weak bond Strong bond Stiff bond Loose bond Internuclear distance Potentialenergy 0 FIGURE 1 The strength of a bond is a measure of the depth of the well in the potential energy curve; the stiffness—which governs the vibrational frequency—is determined by the steepness with which the potential energy rises as the bond is stretched or compressed. 90 *Interference is discussed more fully in Major Technique 3 following Chapter 5. move during the vibration and the force constants associated with the motions involved (Fig. 2). Except in simple cases, it is very difficult to predict the infrared absorption spectrum of a polyatomic molecule, because each of the modes has its characteristic absorption frequency rather than just the single frequency of a diatomic molecule. However, certain groups, such as a benzene ring or a carbonyl group, have characteristic frequencies, and their presence can often be detected in a spectrum. Thus, an infrared spectrum can be used to identify the species present in a sample by looking for the characteristic absorption bands associated with various groups. An example and its analysis are shown in Fig. 3. A further aid to identification comes from the fact that a molecule commonly has a complex series of absorptions spanning a range of wavelengths. This fingerprint region of the spectrum may be too difficult to analyze in detail, but its presence enables us to recognize the substance by comparing the spectrum to an atlas of spectra. Related Exercises 2.112–2.115. (b) CO2 ␯2 ␯1 ␯3 (a) H2O Bend Bend Symmetrical stretch␯1 ␯2 Antisymmetrical stretch␯3 FIGURE 2 (a) The three normal vibrational modes of H2O. Two of these modes are principally stretching motions of the bonds, but mode ␯2 is primarily bending. (b) The four normal vibrational modes of CO2. The first two are symmetrical and antisymmetrical stretching motions, and the last two are perpendicular bending motions. Increasing frequency, ␯ Increasing wavelength, ␭ Transmission Absorption N CO − H C¬H out-of-plane N¬H NH + 3¬NH + 3 2 ¬NH3 + ¬CO − 2 FIGURE 3 The infrared spectrum of an amino acid, with the groups contributing to some of the peaks identified. 91 This page intentionally left blank 93 What Are the Key Ideas? The central ideas of this chapter are, first, that electrostatic repulsions between electron pairs determine molecular shapes and, second, that chemical bonds can be discussed in terms of two quantum mechanical theories that describe the distribution of electrons in molecules. Why Do We Need to Know This Material? The shapes of molecules determine their odors, their tastes, and their actions as drugs. Molecular shape plays an essential role in the reactions that take place throughout our bodies and are necessary for life. It also affects the properties of the materials around us, including their physical states and their solubilities. Perception, thinking, and learning depend on the shapes of molecules and how they change. Modern theories of the electronic structures of molecules can be extended to describe metals and semiconductors, and so the information in this chapter is also at the root of the development of new technologies. What Do We Need to Know Already? This chapter uses atomic orbitals and electron configurations (Chapter 1). It also extends the concept of Lewis structures introduced in Chapter 2. The discussion of polar molecules develops the material on polar bonds described in Section 2.12. T he bright colors of flowers and the varied hues of autumn leaves have always been a cause for delight, but it was not until the twentieth century that chemists understood how these colors arise from the presence of organic compounds with common structural features. They discovered how small differences in the structures of the molecules of these compounds can enhance photosynthesis, produce important vitamins, and attract pollinating bees. They now know how the shapes of molecules and the orbitals occupied by their electrons explain the properties of these compounds and even the processes taking place in our eyes that allow us to see them. The impact of modern theories of bonding, however, goes far beyond understanding the colors around us. Increasing knowledge of the electronic structures of the atoms and molecules in polymers and semiconductors has led to the development of new technologies. The pharmaceutical industry is increasingly turning to computeraided design—in which molecular shape and the distribution of electrons play a crucial role—to discover new, more potent drugs (Box 3.1). In this chapter we meet three increasingly sophisticated models of molecular shape. The first considers molecular shape to be a consequence merely of the electrostatic (coulombic) interaction between pairs of electrons. The other two models are theories that describe the distribution of electrons and molecular shape in terms of the occupation of orbitals. We shall test these models two ways: with experimental data and with the results of calculations based on computer models (see Major Technique 5, following Chapter 14). The computer models take into account all the energies of interaction between every pair of atoms in a molecule. THE VSEPR MODEL Lewis structures simply show the linkages between atoms and the presence of lone pairs. They do not, by themselves, show the three-dimensional arrangement of atoms in space. In this section, we develop Lewis’s ideas so that we can predict the shapes of simple molecules. We proceed in three steps. First, we set up the basic model for molecules without lone pairs on the central atom. Then, we include the effects of lone pairs. Finally, we explore some of the consequences of molecular shape. THE VSEPR MODEL 3.1 The Basic VSEPR Model 3.2 Molecules with Lone Pairs on the Central Atom 3.3 Polar Molecules VALENCE-BOND THEORY 3.4 Sigma and Pi Bonds 3.5 Electron Promotion and the Hybridization of Orbitals 3.6 Other Common Types of Hybridization 3.7 Characteristics of Multiple Bonds MOLECULAR ORBITAL THEORY 3.8 The Limitations of Lewis’s Theory 3.9 Molecular Orbitals 3.10 Electron Configurations of Diatomic Molecules 3.11 Bonding in Heteronuclear Diatomic Molecules 3.12 Orbitals in Polyatomic Molecules 93 Chapter 3 MOLECULAR SHAPE AND STRUCTURE 94 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE FRONTIERS OF CHEMISTRY: DRUGS BY DESIGN AND DISCOVERYBOX 3.1 A field biologist examines a plant in a South American rainforest. The plant produces chemicals that will be investigated for their medicinal value. The search for new drugs relies not only on the skills of synthetic organic chemists but also on biologists, ethnobotanists, and medical researchers. Because there are so many millions of compounds, it would take too long to start with the elements, combine them in different ways, and then test them. Instead, chemists usually start either by drug discovery, the identification and possibly the modification of promising medicines that already exist, or by rational drug design, the identification of characteristics of a target enzyme, virus, bacterium, or parasite and the design of new compounds to react with it. In drug discovery, a chemist usually begins by investigating compounds that have already shown medicinal value. A fruitful path is to find a natural product, an organic compound found in nature, that has been shown to have healing characteristics. Nature is the best of all synthetic chemists, with billions of chemicals that fulfill as many different needs. The challenge is to find compounds that have curative powers. These substances are found in different ways: random or “blind” collection of samples that are then tested, or collection of specific samples identified by native healers as medically effective. Observation of the properties of plants and animals can help to guide a random search. For example, if certain types of fruits remain fresh while others rot, we might expect the former to contain antifungal agents. An example of this type of collection is the gathering of tunicates and sponges in the Caribbean. The chemists harvest the samples by diving from research vessels (see Fig. F.1). The samples are tested for antiviral and antitumor activity in a chemical laboratory on the ship. The antiviral drug didemnin-C and the anticancer drug bryostatin 1 were discovered in marine organisms. The guided route requires fewer samples for testing because the chemist works with a native healer, the ancient lore guiding the modern chemistry. Often an ethnobotanist, a specialist in plants used for native healing, joins the team. This approach saves time for the scientists and can provide an economic benefit for the healers and their nations as well. Drugs that have been discovered in this way include a variety of anticancer and antimalarial drugs, blood-clotting agents, antibiotics, and medicines for the heart and digestive system. Once the empirical and molecular formulas of the active compounds are determined, then their structural formulas are sought. At that point, synthetic work can begin. The chemist can identify compounds in the material that have medicinal value and find a way to synthesize them, or prepare them in the laboratory, so that they can be made available in large quantities. In rational drug design, the chemist begins with the tumor or organism that the drug is intended to eradicate. Virtually all processes in living cells depend on specific enzymes, types of proteins with very large molecules having specific shapes. Usually there is an active site on the enzyme into which only specific molecules can fit and react. If the enzymes that control the growth of parasites or bacteria can be identified and their shapes known, compounds that fit into the active sites and block the reactions can be designed. The chemist taking this route begins by identifying key enzymes in the bacterium or parasite. Then the molecular structure of the enzyme is determined. A computer program is used to design molecules with structures that fit into the active site. Structure–activity relationships (SAR) are investigated to find out which aspects of the structure are important to the activity of the drug. The new compounds are synthesized, and their effects and side effects tested. HOW MIGHT YOU CONTRIBUTE? Despite all the medicines in a modern pharmacy, there is still a great need for specific chemotherapeutic agents with few side effects. We are beginning to see the investigation of a wide array of natural products and the rational drug design of new therapeutic agents. The selection of good candidates for drug development from these large numbers of compounds and synthetic routes to duplicate them need to be optimized. Related Exercises: 3.75 and 3.94 For Further Reading: D. Hart, “Designer drugs,” Science Spectra, no. 8, 1997, p. 52. J. Staunton and K. Weissman, “Medicines from nature,” The New Chemistry, edited by N. Hall (Cambridge: Cambridge University Press, 2000), pp. 199–213. R. P. Szuromi, V. Vinson, and E. Marshall, “Rethinking drug discovery,” Science, vol. 303, p. 1795 [March 19, 2004]. I. Paterson and E. A. Anderson, “The renaissance of natural products as drug candidates,” Science, vol. 310, p. 451 [October 21, 2005]. ? 3.1 The Basic VSEPR Model We begin by looking at molecules that consist of one central atom to which all the other atoms are attached. Many of these molecules have the shapes of the geometrical figures shown in Fig. 3.1; thus, CH4 (1) is tetrahedral, SF6 (2) is octahedral, and PCl5 (3) is trigonal bipyramidal. In a number of these cases the bond angles, the angles between the bonds (the straight lines that join the atom centers), are fixed by the symmetry of the molecule; these bond angles are indicated in Fig. 3.1. Thus, the HCH angle in CH4 is 109.5Њ (the “tetrahedral angle”), the FSF angles in SF6 are 90Њ and 180Њ, and the ClPCl angles in PCl5 are 90Њ, 120Њ, and 180Њ. The bond angles of molecules that are not fixed by symmetry must be determined experimentally. The HOH bond angle in the angular H2O molecule, for instance, has been found to be 104.5Њ and the HNH angle in the trigonal pyramidal NH3 molecule is measured as 107Њ. The principal technique for determining bond angles in small molecules is spectroscopy, especially rotational and vibrational spectroscopy; x-ray diffraction is used for larger molecules. The Lewis structures encountered in Chapter 2 are two-dimensional representations of the links between atoms—their connectivity—and except in the simplest cases do not depict the arrangement of atoms in space. The valence-shell electron-pair repulsion model (VSEPR model) extends Lewis’s theory of bonding to account for molecular shapes by adding rules that account for bond angles. The model starts from the idea that because electrons repel one another, the pairs of bonding electrons in simple molecules lie as far apart as possible. Specifically: Rule 1 Regions of high electron concentration (bonds and lone pairs on the central atom) repel one another and, to minimize their repulsions, these regions move as far apart as possible while maintaining the same distance from the central atom (Fig. 3.2). Once we have identified the arrangement of the “most distant” locations of these regions, which is called the electron arrangement of the molecule, we note where the atoms lie and identify the shape of the molecule by giving it the name of the corresponding shape in Fig. 3.1. In naming the molecular shape, we consider only the positions of atoms, not any lone pairs that may be present on the central atom, even though they affect the shape. A molecule with only two atoms attached to the central atom is BeCl2. The Lewis structure is , and there are no lone pairs on the central atom. To be as far apart as possible, the two bonding pairs lie on opposite sides of the Be atom, and so the electron arrangement is linear. The Cl atoms lie on opposite sides of the Be atom and so the VSEPR model predicts a linear shape for the BeCl2 molecule, with a bond angle of 180Њ (4). That shape is confirmed by experiment. A boron trifluoride molecule, BF3, has the Lewis structure shown in (5). There are three bonding pairs attached to the central atom and no lone pairs. To be as far apart as possible, the three bonding pairs must lie at the corners of an equilateral triangle. Cl ¬ Be ¬ Clå Å Å å Å Å 3.1 THE BASIC VSEPR MODEL 95 Linear Angular Trigonal planar Trigonal pyramidal T-shaped Tetrahedral See-saw Trigonal bipyramidal Square planar Square pyramidal Octahedral Pentagonal bipyramidal 120° 109.5° 90° 90° 90° 90° 72° FIGURE 3.1 The names of the shapes of simple molecules and their bond angles. Lone pairs of electrons are not shown, because they are not included when identifying molecular shapes. 1 Methane, CH4 C H 2 Sulfur hexafluoride, SF6 S F 3 Phosphorus pentachloride, PCl5 P Cl 4 Beryllium chloride, BeCl2 Be Cl The VSEPR model was first explored by the British chemists Nevil Sidgwick and Herbert Powell and has been developed by the Canadian chemist Ronald Gillespie. The electron arrangement is trigonal planar. Because an F atom is attached to each bonding pair, the BF3 molecule is trigonal planar (6), and all three FBF angles are 120Њ, as confirmed experimentally. Methane, CH4, has four bonding pairs on the central atom. To be as far apart as possible, the four pairs must take up a tetrahedral arrangement around the C atom. Because the electron arrangement is tetrahedral and an H atom is attached to each bonding pair, we expect the molecule to be tetrahedral (see 1), with bond angles of 109.5Њ. That is the shape found experimentally. In a phosphorus pentachloride molecule, PCl5 (7), there are five bonding pairs and no lone pairs on the central atom. According to the VSEPR model, the five pairs and the atoms that they carry are farthest apart in a trigonal bipyramidal arrangement (see Fig. 3.2). In this arrangement, three atoms (the “equatorial” atoms) lie at the corners of an equilateral triangle and the other two atoms (the “axial” atoms) lie above and below the plane of the triangle (see 3). This structure has three different bond angles: the bond angles in the equatorial plane are 120Њ; the angle between the axial and the equatorial atoms is 90Њ; the one axial ClPCl bond angle is 180Њ. This structure is also confirmed experimentally. A sulfur hexafluoride molecule, SF6, has six atoms attached to the central S atom and no lone pairs on that atom (8). According to the VSEPR model, the electron arrangement is octahedral, with four pairs at the corners of a square on the equator and the remaining two pairs above and below the plane of the square (see Fig. 3.2). An F atom is attached to each electron pair, and so the molecule is predicted to be octahedral. All its bond angles are either 90Њ or 180Њ, and all the F atoms are equivalent. The second rule of the VSEPR model concerns the treatment of multiple bonds: Rule 2 There is no distinction between single and multiple bonds: a multiple bond is treated as a single region of high electron concentration. That is, the two electron pairs in a double bond stay together and repel other bonds or lone pairs as a unit. The three electron pairs in a triple bond also stay together and act like a single region of high electron concentration. For instance, a carbon dioxide molecule, , has a linear structure similar to that of BeCl2, even though both bonds are double bonds (9). One of the Lewis structures of a carbonate ion, CO3 2– , is shown in (10). The two pairs of electrons in the double bond are treated as a unit, and the resulting shape (11) is trigonal planar. Because each bond, whether single or multiple, acts as a single unit, to count the number of regions of high electron concentration we simply count the number of atoms attached to the central atom and add the number of lone pairs. When there is more than one central atom, we consider the bonding about each atom independently. For example, to predict the shape of an ethene (ethylene) molecule, CH2¢CH2, we consider each carbon atom separately. From the Lewis structure O £C £O Å Å Å Å 96 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 6 Boron trifluoride, BF3 7 Phosphorus pentachloride, PCl5 P .. .. Cl .. .. .. Cl .. .. .. Cl .. .. .. Cl .. .. .. Cl .. .. .. .... .... .. .. .. .. .. .. .. .. .. .. .. .. S F F F F F F Sulfur hexafluoride, SF68 All six terminal atoms are equivalent in a regular octahedral molecule. 9 Carbon dioxide, CO2 C 2Ϫ OO O ෆ͉ .. .. .. .. .. .. .. .. 10 Carbonate ion, CO3 2Ϫ 2Ϫ 11 Carbonate ion, CO3 2Ϫ Linear Trigonal planar Trigonal bipyramidal Pentagonal bipyramidal Tetrahedral Octahedral FIGURE 3.2 The positions that two to seven regions of high electron concentration (atoms and lone pairs) take around a central atom. The regions are denoted by the straight lines sticking out of the central atom. Use this diagram to identify the electron arrangement of a molecule, and then use Fig. 3.1 to identify the shape of the molecule from the locations of its atoms. The sevenregion pentagonal bipyramidal arrangement is not unique: several arrangements have about the same energy. Boron trifluoride, BF3 B .. .. .. .. .. .. F .. F .. F .. 5 (12) we note that each carbon atom has three atoms attached but no lone pairs. The arrangement around each carbon atom is therefore trigonal planar. We predict that the HCH and HCC angles will both be close to 120Њ (13); this prediction is confirmed experimentally (the actual values being 117Њ and 122Њ, respectively). 3.1 THE BASIC VSEPR MODEL 97 12 Ethene, C2H4 C H H C H H 13 Ethene, C2H4 117Њ 122Њ EXAMPLE 3.1 Predicting the shape of a molecule with no lone pairs on the central atom Suggest a shape for the ethyne (acetylene) molecule, . PLAN Write down the Lewis structure and identify the electron arrangement around each “central” atom (each C atom, in this case). Treat each multiple bond as a single unit. Then identify the overall shape of the molecule (refer to Fig. 3.2 if necessary). SOLVE HC‚CH Write the Lewis structure of the molecule. H¬ C‚C ¬H H HC C H HC C: :::: Identify the electron arrangement around each “central” atom. Linear: Each C atom is attached to two other atoms (one H atom and one C atom), and there are no lone pairs. Identify the arrangement of atoms around each C atom. Linear, and the molecule is linear overall. Self-Test 3.1A Predict the shape of an arsenic pentafluoride molecule, AsF5. [Answer: Trigonal bipyramidal] Self-Test 3.1B Predict the shape of a formaldehyde molecule, CH2O. Because we treat single bonds and multiple bonds as equivalent in the VSEPR model, it does not matter which of the Lewis structures contributing to a resonance structure we consider. For example, although we can write several different Lewis structures for a nitrate ion, all of them have three regions of electron concentration around the central N atom—all of them have three atoms attached to the central atom—and in each case we expect a trigonal planar structure (14). That the three N∫O bonds are all equivalent is confirmed experimentally by the fact that all three have the same length and the three bond angles are identical. It is also confirmed by calculation: an electrostatic potential diagram (Section C) shows the symmetry of the calculated electron distribution (15). The equivalence of the three bonds is what we would expect in a resonance structure. Thinking point: Can you think of a way to present VSEPR theory without having to deal with Lewis structures? According to the VSEPR model, regions of high electron concentration take up positions that maximize their separations; electron pairs in a multiple bond are treated as a single unit. The shape of the molecule is then identified from the relative locations of its atoms. Recall that red regions indicate negative electrical potential (an accumulation of electrons) and blue regions indicate positive potential (a deficiency of electrons). 14 Nitrate ion, NO3 Ϫ Ϫ 15 Nitrate ion ␦ϩ ␦Ϫ 3.2 Molecules with Lone Pairs on the Central Atom To help us predict the shapes of molecules, we use the generic “VSEPR formula” AXnEm to identify the different combinations of atoms and lone pairs attached to the central atom. We let A represent a central atom, X an attached atom, and E a lone pair. For example, the BF3 molecule, with three attached fluorine atoms and no lone pairs on B, is an example of an AX3 species. The sulfite ion, SO3 2– (16), which has one lone pair, is an example of an AX3E species. Molecules with the same VSEPR formula have essentially the same electron arrangement and the same shape; so by recognizing the formula we can immediately predict the shape (but not necessarily the precise numerical values of bond angles that are not governed by symmetry). If there are no lone pairs on the central atom (an AXn molecule), each region of high electron concentration corresponds to an atom, and so the molecular shape is the same as the electron arrangement. However, if lone pairs are present, the molecular shape differs from the electron arrangement because only the positions of the atoms are considered when naming the shape. For example, the four regions of high electron concentration in SO3 2– are farthest apart if they adopt a tetrahedral arrangement (see Fig. 3.2). However, the shape of the ion is described by the locations of the atoms, not the lone pair. Because only three of the tetrahedral locations are occupied by atoms, the shape of an SO3 2– ion is trigonal pyramidal (17). The rule to remember is Rule 3 All regions of high electron density, lone pairs and bonds, are included in a description of the electronic arrangement, but only the positions of atoms are considered when identifying the shape of a molecule. A single unpaired electron on the central atom also is a region of high electron density and is treated like a lone pair when determining molecular shape. For example, radicals such as NO2 have a single nonbonding electron, a “lone half-pair.” Thus, NO2 (18) has a trigonal planar electron arrangement (including the unpaired electron on N), but its shape is angular (19). 98 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 16 Sulfite ion, SO3 2؊ O $ $$ O $ $ $$ $ $ $ O ෆ͉2؊ S 2Ϫ 17 Sulfite ion, SO3 2Ϫ 18 Nitrogen dioxide, NO2 .. .. .. . O .. ..ON 19 Nitrogen dioxide, NO2 EXAMPLE 3.2 Predicting the shape of a molecule with lone pairs on the central atom Predict the electron arrangement and the shape of a nitrogen trifluoride molecule, NF3. Anticipate The formula resembles that of ammonia, NH3, which is trigonal pyramidal; so we should suspect that NF3 will also be trigonal pyramidal. PLAN For the electron arrangement, draw the Lewis structure and then use the VSEPR model to decide how the bonding pairs and lone pairs are arranged around the central atom (consult Fig. 3.2 if necessary). Identify the molecular shape from the layout of atoms, as in Fig. 3.1. SOLVE Draw the Lewis structure. Count the bonds and lone pairs on the central atom. The central N atom has one electron pair and three bonds, corresponding to four regions of high electron density. F F F F F F N N: :: : : : : ::: :: : Assign the electron arrangement. Tetrahedral 3.2 MOLECULES WITH LONE PAIRS ON THE CENTRAL ATOM 99 Identify the shape considering only atoms. The three atoms bonded to N form a trigonal pyramid. Note that normally lone pairs are not shown explicitly when drawing molecular structures. Evaluate Spectroscopic measurements confirm the prediction of a trigonal pyramidal shape for NF3. The value of the bond angle found experimentally is 102Њ. Self-Test 3.2A Predict (a) the electron arrangement and (b) the shape of an IF5 molecule. [Answer: (a) Octahedral; (b) square pyramidal] Self-Test 3.2B Predict (a) the electron arrangement and (b) the shape of an SO2 molecule. So far we have regarded lone pairs as equivalent to atoms, but is that really the case? We have predicted, for instance, that the electron arrangement of an SO3 2– ion is tetrahedral, and so we might expect OSO angles of 109.5Њ. However, experimental findings have shown that, although the sulfite ion is indeed trigonal pyramidal, its bond angle is 106Њ (20). Such experimental evidence tells us that the VSEPR model as we have described it is incomplete and needs to be refined. To account for the fact that bond angles in molecules with lone pairs are typically smaller than expected, the VSEPR model treats lone pairs as having a more strongly repelling effect than do electrons in bonds. That is, the lone pairs push the atoms bonded to the central atom closer together. One possible rationalization for this effect is that the electron cloud of a lone pair can spread over a larger volume than a bonding pair, because a bonding pair (or several bonding pairs in a multiple bond) is pinned down by two atoms, not one (Fig. 3.3). In summary, the VSEPR model provides reasonably reliable predictions if we adopt the following rule: Rule 4 The strengths of repulsions are in the order lone pair–lone pair Ͼ lone pair–atom Ͼ atom–atom. Therefore, the lowest energy is achieved when lone pairs are as far from each other as possible. The energy is also lowest if the atoms bonded to the central atom are far from lone pairs, even though that might bring the atoms closer to other atoms. Our improved model helps to account for the bond angle of the AX3E sulfite ion. The atoms and the lone pair adopt a tetrahedral arrangement around the S atom. However, the lone pair exerts a strong repulsion on the O atoms, forcing them to move together slightly, reducing the OSO angle from the 109.5Њ of the regular tetrahedron to 106Њ. Note that, although the VSEPR model can predict the direction of the distortion, it cannot predict its extent. We can predict that, in any AX3E species, the XAX angle will be less than 109.5Њ, but we cannot predict its actual value; we must measure it experimentally or calculate it by solving the Schrödinger equation numerically on a computer. Self-Test 3.3A (a) Give the VSEPR formula of an NH3 molecule. Predict (b) its electron arrangement and (c) its shape. [Answer: (a) AX3E; (b) tetrahedral; (c) trigonal pyramidal (21, LP is lone pair), HNH angle less than 109.5Њ] Self-Test 3.3B (a) Give the VSEPR formula of a ClO2 – ion. Predict (b) its electron arrangement and (c) its shape. Rule 4 allows us to predict the position in which a lone pair will be found. For example, the electron arrangement in an AX4E molecule or ion, such as IF4 ϩ , is trigonal bipyramidal, but there are two different possible locations for the lone pair. An 2Ϫ 20 Sulfite ion, SO3 2Ϫ 106Њ Lone pair Bonding pairs FIGURE 3.3 A possible explanation of why lone pairs have a greater repelling effect than that of bonding electrons. A lone pair is less restrained than bonding pairs and so takes up more space; the bonding pairs (with their atoms) move away from the lone pair in an attempt to lower the repulsion that they experience, thus compressing the bond angle slightly. 21 Ammonia, NH3 LP 107Њ axial lone pair lies on the axis of the molecule, where it repels three electron pairs strongly; an equatorial lone pair lies on the molecule’s equator, on the plane perpendicular to the molecular axis, where it repels only two electron pairs strongly (Fig. 3.4). Experimental evidence for this difference in repulsion is the fact that the axial P–Cl bond length in PCl5 is 219 pm, but the equatorial PßCl bond length is only 204 pm. Therefore, the lowest energy is achieved when a lone pair is equatorial, producing a seesaw-shaped molecule. An AX3E2 molecule, such as ClF3, also has a trigonal bipyramidal arrangement of electron pairs, but two of the pairs are lone pairs. These two pairs are farthest apart if they occupy two of the three equatorial positions but move away from each other slightly. The result is a T-shaped molecule (Fig. 3.5). Now consider an AX4E2 molecule, which has an octahedral arrangement of electron pairs, two of which are lone pairs. The two lone pairs are farthest apart when they lie opposite each other, and so the molecule is square planar (Fig. 3.6). Molecules with the same VSEPR formula all have the same general shape, although their bond angles generally differ slightly. For example, O3 is an AX2E species ; it has a trigonal planar electron arrangement and an angular molecular shape (22). The nitrite ion, NO2 – , has the same general formula and the same shape (23); so too does sulfur dioxide, SO2 , (24). Exceptions sometimes arise when the energy difference between two possible structures is small. For example, the energy of an AX4E square planar structure is only very slightly higher than that of an AX4E seesaw structure and some AX4E species, such as the InCl4 Ϫ ion, are square pyramidal (25). Exceptions to the VSEPR rules are also found for atoms that are so large that lone pairs do not affect the shape of the molecule. For example, The SeCl6 2– ion is octahedral, even though the Se atom contains a lone pair as well as bonds to six atoms. O¬ S £O) Å Å Å Å Å å(O¬ N £O ) Å Å Å Å Å å( Ϫ O¬ O £O) Å Å Å ÅÅ å( 100 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE (a) (b) FIGURE 3.6 The square planar arrangement of atoms taken up in AX4E2 molecules: the two lone pairs are farthest apart when they are on opposite sides of the central atom. FIGURE 3.4 (a) A lone pair in an axial position is close to three equatorial atoms. (b) In an equatorial position, a lone pair is close to only two atoms, a more favorable arrangement. FIGURE 3.5 Two lone pairs in an AX3E2 molecule adopt equatorial positions and move away from each other slightly. As a result, the molecule is approximately T-shaped. 23 Nitrite ion, NO2 Ϫ Ϫ 24 Sulfur dioxide, SO2 22 Ozone, O3 25 InCl4 Ϫ Cl ϪIn TOOLBOX 3.1 HOW TO USE THE VSEPR MODEL CONCEPTUAL BASIS Regions of high electron concentration—bonds and lone pairs attached to a central atom in a molecule—arrange themselves in such a way as to minimize mutual repulsions. PROCEDURE The general procedure for predicting the shape of a molecule is as follows: Step 1 Decide how many atoms and lone pairs are present on the central atom by writing a Lewis structure for the molecule. Step 2 Identify the electron arrangement, including lone pairs and atoms, and treating a multiple bond as equivalent to a single bond (see Fig. 3.2). Step 3 Locate the atoms and identify the molecular shape (according to Fig. 3.1). The molecular shape describes only the positions of the atoms, not the lone pairs. Step 4 Allow the molecule to distort so that lone pairs are as far from one another and from bonding pairs as possible. The repulsions are in the order Lone pair–lone pair Ͼ lone pair–atom Ͼ atom–atom Example 3.3 shows how this procedure is used. Evaluate The slightly bent seesaw shape shown is the one found experimentally. Self-Test 3.4A Predict the shape of an I3 – ion. [Answer: Linear] Self-Test 3.4B Predict the shape of a xenon tetrafluoride molecule, XeF4. In a molecule that has lone pairs or a single nonbonding electron on the central atom, the valence electrons contribute to the electron arrangement about the central atom but only bonded atoms are considered in the identification of the shape. Lone pairs distort the shape of a molecule so as to reduce lone pair–bonding pair repulsions. 3.3 Polar Molecules In Section 2.12, we saw that a polar covalent bond in which electrons are not evenly distributed has a nonzero dipole moment. A polar molecule is a molecule with a nonzero dipole moment. A diatomic molecule is polar if its bond is polar. An HCl molecule, with its polar covalent bond (␦ϩ H∫Cl␦Ϫ ), is a polar molecule. Its dipole moment of 1.1 D is typical of polar diatomic molecules (Table 3.1). All diatomic molecules composed of atoms of two different elements are at least slightly polar. A nonpolar molecule is a molecule that has no electric dipole moment. A homonuclear diatomic molecule, a diatomic molecule built from two atoms of the same element, such as O2, N2, and Cl2, is nonpolar, because its bond is nonpolar. 3.3 POLAR MOLECULES 101 EXAMPLE 3.3 Predicting a molecular shape Predict the shape of a sulfur tetrafluoride molecule, SF4. PLAN We use the procedure in Toolbox 3.1. SOLVE Step 1 Draw the Lewis structure. Because we are focusing on the central atom, there is no need to show the lone pairs on the F atoms. Så ˚ ˚ F F F F œœ Step 2 Assign the electron arrangement around the central atom. Each F atom should have three lone pairs of electrons, leaving 5 regions of high electron density (4 atoms and 1 lone pair) on the S atom; so trigonal bipyramidal. Step 3 Identify the molecular shape. AX4E. To minimize electron pair repulsions, the lone pair occupies an equatorial location. SF4 has a seesaw shape. Step 4 Allow for distortions. The atoms move slightly away from the lone pair. A polyatomic molecule may be nonpolar even if its bonds are polar. For example, the two ␦ϩ C∫O␦Ϫ dipole moments in carbon dioxide, a linear molecule, point in opposite directions, and so they cancel each other (26). and CO2 is a nonpolar molecule. Even though there are positive and negative regions of charge within the molecule, the center of positive charge and the center of negative charge coincide, so the molecule itself is nonpolar. The electrostatic potential diagram (27) illustrates this conclusion. As noted in Section C, the colors show how electron density is distributed in the molecule. Partially positive regions are blue and partially negative regions red. In contrast, the two ␦ϩ H∫O␦Ϫ dipole moments in H2O lie at 104.5Њ to each other and do not cancel, and so H2O is a polar molecule (28). This polarity is part of the reason why water is such a good solvent for ionic compounds. Thinking point: Can you justify that last remark? As we have seen by comparing CO2 and H2O, the shape of a polyatomic molecule affects whether or not it is polar. The same is true of more complicated molecules. For instance, the atoms and bonds are the same in cis-dichloroethene (29) and trans-dichloroethene (30); but in the latter, the C∫Cl bonds point in opposite directions and the dipoles (which point along the C∫Cl bonds) cancel. Thus, whereas cis-dichloroethene is polar, trans-dichloroethene is nonpolar. Because dipole moments are directional, we can treat each bond dipole moment as a vector. The molecule as a whole will be nonpolar if the vector sum of the dipole moments of the bonds is zero. If the four atoms attached to the central atom in a tetrahedral molecule are the same, as in tetrachloromethane (carbon tetrachloride), CCl4 (31), the dipole moments cancel and the molecule is nonpolar. However, if one or more of the atoms are replaced by different atoms, as in trichloromethane (chloroform), CHCl3, or by lone pairs, as in NH3, then the dipole moments associated with the bonds are not all the same, so they do not cancel. Thus, the CHCl3 molecule is polar (32). Figure 3.7 summarizes the shapes of simple molecules that result in their being polar or nonpolar. 102 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE TABLE 3.1 Dipole Moments of Selected Molecules Molecule Dipole moment (D) Molecule Dipole moment (D) HF 1.91 PH3 0.58 HCl 1.08 AsH3 0.20 HBr 0.80 SbH3 0.12 HI 0.42 O3 0.53 CO 0.12 CO2 0 ClF 0.88 BF3 0 NaCl* 9.00 CH4 0 CsCl* 10.42 cis-CHCl¢CHCl 1.90 H2O 1.85 trans-CHCl¢CHCl 0 NH3 1.47 *For pairs of ions in the gas phase, not the bulk ionic solid. 26 Carbon dioxide, CO2 ␦Ϫ ␦Ϫ␦ϩ ␦ϩ 27 Carbon dioxide, CO2 28 Water, H2O 29 cis-Dichloroethene, C2H2Cl2 30 trans-Dichloroethene, C2H2Cl2 31 Tetrachloromethane, CCl4 32 Trichloromethane, CH3Cl EXAMPLE 3.4 Predicting the polar character of a molecule Predict whether (a) a boron trifluoride molecule, BF3, and (b) an ozone molecule, O3, are polar. PLAN In each case, we must decide on the shape of the molecule by using the VSEPR model and then decide whether the symmetry of the molecule results in the cancellation of the dipole moments associated with the bonds. If necessary, refer to Fig. 3.7. 3.3 POLAR MOLECULES 103 VSEPR type Nonpolar Polar VSEPR type Nonpolar Polar None known None known AX2 CO2 SO2, O H2O3 XeF2, I3 – BrF3 NH3 ClF3 COCl2 BrIF – N2O AX2E AX4 CH4 CH3Cl SF4 XeF4 PCl5 PCl4F IF5 SF6 AX4E AX4E2 AX5E AX6 AX5 AX2E2 AX2E3 AX2E4 AX3 AX3E AX3E2 FIGURE 3.7 Arrangements of atoms that give rise to polar and nonpolar molecules. In the VSEPR formulas, A stands for a central atom, X for an attached atom, and E for a lone pair. Identical atoms are the same color; attached atoms colored differently belong to different elements. The green lobes represent lone pairs of electrons. SOLVE 104 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE Assign the electron arrangement. Draw the Lewis structure. Identify the VSEPR formula. BF3 O3 F ¬ B ¬ F Å Å Å Å Å å å å ˚ F å O ¬ O £ O Å Å Å Å Å å AX3 AX2E Name the molecular shape. Identify the polarity. Trigonal planar Angular Nonpolar: The symmetry allows all three B∫F dipoles to cancel. Polar: The dipoles do not cancel. Evaluate This example shows that a homonuclear polyatomic molecule (O3) can be polar: shape is more important than differences in atoms and O3 is polar despite all three atoms being oxygen. In this case, the central O atom has a different electron density associated with it than the outer two O atoms: it is bonded to two O atoms whereas the outer atoms are bonded only to one O atom. Self-Test 3.5A Predict whether (a) SF4, (b) SF6 is polar or nonpolar. [Answer: (a) Polar; (b) nonpolar] Self-Test 3.5B Predict whether (a) PCl5, (b) IF5 is polar or nonpolar. A diatomic molecule is polar if its bond is polar. A polyatomic molecule is polar if it has polar bonds arranged in space in such a way that the dipole moments associated with the bonds do not cancel. VALENCE-BOND THEORY The Lewis model of the chemical bond assumes that each bonding electron pair is located between the two bonded atoms—it is a localized electron model. However, we know from the wave–particle duality of the electron (Sections 1.5–1.7) that the location of an electron in an atom cannot be described in terms of a precise position, but only in terms of the probability of finding it somewhere in a region of space defined by its orbital. The same principles apply to electrons in molecules, except that the electrons are distributed over more than one atom. The first description of covalent bonding to be devised in terms of atomic orbitals, by Walter Heitler, Fritz London, John Slater, and Linus Pauling in the late 1920s, is called valence-bond theory (VB theory). This theory is a quantum mechanical description of the distribution of electrons in bonds that goes beyond Lewis’s theory and the VSEPR model by providing a way of calculating the numerical values of bond angles and bond lengths. We shall not go into the actual calculations, which are very complicated, but shall concentrate instead on some of the qualitative concepts. These bonding concepts are used throughout chemistry, so it is important to know how to apply them. 3.4 Sigma and Pi Bonds We begin with H2, the simplest molecule of all, and start by thinking about the two hydrogen atoms from which it is formed. Each hydrogen atom in its ground state has one electron in a 1s-orbital. In valence-bond theory, we suppose that, as two H atoms come together, their 1s-electrons pair (denoted ↑↓, as in the discussion of atomic structure in Section 1.10), and the atomic orbitals merge together (Fig. 3.8). The resulting sausage-shaped distribution of electrons, with an accumulation of electron density between the nuclei, is called a “␴-bond” (a sigma bond). More formally, a ␴-bond is cylindrically symmetrical (the same in all directions around the long axis of the bond), with no nodal planes containing the internuclear axis. A hydrogen molecule is held together by a ␴-bond. The merging of the two atomic orbitals is called the overlap of orbitals. A general point to keep in mind throughout this section is that, the greater the extent of orbital overlap, the stronger the bond. Much the same kind of ␴-bond formation (“␴-bonding”) occurs in the hydrogen halides. For example, before an H and F atom combine to form hydrogen fluoride, the unpaired electron on the fluorine atom occupies a 2pz-orbital, and the unpaired electron on the hydrogen atom occupies a 1s-orbital. These two electrons are the ones that pair to form a bond (33). They pair as the orbitals that they occupy overlap and merge into a cloud that spreads over both atoms (Fig. 3.9). When viewed from the side, the resulting bond has a more complicated shape than that of the ␴-bond in H2; however, the bond looks much the same—it has cylindrical symmetry and no nodal planes containing the internuclear axis—when viewed along the internuclear (z) axis; hence it too is a ␴-bond. All single covalent bonds are ␴-bonds. We encounter a different type of bond in a nitrogen molecule, N2. There is a single electron in each of the three 2p-orbitals on each atom (34). However, when we try to pair them and form three bonds, only one of the three orbitals on each The Greek letter sigma, ␴, is the equivalent of our letter s. It reminds us that, looking along the internuclear axis, the electron distribution resembles that of an s-orbital. zAtomic orbitals ␴-bond 1s 1s By convention, the bond direction in a linear molecule defines the z-axis. F2s H1sF2p Hydrogen fluoride, HF33 ␴-bond 1s 2pz zAtomic orbitals FIGURE 3.9 A ␴-bond can also be formed when electrons in 1s- and 2pz-orbitals pair (where z is the direction along the internuclear axis). The two electrons in the bond are generally found spread over the entire region of space enclosed by the boundary surface. N2s N2p N2s N2p Nitrogen, N234 FIGURE 3.8 When electrons with opposite spins (depicted as ↑ and ↓) in two hydrogen 1s-orbitals pair and the s-orbitals overlap, they form a ␴-bond, which is depicted here by the boundary surface of the electron cloud. The cloud has cylindrical symmetry around the internuclear axis and spreads over both nuclei. In the illustrations in this book, ␴-bonds are usually colored blue. Animation 3.8 atom can overlap end to end to form a ␴-bond (Fig. 3.10). Two of the 2p-orbitals on each atom (2px and 2py) are perpendicular to the internuclear axis, and each one contains an unpaired electron (Fig. 3.11, top). When the electrons in the p-orbitals on one N atom pair with the p-electrons on the other N atom, the orbitals can overlap only in a side-by-side arrangement. This overlap results in a “␲-bond,” a bond in which the two electrons lie in two lobes, one on each side of the internuclear axis (Fig. 3.11, bottom). More formally, a ␲-bond has a single nodal plane containing the internuclear axis. Although a ␲-bond has electron density on each side of the internuclear axis, it is only one bond, with the electron cloud in the form of two lobes, just as a p-orbital is one orbital with two lobes. In a molecule with two ␲-bonds, such as N2, the electron densities in the two perpendicular ␲-bonds merge, and the two atoms appear to be surrounded by a cylinder of electron density (Fig. 3.12). Thinking point. How do you think a ␦-bond (a delta bond) might be formed? We can generalize from these examples to the description of a multiply bonded species according to valence-bond theory: A single bond is a ␴-bond. A double bond is a ␴-bond plus one ␲-bond. A triple bond is a ␴-bond plus two ␲-bonds. Self-Test 3.6A How many ␴-bonds and how many ␲-bonds are there in (a) CO2 and (b) CO? [Answer: (a) Two ␴, two ␲; (b) one ␴, two ␲] Self-Test 3.6B How many ␴-bonds and how many ␲-bonds are there in (a) NH3 and (b) HCN? In valence-bond theory, we assume that bonds form when unpaired electrons in valence-shell atomic orbitals pair; the atomic orbitals overlap end to end to form ␴-bonds or side by side to form ␲-bonds. 106 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE ␴-bond 2pz 2px 2px z ␲-bond 2px 2px z (a) (b) ␲(2px, 2px) ␲(2py, 2py) ␴(2pz, 2pz) ␲ ␴ FIGURE 3.10 A ␴-bond is formed by the pairing of electron spins in two 2pz-orbitals on neighboring atoms. At this stage, we are ignoring the interactions of any 2px(and 2py-) orbitals that also contain unpaired electrons, because they cannot form ␴-bonds. Most of the time the bonding electron pair is found within the boundary surface shown in the bottom diagram. Notice that the nodal plane of each pz-orbital survives in the ␴-bond. FIGURE 3.11 A ␲-bond is formed when electrons in two 2p-orbitals pair and overlap side by side. The middle diagram shows the extent of the overlap, and the bottom diagram shows the corresponding boundary surface. Even though the bond has a complicated shape, with two lobes, it is occupied by one pair of electrons and counts as one bond. In this text, ␲-bonds are usually colored a shade of yellow. FIGURE 3.12 The bonding pattern in a nitrogen molecule, N2. (a) The two atoms are held together by one ␴-bond (blue) and two perpendicular ␲-bonds (yellow). (b) When the three bonds form, the two ␲-bonds merge to form a long doughnutshaped cloud surrounding the ␴-bond cloud; so the overall structure resembles a cylindrical hot dog. There are a few exceptions to the rule about double bonds: in a very few instances both bonds of a double bond are ␲-bonds. The Greek letter pi, ␲, is the equivalent of our letter p. When we imagine looking along the internuclear axis, a ␲-bond resembles a pair of electrons in a p-orbital. 3.5 Electron Promotion and the Hybridization of Orbitals When we try to apply VB theory to methane we run into difficulties. A carbon atom has the configuration [He]2s2 2px 1 2py 1 with four valence electrons (35). However, two valence electrons are already paired and only the two half-filled 2p-orbitals appear to be available for bonding. It looks as though a carbon atom should have a valence of 2 and form two perpendicular bonds, but in fact it almost always has a valence of 4 (it is commonly “tetravalent”) and in CH4 has a tetrahedral arrangement of bonds. To account for the four bonds we note that a carbon atom would have four unpaired electrons available for bonding if an electron is promoted—that is, has been relocated to a higher-energy orbital. When we promote a 2s-electron into an empty 2p-orbital, we get the configuration [He]2s1 2px 1 2py 1 2pz 1 (36). Without promotion, a carbon atom can form only two bonds; after promotion, it can form four bonds. Although it takes energy to promote an electron, the overall energy of the CH4 molecule is lower than if carbon formed only two C∫H bonds. The characteristic tetravalence of carbon is due to the small promotion energy of a carbon atom. The promotion energy is small because a 2s-electron is transferred from an orbital that it shares with another electron to an empty 2p-orbital. Although the promoted electron enters an orbital of higher energy, it experiences less repulsion from other electrons than before it was promoted. As a result, only a small energy is needed to promote the electron. Nitrogen, carbon’s neighbor, cannot use promotion to increase the number of bonds that it can form, because it has no empty p-orbitals (37). The same is true of oxygen and fluorine. Promotion of an electron is possible if the overall change, taking account of all contributions to the energy and especially the greater number of bonds that can thereby be formed, is toward lower energy. Boron, [He]2s2 2p1 , like carbon, is an element in which promotion can lead to the formation of more bonds (three in its case), and boron does typically form three bonds. At this stage, it looks as though electron promotion should result in two different types of bonds in methane, one bond from the overlap of a hydrogen 1s-orbital and a carbon 2s-orbital, and three more bonds from the overlap of hydrogen 1sorbitals with each of the three carbon 2p-orbitals. The overlap with the 2p-orbitals should result in three ␴-bonds at 90Њ to one another. However, this arrangement is inconsistent with the known tetrahedral structure of methane with four equivalent bonds. To improve our model we note that s- and p-orbitals are waves of electron density centered on the nucleus of an atom. We imagine that the four orbitals interfere with one another and produce new patterns where they intersect, like waves in water. Where the wavefunctions are all positive or all negative, the amplitudes are increased by this interference; where the wavefunctions have opposite signs, the overall amplitude is reduced and might even be canceled completely. As a result, the interference between the atomic orbitals results in new patterns. These new patterns are called hybrid orbitals. Each of the four hybrid orbitals, designated hi, is formed from a linear combination of the four atomic orbitals (note that these orbitals are not normalized; see Exercises 3.47 and 3.48): h1 ϭ s ϩ px ϩ py ϩ pz h2 ϭ s Ϫ px Ϫ py ϩ pz h3 ϭ s Ϫ px ϩ py Ϫ pz h4 ϭ s ϩ px Ϫ py Ϫ pz For instance, in h1 the s- and p-orbitals all have their usual signs and their amplitudes add together where they are all positive. In h2, however, the signs of px and py are reversed, and so the resulting interference pattern is different. The four hybrid orbitals that we have constructed differ only in their orientation, with one pointing toward each corner of a tetrahedron (Fig. 3.13); in all other respects, they are identical. These four hybrid orbitals are called sp3 hybrids because they are formed from one s-orbital and three p-orbitals. In an orbital-energy diagram, we represent the hybridization as the formation of four orbitals of equal energy intermediate between the energies of the s- and p-orbitals from which they are constructed (38). The hybrids are colored green to remind us that they are a blend of (blue) s-orbitals and 3.5 ELECTRON PROMOTION AND THE HYBRIDIZATION OF ORBITALS 107 C2s C2p Carbon, [He]2s2 2px 12py 135 C2s C2p Carbon, [He]2s1 2px 12py 12pz 136 N2s N2p Nitrogen, [He]2s2 2px 12py 12pz 137 FIGURE 3.13 These contours indicate the amplitude of the sp3 hybrid orbital wavefunction in a plane that bisects it and passes through the nucleus. The colors indicate the variation of electron density in the orbital: regions of high electron density are red and regions of low electron density blue. Each sp3 hybrid orbital points toward the corner of a tetrahedron. C2sp3 sp3 hybridized carbon38 Carbon monoxide, CO, is the only common exception to the tetravalence of carbon. Animation 3.13 (yellow) p-orbitals. An sp3 hybrid orbital has two lobes, but one lobe extends farther than those of the contributing p-orbitals and the other lobe is shortened. The fact that hybrid orbitals have their amplitudes concentrated on one side of the nucleus allows them to overlap more effectively with other orbitals, and as a result the bonds that they form are stronger than in the absence of hybridization. We are now ready to account for the bonding in methane. In the promoted, hybridized atom each of the electrons in the four sp3 hybrid orbitals can pair with an electron in a hydrogen 1s-orbital. Their overlapping orbitals form four ␴-bonds that point toward the corners of a tetrahedron (Fig. 3.14). The valence-bond description is now consistent with experimental data on molecular geometry. When there is more than one “central” atom in a molecule, we concentrate on each atom in turn and match the hybridization of each atom to the shape at that atom predicted by VSEPR. For example, in ethane, C2H6 (39), the two carbon atoms are both “central” atoms. According to the VSEPR model, the four electron pairs around each carbon atom take up a tetrahedral arrangement. This arrangement suggests the same sp3 hybridization of the carbon atoms as in methane (see Fig. 3.14). Each C atom has one unpaired electron in each of its four sp3 hybrid orbitals and can therefore form four ␴-bonds that point toward the corners of a regular tetrahedron. The C∫C bond is formed by spin-pairing of the electrons in one sp3 hybrid orbital of each C atom. We label this bond ␴(C2sp3 ,C2sp3 ) to show its composition: C2sp3 denotes an sp3 hybrid orbital composed of 2s- and 2p-orbitals on a carbon atom, and the parentheses show which orbitals on each atom overlap (Fig. 3.15). Each C∫H bond is formed by spinpairing of an electron in one of the remaining sp3 hybrid orbitals with an electron in a 1s-orbital of an H atom (denoted H1s). These bonds are denoted ␴(C2sp3 ,H1s). We can extend these ideas to molecules, such as ammonia, that have a lone pair of electrons on the central atom. According to the VSEPR model, the four electron pairs in NH3 take up a tetrahedral electron arrangement, so we describe the nitrogen atom in terms of four sp3 hybrid orbitals. Because nitrogen has five valence electrons, one of these hybrid orbitals is already doubly occupied (40). The three unpaired electrons in the remaining sp3 hybrid orbitals pair with the 1s-electrons of the three hydrogen atoms to form three N∫H ␴-bonds. Whenever an atom in a molecule has a tetrahedral electron arrangement, we say that it is sp3 hybridized. ␴(Csp3, H1s) ␴(Csp3, Csp3) C H H H C H H H Ethane, CH3CH339 FIGURE 3.15 The valence-bond description of bonding in an ethane molecule, C2H6. The boundary surfaces of only two of the bonds are shown. Each pair of neighboring atoms is linked by a ␴-bond formed by the pairing of electrons in either H1sorbitals or C2sp3 hybrid orbitals. All the bond angles are close to 109.5Њ (the tetrahedral angle). H1sN2sp3 Ammonia, NH340 The promotion of electrons will occur if, overall, it leads to a lowering of energy by permitting the formation of more bonds. Hybrid orbitals are constructed on an atom to reproduce the electron arrangement characteristic of the experimentally determined shape of a molecule. 3.6 Other Common Types of Hybridization We use different hybridization schemes to describe other arrangements of electron pairs (Fig. 3.16). For example, to explain a trigonal planar electron arrangement, like that in BF3 and each carbon atom in ethene, we mix one s-orbital with two p-orbitals and so produce three sp2 hybrid orbitals: h1 ϭ s ϩ 21/2 py h2 ϭ s ϩ 1/2 px Ϫ 1/2 py h3 ϭ s Ϫ 1/2 px Ϫ 1/2 py These identical orbitals (which are not normalized in these expressions) all lie in the same plane and point toward the corners of an equilateral triangle. A1 2 BA3 2 B A1 2 BA3 2 B FIGURE 3.14 Each C∫H bond in methane is formed by the pairing of an electron in a hydrogen 1s-orbital and an electron in one of the four sp3 hybrid orbitals of carbon. Therefore, valence-bond theory predicts four equivalent ␴-bonds in a tetrahedral arrangement, which is consistent with experimental results. The sp3 orbital is shown in both contour form (see Fig. 3.13) and as a boundary surface. Animation 3.14 Animation 3.15 A linear arrangement of electron pairs requires two hybrid orbitals, and so we mix an s-orbital with a p-orbital to obtain two sp hybrid orbitals: h1 ϭ s ϩ p h2 ϭ s Ϫ p These two (unnormalized) sp hybrid orbitals point away from each other at 180Њ and result in a linear molecule. This is the arrangement we see in CO2. Self-Test 3.7A Suggest a structure in terms of hybrid orbitals for BF3. [Answer: Three ␴-bonds formed from F2pz-orbitals and B2sp2 hybrids in a trigonal planar arrangement] Self-Test 3.7B Suggest a structure in terms of hybrid orbitals for each carbon atom in ethyne, C2H2. Some of the elements in Period 3 and later periods can accommodate five or more electron pairs, as in PCl5. We can devise a hybridization scheme to describe these types of bonds by using the d-orbitals of the central atom. To account for a trigonal bipyramidal arrangement of five electron pairs, we use one d-orbital as well as all the valence s- and p-orbitals of the atom. The resulting five orbitals are called sp3 d hybrid orbitals (Fig. 3.17). We need six orbitals to accommodate six electron pairs around an atom in an octahedral arrangement, as in SF6 and XeF4, and so we need to use two d-orbitals in addition to the valence s- and p-orbitals to form six sp3 d2 hybrid orbitals (Fig. 3.18). These identical orbitals point toward the six corners of a regular octahedron. Table 3.2 summarizes the relation between electron arrangement and hybridization type. No matter how many atomic orbitals we mix together, the number of hybrid orbitals is always the same as the number of atomic orbitals with which we started: N atomic orbitals always produce N hybrid orbitals. So far, we have not considered whether terminal atoms, such as the Cl atoms in PCl5, are hybridized. Because they are bonded to only one other atom, we cannot use bond angles to predict a hybridization scheme. However, spectroscopic data and calculations suggest that both s- and p-orbitals of terminal atoms take part in bond formation, and 3.6 OTHER COMMON TYPES OF HYBRIDIZATION 109 (a) (b) (c) sp2 sp3sp FIGURE 3.16 Three common hybridization schemes shown as outlines of the amplitude of the wavefunction and in terms of the orientations of the hybrid orbitals. (a) An s-orbital and a p-orbital hybridize into two sp hybrid orbitals that point in opposite directions, forming a linear molecular shape. (b) An s-orbital and two p-orbitals can blend together to give three sp2 hybrid orbitals that point to the corners of an equilateral triangle. (c) An s-orbital and three p-orbitals can blend together to give four sp3 hybrid orbitals that point to the corners of a tetrahedron. sp3d FIGURE 3.17 One of the five sp3 d hybrid orbitals, and their five directions, that account for a trigonal bipyramidal arrangement of electron pairs. The sp3 d hybridization scheme can be applied only when d-orbitals are available on the central atom. sp3d2 FIGURE 3.18 One of the six sp3 d2 hybrid orbitals, and their six directions, that may be formed when d-orbitals are available and we need to account for an octahedral arrangement of electron pairs. TABLE 3.2 Hybridization and Molecular Shape* Electron Number of Hybridization of Number of hybrid arrangement atomic orbitals the central atom orbitals linear 2 sp 2 trigonal planar 3 sp2 3 tetrahedral 4 sp3 4 trigonal bipyramidal 5 sp3 d 5 octahedral 6 sp3 d2 6 *Other combinations of s-, p-, and d-orbitals can give rise to the same or different shapes, but the combinations in the table are the most common. Animation 3.16 Animation 3.17 Animation 3.18 SOLVE 110 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE Draw the Lewis structure. P .. .. F .. .. .. F .. .. .. F .. .. .. F .. .. .. F .. Determine the electron arrangement about the central atom. Trigonal bipyramidal Identify the molecular shape. Trigonal bipyramidal Select the same number of atomic orbitals as there are hybrid orbitals. 5 Construct the hybrid orbitals, starting with the s-orbital, and proceeding to the p- and d-orbitals. sp3 d Evaluate As predicted, a d-orbital is required to accommodate all the valence electrons. Self-Test 3.8A Describe (a) the electron arrangement, (b) the molecular shape, and (c) the hybridization of the central chlorine atom in chlorine trifluoride. [Answer: (a) Trigonal bipyramidal; (b) T-shaped; (c) sp3 d] Self-Test 3.8B Describe (a) the electron arrangement, (b) the molecular shape, and (c) the hybridization of the central atom in BrF4 – . A hybridization scheme is adopted to match the electron arrangement of the molecule. Valence-shell expansion requires the use of d-orbitals. EXAMPLE 3.5 Assigning a hybridization scheme What is the hybridization of phosphorus in PF5? Anticipate To form five bonds we need five hybrid orbitals, which suggests that a d-orbital should be involved as well as the four s- and p-orbitals of a shell. PLAN Choose the hybridization scheme to match the electron arrangement predicted by the VSEPR model, using N atomic orbitals to form N hybrid orbitals. so it is reasonable to suppose that their orbitals are hybridized. The simplest model is to suppose that the three lone pairs and the bonding pair are arranged tetrahedrally and therefore that the chlorine atoms bond to the phosphorus atom by using sp3 hybrid orbitals. 3.7 Characteristics of Multiple Bonds Atoms of the Period 2 elements C, N, and O readily form double bonds with one another, with themselves, and (especially for oxygen) with atoms of elements in later periods. However, double bonds are rarely found between atoms of elements in Period 3 and later periods, because the atoms are so large and bond lengths consequently so great that it is difficult for their p-orbitals to take part in effective side-by-side overlap. To describe carbon–carbon double bonds, we use the pattern provided by ethene, CH2¢CH2. We know from experimental data that all six atoms in ethene lie in the same plane, with bond angles very close to 120Њ. Bond angles of 120Њ suggest a trigonal planar electron arrangement and sp2 hybridization for each C atom (41). Each of the three hybrid orbitals on the C atom has one electron available for bonding; the fourth valence electron of each C atom occupies the unhybridized 2p-orbital, which is perpendicular to the plane formed by the hybrids. The two carbon atoms form a ␴-bond by overlap of an sp2 hybrid orbital on each atom. The H atoms form ␴-bonds with the remaining lobes of the sp2 hybrids. The electrons in the two unhybridized 2p-orbitals form a ␲-bond through side-by-side overlap. Figure 3.19 shows how the electron density in the ␲-bond lies above and below the axis of the C∫C ␴-bond. In benzene, the C atoms and their attached H atoms all lie in the same plane, with the C atoms forming a hexagonal ring. To describe the bonding in the Kekulé structures of benzene (Section 2.8) in terms of VB theory, we need hybrid orbitals that match the 120Њ bond angles of the hexagonal ring. Therefore, we take each carbon atom to be sp2 hybridized, as in ethene (Fig. 3.20). The three hybrid orbitals each have one electron, with the fourth valence electron in an unhybridized 2p-orbital perpendicular to the plane of the hybrids. The sp2 hybrid orbitals on each carbon atom overlap with those of their neighbors, which results in six ␴-bonds between them. The remaining sp2 hybrid orbital on each carbon atom overlaps with a hydrogen 1s-orbital, resulting in six carbon–hydrogen bonds. Finally, the side-by-side overlap of the 2p-orbitals on each C atom results in a ␲-bond between each carbon atom and one of its neighbors (Fig. 3.21). The resulting pattern of ␲-bonds matches either of the two Kekulé structures, and the overall structure is a resonance hybrid of the two. This resonance ensures that the electrons in the ␲-bonds are spread around the entire ring (Fig. 3.22). The presence of a carbon–carbon double bond strongly influences the shape of a molecule because it prevents one part of a molecule from rotating relative to another part. The double bond of ethene, for example, holds the entire molecule flat. Figure 3.19 shows that the two 2p-orbitals overlap best if the two CH2 groups lie in the same plane. In order for the molecule to rotate about the double bond, the ␲-bond would need to break and reform. 3.7 CHARACTERISTICS OF MULTIPLE BONDS 111 ␲(C2p, C2p) ␴(Csp2, H1s) ␴(Csp2, Csp2) Csp2 C2p sp2 hybridized carbon41 FIGURE 3.19 A view of the bonding pattern in ethene (ethylene), showing the framework of ␴-bonds and the single ␲-bond formed by side-to-side overlap of unhybridized C2p-orbitals. The double bond is resistant to twisting because twisting would reduce the overlap between the two C2porbitals and weaken the ␲-bond. Here the bonding structure is superimposed over a ball-and-stick model. 120Њ ␴(Csp2, H1s) ␴(Csp2, Csp2)␴(Csp2, Csp2) FIGURE 3.20 The framework of ␴-bonds in benzene: each carbon atom is sp2 hybridized, and the array of hybrid orbitals matches the bond angles (of 120Њ) in the hexagonal molecule. The bonds around only one carbon atom are labeled; all the others are the same. FIGURE 3.21 Unhybridized carbon 2p-orbitals can form a ␲-bond with either of their immediate neighbors. Two arrangements are possible, each one corresponding to a different Kekulé structure. One Kekulé structure and the corresponding ␲-bonds are shown here. FIGURE 3.22 As a result of resonance between two structures like the one shown in Fig. 3.21 (corresponding to resonance of the two Kekulé structures), the ␲-electrons form a double doughnut-shaped cloud above and below the plane of the ring. Animation 3.19 Animation 3.22 Double bonds and their influence on molecular shape are vitally important for living organisms. For instance, they enable you to read these words. Vision depends on the shape of the molecule retinal in the retina of the eye. cis-Retinal is held rigid by its double bonds (42). When light enters the eye, it excites an electron out of the ␲-bond marked by the arrow. The double bond is now weaker, and the molecule is free to rotate about the remaining ␴-bond. When the excited electron falls back, the molecule has rotated about the double bond and is now trapped in its trans shape (43). This change in shape triggers a signal along the optic nerve and is interpreted by the brain as the sensation of vision. Now consider the alkynes, hydrocarbons with carbon–carbon triple bonds. The Lewis structure of the linear molecule ethyne (acetylene) is H∫CΩC∫H. A linear molecule has two equivalent orbitals at 180Њ from each other: this is sp hybridization. Each C atom has one electron in each of its two sp hybrid orbitals and one electron in each of its two perpendicular unhybridized 2p-orbitals (44). The electrons in the sp hybrid orbitals on the two carbon atoms pair and form a carbon–carbon ␴-bond. The electrons in the remaining sp hybrid orbitals pair with hydrogen 1s-electrons to form two carbon–hydrogen ␴-bonds. The electrons in the two perpendicular sets of 2p-orbitals pair with a side-by-side overlap, forming two ␲-bonds at 90Њ to each other. As in the N2 molecule, the electron density in the ␲-bonds forms a cylinder about the C∫C bond axis. The resulting bonding pattern is shown in Fig. 3.23. Thinking point: What shape do the atoms connected to two triply bonded carbon atoms impose on a molecule that contains such a group? We can now understand why a carbon–carbon double bond is stronger than one carbon–carbon single bond but weaker than the sum of two single bonds (Section 2.15), and why a carbon–carbon triple bond is weaker than the sum of three carbon–carbon single bonds. Recall that a single CßC bond is a ␴-bond, but the additional bonds in a multiple bond are ␲-bonds. One reason for the difference in strength is that because the p-orbitals overlap in a side-by-side fashion, the overlap in a ␲-bond is smaller and weaker than the end-to-end overlap that results in a ␴-bond. The side-by-side overlap also explains why double bonds are rarely formed between elements in periods later than Period 3. The atoms are too large for the overlap to be strong enough to form a bond. 112 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 42 cis-Retinal 43 trans-Retinal C2p C2sp sp hybridized carbon44 (b) (a) ␲(C2px, C2px) ␲(C2␲y, C2py) ␴(Csp, Csp) FIGURE 3.23 The pattern of bonding in ethyne (acetylene). The carbon atoms are sp hybridized, and the two remaining p-orbitals on each C atom form two ␲-bonds. (a) The resulting pattern is very similar to that for N2 (Fig. 3.12), but C∫H groups replace the two N atoms. (b) Although the two ␲-orbitals are built from p-orbitals, the overall electron density turns out to have cylindrical symmetry. EXAMPLE 3.6 Accounting for the structure of a molecule with multiple bonds Account for the structure of a formic acid molecule, HCOOH, in terms of hybrid orbitals, bond angles, and ␴- and ␲-bonds. The C atom is attached to an H atom, a terminal O atom, and an ∫OH group. Anticipate Because the C atom is attached to three atoms, we should anticipate that its hybridization scheme is sp2 and that one unhybridized p-orbital remains. PLAN Use the VSEPR model to identify the shape of the molecule and then assign the hybridization consistent with that shape. All single bonds are ␴-bonds and multiple bonds are composed of a ␴-bond and one or more ␲-bonds. Finally, we form ␴- and ␲-bonds by allowing the orbitals to overlap. SOLVE Draw the Lewis structure. H ¬ C Å å å å ˚ • O ¬ H O Use the VSEPR model to identify the electron arrangements around the central C and O atoms. The C atom is bonded to 3 atoms and has no lone pairs; therefore, it has a trigonal planar arrangement. The O atom in the ∫OH group has two single bonds and two lone pairs; thus, it has a tetrahedral electron arrangement. C O Animation 3.23 Evaluate As predicted, the hybridization scheme is sp2 , leaving one unhybridized p-orbital. Self-Test 3.9A Describe the structure of the carbon suboxide molecule, C3O2, in terms of hybrid orbitals, bond angles, and ␴- and ␲-bonds. The atoms lie in the order OCCCO. [Answer: Linear; bond angles all 180Њ; each C atom is sp hybridized and forms one ␴-bond and one ␲-bond to each adjacent C or O atom.] Self-Test 3.9B Describe the structure of the propene molecule, CH3∫CH¢CH2, in terms of hybrid orbitals, bond angles, and ␴- and ␲-bonds. Multiple bonds are formed when an atom forms a ␴-bond by using an sp or sp2 hybrid orbital and one or more ␲-bonds by using unhybridized p-orbitals. The side-by-side overlap that forms a ␲-bond makes a molecule resistant to twisting, results in bonds weaker than ␴-bonds, and prevents atoms with large radii from forming multiple bonds. MOLECULAR ORBITAL THEORY Lewis’s theory of the chemical bond was brilliant, but it was little more than guesswork inspired by insight. He had no way of knowing why an electron pair was so important for the formation of covalent bonds. Valence-bond theory explained the importance of the electron pair in terms of spin-pairing but it could not explain the properties of some molecules. Molecular orbital theory, which is also based on quantum mechanics and was introduced in the late 1920s by Mulliken and Hund, has proved to be the most successful theory of the chemical bond: it overcomes all the deficiencies of Lewis’s theory and is easier to use in calculations than valence-bond theory. 3.8 The Limitations of Lewis’s Theory In Lewis’s approach and valence-bond theory the oxygen molecule is somewhat of a puzzle. To appreciate the puzzle, we need to know that substances can be classified according to their behavior in a magnetic field: a diamagnetic substance is one that tends to move out of a magnetic field and a paramagnetic substance is one that tends to move into a magnetic field. Diamagnetism indicates that all the electrons in a molecule are paired; paramagnetism indicates that a molecule possesses unpaired electrons (Box 3.2). According to both Lewis’s approach and valence-bond theory, O2 should be diamagnetic. In fact, it is found to be paramagnetic (Fig. 3.24). Lewis’s theory also fails to account for the compound diborane, B2H6, a colorless gas that bursts into flame on contact with air. The problem is that diborane has only 12 valence electrons (three from each B atom, one from each H atom); but, for a Lewis structure, it needs at least seven bonds, and therefore 14 electrons, to bind the eight atoms together! Diborane is an example of an electron-deficient compound, a compound with too few valence electrons to be assigned a valid Lewis structure. Valence-bond theory can account for the structures of electron-deficient compounds in terms of resonance, but the explanation is not straightforward. 3.8 THE LIMITATIONS OF LEWIS’S THEORY 113 Identify the hybridization and bond angles. C atom: trigonal planar, so 120Њ bond angle; sp2 hybridized. O atom of the ∫OH group: tetrahedral, so bond angles close to 109.5Њ; sp3 hybridized. 120Њ 109.5Њ Form the bonds. A ␲-bond forms by the overlap of the p-orbital on the C atom with the p-orbital on the terminal O atom. H1s H1s Csp2 Osp2 Osp3 ␲ ␴ ␴ ␴ ␴ FIGURE 3.24 The paramagnetic properties of oxygen are evident when liquid oxygen is poured between the poles of a magnet. The liquid sticks to the magnet instead of flowing past it. The development of molecular orbital theory (MO theory) in the late 1920s overcame these difficulties. It explains why the electron pair is so important for bond formation and predicts that oxygen is paramagnetic. It accommodates electron-deficient compounds such as the boranes just as naturally as it deals with methane and water. Furthermore, molecular orbital theory can be extended to account for the structures and properties of metals and semiconductors. It can also be used to account for the electronic spectra of molecules, which arise when an electron makes a transition from an occupied molecular orbital to a vacant molecular orbital. The VB and MO theories are both procedures for constructing approximations to the wavefunctions of electrons, but they construct these approximations in different ways. The language of valence-bond theory, in which the focus is on bonds between pairs of atoms, pervades the whole of organic chemistry, where chemists speak of ␴- and ␲-bonds between particular pairs of atoms, hybridization, and resonance. However, molecular orbital theory, in which the focus is on electrons that spread throughout the nuclear framework and bind the entire collection of atoms together, has been developed far more extensively than valence-bond theory and is the procedure almost universally used in calculations of molecular structures, like those described in Major Technique 5 following Chapter 14. Unlike Lewis’s theory, molecular orbital theory can account for the paramagnetism of oxygen and the existence of electron-deficient compounds. 114 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE HOW DO WE KNOW . . . THAT ELECTRONS ARE NOT PAIRED?BOX 3.2 (a) In a magnetic field, the spins of electrons in both paramagnetic and ferromagnetic substances are aligned (ferromagnetism is described in Chapter 6). (b) The spins of electrons in a paramagnetic substance return to a random orientation after an applied magnetic field is removed. However, the spins of electrons in a ferromagnetic substance remain aligned after a magnetic field is removed. Most common materials are diamagnetic. The tendency of a diamagnetic substance to move out of a magnetic field can be detected by hanging a long, thin sample from the pan of a balance and letting it lie between the poles of an electromagnet. This arrangement, which was once the primary technique used to measure the magnetic properties of samples, is called a Gouy balance. When the electromagnet is turned on, a diamagnetic sample tends to move upward, out of the field, so it appears to weigh less than in the absence of the field. The diamagnetism arises from the effect of the magnetic field on the electrons in the molecule: the field forces the electrons to circulate through the nuclear framework. Because electrons are charged particles, this circulation corresponds to an electric current circulating within the molecule. That current gives rise to its own magnetic field, which opposes the applied field. The sample tends to move out of the field so as to minimize this opposing field. Compounds with unpaired electrons are paramagnetic. They tend to move into a magnetic field and can be identified because they seem to weigh more in a Gouy balance when a magnetic field is applied than when it is absent. Paramagnetism arises from the electron spins, which behave like tiny bar magnets that tend to line up with the applied field. The more that can line up in this way, the greater the lowering of energy and the heavier the sample appears to weigh. Oxygen is a paramagnetic substance because it has two unpaired electrons: this property is used to detect the concentration of oxygen in incubators. All radicals are paramagnetic. Many compounds of the d-block elements are paramagnetic because they have various numbers of unpaired d-electrons. The modern approach to measuring magnetic properties is to use a superconducting quantum interference device (a SQUID), which is highly sensitive to small magnetic fields and can make very precise measurements on small samples. (b) (a) A Gouy balance is used to observe the magnetic character of a sample by detecting the extent to which it is drawn into (paramagnetic substances) or driven out of (diamagnetic substances) a magnetic field. 3.9 Molecular Orbitals In molecular orbital theory, electrons occupy orbitals called molecular orbitals that spread throughout the entire molecule. In other words, whereas in the Lewis and valence-bond models of molecular structure the electrons are localized on atoms or between pairs of atoms, in molecular orbital theory all valence electrons are delocalized over the whole molecule, not confined to individual bonds. In this section we start, as in valence-bond theory, with a simple molecule, H2, and in the following sections extend the same principles to more complex molecules and solids. In every case, molecular orbitals are built from atomic orbitals belonging to the valence shells of the atoms in the molecule. For example, a molecular orbital for H2 is ␺ ϭ ␺A1s ϩ ␺B1s (1)* where ␺A1s is a 1s-orbital centered on one atom (A) and ␺B1s is a 1s-orbital centered on the other atom (B). The technical terms for adding together wavefunctions (sometimes with different weighting coefficients) is called “forming a linear combination” and the molecular orbital in Eq. 1 is called a linear combination of atomic orbitals (LCAO). Any molecular orbital formed from a linear combination of atomic orbitals on different atoms is called an LCAO-MO. Note that at this stage there are no electrons in the molecular orbital: a molecular orbital is just a combination—in this case, a simple sum—of wavefunctions. Like atomic orbitals, the molecular orbital in Eq. 1 is a well-defined mathematical function that can be evaluated at each point in space and pictured in three dimensions. The LCAO-MO in Eq. 1 turns out to have a lower energy than either of the atomic orbitals used in its construction. The two atomic orbitals are like waves centered on different nuclei. Between the nuclei, the waves interfere constructively with each other in the sense that the total amplitude of the wavefunction is increased where they overlap (Fig. 3.25). The increased amplitude in the internuclear region means that there is an enhanced probability density between the nuclei. Any electron that occupies that molecular orbital, therefore, is attracted to both nuclei and so has a lower energy than when it is confined to an atomic orbital on one atom. Moreover, because the electron now occupies a greater volume than when it is confined to a single atom, it also has a lower kinetic energy, just like a particle confined to a bigger box (Section 1.7). A combination of atomic orbitals that results in an overall lowering of energy, like that in Eq. 1, is called a bonding orbital. An important feature of MO theory is that N molecular orbitals can be constructed from N atomic orbitals. In molecular hydrogen, where we are building LCAO-MOs from two atomic orbitals, we expect two molecular orbitals. In the second molecular orbital, the two atomic orbitals interfere destructively where they overlap. This orbital has the form ␺ ϭ ␺A1s Ϫ ␺B1s (2)* The negative sign indicates that the amplitude of ␺B1s subtracts from the amplitude of ␺A1s where they overlap (Fig. 3.26), and there is a nodal surface where the atomic orbitals cancel completely. In a hydrogen molecule, the nodal surface is a plane that lies halfway between the two nuclei. If an electron occupies this orbital, it is largely excluded from the internuclear region and consequently has a higher energy than when it occupies one of the atomic orbitals alone. A combination of atomic orbitals that results in an overall raising of energy, like that in Eq. 2, is called an antibonding orbital. A note on good practice: What the negative sign in Eq. 2 really represents is that we reverse the sign of ␺B1s everywhere (so a peak becomes a trough and vice versa), then add the resulting wavefunction to ␺A1s. The relative energies of the original atomic orbitals and the bonding and antibonding molecular orbitals are shown in a molecular orbital energy-level diagram like that in Fig. 3.27. The increased energy of an antibonding orbital is about equal to or a little greater than the lowering of the energy of the corresponding bonding orbital. Molecular orbitals are built from linear combinations of atomic orbitals: when atomic orbitals interfere constructively, they give rise to bonding orbitals; when they interfere destructively, they give rise to antibonding orbitals. N atomic orbitals combine to give N molecular orbitals. 3.9 MOLECULAR ORBITALS 115 ϩ ϩ FIGURE 3.25 When two 1s-orbitals overlap in the same region of space in such a way that their wavefunctions have the same signs in that region, their wavefunctions (red lines) interfere constructively and give rise to a region of enhanced amplitude between the two nuclei (blue line). Node ϩ Ϫ FIGURE 3.26 When two 1s-orbitals overlap in the same region of space in such a way that their wavefunctions have opposite signs, the wavefunctions interfere destructively and give rise to a region of diminished amplitude and a node between the two nuclei (blue line). Energy Bonding Antibonding Atomic orbital Atomic orbital Atom AtomMolecule FIGURE 3.27 A molecular orbital energy-level diagram for the bonding and antibonding molecular orbitals that can be built from two s-orbitals. Different signs of the s-orbitals (reflecting how they are combined together to form the molecular orbital) are depicted by the different shades of blue. 116 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 3.10 Electron Configurations of Diatomic Molecules In the molecular orbital description of homonuclear diatomic molecules, we first build all possible molecular orbitals from the available valence-shell atomic orbitals. Then we accommodate the valence electrons in molecular orbitals by using the same procedure used in the building-up principle for atoms (Section 1.13). That is, 1 Electrons are accommodated in the lowest-energy molecular orbital, then in orbitals of increasingly higher energy. 2 According to the Pauli exclusion principle, each molecular orbital can accommodate up to two electrons. If two electrons are present in one orbital, they must be paired. 3 If more than one molecular orbital of the same energy is available, the electrons enter them singly and adopt parallel spins (Hund’s rule). We shall illustrate these rules first with H2 and then with other diatomic molecules. The same principles apply to polyatomic molecules, but their molecular orbitals are more complicated and their energies are harder to predict. Mathematical software for calculating the molecular orbitals and their energies is now widely available, and we shall show some of the results that it provides. In H2, two 1s-orbitals (one on each atom) merge to form two molecular orbitals. We denote the bonding orbital ␴1s and the antibonding orbital ␴1s*. The 1s in the notation shows the atomic orbitals from which the molecular orbitals are formed. The ␴ indicates that we have built a “␴-orbital,” a sausage-shaped orbital. More formally, a ␴-orbital is a molecular orbital that has cylindrical symmetry and no nodal plane that contains the internuclear axis. Two electrons, one from each H atom, are available. Both occupy the bonding orbital (the lower-energy orbital) and result in the configuration ␴1s 2 (Fig. 3.28). Because only the bonding orbital is occupied, the energy of the molecule is lower than that of the separate atoms, and hydrogen exists as H2 molecules. Two electrons in a ␴-orbital form a ␴-bond, like the ␴-bond in VB theory. However, even a single electron may be able to hold two atoms together with about half the strength of an electron pair, and so—in contrast to Lewis’s theory and VB theory—an electron pair is not required for a bond. A pair is just the maximum number of electrons allowed by the Pauli exclusion principle to occupy any one molecular orbital. Even a single electron can act to bond atoms together. Now we extend these ideas to other homonuclear diatomic molecules of Period 2 elements. The first step is to build up the molecular orbital energy-level diagram from the valence-shell atomic orbitals provided by the atoms. Because Period 2 atoms have 2s- and 2p-orbitals in their valence shells, we form molecular orbitals from the overlap of these atomic orbitals. There are a total of eight atomic orbitals (one 2s- and three 2p-orbitals on each atom); so we can expect to build eight molecular orbitals. The two 2s-orbitals overlap to form two ␴-orbitals, one bonding (the ␴2s-orbital) and the other antibonding (the ␴2s*-orbital); these orbitals resemble the ␴1s- and ␴1s*-orbitals in H2. The six 2p-orbitals (three on each neighboring atom) form the remaining six molecular orbitals. They can overlap in two distinct ways. The two 2p-orbitals that are directed toward each other along the internuclear axis form a bonding ␴-orbital (␴2p) and an antibonding ␴*-orbital (␴2p*) where they overlap (Fig. 3.29). The two 2p-orbitals on each atom that are perpendicular to the internuclear axis overlap side by side to form bonding and antibonding “␲-orbitals” (Fig. 3.30). A ␲-orbital is a molecular orbital with one nodal plane that contains the internuclear axis. There are two 2p-orbitals on each atom perpendicular to the internuclear axis, and so four molecular orbitals—two bonding ␲2p-orbitals and two antibonding ␲2p*-orbitals—are formed by their overlap. Detailed calculation shows that there are some small differences in the order of energy levels from molecule to molecule (Box 3.3). Figure 3.31 shows the order for the Period 2 elements, with the exception of O2 and F2, which lie in the order shown in Fig. 3.32. The order of energy levels is easy to explain for these two molecules. First, because each O and F atom has many electrons that contribute to shielding, the 2s-orbitals lie well below the 2p-orbitals and we can think of building ␴-orbitals from the two sets of atomic orbitals separately. However, because the atoms of elements earlier in the period have fewer electrons, their 2s- and 2p-orbitals have more similar energies than in O and F. H1sH1s ␴1s* ␴1s Energy FIGURE 3.28 The two electrons in an H2 molecule occupy the lower-energy (bonding) molecular orbital and result in a stable molecule. ϩ ϩ ϩ Ϫ ϩϪ Ϫ Ϫ␴2p* ␴2p FIGURE 3.29 Two p-orbitals can overlap to give bonding (lower) and antibonding (upper) ␴-orbitals. Note that the antibonding combination has a node between the two nuclei. Both ␴-orbitals have nodes passing through the nuclei, but no nodes along the axis of the bond. ϩ ϩ ϩ Ϫ ϩ Ϫ Ϫ Ϫ ␲2p* ␲2p FIGURE 3.30 Two p-orbitals can overlap side by side to give bonding (below) and antibonding (above) ␲-orbitals. Note that the latter has a nodal plane between the two nuclei. Both orbitals have a nodal plane through the two nuclei and look like p-orbitals when viewed along the internuclear axis. 3.10 ELECTRON CONFIGURATIONS OF DIATOMIC MOLECULES 117 As a result, it is no longer possible to think of a ␴-orbital as being formed from either the 2s-orbitals or the 2pz-orbitals separately, and all four of these orbitals must be used to build the four ␴-orbitals. It is then hard to predict without detailed calculation where these four orbitals will lie, and it turns out that they in fact lie where we show them in Fig. 3.31. Once we know what molecular orbitals are available, we can derive the ground-state electron configurations of the molecules by using the building-up principle. For example, consider N2. Because nitrogen belongs to Group 15/V, each atom supplies five valence electrons. A total of ten electrons must therefore be assigned to the eight molecular orbitals shown in Fig. 3.31. Two fill the ␴2s-orbital. The next two fill the ␴2s*-orbital. Next in line for occupation are the two ␲2p-orbitals, which can hold a total of four electrons. The last two electrons then enter the ␴2p-orbital. The ground configuration is therefore N2: ␴2s 2 ␴2s*2 ␲2p 4 ␴2p 2 This configuration is shown as (45), where the boxes represent molecular orbitals. The energies of orbitals are calculated today by solving the Schrödinger equation with computer software. The commercial software available is now so sophisticated that this approach can be as easy as typing in the name of the molecule or drawing it on screen. But these values are theoretical. How do we determine orbital energies experimentally? One of the most direct methods is photoelectron spectroscopy (PES), an adaptation of the photoelectric effect (Section 1.4). A photoelectron spectrometer contains a source of high-frequency, short-wavelength radiation. Ultraviolet radiation is used most often for molecules, but x-rays are used to explore orbitals buried deeply inside solids. Photons in both frequency ranges have so much energy that they can eject electrons from the molecular orbitals they occupy. Let’s suppose that the frequency of the radiation is ␯ (nu), so each photon has an energy h␯. An electron occupying a molecular orbital lies at an energy Eorbital below the zero of energy (corresponding to an electron far removed from the molecule). A photon that collides with the electron can eject it from the molecule if the photon can supply at least that much energy. The remaining energy of the photon, h␯ – Eorbital, then appears as the kinetic energy, Ek, of the ejected electron: h␯ Ϫ Eorbital ϭ Ek We know ␯, the frequency of the radiation being used to bombard the molecules; so, if we could measure the kinetic energy of the ejected electron, Ek, we could solve this expression to find the orbital energy, Eorbital. HOW DO WE KNOW . . . THE ENERGIES OF MOLECULAR ORBITALS?BOX 3.3 Diagram of a photoelectron spectrometer. Electrostatic analyzer Ϫ ϩ Detector Radiation source Sample chamber Electron beam Magnification 1517 13 11 Ionization energy (electronvolts) Detectorsignal The photoelectron spectrum of nitrogen (N2) has several peaks, a pattern indicating that electrons can be found in several energy levels in the molecule. Each main group of lines corresponds to the energy of a molecular orbital. The additional “fine structure” on some of the groups of lines is due to the excitation of molecular vibration when an electron is expelled. The kinetic energy of an ejected electron depends on its speed, v, because (Section A). A photoelectron spectrometer acts like a mass spectrometer in that it measures v for electrons just as a mass spectrometer can measure v for ions, as we saw in Section B. In this method, the electrons pass through a region of electric or magnetic field, which deflects their path. As the strength of the field is changed, the paths of the electrons change, too, until they fall on a detector and generate a signal. From the strength of the field required to obtain a signal, we can work out the speed of electrons ejected from a given orbital. From the speed, we can calculate the kinetic energy of the electrons and so obtain the energy of the orbital from which they came. The photoelectron spectrum of nitrogen is shown below. There are several peaks, corresponding to electrons being ejected from orbitals of different energy. A detailed analysis shows that the spectrum is a good portrayal of the qualitative structure (as depicted in 45). Ek = 1 2mev2 ␴2p ␲2p ␴2s* ␴2s Nitrogen, N245 118 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE At first sight, the molecular orbital description of N2 looks quite different from the Lewis description (:NΩN:). However, it is, in fact, very closely related. We can see their similarity by defining the bond order (b) in molecular orbital theory as the net number of bonds, allowing for the cancellation of bonds by antibonds: Bond order ϭ ϫ (number of electrons in bonding orbitals – number of electrons in antibonding orbitals) b ϭ ϫ (Ne Ϫ Ne*) (3)* Here Ne is the number of electrons in bonding molecular orbitals and Ne* is the number of electrons in antibonding molecular orbitals. This definition of bond order is the generalization of the one given in Section 2.6, where we simply counted shared pairs. In N2, there are eight electrons in bonding orbitals and two in antibonding orbitals, and so the bond order is . Because its bond order is 3, N2 effectively has three bonds between the N atoms, just as the Lewis structure suggests. 1 2(8 - 2) = 3 1 2 1 2 2s 2p 2s 2p ␴2p* ␲2p* ␴2s* ␴2s ␲2p ␴2p Energy FIGURE 3.31 A typical molecular orbital energy-level diagram for the homonuclear diatomic molecules Li2 through N2. Each box represents one molecular orbital and can accommodate up to two electrons. Energy 2s 2p2p 2s ␴2p* ␴2s* ␴2s ␲2p* ␲2p ␴2p FIGURE 3.32 The molecular orbital energy-level diagram for the homonuclear diatomic molecules on the right-hand side of Period 2, specifically O2 and F2. TOOLBOX 3.2 HOW TO DETERMINE THE ELECTRON CONFIGURATION AND BOND ORDER OF A HOMONUCLEAR DIATOMIC SPECIES CONCEPTUAL BASIS When N valence atomic orbitals overlap, they form N molecular orbitals. The ground-state electron configuration of a molecule is deduced by using the building-up principle to accommodate all the valence electrons in the available molecular orbitals. The bond order is the net number of bonds that hold the molecule together. PROCEDURE Step 1 Identify all the atomic orbitals in the valence shells, ignoring how many electrons they contain. Step 2 Use matching valence-shell atomic orbitals to build bonding and antibonding molecular orbitals and draw the resulting molecular orbital energy-level diagram (see Figs. 3.31 and 3.32). Step 3 Note the total number of electrons present in the valence shells of the two atoms. If the species is an ion, adjust the number of electrons to account for the charge. Step 4 Accommodate the electrons in the molecular orbitals according to the building-up principle. Step 5 To determine the bond order, subtract the number of electrons in antibonding orbitals from the number in bonding orbitals and divide the result by 2 (Eq. 3). This procedure is illustrated in Example 3.7. 3.10 ELECTRON CONFIGURATIONS OF DIATOMIC MOLECULES 119 EXAMPLE 3.7 Deducing the ground-state electron configuration and bond order of a diatomic molecule Deduce the ground-state electron configuration of the fluorine molecule and calculate its bond order. Anticipate Since the Lewis structure of F2 is , we should anticipate that the bond order is 1. PLAN Set up the molecular orbital-energy level diagram and use the building-up principle to accommodate the valence electrons as described in Toolbox 3.2. Then calculate the bond order from the resulting configuration. SOLVE F ¬ F ÅÅ Å Å å å 2p 2p 2s2s 2p 2p 2s2s Step 1 Identify the valence atomic orbitals. Each atom contributes a 2s-orbital and three 2p-orbitals, for a total of 8 orbitals. Step 2 Construct the molecular orbital energy-level diagram. See Fig. 3.32. 2p 2p 2s2s Step 3 Count the valence electrons. 2 ϫ 7 ϭ 14 2p 2p 2s2s Step 4 Construct the electron configuration by filling the orbitals in order of increasing energy: ␴2s 2 ␴2s*2 ␴2p 2 ␲2p 4 ␲2p*4 2p 2p 2s2s b b b a a Step 5 Determine the bond order from b = 1 2 * [(2 + 2 + 4) - (2 + 4)] = 1 b = 1 2 * (Ne - Ne*): Evaluate As expected, F2 is a singly bonded molecule, in agreement with the Lewis structure. Notice that the first ten electrons repeat the N2 configuration (apart from the change in order of the ␴2p- and ␲2p-orbitals). 120 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE Self-Test 3.10A Deduce the electron configuration and bond order of the ion C2 2– . [Answer: ␴2s 2 ␴2s*2 ␲2p 4 ␴2p 2 , b ϭ 3] Self-Test 3.10B Suggest a configuration for the O2 ϩ ion and state its bond order. We find the ground-state electron configuration of O2 by adding its twelve valence electrons (six from each atom) to the molecular orbitals shown in Fig. 3.32. The first ten electrons repeat the F2 configuration, as in Example 3.7. According to the building-up principle, the last two electrons occupy the two separate ␲2p*-orbitals and do so with parallel spins. The configuration is therefore O2: ␴2s 2 ␴2s*2 ␴2p 2 ␲2p 4 ␲2p*1 ␲2p*1 as shown in (46). This conclusion is a minor triumph for molecular orbital theory: because the last two spins are not paired, their magnetic fields do not cancel, and the molecule is predicted to be paramagnetic, exactly as observed. The bond order of O2 is The double bond in this molecule is actually a ␴-bond plus two “half ␲-bonds,” each “half bond” consisting of a pair of bonding electrons and one antibonding electron. Thinking point: Can you use molecular orbital theory to explain why fluorine is such a highly reactive gas? The ground-state electron configurations of diatomic molecules are deduced by forming molecular orbitals from all the valence-shell atomic orbitals of the two atoms and adding the valence electrons to the molecular orbitals in order of increasing energy, in accord with the building-up principle. 3.11 Bonding in Heteronuclear Diatomic Molecules The bond in a heteronuclear diatomic molecule, a diatomic molecule built from atoms of two different elements, is polar, with the electrons shared unequally by the two atoms. We therefore rewrite Eq. 1 as the linear combination ␺ ϭ cA␺A ϩ cB␺B (4)* where the coefficients cA and cB are not equal. Because we always take the squares of wavefunctions when interpreting them in terms of probabilities, if cA 2 is large, then the molecular orbital looks more like the atomic orbital of A and the electron density is greater near A; if cB 2 is large, it looks more like the atomic orbital of B and the electron density is greater near B. In general, the atom with the atomic orbitals of lower energy dominates the molecular orbitals and the electron density is greater closer to that atom. The relative values of cA 2 and cB 2 determine the type of bond: • In a nonpolar covalent bond, cA 2 ϭ cB 2 and the electron pair is shared equally between the two atoms. • In an ionic bond, the coefficient belonging to one ion is nearly zero because the other ion captures almost all the electron density. • In a polar covalent bond, the atomic orbital belonging to the more electronegative atom has the lower energy, and so it makes the larger contribution to the lowest energy molecular orbital (Fig. 3.33). Conversely, the contribution to the highest-energy (most antibonding) orbital is greater for the higher-energy atomic orbital, which belongs to the less electronegative atom. To find the ground-state electron configurations of heteronuclear diatomic molecules, we use the same approach that we used for homonuclear diatomic molecules; but first we must modify the energy-level diagrams. For example, consider the HF molecule. The ␴-bond in this molecule consists of an electron pair in a ␴-orbital built from the F2pz-orbital and the H1s-orbital. Because the electronegativity of fluorine is 4.0 and that of hydrogen is 2.2, we can expect the bonding ␴-orbital to be mainly F2pz and the antibonding ␴*-orbital to be mainly H1s in character. These expectations are confirmed by calculation (Fig. 3.34). Because the two electrons in the bonding orbital are b = 1 2 * [(2 + 2 + 4) - (2 + 1 + 1)] = 2 ␴2p ␲2p ␲2p* ␴2s* ␴2s Oxygen, O246 3.12 ORBITALS IN POLYATOMIC MOLECULES 121 more likely to be found in the F2pz-orbital than in the H1s-orbital, there is a partial negative charge on the F atom and a partial positive charge on the H atom. The molecular orbital energy-level diagrams of heteronuclear diatomic molecules are much harder to predict qualitatively and we have to calculate each one explicitly because the atomic orbitals contribute differently to each one. Figure 3.35 shows the calculated scheme typically found for CO and NO. We can use this diagram to state the electron configuration by using the same procedure as for homonuclear diatomic molecules. EXAMPLE 3.8 Writing the configuration of a heteronuclear diatomic molecule or ion Write the electron configuration of the ground state of the carbon monoxide molecule. PLAN Assign the electrons to the orbitals shown in Fig. 3.35, in accordance with the building-up principle. SOLVE There are 4 ϩ 6 ϭ 10 valence electrons to accommodate (4 from C, 6 from O). The resulting configuration is shown in Fig. 3.35, and is CO: 1␴2 2␴*2 1␲4 3␴2 Self-Test 3.11A Write the configuration of the ground state of the nitric oxide (nitrogen monoxide) molecule. [Answer: 1␴2 2␴*2 1␲4 3␴2 2␲*1 ] Self-Test 3.11B Write the configuration of the ground state of the cyanide ion, CNϪ , assuming that its molecular orbital energy-level diagram is the same as that for CO. Bonding in heteronuclear diatomic molecules involves an unequal sharing of the bonding electrons. The more electronegative element contributes more strongly to the bonding orbitals, whereas the less electronegative element contributes more strongly to the antibonding orbitals. 3.12 Orbitals in Polyatomic Molecules The molecular orbital theory of polyatomic molecules follows the same principles as those outlined for diatomic molecules, but the molecular orbitals spread over all the atoms in the molecule. An electron pair in a bonding orbital helps to bind together the whole molecule, not just an individual pair of atoms. The energies of molecular orbitals in polyatomic molecules can be studied experimentally by using ultraviolet and visible spectroscopy (see Major Technique 2, following this chapter). The description of bonding in polyatomic molecules can be quite complex. However, we can illustrate qualitatively how to use molecular orbital theory to describe Energy A2s B2s ␴ ␴* Node FIGURE 3.33 A typical ␴ molecular orbital energylevel diagram for a heteronuclear diatomic molecule AB; the relative contributions of the atomic orbitals to the molecular orbitals are represented by the relative sizes of the spheres and the horizontal position of the boxes. In this case, A is the more electronegative of the two elements. Energy H F 3␴ 2␴ 1␴ 1␲ FIGURE 3.34 A schematic diagram of the molecular orbitals of HF. The orbitals are labeled by using a standard convention. The two 1␲-orbitals are nonbonding; the three ␴-orbitals are progressively more antibonding (1␴, bonding; 3␴, antibonding). Energy E2p E2s O2p O2s 1␴ 2␴* 3σ 4␴* 1␲ 2␲* FIGURE 3.35 The molecular orbital schemes typical of those calculated for a diatomic oxide molecule, EO (where E ϭ C for CO and E ϭ N for NO). Note that the ␴-orbitals are formed from mixtures of s- and pz-orbitals on both atoms; accordingly, we label them simply 1␴, 2␴, etc. in order of increasing energy. 122 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE bonding in one of the simplest but most important polyatomic molecules, water. A water molecule has six atomic orbitals (one O2s, three O2p, and two H1s). These six orbitals are used to build six molecular orbitals in which the degree of net bonding character is related to the number of internuclear nodes (Fig. 3.36). The molecular orbital with no nodes between neighboring atoms is fully bonding and, when occupied, contributes to holding all the atoms together; the one with a node between all neighboring pairs of atoms is fully antibonding and, if occupied, contributes to pushing all the atoms apart. There are eight electrons to accommodate: six are provided by the O atom and one comes from each H atom. Two electrons in the lowest energy, most bonding orbital pull all three atoms together. Two electrons in the orbital composed purely of the O2px-orbital (where x lies perpendicular to the molecular plane) are localized completely on the oxygen atom and do not contribute directly to the bonding. An orbital such as this one that, when occupied, contributes to neither bonding nor antibonding is classified as a nonbonding orbital. In some cases, a nonbonding orbital is a single atomic orbital; in others, it may consist of a linear combination of atomic orbitals on atoms that are not neighbors and so overlap to a negligible extent. Thinking point: Are the nonbonding electrons in an H2O molecule useless, or do they play a role in the properties of water? A note on good practice: The concepts of promotion, hybridization, and resonance belong to valence bond theory, not molecular orbital theory. Instead, molecular orbitals are built from all the available unhybridized atomic orbitals by noting whether or not they have the right shape to overlap with one another. Another important polyatomic molecule is benzene, C6H6, the parent of the aromatic compounds. In the molecular orbital description of benzene, all thirty C2s-, C2p-, and H1s-orbitals contribute to molecular orbitals spreading over all twelve atoms (six C plus six H). The orbitals in the plane of the ring (the C2s-, C2px-, and C2py-orbitals on each carbon atom and all six H1s-orbitals) form delocalized ␴-orbitals that bind the C atoms together and link the H atoms to the C atoms. The six C2pz-orbitals, which are perpendicular to the ring, contribute to six delocalized ␲-orbitals that spread all the way around the ring. However, chemists (other than those carrying out detailed calculations, who use a pure MO scheme) commonly mix MO and VB descriptions when discussing organic molecules. Because the language of hybridization and orbital overlap is well suited to the description of ␴-bonds, chemists typically express the ␴-framework of molecules in VB terms. Thus, they think of the ␴-framework of benzene as formed by the overlap of sp2 hybridized orbitals on neighboring atoms. Then, because delocalization is such an important feature of the ␲-bonding component of conjugated double bonds, which alternate as in ßC¢CßC¢CßC¢C–, they treat such ␲-bonds in terms of MO theory. We shall do the same. First, the VB part of the description of benzene. Each C atom is sp2 hybridized, with one electron in each hybrid orbital. Each C atom has a pz-orbital perpendicular to the plane defined by the hybrid orbitals, and it contains one electron. Two sp2 hybrid orbitals on each C atom overlap and form ␴-bonds with similar orbitals on the two neighboring C atoms, forming the 120Њ internal angle of the benzene hexagon. The third, outward-pointing sp2 hybrid orbital on each C atom forms a ␴-bond with a hydrogen atom. The resulting ␴-framework is the same as that illustrated in Fig. 3.20. Now for the MO part of the description. From the six C2pz-orbitals, we form six delocalized ␲-orbitals: their shapes are shown in Fig. 3.37 and their energies are shown in Fig. 3.38. The character of the orbitals changes from net bonding to net antibonding as the number of internuclear nodes increases from none (fully bonding) to six (fully antibonding). Each carbon atom provides one electron for the ␲-orbitals. Two electrons occupy the lowest energy, most bonding orbital; and the remaining four electrons occupy the next higher energy orbitals (two orbitals of the same energy). Figure 3.38 shows one of the reasons for benzene’s great stability: the ␲-electrons occupy only orbitals with a net bonding effect; none of the destabilizing antibonding orbitals are occupied. H Hϩ ϩ ϩ ϩ ϩ ϩ ϩ ϩ ϩ ϩ ϩ ϩ Ϫ Ϫ Ϫ Ϫ ϪϪ Ϫ Ϫ Ϫ Ϫ O 2b2 3a1 1b1 2a1 1b2 1a1 Energy FIGURE 3.36 A schematic diagram of the molecular orbitals of H2O. The orbitals are labeled according to the conventional notation for angular triatomic molecules. The orbitals become progressively more antibonding (1a1, bonding; 2b2, antibonding). The orbital labeled 1b1 is nonbonding, because it is composed of an orbital (O2px) that does not overlap either hydrogen atom. 3.12 ORBITALS IN POLYATOMIC MOLECULES 123 The delocalization of electrons accounts for the existence of electron-deficient molecules. Because the bonding influence of an electron pair is spread over all the atoms in the molecule, there is no need to provide one pair of electrons for each pair of atoms. A smaller number of pairs of electrons spread throughout the molecule may be able to bind all the atoms together, particularly if the nuclei are not highly charged and so do not repel one another strongly. This is the case in diborane, B2H6 (Section 15.11), where six electron pairs can hold the eight nuclei together. Another mystery solved by molecular orbital theory is the existence of hypervalent compounds, compounds in which a central atom forms more bonds than allowed by the octet rule (recall Section 2.10). In valence-bond theory, hybridization schemes are required to make sense of these compounds. For example, the expanded valence shell of Period 3 elements in compounds like SF6 is explained as sp3 d2 hybridization. However, the d-orbitals of sulfur lie at relatively high energies and may not be accessible for bonding. In molecular orbital theory a bonding scheme can be devised for SF6 that does not involve d-orbitals. The four valence orbitals provided by the sulfur atom and the six orbitals of the fluorine atoms that point toward the sulfur atom, a total of 10 atomic orbitals, result in 10 molecular orbitals with the energies shown in Fig. 3.39. The 12 electrons occupy the lowest six orbitals, which are either bonding or nonbonding, and so bind all the atoms together without needing to use d-orbitals. Because four bonding orbitals are occupied, the average bond order of each of the six SßF links is . Finally, we return to the opening remarks of the chapter and see how molecular orbital theory explains the colors of vegetation. The presence of highly delocalized electrons in the large molecules found in the petals of flowers and in fruits and vegetables is largely responsible for their colors. Because in each of these molecules many carbon atoms contribute p-orbitals to the ␲ system, there are many molecular orbitals. An electron in a ␲ system of such a molecule is like a particle in a huge onedimensional box. Because the “box” is very large, the energy levels are very close together. In these large molecules, the highest occupied molecular orbital (HOMO) is very close in energy to the lowest unoccupied molecular orbital (LUMO). As a result, it takes very little energy to excite an electron from a HOMO to a LUMO 2 3 +– 0 4␲ 3␲ 2␲ 1␲ Energy Energy C2pz 1␲ 2␲ 3␲ 4␲ FIGURE 3.37 The six ␲-orbitals of benzene; locations of nodes are shown with line drawings. Note that the orbitals range from fully bonding (no internuclear nodes) to fully antibonding (six internuclear nodes). The zero of energy corresponds to the total energy of the separated atoms. The three orbitals with negative energies have net bonding character. FIGURE 3.38 The molecular orbital energylevel diagram for the ␲-orbitals of benzene. In the ground state of the molecule, only the net bonding orbitals are occupied. Energy 2a1 2t1 e BondingAntibonding 1t1 1a1 Non- bonding FIGURE 3.39 The molecular orbital energy-level diagram for SF6 and the occupation of the orbitals by the 12 valence electrons of the atoms. Note that no antibonding orbitals are occupied and that there is a net bonding interaction even though no d-orbitals are involved. 124 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE (Fig. 3.40). Photons of visible light have enough energy to excite the electrons across this energy gap, and the absorption of these photons results in the colors that we perceive. The coloring agent of carrots and the precursor of vitamin A, ␤-carotene (47), has a highly delocalized ␲ system, as does lycopene (48), the red compound that gives tomatoes their color.Energy OccupiedUnoccupied LUMO HOMO Excitation FIGURE 3.40 In large molecules, there are many closely spaced energy levels and the HOMO–LUMO gap is quite small. Such molecules are often colored because photons of visible light can be absorbed when electrons are excited from the HOMO to the LUMO. 47 ␤-Carotene, C40H56 48 Lycopene, C40H58 According to molecular orbital theory, the delocalization of electrons in a polyatomic molecule spreads the bonding effects of electrons over the entire molecule. ❑ 1 Explain the basis of the VSEPR model of bonding in terms of repulsions between electrons (Section 3.1). ❑ 2 Use the VSEPR model to predict the electron arrangement and shape of a molecule or polyatomic ion from its formula (Toolbox 3.1 and Examples 3.1, 3.2, and 3.3). ❑ 3 Predict the polar character of a molecule (Example 3.4). ❑ 4 Account for the structure of a molecule in terms of hybrid orbitals and ␴- and ␲-bonds (Examples 3.5 and 3.6). ❑ 5 Construct and interpret a molecular orbital energy-level diagram for a homonuclear diatomic species (Sections 3.9 and 3.10). ❑ 6 Deduce the ground-state electron configurations of Period 2 diatomic molecules (Toolbox 3.2 and Examples 3.7 and 3.8). ❑ 7 Use molecular orbital theory to describe bonding in polyatomic molecules such as the benzene molecule (Section 3.12). SKILLS YOU SHOULD HAVE MASTERED Exercises labeled C require calculus. The Shapes of Molecules and Ions 3.1 Below are ball-and-stick models of two molecules. In each case, indicate whether or not there must be, may be, or cannot be one or more lone pairs of electrons on the central atom: 3.2 Below are ball-and-stick models of two molecules. In each case, indicate whether or not there must be, may be, or cannot be one or more lone pairs of electrons on the central atom: 3.3 (a) What is the shape of the ClO2 ϩ ion? (b) What is the OClO bond angle? 3.4 (a) What is the shape of the ClO2 Ϫ ion? (b) What values are expected for the OClO bond angles? (a) (b) 180° 120° 120° 180° (a) (b) EXERCISES C EXERCISES 125 3.5 (a) What is the shape of the thionyl chloride molecule, SOCl2? Sulfur is the central atom. (b) How many different OSCl bond angles are there in this molecule? (c) What values are expected for the OSCl and ClSCl bond angles? 3.6 (a) What is the shape of the XeF2 molecule? (b) What values are expected for the FXeF bond angles? 3.7 (a) What is the shape of an ICl2 molecule (iodine is the central atom)? (b) What value is expected for the ClICl angle? 3.8 (a) What is the shape of an SbF5 2Ϫ ion? (b) How many different FSbF bond angles are there in this molecule? (c) What values are expected for the FSbF angles? 3.9 Using Lewis structures and VSEPR, give the VSEPR formula for each of the following species and predict its shape: (a) sulfur tetrachloride; (b) iodine trichloride; (c) IF4 Ϫ ; (d) xenon trioxide. 3.10 Using Lewis structures and VSEPR, give the VSEPR formula for each of the following species and predict its shape: (a) PF4 Ϫ ; (b) ICl4 ϩ ; (c) phosphorus pentafluoride; (d) xenon tetrafluoride. 3.11 Write the Lewis structure, VSEPR formula, molecular shape, and bond angles for each of the following species: (a) I3 Ϫ ; (b) POCl3; (c) IO3 Ϫ ; (d) N2O. 3.12 Write the Lewis structure, VSEPR formula, molecular shape, and bond angles for each of the following species: (a) SiH4; (b) AsCl3; (c) SCl2; (d) IF4 ϩ . 3.13 Write the Lewis structure and the VSEPR formula, list the shape, and predict the approximate bond angles for (a) CF3Cl; (b) TeCl4; (c) COF2; (d) CH3 Ϫ . 3.14 Write the Lewis structure and the VSEPR formula, list the shape, and predict the approximate bond angles for (a) PCl3F2; (b) SnF4; (c) SnF6 2Ϫ ; (d) IF5; (e) XeO4. 3.15 The compound 2,4-pentanedione (also known as acetylacetone and abbreviated to acac) is acidic and can be deprotonated. The anion forms complexes with metals that are used in gasoline additives, lubricants, insecticides, and fungicides. (a) Estimate the bond angles marked with arcs and lowercase letters in 2,4-pentanedione and in the acac ion. (b) What are the differences, if any? Acetylacetone Acetylacetonate ion 3.16 Estimate the bond angles marked with arcs and lowercase letters in peroxyacetylnitrate, an eye irritant in smog: 3.17 Predict the bond angles at the central atom of the following molecules and ions: (a) ozone, O3; (b) azide ion, N3 Ϫ ; (c) cyanate ion, CNOϪ ; (d) hydronium ion, H3Oϩ . 3.18 Predict the bond angles at the central atom of the following molecules and ions: (a) OF2; (b) ClO2 Ϫ ; (c) NO2 Ϫ ; (d) SeCl2. O O O O N £ OCH3ϪC a b c O ¶ C H3C C H O ¶ C CH3 a b c ෆ͉ ϪO ¶ C H3C C H2 O ¶ C CH3 a b c 3.19 Write its Lewis structure and predict whether each of the following molecules is polar or nonpolar: (a) CH2Cl2; (b) CCl4; (c) CS2; (d) SF4. 3.20 Write its Lewis structure and predict whether each of the following molecules is polar or nonpolar: (a) H2Se; (b) AsF5; (c) SiO2; (d) NF3. 3.21 Predict whether each of the following molecules is likely to be polar or nonpolar: (a) C5H5N (pyridine, a molecule like benzene except that one ∫CH∫ group is replaced by a nitrogen atom); (b) C2H6 (ethane); (c) CHCl3 (trichloromethane, also known as chloroform, a common organic solvent and once used as an anesthetic). 3.22 Predict whether each of the following molecules is likely to be polar or nonpolar: (a) CI4; (b) CH3OH (methanol, wood alcohol); (c) CH3COCH3 (2-propanone, acetone, a common organic solvent used in nail polish remover). 3.23 There are three different dichlorobenzenes, C6H4Cl2, which differ in the relative positions of the chlorine atoms on the benzene ring. (a) Which of the three forms are polar? (b) Which has the largest dipole moment? 1 2 3 3.24 There are three different difluoroethenes, C2H2F2, which differ in the locations of the fluorine atoms. (a) Which of the forms are polar? (b) Which has the largest dipole moment? 1 2 3 3.25 Acrylonitrile, CH2CHCN, is used in the synthesis of acrylic fibers (polyacrylonitriles), such as Orlon. Write the Lewis structure of acrylonitrile and describe the hybrid orbitals on each carbon atom. What are the approximate values of the bond angles? 3.26 Xenon forms XeO3, XeO4, and XeO6 4Ϫ , all of which are powerful oxidizing agents. Give their Lewis structures, their bond angles, and the hybridization of the xenon atom. Which would be expected to have the longest Xe–O distances? 3.27 Predict the shapes and estimate the bond angles of (a) the thiosulfate ion, S2O3 2Ϫ ; (b) (CH3)2Be; (c) BH2 Ϫ ; (d) SnCl2. 3.28 For each of the following molecules or ions, write the Lewis structure, list the number of lone pairs on the central atom, identify the shape, and estimate the bond angles: (a) PBr5; (b) XeOF2; (c) SF5 ϩ ; (d) IF3; (e) BrO3 Ϫ . 3.29 Write the Lewis structure and give the approximate bond angles of (a) C2H4; (b) ClCN; (c) OPCl3; (d) N2H4. 3.30 Write the Lewis structure and predict the shape of (a) TeF4; (b) NH2 Ϫ ; (c) NO2 ϩ ; (d) NH4 ϩ ; (e) SnH4; (f) OCS. C £C F H F H C £C FH F H C £C F H F H Cl Cl Cl Cl Cl C 126 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 3.31 Write the Lewis structure and predict the shape of (a) OSbCl3; (b) SO2Cl2; (c) IO2F2 Ϫ . The atom in boldface type is the central atom. 3.32 Write the Lewis structure and predict the shape of (a) OCCl2; (b) OSbCl2 Ϫ . The atom in boldface type is the central atom. Valence-Bond Theory 3.33 State the relative orientations of the following hybrid orbitals: (a) sp3 ; (b) sp; (c) sp3 d2 ; (d) sp2 . 3.34 The orientation of bonds on a central atom of a molecule that has no lone pairs can be any of those listed below. What is the hybridization of the orbitals used by each central atom for its bonding pairs: (a) tetrahedral; (b) trigonal bipyramidal; (c) octahedral; (d) linear? 3.35 State the hybridization of the atom in boldface type in each of the following molecules: (a) BeCl2; (b) BH3; (c) BH4 Ϫ ; (d) SiF4. 3.36 State the hybridization of the atom in boldface type in each of the following molecules: (a) SF6; (b) O3Cl∫O∫ClO3; (c) H2N∫CH2∫COOH (glycine); (d) OC(NH2)2 (urea). 3.37 Identify the hybrid orbitals used by the atom in boldface type in each of the following species: (a) BF3; (b) AsF3; (c) BrF3; (d) SeF3 ϩ . 3.38 Identify the hybrid orbitals used by the atom in boldface type in each of the following molecules: (a) CH3CCCH3; (b) CH3NNCH3; (c) (CH3)2CC(CH3)2; (d) (CH3)2NN(CH3)2. 3.39 Identify the hybrid orbitals used by the phosphorus atom in each of the following species: (a) PCl4 ϩ ; (b) PCl6 Ϫ ; (c) PCl5; (d) PCl3. 3.40 Identify the hybrid orbitals used by the atom in boldface type in each of the following molecules: (a) H2CCCH2; (b) H3CCH3; (c) CH3NNN; (d) CH3COOH. 3.41 White phosphorus, P4, is so reactive that it bursts into flame in air. The four atoms in P4 form a tetrahedron in which each P atom is connected to three other P atoms. (a) Assign a hybridization scheme to the P4 molecule. (b) Is the P4 molecule polar or nonpolar? 3.42 In the vapor phase, phosphorus can exist as P2 molecules, which are highly reactive, whereas N2 is relatively inert. Use valence-bond theory to explain this difference. 3.43 Noting that the bond angle of an sp3 hybridized atom is 109.5Њ and that of an sp2 hybridized atom is 120Њ, do you expect the bond angle between two hybrid orbitals to increase or decrease as the s-character of the hybrids is increased? 3.44 Both NH2 Ϫ and NH2 ϩ are angular species, but the bond angle in NH2 Ϫ is less than that in NH2 ϩ . (a) What is the reason for this difference in bond angles? (b) Take the x-axis as lying perpendicular to the plane of the molecule. Does the N2px orbital participate in the hybridization for either species? Briefly explain your answer. 3.45 Describe the structure of the formaldehyde molecule, CH2O, in terms of hybrid orbitals, bond angles, and ␴- and ␲-bonds. The C atom is the central atom to which the other three atoms are attached. 3.46 Describe the structure of the formamide molecule, H2CONH2, in terms of hybrid orbitals, bond angles, and ␴- and ␲-bonds. The C atom is bonded to two H atoms, a terminal O atom, and the N atom. The N atom is also bonded to two H atoms. 3.47 Given that the atomic orbitals used to form hybrids are normalized to 1 and mutually orthogonal, (a) show that the two tetrahedral hybrids h1 ϭ s ϩ px ϩ py ϩ pz and h3 ϭ s Ϫ px ϩ py Ϫ pz are orthogonal. (b) Construct the remaining two tetrahedral hybrids that are orthogonal to these two hybrids. Hint: Two wavefunctions are orthogonal if , where means “integrate over all space.” 3.48 The hybrid orbital h1 ϭ s ϩ px ϩ py ϩ pz referred to in Exercise 3.47 is not normalized. Find the normalization factor N, given that all the atomic orbitals are normalized to 1. 3.49 The composition of hybrids can be discussed quantitatively. The outcome is that, if two equivalent hybrids composed of an s-orbital and two p-orbitals make an angle ␪ to each other, then the hybrids can be regarded as sp␭ , with ␭ ϭ What is the hybridization of the O orbitals that form the two O∫H bonds in H2O? 3.50 Given the information in Exercise 3.49, plot a graph showing how the hybridization depends on the angle between two hybrids formed from an s-orbital and two p-orbitals, and confirm that it ranges from 90Њ when no s-orbital is included in the mixture to 120Њ when the hybridization is sp2 . Molecular Orbital Theory 3.51 Draw a molecular orbital energy-level diagram and determine the bond order expected for each of the following diatomic species: (a) Li2; (b) Li2 ϩ ; (c) Li2 Ϫ . State whether each molecule or ion will be paramagnetic or diamagnetic. If it is paramagnetic, give the number of unpaired electrons. 3.52 Draw a molecular orbital energy-level diagram and determine the bond order expected for the following diatomic species: (a) B2; (b) B2 Ϫ ; (c) B2 ϩ . State whether each molecule or ion will be paramagnetic or diamagnetic. If it is paramagnetic, give the number of unpaired electrons. 3.53 (a) On the basis of the configuration of the neutral molecule F2, write the molecular orbital configuration of the valence molecular orbitals for (1) F2 – ; (2) F2 ϩ ; (3) F2 2– . (b) For each species, give the expected bond order. (c) Which are paramagnetic, if any? (d) Is the highest-energy orbital that contains an electron ␴ or ␲ in character? 3.54 (a) On the basis of the configuration for the neutral molecule N2, write the molecular orbital configuration of the valence molecular orbitals for (1) N2 ϩ ; (2) N2 2ϩ ; (3) N2 2– . (b) For each species, give the expected bond order. (c) Which are paramagnetic, if any? (d) Is the highest-energy orbital that contains an electron ␴ or ␲ in character? 3.55 The ground-state electron configuration of the ion C2 n– is ␴2s 2 ␴2s*2 ␲2p 4 ␴2p 2 . What is the charge on the ion and what is its bond order? 3.56 The ground-state electron configuration of the ion B2 nϪ : ␴2s 2 ␴2s*2 ␲2p 3 . What is the charge on the ion and what is its bond order? 3.57 (a) Draw the molecular orbital energy-level diagram for N2 and label the energy levels according to the type of orbitals from -cos u/cos2 (1 2 u). 1. . . dt 1c1c2 dt = 0 C C EXERCISES 127 which they are made, whether they are ␴- or ␲-orbitals, and whether they are bonding or antibonding. (b) The orbital structure of the heteronuclear diatomic ion NOϩ is similar to that of N2. How will the fact that the electronegativity of N differs from that of O affect the molecular orbital energy-level diagram of NOϩ compared with that of N2? Use this information to draw the energy-level diagram for NOϩ . (c) In the molecular orbitals, will the electrons have a higher probability of being at N or at O? Why? 3.58 (a) How does molecular orbital theory make it possible to explain both ionic and covalent bonding? (b) The degree of ionic character in bonding was related to electronegativity in Chapter 2. How does electronegativity affect the molecular orbital diagram so that bonds become ionic? 3.59 Write the valence-shell electron configurations and bond orders of (a) B2; (b) Be2; (c) F2. 3.60 Write the valence-shell electron configurations and bond orders of (a) NO; (b) N2 ϩ ; (c) C2 2ϩ . 3.61 Give the valence-shell electron configurations and bond orders for CO and COϩ . Use that information to predict which species has the greater bond enthalpy. 3.62 Give the valence-shell electron configurations and bond orders for CN and CNϪ . Use that information to predict which species has the greater bond enthalpy. 3.63 Which of the following species are paramagnetic: (a) B2; (b) B2 Ϫ ; (c) B2 ϩ ? If the species is paramagnetic, how many unpaired electrons does it possess? 3.64 Which of the following species are paramagnetic: (a) N2 Ϫ ; (b) F2 ϩ ; (c) O2 2ϩ ? If the species is paramagnetic, how many unpaired electrons does it possess? 3.65 Determine the bond orders and use them to predict which species of each of the following pairs has the stronger bond: (a) F2 or F2 Ϫ ; (b) B2 or B2 ϩ . 3.66 Determine the bond orders and use them to predict which species of each of the following pairs has the stronger bond: (a) C2 ϩ or C2; (b) O2 or O2 ϩ . 3.67 Based on their valence-shell electron configurations which of the following species would you expect to have the lowest ionization energy: (a) C2 ϩ ; (b) C2; (c) C2 Ϫ ? 3.68 Based on their valence-shell electron configurations which of the following species would you expect to have the greatest electron affinity: (a) Be2; (b) F2; (c) B2 ϩ , (d) C2 ϩ ? 3.69 It is usually convenient to deal with wavefunctions that are “normalized,” which means that the integral The bonding orbital in Eq. 1 is not normalized. A wavefunction c can be normalized by writing it as Nc and finding the factor N which ensures that the integral over (Nc)2 is equal to 1. Find the factor N that normalizes the bonding orbital in Eq. 1, given that the individual atomic orbitals are each normalized. Express your answer in terms of the “overlap integral” . (The notation is the same as in Exercise 3.47.) 3.70 The antibonding orbital in Eq. 2 is not normalized (see Exercise 3.69). Find the factor that normalizes it to 1, given that the individual atomic orbitals are each normalized. Express your answer in terms of the overlap integral (The notation is the same as in Exercise 3.47.) Confirm that the bonding and antibonding orbitals are mutually orthogonal—that is, that the integral over the product of the two wavefunctions is zero. Integrated Exercises 3.71 For each of the following species, write the Lewis structure, predict the shape and hybridization about each central atom, give the bond angles, and state whether it is polar or nonpolar: (a) GaCl4 Ϫ ; (b) TeF4; (c) SbCl4 Ϫ ; (d) SiCl4. 3.72 For each of the following species, write the Lewis structure, predict the shape and hybridization about each central atom, give the bond angles, and state whether it is polar or nonpolar: (a) SnCl3 Ϫ ; (b) TeO3; (c) NO3 Ϫ ; (d) ICl3. 3.73 (a) Draw a Lewis structure for each of the following species: CH3 ϩ ; CH4; CH3 Ϫ ; CH2; CH2 2ϩ ; CH2 2Ϫ . (b) Identify each as a radical or not. (c) Rank them in order of increasing HCH bond angles. Explain your choices. 3.74 The halogens form compounds among themselves. These compounds, called the interhalogens, have the formulas XXЈ, XXЈ3, and XXЈ5, where X is the heavier halogen atom. (a) Predict their structures and bond angles. (b) Which of them are polar? (c) Why is the lighter halogen atom not the central atom of such molecules? 3.75 An organic compound distilled from wood was found to have a molar mass of 32.04 g·molϪ1 and the following composition by mass: 37.5% C, 12.6% H, and 49.9% O. (a) Write the Lewis structure of the compound and determine the bond angles about the carbon and oxygen atoms. (b) Give the hybridization of the carbon and oxygen atoms. (c) Predict whether the molecule is polar or not. 3.76 Draw Lewis structures for each of the following species and predict the hybridization at each carbon atom: (a) H2CCHϩ ; (b) H2CCH3 ϩ ; (c) H3CCH2 Ϫ . 3.77 (a) Draw the bonding and antibonding orbitals that correspond to the ␴-bond in H2. (b) Repeat this procedure for HF. (c) How do these orbitals differ? 3.78 (a) Consider a hypothetical species “HeH.” What charge (magnitude and sign), if any, should be present on this combination of atoms to produce the most stable molecule or ion possible? (b) What is the maximum bond order that such a molecule or ion could have? (c) If the charge on this species were increased or decreased by one, what would be the effect on the bonding in the molecule? 3.79 (a) Order the following molecules according to increasing C∫F bond length: CFϩ , CF, CFϪ . (b) Which of these molecules will be diamagnetic, if any? Explain your reasoning. 3.80 Describe as completely as you can the structure and bonding in a carbamate ion, H2NCO2 Ϫ . The CßO bond lengths are both 128 pm, and the CßN bond length is 136 pm. 3.81 Borazine, B3N3H6, a compound that has been called “inorganic benzene” because of its similar hexagonal structure (but with alternating B and N atoms in place of C atoms), is the basis of a large class of boron–nitrogen compounds. Write its Lewis structure and predict the composition of the hybrid orbitals used by each B and N atom.S = 1cA1scB1sdt. S = 1cA1scB1sdt 1c2 dt = 1. C C 128 CHAPTER 3 MOLECULAR SHAPE AND STRUCTURE 3.82 Given that carbon has a valence of four in nearly all its compounds and can form chains and rings of C atoms, (a) draw any two of the three possible structures for C3H4; (b) determine all bond angles in each structure; (c) determine the hybridization of each carbon atom in the two structures; (d) ascertain whether the two structures are resonance structures and explain your reasoning. 3.83 The two atomic orbitals that contribute to the antibonding orbital in Eq. 2 are each proportional to , where r is the distance of the point from its parent nucleus. Confirm that there is a nodal plane lying halfway between the two nuclei. 3.84 Use the plotting function on the Web site for this book to plot the amplitude of the bonding and antibonding orbitals in Eqs. 1 and 2, given the information in Exercise 3.83, on a line passing through the two nuclei. Ignore the normalization factors, and take the internuclear distance as (a) a0, (b) 2a0, (c) 5a0. Which of these three bond lengths is most likely to be close to the actual bond length? 3.85 Write the Lewis structure and VSEPR formula and identify the molecular shape and bond angles of the interhalogen ion IF6 ϩ . 3.86 Dye molecules are of commercial importance because they are very intensely colored. Most dye molecules possess many multiple bonds and are often aromatic. Why is this type of structure important to the properties of the dye molecule? 3.87 Treat the ␲ system of a dye molecule composed of a conjugated carbon chain of N carbon atoms as a box of length NR, where R is the average C∫C bond length. Given that each C atom contributes one electron and that each state of the box can accommodate two electrons, derive an expression for the wavelength of the light absorbed by the lowest-energy transition. Should you increase or decrease the number of carbon atoms in the chain to shift the wavelength to longer values? Refer to Major Technique 2, which follows these exercises. 3.88 Show that a molecule with configuration ␲4 has a cylindrically symmetrical electron distribution. Hint: Take the ␲-orbitals to be equal to xf and yf, where f is a function that depends only on distance from the internuclear axis. 3.89 In addition to forming ␴ and ␲ types of bonds similar to p-orbitals, d-orbitals may overlap to form ␦-bonds. (a) Draw overlap diagrams showing three different ways in which d-orbitals can combine to form bonds. (b) Place the three types of d–d bonds—␴, ␲, and ␦—in order of strongest to weakest. 3.90 An s-orbital and a p-orbital on different atoms may overlap to form molecular orbitals. One of these interactions forms a bonding ␴-orbital and the other is nonbonding. Draw diagrams to represent the two types of orbital overlap that give rise to ␴-bonding and nonbonding orbitals. 3.91 (a) Describe the changes in bonding that would occur in benzene if two electrons were removed from the HOMO (highest occupied molecular orbital). This removal would correspond to an oxidation of benzene to C6H6 2ϩ . (b) Describe the changes in bonding that would occur if two electrons were added to the LUMO (lowest unoccupied molecular orbital). This addition would correspond to a reduction of benzene by two electrons to give C6H6 2Ϫ . Do you expect these ions to be diamagnetic or paramagnetic? 3.92 (a) Confirm, by using trigonometry, that the dipoles of the three bonds in a trigonal pyrimidal AB3 molecule do not cancel, resulting in a polar molecule. (b) Show that the dipoles of the four bonds in a tetrahedral AB4 molecule cancel and the molecule is nonpolar. 3.93 Benzyne, C6H4, is a highly reactive molecule that is detected only at low temperatures. It is related to benzene in that it has a six-membered ring of carbon atoms; but, instead of three double bonds, the structure is normally drawn with two double bonds and a triple bond. (a) Draw a Lewis structure of the benzyne molecule. Indicate on the structure the hybridization at each carbon atom. (b) On the basis of your understanding of bonding, explain why this molecule might be highly reactive. 3.94 The Lewis structure of caffeine, C8H10N4O2, a common stimulant, follows. (a) Give the hybridization of each atom other than hydrogen. (b) On the basis of your answers in part (a), estimate the bond angles around each carbon and nitrogen atom. (c) Search the chemical literature for the structure of caffeine, and compare the observed structural parameters with your predictions. . 3.95 Cyclopropane, C3H6, is a hydrocarbon composed of a threemembered ring of carbon atoms. (a) Determine the hybridization of the carbon atoms. (b) Predict the CCC and HCH bond angles at each carbon atom on the basis of your answer to part (a). (c) What must the “real” CCC bond angles in cyclopropane be? (d) What is the defining characteristic of a ␴-bond compared with a ␲-bond, for example? (e) How do the C∫C ␴-bonds in cyclopropane extend the definition of conventional ␴-bonds? (f) Draw a picture depicting the molecular orbitals to illustrate your answer. 3.96 The diameter of a C60 molecule (Section 15.12) is approximately 700 pm. (a) Could more than one lanthanum atom occupy the center of a C60 molecule? (b) Because it is possible for C60 to undergo reduction (six step-by-step reductions to give C60 6Ϫ have been reported), it is also possible for a lanthanum ion, La3ϩ , to exist inside the C60 molecule. Could two La3ϩ ions be placed inside a C60 molecule? 3.97 In which of the following molecules could there be an n-to-␲* transition? Explain your choices. (a) Formic acid, HCOOH; (b) ethyne, C2H2; (c) methanol, CH3OH; (d) hydrogen cyanide, HCN. Refer to Major Technique 2, which follows these exercises. 3.98 Aqueous solutions of compounds containing the Cu2ϩ ion are blue as a result of the presence of the Cu(H2O)6 2ϩ complex. Does this complex absorb in the visible region? Suggest an explanation. Refer to Major Technique 2, which follows these exercises. 3.99 Consider the bonding in CH2¢CHCHO. (a) Draw the most important Lewis structure. Include all nonzero formal charges. (b) Identify the composition of the bonds and the hybridization of each lone pair—for example, by writing ␴(H1s,C2sp2 ). C C O CH3 CH3 CH3 N O H N CC N C N e-r/a0 EXERCISES 129 3.100 Consider the molecules H2CCH2, H2CCCH2, and H2CCCCH2. (a) Draw Lewis structures for these molecules. (b) What is the hybridization at each C atom? (c) What type of bond connects the carbon atoms (single, double, etc.)? (d) What are the HCH, CCH, and CCC angles in these molecules? (e) Do all the hydrogen atoms lie in the same plane? (f) A generalized formula for molecules of this type is H2C(C)xCH2, where x is 0, 1, 2, etc. What can be said, if anything, about the relative orientation of the H atoms at the ends of the chain as a function of x? 3.101 The reaction between SbF3 and CsF produces, among other products, the anion [Sb2F7]– . This anion has no F∫F bonds and no Sb∫Sb bonds. (a) Propose a Lewis structure for the ion. (b) Assign a hybridization scheme to the Sb atoms. 3.102 The following molecules are bases that are part of the nucleic acids involved in the genetic code. Identify (a) the hybridization of each C and N atom, (b) the number of ␴- and ␲-bonds, and (c) the number of lone pairs of electrons in the molecule. 3.103 Just as AlCl3 forms dimers (Section 2.11), in the [Bi2Cl4]2Ϫ ion two of the Cl atoms form “bridges” between the two Bi atoms. Propose a structure for the [Bi2Cl4]2Ϫ ion. 3.104 Germanium forms a series of anions called “germides.” In the germide ion Ge4 nϪ the four Ge atoms form a tetrahedron in which each atom is bonded to the other three and each atom has a lone pair of electrons. What is the value of n, the charge on this anion? Explain your reasoning. 3.105 One form of the polyatomic ion I5 Ϫ has an unusual V-shaped structure: one I atom lies at the point of the V, with a linear chain of two I atoms extending on each side. The bond angles are 88Њ at the central atom and 180Њ at the two atoms in the side chains. Draw a Lewis structure for I5 Ϫ that explains its shape and indicate the hybridization you would assign to each nonterminal atom. 3.106 Molecules and ions, like atoms, can be isoelectronic. That is, they can have the same number of electrons. For example, CH4 and NH4 ϩ are isoelectronic. Therefore, they have the same molecular shape. Identify a molecule or ion that is isoelectronic with each of the following species and verify that each pair has the same shape: (a) CO3 2Ϫ ; (b) O3; (c) OHϪ . 3.107 Is the Al2Cl6 molecule, described in Section 2.11, polar or nonpolar? Justify your conclusion. 3.108 The molecular structure of benzene, C6H6, is planar. Is the molecular structure of cyclohexane, C6H12, planar as well? (a) Draw a Lewis structure for cyclohexane. (b) Indicate the bond angles about each carbon atom. (c) What is your conclusion about the shape of the cyclohexane molecule? 3.109 Complexes of d- and f-block metals can be described in terms of hybridization schemes, each associated with a particular shape. Bearing in mind that the number of atomic orbitals hybridized must be the same as the number of hybrid orbitals produced, match the hybrid orbitals sp2 d, sp3 d3 , and sp3 d3 f to the following shapes: (a) pentagonal bipyramidal; (b) cubic; (c) square planar. 3.110 (a) The formula for bromate ion (BrO3 – ) is similar to that of chlorate ion (ClO3 Ϫ ); however, the formulas of the nitrate and phosphate ions have different numbers of oxygen atoms, as do the formulas of the nitrite and phosphite ions. Draw the Lewis structures of all four ions and explain why the formulas differ. (b) Energy is supplied to muscles in the body through changes in ATP, a molecule that contains chains of phosphate ions (∫PO2∫O∫PO2∫O∫PO2∫O∫). Explain how phosphate ions can connect to one another in this way, but nitrate ions cannot. Chemistry Connections 3.111 Hydrogen peroxide, H2O2, is a nontoxic bleaching agent being used as a replacement for chlorine in industry and home laundries. The bleaching process is an oxidation and when hydrogen peroxide acts as a bleaching agent, the only waste it generates is H2O. (a) Draw the Lewis structure of hydrogen peroxide and determine the formal charge on each atom. What is the oxidation number of oxygen in hydrogen peroxide? Which is more useful in predicting the ability of H2O2 to act as an oxidizing agent, formal charge or oxidation number? Explain your reasoning. (b) Predict the bond angles about each O atom in H2O2. Are all the atoms in the same plane? Is the molecule polar or nonpolar? Explain your reasoning. (c) Write the valence electron configuration of (1) O2; (2) O2 Ϫ ; (3) O2 ϩ ; (4) O2 2Ϫ . For each species, give the expected bond order and indicate which, if any, are paramagnetic. (d) The following bond lengths have been reported: (1) O2, 121 pm; (2) O2 Ϫ , 134 pm; (3) O2 ϩ , 112 pm; (4) O2 2Ϫ , 149 pm. Suggest a reason for the differences based on the configurations in part (c). (e) One reaction in which H2O2 acts as an oxidizing agent is Fe2ϩ (aq) ϩ H2O2(aq) ϩ Hϩ (aq) : Fe3ϩ (aq) ϩ H2O(l). Balance the equation and determine what mass of iron(II) can be oxidized to iron(III) by 54.1 mL of 0.200 M H2O2(aq). Hint: Make sure you balance charge as well as mass. (f) Hydrogen peroxide can also act as a reducing agent, as in Fe3ϩ (aq) ϩ H2O2(aq) ϩ OH– (aq) : Fe2ϩ (aq) ϩ H2O(l) ϩ O2(g). Balance the equation and determine what mass of iron(III) can be reduced to iron(II) by 35.6 mL of 0.200 M H2O2(aq). Hint: Make sure you balance charge as well as mass. (g) Hydrogen peroxide must be kept in brown bottles because in the presence of light it can disproportionate, which means that it oxidizes and reduces itself in the reaction 2 H2O2(aq) : 2 H2O(l) ϩ O2(g). How many electrons are transferred in the reaction represented by this equation? (h) Although peroxides do not generate hazardous waste, they can cause problems in the atmosphere. If it makes its way to the stratosphere, a hydrogen peroxide molecule can break into two OH radicals, which threaten the ozone layer that protects Earth from harmful radiation. Use data in Table 2.4 to calculate the minimum frequency and corresponding wavelength of light needed to break the HO∫OH bond. C C O N H H H H N CC N C N 2 C C NH2 N H H H N CC N C N 1 All the colors of the vegetation around us arise from the selective absorption and reflection of visible light. If our eyes were sensitive to ultraviolet radiation—the electromagnetic radiation at shorter wavelengths (higher frequencies) than violet light—we would see an even richer tapestry of color, because substances also absorb and reflect selectively in the ultraviolet region. Honeybees do have this ability, and they can “see” radiation in the ultraviolet as well as in the visible range. The selective absorption and transmittance of visible light and ultraviolet radiation are the basis of a spectroscopic technique for identifying compounds and for determining their concentrations in samples. The Technique When electromagnetic radiation falls on a molecule, the electrons in the molecule can be excited to a higher energy state. Radiation of frequency ␯ (nu) can raise the energy of the molecule by an amount ⌬E, ⌬E ϭ h␯ (1) where h is Planck’s constant. This equation is the Bohr frequency condition (Section 1.4). Provided that an empty orbital exists at the right energy, the incoming radiation can excite an electron into it and hence be absorbed. For typical ultraviolet wavelengths (of 300 nm and less, corresponding to a frequency of about 1015 Hz), each photon brings enough energy to excite the electrons in a molecule into a different distribution. Therefore, the study of visible and ultraviolet absorption gives us information about the electronic energy levels of molecules. Visible and ultraviolet absorption spectra are measured in an absorption spectrometer. The source gives out intense visible light or ultraviolet radiation. The wavelengths can be selected with a glass prism for visible light and with a quartz prism or a diffraction grating for ultraviolet radiation (which is absorbed by glass). A typical absorption spectrum, that of chlorophyll, is shown in Fig. 1. Note that chlorophyll absorbs red and blue light, leaving the green light present in white light to be reflected. That is why most vegetation looks green. The spectrum can help us to assess the absorption quantitatively and to make a precise analysis of the energy-capturing power of the molecule. ULTRAVIOLET AND VISIBLE SPECTROSCOPYMAJOR TECHNIQUE 2 Chromophores The presence of certain absorption bands in visible and ultraviolet spectra can often be traced to the presence of characteristic groups of atoms in the molecules. These groups of atoms are called chromophores, from the Greek words for “color bringer.” An important chromophore is a carbon–carbon double bond. The electronic transition that takes place when energy is absorbed is the excitation of an electron from a bonding ␲-orbital to the corresponding antibonding orbital, ␲*. This transition is therefore known as a ␲-to-␲* (pi to pi star) transition (Fig. 2); it occurs at about 160 nm, which is in the ultraviolet region. The transition can be brought into the visible region by decreasing the separation between bonding and antibonding orbitals. These orbitals lie close in energy when the molecule has a long chain of alternating single and double bonds. Such “conjugated” double bonding occurs in the compound carotene (see structure 47 in Chapter 3), which is partly responsible for the color of carrots, mangoes, and persimmons. Related compounds account for the colors of shrimp and flamingoes. This transition is also responsible for the primary act of vision, as explained in Section 3.7. Another important chromophore is the carbonyl group, ϾC¢O, which absorbs at about 280 nm. The transition responsible for the absorption is the excitation of a lone-pair electron on the oxygen atom (a “nonbonding” electron, denoted n) into the empty antibonding ␲*-orbital of the C¢O double bond (Fig. 3). This transition is therefore called an n-to-␲* (n to pi star) transition. A d-metal ion may also be responsible for color, as is apparent from the varied colors of many d-metal complexes (see ␲* ␲ FIGURE 2 In a ␲-to-␲* transition, an electron in a bonding ␲-orbital is excited into an empty antibonding ␲*-orbital. 100 700600500400 Wavelength (nm) Absorption(%) 0 FIGURE 1 The optical absorption spectrum of chlorophyll as a plot of percentage absorption against wavelength. Chlorophyll a is shown in red, chlorophyll b in blue. FIGURE 3 In an n-to-␲* transition of a carbonyl group, an electron in a nonbonding orbital (one localized wholly on the oxygen atom) is excited into an antibonding ␲*-orbital spread over both atoms. ␲* n 130 Chapter 16). Two types of transitions may be involved. In one, which is called a d-to-d transition, an electron is excited from a d-orbital of one energy to a d-orbital of higher energy. Because the energy differences between d-orbitals are quite small, visible light brings enough energy to cause this excitation, and so colors are absorbed from white light and the sample takes on colors complementary to those absorbed (Fig. 4). In a second type of transition involving d-orbitals, called a charge-transfer transition, electrons migrate from the atoms attached to the central metal atom into the latter’s d-orbitals or vice versa. This transfer of charge can result in very intense absorption; it is responsible, for instance, for the deep purple of permanganate ions, MnO4 Ϫ . Related Exercises: 3.87, 3.97, and 3.98. Red Violet Blue GreenYellow Orange 800 400 430 490 560 580 620 FIGURE 4 The perceived color of a complex in white light is the complementary color of the light that it absorbs. In this color wheel, complementary colors are opposite each other. The numbers are approximate wavelengths in nanometers. 131 This page intentionally left blank 133 What Are the Key Ideas? We can predict the physical properties of any gas by using the set of equations known as “the gas laws.” These equations can be explained in terms of a model of a gas in which the molecules are in ceaseless random motion and so widely separated that they do not interact with one another except during brief collisions. Why Do We Need to Know This Material? In the first three chapters, we investigated the nature of atoms, molecules, and ions. Bulk matter is composed of immense numbers of these particles and its properties emerge from the behavior of the constituent particles. Gases are the simplest state of matter, and so the connections between the properties of individual molecules and those of bulk matter are relatively easy to identify. In later chapters, these concepts will be used to study thermodynamics, equilibrium, and the rates of chemical reactions. What Do We Need to Know Already? We need to be familiar with SI units (Appendix 1B) and the concepts of force and energy (Section A). This chapter also extends the techniques of reaction stoichiometry (Sections L and M) to gases. T he most important gas on the planet is the atmosphere, a thin layer of gas held by gravity to the surface of the Earth. Half the mass of the atmosphere lies below an altitude of 5.5 km. If we were to look from a point where the Earth appears to be the size of a basketball, the atmosphere would appear to be only 1 mm thick (Fig. 4.1). Yet this delicate layer is vital to life: it shields us from harmful radiation and supplies substances needed for life, such as oxygen, nitrogen, carbon dioxide, and water. Eleven elements are gases under normal conditions (Fig. 4.2). So are many compounds with low molar masses, such as carbon dioxide, hydrogen chloride, and organic compounds such as the methane, CH4, of natural gas and the propane, C3H8, of camping fuel. All substances that are gases at ordinary temperatures are molecular, except the six noble gases, which are monatomic (consist of single atoms). THE NATURE OF GASES 4.1 Observing Gases 4.2 Pressure 4.3 Alternative Units of Pressure THE GAS LAWS 4.4 The Experimental Observations 4.5 Applications of the Ideal Gas Law 4.6 Gas Density 4.7 The Stoichiometry of Reacting Gases 4.8 Mixtures of Gases MOLECULAR MOTION 4.9 Diffusion and Effusion 4.10 The Kinetic Model of Gases 4.11 The Maxwell Distribution of Speeds REAL GASES 4.12 Deviations from Ideality 4.13 The Liquefaction of Gases 4.14 Equations of State of Real Gases 133 Chapter 4 THE PROPERTIES OF GASES FIGURE 4.1 The delicate film of the Earth’s atmosphere as seen from space. In this chapter, we follow a typical scientific path. First, we collect experimental observations on the properties of gases and summarize these observations mathematically. We then formulate a simple qualitative molecular model of a gas suggested by these observations and go on to express it quantitatively. Finally, we use more detailed experimental observations to refine the model so that it accounts for the properties of real gases. THE NATURE OF GASES A remarkable characteristic of gases is that many of their physical properties are very similar, particularly at low pressures, regardless of the identity of the gas. Therefore, instead of having to describe the properties of each gas individually, we can describe them all simultaneously. 4.1 Observing Gases Samples of gases large enough to study are examples of bulk matter, forms of matter that consist of large numbers of molecules. The properties of a gas sample emerge from the collective behavior of vast numbers of its individual particles. For example, when we push on a bicycle pump, we see that air is compressible—that is, it can be confined into a smaller volume. The act of reducing the volume of a sample of gas is called compression. The observation that gases are more compressible than solids and liquids suggests that there is a lot of space between the molecules of gases. We also know from everyday experience—by releasing air from an inflated balloon, for instance—that a gas expands rapidly to fill the space available to it. This observation suggests that the molecules are always moving rapidly and hence can respond quickly to changes in the volume available to them. Because the pressure in a balloon is the same in all directions, we can infer that the motion of the molecules is chaotic, not favoring any single direction. Our first primitive picture of a gas could therefore be as a collection of widely spaced molecules hurtling past each other in ceaseless rapid chaotic motion and changing speed and direction only when they happen to collide. We shall use more quantitative observations to refine this simple model as we proceed through the chapter. The fact that gases are readily compressible and immediately fill the space available to them suggests that molecules of gases are widely separated and in ceaseless chaotic motion. 4.2 Pressure If you have ever pumped up a bicycle tire or squeezed an inflated balloon, you have experienced an opposing force arising from the confined air. The pressure, P, of a gas is the force, F, exerted by the gas, divided by the area, A, on which the force is exerted: (1) The SI unit of pressure is the pascal, Pa: 1 Pa ϭ 1 kgиmϪ1 иsϪ2 A pascal is a rather small unit of pressure: the atmosphere exerts about 100 000 Pa (100 kPa) at sea level; 1 Pa is the pressure that would be exerted by a layer of water only 0.1 mm thick. In terms of the model that we are developing, the pressure that a gas exerts on the walls of its container results from the collisions of its molecules with the container’s surface (Fig. 4.3). The more vigorous the storm of molecules on a surface, the stronger the force and hence the higher the pressure. Any object on the surface of the Earth stands in an invisible storm of molecules that beat on it incessantly and exert a force all over its surface. Even on an apparently calm day, we are in the midst of a molecular storm. The pressure exerted by the atmosphere can be measured by various means, most commonly by using a pressure gauge. When we measure the pressure of air in a tire with a pressure gauge, we are actually measuring the “gauge pressure,” the difference P = F A 134 CHAPTER 4 THE PROPERTIES OF GASES Kr Xe Rn ArCl NeFN O HeH FIGURE 4.2 The 11 elements that are gases under normal conditions. Note how they lie toward the upper right of the periodic table. Pressure FIGURE 4.3 The pressure of a gas arises from the collisions that its molecules make with the walls of the container. The storm of collisions, shown in the inset, exerts an almost steady force on the walls. Animation 4.3 between the pressure inside the tire and the atmospheric pressure. A flat tire registers a gauge pressure of zero, because the pressure inside the tire is the same as the pressure of the atmosphere. A laboratory pressure gauge attached to a piece of scientific apparatus, however, measures the actual pressure in the apparatus. The pressure of the atmosphere can be measured with a barometer, an instrument invented in the seventeenth century by the Italian scientist Evangelista Torricelli, a student of Galileo. Torricelli (whose name coincidentally means “little tower” in Italian) formed a little tower of liquid mercury. He sealed a long glass tube at one end, filled it with mercury, and inverted it into an open container (Fig. 4.4). The column of mercury fell until the pressure that it exerted at its base matched the pressure exerted by the atmosphere. To interpret measurements with a barometer, we need to find how the height of the column of mercury depends on the atmospheric pressure. 4.2 PRESSURE 135 Heightproportionalto atmosphericpressure Pressure of atmosphere Pressure of mercury column FIGURE 4.4 A barometer is used to measure the pressure of the atmosphere. The pressure of the atmosphere is balanced by the pressure exerted by the column of mercury, which falls to the appropriate height, leaving a vacuum above it. The height of the column is proportional to the atmospheric pressure. HOW DO WE DO THAT? We want to find the relation between the height, h, of the column of mercury in a barometer and the atmospheric pressure, P. Suppose the cross-sectional area of the cylindrical column is A. The volume of mercury in the column is the height of the cylinder times this area, V ϭ hA. The mass, m, of this volume of mercury is the product of mercury’s density, d, and the volume; so m ϭ dV ϭ dhA. The mercury is pulled down by the force of gravity; and the total force that its mass exerts at its base is the product of the mass and the acceleration of free fall (the acceleration due to gravity), g: F ϭ mg. Therefore, the pressure at the base of the column, the force divided by the area, is h Area, A Mass, m ϭ dhA Force, F ϭ mg From P ϭ F/A and F ϭ mg: P = F A = mg A = dhA g A = dhg #m #mg This equation shows that the pressure, P, exerted by a column of mercury is proportional to the height of the column. Mercury inside a tube sealed at one end and inverted in a pool of mercury will fall until the pressure exerted by the mercury balances the atmospheric pressure. Therefore, the height of the column can be used as a measure of atmospheric pressure. We have shown that the pressure of a gas can be related to the height h of a column of liquid and its density d by P ϭ dhg (2) where g is the acceleration of free fall. The pressure is obtained in pascals when the density, height, and value of g are expressed in SI units. Thinking point: Could you use a mercury barometer to measure pressure on a space station? EXAMPLE 4.1 Calculating atmospheric pressure from the height of a column of mercury Suppose the height of the column of mercury in a barometer is 760. mm at 15ЊC. What is the atmospheric pressure in pascals? At 15ЊC the density of mercury is 13.595 gиcmϪ3 (corresponding to 13 595 kgиmϪ3 ) and the standard acceleration of free fall at the surface of the Earth is 9.806 65 mиsϪ2 . Anticipate We have remarked that atmospheric pressure is close to 100 kPa, so expect a value close to that figure. PLAN We use Eq. 2: in this case, all we need to do is to use the data and recognize that 1 kgиmϪ1 иsϪ2 ϭ 1 Pa. SOLVE 136 CHAPTER 4 THE PROPERTIES OF GASES 760 cm 101 kPa From P ϭ dhg, = 1.01 * 105 kgиm-1 иs-2 = 1.01 * 105 Pa P = (13 595 kgиm-3 ) * (0.760 m) * (9.806 65 mиs-2 ) Evaluate This pressure can also be reported as 101 kPa, where 1 kPa ϭ 103 Pa. This value is close to the anticipated value. The acceleration of free fall varies over the surface of the Earth and depends on the altitude; however, in all calculations in this text, we assume that g has the “standard” value used here. Self-Test 4.1A What is the atmospheric pressure in kilopascals when the height of the mercury column in a barometer at 15ЊC is 756 mm? [Answer: 100. kPa] Self-Test 4.1B The density of water at 20ЊC is 0.998 gиcmϪ3 . What height would the column of liquid be in a water barometer at 20ЊC when the atmospheric pressure corresponds to 760. mm of mercury? Although an electronic pressure gauge is more commonly used to measure the pressure inside a laboratory vessel, a manometer is sometimes used (Fig. 4.5). It consists of a U-shaped tube connected to the experimental system. The other end of the tube may be either open to the atmosphere or sealed. For an open-tube manometer (like that shown in Fig. 4.5a), the pressure in the system is equal to that of the atmosphere when the levels of the liquid in each arm of the U-tube are the same. If the level of mercury on the system side of an open manometer is above that of the atmosphere side, the pressure in the system is lower than the atmospheric pressure. In a closed-tube manometer (like that shown in Fig. 4.5b), one side is connected to a closed flask (the system) and the other side is vacuum. The difference in heights of the two columns is proportional to the pressure in the system. Self-Test 4.2A What is the pressure in kilopascals in a system when the mercury level in the system-side column in an open-tube mercury manometer is 25 mm lower than the mercury level in the atmosphere-side column and the atmospheric pressure corresponds to 760. mm of mercury at 15ЊC? [Answer: 105 kPa] Self-Test 4.2B What is the pressure in pascals inside a system when a closed mercury manometer shows a height difference of 10. cm at 15ЊC? The pressure of a gas, the force that it exerts divided by the area subjected to the force, arises from the impacts of its molecules. 4.3 Alternative Units of Pressure Although the SI unit of pressure is the pascal (Pa), there are several other units in common use. Normal atmospheric pressure is close to 100 kPa, and it is useful to have a unit, the bar, for exactly 100 kPa: 1 bar ϭ 105 Pa Weather charts commonly report pressures in millibars (1 mbar ϭ 10Ϫ3 bar ϭ 102 Pa), with typical atmospheric pressures close to 1000 mbar. The standard pressure for reporting data is now defined as 1 bar exactly and denoted PЊ. However, it had long been conventional to report data in terms of a pressure Atmosphere Low High (a) (b) To apparatus FIGURE 4.5 (a) An open-tube manometer. The pressure inside the apparatus to which the narrow horizontal tube is connected pushes against the external pressure. In this instance, the pressure inside the system is lower than the atmospheric pressure by an amount proportional to the difference in heights of the liquid in the two arms. (b) A closed-tube manometer. The pressure in the adjoining apparatus is proportional to the difference in heights of the liquid in the two arms. The space inside the closed end is a vacuum. HIGH HIGH LOW LOW LOW 1020 1020 1020 1020 1016 1016 1016 1016101610161008 1008 1008 1008 1008 10121004 1004 1000 992 984 1004 1004 1008 1012 1012 1012 1012 1012 1016 JACKSON HURCN "KATRINA" 29.5N 89.5W TRC 0811 Ϫ90 Ϫ80Ϫ100Ϫ110Ϫ120 30 40 40 30 50 FIGURE 4.6 A weather map showing North America during Hurricane Katrina in 2005. The curves are called isobars and are contours of constant atmospheric pressure. Regions of low pressure (seen over southern Louisiana) are called cyclones and regions of high pressure (seen over Canada) are called anticyclones. All pressures are in millibars. The lowest pressure on the map is 984 mbar, at the center of the hurricane. Before making landfall, the pressure at the center of the hurricane had fallen to as low as 902 mbar. corresponding to 760 mm of mercury (written 760 mmHg), corresponding to just over 101 kPa. This convention inspired the use of the unit the atmosphere (atm), which is now defined by the exact relation 1 atm ϭ 1.013 25 ϫ 105 Pa Note that 1 atm ϭ 1.013 25 bar, and so 1 atm is slightly greater than 1 bar. The unit millimeter of mercury (mmHg) is defined in terms of the pressure exerted by a column of mercury 1 mm high under certain conditions (15ЊC and in a standard gravitational field), but it has now been largely displaced by a unit of similar magnitude, the torr (Torr). This unit is defined by the exact relation 760 Torr ϭ 1 atm It is normally safe to use the units mmHg and Torr interchangeably, but in very precise work you should note that they are not exactly the same (they differ by less than 1 part in a million). A note on good practice: The name of the unit torr, like all names derived from the names of people, has a lowercase initial letter; likewise, the symbol for the unit, like all symbols derived from proper names, has an uppercase initial letter (Torr). Pressure units are summarized in Table 4.1. It is important to be familiar with them and to be able to make conversions between them. For example, a pressure of 746 Torr is converted into a pressure in pascals by using a conversion factor derived from Table 4.1: The actual pressure exerted by the atmosphere varies with altitude and weather. The pressure of the atmosphere at the cruising height of a commercial jetliner (10 km) is only about 200 Torr (about 0.3 atm), and so airplane cabins must be pressurized. A very low pressure atmospheric region, such as an area of low pressure on the weather chart in Fig. 4.6, typically has a pressure of about 0.98 atm at sea level. A typical region of high pressure is about 1.03 atm. P = 746 Torr * 133.322 Pa 1 Torr = 9.95 * 104 Pa or 99.5 kPa 4.3 ALTERNATIVE UNITS OF PRESSURE 137 10 kPa$%& TABLE 4.1 Pressure Units* SI unit: pascal (Pa) 1 Pa ϭ 1 kg·mϪ1 ·sϪ2 ϭ 1 N·mϪ2 Conventional units 1 bar ϭ 105 Pa ϭ 100 kPa 1 atm ϭ 1.013 25 ϫ 105 Pa ϭ 101.325 kPa 1 atm ϭ 760 Torr 1 Torr (1 mmHg) ϭ 133.322 Pa 1 atm ϭ 14.7 lb·inchϪ2 (psi) *Figures in bold are exact. See inside back cover for more relations. N, newton. Note that 1 mmHg is the same as 1 Torr to within 1 part in 107 . Self-Test 4.3A The U.S. National Hurricane Center reported that the pressure in the eye of Hurricane Katrina (2005) fell as low as 902 mbar. What is that pressure in atmospheres? [Answer: 0.890 atm] Self-Test 4.3B The atmospheric pressure in Denver, Colorado, on a certain day was 630. Torr. Express this pressure in pascals. The principal units for reporting pressure are torr, atmosphere, and (the SI unit) pascal. Pressure units can be interconverted by using the information in Table 4.1. THE GAS LAWS Summaries of the properties of gases, particularly the variation of pressure with volume and temperature, are known as the “gas laws.” The first reliable measurements of the properties of gases were made by the Anglo-Irish scientist Robert Boyle in 1662 when he examined the effect of pressure on volume. A century and a half later, a new pastime, hot-air ballooning, motivated two French scientists, Jacques Charles and Joseph-Louis Gay-Lussac, to formulate additional gas laws. They measured how the temperature of a gas affects its pressure, volume, and density. The Italian scientist Amedeo Avogadro made a further contribution that established the relation between the volume and the amount of molecules in the sample and thereby helped to establish belief in the reality of atoms. 4.4 The Experimental Observations Boyle took a long tube of glass curved into a J-shape, with the short end sealed (Fig. 4.7). He then poured mercury into the tube, trapping air in the short end of the J. The more mercury he added, the more the air was compressed. He concluded that at constant temperature the volume of a fixed amount of gas (the air in this case) decreases as the pressure on it increases. Figure 4.8 shows a graph of the dependence. The curve shown there is called an isotherm, which is a general term for a constant-temperature plot. An isothermal change is one that takes place at constant temperature. Scientists often look for ways of plotting experimental data in a manner that gives straight lines, because such graphs are easier to identify, analyze, and interpret. Boyle’s data give a straight line when we plot the pressure against 1/volume (Fig. 4.9). This result implies Boyle’s law: For a fixed amount of gas at constant temperature, volume is inversely proportional to pressure. Boyle’s law is written or equivalently PV ϭ constant (at constant n and T) (3a) Volume r 1 pressure or, more simply, V = constant P 138 CHAPTER 4 THE PROPERTIES OF GASES (a) (b) Volume, V FIGURE 4.7 (a) In Boyle’s experiment, a gas was trapped by mercury inside the closed end of a J-shaped tube. (b) The volume of the trapped gas decreased as the pressure on it was increased by adding more mercury to the open end of the tube. High pressure, small volume Pressure,P 1/Volume, 1/V Low pressure, large volume FIGURE 4.9 When the pressure is plotted against 1/volume, a straight line is obtained. Boyle’s law breaks down at high pressures, and a straight line is not obtained in these regions (not shown). High pressure, small volume Pressure,P Volume, V Low pressure, large volume FIGURE 4.8 Boyle’s law summarizes the effect of pressure on the volume of a fixed amount of gas at constant temperature. As the pressure of a gas sample is increased (as depicted by the increasing size of the weight pressing on the piston), the volume of the gas decreases. Living Graph 4.8 Suppose the pressure and volume of a fixed amount of gas at the start of an experiment are P1 and V1, then at the start P1V1 ϭ constant. At the end of the experiment the pressure and volume have become P2 and V2, but P2V2 is equal to the same constant (provided the temperature has not changed). It follows that we can write P2V2 ϭ P1V1 (3b) for this isothermal change. Self-Test 4.4A A sample of neon of volume 10.0 L at 300. Torr is allowed to expand isothermally into an evacuated tube with a volume of 20.0 L. What is the final pressure of the neon in the tube? [Answer: 150. Torr] Self-Test 4.4B In a petroleum refinery a 750.-L container containing ethylene gas at 1.00 bar was compressed isothermally to 5.00 bar. What was the final volume of the container? Charles and Gay-Lussac carried out a number of experiments with the hope of improving the performance of their balloons. They found that, provided the pressure is kept constant, the volume of a gas increases as its temperature is raised. In this case, a straight-line graph is obtained when the volume is plotted against the temperature (Fig. 4.10). This result implies Charles’s law: For a fixed amount of gas under constant pressure, the volume varies linearly with the temperature. Gay-Lussac’s name is sometimes associated with the law, but “Charles’s law” is now more common. Charles’s law has a very important implication. When the straight lines obtained by plotting volume against temperature for different gases and at various pressures are extrapolated (that is, extended beyond the range of the data), it is found that they all reach zero volume at Ϫ273.15ЊC (Fig. 4.11). This point cannot be reached in practice, because no real gas has zero volume and all real gases condense to a liquid before such low temperatures are reached. Because a volume cannot be negative, Ϫ273.15ЊC must be the lowest possible temperature. It is the value corresponding to zero on the Kelvin scale. It follows that, if we use the absolute temperature, T, then we can write Charles’s law as Volume absolute temperature or, more simply, V ϭ constant ϫ T (4a) A similar expression summarizes the linear variation in pressure of a sample of gas when it is heated in a container of fixed volume. The pressure is found experimentally to extrapolate to zero pressure at Ϫ273.15ЊC (Fig. 4.12). Therefore, as Gay-Lussac was able to show Pressure absolute temperature or, more simply, P ϭ constant ϫ T (4b) It follows that doubling the absolute temperature doubles the pressure of a gas, provided the amount and volume are constant. r r 4.4 THE EXPERIMENTAL OBSERVATIONS 139 FIGURE 4.10 When the temperature of a gas is increased and its volume is free to change at constant pressure (as depicted by the constant weight acting on the piston), the volume increases. A graph of volume against temperature is a straight line. The Kelvin scale of absolute temperatures is described in Appendix 1B: the temperature in kelvins (K) is obtained by adding 273.15 to the temperature in degrees Celsius (°C). Temperature, T Volume,V −273°C 0°C FIGURE 4.11 The extrapolation of data like those in Fig. 4.10 for a number of gases suggests that the volume of each gas should become 0 at T ϭ 0 (Ϫ273°C). Extrapolated data are shown in gray. In practice, all gases condense to liquids before that temperature is reached. Living Graph 4.10 High temperature, large volume Volume,V Temperature, T Low temperature, small volume A note on good practice: Note that the volume (or the pressure) doubles when the temperature is doubled on the absolute (Kelvin) scale, not when it is doubled on the Celsius scale. An increase from 20ЊC to 40ЊC corresponds to an increase from 293 K to 313 K, an increase of only 7%. Self-Test 4.5A A rigid oxygen tank stored outside a building has a pressure of 20.00 atm at 6:00 am, when the temperature is 10.ЊC. What will be the pressure in the tank at 6:00 pm, when the temperature is 30.ЊC? [Answer: 21.4 atm] Self-Test 4.5B A sample of hydrogen gas at 760. mmHg and 20.ЊC is heated to 300.ЊC in a container of constant volume. What is the final pressure of the sample? A further contribution was made by the Italian scientist Amedeo Avogadro: Avogadro’s principle: Under the same conditions of temperature and pressure, a given number of gas molecules occupy the same volume regardless of their chemical identity. Avogadro’s principle is commonly expressed in the terms of the molar volume, Vm, the volume occupied per mole of molecules: (5a) for then we can write V ϭ nVm (5b) The molar volume of gases are all close to 22 LиmolϪ1 at 0ЊC and 1 atm (Fig. 4.13). Self-Test 4.6A A helium weather balloon was filled at Ϫ20.ЊC and a certain pressure to a volume of 2.5 ϫ 104 L with 1.2 ϫ 103 mol He. What is the molar volume of helium under those conditions? [Answer: 21 L·mol–1 ] Self-Test 4.6B A large natural gas storage tank contains 200. mol CH4(g) at 1.20 atm. An additional 100. mol CH4(g) is pumped into the tank at constant temperature. What is the final pressure in the tank? Each of the properties we have summarized is consistent with our molecular model of a gas as widely spaced molecules in ceaseless motion. Boyle’s law is consistent with this model because compression increases the number of molecules in a given region of the sample and hence increases the number of collisions that the molecules make with the walls. As a result, the pressure they exert increases (Fig. 4.14). The effect of temperature on the pressure of a gas in a constant-volume container suggests a new feature: as the temperature of a gas is raised, the average speed of the molecules increases. As a result of this increase in average speed, each molecule strikes the walls more often and with greater force. Therefore, the gas exerts a greater pressure as the temperature is increased at Molar volume = volume amount or, more simply, Vm = V n Avogadro’s principle is not a law because it is based not on observation alone but also on a model of matter— namely that matter consists of molecules. Even though there is no longer any doubt that matter consists of atoms and molecules, it remains a principle rather than a law. Carbon dioxide Nitrogen Oxygen Hydrogen 22.09 22.26 22.40 22.40 22.43 Ideal gas 22.41 Argon FIGURE 4.13 The molar volumes (in liters per mole) of various gases at 0°C and 1 atm. The values are all very similar and close to the molar volume of an ideal gas under these conditions, 22.41 L·molϪ1 (Section 4.5). FIGURE 4.12 The pressure of a fixed amount of gas in a vessel of constant volume is proportional to the absolute temperature. Notice the increase in the pressure on the cylinder (represented by the increasing mass of the weight on the piston) as the temperature increases. The pressure extrapolates to 0 at T ϭ 0. Living Graph 4.12 High temperature, high pressurePressure,P Temperature, T Low temperature, low pressure constant volume. We can use this same model of a gas to explain the effect of temperature on the volume when the pressure is held constant. To counteract the increase in pressure as the temperature is raised, the space available to the gas must increase so that fewer molecules are available to strike the walls in a given time interval. Finally, Avogadro’s principle is consistent with the model because, in order to keep the pressure constant as more molecules are added to a container, the size of the container must increase. The three properties of a gas expressed by Eqs. 3, 4, and 5 can all be combined into a single expression relating pressure (P), volume (V), temperature (T), and amount (n) of a gas: PV ϭ constant ϫ nT Thus, if the temperature and amount are constant, PV is a constant (Boyle’s law), if the amount and pressure are constant, V is proportional to T (Charles’ law), and if the pressure and temperature are constant, the volume is proportional to n (Avogadro’s principle). When the constant of proportionality for the laws is written as R, this expression becomes the ideal gas law: PV ϭ nRT (6)* The constant R is called the gas constant and has the same value for all gases; because R is independent of the identity of the gas, we say that it is a “universal constant.” The value of the gas constant can be found by measuring P, V, n, and T and substituting their values into R ϭ PV/nT. When we use SI units (pressure in pascals, volume in meters cubed, temperature in kelvins, and amount in moles), R is obtained in joules per kelvin per mole: R ϭ 8.314 JиKϪ1 иmolϪ1 . Table 4.2 lists the values of R when the volume and pressure are reported in other than SI units. A note on good practice: To avoid overwhelming you with data we usually quote the values of fundamental constants to three decimal places. In actual calculations you should use the more precise values given in tables, including those inside the back cover. The ideal gas law is an example of an equation of state, an expression showing how the pressure of a substance—in this case, a gas—is related to its temperature, volume, and amount of substance. A hypothetical gas that obeys the ideal gas law under all conditions is called an ideal gas. All real gases are found to obey Eq. 6 with increasing accuracy as the pressure is reduced toward zero (which we write P : 0). Therefore, the ideal gas law is an example of a limiting law, a law that is strictly valid only in some limit—in this case, as P : 0. Although the ideal gas law is a limiting law, it is in fact reasonably reliable at normal pressures, and so we can use it to describe the behavior of most gases under normal conditions. The ideal gas law, PV ‫؍‬ nRT, is an equation of state that summarizes the relations describing the response of an ideal gas to changes in pressure, volume, temperature, and amount of molecules; it is an example of a limiting law. 4.5 Applications of the Ideal Gas Law We have seen how to use the individual laws to make predictions when only one variable is changed, such as heating a fixed amount of gas at constant volume. The ideal gas law enables us to make predictions when two or more variables are changed. To do such calculations, we note that, if the initial conditions of a gas are n1, P1, V1, and T1, then from Eq. 6 we can write P1V1 ϭ n1RT1, or P1V1/n1T1 ϭ R. After the change, the conditions become n2, P2, V2, and T2; and, because the ideal gas law still applies, we know that P2V2/n2T2 ϭ R. Because R is a constant, we can equate P1V1/n1T1 and P2V2/n2T2 and hence obtain (7)* This expression is called the combined gas law. However, it is a direct consequence of the ideal gas law and is not a new law. P1V1 n1T1 = P2V2 n2T2 4.5 APPLICATIONS OF THE IDEAL GAS LAW 141 FIGURE 4.14 (a) The pressure of a gas arises from the impact of its molecules on the walls of the container. (b) When the volume of the sample is decreased, there are more molecules in a given volume and so there are more collisions with the same area of the wall in a given time interval. Because the impact on the walls is now greater, so is the pressure. TABLE 4.2 The Gas Constant, R 8.205 74 ϫ 10Ϫ2 L·atm·KϪ1 ·molϪ1 8.314 47 ϫ 10Ϫ2 L·bar·KϪ1 ·molϪ1 8.314 47 L·kPa·KϪ1 ·molϪ1 8.314 47 J·KϪ1 ·molϪ1 62.364 L·Torr·KϪ1 ·molϪ1 Animation 4.14 Pressure Pressure (a) (b) EXAMPLE 4.2 Calculating the pressure of a given sample In a cathode-ray tube, which until recently was widely used in TV sets and computer monitors, the beam of electrons is directed toward a screen that emits light where they strike it. Have you ever wondered what the pressure is inside the tube? Estimate the pressure (in atmospheres), given that the volume of the tube is 5.0 L, its temperature is 23ЊC, and it contains 0.10 ␮g of nitrogen gas. Anticipate We should suspect that the pressure will be very low, for any collisions between the electron beam and the gas molecules would blur the picture. PLAN Convert mass into amount of N2 and convert the temperature into kelvins; then proceed as in Toolbox 4.1. SOLVE 142 CHAPTER 4 THE PROPERTIES OF GASES TOOLBOX 4.1 HOW TO USE THE IDEAL GAS LAW CONCEPTUAL BASIS The ideal gas law, Eq. 6 (PV ϭ nRT), summarizes the observation that the pressure is inversely proportional to the volume and directly proportional to the amount of gas and the absolute temperature. It can be used for real gases at low pressures. PROCEDURE To calculate the pressure, volume, or temperature of a given sample Step 1 Express the temperatures in kelvins and the amount in moles. Step 2 To use Eq. 6, rearrange the equation PV ϭ nRT to give the desired quantity on the left and all other quantities on the right (such as P ϭ nRT/V). Step 3 Substitute the data, if necessary converting from mass of gas to the amount in moles. Select the value of R from Table 4.2 that matches the units of pressure and volume you need to use. Alternatively, convert the pressure units to match the value of R you prefer to use. The procedure is illustrated in Example 4.2. To calculate the response of a gas to a change in conditions The initial and final conditions for a gas undergoing a change are related by Eq. 7 (P1V1/n1T1 ϭ P2V2/n2T2). To use this relation: Step 1 Rearrange the relation so that the quantity required is on the left and all other quantities are on the right. Cancel any quantities that are unchanged and, if necessary, express the temperatures in kelvins. Step 2 Substitute the data and check to see whether the answer agrees with your predictions. The procedure is illustrated in Examples 4.3 and 4.4. 0 100 200 300 400 23ЊC Temperature(K) Step 1 Convert mass to amount (n ϭ m/M) and temperature from degrees Celsius to kelvins by adding 273.15. T = (23 + 273.15) K = 296 K n = 1.0 * 10-7 g 28.02 gиmol-1 = 1.0 * 10-7 28.02 mol 0.10 ␮g $++%++& Step 2 From PV ϭ nRT, P ϭ nRT/V. 17 natm 5.0 L, 23ЊC, 0.10 ␮g Step 3 Substitute the data, using R in LиatmиKϪ1 иmolϪ1 . = 1.7 * 10-8 atm * (8.206 * 10-2 LиatmиK-1 иmol-1 ) * (296 K) 5.0 L P = a 1.0 * 10-7 28.02 molb Evaluate The pressure of 1.7 ϫ 10Ϫ8 atm corresponds to 1.7 mPa, a very low pressure, as we anticipated. Most CRTs were designed to operate close to this pressure. Self-Test 4.7A Calculate the pressure (in kilopascals) exerted by 1.0 g of carbon dioxide in a flask of volume 1.0 L at 300.ЊC. [Answer: 1.1 ϫ 102 kPa] Self-Test 4.7B An idling, badly tuned automobile engine can release as much as 1.00 mol CO per minute into the atmosphere. At 27ЊC, what volume of CO, adjusted to 1.00 atm, is emitted per minute? 4.5 APPLICATIONS OF THE IDEAL GAS LAW 143 EXAMPLE 4.3 Using the combined gas law when one variable is changed Assume that, when you press in the piston of a bicycle pump, the volume inside the pump is decreased from about 100. cm3 to 20. cm3 before the air flows into the tire. Suppose that the compression is isothermal; estimate the final pressure of the compressed air in the pump, given an initial pressure of 1.00 atm. Anticipate The volume is reduced by a factor of 5, so we should expect a fivefold increase in pressure. PLAN Follow the second procedure in Toolbox 4.1. Only the pressure and volume change, so all other variables cancel, resulting in Boyle’s law. SOLVE 1 20 100 ? Pressure Volume PV ϭ constant (P2 ,V2 ) (P1 ,V1 ) Step 1 Rearrange P1V1/n1T1 ϭ P2V2/n2T2 to find P2 by multiplying both sides by n2T2/V2, and set n2 ϭ n1 (no change in the amount) and T2 ϭ T1 (no change in temperature): P2 = P1V1 n1T1 * n2T2 V2 ¡ P1V1 n1T1 * n1T1 V2 = P1 * V1 V2 1.00 atm 100 cm3 20 cm 3 5.0 atm Step 2 Substitute the data: P2 = (1.00 atm) * 100 cm3 20 cm3 = 5.0 atm Evaluate The final pressure is higher by a factor of 5 (more precisely, 5.0), as expected. Self-Test 4.8A A sample of argon gas of volume 10.0 mL at 200. Torr is allowed to expand isothermally into an evacuated tube with a volume of 0.200 L. What is the final pressure of the argon in the tube? [Answer: 10.0 Torr] Self-Test 4.8B A sample of dry air in the cylinder of a test engine at 80. cm3 and 1.00 atm is compressed isothermally to 3.20 atm by pushing a piston into the cylinder. What is the final volume of the sample? EXAMPLE 4.4 Using the combined gas law when two variables are changed In an investigation of the properties of the coolant gas used in an air-conditioning system, a sample of volume 500. mL at 28.0ЊC was found to exert a pressure of 92.0 kPa. What pressure will the sample exert when it is compressed to 300. mL and cooled to Ϫ5.0ЊC? Anticipate Our problem is to judge whether the compression, which will increase the pressure, dominates the cooling, which will decrease the pressure. On the Kelvin scale, the change in temperature is quite small, so we should suspect that the compression will dominate. n2 ϭ n1 T2 ϭ T1 PLAN Follow the procedure set out in Toolbox 4.1. SOLVE 144 CHAPTER 4 THE PROPERTIES OF GASES 0 100 200 300 400 28.0ЊC Ϫ5.0ЊC Temperature(K) Step 1 Convert the temperatures into kelvins. T2 = (273.15 - 5.0) K = 268.2 K T1 = (273.15 + 28.0) K = 301.2 K Step 2 Rearrange P1V1͞n1T1 ϭ P2V2͞n2T2 to find P2, as in Example 4.3, but only set n1 ϭ n2. P2 = P1V1 n1T1 * n2T2 V2 ¡ n2 =n1 P1 * V1 V2 * T2 T1 92.0 kPa 137 kPa Step 3 Substitute the data: = 137 kPa P2 = (92.0 kPa) * 500. mL 300. mL * 268.2 K 301.2 K Evaluate The net outcome is an increase in pressure, so, in this instance, compression has a greater effect than cooling, as we suspected. Self-Test 4.9A A parcel of air (the technical term in meteorology for a small region of the atmosphere) of volume 1.00 ϫ 103 L at 20.ЊC and 1.00 atm rises up the side of a mountain range. At the summit, where the pressure is 0.750 atm, the parcel of air has cooled to Ϫ10.ЊC. What is the volume of the parcel at that point? [Answer: 1.20 ϫ 103 L] Self-Test 4.9B A weather balloon is filled with helium gas at 20.ЊC and 1.00 atm. The volume of the balloon is 250. L. When the balloon rises to a layer of air where the temperature is Ϫ30.ЊC, it has expanded to 800. L. What is the pressure of the atmosphere at that point? The ideal gas law can also be used to predict the molar volume of an ideal gas under any conditions of temperature and pressure. To do so, we combine Eq. 5a (Vm ϭ V/n) and Eq. 6 (as V ϭ nRT/P) by writing (8) At standard ambient temperature and pressure (SATP), which means exactly 25ЊC (298.15 K) and exactly 1 bar, the conditions commonly used to report data in chemistry, the molar volume of an ideal gas is 24.79 LиmolϪ1 , which is about the volume of a cube 1 ft on a side (Fig. 4.15). The common expression standard temperature and pressure (STP) means 0ЊC and 1 atm (both exactly), the conditions formerly used to report data and still widely used in some calculations. At STP, the molar volume of an ideal gas is 22.41 LиmolϪ1 . Note the slightly smaller value: the temperature is lower and the pressure is slightly higher, and so the same amount of gas molecules occupies a smaller volume than at SATP. Table 4.3 gives values of the molar volume of an ideal gas under a variety of common conditions. To obtain the volume of a known amount of gas at a specified temperature and pressure, we simply multiply the molar volume at that temperature and pressure by the amount in moles. Alternatively, we can use the ideal gas law to calculate the volume. Vm = V n = nRT/P n = RT P FIGURE 4.15 The blue cube is the volume (25 L) occupied by 1 mol of ideal gas molecules at 25°C and 1 bar. Self-Test 4.10A Calculate the volume occupied by 1.0 kg of hydrogen at 25ЊC and 1.0 atm. [Answer: 1.2 ϫ 104 L] Self-Test 4.10B Calculate the volume occupied by 2.0 g of helium at 25ЊC and 1.0 atm. The combined gas law describes how a gas responds to changes in conditions. Standard ambient temperature and pressure (SATP) are 25ºC (298.15 K) and 1 bar; standard temperature and pressure (STP) are 0ºC (273.15 K) and 1 atm. 4.6 Gas Density As we saw in Section G, the molar concentration of any substance is the amount of molecules (n, in moles) divided by the volume that they occupy (V). It follows from the ideal gas law that, for a gas behaving ideally (so we can write n ϭ PV/RT), (9) Thinking point: Should you be surprised that the molar concentration of a gas is the inverse of its molar volume? This expression shows that, for a given pressure and temperature, the molar concentration should be the same for every gas. That is, two gas samples of equal volume at the same temperature and pressure should contain the same amount of gas molecules, regardless of the identities of the gases (this, of course, is just Avogadro’s principle). However, if their molar masses are different, the gas samples will have different masses. The density, d, of a gas, like that of any substance, is the mass of the sample divided by its volume, d ϭ m/V. Because the densities of gases are so low, they are usually expressed in grams per liter (gиLϪ1 ). The density of air, for instance, is about 1.6 gиLϪ1 at SATP. Because the mass of the sample is equal to the amount in moles times the molar mass, m ϭ nM, and n ϭ PV/RT, it follows that (10)* We see that: • For a given pressure and temperature, the greater the molar mass of the gas, the greater its density. • At constant temperature, the density of a gas increases with pressure. In this case, the pressure is increased either by adding more material or by compression (reduction of volume). • Raising the temperature of a gas that is free to expand at constant pressure increases the volume occupied by the gas and therefore reduces its density. Equation 10 is the basis for using density measurements to determine the molar mass of a gas or vapor. Thinking point: Why do hot-air balloons float in air? Density = mass volume = m V = nM V = (PV/RT)M V = MP RT Molar concentration = amount volume = n V = PV/RT V = P RT 4.6 GAS DENSITY 145 TABLE 4.3 Molar Volume of an Ideal Gas Temperature Pressure Molar volume (L·mol؊1 ) 0 K 0 0 0°C 1 atm 22.4140 0°C 1 bar 22.7110 25°C 1 atm 24.4654 25°C 1 bar 24.7896 146 CHAPTER 4 THE PROPERTIES OF GASES 0 100 200 300 400 500 260ЊC Temperature(K) Assemble the data: T = (273.15 + 260.) K = 533 K d = 0.480 gиL-1 , P = 103 Torr, and 154.1 g·molϪ1 OH CH3 CH3H3C Rearrange d ϭ MP/RT into M ϭ dRT/P and substitute the data: = 155 gиmol-1 M = (0.480 gиL-1 ) * (62.364 LиTorr иK-1 иmol-1 ) * (533 K) 103 Torr Evaluate This value, 155 gиmolϪ1 , is close to the value that could be calculated from the molecular formula (154.1 gиmolϪ1 , see the illustration). Self-Test 4.11A The oil produced from eucalyptus leaves contains the volatile organic compound eucalyptol. At 190.ЊC and 60.0 Torr, a sample of eucalyptol vapor had a density of 0.320 g·LϪ1 . Calculate the molar mass of eucalyptol. [Answer: 154 g·molϪ1 ] Self-Test 4.11B The Codex Ebers, an Egyptian medical papyrus, describes the use of garlic as an antiseptic. Chemists today have verified that the oxide of diallyl disulfide (the volatile compound responsible for garlic odor) is a powerful antibacterial agent. At 177ЊC and 200. Torr, a sample of diallyl disulfide vapor has a density of 1.04 gиLϪ1 . What is the molar mass of diallyl disulfide? The density of the atmosphere varies greatly from place to place, as does its composition and temperature. The average composition of dry air (air from which water vapor has been removed) is shown in Table 4.4. One reason for the nonuniformity of EXAMPLE 4.5 Calculating the molar mass of a gas from its density The volatile organic compound geraniol, a component of oil of roses, is used in perfumery. The density of the vapor at 260.ЊC and 103 Torr is 0.480 g·LϪ1 . What is the molar mass of geraniol? Anticipate Because the compound is volatile, we anticipate that it will have a moderately low molar mass. PLAN List the information given and convert the temperature into kelvins. Then rearrange Eq. 10 into an expression for M, select a value of R with appropriate units, and substitute the data. SOLVE TABLE 4.4 Composition of Dry Air at Sea Level Composition (%) Constituent Molar mass* (g·mol؊1 ) Volume Mass nitrogen, N2 28.02 78.09 75.52 oxygen, O2 32.00 20.95 23.14 argon, Ar 39.95 0.93 1.29 carbon dioxide, CO2 44.01 0.03 0.05 *The average molar mass of molecules in the air, taking into account the relative amounts of the different components, is 28.97 g·molϪ1 . The percentage of water vapor in ordinary air varies with the humidity. air is the effect of solar radiation, which causes different chemical reactions at different altitudes. The density of air also varies with altitude. For example, the air outside an airplane cruising at 10 km is only 25% as dense as air at sea level. The molar concentrations and densities of gases increase as they are compressed but decrease as they are heated. The density of a gas depends on its molar mass. 4.7 The Stoichiometry of Reacting Gases We can use the ideal gas law in combination with mole ratios to calculate the volume of gas consumed or produced in a reaction. For example, we might need to know the volume of carbon dioxide produced when a fuel burns or the volume of oxygen needed to react with a given mass of hemoglobin in the red cells of our blood. To answer this kind of question, we have to combine the mole-to-mole calculations of the type described in Sections L and M with the conversion of moles of gas molecules into the volume that they occupy. The diagram in (1) extends the stoichiometry strategy introduced in Section L to include the volume of a gas. 4.7 THE STOICHIOMETRY OF REACTING GASES 147 ReactionReaction stoichiometry Molar volume of A Molar volume of B Volume of gas A Volume of gas B Moles of A Mole ratio Moles of B 1 EXAMPLE 4.6 Calculating the mass of reagent needed to react with a specified volume of gas The carbon dioxide generated by the personnel in the artificial atmosphere of submarines and spacecraft must be removed from the air and the oxygen recovered. Submarine design teams have investigated the use of potassium superoxide, KO2, as an air purifier because this compound reacts with carbon dioxide and releases oxygen (Fig. 4.16): Calculate the mass of KO2 needed to react with 50. L of carbon dioxide at 25ЊC and 1.0 atm. Anticipate A volume of 50 L under normal conditions corresponds to about 2 mol CO2, and the stoichiometry of the equation indicates that about 4 mol KO2 would be needed. Because the molar mass of KO2 is about 70 gиmolϪ1 , we can suspect that the answer will be close to 280 g. PLAN We convert from the given volume of gas into moles of molecules (by using the molar volume), then into moles of reactant molecules or formula units (by using a mole ratio), and then into the mass of reactant (by using its molar mass). If the molar volume at the stated conditions is not available, then use the ideal gas law to calculate the amount of gas molecules. SOLVE 4 KO2(s) + 2 CO2(g) ¡ 2 K2CO3(s) + 3 O2(g) 24.47 L·mol Ϫ1 Pressure, P Molarvolume,Vm 1.0 atm 25ЊC Find the molar volume under the stated conditions from a table or calculation. Table 4.3 gives Vm ϭ 24.47 LиmolϪ1 . Find the stoichiometric relation between CO2 and KO2 from the chemical equation. 2 mol CO2 Ё 4 mol KO2, or 1 mol CO2 Ё 2 mol KO2 Find the molar mass of KO2 (Section E). 39.10 ϩ 2(16.00) gиmolϪ1 ϭ 71.10 gиmolϪ1 FIGURE 4.16 When carbon dioxide is passed over potassium superoxide (the yellow solid), it reacts to form colorless potassium carbonate (the white solid coating the walls of the tube) and oxygen gas. The reaction is used to remove carbon dioxide from the air in a closedsystem breathing environment. Evaluate The answer, 290 g, is close to the 280 g that we anticipated. Self-Test 4.12A Calculate the volume of carbon dioxide, adjusted to 25ЊC and 1.0 atm, that plants need to make 1.00 g of glucose, C6H12O6, by photosynthesis in the reaction 6 CO2(g) ϩ 6 H2O(l) : C6H12O6(s) ϩ 6 O2(g). [Answer: 0.81 L] Self-Test 4.12B The reaction of H2 and O2 gases to produce liquid H2O is used in fuel cells on the space shuttles to provide electricity. What mass of water can be produced in the reaction of 100.0 L of oxygen stored at 25ЊC and 1.00 atm? There may be more than a thousandfold increase in volume when liquids or solids react to form a gas. The molar volumes of gases are close to 25 LиmolϪ1 under normal conditions (room temperature and pressure), whereas liquids and solids occupy only about a few tens of milliliters per mole. The molar volume of liquid water, for instance, is only 18 mLиmolϪ1 at 25ЊC. In other words, 1 mol of gas molecules at 25ЊC and 1 atm occupies as much as 1000 times the volume of 1 mol of molecules in a typical liquid or solid. The increase in volume as gaseous products are formed in a chemical reaction is even larger if several gas molecules are produced from each reactant molecule, such as the formation of CO and CO2 from a solid fuel (Fig. 4.17). Lead azide, Pb(N3)2, which is used as a detonator for explosives, suddenly releases a large volume of nitrogen gas when it is struck: Pb(N3)2(s) Pb(s) ϩ 3 N2(g) An explosion of the same kind, but using sodium azide, NaN3, is used in air bags in automobiles (Fig. 4.18). The explosive release of nitrogen is detonated electrically when the vehicle decelerates abruptly in a collision. The molar volume (at the specified temperature and pressure) is used to convert the amount of a reactant or product in a chemical reaction into a volume of gas. 4.8 Mixtures of Gases Many of the gases we meet in chemistry—and in everyday life—are mixtures. The atmosphere, for instance, is a mixture of nitrogen, oxygen, argon, carbon dioxide, and many other gases. The air we inhale is one mixture; the air we exhale is another mixture. Many ¡ 148 CHAPTER 4 THE PROPERTIES OF GASES 50 L 24.47 L 71.1 g 290 g 1 mol CO2 1 mol CO2 2 mol KO2 1 mol KO2 ϫ ϫ ϫ ϭ Convert from volume of CO2 to mass of KO2. * a 71.1 g 1 mol KO2 b = 2.9 * 102 g Mass of KO2 = (50. L) * a 1 mol CO2 24.47 L b * a 2 mol KO2 1 mol CO2 b FIGURE 4.17 An explosion caused by the ignition of coal dust. A shock wave is created by the tremendous expansion of volume as large numbers of gas molecules form. FIGURE 4.18 The rapid decomposition of sodium azide, NaN3, results in the formation of a large volume of nitrogen gas. The reaction is triggered electrically in this air bag. gaseous anesthetics are carefully controlled mixtures. We need to extend the model of a gas that we have been developing to include mixtures of gases. To extend our model, we should note that, at low pressures at least, all gases respond in the same way to changes in pressure, volume, and temperature. Therefore, for calculations of the type that we are doing in this chapter, it does not matter whether all the molecules in a sample are the same. A mixture of gases that do not react with one another behaves like a single pure gas. For instance, we can treat air as a single gas when we want to use the ideal gas law to predict its properties. John Dalton was the first to see how to calculate the pressure of a mixture of gases. His reasoning was something like this. Imagine that we introduce a certain amount of oxygen into a container and end up with a pressure of 0.60 atm. Then we evacuate the container to empty it of all gas. Now we introduce into the container enough nitrogen gas to give a pressure of 0.40 atm at the same temperature. Dalton wondered what the total pressure would be if these same amounts of the two gases were present in the container simultaneously. From some fairly crude measurements, he concluded that the total pressure resulting from the pressure of both gases in the same container would be 1.00 atm, the sum of the individual pressures. Dalton summarized his observations in terms of the partial pressure of each gas, the pressure that the gas would exert if it occupied the container alone. In our example, the partial pressures of oxygen and nitrogen in the mixture are 0.60 atm and 0.40 atm, respectively, because those are the pressures that the gases exert when each one is in the container alone. Dalton then described the behavior of gaseous mixtures by his law of partial pressures: The total pressure of a mixture of gases is the sum of the partial pressures of its components. If we denote the partial pressures of the gases A, B, . . . as PA, PB, . . . and the total pressure of the mixture as P, then we can write Dalton’s law as follows: (11)* The law is illustrated in Fig. 4.19. It is exactly true only for gases that behave ideally, but it is a good approximation for nearly all gases under normal conditions. Dalton’s law is consistent with our model of a gas and adds a little more information. The total pressure of a gas arises, as we have seen, from the battering of the molecules on the walls of the container. That battering is due to all the molecules in a mixture. The molecules of gas A exert a pressure, the molecules of gas B do, too, and the total pressure is the sum of these individual pressures. The additional piece of information that we can use to expand our model is that, for the total pressure to be the sum of the individual contributions, the A molecules must be blind to the presence of the B molecules. That is, there are no interactions—neither attractions nor repulsions—between the two kinds of molecules except during their very brief collisions. Later, we shall see that the absence of such interactions is a characteristic feature of an ideal gas. We use partial pressures to describe the composition of a humid gas. For example, the total pressure of the damp air in our lungs is P ϭ Pdry air ϩ Pwater vapor In a closed container, to which a lung is a good first approximation, water vaporizes until its partial pressure has reached a certain value, called its vapor pressure. The vapor pressure of water at normal body temperature is 47 Torr. The partial pressure of the air itself in our lungs is therefore Pdry air ϭ P Ϫ Pwater vapor ϭ P Ϫ 47 Torr On a typical day, the total pressure at sea level is 760. Torr; so at sea level the pressure in our lungs due to all the gas except the water vapor is 760. Ϫ 47 Torr ϭ 713 Torr. Thinking point: Is damp air more dense or less dense than dry air under the same conditions? P = PA + PB + p 4.8 MIXTURES OF GASES 149 This is the same Dalton whose contribution to atomic theory we met in Section B. P ϭ PA ϩ PB ϭ 1.0 atm PB ϭPA ϭ 0.4 atm0.6 atm FIGURE 4.19 A representation of the experiment that Dalton performed on a gas mixture. According to Dalton’s law, the total pressure, P, of a mixture of gases is the sum of the partial pressures PA and PB of gases A and B. Each partial pressure is the pressure that one of the gases would exert if it were the sole gas in the container (at the same temperature). Self-Test 4.13A As a sample of oxygen was collected over water at 24ЊC and 745 Torr, it became saturated with water vapor. At this temperature, the vapor pressure of water is 24.38 Torr. What is the partial pressure of the oxygen? [Answer: 721 Torr] Self-Test 4.13B Students collecting hydrogen and oxygen gases by electrolysis of water failed to separate the two gases. If the total pressure of the dry mixture is 720. Torr, what is the partial pressure of each gas? A good way to express the relation between the total pressure of a mixture and the partial pressures of its components is to use the mole fraction, x, of each component A, B, . . . , the number of moles of molecules of the gas expressed as a fraction of the total number of moles of molecules in the sample. If the amounts of gas molecules present are nA, nB, and so forth, the mole fraction of A is (12)* and likewise for the mole fractions of the other components. This expression is used to calculate the mole fraction of each component of the mixture. In a binary (twocomponent) mixture of gases A and B, (13) When xA ϭ 1, the mixture is pure A; when xB ϭ 1, the mixture is pure B. When xA ϭ xB ϭ 0.50, half the molecules are A and half are B (Fig. 4.20). Our task is to find the relation between the partial pressure of a gas and its mole fraction. xA + xB = nA nA + nB + nB nA + nB = nA + nB nA + nB = 1 xA = nA n = nA nA + nB + Á 150 CHAPTER 4 THE PROPERTIES OF GASES xRED ϭ 0.1 xRED ϭ 0.5 xRED ϭ 0.9 FIGURE 4.20 A mole fraction, x, tells us the fraction of molecules of a particular kind in a mixture of two or more kinds of molecules. In this illustration, the mole fraction of A molecules, which are colored red, is given below each mixture; the B molecules are colored yellow. The mixture can be solid or liquid as well as gaseous. HOW DO WE DO THAT? To find the relation between the partial pressure of a gas in a mixture and its mole fraction, we first express the partial pressure, PA, of a gas A in terms of the amount of A molecules present, nA, the volume, V, occupied by the mixture, and the temperature, T: Because nA ϭ nxA (where n is the total amount of all gases) and P ϭ nRT/V, The relation that we have derived for the partial pressure of a gas A is (14)* where P is the total pressure and xA is the mole fraction of A in the mixture. In modern applications, Eq. 14 is regarded as the definition of the partial pressure of a gas, ideal or real. PA = xAP PA = nxART V = xA nRT V = xAP PA = nART V EXAMPLE 4.7 Calculating partial pressures Air is a source of reactants for many chemical processes. To determine how much air is needed for these reactions, it is useful to know the partial pressures of the components. A certain sample of dry air of total mass 1.00 g consists almost entirely of 0.76 g of nitrogen and 0.24 g of oxygen. Calculate the partial pressures of these gases when the total pressure is 0.87 atm. Anticipate The molar masses of N2 and O2 are very similar, so very approximately we should expect the amounts of N2 and O2 to be in the ratio of the masses present, which is 0.76:0.24. The partial pressures should be in the same ratio, or about 3:1. PLAN To use Eq. 14, we need the total pressure (given) and the mole fraction of each component. The first step is to calculate the amount (in moles) of each gas present and the total amount (in moles). Then calculate the mole fractions from Eq. 12. To obtain the partial pressures of the gases, multiply the total pressure by the mole fractions of the gases in the mixture (Eq. 14). SOLVE 4.8 MIXTURES OF GASES 151 Use their molar masses to find the amounts (in moles) of each gas present. nO2 = 0.24 g 32.00 gиmol-1 = 0.24 32.00 mol (= 0.0075 mol) nN2 = 0.76 g 28.02 gиmol-1 = 0.76 28.02 mol (= 0.027 mol) Find the total amount of gas molecules from n ϭ nA ϩ nB: nN2 + nO2 = 0.76 28.02 + 0.24 32.00 mol (= 0.035 mol) O2 N2 Calculate the mole fractions from xA ϭ nA/n: xO2 = 0.24/32.02 0.76/28.02 + 0.24/32.00 = 0.22 xN2 = 0.76/28.02 0.76/28.02 + 0.24/32.00 = 0.78 0.19 0.68 Multiply each mole fraction by the total pressure, PA ϭ xAP: PO2 = 0.22 * (0.87 atm) = 0.19 atm PN2 = 0.78 * (0.87 atm) = 0.68 atm Evaluate As expected, is about three times . A check of the calculation against given information shows that 0.68 ϩ 0.19 atm ϭ 0.87 atm, as in the data. Self-Test 4.14A A baby with a severe bronchial infection is in respiratory distress. The anesthetist administers heliox, a mixture of helium and oxygen with 92.3% by mass O2. What is the partial pressure of oxygen being administered to the baby if atmospheric pressure is 730 Torr? [Answer: 4.4 ϫ 102 Torr] Self-Test 4.14B Divers exploring a shipwreck and wishing to avoid the narcosis associated with breathing nitrogen under high pressure switch to a neon–oxygen gas mixture containing 141.2 g of oxygen and 335.0 g of neon. The pressure in the gas tanks is 50.0 atm. What is the partial pressure of oxygen in the tanks? The partial pressure of a gas is the pressure that it would exert if it were alone in the container; the total pressure of a mixture of gases is the sum of the partial pressures of the components; the partial pressure of a gas is related to the total pressure by the mole fraction: PA ϭ xAP. PO2 PN2 MOLECULAR MOTION The empirical results summarized by the gas laws suggest a model of an ideal gas in which widely spaced (most of the time), noninteracting (except during collisions) molecules undergo ceaseless motion, with average speeds that increase with temperature. In the next three sections, we refine our model in two steps. First, we use experimental measurements of the rate at which gases spread from one region to another to gather information about the average speeds of molecules. Then we use this information to set up a quantitative version of our model. 4.9 Diffusion and Effusion Observations of two processes, diffusion and effusion, provide data that show how the average speeds of gas molecules are related to molar mass and temperature. Diffusion is the gradual dispersal of one substance through another substance, such as krypton dispersing through a neon atmosphere (Fig. 4.21). Diffusion explains the spread of perfumes and pheromones (chemical signals exchanged by animals) through air. It also helps to keep the composition of the atmosphere approximately uniform. Effusion is the escape of a gas through a small hole into a vacuum (Fig. 4.22). Effusion occurs whenever a gas is separated from a vacuum by a porous barrier—a barrier that contains microscopic holes—or even a single pinhole, as in a punctured tire. A gas escapes through a pinhole because there are more “collisions” with the hole on the highpressure side than on the low-pressure side, and so more molecules pass from the highpressure region into the low-pressure region than pass in the opposite direction. Effusion is easier to treat than diffusion, so we concentrate on it; but similar remarks apply to diffusion too. The nineteenth-century Scottish chemist Thomas Graham carried out a series of experiments on the rates of effusion of gases. He found that, At constant temperature, the rate of effusion of a gas is inversely proportional to the square root of its molar mass: (15a) This observation is now known as Graham’s law of effusion. The rate of effusion is proportional to the average speed of the molecules in the gas because that speed determines the rate at which molecules approach the hole. Therefore, we can conclude that (15b) This relation is an important clue about the motion of molecules in a gas and we shall use it shortly, but first we look at some practical applications of Graham’s law. If we were to write Graham’s law for two gases A and B with molar masses MA and MB, and divide one equation by the other, we would obtain (16a)* Because the times it takes for the same amount of two substances to effuse through a small hole are inversely proportional to the rates at which they effuse, an equivalent statement is (16b) This relation can be used to estimate the molar mass of a substance by comparing the time required for a given amount of the unknown substance to effuse with that required for the same amount of a substance with a known molar mass. Time for A to diffuse Time for B to diffuse = A MA MB Rate of effusion of A molecules Rate of effusion of B molecules = 1/2MA 1/2MB = A MB MA Average speed r 1 2M Rate of effusion r 1 2molar mass or Rate of effusion r 1 2M 152 CHAPTER 4 THE PROPERTIES OF GASES Time FIGURE 4.21 In diffusion, the molecules of one substance spread into the region occupied by molecules of another in a series of random steps, undergoing collisions as they move. FIGURE 4.22 In effusion, the molecules of one substance escape through a small hole in a barrier into a vacuum or a region of low pressure. Self-Test 4.15A It takes 30. mL of argon 40. s to effuse through a porous barrier. The same volume of vapor of a volatile compound extracted from Caribbean sponges takes 120. s to effuse through the same barrier under the same conditions. What is the molar mass of this compound? [Answer: 3.6 ϫ 102 gиmolϪ1 ] Self-Test 4.15B It takes a certain amount of helium atoms 10. s to effuse through a porous barrier. How long does it take the same amount of methane, CH4, molecules to effuse through the same barrier under the same conditions? We have seen that effusion reveals that the average speed of molecules in a gas is inversely proportional to the square root of their molar mass. In effusion experiments at different temperatures, we find that the rate of effusion increases as the temperature is raised. Specifically, for a given gas, The rate of effusion increases as the square root of the temperature: (17a) Because the rate of effusion is proportional to the average speed of the molecules, we can infer that The average speed of molecules in a gas is proportional to the square root of the temperature: (17b) This very important relation begins to reveal the significance of one of the most elusive concepts in science: the nature of temperature. We see that, when referring to a gas, the temperature is an indication of the average speed of the molecules, and the higher the temperature, the higher the average speed of the molecules. We can combine the two relations that we have found. Because the average speed of molecules in a gas is proportional to the square root of the temperature (Eq. 17b) and inversely proportional to the square root of the molar mass (Eq. 15b), we can write (18) That is, the higher the temperature and the lower the molar mass, the higher is the average speed of molecules in a gas. The average speed of molecules in a gas is directly proportional to the square root of the temperature and inversely proportional to the square root of the molar mass. 4.10 The Kinetic Model of Gases We now have enough information to turn our qualitative ideas about a gas into a quantitative model that can be used to make numerical predictions. The kinetic model (“kinetic molecular theory,” KMT) of a gas is based on four assumptions (Fig. 4.23): 1 A gas consists of a collection of molecules in continuous random motion. 2 Gas molecules are infinitesimally small points. 3 The molecules move in straight lines until they collide. 4 The molecules do not influence one another except during collisions. The fourth assumption means that we are proposing, as part of the model, that there are no attractive forces between ideal gas molecules and no repulsive forces between them except during collisions. Average speed r A T M Average speed r 2T Rate of effusion at T2 Rate of effusion at T1 = A T2 T1 4.10 THE KINETIC MODEL OF GASES 153 FIGURE 4.23 In the kinetic model of gases, the molecules are regarded as infinitesimal points that travel in straight lines until they undergo instantaneous collisions. In this context, “molecules” includes all types of particles, whether atoms, ions, or molecules. In the kinetic model of gases, we picture the molecules as widely separated for most of the time and in ceaseless random motion. They zoom from place to place, always in straight lines, changing direction only when they collide with a wall of the container or another molecule. The collisions change the speed and direction of the molecules, just like balls in a three-dimensional cosmic game of pool. In Section 4.4, we used a molecular model of a gas to explain qualitatively why the pressure of a gas rises as the temperature is increased: as a gas is heated, its molecules move faster and strike the walls of their container more often. The kinetic model of a gas allows us to derive the quantitative relation between pressure and the speeds of the molecules. 154 CHAPTER 4 THE PROPERTIES OF GASES HOW DO WE DO THAT? The following calculation of the pressure of a gas based on the kinetic model may seem complicated at first, but it breaks down into a series of small steps, each of which can be interpreted physically. We begin with the gas sample illustrated in Fig. 4.24 and initially suppose that all the molecules are traveling at the same speed; we remove that constraint later. The molecules strike the wall on the right. If we know how often these impacts occur and what force they exert on the wall, we can calculate the pressure (which is force divided by area) that results. To calculate the force exerted by a single molecule, we use Newton’s second law of motion: force is equal to the rate of change of momentum of a particle (Section A). Momentum is the product of mass and velocity; so, if a molecule of mass m is traveling with a velocity vx parallel to the side of the box that we are calling x, then its linear momentum before it strikes the wall on the right is mvx. Immediately after the collision, the momentum of the molecule is Ϫmvx because the velocity has changed from vx to Ϫvx. We have assumed that the collision is “elastic,” which means that no energy is transferred to the wall and therefore that the speed of the molecule is the same after the collision as it was before. x FIGURE 4.24 In the kinetic model of gases, the pressure arises from the force exerted on the walls of the container when the impacting molecules are deflected. We need to know the force of each impact and the number of impacts in a given time interval. Before, mvx After, Ϫmvx The change in momentum of one molecule: 2mvx Next, we calculate the number of molecules that can strike the wall in a time interval ⌬t. vx⌬t All the molecules within a distance vx⌬t of the wall and traveling toward it will strike the wall during the interval ⌬t. vx⌬t Area, A If the wall has area A, all the particles in a volume Avx⌬t will reach the wall if they are traveling toward it. Suppose that the total number of particles in the container is N and that the volume of the container is V. Because a gas fills its container, we know that the molecules are spread evenly throughout the container. Therefore, Half the molecules in the box are moving toward the wall on the right and half are moving away from that wall. Therefore, 4.10 THE KINETIC MODEL OF GASES 155 The number of molecules in the volume Avx⌬t is that fraction of the total volume V, multiplied by the total number of molecules: Number of molecules = Avx¢t V * N = NAvx¢t V No Yes The average number of collisions with the wall during the interval ⌬t is half the number in the volume Avx⌬t: Number of collisions = NAvx¢t 2V We have calculated the momentum of one molecule and the number of collisions during the interval ⌬t. Now we bring the parts of the calculation together. The total momentum change of the molecules in that interval is the change 2mvx that an individual molecule undergoes multiplied by the total number of collisions: At this point, we calculate the rate of change of momentum by dividing this total momentum change by the time interval during which it occurs (⌬t) and use Newton’s second law that the force is equal to the rate of change of momentum: Total momentum change = NAvx¢t 2V * 2mvx = NmAvx 2 ¢t V ⌬t From Rate of change of momentum ϭ (total momentum change)͞⌬t, Rate of change of momentum = NmAvx 2 ¢t V¢t = NmAvx 2 V F ϭ NmAvx 2 /V From Newton’s second law, Force = rate of change of momentum = NmAvx 2 V F ϭ NmAvx 2 /V A From Pressure ϭ force/area, Pressure = NmAvx 2 VA = Nmvx 2 V Not all the molecules in the sample are traveling at the same speed. To obtain the detected pressure, P, we need to use the average value of vx 2 in place of vx 2 for each individual molecule. Averages are commonly denoted by angular brackets; so we write P = Nm8vx 2 9 V where ͗vx 2 ͘ is the average value of vx 2 for all the molecules in the sample. At this stage, we relate ͗vx 2 ͘ to the root mean square speed, vrms ϭ ͗v2 ͘1/2 , the square root of the average of the squares of the molecular speeds (this quantity is explained in more detail in the text following this derivation). First, we note that the speed, v, of a single molecule is related to the velocity parallel to the x, y, and z directions: 156 CHAPTER 4 THE PROPERTIES OF GASES v vz vx vy From the Pythagorean theorem, v2 ϭ vx 2 ϩ vy 2 ϩ vz 2 Therefore, the mean square speed is given by vrms 2 ϭ ͗v2 ͘ ϭ ͗vx 2 ϩ vy 2 ϩ vz 2 ͘ ϭ ͗vx 2 ͘ ϩ ͗vy 2 ͘ ϩ ͗vz 2 ͘ However, because the particles are moving randomly, the average of vx 2 is the same as the average of vy 2 and the average of vz 2 , the analogous quantities in the y and z directions. Because ͗vx 2 ͘, ͗vy 2 ͘, and ͗vz 2 ͘ are all equal, we know that ͗v2 ͘ ϭ 3͗vx 2 ͘; therefore, ͗vx 2 ͘ ϭ vrms 2 . It follows that The total number of molecules, N, is the product of the amount, n, and Avogadro’s constant, NA (N ϭ nNA) so the last equation becomes where m is the mass of one molecule and M ϭ mNA is the molar mass of the molecules. We have deduced that the pressure of a gas and the volume are related by (19) where n is the amount (in moles) of gas molecules, M is their molar mass, and vrms is the root mean square speed of the molecules. As remarked in the preceding derivation, the root mean square speed, vrms, is the square root of the average value of the squares of the molecular speeds. If there are N molecules in the sample and the speeds of these molecules at some instant are v1, v2, . . . , vN, then the root mean square speed is (20) Thinking point: What is the average velocity of the molecules? We can now use the ideal gas law, derived from observations of the bulk properties of gases, to calculate the root mean square speed of the molecules of a gas. We know that PV ϭ nRT for an ideal gas; therefore, we can set the right-hand side of Eq. 19 equal to nRT and rearrange the resulting expression ( nNvrms 2 ϭ nRT) into (21a)* This important result is used to find the root mean square speeds of the gas-phase molecules at any temperature (Fig. 4.25). We can rewrite this equation to emphasize that, for a gas, the temperature is a measure of mean molecular speed. From vrms 2 ϭ 3RT/M, it follows that (21b)T = Mvrms 2 3R vrms = a 3RT M b 1>2 1 3 vrms = a v2 1 + v2 2 + Á + v2 N N b 1>2 PV = 1 3nMvrms 2 P = nNAmvrms 2 3V = nMvrms 2 3V P = Nmv2 rms 3V 1 3 The importance of the root mean square speed stems from the fact that vrms 2 is proportional to the average kinetic energy of the molecules, 8Ek9 = 1 2m8v2 9 = 1 2mv2 rms. That is, The temperature is proportional to the mean square speed of the molecules in a gas. Thinking point: How is the root mean square speed of a molecule related to its molar mass? 4.11 THE MAXWELL DISTRIBUTION OF SPEEDS 157 Carbon dioxide Oxygen Nitrogen Water Hydrogen 410 480 515 640 1930 FIGURE 4.25 The root mean square speeds of five gases at 25°C, in meters per second. The gases are some of the components of air; hydrogen is included to show that the root mean square speed of light molecules is much greater than that of heavier molecules. EXAMPLE 4.8 Calculating the root mean square speed of gas molecules What is the root mean square speed of nitrogen molecules in air at 20.ЊC? Anticipate Because a sound wave is propagated by the movement of molecules, we can suspect that typical speeds are about the same as the speed of sound in air. That is about 300 mиsϪ1 . PLAN For the actual calculation, we substitute the data into Eq. 21a. In KMT calculations, use R in SI units and molar masses in SI base units, namely kilograms per mole. SOLVE The temperature is 293 K and the molar mass of N2 is 28.02 gиmolϪ1 (corresponding to 2.802 ϫ 10Ϫ2 kgиmolϪ1 ). vrms 0 0 293KTemperature, T 511 m·sϪ1 From vrms ϭ (3RT/M)1/2 , = 511 mиs-1 vrms = a 3 * (8.3145 JиK-1 иmol-1 ) * (293 K) 2.802 * 10-2 kgиmol-1 b 1/2 Evaluate This result, vrms ϭ 511 mиsϪ1 , is close to the speed of sound in air, as we anticipated. It means that nitrogen molecules are zooming about your head at about 1140 miles per hour. A note on good practice: We use SI units throughout: R is in its fundamental SI form and the molar mass is in SI base units to be consistent with the choice for R. The cancellation of the units has made use of the relation 1 J ϭ 1 kgиm2 иsϪ2 . Self-Test 4.16A Estimate the root mean square speed of water molecules in the vapor above boiling water at 100.ЊC. [Answer: 719 mиsϪ1 ] Self-Test 4.16B Estimate the root mean square speed of CH4 molecules at 25ЊC. The kinetic model of gases is consistent with the ideal gas law and provides an expression for the root mean square speed of the molecules. Root mean square speeds of gas molecules are proportional to the square root of the temperature. 4.11 The Maxwell Distribution of Speeds Useful as it is, Eq. 21a gives only the root mean square speed of gas molecules. Like cars in traffic, individual molecules have speeds that vary over a wide range. Moreover, like a car in a head-on collision, a molecule might be brought almost to a standstill when it collides with another. In the next instant (but now unlike a colliding car), it might be struck by another molecule and move off at the speed of sound. An individual molecule undergoes several billion changes of speed and direction each second. The formula for calculating the fraction of gas molecules having a given speed, v, at any instant was first derived from the kinetic model by the Scottish scientist James Clerk Maxwell. He derived the expression (22)¢N = Nf(v)¢v with f(v) = 4␲a M 2␲RT b 3/2 v2 e-Mv2 /2RT where ⌬N is the number of molecules with speeds in the narrow range between v and v ϩ ⌬v, N is the total number of molecules in the sample, M is the molar mass, and R is the gas constant. This expression for f(v) is the Maxwell distribution of speeds (Box 4.1). What does this equation tell us? The exponential factor (which falls rapidly toward zero as v increases) means that very few molecules have very high speeds. The factor v2 that multiplies the exponential factor goes to zero as v goes to zero, so it means that very few molecules have very low speeds. The factor 4␲(M/2␲RT)3/2 simply ensures that the total probability of a molecule having a speed between zero and infinity is 1. Figure 4.26 shows a plot of the Maxwell distribution against speed for several different gases. We see that heavy molecules (of molar mass 100 gиmolϪ1 , for instance) travel with speeds close to their average values. Light molecules (of 20 gиmolϪ1 , for instance) not only have a higher average speed but also a wider range of speeds. Some molecules of gases with low molar masses have such high speeds that they can escape from the gravitational pull of small planets and go off into space. As a consequence, hydrogen molecules and helium atoms, which are both very light, are rare in the Earth’s atmosphere, although they are abundant on massive planets such as Jupiter. A plot of the Maxwell distribution for the same gas at several different temperatures shows that the average speed increases as the temperature is raised (Fig 4.27). We knew that from our observations of gas behavior (Section 4.9); but the curves also show that the spread of speeds widens as the temperature increases. At low temperatures, most molecules of a gas have speeds close to the average speed. At high temperatures, a 158 CHAPTER 4 THE PROPERTIES OF GASES The distribution of molecular speeds in a gas can be determined experimentally in a molecular beam apparatus. In this technique, the gas is heated to the required temperature in an oven. The molecules then stream out of the oven through a small hole into an evacuated region. To ensure that the molecules form a narrow beam, they may also pass through a series of slits, and the pressure must be kept very low so that collisions within the beam do not cause spreading. The molecular beam passes through a series of rotating disks (see diagram). Each disk contains a slit that is offset by a certain angle from its neighbor. A molecule that passes through the first slit will pass through the slit in the next disk only if the time that it takes to pass between the disks is the same as the time required for the slit in the second disk to move into the HOW DO WE KNOW . . . THE DISTRIBUTION OF MOLECULAR SPEEDS?BOX 4.1 Slit Detector Source Molecular beam Diagram of the rotating disks that serve as a velocity selector in a molecular beam apparatus. orientation originally occupied by the first disk. The two times must continue to match if the same molecule is to pass through subsequent disks. Therefore, a particular rate of rotation of the disks allows the passage of only those molecules having the speed that carries them through the slits. To determine the distribution of molecular speeds, we would measure the intensity of the beam of molecules arriving at the detector for different rotational rates of the disks. A typical result is shown in the graph, and we see that it is a good match to the theoretical Maxwell expression (see Figs. 4.26 and 4.27). The points represent a typical result of a molecular speed distribution measurement. They are superimposed on the theoretical curve. To obtain the fraction of molecules with speeds in the range from v to v ϩ ⌬v, multiply f (v) by ⌬v. 0.02 0.015 0.025 0.01 0.005 0 0 100 200 400 600300 500 At 100 K Speed, v (m·sϪ1 ) Fraction,(v)(m·sϪ1 ) 0 600500400300200100 0.020 0.015 0.010 0.005 0 Speed (m⋅s−1 ) Fraction,f(v)(m−1 ⋅s) 100 g⋅mol−1 50 g⋅mol−1 20 g⋅mol−1 FIGURE 4.26 The range of molecular speeds for three gases, as given by the Maxwell distribution. All the curves correspond to the same temperature (300 K). The greater the molar mass, the lower the average speed and the narrower the spread of speeds. To obtain the fraction of molecules with speeds in the range from v to v ϩ ⌬v, multiply f (v) by ⌬v. Living Graphs 4.26 high proportion have speeds widely different from their average speed. Because the kinetic energy of a molecule in a gas is proportional to the square of its speed, the distribution of molecular kinetic energies follows the same trends. Thinking point: Which term in Maxwell’s equation causes the broadening of the curve, (the shift of the peak to the right) as the temperature increases? The molecules of all gases have a wide range of speeds. As the temperature increases, the root mean square speed and the range of speeds both increase. The range of speeds is described by the Maxwell distribution, Eq. 22. REAL GASES In industry and in many research laboratories, gases must be used under high pressures, when the ideal gas law is not followed closely. Recall that the ideal gas law is a limiting law, valid only as P : 0. All actual gases, which are called real gases, have properties that differ from those predicted by the ideal gas law. These differences are significant at high pressures and low temperatures. We first explore the experimental evidence for those differences and then relate the behavior of real gases to the properties of their molecules. We then consider some of the implications of the nonideal behavior of gases and how that behavior can be described mathematically, which brings us to the final, refined version of our model of gases. 4.12 Deviations from Ideality Two types of observations, one qualitative and the other quantitative, show that our model of a gas must be refined. The qualitative observation is that gases can be condensed to liquids when cooled or compressed. This property strongly suggests that, contrary to the assumptions of the kinetic model, gas molecules do attract one another because otherwise they would not cohere (stick together). In addition, liquids are very difficult to compress. This observation strongly suggests that powerful repulsive forces must prevent molecules from being squashed together into a tiny volume. The presence of attractive and repulsive forces implies that once again the kinetic model must be refined. We can assess the effect of intermolecular forces quantitatively by comparing the behavior of real gases with that expected of an ideal gas. One of the best ways of exhibiting these deviations is to measure the compression factor, Z, the ratio of the actual molar volume of the gas to the molar volume of an ideal gas under the same conditions: (23) The compression factor of an ideal gas is 1, and so deviations from Z ϭ 1 are a sign of nonideality. Figure 4.28 shows the experimental variation of Z for a number of gases. We see that all gases deviate from Z ϭ 1 as the pressure is raised. Our model of gases must account for these deviations. All deviations from ideal behavior can be explained by the presence of intermolecular forces, or attractions and repulsions between molecules. Sections 5.1 through 5.5 describe the origin of intermolecular forces. Here, all we need to know is that all molecules attract one another when they are a few molecular diameters apart but (provided they do not react) repel one another as soon as their electron clouds come into contact. Figure 4.29 shows how the potential energy of a molecule varies with its distance from a second molecule. At moderate separations, its potential energy is lower than when it is infinitely far away: attractions always lower the potential energy of an object. As the molecules come into contact, the potential energy starts to rise, because repulsions always increase the potential energy of an object. The presence of attractive intermolecular forces accounts for the condensation of gases to liquids when they are compressed or cooled. Compression reduces the average Z = Vm Vm ideal 4.12 DEVIATIONS FROM IDEALITY 159 FIGURE 4.27 The Maxwell distribution again, but now the curves correspond to the speeds of a single substance (of molar mass 50 g·molϪ1 ) at different temperatures. The higher the temperature, the higher the average speed and the broader the spread of speeds. Living Graph 4.27 FIGURE 4.28 A plot of the compression factor, Z, as a function of pressure for a variety of gases. An ideal gas has Z ϭ 1 for all pressures. For a few real gases with very weak intermolecular attractions, such as H2, Z is always greater than 1. For most gases, at low pressures the attractive forces are dominant and Z Ͻ 1 (see inset). At high pressures, repulsive forces become dominant and Z Ͼ 1 for all gases. 1.00 0.98 0.96 10 H2 H2 CH4 CH4 C2H4 C2H4 NH3 NH3 P, atm 2.0 1.0 0 200 400 600 800 Ideal gas Compressionfactor,Z Pressure, atm Living Graph 4.28 0 600500400300200100 0.020 0.015 0.010 0.005 0 Speed (m⋅s−1) Fraction,f(v)(m−1 ⋅s) 100 K 500 K 300 K separation of the molecules, and neighboring molecules can be captured by one another’s attraction, provided that they are traveling slowly enough (that is, the sample is cool enough). The low compressibility of liquids and solids is consistent, as we have seen, with the presence of strong repulsive forces when molecules are pushed together. Another way to describe the repulsive forces between molecules is to say that molecules have definite volumes. When you touch a solid object, you feel its size and shape because your fingers cannot penetrate into it. The resistance to compression offered by the solid is due to the repulsive forces exerted by its atoms on the atoms in your fingers. The presence of intermolecular forces also accounts for the variation in the compression factor. Thus, for gases under conditions of pressure and temperature such that Z Ͼ 1, the repulsions are more important than the attractions. Their molar volumes are greater than expected for an ideal gas because repulsions tend to drive the molecules apart. For example, a hydrogen molecule has so few electrons that its molecules are only very weakly attracted to one another. For gases under conditions of pressure and temperature such that Z Ͻ 1, the attractions are more important than the repulsions, and the molar volume is smaller than for an ideal gas because attractions tend to draw molecules together. To improve our model of a gas, we need to add to it that the molecules of a real gas exert attractive and repulsive forces on one another. Real gases consist of atoms or molecules with intermolecular attractions and repulsions. Attractions have a longer range than repulsions. The compression factor is a measure of the strength and type of intermolecular forces. When Z Ͼ 1, intermolecular repulsions are dominant; when Z Ͻ 1, attractions are dominant. 4.13 The Liquefaction of Gases As described in Section 4.12, at low temperatures, molecules of a real gas move so slowly that intermolecular attractions may result in one molecule being captured by others and sticking to them instead of moving freely. When the temperature falls below the boiling point of the substance, the gas condenses to a liquid (Fig. 4.30). Gases can also be liquefied by making use of the relation between temperature and molecular speed. Because lower average speed corresponds to lower temperature, slowing the molecules is equivalent to cooling the gas. The molecules of a real gas can be slowed by making use of the attractions between them and allowing the gas to expand: the molecules have to climb away from one another’s attractive forces when a gas expands, rather like a ball rising up above the surface of the Earth against the pull of gravity (Fig. 4.31). Therefore, allowing the gas to occupy a larger volume, and hence increasing the average separation of the molecules, results in the molecules having a lower average speed. In other words, provided attractive effects are dominant, a real gas cools as it expands. This observation is called the Joule–Thomson effect in honor of the scientists who first studied it, James Joule and William Thomson (later to become Lord Kelvin), the inventor of the absolute temperature scale. The Joule–Thomson effect is used in some commercial refrigerators to liquefy gases. The gas to be liquefied is compressed and then allowed to expand through a small hole, called the throttle. The gas cools as it expands, and the cooled gas circulates past the incoming compressed gas (Fig. 4.32). This contact cools the incoming gas before it expands and cools still further. As the gas is continually recompressed and recirculated, its temperature progressively falls until finally it condenses to a liquid. If the gas is a mixture, such as air, then the liquid that it forms can later be distilled to separate its components. This technique is used for harvesting nitrogen, oxygen, neon, argon, krypton, and xenon from the atmosphere. Many gases can be liquefied by making use of the Joule–Thomson effect, cooling brought about by expansion. 160 CHAPTER 4 THE PROPERTIES OF GASES FIGURE 4.30 Chlorine can be condensed to a liquid at atmospheric pressure by cooling it to Ϫ35°C or lower. Here chlorine gas is introduced to the lower flask. The upper flask contains a “cold finger,” a smaller tube filled with dry ice in acetone at Ϫ78°C, on which the chlorine condenses. Exceptions are helium and hydrogen, which have very weak attractive interactions and relatively strong repulsive interactions; at room temperature, they get warmer as they expand. Potentialenergy,EP Separation FIGURE 4.29 Variation in the potential energy of a molecule as it approaches another molecule. The potential energy rises sharply once the two molecules come into direct contact. Living Graph 4.29 4.14 Equations of State of Real Gases How do we describe the behavior of real gases that do not obey the ideal gas law? A common procedure in chemistry is to suppose that the term on the right-hand side of an equation (such as nRT in PV ϭ nRT of the ideal gas law) is just the leading (and predominant) term of a more complicated expression. Thus, to extend the ideal gas law to real gases, one procedure is to write (24) This expression is called the virial equation. The coefficients B, C, . . . are called the second virial coefficient, third virial coefficient, and so on. The virial coefficients, which depend on the temperature, are found by fitting experimental data to the virial equation. Although the virial equation can be used to make accurate predictions about the properties of a real gas, provided that the virial coefficients are known for the temperature of interest, it is not a source of much insight without a lot of advanced analysis. An equation that is less accurate but easier to interpret was proposed by the Dutch scientist Johannes van der Waals. The van der Waals equation is (25) The temperature-independent van der Waals parameters a and b are unique for each gas and are determined experimentally (Table 4.5). Parameter a represents the role of attractions; so it is relatively large for molecules that attract each other strongly and for large molecules with many electrons. Parameter b represents the role of repulsions; it can be thought of as representing the volume of an individual molecule (more precisely, the volume per mole of molecules), because it is the repulsive forces between molecules that prevent one molecule from occupying the space already occupied by another molecule. The roles of the parameters become clearer when we write the compression factor as and substitute the van der Waals’ expression for P, which is obtained by dividing each side by V Ϫ nb and then subtracting an2 /V2 from both sides: (26) We obtain Z = V nRT * a nRT V - nb - a n2 V2 b = V V - nb - an RTV P = nRT V - nb - a n2 V2 Z = V/n RT/P = PV nRT aP + a n2 V2 b(V - nb) = nRT PV = nRT a1 + B Vm + C Vm 2 + Á b 4.14 EQUATIONS OF STATE OF REAL GASES 161 Slows Slows FIGURE 4.31 Cooling by the Joule–Thomson effect can be visualized as a slowing of the molecules (here shown blue) as they climb away from each other (in this case, from the one shown red) against the force of attraction between them. Compressor Throttle Liquefied gas Gas Heat exchanger FIGURE 4.32 A Linde refrigerator for liquefying gases. The compressed gas gives up heat to the surroundings in the heat exchanger (left) and passes through the coil (right). The gas is cooled still further by the Joule–Thomson effect as it emerges through the throttle. This gas cools the incoming gas and is recirculated through the system. Eventually, the temperature of the incoming gas is so low that it condenses to a liquid. The name “virial” comes from the Latin word meaning “force.” TABLE 4.5 Van der Waals Parameters Gas a (L2 ·atm·mol؊2 ) b (10؊2 L·mol؊1 ) ammonia 4.169 3.71 argon 1.337 3.20 benzene 18.57 11.93 carbon dioxide 3.610 4.29 chlorine 6.260 5.42 ethane 5.507 6.51 hydrogen 0.2420 2.65 hydrogen sulfide 4.484 4.34 oxygen 1.364 3.19 water 5.464 3.05 When we divide the numerator and denominator of the first term on the right of the final expression by V we obtain (27) What does this equation tell us? For an ideal gas, a and b are both zero, and Z ϭ 1. We see that Z Ͼ 1 when the attractive contribution (a) is small so the second term on the right can be neglected and the repulsive contribution (b) is appreciable, so the denominator in the first term is less than 1 and the term itself is greater than 1. Conversely, Z Ͻ 1 when the repulsive contribution is weak (b is small) and the attractive interaction is strong (a is large), so the first term on the right is close to 1 and the second term on the right subtracts significantly from it. The values of a and b for a gas are found experimentally by fitting this expression for Z to curves like those in Fig. 4.28. Once the parameters have been determined, they can be used in the van der Waals equation to predict the pressure of the gas under the conditions of interest. Z = 1 1 - nb/V - an RTV 162 CHAPTER 4 THE PROPERTIES OF GASES EXAMPLE 4.9 Estimating the pressure of a real gas Investigators are studying the physical properties of a gas to be used as a refrigerant in an air-conditioning unit. A table of van der Waals parameters shows that for this gas a ϭ 16.2 L2 иatmиmolϪ2 and b ϭ 8.4 ϫ 10Ϫ2 LиmolϪ1 . Estimate the pressure of the gas when 1.50 mol occupies 5.00 L at 0ЊC. Anticipate In most gases under normal conditions, the attractive interaction dominates the repulsive (the clue is in Fig. 4.28, which shows that the compression factor is less than 1 at low pressures for most gases). So, we should suspect that the pressure we calculate will be less than that based on an ideal gas, but small, because real gases typically show only small deviations from ideal behavior. PLAN Substitute the data into Eq. 26 after converting the temperature into the Kelvin scale, if necessary. Use R in units that match those given. SOLVE 0 0 2 4 6 8 10 20 30 5.00 L Ideal 5.44 atm V, L P,atm From P ϭ nRT/(V Ϫ nb) Ϫ an2 /V2 , = 5.44 atm = 1.50 * (0.082 06 atm) * 273 500 - 1.50 * 8.4 * 10-2 - (16.2 atm) * (1.50)2 (5.00)2 - (16.2 L2 иatmиmol-2 ) * (1.50 mol)2 (5.00 L)2 P = (1.50 mol) * (0.082 06 LиatmиK-1 иmol-1 ) * (273 K) 5.00 L - (1.50 mol) * (8.4 * 10-2 Lиmol-1 ) Evaluate An ideal gas under the same circumstances has a pressure of 6.72 atm, so the “real” pressure (at least, as calculated from the van der Waals equation) of 5.44 atm is smaller, as we anticipated. Self-Test 4.17A A 10.0-L tank containing 25 mol O2 is stored in a diving supply shop at 25ЊC. Use the data in Table 4.5 and the van der Waals equation to estimate the pressure in the tank. [Answer: 58 atm] Self-Test 4.17B The properties of carbon dioxide gas are well known in the bottled beverage industry. In an industrial process, a tank of volume 100. L at 20.ЊC contains 20. mol CO2. Use the data in Table 4.5 and the van der Waals equation to estimate the pressure in the tank. We have arrived at our final model. By drawing on a wide range of experimental information, we now visualize a gas as a large number of molecules in ceaseless, random motion. The average speed—and the spread of speeds—of the molecules increases with temperature and decreases with molar mass. Because the average separation of the molecules is so great, intermolecular forces have only a weak effect on the properties of a gas, and the molecules travel in straight lines until they collide with other molecules or with the walls of the container. However, the intermolecular forces are not completely negligible, and repulsions increase the molar volume (at a given temperature and pressure), whereas attractions decrease the molar volume. Which effect dominates in a real gas depends on the relative strengths of the two kinds of interactions. The virial equation is a general equation for describing real gases. The van der Waals equation is an approximate equation of state for a real gas; the parameter a represents the role of attractive forces and the parameter b represents the role of repulsive forces. EXERCISES 163 ❑ 1 Calculate the pressure at the foot of a column of liquid (Example 4.1). ❑ 2 Interpret a manometer reading (Self-Test 4.2). ❑ 3 Use the gas laws to calculate P, V, T, or n for given conditions or after a change in conditions (Toolbox 4.1 and Examples 4.2–4.4). ❑ 4 Determine molar mass from gas density and vice versa (Example 4.5). ❑ 5 Calculate the mass or volume of reactant needed to react with a specified volume of gas (Example 4.6). ❑ 6 Calculate the partial pressures of gases in a mixture and the total pressure of the mixture (Example 4.7). ❑ 7 Use Graham’s law to account for relative rates of effusion (Self-Test 4.15). ❑ 8 Describe the effect of temperature on average speed (Section 4.9). ❑ 9 List and explain the assumptions of the kinetic model of gases (Section 4.10). ❑ 10 Calculate the root mean square speed of molecules in a sample of gas (Example 4.8). ❑ 11 Describe the effect of molar mass and temperature on the Maxwell distribution of molecular speeds (Section 4.11). ❑ 12 Explain how real gases differ from ideal gases (Sections 4.12–4.14). ❑ 13 Use the van der Waals equation to estimate the pressure of a gas (Example 4.9). SKILLS YOU SHOULD HAVE MASTERED The Nature of Gases 4.1 The pressure needed to make synthetic diamonds from graphite is 8 ϫ 104 atm. Express this pressure in (a) Pa; (b) kbar; (c) Torr; (d) lb·inchϪ2 . 4.2 The pressure recorded for an argon gas cylinder is 44.0 lb·inchϪ2 . Convert this pressure into (a) kPa; (b) Torr; (c) bar; (d) atm. 4.3 A student attaches a glass bulb containing neon gas to an open-tube manometer (refer to Fig. 4.5) and calculates the pressure of the gas to be 0.890 atm. (a) If the atmospheric pressure is 762 Torr, what height difference between the two sides of the mercury in the manometer did the student find? (b) Which side is higher, the side of the manometer attached to the bulb or the side open to the atmosphere? (c) If the student mistakenly switches the numbers for the sides of the manometer when recording the data in the laboratory notebook, what would be the reported pressure in the gas bulb? 4.4 A reaction is performed in a vessel attached to a closed-tube manometer. Before the reaction, the levels of mercury in the two sides of the manometer were at the same height. As the reaction proceeds, a gas is produced. At the end of the reaction, the height of the mercury column on the vacuum side of the manometer has risen 30.74 cm and the height on the side of the manometer connected to the flask has fallen by the same amount. What is the pressure in the apparatus at the end of the reaction expressed in (a) Torr; (b) atm; (c) Pa; (d) bar? 4.5 Suppose you were marooned on a tropical island and had to use seawater (density 1.10 g·cmϪ3 ) to make a primitive barometer. What height would the water reach in your barometer when a mercury barometer would reach 73.5 cm? The density of mercury is 13.6 g·cmϪ3 . 4.6 An unknown liquid is used to fill a closed-tube manometer. The atmosphere is found to produce a height difference of 6.14 m in this manometer at the same time that a mercury manometer gives a displacement of 758.7 mm. What is the density of the unknown liquid? 4.7 Assume that the width of your body (across your shoulders) is 20. inches and the depth of your body (chest to back) is 10. inches. If atmospheric pressure is 14.7 lb·inchϪ2 , what mass of air does your body support when you are in an upright position? 4.8 Low-pressure gauges in research laboratories are occasionally calibrated in inches of water (inH2O). Given that the density of mercury at 15°C is 13.5 g·cmϪ3 and the density of water at that temperature is 1.0 g·cmϪ3 , what is the pressure (in Torr) inside a gas cylinder that reads 8.9 inH2O at 15°C? EXERCISES The Gas Laws 4.9 When Robert Boyle conducted his experiments, he measured pressure in inches of mercury (inHg). On a day when the atmospheric pressure was 29.85 inHg, he trapped some air in the tip of a J-tube (1) and measured the difference in height of the mercury in the two arms of the tube (h). When h ϭ 12.0 inches, the height of the gas in the tip of the tube was 32.0 in. Boyle then added additional mercury and the level rose in both arms of the tube so that h ϭ 30.0 inches (2). (a) What was the height of the air space (in inches) in the tip of the tube in (2)? (b) What was the pressure of the gas in the tube in (1) and in (2) in inHg? 164 CHAPTER 4 THE PROPERTIES OF GASES 1 2 32.0 inches h = 12.0 inches h = 30.0 inches ? 4.13 (a) A 350.0-mL flask contains 0.1500 mol Ar at 24°C. What is the pressure of the gas in kilopascals? (b) You are told that 23.9 mg of bromine trifluoride exerts a pressure of 10.0 Torr at 100.°C. What is the volume of the container in milliliters? (c) A 100.0-mL flask contains sulfur dioxide at 0.77 atm and 30.°C. What mass of gas is present? (d) A storage tank of volume 6.00 ϫ 103 m3 contains methane at 129 kPa and 14°C. How many moles of CH4 are present? (e) A 1.0-␮L ampoule of helium has a pressure of 2.00 kPa at Ϫ115°C. How many He atoms are present? 4.14 (a) A 125-mL flask contains argon at 1.30 atm and 77°C. What amount of Ar is present (in moles)? (b) A 120.-mL flask contains 2.7 ␮g of O2 at 17°C. What is the pressure (in Torr)? (c) A 20.0-L flask at 215 K and 20. Torr contains nitrogen. What mass of nitrogen is present (in grams)? (d) A 16.7-g sample of krypton exerts a pressure of 1.00 ϫ 102 mTorr at 44°C. What is the volume of the container (in liters)? (e) A 2.6-␮L ampoule of xenon has a pressure of 2.00 Torr at 15°C. How many Xe atoms are present? 4.15 (a) Using the Living Graphs on the Web site for this book, prepare and print a single plot of the pressure against temperature for 1.00 mol of gas molecules, showing the curves at volumes ranging from 0.01 L to 0.05 L in increments of 0.01 L for T ϭ 0 to 400 K. (b) What is the expression for the slope of each of these lines? (c) What is each intercept? Give your answers to two decimal places. 4.16 (a) Using the Living Graphs on the Web site for this book, prepare and print a single plot of the volume against temperature graph for 1.00 mol of gas molecules, showing the curves at pressures ranging from 11 000 atm to 15 000 atm in increments of 1000 atm for T ϭ 0 to 400 K. (b) What is the expression for the slope of each of these lines? (c) What is each intercept? Give your answers to two decimal places. 4.17 Determine the final pressure when (a) 7.50 mL of krypton at 2.00 ϫ 105 kPa is transferred to a vessel of volume 1.0 L; (b) 54.2 cm3 of O2 at 643 Torr is compressed to 7.8 cm3 . Assume constant temperature. 4.18 (a) Suppose that 4.00 L of methane at a pressure of 800. Torr is transferred to a vessel of volume 2.40 L. What is the final pressure of methane if the change occurs at constant temperature? (b) A fluorinated organic gas in a cylinder is compressed from an initial volume of 936 mL at 158 Pa to 468 mL at the same temperature. What is the final pressure? 4.19 A 250.-mL aerosol can at 25°C and 1.10 atm was thrown into an incinerator. When the temperature in the can reached 712°C, it exploded. What was the pressure in the can just before it exploded, assuming it reached the maximum pressure possible at that temperature? 4.20 An outdoor storage vessel for hydrogen gas with a volume of 300. m3 is at 1.5 atm and 10.°C at 2:00 AM. By 2:00 PM, the temperature has risen to 30.°C. What is the new pressure of the hydrogen in the vessel? 4.21 A helium balloon has a volume of 12.4 L when the pressure is 0.885 atm and the temperature is 22°C. The balloon is cooled at a constant pressure until the temperature is Ϫ18°C. What is the volume of the balloon at this stage? 4.22 A chemist prepares a sample of hydrogen bromide and finds that it occupies 250. mL at 65°C and 500. Torr. What volume would it occupy at 0°C at the same pressure? 4.10 Boyle continued to add mercury to the apparatus in Exercise 4.9 until the height of the trapped air had been reduced to 6.85 inches. Assuming that atmospheric pressure had not changed, what was the pressure of the trapped air at that point (in inHg)? 4.11 The following data were collected for a gas sample consisting of 1.00 mol of molecules in a rigid container. (a) Determine the volume of the sample. (b) Plot the data either by hand or using a computer spreadsheet program. Now suppose you add an additional 1.00 mol of gas molecules into the same volume. Plot the corresponding line for the second sample. (c) At what temperature (in kelvins) would the two lines intersect? Temperature (°C) Pressure (atm) 0 1.12 20 1.20 40 1.28 60 1.36 80 1.45 4.12 The following data were collected for a gas sample consisting of 5.00 mol of molecules in a rigid container. (a) Determine the volume of the sample. (b) Plot the data either by hand or using a computer spreadsheet program. Now suppose you add another 5.00 mol of gas molecules into the same volume. Plot the corresponding line for the second sample. (c) At what temperature (in kelvins) would the two lines intersect? Temperature (°C) Pressure (atm) 0 4.48 20 4.80 40 5.14 60 5.46 80 5.80 EXERCISES 165 4.23 A chemist prepares 0.100 mol Ne gas at a certain pressure and temperature in an expandable container. Another 0.010 mol Ne is then added to the same container. How must the volume be changed to keep the pressure and temperature the same? 4.24 A chemist prepares a sample of helium gas at a certain pressure, temperature, and volume and then removes half the gas molecules. How must the temperature be changed to keep the pressure and volume the same? 4.25 A sample of methane gas, CH4, was slowly heated at a constant pressure of 0.90 bar. The volume of the gas was measured at a series of different temperatures and a plot of volume vs. temperature was constructed. The slope of the line was 2.88 ϫ 10Ϫ4 L·KϪ1 . What was the mass of the sample of methane? 4.26 A sample of butane gas, C4H10, was slowly heated at a constant pressure of 0.80 bar. The volume of the gas was measured at a series of different temperatures and a plot of volume vs. temperature was constructed. The slope of the line was 0.0208 L·KϪ1 . What was the mass of the sample of butane? 4.27 You are told that 35.5 mL of xenon exerts a pressure of 0.255 atm at Ϫ45°C. (a) What volume does the sample occupy at 1.00 atm and 298 K? (b) What pressure would it exert if it were transferred to a flask of volume 12.0 mL at 20.°C? (c) Calculate the temperature needed for the xenon to exert a pressure of 5.00 ϫ 102 Torr in the flask. 4.28 A lungful of air (355 cm3 ) is exhaled into a machine that measures lung capacity. If the air is exhaled from the lungs at a pressure of 1.08 atm at 37°C but the machine is at ambient conditions of 0.958 atm and 23°C, what is the volume of air measured by the machine? 4.29 What is the molar volume of an ideal gas at 1.00 atm and (a) 500.°C; (b) at the normal boiling point of liquid nitrogen (Ϫ196°C)? 4.30 What is the molar volume of an ideal gas at 1.00 atm and (a) 212°F; (b) at the normal sublimation point of dry ice (Ϫ78.5°C)? 4.31 Originally at Ϫ20.°C and 759 Torr, a 1.00-L sample of air is heated to 235°C. Next, the pressure is increased to 765 Torr. Then it is heated to 1250.°C, and finally the pressure is decreased to 252 Torr. What is the final volume of the air? 4.32 A domestic water-carbonating kit uses steel cylinders of carbon dioxide, each with a volume of 250. mL. Each weighs 1.04 kg when full and 0.74 kg when empty. What is the pressure of gas (in bar) in a full cylinder at 20.°C? 4.33 The effect of high pressure on organisms, including humans, is studied to gain information about deep-sea diving and anesthesia. A sample of air occupied 1.00 L at 25°C and 1.00 atm. What pressure (in atm) is needed to compress it to 239 cm3 at this temperature? 4.34 To what temperature must a sample of helium gas be cooled from 127.0°C to reduce its volume from 4.60 L to 0.115 L at constant pressure? 4.35 The “air” in the space suit of astronauts is actually pure oxygen supplied at a pressure of 0.30 bar. The two tanks on a space suit each have a volume of 3980. cm3 and have an initial pressure of 5860. kPa. Assuming a tank temperature of 16°C, what mass of oxygen is contained in the two tanks? 4.36 A balloon vendor has a 20.0 L helium tank under 150 atm pressure at 25°C. How many balloons of 2.50 L each can be filled at 1.0 atm by the helium in this tank? 4.37 Nitrogen monoxide, NO, has been found to act as a neurotransmitter. To prepare to study its effect, a sample was collected in a container of volume 250.0 mL. At 19.5°C, its pressure in this container is found to be 24.5 kPa. What amount (in moles) of NO has been collected? 4.38 Hot-air balloons gain their lift from the reduction in the density of air that occurs when the air in the envelope is heated. To what temperature should you heat a sample of air, initially at 340. K, to increase its volume by 14%? 4.39 At sea level, where the pressure was 104 kPa and the temperature 21.1°C, a certain mass of air occupied 2.0 m3 . To what volume will the air mass expand when it has risen to an altitude where the pressure and temperature are (a) 52 kPa, Ϫ5.0°C; (b) 880. Pa, Ϫ52.0°C? 4.40 A meteorological balloon had a radius of 1.0 m when released at sea level at 20.°C. It expanded to a radius of 3.0 m when it had risen to its maximum altitude, where the temperature was Ϫ20.°C. What was the pressure inside the balloon at that altitude? Gas Density 4.41 Order the following gases according to increasing density: CO; CO2; H2S. The temperature and pressure are the same for all three samples. 4.42 Order the following gases according to increasing density: N2; NH3; NO2. The temperature and pressure are the same for all three samples. 4.43 A 2.00-mg sample of argon is confined to a 0.0500-L vial at 20.°C; 2.00 mg of krypton is confined to a different 0.0500-L vial. What must the temperature of the krypton be if it is to have the same pressure as the argon? 4.44 What mass of ammonia will exert the same pressure as 12 mg of hydrogen sulfide, H2S, in the same container under the same conditions? 4.45 What is the density (in g·LϪ1 ) of chloroform, CHCl3, vapor at (a) 2.00 ϫ 102 Torr and 298 K; (b) 100.°C and 1.00 atm? 4.46 What is the density (in g·LϪ1 ) of hydrogen sulfide, H2S, at (a) 1.00 atm and 298 K; (b) 45.0°C and 0.876 atm? 4.47 A gaseous fluorinated methane compound has a density of 8.0 g·LϪ1 at 2.81 atm and 300. K. (a) What is the molar mass of the compound? (b) What is the formula of the compound if it is composed solely of C, H, and F? (c) What is the density of the gas at 1.00 atm and 298 K? 4.48 The density of a gaseous compound of phosphorus is 0.943 g·LϪ1 at 420. K when its pressure is 727 Torr. (a) What is the molar mass of the compound? (b) If the compound remains gaseous, what would be its density at 1.00 atm and 298 K? 4.49 A compound used in the manufacture of Saran is 24.7% C, 2.1% H, and 73.2% Cl by mass. The storage of 3.557 g of the gaseous compound in a 755-mL vessel at 0°C results in a pressure of 1.10 atm. What is the molecular formula of the compound? 4.50 The analysis of a hydrocarbon revealed that it was 85.7% C and 14.3% H by mass. When 1.77 g of the gas was stored in a 1.500-L flask at 17°C, it exerted a pressure of 508 Torr. What is the molecular formula of the hydrocarbon? 4.51 The density of a gaseous compound was found to be 0.943 g·LϪ1 at 298 K and 53.1 kPa. What is the molar mass of the compound? 4.52 A 115-mg sample of eugenol, the compound responsible for the odor of cloves, was placed in an evacuated flask with a volume of 500.0 mL at 280.0°C. The pressure that eugenol exerted in the flask under those conditions was found to be 48.3 Torr. In a combustion experiment, 18.8 mg of eugenol burned to give 50.0 mg of carbon dioxide and 12.4 mg of water. What is the molecular formula of eugenol? The Stoichiometry of Reacting Gases 4.53 The Haber process for the synthesis of ammonia is one of the most significant industrial processes for the well-being of humanity. It is used extensively in the production of fertilizers as well as polymers and other products. (a) What volume of hydrogen at 15.00 atm and 350.°C must be supplied to produce 1.0 tonne (1 t ϭ 103 kg) of NH3? (b) What volume of hydrogen is needed in part (a) if it is supplied at 376 atm and 250.°C? 4.54 Nitroglycerin is a shock-sensitive liquid that detonates by the reaction 4 C3H5(NO3)3(l) 6 N2(g) ϩ 10 H2O(g) ϩ 12 CO2(g) ϩ O2(g) Calculate the total volume of product gases at 215 kPa and 275°C from the detonation of 1.00 lb (454 g) of nitroglycerin. 4.55 Which starting condition would produce the larger volume of carbon dioxide by combustion of CH4(g) with an excess of oxygen gas to produce carbon dioxide and water: (a) 2.00 L of CH4(g); (b) 2.00 g of CH4(g)? Justify your answer. The system is maintained at a temperature of 75°C and 1.00 atm. 4.56 Which starting condition would produce the larger volume of carbon dioxide by combustion of C2H4(g) with an excess of oxygen gas to produce carbon dioxide and water: (a) 1.00 L of C2H4(g); (b) 1.20 g of C2H4(g)? Justify your answer. The system is maintained at a temperature of 45°C and 2.00 atm. 4.57 Through a series of enzymatic steps, carbon dioxide and water undergo photosynthesis to produce glucose and oxygen according to the equation 6 CO2(g) ϩ 6 H2O(l) C6H12O6(s) ϩ 6 O2(g) Given that the partial pressure of carbon dioxide in the troposphere is 0.26 Torr and that the temperature is 25°C, calculate the volume of air needed to produce 10.0 g of glucose. 4.58 The naturally occurring compound urea, CO(NH2)2, was first synthesized by Friedrich Wöhler in Germany in 1828 by heating ammonium cyanate. This synthesis was a significant event because it was the first time that an organic compound had been produced from an inorganic substance. Urea may also be made by the reaction of carbon dioxide and ammonia: CO2(g) ϩ 2 NH3(g) CO(NH2)2(s) ϩ H2O(g) What volumes of CO2 and NH3 at 200. atm and 450.°C are needed to produce 2.50 kg of urea, assuming the reaction goes to completion? ¡ ¡ ¡ 4.59 A 15.0-mL sample of ammonia gas at 1.00 ϫ 102 Torr and 30.°C is mixed with 25.0 mL of hydrogen chloride gas at 1.50 ϫ 102 Torr and 25°C, and the following reaction takes place: NH3(g) ϩ HCl(g) NH4Cl(s) (a) Calculate the mass of NH4Cl that forms. (b) Identify the gas in excess and determine the pressure of the excess gas at 27°C after the reaction is complete (in the combined volume of the original two flasks). 4.60 A sample of ethene gas, C2H4, of volume 1.00 L at 1.00 atm and 298 K is burned in 4.00 L of oxygen gas to form carbon dioxide gas and liquid water at the same pressure and temperature. Ignore the volume of water, and determine the final volume of the reaction mixture (including any excess reactant) at 1.00 atm and 298 K if the reaction goes to completion. Mixtures of Gases 4.61 A sample of hydrogen chloride gas, HCl, is being collected by bubbling it through liquid benzene into a graduated cylinder. Assume that the molecules pictured as spheres show a representative sample of the mixture of HCl and benzene vapor ( represents an HCl molecule and a benzene molecule). (a) Use the figure to determine the mole fractions of HCl and benzene vapor in the gas inside the container. (b) What are the partial pressures of HCl and benzene in the container when the total pressure inside the container is 0.80 atm? ¡ 166 CHAPTER 4 THE PROPERTIES OF GASES 4.62 A piece of lithium metal was added to a flask of water on a day when the atmospheric pressure was 757.5 Torr. The lithium reacted completely with the water to produce 250.0 mL of hydrogen gas, collected over the water at 23°C, at which temperature the vapor pressure of water is 21.07 Torr. (a) What is the partial pressure of hydrogen in the collection flask? (b) What mass of lithium metal reacted? 4.63 A vessel of volume 22.4 L contains 2.0 mol H2(g) and 1.0 mol N2(g) at 273.15 K. Calculate (a) their partial pressures and (b) the total pressure. 4.64 An apparatus consists of a 4.0-L flask containing nitrogen gas at 25°C and 803 kPa, joined by a valve to a 10.0-L flask containing argon gas at 25°C and 47.2 kPa. The valve is opened and the gases mix. (a) What is the partial pressure of each gas after mixing? (b) What is the total pressure of the gas mixture? 4.65 A 1.00-L flask contains nitrogen gas at a temperature of 15°C and a pressure of 0.50 bar. 0.10 mol O2(g) is added to the flask and allowed to mix. Then a stopcock is opened to allow 0.020 mol of molecules to escape. What is the partial pressure of oxygen in the final mixture? 4.66 A gas mixture being used to simulate the atmosphere of another planet consists of 320. mg of methane, 175 mg of argon, and 225 mg of nitrogen. The partial pressure of nitrogen at 300. K is 15.2 kPa. Calculate (a) the total pressure of the mixture and (b) the volume. EXERCISES 167 4.67 In the course of the electrolysis of water, hydrogen gas was collected at one electrode over water at 20.°C when the external pressure was 756.7 Torr. The vapor pressure of water at 20.°C is 17.54 Torr. The volume of the gas was measured to be 0.220 L. (a) What is the partial pressure of hydrogen? (b) The other product of the electrolysis of water is oxygen gas. Write a balanced equation for the electrolysis of water into H2 and O2. (c) What mass of oxygen was also produced in the reaction? 4.68 Dinitrogen oxide, N2O, gas was generated from the thermal decomposition of ammonium nitrate and collected over water. The wet gas occupied 126 mL at 21°C when the atmospheric pressure was 755 Torr. What volume would the same amount of dry dinitrogen oxide have occupied if collected at 755 Torr and 21°C? The vapor pressure of water is 18.65 Torr at 21°C. Molecular Motion 4.69 Do all the molecules of a gas strike the walls of their container with the same force? Justify your answer on the basis of the kinetic model of gases. 4.70 How does the frequency of collisions of the molecules of a gas with the walls of the container change as the volume of the gas is decreased at constant temperature? Justify your answer on the basis of the kinetic model of gases. 4.71 What is the molecular formula of a compound of empirical formula CH that diffuses 1.24 times more slowly than krypton at the same temperature and pressure? 4.72 What is the molar mass of a compound that takes 2.7 times as long to effuse through a porous plug as it did for the same amount of XeF2 at the same temperature and pressure? 4.73 A sample of argon gas effuses through a porous plug in 147 s. Calculate the time required for the same amount of (a) CO2, (b) C2H4, (c) H2, and (d) SO2 to effuse under the same conditions of pressure and temperature. 4.74 A sample of neon gas effuses through a porous plug in 85.3 s. Calculate the time required for the same amount of (a) CH2O, (b) C3H8, (c) He, and (d) NO2 to effuse under the same conditions of pressure and temperature. 4.75 A hydrocarbon of empirical formula C2H3 takes 349 s to effuse through a porous plug; under the same conditions of temperature and pressure, it took 210. s for the same number of molecules of argon to effuse. What is the molar mass and molecular formula of the hydrocarbon? 4.76 The composition of a compound used to make polyvinyl chloride (PVC) is 38.4% C, 4.82% H, and 56.8% Cl by mass. It took 7.73 min for a given volume of the compound to effuse through a porous plug, but it took only 6.18 min for the same amount of Ar to diffuse at the same temperature and pressure. What is the molecular formula of the compound? 4.77 Calculate the molar kinetic energy (in joules per mole) of Kr(g) at (a) 55.85°C and (b) 54.85°C. (c) The difference between the answers to parts (a) and (b) is the energy per mole that it takes to raise the temperature of Kr(g) by 1.00°C. The quantity is known as the molar heat capacity. What is its value? 4.78 Calculate the molar kinetic energy (in joules per mole) of a sample of Ne(g) at (a) 25.00°C and (b) 26.00°C. (c) The difference between the answers to parts (a) and (b) is the energy per mole that it takes to raise the temperature of Ne(g) by 1°C. The quantity is known as the molar heat capacity. What is its value? 4.79 Calculate the root mean square speeds of (a) methane, (b) ethane, and (c) propane molecules, all at Ϫ20.°C. 4.80 Calculate the root mean square speed of (a) fluorine gas, (b) chlorine gas, and (c) bromine gas molecules, all at 350.°C. 4.81 The root mean square speed of gaseous methane molecules, CH4, at a certain temperature was found to be 550. m·sϪ1 . What is the root mean square speed of krypton atoms at the same temperature? 4.82 In an experiment on gases, you are studying a 1.00-L sample of hydrogen gas at 20°C and 2.40 atm. You heat the gas until the root mean square speed of the molecules of the sample has been doubled. What will be the final pressure of the gas? 4.83 A bottle contains 1.0 mol He(g) and a second bottle contains 1.0 mol Ar(g) at the same temperature. At that temperature, the root mean square speed of He is 1477 m·sϪ1 and that of Ar is 467 m·sϪ1 . What is the ratio of the number of He atoms in the first bottle to the number of Ar atoms in the second bottle having these speeds? Assume that both gases behave ideally. 4.84 The number of molecules in a gas sample that have the most probable speed (vmp) at a temperature T is one-half the number of the same type of molecules that have the most probable speed at 300. K. What is the temperature? 4.85 (a) From the graph of Maxwell distribution of speeds in Fig. 4.27, find the location that represents the most probable speed of the molecules at each temperature. (b) What happens to the percentage of molecules having the most probable speed as the temperature increases? 4.86 A scientist is investigating a sample of 1.00 mol He(g) in a large cylinder at 200. K. Calculate by what factor each of the following variables would change the pressure of the gas and its root mean square speed: (a) The gas is compressed into a third of its original volume. (b) The temperature is reduced to 100. K. (c) The helium is replaced by the same amount of xenon. Real Gases 4.87 The pressure of a sample of hydrogen fluoride is lower than expected and, as the temperature is increased, rises more quickly than the ideal gas law predicts. Suggest an explanation. 4.88 Under what conditions would you expect a real gas to be (a) more compressible than an ideal gas; (b) less compressible than an ideal gas? 4.89 Two identical flasks are each filled with a gas at 20°C and 100 atm. One flask contains 1 mol NH3 and the other 1 mol H2. (a) In which flask do the molecules have the greater root mean square speed? (b) In which flask are the attractions between the molecules the stronger? Explain your reasoning. 4.90 Two identical flasks are each filled with a gas at 20°C and 100 atm. One flask contains 1 mol NH3 and the other 1 mol H2. (a) In which flask do the molecules have more collisions per second with the walls of the container? (b) For each flask predict whether the pressure will be higher or lower than predicted by the ideal gas law. Explain your reasoning. C 4.91 Using the ideal gas equation, calculate the pressure at 298 K exerted by 1.00 mol CO2(g) when confined in a volume of (a) 15.0 L; (b) 0.500 L; (c) 50.0 mL. Repeat these calculations with the use of the van der Waals equation. What do these calculations indicate about how the reliability of the ideal gas law depends on the pressure? 4.92 Using the ideal gas equation, calculate the pressure at 298 K exerted by 1.00 mol H2(g) when confined in a volume of (a) 30.0 L; (b) 1.00 L; (c) 50.0 mL. Repeat these calculations with the use of the van der Waals equation. What do these calculations indicate about how the reliability of the ideal gas law depends on the pressure? 4.93 The following table lists the van der Waals a parameters for CO2, CH3CN, Ne, and CH4. Use your knowledge of the factors governing the magnitudes of a to assign each of these four gases to its a value. a (L2 ·atm·molϪ2 ) Substance 17.58 3.392 2.253 0.2107 4.94 Calculate the pressure exerted by 1.00 mol C2H6(g) behaving as (a) an ideal gas; (b) a van der Waals gas when it is confined under the following conditions: (1) at 273.15 K in 22.414 L; (2) at 1.00 ϫ 103 K in 0.100 L. 4.95 Plot pressure against volume for 1 mol of (a) an ideal gas, (b) ammonia, and (c) oxygen gas, for the range V ϭ 0.05 L to 1.0 L at 298 K. Use the van der Waals equation to calculate the pressures of the two real gases. Use a spreadsheet or the graphical plotter on the Web site for this book. Compare the plots and explain the origin of any differences you find. 4.96 Plot pressure against volume for 1 mol of (a) an ideal gas, (b) carbon dioxide, (c) ammonia, and (d) benzene for the range V ϭ 0.1 L to 1.0 L at 298 K. Use the van der Waals equation to determine the pressures of the real gases. Use a spreadsheet or the graphical plotter on the Web site for this book. Compare the shapes of the curves and explain the differences. Integrated Exercises 4.97 The drawing below shows a tiny section of a flask containing two gases. The orange spheres represent atoms of neon and the blue spheres represent atoms of argon. (a) If the partial pressure of neon in this mixture is 420. Torr, what is the partial pressure of argon? (b) What is the total pressure? 4.99 The interhalogen compounds can be prepared by direct reaction of the elements. The following syntheses were carried out at 298 K and 1.00 atm. In each case, give the volume of product at the same temperature and pressure that can be produced from 2.00 mol F2 and an excess of Cl2: (a) Cl2(g) ϩ F2(g) : 2 ClF(g); (b) Cl2(g) ϩ 3 F2(g) : 2 ClF3(g); (c) Cl2(g) ϩ 5 F2(g) : 2 ClF5(g). 4.100 Roommates fill ten balloons for a party, five with hydrogen and five with helium. After the party they notice that the hydrogen balloons have lost 1/4 of their hydrogen due to diffusion through the walls of the balloons. What fraction of helium will the other balloons have lost at that same time? 4.101 Photochemical smog is formed, in part, by the action of light on nitrogen dioxide. The wavelength of the radiation absorbed by NO2 in this reaction is 197 nm. (a) Draw the Lewis structure for NO2 and sketch its ␲ molecular orbitals. (b) When 1.07 mJ of energy is absorbed by 2.5 L of air at 20.°C and 0.85 atm, all the NO2 molecules in this sample are dissociated by the reaction just shown. Assume that each photon absorbed results in the dissociation (into NO and O) of one NO2 molecule. What is the proportion, in parts per million, of NO2 molecules in this sample? Assume that the sample is behaving ideally. 4.102 The reaction of solid dimethylhydrazine, (CH3)2N2H2, and liquefied dinitrogen tetroxide, N2O4, has been investigated as a rocket fuel; the reaction produces gaseous carbon dioxide (CO2), nitrogen (N2), and water vapor (H2O), which are ejected as exhaust gases. In a controlled experiment, solid dimethylhydrazine reacted with excess nitrogen tetroxide and the gases were collected in a closed vessel until a pressure of 2.50 atm and a temperature of 400.0 K were reached. What are the partial pressures of CO2, N2, and H2O? 4.103 Suppose that 200. mL of hydrogen chloride at 690. Torr and 20.°C is dissolved in 100. mL of water. The solution was titrated to the stoichiometric point with 15.7 mL of a sodium hydroxide solution. What is the molar concentration of the NaOH solution used for the titration? 4.104 Suppose that 2.00 L of propane gas, C3H8, at 1.00 atm and 298 K is mixed with 5.00 L of oxygen gas at the same pressure and temperature and burned to form carbon dioxide gas and liquid water. Ignore the volume of water formed, and determine the final volume of the reaction mixture (including products and excess reactant) at 1.00 atm and 298 K if reaction goes to completion. 4.105 A flask of volume 5.00 L is evacuated and 43.78 g of solid dinitrogen tetroxide, N2O4, is introduced at Ϫ196°C. The sample is then warmed to 25°C, during which time the N2O4 vaporizes and some of it dissociates to form brown NO2 gas. The pressure slowly increases until it stabilizes at 2.96 atm. (a) Write a balanced equation for the reaction. (b) If the gas in the flask at 25°C were all N2O4, what would the pressure be? (c) If all the gas in the flask converted into NO2, what would the pressure be? (d) What are the NO2 ¡ hv NO + O 168 CHAPTER 4 THE PROPERTIES OF GASES 4.98 The four flasks below were prepared with the same volume and temperature. Flask I contains He atoms, Flask II contains Cl2 molecules, Flask III contains Ar atoms, and Flask IV contains NH3 molecules. Which flask has (a) the largest number of atoms; (b) the highest pressure; (c) the greatest density; (d) the highest root mean square speed; (e) the highest molar kinetic energy? I II III IV EXERCISES 169 mole fractions of N2O4 and NO2 once the pressure stabilizes at 2.96 atm? 4.106 When 0.40 g of impure zinc reacted with an excess of hydrochloric acid, 127 mL of hydrogen was collected over water at 10.°C. The external pressure was 737.7 Torr. (a) What volume would the dry hydrogen occupy at 1.00 atm and 298 K? (b) What amount (in moles) of H2 was collected? (c) What is the percentage purity of the zinc, assuming that all the zinc present reacted completely with HCl and that the impurities did not react with HCl to produce hydrogen? The vapor pressure of water at 10.°C is 9.21 Torr. 4.107 Suppose that 0.473 g of an unknown gas that occupies 200. mL at 1.81 atm and 25°C was analyzed and found to contain 0.414 g of nitrogen and 0.0591 g of hydrogen. (a) What is the molecular formula of the compound? (b) Draw the Lewis structure of the molecule. (c) If 0.35 mmol NH3 effuses through a small opening in a glass apparatus in 15.0 min at 200.°C, what amount of the gas being studied will effuse through the same opening in 25.0 min at 200.°C? 4.108 When 2.36 g of phosphorus was burned in chlorine, the product was 10.5 g of a phosphorus chloride. Its vapor took 1.77 times as long to effuse as the same amount of CO2 under the same conditions of temperature and pressure. What is the molar mass and molecular formula of the phosphorus chloride? 4.109 Determine the ratio of the number of molecules in a gas having a speed ten times as great as the root mean square speed to the number having a speed equal to the root mean square speed. Is this ratio independent of temperature? Explain your reasoning. 4.110 Air bags in automobiles contain crystals of sodium azide, NaN3, which during a collision decomposes rapidly to give nitrogen gas and sodium metal. The nitrogen gas liberated by this process instantly inflates the air bag. Assume that the nitrogen gas liberated behaves as an ideal gas and that any solid produced has a negligible volume (which may be ignored). (a) Calculate the mass (in grams) of sodium azide required to generate enough nitrogen gas to fill a 57.0-L air bag at 1.37 atm and 25.0°C. (b) What is the root mean square speed of the N2 gas molecules generated? 4.111 The spreading of smells through still air is due to the diffusion of the gas molecules. In a room that is 5 m long, a vial of ethyl octanoate is opened at the north end of the room, and simultaneously a second vial containing p-anisaldehyde is opened at the south end of the room (5 m away). Ethyl octanoate (C10H20O2) has a fruity smell, and p-anisaldehyde (C8H8O2) has a minty smell. How far (in meters) from the north end of the room must a person stand to smell first a minty smell? 4.112 You are told that 2.55 g of a gaseous hydrocarbon occupies a vessel of volume 3.00 L at 0.950 atm and 82.0°C. Draw the Lewis structure of this hydrocarbon. 4.113 A finely powdered solid sample of an osmium oxide (which melts at 40.°C and boils at 130.°C) with a mass of 1.509 g is placed into a cylinder with a movable piston that can expand against the atmospheric pressure of 745 Torr. Assume that the amount of residual air initially present in the cylinder is negligible. When the sample is heated to 200.°C, it is completely vaporized and the volume of the cylinder expands by 235 mL. What is the molar mass of the oxide? Assuming that the oxide is OsOx, find the value of x. 4.114 How does the root mean square speed of gas molecules vary with temperature? Illustrate this relationship by plotting the root mean square speed of N2 as a function of temperature from T ϭ 100 K to T ϭ 300 K. 4.115 A group of chemistry students have injected 46.2 g of a gas into an evacuated, constant-volume container at 27°C and atmospheric pressure. Now the students want to heat the gas at constant pressure by allowing some of the gas to escape during the heating. What mass of gas must be released if the temperature is raised to 327°C? 4.116 The root mean square speed, vrms, of gas molecules was derived in Section 4.10. Using the Maxwell distribution of speeds, we can also calculate the mean speed and most probable (mp) speed of a collection of molecules. The equations used to calculate these two quantities are vmean ϭ (8RT/␲M)1/2 and vmp ϭ (2RT/M)1/2 . These values have a fixed relation to one another. (a) Place these three quantities in order of increasing magnitude. (b) Show that the relative magnitudes are independent of the molar mass of the gas. (c) Using the smallest speed as the reference point, rank them by magnitude and determine the ratios of the larger values to the smallest. 4.117 (a) The van der Waals parameters for helium are a ϭ 3.41 ϫ 10Ϫ2 L2 ·atm·molϪ2 and b ϭ 2.38 ϫ 10Ϫ2 L·molϪ1 . Calculate the apparent volume (in pm3 ) and radius (in pm) of a helium atom as determined from the van der Waals parameters. (b) Estimate the volume of a helium atom on the basis of its atomic radius. (c) How do these quantities compare? Should they be same? Discuss. 4.118 Show that the van der Waals parameter b is related to the molecular volume Vmol by b ϭ 4NAVmol. Treat the molecules as spheres of radius r, so that Vmol ϭ ␲r3 . The closest that the centers of two molecules can approach is 2r. 4.119 A 1.00-L sample of chlorine gas at 1.00 atm and 298 K reacts completely with 1.00 L of nitrogen gas and 2.00 L of oxygen gas at the same temperature and pressure. There is a single gaseous product, which fills a 2.00-L flask at 1.00 atm and 298 K. Use this information to determine the following characteristics of the product: (a) its empirical formula; (b) its molecular formula; (c) the most favorable Lewis structure based on formal charge arguments (the central atom is an N atom); (d) the molecular shape. 4.120 A sample of gaseous arsine, AsH3, in a 500.0-mL flask at 300. Torr and 223 K is heated to 473 K, at which temperature arsine decomposes to solid arsenic and hydrogen gas. The flask is then cooled to 273 K, at which temperature the pressure in the flask is 508 Torr. Has all the arsine decomposed? Calculate the percentage of arsine molecules that have decomposed. 4.121 The van der Waals equation can be arranged into the following cubic equation: (a) Using this equation, calculate the volume occupied by 0.505 mol NH3(g) at 25°C and 95.0 atm. The van der Waals parameters for NH3 are a ϭ 4.169 L2 ·atm·molϪ2 and b ϭ 3.71 L·molϪ1 . (b) Do the attractive or the repulsive forces dominate at this temperature and pressure? V3 + n a RT + bP P b V2 + a n2 a P b V - n3 ab P = 0 4 3 170 CHAPTER 4 THE PROPERTIES OF GASES Chemistry Connections 4.122 Iron pyrite, FeS2, is the form in which much of the sulfur exists in coal. In the combustion of coal, oxygen reacts with iron pyrite to produce iron(III) oxide and sulfur dioxide, which is a major source of air pollution and a substantial contributor to acid rain. (a) Write a balanced equation for the burning of FeS2 in air to produce iron(III) oxide and sulfur dioxide. (b) Calculate the mass of Fe2O3 that is produced from the reaction of 75.0 L of oxygen at 2.33 atm and 150.°C with an excess of iron pyrite. (c) If the sulfur dioxide that is generated in part (b) is dissolved to form 5.00 L of aqueous solution, what is the molar concentration of H2SO3 in the resulting solution? (d) What mass of SO2 is produced in the burning of 1.00 tonne (1 t ϭ 103 kg) of high-sulfur coal, if the coal is 5% pyrite by mass? (e) What is the volume of the SO2 gas generated in part (d) at 1.00 atm and 25°C? (f) One way to remove SO2 from exhaust gases is to remove it in the reaction CaO(s) ϩ SO2(g) : CaSO3(s). In a test of this reaction, a mixture of sulfur dioxide and nitrogen gases is prepared at 25°C in a vessel of volume 500. mL at 1.09 atm. The mixture is passed over warm calcium oxide powder, which removes the sulfur dioxide, and is then transferred to a vessel of volume 150. mL, where the pressure is 1.09 atm at 50.°C. (i) What was the partial pressure of the SO2 in the initial mixture? (ii) What mass of SO2 was present in the initial mixture? (g) The van der Waals parameters for SO2 are a ϭ 6.865 L2 ·atm·molϪ1 and b ϭ 0.0568 L·molϪ1 . For SO2(g) confined in a 1.00-L vessel at 27°C, calculate the pressure of the gas by using the ideal gas law and the van der Waals equation for 0.100 mol to 0.500 mol SO2 at 0.100-mol increments. (h) Calculate the percentage deviation of the ideal value from the value calculated from the van der Waals equation at each point in part (g). (i) Under the conditions in part (g), which term has the larger effect on the pressure of SO2, the intermolecular attractions or the repulsions? (j) If we consider to be ideal those gases for which the observed pressure differs by no more than 5% from the ideal value, at what pressure does SO2 become a “real” gas? 171 What Are the Key Ideas? The condensed phases of matter result from attractive intermolecular forces. When atoms, ions, and molecules do not have enough energy to escape from their neighbors they form solids with their atoms in characteristic arrangements. They form liquids when they have enough energy to move past their neighbors but not enough to escape from them entirely. Why Do We Need to Know This Material? This chapter shows how atomic and molecular properties are related to the structure and properties of bulk solids and liquids, continuing the process begun in Chapter 4 for gases. Because scientists design new materials by considering how the properties and interactions of individual particles give rise to bulk properties, formulating the materials of tomorrow will require an understanding of these relationships, as we shall see in greater detail in Chapter 6. What Do We Need to Know Already? This chapter uses the concepts of potential energy (Section A), coulombic interactions (Section 2.4), polar molecules and dipoles (Section 3.3), and intermolecular forces in gases (Section 4.12). M olecules attract one another. From that simple fact spring fundamentally important consequences. Rivers, lakes, and oceans exist because water molecules attract one another and form a liquid. Without that liquid, there would be no life. Without forces between molecules, our flesh would drip off our bones and the oceans would be gas. Less dramatically, the forces between molecules govern the physical properties of bulk matter and help to account for the differences in the substances around us. They explain why carbon dioxide is a gas that we exhale, why wood is a solid that we can stand on, and why ice floats on water. Molecules also repel one another. When pressed together, molecules resist further compression. As a result, we do not sink into the floor and solid objects have a specific size and shape. Even in a gas, repulsions are important as they mean that molecules do not simply pass through one another but undergo actual collisions. In Chapter 4 we considered gases, in which intermolecular forces play only a minor role. Here, we deal with liquids and solids, in which the forces that hold molecules together are of crucial importance for determining the physical properties of bulk samples. Individual water molecules, for instance, are not wet, but bulk water is wet because water molecules are attracted to other substances and spread over their surfaces. Individual water molecules neither freeze nor boil, but bulk water does, because in the process of freezing molecules stick together and form a rigid array and in boiling they separate from one another and form a gas. We have to refine our atomic and molecular model of matter to see how bulk properties can be interpreted in terms of the properties of individual molecules, such as their size, shape, and polarity. We begin by exploring intermolecular forces, the forces between molecules, as distinct from the forces responsible for the formation of chemical bonds between atoms. Then we consider how intermolecular forces determine the physical properties of liquids and the structures and physical properties of solids. INTERMOLECULAR FORCES The simplest state of matter is a gas. We can understand many of the bulk properties of a gas—its pressure, for instance—in terms of the kinetic model introduced in Chapter 4, in which the molecules do not interact with one another except during collisions. We have also seen that this model can be improved and used to explain the INTERMOLECULAR FORCES 5.1 The Origin of Intermolecular Forces 5.2 Ion–Dipole Forces 5.3 Dipole–Dipole Forces 5.4 London Forces 5.5 Hydrogen Bonding 5.6 Repulsions LIQUID STRUCTURE 5.7 Order in Liquids 5.8 Viscosity and Surface Tension SOLID STRUCTURES 5.9 Classification of Solids 5.10 Molecular Solids 5.11 Network Solids 5.12 Metallic Solids 5.13 Unit Cells 5.14 Ionic Structures THE IMPACT ON MATERIALS 5.15 Liquid Crystals 5.16 Ionic Liquids 171 Chapter 5 LIQUIDS AND SOLIDS properties of real gases, by taking into account the fact that molecules do in fact attract and repel one another. But what is the origin of these attractive and repulsive forces? How does their strength relate to the properties of bulk matter? These are some of the questions addressed in the next six sections. 5.1 The Origin of Intermolecular Forces Intermolecular forces are responsible for the existence of several different “phases” of matter. A phase is a form of matter that is uniform throughout in both chemical composition and physical state. The phases of matter include the three common physical states, solid, liquid, and gas (or vapor), introduced in Section A. Many substances have more than one solid phase, with different arrangements of their atoms or molecules. For instance, carbon has several solid phases; one is the hard, transparent diamond and another is the soft, black graphite we use in common pencil lead. A condensed phase means simply a solid or liquid phase. The temperature at which a gas condenses to a liquid or a solid depends on the strength of the attractive forces between its molecules. All interionic and almost all intermolecular interactions can be traced to the coulombic interaction between charges (Section 2.4), and throughout the discussion of intermolecular interactions we shall build on Eq. 5 from Section A, the expression for the potential energy EP of two charges Q1 and Q2 separated by a distance r: (1)* This expression applies directly to ions, but it underlies all the interactions we shall discuss, including the interactions between neutral molecules. Figure 5.1 depicts the general features of the distance dependence of this potential energy of the interaction between atoms that form chemical bonds and between atoms or molecules that do not form chemical bonds to one another. In each case, as the separation decreases from large values, their energy is lowered. However, there comes a stage when the potential energy begins to rise. The repulsions rapidly become dominant, and the potential energy rises sharply to high values. The shapes of the two curves are similar, but the depth of the minimum is very much less for intermolecular interactions than when bonds form and the minima occur at greater distances. In this chapter we focus on intermolecular interactions; the different types of interactions are summarized in Table 5.1. Condensed phases form when attractive forces between molecules pull them together; repulsions dominate at short separations. 5.2 Ion–Dipole Forces Ionic solids dissolve in water when a number of water molecules become attached to each ion and separate it from the other ions. The attachment of water molecules to solute EP = Q1Q2 4␲ε0r 172 CHAPTER 5 LIQUIDS AND SOLIDS TABLE 5.1 Interionic and Intermolecular Interactions* Type of interaction Typical energy (kJ·mol–1 ) Interacting species ion–ion 250 ions only ion–dipole 15 ions and polar molecules dipole–dipole 2 stationary polar molecules 0.3 rotating polar molecules dipole–induced-dipole 2 at least one molecule must be polar London (dispersion)† 2 all types of molecules hydrogen bonding 20 molecules containing an N∫H, O∫H, or F∫H bond; a shared H atom links the molecules *The total interaction experienced by a species is the sum of all the interactions in which it can participate. † Also known as the induced-dipole–induced-dipole interaction. 0 Internuclear separation, r Potentialenergy 0 Intermolecular interaction Ionic and covalent bonding FIGURE 5.1 The distance dependence of the potential energy of the interaction between atoms or ions that form a bond (orange, lower line) and those that do not form bonds (brown, upper line). Notice the deep energy well that is a sign of bond formation. The dip in the upper line is an indication that even when atoms or molecules do not form a bond, attractive forces lower the energies of the particles. particles, particularly but not only ions, is called hydration. Hydration of ions is due to the polar character of the H2O molecule (1). The partial negative charge on the O atom is attracted to the cation, and the partial positive charges of the H atoms are repelled by it. Therefore, the water molecules can be expected to cluster around the cation with a lone pair of electrons on each O atom pointing inward and the H atoms pointing outward (Fig. 5.2, left). We expect the reverse arrangement around an anion: the H atoms have partial positive charges, and so they are attracted to the anion’s negative charge (Fig. 5.2, right). Because hydration arises from the interaction between the ion and the partial charges on the polar water molecules, it is an example of an ion–dipole interaction. Neutron diffraction studies of dilute aqueous solutions of LiCl and NaCl verify that the H atoms on the water molecules are attracted to the anions in a linear hydrogen bond-like arrangement while the partial negative charges on the O atoms are attracted to the cations. The potential energy of the interaction between the full charge of an ion and the two partial charges of a polar molecule is (2) Here z is the charge number of the ion and ␮ is the electric dipole moment of the polar molecule. What does this equation tell us? The negative sign means that the potential energy of the ion is lowered by its interaction with the polar solvent. The dependence on 1/r2 means that the interaction between an ion and a dipole depends more strongly on distance than does the interaction between two ions, which is proportional to 1/r, as seen in Eq. 1 (Fig. 5.3); therefore, it acts over a shorter range. Because of the short range of the interaction, polar molecules need to be very close to an ion—almost in contact—before the interaction is significant. Even when the molecule and ion are very close, the ion–dipole forces are still smaller than the attraction between two ions, because the dipole moment of a polar molecule arises from only partial charges. In addition, an ion attracted to the partial charge at one end of a polar molecule is repelled by the charge at the other end and the two effects partly cancel. At large distances, the two partial charges are at almost the same distance from the ion, and the cancellation is nearly complete: that is why the potential energy of interaction between a point charge and a dipole falls off more quickly with distance (as 1/r2 ) than the interaction of two point charges does (as 1/r). When salts crystallize from an aqueous solution, the ions may retain some of the hydrating water molecules and form solid hydrates such as Na2CO3и10H2O and CuSO4и5H2O. Both the size of the ion and its charge control the extent of hydration. The strength of the ion–dipole interaction is greater the smaller the value of r in Eq. 2 (that is, the closer the dipole can come to the center of the ion). Because of their stronger ion–dipole interactions, small cations attract the polar H2O molecules more strongly than large cations do. As a result, small cations are more extensively hydrated than large cations. In fact, lithium and sodium commonly form hydrated salts, whereas the heavier Group 1 elements (potassium, rubidium, and cesium), which have bigger cations, do not. Solid ammonium salts are usually anhydrous, or water free, for a similar reason: an NH4 ϩ ion has about the same radius (151 pm) as an Rbϩ ion (152 pm). For ions of similar size we should expect hydration to be more important the higher the charge. We can see the effect of charge on the extent of hydration by comparing barium and potassium cations, which have similar radii (135 pm for Ba2ϩ and 138 pm for Kϩ ). In the solid state potassium salts are not hydrated to any appreciable extent, but barium salts are often hydrated. For example, barium chloride is found as BaCl2и2H2O, but potassium chloride is anhydrous. The difference can be traced to the barium ion’s higher charge. Lanthanum, barium’s neighbor has an ion that is both smaller (122 pm) and more highly charged (La3ϩ ); so we can expect it to have strong ion–dipole interactions and its compounds to be extensively hydrated. In fact, its salts include La(NO3)3и6H2O and La2(SO4)3и9H2O. Ion–dipole interactions are strong for small, highly charged ions; one consequence is that small, highly charged cations are often hydrated in compounds. Ep r ƒzƒ m r2 5.2 ION–DIPOLE FORCES 173 δ− δ+ δ+ δ− 1 Cation Anion FIGURE 5.2 In water, ions are hydrated. On the left, a cation is surrounded by water molecules, oriented with their partially negatively charged oxygen atoms facing the ion. On the right, an anion is surrounded by water molecules that direct their partially positively charged hydrogen atoms toward the ion. Separation, r Potentialenergy,EP 1/r6 1/r3 1/r2 1/r 0 FIGURE 5.3 The distance dependence of the potential energy of the interaction between ions (red, lowest line), ions and dipoles (brown), stationary dipoles (green), and rotating dipoles (blue, uppermost line). Living Graph 5.3 174 CHAPTER 5 LIQUIDS AND SOLIDS 5.3 Dipole–Dipole Forces What would we see if we could observe a polar molecule surrounded by other polar molecules in a solid? An example of a polar molecule is chloromethane, CH3Cl, with the partial negative charge on the Cl atom and the partial positive charge spread over the H atoms (2). The arrangement of molecules has a low energy if the partial negative charge of a Cl atom on one molecule is closer to the partial positive charge on the H atoms on a neighboring molecule than it is to the partial negative charge. So we would expect to see the surrounding molecules lined up with opposite partial charges on neighboring molecules as close together as possible (Fig. 5.4). The interaction between dipoles is called the dipole–dipole interaction, and the resulting potential energy is (3) Here, ␮1 and ␮2 are the dipole moments of two interacting molecules (for a solid composed of identical molecules, ␮1 ϭ ␮2). The greater the polarity of the molecules, the stronger are the interactions. Equation 3 also shows that doubling the distance between the molecules reduces the strength of their interaction by a factor of 23 ϭ 8. The strong dependence on distance means that the potential energy falls off eight times as fast as the energies of ion–ion interactions and twice as fast as ion–dipole interactions (see Fig. 5.3). The reason for this more rapid falling off is that the opposite partial charges on each molecule seem to cancel and merge as the distance between the molecules increases, whereas in the interaction between a point charge and a dipole, only the partial charges on the dipole seem to merge. Now imagine that we can observe the same chloromethane molecule in a gas. The molecule and its neighbors are all rotating rapidly (Fig. 5.5). For perfectly free rotation, the attractions between opposite partial charges and the repulsions between like partial charges cancel and there is no net interaction. However, in reality the rotating neighbors linger slightly in energetically favorable orientations (their oppositely charged ends adjacent), and so the attractive interactions between opposite partial charges slightly outweigh the repulsive interactions between like partial charges. As a result, there is a weak net attraction between rotating polar molecules in the gas phase. It turns out that the potential energy varies as the sixth power of the distance between the molecules (see Fig. 5.3): (4) Doubling the separation of polar molecules reduces the strength of the interaction by a factor of 26 ϭ 64, and so dipole–dipole interactions between rotating molecules have a significant effect only when the molecules are very close. We can now start to understand why the kinetic model accounts for the properties of gases so well: gas molecules rotate and are far apart for most of the time, so any interactions between their molecules are very weak. Equation 4 also describes attractions between rotating molecules in a liquid. However, in the liquid phase, molecules are closer than in the gas phase and therefore the dipole–dipole interactions are much stronger. Because a lot of energy is required to separate molecules with strong attractions to one another, substances with strong intermolecular forces boil only at high temperatures. We say that they have high boiling points. Ep r - m1m2 r6 Ep r - m1m2 r3 Ϫ␦ ϩ␦ Ϫ␦ϩ␦ Ϫ␦ ϩ␦ Ϫ␦ ϩ␦ δϪ δϪδϪ δϩ δϩ δϩ 2 FIGURE 5.4 Polar molecules attract each other by the interaction between the partial charges of their electric dipoles (represented by the arrows). Both the relative orientations shown (end to end or side by side) result in a lower energy. It takes about 1 ps for a small molecule to make a complete revolution in the gas phase. EXAMPLE 5.1 Predicting relative boiling points on the basis of dipole–dipole interactions Which would you expect to have the higher boiling point, p-dichlorobenzene (3) or o-dichlorobenzene (4)? PLAN The substance with the stronger intermolecular forces will have the higher boiling point. When two compounds have different dipole moments but are otherwise very similar, we expect the molecules with the larger electric dipole moment to interact more strongly. Therefore, assign the higher boiling point to the more strongly polar compound. To decide 3 p-Dichlorobenzene Cl Cl 4 o-Dichlorobenzene Cl Cl whether a molecule is polar, determine whether the dipole moments of the bonds cancel each other, as explained in Section 3.3. The polarity of C∫H bonds is sufficiently low that those bonds have little effect on the molecular polarity and can be ignored. SOLVE 5.4 LONDON FORCES 175 The two C∫Cl bonds in p-dichlorobenzene lie directly across the ring and their dipole moments cancel, thereby producing a nonpolar molecule. An o-dichlorobenzene molecule is polar because the two C∫Cl bond dipoles do not cancel. We therefore predict that o-dichlorobenzene will have a higher boiling point than that of p-dichlorobenzene. Evaluate The experimental values are found to be 180°C for o-dichlorobenzene and 174°C for p-dichlorobenzene. Self-Test 5.1A Which will have the higher boiling point, cis-dichloroethene (5) or trans-dichloroethene (6)? [Answer: cis-Dichloroethene] Self-Test 5.1B Which will have the higher boiling point, 1,1-dichloroethene (7) or trans-dichloroethene? Polar molecules take part in dipole–dipole interactions, the attraction between the partial charges of their molecules. Dipole–dipole interactions are weaker than forces between ions and fall off rapidly with distance, especially in the liquid and gas phases, where the molecules rotate. 5.4 London Forces Attractive interactions are found even between nonpolar molecules. The evidence for these interactions includes the fact that the noble gases—which, because they are monatomic, are necessarily nonpolar—can be liquefied, and many nonpolar compounds, such as the hydrocarbons that make up gasoline, are liquids. At first sight, there seems to be no means by which two nonpolar molecules could attract each other. To find the explanation, we must refine our model of the electron distribution in a molecule. First, recall that all the representations of electron distributions and charge distributions in the computer graphics that we have seen (for example, structures 1 and 2) are average values. In a nonpolar molecule or a single atom, the electrons appear to be symmetrically distributed. In fact, at any instant, the electron clouds of atoms and molecules are not uniform. If we could take a snapshot of a molecule at a given instant, the electron distribution would look like a swirling fog. Electrons may accumulate somewhere in a molecule, leaving a nucleus elsewhere partly exposed. As a result, one region of the molecule will have a fleeting partial negative charge and another region will have a fleeting partial positive charge; in the next moment—about 10Ϫ16 s later—the charges may be reversed or in other locations. Even a nonpolar molecule may have an instantaneous, fleeting dipole moment (Fig. 5.6). An instantaneous dipole moment on one molecule distorts the electron cloud on a neighboring molecule and gives rise to a dipole moment on that molecule: the two 5 cis-Dichloroethene C ClH C ClH 6 trans-Dichloroethene C ClH C HCl 7 1,1-Dichloroethene Cl H C Cl C H High-energy orientations Low-energy orientations ϩ␦Ϫ␦ ϩ␦ Ϫ␦ FIGURE 5.5 A polar molecule rotating near another polar molecule spends more time in the low-energy orientations (bottom) that maximize attractions, and so the net interaction is attractive, but not as strong as it would be if the molecules were not rotating. instantaneous dipoles attract each other. An instant later, the swirling electron cloud of the first molecule will give rise to a dipole moment in a different direction, but that new dipole moment induces a dipole moment in the second molecule, and still the two molecules attract each other. That is, although there is a constant flickering of the dipole moment of one molecule from one orientation to another, the induced dipole moment of the second molecule follows it faithfully, and there is a net attraction between the two molecules. This attractive interaction is called the London interaction. It acts between all molecules and is the only interaction between nonpolar molecules. The strength of the London interaction depends on the polarizability, ␣ (alpha), of the molecules, the ease with which their electron clouds can be distorted. Highly polarizable molecules are those in which the nuclear charges have little control over the surrounding electrons, perhaps because the atoms are large and the distance between electrons and the nuclei is great or because the valence electrons are well shielded by the inner electrons. There can then be big fluctuations in electron density, and hence highly polarizable molecules can have large instantaneous dipole moments and strong London interactions. Detailed calculations show that the potential energy of the London interaction varies as the inverse sixth power of the separation of two molecules: (5) Like the potential energy of dipole–dipole interactions between rotating polar molecules, the potential energy of the London interaction decreases very rapidly with distance (as 1/r6 ; see Fig. 5.3). The strength of the interaction increases with the polarizability of the interacting molecules. Because a large molecule with many electrons is typically more polarizable than a small molecule with only a few electrons, a large molecule is likely to have stronger London interactions than a smaller one (Fig. 5.7). We can now see why the halogens range from gases (F2 and Cl2), through a liquid (Br2), to a solid (I2) at room temperature: the molecules have an increasing number of electrons, so their polarizabilities and hence their London interactions increase going down the group. The increase in strength of London forces is striking when heavier atoms are substituted for hydrogen atoms. Methane boils at Ϫ161°C, but tetrachloromethane (carbon tetrachloride, CCl4) has many more electrons and is a liquid that boils at 77°C (Table 5.2). Tetrabromomethane, CBr4, has even more electrons: it is a solid at room temperature. The effectiveness of London forces also depends on the shapes of molecules. Both pentane (8) and 2,2-dimethylpropane (9), for instance, have the molecular formula C5H12, and so they each have the same number of electrons. However, they have different boiling points (36° and 10°C, respectively). Molecules of pentane are relatively long and rod shaped. The instantaneous partial charges on adjacent rod-shaped molecules can be in contact at several points, leading to strong interactions. In contrast, the instantaneous partial charges on more spherical molecules such as 2,2-dimethylpropane cannot get so close to one another, because only a small region of each molecule can be in contact (Fig. 5.8). As a result of the strong dependence on distance (1/r6 in Eq. 5), the London interactions between rod-shaped molecules are more effective than those between spherical molecules with the same number of electrons. Closely related to the London interaction is the dipole–induced-dipole interaction, in which a polar molecule interacts with a nonpolar molecule (for example, when oxygen dissolves in water). Like the London interaction, the dipole–induced-dipole interaction arises from the ability of one molecule to induce a dipole moment in the other. However, in this case, the molecule that induces the dipole moment has a permanent dipole moment. The potential energy of the interaction is (6) Once again, the potential energy is inversely proportional to the sixth power of the separation. Notice that the potential energies of the dipole–dipole interaction of rotating Ep r - m1 2 a2 r6 Ep r - a1a2 r6 176 CHAPTER 5 LIQUIDS AND SOLIDS ϩ␦ ϩ␦ ϩ␦ ϩ␦ Ϫ␦ Ϫ␦ Ϫ␦ Ϫ␦ 8 Pentane, C5H12 9 2,2-Dimethylpropane, C(CH3)4 FIGURE 5.7 These hydrocarbons show how London forces increase in strength with molar mass. Pentane is a mobile liquid (left); pentadecane, C15H32, a viscous liquid (middle); and octadecane, C18H38, a waxy solid (right). To some extent, the effect of increasing intermolecular forces is enhanced by the ability of long-chain molecules to tangle with one another. FIGURE 5.6 The rapid fluctuations in the electron distribution in two neighboring molecules result in two instantaneous electric dipole moments that attract each other. The fluctuations flicker into different positions, but each new arrangement in one molecule induces an arrangement in the other that results in mutual attraction. polar molecules in the gas phase, the London interaction, and the dipole–induced-dipole interaction all have the form (7)* with C depending on the molecules and the type of interaction. Intermolecular interactions that depend on the inverse sixth power of the separation are known collectively as van der Waals interactions, after Johannes van der Waals, the Dutch scientist who studied them extensively. Ep r - C r6 5.4 LONDON FORCES 177 TABLE 5.2 Melting and Boiling Points of Substances* Substance Melting point (°C) Boiling point (°C) Substance Melting point (°C) Boiling point (°C) Noble gases Inorganic substances with small molecules He Ϫ270 (3.5 K)† Ϫ269 (4.2 K) H2 Ϫ259 Ϫ253 Ne Ϫ249 Ϫ246 N2 Ϫ210 Ϫ196 Ar Ϫ189 Ϫ186 O2 Ϫ218 Ϫ183 Kr Ϫ157 Ϫ153 H2O 0 100 Xe Ϫ112 Ϫ108 H2S Ϫ86 Ϫ60 Halogens NH3 Ϫ78 Ϫ33 F2 Ϫ220 Ϫ188 CO2 — Ϫ78s Cl2 Ϫ101 Ϫ34 SO2 Ϫ76 Ϫ10 Br2 Ϫ7 59 Organic compounds I2 114 184 CH4 Ϫ182 Ϫ162 Hydrogen halides CF4 Ϫ150 Ϫ129 HF Ϫ93 20 CCl4 Ϫ23 77 HCl Ϫ114 Ϫ85 C6H6 6 80 HBr Ϫ89 Ϫ67 CH3OH Ϫ94 65 HI Ϫ51 Ϫ35 glucose 142 d sucrose 184d — *Abbreviations: s, solid sublimes; d, solid decomposes. † Under pressure. (a) (b) ϩ␦ ϩ␦ϩ␦Ϫ␦ Ϫ␦ ϩ␦ Ϫ␦ Ϫ␦ FIGURE 5.8 (a) The instantaneous dipole moments in two neighboring rodshaped molecules tend to be close together and interact strongly over a relatively broad region of the molecule, as indicated by the vertical lines. (b) Those on neighboring spherical molecules tend to be farther apart and interact weakly over only a small region of the molecule. EXAMPLE 5.2 Accounting for a trend in boiling points Explain the trend in the boiling points of the hydrogen halides: HCl, –85°C; HBr, –67°C; HI, –35°C. PLAN Stronger intermolecular forces result in higher boiling points. The dipole moments, and therefore the strength of the dipole–dipole interactions, increase with the polarity of the H∫X bond and therefore with the difference in electronegativity between the hydrogen and the halogen atoms. The strength of London forces increases with the number of electrons. Use the data to decide which is the dominant effect. SOLVE The data in Fig. 2.12 show that electronegativity differences decrease from HCl to HI, and so the dipole moments decrease as well. Therefore, dipole–dipole forces decrease, too, a trend suggesting that the boiling points should decrease from HCl to HI. This prediction conflicts with the data; so we examine the London forces. The number of electrons in a molecule increases from HCl to HI, and so the strength of the London interaction increases, too. Therefore, the boiling points should increase from HCl to HI, in accord with the data. This analysis suggests that London forces dominate dipole–dipole interactions for these molecules. Self-Test 5.2A Account for the trend in boiling points of the noble gases, which increase from helium to xenon. [Answer: The strength of the London interaction increases as the number of electrons increases.] Self-Test 5.2B Suggest a reason why trifluoromethane, CHF3, has a higher boiling point than tetrafluoromethane, CF4. The London interaction arises from the attraction between instantaneous electric dipoles on neighboring molecules and acts between all types of molecules; its strength increases with the number of electrons and occurs in addition to any dipole–dipole interactions. Polar molecules also attract nonpolar molecules by weak dipole–induced-dipole interactions. 5.5 Hydrogen Bonding The London interaction is “universal” in the sense that it applies to all molecules regardless of their chemical identity. Similarly, the dipole–dipole interaction depends only on the polarity of the molecule, regardless of its chemical identity. However, there is another very strong interaction between molecules that is specific to molecules with certain types of atoms. We might suspect the existence of a special interaction when we plot the boiling points of the common binary hydrogen compounds of the elements in Groups 14/IV to 17/VII (Fig. 5.9). The trend in Group 14/IV is what we expect for similar compounds that differ in their number of electrons—the boiling points increase down the group because the strength of the London interaction increases. However, ammonia, water, and hydrogen fluoride all show anomalous behavior. Their exceptionally high boiling points suggest that there are unusually strong attractive forces between their molecules. The strong interaction responsible for the high boiling points of these substances and certain others is the hydrogen bond, an intermolecular attraction in which a hydrogen atom bonded to a small, strongly electronegative atom, specifically N, O, or F, is attracted to a lone pair of electrons on another N, O, or F atom (10). To understand how it forms, let’s imagine what happens when one water molecule comes close to another. Each O∫H bond is polar. The electronegative O atom exerts a strong pull on the electrons in the bond, and the proton of the H atom is almost completely unshielded. Because it is so small, the hydrogen atom, with its partial positive charge, can get very close to one of the lone pairs of electrons on the O atom of another water molecule. The lone pair and the partial positive charge attract each other strongly and form a hydrogen bond. Hydrogen bonding is strongest when the hydrogen atom is on a straight line between the two oxygen atoms. A hydrogen bond is denoted by a dotted line, so the hydrogen bond between two O atoms is denoted O∫HLO. The O∫H bond length is 101 pm and the HLO distance is somewhat longer; in ice it is 175 pm. Self-Test 5.3A Which of the following intermolecular links can be made by hydrogen bonds: (a) CH3NH2 to CH3NH2; (b) CH3OCH3 to CH3OCH3; (c) HBr to HBr? [Answer: Only in (a) is H bonded directly to N, O, or F.] Self-Test 5.3B Which of the following molecules can take part in hydrogen bonding with other molecules of the same compound: (a) CH3OH; (b) PH3; (c) HClO (which has the structure Cl∫O∫H)? 178 CHAPTER 5 LIQUIDS AND SOLIDS –200 –100 0 100 100 H2O −33 NH3 −85 HCl −61 H2S SiH4 −112 H2Se −42 AsH3 −55 HBr −67 GeH4 −88 H2Te −2 SbH3 −17 HI −35 SnH4 −52 −88 PH3 −164 CH4 20 HF 200 Normalboilingpoint(°C) 2 3 4 5 Period FIGURE 5.9 The boiling points of most of the molecular hydrides of the p-block elements show a smooth increase with molar mass in each group. However, the boiling points of three compounds— ammonia, water, and hydrogen fluoride—are strikingly out of line. O OH 10 Hydrogen bond (in water) When it can form, a hydrogen bond is so strong—about 10% of a typical covalent bond strength—that it dominates all the other types of intermolecular interactions. Hydrogen bonding is strong enough to survive even in the vapor of some substances. Liquid hydrogen fluoride, for instance, contains zigzag chains of HF molecules (11), and the vapor contains short fragments of the chains and (HF)6 rings. The vapor of acetic acid, CH3COOH, contains dimers, pairs of molecules, linked by two hydrogen bonds (12). Hydrogen bonds play a vital role in maintaining the shapes of biological molecules. The shape of a protein molecule is governed largely by hydrogen bonds; once the bonds are broken, the delicately organized protein molecule loses its function. When we cook an egg, the clear albumen becomes milky white, because the heat breaks the hydrogen bonds in its protein molecules, which collapse into a random jumble. Trees are held upright by hydrogen bonds (Fig. 5.10). Cellulose molecules (which have many ∫OH groups) can form many hydrogen bonds with one another, and the strength of wood is due in large part to the strength of the hydrogen bonds between neighboring ribbonlike cellulose molecules. Hydrogen bonding also binds the two chains of a DNA molecule together, and so hydrogen bonding is a key to understanding reproduction (see Section 19.15). The hydrogen bonds are strong enough to keep the two chains of a DNA molecule together but so much weaker than typical covalent bonds that they readily give way in cell division without affecting the covalent bonds within the strands of the DNA. Hydrogen bonding, which occurs when hydrogen atoms are bonded to oxygen, nitrogen, or fluorine atoms, is the strongest type of intermolecular interaction. 5.6 Repulsions As we have remarked, when molecules (or atoms that do not form bonds) are very close together, they repel one another, as was shown on the left of Fig. 5.1. This repulsion can be traced to the Pauli exclusion principle. To see why this is so, think about two He atoms approaching each other. At short separations, their 1s atomic orbitals overlap and form a bonding and an antibonding molecular orbital. Two of the four electrons supplied by the two atoms occupy the lower, bonding orbital; the Pauli exclusion principle then requires the remaining two electrons to occupy the antibonding orbital. As we remarked in Section 3.9, an antibonding orbital is more antibonding than a bonding orbital is bonding, so the net effect is an increase in energy as the two atoms merge into each other. The effect increases sharply as the distance decreases because the overlap between the atomic orbitals increases very rapidly as they approach. The same effect arises for all molecules in which the atoms have filled shells, even though the details of the bonding and antibonding orbitals they form may be much more complicated, and all molecules repel each other when they come into contact and their orbitals overlap. The electron density in all atomic orbitals and the molecular orbitals they form decreases exponentially toward zero at large distances from the nucleus, so we can expect the overlap between orbitals on neighboring molecules also to depend exponentially on their separation. As a result, the repulsions between molecules depend, typically, exponentially on their separation, and are effective only when the two molecules are very close together, but once they are close, increase sharply. This sharp dependence on separation is the underlying reason why the objects around us have definite, well defined shapes. Intermolecular repulsions arise from the overlap of orbitals on neighboring molecules and the requirements of the Pauli exclusion principle. LIQUID STRUCTURE The molecules in a liquid are held in close contact with their neighbors by intermolecular forces, but they have enough energy to move past and tumble over one another (Fig. 5.11). When we imagine a liquid, we can think of a jostling crowd of molecules, each one constantly changing places with its neighbors. A liquid at rest is like a crowd of people milling about in a stadium; a flowing liquid is like a crowd of people leaving a stadium. 5.6 REPULSIONS 179 11 Hydrogen fluoride, (HF)n H F 12 Acetic acid dimer FIGURE 5.10 Vegetation, even huge trees such as these, is held upright by the powerful intermolecular hydrogen bonds that exist between the ribbonlike cellulose molecules that form much of its bulk. Without hydrogen bonding, these trees would collapse. 5.7 Order in Liquids The liquid phase of matter is the most difficult to visualize. We have seen that a gasphase molecule moves with almost complete freedom. The intermolecular forces from other molecules are minimal, and movement is highly disordered. In the solid phase, a molecule is locked in place by intermolecular forces and can only oscillate around an average location. The liquid phase lies between the extremes of the gas and solid phases. The molecules are mobile, but they cannot escape from one another completely. A crystalline solid has long-range order. In other words, its atoms or molecules lie in an orderly arrangement that is repeated over long distances. When the crystal melts, that long-range order is lost. In the liquid, the kinetic energy of the molecules can partly overcome the intermolecular forces, and so the molecules are able to move past one another. However, the molecules still experience strong attractions to one another. In water, for instance, only about 10% of the hydrogen bonds are broken on melting. The rest are continually broken and re-formed with different water molecules. At any given moment, the immediate vicinity of a molecule in the liquid is like that in the solid, but the ordering does not extend very far past the nearest neighbors. This local ordering is called short-range order. In water, each molecule is surrounded by an approximately tetrahedral arrangement of other molecules as a result of hydrogen bonds. These interactions are ceaselessly changing from one moment to the next, but are strong enough to affect the local structure of molecules up to the boiling point. In the liquid phase, molecules have short-range order but not long-range order. 5.8 Viscosity and Surface Tension The viscosity of a liquid is its resistance to flow: the higher the viscosity of the liquid, the more sluggish the flow. A liquid with a high viscosity, such as molasses at room temperature or molten glass, is said to be “viscous.” The viscosity of a liquid is an indication of the strength of the forces between its molecules: strong intermolecular forces hold molecules together and do not let them move past one another easily (Fig. 5.12). However, the prediction of viscosity is very difficult because it depends not only on the strength with which molecules interact with one another but the ease with which they can take up new positions as the fluid flows. The strong hydrogen bonds in water give it a viscosity greater than that of benzene: benzene molecules can easily slip past one another in the liquid but, for water molecules to move, hydrogen bonds have to be wrenched apart. Nevertheless, the viscosity of water is not very high because an H2O molecule can quickly readjust the pattern of hydrogen bonds that it forms with its neighbors. On the other hand, glycerol, HOCH2CH(OH)CH2OH, is much more viscous not only because it forms numerous hydrogen bonds but also because the bulky molecule is less agile at forming hydrogen bonds as the fluid flows. Another factor is the entanglement of long hydrocarbon chains. The molecules of hydrocarbon oils and greases are nonpolar and so participate only in London forces. However, they have long chains that tangle together like cooked spaghetti (Fig. 5.13), and the molecules move past one another only with difficulty. 180 CHAPTER 5 LIQUIDS AND SOLIDS Mercury Ethanol Water Tetrachloromethane Benzene Octane Diethylether 0.60 0.91 1.06 1.55 0.89 0.52 0.22 Viscosity(centipoise) FIGURE 5.12 The viscosities of several liquids. Liquids composed of molecules that cannot form hydrogen bonds are generally less viscous than those that can form hydrogen bonds. Mercury is an exception: its atoms stick together by a kind of metallic bonding, and its viscosity is very high. The centipoise (cP) is the unit commonly used to report viscosity (1 cP ϭ 10Ϫ3 kgиmиsϪ1 ). FIGURE 5.13 The long threadlike molecules of heavy hydrocarbon oils tend to get tangled together like a plate of cooked spaghetti. As a result, the molecules do not move past one another very readily and the liquid is very viscous. FIGURE 5.11 The structure of a liquid. Although the molecules (represented by the spheres in this series of diagrams) remain in contact with their neighbors, they can move away from one another and have enough energy to push through to a new neighborhood. Consequently, the entire substance is fluid. One sphere is slightly darker so that you can follow its motion. Its path is shown in the insets. Animation 5.11 Viscosity usually decreases as the temperature rises. Molecules have more energy at high temperatures and can wriggle past their neighbors more readily. The viscosity of water at 100°C, for instance, is only one-sixth of its value at 0°C, and so the same amount of water flows through a tube six times as fast at the higher temperature. Another property of a liquid that arises from intermolecular forces is surface tension. The surface of a liquid is smooth because intermolecular forces tend to pull the molecules together and inward (Fig. 5.14); the surface tension is the net inward pull. Once again, we can expect liquids composed of molecules with strong intermolecular forces to have high surface tensions, because the inward pull at the surface will be strong. Indeed, the surface tension of water is about three times as high as that of most other common liquids, because of its strong hydrogen bonds (Table 5.3). The surface tension of mercury is higher still—more than six times that of water. Its high surface tension suggests that the bonds between mercury atoms in the liquid are very strong: in fact, they are partially covalent in character. Surface tension accounts for a number of everyday phenomena. For example, a droplet of liquid suspended in air or on a waxy surface is spherical because the surface tension pulls the molecules into the most compact shape, a sphere (Fig. 5.15). The attractive forces between water molecules are greater than those between water and wax, which is largely hydrocarbon. Surface tension decreases as the temperature rises and the interactions between molecules are overcome by the increased molecular motion. Water has strong interactions with paper, wood, and cloth because it can form hydrogen bonds with the molecules in their surfaces. As a result, water maximizes its contact with these materials by spreading over them; in other words, water wets them. We now see that water is wet because of the hydrogen bonds that its molecules can form. Capillary action, the rise of liquids up narrow tubes, occurs when there are favorable attractions between the molecules of the liquid and the tube’s inner surface. These attractions are forces of adhesion, forces that bind a substance to a surface, as distinct from the forces of cohesion, the forces that bind the molecules of a substance together to form a bulk material. An indication of the relative strengths of adhesion and cohesion is the formation of a meniscus, the curved surface of a liquid, in a narrow tube (Fig. 5.16). The meniscus of water in a glass capillary is curved upward at the edges (forming a concave shape) because the adhesive forces between water molecules and the oxygen atoms and ∫OH groups that are present on a typical glass surface are comparable in strength to the cohesive forces between water molecules. The water therefore tends to spread over the greatest possible area of glass. In contrast, the meniscus of mercury curves downward in glass (forming a convex shape). This shape is a sign that the cohesive forces between mercury atoms are stronger than the forces between mercury atoms and the glass, and so the liquid tends to reduce its contact with the glass. 5.8 VISCOSITY AND SURFACE TENSION 181 FIGURE 5.14 Surface tension arises from the attractive forces acting on the molecules at the surface. The inset shows that a molecule within the liquid experiences attractive forces from all directions, but a molecule at the surface experiences a net inward force. TABLE 5.3 Surface Tensions of Liquids at 25°C Surface tension, Liquid ␥ (mNиmϪ1 ) benzene 28.88 carbon 27.0 tetrachloride ethanol 22.8 hexane 18.4 mercury 472 methanol 22.6 water 72.75 58.0 at 100°C FIGURE 5.15 The nearly spherical shapes of these beads of water on the waxy surface of a leaf arise from the effect of surface tension. FIGURE 5.16 When the adhesive forces between a liquid and glass are stronger than the cohesive forces within the liquid, the liquid curves up to maximize contact with the glass, forming the meniscus shown here for water in glass (left). When the cohesive forces are stronger than the adhesive forces (as they are for mercury in glass), the edges of the surface curve downward to minimize contact with the glass (right). The greater the viscosity of a liquid, the more slowly it flows. Viscosity usually decreases with increasing temperature. Surface tension arises from the imbalance of intermolecular forces at the surface of a liquid. Capillary action arises from the imbalance of adhesive and cohesive forces. SOLID STRUCTURES When the temperature is so low that the molecules of a substance do not have enough energy to escape even partially from their neighbors, the substance solidifies. The nature of the solid depends on the types of forces that hold the atoms, ions, or molecules together. An understanding of solids in terms of the properties of their atoms will help us to understand why, for instance, metals can be pounded into different shapes but salt crystals shatter, and why diamonds are so hard. 5.9 Classification of Solids A crystalline solid is a solid in which the atoms, ions, or molecules lie in an orderly array (Fig. 5.17). A crystalline solid has long-range order. An amorphous solid is one in which the atoms, ions, or molecules lie in a random jumble, as in butter, rubber, and glass (Fig. 5.18). An amorphous solid has a structure like that of a frozen instant in the life of a liquid, with only short-range order. Crystalline solids typically have flat, welldefined planar surfaces called crystal faces, which lie at definite angles to one another. These faces are formed by orderly layers of atoms (Box 5.1). Amorphous solids do not have well-defined faces unless they have been molded or cut. The arrangement of atoms, ions, and molecules within a crystal is determined by x-ray diffraction (Major Technique 3, which follows this chapter), one of the most useful techniques for determining the structures of solids. We classify crystalline solids according to the bonds that hold their atoms, ions, or molecules in place: Molecular solids are assemblies of discrete molecules held in place by intermolecular forces. Network solids consist of atoms covalently bonded to their neighbors throughout the extent of the solid. Metallic solids, also called simply metals, consist of cations held together by a sea of electrons. Ionic solids are built from the mutual attractions of cations and anions. 182 CHAPTER 5 LIQUIDS AND SOLIDS FIGURE 5.18 (Left) Quartz is a crystalline form of silica, SiO2, with the atoms in an orderly network, represented here in two dimensions. (Right) When molten silica solidifies in an amorphous arrangement, it becomes glass. Now the atoms form a disorderly network. FIGURE 5.17 Crystalline solids have well-defined faces and an orderly internal structure. Each face of the crystal is formed by the top plane of an orderly stack of atoms, molecules, or ions. 5.9 CLASSIFICATION OF SOLIDS 183 Even the most powerful optical microscopes cannot reveal the individual atoms of a solid surface. However, the new field of nanotechnology, the development and study of devices only nanometers in size, requires the ability to resolve surfaces on an atomic scale. A new technique that allows individual atoms to be visualized, scanning tunneling microscopy (STM), is an important tool for nanotechnology. The technique produces images like those on this page. The first figure shows a tiny sodium iodide crystal lying on a copper surface. HOW DO WE KNOW . . . WHAT A SURFACE LOOKS LIKE?BOX 5.1 An experimenter attempted to create a two-dimensional sodium iodide crystal on a copper surface, but the ions spontaneously rearranged themselves into a tiny three-dimensional crystal. the “scanning” in the name). The tip ends in a single atom (see the second figure). As the tip moves across the surface at a constant height, the tunneling ebbs and flows, and the current varies correspondingly through the circuit. The image is a portrayal of the current measured on each scan. In a modification, the current is maintained at a constant level by varying and monitoring the height of the tip above the surface. That height is controlled by using a piezoelectric substance to support the tip, a substance that changes dimensions according to the electrical potential difference applied to it. By measuring the potential difference that must be applied to the piezoelectric support to maintain a constant current through the tip, the height of the tip can be inferred and plotted on a computer screen. Yet another modification is atomic force microscopy (AFM), in which a fine tip attached to a tiny flexible beam is scanned across the surface. The atom at the end of the tip experiences a force that pulls it toward or pushes it away from the atoms on the surface. The deflection of the beam, which shows the shape of the surface, can be monitored by using light from a laser. An advantage of AFM is that it can image biological surfaces that cannot conduct an electrical current. For example AFM can be used to study the shapes of human chromosomes and how carcinogenic (cancer-causing) substances promote the development of tumors by interfering with the reproduction of the DNA molecule. An AFM image of the human X chromosome is shown in the third figure. Electron current Tip Surface This AFM image shows the X chromosome that determines the gender of a person. It includes about 5% of a person’s DNA. Females have two X chromosomes, males have one X and one Y chromosome. Because AFM spectroscopy does not require chemical modification of the substance being studied, it can reveal important details of chromosome structure. The key idea behind STM is that, because electrons have wavelike properties (Section 1.5), they can penetrate into and through regions where classical mechanics would forbid them to be. This penetration is called tunneling. The effect is used in STM (hence the “tunneling” in the name) by bringing a fine tip up to a surface and monitoring the current that flows through the gap between the tip and the surface. The magnitude of the current, like the tunneling itself, is very sensitive to the separation of the tip and the surface, and even atomic-scale variations affect it. To obtain an STM image, a fine tip is moved back and forth across the surface in a series of closely spaced lines (hence The tip of a scanning tunneling microscope above a surface. Because the tip is too close to the surface for other molecules to interfere, STM devices can be used in a gaseous atmosphere or even in liquids. The images in this box are computer-generated representations, not true photographs. However, they have opened our eyes to the appearance of surfaces in the most extraordinary ways. The 1986 Nobel Prize in Physics was awarded to Ernst Ruska and Gerd Binnig of Germany and Heinrich Rohrer of Switzerland for their invention of the scanning tunneling microscope. Table 5.4 lists examples of each type of solid and their typical characteristics. Solids are dense forms of matter because their atoms, ions, and molecules are packed closely together. Metals are often denser than other kinds of solids because their atoms are packed even more closely. The metallic bond is relatively strong. As a result, most metals have high melting points and serve as tough, strong materials for construction. Ionic solids have higher melting points than molecular solids because interionic forces are much stronger than intermolecular forces. Network solids (such as diamond) have very high melting points because they do not melt until the covalent bonds between their atoms have been overcome. In this part of the chapter, we begin with molecular solids and distinguish them from network solids. Then we examine metallic solids, which, if consisting of a single element, are built from identical atoms stacked together in orderly arrays. The structures of ionic solids are based on the same kinds of arrays but are complicated by the need to take into account the presence of ions of opposite charges and different sizes. Crystalline solids have a regular internal arrangement of atoms or ions; amorphous solids do not. Solids are classified as molecular, network, metallic, or ionic. 5.10 Molecular Solids Molecular solids consist of molecules held together by intermolecular forces and their physical properties depend on the strengths of those forces. Amorphous molecular solids may be as soft as paraffin wax, which is a mixture of long-chain hydrocarbons. These molecules lie together in a disorderly way, and the forces between them are so weak that they can be pushed past one another very easily. Many other molecular solids have crystalline structures and strong intermolecular forces that make them brittle and hard. For example, sucrose molecules, C12H22O11, are held together by hydrogen bonds between their numerous ∫OH groups. Hydrogen bonding between sucrose molecules is so strong that, by the time the melting point has been reached (at 184°C), the molecules themselves have started to decompose. The mixture of partly decomposed products, called caramel, is used to add flavor and color to food. Some molecular solids are very tough. For example, “ultrahigh-density polyethylene” consists of long hydrocarbon chains that lie densely together like close-packed cylinders: the resulting material is so smooth yet tough that it is used to make bullet-proof vests and joint replacements for the human body. Because molecules have such diverse shapes, they stack together in a wide variety of different ways. In ice, for example, each O atom is surrounded by four H atoms in a 184 CHAPTER 5 LIQUIDS AND SOLIDS TABLE 5.4 Typical Characteristics of Solids Class Examples Characteristics metallic s- and d-block elements malleable, ductile, lustrous, electrically and thermally conducting ionic NaCl, KNO3, CuSO4·5H2O hard, rigid, brittle; high melting and boiling points; those soluble in water give conducting solutions network B, C, black P, BN, SiO2 hard, rigid, brittle; very high melting points; insoluble in water molecular BeCl2, S8, P4, I2, ice, relatively low melting and boiling points; glucose, naphthalene brittle if pure FIGURE 5.19 Ice is made up of water molecules that are held together by hydrogen bonds in an open structure. Each O atom is surrounded tetrahedrally by four hydrogen atoms, two of which are ␴-bonded to it and two of which are hydrogen-bonded to it. To show the structure more clearly, only the hydrogen atoms in the front layer are shown. Animation 5.19 tetrahedral arrangement. Two of these H atoms are linked covalently to the O atom through ␴-bonds. The other two belong to neighboring H2O molecules and are linked to the O atom by hydrogen bonds. As a result, the structure of ice is an open network of H2O molecules held in place by hydrogen bonds (Fig. 5.19). Some of the hydrogen bonds break when ice melts; and, as the orderly arrangement collapses, the molecules pack less uniformly but more densely (Fig. 5.20). The openness of the network in ice compared with the closer arrangement of molecules in the liquid explains why it has a lower density than liquid water (0.92 gиcm–3 and 1.00 gиcm–3 , respectively, at 0°C). Solid benzene and solid tetrachloromethane, in contrast, have higher densities than their liquids (Fig. 5.21). Their molecules are held in place by London forces, which are much less directional than hydrogen bonds, and so they can pack together more closely in the solid than in the liquid. Molecular solids are relatively soft and typically melt at relatively low temperatures. 5.11 Network Solids Whereas molecular solids consist of molecules held together by relatively weak intermolecular forces, the atoms in network solids are joined to their neighbors by strong covalent bonds that form a framework extending throughout the crystal. In order to break apart a crystal of a network solid, covalent bonds, which are much stronger than intermolecular forces, must be broken. Therefore, network solids are very hard, rigid materials with high melting and boiling points. Diamond and graphite are elemental network solids. These two forms of carbon are allotropes, meaning forms of an element that differ in the way in which the atoms are linked. Each C atom in diamond is covalently bonded to four neighbors through sp3 hybrid ␴-bonds (Fig. 5.22). The tetrahedral framework extends throughout the solid like the steel framework of a large building. This structure accounts for the great hardness of the solid. Graphite, the most important component of the “lead” of pencils, is a black, lustrous, electrically conducting solid that vaporizes at 3700°C. It consists of flat sheets of sp2 hybridized carbon atoms bonded covalently into hexagons like chicken wire (Fig. 5.23). There are also weak bonds between the sheets. FIGURE 5.20 As a result of its open structure, ice is less dense than liquid water and floats in it (left). Solid benzene is denser than liquid benzene and “benzenebergs” sink in liquid benzene (right). Density −20 +40 Temperature (°C) Water Tetrachloromethane Layer A Layer A Layer B FIGURE 5.23 Graphite consists of layers of hexagonal rings of sp2 hybridized carbon atoms. The slipperiness of graphite results from the ease with which the layers can slide over one another when there are impurity atoms lying between the planes. FIGURE 5.21 Variation in the densities of water and tetrachloromethane with temperature. Note that ice is less dense than liquid water at its freezing point and that water has its maximum density at 4°C. Animation 5.21 FIGURE 5.22 The structure of diamond. Each sphere represents the location of the center of a carbon atom. Each atom is at the center of a tetrahedron formed by the sp3 hybrid covalent bonds to each of its four neighbors. Animation 5.22 Animation 5.23 Ceramic materials are typically noncrystalline inorganic oxides with a network structure that is produced by heat treatment of a powder. They include many silicate minerals, such as quartz (silicon dioxide, which has the empirical formula SiO2), and high-temperature superconductors (Section 6.14). Ceramic materials have great strength and stability, because covalent bonds must be broken to cause any deformation in the crystal. As a result, ceramic materials under physical stress tend to shatter rather than bend. Section 6.11 contains further information on the properties of ceramic materials. Network solids are typically hard and rigid; they have high melting and boiling points. Ceramic materials are commonly network solids. 5.12 Metallic Solids The cations in a metal are bound together by their interaction with the sea formed by the electrons that they have lost (recall Fig. 1.53). For instance, metallic sodium consists of Naϩ ions held together by electrons that spread throughout the solid, with one electron for each cation. Because the interaction between the ions and the electrons is the same in any direction, the arrangement of the cations can be modeled as hard spheres stacked together. It turns out that we can explain the structures and properties of many metals if we suppose that the spheres representing the cations adopt a close-packed structure, in which the spheres stack together with the least waste of space, like oranges in a display (Fig. 5.24). To see how to stack identical spheres together to give a close-packed structure, look at Fig. 5.25. In the first layer (A) each sphere lies at the center of a hexagon of other spheres. The spheres of the second (upper) layer (B) lie in the dips of the first layer (Fig. 5.26). The third layer of spheres will lie in the dips of the second layer, with the pattern repeating over and over again. The third layer of spheres may be added in either of two ways. In the first arrangement, the spheres lie in the dips that are directly above the spheres of the first layer (Fig. 5.27). The third layer then duplicates layer A, the next layer duplicates B, and so on. This procedure results in an ABABAB . . . pattern of layers called a hexagonal closepacked structure (hcp). The hexagonal pattern in the arrangement of atoms can be seen in Fig. 5.28. Magnesium and zinc are examples of metals that crystallize in this way. As can be seen from Fig. 5.28, each sphere has three nearest neighbors in the plane below, six in its own plane, and three in the plane above, giving twelve in all. This arrangement is reported by saying that the coordination number, the number of nearest neighbors of each atom, in the solid is 12. It is impossible to pack identical spheres together with a coordination number greater than 12. In the second arrangement, the spheres of the third layer lie in the dips of the second layer that do not lie directly over the atoms of the first layer (Fig. 5.29). If we call this third layer C, the resulting structure has an ABCABC . . . pattern of layers to give a cubic closepacked structure (ccp, Fig. 5.30), because the atoms form cubes when viewed at an angle to the layers. A ccp structure can be thought of as many of these tiny cubes repeating over and over again in all directions. The coordination number is also 12: each sphere has three nearest neighbors in the layer below, six in its own layer, and three in the layer above. Aluminum, copper, silver, and gold are examples of metals that crystallize in this way. 186 CHAPTER 5 LIQUIDS AND SOLIDS FIGURE 5.24 The close-packed stacks of apples, oranges, and other produce in a grocery display illustrate how atoms stack together in metals to form crystals with flat faces. Layer ALayer A Layer ALayer A Layer BLayer B Layer ALayer A Layer ALayer A Layer BLayer B FIGURE 5.25 A close-packed structure can be built up in stages. The first layer (A) is laid down with minimum waste of space. FIGURE 5.26 The second layer (B) lies in the dips—the depressions—between the spheres of the first layer. Each sphere is touching six other spheres in its layer, as well as three in the layer below and three in the layer above. FIGURE 5.27 When the spheres in the third layer lie directly above the spheres of the first layer, an ABABAB . . . structure is formed. FIGURE 5.28 A fragment of the structure formed as described in Fig. 5.27 shows the hexagonal symmetry of the arrangement—and the origin of its name, “hexagonal close-packed.” Even in a close-packed structure, hard spheres do not fill all the space in a crystal. The gaps—the interstices—between the atoms are called “holes.” To determine just how much space is occupied, we need to calculate the fraction of the total volume occupied by the spheres. 5.12 METALLIC SOLIDS 187 Layer ALayer A Layer BLayer B Layer CLayer C FIGURE 5.29 In an alternative to the scheme shown in Fig. 5.27, the spheres of the third layer can lie in the dips in the second layer that are directly above the dips in the first layer, to give an ABCABC . . . arrangement of layers. FIGURE 5.30 A fragment of the structure constructed as described in Fig. 5.29. This fragment shows the origin of the names “cubic close-packed” or “face-centered cubic” for this arrangement. The layers A, B, and C can be seen along the diagonals of the faces of the cube and are indicated by the different colors of the atoms. HOW DO WE DO THAT? To calculate the fraction of occupied space in a close-packed structure, we consider a ccp structure. We can use the radius of the atoms to find the volume of the cube and how much of that volume is taken up by atoms. First, we look at how the cube is built from the atoms. In Fig. 5.31, we see that the corners of the cubes are at the centers of eight atoms. Only 1/8 of each corner atom projects into the cube, so the corner atoms collectively contribute 8 ϫ 1/8 ϭ 1 atom to the cube. There is half an atom on each of the six faces, so the atoms on each face contribute 6 ϫ 1/2 ϭ 3 atoms, giving four atoms in all within the cube. The length of the diagonal of the face of the cube shown in Fig. 5.31 is 4r, where r is the atomic radius. Each of the two corner atoms contributes r and the atom at the center of the face contributes 2r. From the Pythagorean theorem, we know that the length of the side of the face, a, is related to the diagonal by a2 ϩ a2 ϭ (4r)2 , or 2a2 ϭ 16r2 , and so a ϭ 81/2 r. The volume of the cube is therefore a3 ϭ 83/2 r3 . The volume of each atom is ; so the total volume of the atoms inside the cube is . The ratio of this occupied volume to the total volume of the cube is therefore Total volume of spheres Total volume of cube = (16/3)␲r3 83/2 r3 = 16␲ 3 * 83/2 = 0.74 4 * 4 3␲r3 = 16 3 ␲r3 4 3␲r3 The Pythagorean theorem states that the square of the hypotenuse of a right-angled triangle is equal to the sums of the squares of the other two sides. That is, if the hypotenuse is c and the other two sides are a and b, then a2 ؉ b2 ‫؍‬ c2 . We have shown that 74% of the crystal’s space is occupied by atoms and 26% is considered to be empty. Because the hcp structure has the same coordination number of 12, we know that it is packed as densely and must have the same fraction of occupied space. The holes in the close-packed structure of a metal can be filled with smaller atoms to form alloys (alloys are described in more detail in Sections 6.1–6.4). If a dip between three atoms is directly covered by another atom, we obtain a tetrahedral hole, because it is formed by four atoms at the corners of a regular tetrahedron (Fig. 5.32). There are two tetrahedral holes per atom in a close-packed lattice. When a dip in a layer coincides with a dip in the next layer, we obtain an octahedral hole, because it is formed by six atoms at the corners of a regular octahedron, as shown in Fig. 5.32. There is one octahedral hole for each atom in the lattice. Note that, because holes are formed by two adjacent layers and because neighboring close-packed layers have identical arrangements in hcp and ccp, the numbers of holes are the same for both close-packed structures. a a 4r FIGURE 5.31 The relation of the dimensions of a face-centered cubic unit cell to the radius, r, of the spheres. The spheres are in contact along the face diagonals. Octahedral hole Tetrahedral hole FIGURE 5.32 The locations of octahedral and tetrahedral holes. There are twice as many tetrahedral holes as octahedral holes. Note that both types of holes are defined by two neighboring close-packed layers, so they are present with equal abundance in both hcp and ccp structures. Which close-packed structure—if either—is adopted by a metal depends on which has the lower energy, and that in turn depends on details of its electronic structure. In fact, some elements achieve a lower energy by adopting a different arrangement altogether, as we see in the next section. Many metals have close-packed structures, with the atoms stacked in either a hexagonal or a cubic arrangement; close-packed atoms have a coordination number of 12. Close-packed structures have one octahedral and two tetrahedral holes per atom. 5.13 Unit Cells We do not have to draw the complete crystal lattice every time we want to convey the structure of a solid. Instead, we can focus our attention on a small region of the crystal that is representative of the entire crystal. The small group illustrated in Fig. 5.30 is an example of a unit cell, the smallest unit that, when stacked together repeatedly without any gaps and without rotations, can reproduce the entire crystal (Fig. 5.33). A cubic close-packed unit cell like that illustrated in Fig. 5.33 has an atom at the center of each face of the unit cell; for this reason, it is also called a face-centered cubic structure (fcc). In a body-centered cubic structure (bcc), a single atom lies at the center of a cube formed by eight other atoms (Fig. 5.34). This structure is not close packed, and metals that have a body-centered cubic structure can often be forced under pressure into a close-packed form. Iron, sodium, and potassium are examples of metals that crystallize with bcc structures. A primitive cubic structure has an atom at each corner of a cube. The atoms touch along the edges (Fig. 5.35). This structure is known for only one element, polonium: covalent forces are so strong in this metalloid that they overcome the tendency toward close packing characteristic of metallic bonding. Unit cells are drawn by representing each atom by a dot that marks the location of the atom’s center (Fig. 5.36). All crystal structures can be expressed in terms of only 14 basic patterns of unit cell called Bravais lattices (Fig. 5.37). We can begin to understand why the number of types of unit cells is limited to such a small number by recognizing that regular pentagonal shapes are absent from the Bravais lattices: regular pentagons cannot cover space without gaps (Fig. 5.38). Similarly, regular heptagonal (seven-sided) and higher polygonal shapes cannot be stacked together to cover all space; hence they do not occur among the Bravais lattices. The number of atoms in a unit cell is counted by noting how they are shared between neighboring cells. For example, an atom at the center of a cell belongs entirely to that cell, but one on a face is shared between two cells and counts as one-half an atom. As noted earlier, for an fcc structure, the eight corner atoms contribute 8 ϫ 1/8 ϭ 1 atom to the cell. The six atoms at the centers of faces contribute 6 ϫ 1/2 ϭ 3 atoms (Fig. 5.39). The total number of atoms in an fcc unit cell is therefore 1 ϩ 3 ϭ 4, and the mass of the unit cell is four times the mass of one atom. For a bcc unit cell (like 188 CHAPTER 5 LIQUIDS AND SOLIDS (a) (b) FIGURE 5.33 The entire crystal structure is constructed from a single type of unit cell by stacking the cells together without any gaps. FIGURE 5.34 The body-centered cubic (bcc) structure. This structure is not packed as closely as the face-centered cubic and hexagonal close-packed structures. It is less common among metals than closepacked structures. Some ionic structures are based on this model. FIGURE 5.35 A primitive cubic unit cell has an atom at each corner. It is rarely found in metals. FIGURE 5.36 The unit cells of the (a) ccp (fcc) and (b) bcc structures in which the locations of the centers of the spheres are marked by dots. FIGURE 5.37 The 14 Bravais lattices. P denotes primitive; I, body-centered; F, face-centered; C, with a lattice point on two opposite faces; and R, rhombohedral (a rhomb is an oblique equilateral parallelogram). Cubic P Cubic I Cubic F Tetragonal P Tetragonal I Orthorhombic P Orthorhombic C Orthorhombic I Orthorhombic F Monoclinic P Monoclinic C Triclinic Hexagonal Trigonal R a a a a a a c a b c a a α b b c c γ β β a a a a a c 120° FIGURE 5.38 A plane surface cannot be covered by regular pentagons without leaving gaps. The same is true of regular heptagons. that in Fig. 5.36b), we count 1 for the atom at the center and 1/8 for each of the eight atoms at the vertices, giving 1 ϩ (8 ϫ 1/8) ϭ 2 overall. Self-Test 5.4A How many atoms are there in a primitive cubic cell (see Fig. 5.35)? [Answer: 1] Self-Test 5.4B How many atoms are there in the structure made up of unit cells like the one shown in (13), which has an atom at each corner, two on opposite faces, and two inside the cell on a diagonal? 13 1/8 1/8 1/8 1 /8 1 /8 1 /8 1 /8 1/8 1 /8 1 /8 1 /8 1 /8 1 /8 1 /8 1 /2 1/2 1 /2 1 /2 1 /2 1 /2 1 /2 FIGURE 5.39 The calculation of the net number of atoms in a face-centered cubic cell. The best way to determine the type of unit cell adopted by a metal is x-ray diffraction, which gives a characteristic diffraction pattern for each type of unit cell (see Major Technique 3 following this chapter). However, a simpler procedure that can be used to distinguish between close-packed and other structures is to measure the density of the metal; we then calculate the densities of the candidate unit cells and decide which structure accounts for the observed density. Density is an intensive property, which means that it does not depend on the size of the sample (Section A). Therefore, it is the same for a unit cell and a bulk sample. Hexagonal and cubic close packing cannot be distinguished in this way, because they have the same coordination numbers and therefore the same densities (for a given element). 190 CHAPTER 5 LIQUIDS AND SOLIDS EXAMPLE 5.3 Deducing the structure of a metal from its density The density of copper is 8.93 gиcm–3 and its atomic radius is 128 pm. Is the metal (a) closepacked or (b) body-centered cubic? PLAN We calculate the density of the metal by assuming first that its structure is ccp (fcc) and then that it is bcc. The structure with the density closer to the experimental value is more likely to be the actual structure. The mass of a unit cell is the sum of the masses of the atoms that it contains. The mass of each atom is equal to the molar mass of the element divided by Avogadro’s constant. The volume of a cubic unit cell is the cube of the length of one of its sides. That length is obtained from the radius of the metal atom, the Pythagorean theorem, and the geometry of the cell. SOLVE (a) We established in Section 5.12 that the length, a, of the side of an fcc unit cell composed of spheres of radius r is a ϭ 81/2 r. The volume of the unit cell is a3 (Fig. 5.40c). Because there are four atoms in the cell, the mass, m, of one unit cell is four times the mass of one atom (M/NA). The density, d, is therefore a a r a a a a a a a a a a f ϭ 21/2 a r b f r r (a) Primitive cubic (b) Body-centered cubic (c) Face-centered cubic (ccp) FIGURE 5.40 The geometries of three cubic unit cells, showing the relation of the dimensions of each cell to the radius, r, of a sphere representing an atom or ion. The side of a cell is a, the diagonal of the body of a cell b, and the diagonal of a face f. 81/2 r r From d ϭ m/a3 , m ϭ 4M/NA, and a ϭ 81/2 r, d = 4M/NA (81/2 r)3 = 4M 83/2 NAr3 From d ϭ 4M/(83/2 NAr3 ), d = 4 * (63.55 gиmol-1 ) 83/2 * (6.022 * 1023 mol-1 ) * (1.28 * 10-8 cm)3 = 8.90 gиcm-3 A radius of 128 pm corresponds to 1.28 ϫ 10Ϫ8 cm, and the molar mass of copper (from the periodic table on the inside front cover) is 63.55 gиmolϪ1 . The predicted density is therefore The value for a body-centered structure is farther from 8.93 gиcmϪ3 , the experimental value, than that for a close-packed structure, 8.90 gиcmϪ3 , and so we conclude that copper has a close-packed structure. In fact, x-ray diffraction shows that copper is cubic close-packed at room temperature. Self-Test 5.5A The atomic radius of silver is 144 pm and its density is 10.5 g·cm–3 . Is the structure close-packed or body-centered cubic? [Answer: Close-packed cubic] Self-Test 5.5B The atomic radius of iron is 124 pm and its density is 7.87 g·cm–3 . Is this density consistent with a close-packed or a body-centered cubic structure? All crystal structures are derived from the 14 Bravais lattices. The atoms in a unit cell are counted by determining what fraction of each atom resides within the cell. The type of unit cell adopted by a metal can be determined by measuring its density. 5.14 Ionic Structures As we have seen, we can model elemental metals by spheres of the same radius. However, to model ionic solids, we need to pack together spheres of different radii and opposite charges. Sodium chloride, for instance, is modeled by stacking together positively charged spheres of radius 102 pm, representing the Naϩ ions, and negatively charged spheres of radius 181 pm, representing the ClϪ ions. Because the crystal is electrically neutral overall, each unit cell must reflect the stoichiometry of the compound and itself be electrically neutral. A helpful starting point is one of the close-packed structures we have already considered. Because anions are usually larger than the accompanying cations, we think of the anions as forming a slightly expanded version of a close-packed structure with the smaller cations occupying some of the enlarged holes in the expanded lattice. A slightly enlarged tetrahedral hole is still relatively small and can accommodate only small cations. Octahedral holes are larger and can accommodate somewhat bigger cations. The rock-salt structure is a common ionic structure that takes its name from the mineral form of sodium chloride. In it, the Naϩ ions lie at the corners and in the centers of the faces of a cube, forming a face-centered cube (Fig. 5.41). This arrangement 5.14 IONIC STRUCTURES 191 4r/31/2 r From d ϭ m/a3 , m ϭ 2M/NA, and a ϭ 4r/31/2 , d = 2M/NA (4r/31/2 )3 = 33/2 M 32NAr3 From d ϭ 33/2 M/(32NAr3 ), d = 33/2 * (63.55 gиmol-1 ) 32 * (6.022 * 1023 mol-1 ) * (1.28 * 10-8 cm)3 = 8.17 gиcm-3 (b) To calculate the density of a bcc unit cell, we let the length of the diagonal of a face of the cell be f and the length of the diagonal through the body of the cell be b. Then, from Fig. 5.40b and the Pythagorean theorem, a2 ϩ f 2 ϭ b2 ϭ (4r)2 . The Pythagorean theorem also tells us that f 2 ϭ 2a2 , and so a2 ϩ f2 ϭ a2 ϩ 2a2 ϭ 3a2 It follows that 3a2 ϭ (4r)2 and therefore that a ϭ 4r/31/2 . Each unit cell contains one sphere at each of the eight corners and one sphere at the center: 8 ϫ 1/8 ϩ 1 ϭ 2 spheres; so the total mass of a body-centered cubic unit cell is 2M/NA. Therefore, When we insert numerical values, we obtain Na+ Cl– FIGURE 5.41 The arrangement of ions in the rock-salt structure. Above is the unit cell, showing the packing of the individual ions, and below a representation of the same structure by spheres that identify the centers of the ions. Animation 5.41 is like an expanded ccp arrangement: the expansion keeps the cations out of contact with one another, thereby reducing their repulsion, and opens up holes that are big enough to accommodate the Cl– ions. These ions fit into the octahedral holes between the Naϩ ions. There is one octahedral hole for each cation in the close-packed array, and so all the octahedral holes are occupied. If we look carefully at the structure, we can see that each cation is surrounded by six anions and each anion is surrounded by six cations. The pattern repeats over and over, with each ion surrounded by six other ions of the opposite charge (Fig. 5.42). A crystal of sodium chloride is a three-dimensional array of a vast number of these little cubes. In an ionic solid, the “coordination number” means the number of ions of opposite charge immediately surrounding a specific ion. In the rock-salt structure, the coordination numbers of the cations and the anions are both 6, and the structure overall is described as having (6,6)-coordination. In this notation, the first number is the cation coordination number and the second is that of the anion. The rock-salt structure is found for a number of other minerals having ions of the same charge number, including KBr, RbI, CaO, and AgCl. It is common whenever the cations and anions have very different radii, in which case the smaller cations can fit into the octahedral holes in a face-centered cubic array of anions. The radius ratio, ␳ (rho), which is defined as (8)* is a guide to the type of structure to expect. Although there are many exceptions, a rock-salt structure can be expected when the radius ratio is in the range from 0.4 to 0.7. For example, the radius of the Mg2ϩ ion is 72 pm and that of the O2Ϫ ion is 140. pm. Therefore, for MgO, This ratio is consistent with the rock-salt structure, which is indeed the one observed in MgO crystals. When the radii of the cations and anions are similar and ␳ Ͼ 0.7, more anions can fit around each cation. Now the ions may adopt the cesium chloride structure typified by cesium chloride, CsCl (Fig. 5.43). The radius of a Csϩ ion is 167 pm and that of a ClϪ ion is 181 pm, giving a radius ratio of 0.923; so the two ions are almost the same size. In this structure, the anions form an expanded primitive cubic array, with a ClϪ ion at the eight corners of each cubic unit cell. There is a large “cubic” hole at the center of the cell, and the Csϩ ion fits into it. Equivalently, each ClϪ ion can be regarded as being at the center of a cubic unit cell with eight Csϩ ions at its corners, and so overall the crystal can be thought of as built from two interpenetrating primitive cubic lattices (Fig. 5.44). The coordination number of each type of ion is 8, and overall the structure has (8,8)-coordination. The cesium chloride structure is much less common than the rock-salt structure, but it is also found for CsBr, CsI, TlCl, and TlBr. When the radius ratio of an ionic compound is less than about 0.4, corresponding to cations that are significantly smaller than the anion, the small tetrahedral holes may be occupied. An example is the zinc-blende structure (which is also called the r = 72 pm 140. pm = 0.514 Radius ratio = radius of smaller ion radius of larger ion or r = rsmaller rlarger 192 CHAPTER 5 LIQUIDS AND SOLIDS Na+ Na+ Na+ Na+ Na+ Na+ NaCl– Cl– Cl– Cl– Cl– Cl FIGURE 5.42 Billions of unit cells stack together to recreate the smooth faces of the crystal of sodium chloride seen in this micrograph. The first inset shows some of the stacked unit cells. The second inset identifies the individual ions. The third inset (lower right) illustrates the coordination of an anion to its six cation neighbors. radius of Mg2ϩ radius of O2Ϫ ⎫⎪ ⎬ ⎪ ⎭ Cs+Cl– FIGURE 5.43 The cesium chloride structure: above is the unit cell and below a second unit cell showing the location of the centers of the ions. $+%'& FIGURE 5.44 The repetition of the cesium chloride unit cell recreates the entire crystal. This view is from one side of the crystal and shows several unit cells stacked together. Animation 5.44 sphalerite structure), named after a form of the mineral ZnS (Fig. 5.45). This structure is based on an expanded cubic close-packed lattice of the big S2Ϫ anions, with the small Zn2ϩ cations occupying half the tetrahedral holes. Each Zn2ϩ ion is surrounded by four S2Ϫ ions, and each S2Ϫ ion is surrounded by four Zn2ϩ ions; so the zinc-blende structure has (4,4)-coordination. Self-Test 5.6A Predict (a) the likely structure and (b) coordination type of solid ammonium chloride. Assume that the ammonium ion can be approximated as a sphere with a radius of 151 pm. [Answer: (a) cesium chloride structure; (b) (8,8)-coordination] Self-Test 5.6B Predict (a) the likely structure and (b) coordination type of solid calcium sulfide. When we discuss the structures of ionic solids, we usually treat ions as spheres of the appropriate radius and stack them together in the arrangement that has the lowest total energy. However, the simple sphere-packing arrangement may break down if the bonding is not purely ionic. In cases where the bonding has a significant degree of covalent character, the ions will lie in specific positions around one another. An example is nickel arsenide, NiAs. In this solid, the small Ni3ϩ cations polarize the big As3Ϫ anions, and the bonds have some covalent character. The ions pack together in an arrangement that is quite different from that of a purely ionic, sphere-packing model (Fig. 5.46). Once the structure of an ionic compound is known, its density can be estimated by using an approach similar to that used for metals. 5.14 IONIC STRUCTURES 193 Zn S FIGURE 5.45 The zinc-blende (sphalerite) structure. The four zinc ions (purple) form a tetrahedron within a face-centered cubic unit cell composed of sulfide ions (yellow). The zinc ions occupy half the tetrahedral holes between the sulfide ions. Each zinc ion is surrounded by four sulfide ions; each sulfide ion is similarly surrounded by four zinc ions. Ni As FIGURE 5.46 The structure of nickel arsenide, NiAs. Atypical structures such as this one are often found when the covalent character of the bonding is important and the ions have to take up specific positions relative to one another to maximize their bonding. EXAMPLE 5.4 Estimating the density of an ionic solid Estimate the density of cesium chloride from its crystal structure. Anticipate The densities of ionic compounds are typically a few grams per cubic centimeter. PLAN As for metals, the density of the bulk solid is the same as that of the unit cell. The volume of the cesium chloride unit cell is the cube of the length of one of its sides, and that length can be worked out from the Pythagorean theorem. The mass of the unit cell is obtained by counting the net number of ions of each kind and using the mass of each ion (its molar mass divided by Avogadro’s constant). The density is obtained by dividing the mass by the volume. Assume cations and anions touch either along diagonals (as in cesium chloride) or along edges, as in rock salt. SOLVE The radius of the Csϩ ion is 170 pm and that of the ClϪ is 181 pm. Therefore, the length of the diagonal of the unit cell is, from r(Csϩ ) ϩ 2r(ClϪ ) ϩ r(Csϩ ), b ϭ 170 ϩ 2(181) ϩ 170 pm ϭ 702 pm (Fig. 5.43), corresponding to 7.02 ϫ 10–8 cm. The length of the side, a, is related to b by a ϭ b/31/2 (recall Example 5.3). The volume of the unit cell is therefore a3 ϭ (b/31/2 )3 . Each body-centered unit cell contains one Csϩ ion (of molar mass 132.91 gиmolϪ1 ) and one ClϪ ion (of molar mass 35.45 gиmolϪ1 ). The total mass of the unit cell is the sum of these two masses divided by Avogadro’s constant, NA. From d ϭ M/NA(b/31/2 )3 , d = (132.91 + 35.45) gиmol-1 (6.022 * 1023 mol-1 ) * (7.02 * 10-8 cm/31/2 )3 = 4.20 gиcm-3 Evaluate The calculated value is in the expected range, but the experimental value is 3.99 gиcmϪ3 . The discrepancy is probably due to the assumption that the ions have the radii listed and behave like hard spheres. Self-Test 5.7A Estimate the density of sodium chloride from its crystal structure. [Answer: 2.14 gиcmϪ3 ] Self-Test 5.7B Estimate the density of cesium iodide from its crystal structure. Ions stack together in the regular crystalline structure corresponding to lowest energy. The structure adopted depends on the radius ratio of cation and anion. Covalent character in an ionic bond imposes a directional character on the bonding. THE IMPACT ON MATERIALS Some materials do not fall so easily into the categories of solid, liquid, and gas. Others appear to violate the chemical principles we have seen so far in this chapter. Such materials are not rare substances and play a part in our daily lives. In the following sections you will see how a liquid can have some of the properties of a crystal, how some ionic substances can be liquid at room temperature, and how these unusual properties allow such materials to play important roles in modern technology. 5.15 Liquid Crystals One type of material that has transformed electronic displays is neither a solid nor a liquid, but something intermediate between the two. Liquid crystals are substances that flow like viscous liquids, but their molecules lie in a moderately orderly array, like those in a crystal. They are examples of a mesophase, an intermediate state of matter with the fluidity of a liquid and some of the molecular order of a solid. Liquid crystalline materials are finding many applications in the electronics industry because they are responsive to changes in temperature and electric fields. A typical liquid-crystal molecule, such as p-azoxyanisole, is long and rodlike (14). Their rodlike shape enables the molecules to stack together like dry, uncooked spaghetti: they lie parallel to one another but are free to slide past one another along their long axes. Liquid crystals are anisotropic because of this ordering. Anisotropic materials have properties that depend on the direction of measurement. The viscosity of liquid crystals is least in the direction parallel to the long axis of the molecules: it is easier for the long rod-shaped molecules to slip past one another along their axes than to move sideways. Isotropic materials have properties that do not depend on the direction of measurement. Ordinary liquids, like water, are isotropic: their viscosities are the same in every direction. 194 CHAPTER 5 LIQUIDS AND SOLIDS 14 p-Azoxyanisole The three classes of liquid crystals differ in the arrangement of their molecules. In the nematic phase the molecules lie together, all in the same direction but staggered, like cars on a busy multilane highway (Fig. 5.47). In the smectic phase the molecules line up like soldiers on parade and form layers (Fig. 5.48). Cell membranes are composed mainly of smectic liquid crystals. In the cholesteric phase the molecules form FIGURE 5.47 A representation of the nematic phase of a liquid crystal. The long molecules lie parallel to one another but are staggered along their long axes. In this and the next two illustrations we have not attempted to show the thermal disorder that upsets the regularity of the arrays to some extent. FIGURE 5.48 The smectic phase of a liquid crystal. Not only do the molecules lie parallel to one another, they also line up next to one another to form sheets. Nematic comes from the Greek word for “thread”; smectic comes from the Greek word for “soapy”; cholesteric is related to the word cholesterol, which comes from the Greek words for “bile solid.” ordered layers, but neighboring layers have molecules at different angles and so the liquid crystal has a helical arrangement of molecules (Fig. 5.49). Liquid crystals are also classified by their manner of preparation. Thermotropic liquid crystals are made by melting the solid phase. The highly viscous liquid-crystal phase exists over a short temperature range between the solid and liquid states. Thermotropic liquid crystals become isotropic liquids when they are heated above a characteristic temperature, because then the molecules have enough energy to overcome the attractions that restrict their movement. p-Azoxyanisole is a thermotropic liquid crystal. Thermotropic liquid crystals are used in applications such as watches, computer screens, and thermometers. Lyotropic liquid crystals are layered structures that result from the action of a solvent on a solid or liquid. Examples are cell membranes and aqueous solutions of detergents and lipids (fats). These molecules, like the detergent sodium lauryl sulfate, have long, nonpolar hydrocarbon chains attached to polar heads (15). When the lipids that form cell membranes are mixed with water, they spontaneously form sheets in which the molecules are aligned in rows, forming a double layer, with their polar heads facing outward on each side of the sheet. These sheets form the protective membranes of the cells that make up living tissues (see Fig. 9.45). 5.16 IONIC LIQUIDS 195 FIGURE 5.49 The cholesteric phase of a liquid crystal. In this phase, sheets of parallel molecules are rotated relative to their neighbors and form a helical structure. 15 Sodium lauryl sulfate – Na+ Electronic displays make use of the anisotropy of the nematic phase and the changes in orientation of liquid-crystal molecules caused by an electric field. In an LCD (liquid-crystal display) television or computer monitor, layers of a liquid crystal in a nematic phase lie between the surfaces of two glass or plastic plates. The long axis of the molecules twists from the orientation governed by grooves in one plate to the perpendicular orientation governed by the grooves in the second plate (Fig. 5.50). The light from the lamp is polarized, and as it passes through the twisted liquid crystal its plane of polarization changes too, and it is able to pass through the second polarizer. However, where a potential difference is applied between the electrodes (the second being in the shape of the characters it is intended to display, in this case, a simple numerical display), the twist is lost, and so too is the change of polarization of the light. As a result, a dark spot forms on the screen. In a “super-twist” LCD screen, the twist of the resting liquid crystal has more than one turn. Cholesteric liquid crystals are also of interest because the helical structure unwinds slightly as the temperature is changed. Because the twist of the helical structure affects the optical properties of the liquid crystal, such as its color, these properties change with temperature. The effect is utilized in liquid-crystal thermometers. Liquid crystals have a degree of order characteristic of solid crystals, but they can flow like viscous liquids. They are mesophases, intermediate between solids and liquids; their properties can be modified by electric fields and changes in temperature. 5.16 Ionic Liquids We have seen that molecular substances tend to have low melting points, whereas network, ionic, and metallic substances tend to have high melting points. Therefore, with a few exceptions, such as mercury, a substance that is liquid at room temperature is likely to be a molecular substance. Liquid solvents are heavily used in industry to extract substances from natural products and to promote the synthesis of desired compounds. Because many of these solvents have high vapor pressures and so give off hazardous fumes, liquids that have low vapor pressures but dissolve organic compounds have been sought. Back light Polarizer Polarizer Glass Glass Glass screen Electrode Electrode Liquid crystal FIGURE 5.50 The structure of a back-lit LCD screen. The inset shows how the liquid crystal molecules twist from one orientation to another as determined by the grooves in the transparent plates. When a potential difference is applied between the electrodes, this twist is lost. A new class of solvents called ionic liquids has been developed to meet this need. A typical ionic liquid has a relatively small anion, such as BF4 Ϫ , and a relatively large, organic cation, such as 1-butyl-3-methylimidazolium (16). Because the cation has a large nonpolar region and is often asymmetrical, the compound does not crystallize easily and so is liquid at room temperature. It can also dissolve nonpolar organic compounds. However, the attractions between the ions reduce the vapor pressure to about the same as that of an ionic solid, thereby reducing air pollution. Because different cations and anions can be used, solvents can be designed for specific applications. For example, one formulation can dissolve the rubber in old tires so that it can be recycled. Other solvents can be used to extract radioactive waste from groundwater. Ionic liquids are compounds in which one of the ions is a large, organic ion that prevents the liquid from crystallizing at ordinary temperatures. The low vapor pressures of ionic liquids make them desirable solvents that reduce pollution. 196 CHAPTER 5 LIQUIDS AND SOLIDS ϩ 16 1-Butyl-3-methylimidazolium ion ❑ 1 Predict the relative strengths of ion–dipole interactions (Section 5.2). ❑ 2 Explain how London forces arise and how they vary with the polarizability of an atom and the size and shape of a molecule (Section 5.4). ❑ 3 Predict the relative order of the boiling points of two substances from the strengths of their intermolecular forces (Examples 5.1 and 5.2). ❑ 4 Identify molecules that can take part in hydrogen bonding (Self-Test 5.3). ❑ 5 Describe the structure of a liquid and explain how viscosity and surface tension vary with temperature and the strength of intermolecular forces (Sections 5.7 and 5.8). ❑ 6 Distinguish metallic solids, ionic solids, network solids, and molecular solids by their structures and by their properties (Sections 5.9–5.12). ❑ 7 Determine the fraction of occupied space in a given crystal lattice (Section 5.12). ❑ 8 Give the coordination number of an atom or ion in a given crystal lattice (Section 5.12). ❑ 9 Find the number of atoms or ions in a given unit cell (Self-Test 5.4). ❑ 10 Deduce the crystal structure of a metal from its density (Example 5.3). ❑ 11 Describe the structure of ionic solids and liquids (Sections 5.14 and 5.16). ❑ 12 Predict the structure of an ionic solid from the relative radii of the ions (Section 5.14). ❑ 13 Calculate the density of an ionic solid (Example 5.4). ❑ 14 Identify the different types of liquid crystals (Section 5.15). SKILLS YOU SHOULD HAVE MASTERED Exercises labeled require calculus Intermolecular Forces 5.1 Identify the kinds of intermolecular forces that might arise between molecules of each of the following substances: (a) NH2OH; (b) CBr4; (c) H2SeO4; (d) SO2. 5.2 Identify the kinds of intermolecular forces that might arise between molecules of each of the following substances: (a) NF3; (b) PH3; (c) HI; (d) HIO (O is the central atom). 5.3 For which of the following molecules will dipole–dipole interactions be important: (a) CH4; (b) CH3Cl; (c) CH2Cl2; (d) CHCl3; (e) CCl4? 5.4 For which of the following molecules will dipole–dipole interactions be important: (a) O2; (b) O3; (c) CO2; (d) SO2? 5.5 Suggest, giving reasons, which substance in each of the following pairs is likely to have the higher normal melting point (Lewis structures may help your arguments): (a) HCl or NaCl; (b) C2H5OC2H5 (diethyl ether) or C4H9OH (butanol); (c) CHI3 or CHF3; (d) C2H4 or CH3OH. 5.6 Suggest, giving reasons, which substance in each of the following pairs is likely to have the higher normal boiling point: (a) H2S or H2O; (b) NH3 or PH3; (c) KBr or CH3Br; (d) CH4 or SiH4. 5.7 Using the VSEPR model, predict the shapes of each of the following molecules and identify the member of each pair with the higher boiling point: (a) PBr3 or PF3; (b) SO2 or CO2; (c) BF3 or BCl3. 5.8 Using the VSEPR model, predict the shapes of each of the following molecules and identify the member of each pair with the higher boiling point: (a) BF3 or ClF3; (b) SF4 or CF4; (c) cis-CHCl≈CHCl or trans-CHCl≈CHCl. (See structures 5 and 6.) 5.9 Place the following types of molecular and ion interactions in order of increasing magnitude: (a) ion–dipole; (b) induceddipole–induced-dipole; (c) dipole–dipole in the gas phase; (d) ion–ion; (e) dipole–dipole in the solid phase. 5.10 In each pair, indicate which substance has the stronger intermolecular forces and explain your reasoning: (a) Ne, Ar; (b) NF3, BF3; (c) SiH4, GeH4; (d) NaF, HF. EXERCISES C EXERCISES 197 I II III 5.11 Which of the following molecules are likely to form hydrogen bonds: (a) PH3; (b) HBr; (c) C2H4; (d) HNO2? 5.12 Which of the following molecules are likely to form hydrogen bonds: (a) CH3OCH3; (b) CH3COOH; (c) CH3CH2OH; (d) CH3CHO? 5.13 Identify the arrangement (I, II, or III; all molecules are CH2Cl2) that should possess the strongest intermolecular attractions, and justify your selection. additional measurements, so make the following guesses about the two compounds. In each case indicate whether the guess can be justified by the data, is in error, or could be either true or false. Justify your answers. (a) Compound B has the higher molar mass. (b) Compound A is the more viscous. (c) Compound B has stronger intermolecular forces. (d) Compound B has the higher surface tension. 5.19 We have been using “intermolecular interaction” and “intermolecular force” almost interchangeably. However, it is important to distinguish the force from the potential energy of interaction. In classical mechanics, the magnitude of the force, F, is related to the distance dependence of the potential energy, EP, by F ϭ ϪdEP/dr. How does the intermolecular force depend on separation for a typical intermolecular interaction that varies as 1/r6 ? 5.20 Would you expect the energy of interaction of two rotating polar molecules, as given by Eq. 4, to depend on the temperature? If so, should the interaction increase or decrease as the temperature is raised? Liquid Structure 5.21 Predict how each of the following properties of a liquid varies as the strength of intermolecular forces increases and explain your reasoning: (a) boiling point; (b) viscosity; (c) surface tension. 5.22 Predict how each of the following properties of a liquid changes as the temperature increases and explain your reasoning: (a) boiling point; (b) viscosity; (c) surface tension. 5.23 Predict which liquid in each of the following pairs has the greater surface tension: (a) cis-dichloroethene or transdichloroethene (see structures 5 and 6); (b) benzene at 20°C or benzene at 60°C. 5.24 Predict which substance in each of the following pairs has the greater viscosity in its liquid form at 0°C: (a) ethanol, CH3CH2OH, or dimethyl ether, CH3OCH3; (b) butane, C4H10, or propanone, CH3COCH3. 5.25 Rank the following molecules in order of increasing viscosity at 50°C: C6H5SH, C6H5OH, C6H6. 5.26 Rank the following liquids in order of increasing viscosity at 25°C: C6H6, CH3CH2OH, CH2OHCHOHCH2OH, CH2OHCH2OH, and H2O. Explain your ordering. 5.27 The following boiling points correspond to the substances listed. Match the boiling points to the substances by considering the relative strengths of their intermolecular forces. b.p. (°C): Ϫ162, Ϫ88.5, 28, 36, 64.5, 78.3, 82.5, 140, 205, 290; substance: CH4, CH3CHOHCH3, C6H5CH2OH (has a benzene ring), CH3CH3, C5H9OH (cyclic), (CH3)2CHCH2CH3, CH3OH, HOCH2CHOHCH2OH, CH3(CH2)3CH3, CH3CH2OH. Hint: The boiling point of (CH3)2CHCH2CH3 is 28°C and that of CH3OH is 64.5°C. 5.28 The following surface tensions (in millinewtons per meter, mN·mϪ1 , at 20°C) correspond to the liquids listed. Match the surface tension to the substance. Surface tension: 18.43, 22.75, 27.80, 28.85, 72.75; compound: H2O, CH3(CH2)4CH3, C6H6, CH3CH2OH, CH3COOH. 5.29 Consider Fig. 5.9. (a) Explain the large differences in the boiling points of H2O and those of the remainder of the series (H2S to H2Te). (b) Explain the steady increase in the boiling points in the series CH4 to SnH4. 5.14 Identify the arrangement (I, II, or III; all molecules are NH3) that should possess the strongest intermolecular attractions, and justify your selection. I II III 5.15 Calculate the ratio of the potential energies for the interaction of a water molecule with an Al3ϩ ion and with a Be2ϩ ion. Take the center of the dipole to be located at rion ϩ 100. pm. Which ion will attract a water molecule more strongly? 5.16 Calculate the ratio of the potential energies for the interaction of a water molecule with a Ca2ϩ ion and with an In3ϩ ion. Take the center of the dipole to be located at rion ϩ 100. pm. Which ion will attract a water molecule more strongly? 5.17 Account for the following observations in terms of the type and strength of intermolecular forces. (a) The melting point of solid xenon is –112°C and that of solid argon is –189°C. (b) The vapor pressure of diethyl ether (C2H5OC2H5) is greater than that of water. (c) The boiling point of pentane, CH3(CH2)3CH3, is 36.1°C, whereas that of 2,2-dimethylpropane (also known as neopentane), C(CH3)4, is 9.5°C. 5.18 Two students are assigned two pure compounds to investigate. They observe that compound A boils at 37°C and compound B at 126°C. However, they run out of time to make any C 198 CHAPTER 5 LIQUIDS AND SOLIDS 5.30 The surface of glass contains many ∫OH groups that are bonded to the silicon atoms of SiO2, which is the major component of glass. If the glass is treated with Si(CH3)3Cl (chlorotrimethylsilane), a reaction takes place to eliminate HCl and attach the Si atom to the oxygen atom: (surface of glass)∫OH ϩ Si(CH3)3Cl (surface of glass)∫OSi(CH3)3 ϩ HCl How will this rearrangement affect the interaction of liquids with the glass surface? 5.31 The height, h, of a column of liquid in a capillary tube can be estimated by using h ϭ 2␥/gdr, where ␥ is the surface tension, d is the density of the liquid, g is the acceleration of free fall, and r is the radius of the tube. Which will rise higher in a tube that is 0.15 mm in diameter at 25°C, water or ethanol? The density of water is 0.997 gиcmϪ3 and that of ethanol is 0.79 gиcmϪ3 . See Table 5.3. 5.32 The expression for the capillary rise in Exercise 5.31 assumes that the tube is vertical. How will the expression be modified when the tube is held at an angle ␪ (theta) to the vertical? Classification of Solids 5.33 Glucose, benzophenone (C6H5COC6H5), and methane are examples of compounds that form molecular solids. The structures of glucose and benzophenone are given here. (a) What types of forces hold these molecules in a molecular solid? (b) Place the solids in order of increasing melting point. ¡ Melting Electrical Solubility Substance Appearance point, ºC conductivity in water A hard, white 800 only when soluble dissolved in water B lustrous, 1500 high insoluble malleable C soft, yellow 113 none insoluble 5.38 Three unknown substances were tested in order to classify them. The following table shows the results of the tests. Use Table 5.4 to classify substances X, Y, and Z as metallic, ionic, network, or molecular solids. Melting Electrical Solubility Substance Appearance point, ºC conductivity in water X brittle, white 146 none soluble Y very hard, 1600 none insoluble colorless Z hard, orange 398 only when soluble dissolved in water Solid Metallic Structures 5.39 Iron crystallizes in a bcc structure. The atomic radius of iron is 124 pm. Determine (a) the number of atoms per unit cell; (b) the coordination number of the lattice; (c) the length of the side of the unit cell. 5.40 The metal polonium (which was named by Marie Curie after her homeland, Poland) crystallizes in a primitive cubic structure, with an atom at each corner of a cubic unit cell. The atomic radius of polonium is 167 pm. Sketch the unit cell and determine (a) the number of atoms per unit cell; (b) the coordination number of an atom of polonium; (c) the length of the side of the unit cell. 5.41 Calculate the density of each of the following metals from the data given: (a) aluminum, fcc structure, atomic radius 143 pm; (b) potassium, bcc structure, atomic radius 227 pm. 5.42 Calculate the density of each of the following metals from the data given: (a) strontium, fcc structure, atomic radius 215 pm; (b) europium, bcc structure, atomic radius 204 pm. 5.43 Calculate the atomic radius of each of the following elements from the data given: (a) platinum, fcc structure, density 21.450 g·cmϪ3 ; (b) tantalum, bcc structure, density 16.654 g·cmϪ3 . 5.44 Calculate the atomic radius of each of the following elements from the data given: (a) silver, fcc structure, density 10.500 g·cmϪ3 ; (b) chromium, bcc structure, density 7.190 g·cmϪ3 . 5.45 The density of rhodium is 12.42 g·cmϪ3 and its atomic radius is 134 pm. Is the metal close-packed or body-centered cubic? 5.46 The density of vanadium is 6.11 g·cmϪ3 and its atomic radius is 132 pm. Is the metal close-packed or body-centered cubic? 5.47 One form of silicon has density of 2.33 g·cmϪ3 and crystallizes in a cubic lattice with a unit cell edge of 543 pm. (a) What is the mass of each unit cell? (b) How many silicon atoms does one unit cell contain? 5.48 Krypton crystallizes with a face-centered cubic unit cell of edge 559 pm. (a) What is the density of solid krypton? (b) What is H HO HO H H H OH O CH2 HO OH H Glucose C O Benzophenone 5.34 Chloromethane (CH3Cl), methane, and acetic acid (CH3COOH) form molecular solids. (a) What types of forces hold these molecules in a molecular solid? (b) Place the solids in order of increasing melting point. 5.35 Classify each of the following solids as ionic, network, metallic, or molecular: (a) quartz, SiO2; (b) limestone, CaCO3; (c) dry ice, CO2; (d) sucrose, C12H22O11; (e) polyethylene, a polymer with molecules consisting of chains of thousands of repeating ∫CH2CH2∫ units. 5.36 Classify each of the following solids as ionic, network, metallic, or molecular: (a) iron pyrite (fool’s gold), FeS2; (b) octane (a component of gasoline), C8H18; (c) cubic boron nitride (a compound with a structure similar to that of diamond, but with alternating boron and nitrogen atoms), BN; (d) calcium sulfate (gypsum), CaSO4; (e) the chromium plating on a motorcycle. 5.37 Three unknown substances were tested in order to classify them. The following table shows the results of the tests. Use Table 5.4 to classify substances A, B, and C as metallic, ionic, network, or molecular solids. EXERCISES 199 the atomic radius of krypton? (c) What is the volume of one krypton atom? (d) What percentage of the unit cell is empty space if each atom is treated as a hard sphere? 5.49 What percentage of space is occupied by close-packed cylinders of length l and radius r? 5.50 Calculate the radius of the cavity formed by three circular disks of radius r that lie in a close-packed planar arrangement. Check your answer experimentally by using three compact disks and measuring the radius of the cavity that they form. Nonmetallic Solids 5.51 Indium arsenide crystallizes in the sphalerite structure (Fig. 5.45). (a) What are the coordination numbers of the indium and arsenide ions? (b) What is the formula of indium arsenide? 5.52 Uranium carbide crystallizes in the rock-salt structure (Fig. 5.41). (a) What are the coordination numbers of the uranium and carbide ions? (b) What is the formula of uranium carbide? 5.53 Calculate the number of cations, anions, and formula units per unit cell in each of the following solids: (a) the cesium chloride unit cell shown in Fig. 5.43; (b) the rutile (TiO2) unit cell shown here. (c) What are the coordination numbers of the ions in rutile? 5.57 Use radius ratios to predict the coordination number of the cation in (a) RbF; (b) MgO; (c) NaBr. (See Fig. 1.48.) 5.58 Use radius ratios to predict the coordination number of the cation in (a) KBr; (b) LiBr; (c) BaO. (See Fig. 1.48.) 5.59 Estimate the density of each of the following solids from the ionic radii given in Fig. 1.48: (a) calcium oxide (rock-salt structure, Fig. 5.41); (b) cesium bromide (cesium chloride structure, Fig. 5.43). 5.60 Calculate the density of each of the following solids: (a) magnesium oxide (rock-salt structure, Fig. 5.41), distance between centers of Mg2ϩ and O2Ϫ ions is 212 pm; (b) calcium sulfide (cesium chloride structure, Fig. 5.43), distance between the centers of the Ca2ϩ and S2Ϫ ions is 284 pm. 5.61 Graphite forms extended two-dimensional layers (see Fig. 5.23). (a) Draw the smallest possible rectangular unit cell for a layer of graphite. (b) How many carbon atoms are in your unit cell? (c) What is the coordination number of carbon in a single layer of graphite? 5.62 The ammonium ion can be represented by a sphere of radius 151 pm. Use radius ratios to predict the type of lattice structure found in (a) NH4F; (b) NH4I. 5.63 If the edge length of a fcc unit cell of RbI is 732.6 pm, how long would the edge of a cubic single crystal of RbI be that contains 1.00 mol RbI? 5.64 The edge length of the fcc unit cell of NaCl is 562.8 pm. (a) How many unit cells are present in a single crystal of NaCl (table salt) that is a cube with edges 1.00 mm in length? (b) What amount (in moles) of NaCl is present in this crystal? 5.65 Why do long hydrocarbon molecules that do not have multiple bonds, such as decane, CH3(CH2)8CH3, not form liquid crystals? 5.66 Consider the structure of p-azoxyanisole (14). (a) Using the VSEPR model, draw a picture that represents the shape of the molecule and predict the CNN bond angles. (b) What features of the bonding of this molecule give rise to its rodlike nature? (c) Use your conclusions in part (b) to design another simple organic molecule that is composed only of C, H, N, and O and might be likely to form rodlike, liquid crystalline materials. 5.67 When long surfactant molecules having a polar headgroup and a nonpolar “tail” are placed into water, micelles are formed in which the nonpolar tails aggregate, with the polar headgroups pointing out toward the solvent. Inverse micelles are similar but have the nonpolar regions pointing outward. How can inverse micelles be produced? 5.68 p-Azoxyanisole (14) has a liquid crystalline range of approximately 117° to 137°C. How might this molecule be modified to lower the melting point of the solid and make it more suitable for lower-temperature applications (near room temperature, for example)? 5.69 Two solutes were used to study diffusion in liquids, methylbenzene, which is a small molecule that can be approximated as a sphere, and a liquid crystal that is long and rodlike. The two solutes were found to move and rotate in all directions to the same extent in benzene. In a liquid crystal solvent the methylbenzene again moved and rotated to the same extent in all directions, but the liquid crystal solute moved much more O Ti 5.54 Calculate the number of cations, anions, and formula units per unit cell in each of the following solids: (a) the rock-salt unit cell shown in Fig. 5.41; (b) the fluorite (CaF2) unit cell shown here. (c) What are the coordination numbers of the ions in fluorite? Ca F (at centers of small cubes) 5.55 An oxide of rhenium crystallizes with a cubic unit cell that has a rhenium cation at each corner and an oxide ion at the center of each edge of the crystal. (a) Determine the coordination numbers of the two ions. (b) Write the formula of the oxide. 5.56 When an oxide of uranium crystallizes the uranium cations form an expanded cubic close-packed array with an oxide ion in each tetrahedral hole. (a) Determine the coordination numbers of the two ions. (b) Write the formula of the oxide. 200 CHAPTER 5 LIQUIDS AND SOLIDS rapidly along the long axis of the molecule than it did in a “sideways” mode, perpendicular to the long axis. It also was found to rotate more rapidly around the long axis than perpendicular to it. Explain this behavior. 5.70 The molecular structures of many common liquid crystals are long and rodlike. In addition, they contain polar groups. Explain how both characteristics of liquid crystals contribute to their anisotropic nature. Integrated Exercises 5.71 Draw the Lewis structure of (a) NI3 and (b) BI3, name the molecular shape, and indicate whether each can participate in dipole–dipole interactions. 5.72 Draw the Lewis structure of (a) CF4, (b) SF4, name the molecular shape, and indicate whether each can participate in dipole–dipole interactions. 5.73 (a) Calculate the surface areas of the isomers 2,2dimethylpropane and pentane. Assume that 2,2-dimethylpropane is spherical with a radius of 254 pm and that pentane can be approximated by a rectangular prism with dimensions 295 pm ϫ 692 pm ϫ 766 pm. (b) Which has the larger surface area? (c) Which do you expect to have the higher boiling point? 5.74 (a) Calculate the ratio of potential energies for an ion–ion interaction for Liϩ and for Kϩ with the same anion. (b) Repeat the ratio calculation, but for an ion–dipole interaction between Liϩ and Kϩ and a water molecule. (c) What do these numbers indicate about the relative importance of the hydration of salts of lithium compared with those of potassium? 5.75 All noble gases except helium crystallize with ccp structures at very low temperatures. Find an equation relating the atomic radius to the density of a ccp solid of given molar mass and apply it to deduce the atomic radius of each of the following noble gases, given the density of each (in g·cmϪ3 ): Ne, 1.20; Ar, 1.40; Kr, 2.16; Xe, 2.83; Rn, 4.4 (estimated). 5.76 All the alkali metals crystallize with bcc structures. (a) Find a general equation relating the metallic radius to the density of a bcc solid of an element in terms of its molar mass and use it to deduce the atomic radius of each of the following elements, given the density of each (in g·cm–3 ): Li, 0.53; Na, 0.97; K, 0.86; Rb, 1.53; Cs, 1.87. (b) Find a factor for converting the density of a bcc element into the density that it would have if it crystallized in a ccp structure. (c) Calculate what the densities of the alkali metals would be if they were ccp. (d) Which, if any, would float on water? 5.77 Metals with bcc structures, such as tungsten, are not close packed. Therefore, their densities would be greater if they were to change to a ccp structure (under pressure, for instance). What would the density of tungsten be if its structure were ccp rather than bcc? Its actual density is 19.3 g·cmϪ3 . 5.78 An oxide of niobium has a unit cell in which there are oxide ions at the middle of each edge and niobium ions at the center of each face. What is the empirical formula of this oxide? 5.79 A number of metal oxides are known to form nonstoichiometric compounds, in which the ratios of atoms that make up the compound cannot be expressed in small whole numbers. In the crystal structure of a nonstoichiometric compound, some of the lattice points where one would have expected to find atoms are vacant. Transition metals most easily form nonstoichiometric compounds because of the number of oxidation states that they can have. For example, a titanium oxide with formula TiO1.18 is known. (a) Calculate the average oxidation state of titanium in this compound. (b) If the compound has both Ti2ϩ and Ti3ϩ ions present, what fraction of the titanium ions will be in each oxidation state? 5.80 Uranium dioxide, UO2, can be further oxidized to give a nonstoichiometric compound UO2ϩx, where 0 Ͻ x Ͻ 0.25. See Exercise 5.79 for a description of nonstoichiometric compounds. (a) What is the average oxidation state of uranium in a compound with composition UO2.17? (b) If we assume that the uranium exists in either the ϩ4 or the ϩ5 oxidation state, what is the fraction of uranium ions in each? 5.81 Are the following statements true or false? (a) If there is an atom present at the corner of a unit cell, there must be the same type of atom at all the corners of the unit cell. (b) A unit cell must be defined so that there are atoms at the corners. (c) If one face of a unit cell has an atom in its center, then the face opposite that face must also have an atom at its center. (d) If one face of a unit cell has an atom in its center, all the faces of the unit cell must also have atoms at their centers. 5.82 Are the following statements true or false? (a) Because cesium chloride has chloride ions at the corners of the unit cell and a cesium ion at the center of the unit cell, it is classified as having a body-centered unit cell. (b) The density of the unit cell must be the same as the density of the bulk material. (c) When xrays are passed through a single crystal of a compound, the x-ray beam will be diffracted because it interacts with the electrons in the atoms of the crystal. (d) All the angles of a unit cell must be equal to 90°. 5.83 For each of the two-dimensional arrays shown here, draw a unit cell that, when repeated, generates the entire two-dimensional lattice. (a) (b) 5.84 For each of the two-dimensional arrays shown here, draw a unit cell that, when repeated, generates the entire two-dimensional lattice. (a) (b) EXERCISES 201 5.85 Buckminsterfullerene is an allotrope of carbon in which the carbon atoms form nearly spherical molecules of 60 atoms each (see Section 15.12). In the pure compound the spheres pack in a cubic close-packed array. (a) The length of a side of the facecentered cubic cell formed by buckminsterfullerene is 142 pm. Use this information to calculate the radius of the buckminsterfullerene molecule treated as a hard sphere. (b) The compound K3C60 is a superconductor at low temperatures. In this compound the Kϩ ions lie in holes in the C60 Ϫ face-centered cubic lattice. Considering the radius of the Kϩ ion and assuming that the radius of C60 – is the same as for the C60 molecule, predict in what type of holes the Kϩ ions lie (tetrahedral, octahedral, or both) and indicate what percentage of those holes are filled. 5.86 A reflection from a cubic crystal was observed at a glancing angle of 12.1° when x-rays of wavelength 152 pm were used. (a) What is the separation of layers causing this reflection? (b) At what glancing angle would you detect the reflection arising from planes at twice the layer separation? Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.87 Glass is composed mainly of silica, SiO2, with various oxides added to change the properties. The property differences are substantial, and different amounts of added oxide compounds produce glasses with very different applications derived from these properties. Often the added material is B2O3 and the products are called borosilicate glasses. From standard reference sources, determine how the properties of glass change as the amount of B2O3 is increased. 5.88 In an aqueous solution, solute molecules or ions require a certain amount of time to migrate through the solution. The rate of this migration sets an upper limit on how fast reactions can take place, because no reaction can take place faster than the ions can be supplied. This limit is known as the diffusion-controlled rate. It has been found that the diffusion rate for hydrogen ions is about three times as fast as that for other ions in aqueous solution. Explain why this is so. 5.89 Iron corrodes in the presence of oxygen to form rust, which for simplicity can be taken to be iron(III) oxide. If a cubic block of iron of side 1.5 cm reacts with 15.5 L of oxygen at 1.00 atm and 25°C, what is the maximum mass of iron(III) oxide that can be produced? Iron metal has a bcc structure, and the atomic radius of iron is 124 pm. The reaction takes place at 298 K and 1.00 atm. 5.90 Real gases and vapors have intermolecular interactions. Recall that one equation of state for a real gas is the van der Waals equation, which is expressed in terms of two parameters, a and b. (a) For each of the following pairs of gases, decide which substance has the larger van der Waals a parameter: (i) He and Ne; (ii) Ne and O2; (iii) CO2 and H2; (iv) H2CO and CH4; (v) C6H6 and CH3(CH2)10CH3. (b) For each of the following pairs of gases, decide which substance has the larger van der Waals b parameter: (i) F2 and Br2; (ii) Ne and F2; (iii) CH4 and CH3CH2CH3; (iv) N2 and Kr; (v) CO2 and SO2. 5.91 A commonly occurring mineral has a cubic unit cell in which the metal cations, M, occupy the corners and face centers. Inside the unit cell, anions, A, occupy all the tetrahedral holes created by the cations. What is the empirical formula of the MmAa compound? 5.92 Tetrahedral and octahedral interstitial holes are formed by the vacancies left when anions pack in a ccp array. (a) Which hole can accommodate the larger ions? (b) What is the size ratio of the largest metal cation that can occupy an octahedral hole to the largest that can occupy a tetrahedral hole while maintaining the close-packed nature of the anion lattice? (c) If half the tetrahedral holes are occupied, what will be the empirical formula of the compound MxAy, where M represents the cations and A the anions? 5.93 The density of cesium chloride is 3.988 g·cmϪ3 . Calculate the percentage of empty space in a cesium chloride lattice with the ions treated as hard spheres. 5.94 Use information from Exercise 5.54 to calculate the percentage of empty space in a calcium fluoride lattice with the ions treated as hard spheres. The density of CaF2 is 3.180 g·cmϪ3 . 5.95 (a) If a pure element crystallizes with a primitive cubic lattice, what percentage of the unit cell is empty space? (b) How does this percentage compare with that of empty space in an fcc unit cell? 5.96 Many ionic compounds are considered to pack in such as way that the anions form a close-packed lattice in which the metal cations fill holes or interstitial sites left between the anions. These lattices, however, may not necessarily be as tightly packed as the label “close-packed” implies. The radius of an FϪ ion is approximately 133 pm. The edge distances of the cubic unit cells of LiF, NaF, KF, RbF, and CsF, all of which pack in the rock-salt structure, are 568 pm, 652 pm, 754 pm, 796 pm, and 850 pm, respectively. Which of these lattices, if any, can be thought to be based on close-packed arrays of FϪ ions? Justify your conclusions. 5.97 Due to its strong hydrogen bonds, in the vapor state hydrogen fluoride is found as short chains and rings. Draw the Lewis structure of an (HF)3 chain and indicate the approximate bond angles. 5.98 Consider a metallic element that crystallizes in a cubic close-packed lattice. The edge length of the unit cell is 408 pm. If close-packed layers are deposited on a flat surface to a depth (of metal) of 0.125 mm, how many close-packed layers are present? 5.99 “Graphite bisulfates” are formed by heating graphite with a mixture of sulfuric and nitric acids. In the reaction, the graphite planes are partially oxidized. There is approximately one positive charge for every 24 carbon atoms, and the HSO4 Ϫ anions are distributed between the planes. (a) What effect is this oxidation likely to have on the electrical conductivity? (b) What effect would you expect it to have on the x-ray diffraction pattern observed for this material? Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.100 Using the density of calcium fluoride (CaF2, found in nature as the mineral fluorite), which is known to be 3.180 g·cmϪ3 , and the information given in Exercise 5.54, calculate (a) the edge length of the unit cell and (b) the Ca–F separation in fluorite. (c) Compare this value to that expected from the ionic radii tabulated in Fig. 1.48. 5.101 The following diagram shows two lattice planes from which two parallel x-rays are diffracted. If the two incoming x-rays are in phase, show that the Bragg equation 2d sin ␪ ϭ n␭ is true when n is an integer. Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. X-rays d 2 ␪ 1 Lattice layer 1 Lattice layer 2 5.102 X-rays generated from a copper target have a wavelength of 154 pm. If an x-ray beam of this type is passed through a single crystal of NaBr, a diffracted beam is observed when the incident x-ray beam is at an angle of 7.42° to the surface of the crystal. What is the minimum spacing between the planes in the crystal that give rise to this diffracted beam? Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.103 The unit-cell edge length of lithium fluoride is 401.8 pm. What is the smallest angle at which the x-ray beam generated from a molybdenum source (␭ ϭ 71.07 pm) must strike the planes making up the faces of the unit cell for the beam to be diffracted from those planes? Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.104 Could electrons be used for diffraction studies of molecules? The energy of an electron accelerated through a potential difference V (in volts) is eV. What potential difference is needed to accelerate electrons from rest so that they have a wavelength of 100 pm? Hint: Use the de Broglie relation and the fact that acceleration of an electron to an energy eV gives it a kinetic energy of mev2 . Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.105 Could neutrons be used for diffraction studies of molecules? The average kinetic energy of neutrons in a beam at a temperature T is kT, where k is Boltzmann’s constant. What temperature is needed to achieve a wavelength of 100. pm for a neutron? Refer to Major Technique 3 on x-ray diffraction, which follows this set of exercises. 5.106 Calculate the Coulomb potential energy at a point a distance r from a dipole composed of charges Q and ∫Q separated by a distance l in the arrangement shown in the diagram. Use the fact that l Ͻ r to expand the expression 1/(1 ϩ x) into 1 Ϫ x ϩ · · · and identify the magnitude of the dipole moment as ␮ ϭ Ql. Show that the potential energy is proportional to 1/r2 (as in Eq. 2). 1 2 1 2 202 CHAPTER 5 LIQUIDS AND SOLIDS Chemistry Connections 5.107 Ethylammonium nitrate, CH3CH2NH3NO3, was the first ionic liquid to be discovered. Its melting point of 12°C was reported in 1914 and it has since been used as a nonpolluting solvent for organic reactions and for facilitating the folding of proteins. (a) Draw the Lewis structure of each ion in ethylammonium nitrate and indicate the formal charge on each atom (in the cation, the carbon atoms are attached to the N atom in a chain: C∫C∫N). (b) Assign a hybridization scheme to each C and N atom. (c) Ethylammonium nitrate cannot be used as a solvent for some reactions because it can oxidize some compounds. Which ion is more likely to be the oxidizing agent, the cation or anion? Explain your answer. (d) Ethylammonium nitrate can be prepared by the reaction of gaseous ethylamine, CH3CH2NH2, and aqueous nitric acid. Write the chemical equation for the reaction. What type of reaction is this? (e) 2.00 L of ethylamine at 0.960 atm and 23.2°C was bubbled into 250.0 mL of 0.240 M HNO3(aq) and 4.10 g of ethylammonium nitrate was produced. What were the theoretical and percentage yields of the salt? (f) Suggest ways in which the forces that hold ethylammonium nitrate ions together in the solid state differ from those that hold together salts such as sodium chloride or sodium bromide. (g) Low-melting salts in which the cation is inorganic and the anion organic have been prepared. Explain the trend in melting point seen in the following series: sodium acetate (NaCH3CO2), 324°C; sodium propanoate (NaCH3CH2CO2), 285°C; sodium butanoate (NaCH3CH2CH2CO2), 76°C; and sodium pentanoate (NaCH3CH2CH2CH2CO2), 64°C. ϩQ ϪQ l r X-RAY DIFFRACTIONMAJOR TECHNIQUE 3 Detector Diffracted rayIncident x-rays ␪ ␪Angle EXAMPLE MT 3.1 Determining the spacing between layers of atoms in a crystal In an x-ray diffraction experiment on a single crystal of sodium chloride, with the use of radiation from a copper source (␭ ϭ 154 pm), constructive interference was observed at ␪ ϭ 11.2°. What is the spacing of the layers responsible for the diffraction? PLAN Spacing between layers in a crystal can be obtained from the Bragg equation. Agreat deal of our knowledge about the interior of solids has come from x-ray diffraction. This important technique is used to determine the arrangement of atoms in solid compounds and to measure bond lengths and angles. Almost all recent advances in molecular biology have stemmed from the application of this technique to determine the structures of molecules such as proteins and nucleic acids. The Technique When two or more waves pass through the same region of space, the phenomenon of interference is observed as an increase or a decrease in the total amplitude of the wave (recall Fig. 1.20). Constructive interference, an increase in the total amplitude of the wave, occurs when the peaks of one wave coincide with the peaks of another wave. If the waves are electromagnetic radiation, the increased amplitude corresponds to an increased intensity of the radiation. Destructive interference, a decrease in the total amplitude of the waves, occurs when the peaks of one wave coincide with the troughs of the other wave: it results in a reduction in intensity. The phenomenon of diffraction is interference between waves that arises when there is an object in their path. One of the earliest demonstrations of interference was the Young’s slit experiment, in which light passes through two slits and gives rise to a pattern on a screen (see Fig. 1.19). If we were presented with the pattern and were told the wavelength of the light and the distance of the detection screen from the screen containing the slits, it would be possible to work out the spacing of the two slits. An x-ray diffraction experiment is a more elaborate version of the Young’s slit experiment. The regular layers of atoms in a crystal act as a three-dimensional collection of slits and give rise to a diffraction pattern that varies as the crystal is rotated and the “slits” are brought into a new arrangement. The task for the x-ray crystallographer is to use the diffraction pattern to determine the spacing and arrangement of the “slits” that gave rise to it. This enormously complex task is universally carried out on computers. Why x-rays? Diffraction occurs when the wavelength of the radiation is comparable to characteristic spacings within the object causing the diffraction. Therefore, to obtain diffraction patterns from layers of atoms, we need to use radiation with a wavelength comparable to the spacing of the layers. The separation between layers of atoms in a crystal is about 100 pm, and so electromagnetic radiation of that wavelength, which corresponds to the x-ray region, must be used. Experimental Techniques X-rays are generated by accelerating electrons to very high speeds and then letting them plunge into a metal target. This technique generates two types of x-radiation. One type comes from the bombarding electrons themselves. Because accelerating and decelerating charges emit electromagnetic radiation, the electrons generate radiation as they are brought to a standstill in the metal. The radiation covers a wide range of frequencies, including that of x-rays. However, for current versions of x-ray diffraction, we need a well-defined wavelength. Such radiation is generated by a second mechanism. The fast electrons hit electrons occupying orbitals in the inner shells of atoms and drive them out of the atom. That collision leaves a gap in the atom, which is filled when an electron in another shell falls into the vacancy. The difference in energy is given out as a photon. Because the energy difference between shells is so great, the photon has a very high energy, corresponding to the x-ray region. When copper is used as the target, for example, the x-radiation has a wavelength of 154 pm. In the powder diffraction technique, a monochromatic (single-frequency) beam of x-rays is directed at a powdered sample spread on a support, and the diffraction intensity is measured as the detector is moved to different angles (Fig. 1). The pattern obtained is characteristic of the material in the sample, and it can be identified by comparison with a database of patterns. In effect, powder x-ray diffraction takes a fingerprint of the sample. It can also be used to identify the size and shape of the unit cell by measuring the spacing of the lines in the diffraction pattern. The central equation for analyzing the results of a powder diffraction experiment is the Bragg equation 2d sin ␪ ϭ ␭ which relates the angles ␪ (theta), at which constructive interference occurs, to the spacing, d, of layers of atoms in the sample, for x-rays of wavelength ␭ (lambda). The illustration in Exercise 5.101 shows how the parameters ␭ and d relate to the crystal dimensions. FIGURE 1 In the powder diffraction technique, a sample is spread on a flat plate and exposed to a beam of monochromatic (singlefrequency) x-rays. The diffraction pattern (inset) is recorded by moving the detector to different angles. 203 (continued) Self-Test MT3.1A Constructive interference at 7.23° was observed from a crystal when x-radiation from a molybdenum source (␭ ϭ 71.0 pm) was used. What is the spacing of the layers of atoms responsible for the diffraction? [Answer: 282 pm] Self-Test MT3.1B Constructive interference at 12.1° was observed from a cubic crystal when x-radiation of wavelength 152 pm was used. What is the spacing of the layers of atoms responsible for the diffraction? The x-ray diffraction pattern from a liquid resembles that from a powdered sample, but the lines are diffuse rather than sharp. This pattern indicates that the molecules of a liquid have a degree of short-range order but that the distances between molecules vary; this variation produces the diffuse lines. The single-crystal diffraction technique is much more elaborate and gives much richer information. The first task is to grow a perfect single crystal of the sample. Whereas that task is usually straightforward for simple inorganic solids, it is often one of the most difficult parts of the investigation for the huge molecules characteristic of biologically important compounds such as proteins. Only a tiny crystal is needed, about 0.1 mm on a side, but the task of growing one can be very challenging. Once the crystal has been grown, it is placed at the center of a fourcircle diffractometer (Fig. 2), a device for rotating the crystal and the detector so that the entire diffraction pattern can be recorded under the control of a computer. The raw data consist of the intensities of the x-rays at all the settings of the angles in the diffractometer. The computational task is to analyze these measurements and convert them into the locations of the atoms. The process of conversion is called Fourier synthesis and requires lengthy calculations carried out on a computer that is an integral part of the diffractometer. The end product is a detailed description of the location of all the atoms in the molecule, the bond lengths, and the bond angles. The most spectacular achievement of this kind was the elucidation of the functioning of the genetic messenger, DNA, where x-rays were a source of insight into the workings of life itself. Even at this stage in your studies, you can begin to see the spark that ignited Watson and Crick’s vision of the structure of DNA. Figure 3 shows the characteristic X pattern obtained by Rosalind Franklin. The two crossed arms of the X told Watson and Crick that the molecule must be a helix, and from the slopes of the arms and the diffraction spots along them they were able to deduce its pitch (the distance between turns) and radius. The two arcs at the top and bottom of the photograph represent diffraction through a big angle and therefore a narrow spacing: this they could interpret in terms of the spacing of the nucleotide bases along the helix, with 10 bases per turn of helix. Related Exercises: 5.86, 5.99, and 5.101–5.105. Circle 1 Circle 2 Circle 3 Circle 4 Sample Detector X-ray beam FIGURE 3 The x-ray diffraction pattern that led to the elucidation of the structure of DNA. Substitute the data. d = 154 pm 2 sin 11.2° = 396 pm FIGURE 2 A four-circle diffractometer is used to obtain highly detailed information about x-ray diffraction patterns from single crystals. The diffraction pattern is monitored as the orientations around each of the four axes are changed. 204 Rearrange the Bragg equation to give d in terms of ␪. d = l 2 sin u SOLVE X-RAY DIFFRACTION (continued)MAJOR TECHNIQUE 3 205 What Are the Key Ideas? The mechanical, electrical, magnetic, and optical properties of materials depend on their chemical composition, may be tailored to match the requirements of technology, and may open up paths to new technologies. Why Do We Need to Know This Material? To select the best material for a purpose or to design a new one, we need to know what properties to expect from particular combinations of atoms. The chemical principles in the first five chapters of this book can help us to understand the properties of materials, to predict their properties, and to design materials for new tasks and new technologies. What Do We Need to Know Already? This chapter assumes an understanding of periodic properties and electron configurations (Chapter 1), molecular structure (Chapters 2 and 3), and the solid state and intermolecular forces (Chapter 5). The discussion of bonding in solids builds on molecular orbital theory (Sections 3.9–3.12). T he growth of civilization to a large extent depends on the development of new materials that give rise to new technologies and thereby open up new opportunities. Concrete led to remarkable advances in architecture and construction, steel led to the industrial revolution, plastics transformed daily life, and silicon-based semiconductors transformed communication and calculation. The twenty-first century continues to thrive on the discovery and manufacture of new materials. Whether designing a building, crafting artificial limbs, or developing new means of communication, engineers, medical researchers, architects, and scientists must all understand the chemical basis of materials. Materials not yet imagined will be developed—perhaps by you—as our ability to fabricate new forms of matter increases. Material used in technology, medicine, and construction is classified as either “hard” or “soft.” Hard matter can withstand strong forces without deforming; soft matter responds more readily to applied force. Most hard matter is inorganic and most soft matter is organic and plays important roles in biology. Organic soft matter is described in more detail in Chapters 9 and 19; the focus of this chapter is largely on inorganic materials. In fact, the distinction between inorganic hard matter and soft organic matter is blurring as chemists find ways of making materials that have both inorganic and organic components, yet in some cases are hard and in others soft. In this chapter you will see how the knowledge of the properties of atoms and of bulk matter that we have encountered so far can be used to develop and select materials for different applications. You will also see how some of the calculations introduced in earlier chapters are applied to questions related to materials. METALLIC MATERIALS Metals have been used as materials for more than 10 000 years. They are commonly used as an alloy, a mixture of metals formed in the melt and, in the case of steels, containing carbon. Steel is a ferrous alloy, meaning that it is based on iron and often includes various other d-block metals that confer strength and corrosion resistance. Nonferrous alloys are those based on metals other than iron, such as the brasses and bronzes that are based on copper. 6.1 The Properties of Metals A metal can be thought of as an array of cations held together by a “sea” of mobile electrons (recall Fig. 1.53). This model explains many of their physical properties. For example, metals conduct electricity because the electrons of the sea can respond to an METALLIC MATERIALS 6.1 The Properties of Metals 6.2 Alloys 6.3 Steel 6.4 Nonferrous Alloys HARD MATERIALS 6.5 Diamond and Graphite 6.6 Calcium Carbonate 6.7 Silicates 6.8 Cement and Concrete 6.9 Borides, Carbides, and Nitrides 6.10 Glasses 6.11 Ceramics MATERIALS FOR NEW TECHNOLOGIES 6.12 Bonding in the Solid State 6.13 Semiconductors 6.14 Superconductors 6.15 Luminescent Materials 6.16 Magnetic Materials 6.17 Composite Materials NANOMATERIALS 6.18 The Nature and Uses of Nanomaterials 6.19 Nanotubes 6.20 Preparation of Nanomaterials 205 Chapter 6 INORGANIC MATERIALS applied potential difference and move past the stationary cations. In contrast, ionic, molecular, and network solids are typically electrical insulators or semiconductors (see Section 6.12) because their electrons are confined to individual atoms and molecules. Notable exceptions include the ionic materials that act as high-temperature superconductors—which no one really understands yet—and the organic polymers (compounds formed by linking together large numbers of small molecules into chains) that are electrical conductors by virtue of their extended conjugated ␲-orbitals (see Box 19.1). The characteristic luster of metals is due to the mobility of the electrons that form the sea. An incident light wave is an oscillating electromagnetic field. When it strikes the surface of a metal, the electric field of the radiation pushes the mobile electrons backward and forward. These oscillating electrons radiate light, and we see it as a luster— essentially a re-emission of the incident light (Fig. 6.1). The electrons oscillate in step with the incident light, and so they generate light of the same frequency. In other words, red light reflected from a metallic surface is red and blue light is reflected as blue. That is why an image in a mirror—a thin metallic coating on glass—is a faithful portrayal of the reflected object. Self-Test 6.1A The pink color of copper is due to the absorption of light in the blue region of the spectrum, at wavelengths of about 470 nm. To what energy separation (in joules) does that wavelength correspond? [Answer: 4.2 ϫ 10Ϫ19 J] Self-Test 6.1B The yellow color of gold is due to the absorption of light in the violet region of the spectrum, at wavelengths of about 420 nm. To what energy separation (in joules) does that wavelength correspond? The mobility of its electrons also explains a metal’s malleability, the ability to be hammered into shape, and its ductility, the ability to be drawn into wires. Because the cations are surrounded by an electron sea, metallic bonding has very little directional character. As a result, a cation can be pushed past its neighbors without much effort. A blow from a hammer can drive large numbers of cations past their neighbors. The electron sea immediately adjusts, so that the atoms move relatively easily into their new positions (Fig. 6.2). Metals are more malleable than other solids: when groups of atoms are moved from one location to another, the electron sea follows them. Ionic solids are commonly brittle: the interaction between ions is lost when a group of them is moved by a hammer blow (Section 2.4). The different malleabilities of various metals can be traced to their different crystal structures. The crystal structure of a metal typically has slip planes, which are planes of atoms that under stress may slip or slide relative to one another. The slip planes of a cubic close-packed (ccp) structure are the close-packed planes, and careful 206 CHAPTER 6 INORGANIC MATERIALS Incident radiation Reflected radiation Electrons driven into oscillation (b) FIGURE 6.1 (a) When light of a particular color shines on the surface of a metal, the electrons at the surface oscillate in step. This oscillating motion gives rise to an electromagnetic wave that we perceive as the reflection of the source. (b) Each of these solar (a) mirrors at Sandia National Laboratories in California is positioned at the best angle to reflect sunlight into a collector that uses the incident energy to generate electricity. Animation 6.2 inspection of a unit cell shows that there are eight sets of slip planes in different directions (Fig. 6.3). As a result, metals with ccp structures, such as copper, are malleable: they can be easily bent, flattened, or pounded into shape. In contrast, a hexagonal close-packed structure has only one set of slip planes (parallel to the close-packed layers), and metals with hexagonal close packing, such as zinc or cadmium, tend to be relatively brittle. The mobility of the valence electrons in a metal accounts for its electrical conductivity, luster, malleability, and ductility. 6.2 Alloys Some common alloys are listed in Table 6.1. The properties of alloys are affected by their composition, their crystalline structure, and the size and texture of the individual grains. In homogeneous alloys, atoms of the different elements are distributed uniformly, either randomly or in regular arrays, like true compounds. Examples are some varieties of brass and bronze and the alloys used for coinage. Heterogeneous alloys consist of mixtures of crystalline phases with different compositions. Examples are tin–lead solder and the mercury–silver amalgams once used to fill teeth. Unlike pure metals, which have a distinct melting point, alloys typically melt and solidify over a range of temperatures. Because the metallic radii of the d-block elements are all similar, they can form an extensive series of alloys with one another when an atom of one element takes the place of another. An example is the copper–zinc alloy used for some “copper” coins. Zinc 6.2 ALLOYS 207 (b) Mobile electron sea (a) FIGURE 6.2 (a) When a metal’s cations are displaced by a blow from a hammer, the mobile electrons can immediately respond and follow the cations to their new positions, and consequently the metal is malleable. (b) This piece of lead has been flattened by a hammer, whereas crystals of the orange-colored ionic compound lead(II) oxide have shattered. FIGURE 6.3 (a) Three of the eight orientations of the slip planes found in a cubic close-packed crystal structure; and (b) the single orientation of the slip planes found in a hexagonal closepacked crystal structure. Sections of the crystal on opposite sides of one of these planes can easily move past one another along the plane. (a) (b) TABLE 6.1 Compositions of Typical Alloys Alloy Mass percentage composition brass up to 40% zinc in copper bronze a metal other than zinc or nickel in copper (casting bronze: 10% Sn and 5% Pb) cupronickel nickel in copper (coinage cupronickel: 25% Ni) pewter 6% antimony and 1.5% copper in tin solder tin and lead stainless steel* more than 12% chromium in iron *For more detailed information on steels, see Tables 6.2 and 16.2. atoms are nearly the same size as copper atoms (their radii are 133 pm and 128 pm, respectively) and have similar electronic structures (they belong to neighboring groups; the electron configuration of Cu is [Ar]3d10 4s1 and that of Zn is [Ar]3d10 4s2 ). Therefore, zinc atoms can take the place of some of the copper atoms in the crystal. An alloy in which atoms of one metal are substituted for atoms of another metal is called a substitutional alloy (Fig. 6.4). Elements that can form substitutional alloys have atoms with atomic radii that differ by no more than about 15%. Because there are slight differences in size and electronic structure, the less abundant atoms in a substitutional alloy distort the shape of the lattice of the more abundant atoms of the host metal and hinder the flow of electrons and the spread of thermal motion. A substitutional alloy therefore typically has lower electrical and thermal conductivity than the pure element. Because the lattice is distorted, it is more difficult for one plane of atoms to slip past another. Consequently, a substitutional alloy is harder and stronger than the pure metal. Self-Test 6.2A Estimate the relative density of a brass (compared to pure copper) in which 20.00% of copper atoms have been replaced by zinc atoms without distortion of the crystal structure. [Answer: 1.006] Self-Test 6.2B Estimate the relative density of a brass (compared to pure copper) in which 50.00% of copper atoms have been replaced by zinc atoms without distortion of the crystal structure. Steel, which is discussed in Section 6.3, is a homogeneous alloy based on iron and containing up to 2% by mass of carbon. Carbon atoms (77 pm) are much smaller than iron atoms (124 pm), and do not substitute for iron in the crystal lattice. They are so small that they can fit into the interstices (the holes) in the iron lattice. The resulting material is called an interstitial alloy (Fig.6.5). For two elements to form an interstitial alloy, the atomic radius of the solute element must be less than about 60% of the atomic radius of the host metal. The interstitial atoms interfere with electrical conductivity and with the movement of the atoms forming the lattice. This restricted motion, with the interstitial atoms helping to pin the bigger atoms together, makes the alloy harder and stronger than the pure host metal. Some alloys are softer than the component metals and melt at lower temperatures. The presence of big lead atoms (175 pm) and bismuth atoms (155 pm) helps to soften a metal composed of smaller atoms and lower its melting point, much as melons in a display of oranges would destabilize the stack. A low-melting-point alloy of bismuth, lead, and tin (141 pm) is employed to control automatic water sprinklers used in certain fire-extinguishing systems. Whereas the individual metals melt at 271°C (Bi), 328°C (Pb), and 232°C (Sn), one such alloy melts at 95°C. The heat of the fire melts the alloy, which activates the sprinklers before the fire can spread. Alloys of metals tend to be stronger and have lower electrical conductivity than pure metals. In substitutional alloys, atoms of the solute metal take the place of some atoms of a metal of similar atomic radius. In interstitial alloys, atoms of the solute element fit into the interstices in a lattice formed by atoms of a metal with a larger atomic radius. 6.3 Steel Before about 1400 CE, iron was available primarily as high-carbon wrought iron or cast iron, which has a high carbon content, is hard, has a high melting point, and is brittle. Cast iron is still widely used for objects that experience little mechanical and thermal shock, such as ornamental railings, engine blocks, brake drums, and transmission housings. Steel was probably first prepared by heating iron in a charcoal fire, which results in a lower carbon content than cast iron, and thanks to its hardness, strength, and corrosion resistance, it is the primary form in which iron is used today. The iron produced in blast furnaces (see Section 16.3) is pig iron. Basic grade pig iron is 90–95% by mass iron, 3.5–4.5% carbon, 0.4–1.0% manganese, 0.5–1.2% silicon, 208 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.4 In a substitutional alloy, the positions of some of the atoms of one metal are taken by atoms of another metal. The two elements must have similar atomic radii. In steel, carbon is so important and widely used that it is regarded as an “honorary metal” even though it is actually a nonmetal. FIGURE 6.5 In an interstitial alloy, the atoms of one metal lie in the gaps between the atoms of another metal. The two elements need to have markedly different atomic radii. FIGURE 6.6 In the basic oxygen process, a blast of oxygen and powdered limestone is used to purify molten iron by oxidizing and combining with the impurities present in it. Animation 6.6 and trace amounts of other elements found in the original ore, which include phosphorus and sulfur. It must be processed further to produce steel. The first stage is to lower the carbon content of the iron and to remove the remaining impurities. In the basic oxygen process, oxygen and powdered limestone are forced through the molten metal (Fig. 6.6). In the second stage, steels are produced by adding the appropriate metals, often as ferroalloys (mixtures of the metal with iron, such as ferrovanadium, a homogeneous mixture of iron and vanadium), to the molten iron. The steel that results is a homogeneous alloy of 2% or less carbon in iron. Different formulations of steels have various hardnesses, tensile strengths, and ductilities; the higher the carbon content, the harder and more brittle the steel (Table 6.2). Heat treatment can greatly increase the strength and toughness of steel by controlling the sizes of the tiny crystallites that form the solid metal. Self-Test 6.3A What is the minimum mass of oxygen needed to reduce the carbon content of 1.0 t of pig iron from 4.0% carbon to 1.5% carbon? Assume that the only product of the reaction with oxygen is CO2. [Answer: 67 kg] Self-Test 6.3B What is the minimum mass of oxygen needed to reduce the carbon content of 1.0 t of pig iron from 4.5% carbon to 1.0% carbon? Assume that the only product of the reaction with oxygen is CO2. The corrosion resistance of iron is significantly improved by forming alloys with other elements. Stainless steels are highly corrosion resistant; they are typically about 15% chromiumbymass.Theresistancetocorrosionresultsfromthethinlayerof chromium(III) oxide that forms on the surface of the iron and protects it from further oxidation. The density of the Cr2O3 layer is about the same as that of the steel, so it adheres firmly to the surface and prevents oxidizing agents from reaching the iron. Steel is an alloy of iron with 2% or less carbon. It is produced from pig iron in the basic oxygen process and has properties that are modified by blending with other metals. 6.4 Nonferrous Alloys Nonferrous alloys can be homogeneous or heterogeneous. Both types of alloy are often prepared by mixing the elements while molten and then pouring the mixture into a mold. An alternative method for making an alloy is sintering, in which finely powdered metals are mixed and pressed into a mold as a hot, sticky powder. Alloys prepared by sintering tend to be more porous than alloys prepared from mixing the molten metals. For example, sintered bronze is used for bearings because the porous metal can absorb lubricants. Homogeneous alloys of metals with atoms of similar radius are typically substitutional alloys. For example, in brass, as already discussed, zinc atoms readily replace copper atoms in the crystalline lattice (Fig. 6.7). The presence of the zinc atoms changes the lattice parameters and distorts the local electronic structure. This distortion lowers the electrical and thermal conductivity of the host metal, but it also increases hardness and strength. The result is a strong, hard metal with good corrosion resistance that can be easily formed into desired shapes. The percentage of zinc in brass varies, but is generally around 30%. Other elements may be added to enhance desired properties. For example, tin, arsenic, and antimony improve the corrosion resistance of brass and iron increases its hardness. 6.4 NONFERROUS ALLOYS 209 TABLE 6.2 The Effect of Carbon Content on Steel Type of steel Carbon content (%) Properties and applications low-carbon steel Ͻ 0.15 ductility and low hardness, iron wire mild-carbon steel 0.15 to 0.25 cables, nails, chains, and horseshoes medium-carbon steel 0.20 to 0.60 nails, girders, rails, and structural purposes high-carbon steel 0.61 to 1.5 knives, razors, cutting tools, drill bits The resistance to corrosion provided by some oxides is called passivation and is discussed further in Section 13.14 FIGURE 6.7 The atomic radii of copper and zinc are similar, and atoms of one element fit reasonably comfortably into the lattice of the other element to give the range of alloys that we know as brass. Cu (128 pm) Zn (133 pm) One of the oldest alloys is bronze. The Bronze Age, from about 3000 to 1200 BCE, arose in eastern Turkey and Syria, when tin was extracted from its ore, cassiterite, and melted together with copper. Pure copper melts at a very high temperature (1083°C) and so is difficult to work and form in a hot charcoal fire. Tin melts at a low temperature (232°C), and so cannot be used to make cooking pots. Both metals are rather soft and so do not make good weapons. However, bronze melts at temperatures between the melting points of copper and tin, and the higher the proportion of copper, the higher the melting point. In addition, bronze is much harder than either copper or tin and is more resistant to corrosion than either pure metal. Coinage alloys are usually substitutional alloys. They are selected for durability— a coin must last for at least 3 years—and electrical resistance so that genuine coins can be identified by vending machines. As its name indicates, alnico is a homogeneous alloy of aluminum, nickel, and cobalt. It is a strong, hard alloy with good temperature stability and corrosion resistance that is usually manufactured by casting the melt in a mold or by sintering. However, alnico alloys tend to be brittle and so difficult to shape. Because they are ferromagnetic (Section 6.16), the primary use of alnico alloys is in permanent magnets, particularly in speakers, mobile phones, and high-temperature applications. Bismuth and cadmium form a heterogeneous alloy. When a molten mixture of bismuth and cadmium solidifies, the solid is a mixture of small crystals of pure bismuth and pure cadmium. As a bismuth-rich melt is cooled, bismuth is deposited and the composition of the remaining liquid changes, becoming richer in cadmium. As a cadmiumrich melt is cooled, solid cadmium is deposited and the composition of the remaining liquid changes, becoming richer in bismuth. Because of the changing compositions, the alloys freeze and melt over a temperature range. However, there is one composition at which the entire sample freezes and melts at a single fixed temperature that is lower than the melting point of either pure metal (Fig. 6.8). A mixture that behaves in this way is called a eutectic (from the Greek words for “easily melted”). Self-Test 6.4A Suppose that the illustration in Fig. 6.8 corresponds to a mixture of lead (metal A) and tin (metal B). Estimate the mass percentage composition of the eutectic mixture. [Answer: 51% Pb, 0.49% Sn] Self-Test 6.4B Suppose instead that the illustration in Fig. 6.8 corresponds to a mixture of silver (metal A) and nickel (metal B). Estimate the mass percentage composition of the eutectic mixture. Alloys are mixtures of metals and other elements formulated to achieve desired properties. Generally, an alloy is harder and stronger than the pure metal but has lower electrical and thermal conductivity. HARD MATERIALS Structural materials are typically hard as they must withstand strong deforming forces. They include cement, concrete, and steel and are chosen for their strength and endurance. Some structural materials have been known since prehistoric times, but new materials have allowed architects to design ever taller, often more graceful buildings and to ensure that they are economical to inhabit and easy to maintain. Some of the older structural materials are also found in organisms, where their task is to form a rigid framework or to act as weapons. 6.5 Diamond and Graphite The differences in the properties of the various allotropes of carbon can be traced to their structures. As described in Section 5.11, graphite consists of planar sheets of sp2 hybridized carbon atoms in a hexagonal network (Fig. 6.9). Electrons spread through the delocalized ␲-network and this delocalization accounts for graphite being a black, lustrous, electrically conducting solid; indeed, graphite is used as an electrical conductor 210 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.8 This temperature– composition plot shows how the melting point of a heterogenous alloy changes with temperature. Point e is the eutectic composition of the system. Note that it melts at the lowest temperature possible for the alloy. Liquid ϩ metal A Liquid ϩ metal B Liquid Solid alloy e Temperature,T 0 1 Mole fraction of B, xB (a) (b) FIGURE 6.9 (a) Graphite consists of flat planes of hexagons lying above one another; (b) the ABAB stacking arrangement of adjacent planes. Only the ␴-bonding framework is shown: the ␲-bonds spread above and below the planes. When impurities are present, the planes can slide past one another quite easily. The extensive delocalization through the network of bonding within the planes allows graphite to conduct electricity well along the planes but less well perpendicular to the planes. Animation 6.9 in industry and as electrodes in electrochemical cells and batteries. Electrons can move within the sheets of graphite but much less readily from one sheet to another. Hence, graphite conducts electricity better parallel to the sheets than perpendicular to them. In commercially available forms of graphite, many impurity atoms are trapped between the sheets; these atoms weaken the already weak intersheet bonds and let the sheets of atoms slide over one another. Thus, graphite is soft and, when impure, slippery. In pencil lead the graphite is mixed with clay. When we write with a pencil, the mark left on the paper consists of rubbed-off layers of graphite. Self-Test 6.5A Suppose you shade a square of side 1.0 cm with a pencil that leaves a layer of graphite 315 nm thick. Estimate (a) the number of carbon atoms that you deposited and (b) the amount in moles. [Answer: (a) 4.1 ϫ 1018 atoms; (b) 6.7 ␮mol] Self-Test 6.5B Suppose you draw a line of length 10 cm and width 0.5 mm with a pencil that leaves a layer of graphite 710 nm thick. Estimate (a) the number of carbon atoms that you deposited and (b) the amount in moles. Each chicken-wire like sheet of carbon atoms in graphite is called a graphene sheet. Graphene itself, a single sheet of graphite, is a new material with exceptional promise in the electronics industry. Sheets of graphene can be prepared in a very pure state, then stacked together with water molecules that act as a kind of glue between them. The result is a very strong, flexible, but vanishingly thin paperlike material that conducts electricity but is tougher than diamond. Absorption of gas molecules changes its electrical properties, making graphene a good sensor for gas. It can also be used in transistors, as a protective coating, and as a substrate for scanning tunneling microscopy (see Box 5.1). In diamond, each carbon atom is sp3 hybridized and linked tetrahedrally to its four neighbors, with all electrons in CßC ␴-bonds (Fig. 6.10). Diamond is a rigid, transparent, electrically insulating solid. It is the hardest substance known and the best conductor of heat, being about five times better than copper. These last two properties make it an ideal abrasive, because it can scratch all other substances, yet the heat generated by friction is quickly conducted away. Diamond is also used as a protective coating for drill bits. Its high heat conductivity makes thin films of diamond ideal for use as a base for some integrated circuits so that they do not overheat. The vigorous vibration of an atom in a hot part of the crystal is rapidly transmitted to distant, cooler parts through the covalent bonds, rather like the effect of slamming a door in a steel-framed building. In nature, diamond is found embedded in a soft rock called kimberlite. This rock rises in columns from deep in the Earth, where the diamonds are formed under intense pressure. One method used to make synthetic industrial diamonds recreates the geological conditions that produce natural diamonds by compressing graphite at pressures greater than 80 kbar and temperatures above 1500°C (Fig. 6.11). Small amounts of metals such as chromium and iron are added to the graphite. The molten metals are thought to dissolve the graphite and then, as they cool, to deposit crystals of diamond, which are less soluble than graphite in the molten metal. Most synthetic diamonds are produced by thermal decomposition of methane. In this technique, the carbon atoms settle on a cool surface as both graphite and diamond. However, because hydrogen atoms produced in the decomposition react more quickly with graphite, forming volatile hydrocarbons, more diamond than graphite survives. Diamond and graphite are allotropes of carbon. They both have network structures, but diamond has greater strength and thermal conductivity due to its single bonds and sp3 hybridization. Graphite has greater electrical conductivity due to the delocalization of its ␲-orbitals over its graphene sheets. 6.6 Calcium Carbonate Ionic compounds of calcium are often used as structural materials in organisms, buildings, and civil engineering, on account of the rigidity of their structures. This rigidity stems from the strength with which the small, highly charged Ca2ϩ cation interacts 6.6 CALCIUM CARBONATE 211 FIGURE 6.10 Structure of diamond. Each carbon atom is sp3 hybridized and forms tetrahedral ␴-bonds to four neighbors. This pattern is repeated throughout the crystal and accounts for diamond’s great hardness. 0 2000 4000 Temperature (K) 0 5 10 15 20 25 30 Pressure(GPa) Diamond Graphite Liquid 10 000 atm FIGURE 6.11 The phase diagram of carbon, showing the regions of phase stability. Animation 6.10 with its neighbors. Because the carbonate ion is also doubly charged, calcium carbonate, CaCO3, has a relatively high lattice energy (see Section 2.3). Consequently, one of the earliest building materials was limestone, an impure form of calcium carbonate, which takes its honey color from impurities such as Fe2ϩ ions. In its compressed and harder form, it is marble; in its less compacted form it is chalk. All these forms of calcium carbonate are aggregates of small crystals. The two most common forms of crystalline calcium carbonate are calcite and aragonite. Although aragonite is harder and denser than calcite, it is less abundant and less stable. In addition, it converts to calcite at high temperatures. Therefore, most limestone buildings are blocks of aggregates of impure calcite. One problem with the use of limestone in construction today is that carbonates can react with acids. The acidity of rain has increased since the industrial revolution due to the presence of sulfur and nitrogen oxides in the air from burning coal, oil, and gasoline, which causes erosion of limestone buildings and statuary (see Box 11.1). Chalk was sometimes used in construction before power tools were available because it is easy to cut and shape. However, it is not as durable as limestone. Marble is a hard, dense form of calcium carbonate that can be given a high polish; it is often used to clad the exterior and interior walls of buildings to give them an attractive appearance. Self-Test 6.6A What is the change in the length of a side of a 1.0-cm cube of aragonite (density 2.83 gиcmϪ3 ) when it converts to calcite (density 2.71 gиcmϪ3 )? [Answer: ϩ0.15 mm] Self-Test 6.6B What is the change in the length of a side of a 1.0-cm cube of diamond (density 3.51 gиcmϪ3 ) when it converts to graphite (density 2.27 gиcmϪ3 )? Nature has made extensive use of the ability of calcium to form rigid structures. It is found as the calcium carbonate of the shells of shellfish and the calcium phosphate of bone. In fact, large deposits of limestone have resulted from seashells and microorganisms that accumulated on ocean floors millions of years ago. Both seashells and bones are much stronger than the pure calcium salts, because they have a composite structure, with the carbonate or phosphates imbedded in a tough matrix (see Section 6.17). Calcium compounds are common in structural materials because the small, highly charged Ca2؉ ion results in rigid structures. 6.7 Silicates Silica, SiO2, is a hard, rigid material that differs from calcium carbonate in that it is a network solid. It is insoluble in water and occurs naturally as quartz and sand, which consists of small fragments of quartz, usually colored golden brown by iron oxide impurities (Fig. 6.12). Minerals based on silica and silicates, such as sandstone and granite, are used when a strong, durable, corrosion-resistant construction material is required. 212 CHAPTER 6 INORGANIC MATERIALS (a) (b) (c) FIGURE 6.12 Three common forms of silica (SiO2): (a) quartz; (b) quartzite; and (c) cristobalite. The black parts of the sample of cristobalite are obsidian, a volcanic rock that contains silica. Sand consists primarily of small pieces of impure quartz. Silica gets its strength from its covalently bonded network structure. In silica itself, each Si atom is at the center of a tetrahedron of O atoms, and each corner O atom is shared by two Si atoms (1). Hence, each tetrahedron contributes one Si atom and ϭ 2 O atoms to the solid, which has the empirical formula SiO2. Quartz has a complicated structure; it is built from helical chains of SiO4 units (for a net composition of SiO2 when the sharing of O atoms between units is taken into account) wound around one another. When it is heated to about 1500°C, it changes to another arrangement, that of the mineral cristobalite (Fig. 6.13). This structure is easier to describe: its Si atoms are arranged like the C atoms in diamond; but, in cristobalite, an O atom lies between each pair of neighboring Si atoms. There are a variety of silicates, which can be viewed as various arrangements of tetrahedral oxoanions of silicon in which each SißO bond has considerable covalent character. The differences in properties between the various silicates are related to the number of negative charges on each tetrahedron, the number of corner O atoms shared with other tetrahedra, and the manner in which chains and sheets of the linked tetrahedra lie together. Differences in the internal structures of these highly regular network solids lead to a wide array of materials, ranging from gemstones to fibers. Most glasses are primarily mixtures of silicates and ionic compounds (see Section 6.10). Quartz itself is useful in spectroscopy because it is transparent to ultraviolet radiation. The simplest silicates, the orthosilicates, are built from SiO4 4Ϫ ions. They are not very common but include the mineral zircon, ZrSiO4, which is used as a substitute for diamond in costume jewelry. The pyroxenes consist of chains of SiO4 units in which two corner O atoms are shared by neighboring units (Fig. 6.14); the repeating unit is the metasilicate ion, SiO3 2Ϫ . Electrical neutrality is provided by cations regularly spaced along the chain. The pyroxenes include jade, NaAl(SiO3)2. Chains of silicate units can link together to form ladderlike structures that include tremolite, Ca2Mg5(Si4O11)2(OH)2. Tremolite is one of the fibrous minerals called asbestos, which can withstand extreme heat (Fig. 6.15). Their fibrous quality is due to the way in which the ladders of SiO4 units lie together but can easily be torn apart. Because of their great resistance to fire, asbestos fibers were once widely used for heat insulation in buildings. However, these fibers can lodge in lung tissue, where fibrous scar tissue forms around them, giving rise to asbestosis and a susceptibility to lung cancer. In some minerals, the SiO4 tetrahedra link together to form sheets. An example is talc, a hydrated magnesium silicate, Mg3(Si2O5)2(OH)2. Talc is soft and slippery because the silicate sheets slide past one another. More complex (and more common) structures result when some of the silicon(IV) in silicates is replaced by aluminum(III) to form the aluminosilicates. The missing positive charge is made up by the presence of extra cations. These cations account for the difference in properties between the silicate talc and the aluminosilicate mica. One form of mica is KMg3(Si3AlO10)(OH)2. In this mineral, the sheets of tetrahedra are held together by extra Kϩ ions. Although it cleaves neatly into transparent layers when the sheets are torn apart, mica is not slippery like talc (Fig. 6.16). Because they are more heat resistant than glass, sheets of mica are used for windows in furnaces. The feldspars are aluminosilicates in which as much as half the silicon(IV) has been replaced by aluminum(III). They are the most abundant silicate materials on Earth and are a major component of granite, a compressed mixture of mica, quartz, and feldspar that serves as one of the most valued and attractive building materials (Fig. 6.17). When some of the ions between the crystal layers are washed away as these rocks weather, the structure crumbles to clay, one of the main inorganic components of soil. A typical feldspar has the formula KAlSi3O8. Its weathering by carbon dioxide and water can be described by the equation 2 KAlSi3O8(s) ϩ 2 H2O(l) ϩ CO2(g) K2CO3(aq) ϩ Al2Si2O5(OH)4(s) ϩ 4 SiO2(s) ¡ 4 * 1 2 6.7 SILICATES 213 FIGURE 6.13 The structure of cristobalite is like that of diamond except that an O atom (red) lies between the Si atoms (gray). The arrangement about each Si atom is shown in structure 1. 1 An SiO4 unit Si O O O Si OϪ OϪ FIGURE 6.14 The basic structural unit of the minerals called pyroxenes. Each tetrahedron is an SiO4 unit (like that in structure 1), and a shared corner represents a shared O atom (red in the inset where one O atom lies directly over an Si atom). The two unshared O atoms each carry a negative charge. The potassium carbonate is soluble and washes away, but the aluminosilicate remains as the clay. Silicate structures are based on SiO4 tetrahedral units with different negative charges and different numbers of shared O atoms. 6.8 Cement and Concrete The building blocks used in construction are commonly held together by binders called cements. The most common type of cement is Portland cement, which is made by heating a mixture of crushed limestone, clay or shale, sand, and oxides such as iron ore in a kiln (Table 6.3). As shown in Table 6.3, different types of Portland cement have been developed to meet different requirements. Clays are primarily aluminosilicates (see Section 6.7), which are composed of layers of ions separated by water molecules. When they are heated with calcium carbonate, the water molecules are driven off. The hard pellets that result, the “clinkers,” are a mixture of mainly calcium oxide, calcium silicates, and calcium aluminum silicates. These pellets are ground together with gypsum, CaSO4и2H2O, into a powder that sets into a hard mass when mixed with water. The water reacts with the mixture to produce hydrates and hydroxides. The reactions are complex, but a representative equation is (Al2O3)и(CaO)3(s) ϩ 3 CaSO4и2H2O(s) ϩ 26 H2O(l) (Al2O3)и(CaO)3и(CaSO4)3и32 H2O(s) ¡ 214 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.15 The minerals commonly called asbestos (from the Greek words meaning “not burning”) are fibrous because they consist of long chains based on SiO4 tetrahedra linked through shared oxygen atoms. FIGURE 6.16 The aluminosilicate mica cleaves into thin transparent sheets with high melting points. These properties allow it to be used for windows in furnaces. FIGURE 6.17 The mineral granite is a compressed mixture of mica, quartz, and feldspar. TABLE 6.3 The Compositions of Common Portland Cement Clinkers Type of cement Typical composition* 1. General use 50–70% (SiO2)и(CaO)3, 15–30% (SiO2)и(CaO)2, 5–10% (Al2O3)и(CaO)3, 5–15% (4CaO)иAlnиFe2–nO3. 2. Moderate sulfate resistance Resists attack by sulfates. Generates heat slowly and so sets slowly. Low (Al2O3)и(CaO)3 content. 3. High early strength Has more (SiO2)и(CaO)3 than Type 1 and has been ground finer to set faster. 4. Low heat Used when hydration heat must be minimized. Has about half the percentage of (SiO2)и(CaO)3 and (Al2O3)и(CaO)3 and double the abundance of (SiO2)и(CaO)2 of Type 1. 5. High sulfate resistance Highly resistant to reaction with sulfates. Very low percentage of (Al2O3)и(CaO)3 and high percentage of (SiO2)и(CaO)2. *Small, variable amounts of other oxides are present in all Portland cements. Because the particles in Portland cement are finely ground and mixed together, the hydrates bind the salts together into an intricate three-dimensional network, forming a hard, strong material as the cement dries and other reactions take place, such as: 6 (SiO2)и(CaO)3(s) ϩ 18 H2O(l) (SiO2)6и(CaO)5и5 H2O(s) ϩ 13 Ca(OH)2(s) Self-Test 6.7A What mass of water is needed to react completely with 1.0 kg of Al2O3и(CaO)3(s)? [Answer: 1.7 kg] Self-Test 6.7B What mass of water is needed to react completely with 1.0 kg of SiO2и(CaO)3(s)? Concrete consists of a binder and a filler. The filler is usually gravel, but sometimes polymer or vermiculite pellets are added to lower the density. Vermiculite is a low-density clay-like silicate material with a structure that has been expanded by heating. The binder is cement, usually Portland cement. Mortar is a cement-like substance used to hold bricks and other building materials together. Portland cement mortar consists of about one part cement and three parts sand (largely silica, SiO2). Lime mortar is a fastsetting mortar that contains limestone. It sets to a hard mass as the lime reacts with the carbon dioxide of the air to form the carbonate (Fig. 6.18). Portland cement forms when a mixture of limestone, clay, and other substances are heated to a high temperature. It sets when water is added, forming a network of hydrates. 6.9 Borides, Carbides, and Nitrides Numerous borides of the metals and nonmetals are known. Their formulas are typically unrelated to their location in the periodic table and include AlB2, CaB6, B13C2, B12S2, Ti3B4, TiB, and TiB2. In some metal borides, the boron atoms are found at the centers of clusters of metal atoms. More commonly, the boron atoms form extended structures such as zigzag chains, branched chains, or networks of hexagonal rings of boron atoms, as in MgB2, which is a superconductor below 39 K (Section 6.14). The hardness and heat stability related to their network structures make some borides suitable for rocket nozzles and turbine blades. The covalent carbides include silicon carbide, SiC, which is sold as carborundum: SiO2(s) ϩ 3 C(s) 2000°C ∫∫∫B SiC(s) ϩ 2 CO(g) Pure silicon carbide is colorless, but iron impurities normally impart an almost black color to the crystals. Carborundum is an excellent abrasive because it is very hard, with a diamondlike structure that fractures into pieces with sharp edges (Fig. 6.19). The interstitial carbides are compounds formed by the direct reaction of a d-block metal and carbon at temperatures above 2000°C. As in steel, the C atoms pin the metal atoms together into a rigid structure, resulting in very hard substances with melting points often well above 3000°C. Tungsten carbide, WC, is used for the cutting surfaces of drills. When boron is heated to white heat in ammonia, boron nitride, BN, is formed as a fluffy, slippery powder: 2 B(s) ϩ 2 NH3(g) ⌬ 2 BN(s) ϩ 3 H2(g) Its structure resembles that of graphite, but the latter’s flat planes of carbon hexagons are replaced in boron nitride by planes of hexagons of alternating B and N atoms (Fig. 6.20). Although it is isoelectronic with graphite, boron nitride is white and has much lower electrical conductivity than graphite because the electrons are localized on the nitrogen atoms. Under high pressure, boron nitride is converted into a very hard, diamondlike crystalline form called Borazon (a proprietary name). In recent years, boron nitride nanotubes similar to those formed by carbon have been synthesized, and they have been found to be semiconducting (see Section 6.19). ¡ ¡ 6.9 BORIDES, CARBIDES, AND NITRIDES 215 FIGURE 6.18 An electron micrograph of the surface of cement, showing the growth of tiny interlocking crystals as carbon dioxide reacts with calcium oxide and silica. FIGURE 6.19 Carborundum crystals, showing the sharp fractured edges that give the substance its abrasive power. FIGURE 6.20 (a) The structure of hexagonal boron nitride, BN, resembles that of graphite, consisting of flat planes of hexagons of alternating B and N atoms (in place of C atoms) but, as shown for two adjacent layers in part (b), the planes are stacked differently, with each B atom directly over an N atom and vice-versa (compare with Fig. 6.9). (a) (b) N B Self-Test 6.8A Assuming that the oxidation number of aluminum is ϩ3 in both compounds, what is the oxidation number of silicon in (a) carborundum; (b) feldspar? [Answer: (a) ϩ4; (b) ϩ4] Self-Test 6.8B What is the hybridization of boron and of nitrogen in (a) the graphite form of boron nitride; (b) the diamondlike form? Borides form extended structures, covalent and insterstitial carbides are very hard substances, and boron nitride has structures related to those of carbon. 6.10 Glasses A glass is an ionic solid with an amorphous structure resembling that of a liquid, generally created by freezing a melt quickly so that crystals cannot form. Glass has a network structure based on a nonmetal oxide, usually silica, SiO2, that has been melted together with metal oxides acting as “network modifiers,” which alter the arrangement of bonds in the solid. Glass was first used in ancient times and has played an important role in the development of modern architecture. Today interest in glass is growing due to the use of optical fibers to provide wideband telecommunications networks. To make glass, silica in the form of sand is heated to about 1600°C. Metal oxides, such as MO (where M is a metal cation), are added to the silica. As the mixture melts, many of the SißO bonds break and the orderly structure of the individual crystals is lost. When the melt cools, the SißO bonds re-form but are prevented from forming a crystalline lattice because some of the silicon atoms bond with the O2Ϫ ions of the metal oxide to give ßSißOϪ ßMϩ groups in place of some of the ßSißOßSiß links present in pure silica. Because of the strong covalent character of the SißO bonds, a short-range order is preserved in the glass; however, long-range order is lost. Silicate glasses are generally transparent and durable and can be formed in flat sheets, blown into bottles, or molded into desired shapes. Almost 90% of all manufactured glass combines sodium and calcium oxides with silica to form soda-lime glass. This glass, which is used for windows and bottles, is about 12% by mass Na2O prepared by the action of heat on sodium carbonate (the soda) and 12% CaO (the lime). When the proportions of soda and lime are reduced and 16% B2O3 is added, a borosilicate glass, such as Pyrex, is produced. Because borosilicate glasses do not expand much when heated, they survive rapid heating and cooling and are used for ovenware and laboratory beakers. Because crystalline regions are not present in glass, light is not scattered by the tiny crystallites that make some minerals opaque, but instead can pass easily through the glass, just as it does through water. In general, silicate-based glasses are brittle, hard, and optically transparent. These properties make them desirable for use in optical fibers. Optical fibers are made by drawing a thin fiber from an optically pure glass rod heated until it softens. The fiber is then coated with plastic (Fig. 6.21). Transmission of information through an optical fiber is much faster than it would be through a wire. However, for transmission of information it is important to avoid loss of light from the sides of the fiber. Typically in an optical fiber a gradient of composition from the center of the fiber to the edge is created, so that light is easily transmitted along the axis of the fiber, but not out to the sides. Self-Test 6.9A The refractive index is the ratio nr ϭ c/cЈ, where c is the speed of light in a vacuum and cЈ the speed of light in matter. The refractive index of glass is typically 1.6. How far can a pulse of light travel through glass in 1.0 ns? [Answer: 19 cm] Self-Test 6.9B The refractive index of water is 1.35 for blue light and 1.33 for red light. What is the spatial separation of pulses of blue and red light after 1.0 ns, given that they set out at the same instant? (See Self-Test 6.9A.) Glass can be etched (by scratching or by roughening the surface abrasively or chemically) to create decorative effects or to change its optical properties (Fig. 6.22). It is 216 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.21 Glass fibers, such as this one, about the diameter of a human hair, are used in communication networks when large amounts of information must be transmitted in a short time. FIGURE 6.22 When glass is etched by hydrofluoric acid the surface of the glass is first covered with wax and a design is scratched on the wax. The acid is then poured over it. This etched glass vase was designed by the artist Frederick Carder in the 1920s. resistant to attack by most chemicals. However, the silica in glass reacts with the F– ion from hydrofluoric acid to form fluorosilicate ions: SiO2(s) ϩ 6 HF(aq) SiF6 2Ϫ (aq) ϩ 2 H3Oϩ (aq) It is also attacked by the OHϪ ion in hot, molten sodium hydroxide and by O2Ϫ from the carbonate anion of hot molten sodium carbonate: SiO2(s) ϩ Na2CO3(l) 1400°C ∫∫∫B Na2SiO3(s) ϩ CO2(g) Self-Test 6.10A Water adheres to glass. Predict the type of intermolecular forces that form between glass and water. [Answer: Ion–dipole forces and hydrogen bonding between H2O and the partially negative O atoms in SiO2.] Self-Test 6.10B Predict the products and write the chemical equation for the etching of the SiO2 in glass by OHϪ ions. Silicate glasses have amorphous structures produced by addition of salts that disrupt the crystalline structure. They can be attacked by strong base and hydrofluoric acid. 6.11 Ceramics Many of the materials used in the most advanced technologies are based on a material characteristic of one of the oldest technologies: common clay. Most clays used commercially are oxides of silicon, aluminum, and magnesium. China clay contains primarily kaolinite, a form of aluminum aluminosilicate that can be obtained reasonably free of the iron impurities that make many clays look reddish brown, and so it is white. However, other clays contain the iron oxides that cause the orange color of terra cotta tiles and flower pots. The appearance of a flake of clay reflects its internal structure, which is something like an untidy stack of papers (Fig. 6.23). Sheets of tetrahedral silicate units or octahedral units of aluminum or magnesium oxides are separated by layers of water molecules that serve to bind the layers of the flake together. Each flake of clay is surrounded by a double layer of ions that separates the flakes by repelling the like charges on the other flakes. This repulsion allows the flakes to slide past one another and gives the clay the ability to flow in response to stress. As a result, clays can be easily molded. When clay is baked in a kiln, it forms the hard, tough ceramic materials used in firebricks, tiles, and pots as the water is driven out and strong chemical bonds form between the flakes. Large amounts of china clay, which is used to make ceramics such as porcelain and china, are applied in the coating of paper (such as this page) to give a smooth, nonabsorbent surface. Clay was the first substance to be made into a ceramic, an inorganic material that has been hardened by heating to a high temperature. Today a wide variety of compounds, often oxides, are used to create ceramics with specific properties. Typically, a ceramic material is very hard, insoluble in water, and stable to corrosion and high temperatures. These characteristics are the key to their technological value. Although many ceramics are brittle, they can be used at high temperatures without failing, and they resist deformation. Ceramics are often the oxides of elements that are on the border between metals and nonmetals, but d-metal oxides and some compounds of boron and silicon with carbon and nitrogen are also ceramic materials. Most ceramics are electrical insulators; however, some d-metal oxides, such as barium titanate, BaTiO3, and zinc oxide, ZnO, are semiconductors. In addition, some of the most promising high-temperature superconductors are ceramics (see Section 6.14). Many aluminosilicate ceramics are created by heating aluminosilicate clays to drive the water out from between the sheets of tetrahedra. This procedure leaves a rigid heterogeneous mass of tiny interlocking crystals bound together by glassy silica. Bone china, which is strong enough to be used for thin, lightweight dishes, is made from china clay with bone ash as a binder that strengthens the ceramic. ¡ 6.11 CERAMICS 217 FIGURE 6.23 The layers of clay particles can be seen in this micrograph. Because the surfaces of these layers have like charges, they repel one another and easily slide past one another, making clay soft and malleable. Aluminum oxide, Al2O3, is a ceramic oxide found in different solid forms, each of which is an important material. As ␣-alumina, it is the very hard, stable, crystalline substance corundum; impure microcrystalline corundum is the purple-black abrasive known as emery. Corundum makes up about 80% of the advanced ceramics used in high-technology applications. Its hardness, rigidity, thermal conductivity, stability at high temperatures, electrical insulating ability, and low cost make it suitable for a wide range of applications, including acting as the substrate for microchips. Corundum is prepared from powdered Al2O3 dispersed in liquid. Granules that form in the dispersion are compressed in a mold and sintered. Single-crystal forms of aluminum oxide are known and large single crystals of aluminum oxide called sapphires, which derive their color from iron and titanium impurities, are grown for specialized applications such as acoustic microscopes and as heat-resistant windows on heat-seeking missiles. The challenge presented by corundum and most other ceramics is to find a way to overcome their brittleness when that needs to be avoided. One route used with some silicon dioxide ceramics is the sol-gel process. In this process, an organic silicon compound is dissolved in a solvent such as an alcohol; water is then added to create hydrate cross-links as the compound is polymerized into a network structure. Many cross-links form as the gel sets. These cross-links form a rigid, strong matrix that has few of the tiny cracks that can initiate breakage in brittle ceramics. If the solvent is removed at high temperatures and low pressures, an aerogel, a solid foam that has a density about the same as that of air, but is a good insulator, is formed (Fig. 6.24). Some of the TiO2 and SiO2 nanoparticles used in ink and coatings can be made by the sol-gel process if care is taken to control particle size and shape during synthesis (see Section 6.20). The stability of ceramic materials at high temperatures has made them useful as furnace liners and has led to interest in ceramic automobile engines, which could endure overheating. Currently, a typical automobile contains about 35 kg of ceramic materials such as spark plugs, pressure and vibration sensors, brake linings, catalytic converters, and thermal and electrical insulation. Some fuel cells make use of a porous solid electrolyte such as zirconia, ZrO2, that contains a small amount of calcium oxide. It is an electronic insulator, and so electrons do not flow through it, but oxide ions do. Self-Test 6.11A Suppose a ceramic is made from pure Al2O3. What is the contribution of the electrons to the mass of a block of this ceramic of mass 10. kg? [Answer: 2.7 g] Self-Test 6.11B Suppose a ceramic is made from pure SiO2. What is the contribution of the electrons to the mass of a block of this ceramic of mass 10. kg? Ceramics are inorganic materials that have been hardened by heating. MATERIALS FOR NEW TECHNOLOGIES Solid-state chemistry is an exciting area of research, not only because of the importance of the applications, but because of what scientists are learning about the nature of matter. In these sections we shall see how an understanding of the nature of solids allows us to design materials that are magnetic, glow in the dark, make miniature electronics possible, and conduct electricity without resistance. 6.12 Bonding in the Solid State Many of the interesting and desirable properties of solids stem from the ability of their electrons to migrate from one region to another, that is, their ability to conduct an electric current, which is the flow of electric charge. In electronic conduction, the charge is carried by electrons. Electronic conduction is the mechanism of conduction in metals and graphite. In ionic conduction, the charge is carried by ions. This is the mechanism of electrical conduction—the transport of charge—in a molten salt or an electrolyte solution. Because ions are too bulky to travel easily through most solids, the flow of charge through solids is in most cases a result of electronic conduction. However, solid 218 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.24 An aerogel is a ceramic foam. Its low density and low thermal conductivity, combined with great strength, make it an ideal insulating material. Here a thin piece protects three wax crayons from the heat of a flame. Aerogels were used to insulate the Mars Rover. electrolytes that allow ions to move through their lattices are important materials used in rechargeable batteries. We can classify substances according to their resistance and how it varies with temperature (Fig. 6.25): An insulator is a substance that has such a high resistance that it does not conduct electricity. A metallic conductor is an electronic conductor with a resistance that increases as the temperature is raised. A semiconductor is an electronic conductor with a resistance that decreases as the temperature is raised. A superconductor is an electronic conductor that conducts electricity with zero resistance, usually at very low temperatures. A solid electrolyte is an ionic conductor. The electric conductivity, ␬ (kappa), of a sample of length l and cross-sectional area A is defined in terms of its resistance R as (1) and is measured in siemens per meter (SиmϪ1 , where 1 S ϭ 1 ⍀Ϫ1 , with ⍀, omega, the symbol for ohm). The conductivity of a metal is typically about 107 Sиm–1 ; that of a semiconductor about 10Ϫ4 SиmϪ1 . In most cases, a metallic conductor has a much higher electrical conductivity than a semiconductor, but it is the temperature dependence of the conductivity that distinguishes the two types of conductors. Self-Test 6.12A What is the resistance of a copper wire of length 1.0 m and crosssectional area 0.10 mm2 ? The conductivity of copper at room temperature is 60.7 MSиmϪ1 . [Answer: 0.16 ⍀] Self-Test 6.12B What is the resistance of a sheet of semiconductor of thickness 0.10 mm and cross-sectional area 1.0 cm2 ? The conductivity of the semiconductor at room temperature is 0.2 mS·mϪ1 . Molecular orbital theory explains the electrical properties of metallic conductors, semiconductors, and insulators by treating them as one huge molecule and supposing that their valence electrons occupy delocalized orbitals that spread throughout the solid. We have already seen (in Section 3.9) that, when N atomic orbitals merge together in a molecule, they form N molecular orbitals. The same is true of a metal; but, for a metal, N is enormous (about 1023 for 10 g of copper, for example). Instead of the few molecular orbitals with widely spaced energies typical of small molecules, the huge number of molecular orbitals in a metal are so close together in energy that they form a nearly continuous band (Fig. 6.26). As a guide to the type of energy separation to expect, we saw in Section 1.7 that the separation of neighboring energy levels of a particle of mass m in a one-dimensional box of length L is For an electron (m ϭ me) in a box of length 1.0 cm, h2 /8mL2 ϭ 6.0 ϫ 10Ϫ42 J, so even when n is enormous, the separation is still very tiny. Self-Test 6.13A Estimate the value of n for the uppermost filled level in a one-dimensional line of sodium atoms of length 1.0 cm. Hint: remember the Pauli exclusion principle, and take the radius of an Na atom as 154 pm. [Answer: n Ϸ 1.6 ϫ 107 ] Self-Test 6.13B Estimate the value of n for the uppermost filled level in a onedimensional line of calcium atoms of length 1.0 cm. Hint: Take the radius of a Ca atom as 197 pm. Now consider a molecular orbital treatment. Consider, for instance, sodium. Each atom contributes one valence orbital (the 3s-orbital in this case) and one valence electron. En+1 - En = (2n + 1) h2 8mL2 k = l A * R 6.12 BONDING IN THE SOLID STATE 219 FIGURE 6.26 A line of atoms gives rise to an almost continuous band of molecular orbital energies. At the lower edge of the band, the molecular orbitals are fully bonding; at the upper edge, the molecular orbitals are fully antibonding. The enlargement shows that, although the band of allowed energies appears to be continuous, it is in fact composed of discrete, closely spaced levels. Energy Most antibonding Most bonding Resistance Semiconductor Superconductor Metallic conductor Tc Temperature Animation 6.25 FIGURE 6.25 The resistance of a metallic conductor increases with temperature. That of a semiconductor decreases with increasing temperature. A superconductor is a substance that has zero resistance below a certain temperature (Tc). An insulator behaves like a semiconductor with a very high resistance. If there are N atoms in the sample, then the N 3s-orbitals merge to form a band of N molecular orbitals, of which half are net bonding and half are net antibonding. We say “net” bonding or antibonding because, in general and as we saw in connection with benzene (Section 3.12), a molecular orbital is bonding between some neighbors and antibonding between others, depending on where its internuclear nodes lie; only the molecular orbital of lowest energy, with no internuclear nodes, is bonding between all neighboring atoms. The N electrons contributed by the N atoms occupy the orbitals according to the building-up principle. Because two electrons can occupy each orbital, the N electrons occupy the lower N bonding orbitals. An empty or incompletely filled band of molecular orbitals is called a conduction band. Because neighboring orbitals in metals lie so close together in energy, it takes very little additional energy to excite the electrons from the topmost filled molecular orbitals to the empty orbitals of the conduction band. Electrons in the conduction band can move freely through the solid, and so they can carry an electric current. The resistance of the metal increases with temperature because, when it is heated, the atoms vibrate more vigorously. The passing electrons collide with the vibrating atoms and do not pass through the solid so easily. In an insulator, the valence electrons fill all the available molecular orbitals to give a full band called a valence band. There is a substantial band gap, a range of energies for which there are no orbitals, before the next band, the conduction band composed of the empty orbitals, begins (Fig. 6.27). The electrons in the valence band can be excited into the conduction band only by a very large injection of energy. Because the valence band is full and because the conduction band is separated from it by a large energy gap, the electrons are not mobile and the solid does not conduct electricity. Bonding in solids may be described in terms of bands of molecular orbitals. In metals, the conduction bands are incompletely filled orbitals that allow electrons to flow. In insulators, the valence bands are full and the large band gap prevents the promotion of electrons to empty orbitals. 6.13 Semiconductors Semiconductors have revolutionized the electronics industry because very tiny semiconducting devices can be used to control the flow of an electrical current. As its name implies, an electrical current does not flow as well through a semiconductor as it does through a metal. In an intrinsic semiconductor, an empty conduction band lies close in energy to a full valence band. As a result, as the solid is warmed, electrons can be excited from the valence band into the conduction band, where they can travel throughout the solid. Hence, the resistance of a semiconductor decreases as its temperature is raised. The ability of a semiconductor to carry an electric current can also be enhanced by adding electrons to the conduction band or by removing some from the valence band. This modification is carried out chemically by doping the solid, or spreading small amounts of impurities throughout it, and results in an extrinsic semiconductor. In one example, a minute amount of a Group 15/V element such as arsenic is added to very pure silicon. The arsenic increases the number of electrons in the solid: each Si atom (Group 14/IV) has four valence electrons, whereas each As atom (Group 15/V) has five. The additional electrons enter the upper, normally empty conduction band of silicon and allow the solid to conduct (Fig. 6.28). This type of material is called an n-type semiconductor because it contains excess negatively charged electrons. When silicon (Group 14/IV) is doped with indium (Group 13/III) instead of arsenic, the solid has fewer valence electrons than does pure silicon; so the valence band is no longer completely full (Fig. 6.29). We say that the valence band now contains “holes.” Because the valence band is no longer full, it has been turned into a conduction band, and an electric current can flow. This type of semiconductor is called a p-type semiconductor, because the absence of negatively charged electrons is equivalent to the presence of positively charged holes. The doped solids are overall electrically neutral, because the nuclei of the doping atoms have a charge that matches the number of their electrons. 220 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.27 In a typical insulating solid, a full valence band is separated by a substantial energy gap from the empty conduction band. Note the break in the vertical scale. Energy Valence band Conduction band Band gap FIGURE 6.28 In an n-type semiconductor, the additional electrons supplied by the electron-rich dopant atoms enter the conduction band (forming the pink band at the bottom of the conduction band), where they can act as carriers for the current. Energy Valence band Conduction band Band gap Additional electrons Solid-state electronic devices such as diodes, transistors, and integrated circuits contain p–n junctions in which a p-type semiconductor is in contact with an n-type semiconductor (Fig. 6.30). The structure of a p–n junction allows an electric current to flow in only one direction. When the electrode attached to the p-type semiconductor has a negative charge, the holes in the p-type semiconductor are attracted to it, the electrons in the n-type semiconductor are attracted to the other (positive) electrode, and current does not flow. When the polarity is reversed, with the negative electrode attached to the n-type semiconductor, electrons flow from the n-type semiconductor through the p-type semiconductor toward the positive electrode. Self-Test 6.14A Which type of semiconductor is germanium doped with arsenic? [Answer: n-type] Self-Test 6.14B Which type of semiconductor is antimony doped with tin? In semiconductors, empty levels are close in energy to filled levels. 6.14 Superconductors Three of the biggest problems facing scientists and engineers are to provide energyefficient transportation, improve the capacity and quality of communication systems, and reduce the loss of scarce power resources during transmission. Currently, less than 40% of the energy generated by burning fossil fuels in an electrical power plant actually reaches our homes, much of it being lost during transmission. Scientists and engineers suspect that all three of these problems can be solved by the development of appropriate high-temperature superconductors. High-temperature superconductors, which were mentioned earlier (in Sections 6.9, 6.11, and 6.12), have enormous technological potential because they offer the prospect of efficient power transmission and the generation of high magnetic fields for use in transport systems (Fig. 6.31). Superconductivity is the loss of electrical resistance when a substance is cooled below a characteristic transition temperature (Ts). Conventional superconductivity arises from the ability of electrons to pair by making use of lattice vibrations. The electron pairs, which are called Cooper pairs after the scientist who first proposed the mechanism, can travel almost freely through the lattice, rather like oxen yoked together are less deflected by obstacles than individual oxen. A Cooper pair forms when the presence of one electron distorts the cations of the lattice in its vicinity, and that region of distorted lattice attracts a second electron into its vicinity (Fig. 6.32). 6.14 SUPERCONDUCTORS 221 FIGURE 6.29 In a p-type semiconductor, the electron-poor dopant atoms effectively remove electrons from the valence band, and the “holes” that result (blue band at the top of the valence band) enable the remaining electrons to become mobile and conduct electricity through the valence band. Energy Valence band Conduction band Band gap Holes FIGURE 6.30 The structure of a p–n junction allows an electric current to flow in only one direction. (a) Reverse bias: the negative electrode is attached to the p-type semiconductor and current does not flow. (b) Forward bias: the electrodes are reversed to allow charge carriers to be regenerated. (a) ϩ Ϫ Hole Electron (b) Ϫ ϩ FIGURE 6.31 Superconductors have the ability to levitate vehicles with embedded magnets. This picture shows an experimental zerofriction train in Japan, built to use helium-cooled metal superconductors. The two electrons are attracted together weakly in this way; the pair—and the resulting superconductivity—survives only if the temperature is so low that the pair is not shaken apart by lattice vibrations. Superconductivity was first observed in 1911 in mercury, for which Ts ϭ 4 K. Over the years, many other metallic superconductors were identified, some having transition temperatures as high as 23 K. However, low-temperature superconductors need to be cooled with liquid helium, which is very expensive. In 1986 a record-high transition temperature of 35 K was observed, not for a metal but for a ceramic material, a lanthanum–copper oxide doped with barium. Then early in 1987, a new record Ts of 93 K was set with a yttrium–barium–copper oxide and a series of related compounds. In 1988, two more oxide series of bismuth–strontium– calcium–copper and thallium–barium–calcium–copper exhibited transition temperatures of 110 K and 125 K, respectively. By 2006, the highest transition temperature attained was 130 K. These temperatures can be reached by cooling the materials with liquid nitrogen, at only 0.2% of the cost of liquid helium. Almost all these high-temperature superconductors (HTSCs) are hard, brittle ceramic oxides that have sheets of copper and oxygen atoms sandwiched between layers of either cations or a combination of cations and oxide ions, and all are derived from their respective parent insulators by doping (Fig. 6.33). Because of their layered structure, their electrical and magnetic properties are strongly anisotropic (Section 5.15). The electric current flows easily along the planes of the copper–oxygen sheets, but only weakly perpendicular to them. Thus, the materials must be positioned with the copper–oxygen planes in a favorable orientation. A major challenge to the use of superconductors for transmitting electrical power is the difficulty of making electrical wires from a brittle ceramic material. Superconducting materials need to be formed into very long, flexible cables that can carry high current without excessive heat loss and that can retain their superconducting properties for a long period of time without chemical or physical degradation. One solution has been to deposit the superconducting material on the surface of wire or tape made of a metal such as silver. The metal is usually prepared with a textured surface that helps to align the crystal grains in the desired direction. Twenty-five kilograms of superconducting wire made in this way can carry as much current as 1800 kg of today’s copper-based electrical cable (Fig. 6.34). A better option for the transmission of electricity being considered for use in transformers may be the metallic superconductor magnesium diboride, MgB2, which is a superconductor below 39 K (Fig. 6.35). Magnesium diboride is so inexpensive to make that, even with the cost of cooling, it is less expensive than either copper wire or nonmetallic HTSC materials. It requires only inexpensive iron for cladding and can be used to make long, flexible wires. Although 39 K is a not a very high temperature, unlike Ts for metallic superconductors, it can be reached by the use of a refrigeration unit, and so liquid helium is not required. Because superconductors can create a mirror image of a magnetic field within themselves, they trap magnetic fields and can even levitate objects. This property has 222 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.32 The formation of a Cooper pair. As one electron distorts the crystal lattice, the energy of a second electron is lowered as it enters that same region. These electron–lattice interactions bind the two electrons into a pair. eϪ BaY O Cu FIGURE 6.33 The structure of a “123 superconductor,” a ceramic that has the variable formula YBa2Cu3O6.5Ϫ7.0. The numbers 1, 2, and 3 refer to the implied or specified subscripts on the first three elements in the formula. FIGURE 6.35 The unit cell of MgB2 has six boron atoms in the center of a hexagonal array of magnesium atoms. The superconductivity appears to stem from the high-energy vibrational modes of the planes of boron atoms that extend throughout the crystal. MgB FIGURE 6.34 Twenty-five kilograms of the experimental superconducting wire in the foreground can carry as much current as 1800 kg of the bulky copper cable in the background. led to research on possibilities such as levitating railroad trains over magnetic tracks (see Fig. 6.31). However, many technical problems remain to be solved before the promise of high-temperature superconductivity can be realized. Superconductors conduct electricity with no resistance at low temperatures. Metals and some ceramic materials have shown superconducting behavior. 6.15 Luminescent Materials Incandescence is light emitted by a hot body, such as the filament in a lamp or the particles of hot soot in a candle flame. Luminescence is the emission of light by a process other than incandescence. For example, when hydrogen peroxide reacts with chlorine, the O2 formed by the oxidation of H2O2 may be produced in an energetically excited state and emit light as it discards its excess energy. This process is an example of chemiluminescence, the emission of light by products formed in energetically excited states in a chemical reaction (Fig. 6.36). The light sticks used for emergency lighting glow with light from a chemiluminescent process. Bioluminescence is a form of chemiluminescence generated by a living organism. For example, the enzyme luciferase produces the luminescent compound luciferin in fireflies and some bacteria. Fluorescence and phosphorescence are the emission of light from molecules excited by radiation of higher frequency, such as visible light being emitted when a substance is illuminated with ultraviolet radiation. In fluorescence emission of light persists for only a few nanoseconds after the illumination ceases. In phosphorescence the emission persists, sometimes for seconds, as in the element phosphorus, from which the phenomenon gets its name (see Section 15.15). The crucial difference in mechanism is that fluorescence involves the retention of the relative spin orientation of the excited electron whereas in phosphorescence the electron becomes unpaired and it takes time for its spin to reverse again. Technically, we say that in phosphorescence a “singlet state” (in which a pair of electron spins are ↑↓) becomes a “triplet state” (with spins parallel, ↑↑). Because the spins can revert to ↑↓ only slowly, the excited state survives for long periods and the phosphorescent glow normally lasts longer than fluorescence. Fluorescent materials are very important in the electronic industry, as narrow fluorescent light tubes about the size of a pencil are used to provide the backlight for LCD displays in laptop computers (Section 5.15). A dim light generated in the tube excites fluorescent material coating the inside surface of the tube, which shines brightly and illuminates the screen. Fluorescent materials are also vital for medical research. Dyes such as fluorescein (2) can be attached to protein molecules, and the protein can be traced in a biological system by exciting the fluorescein and looking for its emissions. The use of a fluorescent material allows the detection of much smaller concentrations than would otherwise be possible. Because fluorescent materials can be activated by radioactivity, they are also used in scintillation counters to measure radiation (see Box 17.2). Triboluminescence is luminescence that results from mechanical shock to a crystal. It is observed in many crystalline substances and can be detected by striking or grinding sugar crystals in a dark room. The grinding creates crystal defects that trap electrons. When the electrons fall back into their usual locations, light is emitted. The cathode ray tubes that were once widely used for television and computer displays and the plasma screens that (together with liquid-crystal displays) have replaced them, both make use of phosphors, phosphorescent materials that glow when they are excited by the impact of electrons or ultraviolet radiation. In a cathode ray color monitor or television set tube, clusters of three phosphors consisting of zinc sulfide doped by a d-block metal are used for each dot in the screen. The red phosphor is often yttrium oxysulfide, Y2O2S, activated by europium. Silver-activated ZnS is often used for the blue phosphor and copper-activated ZnS for the green phosphor. Solid zinc sulfide is an insulator, with a large energy difference between the conductance and the valence bands, and the activating metal has an energy level between those two bands. When the zinc sulfide is struck by electrons of sufficient energy, one of its electrons is excited to the conduction band, leaving a positively charged hole in the lattice. The hole travels to an atom of the activating metal (in other words, electrons move into the hole, leaving 6.15 LUMINESCENT MATERIALS 223 FIGURE 6.36 Chemiluminescence, the emission of light as the result of a chemical reaction, occurs when hydrogen peroxide is added to a solution of the organic compound perylene. Although hydrogen peroxide itself can fluoresce, in this case the light is emitted by the perylene. 2 Fluorescein a hole elsewhere, and so the hole effectively travels through the solid). The excited electron then drops back from the conduction band into that hole, emitting light of a wavelength corresponding to the energy separation between the activating metal and the excited state. The phosphors must stop glowing as soon as the excitation beam passes on, so that the picture can change rapidly. In a plasma screen the excitation is caused by the ultraviolet radiation emitted by an electric discharge through a low-pressure mixture of noble gases in a cell behind each dot of phosphor. Light-emitting diode (LED) displays also use luminescent materials. In an LED a luminescent material generates light when an electric current is applied to a p–n junction. Compounds used to make different colors of light vary, but commonly aluminum gallium arsenide is used to make red LEDs, indium gallium nitride green LEDs, and zinc selenide blue LEDs. When tiny LEDs of these three colors are clustered tightly together on a display screen, any color can be generated depending on which of the three colors are activated. Organic light-emitting diodes (OLEDs) use a film consisting of an organic polymer that conducts electricity to generate light of different colors. Although LCD displays (Section 5.15) are more common, LED displays do not require backlighting, and so can be made much thinner. LED lights are being investigated for many applications, as they use much less power than incandescent lights. Self-Test 6.15A Explain how fluorescent materials can be used to detect radioactivity. [Answer: The fluorescent materials absorb energy from the radiation and release it as light.] Self-Test 6.15B Explain the difference between chemiluminescence and phosphorescence. Luminescent materials release energy as light as they return from excited states to lower energy states. 6.16 Magnetic Materials As remarked in Box 3.2, paramagnetism is the tendency of a substance to move into a magnetic field. It arises when an atom or molecule has at least one unpaired electron, which aligns with the applied field. However, because the spins on neighboring atoms or molecules are aligned almost randomly, paramagnetism is very weak and the alignment of electron spins is lost when the magnetic field is removed. In some d-metals, however, when the unpaired electrons of many neighboring atoms align with one another in an applied magnetic field, the much stronger effect of ferromagnetism arises. The regions of aligned spins, which are called domains (Fig. 6.37), survive even after the applied field is turned off. Ferromagnetism is much stronger than paramagnetism, and ferromagnetic materials are used to make permanent magnets. They are also used in the coatings of cassette tapes and computer disks. The electromagnetic recording heads align large numbers of spins as the tape passes underneath, and the spin alignment in the domains remains for years. In an antiferromagnetic material, neighboring spins are locked into an antiparallel arrangement; so the magnetic moments cancel. Manganese is antiferromagnetic. In a ferrimagnetic material, the spins on neighboring atoms are different, and although they are locked together in an antiparallel arrangement, the two magnetic moments do not completely cancel. Ferromagnetism also occurs in alloys such as alnico (Section 6.4) and some compounds of the d-metals, such as the oxides of iron and chromium. Ceramic magnets, which are used in refrigerator magnets, are made of barium ferrite (BaOиnFe2O3) or strontium ferrite (SrOиnFe2O3). They are made by compressing the powdered ferrite in a magnetic field and heating it until it hardens. Because these magnets are ceramic, they are hard and brittle, with low densities. However, they are the most widely used magnets because of their low cost. Ferrofluids are ferromagnetic liquids. They are suspensions of finely powdered magnetite, Fe3O4, in a viscous, oily liquid (such as mineral oil) that contains a detergent (such as oleic acid, a long-chain carboxylic acid). The iron oxide particles do not settle out, because they are attracted to the polar ends of the detergent molecules, which form compact clusters called micelles (Section 9.9) around the particles. The nonpolar ends of the detergent molecules point outward, allowing the micelles to form a colloidal suspension 224 CHAPTER 6 INORGANIC MATERIALS (a) (b) FIGURE 6.37 Ferromagnetic materials include iron, cobalt, and the iron oxide mineral magnetite. They consist of crystals in which the electrons of many atoms spin in the same direction and give rise to a strong magnetic field. (a) Before magnetization, when the spins are almost randomly aligned; (b) after magnetization. The orange arrows represent the electron spins. Lab Video 6.37 FIGURE 6.38 When a magnet is pulled up from this viscous ferrofluid, the particles of iron(III) oxide align themselves with the magnetic field. Because strong attractions exist between the particles and the detergent molecules in the oil, the liquid is pulled into the field along with the particles. FIGURE 6.39 The structure of a molecular magnet. The nano-size molecular torus contains 84 manganese atoms and is approximately 4 nm in diameter. The manganese atoms are bonded to groups of carbon atoms in the form of acetate ions, water molecules, and chlorine atoms. In this molecule the manganese atoms act as ferromagnets. in the oil. When a magnet is brought near a ferrofluid, the particles in the liquid try to align themselves with the magnetic field, but they are kept in place by the oil (Fig. 6.38). As a result, it is possible to control the flow and position of the ferrofluid by means of an applied magnetic field. One application of ferrofluids is in the braking systems of exercise machines. The stronger the magnetic field, the greater the resistance to motion. Recently interest in single molecule magnets has grown. Individual molecular magnets contain several d-block metal atoms bonded to groups of nonmetal atoms such as carbon, hydrogen, and oxygen. They can respond to a magnetic field as if they were nano-size compass needles and thus have great potential for miniaturizing electronic storage media such as computer disks. Typically the d-block metal atoms are imbedded in cage-like structures and some of the nano-size molecular magnets have interesting shapes, such as rings, tubes, or spheres (Fig. 6.39). Magnetic materials can be paramagnetic, ferromagnetic, or antiferromagnetic. In ferromagnetic materials, large domains of electron spins are locked together in the same orientation. 6.17 Composite Materials A composite material consists of two or more substances that have been combined into a heterogeneous material, while retaining their individual characteristics. Composite materials are found in nature. For instance, seashells owe their strength to a tough organic matrix and their hardness to the calcium carbonate crystals imbedded in the matrix (Fig. 6.40). Bones have low density, but they are strong because of their composite nature. In bone tissue, crystals of phosphate salts are embedded in fibers of a natural polymer (an organic compound with long chains) called collagen that hold them in place but allow a small amount of flexibility. Artificial bone and cartilage are now becoming realities through the preparation of synthetic composite materials such as fiberglass. These materials mimic bone in that they have inorganic solids mixed into a crack-resistant polymer matrix. The result is a material that has great strength yet remains flexible. Some lightweight composites, such as the graphite composite used for tennis rackets, in which graphite fibers are imbedded in a polymer matrix, and the fibrous refractory composite insulation tiles used on the body of the space shuttle, in which alumina-borosilicate fibers are added to a silica ceramic matrix, can have three times the strength-to-density ratio of steel (Fig. 6.41). Ceramic materials are hard, but tend to be brittle. Flakes of very strong, tough materials such as titanium diboride, TiB2, can be distributed throughout ceramics to strengthen them. Even if a crack did form, it would be unable to propagate past the first flake that it encountered. A composite material containing ceramic flakes in a polylactic acid polymer is being used to provide instant mends for broken bones. The material is 6.17 COMPOSITE MATERIALS 225 FIGURE 6.40 A photomicrograph of the cross section of the mother-of-pearl lining a mollusk shell. The composite material making up mother-of-pearl consists of flat crystals of calcium carbonate embedded in a tough, flexible organic matrix that resists cracking. FIGURE 6.41 This state-of-the-art sports car makes use of a design related to that of the mollusk shell in Fig. 6.40. The body of the car is constructed of composite materials that are stronger than steel, but much lighter, resulting in higher performance. injected as a paste into the cracked bone, where it sets at body temperature into a scaffold that acts like bone tissue and promotes healing as new bone cells form around it. Composite materials combine the advantages of more than one component material. Copolymers contain more than one type of monomer. NANOMATERIALS A new area of research with the potential, among other things, for revolutionizing medical diagnosis and treatment and improving our quality of life is nanoscience, the study of the properties of nanomaterials, and its application, nanotechnology, the procedures used to manipulate matter on this scale. These procedures include new imaging technologies such as the scanning tunneling microscope and atomic force microscope (see Box 5.1). Nanomaterials are materials with particle sizes in the range 1 to 100 nm; they are larger than individual molecules but too small to exhibit most bulk properties. Nanotechnology has the promise to provide new materials such as biosensors that monitor and even repair bodily processes, microscopic computers, artificial bone, and lightweight, remarkably strong materials. 6.18 The Nature and Uses of Nanomaterials In this section we summarize what nanomaterials are, how they are prepared, some of the ways the properties of nanomaterials differ from atomic properties or those of bulk matter, and why they have raised such interest in the scientific and business communities. The discovery of how some nonmetals and metalloids can be manipulated into assembling themselves into regular, extended structures is creating entirely new areas of research (Box 15.2). In a block of metal the separation of neighboring energy levels is infinitesimal. However, the separation is significant in a cluster of atoms with dimensions in the nanometer scale. A cluster of atoms in a medium can act as a trap for electrons, and to a good approximation we can treat the cluster as a potential well and use what we already know about electrons trapped in wells to estimate the allowed energy levels. The fact that the well is not empty does not matter; it is a region in which an electron has lower potential energy than when in its surroundings. The difference between the one-dimensional well treated in Section 1.7 (where we saw that the energy levels are En ϭ n2 h2 /8meL2 ) and the present case is that the well we now consider is three-dimensional and best regarded as spherical. Therefore, we need to consider the energies of electrons trapped in a region rather like a hydrogen atom without the central nucleus but with a surrounding wall. A spherical well is more difficult to deal with than a rectangular well, but the results are very similar. For instance, the spherically symmetrical energy levels (l ϭ 0, corresponding to the s-orbitals of a hydrogen atom) of an electron in a spherical cavity of radius r are given by (2) As usual, n is the quantum level, h is Planck’s constant, and me is the mass of an electron. What does this equation tell us? Equation 2 shows that as the radius of the well decreases, the separation of energy levels increases (as 1/r2 ) , and so the wavelength of light (from ⌬E ϭ h␯ ϭ hc/␭) that can cause excitation decreases. That is, as the size of the cavity varies, so does the color of the material. Three-dimensional clusters of semiconducting materials, such cadmium selenide (CdSe), containing 10 to 105 atoms are called quantum dots. They can be made in solution or by depositing atoms on a surface, with the size of the nanocrystal being determined by the details of the synthesis. The variation of color with the radius of the quantum dot is readily observed in suspensions of CdSe quantum dots of different sizes (Fig. 6.42). Some quantum dots emit light when an excited electron falls back to a lower level in the dot. One application of this phenomenon is to monitor processes going on in biological cells. For example, a CdSe quantum dot can be attached to the surface of a En = n2 h2 8mer2 226 CHAPTER 6 INORGANIC MATERIALS Nano is derived from the Greek word for dwarf. cell, perhaps to a protein or another component, through an organic linking molecule. The spatial distribution of emission intensity and, consequently, of the labeled molecule can then be measured with a microscope. In nanomaterials, such as quantum dots, differences between energy levels may give rise to transitions in the visible region of the spectrum. 6.19 Nanotubes In 1991 scientists identified a previously unknown form of carbon when they sealed two graphite rods inside a container of helium gas and passed an electric discharge between them. Much of one rod evaporated, but some surprising structures resulted (Fig. 6.43). As well as the tiny 60-atom carbon spheres known as buckminsterfullerene, which had been known since 1985, hollow, perfectly straight carbon nanotubes were detected. A nanotube can be thought of as a graphene sheet of millions of carbon atoms rolled into a cylinder only 1–3 nm in diameter. Carbon nanotubes conduct electricity because of the extended network of delocalized ␲-bonds that runs from one end of the tube to the other. The conductivity of nanotubes depends on the way the tubes are rolled (Fig. 6.44). If the points of the hexagons 6.19 NANOTUBES 227 FIGURE 6.42 The different colors of these CdSe/ZnS quantum dot suspensions indicate the different sizes of the quantum dots that they contain. The longer the wavelength of the color emitted, the larger the diameter of the quantum dots. FIGURE 6.43 A cluster of carbon nanotubes that has formed a “rope.” The surrounding material below the rope in the photograph consists of fullerenes and other carbon structures. (a) (b) (c) FIGURE 6.44 Three versions of singlewalled carbon nanotubes: (a) “armchair”, (b) zigzag, and (c) chiral. Most tubes have ends capped by hemispheres of atoms. The electrical conducting properties of the nanotubes depend on their structures. are aligned along the long axis of the tube, their conductivity is high enough to be considered metallic. In this configuration electrons can travel through the ␲-orbitals with little resistance. If the points are aligned perpendicular to the long axis, the nanotubes act as semiconductors. Like diamonds, carbon nanotubes are good conductors of heat. Their interesting electrical conductivity and high thermal conductivity make carbon nanotubes good candidates for the development of miniature integrated circuits. Carbon nanotubes are very strong, and their tensile strength parallel to the axis of the tube is the greatest of any material that has been measured. Because they have a very low density, their strength-to-mass ratio is 40 times that of steel. This may seem surprising at first, because we do not associate graphite with great strength. However, graphite consists of flat sheets, not tubes. If you were to roll a graphene sheet into a tight cylinder, it would form a strong structure, just as a tightly rolled sheet of paper can support a weight. At least 50 different types of nanotubes and nanospheres have been synthesized from substances other than carbon. For example, MoS2 and WS2 nanotubes and nanospheres serve as solid lubricants, TiO2 nanotubes show promise as a means of storing hydrogen gas, and nanospheres of ruthenium coated with platinum serve as a catalyst for the purification of hydrogen fuel (Fig. 6.45). Nanotubes formed from boron nitride are also of great interest. Unlike carbon nanotubes, boron nitride nanotubes have electrical characteristics that do not depend on the diameter of the tube or the way the sheets are rolled. They have a moderately large band gap, and so they are considered to be only weakly semiconducting. Carbon nanotubes grow until they are capped by bonds to another element or by five-membered rings. The five-membered rings pucker the structure, forming bends along the length of tubes and domes at their ends. In the case of BN nanotubes, however, five-membered rings cannot form, because they would require boron–boron or nitrogen– nitrogen bonds, which would be too weak to maintain the structure. Instead, BN nanotubes are capped by the atom of a metal such as tungsten. The rigidity of nanotubes may also allow them to be used as minute molds or templates for nanostructures of other elements. For example, they can be filled with molten lead to create lead wires one atom in diameter. They can also serve as tiny “test tubes” that hold individual molecules in place. Nanotubes that are filled with biomolecules such as cytochrome c hold the promise of acting as nanosensors for medical applications. The very large surface area provided by the highly porous nanotubes means that atoms of gases are readily adsorbed on the inner surfaces of the tubes. Nanotubes carrying hydrogen molecules could therefore become a high-energy-density storage medium for hydrogen-powered vehicles (see Box 13.1). Such a material would solve a major obstacle to the use of hydrogen fuel cells—the problem of a safe, compact storage medium for hydrogen. Hydrogen absorbed into nanotubes can be stored in a volume much smaller than that required to store the gas. Nanotubes are tiny cylinders only a few nanometers in diameter that are constructed of rolled sheets of a graphite-like array of atoms. Carbon and boron nitride are the most extensively studied nanotubes. 6.20 Preparation of Nanomaterials Nanomaterials can be manufactured by one of two groups of methods. In “top-down” approaches, nanoscale materials are carved into shape by the use of physical nanotechnology methods such as lithography (Fig. 6.46). In “bottom-up” approaches, molecules are encouraged to assemble themselves into desired patterns by making use of specific intermolecular interactions (Fig. 6.47). In solution-based bottom-up methods, tiny crystals are formed in solution and prevented from growing larger by the addition of stabilizers in the form of surfactant molecules. In vapor-phase synthesis a substance is vaporized and then condensed or mixed with a reactant and the product condensed to form the desired tiny crystals. In both methods one-molecule-thick layers of different materials in which the molecules are oriented in a particular direction can be formed, giving the nanomaterial interesting electrical and optical properties. One type of bottom-up approach used for creating very regular arrays of nanotubes is template synthesis. In this approach, porous membranes of polymers such as polycarbonates or ceramics such as alumina are prepared, then placed into a solution 228 CHAPTER 6 INORGANIC MATERIALS FIGURE 6.45 This catalyst consists of a nanosphere of platinum atoms surrounding a ruthenium core 3 nm in diameter. These nanospheres catalyze the conversion of CO to CO2 at a lower temperature than is possible with conventional catalysts and can be used to purify hydrogen for use as a fuel. FIGURE 6.46 The images show four stages in the construction of a ring of iron atoms on a copper substrate. The scientists used “top-down” techniques to place 48 iron atoms into a ring. The circular waves seen in the final image show the density of the surface electrons inside the ring, which acts as a “corral” for the electrons. 6.20 PREPARATION OF NANOMATERIALS 229 FIGURE 6.47 A “forest” of carbon nanotubes that grew in vertical alignment in a “bottom-up” fashion. EXAMPLE 6.1 Investigating quantum dots A team of chemists wants to make a series of quantum dot suspensions by forming colloidal suspensions of nanospheres. (a) Of the following, which compounds would not be suitable for the formation of quantum dots by this method: CdS, ZnSe, CaO, CaS, K2S? Explain your answer. (b) Describe how you could prepare a quantum dot sample that emits white light. (c) The chemists prepare a CdSe quantum dot sample by mixing 5.0 mL of 0.0020 M Cd(NO3)3(aq) with 5.0 mL of 0.0020 M Na2Se(aq) in the presence of a polymer that coils into pockets that serve as templates for the spheres. Each quantum dot contains an average of 155 formula units of CdSe. What is the concentration of the quantum dots in the final suspension? (d) What is the average molar mass of the quantum dot? (e) The suspension fluoresces at 528 nm. What color is the sample and what is the diameter of the quantum dots it contains? PLAN (a) Find the solubilities of the compounds in Table I.1 in the Fundamentals section, because only compounds that are insoluble in water will be suitable (soluble compounds will simply dissolve). (b) Consider the nature of white light (a mixture of different wavelengths) and how to produce it. (c) Calculate the amount (in moles) of CdSe formed, then the molar concentration of CdSe in the solution; divide that value by the average number of CdSe formula units in a quantum dot. (d) Find the molar mass from the number of formula units per particle. (e) Find the color of the light in Table 1.1, convert wavelength to frequency, and use Eq. 2 to determine the diameter (twice the radius) of the particle. What should we assume? That the transition responsible for the color occurs between the lowest two energy levels of an electron in a spherical cavity. SOLVE (a) According to Table I.1, CdS, ZnSe (noting that selenides resemble sulfides), and CaS are insoluble, but CaO and K2S are soluble (and react with water). CaO and K2S would not be suitable. 420 nm 470 nm 530 nm 700 nm 580 nm 620 nm (b) White light contains many different wavelengths of visible light. Prepare a series of samples, each of which emits a different wavelength when excited, and mix them together. of a salt. The metal cation of the salt is reduced electrochemically and the metal plates onto the insides of the pores in the membranes. The membrane in then removed or dissolved away, leaving the nanotubes. Thinking point: The physicist Richard Feynman is credited with foreseeing the nanotechnology revolution in a talk called “There is plenty of room at the bottom.” What did he mean? 230 CHAPTER 6 INORGANIC MATERIALS 2.0 mmol 0.010 mmol 5.0 mL CdSe CdSe 1L ϭ ϫ (c) From the knowledge that each mole of Cd2ϩ reacts with 1 mol of Se2Ϫ , from n ϭ c ϫ V, and converting milliliters to liters, = 1.0 * 10-5 mol CdSe n(CdSe) = 0.0020 mol CdSe 1 L * (5.0 * 10-3 L) 0.010 mmol 0.0100 L 1.0 mmol CdSe 1L ϭ From c ϭ n/V, and using the total volume of the two solutions that were added together, Vtotal ϭ 0.0050 L ϩ 0.0050 L ϭ 0.0100 L c(CdSe) = 1.0 * 10-5 mol 0.0100 L = 0.0010 molиL-1 From c/(number of formula units per quantum dot), c(quantum dots) = 0.0010 molиL-1 155 = 6.5 * 10-6 molиL-1 Cd 119.37 g.molϪ1 Se (d) From M(CdSe) ϫ (number of formula units per quantum dot), M(CdSe) ϭ 112.41 g·molϪ1 ϩ 78.96 gиmolϪ1 ϭ 191.37 gиmolϪ1 M(quantum dot) ϭ 191.37 gиmolϪ1 ϫ 155 ϭ 2.97 ϫ 104 gиmolϪ1 or 29.7 kgиmolϪ1 528 nm (e) By referring to Table 1.1 we can identify the color of 528-nm radiation: 528-nm radiation is green light 3 2 1 Energy From Eq. 2 (En ϭ n2 h2 /8mer2 ), the energy separation of the two lowest levels (n ϭ 2 and n ϭ 1) is ¢E = 4h2 8mer2 - h2 8mer2 = 3h2 8mer2 0.693 nm From , the wavelength and radius are related by = 6.93 * 10-10 m = a 3 * (6.626 * 10-34 Jиs) * (528 * 10-9 m) 8 * (9.109 * 10-31 kg) * (2.998 * 108 mиs-1 ) b 1/2 r = a 3hl 8mec b 1/2 ¢E = hn = hc/l EXERCISES 231 ❑ 1 Distinguish the main types of alloys and explain how their properties differ from those of pure metals (Sections 6.2 and 6.4). ❑ 2 Describe the operation of a blast furnace and how steel is made by the basic oxygen process (Section 6.3). ❑ 3 Explain why calcium carbonate is the basis of so many structural materials (Section 6.6). ❑ 4 Distinguish the principal silicate structures and describe their properties (Section 6.7). ❑ 5 Describe the nature and properties of glasses and ceramics (Sections 6.10 and 6.11). ❑ 6 Use molecular orbital theory to account for the differences between metals, insulators, and semiconductors (Sections 6.12 and 6.13). ❑ 7 Explain the properties of luminescent materials (Section 6.15). ❑ 9 Distinguish the principal types of magnetism (Section 6.16). ❑ 10 Describe the nature of nanomaterials and how they differ from other materials (Sections 6.18 and 6.19). ❑ 11 Describe the primary routes for the preparation of nanomaterials (Section 6.20). SKILLS YOU SHOULD HAVE MASTERED EXERCISES Metallic Materials 6.1 The gold color of a certain brass is due to the absorption of light in the violet region of the spectrum, at wavelengths of 445 nm. To what energy separation (in joules) does that wavelength correspond? 6.2 The pink color of a certain bronze is due to the absorption of light in the blue-violet region of the spectrum, at wavelengths of 465 nm. To what energy separation (in joules) does that wavelength correspond? 6.3 Estimate the relative density (compared to pure aluminum) of magnalium, a magnesium–aluminum alloy in which 30.0% of the aluminum atoms have been replaced by magnesium atoms without distortion of the crystal structure. 6.4 Estimate the relative density (compared to pure copper) of coinage cupronickel, an alloy in which 25.0% of the copper atoms have been replaced by nickel atoms without distortion of the crystal structure. 6.5 How is the impurity present in pig iron removed to create high-quality steel? 6.6 What metal is generally added to steel to make it corrosion resistant? 6.7 How do alloys differ from the pure metals from which they are made? 6.8 What is the difference between homogeneous and heterogeneous alloys? 1.39 nm The diameter (d ϭ 2r) of the quantum dot is therefore d = 2 * 6.93 * 10-10 m = 1.39 * 10-9 m, or 1.39 nm Self-Test 6.16A A CdS quantum dot sample is prepared by mixing 5.0 mL of 0.0016 M Cd(NO3)3(aq) with 5.0 mL of 0.0016 M Na2S(aq) Each quantum dot contains an average of 151 formula units of CdS. (a) What is the concentration of the quantum dots in the final suspension? (b) What is the average molar mass of the quantum dot? (c) The suspension fluoresces at 499 nm. What color is the sample and what is the diameter of the quantum dots it contains? [Answer: (a) 5.3 ϫ 10Ϫ6 molиLϪ1 ; (b) 21.81 kgиmolϪ1 ; (c) blue-green, 1.35 nm] Self-Test 6.16B A PbSe quantum dot sample is prepared by mixing 6.0 mL of 0.0012 M Pb(NO3)3(aq) with 6.0 mL of 0.0012 M K2Se(aq) Each quantum dot contains an average of 165 formula units of PbSe. (a) What is the concentration of the quantum dots in the final suspension? (b) What is the average molar mass of the quantum dot? (c) The suspension fluoresces at 601 nm. What color is the sample and what is the diameter of the quantum dots it contains? Nanomaterials are particles between 1 and 100 nm in diameter. They have properties that differ from the properties of atoms and from those of bulk materials and are used to create miniature circuits and drug delivery systems. 6.9 When iron surfaces are exposed to ammonia at high temperatures, “nitriding”—the incorporation of nitrogen into the iron lattice—occurs. The atomic radius of iron is 124 pm. (a) Is the alloy interstitial or substitutional? Justify your answer. (b) How do you expect nitriding to change the properties of iron? 6.10 Silicon can be doped with small amounts of phosphorus to create a semiconductor used in transistors. (a) Is the alloy interstitial or substitutional? Justify your answer. (b) How do you expect the properties of the doped material to differ from those of pure silicon? 6.11 Calculate the relative number of atoms of each element contained in each of the following alloys: (a) coinage cupronickel, which is 25% Ni by mass in copper; (b) a type of pewter that is about 7% antimony and 3% copper by mass in tin. 6.12 Calculate the relative number of atoms of each element contained in each of the following alloys: (a) Wood’s metal, which is a low-melting-point alloy used to trigger automatic sprinkler systems and is 12.5% tin, 12.5% cadmium, and 24% lead by mass in bismuth; (b) a steel that is 1.75% by mass carbon in iron. Hard Matter 6.13 Compare the hybridization and structure of carbon in diamond and graphite. How do these features explain the physical properties of the two allotropes? 6.14 Ordinary “hexagonal” graphite has a structure that repeats the ABAB . . . alternation of layers; “rhombohedral graphite” has the repetition ABCABC . . . , with the C layer displaced from the other two. Sketch a structure for rhombohedral graphite. 6.15 One-atom-thin sheets of graphene were first prepared in the laboratory of Andre Geim at the University of Manchester. The scientists picked up flecks of graphite with adhesive tape and then pulled the layers apart with another piece of tape until one layer remained. Suppose you repeated this process with a piece of tape 2.0 cm wide until one layer remained that completely covered 1.0 cm of the tape. Estimate (a) the number of carbon atoms that remain on the tape and (b) the amount in moles. 6.16 A ten-atom-thin layer of graphene was deposited on a circular silicon wafer 1 cm in diameter. Estimate (a) the number of carbon atoms deposited and (b) the amount in moles. 6.17 When the mineral dolomite, CaCO3·MgCO3, is heated, it gives off carbon dioxide and forms a mixture of a metal oxide and a metal carbonate. Which oxide is formed, CaO or MgO? Which carbonate remains, CaCO3 or MgCO3? Justify your answer. 6.18 (a) Calculate the heat released when 25 kg of quicklime, the amount needed to produce 500. kg of iron, reacts with water to produce slaked lime. (b) Describe a chemical process that could be used to reconvert the slaked lime into quicklime. 6.19 A very pure crystalline form of silicon carbide called moissanite has attracted interest because it is as bright as diamond, is nearly as hard, and has similar thermal conductivity. The structure of moissanite is hexagonal close-packed, with alternating C and Si atoms. (a) Draw one unit cell of moissanite (see Fig. 5.28). (b) Despite the fact that silicon atoms are heavier than carbon atoms, moissanite has a density of 3.2 g·cmϪ3 , which is less than the density of diamond (3.5 gиcmϪ3 ). Account for the difference in densities of the two substances. 6.20 In Fig. 6.20 we see that the planes in hexagonal boron nitride take positions in which the B atoms are located directly over N atoms, whereas in graphite (Fig. 6.9), the carbon atoms are offset. Explain this difference in structure between the two substances. 6.21 A unit cell for the calcite structure can be found on the Web site for this book. From this structure, determine (a) the crystal system and (b) the number of formula units present in the unit cell. 6.22 Using the Web site for this book, examine the unit cells of calcite and dolomite. (a) How are these two structures the same? (b) What makes them different? (c) Where are the magnesium and calcium ions located in dolomite? 6.23 Iron pyrite (FeS2) is known as Fool’s Gold because of its resemblance to gold metal. However, it can easily be distinguished from gold by the difference in their densities. The density of gold is 19.28 g·cm3 and that of Fool’s Gold is 5.01 gиcm3 . What volume of Fool’s Gold would have the same mass as a 4.0 cm3 piece of gold? 6.24 Mica with a density of 1.5 g·cm3 can be expanded into vermiculite, which is used as a low-density soil amendment. The vermiculite used in soils has an average density of 0.10 gиcm3 . Estimate the volume of the vermiculite obtained by expanding 12.0 cm3 of mica. 6.25 Write a Lewis structure for the orthosilicate anion, SiO4 4Ϫ , and deduce the formal charges and oxidation numbers of the atoms. Use the VSEPR model to predict the shape of the ion. 6.26 Use the VSEPR model to estimate the SißOßSi bond angle in silica. 6.27 Describe the structures of a silicate in which the silicate tetrahedra share (a) one O atom; (b) two O atoms. 6.28 What is the empirical formula of a potassium silicate in which the silicate tetrahedra share (a) two O atoms and form a chain or (b) three O atoms and form a sheet? In each case, there are single negative charges on the unshared O atoms. 6.29 What is the oxidation number of silicon in the anion formed when glass is etched by HF? 6.30 In a typical procedure for etching glass, the glass surface is covered by a mask (a protective coating). The mask is then removed from the areas that are to be etched and a paste made of fluorite and sulfuric acid is placed on the surface. From standard reference sources, determine the chemical formula of fluorite and describe the chemical reactions that take place to achieve the etching. 6.31 What mass of clay, Al2Si2O5(OH)4, can be produced by the weathering of 2.0 kg of feldspar, KAlSi3O8? 6.32 What mass of carbon is required for complete conversion of 3.0 kg of SiO2 to SiC? 6.33 Why is it unwise to store metal fluorides in glass bottles? 6.34 Solutions of strong bases stored in glass bottles react slowly with their containers. Write the balanced chemical equations for four possible reactions between OH– and SiO2. 6.35 Why is it desirable to remove iron from ceramic clays? 6.36 Draw a simple chemical picture to show how the removal of water helps to make aluminosilicates into rigid ceramics. 6.37 What is the oxidation number of (a) phosphorus in Li7P3S11, which forms in some ceramic electrolytes; (b) titanium in BaTiO3? 6.38 Assuming that the oxidation number of aluminum is ϩ3 in both compounds, what is the oxidation number of silicon in (a) clay, Al2Si2O5(OH)4; (b) mica, KMg3(Si3AlO10)(OH)2? 232 CHAPTER 6 INORGANIC MATERIALS Materials for New Technologies 6.39 How does the change in conductivity of a semiconductor differ from that of a metal as temperature is increased? 6.40 Normally, in conducting materials, we think of current as being carried by electrons as they move through a solid. In semiconductors, it is also common to talk about the current being carried by the “holes” in the valence band. (a) Explain how holes move through a solid material. (b) If, in a p-type semiconductor device, electric current is moving from left to right, in which direction will the holes be moving? 6.41 What is the resistance of an aluminum wire of length 2.0 m, cross-sectional area 0.12 mm2 ? The conductivity of aluminum at room temperature is 60.7 MSиmϪ1 . 6.42 What is the resistance of a sheet of semiconductor of thickness 0.10 mm, cross-sectional area 1.0 cm2 ? The conductivity of the semiconductor at room temperature is 0.2 mSиmϪ1 . 6.43 Estimate the value of n for the uppermost filled level in a one-dimensional line of silver atoms of length 1.0 mm. Hint: Take the radius of an Ag atom as 144 pm. 6.44 Estimate the value of n for the uppermost filled level in a one-dimensional line of copper atoms of length 1.0 mm. Hint: Take the radius of a Cu atom as 128 pm. 6.45 Germanium is a semiconductor. If small amounts of the elements In, P, Sb, and Ga are present as impurities, which of them will make germanium into (a) a p-type semiconductor; (b) an n-type semiconductor? 6.46 Gallium arsenide is a semiconducting material. If we wish to modify the sample by replacing a small amount of the arsenic with an element to produce an n-type semiconductor, which element would we choose: selenium, phosphorus, or silicon? Why? 6.47 The unit cell of a high-temperature superconductor is shown here. What is its formula? 6.48 The unit cell of the mineral perovskite, which has a structure similar to that of some of the ceramic superconductors, is shown here. What is its formula? 6.49 Distinguish between fluorescence and phosphorescence. 6.50 Describe how triboluminescence and fluorescence are produced. 6.51 What is the main advantage of using a fluorescent dye to trace the function of biomolecules in a living cell? 6.52 In fluorescence, how does the energy of the emitted radiation compare with the energy of the exciting radiation? 6.53 Identify the elements in the d-block that are paramagnetic. 6.54 Identify the elements in the d-block that are ferromagnetic. 6.55 The magnetic susceptibility, ␹ (chi), is an indication of the number of unpaired electrons in a compound; it varies with temperature, T. A graph of magnetic susceptibility as a function of temperature for a typical ferromagnetic material is shown here. The temperature labeled TC is known as the Curie temperature. On one side of the Curie temperature, the compound is a simple paramagnetic material and, on the other side, the substance is ferromagnetic. From the graph, determine whether this compound is ferromagnetic above or below the Curie temperature. Explain your reasoning. 6.56 Describe the differences between diamagnetism, paramagnetism, ferromagnetism, and antiferromagnetism. Nanomaterials 6.57 Distinguish between the “top down” and “bottom up” approaches to manufacturing nanomaterials. 6.58 Describe the structure of a nanowire and how it conducts electricity. 6.59 A quantum dot suspension fluoresces at 580.8 nm. What color is the sample and what is the diameter of the quantum dots it contains? 6.60 A quantum dot suspension fluoresces at 490.1 nm. What color is the sample and what is the diameter of the quantum dots it contains? 6.61 The uncertainty principle is negligible for macroscopic objects. However, the properties of nanoparticles may be different from those of larger particles as a result of quantum mechanical phenomena. Calculate the minimum uncertainty in the speed of an electron confined in a nanoparticle of diameter 200. nm and compare that uncertainty with the uncertainty in speed of an electron confined to a wire of length 1.00 mm. 6.62 (a) Calculate the minimum uncertainty in the speed of a Liϩ ion confined in a nanoparticle that has a diameter of 200. nm and is composed of a lithium compound through which the lithium ions can move at elevated temperatures. (b) Which could be measured more accurately in a nanoparticle, the speed of an electron (see Exercise 6.61) or the speed of a Liϩ ion? 6.63 An electron trapped within a nanoparticle can be approximated as a particle of mass me confined to a cubic box of side L. The energy levels of the electron are E = h2 8meL2 An2 x + n2 y + n2 z B Susceptibility,χ Temperature, T Tc Ca Ti O Y Ba Cu O EXERCISES 233 (a) Write expressions for the energies of the three lowest levels. Which of these levels are degenerate? For those levels that are degenerate, give the quantum numbers corresponding to each degenerate level. 6.64 Buckminsterfullerene is form of carbon having nearly spherical molecules that are composed of 60 carbon atoms (see Section 15.12). The interior of a C60 molecule is about 0.7 nm in diameter and is being considered as a container for various atoms and molecules. Suppose that buckminsterfullerene were used to transport molecular hydrogen. It can be approximated as a cube with a side of 0.7 nm. Approximating the hydrogen molecule as a point mass, how much energy does a hydrogen molecule inside a C60 molecule need to be excited from the lowest energy level to (a) the second energy level; (b) the third energy level? (See Exercise 6.63.) Integrated Exercises 6.65 Solid silicon carbide reacts with molten sodium hydroxide and oxygen gas at high temperatures to form solid Na2SiO3, gaseous water, and carbon dioxide. Write a balanced equation for the reaction. 6.66 Aluminum carbide is considered a covalent carbide. However, it reacts with water as ionic carbides do, to produce solid aluminum hydroxide and methane gas, CH4. Write a balanced equation for the reaction. 6.67 What is the total mass of (a) the electrons; (b) the protons in a block of the ceramic ZrO2 of mass 15.0 kg? 6.68 What is the total mass of (a) the electrons; (b) the protons in a block of the ceramic BaTiO3 of mass 12.0 kg? 6.69 Zinc oxide is a semiconductor. Its conductivity increases when it is heated in a vacuum but decreases when it is heated in oxygen. Account for these observations. 6.70 The surface of glass contains many groups that are bonded to the silicon atoms of SiO2, which is the major component of glass. If the glass is treated with Si(CH3)3Cl (chlorotrimethylsilane), a reaction takes place to eliminate HCl and attach the Si atom to the oxygen atom: (surface of glass) ϩ Si(CH3)3Cl (surface of glass) OSi(CH3)3 ϩ HCl How will this rearrangement affect the interaction of liquids with the glass surface? 6.71 Below are two absorption plots. One was obtained from a solution of an organic dye and the other from a quantum dot suspension. Which plot was obtained from which solution? Explain your reasoning. 6.72 Light-emitting diodes (LEDs) contain p–n junctions. The circuit in an LED is arranged so that electrons from the power source flow into the conduction band of the n-type side. As electrons continue to flow, they are pushed to the conduction band of the p-type side, which can hold more electrons. These electrons enter the conduction band of the p-type side, because they already occupy the higher-energy band in the n-type side. However, once the electrons are in the higher-energy band of the p-type side, they fall into the lower-energy band unless it is full. As these electrons make transitions to the lower-energy band, energy is released in the form of light. (a) Explain, in terms of the movement of electrons, why an LED cannot be made from the junction of pure silicon and silicon doped with phosphorus. (b) If the direction of the circuit in the LED is reversed, so that the electrons flow from the power source into the p-type side of the p–n junction directly, where would the electrons go once they enter the p–n junction? (That is, indicate which bands would receive the electrons and whether the electrons would then migrate to other bands.) (c) Would you expect the LED to emit light when it is placed in the reverse circuit described in part (b)? Explain your answer. Chemistry Connections 6.73 The tiny structures such as spheres and tubes formed by carbon atoms are the basis for a large part of the field of nanotechnology. Boron nitride forms similar structures. (a) What is the hybridization of carbon atoms in carbon nanotubes and of boron and nitrogen atoms in boron nitride nanotubes? (b) A simple carbon nanotube is made up of a sheet resembling a layer of graphite (similar to chicken wire) that has been curled up and bonded to itself. How many hexagons must be strung together (the hexagons denoted by the colored bonds in the following diagram) around the circumference of a nanotube to form a tube that is approximately 1.3 nm in diameter? The diagram shows the orientation of hexagons with respect to the curvature of the nanotube. The CßC bond distance in carbon nanotubes is 142 pm. (c) Buckminsterfullerene, C60, can be hydrogenated, but, to date, a compound with the formula C60H60 has not been prepared. The most hydrogenated form of C60 known is C60H36. Suggest an explanation for why the hydrogenation stops at this point. See Section 15.12. (d) Boron nitride can form nanotubes, but does not form spheres that resemble buckminsterfullerene. Suggest a reason why BN cannot form spheres. (e) In its cubic crystalline form the nitrogen atoms of BN form a face-centered cubic unit cell in which half the tetrahedral interstitial sites are occupied by B atoms (if all B and N atoms were replaced by C atoms, the diamond structure would result). Calculate the density of cubic BN if the edge length of the unit cell is 361.5 pm. (f) The density of hexagonal BN is 2.29 g·cmϪ3 . Which form of BN is favored at high pressures, hexagonal or cubic? Absorption 800700600500400 (a) (b) 300 Wavelength (nm) ¬ ¡¬OH ¬ OH 234 CHAPTER 6 INORGANIC MATERIALS 235 What Are the Key Ideas? Heat and work are equivalent ways of transferring energy between a system and its surroundings. The total energy of an isolated system is constant. The enthalpy change for a process is equal to the heat released at constant pressure. Why Do We Need to Know This Material? The laws of thermodynamics govern chemistry and life. They explain why reactions take place and let us predict how much heat reactions release and how much work they can do. Thermodynamics plays a role in every part of our lives. For example, the energy released as heat can be used to compare fuels, and the energy resources of food are used to assess its nutritional value. The material in this chapter provides a foundation for the following chapters, in particular Chapter 8, which deals with the driving force of chemical reactions. What Do We Need to Know Already? This chapter assumes that we are familiar with the concept of energy (Section A), stoichiometry (Sections L and M), and the ideal gas law (Chapter 4). Some of the explanations refer to intermolecular forces (Sections 4.12 and 5.1–5.6). Ionic bonding (Sections 2.3–2.4) and bond strengths (Sections 2.14–2.15) are developed further in this chapter. E nergy is the basis of civilization. Every day we use energy in its various forms to maintain life, to stay sufficiently cool or warm, to move about, and to think. All these processes involve the release, absorption, transfer, or conversion of energy. A huge global effort is currently under way to find new sources of energy, to use what energy is available more efficiently, and to conserve its use. Access to energy is one of the major problems facing humanity, for so much depends on it. Thinking point: Can you identify any human activity that does not make use of energy? The study of the transformations of energy from one form into another is called thermodynamics. The first law of thermodynamics, which is introduced in this chapter, is concerned with keeping track of energy changes. It allows us to calculate, for instance, how much heat a reaction can produce. The second law of thermodynamics, which is the subject of Chapter 8, explains why some chemical reactions take place but others do not. Both laws are summaries of experience with bulk matter and are independent of any model that we might have of its microscopic structure—you could do thermodynamics even if you had never heard of atoms! However, we can use the models of atoms and molecules we have been developing to elucidate these laws and enrich our understanding of them. The link between the properties of atoms and those of bulk matter is statistical thermodynamics, the interpretation of the laws of thermodynamics in terms of the average behavior of the large numbers of atoms and molecules that make up a typical sample. SYSTEMS, STATES, AND ENERGY Two of the fundamental concepts of thermodynamics are heat and work. People once thought that heat was a material fluid called caloric, which flowed from a hot substance to a cooler one. The French engineer Sadi Carnot (Fig. 7.1), who helped to lay the foundations of thermodynamics, believed that work resulted from the flow of caloric, just as the flow of water does work by turning a water wheel. Some of Carnot’s conclusions survive, but we now know that there is no such substance as caloric. About 25 years after Carnot proposed his ideas in the early nineteenth century, the English physicist James Joule (Fig. 7.2) showed that heat and work are simply two ways in which energy can be transferred. In this chapter we first examine work, then heat, and see that in fact heat is not a substance that flows. SYSTEMS, STATES, AND ENERGY 7.1 Systems 7.2 Work and Energy 7.3 Expansion Work 7.4 Heat 7.5 The Measurement of Heat 7.6 The First Law 7.7 A Molecular Interlude: The Origin of Internal Energy ENTHALPY 7.8 Heat Transfers at Constant Pressure 7.9 Heat Capacities at Constant Volume and Constant Pressure 7.10 A Molecular Interlude: The Origin of the Heat Capacities of Gases 7.11 The Enthalpy of Physical Change 7.12 Heating Curves THE ENTHALPY OF CHEMICAL CHANGE 7.13 Reaction Enthalpies 7.14 The Relation Between ΔH and ΔU 7.15 Standard Reaction Enthalpies 7.16 Combining Reaction Enthalpies: Hess’s Law 7.17 The Heat Output of Reactions 7.18 Standard Enthalpies of Formation 7.19 The Born–Haber Cycle 7.20 Bond Enthalpies 7.21 The Variation of Reaction Enthalpy with Temperature 235 Chapter 7 THERMODYNAMICS: THE FIRST LAW 7.1 Systems In thermodynamics we study how energy is transformed from one form into another and transferred from one place to another. For instance, electricity may be generated in a power station but used a great distance away; food may be digested in your stomach but the energy released may be used in your head. To keep track of changes in energy, we divide the world into two parts. The region in which we are interested, such as a flask of gas, a beaker of acid, a reaction mixture, or a muscle fiber, is called a system (Fig. 7.3). Everything else, such as the water bath in which a reaction mixture may be immersed, is called the surroundings. The surroundings are where we make observations on the energy transferred into or out of the system. The system and the surroundings jointly make up the universe. However, often the only part of the universe significantly affected by a process consists of the sample, a flask, and a water bath; in such cases, which include most of the processes in this book, we need to measure changes only in the sample and its immediate surroundings. A system can be open, closed, or isolated (Fig. 7.4). An open system can exchange both matter and energy with the surroundings. Examples of open systems are automobile engines and the human body. A closed system has a fixed amount of matter, but it can exchange energy with the surroundings. An example of a closed system is a cold pack used for treating athletic injuries. An isolated system has no contact with its surroundings. We can think of an isolated system as sealed inside rigid, thermally insulating walls. A good approximation to an isolated system is a hot liquid inside a sealed vacuum flask. In thermodynamics, the universe consists of a system and its surroundings. An open system can exchange both matter and energy with the surroundings; a closed system can exchange only energy; an isolated system can exchange nothing. 7.2 Work and Energy The most fundamental property in thermodynamics—in the sense that it provides a basis for defining the principal concepts—is work, the process of achieving motion against an opposing force (Section A). All forms of work can be thought of as equivalent to the work of raising a weight against the pull of gravity. The chemical reaction in a battery does work when it pushes an electric current through a circuit. Gas in a cylinder—such as the hot gas mixture in the cylinder of an automobile engine—does work when it expands and pushes back a piston. We can identify whether a process can do work by noting whether, in principle at least, it can be harnessed to raise a weight in the surroundings. The expansion of a gas, for example, can be used to raise a weight 236 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW FIGURE 7.1 Nicolas Leonard Sadi Carnot (1796–1832). FIGURE 7.2 James Prescott Joule (1818–1889). FIGURE 7.3 The system is the sample or reaction mixture in which we are interested. Outside the system are the surroundings. The system plus its surroundings is sometimes called the universe. Surroundings System FIGURE 7.4 We can classify any system according to its interactions with its surroundings. An open system can exchange matter and energy with its surroundings. A closed system can exchange energy but not matter. An isolated system can exchange neither matter nor energy. Open Closed Isolated because the piston can be connected to the weight. An electric current produced by a battery can be used to raise a weight if it is used to power an electric motor. The work required to move an object a certain distance against an opposing force is calculated by multiplying the opposing force by the distance moved against it: Work ϭ opposing force ϫ distance moved (1) As pointed out in Section A, the unit in which work is reported is the joule, J, with 1 J ϭ 1 kgиm2 иsϪ2 . This unit is consistent with Eq. 1, because force is measured in newtons (1 N ϭ 1 kgиmиsϪ2 ), so the units of force ϫ distance are kgиmиsϪ2 ϫ m ϭ kgиm2 иsϪ2 , or J. Energy is the capacity of a system to do work (and ultimately, to lift a weight). If a system can do a lot of work, we say that it possesses a lot of energy. A hot compressed gas can do more work than the same gas after it has expanded and cooled, so we say that it possesses more energy initially. A wound spring can do more work than an unwound spring, so we say that it possesses more energy. When a system does work in the surroundings, its capacity to do work is reduced, so we say that its energy has fallen. If we do work on a system, such as by winding a spring, then we increase its capacity to do work and therefore can say that its energy has increased. In thermodynamics, the total store of energy in a system is called its internal energy, U. We cannot measure the absolute value of the internal energy of a system, because that value includes the energies of all the atoms, their electrons, and the components of their nuclei. The best we can do is to measure changes in internal energy. For instance, if a system does 15 J of work (and no other changes take place), then it has used up some of its store of energy, and we say that its internal energy has fallen by 15 J and write ΔU ϭ Ϫ15 J. Throughout thermodynamics, the symbol ΔX means a difference in a property X: ΔX ϭ Xfinal Ϫ Xinitial (2) A negative value of ΔX, as in ΔU ϭ Ϫ15 J, signifies that the value of X has decreased. A note on good practice: Except in the special cases we shall specify, always show the sign of ΔU (and other ΔX) explicitly, even if it is positive. Thus, if the internal energy increases by 15 J during a change, we write ΔU ϭ ϩ15 J, not simply ΔU ϭ 15 J. When we do work on a system (and, once again, there are no other changes taking place), the internal energy of the system is increased. Compressing a gas inside a thermally insulated container increases its internal energy, because the hot compressed gas can do more work than the uncompressed cooler gas when it pushes out again. Winding a spring transfers energy to the spring: when the spring is fully wound, it can do work as it unwinds. Passing an electric current through a system, as we do when we charge a battery, is another way to do work on a system. We use the symbol w to denote the energy transferred to a system by doing work and, provided that no other type of transfer of energy is taking place, write ΔU ϭ w. When energy is transferred to a system as work, the internal energy of the system increases and w is positive. When energy leaves the system as work, the internal energy of the system decreases and w is negative. For example, if a system does 40 J of work, w ϭ Ϫ40 J and ΔU ϭ Ϫ40 J. Work is the transfer of energy to a system by a process that is equivalent to raising or lowering a weight. For work done on a system, w is positive, for work done by a system w is negative. The internal energy of a system may be changed by doing work: in the absence of other changes, ΔU ‫؍‬ w. 7.3 Expansion Work A system can do two kinds of work. The first type is expansion work, the work arising from a change in the volume of a system. A gas expanding in a cylinder fitted with a piston pushes out against the atmosphere and thus does expansion work. The second type of work is nonexpansion work, work that does not involve a change in volume of 7.3 EXPANSION WORK 237 the system. A chemical reaction in a battery can do nonexpansion work by causing an electrical current to flow, and our bodies do nonexpansion work when we move about. Table 7.1 lists some of the kinds of work that a system can do. First, we consider expansion work. The simplest example is the work done by a system consisting of a gas in a cylinder. The external pressure acting on the outer face of the piston provides the force opposing expansion. We shall assume initially that the external pressure is constant, as when the piston is pressed on by the atmosphere (Fig. 7.5). We need to find how the work done when the system expands through a volume ΔV is related to the external pressure Pex. 238 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW HOW DO WE DO THAT? We relate pressure to the work of expansion against a constant pressure by using the fact that pressure is the force divided by the area to which it is applied: P ϭ F/A (Section 4.2). Therefore, the force opposing expansion is the product of the pressure acting on the outside of the piston, Pex, and the area of the piston, A (F ϭ PexA). The work needed to drive the piston out through a distance d is therefore d F = PexA From work ϭ force ϫ distance, Work ϭ PexA ϫ d However, the product of area and distance moved is equal to the change in volume of the sample: d Area, A Volume = Ad From volume ϭ area ϫ height, A ϫ d ϭ ⌬V External pressure, Pex Change in volume, ⌬V (a) (b) TABLE 7.1 Varieties of work Type of work w Comment Units* expansion ϪPex⌬V Pex is the external pressure Pa ⌬V is the change in volume m3 extension f⌬l f is the tension N ⌬l is the change in length m raising a weight mg⌬h m is the mass kg g is the acceleration of free fall mиsϪ2 ⌬h is the change in height m electrical ␾⌬q ␾ is the electrical potential V ⌬q is the change in charge C surface expansion ␥⌬A ␥ is the surface tension NиmϪ1 ⌬A is the change in area m2 *For work in joules (J). Note that 1 Nиm ϭ 1 J and 1 VиC ϭ 1 J. FIGURE 7.5 A system does work when it expands against an external pressure. (a) A gas in a cylinder with a piston held in place. (b) The piston is released and (provided the pressure of the gas is greater than the external pressure, Pex) the gas expands and pushes out against Pex. The work done is proportional to Pex and the change in volume, ⌬V, that the system undergoes. Therefore, the work done by the expanding gas is Pex⌬V. At this point, we match the signs to our convention. When a system expands, it loses energy as work; so, when ⌬V is positive (an expansion), w is negative. Therefore, 7.3 EXPANSION WORK 239 Internal energy From the sign convention, w ϭ ϪPex⌬V We have deduced that the work done when a system expands by ⌬V against a constant external pressure Pex is w ϭ ϪPex⌬V (3)* This expression applies to all systems. A gas is easiest to visualize, but the expression also applies to an expanding liquid or solid. However, Eq. 3 applies only when the external pressure is constant during the expansion. What does this equation tell us? The minus sign in Eq. 3 tells us that the internal energy of the system decreases because some energy is lost as work when the system expands. The factor Pex tells us that more work has to be done by the system when the external pressure (which is responsible for the opposing force) is high. The factor ⌬V tells us that, for a given external pressure, more work is done when the system expands by a large amount than when it expands only a little. In SI units, the external pressure is expressed in pascals (1 Pa ϭ 1 kgиmϪ1 иsϪ2 , Section 4.2) and the change in volume is expressed in cubic meters (m3 ). The product of 1 Pa and 1 m3 is 1 Paиm3 ϭ 1 kgиmϪ1 иsϪ2 ϫ 1 m3 ϭ 1 kgиm2 иsϪ2 ϭ 1 J Therefore, if we work in pascals and cubic meters, the work is obtained in joules. However, we might have expressed the pressure in atmospheres and the volume in liters. In this case, we may need to convert the answer (in liter-atmospheres) into joules. The conversion factor is obtained by noting that 1 L ϭ 10Ϫ3 m3 and 1 atm ϭ 101 325 Pa exactly; therefore 1 Lиatm ϭ 10Ϫ3 m3 ϫ 101 325 Pa ϭ 101.325 Paиm3 ϭ 101.325 J (exactly) If the external pressure is zero (Pex ϭ 0, a vacuum), it follows from Eq. 3 that w ϭ 0: that is, a system does no expansion work when it expands into a vacuum, because there is no opposing force. You do no work by pushing if there is nothing to push against. Expansion against zero pressure is called free expansion. EXAMPLE 7.1 Calculating the work done when a gas expands Suppose a gas expands by 500. mL (0.500 L) against a pressure of 1.20 atm and no heat is exchanged with the surroundings during the expansion. (a) How much work is done in the expansion? (b) What is the change in internal energy of the system? Anticipate Because work is done by the system, we expect w and therefore ⌬U to be negative, signifying that energy has been lost from the system. PLAN We use Eq. 3 to calculate the work, and then convert liter-atmospheres into joules. What should we assume? That the only energy exchanged with the surroundings is the work of expansion. 240 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW Convert into joules by using 1 Lиatm ϭ 101.325 J. w = -(0.600 Lиatm) * 101.325 J 1 Lиatm = -60.8 J 60.8 JwϪ60.8 J (b) Because no energy is transferred as heat, w ϭ ⌬U. ⌬U ϭ Ϫ60.8 J Evaluate The negative sign in w ϭ Ϫ60.8 J (which we anticipated) means that the internal energy decreases by 60.8 J when the gas expands and the system does 60.8 kJ of work on its surroundings (and there are no other changes). Self-Test 7.1A Water expands when it freezes. How much work does 100. g of water do when it freezes at 0°C and pushes back the metal wall of a pipe that exerts an opposing pressure of 1070 atm? The densities of water and ice at 0°C are 1.00 gиcmϪ3 and 0.92 gиcmϪ3 , respectively. [Answer: w ϭ Ϫ0.9 kJ] Self-Test 7.1B The gases in the four cylinders of an automobile engine expand from 0.22 L to 2.2 L during one ignition cycle. Assuming that the gear train maintains a steady pressure of 9.60 atm on the gases, how much work can the engine do in one cycle? To calculate the work done by a gas that expands against a changing external pressure, we need to specify exactly how we want the pressure to change during the course of the expansion. In particular, we consider the very important case of “reversible” expansion of an ideal gas. In everyday language, a reversible process is one that can take place in either direction. This common usage is refined in science: in thermodynamics, a reversible process is one that can be reversed by an infinitely small change in a variable (an “infinitesimal” change). For example, if the external pressure exactly matches the pressure of the gas in the system, then the piston moves in neither direction. If the external pressure is increased infinitesimally, the piston moves in. If, instead, the external pressure is reduced infinitesimally, the piston moves out. Expansion against an external pressure that differs by a finite (measurable) amount from the pressure of the system is an irreversible process in the sense that an infinitesimal change in the external pressure does not reverse the direction of travel of the piston. For instance, if the pressure of the system is 2.0 atm at some stage of the expansion and the external pressure is 1.0 atm, then a tiny increase in the latter does not convert expansion into compression. Reversible processes are of the greatest importance in thermodynamics because, as we shall see, the work a system can do is greatest in a reversible process. Thinking point: How could you ensure that an electric battery produced an electric current reversibly? The simplest kind of reversible change to consider is the reversible, isothermal (constant temperature) expansion of an ideal gas. We can maintain the same temperature SOLVE 1.20 atm 0.500 L (a) From w ϭ ϪPex⌬V, w ϭ Ϫ(1.20 atm) ϫ (0.500 L) ϭ Ϫ0.600 Lиatm 7.3 EXPANSION WORK 241 by ensuring that the system is in thermal contact with a constant-temperature water bath at all stages of the expansion. In an isothermal expansion, the pressure of the gas falls as it expands (by Boyle’s law); so, to achieve reversible expansion, the external pressure must be reduced in step with the change in volume so that at every stage the external pressure is the same as the pressure of the gas (Fig. 7.6). To calculate the work, we have to take into account the gradual reduction in external pressure and therefore the changing opposing force. External pressure Pressure of confined gas Pressure,P Volume, V HOW DO WE DO THAT? To calculate the work of reversible, isothermal expansion of a gas, we have to use calculus, starting at Eq. 3 written for an infinitesimal change in volume, dV: dw ϭ ϪPexdV Because the external pressure is matched to the pressure, P, of the gas at every stage of a reversible expansion, we write Pex ϭ P and the expression for dw becomes dw ϭ ϪPdV At each stage of the expansion, the pressure of the gas is related to its volume by the ideal gas law, PV ϭ nRT, so we can replace P by nRT/V: From dw ϭ ϪPdV and P ϭ nRT/V, dw = - nRT V dV The total work done is the sum (integral) of these infinitesimal contributions as the volume changes from its initial value to its final value. That is, we have to integrate dw from the initial to the final volume with nRT a constant (because the change is isothermal): Pressure(P) Volume (V) Vinitial |w| Vfinal From w ϭ dw, with nRT a constant, w = -nRT L Vfinal Vinitial dV V = -nRT ln Vfinal Vinitial 1 In the final step we used the standard integral and then ln x – ln y ϭ ln(x/y). We have found that the work of reversible, isothermal expansion of an ideal gas from the volume Vinitial to the volume Vfinal is (4)* where n is the amount of gas molecules (in moles) in the container and T is the temperature. One way to visualize Eq. 4 is to realize that, apart from the sign, the work done by the system as it expands is equal to the area beneath the ideal gas isotherm lying between the initial and the final volumes (Fig. 7.7). What does this equation tell us? For a given initial and final volume, more work is done when the temperature is high than when it is low. For a given volume and amount of molecules, a high temperature corresponds to a high gas pressure, and so the expansion takes place against a stronger opposing force and therefore must do more work. More work is also done if the final volume is very much greater than the initial volume. w = -nRT ln Vfinal Vinitial L dx x = ln x + constant FIGURE 7.6 When a gas expands reversibly, the external pressure is matched to the pressure of the gas at every stage of the expansion. This arrangement (when the steps corresponding to the increase in volume are infinitesimal) achieves maximum work (the area under the curve). FIGURE 7.7 The work done by a system is equal to the area below the curve of the graph of external pressure as a function of volume. The work done on a system is equal to the negative of that area. Area = work done by system Pressure,P Volume, V Vinitial Vfinal If the external pressure were to be increased even infinitesimally at any stage of the expansion, the piston would move in instead of out. Therefore, the work done during a reversible expansion of a gas is the maximum expansion work possible. Thinking point: How could you achieve maximum work from an electric battery? 242 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW EXAMPLE 7.2 Calculating the work of isothermal expansion A piston confines 0.100 mol Ar(g) in a volume of 1.00 L at 25°C. Two experiments are performed. (a) The gas is allowed to expand through an additional 1.00 L against a constant pressure of 1.00 atm. (b) The gas is allowed to expand reversibly and isothermally to the same final volume. Which process does more work? Anticipate Provided the initial and final states are the same, a change carried out reversibly always does more work than a change carried out irreversibly, so we should expect the second path to produce more work and therefore correspond to a more negative w (because more energy is lost from the system). PLAN For expansion against constant external pressure we use Eq. 3 and for reversible, isothermal expansion we use Eq. 4. What should we assume? That the gas is ideal. SOLVE Pressure(P) Path 2 Path 1 1.00 atm 1.00 L 2.00 L Volume (V) (a) Irreversible path: From Eq. 3, w ϭ ϪPex⌬V, and then converting to joules, w ϭ Ϫ(1.00 atm) ϫ (1.00 L) = -1.00 * 1.00 Lиatm * 101.325 J 1 Lиatm = -101 J (b) Reversible path: From Eq, 4, w ϭ ϪnRT ln (Vfinal/Vinitial), ϭ Ϫ172 J Evaluate We see that the gas does more work in the reversible process, as we expected. Self-Test 7.2A A cylinder of volume 2.00 L contains 0.100 mol He(g) at 30°C. Which process does more work on the system, compressing the gas isothermally to 1.00 L with a constant external pressure of 5.00 atm or compressing it reversibly and isothermally to the same final volume? [Answer: Reversible compression] Self-Test 7.2B A cylinder of volume 2.00 L contains 1.00 mol He(g) at 30°C. Which process does more work on the surroundings, allowing the gas to expand isothermally to 4.00 L against a constant external pressure of 1.00 atm or allowing it to expand reversibly and isothermally to the same final volume? The change in internal energy is the same regardless of the path taken between the same initial and final states. However, in an irreversible process some of the potential of the system to do work is wasted because the opposing pressure is less than the maximum possible at each stage of the expansion. The work done by any system on its surroundings during expansion against a constant pressure is calculated from Eq. 3; for a reversible, isothermal expansion of an ideal gas, the work is calculated from Eq. 4. A reversible process is a process that can be reversed by an infinitesimal change in a variable. w = -(0.100 mol) * (8.3145 JиK-1 иmol-1 ) * (298 K) * ln 2.00 L 1.00 L 7.4 Heat The internal energy of a system, its capacity to do work, can also be changed by transferring energy to or from the surroundings as heat. Heat is a familiar term, but in thermodynamics it has a special meaning. In thermodynamics, heat is the energy transferred as a result of a temperature difference. Energy flows as heat from a high-temperature region to a low-temperature region. Therefore, provided that the walls of the system are not thermally insulating, if the system is cooler than its surroundings, energy flows into the system from the surroundings. In the introduction to this chapter we remarked that heat is not a substance and that heat does not flow. What, then, is heat and what is it that is transferred during heating? As described in Section A, what is often called the “thermal energy” of a system is the sum of the potential and kinetic energies arising from the chaotic thermal motion of atoms, ions, and molecules. Molecules in a high temperature region move more vigorously than molecules in a lower temperature region. When the two regions are brought into contact, the energetic molecules in the higher temperature region stimulate the motion of the molecules in the lower temperature regions. As a result, the internal energy of the cooler system increases as that of the hotter system decreases. The “flowing” of energy due to a temperature difference is simply the transfer of the energy of thermal motion, the energy associated with the random motion of molecules. A note on good practice. Be careful not to confuse the terms heat and thermal energy. Heat is energy in transition as a result of a temperature difference. Thermal energy, or better the energy of thermal motion, is the energy associated with the chaotic motion of molecules at temperatures above absolute zero. We write the energy transferred to a system as heat as q. Therefore, when the internal energy of the system is changed by transferring energy as heat (and no other processes take place), ⌬U ϭ q. If energy enters a system as heat, the internal energy of the system increases and q is positive; if energy leaves the system as heat, the internal energy of the system decreases and q is negative. Thus, if 10 J enters the system as heat, we write q ϭ ϩ10 J and (provided no work is done on or by the system) ⌬U ϭ ϩ10 J. Likewise, if 10 J leaves the system as heat, we write q ϭ Ϫ10 J and ⌬U ϭ Ϫ10 J. As these examples show, energy transferred as heat (like any energy) is measured in joules, J. However, a unit still widely used in biochemistry and related fields is the calorie, cal. Originally, 1 cal was the energy needed to raise the temperature of 1 g of water by 1°C. The modern definition is 1 cal ϭ 4.184 J (exactly) This exact relation defines the calorie in terms of the joule; the joule is the fundamental unit. The nutritional calorie, Cal, is actually 1 kilocalorie (kcal), and so it is important to note which unit is being used when assessing the energy content of food. A process that releases heat into the surroundings is called an exothermic process. Most common chemical reactions—and all combustions, such as those that power transport and heating—are exothermic (Fig. 7.8). Less familiar are chemical reactions that absorb heat from the surroundings. A process that absorbs heat is called an endothermic process (Fig. 7.9). A number of common physical processes are endothermic. For instance, vaporization is endothermic, because heat must be supplied to drive molecules of a liquid apart from one another. The dissolution of ammonium nitrate in water is endothermic; in fact, this process is used in instant cold packs for sports injuries. Heat is the transfer of energy as a result of a temperature difference. When energy is transferred as heat and no other processes occur, ⌬U ϭ q. When energy enters a system as heat, q is positive; when energy leaves a system as heat, q is negative. 7.5 The Measurement of Heat The measurement of heat produced or absorbed by a process is used to monitor the change in internal energy of a system. However, before we see how this is done, we have to distinguish between two types of walls between the system and its surroundings. 7.5 THE MEASUREMENT OF HEAT 243 Recall from Section 4.10 that the temperature of a gas is proportional to the mean square speed of its molecules. FIGURE 7.8 The thermite reaction is so exothermic that it melts the metal that it produces and is used to weld railroad tracks together. Here, aluminum metal is reacting with iron(III) oxide, Fe2O3, causing a shower of molten iron sparks. Lab Video 7.8 If the walls are thermally insulating, heat cannot be transferred across them even if there is a temperature difference across them. The walls of a vacuum flask are a good approximation because the vacuum between them does not allow energy to be conducted from one wall to another by molecules and their silvered surfaces cuts down the transfer of energy by radiation. The technical term for a thermally insulating wall is an adiabatic wall (from the Greek words for “not passing through”). A system with adiabatic walls is not necessarily an isolated system: energy may be transferred to or from a system in an adiabatic container as work. In a closed adiabatic system, ⌬U ϭ w. Diathermic walls do permit the transfer of energy as heat. Provided the system does not lose energy as work, an influx of energy through the walls of a diathermic container typically raises the temperature of the system, so monitoring the temperature change is a way to monitor the heat transferred and therefore to infer the change in internal energy. To convert a temperature change into energy, we need to know the heat capacity, C, the ratio of the heat supplied to the rise in temperature produced: (5a) A large heat capacity means that a given supply of heat produces only a small rise in temperature. A small heat capacity means that even a small transfer of energy as heat will produce a large rise in temperature. Once we know the heat capacity, we can measure the change in temperature, ⌬T, of the system and calculate how much heat has been supplied by using Eq. 5a in the form q ϭ C⌬T (5b) Heat capacity is an extensive property: the larger the sample, the more heat is required to raise its temperature by a given amount (Fig. 7.10). It is therefore common to report either the specific heat capacity (often called just “specific heat”), Cs, which is the heat capacity divided by the mass of the sample (Cs ϭ C/m), or the molar heat capacity, Cm, the heat capacity divided by the amount (in moles) of the sample (Cm ϭ C/n). For example, the specific heat capacity of liquid water at room temperature is 4.18 J·(°C)Ϫ1 ·gϪ1 , or 4.18 J·KϪ1 ·gϪ1 , and its molar heat capacity is 75 J·KϪ1 ·molϪ1 . We can calculate the heat capacity of a substance from its mass and its specific heat capacity by using C ϭ m ϫ Cs. If we know the mass of a substance, its specific heat capacity, and the temperature rise it undergoes in a process, then the energy supplied as heat to the substance is q ϭ C⌬T ϭ mCs⌬T (6a) We use a similar expression, C ϭ n ϫ Cm, for the molar heat capacity of a substance and write q ϭ nCm⌬T (6b) These expressions may be rearranged to calculate the specific or molar heat capacity from the measured temperature rise caused by a known quantity of heat. A point to note is that the specific heat capacity of a dilute solution is normally taken to be the same as that of the pure solvent (which is commonly water). Table 7.2 lists the specific and molar heat capacities of some common substances. Thinking point: The molar heat capacity of lead is much greater than that of diamond at room temperature. Can you think of a reason for the difference? Heat capacity = heat supplied temperature rise produced that is, C = q ¢T 244 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW FIGURE 7.9 The endothermic reaction between ammonium thiocyanate, NH4SCN, and barium hydroxide octahydrate, Ba(OH)2·8H2O, absorbs a lot of heat and can cause water vapor in the air to freeze on the outside of the beaker. Lab Video 7.9 Heat Heat FIGURE 7.10 The heat capacity of an object determines the change in its temperature brought about by the quantity of energy transferred as heat: an object with a large heat capacity requires a lot of heat to bring about a given rise in temperature. Heat capacity is an extensive property; so a large object (bottom) has a larger heat capacity than a small object (top) made of the same material. Heat capacities also, in general, depend on temperature. EXAMPLE 7.3 Calculating the heat needed to bring about a rise in temperature Calculate the heat necessary to increase the temperature of (a) 100. g of water, (b) 2.00 mol H2O(l) by 20.°C from room temperature. Anticipate Because the molar mass of water is about 18 gиmolϪ1 , 100 g of water is greater than 2.00 mol H2O, so we expect more heat to be required in (a) than in (b). 7.5 THE MEASUREMENT OF HEAT 245 TABLE 7.2 Specific and Molar Heat Capacities of Common Materials* Material Specific heat capacity (J·(°C)؊1 ·g؊1 ) Molar heat capacity (J·K؊1 ·mol؊1 ) air 1.01 — benzene 1.05 136 brass 0.37 — copper 0.38 33 ethanol 2.42 111 glass (Pyrex) 0.78 — granite 0.80 — marble 0.84 — polyethylene 2.3 — stainless steel 0.51 — water: solid 2.03 37 liquid 4.184 75 vapor 2.01 34 *More values are available in Appendices 2A and 2D; values assume constant pressure. Specific heat capacities commonly use Celsius degrees in their units, whereas molar heat capacities commonly use kelvins. All values except that for ice are for 25°C. (a) From q ϭ mCs⌬T, q = (100. g) * (4.18 JиK-1 иg-1 ) * (20. K) = +8.4 kJ 8.4 kJ 20. K 3.0 kJ 20. K (b) From q ϭ nCm⌬T, q = (2.00 mol) * (75 JиK-1 иmol-1 ) * (20. K) = +3.0 kJ Transfers of energy as heat are measured with a calorimeter, a device in which heat transfer is monitored by recording the change in temperature that it produces, and then using q ϭ Ccal⌬T, where Ccal is the heat capacity of the calorimeter (which is sometimes called the “calorimeter constant”). A calorimeter can be as simple as a thermally PLAN The heat required is given by Eq. 6. In each case, ⌬T ϭ ϩ20. K. What should we assume? That no energy is lost to the container or the surroundings during the heating and that the water is thoroughly mixed, so that it is at the same temperature throughout. SOLVE Evaluate As we anticipated, more heat is needed for (a) than for (b). It will be useful to keep these magnitudes in mind. Self-Test 7.3A Potassium perchlorate, KClO4, is used as an oxidizer in fireworks. Calculate the heat required to raise the temperature of 10.0 g of KClO4 from 25°C to an ignition temperature of 900.°C. The specific heat capacity of KClO4 is 0.8111 J·KϪ1 ·gϪ1 . [Answer: 7.10 kJ] Self-Test 7.3B Calculate the heat necessary to increase the temperature of 3.00 mol CH3CH2OH(l), ethanol, by 15.0°C from room temperature (see Table 7.2). insulated container equipped with a thermometer (Fig. 7.11). A more sophisticated version is a bomb calorimeter (Fig. 7.12). The reaction takes place inside the sturdy sealed metal vessel (the bomb), which is immersed in water, and the rise in temperature of the entire assembly is monitored. Its heat capacity is first measured by supplying a known quantity of heat and noting the resulting rise in temperature. This process is called “calibrating” the calorimeter. 246 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW Thermometer Reaction mixture Stirrer Foamed polystyrene cups FIGURE 7.11 The energy released or absorbed as heat by a reaction at constant pressure can be measured in this simple calorimeter. The outer polystyrene cup acts as an extra layer of insulation to ensure that no heat enters or leaves the inner cup. The quantity of energy released or absorbed as heat is proportional to the change in temperature of the calorimeter. Thermometer Firing leads Oxygen inlet Stirrer Water Sample Oxygen under pressure Bomb FIGURE 7.12 A bomb calorimeter is used to measure heat transfers at constant volume. The sample in the central rigid container called the bomb is ignited electrically with a fuse wire. Once combustion has begun, energy released as heat spreads through the walls of the bomb into the water. The heat released is proportional to the temperature change of the entire assembly. EXAMPLE 7.4 Determining the internal energy change accompanying a reaction A constant-volume calorimeter was calibrated by carrying out a reaction known to release 1.78 kJ of heat in 0.100 L of solution in the calorimeter, resulting in a temperature rise of 3.65°C. Next, 50. mL of 0.20 M HCl(aq) and 50. mL of 0.20 M NaOH(aq) were mixed in the same calorimeter and the temperature rose by 1.26°C. What is the change in the internal energy of the neutralization reaction? Anticipate The rise in temperature in the actual experiment is about one-third the rise in the calibration, so we can suspect that the heat released by the reaction is about one-third of 1.78 kJ, or about 0.6 kJ. PLAN The calculation has two steps. First, calibrate the calorimeter by calculating its heat capacity with data from the first reaction, Ccal ϭ qcal͞⌬T. Second, use that value of Ccal to find the energy change of the neutralization reaction. For the second step, use the same equation rearranged to qcal ϭ Ccal⌬T, but with ⌬T now the change in temperature observed during the reaction. Note that the calorimeter contains the same volume of liquid in both cases. Finally, relate the energy transferred as heat to the change in internal energy by using ⌬U ϭ q and decide on the sign of ⌬U by judging whether the system loses or gains energy. What should we assume? Because dilute aqueous solutions have approximately the same heat capacities as pure water, assume that the heat capacity for the calorimeter during the reaction is the same as in the calibration. SOLVE Calibration: From Ccal ϭ qcal/⌬T, Ccal = 1.78 kJ 3.65°C = 1.78 3.65 kJи(°C)-1 1.78 kJ 3.65ЊC Application: From qcal ϭ Ccal⌬T, qcal = a 1.78 3.65 kJи(°C)-1 b * (1.26°C) = 0.614 kJ 0.614 kJ 1.26ЊC Evaluate Because the temperature rises, the process is exothermic, energy leaves the system as heat, and ⌬U ϭ Ϫ0.614 kJ, in agreement with our expectation. Self-Test 7.4A A small piece of calcium carbonate was placed in the same calorimeter, and 0.100 L of dilute hydrochloric acid was poured over it. The temperature of the calorimeter rose by 3.57°C. What is the value of ⌬U for the reaction of the hydrochloric acid with the calcium carbonate? [Answer: Ϫ1.74 kJ] Self-Test 7.4B A calorimeter was calibrated by mixing two aqueous solutions together, each of volume 0.100 L. The heat output of the reaction that took place was known to be 4.16 kJ, and the temperature of the calorimeter rose by 3.24°C. Calculate the heat capacity of this calorimeter when it contains 0.200 L of water. The heat capacity of an object is the ratio of the heat supplied to the temperature rise produced. Heat transfers are measured by using a calibrated calorimeter. 7.6 The First Law So far, we have considered the transfer of energy as work or heat separately. However, in many processes, the internal energy changes as a result of both work and heat. For example, when a spark ignites the mixture of gasoline vapor and air in the engine of a moving automobile, the vapor burns and expands, transferring energy to its surroundings as both work and heat. In general, the change in the internal energy of a closed system is the net result of both kinds of transfers; so we write ⌬U ϭ q ϩ w (7)* This expression summarizes the experimental fact that both heat and work are means of transferring energy and thereby changing the internal energy of a system. The fundamental molecular difference between work and heat is that when energy is transferred as work, the system moves molecules in the surroundings in a definite direction (think of the atoms of a rising weight all moving upward simultaneously), but during the transfer of energy as heat, the molecules of the surroundings are moved in random directions (think of the atoms of a hot object jostling the atoms of the surroundings into more vigorous random motion, Fig. 7.13). Self-Test 7.5A An automobile engine does 520. kJ of work and loses 220. kJ of energy as heat. What is the change in the internal energy of the engine? Treat the engine, fuel, and exhaust gases as a closed system. [Answer: Ϫ740. kJ] Self-Test 7.5B A system was heated by using 300. J of heat, yet it was found that its internal energy decreased by 150. J (so ⌬U ϭ Ϫ150. J). Calculate w. Was work done on the system or did the system do work? It is an experimental fact—a fact supported by thousands of experiments—that we cannot use a system to do work, leave it isolated for a while, and then return to it to find its internal energy restored to its original value and ready to provide the same amount of work again. Despite the great amount of effort that has been spent trying to build a “perpetual motion machine,” a device that would be an exception to this rule by producing work without using fuel, no one has ever succeeded in building one. In other words, Eq. 7 is a complete statement of how changes in internal energy may be achieved in a closed system of constant composition: the only way to change the internal energy of such a system is to transfer energy into it as heat or as work. If the system is isolated, then even that ability is eliminated, and the internal energy cannot change at all. This conclusion is known as the first law of thermodynamics, which states: The internal energy of an isolated system is constant. According to the first law, if an isolated system has a certain internal energy at one instant and we inspect it again later, then we shall find that it still has exactly the same internal energy, no matter how much time has passed. Alternatively, if we allow the system to go through a series of changes but ensure that it is restored to its original state, then we would find that it has the same internal energy as it had originally. We summarize these statements by saying that the internal energy is a state function, a property that depends only on the current state of the system and is independent of how that state was prepared. The pressure, volume, temperature, and density of a system are also state functions. The importance of state functions in thermodynamics is that, because a state function depends only on the current state of the system, then if the system is changed from one state to another, the change in a state function is independent of how that change was brought about. A state function is like altitude on a mountain (Fig. 7.14). We may 7.6 THE FIRST LAW 247 FIGURE 7.13 On an atomic scale, the transfer of energy as heat can be pictured as a process in which the vigorous thermal motion of atoms in the system jostle the less vigorously moving atoms of the surroundings and transfer some of their energy to them. The double-headed arrows represent the motion of the atoms; the large pink arrows represent the direction of heat transfer. The first law is closely related to the conservation of energy (Section A) but goes beyond it: the concept of heat does not apply to the single particles treated in classical mechanics. take any number of different paths between two huts on the mountain, but the change in altitude between the two huts is the same regardless of the path. Similarly, if we took 100 g of water at 25°C and raised its temperature to 60°C, its internal energy would change by a certain amount. However, if we took the same mass of water at 25°C and heated it to boiling, vaporized it, condensed the vapor, and then allowed the water to cool to 60°C, the net change in the internal energy of the water would be exactly the same as if we had heated it to 60°C in one step. The work done by a system is not a state function: it depends on how the change is brought about. For example, we could let a gas at 25°C expand at constant temperature (by keeping it in touch with a water bath) through 100 cm3 by two different paths. In the first experiment, the gas might push on a piston and do a certain amount of work against an external force. In the second experiment, the gas might push a piston into a vacuum; it then does no work, because there is no external opposing force (Fig. 7.15). The change in the state of the gas is the same in each case, but the work done by the system is different: in the first case, w is nonzero; in the second case, w ϭ 0. Indeed, even everyday language suggests that work is not a state function, because we never speak of a system as possessing a certain amount of “work.” Similarly, heat is not a state function. The energy transferred as heat during a change in the state of a system depends on how the change is brought about. For example, suppose we want to raise the temperature of 100 g of water from 25°C to 30°C. One way to raise the temperature would be to supply energy as heat by using an electric heater. The heat required can be calculated from the specific heat capacity of water: q ϭ (4.18 J·°CϪ1 ·gϪ1 ) ϫ (100 g) ϫ (5°C) ϭ ϩ2 kJ. Another way to raise the temperature would be to stir the water vigorously with paddles until 2 kJ of work has been supplied. In the latter case, all the energy required is transferred as work; none is supplied as heat. So, in the first case, q ϭ ϩ2 kJ; and, in the second case, q ϭ 0. However, the final state of the system is the same in each case. Because heat is not a state function, we should not speak of a system as possessing a certain amount of “heat.” Because internal energy is a state function, we can choose any convenient path between the given initial and final states of a system and calculate ⌬U for that path. The result will have the same value of ⌬U as the actual path between the same two states, even if the actual path is so complicated that ⌬U cannot be calculated directly. In some cases we can use our molecular insight to give the change in internal energy for a process without doing a calculation. For instance, when an ideal gas expands isothermally, its molecules continue to move at the same average speed, so their total kinetic energy remains the same. Because there are no forces between the molecules, their total potential energy also remains the same even though their average separation has increased. Because neither the total kinetic energy nor the total potential energy changes, the internal energy of the gas is unchanged too. That is, ⌬U ϭ 0 for the isothermal expansion (or compression) of an ideal gas. It follows that when a sample of an ideal gas changes by any path between two states, then provided the initial and final states have the same temperature we know at once that ⌬U ϭ 0. 248 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW AltitudeInternalenergy B A A B ⌬U h (a) (b) FIGURE 7.14 (a) The altitude of a location on a mountain is like a thermodynamic state function: no matter what route is taken between points A and B, the net change in altitude is the same. (b) Internal energy is a state function: if a system changes from state A to state B (as depicted diagrammatically here), the net change in internal energy is the same whatever the route—the sequence of chemical or physical changes—between the two states. Heat Heat No heat input Vacuum Vacuum Work done No work done External pressure, Pex (b) (a) FIGURE 7.15 Two different paths between the same initial and final states of an ideal gas. (a) The gas does work as it expands isothermally against an applied, matching pressure. Because energy flows in as heat to restore the energy lost as work, the temperature remains constant. (b) The gas does no work as it expands isothermally into a vacuum. Because internal energy is a state function, the change in internal energy is the same for both processes: ⌬U ϭ 0 for the isothermal expansion of an ideal gas on any path. However, the exchange of heat and work is different in each case. 7.6 THE FIRST LAW 249 EXAMPLE 7.5 Calculating the work, heat, and change in internal energy for the expansion of an ideal gas Suppose that 1.00 mol of ideal gas molecules maintained at 292 K and 3.00 atm expands from 8.00 L to 20.00 L and a final pressure of 1.20 atm by two different paths. (a) Path A is an isothermal, reversible expansion. (b) Path B has two parts. In step 1, the gas is cooled at constant volume until its pressure has fallen to 1.20 atm. In step 2, it is heated and allowed to expand against a constant pressure of 1.20 atm until its volume is 20.00 L and T ϭ 292 K. Determine for each path the work done, the heat transferred, and the change in internal energy (w, q, and ⌬U). Anticipate Because internal energy is a state function and because the initial and final states are the same in both paths, ⌬U for path B is the same as for path A. Because the process is isothermal, the change in internal energy (of this ideal gas) is zero. We should expect the value of w to be less negative (less energy lost as work) in the irreversible path and therefore q to be less positive as less heat is needed to maintain the temperature. PLAN It is a good idea to begin by sketching a plot of each process (Fig. 7.16). (a) For an isothermal, reversible expansion, we use Eq. 4 to calculate w. (b) In step 1, the volume does not change, and so no work is done (w ϭ 0). Step 2 is a constant-pressure process, so we use Eq. 3 to calculate w. Because ⌬U ϭ 0 for an isothermal expansion of an ideal gas, in each case, we find q for the overall path from ⌬U ϭ q ϩ w with ⌬U ϭ 0. Use 1 L·atm ϭ 101.325 J to convert liter-atmospheres into joules. SOLVE Volume, V 8.00 L 20.00 L Volume, V 8.00 L 20.00 L 3.00 atm 1.20 atm Pressure,Pex Pressure,Pex Path A Path B w = −area = −2.22 kJ q = −w = +2.22 kJ w = −area = −1.46 kJ q = −w = +1.46 kJ 3.00 atm 1.20 atm (a) (b) (a) From w ϭ ϪnRT ln(Vfinal͞Vinitial), = -2.22 * 103 J = -2.22 kJ * ln 20.00 L 8.0 L w = -(1.00 mol) * (8.3145 JиK-1 иmol-1 ) * (292 K) 2.22 kJ Pressure(P) Volume (V) 8.00 L 20.00 L 3.00 atm 1.20 atm FIGURE 7.16 (a) On the reversible path, the work done in Example 7.5 is relatively large (w ϭ –2.22 kJ); because the change in internal energy is zero, heat flows in to maintain constant temperature and constant internal energy. Therefore, q ϭ ϩ2.22 kJ. (b) On the irreversible path, the work done is also equal to the negative of the area beneath the curve and, for this path, is relatively small (w ϭ –1.46 kJ). The net heat input, allowing for outflow of heat in the cooling step and influx of heat in the expansion, is q ϭ ϩ1.46 kJ. From ⌬U ϭ q ϩ w ϭ 0, q ϭ Ϫw ϭ ϩ2.22 kJ 2.22 kJ 2.22 kJ ⌬U = 0 w q Living Graph 7.16 250 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW Pressure(P) Volume (V) 3.00 atm 1.20 atm (b) Step 1 Cool at constant volume, so no work is done. w ϭ 0 Pressure(P) Volume (V) 1.46 kJ 8.00 L 20.00 L Step 2 From w ϭ ϪPex⌬V, w ϭ Ϫ(1.20 atm) ϫ (20.00 Ϫ 8.00) L ϭ Ϫ14.4 Lиatm Convert liter-atmospheres to joules. w = -(14.4 Lиatm) * a 101.325 J 1 Lиatm b = -1.46 * 103 J = -1.46 kJ 1.46 kJ 1.46 kJ ⌬U = 0 w q From ⌬U ϭ q ϩ w ϭ 0, q ϭ Ϫw ϭ ϩ1.46 kJ Pressure(P) Volume (V) Ϫ1.46 kJ 0 Calculate total work for path B. w ϭ 0 ϩ (Ϫ1.46) kJ ϭ Ϫ1.46 kJ In summary, q w ⌬U For the reversible path: ϩ2.22 kJ Ϫ2.22 kJ 0 For the irreversible path: ϩ1.46 kJ Ϫ1.46 kJ 0 Evaluate As expected, less work is done in the irreversible path and less energy has to enter the system as heat to maintain its temperature. Self-Test 7.6A Suppose that 2.00 mol CO2 at 2.00 atm and 300. K is compressed isothermally and reversibly to half its original volume before being used to produce soda water. Calculate w, q, and ⌬U by treating the CO2 as an ideal gas. [Answer: w ϭ ϩ3.46 kJ, q ϭ Ϫ3.46 kJ, ⌬U ϭ 0] Self-Test 7.6B Suppose that 1.00 kJ of energy is transferred as heat to oxygen in a cylinder fitted with a piston; the external pressure is 2.00 atm. The oxygen expands from 1.00 L to 3.00 L against this constant pressure. Calculate w and ⌬U for the entire process by treating the O2 as an ideal gas. The first law of thermodynamics states that the internal energy of an isolated system is constant. A state function depends only on the current state of a system. The change in a state function between two states is independent of the path between them. Internal energy is a state function but work and heat are not. 7.7 A Molecular Interlude: The Origin of Internal Energy Internal energy is energy stored in a system as kinetic energy and potential energy. We saw in Section A that kinetic energy is energy due to motion and that the faster a molecule travels, the greater is its translational kinetic energy. When we heat a gas, the average speed of the molecules increases. When we do work on a gas in an insulated container, the molecules are also stimulated to move faster. The increase in the average speed of the gas molecules corresponds to an increase in the total kinetic energy of the molecules and therefore to an increase in the internal energy of the gas. We have already seen (in Section 4.10) that the temperature is an indication of the average speed of gas molecules, and so this increase in internal energy also corresponds to an increase in temperature. It is always the case that a system at high temperature has a greater internal energy than the same system at a lower temperature. Molecules in a gas can move in a variety of different ways, and each mode of motion can act as a store of energy (Fig. 7.17). The energy of an atom or molecule due to its motion through space is called its translational energy (this energy is kinetic energy). Molecules (in contrast to atoms) can also store energy as rotational energy, the energy due to their rotational motion (this energy is also kinetic). A third store of energy for molecules is in the oscillation of their atoms relative to one another: this contribution is called vibrational energy and is the sum of kinetic and potential contributions. Most molecules are not vibrationally excited at room temperature, and so we ignore that mode for now. The contribution of translational and rotational motion to the internal energy can be estimated from the temperature. 7.7 A MOLECULAR INTERLUDE: THE ORIGIN OF INTERNAL ENERGY 251 (a) (b) (c) kT kT kT kT kT kT kT kT 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 FIGURE 7.17 The translational and rotational modes of atoms and molecules and the corresponding average energies of each mode at a temperature T. (a) An atom or molecule can undergo translational motion in three dimensions. (b) A linear molecule can also rotate about two axes perpendicular to the line of atoms. (c) A nonlinear molecule can rotate about three perpendicular axes. HOW DO WE DO THAT? First, we need to know that a “quadratic contribution” to the energy is an expression that depends on the square of a velocity or a displacement, as in mv2 for translational kinetic energy. The equipartition theorem (which we shall not derive here) then states that the average value of each quadratic contribution to the energy of a molecule in a sample at a temperature T is equal to kT. The name “equipartition” simply means that the available energy is shared (partitioned) equally over all the available modes. In this expression, k is Boltzmann’s constant, a fundamental constant with the value 1.381 ϫ 10Ϫ23 J·KϪ1 . Boltzmann’s constant is related to the gas constant (8.314 J·K–1 ·mol–1 ) by R ϭ NAk, where NA is Avogadro’s constant. The equipartition theorem is a result from classical mechanics; so we can use it for translational and rotational motion of molecules at room temperature and above, where quantization is unimportant. We cannot use it reliably for vibrational motion, except at very high temperatures, because at ordinary temperatures only the lowest vibrational quantum state is occupied and the effects of quantization are very important. The following remarks therefore apply only to translational and rotational motion. A molecule can move through space along any of three dimensions, so it has three translational modes of motion, each one giving a quadratic contribution to the energy. It follows from the equipartition theorem that the average translational kinetic energy of a molecule in a sample at a temperature T is 3 ϫ kT ϭ kT. The contribution to the molar internal energy (the energy per mole of molecules, Um) is therefore NA times this value, or Because RT ϭ 2.48 kJ·molϪ1 at 25°C, the translational motion of gas molecules contributes ϫ 2.48 kJ mol–1 to the internal energy of the sample at 25°C. Apart from the energy arising from the internal structures of the atoms themselves, this is the only motional contribution to the internal energy of a monatomic gas, such as argon or any other noble gas. A linear molecule, such as any diatomic molecule, carbon dioxide, and ethyne (acetylene, HC CH), can rotate about two axes perpendicular to the line of atoms, and so it‚ и3 2 Um(translation) = 3 2 NAkT = 3 2 RT 3 2 1 2 1 2 1 2 has two rotational modes of motion. Its average rotational energy is therefore 2 ϫ kT and the contribution to the molar internal energy is NA times this value: Um(rotation, linear) ϭ NAkT ϭ RT or about 2.48 kJ·molϪ1 at 25°C. The total motional contribution to the internal energy of a gas of linear molecules is the sum of the translational and rotational contributions, or RT, which corresponds to 6.20 kJ·molϪ1 at 25°C. A nonlinear molecule, such as water, methane, or benzene, can rotate about any of three perpendicular axes, and so it has three rotational modes of motion. The average rotational energy of such a molecule is therefore 3 ϫ kT ϭ kT. The contribution of rotation to the molar internal energy of a gas of nonlinear molecules is therefore Um(rotation, nonlinear) ϭ RT At 25°C, the contribution of rotation to the energy is 3.72 kJ·molϪ1 (the same as for the translational motion), and the total motional contribution for nonlinear molecules is therefore 3RT, or about 7.44 kJ·molϪ1 at 25°C. We have shown that the contribution to the molar internal energy of a monatomic ideal gas (such as argon) that arises from molecular motion is RT. We can conclude that if the gas is heated through ⌬T, then the change in its molar internal energy, ⌬Um, is ⌬Um ϭ R⌬T. For instance, if the gas is heated from 20.°C to 100.°C (so ⌬T ϭ ϩ80. K), then its molar internal energy increases by ϫ (8.314 J·KϪ1 ·molϪ1 ) ϫ (80. K), or 1.0 kJ·molϪ1 . Internal energy is stored as molecular kinetic and potential energy. The equipartition theorem can be used to estimate the translational and rotational contributions to the internal energy of an ideal gas. The vibrational contribution to the energy is insignificant at ordinary temperatures. ENTHALPY If the system has rigid walls, its volume remains the same even though other changes may take place, so it does no expansion work. Suppose also that it does no nonexpansion work (for instance, it is not an electric battery driving an electric motor). Then we can set w ϭ 0 in Eq. 7 (⌬U ϭ w ϩ q) and obtain At constant volume and no nonexpansion work: ⌬U ϭ q (8)* That is, in such a system, the change in the internal energy of the system is equal to the energy supplied to it as heat and we can monitor changes in internal energy simply by monitoring the flow of energy as heat into or out of the system. In chemistry, though, we are more concerned with heat transfers at constant pressure: most chemical reactions take place in containers open to the atmosphere and therefore take place at a constant pressure of about 1 atm. Such systems are free to expand or contract. If a gas is evolved, the expanding gas needs to drive back the surrounding atmosphere to make room for itself. Work is done, even though there is no actual piston. For example, if in some process we supply 100 J of heat to a system (q ϭ ϩ100 J) and the system does 20 J of work (w ϭ Ϫ20 J) as it expands at constant pressure, the internal energy of the system rises by only 80 J. We need another state function, one that will allow us to keep track of energy changes at constant pressure by taking into account automatically losses of energy as expansion work. 7.8 Heat Transfers at Constant Pressure The state function that allows us to keep track of energy changes at constant pressure is called the enthalpy, H: H ϭ U ϩ PV (9)* where U, P, and V are the internal energy, pressure, and volume of the system. We can see that enthalpy is a state function by noting that U (from the first law), P, and V are 3 2 3 2 3 2 3 2 3 2 1 2 5 2 1 2 252 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.8 HEAT TRANSFERS AT CONSTANT PRESSURE 253 HOW DO WE DO THAT? Consider a process at constant pressure for which the change in internal energy is ⌬U and the change in volume is ⌬V. It then follows from the definition of enthalpy in Eq. 9 that the change in enthalpy is At constant pressure: ⌬H ϭ ⌬U ϩ P⌬V (10) Now we use ⌬U ϭ q ϩ w, where q is the energy supplied to the system as heat and w is the energy supplied as work. Therefore, ⌬H ϭ q ϩ w ϩ P⌬V Next, suppose that the system can do no work other than expansion work. In that case, we can use Eq. 3 (w ϭ ϪPex⌬V) to write ⌬H ϭ q Ϫ Pex⌬V ϩ P⌬V Finally, because the system is open to the atmosphere, the pressure of the system is the same as the external pressure; so Pex ϭ P, and the last two terms cancel to leave ⌬H ϭ q. We have shown that for a system that can do work only by expansion against a constant pressure, At constant pressure, and with no nonexpansion work: ⌬H ϭ q (11)* The implication of this equation is that, because chemical reactions typically take place at constant pressure in vessels open to the atmosphere, the heat that they release or require can be equated to the change in enthalpy of the system. It follows that if we study a reaction in a calorimeter that is open to the atmosphere (such as that depicted in Fig. 7.11), then the measurement of its temperature rise gives us the enthalpy change that accompanies the reaction. For instance, if a reaction releases 1.25 kJ of heat in this kind of calorimeter, then we can write ⌬H ϭ q ϭ Ϫ1.25 kJ. It is important to realize that the enthalpy is not a measure of the energy that a system possesses in the same fundamental sense as the internal energy. It is really an accounting device that accounts for the effects of allowing the volume to change during heat transactions at constant pressure. When we transfer energy to a constant-pressure system as heat, the enthalpy of the system increases by that amount. When energy leaves a constant-pressure system as heat, the enthalpy of the system decreases by that amount. For example, the formation of zinc iodide from its elements is an exothermic reaction that (at constant pressure) releases 208 kJ of heat to the surroundings for each mole of ZnI2 formed: Zn(s) ϩ I2(s) ZnI2(s) We can therefore report that ⌬H ϭ Ϫ208 kJ because the enthalpy of the reaction mixture decreases by 208 kJ in this reaction (Fig. 7.18). An endothermic process absorbs heat, and so when ammonium nitrate dissolves in water the enthalpy of the system increases (Fig. 7.19). Note that ⌬H Ͻ 0 for exothermic reactions, whereas ⌬H Ͼ 0 for endothermic reactions. Self-Test 7.7A In an exothermic reaction at constant pressure, 50. kJ of energy left the system as heat and 20. kJ of energy left the system as expansion work. What are the values of (a) ⌬H and (b) ⌬U for this process? [Answer: (a) Ϫ50. kJ; (b) Ϫ70. kJ] Self-Test 7.7B In an endothermic reaction at constant pressure, 30. kJ of energy entered the system as heat. The products took up less volume than the reactants, and 40. kJ of energy entered the system as work as the outside atmosphere pressed down on it. What are the values of (a) ⌬H and (b) ⌬U for this process? ¡ Enthalpy Energy as heat Enthalpy 208 kJ 208 kJ FIGURE 7.18 The enthalpy of a system is like a measure of the height of water in a reservoir. When an exothermic reaction releases 208 kJ of heat at constant pressure, the “reservoir” falls by 208 kJ and ⌬H ϭ –208 kJ. Enthalpy Enthalpy Energy as heat 100 kJ 100 kJ FIGURE 7.19 If an endothermic reaction absorbs 100 kJ of heat at constant pressure, the height of the enthalpy “reservoir” rises by 100 kJ and ⌬H ϭ ϩ100 kJ. all state functions, and so H ϭ U ϩ PV must be a state function, too. What we now need to show is that it follows from this definition that a change in the enthalpy of a system is equal to the heat released or absorbed at constant pressure. The change in enthalpy of a system is equal to the heat supplied to the system at constant pressure. For an endothermic process, ⌬H Ͼ 0; for an exothermic process, ⌬H Ͻ 0. 7.9 Heat Capacities at Constant Volume and Constant Pressure As explained in Section 7.5, the heat capacity C is the constant of proportionality between the heat supplied to a substance and the temperature rise that results (q ϭ C⌬T). However, the rise in temperature and therefore the heat capacity depend on the conditions under which the heating takes place because, at constant pressure, some of the heat is used to do expansion work rather than to raise the temperature of the system. We need to refine our definition of heat capacity. Because heat transferred at constant volume can be identified with the change in internal energy, ⌬U, we can combine Eq. 8 with C ϭ q/⌬T and define the heat capacity at constant volume, CV, as (12a) Similarly, because heat transferred at constant pressure can be identified with the change in enthalpy, ⌬H, we can define the heat capacity at constant pressure, CP, as (12b) The corresponding molar heat capacities are these quantities divided by the amount of substance and are denoted CV,m and CP,m. Thinking point: Which would you expect to be larger, CV,m or CP,m? The constant-volume and constant-pressure heat capacities of a solid substance are similar; the same is true of a liquid but not of a gas. The difference is a reflection of the fact that gases expand much more than solids and liquids when they are heated, so more energy is lost as work when a gas is heated at constant pressure than when a solid or a liquid is heated. We can use the definition of enthalpy and the ideal gas law to find a simple quantitative relation between CP and CV for an ideal gas. CP = ¢H ¢T CV = ¢U ¢T 254 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW HOW DO WE DO THAT? For an ideal gas, the PV in the definition of enthalpy, H ϭ U ϩ PV, can be replaced by nRT, and so H ϭ U ϩ nRT. When a sample of an ideal gas is heated, the enthalpy, internal energy, and temperature all change, and it follows that ⌬H ϭ ⌬U ϩ nR⌬T The heat capacity at constant pressure can therefore be expressed as To obtain the relation between the two molar heat capacities, we divide this expression by n. We have shown that the two molar heat capacities of an ideal gas are related by CP,m ϭ CV,m ϩ R (13)* As an example, the molar constant-volume heat capacity of argon is 12.8 J·KϪ1 ·molϪ1 , and so the corresponding constant-pressure value is 12.8 ϩ 8.3 J·KϪ1 ·molϪ1 ϭ 21.1 J·KϪ1 ·molϪ1 , a difference of 65%. The heat capacity at constant pressure is greater than that at constant volume because at constant pressure not all the heat supplied is used to raise the temperature: some returns to the surroundings as expansion CP = ¢H ¢T = ¢U + nR¢T ¢T = ¢U ¢T + nR = CV + nR work and C ϭ q/⌬T is larger (because ⌬T is smaller) than at constant volume (when all the energy remains inside the system). The molar heat capacity of an ideal gas at constant pressure is greater than that at constant volume; the two quantities are related by Eq. 13. 7.10 A Molecular Interlude: The Origin of the Heat Capacities of Gases We can see how the values of heat capacities depend on molecular properties by using the relations in Section 7.7 and the equipartition theorem. We start with a simple system, a monatomic ideal gas such as argon. We saw in Section 7.7 that the molar internal energy of a monatomic ideal gas at a temperature T is RT and that the change in molar internal energy when the temperature is changed by ⌬T is ⌬Um ϭ R⌬T. It follows from Eq. 12a that the molar heat capacity at constant volume is or about 12.5 J·KϪ1 ·molϪ1 , in agreement with the value found experimentally. Note that the molar heat capacity of a monatomic ideal gas is independent of temperature and pressure. From Eq. 13 (CP,m ϭ CV,m ϩ R), the molar heat capacity of an ideal gas at constant pressure is CP,m ϭ The molar heat capacities of gases composed of molecules (as distinct from atoms) are higher than those of monatomic gases because the molecules can store energy as rotational kinetic energy as well as translational kinetic energy. We saw in Section 7.7 that the rotational motion of linear molecules contributes another RT to the molar internal energy: For a linear molecule: For nonlinear molecules, the rotational contribution is , for a total (rotational ϩ translational) contribution of 3RT. Therefore, we have the following expressions: Atoms Linear molecules Nonlinear molecules CV,m 3R CP,m 4R (In each case, CP,m has been calculated from CP,m ϭ CV,m ϩ R.) Note that the molar heat capacity increases with molecular complexity. The molar heat capacity of nonlinear molecules is higher than that of linear molecules because nonlinear molecules can rotate about three rather than only two axes (recall Fig. 7.17). The graph in Fig. 7.20 shows how CV,m for iodine vapor, I2(g), varies with temperature. At very low temperatures CV,m ϭ , but rises to as molecular rotation takes place. At still higher temperatures, molecular vibrations start to absorb energy and the heat capacity rises toward . At 298 K, the experimental value is equivalent to 3.4R.7 2R 5 2R3 2R 7 2R5 2R 5 2R3 2R 3 2RT CV,m = ¢Um ¢T = 3 2R¢T + RT ¢T = 5 2R 3 2R + R = 5 2R. For a monatomic gas: CV,m = ¢Um ¢T = 3 2R¢T ¢T = 3 2R 3 2 3 2 7.10 A MOLECULAR INTERLUDE: THE ORIGIN OF THE HEAT CAPACITIES OF GASES 255 3R 2R R Molarheatcapacity,CV,m Translation Rotation Vibration Dissociation Translation of 2 I atoms 0.1 K 310 K Temperature 0 FIGURE 7.20 Variation in the molar heat capacity of iodine vapor at constant volume. The translational motion of the gaseous molecules contributes to the heat capacity even at very low temperatures. As the temperature rises past 0.05 K, rotation makes a significant contribution, but vibrations of the molecule contribute only at high temperatures (above about 310 K; for most other molecules the temperature must be much higher). When the molecules dissociate, the heat capacity becomes very large during dissociation, but then settles down to a value characteristic of 2 mol I atoms undergoing only translational motion. EXAMPLE 7.6 Calculating the energy changes when heating an ideal gas Calculate the final temperature and the change in internal energy when 500. J of energy is transferred as heat to 0.900 mol O2(g) at 298 K and 1.00 atm at (a) constant volume; (b) constant pressure. Treat the gas as ideal. Anticipate We expect the temperature to rise more as a result of heating at constant volume than at constant pressure because at constant pressure some of the energy is used to expand the system. PLAN Oxygen is a linear molecule and its heat capacities can be estimated from the equipartition theorem; then we can use q ϭC⌬T, with C ϭ nCm, to find the final temperature. The internal energy change at constant volume is equal to the heat supplied. At constant pressure, find the internal energy change by regarding the process as taking place in two steps: heating to the final temperature at constant volume, followed by isothermal expansion. (b) To find ⌬U for heating at constant pressure, find the final temperature, then break down the overall process into two steps (heating at constant volume to the final temperature, then allowing the gas to expand isothermally): 256 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW R1 2 R1 2 R1 2 R1 2 R1 2 From CV,m ϭ and CP,m ϭ CV,m ϩ R, CV,m ϭ (8.3145 JиKϪ1 иmolϪ1 ) ϭ 20.79 JиKϪ1 иmolϪ1 CP,m ϭ (8.3145 JиKϪ1 иmolϪ1 ) ϭ 29.10 JиKϪ1 иmolϪ17 2 5 2 5 2R 500 J 26.7 K (a) From ⌬T ϭ q/nCV,m, ¢T = 500. J (0.900 mol) * (20.79 JиK-1 иmol-1 ) = +26.7 K Find the final temperature. T ϭ 298 ϩ 26.7 K ϭ 325 K, or 52°C 500 J ⌬U = ϩ500 J q From ⌬U ϭ q at constant volume, ⌬U ϭ ϩ500. J 19.1 K 500 J From ⌬T ϭ q/nCP,m, ¢T = 500. J (0.900 mol) * (29.10 JиK-1 иmol-1 ) = +19.1 K Find the final temperature. T ϭ 298 ϩ 19.1 K ϭ 317 K, or 44°C 19.1 K 317 K 357 J ⌬U = ϩ357 J q Heat: Transfer enough energy at constant volume to raise the temperature to its final value (317 K), and use ⌬U ϭ q. ⌬U ϭ q ϭ (0.900 mol) ϫ (20.79 JиKϪ1 иmolϪ1 ) ϫ (19.1 K) ϭ ϩ357 J What should we assume? That oxygen behaves as an ideal gas and that there is no vibrational contribution to the heat capacity. SOLVE Evaluate The overall change is smaller than for the constant-volume case, as predicted. Self-Test 7.8A Calculate the final temperature and the change in internal energy when 500. J of energy is transferred as heat to 0.900 mol Ne(g) at 298 K and 1.00 atm (a) at constant volume; (b) at constant pressure. Treat the gas as ideal. [Answer: (a) 343 K, 500. J; (b) 325 K, 300. J] Self-Test 7.8B Calculate the final temperature and the change in internal energy when 1.20 kJ of energy is transferred as heat to 1.00 mol H2(g) at 298 K and 1.00 atm (a) at constant volume; (b) at constant pressure. Treat the gas as ideal. Rotation requires energy and leads to higher heat capacities for complex molecules; the equipartition theorem can be used to estimate the molar heat capacities of gas-phase molecules. 7.11 The Enthalpy of Physical Change The molecules in a solid or liquid are held together by intermolecular attractions. A phase change in which the molecules become further separated, such as melting or vaporization, requires energy to overcome these intermolecular attractions and is therefore endothermic. Phase changes that increase molecular contact, such as condensation or freezing, are exothermic because energy is released when molecules come closer together and can interact with one another more strongly. When a phase transition takes place at constant pressure, as is most common, the heat transfer accompanying the phase change is equal to the change in enthalpy of the substance. At a given temperature, the vapor phase of a substance has a higher energy and therefore a higher enthalpy than the liquid phase. The difference in molar enthalpy between the vapor and the liquid states is called the enthalpy of vaporization, ⌬Hvap: ⌬Hvap ϭ Hm(vapor) Ϫ Hm(liquid) (14) The enthalpy of vaporization of most substances changes little with temperature. For water at its boiling point, 100°C, ⌬Hvap ϭ 40.7 kJиmolϪ1 ; but, at 25°C, ⌬Hvap ϭ 44.0 kJиmolϪ1 . The latter value means that to vaporize 1.00 mol H2O(l), corresponding to 18.02 g of water, at 25°C and constant pressure, we have to supply 44.0 kJ of energy as heat. Self-Test 7.9A A sample of benzene, C6H6, was heated to 80°C, its normal boiling point. The heating was continued until 15.4 kJ had been supplied; as a result, 39.1 g of boiling benzene was vaporized. What is the enthalpy of vaporization of benzene at its boiling point? [Answer: 30.8 kJиmolϪ1 ] Self-Test 7.9B The same heater was used to heat a sample of ethanol, C2H5OH, of mass 23 g to its boiling point. It was found that 22 kJ was required to vaporize all the ethanol. What is the enthalpy of vaporization of ethanol at its boiling point? 7.11 THE ENTHALPY OF PHYSICAL CHANGE 257 317 K ⌬U = 0 Expand: Allow the sample to expand isothermally to its final volume. Because U is independent of volume for an ideal gas, ⌬Ustep 2 ϭ 0 Pressure(P) Volume (V) 317 K ⌬U = ϩ357 J ⌬U = 0 Now add the two changes in internal energy. ⌬U ϭ ϩ357 J Table 7.3 lists the enthalpies of vaporization of various substances. All enthalpies of vaporization are positive, and so it is conventional to report them without their sign. Notice that compounds with strong intermolecular forces, such as hydrogen bonds, tend to have the highest enthalpies of vaporization. That correlation is easy to explain, because the enthalpy of vaporization is a measure of the energy needed to separate molecules from their attractions in the liquid state into a free state in the vapor. In plots of the potential energy arising from intermolecular interactions, like that shown in Fig. 7.21, the enthalpy of the substance in the liquid state, where molecular interactions are strong, is related to the depth of the bottom of the well in the curve. The enthalpy of the vapor state, where the interactions are almost insignificant, corresponds to the horizontal part of the curve to the right. A substance with a high molar enthalpy of vaporization has a deep intermolecular potential well, indicating strong intermolecular attractions. The molar enthalpy change that accompanies melting (fusion) is called the enthalpy of fusion, ⌬Hfus, of the substance: ⌬Hfus ϭ Hm(liquid) Ϫ Hm(solid) (15) Melting, with only one known exception (helium), is endothermic, and so all enthalpies of fusion (with the exception of that special case) are positive and are reported without their sign (see Table 7.3). The enthalpy of fusion of water at 0°C is 6.0 kJиmolϪ1 : to melt 1.0 mol H2O(s) (18 g of ice) at 0°C, we have to supply 6.0 kJ of heat. Vaporizing the same amount of water takes much more energy (more than 40 kJ) because, when water is vaporized to a gas, its molecules must be separated completely. When a solid melts, the molecules can move more freely, but because they stay nearly as close together in the liquid as in the solid, the interactions between them remain nearly as strong (Fig. 7.22). The enthalpy of freezing is the change in molar enthalpy of a liquid when it solidifies. Because enthalpy is a state property, the enthalpy of a sample of water must be the same after being frozen and then melted as it was before it was frozen. Therefore, the enthalpy of freezing of a substance is the negative of its enthalpy of fusion. For water at 0°C, the enthalpy of freezing is Ϫ6.0 kJиmolϪ1 , because 6.0 kJ of heat is released when 1 mol H2O(l) freezes. In general, to obtain the enthalpy change for the reverse of any process, we just take the negative of the enthalpy change for the original process: ⌬Hreverse process ϭ Ϫ⌬Hforward process (16)* This relation is illustrated in Fig. 7.23. 258 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW Molecular separation, r Potentialenergy,EP Energy required to escape 0 FIGURE 7.21 The potential energies of molecules decrease as they approach one another and experience intermolecular attractions, then rise again as the molecules are pressed closely together. The average intermolecular distance in a liquid is given by the position of the energy minimum. To vaporize a liquid, molecules must be raised from the bottom of the well to the energy of the horizontal part of the curve on the right. Lab Video 7.21 TABLE 7.3 Standard Enthalpies of Physical Change* Freezing ⌬Hfus° Boiling ⌬Hvap° Substance Formula point (K) (kJؒmol؊1 ) point (K) (kJؒmol؊1 ) acetone CH3COCH3 177.8 5.72 329.4 29.1 ammonia NH3 195.4 5.65 239.7 23.4 argon Ar 83.8 1.2 87.3 6.5 benzene C6H6 278.6 10.59 353.2 30.8 ethanol C2H5OH 158.7 4.60 351.5 43.5 helium He 3.5 0.021 4.22 0.084 mercury Hg 234.3 2.292 629.7 59.3 methane CH4 90.7 0.94 111.7 8.2 methanol CH3OH 175.2 3.16 337.8 35.3 water H2O 273.2 6.01 373.2 40.7 (44.0 at 25°C) *Values correspond to the temperature of the phase change. The superscript ° signifies that the change takes place at 1 bar and that the substance is pure (that is, the values are for standard states; see Section 7.15). FIGURE 7.22 Melting (fusion) is an endothermic process. Molecules in a solid sample vibrate about ordered positions (top) but, as molecules acquire more energy, they begin to be able to struggle past their neighbors (center). Finally, the solid changes completely into a liquid with disordered, mobile molecules (bottom). Animation 7.22 Sublimation is the direct conversion of a solid into its vapor. Frost disappears on a cold, dry morning as the ice sublimes directly into water vapor. Solid carbon dioxide also sublimes, which is why it is called “dry ice.” Each winter on Mars, solid carbon dioxide is deposited as polar frost, which sublimes when the feeble summer arrives (Fig. 7.24). The enthalpy of sublimation, ⌬Hsub, is the molar enthalpy change when a solid sublimes: ⌬Hsub ϭ Hm(vapor) Ϫ Hm(solid) (17) Because enthalpy is a state function, the enthalpy of sublimation of a substance is the same whether the transition takes place in one step, directly from solid to gas, or we imagine it as taking place in two steps, first from solid to liquid and then from liquid to gas. The enthalpy of sublimation of a substance must therefore be equal to the sum of the enthalpies of fusion and vaporization, provided that they are measured at the same temperature (Fig. 7.25): ⌬Hsub ϭ ⌬Hfus ϩ ⌬Hvap (18)* Self-Test 7.10A The enthalpy of fusion of sodium metal is 2.6 kJиmolϪ1 at 25°C, and the enthalpy of sublimation of solid sodium at that temperature is 101 kJиmolϪ1 . What is the enthalpy of vaporization of sodium at 25°C? [Answer: 98 kJиmolϪ1 ] Self-Test 7.10B The enthalpy of vaporization of methanol is 38 kJ·molϪ1 at 25°C, and the enthalpy of fusion is 3 kJиmolϪ1 at the same temperature. What is the enthalpy of sublimation of methanol at that temperature? The enthalpy change for a reverse reaction is the negative of the enthalpy change for the forward reaction. Enthalpy changes can be added to obtain the value for an overall process. 7.12 Heating Curves The enthalpies of fusion and vaporization affect the appearance of the heating curve of a substance. A heating curve is the graph showing the variation in the temperature of a sample as it is heated at a constant rate at constant pressure and therefore at a constant rate of increase in enthalpy (Box 7.1). Consider what happens when we heat a sample of very cold ice. As we see in Fig. 7.26, at first its temperature rises steadily. Although the molecules are still locked in a solid mass, they are oscillating more and more vigorously around their mean positions. However, once the temperature has reached the melting point, the molecules have enough energy to move past one another. At this temperature, all the added energy is used to overcome the attractive forces between molecules. Thus, although heating continues, the temperature remains constant at the melting point until all the ice has melted. Only then does the temperature rise again, and the rise continues right up to the boiling point. At the boiling point, the temperature rise again comes to a halt. Now the water molecules have enough energy to escape into the vapor state, and all the heat supplied is used to form the vapor. After the sample has evaporated and heating continues, the temperature of the vapor rises again. Thinking point: What is the molar heat capacity of water at its boiling point? The steeper the slope of a heating curve, the lower the heat capacity. In the heating curve for water, for instance, the heating curves of the solid and vapor phases have steeper slopes than the liquid; therefore, we know that the liquid has a greater heat capacity than either the solid or the gas phase does. The high heat capacity of liquid water is due largely to the extensive hydrogen-bonding network that survives in the liquid. The molecules are linked to one another by loose intermolecular hydrogen bonds 7.12 HEATING CURVES 259 Final state Initial state ⌬H Ϫ⌬H Enthalpy FIGURE 7.23 The enthalpy change for a reverse process has the same value but the opposite sign of the enthalpy change for the forward process at the same temperature. FIGURE 7.24 The polar ice caps on Mars extend and recede with the seasons. They are mostly solid carbon dioxide and form by direct conversion of the gas into a solid. They disappear by sublimation. Although some water ice is also present in the polar caps, the temperature on Mars never becomes high enough to melt it. On Mars, ice is just another rock. Vapor ⌬Hvap ⌬Hfus ⌬Hsub Solid Liquid Fusion (melting) Vaporization Sublimation Enthalpy FIGURE 7.25 Because enthalpy is a state property, the enthalpy of sublimation can be expressed as the sum of the enthalpies of fusion and vaporization measured at the same temperature. 260 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW The heating curve of a substance shows how its temperature changes as heat is supplied at a constant rate, usually at constant pressure. How are these curves produced? Simple laboratory heaters can be used to obtain a crude estimate of a heating curve. However, for accuracy, one of two related techniques is normally used. In differential thermal analysis (DTA), equal masses of a sample and a reference material that will not undergo any phase changes, such as Al2O3 (which melts at a very high temperature), are inserted into two separate sample wells in a large steel block that acts as a heat sink (see the following illustration). Because the steel block is so large, it is possible to heat the sample and reference at the same slow and accurately monitored rate. Thermocouples are placed in each well and in the block itself. Then the block is gradually heated and the temperatures of the sample and the reference are compared. An electrical signal is generated if the temperature of the sample suddenly stops rising while that of the reference continues to rise. Such an event signals an endothermic process in the sample, such as a phase change. The output of a DTA analysis is a thermogram, which shows the temperatures of phase changes as heat absorption peaks at the transition temperatures. HOW DO WE KNOW . . . THE SHAPE OF A HEATING CURVE?BOX 7.1 between the reference and the sample will trigger a switch that sends more or less power to the sample to maintain the constant temperature. If the heat capacity of the sample is higher than the heat capacity of the reference, energy must be supplied at a greater rate to the sample cell. If a phase transition occurs in the sample, a great deal of energy must be supplied to the sample until the phase transition is complete and the temperature begins to rise again. In differential thermal analysis, a sample and reference material are placed in the same large metal heat sink. Changes in the heat capacity of the sample are measured by noting differences in temperature between the sample and the reference materials as they are heated at the same rate. Thermocouples Solid block Furnace Sample Reference In differential scanning calorimetry (DSC), higher precision can be obtained and heat capacities can be measured. The apparatus is similar to that for a DTA analysis, with the primary difference being that the sample and reference are in separate heat sinks that are heated by individual heaters (see the following illustration). The temperatures of the two samples are kept the same by differential heating. Even slight temperature differences Thermocouples Sample Reference Heater Heater In a differential scanning calorimeter, a sample and reference material are heated in separate, but identical, metal heat sinks. The temperatures of the sample and reference material are kept the same by varying the power supplied to the two heaters. The output is the difference in power as a function of heat added. Temperature Differentialpower Area ϭ ΔH A thermogram from a differential scanning calorimeter. The peak indicates a phase change in the sample, and the difference in base line before and after the phase transition is due to the difference in heat capacities of the two phases. The output of a differential scanning calorimeter is a measure of the power (the rate of energy supply) supplied to the sample cell. The thermogram in the third illustration shows a peak that signals a phase change. The thermogram does not look much like a heating curve, but it contains all the necessary information and is easily transformed into the familiar shape. 7.13 REACTION ENTHALPIES 261 and the vibrations of these “bonds” can take up energy more readily than can the stiff chemical bonds between atoms. The temperature of a sample is constant at its melting and boiling points, even though heat is being supplied. The slope of a heating curve is steeper for a phase with a low heat capacity than for one with a high heat capacity. THE ENTHALPY OF CHEMICAL CHANGE We have seen that enthalpy changes accompany physical changes, such as vaporization. The same principles apply to the energy and enthalpy changes that accompany chemical changes. Enthalpies of chemical change are important in many areas of chemistry, such as the selection of materials that make good fuels, the design of chemical plants, and the study of biochemical processes. 7.13 Reaction Enthalpies Every chemical reaction is accompanied by a change in energy, and commonly that energy is released as heat. For example, complete reaction with oxygen is called combustion and the combustion of methane, the major component of natural gas, is the following reaction: CH4(g) ϩ 2 O2(g) CO2(g) ϩ 2 H2O(l) Calorimetry shows that burning 1.00 mol CH4(g) produces 890. kJ of heat at 298 K and 1 bar. To report this value, we write CH4(g) ϩ 2 O2(g) CO2(g) ϩ 2 H2O(l) ⌬H ϭ Ϫ890. kJ (A) This entire expression is called a thermochemical equation, and consists of a chemical equation together with a statement of the reaction enthalpy, the corresponding enthalpy change. The stoichiometric coefficients indicate the number of moles that react to give the reported change in enthalpy. Therefore, in this case, the enthalpy change is that resulting from the complete reaction of 1 mol CH4(g) and 2 mol O2(g). If the same reaction is written with the coefficients all multiplied by 2, then the change in enthalpy will be twice as great: 2 CH4(g) ϩ 4 O2(g) 2 CO2(g) ϩ 4 H2O(l) ⌬H ϭ Ϫ1780 kJ This result makes sense because the equation now represents the burning of twice as much methane. We saw in Section 7.11 that the first law of thermodynamics implies that, because enthalpy is a state function, the enthalpy change for the reverse of a process is the negative of the enthalpy change of the forward process. The same relation applies to forward and reverse chemical reactions. For the reverse of reaction A, for instance, we can write CO2(g) ϩ 2 H2O(l) CH4(g) ϩ 2 O2(g) ⌬H ϭ ϩ890. kJ¡ ¡ ¡ ¡ FIGURE 7.26 The heating curve of water. The temperature of the solid rises as heat is supplied. At the melting point, the temperature remains constant, because all the heat is used to melt the sample. When enough heat has been supplied to melt all the solid, the temperature begins to rise again. The heating curve for the liquid is not as steep as for the solid because the liquid has the higher heat capacity. A similar pause occurs at the boiling point. Temperature(°C) Heat supplied Boiling point Melting point Solid Liquid Solid melting Liquid vaporizing 0 100 6.01 kJ.mol –1 7.5 kJ.mol –1 kJ.mol –140.7 Vapor Note that, although burning takes place at much higher temperatures than 298 K, the value of ⌬H is determined by the difference in enthalpies of the products and reactants, both measured at 298 K. We can therefore write the thermochemical equation as 2 C6H6(l) ϩ 15 O2(g) 12 CO2(g) ϩ 6 H2O(l) ⌬H ϭ Ϫ6.55 MJ Evaluate As expected, the enthalpy is negative, indicating an exothermic reaction. Self-Test 7.11A When 0.231 g of phosphorus reacts with chlorine to form phosphorus trichloride, PCl3, in a constant-pressure calorimeter of heat capacity 216 J·(°C)Ϫ1 , the temperature of the calorimeter rises by 11.06°C. Write the thermochemical equation for the reaction. [Answer: 2 P(s) ϩ 3 Cl2(g) 2 PCl3(l), ⌬H ϭ Ϫ641 kJ]¡ ¡ 262 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW EXAMPLE 7.7 Determining a reaction enthalpy from experimental data When 0.113 g of benzene, C6H6, burns in excess oxygen in a calibrated constant-pressure calorimeter with a heat capacity of 551 J·(°C)Ϫ1 , the temperature of the calorimeter rises by 8.60°C. Write the thermochemical equation for 2 C6H6(l) ϩ 15 O2(g) 12 CO2(g) ϩ 6 H2O(l) Anticipate Because the temperature rises, the reaction is exothermic and therefore we should expect ⌬H to be negative. All combustions are exothermic. PLAN The heat released by the reaction at constant pressure is calculated from the temperature change multiplied by the heat capacity of the calorimeter. Use the molar mass of one species (the benzene) to convert the heat released into the reaction enthalpy corresponding to the thermochemical equation as written (for 2 mol C6H6). From Appendix 2A, the molar mass of benzene is 78.12 gиmolϪ1 . What should we assume? That all the heat released by the reaction is absorbed by the calorimeter, with none lost to the rest of the surroundings. SOLVE ¡ 4.74 kJ q 8.60ЊC Find the heat transferred to the calorimeter from qcal ϭ Ccal⌬T. qcal ϭ [551 Jи(°C)Ϫ1 ] ϫ (8.60°C) ϭ 8.60 ϫ 551 J (4.74 kJ) Calculate the amount of C6H6 that reacts from n ϭ m/M. n = 0.113 g 78.12 gиmol-1 = 0.113 78.12 mol 2 mol C6 H6 ⌬H = Ϫ6.55 MJ Because the stoichiometric coefficient of C6H6 in the chemical equation is 2, calculate ⌬H for 2 mol C6H6 from ⌬H ϭ q ϫ (2 mol)/n. Because the reaction is exothermic, ⌬H is negative. = -6.55 * 106 J (-6.55 MJ) ¢H = (2 mol) * (8.60 * 551 J) (0.113/78.12) mol Once we know the reaction enthalpy, we can calculate the enthalpy change, and therefore the heat released or required, for any amount, mass, or volume of reactant consumed or product formed. As shown in the following example, we carry out a stoichiometry calculation like those described in Section L but with heat treated as a reactant or a product. 7.14 THE RELATION BETWEEN ⌬H AND ⌬U 263 Self-Test 7.11B When 0.338 g of pentane, C5H12, burns in an excess of oxygen to form carbon dioxide and liquid water in the same calorimeter as that used in Self-Test 7.11A, the temperature rises by 76.7°C. Write the thermochemical equation for the reaction. A thermochemical equation is a statement of a chemical equation and the corresponding reaction enthalpy, the enthalpy change for the stoichiometric amounts of substances in the chemical equation. 7.14 The Relation Between ⌬H and ⌬U We have seen that a constant-pressure calorimeter and a constant-volume bomb calorimeter measure changes in different state functions: at constant volume, the heat transfer is interpreted as ⌬U; at constant pressure, it is interpreted as ⌬H. However, it is sometimes necessary to convert the measured value of ⌬U into ⌬H. For example, it is easy to measure the heat released by the combustion of glucose in a bomb calorimeter, but to use that information in assessing energy changes in metabolism, which take place at constant pressure, we need the enthalpy of reaction. For reactions in which no gas is generated or consumed, little expansion work is done as the reaction proceeds and the difference between ⌬H and ⌬U is negligible; so we can set ⌬H ϭ ⌬U. However, if a gas is formed in the reaction, so much expansion work is done to make room for the gaseous products that the difference can be significant. We can use the ideal gas law to relate the values of ⌬H and ⌬U for gases that behave ideally. EXAMPLE 7.8 Relating the enthalpy change and internal energy change for a chemical reaction A constant-volume calorimeter showed that the heat generated by the combustion of 1.000 mol glucose molecules in the reaction C6H12O6(s) ϩ 6 O2(g) 6 CO2(g) ϩ 6 H2O(g) is 2559 kJ at 298 K, and so ⌬U ϭ Ϫ2559 kJ. What is the change in enthalpy for the same reaction? Anticipate Because there is a net formation of gas (from 6 mol to 12 mol), we expect ⌬H to be less negative than ⌬U. What should we assume? That each gas is ideal. ¡ HOW DO WE DO THAT? To calculate the relation between ⌬H and ⌬U for a chemical reaction, we suppose that the amount of ideal gas reactant molecules is ninitial. Because for an ideal gas PV ϭ nRT, the initial enthalpy is Hinitial ϭ Uinitial ϩ PVinitial ϭ Uinitial ϩ ninitialRT After the reaction is complete, the amount of ideal gas product molecules is nfinal. The enthalpy is then Hfinal ϭ Ufinal ϩ PVfinal ϭ Ufinal ϩ nfinalRT The difference is ⌬H ϭ Hfinal Ϫ Hinitial ϭ ⌬U ϩ (nfinal Ϫ ninitial)RT We have deduced that ⌬H ϭ ⌬U ϩ ⌬ngasRT (19)* where ⌬ngas ϭ nfinal Ϫ ninitial is the change in the amount of gas molecules in the reaction (positive for net gas formation, negative for net gas consumption). Notice that ⌬H is less negative (more positive) than ⌬U for reactions that generate gases: less energy can be obtained from a reaction as heat at constant pressure than at constant volume because the system must use some energy to expand to make room for the reaction products. For reactions with no change in the amount of gas, the two quantities are about the same. 264 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW Evaluate As we anticipated, the reaction enthalpy is less negative than the reaction internal energy. Self-Test 7.12A The thermochemical equation for the combustion of cyclohexane, C6H12, is C6H12(l) ϩ 9 O2(g) : 6 CO2(g) ϩ 6 H2O(l), ⌬H ϭ Ϫ3920 kJ at 298 K. What is the change in internal energy for the combustion of 1.00 mol C6H12(l) at 298 K? [Answer: Ϫ3.91 ϫ 103 kJ] Self-Test 7.12B The reaction 4 Al(s) ϩ 3 O2(g) : 2 Al2O3(s) was investigated as part of a study on using aluminum powder as a rocket fuel (Fig. 7.27). It was found that 1.000 mol Al produced 3378 kJ of heat in this reaction under constant-pressure conditions at 1000.°C. What is the change in internal energy for the combustion of 1.000 mol Al at 1000.°C? The reaction enthalpy is less negative (more positive) than the reaction internal energy for reactions that generate gases; for reactions with no change in the amount of gas, the two quantities are almost the same. FIGURE 7.27 In this preparation of rocket fuel for the space shuttle, powdered aluminum is mixed with an oxidizing agent in a liquid polymer base that hardens inside the booster rocket shell. From ⌬H ϭ ⌬U ϩ ⌬ngasRT, ⌬H ϭ Ϫ2559 kJ ϩ [(6 mol) ϫ (8.3145 JиKϪ1 ·molϪ1 ) ϫ (298 K)] ϭ Ϫ2559 kJ ϩ 14.9 kJ ϭ Ϫ2544 kJ From ⌬ngas ϭ nfinal Ϫ ninitial, ⌬ngas ϭ 12 Ϫ 6 mol ϭ ϩ6 mol SOLVE 7.15 Standard Reaction Enthalpies Because the heat released or absorbed by a reaction depends on the physical states of the reactants and products, when calculating the reaction enthalpy we need to specify the state of each substance. For example, when describing the combustion of methane, we can write two different thermochemical equations for two different sets of products: (B) (C) In the first reaction, the water is produced as a vapor; in the second, it is produced as a liquid. The heat generated is different in each case. We have already seen that the enthalpy of water vapor is higher than that of liquid water at 25°C (see Table 7.3). As a result, an additional 88 kJ (for 2 mol H2O) remains stored in the system if water vapor is formed (Fig. 7.28). If the 2 mol H2O(g) subsequently condenses, an additional 88 kJ is given off as heat. An enthalpy of reaction also depends on the conditions (such as the pressure). All the tables in this book list data for reactions in which each reactant and product is in its standard state, its pure form at exactly 1 bar. The standard state of liquid water is pure water at 1 bar. The standard state of ice is pure ice at 1 bar. A solute in a liquid solution is in its standard state when its concentration is . The standard value of a property X (that is, the value of X for the standard state of the substance) is denoted X°. The standard reaction enthalpy, , is the reaction enthalpy when reactants in their standard states change into products in their standard states. For example, for reaction C, the value signifies that the heat output is 890. kJ when 1 mol CH4(g) as pure methane gas at 1 bar is allowed to react with pure oxygen gas at 1 bar, giving pure carbon dioxide gas and pure liquid water, both at 1 bar (Fig. 7.29). Reaction enthalpies do not change very much with pressure over the small ranges normally encountered, so the standard value gives a good indication of the change in enthalpy for pressures near 1 bar. ¢H° = -890. kJ ¢H° 1 molиL-1 44 kJиmol-1 ¢H = -890. kJCH4(g) + 2 O2(g) ¡ CO2(g) + 2 H2O(l) ¢H = -802 kJCH4(g) + 2 O2(g) ¡ CO2(g) + 2 H2O(g) CH4(g) ϩ 2 O2(g) CO2(g) ϩ 2 H2O(l) CO2 (g) ϩ 2 H2 O(g) Ϫ802 kJ Ϫ88 kJ Ϫ890 kJ Enthalpy FIGURE 7.28 The enthalpy changes for the reactions in which 1 mol CH4(g) burns to give carbon dioxide and water in either the gaseous (left) or the liquid (right) state. The difference in enthalpy is equal to 88 kJ, the enthalpy of vaporization of 2 mol H2O(l). You may see some tables reporting data at 1 atm, the former standard. The small change in standard pressure makes a negligible difference to most numerical values, and except in very precise work it is normally safe to use data compiled for 1 atm instead of 1 bar. 7.16 COMBINING REACTION ENTHALPIES: HESS’S LAW 265 Most thermochemical data are reported for 25°C (more precisely, for 298.15 K). Temperature is not part of the definition of standard states: we can have a standard state at any temperature; 298.15 K is simply the most common temperature used in tables of data. All reaction enthalpies used in this text are for 298.15 K unless another temperature is indicated. Standard reaction enthalpies refer to reactions in which the reactants and products are in their standard state, the pure form at 1 bar; they are usually reported for a temperature of 298.15 K. 7.16 Combining Reaction Enthalpies: Hess’s Law Enthalpy is a state function; therefore, the value of is independent of the path between given initial and final states. We saw an application of this approach in Section 7.11, when we calculated the enthalpy change for an overall physical process as the sum of the enthalpy changes for a series of two individual steps. The same rule applied to chemical reactions is known as Hess’s law: the overall reaction enthalpy is the sum of the reaction enthalpies of the steps into which the reaction can be divided. Hess’s law applies even if the intermediate reactions or the overall reaction cannot actually be carried out. Provided that the equation for each step balances and the individual equations add up to the equation for the reaction of interest, a reaction enthalpy can be calculated from any convenient sequence of reactions (Fig. 7.30). As an example of Hess’s law, let’s consider the oxidation of carbon as graphite, denoted C(gr), to carbon dioxide: This reaction can be thought of as the outcome of two steps. One step is the oxidation of carbon to carbon monoxide: The second step is the oxidation of carbon monoxide to carbon dioxide: This two-step process is an example of a reaction sequence, a series of reactions in which the products of one reaction take part as reactants in another reaction. The equation for the overall reaction, the net outcome of the sequence, is the sum of the equations for the intermediate steps: (a) (b) (a ؉ b) The same procedure is used to predict the enthalpies of reactions that we cannot measure directly in the laboratory. The procedure is described in Toolbox 7.1. ¢H° = -393.5 kJC(gr) + O2(g) ¡ CO2(g) ¢H° = -283.0 kJCO(g) + 1 2O2(g) ¡ CO2(g) ¢H° = -110.5 kJC(gr) + 1 2O2(g) ¡ CO(g) ¢H° = -283.0 kJCO(g) + 1 2O2(g) ¡ CO2(g) ¢H° = -110.5 kJC(gr) + 1 2O2(g) ¡ CO(g) C(gr) + O2(g) ¡ CO2(g) ¢H Enthalpy Reactants Overallenthalpychange Products Alternative path FIGURE 7.30 If an overall reaction can be broken down into a series of steps, then the corresponding overall reaction enthalpy is the sum of the reaction enthalpies of those steps. None of the steps need be a reaction that can actually be carried out. 2 mol O2(g) 1 bar 1 mol CO2(g) 2 mol H2O(I) 1 bar 1 mol CH4(g) 1 bar Reactants Products FIGURE 7.29 The standard reaction enthalpy is the difference in enthalpy between the pure products and the pure reactants, each at 1 bar and the specified temperature (which is commonly but not necessarily 298 K). The scheme here is for the combustion of methane gas to carbon dioxide gas and liquid water. TOOLBOX 7.1 HOW TO USE HESS’S LAW CONCEPTUAL BASIS Because enthalpy is a state function, the enthalpy change of a system depends only on its initial and final states. Therefore, we can carry out a reaction in one step or, if that is not convenient, visualize it as the sum of several steps; the reaction enthalpy is the same in each case. PROCEDURE To use Hess’s law to find the enthalpy of a given reaction, we find a sequence of reactions with known reaction enthalpies that adds up to the reaction of interest. Step 1 Select one of the reactants in the overall reaction and write down a chemical equation in which it also appears as a reactant. Step 2 Select one of the products in the overall reaction and write down a chemical equation in which it also appears as a product. Add this equation to the equation written in step 1 and cancel species that appear on both sides of the equation. Step 3 Cancel unwanted species in the sum obtained in step 2 by adding an equation that has the same substance or substances on the opposite side of the arrow. Step 4 Once the sequence is complete, combine the standard reaction enthalpies. In each step, we may need to reverse the equation or multiply it by a factor. Recall from Eq. 16 that, if we want to reverse a chemical equation, we have to change the sign of the reaction enthalpy. If we multiply the stoichiometric coefficients by a factor, we must multiply the reaction enthalpy by the same factor. This procedure is illustrated in Example 7.9. EXAMPLE 7.9 Using Hess’s law Consider the synthesis of propane, , a gas used as camping fuel: It is difficult to measure the enthalpy change of this reaction directly. However, standard enthalpies of combustion reactions are easy to measure. Calculate the standard enthalpy of this reaction from the following experimental data: (a) (b) (c) PLAN Use the procedure in Toolbox 7.1 to combine the chemical equations in a way that yields the desired equation. SOLVE ¢H° = -286 kJH2(g) + 1 2O2(g) ¡ H2O(l) ¢H° = -394 kJC(gr) + O2(g) ¡ CO2(g) ¢H° = -2220. kJC3H8(g) + 5 O2(g) ¡ 3 CO2(g) + 4 H2O(l) 3 C(gr) + 4 H2(g) ¡ C3H8(g) C3H8 Step 1 To treat carbon as a reactant, select (b) and multiply it through by 3. ¢H° = 3 * (-394 kJ) = -1182 kJ3 C(gr) + 3 O2(g) ¡ 3 CO2(g) Step 2 Reverse equation (a), changing the sign of its reaction enthalpy. ¢H° = +2220. kJ3 CO2(g) + 4 H2O(l) ¡ C3H8(g) + 5 O2(g) Add the two preceding equations and their enthalpies. ¢H° = (-1182) + (2200) kJ = +1038 kJ C3H8(g) + 5 O2(g) + 3 CO2(g)3 C(gr) + 3 O2(g) + 3 CO2(g) + 4 H2O(l) ¡ Simplify the equation. ¢H° = +1038 kJ3 C(gr) + 4 H2O(l) ¡ C3H8(g) + 2 O2(g) Step 3 To cancel the unwanted and , multiply equation (c) by 4. ¢H° = 4 * (-286 kJ) = -1144 kJ4 H2(g) + 2 O2(g) ¡ 4 H2O(l) O2H2O 266 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.17 THE HEAT OUTPUT OF REACTIONS 267 Step 4 Add the equations in steps 2 and 3. ¢H° = 1038 + (-1144) kJ = -106 kJ C3H8(g) + 2 O2(g) + 4 H2O(l)3 C(gr) + 4 H2(g) + 4 H2O(l) + 2 O2(g) ¡ Simplify the equation by canceling species that appear on both sides. Self-Test 7.13A Gasoline, which contains octane, may burn to carbon monoxide if the air supply is restricted. Determine the standard reaction enthalpy for the incomplete combustion of liquid octane to carbon monoxide gas and liquid water from the standard reaction enthalpies for the combustions of octane and carbon monoxide: [Answer: : Self-Test 7.13B Methanol is a clean-burning liquid fuel proposed as a replacement for gasoline. Suppose it could be produced by the controlled reaction of the oxygen in air with methane. Find the standard reaction enthalpy for the formation of 1 mol from methane and oxygen, given the following information: According to Hess’s law, thermochemical equations for the individual steps of a reaction sequence may be combined to give the thermochemical equation for the overall reaction. 7.17 The Heat Output of Reactions Most of our energy comes from the Sun, either directly or indirectly. The energy of all the solar radiation absorbed by the vegetation on Earth is enough to build about 6 ϫ 1014 kg of glucose a year. Most of this glucose is converted to starches and cellulose. As long as these compounds do not decay completely back to carbon dioxide and water, dead vegetation remains a store of energy. If losses through forest fires are ignored, this store, called the biomass, increases by about 1019 kJ each year, which is about 20 times the current annual global industrial demand for energy. However, because biomass is bulky and widely dispersed, most of our fuels are fossil fuels, energyrich decomposition products of ancient vegetation that have been kept from oxidizing by favorable geological formations. Coal, for example, originated as matter that collected at the bottoms of swamps (see Section 18.10). It has been estimated that less than 0.07% of all vegetation has avoided oxidation to be stored in this way. The rate at which biomass energy is stored in a useful form is therefore only about 1011 kJ per year. Yet we are using it at the rate of 5 ϫ 1017 kJ per year, which is 5 million times more rapidly than it is being stored. Therefore, conservation of existing energy resources has grown in importance, along with research into alternative fuels (Box 7.2). The standard enthalpy of combustion, , is the change in enthalpy per mole of a substance that is burned in a combustion reaction under standard conditions. The products of the combustion of an organic compound are carbon dioxide gas and liquid water; any nitrogen present is released as N2, unless other products are specified. Standard enthalpies of combustion are listed in Table 7.4 and Appendix 2A (for organic compounds). One practical measure of a fuel’s value, also shown in Table 7.4, is its specific enthalpy, the enthalpy of combustion per gram. Fuels with a high specific ¢Hc° ¢H° = -483.64 kJ2 H2(g) + O2(g) ¡ 2 H2O(g) ¢H° = -128.33 kJ2 H2(g) + CO(g) ¡ CH3OH(l) ¢H° = +206.10 kJCH4(g) + H2O(g) ¡ CO(g) + 3 H2(g) CH3OH(l) ¢H° = -6414 kJ] 16 CO(g) + 18 H2O(l),2 C8H18(l) + 17 O2(g) ¢H° = -566.0 kJ2 CO(g) + O2(g) ¡ 2 CO2(g) ¢H° = -10 942 kJ2 C8H18(l) + 25 O2(g) ¡ 16 CO2(g) + 18 H2O(l) ¢H° = -106 kJ3 C(gr) + 4 H2(g) ¡ C3H8(g) Alternative Fuels Our complex modern life style was made possible by the discovery and refining of fossil fuels, fuels that are the result of the decay of organic matter laid down millions of years ago. The natural gas that heats our homes, the gasoline that powers our automobiles, and the coal, gas, and oil that provide much of our electrical power are fossil fuels. Vast reserves of petroleum, the source of liquid hydrocarbon fuels such as gasoline and coal, exist in many areas of the world. However, although large, these reserves are limited and essentially irreplaceable. Yet we are using them up rapidly. Alternative and sustainable power generation methods, such as hydroelectric power, wind power, geothermal power, solar power, and alternative fuels are being sought to reduce the demand for fossil fuels. Four of the most promising alternative fuels are hydrogen, ethanol, methane, and biodiesel. Hydrogen is extracted from ocean water by electrolysis. Ethanol is obtained by fermenting biomass, the name given to plant materials that can be burned or reacted to produce fuels. Methane is generated by bacterial digestion of wastes such as sewage and agricultural wastes. In each case, the fuel is renewable. That means the source of the fuel is replenished every year by the Sun. The use of hydrogen as a fuel is discussed in Section 15.3. Here, we look at ethanol, methane, and biodiesel. Ethanol, CH3CH2OH, is produced from the biological fermentation of the starches in grains, mainly corn. It is used as an additive in gasoline or as “E85,” which is 85% ethanol and 15% gasoline by volume. Ethanol currently makes up about 10% by volume of gasoline in the United States, thereby reducing pollution as well as the use of petroleum. The 2005 U.S. Energy Policy Act required that, by 2012, 7.5 billion gallons (2.8 ϫ 1010 L) of WHAT HAS THIS TO DO WITH . . . THE ENVIRONMENT?BOX 7.2 The cellulose-based waste biomass in this reactor is being digested by special enzymes that break it down into ethanol. These enzymes are being intensively studied to improve the efficiency of conversion. renewable fuel be used per year. The 2007 Energy Independence and Security Act requires that by 2022 the annual usage of renewable fuels increase to 36 billion gallons (1.4 ϫ 1011 L, about 23% of the total annual volume of liquid fuels used in the United States). The oxygen atom in the ethanol molecule reduces emissions of carbon monoxide and hydrocarbons by helping to ensure complete combustion. However, because ethanol is already partly oxygenated, it can provide less energy per liter; currently mileage for a car burning E85 is 15% lower than for pure gasoline. One bushel of corn (about 30 L) can produce nearly 10 L of ethanol. A problem with ethanol as a fuel is that the sugars and starches fermented to produce it are expensive. However, the cellulose in straw and cornstalks left behind as stubble when grains 268 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW TABLE 7.4 Standard Enthalpies of Combustion at 25°C* ⌬Hc° Specific enthalpy Substance Formula (kJؒmol؊1 ) (kJؒg؊1 ) benzene C6H6(l) Ϫ3268 41.8 carbon C(s, graphite) Ϫ394 32.8 ethanol C2H5OH(l) Ϫ1368 29.7 ethyne (acetylene) C2H2(g) Ϫ1300. 49.9 glucose C6H12O6(s) Ϫ2808 15.59 hydrogen H2(g) Ϫ286 142 methane CH4(g) Ϫ890. 55 octane C8H18(l) Ϫ5471 48 propane C3H8(g) Ϫ2220. 50.35 urea CO(NH2)2(s) Ϫ632 10.52 *In a combustion, carbon is converted into carbon dioxide, hydrogen into liquid water, and nitrogen into nitrogen gas. More values are given in Appendix 2A. enthalpy release a lot of heat per gram when they burn. Hence, specific enthalpy is an important criterion when mass is important, as it is in airplanes and spacecraft. Notice that fuels that have already been partially oxygenated, such as glucose and ethanol, have lower specific enthalpies than the hydrocarbons. 7.17 THE HEAT OUTPUT OF REACTIONS 269 A great advantage of hydrogen over hydrocarbon fuels is that it produces no carbon dioxide when it burns. Carbon dioxide is potentially harmful, because it contributes to the greenhouse effect (see Box 15.1). However, although hydrogen forms only water when it burns, its use is limited by the high volume required for a gas. Chemists are working to synthesize solid compounds that concentrate hydrogen and release it as needed. Candidates include the hydrides formed when titanium, copper, and other metals are heated in hydrogen. These compounds occupy a much smaller volume than the equivalent amount of hydrogen gas and release hydrogen when heated or treated with acid. One example is an iron titanium hydride of approximate formula FeTiH2. Another promising low-density storage medium for hydrogen is offered by carbon nanotubes (see Section 6.19). We have seen in Toolbox 7.1 how to use enthalpies of combustion to obtain the standard enthalpies of reactions. Here we consider another practical application— the choice of a fuel. For example, suppose we want to know the heat output from the combustion of 150. g of methane. The thermochemical equation allows us to write the following relation and to use it as a conversion factor in the usual way (1). 1 mol CH4 ϴ 890. kJ biological materials. The “digestion” of the biomaterials by bacteria is anaerobic, which means that it takes place in the absence of oxygen. Currently, many sewage treatment plants have anaerobic digesters that produce the methane used to operate the plants. To generate methane by anaerobic digestion on a largescale basis, additional materials, such as sugars from the enzymatic breakdown of biomass, would need to be used. Methane would be less useful than ethanol as a transportation fuel, because it is a gas and so has a low enthalpy density, the enthalpy of combustion per liter. However, it can be used wherever natural gas is used. Biodiesel is the term used for diesel fuel that comes from renewable, biological sources, such as vegetable oil. Even used oils, such as those discarded from restaurant deep fryers, can be filtered and used as biodiesel. Biodiesel engines are more efficient than gasoline engines, as the fuel has a high energy density (enthalpy of combustion per liter). A problem with biodiesel is that it is more viscous than gasoline and can solidify at low temperatures. These alternative fuels do produce carbon dioxide when burned and thus contribute to the greenhouse effect and global warming (Box 15.1). However, they can be renewed every year, as long as the Sun shines and produces green plants. Related Exercises: 7.45–7.47, 7.52, 7.54, 7.103, 7.115. For Further Reading: Alternative Fuels & Advanced Vehicles Data Center, http://www.afdc.energy.gov/afdc/ (U.S. Department of Energy, 2009). A Student’s Guide to Alternative Fuel Vehicles, http://www.energyquest.ca.gov/transportation/ (California Energy Commission, 2005). M. Allen, “Crunching the Numbers on Alternative Fuels,” Popular Mechanics, May, 2006, http://www.popularmechanics.com/science/ earth/2690341.html. These tanks at a water treatment facility are used to generate a mixture of methane and carbon dioxide by anaerobic digestion of sewage. The methane produced provides much of the power needed to run the facility. are harvested is now attracting attention. Cellulose is the structural material in plants (see Section 19.14). It is made up of simple sugars, just as starches are, but the bacteria that ferment starches cannot digest cellulose. Research is now being conducted on enzymes that break down cellulose into sugars that can be digested. This process would greatly increase the biomass available for fuel production, because straw, wood, grasses, and in fact, nearly any plant materials, could be used for fuel. It would also partly avoid the problem of the production of fuel being in competition with the production of food. Methane, CH4, is found in underground reserves as the primary component of natural gas, but it is also obtained from Moles of A Reaction enthalpy Molar mass of A Mass of A Heat 1 EXAMPLE 7.10 Calculating the heat output of a fuel How much butane should a backpacker carry? Calculate the mass of butane that you would need to burn to obtain 350. kJ of heat, which is just enough energy to heat 1 L of water from 17°C to boiling at sea level (if we ignore all heat losses). The thermochemical equation is Anticipate From experience, you might suspect that only a few grams of fuel will be sufficient. PLAN The first step is to convert heat output required into moles of fuel molecules by using the thermochemical equation. Then use the molar mass of the fuel to convert from moles of fuel molecules into grams. What should we assume? That no heat is lost to the surroundings, so that all the heat generated by the reaction is available to boil the water. ¢H° = -5756 kJ2 C4H10(g) + 13 O2(g) ¡ 8 CO2(g) + 10 H2O(l) 2 mol C4 H10 5756 kJ Find the relation of the enthalpy change to amount of fuel molecules from the thermochemical equation. 5756 kJ ϴ 2 mol C4H10 350. kJ 5756 kJ 2 mol 1 mol 58.12 g 7.07 g= ϫϫ Convert heat output into moles of fuel molecules. = 350. * 2 5756 mol C4H10 (0.122 mol C4H10) n(C4H10) = (350. kJ) * 2 mol C4H10 5756 kJ Use m ϭ nM and the molar mass of butane, 58.12 g·molϪ1 , to find the mass of reactant. = 7.07 g C4H10 m(C4H10) = a 350. * 2 5756 mol C4H10b * (58.12 gиmol-1 ) Evaluate The mass needed, just over 7 g, is consistent with our anticipation that only a few grams need be carried. Self-Test 7.14A The thermochemical equation for the combustion of propane is What mass of propane must be burned to supply 350. kJ as heat? Would it be easier to pack propane rather than butane? [Answer: 6.95 g. Yes, propane would be very slightly lighter to carry.] Self-Test 7.14B Ethanol trapped in a gel is another common camping fuel. What mass of ethanol must be burned to supply 350. kJ as heat? The thermochemical equation for the combustion of ethanol is The heat absorbed or released by a reaction can be treated like a reactant or product in a stoichiometric calculation. ¢H° = -1368 kJC2H5OH(l) + 3 O2(g) ¡ 2 CO2(g) + 3 H2O(l) ¢H° = -2220. kJC3H8(g) + 5 O2(g) ¡ 3 CO2(g) + 4 H2O(l) 270 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.18 STANDARD ENTHALPIES OF FORMATION 271 7.18 Standard Enthalpies of Formation There are millions of possible reactions, and it is impractical to list every one with its standard reaction enthalpy. However, chemists have devised an ingenious alternative. First, they report the “standard enthalpies of formation” of substances. Then they combine these quantities to obtain the standard enthalpy of any reaction. Let’s look at these two stages in turn. The standard enthalpy of formation, , of a substance is the standard reaction enthalpy per mole of formula units for the formation of a substance from its elements in their most stable form, as in the reaction for the formation of ethanol: ⌬H° ϭ –277.69 kJ where gr denotes graphite, the most stable form of carbon at normal temperatures. The chemical equation that corresponds to the standard enthalpy of formation of a substance has the substance as the sole product with a stoichiometric coefficient of 1 (implying the formation of 1 mol of the substance). Sometimes, as here, fractional coefficients are required for the reactants. Because standard enthalpies of formation are expressed in kilojoules per mole of the substance of interest, we report that . Note also how the substance and its state are used to label the enthalpy change so that we know which species and which form of that species (liquid, in this case) we are talking about. A note on good practice: You should always be alert to the difference between a quantity per mole of molecules and the same quantity for or of a mole of molecules. Standard enthalpies of formation are expressed per mole of molecules, as in Ϫ277.69 kJиmolϪ1 ; the standard enthalpy of forming 1 mol . The point might seem picky, but it will help you to keep units straight. It follows from the definition just given that the standard enthalpy of formation of an element in its most stable form is zero. For instance, the standard enthalpy of formation of C(gr) is zero because C(gr) : C(gr) is a “null reaction” (that is, nothing changes). We write, for instance, . However, the enthalpy of formation of an element in a form other than its most stable one is nonzero. For example, the conversion of carbon from graphite (its most stable form) into diamond is endothermic: The standard enthalpy of formation of diamond is therefore reported as ⌬Hf° (C, diamond) ϭ ϩ1.9 kJиmolϪ1 . Values for a selection of other substances are listed in Table 7.5 and Appendix 2A. Now let’s see how to combine standard enthalpies of formation to calculate a standard reaction enthalpy. To do so, we imagine that to carry out the reaction we convert ¢H° = +1.9 kJC(gr) ¡ C(diamond) ¢Hf°(C, gr) = 0 C2H5OH(l) is -277.69 kJ ¢Hf°(C2H5OH, l) = -277.69 kJиmol-1 2 C(gr) + 3 H2(g) + 1 2O2(g) ¡ C2H5OH(l) ¢Hf° Phosphorus is an exception: white phosphorus is used because it is much easier to obtain pure than the other, more stable allotropes. TABLE 7.5 Standard Enthalpies of Formation at 25°C (kJؒmol؊1 )* Substance Formula ⌬Hf° Substance Formula ⌬Hf° Inorganic compounds Organic compounds ammonia NH3(g) Ϫ46.11 benzene C6H6(l) ϩ49.0 carbon dioxide CO2(g) Ϫ393.51 ethanol C2H5OH(l) Ϫ277.69 carbon monoxide CO(g) Ϫ110.53 ethyne C2H2(g) ϩ226.73 dinitrogen tetroxide N2O4(g) ϩ9.16 (acetylene) hydrogen chloride HCl(g) Ϫ92.31 glucose C6H12O6(s) Ϫ1268 hydrogen fluoride HF(g) Ϫ271.1 methane CH4(g) Ϫ74.81 nitrogen dioxide NO2(g) ϩ33.18 nitric oxide NO(g) ϩ90.25 sodium chloride NaCl(s) Ϫ411.15 water H2O(l) Ϫ285.83 H2O(g) Ϫ241.82 *A much longer list is given in Appendix 2A. the reactants into the elements in their most stable form, then form the products from those elements. The first step is usually to calculate the reaction enthalpy for the formation of all the products from their elements. For this step, we use the enthalpies of formation of the products. Then, we calculate the reaction enthalpy for the formation of all the reactants from their elements. The difference between these two totals is the standard enthalpy of the reaction (Fig. 7.31): (20)* In this expression, the n are the stoichiometric coefficients in the chemical equation and the symbol ∑ (sigma) means a sum. The first sum is the total standard enthalpy of formation of the products. The second sum is the similar total for the reactants. ¢H° = an¢Hf° (products) - an¢Hf°(reactants) Enthalpy Reactants Products Elements Enthalpy of reaction Formation of reactants Formation of products FIGURE 7.31 The reaction enthalpy can be constructed from standard enthalpies of formation by imagining forming the reactants and products from their elements. Then the reaction enthalpy is the difference between the standard enthalpies of formation of products and reactants. EXAMPLE 7.11 Using standard enthalpies of formation to calculate a standard enthalpy of reaction Amino acids are the building blocks of proteins, which have long chainlike molecules. They are oxidized in the body to urea, carbon dioxide, and liquid water. Is this reaction a source of heat for the body? Use the information in Appendix 2A to predict the standard enthalpy of reaction for the oxidation of the simplest amino acid, glycine (NH2CH2COOH), a solid, to solid urea (H2NCONH2), carbon dioxide gas, and liquid water: 2 NH2CH2COOH(s) ϩ 3 O2(g) H2NCONH2(s) ϩ 3 CO2(g) ϩ 3 H2O(l) Anticipate We expect a strongly negative value because all combustions are exothermic and this oxidation is like an incomplete combustion. PLAN First, add together the standard enthalpies of formation of the products, multiplying each value by the appropriate number of moles from the balanced equation. Remember that the standard enthalpy of formation of an element in its most stable form is zero. Then, calculate the total standard enthalpy of formation of the reactants in the same way and use Eq. 20 to calculate the standard reaction enthalpy. SOLVE ¡ Calculate the total enthalpy of formation of the products. n⌬Hf°(products) ϭ (1 mol)⌬Hf°(H2NCONH2, s) ϩ (3 mol)⌬Hf°(CO2, g) ϩ (3 mol)⌬Hf°(H2O, l) ϭ (1 mol)(Ϫ333.51 kJиmolϪ1 ) ϩ (3 mol)(Ϫ393.51 kJиmolϪ1 ) ϩ (3 mol)(Ϫ285.83 kJиmolϪ1 ) ϭ Ϫ333.51 ϩ (Ϫ1180.53) ϩ (Ϫ857.49) kJ ϭ Ϫ2371.53 kJ a Elements Ϫ2371.53 kJ·mol Ϫ1 Products Enthalpy Calculate the total enthalpy of formation of the reactants. nHf°(reactants) ϭ (2 mol)⌬Hf°(NH2CH2COOH, s) ϩ (3 mol)⌬Hf°(O2, g) ϭ (2 mol)(Ϫ532.9 kJиmolϪ1 ) ϩ (3 mol)(0) ϭ Ϫ1065.8 kJ a Elements Reactants Ϫ1065.8 kJ·mol Ϫ1 Enthalpy From ⌬H° ϭ n⌬Hf°(products) Ϫ n⌬Hf°(reactants), ⌬H° ϭ Ϫ2371.53 Ϫ (Ϫ1065.8) kJ ϭ Ϫ1305.7 kJ aa Elements Reactants Products Ϫ1305.7 kJ·mol Ϫ1 Enthalpy 272 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.18 STANDARD ENTHALPIES OF FORMATION 273 Evaluate The thermochemical equation is therefore 2 NH2CH2COOH(s) ϩ 3 O2(g) H2NCONH2(s) ϩ 3 CO2(g) ϩ 3 H2O(l) ⌬H°ϭ Ϫ1305.7 kJ As we anticipated, the reaction is strongly exothermic. Because reactions in the body take place in aqueous solution, this value is not the same as the enthalpy change for the reaction in the body. However, the two values are fairly close. Therefore, the oxidation of glycine, which we have found to be exothermic, is a potential source of energy in the body. A note on good practice: Enthalpies of formation are expressed in kilojoules per mole and enthalpies of reaction in kilojoules for the reaction as written. Note how the stoichiometric coefficients are interpreted as numbers of moles, and that an unwritten coefficient of 1 for urea is included as 1 mol in the calculation. Self-Test 7.15A Calculate the standard enthalpy of combustion of glucose from the standard enthalpies of formation in Table 7.5 and Appendix 2A. [Answer: Ϫ2808 kJиmolϪ1 ] Self-Test 7.15B You have an inspiration: maybe diamonds would make a great fuel! Calculate the standard enthalpy of combustion of diamonds from the information in Appendix 2A. Standard enthalpies of formation are commonly determined from combustion data by using Eq. 20. The procedure is the same, but the standard reaction enthalpy is known and the unknown value is one of the standard enthalpies of formation. ¡ EXAMPLE 7.12 Using the enthalpy of combustion to calculate an enthalpy of formation Use the information in Table 7.5 and the enthalpy of combustion of propane gas to calculate the enthalpy of formation of propane, a gas commonly used for camping stoves and outdoor barbecues. PLAN Use Eq. 20 and the procedure set out in Example 7.11, but solve for the standard enthalpy of formation of propane. SOLVE Write the thermochemical equation for the combustion of 1 mol C3H8. C3H8(g) ϩ 5 O2(g) 3 CO2(g) ϩ 4 H2O(l) ⌬H° ϭ Ϫ2220. kJ ¡ Reactants Products Ϫ2220. kJ·mol Ϫ1 Enthalpy Find the total enthalpy of formation of the products. n⌬Hf°(products) ϭ (3 mol)⌬Hf°(CO2, g) ϩ (4 mol)⌬Hf°(H2O, l) ϭ (3 mol)(Ϫ393.51 kJиmolϪ1 ) ϩ (4 mol)(Ϫ285.83 kJиmolϪ1 ) ϭ Ϫ1180.53 Ϫ 1143.32 kJ ϭ Ϫ2323.85 kJ a Products Elements Ϫ2323.85 kJ·mol Ϫ1 Enthalpy Find the total enthalpy of formation of the reactants. n⌬Hf°(reactants) ϭ (1 mol)⌬Hf°(C3H8, g) ϩ (5 mol)⌬Hf°(O2, g) ϭ (1 mol)⌬Hf°(C3H8, g) a Reactants Elements Enthalpy ⌬Hf Њ From ⌬Hr° ϭ ∑n⌬Hf° (products) Ϫ ∑n⌬Hf° (reactants), Ϫ2220. kJ ϭ Ϫ2323.85 kJ Ϫ (1 mol)⌬Hf°(C3H8, g) Reactants Products Elements Enthalpy Ϫ2323.85 kJ·mol Ϫ1 Ϫ104 kJ·mol Ϫ1 Ϫ2220. kJ·molϪ1 Solve for ⌬Hf°(C3H8, g). ⌬Hf°(C3H8, g) ϭ Ϫ2323.85 Ϫ (Ϫ2220.) kJиmolϪ1 ϭ Ϫ104 kJиmolϪ1 Self-Test 7.16A Calculate the standard enthalpy of formation of ethyne, the fuel used in oxyacetylene welding torches, from the information in Tables 7.4 and 7.5. [Answer: +227 kJиmolϪ1 ] Self-Test 7.16B Calculate the standard enthalpy of formation of urea, CO(NH2)2, a by-product of the metabolism of proteins, from the information in Tables 7.4 and 7.5. Standard enthalpies of formation can be combined to obtain the standard enthalpy of any reaction. 7.19 The Born–Haber Cycle We saw in Section 2.4 that the energy changes accompanying the formation of a solid could be estimated on the basis of a model—the ionic model—in which the principal contribution to the lattice energy was the Coulomb interaction between ions. However, a model can give only an estimate: we need a way to measure the energy change. If the measured and calculated energies are similar, we can conclude that the ionic model is reliable for the particular substance. If the two energies are markedly different, then we know that the ionic model must be improved or even discarded. For a given solid, the difference in molar enthalpy between the solid and a gas of widely separated ions is called the lattice enthalpy of the solid, ⌬HL: ⌬HL ϭ Hm(ions, g) Ϫ Hm(solid) (21) The lattice enthalpy can be identified with the heat required to vaporize the solid at constant pressure. The greater the lattice enthalpy, the greater is the heat required. Heat equal to the lattice enthalpy is released when the solid forms from gaseous ions. In Section 2.4 we calculated the lattice energy and discussed how it depended on the attractions between the ions. The lattice enthalpy differs from the lattice energy by only a few kilojoules per mole and can be interpreted in a similar way. The lattice enthalpy of a solid cannot normally be measured directly. However, we can obtain it indirectly by combining other measurements in an application of Hess’s law. This approach takes advantage of the first law of thermodynamics and, in particular, the fact that enthalpy is a state function. The procedure uses a Born–Haber cycle, a closed path of steps, one of which is the formation of a solid lattice from the gaseous ions. The enthalpy change for this step is the negative of the lattice enthalpy. Table 7.6 lists some lattice enthalpies found in this way. In a Born–Haber cycle, we imagine that we break apart the bulk elements into atoms, ionize the atoms, combine the gaseous ions to form the ionic solid, then form the elements again from the ionic solid (Fig. 7.32). Only the lattice enthalpy, the negative of the enthalpy of the step in which the ionic solid is formed from the gaseous ions, is unknown. The sum of the enthalpy changes for a complete Born–Haber cycle is zero, because the enthalpy of the system must be the same at the start and finish. 274 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.19 THE BORN–HABER CYCLE 275 EXAMPLE 7.13 Using a Born–Haber cycle to calculate a lattice enthalpy Devise and use a Born–Haber cycle to calculate the lattice enthalpy of potassium chloride. Anticipate Typical lattice enthalpies are close to 1000 kJиmolϪ1 . PLAN A Born–Haber cycle combines the enthalpy changes that take place when we begin with the pure elements, atomize them to form gaseous atoms, ionize the atoms to form gaseous ions, allow the ions to form an ionic solid, and then convert the solid back into the pure elements. The only unknown enthalpy change is that of the step in which the ionic solid forms from gaseous ions (Ϫ⌬HL). Because the sum of the enthalpy changes for the complete cycle is zero, we can solve for the lattice enthalpy, ⌬HL. SOLVE The Born–Haber cycle for KCl is shown in Fig. 7.33. TABLE 7.6 Lattice Enthalpies at 25°C (kJؒmol؊1 ) Halides LiF 1046 LiCl 861 LiBr 818 LiI 759 NaF 929 NaCl 787 NaBr 751 NaI 700. KF 826 KCl 717 KBr 689 KI 645 AgF 971 AgCl 916 AgBr 903 AgI 887 BeCl2 3017 MgCl2 2524 CaCl2 2260. SrCl2 2153 MgF2 2961 CaBr2 1984 Oxides MgO 3850. CaO 3461 SrO 3283 BaO 3114 Sulfides MgS 3406 CaS 3119 SrS 2974 BaS 2832 Find ⌬Hf(K, atoms) in Appendix 2A. K(s) K(g) ϩ89 kJиmolϪ1 ¡ Find ⌬Hf(Cl, atoms) in Appendix 2A. ϩ122 kJиmolϪ1 Cl(g)¡ 1 2Cl2(g) Find the ionization energy of K in Fig. 1.50 or Appendix 2D. ϩ418 kJиmolϪ1 K+ (g) + e- (g)¡K(g) Use Appendix 2A to write the negative of the standard enthalpy of formation of KCl, Ϫ⌬Hf(KCl). Ϫ(Ϫ437 kJиmolϪ1 )K(s) + 1 2Cl2(g)¡KCl(s) Set up the cycle, with a sum of zero. {89 ϩ 122 ϩ 418 Ϫ 349 Ϫ (Ϫ437)} kJиmolϪ1 Ϫ ⌬HL ϭ 0 Solve for ⌬HL, the enthalpy of the reaction KCl(s) K+ (g) ϩ ClϪ (g), ⌬HL ϭ (89 ϩ 122 ϩ 418 Ϫ 349 ϩ 437) kJиmolϪ1 ϭ ϩ717 kJиmolϪ1 ¡ Write the electron gain enthalpy of Cl as the negative of the electron affinity (Fig. 1.54 or Appendix 2D). Ϫ349 kJиmolϪ1 Cl(g)¡Cl(g) + e- (g) FIGURE 7.33 The Born–Haber cycle used to determine the lattice enthalpy of potassium chloride (see Example 7.13). The enthalpy changes are in kilojoules per mole. Enthalpy Gaseous ions Solid compound Atoms Elements Enthalpy of ionization Ϫ(Enthalpy of formation) Ϫ(Latticeenthalpy) Enthalpy of atomization FIGURE 7.32 In a Born–Haber cycle, we select a sequence of steps that starts and ends at the same point (the solid compound, for instance). The lattice enthalpy is the enthalpy change accompanying the reverse of the step in which the solid is formed from a gas of ions. The sum of enthalpy changes around the complete cycle is 0 because enthalpy is a state function. Enthalpy Kϩ (g) ϩ eϪ (g) ϩ Cl(g) K ϩ (g) ϩ Cl Ϫ (g) ϩ418 Ϫ349 Ϫ⌬HL(KCl) ϩ122 ϩ437 ϩ89 K(g) ϩ Cl(g) KCl(s) K(g) ϩ Cl2 (g) 1 2 K(g) ϩ Cl2 (g) 1 2 Evaluate The lattice enthalpy of potassium chloride is 717 kJиmolϪ1 , of the order of magnitude expected. Self-Test 7.17A Calculate the lattice enthalpy of calcium chloride, CaCl2, by using the data in Appendices 2A and 2D. [Answer: 2259 kJиmolϪ1 ] Self-Test 7.17B Calculate the lattice enthalpy of magnesium bromide, MgBr2, by using the data in Appendices 2A and 2D. The strength of interaction between ions in a solid is measured by the lattice enthalpy, which can be determined by using a Born–Haber cycle. 7.20 Bond Enthalpies In a chemical reaction, old bonds are broken and new ones formed. We can estimate reaction enthalpies if we know the enthalpy changes that accompany the breaking and making of bonds. The strength of a chemical bond is measured by the bond enthalpy, ⌬HB, the difference between the standard molar enthalpies of a molecule, XᎏY (for instance, H3CᎏOH), and its fragments X and Y (such as CH3 and OH) in the gas phase: ⌬HB(X Ϫ Y) ϭ {Hm°(X, g) ϩ Hm°(Y, g)} Ϫ Hm°(XY, g) (22) Whereas a lattice enthalpy is equal to the heat required (at constant pressure) to break up an ionic substance, a bond enthalpy is the heat required to break a specific type of bond at constant pressure. For example, the bond enthalpy of H2 is derived from the thermochemical equation H2(g) 2 H(g) ⌬H° ϭ ϩ436 kJ We write ⌬HB(HᎏH) ϭ 436 kJиmolϪ1 to report this value and conclude that 436 kJ of heat is needed to dissociate 1 mol H2(g) into atoms. All bond enthalpies are positive because heat must be supplied to break a bond. In other words, bond breaking is always endothermic and bond formation is always exothermic. Table 7.7 lists bond enthalpies of some diatomic molecules. In a polyatomic molecule, all the atoms in the molecule exert a pull—through their electronegativities (recall Section 2.12)—on all the electrons in the molecule (Fig. 7.34). As a result, the bond strength between a given pair of atoms varies to a small extent from one compound to another. For example, the OᎏH bond enthalpy in water, HOᎏH (492 kJиmolϪ1 ), is somewhat different from that of the same bond in CH3OᎏH (437 kJиmolϪ1 ). However, these variations in bond enthalpy are not very great, and so the mean bond enthalpy, which we also denote ⌬HB, is a guide to the strength of a bond in any molecule containing the bond (Table 7.8). A bond enthalpy refers to the dissociation of a species in the gas phase; to find the enthalpy change accompanying the dissociation of a liquid or solid sample, we must add the enthalpy of vaporization or sublimation of the sample: X2(l) 2 X(g) ⌬H° ϭ ⌬Hvap°(X2, l) ϩ ⌬HB°(X Ϫ X) Reaction enthalpies can be estimated by using mean bond enthalpies to determine the total energy required to break the reactant bonds and form the product bonds. In practice, only the bonds that change are treated. Because bond enthalpies refer to gaseous substances, to use the tabulated values, all substances must be gases or converted into the gas phase. ¡ ¡ TABLE 7.7 Bond Enthalpies of Diatomic Molecules (kJ·mol؊1 ) Molecule ⌬HB H2 436 N2 944 O2 496 CO 1074 F2 158 Cl2 242 Br2 193 I2 151 HF 565 HCl 431 HBr 366 HI 299 FIGURE 7.34 An electrostatic potential diagram of ethanol, C2H5OH. An electronegative atom (here, the O atom) can pull electrons toward itself from more distant parts of the molecule, as shown by the red tint over the O atom. Hence it can influence the strengths of bonds even between atoms to which it is not directly attached. A bond dissociation energy (Section 2.14) is strictly the energy required to break the bond at T ‫؍‬ 0; a bond enthalpy is the change in enthalpy at the temperature of dissociation (typically 298 K). The two quantities differ by a few kilojoules per mole. Electronegative atom 276 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 7.20 BOND ENTHALPIES 277 TABLE 7.8 Mean Bond Enthalpies (kJؒmol؊1 ) Bond Mean bond enthalpy Bond Mean bond enthalpy CßH 412 CßI 238 CßC 348 NßH 388 C≈C 612 NßN 163 C…ᎏC* 518 N≈N 409 C C 837 NßO 210. CßO 360 N≈O 630. C≈O 743 NßF 195 CßN 305 NßCl 381 CßF 484 OßH 463 CßCl 338 OßO 157 CßBr 276 *In benzene. ‚ EXAMPLE 7.14 Using mean bond enthalpies to estimate the enthalpy of a reaction Estimate the enthalpy of the reaction between gaseous iodoethane and water vapor: CH3CH2I(g) ϩ H2O(g) CH3CH2OH(g) ϩ HI(g) Anticipate The HᎏI bond is weak and the HᎏO bonds in water are strong, so it would not be surprising if this reaction turned out to be endothermic. PLAN Decide which bonds are broken and which bonds are formed. Use the mean bond enthalpies in Table 7.8 to estimate the change in enthalpy when the reactant bonds break and the change in enthalpy when the new product bonds form. For diatomic molecules, use the information in Table 7.7 for the specific molecule. Finally, add the enthalpy change required to break the reactant bonds (a positive value) to the enthalpy change that occurs when the product bonds form (a negative value). What should we assume? That the mean bond enthalpies in the table are close to the actual bond enthalpies in the reactants and products. SOLVE ¡ Reactants: Break 1 mol CᎏI bonds in CH3CH2I (average value 238 kJ·molϪ1 ) and 1 mol OᎏH bonds in H2O (average value 463 kJиmolϪ1 ). ⌬H° ϭ 238 ϩ 463 kJ ϭ ϩ701 kJ 463 238 Products: Form 1 mol CᎏO bonds (average value 360 kJиmolϪ1 ) and 1 mol HᎏI bonds (299 kJиmolϪ1 ). The enthalpy change when the product bonds form are the negative of the bond formation enthalpy. ⌬H° ϭ Ϫ(360 ϩ 299) kJ ϭ Ϫ659 kJ 299.360 42 360 463 238 299. The overall enthalpy change is the sum of the bond enthalpy changes. ⌬H° ϭ 701 ϩ (Ϫ659) kJ ϭ ϩ42 kJ Evaluate The reaction is endothermic, as we suspected might be the case, primarily because a relatively large energy is needed to break an O—H bond and not much is recovered from the formation of an H—I bond. Self-Test 7.18A Use bond enthalpies to estimate the standard enthalpy of the reaction CCl3CHCl2(g) ϩ 2 HF(g) : CCl3CHF2(g) ϩ 2 HCl(g). [Answer: –24 kJиmolϪ1 ] Self-Test 7.18B Use bond enthalpies to estimate the standard enthalpy of the reaction in which 1.00 mol of gaseous CH4 reacts with gaseous F2 to form gaseous CH2F2 and HF. A note on good practice. The use of mean bond enthalpies is hazardous because actual bond enthalpies may differ considerably from mean values. The modern procedure for estimating a reaction enthalpy is to use commercial software to calculate the enthalpies of formation of the reactants and products and then to take the difference, as in Section 7.18. A mean bond enthalpy is the average molar enthalpy change accompanying the dissociation of a given type of bond. 7.21 The Variation of Reaction Enthalpy with Temperature Suppose we know the reaction enthalpy for one temperature but require it for another temperature. For instance, the temperature of the human body is about 37°C, but the data in Appendix 2A are for 25°C. How can we find out whether an increase of 12°C makes much difference to the reaction enthalpy of a metabolic process? The enthalpies of both reactants and products increase with temperature. If the total enthalpy of the reactants increases more than that of the products when the temperature is raised, then the reaction enthalpy of an exothermic reaction becomes more negative (Fig. 7.35). On the other hand, if the enthalpy of the products increases more than that of the reactants, then the reaction enthalpy will become less negative. The increase in enthalpy of a substance when the temperature is raised depends on its heat capacity at constant pressure (Eq. 12b), and it is easy to deduce Kirchhoff’s law (see Exercise 7.89) that (23)* To use this expression, we need to know ⌬CP, the difference between the constantpressure heat capacities of the products and reactants: (24) These values can be found in Appendix 2A. Because the difference between ⌬H°(T2) and ⌬H°(T1) depends on the difference in the heat capacities of the reactants and products—a difference that is normally small—in most cases, the reaction enthalpy depends only weakly on the temperature and, for small ranges of temperature, can be treated as a constant. ¢CP = anCP,m(products) - anCP,m(reactants) ¢H°(T2) = ¢H°(T1) + (T2 - T1)¢CP Enthalpy Reactants Products ⌬HЊ(T1) T1 T2 ⌬HЊ(T2) Temperature FIGURE 7.35 If the heat capacity of the reactants is larger than that of the products, the enthalpy of the reactants will increase more sharply with increasing temperature. If the reaction is exothermic, the reaction enthalpy will become more negative, as shown here. If the reaction is endothermic, the reaction enthalpy will become less positive and may even become negative. EXAMPLE 7.15 Predicting the reaction enthalpy at a different temperature The standard enthalpy of reaction of N2(g) ϩ 3 H2(g) : 2 NH3(g) is Ϫ92.22 kJ·molϪ1 at 298 K. The industrial synthesis takes place at 450.°C. What is the standard reaction enthalpy at the latter temperature? Anticipate There are more reactant molecules than product molecules, so we should suspect that the heat capacity of the products is less than that of the reactants, and therefore that ⌬CP is negative. If that is so, an increase in temperature will make ⌬H more negative and therefore the reaction more exothermic. 278 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW SKILLS YOU SHOULD HAVE MASTERED 279 What should we assume? That the heat capacities of reactants and products are constant over the temperature range of interest. SOLVE Evaluate The individual contributions of the changes in enthalpy of the reactants and products are depicted in Fig. 7.36. As we anticipated, ⌬CP is negative and the reaction is more exothermic at the higher temperature. Self-Test 7.19A The reaction enthalpy of 4 Al(s) ϩ 3 O2(g) : 2 Al2O3(s) is Ϫ3351 kJ at 298 K. Estimate its value at 1000.°C. [Answer: Ϫ3378 kJ] Self-Test 7.19B The standard enthalpy of formation of ammonium nitrate is Ϫ365.56 kJ·molϪ1 at 298 K. Estimate its value at 250.°C. The temperature variation of the standard reaction enthalpy is given by Kirchhoff’s law, Eq. 23, in terms of the difference in molar heat capacities at constant pressure between the products and the reactants. Calculate the difference in heat capacities. ⌬CP ϭ (2 mol)CP,m(NH3, g) Ϫ {(1 mol)CP,m(N2, g)ϩ(3 mol)CP,m(H2, g)} ϭ (2 mol)(35.06 J·KϪ1 ·molϪ1 ) Ϫ{(1 mol) (29.12 J·KϪ1 ·molϪ1 ) ϩ (3 mol)(28.82 J·KϪ1 ·molϪ1 )} ϭ Ϫ45.46 J·KϪ1 Evaluate T2 Ϫ T1. T2 Ϫ T1 ϭ (450 ϩ 273 K) Ϫ 298 K ϭ 425 K Calculate the enthalpy change at the final temperature from ⌬H°(T2) ϭ ⌬H°(T1) ϩ (T2 Ϫ T1)⌬CP ⌬H°(450 K) ϭ Ϫ92.22 kJ ϩ (425 K) ϫ (Ϫ45.46 J·KϪ1 ) ϭ Ϫ92.22 kJ Ϫ 1.932 ϫ 104 J ϭ Ϫ92.22 kJ Ϫ 19.32 kJ ϭ Ϫ111.54 kJ Enthlapy Temperature Ϫ111.54 Ϫ92.22 25ЊC 450ЊC 298 K (25°C) 723 K (450°C) 425 K −92.22 −111.54 N2 3 H2 2 NH3 Enthalpy(kJ•mol−1 ) Temperature 29.80 49.12 FIGURE 7.36 A depiction of the individual contributions to the change in standard reaction enthalpy for the reaction treated in Example 7.15. ❑ 1 Calculate the work done by a gas due to expansion (Examples 7.1 and 7.2). ❑ 2 Use the heat capacity of a substance to calculate the heat required to raise its temperature by a given amount (Example 7.3). ❑ 3 Calculate energy changes from calorimetry data and write a thermochemical equation (Examples 7.4 and 7.7). ❑ 4 State, and explain the implications of, the first law of thermodynamics (Sections 7.6–7.7). ❑ 5 Calculate the change in internal energy due to heat and work (Self-Test 7.5). ❑ 6 Calculate the work, heat, and change in internal energy when an ideal gas undergoes an isothermal expansion (Example 7.5). ❑ 7 Calculate the change in internal energy when an ideal gas is heated (Example 7.6). ❑ 8 Determine the enthalpy of vaporization (Self-Test 7.9). ❑ 9 Interpret the heating curve of a substance (Section 7.12). ❑ 10 Distinguish between the internal energy and the enthalpy of a process and describe how each is measured (Sections 7.8 and 7.14). ❑ 11 Determine the enthalpy change of a reaction, given the change in internal energy, and vice versa (Example 7.8). ❑ 12 Calculate an overall reaction enthalpy from the enthalpies of the reactions in a reaction sequence by using Hess’s law (Toolbox 7.1 and Example 7.9). SKILLS YOU SHOULD HAVE MASTERED ❑ 13 Calculate the heat output of a fuel (Example 7.10). ❑ 14 Use standard enthalpies of formation to calculate the standard enthalpy of a reaction, and vice versa (Examples 7.11 and 7.12). ❑ 15 Calculate a lattice enthalpy by using the Born–Haber cycle (Example 7.13). ❑ 16 Use average bond enthalpies to estimate the standard enthalpy of a reaction, (Example 7.14). ❑ 17 Predict the reaction enthalpy at a temperature different from that of the data (Example 7.15). EXERCISES Systems 7.1 Identify the following systems as open, closed, or isolated: (a) coffee in a very high quality thermos bottle; (b) coolant in a refrigerator coil; (c) a bomb calorimeter in which benzene is burned; (d) gasoline burning in an automobile engine; (e) mercury in a thermometer; (f) a living plant. 7.2 (a) Describe three ways in which you could increase the internal energy of an open system. (b) Which of these methods could you use to increase the internal energy of a closed system? (c) Which, if any, of these methods could you use to increase the internal energy of an isolated system? The First Law 7.3 Air in a bicycle pump is compressed by pushing in the handle. If the inner diameter of the pump is 3.0 cm and the pump is depressed 20. cm with a pressure of 2.00 atm, (a) how much work is done in the compression? (b) Is the work positive or negative with respect to the air in the pump? 7.4 Each of the four cylinders of a new type of combustion engine has a displacement of 3.60 L. (The volume of the cylinder expands 3.60 L each time the fuel is ignited.) (a) If each piston in the four cylinders is displaced against a pressure of 1.80 kbar and each cylinder is ignited once per second, how much work can the engine do in 1.00 minute? (b) Is the work positive or negative with respect to the engine and its contents? 7.5 A gas sample in a cylinder is supplied with 524 kJ of energy as heat. At the same time, a piston compresses the gas, doing 340 kJ of work. What is the change in internal energy of the gas during this process? 7.6 A gas sample in a piston assembly expands, doing 536 kJ of work on its surroundings at the same time that 214 kJ of heat is added to the gas. (a) What is the change in internal energy of the gas during this process? (b) Will the pressure of the gas be higher or lower when these changes are completed? 7.7 The internal energy of a system increased by 982 J when it absorbed 492 J of heat. (a) Was work done by or on the system? (b) How much work was done? 7.8 (a) Calculate the value of w for a system that releases 216 kJ of heat in a process for which the decrease in internal energy is 184 kJ. (b) Is work done on or by the system during this process? 7.9 A gas in a cylinder was placed in a heater and gained 5500 kJ of energy as heat. If the cylinder increased in volume from 345 mL to 1846 mL against an atmospheric pressure of 750. Torr during this process, what is the change in internal energy of the gas in the cylinder? 7.10 A 100.-W electric heater (1 W ϭ 1 J·s–1 ) operates for 10.0 min to heat the gas in a cylinder. At the same time, the gas expands from 2.00 L to 10.00 L against a constant atmospheric pressure of 0.975 atm. What is the change in internal energy of the gas? 7.11 In a combustion cylinder, the total internal energy change produced from the burning of a fuel is –2573 kJ. The cooling system that surrounds the cylinder absorbs 947 kJ as heat. How much work can be done by the fuel in the cylinder? 7.12 A laboratory animal exercised on a treadmill that was connected to a weight with a mass of 250 g through a pulley. The work done by the animal raised the weight through 1.32 m. At the same time the animal gave off 8.0 J of energy as heat. Disregarding any other losses and treating the animal as a closed system, what was the change in internal energy of the animal? 7.13 In an adiabatic process, no energy is transferred as heat. Indicate whether each of the following statements about an adiabatic process in a closed system is always true, always false, or true in certain conditions (specify the conditions): (a) ⌬U ϭ 0; (b) q ϭ 0; (c) q Ͻ 0; (d) ⌬U ϭ q; (e) ⌬U ϭ w. 7.14 Indicate whether each of the following statements about a process in a closed system with a constant volume is always true, always false, or true in certain conditions (specify the conditions): (a) ⌬U ϭ 0; (b) w ϭ 0; (c) w Ͻ 0; (d) ⌬U ϭ q; (e) ⌬U ϭ w. 7.15 Each of the pictures below shows a molecular view of a system undergoing a change at constant temperature. In each case, indicate whether heat is absorbed or given off by the system, whether expansion work is done on or by the system, and predict the signs of q and w for the process. 7.16 Each of the pictures below shows a molecular view of a system undergoing a change. In each case, indicate whether heat is absorbed or given off by the system, whether expansion work is done on or by the system, and predict the signs of q and w for the process. Solute (a) (b) SolutionSolvent Solid Gas Gas Solid Liquid Liquid (a) (b) Vapor 280 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW EXERCISES 281 7.17 (a) Calculate the heat that must be supplied to a 500.0-g copper kettle containing 400.0 g of water to raise its temperature from 22.0°C to the boiling point of water, 100.0°C. (b) What percentage of the heat is used to raise the temperature of the water? (See Table 7.2.) 7.18 (a) Calculate the heat that must be supplied to a 500.0-g stainless steel vessel containing 400.0 g of water to raise its temperature from 22.0°C to the boiling point of water, 100.0°C. (b) What percentage of the heat is used to raise the temperature of the water? (c) Compare these answers with those of Exercise 7.17. (See Table 7.2.) 7.19 A piece of copper of mass 20.0 g at 100.0°C is placed in a vessel of negligible heat capacity but containing 50.7 g of water at 22.0°C. Calculate the final temperature of the water. Assume that there is no energy lost to the surroundings. 7.20 A piece of metal of mass 20.0 g at 100.0°C is placed in a calorimeter containing 50.7 g of water at 22.0°C. The final temperature of the mixture is 25.7°C. What is the specific heat capacity of the metal? Assume that there is no energy lost to the surroundings. 7.21 A calorimeter was calibrated with an electric heater, which supplied 22.5 kJ of energy as heat to the calorimeter and increased the temperature of the calorimeter and its water bath from 22.45°C to 23.97°C. What is the heat capacity of the calorimeter? 7.22 The enthalpy of combustion of benzoic acid, C6H5COOH, which is often used to calibrate calorimeters, is –3227 kJ·molϪ1 . When 1.453 g of benzoic acid was burned in a calorimeter, the temperature increased by 2.265°C. What is the heat capacity of the calorimeter? 7.23 Calculate the work for each of the following processes beginning with a gas sample in a piston assembly with T ϭ 305 K, P ϭ 1.79 atm, and V ϭ 4.29 L: (a) irreversible expansion against a constant external pressure of 1.00 atm to a final volume of 6.52 L; (b) isothermal, reversible expansion to a final volume of 6.52 L. 7.24 A sample of gas in a cylinder of volume 3.42 L at 298 K and 2.57 atm expands to 7.39 L by two different pathways. Path A is an isothermal, reversible expansion. Path B has two steps. In the first step, the gas is cooled at constant volume to 1.19 atm. In the second step, the gas is heated and allowed to expand against a constant external pressure of 1.19 atm until the final volume is 7.39 L. Calculate the work for each path. Enthalpy 7.25 Which molecular substance do you expect to have the higher molar heat capacity, NO or NO2? Why? 7.26 Explain why the heat capacities of methane and ethane differ from the values expected for an ideal monatomic gas and from each other. The values of CP are 35.31 J·KϪ1 ·molϪ1 for CH4 and 52.63 J·KϪ1 ·molϪ1 for C2H6. 7.27 Calculate the heat released by 5.025 g of Kr(g) at 0.400 atm as it cools from 97.6°C to 25.0°C at (a) constant pressure and (b) constant volume. Assume that krypton behaves as an ideal gas. 7.28 Calculate the heat that must be supplied to 0.104 g of Ne(g) at 0.250 atm to raise its temperature from 22.0°C to 60.0°C at (a) constant pressure and (b) constant volume. Assume that neon behaves as an ideal gas. 7.29 Predict the contribution to the heat capacity CV,m made by molecular motions for each of the following atoms and molecules: (a) HCN; (b) C2H6; (c) Ar; (d) HBr. 7.30 Predict the contribution to the heat capacity CV,m made by molecular motions for each of the following molecules: (a) NO; (b) NH3; (c) HClO; (d) SO2. 7.31 In a microwave oven, radiation is absorbed by water in the food and the food is heated. How many photons of wavelength 4.50 mm are required to heat 350. g of water from 25.0°C to 100.0°C, assuming all the energy is used to raise the temperature? 7.32 Samples consisting of 1 mol N2 and 1 mol CH4 are in identical but separate containers, with initial temperatures of 500. K. Both gases gain 1200. J of heat at constant volume. Do the gases have the same final temperature? If not, which gas has the higher final temperature? Justify your reasoning. 7.33 The high-temperature contribution of vibrational modes to the molar heat capacity of a solid at constant volume is R for each mode of vibrational motion. Hence, for a monatomic solid, the molar heat capacity at constant volume is approximately 3R. (a) The specific heat capacity of a certain monatomic solid is 0.392 J·KϪ1 ·gϪ1 . The chloride of this element (XCl2) is 52.7% chlorine by mass. Identify the element. (b) This element crystallizes in a face-centered cubic unit cell and its atomic radius is 128 pm. What is the density of this solid? 7.34 Estimate the molar heat capacity (at constant volume) of sulfur dioxide gas. In addition to translational and rotational motion, there is vibrational motion. Each vibrational degree of freedom contributes R to the molar heat capacity. The temperature needed for the vibrational modes to be accessible can be approximated by ϭ h␯vib/k, where k is Boltzmann’s constant. The vibrational modes have frequencies 3.5 ϫ 1013 Hz, 4.1 ϫ 1013 Hz, and 1.6 ϫ 1013 Hz. (a) What is the high-temperature limit of the molar heat capacity at constant volume? (b) What is the molar heat capacity at constant volume at 1000. K? (c) What is the molar heat capacity at constant volume at room temperature? 7.35 (a) At its boiling point, the vaporization of 0.579 mol CH4(l) requires 4.76 kJ of heat. What is the enthalpy of vaporization of methane? (b) An electric heater was immersed in a flask of boiling ethanol, C2H5OH, and 22.45 g of ethanol was vaporized when 21.2 kJ of energy was supplied. What is the enthalpy of vaporization of ethanol? 7.36 (a) When 25.23 g of methanol, CH3OH, froze, 4.01 kJ of heat was released. What is the enthalpy of fusion of methanol? (b) A sample of benzene was vaporized at 25°C. When 37.5 kJ of heat was supplied, 95 g of the liquid benzene vaporized. What is the enthalpy of vaporization of benzene at 25°C? 7.37 How much heat is needed to convert 80.0 g of ice at 0.0°C into liquid water at 20.0°C (see Tables 7.2 and 7.3)? 7.38 If we start with 325 g of water at 30.°C, how much heat must we add to convert all the liquid into vapor at 100.°C (see Tables 7.2 and 7.3)? 7.39 A 50.0-g ice cube at 0.0°C is added to a glass containing 400.0 g of water at 45.0°C. What is the final temperature of the system (see Tables 7.2 and 7.3)? Assume that no heat is lost to the surroundings. u 7.40 When 25.0 g of a metal at 90.0°C is added to 50.0 g of water at 25.0°C, the temperature of the water rises to 29.8°C. What is the specific heat capacity of the metal (see Table 7.2)? 7.41 The following data were collected for a new compound used in cosmetics: ⌬Hfus ϭ 10.0 kJ·molϪ1 , ⌬Hvap ϭ 20.0 kJ·molϪ1 ; heat capacities: 30 J·molϪ1 for the solid; 60 J·molϪ1 for the liquid; 30 J·molϪ1 for the gas. Which heating curve below best matches the data for this compound? 7.42 Use the following information to construct a heating curve for bromine from Ϫ7.2°C to 70.0°C. The molar heat capacity of liquid bromine is 75.69 J·KϪ1 ·molϪ1 and that of bromine vapor is 36.02 J·KϪ1 ·molϪ1 . The enthalpy of vaporization of liquid bromine is 30.91 kJ·molϪ1 . Bromine melts at Ϫ7.2°C and boils at 58.78°C. Reaction Enthalpies 7.43 Carbon disulfide can be prepared from coke (an impure form of carbon) and elemental sulfur: 4 C(s) ϩ S8(s) 4 CS2(l) ⌬H° ϭ ϩ358.8 kJ How much heat is absorbed in the reaction of 1.25 mol S8? (b) Calculate the heat absorbed in the reaction of 197 g of carbon with an excess of sulfur. (c) If the heat absorbed in the reaction was 415 kJ, how much CS2 was produced? 7.44 The oxidation of nitrogen in the hot exhaust of jet engines and automobiles occurs by the reaction N2(g) ϩ O2(g) 2 NO(g) ⌬H° ϭ ϩ180.6 kJ How much heat is absorbed in the formation of 1.55 mol NO? (b) How much heat is absorbed in the oxidation of 5.45 L of nitrogen measured at 1.00 atm and 273 K? (c) When the oxidation of N2 to NO was completed in a bomb calorimeter, the heat absorbed was measured as 492 J. What mass of nitrogen gas was oxidized? 7.45 The combustion of octane is expressed by the thermochemical equation Estimate the mass of octane that would need to be burned to produce enough heat to raise the temperature of the air in a 12 ft ϫ 12 ft ϫ 8.0 ft room from 40.°F to 78°F on a mild winter’s day. Use the normal composition of air to determine its density and assume a pressure of 1.00 atm. (b) How much heat will be evolved from the combustion of 1.0 gal of gasoline (assumed to be exclusively octane)? The density of octane is 0.70 g·mLϪ1 . 7.46 Coal-fired steam engines get their power by using the heat from burning coal to boil water. Suppose that coal of density 1.5 g·cmϪ3 is carbon (it is, in fact, much more complicated, but this is a reasonable first approximation). The combustion of carbon is described by the equation C(s) ϩ O2(g) CO2(g) ⌬H° ϭ –394 kJ Calculate the heat produced when a lump of coal of size 7.0 cm ϫ 6.0 cm ϫ 5.0 cm is burned. (b) Estimate the mass of water that can be heated from 25°C to 100.°C by burning this piece of coal. 7.47 A student rides a bicycle to class every day, a 10.-mile round trip that takes 30. minutes in each direction. The student burns 1250 kJ·hϪ1 cycling. The same round trip in an automobile would require 0.40 gallons of gasoline. Assume that the student goes to class 150 days per year and that the enthalpy of combustion of gasoline can be approximated by that of octane, which has a density of 0.702 g·cmϪ3 (3.785 L ϭ 1.000 gal). What is the yearly energy requirement of this journey by (a) bicycle and (b) automobile? 7.48 Calculate the heat generated by a reaction mixture of 13.4 L of sulfur dioxide at 1.00 atm and 273 K and 15.0 g of oxygen in the reaction 2 SO2(g) ϩ O2(g) 2 SO3(g) ⌬H° ϭ –198 kJ 7.49 For a certain reaction at constant pressure, ⌬H ϭ Ϫ15 kJ, and 22 kJ of expansion work is done on the system. What is ⌬U for this process? 7.50 For a certain reaction at constant pressure, ⌬U ϭ Ϫ72 kJ, and 35 kJ of expansion work is done by the system. What is ⌬H for this process? 7.51 Oxygen difluoride is a colorless, very poisonous gas that reacts rapidly with water vapor to produce O2, HF, and heat: OF2(g) ϩ H2O(g) O2(g) ϩ 2HF(g) ⌬H ϭ Ϫ318 kJ What is the change in internal energy for the reaction of 1.00 mol OF2? 7.52 One step in the production of hydrogen as a fuel is the reaction of methane with water vapor: CH4(g) ϩ H2O(g) CO2(g) ϩ 3 H2(g) ⌬H ϭ Ϫ318 kJ What is the change in internal energy for the production of 1.00 mol H2? 7.53 Hydrochloric acid oxidizes zinc metal in a reaction that produces hydrogen gas and chloride ions. A piece of zinc metal of mass 8.5 g is dropped into an apparatus containing 800.0 mL of 0.500 M HCl(aq). If the initial temperature of the hydrochloric acid solution is 25°C, what is the final temperature of this solution? Assume that the density and molar heat capacity of the hydrochloric acid solution are the same as those of water and that all the heat is used to raise the temperature of the solution. 7.54 “Synthesis gas” is a mixture of carbon monoxide, hydrogen, methane, and some noncombustible gases. A certain synthesis gas is 40.0% by volume carbon monoxide, 25.0% hydrogen gas, 10.0% noncombustible gases, and the rest methane. What volume of this gas must be burned to raise the temperature of 5.5 L of water by 5°C? Assume the gas is at 1.0 atm and 298 K and that all three gases are completely oxidized in the combustion. ¡ Ni ¡ ¡ ¡ ¢H° = -5471 kJ C8H18(l) + 25 2 O2(g) ¡ 8 CO2(g) + 9 H2O(l) ¡ ¡ Heat supplied Temperature Heat supplied Heat supplied Heat supplied Temperature Temperature Temperature (a) (b) (c) (d) 282 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW EXERCISES 283 7.55 The enthalpy of formation of trinitrotoluene (TNT) is Ϫ67 kJ·molϪ1 , and the density of TNT is 1.65 g·cmϪ3 . In principle, it could be used as a rocket fuel, with the gases resulting from its decomposition streaming out of the rocket to give the required thrust. In practice, of course, it would be extremely dangerous as a fuel because it is sensitive to shock. Explore its potential as a rocket fuel by calculating its enthalpy density (enthalpy released per liter) for the reaction 4 C7H5N3O6(s) ϩ 21 O2(g) 28 CO2(g) ϩ 10 H2O(g) ϩ 6 N2(g) 7.56 A natural gas mixture is burned in a furnace at a powergenerating station at a rate of 13.0 mol per minute. (a) If the fuel consists of 9.3 mol CH4, 3.1 mol C2H6, 0.40 mol C3H8, and 0.20 mol C4H10, what mass of CO2(g) is produced per minute? (b) How much heat is released per minute? 7.57 The reaction of 1.40 g of carbon monoxide with excess water vapor to produce carbon dioxide and hydrogen gases in a bomb calorimeter causes the temperature of the calorimeter assembly to rise from 22.113°C to 22.799°C. The calorimeter assembly is known to have a total heat capacity of 3.00 kJ·(°C)Ϫ1 . (a) Write a balanced equation for the reaction. (b) Calculate the internal energy change, ⌬U, for the reaction of 1.00 mol CO(g). 7.58 Benzoic acid has a known internal energy of combustion (Ϫ3251 kJ·molϪ1 ). When a bomb calorimeter was calibrated by burning 0.825 g of benzoic acid in oxygen, the temperature rose 1.94°C. A 0.727-g sample of the sugar D-ribose (C5H10O5) was then burned in excess oxygen in the same calorimeter, forming gaseous CO2 and liquid H2O. The temperature of the calorimeter rose from 21.81°C to 22.72°C. (a) Write a balanced equation for the combustion. (b) Calculate the internal energy change, ⌬U, for the combustion of 1.00 mol ribose molecules. Hess’s Law 7.59 The standard enthalpies of combustion of graphite and diamond are Ϫ393.51 kJ·molϪ1 and Ϫ395.41 kJ·molϪ1 , respectively. Calculate the enthalpy of the graphite : diamond transition. 7.60 Elemental sulfur exists in several forms, with rhombic sulfur the most stable under normal conditions and monoclinic sulfur slightly less stable. The standard enthalpies of combustion of the two forms (to sulfur dioxide) are Ϫ296.83 kJ·molϪ1 and Ϫ297.16 kJ·molϪ1 , respectively. Calculate the enthalpy of the rhombic : monoclinic transition. 7.61 Barium metal is produced by the reaction of aluminum metal with barium oxide. From the standard reaction enthalpies 2 Ba(s) ϩ O2(g) 2 BaO(s) ⌬H° ϭ Ϫ1107 kJ 2 Al(s) ϩ O2(g) Al2O3(s) ⌬H° ϭ Ϫ1676 kJ calculate the reaction enthalpy for the production of metallic barium in the reaction: 3 BaO(s) ϩ 2 Al(s) Al2O3(s) ϩ 3 Ba(s) 7.62 In the manufacture of nitric acid by the oxidation of ammonia, the first product is nitric oxide, which is then oxidized to nitrogen dioxide. From the standard reaction enthalpies N2(g) ϩ O2(g) 2 NO(g) ⌬H° ϭ ϩ180.5 kJ N2(g) ϩ 2 O2(g) 2 NO2(g) ⌬H° ϭ ϩ66.4 kJ¡ ¡ ¡ ¢ ¡3 2 ¡ ¡ calculate the standard reaction enthalpy for the oxidation of nitric oxide to nitrogen dioxide: 2 NO(g) ϩ O2(g) 2 NO2(g) 7.63 Determine the reaction enthalpy for the hydrogenation of ethyne to ethane, C2H2(g) ϩ 2 H2(g) : C2H6(g), from the following data: ⌬Hc°(C2H2, g) ϭ Ϫ1300. kJ·molϪ1 , ⌬Hc°(C2H6, g) ϭ Ϫ1560. kJ·molϪ1 , ⌬Hc°(H2, g) ϭ Ϫ286 kJ·molϪ1 . 7.64 Determine the enthalpy for the partial combustion of methane to carbon monoxide, 2 CH4(g) ϩ 3 O2(g) : 2 CO(g) ϩ 4 H2O(l), from ⌬Hc°(CH4, g) ϭ Ϫ890. kJ·molϪ1 and ⌬Hc°(CO, g) ϭ Ϫ283.0 kJ·molϪ1 . 7.65 Use the data provided in Appendix 2A to calculate the standard reaction enthalpy for the reaction of pure nitric acid with hydrazine: 4 HNO3(l) ϩ 5 N2H4(l) 7 N2(g) ϩ 12 H2O(l) 7.66 Use the data provided in Appendix 2A to calculate the standard reaction enthalpy for the reaction of calcite with hydrochloric acid: CaCO3(s) ϩ 2 HCl(aq) CaCl2(aq) ϩ H2O(l) ϩ CO2(g) 7.67 Calculate the reaction enthalpy for the synthesis of hydrogen chloride gas, H2(g) ϩ Cl2(g) : 2 HCl(g), from the following data: NH3(g) ϩ HCl(g) NH4Cl(s) ⌬H° ϭ Ϫ176.0 kJ N2(g) ϩ 3 H2(g) 2 NH3(g) ⌬H° ϭ Ϫ92.22 kJ N2(g) ϩ 4 H2(g) ϩ Cl2(g) 2 NH4Cl(s) ⌬H° ϭ Ϫ628.86 kJ 7.68 Calculate the reaction enthalpy for the formation of anhydrous aluminum chloride, 2 Al(s) ϩ 3 Cl2(g) : 2 AlCl3(s), from the following data: 2 Al(s) ϩ 6 HCl(aq) 2 AlCl3(aq) ϩ 3 H2(g) ⌬H° ϭ Ϫ1049 kJ HCl(g) HCl(aq) ⌬H° ϭ Ϫ74.8 kJ H2(g) ϩ Cl2(g) 2 HCl(g) ⌬H° ϭ Ϫ185 kJ AlCl3(s) AlCl3(aq) ⌬H° ϭ Ϫ323 kJ 7.69 Calculate the reaction enthalpy for the synthesis of hydrogen bromide gas, H2(g) ϩ Br2(l) : 2 HBr(g), from the following data: NH3(g) ϩ HBr(g) NH4Br(s) ⌬H° ϭ Ϫ188.32 kJ N2(g) ϩ 3 H2(g) 2 NH3(g) ⌬H° ϭ Ϫ92.22 kJ N2(g) ϩ 4 H2(g) ϩ Br2(l) 2 NH4Br(s) ⌬H° ϭ Ϫ541.66 kJ 7.70 Calculate the reaction enthalpy for the formation of anhydrous aluminum bromide, 2 Al(s) ϩ 3 Br2(l) : 2 AlBr3(s), from the following data: 2 Al(s) ϩ 6 HBr(aq) 2 AlBr3(aq) ϩ 3 H2(g) ⌬H° ϭ Ϫ1061 kJ HBr(g) HBr(aq) ⌬H° ϭ Ϫ81.15 kJ H2(g) ϩ Br2(l) 2 HBr(g) ⌬H° ϭ Ϫ72.80 kJ AlBr3(s) AlBr3(aq) ⌬H° ϭ Ϫ368 kJ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ Standard Enthalpies of Formation 7.71 Calculate the standard enthalpy of formation of dinitrogen pentoxide from the following data 2 NO(g) ϩ O2(g) 2 NO2(g) ⌬H° ϭ Ϫ114.1 kJ 4 NO2(g) ϩ O2(g) 2 N2O5(g) ⌬H° ϭ Ϫ110.2 kJ and from the standard enthalpy of formation of nitric oxide, NO (see Appendix 2A). 7.72 An important reaction that takes place in the atmosphere is NO2(g) : NO(g) ϩ O(g), which is brought about by sunlight. How much energy must be supplied by the Sun to cause it? Calculate the standard enthalpy of the reaction from the following information O2(g) 2 O(g) ⌬H° ϭ ϩ498.4 kJ NO(g) ϩ O3(g) NO2(g) ϩ O2(g) ⌬H° ϭ Ϫ200. kJ and from additional information in Appendix 2A. 7.73 Calculate the standard enthalpy of formation of PCl5(s) from the standard enthalpy of formation of PCl3(l) (see Appendix 2A) and PCl3(l) ϩ Cl2(g) : PCl5(s), ⌬H° ϭ Ϫ124 kJ. 7.74 Using standard enthalpies of formation from Appendix 2A, calculate the standard reaction enthalpy for each of the following reactions: (a) the final stage in the production of nitric acid: 3 NO2(g) ϩ H2O(l) 2 HNO3(aq) ϩ NO(g) (b) the industrial synthesis of boron trifluoride: B2O3(s) ϩ 3 CaF2(s) 2 BF3(g) ϩ 3 CaO(s) (c) the formation of a sulfide by the action of hydrogen sulfide on an aqueous solution of a base: H2S(aq) ϩ 2 KOH(aq) K2S(aq) ϩ 2 H2O(l) 7.75 Use the information in Tables 7.3, 7.7, and 7.8 to estimate the enthalpy of formation of each of the following compounds in the liquid state. The standard enthalpy of sublimation of carbon is ϩ717 kJ·molϪ1 . (a) H2O; (b) methanol, CH3OH; (c) benzene, C6H6 (without resonance); (d) benzene, C6H6 (with resonance). 7.76 Use the information in Tables 7.3, 7.7, and 7.8 to estimate the enthalpy of formation of each of the following compounds in the liquid state. The standard enthalpy of sublimation of carbon is ϩ717 kJ·molϪ1 . (a) NH3; (b) ethanol, CH3CH2OH; (c) acetone, CH3COCH3. The Born–Haber Cycle 7.77 Use Fig. 1.54, Appendix 2A, Appendix 2D, and the following data to calculate the lattice enthalpy of Na2O: ⌬Hf°(Na2O) ϭ Ϫ409 kJ·molϪ1 ; ⌬Hf°(O, g) ϭ ϩ249 kJ·molϪ1 . 7.78 Use Fig. 1.54, Appendix 2A, Appendix 2D, and the following data to calculate the lattice enthalpy of AlCl3: ⌬Hf°(Al, g) ϭ ϩ326 kJ·molϪ1 . 7.79 Complete the following table (all values are in kilojoules per mole). Ionization Electron Compound ⌬Hf ° energy ⌬Hf ° affinity ⌬HL ⌬Hf ° MX M(g) M X(g) X MX MX(s) (a) NaCl 108 494 122 ϩ349 787 ? (b) KBr 89 418 97 ϩ325 ? –394 (c) RbF ? 402 79 ϩ328 774 –558 7.80 By assuming that the lattice enthalpy of NaCl2 is the same as that of MgCl2, use enthalpy arguments based on data in Appendix 2A, Appendix 2D, and Fig. 1.54 to explain why NaCl2 is an unlikely compound. Bond Enthalpies 7.81 Use the bond enthalpies in Tables 7.7 and 7.8 to estimate the reaction enthalpy for (a) 3 C2H2(g) C6H6(g) (b) CH4(g) ϩ 4 Cl2(g) CCl4(g) ϩ 4 HCl(g) (c) CH4(g) ϩ CCl4(g) CHCl3(g) ϩ CH3Cl(g) 7.82 Use the bond enthalpies in Tables 7.7 and 7.8 to estimate the reaction enthalpy for (a) HCl(g) ϩ F2(g) HF(g) ϩ ClF(g), given that ⌬HB(ClßF) ϭ –256 kJ·molϪ1 (b) C2H4(g) ϩ HCl(g) CH3CH2Cl(g) (c) C2H4(g) ϩ H2(g) CH3CH3(g) 7.83 Use the bond enthalpies in Tables 7.7 and 7.8 to estimate the reaction enthalpy for (a) N2(g) ϩ 3 F2(g) 2 NF3(g) (b) CH3CH CH2(g) ϩ H2O(g) CH3CH(OH)CH3(g) (c) CH4(g) ϩ Cl2(g) CH3Cl(g) ϩ HCl(g) 7.84 The bond enthalpy in NO is 632 kJ·molϪ1 and that of each NßO bond in NO2 is 469 kJ·molϪ1 . Using Lewis structures and the mean bond enthalpies given in Table 7.8, explain (a) the difference in bond enthalpies between the two molecules; (b) the fact that the bond enthalpies of the two bonds in NO2 are the same. 7.85 Benzene is more stable and less reactive than would be predicted from its Kekulé structures. Use the mean bond enthalpies in Table 7.8 to calculate the lowering in molar energy when resonance is allowed between the Kekulé structures of benzene. 7.86 Investigate whether the replacement of a carbon–carbon double bond by single bonds is energetically favored by using Tables 7.7 and 7.8 to calculate the reaction enthalpy for the conversion of ethene, C2H4, to ethane, C2H6. The reaction is H2C CH2(g) ϩ H2(g) : CH3—CH3(g). The Variation of Reaction Enthalpy with Temperature 7.87 (a) From the data in Appendix 2A, calculate the enthalpy of vaporization of benzene (C6H6) at 298.2 K. The standard enthalpy of formation of gaseous benzene is ϩ82.93 kJ·molϪ1 . (b) Given that, for liquid benzene, CP,m ϭ 136.1 J·molϪ1 ·KϪ1 and that, for gaseous benzene, CP,m ϭ 81.67 J·molϪ1 ·KϪ1 , calculate the enthalpy of vaporization of benzene at its boiling point (353.2 K). (c) Compare the value obtained in part (b) with that found in Table 7.3. What is the source of difference between these numbers? “ ¡ ¡“ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ 284 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW EXERCISES 285 7.88 (a) From the data in Appendix 2A, calculate the enthalpy required to vaporize 1 mol CH3OH(l) at 298.2 K. (b) Given that the molar heat capacity, CP,m, of liquid methanol is 81.6 J·KϪ1 ·molϪ1 and that of gaseous methanol is 43.89 J·KϪ1 ·molϪ1 , calculate the enthalpy of vaporization of methanol at its boiling point (64.7°C). (c) Compare the value obtained in part (b) with that found in Table 7.3. What is the source of difference between these values? 7.89 Derive Kirchhoff’s law for a reaction of the form A ϩ 2 B : 3 C ϩ D by considering the change in molar enthalpy of each substance when the temperature is increased from T1 to T2. 7.90 Use the estimates of molar constant-volume heat capacities given in the text (as multiples of R) to estimate the change in reaction enthalpy of N2(g) ϩ 3 H2(g) : 2 NH3(g) when the temperature is increased from 300. K to 500. K. Ignore the vibrational contributions to heat capacity. Is the reaction more or less exothermic at the higher temperature? Integrated Exercises 7.91 How much heat is required to convert a 42.30-g block of ice at Ϫ5.042°C into water vapor at 150.35°C? 7.92 A 155.7-g piece of stainless steel was heated to 475°C and quickly added to 25.34 g of ice at Ϫ24°C in a well-insulated flask that was immediately sealed. (a) If there is no loss of energy to the surroundings, what will be the final temperature of this system? (b) What phases of water will be present and in what quantities when the system reaches its final temperature? 7.93 Crude petroleum is often contaminated by poisonous hydrogen sulfide gas. The Claus process for the extraction of sulfur from petroleum has two steps: 2 H2S(g) ϩ 3 O2(g) 2 SO2(g) ϩ 2 H2O(l) 2 H2S(g) ϩ SO2(g) 3 S(s) ϩ 2 H2O(l) (a) Write a thermochemical equation for the overall reaction that does not contain SO2. (b) What enthalpy change would be associated with the production of 60.0 kg of sulfur? (c) Would the reactor need to be cooled or heated to maintain a constant temperature? 7.94 A reaction being studied to regenerate oxygen from carbon dioxide on long spaceflights takes place in the following two steps: CO2(g) ϩ 2 H2(g) C(s) ϩ 2 H2O(l) 2 H2O(l) 2 H2(g) ϩ O2(g) (a) Write the thermochemical equation for the overall reaction. (b) What enthalpy change would be associated with the production of 45.0 L of oxygen at 0.80 atm and 300 K? (c) Would the reactor need to be cooled or heated to maintain a constant temperature? 7.95 The heat capacity of liquid iodine is 80.7 J·KϪ1 ·molϪ1 , and the enthalpy of vaporization of iodine is 41.96 kJ·molϪ1 at its boiling point (184.3°C). Using these facts and information in Appendix 2A, calculate the enthalpy of fusion of iodine at 25°C. 7.96 A typical bathtub can hold 100. gallons of water. (a) Calculate the mass of natural gas that would need to be burned to heat the water for a tub of this size from 65°F to 108°F. Assume that the natural gas is pure methane, CH4. (b) What volume of natural gas does this correspond to at 25°C and 1.00 atm? See Table 7.4. 7.97 In 1750 Joseph Black performed an experiment that eventually led to the discovery of enthalpies of fusion. He placed two 150.-g samples of water at 0.00°C (one ice and one liquid) in a room kept at a constant temperature of 5.00°C. He then observed how long it took for each sample to warm to its final temperature. The liquid sample reached 5.00°C after 30.0 min. However, the ice took 10.5 h to reach 5.00°C. He concluded that the difference in time that the two samples required to reach the same final temperature represented the difference in heat required to raise the temperatures of the samples. Use Black’s data to calculate the enthalpy of fusion of ice in kJ·molϪ1 . Use the known heat capacity of liquid water. 7.98 (a) Calculate the work associated with the isothermal, reversible expansion of 1.000 mol of an ideal gas from 7.00 L to 15.50 L at 25.0°C. (b) Calculate the work associated with the irreversible adiabatic expansion of the sample of gas described in part (a) against a constant atmospheric pressure of 760. Torr. (c) How will the temperature of the gas in part (b) compare with that in part (a) after the expansion? 7.99 Aniline, C6H5NH2(l), is a derivative of benzene in which a hydrogen atom has been replaced by an NH2 group. (a) Write the balanced equation for the combustion of aniline. (b) What is the mass of each product when 0.1754 g of aniline is burned in excess oxygen? (c) If the bomb calorimeter in which this reaction was carried out had a volume of 355 mL, what minimum pressure of oxygen at 23°C must have been used to ensure complete combustion? Assume that the volume of the aniline is negligible. 7.100 Calculate the work done by the reaction described in Exercise 7.53 and report it with the correct sign. Assume reaction is open to the surroundings at a constant external pressure of 1.0 atm and 25°C. 7.101 (a) Is the production of water gas (a cheap, low-grade industrial fuel) exothermic or endothermic? The reaction is C(s) ϩ H2O(g) CO(g) ϩ H2(g). (b) Calculate the enthalpy change for the production of 200. L of hydrogen at 500. Torr and 65°C by this reaction. 7.102 The ABC cereal company is developing a new type of breakfast cereal to compete with a rival product that they call Brand X. You are asked to compare the energy content of the two cereals to see if the new ABC product is lower in calories; so you burn 1.00-g samples of the cereals in oxygen in a calorimeter with a heat capacity of 600. J·(°C)Ϫ1 . When the Brand X cereal sample burned, the temperature rose from 300.2 K to 309.0 K. When the ABC cereal sample burned, the temperature rose from 299.0 K to 307.5 K. (a) What is the heat output of each sample? (b) One serving of each cereal is 30.0 g. How would you label the packages of the two cereals to indicate the fuel value per 30.0-g serving in joules? in nutritional Calories (kilocalories)? 7.103 An experimental automobile burns hydrogen for fuel. At the beginning of a test drive, the rigid 30.0-L tank was filled with hydrogen at 16.0 atm and 298 K. At the end of the drive, the temperature of the tank was still 298 K, but its pressure was 4.0 atm. (a) How many moles of H2 were burned during the drive? (b) How much heat, in kilojoules, was given off by the combustion of that amount of hydrogen? 7.104 In hot, dry climates an inexpensive alternative to air conditioning is the swamp cooler. In this device water continuously wets porous pads through which fans blow the hot air. The air is cooled as the water evaporates. Use the information in Tables 7.2 and 7.3 to determine how much water must be evaporated to cool the air in a room of dimensions 4.0 m ϫ 5.0 m ϫ 3.0 m by 20.°C. Assume that the enthalpy of vaporization of water is the same as it is at 25°C. ¡ ¡ ¡ ¡ ¡ 7.105 (a) Calculate the work that must be done against the atmosphere for the expansion of the gaseous products in the combustion of 1.00 mol C6H6(l) at 25°C and 1.00 bar. (b) Using data in Appendix 2A, calculate the standard enthalpy of the reaction. (c) Calculate the change in internal energy, ⌬U°, of the system. 7.106 A system undergoes a two-step process. In step 1, it absorbs 50. J of heat at constant volume. In step 2, it releases 5 J of heat at 1.00 atm as it is returned to its original internal energy. Find the change in the volume of the system during the second step and identify it as an expansion or compression. 7.107 Consider the hydrogenation of benzene to cyclohexane, which takes place by the step-by-step addition of two H atoms per step: (1) C6H6(l) ϩ H2(g) C6H8(l) ⌬H° ϭ ? (2) C6H8(l) ϩ H2(g) C6H10(l) ⌬H° ϭ ? (3) C6H10(l) ϩ H2(g) C6H12(l) ⌬H° ϭ ? Draw Lewis structures for the products of the hydrogenation of benzene. If resonance is possible, show only one resonance structure. (b) Use bond enthalpies to estimate the enthalpy changes of each step and the total hydrogenation. Ignore the delocalization of electrons in this calculation and the fact that the compounds are liquids. (c) Use data from Appendix 2A to calculate the enthalpy of the complete hydrogenation of benzene to cyclohexane. (d) Compare the value obtained in part (c) with that obtained in part (b). Explain any difference. 7.108 Draw the Lewis structure for the hypothetical molecule N6, consisting of a six-membered ring of nitrogen atoms. Using bond enthalpies, calculate the enthalpy of reaction for the decomposition of N6 to N2(g). Do you expect N6 to be a stable molecule? 7.109 Robert Curl, Richard Smalley, and Harold Kroto were awarded the Nobel prize in chemistry in 1996 for the discovery of the soccer-ball-shaped molecule C60. This fundamental molecule was the first of a new series of molecular allotropes of carbon. The enthalpy of combustion of C60 is Ϫ25 937 kJ·molϪ1 , and its enthalpy of sublimation is ϩ233 kJ·molϪ1 . There are 90 bonds in C60, of which 60 are single bonds and 30 are double bonds. Like benzene, C60 has a set of multiple bonds for which resonance structures may be drawn. (a) Determine the enthalpy of formation of C60 from its enthalpy of combustion. (b) Calculate the expected enthalpy of formation of C60 from bond enthalpies, assuming the bonds to be isolated double and single bonds. (c) Is C60 more or less stable than predicted on the basis of the isolated-bond model? (d) Quantify the answer to part (c) by dividing the difference between the enthalpy of formation calculated from the combustion data and that obtained from the bond enthalpy calculation by 60 to obtain a per carbon value. (e) How does the number in part (d) compare with the per carbon resonance stabilization energy of benzene (the total resonance stabilization energy of benzene is approximately 150 kJ·molϪ1 )? (f) Why might these values differ? The enthalpy of atomization of C(gr) is ϩ717 kJ·molϪ1 . 7.110 Normally, when sulfur is oxidized, the product is SO2, but SO3 may also be formed. When 0.6192 g of sulfur was burned, by using ultrapure oxygen in a bomb calorimeter with a heat capacity of 5.270 kJ·(°C)Ϫ1 , the temperature rose 1.140°C. Assuming that all the sulfur was consumed in the reaction, what was the ratio of sulfur dioxide to sulfur trioxide produced? 7.111 Speculate as to whether the combustion of 1,3,5trinitrobenzene, C6H3(NO2)3, or the combustion of 1,3,5triaminobenzene, C6H3(NH2)3, would be more exothermic. Support your answer with appropriate calculations. 7.112 Rank the following compounds in order of increasing enthalpy of vaporization: CH4, H2O, N2, NaCl, C6H6, and H2. Do not look up the enthalpy of vaporization. Explain your ordering. 7.113 A technician carries out the reaction 2 SO2(g) ϩ O2(g) : 2 SO3(g) at 25°C and 1.00 atm in a constant-pressure cylinder fitted with a piston. Initially, 0.030 mol SO2 and 0.030 mol O2 are present in the cylinder. The technician then adds a catalyst to initiate the reaction. (a) Calculate the volume of the cylinder containing the reactant gases before reaction begins. (b) What is the limiting reactant? (c) Assuming that the reaction goes to completion and that the temperature and pressure of the reaction remain constant, what is the final volume of the cylinder (include any excess reactant)? (d) How much work takes place, and is it done by the system or on the system? (e) How much enthalpy is exchanged, and does it leave or enter the system? (f) From your answers to parts (d) and (e), calculate the change in internal energy for the reaction. 7.114 In Section 7.3 we saw how to calculate the work of reversible, isothermal expansion of a perfect gas. Now suppose that the reversible expansion is not isothermal and that the temperature decreases during expansion. (a) Derive an expression for the work when T ϭ Tinitial Ϫ c(V Ϫ Vinitial), with c a positive constant. (b) Is the work in this case greater or smaller than that of isothermal expansion? Explain your observation. Chemistry Connections 7.115 Petroleum based fuels create large amounts of pollution, contribute to climate change, and are becoming scarce. Consequently, alternative fuels are being sought (see Box 7.2). Three compounds that could be produced biologically and used as fuels are methane, CH4, which can be produced from the anaerobic digestion of sewage; dimethyl ether, H3CßOßCH3, a gas that can be produced from methanol and ethanol; and ethanol, CH3CH2OH, a liquid obtained from the fermentation of sugars. (a) Draw the Lewis structure of each compound. (b) Use bond enthalpies (and, for ethanol, its enthalpy of vaporization) to calculate the enthalpy of combustion of each fuel, assuming that they burn to produce gaseous CO2 and gaseous H2O. Explain any differences. (c) Use the values for the enthalpies of combustion of organic compounds found in Appendix 2A to compare methane and ethanol with octane, a primary constituent of gasoline, as fuels by calculating the specific enthalpy (heat produced per gram) of each fuel. On the basis of this information, which would you choose as a fuel? (d) What volume of methane gas at 10.00 atm and 298 K would you need to burn at constant pressure to produce the same amount of heat as 10.00 L of octane (the density of octane is 0.70 g·mLϪ1 )? (e) A problem with fuels containing carbon is that they produce carbon dioxide when they burn, and so a consideration governing the selection of a fuel could be the heat per mole of CO2 produced. Calculate this quantity for methane, ethanol, and octane. Which process produces more carbon dioxide in the environment for each kilojoule generated? ¡ ¡ ¡ 286 CHAPTER 7 THERMODYNAMICS: THE FIRST LAW 287 What Are the Key Ideas? The direction of natural change corresponds to the increasing disorder of energy and matter. Disorder is measured by the thermodynamic quantity called entropy. A related quantity—the Gibbs free energy—provides a link between thermodynamics and the description of chemical equilibrium. Why Do We Need to Know This Material? The second law of thermodynamics is the key to understanding why one chemical reaction has a natural tendency to occur but another one does not. We apply the second law by using the very important concepts of entropy and Gibbs free energy. The third law of thermodynamics is the basis of the numerical values of these two quantities. The second and third laws jointly provide a way to predict the effects of changes in temperature and pressure on physical and chemical processes. They also lay the thermodynamic foundations for discussing chemical equilibrium, which the following chapters explore in detail. What Do We Need to Know Already? The discussion draws on concepts related to the first law of thermodynamics, particularly enthalpy (Section 7.8) and work (Sections 7.2 and 7.3). We need to be aware that molecules can occupy only a series of discrete energy levels and so possess only certain energies (Section 1.7). S ome things happen naturally; some don’t. Decay is natural; construction requires work. Water flows downhill naturally; we have to pump it uphill. A spark is enough to initiate a forest fire; the ceaseless input of energy from the Sun is required to rebuild the forest from carbon dioxide and water. Anyone who thinks about the world may wonder what determines the natural direction of change. What drives events forward? What drives a reaction toward products, and, on a larger scale, what drives the great and intricate network of reactions in biological systems forward in the extraordinary phenomenon we call life? As this chapter unfolds, we shall see that we can use a single quantity, “entropy,” to provide an elegant and quantitative answer to all these questions: an increase in entropy accounts both for physical change and for the more intricate changes that accompany chemical reactions. We shall also see that, although entropy is a thermodynamic concept in the sense that it is a property of bulk samples of matter, it has a very straightforward molecular interpretation. ENTROPY The first law of thermodynamics tells us that, if a reaction takes place, then the total energy of the universe (the reaction system and its surroundings) remains unchanged. But the first law does not address the questions that lie behind the “if.” Why do some reactions have a tendency to occur, whereas others do not? Why does anything happen at all? To answer these deeply important questions about the world around us, we need to take a further step into thermodynamics and learn more about energy beyond the fact that it is conserved. 8.1 Spontaneous Change A spontaneous change is a change that has a tendency to occur without needing to be driven by an external influence. A simple example is the cooling of a block of hot metal to the temperature of its surroundings (Fig. 8.1). The reverse change, a block of metal spontaneously growing hotter than its surroundings, has never been observed. The expansion of a gas into a vacuum is spontaneous (Fig. 8.2): a gas has no tendency to contract spontaneously into one part of a container. ENTROPY 8.1 Spontaneous Change 8.2 Entropy and Disorder 8.3 Changes in Entropy 8.4 Entropy Changes Accompanying Changes in Physical State 8.5 A Molecular Interpretation of Entropy 8.6 The Equivalence of Statistical and Thermodynamic Entropies 8.7 Standard Molar Entropies 8.8 Standard Reaction Entropies GLOBAL CHANGES IN ENTROPY 8.9 The Surroundings 8.10 The Overall Change in Entropy 8.11 Equilibrium GIBBS FREE ENERGY 8.12 Focusing on the System 8.13 Gibbs Free Energy of Reaction 8.14 The Gibbs Free Energy and Nonexpansion Work 8.15 The Effect of Temperature 8.16 Impact on Biology: Gibbs Free Energy Changes in Biological Systems 287 Chapter 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS A spontaneous change need not be fast and in some cases must be initiated. Molasses has a spontaneous tendency to flow out of an overturned can; but, at low temperatures, that flow may be very slow. Hydrogen and oxygen have a tendency to react to form water—the reaction is spontaneous in the thermodynamic sense—but a mixture of the two gases can be kept safely for centuries, provided it is not ignited with a spark. Diamonds have a natural tendency to turn into graphite, but diamonds last unchanged for countless years—on the human scale, diamonds are, in practice, forever. A spontaneous process has a natural tendency to occur; it does not necessarily take place rapidly. Throughout this chapter, and whenever we consider the thermodynamics of change, we must remember that we are exploring only the tendency of a process to occur. Whether that tendency is actually realized in practice depends on its rate: rates are outside the reach of thermodynamics and are considered in Chapter 14. Changes can be made to happen in their “unnatural” direction. For example, we can force an electric current through a block of metal to heat it to a temperature higher than that of its surroundings. We can drive a gas into a smaller volume by pushing in a piston. In every case, though, to bring about a nonspontaneous change in a system, we have to contrive a way of forcing it to happen by applying an influence from outside the system. In short, a nonspontaneous change can be brought about only by doing work. A process is spontaneous if it has a tendency to occur without being driven by an external influence; spontaneous changes need not be fast. 8.2 Entropy and Disorder In science, we look for patterns to discover nature’s laws. What is the pattern common to all spontaneous changes? To find a pattern, it is often best to start with very simple examples, because then the pattern is likely to be more obvious. So, let’s think about two simple spontaneous changes—the cooling of a hot metal and the expansion of a gas—at a molecular level and search for their common feature. A hot block of metal cools as the energy of its vigorously vibrating atoms spreads into the surroundings. The vigorously moving atoms of the metal collide with the slower atoms and molecules of the surroundings, transferring some of their energy in the collisions. The reverse change is very improbable, because it would require that energy migrate from the cooler surroundings and concentrate in a small hot block of metal. Such a process would require that collisions of the less vigorously moving atoms of the surroundings with the more vigorously moving atoms of the metal would cause the latter to move even more vigorously. The randomly moving molecules of a gas spread out all over their container; it is very unlikely that their random motion will bring them all simultaneously back into one corner. The pattern starting to emerge is that energy and matter tend to disperse in a disorderly fashion. As this chapter unfolds, we shall see how to use the idea of increasing disorder to account for any spontaneous change. In the language of thermodynamics, this simple idea is expressed as the entropy, S, a measure of disorder. Low entropy means little disorder; high entropy means great disorder. It follows that we can express the pattern that we have identified as follows: The entropy of an isolated system increases in the course of any spontaneous change. Thus, the cooling of hot metal is accompanied by an increase in entropy as energy spreads into the surroundings. The “isolated system” in this case is taken to be the block and its immediate surroundings. Likewise, the expansion of a gas is accompanied 288 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS FIGURE 8.1 A hot block of metal (top) spontaneously cools to the temperature of its surroundings (bottom). The reverse process, in which a block at the same temperature as its surroundings spontaneously becomes hotter, does not occur. FIGURE 8.2 A gas spontaneously fills its container. A glass cylinder containing the brown gas nitrogen dioxide (upper piece of glassware in the top illustration) is attached to an evacuated flask. When the stopcock between them is opened, the gas spontaneously fills both upper and lower vessels (bottom illustration). The reverse process, in which the gas now in both vessels collects spontaneously back in the upper vessel, does not occur. Spontaneous Not spontaneous å å å A å å å A Spontaneous Not spontaneous å å å A å å å A by an increase in entropy as the molecules spread through the container. The pattern we have identified is one version of the second law of thermodynamics. The natural progression of a system and its surroundings (which together make up “the universe”) is from order to disorder, from organized to random, from lower to higher entropy. For practical measurements, a small isolated region, such as a thermally insulated, sealed flask or a calorimeter, is considered to represent the universe. We need a quantitative definition of entropy to measure and make precise predictions about disorder. Provided that the temperature is constant, it turns out that a change in the entropy of a system can be calculated from the following expression: (1)* where q is the energy transferred as heat and T is the (absolute) temperature at which the transfer takes place. The subscript “rev” on q signifies that the energy must be transferred reversibly in the sense described in Section 7.3. For a reversible transfer of energy as heat, the temperatures of the surroundings and the system must be only infinitesimally different. With heat measured in joules and temperature in kelvins, the change in entropy (and entropy itself) is measured in joules per kelvin (J·K–1 ). What does this equation tell us? If a lot of energy is transferred as heat (large qrev), a lot of disorder is stirred up in the system and we expect a correspondingly big increase in entropy. For a given transfer of energy, we expect a greater change in disorder when the temperature is low than when it is high. The arriving energy stirs up the molecules of a cool system, which have little thermal motion, more noticeably than those of a hot system, in which the molecules are already moving vigorously. (Think of how sneezing in a quiet library will attract attention, but sneezing in a noisy street may pass unnoticed.) ¢S = qrev T 8.2 ENTROPY AND DISORDER 289 EXAMPLE 8.1 Calculating the change in entropy when a system is heated A large flask of water is placed on a heater and 100. J of energy is transferred reversibly to the water at 25°C. What is the change in entropy of the water? Anticipate Because the water is absorbing energy as heat, we expect its entropy to increase. PLAN Use Eq. 1 to calculate the entropy change. What should we assume? That the flask of water is so large that its temperature remains virtually constant as the heat is transferred: Eq. 1 applies only at constant temperature. SOLVE From ¢S = 100 J (273.15 + 25) K = 1.00 * 102 298 J K = +0.336 J.K-1 ¢S = qrev/T, ϩ0.336 J·KϪ1 100 J 25ЊC $%&Convert to kelvins Evaluate As predicted, the entropy of the water increases as a result of the flow of heat into it. A note on good practice: Note the ϩ sign on the answer: always show the sign explicitly for the change in a quantity, even if it is positive. Self-Test 8.1A Calculate the change in entropy of a large block of ice when 50. J of energy is removed reversibly from it as heat at 0°C in a freezer. [Answer: –0.18 J·K–1 ] Self-Test 8.1B Calculate the change in entropy of a large vat of molten copper when 50. J of energy is removed reversibly from it as heat at 1100.°C. A very important characteristic of entropy that is not immediately obvious from Eq. 1 but can be proved by using thermodynamics is that, like the enthalpy, entropy is a state function. This property is consistent with entropy being a measure of disorder, because the disorder of a system depends only on its current state and is independent of how that state was achieved. Because entropy is a state function, the change in entropy of a system is independent of the path between its initial and final states. This independence means that, if we want to calculate the entropy difference between a pair of states joined by an irreversible path, we can look for a reversible path between the same two states and then use Eq. 1 for that path. For example, suppose an ideal gas undergoes free (irreversible) expansion at constant temperature. To calculate the change in entropy, we allow the gas to undergo reversible, isothermal expansion between the same initial and final volumes, calculate the heat absorbed in this process, and use it in Eq.1. Because entropy is a state function, the change in entropy calculated for this reversible path is also the change in entropy for the free expansion between the same two states. Entropy is a measure of disorder; according to the second law of thermodynamics, the entropy of an isolated system increases in any spontaneous process. Entropy is a state function. 8.3 Changes in Entropy We can expect disorder to increase when a system is heated because the supply of energy increases the thermal motion of the molecules. Heating increases the thermal disorder, the disorder arising from the thermal motion of the molecules. We can also expect the entropy to increase when a given amount of matter spreads into a greater volume or is mixed with another substance. These processes disperse the molecules of the substance over a greater volume and increase the positional disorder, the disorder related to the locations of the molecules. Equation 1 allows us to express these changes quantitatively. First, let’s calculate the entropy change that results when a system is heated and its temperature increases. 290 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS HOW DO WE DO THAT? To derive an expression for the change in entropy when a system is heated, we first note that Eq. 1 applies only when the temperature remains constant as heat is supplied to a system. Except in special cases, that can be true only for infinitesimal transfers of heat; so we have to break down the calculation into an infinite number of infinitesimal steps, with each step taking place at a constant but slightly different temperature, and then add together the infinitesimal entropy changes for all the steps. To do this we use calculus. For an infinitesimal reversible transfer dqrev at the temperature T, the increase in entropy is also infinitesimal; and, instead of Eq. 1, we write The energy supplied as heat is related to the resulting increase in temperature, dT, by the heat capacity, C, of the system: dqrev ϭ CdT (This equation is the infinitesimal form of Eq. 5b of Chapter 7, which also applies to reversible changes.) If the change in temperature is carried out at constant volume, we use the constantvolume heat capacity, CV. If the change is carried out at constant pressure, we use the constant-pressure heat capacity, CP. By combining the preceding two equations, we get Now suppose that the temperature of a sample is increased from T1 to T2. The overall change in entropy is the sum (integral) of all these infinitesimal changes: ¢S = L T2 T1 CdT T dS = CdT T dS = dqrev T These special cases include any isothermal process, such as isothermal expansion of a gas, and transfers of energy at freezing or boiling points (see Section 8.4). Because an integral can be identified with an area, this expression for ⌬S can be identified with the area under the graph of C͞T plotted against T enclosed by vertical lines at T1 and T2 (see the following Example). Provided the heat capacity is independent of temperature in the temperature range of interest, C can be taken outside the integral and we obtain To evaluate the integral, we have used the standard integral We have shown that, provided the heat capacity can be treated as constant in the temperature range of interest, the entropy change that occurs when a system is heated from T1 to T2 is given by (2)* where C is the heat capacity of the system (CV if the volume is constant, CP if the pressure is constant). What does this equation tell us? If T2 is higher than T1, then T2͞T1 Ͼ 1, the logarithm of this ratio is positive, and therefore ⌬S is positive too, corresponding to the expected increase in entropy as the temperature is raised. The greater the heat capacity of the substance, the greater the increase in entropy for a given change in temperature. Figure 8.3 shows how the entropy of a substance changes as it is heated through a temperature range in which it has a constant heat capacity. ¢S = C ln T2 T1 L dx x = ln x + constant ¢S = C L T2 T1 dT T = C ln T2 T1 8.3 CHANGES IN ENTROPY 291 1 2 3 4 10 20 301 0 ⌬S/C T2/T1 FIGURE 8.3 The change in entropy as a sample is heated for a system with a constant heat capacity (C) in the range of interest. Here we have plotted ⌬S/C against the ratio of the final to the initial temperature. The entropy increases logarithmically with temperature. EXAMPLE 8.2 Calculating the entropy change due to an increase in temperature A sample of nitrogen gas of volume 20.0 L at 5.00 kPa is heated from 20.°C to 400.°C at constant volume. What is the change in the entropy of the nitrogen? The molar heat capacity of nitrogen at constant volume, CV,m, is 20.81 J·K–1 ·mol–1 . Anticipate Because the thermal disorder in a system increases as the temperature rises, we should expect a positive entropy change. PLAN We use Eq. 2, with the heat capacity at constant volume, CV ϭ nCV,m. Find the amount (in moles) of gas molecules by using the ideal gas law, PV ϭ nRT in the form n ϭ PV/RT and the initial conditions; remember to express temperature in kelvins. Because the data are liters and kilopascals, use R expressed in those units. As always, avoid rounding errors by delaying the numerical calculation to the last possible stage. What should we assume? That nitrogen is an ideal gas (for the calculation of n) and that CV is constant over the temperature range. SOLVE Convert temperatures into kelvins. T1 ϭ 20. ϩ 273.15 K ϭ 293 K T2 ϭ 400. ϩ 273.15 K ϭ 673 K 20ЊC 400ЊC700 600 500 Temperature(K) 400 300 200 100 0 Evaluate The change is positive (an increase), as expected. Note that, as remarked earlier, the change in entropy is equal to the area beneath the graph of C/T plotted against T. Self-Test 8.2A The temperature of 1.00 mol He(g) is increased from 25°C to 300.°C at constant volume. What is the change in the entropy of the helium? Assume ideal behavior and use CV,m ϭ R. [Answer: ϩ8.15 J·K–1 ] Self-Test 8.2B The temperature of 5.5 g of stainless steel is increased from 20.°C to 100.°C. What is the change in the entropy of the stainless steel? The specific heat capacity of stainless steel is 0.51 J·(°C)Ϫ1 иgϪ1 . Some changes are accompanied by a change in volume. Because a larger volume provides a greater range of locations for the molecules, we can expect the positional disorder of a gas and therefore its entropy to increase as the volume it occupies is increased. Once again, we can use Eq. 1 to turn this intuitive idea into a quantitative expression of the entropy change for the isothermal expansion of an ideal gas. We choose an isothermal expansion because both temperature and volume affect the entropy of a substance; at this stage, we do not want to have to consider changes in both temperature and volume. 3 2 292 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS Find the amount of N2 from PV ϭ nRT in the form n ϭ PV/RT. = 5.00 * 20.0 8.3145 * 293 mol (= 0.0410 mol) n = (5.00 kPa) * (20.0 L) (8.3145 LиkPaиK-1 иmol-1 ) * (293 K) 5.00 kPa 20.0 L 293 K n = PV/RT 0.0410 mol Calculate the change in entropy from ⌬S ϭ C ln(T2/T1) with C ϭ nCV,m. = +0.710 JиK-1 * ln 673 K 293 K ¢S = 5.00 * 20.0 8.3145 * 293 mol * (20.81 JиK-1 иmol-1 ) C/T T 293 K 673 K 0.710 J·K Ϫ1 HOW DO WE DO THAT? To derive an expression for the dependence of the entropy of an ideal gas on its volume, we note that, when the expansion is isothermal, implying that T is constant, we can use Eq. 1 directly. We then use the first law in the form ⌬U ϭ q ϩ w to relate q for a reversible, isothermal expansion to the change in volume of the gas. We know that ⌬U ϭ 0 for the isothermal expansion of an ideal gas (Section 7.6); so we can conclude that q ϩ w ϭ 0 and therefore that q ϭ Ϫw. Physically, that equality means that the energy the system loses by doing expansion work is replaced by an influx of energy as heat, so the internal energy remains the same. The same relation applies if the change is carried out reversibly, and so we can write qrev ϭ Ϫwrev. Therefore, to calculate qrev, we calculate the work done when an ideal gas expands reversibly and isothermally and then change the sign. For that calculation, we can use the following expression, which we derived in Section 7.3: We can substitute this value in the expression for entropy and obtain ¢S = ¢qrev T = (-wrev) T = nRT ln(V2/V1) T = nR ln V2 V1 wrev = -nRT ln V2 V1 We have shown that the change in entropy of an ideal gas when it expands isothermally from a volume V1 to a volume V2 is (3a)* where n is the amount of gas molecules (in moles) and R is the gas constant (in joules per kelvin per mole). When the final volume is greater than the initial volume (V2 Ͼ V1), the change in entropy is positive, corresponding to an increase in entropy, as expected (Fig. 8.4). Notice that here we see an important aspect of thermodynamics: although we have calculated the change in entropy for a reversible path, Eq. 3 is also the change in entropy of the gas when it expands irreversibly between the same two states, in this case from V1 to V2 at any constant temperature. As we saw in Section 8.2, this conclusion follows from the fact that entropy is a state function, and therefore independent of the path. You should not jump to the conclusion, though, that there is no difference between reversible and irreversible processes: at this point we are considering only the change in entropy of the system and have not yet discussed what is going on in the surroundings. We consider that in Section 8.9. ¢S = nR ln V2 V1 8.3 CHANGES IN ENTROPY 293 1 2 3 4 10 20 301 0 ⌬S/nR V2/V1 FIGURE 8.4 The change in entropy as a sample of a perfect gas expands at constant temperature. Here we have plotted ⌬S/nR against the ratio of the final to the initial volume. The entropy increases logarithmically with volume. EXAMPLE 8.3 Calculating the change in entropy when an ideal gas expands isothermally What is the change in entropy of the gas when 1.00 mol N2(g) expands isothermally from 22.0 L to 44.0 L? Anticipate Because the greater volume provides more locations into which the molecules of the gas can spread, we should expect its entropy to increase. PLAN Use Eq. 3a to calculate the entropy change for an isothermal expansion when the initial and final volumes are known. What should we assume? That nitrogen behaves as an ideal gas. SOLVE From ⌬S ϭ nRln (V2/V1), ϭ ϩ5.76 JиKϪ1 ¢S = (1.00 mol) * (8.3145 JиK-1 иmol-1 ) * ln 44.0 L 22.0 L 1 mol 5.76 J·K Ϫ1 Evaluate As expected, the entropy increases as the space available to the gas expands. A note on good practice: Note that the entropy change for 1 mol of a substance is reported differently from the entropy change per mole: the units of the former are joules per kelvin (J·K–1 ), those of the latter are joules per kelvin per mole (J·K–1 ·mol–1 ). Self-Test 8.3A Calculate the change in molar entropy of an ideal gas when it is compressed isothermally to one-third its initial volume. [Answer: Ϫ9.13 JиK–1 ·mol–1 ] Self-Test 8.3B Calculate the change in molar entropy of carbon dioxide that is allowed to expand isothermally to 10. times its initial volume (treat carbon dioxide as an ideal gas). The entropy change accompanying the isothermal compression or expansion of an ideal gas can be expressed in terms of its initial and final pressures. To do so, we use the ideal gas law—specifically, Boyle’s law—to express the ratio of volumes in Eq. 3 in terms of the ratio of the initial and final pressures. Because pressure is inversely proportional to volume (Boyle’s law), we know that at constant temperature V2/V1 ϭ P1/P2 where P1 is the initial pressure and P2 is the final pressure. Therefore, (3b)¢S = nR ln P1 P2 294 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS EXAMPLE 8.4 Calculating the change in entropy with pressure Calculate the change in entropy when the pressure of 0.321 mol O2(g) is increased from 0.300 atm to 12.00 atm at constant temperature. Anticipate For a fixed amount of gas and a fixed temperature, the only way to increase the pressure is to compress it (that is, decrease the volume it occupies). We can therefore expect the entropy to decrease because the molecules are confined to a smaller volume. PLAN Use Eq. 3b to calculate the entropy change for an isothermal increase in pressure. What should we assume? That oxygen is an ideal gas. SOLVE From ⌬S ϭ nR ln(P1/P2), ϭ Ϫ9.85 JиKϪ1 ¢S = (0.321 mol) * (8.3145 JиK-1 иmol-1 ) * ln 0.300 atm 12.00 atm 0.3 atm 12 atm 0.321 mol Ϫ9.85 J·K Ϫ1 Evaluate The entropy decreases, as expected for a sample that has been compressed into a smaller volume at constant temperature. Self-Test 8.4A Calculate the change in entropy when the pressure of 1.50 mol Ne(g) is decreased isothermally from 20.00 bar to 5.00 bar. Assume ideal behavior. [Answer: ϩ17.3 JиKϪ1 ] Self-Test 8.4B Calculate the change in entropy when the pressure of 70.9 g of chlorine gas is increased isothermally from 3.00 kPa to 24.00 kPa. Assume ideal behavior. To calculate a change in entropy for a process we find a reversible path between the initial and final states. It is immaterial whether the actual process is irreversible or reversible. Because entropy is a state function, the change for that path will be the same as that for the irreversible path, provided the two paths have the same initial and final states. EXAMPLE 8.5 Calculating the change in entropy when both temperature and volume change In an experiment, 1.00 mol Ar(g) was compressed suddenly (and irreversibly) from 5.00 L to 1.00 L by driving in a piston (like a big bicycle pump), and in the process its temperature was increased from 20.0°C to 25.2°C. What is the change in entropy of the gas? Anticipate The entropy will decrease when a gas is compressed, but increase when its temperature rises. Because the temperature rise is small, we expect an overall decrease, but must do the calculation to be sure. PLAN Because the entropy is a state function, we can calculate the change in entropy by choosing a reversible path that results in the same final state. In this case, consider the following: Step 1 Reversible isothermal compression at the initial temperature from the initial volume to the final volume (and use Eq. 3a). Step 2 An increase in temperature of the gas at constant final volume to the final temperature (and use CV in Eq. 2 with C the heat capacity at constant volume). What should we assume? That argon is an ideal gas and that CV is constant over the temperature range. SOLVE 8.4 ENTROPY CHANGES ACCOMPANYING CHANGES IN PHYSICAL STATE 295 Step 1 From Eq. 3a, ⌬S ϭ nR ln(V2/V1), ϭ Ϫ13.4 JиKϪ1 ¢S = (1.00 mol) * (8.3145 JиK-1 иmol-1 ) * ln 1.00 L 5.00 L 25.2 rev 1.0 5.0 20.0 Temperature(ЊC) Volume (L) Ϫ13.4 J·K Ϫ1 Step 2 From ⌬S ϭ CV ln(T2/T1) with CV ϭ nCV,m, ϭ ϩ0.22 JиKϪ1 ¢S = (1.00 mol) * (12.47 JиK-1 иmol-1 ) * ln 298.4 K 293.2 K rev 25.2 20.0 Temperature(ЊC) 1.0 5.0 Volume (L) ϩ0.22J·KϪ1 Add the entropy changes for the two steps, ⌬S ϭ ⌬S (step 1) ϩ ⌬S (step 2). ⌬S ϭ Ϫ13.4 ϩ 0.22 JиKϪ1 ϭ Ϫ13.2 JиKϪ1 25.2 20.0 Temperature(ЊC) 1.0 5.0 Volume (L) Ϫ13.2 J·KϪ1 Evaluate As expected, the decrease in entropy due to the fivefold compression is much greater than that due to the small rise in temperature. Self-Test 8.5A Calculate the change in entropy when the volume of 2.00 mol Ar(g) is increased from 5.00 L to 10.00 L while the temperature increases from 100. K to 300. K. Assume ideal behavior. [Answer: ϩ38.9 JиKϪ1 ] Self-Test 8.5B Calculate the change in entropy when the pressure of 23.5 g of oxygen gas is increased from 2.00 kPa to 8.00 kPa while the temperature increases from 240 K to 360 K. Assume ideal behavior. The entropy of a system increases when its temperature increases and when its volume increases. 8.4 Entropy Changes Accompanying Changes in Physical State We can expect the entropy to increase when a solid melts and its molecules become more disordered as they form a liquid. Similarly, we can expect an even greater increase in entropy when a liquid vaporizes, because its molecules then occupy a much greater volume and their motion is highly chaotic. As we saw in Section 4.8, a liquid vaporizes until its partial pressure has reached a certain value, called its vapor pressure. As the liquid is heated, its vapor pressure increases until it is equal to the external pressure. At that temperature, which is called the boiling temperature, the liquid boils. In this section, we develop expressions for the change in entropy at the transition temperature for the prevailing pressure. For instance, if the pressure is 1 atm, then these expressions are applicable only at the normal melting point, Tf (the f stands for fusion, another term for melting), the temperature at which a solid melts when the pressure is 1 atm, or the normal boiling point, Tb, the temperature at which a liquid boils when the pressure is 1 atm. In most cases, the boiling temperature at 1 bar is negligibly different from the normal boiling point. To use Eq. 1 to calculate the entropy change for a substance undergoing a transition from one phase to another at its transition temperature, we need to note three facts: 1 At the transition temperature (such as the boiling point for vaporization), the temperature of the substance remains constant as heat is supplied. All the energy supplied is used to drive the phase transition, such as the conversion of liquid into vapor, rather than to raise the temperature. The T in the denominator of Eq. 1 is therefore a constant and may be set equal to the transition temperature (in kelvins). 2 At the temperature of a phase transition, the transfer of heat is reversible. Provided the external pressure is fixed (at 1 atm, for instance), raising the temperature of the surroundings an infinitesimal amount results in complete vaporization and lowering the temperature causes complete condensation. 3 Because the transition takes place at constant pressure (for instance, 1 atm), the heat supplied is equal to the change in enthalpy of the substance (Section 7.8). It follows that we can replace qrev in the expression for the entropy change with ⌬H for the phase change. The entropy of vaporization, ⌬Svap, is the change in entropy per mole of molecules when a substance changes from a liquid into a vapor. The heat required per mole to vaporize the liquid at constant pressure is equal to the enthalpy of vaporization (⌬Hvap, Section 7.11). It then follows from Eq. 1, by setting qrev ϭ ⌬Hvap, that the entropy of vaporization at the boiling temperature is At the boiling temperature: (4)* When the liquid and the vapor are in their standard states (both pure, both at 1 bar) and the boiling temperature is for 1 bar, we refer to the standard entropy of vaporization, ⌬Svap°. Because all standard entropies of vaporization are positive, they are normally reported without their positive sign. ¢Svap = ¢Hvap Tb 296 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS EXAMPLE 8.6 Calculating the standard entropy of vaporization What is the standard entropy of vaporization of acetone at its normal boiling point of 56.2°C? PLAN Find the standard enthalpy of vaporization of acetone at its boiling point in Table 7.3 and substitute the data into Eq. 4. SOLVE The boiling point corresponds to 329.4 K, and we note from Table 7.3 that the standard enthalpy of vaporization of acetone at its boiling point is 29.1 kJиmolϪ1 . Therefore, From ⌬Svap° ϭ ⌬Hvap°/Tb, ¢Svap = 2.91 * 104 Jиmol-1 329.4 K = 88.3 JиK-1 иmol-1 329.4 K ϩ88.4 J·K Ϫ1 29.1 kJ·mol Ϫ1 $%& (273.15 ϩ 56.2) K 29.1 kJиmolϪ1 Self-Test 8.6A Calculate the standard entropy of vaporization of argon at its normal boiling point (see Table 7.3). [Answer: ] Self-Test 8.6B Calculate the standard entropy of vaporization of water at its normal boiling point (see Table 7.3). 74 JиK-1 иmol-1 $++%++& Table 8.1 lists the standard entropies of vaporization of a number of liquids. These and other data show a striking pattern: many values are close to . This observation is called Trouton’s rule. The explanation of Trouton’s rule is that approximately the same increase in positional disorder occurs when any liquid is converted into vapor, and so we can expect the change in entropy to be much the same in each case. Because all gases behave similarly, substantial departures from Trouton’s rule normally indicate that the molecules have a more orderly arrangement in the liquid than is typical of most liquids, and so there is a greater increase in disorder when such liquids vaporize. The molecules in a liquid are relatively highly ordered if there are extensive intermolecular interactions. Liquids such as water that can take part in extensive hydrogen bonding typically have entropies of vaporization greater than . Thinking point: Why does mercury have such a high entropy of vaporization? Self-Test 8.7A Use Trouton’s rule to estimate the standard enthalpy of vaporization of liquid bromine, which boils at 59°C. [Answer: (experimentally, )] Self-Test 8.7B Use Trouton’s rule to estimate the standard enthalpy of vaporization of diethyl ether, C4H10O, which boils at 34.5°C. A smaller increase in entropy occurs when solids melt than when liquids vaporize, because a liquid is only slightly more disordered than a solid (Fig. 8.5). By applying the same argument used for vaporization to the standard entropy of fusion of a substance at its melting (or freezing) point, we obtain At the freezing temperature: (5)* Here, is the standard enthalpy of fusion and Tf is the melting point. All entropies of fusion are positive (there is a single exception: solid helium-3), and so they are normally reported without their positive sign. Self-Test 8.8A Calculate the standard entropy of fusion of mercury at its freezing point (see Table 7.3). [Answer: ] Self-Test 8.8B Calculate the standard entropy of fusion of benzene at its melting point (see Table 7.3). Because entropy changes may depend on temperature, to find the entropy of transition at a temperature other than the normal transition temperature, we have to break the calculation down into three steps (1). For example, if we want to know the entropy of vaporization of water at 25°C and 1 bar we imagine that we • heat the liquid to its normal boiling point, 100.°C, 9.782 JиK-1 иmol-1 ¢Hfus° ¢Sfus° = ¢Hfus° Tf 29.45 kJиmol-1 28 kJиmol-1 85 JиK-1 иmol-1 85 JиK-1 иmol-1 8.4 ENTROPY CHANGES ACCOMPANYING CHANGES IN PHYSICAL STATE 297 TABLE 8.1 Standard Entropy of Vaporization at the Normal Boiling Point* Liquid Boiling point (K) Svap° (J·K؊1 ·mol؊1 ) acetone 329.4 88.3 ammonia 239.7 97.6 argon 87.3 74 benzene 353.2 87.2 ethanol 351.5 124 helium 4.22 20. mercury 629.7 94.2 methane 111.7 73 methanol 337.8 105 water 373.2 109 *The normal boiling point is the boiling temperature at 1 atm. ¢ Temperature Tb T Eq. 4 1 Eq.2,CP(l) Eq.2,CP(g) ΔSvap(T) FIGURE 8.5 A representation of the arrangement of molecules in (a) a liquid and (b) a solid. When the liquid freezes, the molecules lie in an ordered array; consequently there is a decrease in the disorder of the system (a drop in entropy). The entropy rises again when the solid melts. Lab Video 8.5 • allow it to vaporize, • then cool the vapor back to 25°C. To match these steps: • Use Eq. 2 to calculate the entropy change accompanying the heating of water from 25°C to 100.°C (the heat capacity of water is approximately constant over that range). • Use Eq. 4 to calculate the entropy of vaporization at 100.°C. • Use Eq. 2 to calculate the entropy change accompanying the cooling of water vapor from 100.°C back to 25°C (a negative value). Finally, we add the three contributions together to get the quantity that we require: (heating liquid from 25°C to 100.°C) (cooling vapor from 100.°C to 25°C) We can break the overall calculation down in this way because entropy is a state function. For an example of this type of calculation, see Exercise 8.43. The entropy of a substance increases when it melts and when it vaporizes. 8.5 A Molecular Interpretation of Entropy So far, we have calculated only changes in the entropy of a substance. However, entropy is a measure of disorder, and it is possible to imagine a perfectly orderly state of matter with neither positional nor, at , thermal disorder. Such a state represents a natural zero of entropy, a state of perfect order; therefore, we should be able to set up an absolute scale of entropy just as we can set up an absolute scale of temperature. This idea is summarized by the third law of thermodynamics: The entropies of all perfect crystals approach zero as the absolute temperature approaches zero. That is, S : 0 as T : 0. The “perfect crystal” part of this statement of the third law refers to a substance in which all the atoms are in a perfectly orderly array, and so there is no positional disorder. The T : 0 part of the statement implies the absence of thermal motion—thermal disorder vanishes as the temperature approaches zero. As the temperature of a substance is raised from zero, more orientations become available to the molecules and their thermal disorder increases. Thus we can expect the entropy of any substance to be greater than zero above . In 1877, the Austrian physicist Ludwig Boltzmann proposed a molecular definition of entropy that enables us to calculate the absolute entropy at any temperature (Fig. 8.6). His formula provided a way of calculating the entropy when measurements could not be made and deepened our insight into the meaning of entropy at the molecular level. The Boltzmann formula for the entropy is (6)* We met Boltzmann’s constant, , in Section 7.7 in connection with the equipartition theorem and saw that it is related to the gas constant by . The quantity W is the number of ways that the atoms or molecules in the sample can be arranged and yet still give rise to the same total energy. Each arrangement of the molecules in a sample is a different state called a microstate; so W is equal to the number of different microstates that correspond to the same energy. A microstate lasts only for an instant; so, when we measure the bulk properties of a system, we are measuring an average taken over the many microstates that the system has occupied during the measurement. The entropy calculated from the Boltzmann formula is called the statistical entropy. To understand Eq. 6, imagine that we have a large number of replicas of the system that we are investigating, with each replica having the same total energy. This collection is called an ensemble. Although the energy of each replica is the same, the molecules R = kNA k = 1.381 * 10-23 JиK-1 S = kln W T = 0 T = 0 + ¢Svap(100.°C) + ¢S ¢Svap(25°C) = ¢S 298 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS FIGURE 8.6 Ludwig Boltzmann (1844–1906). His formula for entropy (using an earlier notation for natural logarithms) became his epitaph. may be distributed differently over the available energy levels. We can imagine that all the replicas are placed in a box, and we select them blindly, one by one. If there is only one way of achieving the energy (for instance, all the molecules are in exactly the same energy level), then . In this case every replica that we select will have exactly the same distribution of molecules and will be in exactly the same microstate. Such a system has zero entropy (ln ) and zero disorder because each time we make a selection we find the system in that single microstate. We can be absolutely certain that the selection will be the same in each case. However, if there is more than one way of arranging the molecules in the sample to achieve the same energy, then not every replica that we draw will be the same. For instance, if a certain energy can be achieved with 1000 different microstates ( ), then there is only 1 chance in 1000 of drawing a specific one of those microstates. Because the disorder of the system is higher for this state than for that with , the entropy for this state is greater than zero.W = 1 W = 1000 1 = 0 W = 1 8.5 A MOLECULAR INTERPRETATION OF ENTROPY 299 EXAMPLE 8.7 Calculating the entropy of a system Calculate the entropy of a tiny solid made up of four diatomic molecules of a compound such as carbon monoxide, CO, at T ϭ 0 when (a) the four molecules have formed a perfectly ordered crystal in which all molecules are aligned with their C atoms on the left (top-left image in Fig. 8.7) and (b) the four molecules lie in random orientations (but parallel, any of the images in Fig. 8.7). Anticipate We expect that at T ϭ 0 the sample in (a) will have zero entropy, because there is no disorder in either location or energy as all the molecules are in their lowest possible energy state. The sample in (b) has greater disorder, so we expect its entropy to have a positive value. PLAN Use the Boltzmann formula (Eq. 6) to calculate the entropy of the sample. SOLVE (a) Because there is only one way of arranging the molecules in the perfect crystal, W ϭ 1. From S ϭ k ln W and W ϭ 1, S ϭ k ln 1 ϭ 0 FIGURE 8.7 A tiny sample of solid carbon monoxide consisting of four molecules. Each box represents a different arrangement of the four molecules. When there is only one way of arranging the four molecules so that they all point in one direction (as in the top left image), the entropy of the solid is zero. When all sixteen ways of arranging four CO molecules are accessible, the entropy of the solid is greater than zero. 300 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS In this case, every member of the ensemble is identical, and we can be sure that any selection results in the same microstate. (b) Because each of the four molecules can take two orientations, the total number of ways of arranging them is W ϭ 2 ϫ 2 ϫ 2 ϫ 2 ϭ 24 or 16 different possible arrangements corresponding to the same total energy. Now there is only 1 chance in 16 of selecting a given microstate from the ensemble, and so we can be less sure about the actual state of the system. The entropy of this tiny solid is therefore From S ϭ k ln W and W ϭ 24 , S ϭ k ln 24 ϭ (1.3807 ϫ 10–23 JиKϪ1 ) ϫ ln 16 ϭ 3.8281 ϫ 10Ϫ23 JиKϪ1 Evaluate As expected, the entropy of the disordered solid is higher than that of the perfectly ordered solid. Self-Test 8.9A Calculate the entropy of a sample of a solid in which the molecules may be found in any one of three orientations with the same energy. Suppose there are 30 molecules in the sample. [Answer: 4.5 ϫ 10Ϫ22 JиKϪ1 ] Self-Test 8.9B Calculate the entropy of a sample of a solid in which it is supposed that a substituted benzene molecule, C6H5F, may be found in any one of six orientations with the same energy. Suppose there is 1.0 mol of molecules in the sample. For a more realistic sample size than that in Example 8.7, one that contains 1.00 mol CO, corresponding to 6.02 ϫ 1023 CO molecules, each of which could be oriented in either of two ways, there are 26.02ϫ1023 (an astronomically large number) different microstates, and a chance of only 1 in 26.02ϫ1023 of drawing a given microstate in a blind selection. We can expect the entropy of the solid to be high and calculate by using ln xa ϭ a ln x that From S ϭ k ln W and S ϭ k ln ϭ (1.3807 ϫ 10Ϫ23 JиKϪ1 ) ϫ (6.02 ϫ 1023 ) ϫ ln 2 ϭ 5.76 JиKϪ1 When the entropy of 1.00 mol CO is actually measured at temperatures close to T ϭ 0, the value found is 4.6 JиKϪ1 . This value—which is called the residual entropy of the sample, the entropy of a sample at T ϭ 0 arising from positional disorder surviving at that temperature—is close enough to 5.76 JиKϪ1 to suggest that in the crystal the molecules are indeed arranged nearly randomly. The reason for this randomness is that the electric dipole moment of a CO molecule is very small, and so there is little energy advantage in the molecules lying head-to-tail, head-to-head, or tail-to-tail; thus the molecules lie in either direction. For solid HCl, the same experimental measurements give close to T ϭ 0. This value indicates that the bigger dipole moments of the HCl molecules pull them into an orderly arrangement; so they lie strictly head-to-tail and there is no positional disorder at T ϭ 0. S L 0 26.02*1023 W = 26.02*1023 EXAMPLE 8.8 Using the Boltzmann formula to interpret a residual entropy The entropy of 1.00 mol FClO3(s) at T ϭ 0 is 10.1 JиKϪ1 . Suggest an interpretation. Anticipate The observation that the entropy is nonzero at T ϭ 0 should suggest that the molecules are positionally disordered at that temperature. PLAN From the shape of the molecule (which can be obtained by using VSEPR theory), we need to determine how many orientations, W, it is likely to be able to adopt in a crystal; then we can use the Boltzmann formula to see whether that number of orientations leads to the observed value of S. SOLVE An FClO3(s) molecule is tetrahedral, and—provided the energy of each orientation is almost the same—can take any of four orientations in the solid, with the F atom in a different position in each case (Fig. 8.8). The total number of ways of arranging the molecules in a crystal containing N molecules is therefore W ϭ (4 ϫ 4 ϫ 4 ϫ . . . ϫ 4)N factors ϭ 4N The entropy is 8.6 THE EQUIVALENCE OF STATISTICAL AND THERMODYNAMIC ENTROPIES 301 From S ϭ k ln W, W ϭ 4N , N ϭ 6.02 ϫ 1023 , and ln xa ϭ a ln x, ϭ (1.3807 ϫ 10Ϫ23 JиKϪ1 ) ϫ (6.02 ϫ 1023 ) ϫ ln 4 ϭ 11.5 JиKϪ1 S = k ln 46.02*1023 Cl F O FIGURE 8.8 The four possible orientations of a tetrahedral FClO3 molecule in a solid. Evaluate This value is reasonably close to the experimental value of 10.1 JиKϪ1 , which suggests that, at T ϭ 0, the molecules lie nearly randomly in any of four possible orientations. Self-Test 8.10A Explain the observation that the entropy of 1 mol N2O(s) at T ϭ 0 is 6 JиKϪ1 . [Answer: In the crystal, the orientations NNO and ONN are equally likely.] Self-Test 8.10B Suggest a reason why the entropy of ice is nonzero at T ϭ 0; think about how the structure of ice is affected by the hydrogen bonds. The Boltzmann formula relates the entropy of a substance to the number of arrangements of molecules that result in the same energy: when many energy levels are accessible, this number and the corresponding entropy are large. 8.6 The Equivalence of Statistical and Thermodynamic Entropies The expressions in Eq. 1 (⌬S ϭ qrev/T) and Eq. 6 (S ϭ k ln W) are two apparently very different definitions of entropy. The first was established by considerations of the behavior of bulk matter and the second by statistical analysis of molecular behavior. To verify that the two definitions are in fact essentially the same we need to show that the entropy changes predicted on the basis of Eq. 6 are the same as those deduced from Eq. 1. To do so, we will show that the Boltzmann formula predicts the correct form of the volume dependence of the entropy of an ideal gas (Eq. 3a). More detailed calculations show that the two definitions are consistent with each other in every respect. In the process of developing these ideas, we shall also deepen our understanding of what we mean by “disorder.” An ideal gas consists of a large number of molecules that can be viewed as occupying the energy levels characteristic of a particle in a box. For simplicity, we consider a one-dimensional box (Fig. 8.9a), but the same considerations apply to a real threedimensional container of any shape. At T ϭ 0, only the lowest energy level is occupied; so W ϭ 1 and the entropy is zero. There is no “disorder,” because we know which state each molecule occupies. At any temperature above T ϭ 0, the molecules occupy large numbers of different energy levels, as shown in Fig. 8.9. Because the molecules can now be found in a larger number of microstates, W is greater than 1. Therefore, the entropy (which is proportional to ln W) is greater than zero. Now the disorder has increased; consequently we are less confident about precisely which state a given molecule occupies. For instance, in a tiny system with only two molecules, A and B, at T ϭ 0 we can be confident that both molecules occupy the lowest energy level. However, if at a higher temperature a second state becomes available, we don’t know whether it is molecule A that occupies the higher level, with B still in the ground state, or vice versa. Energy (a) (b) FIGURE 8.9 The energy levels of a particle in a box (a) become closer together as the width of the box is increased. (b) As a result, the number of levels accessible to the particles in the box increases, and the entropy of the system increases accordingly. The range of thermally accessible levels is shown by the tinted band. The change from part (a) to part (b) is a model of the isothermal expansion of an ideal gas. The total energy of the particles is the same in each case. When the length of the box is increased at constant temperature (with T Ͼ 0), more energy levels become accessible to the molecules because the levels now lie closer together (Fig. 8.9b). Because the molecules are now distributed across more levels , we are less sure about which energy level any given molecule occupies. Therefore, the value of W increases as the box is lengthened and, by the Boltzmann formula, the entropy increases, too. The same argument applies to a three-dimensional box: as the volume of the box increases, the number of accessible states increases, too. We can use this relationship to show that the expression in Eq. 3a (⌬S ϭ nR ln V2/V1), which we derived from Eq. 1, can also be deduced from Eq. 6. 302 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS HOW DO WE DO THAT? To deduce Eq. 3 from the Boltzmann formula we start by supposing that the number of microstates available to a single molecule is proportional to the volume available to it. Then we can write W ϭ constant ϫ V. For N molecules, the number of microstates is proportional to the Nth power of the volume: W ϭ (constant ϫ V) ϫ (constant ϫ V) . . . N times ϭ (constant ϫ V)N Therefore, the change in the statistical entropy when a sample expands isothermally from volume V1 to a volume V2 is From S ϭ k ln W, ¢S = k ln (constant * V2)N - k ln (constant * V1)N Use ln xa ϭ a ln x. ¢S = Nk ln (constant * V2) - Nk ln (constant * V1) Use ln x Ϫ ln y ϭ ln (x/y) and cancel the constants. ¢S = Nk ln constant * V2 constant * V1 = Nk ln V2 V1 This expression is identical to Eq. 3 because N ϭ nNA (where NA is Avogadro’s constant) and NAk ϭ R, the gas constant; therefore, Nk ϭ nNAk ϭ nR and ⌬S ϭ Nk ln(V2/V1) ϭ nR ln(V2/V1). In at least the case of the isothermal expansion of an ideal gas, the two definitions give identical results. A further point is that the logarithm of the volume in Eq. 3 can now be seen to stem from the logarithm of W in the Boltzmann formula, and this derivation shows that the fact that S depends on the logarithm of V is related to the fact that the number of accessible states (as measured by W) increases with the size of the container. We can also use the Boltzmann formula to interpret the increase in entropy of a substance as its temperature is raised (Eq. 2 and Table 8.2). We use the same particle-in-abox model of a gas, but this reasoning also applies to liquids and solids, even though their energy levels are much more complicated. At low temperatures, the molecules of a gas can occupy only a few of the energy levels; so W is small and the entropy is low. As the temperature is raised, the molecules have access to larger numbers of energy levels (Fig. 8.10); so W rises and the entropy increases, too. We have shown that the statistical and thermodynamic entropies lead to the same conclusions. We can expect their more general properties to be the same, too: 1 Both are state functions. Because the number of microstates available to the system depends only on its current state, not on its past history, W depends only on the current state of the system, and therefore the statistical entropy does, too. TABLE 8.2 Standard Molar Entropy of Water at Various Temperatures Temperature Sm ° Phase (°C) (JؒK؊1 ؒmol؊1 ) solid Ϫ273 (0 K) 3.4 0 43.2 liquid 0 65.2 20 69.6 50 75.3 100 86.8 vapor 100 196.9 200 204.1 Energy (a) (b) Low T High T FIGURE 8.10 More energy levels become accessible in a box of fixed width as the temperature is raised. The change from part (a) to part (b) is a model of the effect of heating an ideal gas at constant volume. The thermally accessible levels are shown by the tinted band. The average energy of the molecules also increases as the temperature is raised: that is, both internal energy and entropy increase with temperature. 2 Both are extensive properties. Doubling the number of molecules increases the number of microstates from W to W2 , and so the entropy changes from k ln W to k ln W2 , or 2k ln W. Therefore, the statistical entropy, like the thermodynamic entropy, is an extensive property. 3 Both increase in a spontaneous change. In any irreversible change, the overall disorder of the system and its surroundings increases, which means that the number of microstates increases. If W increases, then so does ln W, and the statistical entropy increases, too. 4 Both increase with temperature. When the temperature of the system increases, more microstates become accessible, and so the statistical entropy increases. The equations used to calculate changes in the statistical entropy and the thermodynamic entropy lead to the same result. 8.7 Standard Molar Entropies To calculate the entropy of a substance, we use Boltzmann’s formula, but the calculations are sometimes very difficult and require a lot of manipulation of Eq. 6. To measure the entropy of a substance, we use the thermodynamic definition, Eq. 1, in combination with the third law of thermodynamics. Because the third law tells us that S(0) ϭ 0 and Eq. 2 can be used to calculate the change in entropy as a substance is heated to the temperature of interest, we can write S(T) ϭ S(0) ϩ ⌬S(heating from 0 to T) ϭ ⌬S(heating from 0 to T) The change in entropy on heating is calculated from the heat capacity and the temperature, as we did in Example 8.2. However, because we cannot assume that the heat capacity is constant all the way down to T ϭ 0, we have to use a more general expression. 8.7 STANDARD MOLAR ENTROPIES 303 HOW DO WE DO THAT? To take into account the possibility that the heat capacity changes with temperature, we go back to the expression We set T1 ϭ 0 and T2 ϭ T, the temperature of interest, in the limits of the integral. Heating commonly takes place at constant pressure, and so we replace C by CP: Therefore, by invoking the third law and setting S(0) ϭ 0, we have An integral of a function—in this case, the integral of CP/T—is the area under the graph of the function. Therefore, to measure the entropy of a substance, we need to measure the heat capacity (typically the constant-pressure heat capacity) at all temperatures from T ϭ 0 to the temperature of interest. Then the entropy of the substance is obtained by plotting CP/T against T and measuring the area under the curve (Fig. 8.11). Note that we have drawn CP approaching zero as T : 0. This feature is a general phenomenon, and explained by quantum mechanics. At low temperatures, the energy available is so small that there is not enough to stimulate transitions to higher energy states, so the sample cannot take up energy, and its “capacity for heat” is zero. This property of matter is one reason why the absolute zero of temperature has never been reached (Box 8.1). ¢S(T) = L T 0 CP dT T ¢S(heating from 0 to T) = L T 0 CPdT T ¢S(heating from T1 to T2) = L T2 T1 CdT T 304 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS Temperature Temperature Temperature Heatcapacity,CP CP/T Entropy,S Area (b) (c)(a) FIGURE 8.11 The experimental determination of entropy. (a) The heat capacity (at constant pressure in this instance) of the substance is determined from close to absolute zero up to the temperature of interest. (b) The area under the plot of CP /T against T is determined up to the temperature of interest. (c) This area is the entropy of the substance at that temperature. Living Graph 8.11 The possibility of achieving absolute zero (T ϭ 0) has intrigued scientists for many years. At absolute zero it would be possible to study the properties of materials in their lowest allowed energy state. For instance, at very low temperatures an interference pattern of laser beams can be used to create an “optical lattice,” a set of spatially symmetric potential energy wells in which atoms can be trapped to form perfect crystals. These arrays could be used to create tiny building blocks for nanoscale computers. The third law of thermodynamics tells us that it is not possible to reach absolute zero in a cyclical thermodynamic process with a finite number of steps. However, it may still be possible to reach absolute zero by using a noncyclic process, and record low temperatures have recently been reached by a variety of means. One method to approach T ϭ 0 is to alternate isothermal magnetization with adiabatic demagnetization. This approach takes advantage of the fact that in a magnetic field electrons with down spins (p) have slightly lower energies than electrons with up spins (q). If the up spins can be converted to down spins, the sample will have lower energy overall and therefore a lower temperature. If all the up spins could be converted to down spins, the temperature would reach absolute zero. A cool paramagnetic sample that is not in a magnetic field has equal numbers of up and down electrons because the two spin states have the same energy (see Box 3.2). This is true whatever the temperature. So the first step is to cool the sample by conventional means (for instance, by putting it in contact with liquid helium). Then a magnetic field is turned on. The down spin states now have lower energy than the up spin states, and FRONTIERS OF CHEMISTRY: THE QUEST FOR ABSOLUTE ZEROBOX 8.1 so they are slightly more numerous. We shall call this state A. The sample in this state has a characteristic entropy that reflects the slightly greater number of down spins than up spins and the temperature of the sample. If there were even more down spins, we would report that the temperature of the sample was lower. Our task, therefore, is to turn some up spins into down spins. To do so, we use two steps, as summarized in the first figure. In the first step, the field is increased. As a result, the energies of the two states diverge and the populations adjust. This adjustment of populations takes place while the sample is in contact with its surroundings and occurs without change of temperature: it is the isothermal magnetization step. The entropy decreases in this step because, although the temperature remains the same, the spins have become more ordered. We shall call this state B. In the second step, thermal contact with the surroundings is broken, so any subsequent change will be adiabatic; that is, not involve a transfer of energy as heat between the system and the surroundings. In any reversible adiabatic process the entropy does not change (because ⌬S ϭ qrev/T and qrev ϭ 0). Under these adiabatic conditions, the magnetic field is reduced to the value it had in state A. However, although the magnetic field has been reduced, the entropy is the same as in state B when a high magnetic field was present. As we saw, this lower entropy corresponds to a lower temperature than the sample had initially: the sample has been cooled. The two steps are repeated until the temperature has been lowered as much as possible. However, because the two curves in the illustration converge at T ϭ 0, this cyclic process cannot achieve absolute zero itself. 8.7 STANDARD MOLAR ENTROPIES 305 The team achieved a temperature of about 700 nK. At such a low temperature the atoms appear to lose their individual identities and by a quantum mechanical process form a “condensate,” a new form of matter in which atoms merge to form a single large particle that behaves as a single atom. The second figure is a visualization of the condensate. At MIT researchers have found a way to use lasers to reduce the temperature of large objects to within one degree of absolute zero. At such a low temperature quantum effects can be seen even in macroscopic objects. HOW MIGHT YOU CONTRIBUTE? Methods for bringing large samples to very low temperatures need to be refined further. In addition, there are many unanswered questions about absolute zero that remain to be solved. For example, many substances become superconducting at very low temperatures. What would happen to conductivity at absolute zero? Related exercises: 8.95–8.98 For Further Reading: P. Atkins, “The third law: The unattainability of zero,” Four Laws That Drive the Universe, pp. 101–121, Oxford University Press, 2007. M. Lewenstein & A. Sanpera, “Probing quantum magnetism with cold atoms,” Science, vol. 319, Jan. 18, 2008, pp. 292–293. Nova, “Absolute zero,” http://www.pbs.org/wgbh/nova/zero/. ? This 3-D visualization of a Bose–Einstein condensate illustrates how the circulating atoms are held together by a magnetic field. Variations in brightness show variations in density. The darker the area, the denser the matter. The brightest areas are vortices created by the interacting forces. The line around the equator is an artifact of the visualization. Entropy Temperature0 Low field High field Entropy Temperature0 Isothermal Adiabatic (a) (b) The cooling of a sample by adiabatic demagnetization follows the steps shown here. The arrows in the inset represent the spin alignment of the electrons in the sample. The arrows in the graph show the direction the sample takes. First the entropy decreases at constant temperature as a magnetic field is applied, then as the sample is demagnetized in an adiabatic environment its temperature decreases to maintain a constant entropy. (a) If the two curves did not coincide, absolute zero could be reached. However, (b) the curves coincide before absolute zero can be reached. In a refinement of the process, nuclear spins are used instead of electron spins. Because nuclear magnetic moments are much weaker than electron magnetic moments, they do not interact so strongly with the surroundings and so are insulated from it more effectively. Very low temperatures can be reached using nuclear spins, which is called nuclear adiabatic demagnetization. Other approaches have been used to reach very low temperatures. At the University of Colorado, Eric Cornell and Carl Wieman worked with a team of students and researchers to create one of the lowest temperatures ever reached. They cooled a tiny sample of only 10 million rubidium atoms by arranging a beam of infrared radiation along the line of flight of the atoms in a beam traveling in the opposite direction. The impact of the infrared photons brought the atoms almost to a standstill. The atoms were then held in place by a magnetic field and cooled further by allowing the atoms with higher energies to escape. We have seen that S(T) ϭ area under graph of CP /T against T from 0 to the temperature of interest (7) If a phase transition takes place between T ϭ 0 and the temperature of interest, then we also have to include in S(T) the corresponding entropy of transition by using Eq. 5 and possibly Eq. 4 (Fig. 8.12). For instance, if we want to know the entropy of liquid water at 25°C, we measure the heat capacity of ice from T ϭ 0 (or as close to it as we can get) to T ϭ 273.15 K, determine the entropy of fusion at that temperature from the enthalpy of fusion, and then measure the heat capacity of liquid water from T ϭ 273.15 K to T ϭ 298.15 K. Table 8.3 gives selected values of the standard molar entropy, Sm°, the molar entropy of the pure substance at 1 bar. All the values in Table 8.3 refer to 298.15 K, the conventional temperature for reporting thermodynamic data. We can use the molecular interpretation of entropy to understand why some substances have high molar entropies and others have low molar entropies. For example, compare the molar entropy of diamond, 2.4 J·KϪ1 ·molϪ1 , with the much higher value for lead, 64.8 JиKϪ1 ·molϪ1 . The low entropy of diamond is what we should expect for a solid that has rigid bonds: at room temperature, its atoms are not able to jiggle around as much as the atoms of lead. Lead atoms are also much heavier than carbon atoms, and heavier atoms have more vibrational energy levels available than do lighter ones (because their allowed energies are closer together). The difference in molar entropy between two gases (compare H2 and N2 in Table 8.3, for instance) can be understood in terms of the particle-in-a-box model and the fact that the greater the mass of the molecules, the closer together are the energy levels (Fig. 8.13). We also see that large, complex species have higher molar entropies than smaller, simpler ones (compare CaCO3 with CaO or C2H5OH with H2O). Liquids have higher molar entropies than solids because the greater freedom of movement of the molecules in a liquid results in a less ordered state of matter. The molar entropies of gases, in which molecules occupy much larger volumes and undergo almost completely disordered motion, are substantially higher than those of the corresponding liquids. Self-Test 8.11A Which substance in each of the following pairs has the higher molar entropy: (a) 1 mol CO2(g) at 25°C and 1 bar or 1 mol CO2(g) at 25°C and 3 bar; (b) 1 mol He(g) at 25°C or 1 mol He(g) at 100°C in the same volume; (c) Br2(l) or Br2(g) at the same temperature? Explain your conclusions. [Answer: (a) CO2(g) at 1 bar, because disorder increases with volume; (b) He(g) at 100°C, because disorder increases with temperature; (c) Br2(g), because the vapor state has greater disorder than the liquid state.] Self-Test 8.11B Use the information in Table 8.3 or Appendix 2A to determine which allotrope is the more ordered form and predict the sign of ⌬S for each transition: (a) white tin (Fig. 8.14) changes into gray tin at 25°C; (b) diamond changes into graphite at 25°C. 306 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS TABLE 8.3 Standard Molar Entropies at 25°C (JؒK؊1 ؒmol؊1 )* Gases Sm° Liquids Sm° Solids Sm° ammonia, NH3 192.4 benzene, C6H6 173.3 calcium oxide, CaO 39.8 carbon dioxide, 213.7 ethanol, C2H5OH 160.7 calcium carbonate, 92.9 CO2 CaCO3 † hydrogen, H2 130.7 water, H2O 69.9 diamond, C 2.4 nitrogen, N2 191.6 graphite, C 5.7 oxygen, O2 205.1 lead, Pb 64.8 *Additional values are given in Appendix 2A. † Calcite. FIGURE 8.12 The entropy of a solid increases as its temperature is raised. The entropy increases sharply when the solid melts to form the more disordered liquid and then gradually increases again up to the boiling point. A second, larger jump in entropy occurs when the liquid vaporizes. Temperature, T Entropy,S Solid Liquid Gas Meltingpoint Boilingpoint Energy (a) (b) FIGURE 8.13 The energy levels of a particle in a box are more widely spaced for (a) light molecules than for (b) heavy molecules. As a result, the number of thermally accessible levels, as shown by the tinted band, is greater for heavy molecules than for light molecules at the same temperature, and the entropy of the substance with heavy molecules is correspondingly greater. Standard molar entropies increase as the complexity of a substance increases. The standard molar entropies of gases are higher than those of comparable solids and liquids at the same temperature. 8.8 Standard Reaction Entropies Entropy is an important concept in chemistry because it is the basis for predicting the natural direction of a reaction. However, we have to remember that the entropy of the surroundings, not only that of the system, changes as the heat produced or absorbed by the reaction enters or leaves them. Both the entropy change of the system and that of the surroundings affect the direction of a reaction, because both contribute to the entropy of the universe. It is easy to predict the sign of the entropy change of the surroundings if the sign of the reaction enthalpy is known. If the reaction is exothermic, heat is released into the surroundings and their entropy increases (⌬Ssurr Ͼ 0). If the reaction is endothermic, heat leaves the surroundings, so their entropy decreases (⌬Ssurr Ͻ 0). We shall develop this point quantitatively in the following section, but it will be very helpful to keep this qualitative conclusion in mind. In some cases, we can also predict the sign of the entropy change of the system without doing any calculation. For instance, because the molar entropy of a gas is so much greater than that of solids and liquids, a change in the amount of gas molecules normally dominates any other entropy change in a reaction. A net increase in the amount of gas usually results in a positive change in entropy. Conversely, a net consumption of gas usually results in a negative change. Reactions that produce a large number of small molecules and the dissolving of a substance typically have positive entropies. However, entropy changes are much more finely balanced for reactions in which there is no net change in the amount of gas or in which gases do not take part, and for these reactions we have to use numerical data to predict the sign of the entropy change of the system. Self-Test 8.12A Without doing any calculations, estimate the sign of the entropy change of the system for the reaction N2(g) ϩ 3 H2(g) : 2 NH3(g) and explain your answer. [Answer: negative, because there is a net decrease in the number of moles of gas molecules] Self-Test 8.12B Without doing any calculations, estimate the sign of the entropy change of the system for the reaction CaCO3(s) : CaO(s) ϩ CO2(g) and explain your answer. To calculate the change in entropy that accompanies a reaction, we need to know the molar entropies of all the substances taking part; then we calculate the difference between the entropies of the products and those of the reactants. More specifically, the standard reaction entropy, ⌬S°, is the difference between the standard molar entropies of the products and those of the reactants, taking into account their stoichiometric coefficients: (8)* The first term on the right is the total standard entropy of the products, and the second term is that of the reactants; n denotes the amount of each substance in the chemical equation. Provided the temperature of interest is 25°C, we can use the values in Table 8.3 and Appendix 2A to calculate ⌬S°. ¢S° = anSm°(products) - anSm°(reactants) 8.8 STANDARD REACTION ENTROPIES 307 FIGURE 8.14 Gray tin and white tin are two solid forms of tin. The denser white metallic form is the more stable phase above 13°C, and the powdery gray form is more stable below that temperature. White tin Gray tin EXAMPLE 8.9 Calculating the standard reaction entropy Calculate the standard reaction entropy of N2(g) ϩ 3 H2(g) : 2 NH3(g) at 25°C. Anticipate We expect a decrease in entropy because there is a net reduction in the amount of gas molecules. PLAN To find the numerical value, we use the chemical equation to write an expression for ⌬S°, as shown in Eq. 8, and then substitute values from Table 8.3 or Appendix 2A. Evaluate Because the value of ⌬S° is negative, the product is less disordered than the reactants— in part because it occupies a smaller volume—just as we expected. A note on good practice: Avoid the error of setting the standard entropies of elements equal to zero, as you would for ⌬Hf°: the entropies to use are the absolute values for the given temperature and are zero only at T ϭ 0. Self-Test 8.13A Use data from Appendix 2A to calculate the standard reaction entropy of N2O4(g) : 2 NO2(g) at 25°C. [Answer: ϩ175.83 JиKϪ1 ] Self-Test 8.13B Use data from Appendix 2A to calculate the standard reaction entropy of C2H4(g) ϩ H2(g) : C2H6(g) at 25°C. The standard reaction entropy is the difference between the standard molar entropy of the products and that of the reactants weighted by the amounts of each species taking part in the reaction. It is positive (an increase in entropy) if there is a net production of gas in a reaction; it is negative (a decrease) if there is a net consumption of gas. GLOBAL CHANGES IN ENTROPY Some processes seem to defy the second law. For example, water spontaneously freezes to ice at low temperatures, and cold packs for athletic injuries spontaneously become ice cold, even on warm days, when the ammonium nitrate inside the pack dissolves in the water that it contains. Life itself appears to go against the second law. Every cell of a living being is organized to an extraordinary extent. Thousands of different compounds, each one having a specific function to perform, move in the intricately organized dance we call life. How can the molecules in our bodies form such highly organized, complex structures from slime, mud, or gas? Our existence seems at first sight to be a contradiction of the second law. The dilemma is resolved when we realize that the second law refers to an isolated system. To interpret the second law correctly, we must consider any system to be part of a larger isolated system that includes the surroundings of the system of interest. The process is spontaneous only if the total change in entropy, the sum of the changes in the system and the surroundings, is positive. Our task, therefore, is first to see how to calculate the change in entropy of the surroundings and then to combine that change with the change in entropy of the system. We have already mentioned what we should expect qualitatively: exothermic processes lead to an increase in the entropy of the surroundings and endothermic processes reduce it. Now we have to make this qualitative conclusion quantitative. Then, once we know the total entropy change, we shall be able to predict whether a reaction is spontaneous, whether its reverse is spontaneous, or whether the system is at equilibrium. 8.9 The Surroundings The system of interest and its surroundings constitute the “isolated system” to which the second law refers (Fig. 8.15). Only if the total entropy change, (9)*¢Ssurr¢S¢Stot 308 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS From the chemical equation, we can write = -198.9 JиK-1 = 2(192.4 JиK-1 ) - {(191.6 JиK-1 ) + 3(130.7 JиK-1 )} ¢S° = (2 mol)Sm°(NH3, g) - {(1 mol)Sm°(N2, g) + (3 mol)Sm°(H2, g)} SOLVE $++%++& Product $++++++%++++++& Reactants Total entropy change $%& Entropy change of system # $%& Entropy change of surroundings ϭ ϩ FIGURE 8.15 The global isolated system that models events taking place in the world consists of a smaller system together with its immediate surroundings. The only events that can take place spontaneously in the global isolated system are those corresponding to an increase in the total entropy of both the smaller system and its immediate surroundings. System of interest System, ⌬S Surroundings, ⌬Ssurr Total, ⌬Stot EXAMPLE 8.10 Calculating the change in entropy of the surroundings Calculate the change in entropy of the surroundings when water freezes at Ϫ10.°C; use ⌬Hfus(H2O) ϭ 6.0 kJиmolϪ1 at Ϫ10.°C. Anticipate We expect the entropy of the surroundings to increase when water freezes because the heat released stirs up the thermal motion of the atoms in the surroundings (Fig. 8.17). PLAN To calculate the change in entropy of the surroundings when water freezes we write ⌬Hfreeze ϭ Ϫ⌬Hfus and convert the temperature to kelvins. What should we assume? That the temperature of the surroundings is constant and that ⌬Hfus is the same at Ϫ10.°C as it is at 0°C. SOLVE ⌬Hfreeze ϭ Ϫ⌬Hfus ϭ Ϫ6.0 kJиmolϪ1 and T ϭ (Ϫ10. ϩ 273) K ϭ 263 K. Then is positive will the process be spontaneous. As is customary, properties of the system are written without subscripts; so here ⌬S is the entropy change of the system and ⌬Ssurr that of the surroundings. It is critically important to understand that a process in which ⌬S decreases may be spontaneous, provided that the entropy increases so much in the surroundings that ⌬Stot increases. An example of the role of the surroundings in determining the spontaneous direction of a process is the freezing of water. We can see from Table 8.2 that, at 0°C, the molar entropy of liquid water is 22.0 JиKϪ1 иmolϪ1 higher than that of ice at the same temperature. It follows that, when water freezes at 0°C, its entropy decreases by 22.0 JиKϪ1 иmolϪ1 . Although the entropies of substances increase as the temperature increases, they do so at about the same rate, so entropy changes for a phase transition or chemical reaction do not vary much with temperature. Therefore, just below 0°C, we can expect almost the same decrease. Yet we know from everyday experience that the freezing of water is spontaneous below 0°C. Clearly, the surroundings must be playing a deciding role: if their entropy increases by more than 22.0 JиKϪ1 иmolϪ1 when water freezes, then the total entropy change will be positive. We can use Eq. 1 to calculate the entropy change of the surroundings by noting the following steps: • Because the surroundings are always taken to be large, their temperature remains constant however much energy is transferred to or from them as heat, so we can always use Eq. 1 in the form ⌬Ssurr ϭ qsurr, rev/T. • The heat that leaves the system enters the surroundings, qsurr ϭ Ϫq (so if q ϭ Ϫ10 kJ, meaning that 10 kJ has left the system, qsurr ϭ ϩ10 kJ, meaning that 10 kJ has entered the surroundings). • For a system maintained at constant pressure the heat that leaves the system can be equated to the change in enthalpy of the system and we can write q ϭ ⌬H, and therefore qsurr ϭ Ϫ⌬H. • Because the surroundings are large, any transfer of heat into them will, from their perspective, be so tiny that it can be regarded as occurring reversibly and hence qsurr,rev ϭ Ϫ⌬H. We can therefore write (10)* This important formula, which can be derived more formally from the laws of thermodynamics, applies when any change takes place in a system maintained at constant pressure and temperature. Notice that, for a given enthalpy change of the system (that is, a given output of heat), the entropy of the surroundings increases more if their temperature is low than if it is high (Fig. 8.16). The explanation is the “sneeze in the street” analogy mentioned in Section 8.2. Because ⌬H is independent of path, Eq. 10 is applicable whether the process occurs reversibly or irreversibly. ¢Ssurr = - ¢H T at constant temperature and pressure 8.9 THE SURROUNDINGS 309 FIGURE 8.16 (a) When a given quantity of heat flows into hot surroundings, it produces very little additional chaos and the increase in entropy is small. (b) When the surroundings are cool, however, the same quantity of heat can make a considerable difference to the disorder, and the change in entropy of the surroundings is correspondingly large. Heat System System Warm Cool EntropyEntropy (b) (a) FIGURE 8.17 (a) In an exothermic process, heat escapes into the surroundings and increases their entropy. (b) In an endothermic process, the entropy of the surroundings decreases. The red arrows represent the transfer of heat between system and surroundings, and the green arrows indicate the entropy change of the surroundings. Entropy of the surroundings Heat (a) (b) 310 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS 263 K ϩ23 J·K Ϫ1 ·mol Ϫ1 6.01 kJ·mol Ϫ1 From ⌬Ssurr ϭ Ϫ⌬H/T, = +23 JиK-1 иmol-1 ¢Ssurr = (-6.0 * 103 Jиmol-1 ) 263 Evaluate Note that the increase in entropy of the surroundings is indeed greater than the decrease in entropy of the system, Ϫ22.0 JиKϪ1 (the value at –10.°C is similar to that at 0°C), so the overall change is positive and the freezing of water is spontaneous at Ϫ10.°C. Self-Test 8.14A Calculate the entropy change of the surroundings when 1.00 mol H2O(l) vaporizes at 90°C and 1 bar. Take the enthalpy of vaporization of water as 40.7 kJиmolϪ1 . [Answer: Ϫ112 JиKϪ1 ] Self-Test 8.14B Calculate the entropy change of the surroundings when 2.00 mol NH3(g) is formed from the elements at 298 K. The entropy change of the surroundings due to a process taking place at constant pressure and temperature is equal to ؊⌬H/T, where ⌬H is the change in enthalpy of the system. 8.10 The Overall Change in Entropy As we have already emphasized, to use the entropy to judge the direction of spontaneous change, we must consider the change in the entropy of the system plus the entropy change in the surroundings: If ⌬Stot is positive (an increase), the process is spontaneous. If ⌬Stot is negative (a decrease), the reverse process is spontaneous. If ⌬Stot ϭ 0, the process has no tendency to proceed in either direction. In an exothermic reaction, such as the synthesis of ammonia or a combustion reaction, the heat released by the reaction increases the disorder of the surroundings. In some cases, the entropy of the system may decrease, as when a gaseous reactant is converted into a solid or liquid. However, provided that ⌬H is large and negative, the release of energy as heat into the surroundings increases their entropy so much that it dominates the overall change in entropy and the reaction is spontaneous (Fig. 8.18). FIGURE 8.18 In an exothermic reaction, (a) the overall entropy change is certainly positive when the entropy of the system increases. (b) The overall entropy change may also be positive when the entropy of the system decreases. The reaction is spontaneous in both cases. Total entropy Entropy of the surroundings Entropy of the system Heat (a) (b) EXAMPLE 8.11 Calculating the total change in entropy accompanying a reaction Assess whether the combustion of magnesium is spontaneous at 25°C under standard conditions, given 2 Mg(s) ϩ O2(g) 2 MgO(s) ⌬S° ϭ Ϫ217 JиKϪ1 ⌬H° ϭ Ϫ1202 kJ Anticipate We know that magnesium burns in air with a brilliant flame (recall the illustration on p. F2), so we should be confident that the combustion, like all combustions, is spontaneous (in the thermodynamic sense). PLAN Find the entropy change in the surroundings by using Eq. 10, then calculate the total entropy change by using Eq. 9. SOLVE ¡ Ϫ217 J·K Ϫ1 Determine the change in entropy of the system (given in this case). ⌬S° ϭ Ϫ217 JиKϪ1 8.10 THE OVERALL CHANGE IN ENTROPY 311 1202 kJ ϩ4.03 kJ·K Ϫ1 ϩ4 Determine the change in entropy of the surroundings from ⌬Ssurr° ϭ Ϫ⌬H°/T. ϭ ϩ4.03 ϫ 103 JиKϪ1 ¢Ssurr° = (-1.202 * 106 J) 298 K ϩ3.81 kJ·K Ϫ1 ϩ3.81 kJk ·K Ϫ Determine the total change in entropy from ⌬Stot° ϭ ⌬S° ϩ ⌬Ssurr. ⌬Stot° ϭ Ϫ217 JиKϪ1 ϩ (4.03 ϫ 103 JиKϪ1 ) ϭ ϩ3.81 ϫ 103 JиKϪ1 Evaluate Because ⌬Stot° is positive, the reaction is spontaneous under standard conditions even though the entropy of the system decreases. Self-Test 8.15A Is the formation of hydrogen fluoride from its elements spontaneous under standard conditions at 25°C? For the reaction H2(g) ϩ F2(g) : 2 HF(g), ⌬H° ϭ Ϫ542.2 kJ and ⌬S° ϭ ϩ14.1 JиKϪ1 . [Answer: ⌬Ssurr ϭ ϩ1819 JиKϪ1 ; therefore, ⌬Stot ϭ ϩ1833 JиKϪ1 ; spontaneous] Self-Test 8.15B Is the formation of benzene from its elements spontaneous at 25°C? For the reaction 6 C(s, graphite) ϩ 3 H2(g) : C6H6(l), ⌬H° ϭ ϩ49.0 kJ and ⌬S° ϭ Ϫ253.18 JиKϪ1 . Spontaneous endothermic reactions were a puzzle for nineteenth-century chemists, who believed that reactions ran only in the direction of decreasing energy of the system. It seemed to them that, in endothermic reactions, reactants were rising spontaneously to higher energies, like a weight suddenly leaping up from the floor onto a table. However, the criterion for spontaneity is an increase in the total entropy of the system and its surroundings, not a decrease in the energy of a system. In an endothermic reaction, the entropy of the surroundings certainly decreases as heat flows from them into the system. Nevertheless, there can still be an overall increase in entropy if the disorder of the system increases enough. Every endothermic reaction must be accompanied by increased disorder of the system if it is to be spontaneous (Fig. 8.19): spontaneous endothermic reactions are driven by the dominating increase in disorder of the system. By considering the total entropy change, we can draw some far-reaching conclusions about processes going on in the universe. For instance, we saw in Section 7.3 that maximum work is achieved if expansion takes place reversibly, by matching the external pressure to the pressure of the system at every stage. That relation is always true: a process produces maximum work if it takes place reversibly. That is, wrev is more negative (more energy leaves the system as work) than wirrev. However, because the internal energy is a state function, ⌬U is the same for any path between the same two states. Therefore, because ⌬U ϭ q ϩ w, it follows that qrev, the heat absorbed along the reversible path, must be greater than qirrev, the heat absorbed along any other path, because only then can the sums of q and w be the same for the two paths. If now we replace qrev in Eq. 1 by the smaller quantity qirrev, we get ⌬S Ͼ qirrev/T. In general, we can write the Clausius inequality: (11a)*¢S Ú q T FIGURE 8.19 An endothermic reaction is spontaneous only if the entropy of the system increases enough to overcome the decrease in entropy of the surroundings. Total entropy Entropy of the surroundings Entropy of the system Heat with the equality valid for a reversible process. For a fully isolated system like that in Fig. 8.15, q ϭ 0 for any process taking place inside the system. It follows from Eq. 11a that for any process in an isolated system (11b) That is, we have shown that the entropy cannot decrease in an isolated system. This is another statement of the second law of thermodynamics. It tells us, in effect, that, as a result of all the processes going on around us, the entropy of the universe is steadily increasing. Now consider an isolated system consisting of both the system that interests us and its surroundings (again like that in Fig. 8.15). For any spontaneous change in this isolated system, we know from Eq. 11b that ⌬Stot Ͼ 0. If we calculate for a particular hypothetical process that ⌬Stot Ͻ 0, we can conclude that the reverse of that process is spontaneous. A final point is that reversible and irreversible paths between two given states of the system leave the surroundings in different states. Because entropy is a state function, the value of ⌬S, the change in entropy of the system, is the same for both paths. However, ⌬Stot is different for the two paths because the entropy of the surroundings changes by different amounts in each case. For example, the isothermal expansion of an ideal gas always results in the change in the entropy of the system given by Eq. 3. However, the change in entropy of the surroundings is different for reversible and irreversible paths because the surroundings are left in different states in each case (Fig. 8.20). Table 8.4 lists the characteristics of reversible and irreversible processes. ¢S Ú 0 312 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS FIGURE 8.20 (a) When a process takes place reversibly—that is, when the system is at equilibrium with its surroundings—the change in entropy of the surroundings is the negative of the change in entropy of the system and the overall change is zero. (b) For an irreversible change between the same two states of the system, the final state of the surroundings is different from the final state in part (a), and the change in the system is not canceled by the entropy change of the surroundings. Overall, there is an increase in entropy. ⌬Stot = 0 ⌬Stot > 0 (a) (b) TABLE 8.4 Criteria for Spontaneity ⌬S ⌬Ssurr ⌬Stot Character Ͼ0 Ͼ0 Ͼ0 spontaneous Ͻ0 Ͻ0 Ͻ0 not spontaneous; reverse change is spontaneous Ͼ0 Ͻ0 spontaneous if ⌬S is greater than Ϫ⌬Ssurr Ͻ0 Ͼ0 spontaneous if ⌬Ssurr is greater than Ϫ⌬S EXAMPLE 8.12 Calculating the total entropy change for the expansion of an ideal gas Calculate ⌬S, ⌬Ssurr, and ⌬Stot for (a) the isothermal, reversible expansion and (b) the isothermal, free expansion of 1.00 mol of ideal gas molecules from 8.00 L to 20.00 L at 292 K. Explain any differences between the two paths. Anticipate (a) We should expect a positive increase in the entropy of the expanding gas but because the expansion is reversible, a total entropy change of zero. (b) For an irreversible expansion we should expect the total entropy change to be positive. PLAN Because entropy is a state function, the change in entropy of the system is the same regardless of the path between the two states, so we can use Eq. 3 to calculate ⌬S for both part (a) and part (b). For the entropy of the surroundings, we need to find the heat transferred to the surroundings. In each case, we can combine the fact that ⌬U ϭ 0 for an isothermal expansion of an ideal gas with ⌬U ϭ w ϩ q and conclude that q ϭ –w. We then use Eq. 4 in Chapter 7 to calculate the work done in an isothermal, reversible expansion of an ideal gas and Eq. 9 in this chapter to find the total entropy. The changes that we calculate are summarized in Fig. 8.21. ⌬Stot = 0 ⌬Ssurr = 0 ⌬S = ϩ7.6 J·KϪ1 ⌬S = ϩ7.6 J·KϪ1 ⌬Ssurr = Ϫ7.6 J·KϪ1 ⌬Stot = ϩ7.6 J·KϪ1 (a) (b) FIGURE 8.21 The changes in entropy and internal energy when an ideal gas undergoes (a) reversible and (b) irreversible changes between the same two states, as described in Example 8.12. SOLVE (a) For the reversible path, 8.10 THE OVERALL CHANGE IN ENTROPY 313 From ⌬S ϭ nR ln (V2/V1), ϭ ϩ7.6 JиK–1 ¢S = (1.00 mol) * (8.3145 JиK-1 иmol-1 ) * ln 20.0 L 8.00 L 1 mol ϩ7.6 J·K Ϫ1 From qsurr ϭ Ϫq, q ϭ Ϫw, and w ϭ ϪnRT ln (V2/V1), qsurr = -nRT ln V2 V1 w q Ϫq surr w ϩ q ϭ 0 From ⌬Ssurr ϭ qsurr/T, ¢Ssurr = - nRT T ln V2 V1 = -nR ln V2 V1 = -¢S = -7.6 JиK-1 Ϫ7.6 J·K Ϫ1 From ⌬Stot ϭ ⌬S ϩ ⌬Ssurr, ⌬Stot ϭ 7.6 JиK–1 – 7.6 JиK–1 ϭ 0 0 The change in the entropy of the gas is positive, as expected. Because ⌬U ϭ 0, q ϭ –w. Therefore, because the heat that flows into the surroundings is equal to the heat that flows out of the system, (b) For the irreversible process. No work is done in free expansion (Section 7.3), and so w ϭ 0. Because ⌬U ϭ 0, it follows that q ϭ 0 and therefore qsurr ϭ 0 From ⌬Ssurr ϭ qsurr/T, ⌬Ssurr ϭ 0 ⌬S is the same, at ϩ7.6 JиK–1 . The total change in entropy is therefore ⌬Stot ϭ ϩ7.6 JиK–1 Evaluate As expected, for the reversible process ⌬Stot ϭ 0 and for the irreversible process ⌬Stot Ͼ 0. Self-Test 8.16A Determine ⌬S, ⌬Ssurr, and ⌬Stot for (a) the reversible, isothermal expansion and (b) the isothermal free expansion of 1.00 mol of ideal gas molecules from 10.00 atm and 0.200 L to 1.00 atm and 2.00 L at 298 K. [Answer: (a) ⌬S ϭ ϩ19.1 JиK–1 ; ⌬Ssurr ϭ –19.1 JиK–1 ; ⌬Stot ϭ 0; (b) ⌬S ϭ ϩ19.1 JиK–1 ; ⌬Ssurr ϭ 0; ⌬Stot ϭ ϩ19.1 JиK–1 ] Self-Test 8.16B Determine ⌬S, ⌬Ssurr, and ⌬Stot for the reversible, isothermal compression of 2.00 mol of ideal gas molecules from 1.00 atm and 4.00 L to 20.00 atm and 0.200 L at 298 K. A process is spontaneous if it is accompanied by an increase in the total entropy of the system and the surroundings. 8.11 Equilibrium Although this section provides only a brief introduction to equilibrium, the principles presented here are critically important, because the tendency of reactions to proceed toward equilibrium is the basis of much of chemistry. The material in this section lays the foundation for the next five chapters, including phase changes, the reactions of acids and bases, and redox reactions. A system at equilibrium has no tendency to change in either direction (forward or reverse). Such a system remains in its current state until it is disturbed by changing the conditions, such as raising the temperature, decreasing the volume, or adding more reactants. The equilibrium state important in chemistry is a dynamic equilibrium, in which forward and reverse processes still continue but at matching rates. For example, when a block of metal is at the same temperature as its surroundings, it is in thermal equilibrium with its surroundings. Energy continues to flow in both directions, but at the same rate; there is no net flow (Fig. 8.22). When a gas confined to a cylinder by a piston has the same pressure as that of the surroundings, the system is in mechanical equilibrium with the surroundings and the gas has no tendency to expand or contract. The pressure inside is causing the piston to move outward, but the pressure outside is causing the piston to move inward to the same extent, and there is no net change. When a solid, such as ice, is in contact with its liquid form, such as water, at certain conditions of temperature and pressure (at 0°C and 1 atm for water), the two states of matter are in dynamic equilibrium with each other, and there is no tendency for one form of matter to change into the other form. When solid and liquid water are at equilibrium, water molecules continually leave solid ice to form liquid water, and water molecules continually leave the liquid phase to form ice. However, there is no net change, because these processes occur at the same rate and so balance each other. When a chemical reaction mixture reaches a certain composition, the reaction seems to come to a halt. A mixture of substances at chemical equilibrium has no tendency either to produce more products or to revert to reactants. At equilibrium, reactants are still forming products, but products are decaying at a matching rate into reactants and there is no net change of composition. The common characteristic of any kind of dynamic equilibrium is the continuation of processes at the microscopic level but no net tendency for the system to change in either the forward or the reverse direction. That is, neither the forward nor the reverse process is spontaneous. Expressed thermodynamically, ⌬Stot ϭ 0 (12)* The total entropy varies with the composition of a reaction mixture and by looking for the composition at which ⌬Stot ϭ 0, we can predict the equilibrium composition of the reaction. At this composition, the reaction has no tendency either to form more products or to decompose into reactants. Self-Test 8.17A Confirm that liquid water and water vapor are in equilibrium when the temperature is 100.°C and the pressure is 1 atm. Data are available in Tables 7.3 and 8.2. [Answer: ⌬Stot ϭ 0 at 100.°C] Self-Test 8.17B Confirm that liquid benzene and benzene vapor are in equilibrium at the normal boiling point of benzene, 80.1°C, and 1 atm pressure. The enthalpy of vaporization of benzene at its boiling point is 30.8 kJиmol–1 and its entropy of vaporization is 87.2 JиK–1 иmol–1 . The general criterion for equilibrium in thermodynamics is ⌬Stot ‫؍‬ 0. 314 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS High temperature Thermal equilibrium Low temperature Heat Heat FIGURE 8.22 Energy flows as heat from a high-temperature region (dark red) to a low-temperature region (tan) through a thermally conducting wall. A system is in thermal equilibrium with its surroundings when the temperatures on both sides of the wall are the same (center). However, because the systems are in contact, energy continues to flow as heat, but at the same rate in each direction. 8.12 FOCUSING ON THE SYSTEM 315 GIBBS FREE ENERGY One of the problems with using the second law to judge whether a reaction is spontaneous is that to get the total entropy change we must calculate three quantities: the entropy change of the system, the entropy change of the surroundings, and the sum of the two changes. We could avoid some of this work if a single property combined the entropy calculations for the system and the surroundings. We could then carry out the calculation in one step by using a single table of data. This simplification is achieved by introducing a new state function, the “Gibbs free energy.” Not only does the Gibbs free energy allow us to assess whether a reaction is spontaneous, it also tells us how much nonexpansion work we can get from the system—a central consideration in the study of foods and fuels—and how a change in temperature can change the spontaneity of a reaction. In Chapter 10, we shall also see how the Gibbs free energy controls the composition of a reaction mixture at equilibrium. The Gibbs free energy is probably the single most widely used and useful quantity in the application of thermodynamics to chemistry. 8.12 Focusing on the System The total entropy change, ⌬Stot, is the sum of the changes in the system, ⌬S, and its surroundings, ⌬Ssurr, with ⌬Stot ϭ ⌬S ϩ ⌬Ssurr. For a process at constant temperature and pressure, the change in the entropy of the surroundings is given by Eq. 10, ⌬Ssurr ϭ –⌬H/T. Therefore, at constant temperature and pressure (13) This equation shows how to calculate the total entropy change from information about the system alone. The limitation is that the equation is valid only at constant temperature and pressure. To take the next step, we introduce the Gibbs free energy, G, which is defined as G ϭ H – TS (14)* This quantity, which is commonly known as the free energy and more formally as the Gibbs energy, is defined solely in terms of state functions, and so G is a state function. Throughout chemistry, we use only changes in Gibbs free energy, not its absolute values; and, for a process occurring at constant temperature, the change in Gibbs free energy is ⌬G ϭ ⌬H – T⌬S at constant temperature (15)* By comparing this expression rearranged into with Eq. 13, where there is the additional constraint of constant pressure, we see that ⌬G/T ϭ –⌬Stot and therefore that ⌬G ϭ –T⌬Stot at constant temperature and pressure (16) The minus sign in this equation means that, provided the temperature and pressure are constant, an increase in total entropy corresponds to a decrease in Gibbs free energy. Therefore, at constant temperature and pressure, the direction of spontaneous change is the direction of decreasing Gibbs free energy (Fig. 8.24). The great importance of the introduction of Gibbs free energy is that, provided that the temperature and pressure are constant, we can predict the spontaneity of a process solely in terms of the thermodynamic properties of the system. Note that we have restricted this discussion to processes at constant temperature and pressure, but by doing so we can express spontaneity under common laboratory conditions in terms of the system alone. ¢G T = ¢H T - ¢S ¢Stot = ¢S + ¢Ssurr = ¢S - ¢H T The Gibbs free energy is named for Josiah Willard Gibbs (Fig. 8.23), the nineteenth-century American physicist who was responsible for turning thermodynamics from an abstract theory into a subject of great usefulness. FIGURE 8.23 Josiah Willard Gibbs (1839–1903). ()* Ϫ⌬H/T 316 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS Gibbsfreeenergy,G Process Spontaneous Equilibrium FIGURE 8.24 At constant temperature and pressure, the direction of spontaneous change is toward lower Gibbs free energy. The horizontal axis represents the progress of the reaction or process. The equilibrium state of a system corresponds to the lowest point on the curve. Equation 15 summarizes the factors that determine the direction of spontaneous change at constant temperature and pressure: for a spontaneous change, we look for values of ⌬H, ⌬S, and T that result in a negative value of ⌬G (Table 8.5). One condition that may result in a negative ⌬G is a large negative ⌬H, such as that for a combustion reaction. As we have seen, a large negative ⌬H corresponds to a large increase in the entropy of the surroundings. However, a negative ⌬G can occur even if ⌬H is positive (an endothermic reaction), provided that T⌬S is large and positive. In this case, as we saw in Section 8.10, the driving force of the reaction is the increase in entropy of the system. Self-Test 8.18A Can a nonspontaneous process with a negative ⌬S become spontaneous if the temperature is increased (assuming that ⌬H and ⌬S are both independent of temperature)? [Answer: No] Self-Test 8.18B Can a nonspontaneous process with a positive ⌬S become spontaneous if the temperature is increased (assuming that ⌬H and ⌬S are both independent of temperature)? We have seen that the criterion for equilibrium is ⌬Stot ϭ 0. It follows from Eq. 16 that, for a process at constant temperature and pressure, the condition for equilibrium is ⌬G ϭ 0 at constant temperature and pressure (17) If we find that ⌬G ϭ 0 for a process, then we know at once that the system is at equilibrium. For example, when ice and water are in equilibrium with each other at a particular temperature and pressure, the Gibbs free energy of 1 mol H2O(l) must be the same as the Gibbs free energy of 1 mol H2O(s). In other words, the molar Gibbs free energy, the Gibbs free energy per mole, of water in each phase is the same. TABLE 8.5 Factors That Favor Spontaneity Enthalpy change Entropy change Spontaneous? exothermic (⌬H Ͻ 0) increase (⌬S Ͼ 0) yes, ⌬G Ͻ 0 exothermic (⌬H Ͻ 0) decrease (⌬S Ͻ 0) yes, if ⏐T⌬S⏐ Ͻ ⏐⌬H⏐, ⌬G Ͻ 0 endothermic (⌬H Ͼ 0) increase (⌬S Ͼ 0) yes, if T⌬S Ͼ ⌬H, ⌬G Ͻ 0 endothermic (⌬H Ͼ 0) decrease (⌬S Ͻ 0) no, ⌬G Ͼ 0 EXAMPLE 8.13 Deciding whether a process is spontaneous Calculate the change in molar Gibbs free energy, ⌬Gm, for the process H2O(s) : H2O(l) at 1 atm and (a) 10.°C; (b) 0.°C. Decide for each temperature whether melting is spontaneous or not. Treat ⌬Hfus and ⌬Sfus as independent of temperature. Anticipate Because the solid and liquid phases are in equilibrium at the melting point, we expect to find that ⌬G ϭ 0 at 0.°C. Above that temperature the melting of the solid state is favored so we expect that ⌬G will be negative at 10.°C. PLAN Find the enthalpy of fusion of water in Table 7.3 (the values there are for 1 atm and the transition temperature). The entropy of fusion of water is given in Section 8.9. Use Eq. 15 to calculate the change in free energy. What should we assume? That ⌬Hfus and ⌬Sfus are constant over the temperature range of interest. SOLVE The enthalpy of fusion is 6.01 kJиmol–1 and the entropy of fusion is 22.0 JиK–1 иmol–1 . These values are almost independent of temperature over the temperature range considered. Evaluate As expected, because the difference in molar Gibbs free energy is negative at 10.°C, melting is spontaneous at that temperature, but at 0.°C, ice and water are in equilibrium. Self-Test 8.19A Calculate the change in molar Gibbs free energy for the process H2O(l) : H2O(g) at 1 atm and (a) 95°C; (b) 105°C. The enthalpy of vaporization is 40.7 kJиmol–1 , and the entropy of vaporization is 109и1 J·K–1 ·mol–1 . In each case, indicate whether vaporization would be spontaneous or not. [Answer: (a) ϩ0.6 kJ·mol–1 , not spontaneous; (b) Ϫ0.5 kJ·mol–1 , spontaneous] Self-Test 8.19B Calculate the change in molar Gibbs free energy for the process Hg(l) : Hg(g) at 1 atm and (a) 350.°C; (b) 370.°C. The enthalpy of vaporization is 59.3 kJиmol–1 , and the entropy of vaporization is 94.2 JиK–1 иmol–1 . In each case, indicate whether or not vaporization would be spontaneous. The Gibbs free energy of a substance decreases as its temperature is raised at constant pressure. This conclusion follows from the definition G ϭ H Ϫ TS and the fact that the entropy of a pure substance is invariably positive; as T increases, TS increases, too, and a larger quantity is subtracted from H. Another important conclusion is that, because the molar entropy of the gas phase of a substance is greater than that of its liquid phase, the Gibbs free energy decreases more sharply with temperature for the gas phase of a substance than for the liquid phase. Similarly, the Gibbs free energy of the liquid phase of a substance decreases more sharply than that of its solid phase (Fig. 8.25). We can now see the thermodynamic origin of phase transitions. At low temperatures, the molar Gibbs free energy of the solid phase lies lowest; so there is a spontaneous tendency for a liquid to freeze and thereby reduce its Gibbs free energy. Above a certain temperature, the molar Gibbs free energy of the liquid has fallen below that of the solid, and the substance has a spontaneous tendency to melt. At an even higher temperature, the molar Gibbs free energy of the gas phase has fallen to below the liquid line, and the substance has a spontaneous tendency to vaporize. The temperature of each phase change corresponds to the point of intersection of the lines for the two phases, as can be seen in Fig. 8.25. The relative positions of the three lines shown in Fig. 8.25 are different for each substance. One possibility—which depends on the strength of intermolecular interactions in the condensed phases—is for the liquid line to lie in the position shown in Fig. 8.26. In this case, the liquid line is never the lowest line, at any temperature. As soon as the temperature has been raised above the point corresponding to the intersection of the solid and gas lines, the direct transition of the solid to the vapor becomes spontaneous. 8.12 FOCUSING ON THE SYSTEM 317 From ⌬Gm ϭ ⌬Hm Ϫ T⌬Sm, ⌬Hm (273.15 ϩ 10.) K ⌬Sm = -0.22 kJиmol-1 = 6.01 kJиmol-1 - 6.23 kJиmol-1 = 6.01 kJиmol-1 - 6.23 * 103 Jиmol-1 ¢Gm = 6.01 kJиmol-1 - (283 K) * (22.0 JиK-1 иmol-1 ) ⌬G ⌬H T⌬S Ϫ6.23 kJ·molϪ1 ϩ6.01 kJ·mol Ϫ1 Ϫ0.22 kJ·mol Ϫ1 A note on good practice: Be sure to convert joules to kilojoules before subtracting T⌬S from ⌬H. (b) At 0.°C From ⌬Gm ϭ ⌬Hm – T⌬Sm, ⌬Gm ϭ 6.01 kJиmol–1 Ϫ (273 K) ϫ (22.0 JиK–1 ·mol–1 ) ϭ 6.01 kJиmol–1 Ϫ 6.01 kJиmol–1 ϭ 0 Ϫ6.01 kJ·molϪ1 ϩ6.01 kJ·mol Ϫ1 0 ⌬H T⌬S ⌬G (++)++* ()* (+++)+++* Temperature, T MolarGibbsfreeenergy,Gm Vapor Liquid Solid Solid stable Liquid stable Vapor stable FIGURE 8.25 The variation of the (molar) Gibbs free energy with temperature for three phases of a substance at a given pressure. The most stable phase is the phase with lowest molar Gibbs free energy. We see that, as the temperature is raised, the solid, liquid, and vapor phases in succession become the most stable. 103 J # Temperature, T MolarGibbsfreeenergy,Gm Vapor Liquid Solid Solid stable Vapor stable FIGURE 8.26 For some substances and at certain pressures, the molar Gibbs free energy of the liquid phase might never lie lower than those of the other two phases. For such substances, the liquid is never the stable phase and, at constant pressure, the solid sublimes when the temperature is raised to the point of intersection of the solid and vapor lines. (a) At 10.°C This plot is the type that we would expect for carbon dioxide, which sublimes at atmospheric pressure. The change in Gibbs free energy for a process is a measure of the change in the total entropy of a system and its surroundings at constant temperature and pressure. Spontaneous processes at constant temperature and pressure are accompanied by a decrease in Gibbs free energy. 8.13 Gibbs Free Energy of Reaction The decrease in Gibbs free energy as a signpost of spontaneous change and ⌬G ϭ 0 as a criterion of equilibrium are applicable to any kind of process, provided that it is occurring at constant temperature and pressure. Because chemical reactions are our principal interest in chemistry, we now concentrate on them and look for a way to calculate ⌬G for a reaction. The thermodynamic function used as the criterion of spontaneity for a chemical reaction is the Gibbs free energy of reaction, ⌬G (which is commonly referred to as the “reaction free energy”). This quantity is defined as the difference in molar Gibbs free energies, Gm, of the products and the reactants: (18) The n are the stoichiometric amounts of each substance in the chemical equation. For example, for the formation of ammonia, N2(g) ϩ 3 H2(g) : 2 NH3(g): ⌬G ϭ {(2 mol) ϫ Gm(NH3)} Ϫ {(1 mol) ϫ Gm(N2) ϩ (3 mol) ϫ Gm(H2)} The molar Gibbs free energy of a substance in a mixture depends on what molecules it has as neighbors, so the molar Gibbs free energies of NH3, N2, and H2 change as the reaction proceeds. For example, at an early stage of the reaction, an NH3 molecule has mostly N2 and H2 molecules around it, but at a later stage of the reaction, most of its neighbors may be NH3 molecules. Because the individual Gibbs free energies change as the reaction proceeds, the Gibbs free energy of reaction also changes. If ⌬G Ͻ 0 at a certain composition of the reaction mixture, then the reaction is spontaneous. If ⌬G Ͼ 0 at a certain composition, then the reverse reaction (the decomposition of ammonia in our example), is spontaneous. The standard Gibbs free energy of reaction, ⌬G°, is defined like the Gibbs free energy of reaction but in terms of the standard molar Gibbs energies of the reactants and products: (19) That is, the standard Gibbs free energy of reaction is the difference in Gibbs free energy between the products in their standard states and the pure reactants in their standard states (at the specified temperature). Because the standard state of a substance is its pure form at 1 bar, the standard Gibbs free energy of reaction is the difference in Gibbs free energy between the pure products and the pure reactants: it is a fixed quantity for a given reaction and does not vary as the reaction proceeds. We shall unfold the enormous importance of this quantity shortly. The points to remember are: • ⌬G° is fixed for a given reaction and temperature, • ⌬G depends on the composition of the reaction mixture and so it varies—and might even change sign—as the reaction proceeds. Equations 18 and 19 are not very useful in practice, because, as remarked earlier, we can know only changes in the Gibbs free energies of substances, not their absolute values. However, we can use the same technique that we used to find the standard reaction enthalpy in Section 7.18, where we assigned each compound a standard enthalpy of formation, ⌬Hf°. We can also tabulate Gibbs free energies of formation of substances ¢G° = anGm°(products) - anGm°(reactants) ¢G = anGm(products) - anGm(reactants) 318 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS As remarked previously, in some texts you will see 1 atm used in the definition of standard states. The modern definition is 1 bar. The change in standard pressure has little effect on the tabulated values. Standard states are defined in Section 7.15. and then use them to calculate ⌬G°. The standard Gibbs free energy of formation, ⌬Gf° (the “standard free energy of formation”), of a substance is the standard Gibbs free energy of reaction per mole for the formation of a compound from its elements in their most stable form. The most stable form of an element is the state with the lowest Gibbs free energy (Table 8.6). For example, the standard Gibbs free energy of formation of hydrogen iodide gas at 25°C is ⌬Gf°(HI, g) ϭ ϩ1.70 kJиmolϪ1 . It is the standard Gibbs free energy per mole of HI for the reaction H2(g) ϩ I2(s) : HI(g). It follows from the definition that the standard Gibbs free energies of formation of elements in their most stable forms are exactly zero; for example, ⌬Gf°(I2, s) ϭ 0 for the “null” reaction I2(s) : I2(s), for there is no change between reactants and products. Standard Gibbs free energies of formation can be determined in various ways. One straightforward way is to combine standard enthalpy and entropy data from tables such as Tables 7.5 and 8.3. A list of values for several common substances is given in Table 8.7, and a more extensive one appears in Appendix 2A. 1 2 1 2 8.13 GIBBS FREE ENERGY OF REACTION 319 TABLE 8.6 Examples of the Most Stable Forms of Elements Most stable form at 25°C Element and 1 bar H2, O2, Cl2, Xe gas Br2, Hg liquid C graphite Na, Fe, I2 solid EXAMPLE 8.14 Calculating a standard Gibbs free energy of formation from enthalpy and entropy data Calculate the standard Gibbs free energy of formation of HI(g) at 25°C from its standard molar entropy and standard enthalpy of formation. PLAN We write the chemical equation for the formation of HI(g) and calculate the standard Gibbs free energy of reaction from ⌬G° ϭ ⌬H° Ϫ T⌬S°. It is best to write the equation with a stoichiometric coefficient of 1 for the compound of interest, because then ⌬G° ϭ ⌬Gf°. The standard enthalpy of formation is found in Appendix 2A. The standard reaction entropy is found as shown in Example 8.9, by using the data from Table 8.3 or Appendix 2A. SOLVE The chemical equation is H2(g) ϩ I2(s) : HI(g).1 2 1 2 From data in Appendix 2A, ⌬H° ϭ (1 mol) ϫ ⌬Hf°(HI, g) ϭ ϩ26.48 kJ ϩ26.48 kJ 1 mol HI H2 mol I2 ⌬HЊ 1 2 mol 1 2 From Eq. 8 of this chapter, ⌬S° ϭ Sm°(HI, g) Ϫ { Sm°(H2, g) ϩ Sm°(I2, s)} ϭ{(1 mol) ϫ (206.6 JиKϪ1 иmolϪ1 )} Ϫ { mol ϫ (130.7) ϩ mol ϫ (116.1)} JиKϪ1 иmolϪ1 ϭ ϩ83.2 JиKϪ1 ϭ ϩ0.0832 kJиKϪ1 B1 2AB1 2A 1 2 1 2 ϩ83.2 J·K Ϫ1⌬SЊ 1 mol HI H2 mol I2 1 2 mol 1 2 TABLE 8.7 Standard Gibbs Free Energies of Formation at 25°C (kJ·mol؊1 )* Gases ⌬Gf° Liquids ⌬Gf° Solids ⌬Gf° ammonia, NH3 Ϫ16.45 carbon dioxide, Ϫ394.4 CO2 nitrogen dioxide, ϩ51.3 NO2 water, H2O Ϫ228.6 *Additional values are given in Appendix 2A. † Calcite. benzene, C6H6 ϩ124.3 ethanol, Ϫ174.8 C2H5OH water, H2O Ϫ237.1 Calcium Ϫ1128.8 carbonate, CaCO3 † silver chloride, Ϫ109.8 AgCl 320 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS Evaluate The standard Gibbs free energy of formation of HI(g) is therefore ϩ1.69 kJиmol–1 , in good agreement with the value of ϩ1.70 kJиmol–1 quoted in the text. Note that, because this value is positive, the formation of pure HI from the elements at 1 bar is not spontaneous. Self-Test 8.20A Calculate the standard Gibbs free energy of formation of NH3(g) at 25°C from the enthalpy of formation and the molar entropies of the species taking part in its formation. [Answer: Ϫ16.5 kJиmolϪ1 ] Self-Test 8.20B Calculate the standard Gibbs free energy of formation of C3H6(g), cyclopropane, at 25°C. The standard Gibbs free energy of formation at a given temperature is an indication of a compound’s stability relative to its elements under standard conditions. The data in Appendix 2A are for 298.15 K, the conventional temperature for reporting thermodynamic data. If ⌬Gf° Ͻ 0 at a certain temperature, the pure compound has a lower Gibbs free energy than that of its pure elements and the elements are poised to change spontaneously into the compound at that temperature (Fig. 8.27). We say that the compound is “more stable” under standard conditions than the elements. If ⌬Gf° Ͼ 0, the Gibbs free energy of the compound is higher than that of its elements and the compound is poised to change spontaneously into the pure elements. In this case, we say that the pure elements are “more stable” than the pure compound. For example, the standard Gibbs free energy of formation of benzene is ϩ124 kJиmolϪ1 at 25°C, and benzene is unstable with respect to its elements under standard conditions at 25°C. A thermodynamically stable compound is a compound with a negative standard Gibbs free energy of formation (water is an example). A thermodynamically unstable compound is a compound with a positive standard Gibbs free energy of formation (benzene is an example). Such a compound is poised to decompose spontaneously into its elements. However, that tendency may not be realized in practice, because the decomposition may be very slow. Benzene can, in fact, be kept indefinitely without decomposing at all. Substances that are thermodynamically unstable but survive for long periods are called nonlabile or even inert. For example, benzene is thermodynamically unstable but nonlabile. Substances that do decompose or react rapidly are called labile. Most radicals are labile. It is important to keep in mind the distinction between stability and lability: • Stable and unstable are terms that refer to the thermodynamic tendency of a substance to decompose into its elements. • Labile, nonlabile, and inert are terms that refer to the rate at which a thermodynamic tendency to react is realized. Self-Test 8.21A Is glucose stable relative to its elements at 25°C and under standard conditions? [Answer: Yes; for glucose, ⌬Gf° ϭ Ϫ910. kJиmolϪ1 , a negative value.] Self-Test 8.21B Is methylamine, CH3NH2, stable relative to its elements at 25°C and under standard conditions? From ⌬G° ϭ ⌬H° Ϫ T⌬S°, ⌬G° ϭ (1 mol) ϫ (ϩ26.48 kJиmolϪ1 ) Ϫ (298 K) ϫ (0.0832 kJиKϪ1 ) ϭ ϩ1.69 kJ ϩ1.69 kJ Ϫ24.79 kJ Ϫ26.48 kJ ⌬HЊ ⌬GЊ T⌬SЊ Elements C6H6 ϩ124 NO2 ϩ51 Ϫ16 NH3 Ϫ237 H2O Ϫ110 AgCl HI ϩ2 Gibbsfreeenergyofformation,⌬GfЊ(kJ·molϪ1 ) FIGURE 8.27 The standard Gibbs free energy of formation of a compound is defined as the standard reaction Gibbs free energy per mole of formula units of the compound when the compound is formed from its elements. It represents a “thermodynamic altitude” with respect to the elements at “sea level.” The numerical values are in kilojoules per mole. The rates of reactions are discussed in Chapter 14. Just as we can combine standard enthalpies of formation to obtain standard reaction enthalpies, we can also combine standard Gibbs free energies of formation to obtain standard Gibbs free energies of reaction: (20)* where, as usual, the n are the amounts of each substance in the chemical equation. ¢G° = an¢Gf°(products) - an¢Gf°(reactants) 8.14 THE GIBBS FREE ENERGY AND NONEXPANSION WORK 321 EXAMPLE 8.15 Calculating the standard Gibbs free energy of reaction Calculate the standard Gibbs free energy of the reaction 4 NH3(g) ϩ 5 O2(g) 4 NO(g) ϩ 6 H2O(g) and decide whether the reaction is spontaneous under standard conditions at 25°C. Anticipate The reaction is a combustion (in this case, of ammonia), and combustions are typically spontaneous (in the thermodynamic sense); therefore, we should expect a negative Gibbs free energy. PLAN Obtain the standard Gibbs free energies of formation from Appendix 2A, then use Eq. 20 to calculate the reaction Gibbs free energy. What should we assume? That all reactants and products are pure substances and that the pressure of each one is 1 bar. SOLVE ¡ From Appendix 2A and Eq. 20, ⌬G° ϭ {(4 mol) ϫ ⌬Gf°(NO, g) ϩ (6 mol) ϫ ⌬Gf°(H2O, g)} Ϫ {(4 mol) ϫ ⌬Gf°(NH3, g) ϩ (5 mol) ϫ ⌬Gf°(O2, g)} ϭ {4(86.55) ϩ 6(Ϫ228.57)} Ϫ {4(Ϫ16.45) ϩ 0} kJ ϭ Ϫ959.42 kJ ⌬GfЊ Elements ϩ86.55 NO Ϫ228.57 H2O O2 Ϫ16.45 NH3 0 Evaluate We can conclude that, as expected, the combustion of ammonia is spontaneous at 25°C under standard conditions. Self-Test 8.22A Calculate the standard Gibbs free energy of the reaction 2 CO(g) ϩ O2(g) : 2 CO2(g) from standard Gibbs free energies of formation at 25°C. [Answer: ⌬G° ϭ –514.38 kJ] Self-Test 8.22B Calculate the standard Gibbs free energy of the reaction 6 CO2(g) ϩ 6 H2O(l) : C6H12O6(s, glucose) ϩ 6 O2(g) from standard Gibbs free energies of formation at 25°C. The standard Gibbs free energy of formation of a substance is the standard Gibbs free energy of reaction per mole of compound when it is formed from its elements in their most stable forms. The sign of ⌬Gf° tells us whether a compound is stable or unstable with respect to its elements. Standard Gibbs free energies of formation are used to calculate standard Gibbs free energies of reaction by using Eq. 20. 8.14 The Gibbs Free Energy and Nonexpansion Work We are now ready to see why the Gibbs free energy is called the free energy: we shall see that the change in Gibbs free energy that accompanies a process allows us to predict the maximum nonexpansion work that the process can do at constant temperature and pressure. That is, the Gibbs free energy is a measure of the energy free to do nonexpansion work. As explained in Section 7.3, nonexpansion work, we, is any kind of work other than that due to expansion against an opposing pressure; so it includes electrical work and mechanical work (like stretching a spring or carrying a weight up a slope). The fact that nonexpansion work includes electrical work—the work of pushing electrons through an electrical circuit—is the basis of the chemical generation of electrical power: we pursue that connection in Chapter 13. Nonexpansion work also includes the work of muscular activity, the work of linking amino acids together to form protein molecules, and the work of sending nerve signals through neurons; so a knowledge of changes in Gibbs free energy is central to an understanding of bioenergetics, the deployment and utilization of energy in living cells. The challenge that we now face is to derive a quantitative relation between the Gibbs free energy and the maximum nonexpansion work that a system can do. 322 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS HOW DO WE DO THAT? To find the relation between the Gibbs free energy and the maximum nonexpansion work, we start with Eq. 15 for an infinitesimal change (denoted d) in G at constant temperature: dG ϭ dH Ϫ TdS at constant temperature We then use Eq. 9 of Chapter 7 (H ϭ U ϩ PV) to express the infinitesimal change in enthalpy at constant pressure in terms of the change in internal energy dH ϭ dU ϩ PdV at constant pressure Then we substitute this expression into the first: dG ϭ dU ϩ PdV Ϫ TdS at constant temperature and pressure Now we use Eq. 7 from Chapter 7 for an infinitesimal change in internal energy (dU ϭ dw ϩ dq) and obtain dG ϭ dw ϩ dq ϩ PdV Ϫ TdS at constant temperature and pressure We are interested in the maximum work that a process can do, which means that the process has to occur reversibly (recall Section 7.3). For a reversible change, dG ϭ dwrev ϩ dqrev ϩ PdV Ϫ TdS at constant temperature and pressure Now we use the infinitesimal version of Eq. 1 (dS ϭ dqrev/T) to replace dqrev by TdS and cancel the two TdS terms: dG ϭ dwrev ϩ TdS ϩ PdV Ϫ TdS ϭ dwrev ϩ PdV at constant temperature and pressure At this point, we recognize that the system may do both expansion work and nonexpansion work: dwrev ϭ dwrev, e ϩ dwrev, expansion Reversible expansion work (achieved by matching the external to the internal pressure) is given by the infinitesimal version of Eq. 3 of Chapter 7 (wexpansion ϭ ϪPex⌬V, which becomes dwexpansion ϭ ϪPexdV) and setting the external pressure equal to the pressure of the gas in the system at each stage of the expansion: dwrev, expansion ϭ ϪPdV It follows that dwrev ϭ dwrev, e Ϫ PdV When we substitute this expression into the last line of the expression for dG (dG ϭ dwrev ϩ PdV), the PdV terms cancel and we are left with dG ϭ dwrev, e at constant temperature and pressure Because dwrev, e is the maximum nonexpansion work that the system can do (because it is achieved reversibly), we obtain dG ϭ dwe, max at constant temperature and pressure When we consider a measurable change in the Gibbs free energy, the equation we have derived becomes ⌬G ϭ we, max at constant temperature and pressure (21)* The subscript e in we stands for “extra.” This important relation tells us that, if we know the change in Gibbs free energy of a process taking place at constant temperature and pressure, then we immediately know how much nonexpansion work it can do. Equation 21 is also important in practice because we are often interested in various types of work, not just heating (see Table 7.1). In particular, the equation lets us consider the energetics of biological processes quantitatively. For instance, for the oxidation of glucose, C6H12O6(s) ϩ 6 O2(g) 6 CO2(g) ϩ 6 H2O(l) the standard Gibbs free energy of reaction is Ϫ2879 kJ. Therefore, at 1 bar the maximum nonexpansion work obtainable from 1.000 mol C6H12O6(s), corresponding to 180.0 g of glucose, is 2879 kJ. Because about 17 kJ of work must be done to build 1 mol of peptide links (a link between amino acids) in a protein, the oxidation of 180 g of glucose can be used to build about (2879 kJ)/(17 kJ) ϭ 170 moles of such links. In other words, the oxidation of one glucose molecule is needed to build about 170 peptide links. In practice, biosynthesis occurs indirectly, there are energy losses, and only about 10 such links can be built. A typical protein has several hundred peptide links, and so several glucose molecules must be sacrificed to build one protein molecule. The change in Gibbs free energy for a process is equal to the maximum nonexpansion work that the system can do at constant temperature and pressure. 8.15 The Effect of Temperature The enthalpies of reactants and products are both affected by a temperature rise and the difference between their values changes only a little with temperature (recall Section 7.21). The same is true of the entropies. As a result, the values of ⌬H° and ⌬S° do not change much with temperature. However, ⌬G° does depend on temperature (remember the T in ⌬G° ϭ ⌬H° Ϫ T⌬S°) and might change sign as the temperature is changed. There are four cases to consider: 1 For an exothermic reaction (⌬H° Ͻ 0) with a negative reaction entropy (⌬S° Ͻ 0), ϪT⌬S° contributes a positive term to ⌬G°. For such a reaction, ⌬G° is negative (and the formation of products spontaneous) at low temperatures because ⌬H° dominates ϪT⌬S°, but it may become positive (and the reverse reaction, the decomposition of pure products, spontaneous) at higher temperatures when ϪT⌬S° dominates ⌬H° (Fig. 8.28a). In this case, the increase in entropy of the surroundings drives the reaction forward, but it is opposed by the decrease in entropy of the system. 2 For an endothermic reaction (⌬H° Ͼ 0) with a positive reaction entropy (⌬S° Ͼ 0), the reverse is true (Fig. 8.28b). In this case, ⌬G° is positive at low temperatures but may become negative when the temperature is raised to the point that T⌬S° ¡ 8.15 THE EFFECT OF TEMPERATURE 323 FIGURE 8.28 The effect of an increase in temperature on the spontaneity of a reaction under standard conditions. In each case, “spontaneous” is taken to mean ⌬G° Ͻ 0 and “nonspontaneous” is taken to mean ⌬G° Ͼ 0. (a) An exothermic reaction with negative reaction entropy becomes spontaneous below the temperature marked by the vertical dotted line. (b) An endothermic reaction with a positive reaction entropy becomes spontaneous above the temperature marked by the vertical dotted line. (c) An endothermic reaction with negative reaction entropy is not spontaneous at any temperature. (d) An exothermic reaction with positive reaction entropy is spontaneous at all temperatures. 0 0 0 Property 0 ΔG° ΔG° ΔG° ΔG° ΔH° ΔH° ΔH° ΔH° TΔS° TΔS° TΔS° TΔS° (a) ΔH° < 0 ΔS° < 0 Temperature, T (b) ΔH° > 0 ΔS° > 0 Temperature, T (c) ΔH° > 0 ΔS° < 0 Temperature, T (d) ΔH° < 0 ΔS° > 0 Temperature, T becomes larger than ⌬H°. The formation of products from pure reactants becomes spontaneous when the temperature is high enough. Here, the increase in entropy of the system is opposed by the decrease in entropy of the surroundings, the effect of which is reduced by raising the temperature. 3 For an endothermic reaction (⌬H° Ͼ 0) with a negative reaction entropy (⌬S° Ͻ 0), ⌬G° Ͼ 0 at all temperatures and the reaction is not spontaneous at any temperature (Fig. 8.28c). In this case, the entropies of the system and the surroundings both decrease whatever the temperature. 4 For an exothermic reaction (⌬H° Ͻ 0) with a positive reaction entropy (⌬S° Ͼ 0), ⌬G° Ͻ 0 and the formation of products from pure reactants is spontaneous at all temperatures (Fig. 8.28d). In this case, the entropies of the system and the surroundings both increase whatever the temperature. 324 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS From Eq. 20 of Chapter 7, ⌬H° ϭ (3 mol) ϫ ⌬Hf°(CO2, g) Ϫ (2 mol) ϫ ⌬Hf°(Fe2O3, s) ϭ 3(Ϫ393.5) Ϫ 2(Ϫ824.2) kJ ϭ ϩ467.9 kJ ⌬HfЊ CO2 Fe2O3 Elements 00 Ϫ393.5 Ϫ824.2 CFe EXAMPLE 8.16 Calculating the temperature at which an endothermic reaction becomes spontaneous Estimate the temperature at which it is thermodynamically possible for carbon to reduce iron(III) oxide to iron under standard conditions by the endothermic reaction 2 Fe2O3(s) ϩ 3 C(s) 4 Fe(s) ϩ 3 CO2(g) Anticipate Because a gas is produced, ⌬S° Ͼ 0; because ⌬H° Ͼ 0 also, we should expect the reaction to become spontaneous at a high temperature. PLAN At low temperatures ⌬G° ϭ ⌬H° Ϫ T⌬S° ⌬H° and is positive (we are told the reaction is endothermic). If the temperature is increased there will come a point, when T ϭ ⌬H°͞⌬S°, above which ⌬G° is negative. That, therefore, is the temperature we seek. We use data from Appendix 2A. What should we assume? That ⌬H° and ⌬S° are approximately constant over the temperature range considered. SOLVE L ¡ From Eq. 8 of this chapter, ⌬S° ϭ {(4 mol) ϫ Sm°(Fe, s) ϩ (3 mol) ϫ Sm°(CO2, g)} Ϫ {(2 mol) ϫ Sm°(Fe2O3, s) ϩ (3 mol) ϫ Sm°(C, s)} ϭ {4(27.3) ϩ 3(213.7)} Ϫ {2(87.4) ϩ 3(5.7)} JиKϪ1 ϭ ϩ558.4 JиKϪ1 SmЊ Fe2O3 CO2FeC 27.3 87.4 5.7 213.7 From T ϭ ⌬H°͞⌬S°, 467.9 kJ T = 4.679 * 105 J 558.4 JиK-1 = 838 K Temperature, T T⌬SЊ ⌬HЊ 838K $+%+& Evaluate As expected, because the reaction is endothermic, the minimum temperature at which reduction occurs at 1 bar is high, about 565°C. Self-Test 8.23A What is the minimum temperature at which magnetite, Fe3O4, can be reduced to iron by using carbon (to produce CO2)? [Answer: 943 K] Self-Test 8.23B Estimate the temperature at which magnesium carbonate can be expected to decompose to magnesium oxide and carbon dioxide. The Gibbs free energy increases with temperature for reactions with a negative ⌬S° and decreases with temperature for reactions with a positive ⌬S°. 8.16 Impact on Biology: Gibbs Free Energy Changes in Biological Systems Many biological reactions, such as the construction of a protein from amino acids or the construction of a DNA molecule, are not spontaneous and therefore must be driven by an external source of energy. That energy comes from sunlight and the chemicals in food that have stored solar energy (Fig 8.29). When food is metabolized, the resulting exothermic reaction generates a lot of entropy, and if the reaction is coupled to a biochemical reaction that is nonspontaneous, the overall change in entropy may be positive, and the overall process spontaneous. In other words, a reaction that produces a lot of entropy can drive a nonspontaneous reaction forward. In terms of Gibbs free energy, one biochemical process may be driven uphill in Gibbs free energy by another reaction that rolls downhill. Staying alive is very much like the effect of a heavy weight tied to another weight by a string that passes over a pulley (Fig. 8.30). The lighter weight could never fly up into the air on its own. However, when it is connected to a heavier weight falling downward on the other side of a pulley, the light weight can soar upward. The hydrolysis of adenosine triphosphate, ATP (2), to adenosine diphosphate, ADP (3), is the reaction used most frequently by biological organisms to couple with and drive nonspontaneous reactions. This hydrolysis is the key metabolic reaction by which Gibbs free energy is stored and used in living systems. The value of ⌬G° for the hydrolysis of 1 mol ATP is about Ϫ30 kJ. To restore ADP back to ATP, which is accompanied by a Gibbs free energy change of ϩ30 kJ, an ADP molecule and a phosphate group must be linked by coupling them to another reaction for which the Gibbs free energy of reaction is more negative than Ϫ30 kJ. That is one reason why 8.16 IMPACT ON BIOLOGY: GIBBS FREE ENERGY CHANGES IN BIOLOGICAL SYSTEMS 325 FIGURE 8.29 The process of life is fueled by energy from sunlight, either directly or from energy stored in food. FIGURE 8.30 A natural process can be represented as a falling weight (left). A weight rising spontaneously would be regarded as highly unusual until we recognize that it is actually part of a natural process overall (right). The natural fall of the heavier weight causes the apparently “unnatural” rise of the smaller weight. Apparently spontaneous Spontaneous Adenosine triphosphate, ATP2 Adenosine diphosphate, ADP3 Exercises labeled require calculus Entropy 8.1 A human body generates heat at the rate of about 100. W (1 W ϭ 1 JиsϪ1 ). (a) At what rate does your body heat generate entropy in your surroundings, taken to be at 20.°C? (b) How much entropy do you generate each day? (c) Would the entropy generated be greater or less if you were in a room kept at 30.°C? Explain your answer. 8.2 An electric heater is rated at 2.3 kW (1 W ϭ 1 JиsϪ1 ). (a) At what rate does it generate entropy in a room maintained at 24°C? (b) How much entropy does it generate in the course of a day? (c) Would the entropy generated be greater or less if the room were maintained at 21°C? Explain your answer. 8.3 (a) Calculate the change in entropy of a block of copper at 25°C that absorbs 65 J of energy from a heater. (b) If the block of copper is at 100.°C and it absorbs 65 J of energy from the heater, what is its entropy change? (c) Explain any difference in entropy change. 8.4 (a) Calculate the change in entropy of 1.0 L of water at 0.°C when it absorbs 470 J of energy from a heater. (b) If the 1.0 L of water is at 99°C, what is its entropy change? (c) Explain any difference in entropy change. 8.5 Assuming that the heat capacity of an ideal gas is independent of temperature, calculate the entropy change associated with raising the temperature of 1.00 mol of ideal gas atoms reversibly from 37.6°C to 157.9°C at (a) constant pressure and (b) constant volume. 8.6 Assuming that the heat capacity of an ideal gas is independent of temperature, calculate the entropy change associated with lowering the temperature of 2.92 mol of ideal gas atoms from 107.35°C to Ϫ52.39°C at (a) constant pressure and (b) constant volume. EXERCISES we have to eat. When we eat food containing glucose, we consume a fuel. Like all fuels, it has a spontaneous tendency to form combustion products. If we were simply to burn glucose in an open container, it would do no work other than pushing back the atmosphere, and it would give off a lot of heat. However, in our bodies, the “combustion” is a highly controlled and sophisticated version of burning. In such a controlled reaction, the nonexpansion work that the process can do approaches 2500 kJ per mole of glucose molecules, which is enough to “recharge” about 80 mol ADP molecules. When living organisms die, they no longer ingest the second-hand sunlight stored in molecules of carbohydrate, protein, and fat. Then the natural direction of change becomes dominant, and the intricate molecules that support life start to decompose. Living organisms are engaged in a constant battle to generate enough entropy in their surroundings to go on building and maintaining their intricate interiors. As soon as they stop the battle, they stop generating that external entropy, and their bodies decay. Reactions that are nonspontaneous can be made to take place by coupling them with spontaneous reactions. This coupling is used extensively in biological systems. 326 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS ❑ 1 Calculate the entropy change for reversible heat transfer (Example 8.1). ❑ 2 Calculate the entropy change when the temperature of a substance is changed (Example 8.2). ❑ 3 Determine the entropy change for the isothermal expansion or compression of an ideal gas (Examples 8.3, 8.4, and 8.5). ❑ 4 Calculate the standard entropy of a phase change (Example 8.6). ❑ 5 Use the Boltzmann formula to calculate and interpret the entropy of a substance (Examples 8.7 and 8.8). ❑ 6 Predict which of two systems has the greater entropy, given their compositions and conditions (Self-Test 8.11). ❑ 7 Calculate the standard reaction entropy from standard molar entropies (Example 8.9). ❑ 8 Estimate the change in entropy of the surroundings due to heat transfer at constant pressure and temperature (Example 8.10). ❑ 9 Calculate the total change in entropy for a process (Examples 8.11 and 8.12). ❑ 10 Use the change in Gibbs free energy to determine the spontaneity of a process at a given temperature (Example 8.13). ❑ 11 Calculate a standard Gibbs free energy of formation from enthalpy and entropy data (Example 8.14). ❑ 12 Calculate the standard Gibbs free energy of reaction from standard Gibbs free energies of formation (Example 8.15). ❑ 13 Estimate the maximum nonexpansion work that can be done by a process (Section 8.14). ❑ 14 Predict the minimum temperature at which an endothermic reaction can occur spontaneously (Example 8.16). SKILLS YOU SHOULD HAVE MASTERED C EXERCISES 327 8.7 Calculate the entropy change associated with the isothermal expansion of 5.25 mol of ideal gas atoms from 24.252 L to 34.058 L. 8.8 Calculate the entropy change associated with the isothermal compression of 4.80 mol of ideal gas atoms from 12.86 L to 4.80 L. 8.9 Calculate the change in entropy when the pressure of 1.50 mol Ne(g) is decreased isothermally from 15.0 atm to 0.500 atm. Assume ideal behavior and 1 mole of N2(g). 8.10 Calculate the change in entropy when the pressure of 70.9 g of methane gas is increased isothermally from 7.00 kPa to 350.0 kPa. Assume ideal behavior. 8.11 During the test of an internal combustion engine, 3.00 L of nitrogen gas at 18.5°C was compressed suddenly (and irreversibly) to 0.500 L by driving in a piston. In the process the temperature of the gas increased to 28.1°C. Assume ideal behavior. What is the change in entropy of the gas? 8.12 Calculate the change in entropy when the pressure of 3.44 g of helium gas is decreased from 125.0 kPa to 65.0 kPa while the temperature decreases from 335 K to 273 K. Assume ideal behavior. 8.13 Show that, if two copper blocks with different temperatures are placed in contact, then the direction of spontaneous change is toward the equalization of temperatures. Do so by considering the transfer of 1 J of energy as heat from one to the other and assessing the sign of the entropy change. Assume that the temperatures of the blocks remain constant. 8.14 Suppose that 100. J of energy is taken from a hot source at 300.°C, passes through a turbine that converts some of the energy into work, and then releases the rest of the energy as heat into a cold sink at 20.°C. What is the maximum amount of work that can be produced by this engine if overall it is to operate spontaneously? What is the efficiency of the engine, with work done divided by heat supplied expressed as a percentage? How could the efficiency be increased? 8.15 A heat pump heats a house in winter by extracting heat from the cold outdoors and releasing it into the warm interior. For the transfer of a given amount of heat, (a) how do the entropies of the interior and exterior of the house change (increase or decrease)? (b) Which change is greater? Assume that the temperatures inside and outside the house do not change. Explain your answers. 8.16 Suppose that you were able to design an engine without a cold sink, so that the energy from a hot object could be transferred to the surroundings entirely as work, with no heat exchanged. (a) What would be the entropy change of the surroundings? (b) Could such an engine operate spontaneously? Explain your answer. 8.17 Use data in Table 7.3 or Appendix 2A to calculate the entropy change for (a) the freezing of 1.00 mol H2O(l) at 0.00°C; (b) the vaporization of 50.0 g of ethanol, C2H5OH, at 351.5 K. 8.18 Use data in Table 7.3 or Table 8.2 to calculate the entropy change for (a) the vaporization of 2.40 mol H2O(l) at 100.°C and 1 atm; (b) the freezing of 4.50 g of ethanol, C2H5OH, at 158.7 K. 8.19 (a) Using data provided in Appendix 2A, estimate the boiling point of ethanal, CH3CHO(l). (b) From standard reference sources, find the actual boiling point of ethanal. (c) How do these values compare? (d) What gives rise to the differences? 8.20 Using data provided in Appendix 2A, estimate the boiling point of Br2(l). (b) From standard reference sources, find the actual boiling point of bromine. (c) How do these values compare? 8.21 (a) Using Trouton’s rule, estimate the boiling point of dimethyl ether, CH3OCH3, given that ⌬Hvap° ϭ 21.51 kJиmolϪ1 . (b) Using standard reference sources available in your library, find the actual boiling point of dimethyl ether and compare this value with the value obtained by using Trouton’s rule. Explain any difference. 8.22 (a) Using Trouton’s rule, estimate the boiling point of methylamine, CH3NH2, given that ⌬Hvap° ϭ 25.60 kJиmolϪ1 . (b) Using standard reference sources available in your library, find the actual boiling point of methylamine and compare this value with the value obtained by using Trouton’s rule. Explain any difference. 8.23 The standard entropy of vaporization of benzene is approximately 85 JиKϪ1 иmolϪ1 at its boiling point. (a) Estimate the standard enthalpy of vaporization of benzene at its normal boiling point of 80.°C. (b) What is the standard entropy change of the surroundings when 10. g of benzene, C6H6, vaporizes at its normal boiling point? 8.24 The standard entropy of vaporization of acetone is approximately 85 JиKϪ1 ·molϪ1 at its boiling point. (a) Estimate the standard enthalpy of vaporization of acetone at its normal boiling point of 56.2°C. (b) What is the entropy change of the surroundings when 10. g of acetone, CH3COCH3, condenses at its normal boiling point? 8.25 Which would you expect to have a higher molar entropy at T ϭ 0, single crystals of BF3 or of COF2? Why? 8.26 On the basis of the structures of each of the following molecules, predict which ones would be most likely to have a residual entropy in their crystal forms at T ϭ 0: (a) CO2; (b) NO; (c) N2O; (d) Cl2. 8.27 If SO2F2 adopts a disordered arrangement in its crystal form, what would its residual molar entropy be? 8.28 What would you expect the residual molar entropy of PH2F to be if it were to adopt a disordered arrangement in its crystal form? 8.29 Which substance in each of the following pairs has the higher molar entropy at 298 K: (a) HBr(g) or HF(g); (b) NH3(g) or Ne(g); (c) I2(s) or I2(l); (d) 1.0 mol Ar(g) at 1.00 atm or 1.0 mol Ar(g) at 2.00 atm? 8.30 Which substance in each of the following pairs has the higher molar entropy? (Assume the temperature to be 298 K unless otherwise specified.) (a) CH4(g) or C2H6(g); (b) KCl(aq) or KCl(s); (c) Ne(g) or Kr(g); (d) O2(g) at 273 K and 1.00 atm or O2(g) at 450. K and 1.00 atm. 8.31 List the following substances in order of increasing molar entropy at 298 K: H2O(l), H2O(g), H2O(s), C(s, diamond). Explain your reasoning. 8.32 List the following substances in order of increasing molar entropy at 298 K: CO2(g), Ar(g), H2O(l), Ne(g). Explain your reasoning. 8.33 Which substance in each of the following pairs would you expect to have the higher standard molar entropy at 298 K? Explain your reasoning. (a) Iodine vapor or bromine vapor; (b) the two liquids cyclopentane and 1-pentene (see structures); (c) ethene (ethylene) or an equivalent mass of polyethylene, a substance formed by the polymerization of ethylene. 8.34 Predict which of the hydrocarbons below has the greater standard molar entropy at 25°C. Explain your reasoning. 8.35 Without performing any calculations, predict whether there is an increase or a decrease in entropy for each of the following processes: (a) Cl2(g) ϩ H2O(l) : HCl(aq) ϩ HClO(aq); (b) Cu3(PO4)2(s) : 3 Cu2ϩ (aq) ϩ 2 PO4 3Ϫ (aq); (c) SO2(g) ϩ Br2(g) ϩ 2 H2O(l) : H2SO4(aq) ϩ 2 HBr(aq). 8.36 Without performing any calculations, state whether the entropy of the system increases or decreases in each of the following processes: (a) the dissolution of table salt: NaCl(s) : NaCl(aq); (b) the photosynthesis of glucose: 6 CO2(g) ϩ 6 H2O(l) : C6H12O6(s) ϩ 6 O2(g); (c) the evaporation of water from damp clothes. Explain your reasoning. 8.37 Container A is filled with 1.0 mol of the atoms of an ideal monatomic gas. Container B has 1.0 mol of atoms bound together as diatomic molecules that are not vibrationally active. Container C has 1.0 mol of atoms bound together as diatomic molecules that are vibrationally active. The containers all start at Ti and the temperature is increased to Tf. Rank the containers in order of increasing change in entropy. Explain your reasoning. 8.38 A closed vessel of volume 2.5 L contains a mixture of neon and fluorine. The total pressure is 3.32 atm at 0.0°C. When the mixture is heated to 15°C, the entropy of the mixture increases by 0.345 JиKϪ1 . What amount (in moles) of each substance (Ne and F2) is present in the mixture? 8.39 Use data in Table 8.3 or Appendix 2A to calculate the standard reaction entropy for each of the following reactions at 25°C. For each reaction, interpret the sign and magnitude of the reaction entropy. (a) The formation of 1.00 mol H2O(l) from the elements in their most stable state at 298 K. (b) The oxidation of 1.00 mol CO(g) to carbon dioxide. (c) The decomposition of 1.00 mol calcite, CaCO3(s), to carbon dioxide gas and solid calcium oxide. (d) The decomposition of potassium chlorate: 4 KClO3(s) : 3 KClO4(s) ϩ KCl(s). 8.40 Use data in Table 8.3 or Appendix 2A to calculate the standard entropy change for each of the following reactions at 25°C. For each reaction, interpret the sign and magnitude of the reaction entropy. (a) The synthesis of carbon disulfide from natural gas (methane): CH4(g) ϩ 4 S(s, rhombic) :CS2(l) ϩ 2 H2S(g). (b) The production of acetylene from calcium carbide and water: CaC2(s) ϩ 2 H2O(l) : C2H2(g) ϩ Ca(OH)2(s). (c) The oxidation of ammonia, which is the first step in the commercial production of nitric acid: 4 NH3(g) ϩ 5 O2(g) : 4 NO(g) ϩ 6 H2O(l). (d) The industrial synthesis of urea, a common fertilizer: CO2(g) ϩ 2 NH3(g) : CO(NH2)2(s) ϩ H2O(l). 8.41 The temperature dependence of the heat capacity of a substance is commonly written in the form CP,m ϭ a ϩ bT ϩ c/T2 , with a, b, and c constants. Obtain an expression for the entropy change when the substance is heated from T1 to T2. Evaluate this change for graphite, for which a ϭ 16.86 JиKϪ1 иmolϪ1 , b ϭ 4.77 mJиKϪ2 иmolϪ1 , and c ϭ Ϫ8.54 ϫ 105 JиKиmolϪ1 , heated from 298 K to 400. K. What is the percentage error in assuming that the heat capacity is constant with its mean value in this range? 8.42 At low temperatures, heat capacities are proportional to T3 . Show that, near T ϭ 0, the entropy of a substance is equal to onethird of its heat capacity at the same temperature. 8.43 Calculate the standard entropy of vaporization of water at 85°C, given that its standard entropy of vaporization at 100.°C is 109.0 JиKϪ1 иmolϪ1 and the molar heat capacities at constant pressure of liquid water and water vapor are 75.3 JиKϪ1 иmolϪ1 and 33.6 JиKϪ1 иmolϪ1 , respectively, in this range. 8.44 Three liquid samples with known masses are heated to their boiling points with the use of a 500.-W heater. Once their boiling points are reached, heating continues for 4.0 min and some of each sample is vaporized. After 4.0 min, the samples are cooled and the masses of the remaining liquids are determined. The process is performed at constant pressure. Using the following data, (a) calculate ⌬Svap and ⌬Hvap for each sample. Assume that all the heat from the heater goes into the sample. (b) What do the values of ⌬Svap indicate about the relative degree of order in the liquids? Boiling Initial Final Liquid temperature (°C) mass (g) mass (g) C2H5OH 78.3 400.15 271.15 C4H10 0.0 398.05 74.95 CH3OH 64.5 395.15 294.25 Global Changes in Entropy 8.45 Suppose that 50.0 g of H2O(l) at 20.0°C is mixed with 65.0 g of H2O(l) at 50.0°C at constant atmospheric pressure in a thermally insulated vessel. Calculate ⌬S and ⌬Stot for the process. 8.46 Suppose that 150.0 g of ethanol at 22.0°C is mixed with 200.0 g of ethanol at 56.0°C at constant atmospheric pressure in a thermally insulated vessel. Calculate ⌬S and ⌬Stot for the process. 8.47 Use the information in Table 7.3 to calculate the changes in entropy of the surroundings and of the system for (a) the vaporization of 1.00 mol CH4(l) at its normal boiling point; (b) the melting of 1.00 mol C2H5OH(s) at its normal melting point; (c) the freezing of 1.00 mol C2H5OH(l) at its normal freezing point. 8.48 Use the information in Table 7.3 to calculate the changes in entropy of the surroundings and of the system for (a) the melting of 1.00 mol NH3(s) at its normal melting point; (b) the freezing of 1.00 mol CH3OH(l) at its normal freezing point; (c) the vaporization of 1.00 mol H2O(l) at its normal boiling point. 8.49 Initially a sample of ideal gas at 323 K occupies 1.67 L at 4.95 atm. The gas is allowed to expand to 7.33 L by two pathways: (a) isothermal, reversible expansion; (b) isothermal, (b) Cyclohexane, C6H12(a) Cyclobutane, C4H8 1-Pentene, C5H10Cyclopentane, C5H10 328 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS C C EXERCISES 329 irreversible free expansion. Calculate ⌬Stot, ⌬S, and ⌬Ssurr for each pathway. 8.50 Initially a sample of ideal gas at 412 K occupies 12.62 L at 0.6789 atm. The gas is allowed to expand to 19.44 L by two pathways: (a) isothermal, reversible expansion and (b) isothermal, irreversible free expansion. Calculate ⌬Stot, ⌬S, and ⌬Ssurr for each pathway. 8.51 The following pictures show a molecular visualization of a system undergoing a spontaneous change. Account for the spontaneity of the process in terms of the entropy changes in the system and the surroundings. The thermometers show the temperature of the system. 8.52 The following pictures show a molecular visualization of a system undergoing a spontaneous change. Determine from the picture whether entropy increases or decreases during the process. Account for the spontaneity of the process in terms of the entropy changes in the system and the surroundings. The thermometers show the temperature of the system. Gibbs Free Energy 8.53 Why are so many exothermic reactions spontaneous? 8.54 Explain how an endothermic reaction can be spontaneous. 8.55 Calculate the standard enthalpy, entropy, and Gibbs free energy at 298 K for each of the following reactions by using data in Appendix 2A. For each case, confirm that the value obtained from the Gibbs free energies of formation is the same as that obtained by using the relation ⌬G° ϭ ⌬H° Ϫ T⌬S°. (a) the oxidation of magnetite to hematite: 2 Fe3O4(s) ϩ O2(g) : 3 Fe2O3(s) (b) the dissolution of CaF2 in water: CaF2(s) : CaF2(aq) (c) the dimerization of NO2: 2 NO2(g) : N2O4(g) 8.56 Calculate the standard enthalpy, entropy, and Gibbs free energy for each of the following reactions at 298 K by using data in Appendix 2A. For each case, confirm that the value obtained from the Gibbs free energies of formation is the same as that obtained by using the relation ⌬G° ϭ ⌬H° Ϫ T⌬S°. (a) the hydration of copper sulfate: CuSO4(s) ϩ 5 H2O(l) : CuSO4и5H2O(s) (b) the reaction of H2SO4(l), an effective dehydrating agent, with water to form aqueous sulfuric acid: H2SO4(l) : H2SO4(aq) (c) the reaction of calcium oxide with water to form calcium hydroxide: CaO(s) ϩ H2O(l) : Ca(OH)2(s) (d) Which of the reagents in parts (a)–(c) would you expect to be the most effective at removing water from a substance? 8.57 Write a balanced chemical equation for the formation reaction of (a) NH3(g); (b) H2O(g); (c) CO(g); (d) NO2(g). For each reaction, determine ⌬H°, ⌬S°, and ⌬G° from data in Appendix 2A. 8.58 Write a balanced chemical equation for the formation reaction of (a) HCl(g); (b) C6H6(l); (c) CuSO4и5H2O(s); (d) CaCO3(s, calcite). For each reaction, determine ⌬H°, ⌬S°, and ⌬G° from data in Appendix 2A. 8.59 Use the standard Gibbs free energies of formation in Appendix 2A to calculate ⌬G° for each of the following reactions at 25°C. Comment on the spontaneity of each reaction under standard conditions at 25°C. (a) 2 SO2(g) ϩ O2(g) : 2 SO3(g) (b) CaCO3(s, calcite) : CaO(s) ϩ CO2(g) (c) 2 C8H18(l) ϩ 25 O2(g) : 16 CO2(g) ϩ 18 H2O(l) 8.60 Use the standard Gibbs free energies of formation in Appendix 2A to calculate ⌬G° for each of the following reactions at 25°C. Comment on the spontaneity of each reaction under standard conditions at 25°C. (a) NH4Cl(s) : NH3(g) ϩ HCl(g) (b) H2(g) ϩ D2O(l) : D2(g) ϩ H2O(l) (c) N2(g) ϩ NO2(g) : NO(g) ϩ N2O(g) (d) 2 CH3OH(g) ϩ 3 O2(g) : 2 CO2(g) ϩ 4 H2O(l) 8.61 Determine which of the following compounds are stable with respect to decomposition into their elements under standard conditions at 25°C (see Appendix 2A): (a) PCl5(g); (b) HCN(g); (c) NO(g); (d) SO2(g). 8.62 Determine which of the following compounds are stable with respect to decomposition into their elements under standard conditions at 25°C (see Appendix 2A): (a) C3H6(g), cyclopropane; (b) CaO(s); (c) N2O(g); (d) HN3(g). 8.63 Which of the following compounds become less stable with respect to the elements as the temperature is raised: (a) PCl5(g); (b) HCN(g); (c) NO(g); (d) SO2(g)? 8.64 Which of the following compounds become less stable with respect to their elements as the temperature is raised: (a) C3H6(g), cyclopropane; (b) CaO(s); (c`) N2O(g); (d) HN3(g)? 8.65 Calculate the standard reaction entropy, enthalpy, and Gibbs free energy for each of the following reactions from data found in Appendix 2A: (a) the decomposition of hydrogen peroxide: 2 H2O2(l) : 2 H2O(l) ϩ O2(g) (b) the preparation of hydrofluoric acid from fluorine and water: 2 F2(g) ϩ 2 H2O(l) : 4 HF(aq) ϩ O2(g) 8.66 Calculate the standard reaction entropy, enthalpy, and Gibbs free energy for each of the following reactions from data in Appendix 2A: (a) the production of “synthesis gas,” a low-grade industrial fuel: CH4(g) ϩ H2O(g) : CO(g) ϩ 3 H2(g) (b) the thermal decomposition of ammonium nitrate: NH4NO3(s) : N2O(g) ϩ 2 H2O(g) 8.67 Assume that ⌬H° and ⌬S° are independent of temperature and use data in Appendix 2A to calculate ⌬G° for each of the 1 2 Solid Gas Gas LiquidVapor 330 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS following reactions at 80.°C. Over what temperature range will each reaction be spontaneous under standard conditions? (a) B2O3(s) ϩ 6 HF(g) : 2 BF3(g) ϩ 3 H2O(l) (b) CaC2(s) ϩ 2 HCl (aq) : CaCl2 (aq) ϩ C2H2(g) (c) C(s, graphite) : C(s, diamond) 8.68 Assume that ⌬H° and ⌬S° are independent of temperature and use data in Appendix 2A to calculate ⌬G° for each of the following reactions at 250.°C. Over what temperature range will each reaction be spontaneous under standard conditions? (a) HCN(g) ϩ 2 H2(g) : CH3NH2(g) (b) 2 Cuϩ (aq) : Cu(s) ϩ Cu2ϩ (aq) (c) CaCl2(s) ϩ 2 HF(g) : CaF2(s) ϩ 2 HCl(g) 8.69 A scientist proposed the following two reactions to produce ethanol, a liquid fuel: C2H4(g) ϩ H2O(g) CH3CH2OH(l) (A) C2H6(g) ϩ H2O(g) CH3CH2OH(l) ϩ H2(g) (B) Reaction B is preferred if spontaneous, because C2H6(g) is a cheaper starting material than C2H4(g). Assume standard-state conditions and determine if either reaction is thermodynamically spontaneous. 8.70 A rocket fuel would be useless if its oxidation were not spontaneous. Although rockets operate under conditions that are far from standard, an initial estimation of the potential of a rocket fuel might assess whether its oxidation at the high temperatures reached in a rocket is spontaneous. A chemist exploring potential fuels for use in space considered using vaporized aluminum chloride in a reaction for which the skeletal equation is AlCl3(g) ϩ O2(g) Al2O3(s) ϩ ClO(g) Balance this equation. Then use the following data (which are for 2000 K) to decide whether the fuel is worth further investigation: ⌬Gf°(AlCl3, g) ϭ Ϫ467 kJиmolϪ1 , ⌬Gf°(Al2O3, s) ϭ Ϫ1034 kJиmolϪ1 , ⌬Gf°(ClO, g) ϭ ϩ75 kJиmolϪ1 . Impact on Biology 8.71 Coupled reactions are used in organisms to drive important biochemical processes. Individual chemical reactions may be added together to form a net reaction, and the overall reaction Gibbs free energy is the sum of the individual Gibbs free energies of reaction. For example, ATP is the primary molecule that stores and releases energy to drive vital nonspontaneous chemical reactions in our bodies. However, the generation of ATP from ADP is nonspontaneous and must itself be coupled to a spontaneous reaction. This process is called oxidative phosphorylation and the reactions are: (1) ADP3Ϫ (aq) ϩ HPO4 2Ϫ (aq) ϩ Hϩ (aq) ATP4Ϫ (aq) ϩ H2O(l) ⌬G ϭ ϩ30.5 kJ (2) NADH(aq) NADϩ (aq) ϩ Hϩ (aq) ϩ 2 eϪ ⌬G ϭ Ϫ158.3 kJ (3) O2(g) ϩ 2 Hϩ (aq) ϩ 2 eϪ H2O(l) ⌬G ϭ Ϫ61.9 kJ (The reaction Gibbs free energies are for pH ϭ 7 but otherwise standard conditions.) What amount (in moles) of ATP could be formed if all the Gibbs free energy released in the oxidation of 3.00 mol NADH were used to generate ATP? 8.72 For the hydrolysis of acetyl phosphate under the conditions prevailing in the body, ⌬G ϭ Ϫ41 kJиmolϪ1 . If the phosphorylation of acetic acid (the reverse of the hydrolysis of acetyl phosphate) was driven by coupling to the hydrolysis of ATP at pH ϭ 7, what is the minimum amount of ATP molecules (in moles) that would have to be hydrolyzed to form 1.0 mol acetyl phosphate molecules by the phosphorylation of acetic acid? (See Exercise 8.71 for more details.) Integrated Exercises 8.73 (a) Which substance would you expect to have the highest molar entropy in the liquid phase, benzene, methanol (CH3OH), or 1-propanol (CH3CH2CH2OH)? (b) Would your answer be different if these substances were in the gas phase? 8.74 (a) Before checking the numbers, which substance would you expect to have the higher standard molar entropy, CH3COOH(l) or CH3COOH(aq)? Having made this prediction, examine the values in Appendix 2A and explain your findings. 8.75 Under what conditions, if any, does the sign of each of the following quantities provide a criterion for assessing the spontaneity of a reaction? (a) ⌬G°; (b) ⌬H°; (c) ⌬S°; (d) ⌬Stot. 8.76 The normal boiling point of methanol is lower than predicted by Trouton’s rule. Provide a molecular interpretation for this observation. 8.77 Assuming statistical disorder, would you expect a crystal of octahedral cis-MX2Y4 to have the same, higher, or lower residual entropy than the corresponding trans isomer? Explain your conclusion. 8.78 There are three different substituted benzene compounds with the formula C6H4F2. (a) Draw the structures of the three compounds. (b) Assume that the benzene rings pack similarly into their crystal lattices. If the positions of the H and F atoms are statistically disordered in the solid state, which isomer will have the least residual molar entropy? 8.79 Suppose that you create two tiny systems consisting of three atoms each, and each atom can accept energy in quanta of the same magnitude. (a) How many distinguishable arrangements are there of two quanta of energy distributed among the three atoms in one of these systems? (b) You now bring the two tiny systems together. How many distinguishable arrangements are there if the two quanta of energy are distributed among the six atoms? (c) In what direction will the energy quanta flow starting from the initial arrangement? 8.80 Suppose that you create two tiny systems consisting of four atoms each, and each atom can accept energy in quanta of the same magnitude. (a) How many distinguishable arrangements are there of two quanta of energy distributed among the four atoms in one of these systems? (b) You now bring the two tiny systems together. How many distinguishable arrangements are there if the two quanta of energy are distributed among the eight atoms? (c) Which state is more disordered, that in part (a) or that in part (b)? cis-MX2Y4 trans-MX2Y4 X Y M ¡1 2 ¡ ¡ ¡ ¡ ¡ 8.81 Consider the enthalpies of fusion and the melting points of the following elements: Pb, 5.10 kJиmolϪ1 , 327°C; Hg, 2.29 kJиmolϪ1 , Ϫ39°C; Na, 2.64 kJиmolϪ1 , 98°C. Given these data, determine whether a relation similar to Trouton’s rule can be obtained for the entropy of fusion of the metallic elements. 8.82 Determine whether titanium dioxide can be reduced by carbon at 1000. K in each of the following reactions: (a) TiO2(s) ϩ 2 C(s) : Ti(s) ϩ 2 CO(g) (b) TiO2(s) ϩ C(s) : Ti(s) ϩ CO2(g) given that, at 1000. K, ⌬Gf°(CO, g) ϭ Ϫ200. kJиmolϪ1 , ⌬Gf°(CO2, g) ϭ Ϫ396 kJиmolϪ1 ; and ⌬Gf°(TiO2, s) ϭ Ϫ762 kJиmolϪ1 . 8.83 Which is the thermodynamically more stable iron oxide in air, Fe3O4(s) or Fe2O3(s)? Justify your selection. 8.84 (a) Calculate the work that must be done at 298.15 K and 1.00 bar against the atmosphere for the production of CO2(g) and H2O(g) in the combustion of 8.50 mol C6H6(l). Using data in Appendix 2A, calculate the standard enthalpy of the reaction. (c) Calculate the change in internal energy, ⌬U°, of the system. 8.85 Hydrogen burns in an atmosphere of bromine gas to give hydrogen bromide gas. (a) What is the standard Gibbs free energy of the reaction H2(g) ϩ Br2(g) : 2 HBr(g) at 298 K? (b) If 120. mL of H2 gas at STP combines with a stoichiometric amount of bromine and the resulting hydrogen bromide dissolves to form 150. mL of an aqueous solution, what is the molar concentration of the resulting hydrobromic acid? 8.86 Hydrogen reacts with nitrogen gas to form ammonia. (a) What is the standard Gibbs free energy of the reaction 3 H2(g) ϩ N2(g) : 2 NH3(g) at 298 K? (b) If 50.1 L of H2 gas at 1 bar and 298 K is added to 15.6 L of N2, also at 1 bar and 298 K, and the resulting ammonia dissolves to form 2.00 L of an aqueous solution, (a) what amount of ammonia can be formed? (b) What is the molar concentration of the resulting aqueous ammonia solution? 8.87 Potassium nitrate dissolves readily in water, and its enthalpy of solution is ϩ34.9 kJиmolϪ1 . (a) Does the enthalpy of solution favor the dissolving process? (b) Is the entropy change of the system likely to be positive or negative when the salt dissolves? (c) Is the entropy change of the system primarily a result of changes in positional disorder or thermal disorder? (d) Is the entropy change of the surroundings primarily a result of changes in positional disorder or thermal disorder? (e) What is the driving force for the dissolution of KNO3? 8.88 Explain why each of the following statements is false. (a) Reactions with negative Gibbs free energies of reaction occur spontaneously and rapidly. (b) Every sample of a pure element, regardless of its physical state, is assigned zero Gibbs free energy of formation. (c) An exothermic reaction producing more moles of gas molecules than are consumed has a positive standard reaction Gibbs free energy. 8.89 A common antiseptic used in first aid for cuts and scrapes is a 3% aqueous solution of hydrogen peroxide. The oxygen that bubbles out of the hydrogen peroxide as it is decomposed by enzymes in blood into oxygen and water helps to clean the wound. Two possible industrial routes for the synthesis of hydrogen peroxide are: (i) H2(g) ϩ O2(g) ∫∫∫∫B H2O2(l), which uses either a metal such as palladium or the organic compound quinone as catalyst, and (ii) 2 H2O(l) ϩ O2(g) : 2 H2O2(l). (a) At 298 K and 1 atm, which method releases more energy per mole of O2? (b) Which method has the more negative standard Gibbs free energy? (c) Once hydrogen peroxide has been used at home, can it be regenerated easily from oxygen and water? 8.90 Acetic acid, CH3COOH(l), could be produced from (a) the reaction of methanol with carbon monoxide; (b) the oxidation of ethanol; (c) the reaction of carbon dioxide with methane. Write balanced chemical equations for each process. Carry out a thermodynamic analysis of the three possibilities and decide which you would expect to be the easiest to accomplish. 8.91 Some entries for Sm° in Appendix 2A are negative. What is common about these entries and why would the entropy be negative? 8.92 According to current theories of biological evolution, complex amino and nucleic acids were produced from randomly occurring reactions of compounds thought to be present in the Earth’s early atmosphere. These simple molecules then assembled into more and more complex molecules, such as DNA and RNA. Is this process consistent with the second law of thermodynamics? Explain your answer. 8.93 Using values in Appendix 2A, calculate the standard Gibbs free energy for the vaporization of water at 25.0°C, 100.0°C, and 150.0°C. (b) What should the value at 100.0°C be? (c) Why is there a discrepancy? 8.94 Propose the argument that, for any liquid at atmospheric pressure (that is, a liquid that boils above room temperature when the external pressure is 1 atm), the numerical value of ⌬Hvap in joules per mole is greater than the numerical value of ⌬Svap in joules per kelvin per mole. (Explain and justify each step and any assumptions.) 8.95 The molar entropy of electron spins in a magnetic field B is where ⌬E ϭ 2␮BB is the separation in energy of the two spin states in a magnetic field, ␮B is the Bohr magneton, ␮B ϭ 9.274 ϫ 10Ϫ24 J TϪ1 и Plot this function against temperature for the following values of B: 0.1 T, 1 T, 10 T, and 100 T. (See Box 8.1. Notice that the unit of magnetic induction, tesla, T, where 1 T ϭ 1 kg sϪ2 AϪ1 , cancels.) 8.96 The populations p of the up and down spin states of electrons in a magnetic field B are given by where ⌬E ϭ 2␮BB is the energy difference between the two spin states (see Exercise 8.95). Plot these two populations as a function of temperature for B ϭ 1 T. (See Box 8.1.) 8.97 Without doing any calculations, predict what temperature corresponds to equal populations of up and down spin states. (See Exercise 8.96.) 8.98 Suppose it could be arranged for there to be twice as many electrons with up spins than down spins in a sample in a magnetic field. Without doing any calculations, predict the sign of the temperature of such a sample. (See Exercise 8.96.) pdown = 1 1 + e-¢E/kT and pup = e-¢E/kT 1 + e-¢E/kT S = R e ¢E/kT e¢E/kT - 1 - ln (1 - e-¢E/kT )f EXERCISES 331 Catalyst 332 CHAPTER 8 THERMODYNAMICS: THE SECOND AND THIRD LAWS 8.99 It is helpful in understanding graphs of thermodynamic functions to interpret them in terms of molecular behavior. Consider the plot of the temperature dependence of the standard molar Gibbs free energy of the three phases of a substance in Fig. 8.25. (a) Explain in terms of molecular behavior why the Gibbs free energy of each phase decreases with temperature. (b) Explain in terms of molecular behavior why the Gibbs free energy of the vapor phase decreases more rapidly with temperature than that of the solid or liquid phase. 8.100 Because state functions depend only on the state of the system, when a system undergoes a series of processes that bring it back to the original state, a thermodynamic cycle has been carried out and all the state functions have returned to their original value. However, functions that depend on the path may have changed. (a) Verify that there is no difference in the state function S, for a process in which 1.00 mol of ideal gas molecules in a 3.00-L cylinder at 302 K undergoes the following three steps: (i) cooling at constant volume until T ϭ 75.6 K; (ii) heating at constant pressure until T ϭ 302 K; (iii) compressing at constant temperature until V ϭ 3.00 L. Calculate ⌬U and ⌬S for this entire cycle. (b) What are the values of q and w for the entire cycle? (c) What are ⌬Ssurr and ⌬Stotal for the cycle? If any values are nonzero, explain how this can be so, despite entropy being a state function. (d) Is the process spontaneous, nonspontaneous, or at equilibrium? 8.101 A technique used to overcome the unfavorable thermodynamics of one reaction is to “couple” that reaction with another process that is thermodynamically favored. For instance, the dehydrogenation of cyclohexane to form benzene and hydrogen gas is not spontaneous. Show that, if another molecule such as ethene is present to act as a hydrogen acceptor (that is, the ethene reacts with the hydrogen produced to form ethane), then the process can be made spontaneous. 8.102 Adenosine triphosphate (ATP) is an extremely important molecule in biological systems. Consult standard reference sources in your library to describe how this molecule is used in energy transfer to facilitate nonspontaneous processes necessary for life. 8.103 Three isomeric alkenes have the formula C4H8 (see the following table). (a) Draw Lewis structures of these compounds. (b) Calculate ⌬G°, ⌬H°, and ⌬S° for the three reactions that interconvert each pair of compounds. (c) Which isomer is the most stable? (d) Rank the isomers in order of decreasing Sm°. Compound ⌬Hf° (kJиmolϪ1 ) ⌬Gf° (kJиmolϪ1 ) 2-methylpropene Ϫ16.90 ϩ58.07 cis-2-butene Ϫ6.99 ϩ65.86 trans-2-butene Ϫ11.17 ϩ62.97 8.104 When a space shuttle re-enters the atmosphere, its temperature rises and it can heat the surrounding air to 1260°C. At that temperature some endothermic reactions take place that at lower temperatures are not spontaneous under standard conditions (pure substances, each at 1 bar). Estimate the temperatures at which the following stratospheric reactions become spontaneous under standard conditions. Which ones could occur during reentry of the space shuttle? (a) The formation of nitrogen monoxide from nitrogen and oxygen; (b) the formation of ozone from molecular oxygen. A word of warning: Because at this stage we have to assume that ⌬H° and ⌬S° are constant over the temperature range and that the conditions are standard (but see Section 8.15), this calculation gives only a very approximate estimate of the temperature at which such reactions are significant in practice. Chemistry Connections 8.105 Vehicle air bags protect passengers by allowing a chemical reaction to occur that generates gas rapidly. Such a reaction must be both spontaneous and explosively fast. A common reaction is the decomposition of sodium azide, NaN3, to nitrogen gas and sodium metal. (a) Write a balanced chemical equation for this reaction using the smallest whole-number coefficients. (b) Predict the sign of the entropy change for this reaction without doing a calculation. Explain your reasoning. (c) Determine the oxidation number of nitrogen in the azide ion and in nitrogen gas. Is nitrogen oxidized or reduced in the reaction? (d) Use the data in Appendix 2A and the fact that, for sodium azide, Sm° ϭ 96.9 JиKϪ1 ·molϪ1 , to calculate ⌬S° at 298 K for the decomposition of sodium azide. (e) Use your result from part (d) and the fact that, for sodium azide, ⌬Hf° ϭ ϩ21.7 kJиmolϪ1 , to calculate ⌬H° and ⌬G° at 298 K for the decomposition of sodium azide. (f) Is the reaction spontaneous at 298 K and a constant pressure of 1 bar? (g) Can the reaction become nonspontaneous (at a constant pressure of 1 bar) if the temperature is changed? If so, must the temperature be raised or lowered? 333 What Are the Key Ideas? Dynamic equilibrium between two phases is reached when the rate of conversion between them is the same in each direction. The rates are equal when the molar Gibbs free energy of the substance is the same in each phase and therefore there is no tendency to change in either direction. The same concepts apply to the dissolving of a solute. The presence of a solute alters the entropy of a solvent and consequently affects its thermodynamic properties. Why Do We Need to Know This Material? In earlier chapters, we investigated the nature of the solid, liquid, and gaseous states of matter; in this chapter, we extend the discussion to transformations between these states. This chapter introduces the concept of equilibrium between different phases of a substance, a concept that will prove to be of the greatest importance for chemical and biochemical transformations. We also take a deeper look at solutions in this chapter. We shall see how the presence of solutes is used by the body to control the flow of nutrients into and out of living cells and how the properties of solutions are used to separate the components of petroleum. What Do We Need to Know Already? This chapter develops the concepts of physical equilibria introduced in the context of thermodynamics (Chapters 7 and 8) and assumes a knowledge of intermolecular forces (Sections 5.1–5.5). The compositions of some of the solutions discussed are expressed in terms of mole fraction (Section 4.8). N early all the gases, liquids, and solids we encounter in our daily life are mixtures or solutions. In Section 4.8 we considered gaseous mixtures. In this chapter we investigate liquid solutions and see how the solutes dissolved in them affect their physical properties. The largest solutions on Earth are the oceans, which account for 1.4 ϫ 1021 kg of the Earth’s surface water. That mass amounts to nearly 2 ϫ 1018 t (1 t ϭ 103 kg) of water for each inhabitant, more than enough to supply all the drinking water needed for a thirsty world. However, drinking seawater itself can be fatal, because of the high concentrations of dissolved salts, in particular Naϩ and ClϪ ions (Table 9.1). The transformation of seawater into potable (drinkable) water is a major challenge around the world. This chapter describes one way that this purification can be achieved. Another solution of great importance to our lives is the plasma that carries the erythrocytes (red blood cells) through our bodies. These cells can cease to function if the concentrations of solutes in the plasma drift from their optimal values. This chapter explains why such changes occur and guides us through building a model that accounts for the behavior of solutions. We begin by examining phase changes in pure substances, then we see how the presence of a solute affects the properties of the substance. PHASES AND PHASE TRANSITIONS As we saw in Section 5.1, a single substance can exist in different phases, or physical forms. The phases of a substance include its solid, liquid, and gaseous forms. They also include its different solid forms, such as the diamond and graphite phases of carbon. In one case—helium—two liquid phases are known to exist. The conversion of a substance from one phase into another, such as the melting of ice, the vaporization of water, and the conversion of graphite into diamond, is called a phase transition. The unifying concept of this chapter is equilibrium. For a given pressure, a substance undergoes a phase transition at a specific temperature, such as the change from solid to liquid at the melting temperature. At this characteristic temperature, the solid and liquid phases of a substance are in equilibrium, at which point there is no change in Gibbs free energy, ⌬G ϭ 0, when one phase changes into the other. Thus, even though the entropy of the system would increase if some of it melted or vaporized, PHASES AND PHASE TRANSITIONS 9.1 Vapor Pressure 9.2 Volatility and Intermolecular Forces 9.3 The Variation of Vapor Pressure with Temperature 9.4 Boiling 9.5 Freezing and Melting 9.6 Phase Diagrams 9.7 Critical Properties SOLUBILITY 9.8 The Limits of Solubility 9.9 The Like-Dissolves-Like Rule 9.10 Pressure and Gas Solubility: Henry’s Law 9.11 Temperature and Solubility 9.12 The Enthalpy of Solution 9.13 The Gibbs Free Energy of Solution COLLIGATIVE PROPERTIES 9.14 Molality 9.15 Vapor-Pressure Lowering 9.16 Boiling-Point Elevation and Freezing-Point Depression 9.17 Osmosis BINARY LIQUID MIXTURES 9.18 The Vapor Pressure of a Binary Liquid Mixture 9.19 Distillation 9.20 Azeotropes THE IMPACT ON BIOLOGY AND MATERIALS 9.21 Colloids 9.22 Bio-based and Biomimetic Materials 333 Chapter 9 PHYSICAL EQUILIBRIA there is a compensating reduction in entropy of the surroundings as heat is drawn in from them, and there is no change in the total entropy of the system and its surroundings. Likewise, although the entropy of the system would decrease if vapor condensed or liquid froze, there is a compensating increase in the entropy of the surroundings as heat is released into them. In short, there is no thermodynamic driving force in either direction when two phases are in equilibrium. 9.1 Vapor Pressure A simple experiment can be used to show that, in a closed vessel, the liquid and vapor phases of a substance reach equilibrium with each other. First, we set up a mercury barometer. As we saw in Section 4.2, the mercury inside the tube falls to a height proportional to the external atmospheric pressure, leaving it about 76 cm high at sea level on Earth. The space above the mercury is almost a vacuum (the trace of mercury vapor present is so small that we can ignore it). Now suppose we inject a tiny drop of water into the space above the mercury. All the water added immediately evaporates and fills the space with vapor. The molecules in this vapor push the surface of the mercury down a few millimeters. The pressure exerted by the vapor—as measured by the change in the height of mercury—depends on the amount of water added. However, suppose we add so much water that a little liquid water remains on the surface of the mercury. The pressure of the vapor now remains constant, no matter how much liquid water is present (Fig. 9.1). We conclude that, at a fixed temperature, as long as some liquid is present, the vapor exerts a characteristic pressure regardless of the amount of liquid water present. For example, at 20°C, the mercury falls 18 mm, and so the pressure exerted by the water vapor is 18 Torr. The pressure of the water vapor is the same whether there is 0.1 mL or 1 mL of liquid water still present. This characteristic pressure is the “vapor pressure” of the liquid at the temperature of the experiment (Table 9.2). Liquids with high vapor pressures at ordinary temperatures are said to be volatile. Methanol (vapor pressure 98 Torr at 20°C) is highly volatile; mercury (1.4 mTorr) is not. Solids also exert a vapor pressure, but their vapor pressures are usually much lower than those of liquids because the molecules are gripped more tightly in a solid than they are in a liquid. Nevertheless, some solids vaporize in the process called “sublimation” (Section 7.11), which we can observe in the presence of some pungent solids—such as menthol and mothballs (naphthalene)—even at room temperature. To build a molecular model of the equilibrium between a liquid and its vapor we first suppose that the liquid is introduced into an evacuated closed container. Vapor forms as molecules leave the surface of the liquid. Most evaporation takes place from the surface of the liquid because the molecules there are least strongly bound to their neighbors and can escape more easily than those in the bulk. However, as the number of molecules in the vapor increases, more of them become available to strike the surface of the liquid, stick to it, and become part of the liquid again. Eventually, the number of molecules returning to the liquid each second matches the number escaping (Fig. 9.2). The vapor is now condensing as fast as the liquid is vaporizing, and so the equilibrium is dynamic in the sense introduced in Section 8.11: Rate of evaporation ϭ rate of condensation The dynamic equilibrium between liquid water and its vapor is denoted H2O(l) #¢4 H2O(g) Whenever we see the symbol T, it means that the species on both sides of the symbol are in dynamic equilibrium with each other. Although “products” (water molecules in the gas phase) are continually being formed from “reactants” (water molecules in the liquid phase), the products are changing back into reactants at a matching rate. With this picture in mind, we can now define the vapor pressure of a liquid (or a solid) as the pressure exerted by its vapor when the vapor and the liquid (or the solid) are in dynamic equilibrium with each other. The vapor pressure of a substance is the pressure exerted by its vapor when the vapor is in dynamic equilibrium with the condensed phase. 334 CHAPTER 9 PHYSICAL EQUILIBRIA TABLE 9.1 Principal Ions Found in Seawater Principal Concentration Element form (gؒL؊1 ) Cl ClϪ 19.0 Na Naϩ 10.5 Mg Mg2ϩ 1.35 S SO4 2Ϫ 0.89 Ca Ca2ϩ 0.40 K Kϩ 0.38 Br BrϪ 0.065 C HCO3 Ϫ , 0.028 H2CO3, CO2 TABLE 9.2 Vapor Pressures at 25°C Vapor pressure Substance (Torr) benzene 94.6 ethanol 58.9 mercury 0.0017 methanol 122.7 water* 23.8 *For values at other temperatures, see Table 9.3. Vacuum Water vapor Vapor pressure FIGURE 9.1 The apparatus is a mercury barometer. In the closeup, the left-hand column shows the vacuum above the mercury and the right-hand column shows the effect of the addition of a small amount of water. At equilibrium, some of the water has evaporated and the vapor pressure exerted by the water on the mercury has lowered the height of the mercury column. The vapor pressure is the same however much water is present in the column. 9.2 Volatility and Intermolecular Forces We can expect high vapor pressure when the molecules of a liquid are held together by weak intermolecular forces in the liquid and low vapor pressure when the intermolecular forces are strong. We therefore expect compounds capable of forming hydrogen bonds (which are stronger than other types of intermolecular interactions) to be less volatile than other molecular compounds of similar molar mass but unable to form hydrogen bonds. We can see the effect of hydrogen bonding clearly when we compare dimethyl ether (1) and ethanol (2), which have the same molecular formula, C2H6O. Because the two compounds have the same numbers of electrons, we can expect them to have similar London interactions and therefore similar vapor pressures. However, an ethanol molecule has an ßOH group and can form a hydrogen bond to another ethanol molecule. Ether molecules cannot form hydrogen bonds to one another because all their hydrogen atoms are attached to carbon atoms and the CßH bond is not very polar. As a result of this difference, ethanol is a liquid at room temperature, whereas dimethyl ether is a gas. Thinking point: Why does mercury have such a low vapor pressure at room temperature? Self-Test 9.1A Which do you expect to have the higher vapor pressure at room temperature, tetrabromomethane, CBr4, or tetrachloromethane, CCl4? Give your reasons. [Answer: CCl4; weaker London forces] Self-Test 9.1B Which do you expect to have the higher vapor pressure at 25°C, CH3CHO or CH3CH2CH3? The vapor pressure of a liquid at a given temperature is expected to be low and its enthalpy of vaporization high if the forces acting between its molecules are strong. 9.3 The Variation of Vapor Pressure with Temperature The vapor pressure of a liquid depends on how readily the molecules in the liquid can escape from the forces that hold them together. More energy to overcome these attractions is available at higher temperatures than at low, and so we can expect the vapor pressure of a liquid to rise with increasing temperature. Table 9.3 shows the temperature dependence of the vapor pressure of water and Fig. 9.3 shows how the vapor pressures of several liquids rise as the temperature increases. The data in the plot show the dependence of vapor pressure on the strengths of intermolecular forces. The compounds in the graph that can form hydrogen bonds (water and ethanol) have lower vapor pressures than diethyl ether. We can use the thermodynamic relations introduced in Chapter 8 to find an expression for the temperature dependence of vapor pressure and trace it to the role of intermolecular forces. TABLE 9.3 Vapor Pressure of Water Vapor pressure Temperature (°C) (Torr) 0 4.58 10 9.21 20 17.54 21 18.65 22 19.83 23 21.07 24 22.38 25 23.76 30 31.83 37* 47.08 40 55.34 60 149.44 80 355.26 100 760.00 *Body temperature. FIGURE 9.2 When a liquid and its vapor are in dynamic equilibrium inside a closed container, the rate of condensation is equal to the rate of evaporation. Animation 9.2 HOW DO WE DO THAT? To find how vapor pressure changes with temperature we make use of the fact that, when a liquid and its vapor are in equilibrium, there is no difference in the molar Gibbs free energies of the two phases: ⌬Gvap ϭ Gm(g) Ϫ Gm(l) ϭ 0 The Gibbs free energy of a liquid is almost independent of pressure, and so we can replace Gm(l) by its standard value (its value at 1 bar), Gm°(l). To derive the pressure dependence for a gas we recall that G ϭ H Ϫ TS, and therefore G(g, P) Ϫ Gm°(g) ϭ Hm(g, P) Ϫ Hm°(g) Ϫ T{Sm(g, P) Ϫ Sm°(g)} The enthalpy of an ideal gas is independent of pressure at constant temperature, so the first two terms on the right cancel. In Chapter 8 we derived the relation (recall Eq. 3b in Chapter 8) Therefore, by setting P1 ϭ P and P2 ϭ P°, -T{Sm(g, P) - Sm°(g)} = RT ln(P>P°) Sm(g, P2) - Sm(g, P1) = R ln(P1/P2) 1 Dimethyl ether 2 Ethanol It follows that, for an ideal gas, Gm(g, P) ϭ Gm°(g) ϩ RT ln(P͞P°) where P is the pressure, P° is the standard pressure (1 bar), and Gm° is the standard molar Gibbs free energy of the gas (its value at 1 bar). This pressure dependence is illustrated in Fig. 9.4. It follows that when the pressure P is the vapor pressure of the liquid, ⌬Gvap ϭ {Gm°(g) ϩ RT ln(P͞P°)} Ϫ Gm°(l) ϭ {Gm°(g) Ϫ Gm°(l)} ϩ RT ln(P͞P°) ϭ ⌬Gvap° ϩ RT ln(P/P°) ⌬Gvap° is the standard Gibbs free energy of vaporization, the change in molar Gibbs free energy when a liquid at 1 bar changes into a vapor at 1 bar. At equilibrium, ⌬Gvap ϭ 0, and so 0 ϭ ⌬Gvap° ϩ RT ln(P͞P°) It follows that At this point we can use ⌬Gvap° ϭ ⌬Hvap° Ϫ T⌬Svap°, where ⌬Hvap° and ⌬Svap° are the standard enthalpy and entropy of vaporization, respectively, and obtain Neither the enthalpy nor the entropy of vaporization varies much with temperature; so, for a given substance, ⌬Svap° and ⌬Hvap° can both be treated as approximately constant. It follows that the vapor pressures P1 and P2 at any two temperatures T1 and T2 are related by writing this equation for two temperatures and subtracting one from the other. In the process, the entropy terms cancel: We can also make use of the fact that ln x Ϫ ln y ϭ ln(x/y) to write the left hand side of this expression as ln(P2/P1). = ¢Hvap° R a 1 T1 - 1 T2 b ln(P2>P°) - ln(P1>P°) = a - ¢Hvap° RT2 + ¢Svap° R b - a - ¢Hvap° RT1 + ¢Svap° R b ln(P>P°) = ¢Hvap° - T¢Svap° RT = - ¢Hvap° RT + ¢Svap° R ln(P>P°) = - ¢Gvap° RT 336 CHAPTER 9 PHYSICAL EQUILIBRIA 20 40 60 80 100 Vaporpressure(kPa) 0 −150 −100 −50 0 50 100 Temperature (°C) Temperature (°C) Diethyl ether Ethanol Benzene Water 80 90 100 110 120 10 60 110 160 Vaporpressure(kPa) 101.325 kPa 120 101.325 kPa FIGURE 9.3 The vapor pressures of liquids increase sharply with temperature, as shown here for diethyl ether (red), ethanol (blue), benzene (green), and water (orange). The normal boiling point is the temperature at which the vapor pressure is 1 atm (101.325 kPa). Notice that the curve for ethanol, which has a higher enthalpy of vaporization than benzene, rises more steeply than that of benzene, as predicted by the Clausius–Clapeyron equation. The diagram on the right shows the vapor pressure of water close to its normal boiling point in more detail. MolarGibbsfreeenergy,Gm Pressure, P 0 0 1bar Gm° FIGURE 9.4 The variation of the molar Gibbs free energy of an ideal gas with pressure. The Gibbs free energy has its standard value when the pressure of the gas is 1 bar. The value of the Gibbs free energy approaches minus infinity as the pressure falls to zero. We have deduced the Clausius–Clapeyron equation for the vapor pressure of a liquid at two different temperatures: (1)* What does this equation tell us? When T2 Ͼ T1, the term in parentheses is positive, and because the enthalpy of vaporization is positive, ln(P2/P1) is positive too and we can conclude that P2 is greater than P1. In other words, the equation tells us that the vapor pressure increases with increasing temperature. Because ⌬Hvap° occurs in the numerator, the increase is greatest for substances with high enthalpies of vaporization (strong intermolecular interactions). ln P2 P1 = ¢Hvap° R a 1 T1 - 1 T2 b 9.3 THE VARIATION OF VAPOR PRESSURE WITH TEMPERATURE 337 EXAMPLE 9.1 Estimating the vapor pressure of a liquid from its value at a different temperature Tetrachloromethane, CCl4, which is now known to be carcinogenic, was once used as a drycleaning solvent. The enthalpy of vaporization of CCl4 is 33.05 kJиmolϪ1 and its vapor pressure at 57.8°C is 405 Torr. What is the vapor pressure of tetrachloromethane at 25.0°C? Anticipate Vapor pressure increases with temperature because the molecules have more energy to escape from their neighbors, so we should expect the vapor pressure of CCl4 to be lower at 25.0°C than at 57.8°C. We therefore expect a vapor pressure of less than 405 Torr. PLAN Substitute the temperatures and the enthalpy of vaporization into the Clausius–Clapeyron equation to find the ratio of vapor pressures. Then substitute the known vapor pressure to find the desired one. To use the equation, convert the enthalpy of vaporization into joules per mole and express all temperatures in kelvins. What should we assume? That ⌬Hvap° is constant over the temperature range of interest and that the vapor behaves as an ideal gas (so that the Clausius–Clapeyron equation is applicable). SOLVE Note that ⌬Hvap° ϭ 33.05 kJиmolϪ1 corresponds to 3.305 ϫ 104 JиmolϪ1 . 400 300 200 100 0 57.8ЊC 25ЊC Temperature(K) Convert temperatures to kelvins. T1 ϭ 57.8 ϩ 273.15 K ϭ 331.0 K T2 ϭ 25.0 ϩ 273.15 K ϭ 298.2 K 107 298 331 405 Vaporpressure(Torr) Temperature (K) Solve for P2 by taking the exponential (ex ) of both sides and using P1 ϭ 405 Torr. P2 = (405 Torr) * e 3.305*104 8.3145 A 1 331.0- 1 298.2B = 107 Torr A 1 T1 - 1 T2 BP2 = P1e ¢Hvap° R From ln(P2/P1) ϭ (⌬Hvap°/R) (1/T1 Ϫ 1/T2), (This expression evaluates to Ϫ1.33.) = 3.305 * 104 8.3145 a 1 331.0 - 1 298.2 b ln P2 P1 = 3.305 * 104 Jиmol-1 8.3145 JиK-1 иmol-1 a 1 331.0 K - 1 298.2 K b Evaluate As expected, the vapor pressure at 25°C, 107 Torr, is lower than its value at 57.8°C (405 Torr). A note on good practice: Exponential functions are very sensitive to rounding errors, so it is important to carry out the numerical calculation in one step. A common error is to forget to express the enthalpy of vaporization in joules (not kilojoules) per mole, but keeping track of units will help you to avoid that mistake. Self-Test 9.2A The vapor pressure of water at 25°C is 23.76 Torr and its standard enthalpy of vaporization at that temperature is 44.0 kJиmolϪ1 . Estimate the vapor pressure of water at 35°C. [Answer: 42 Torr] Self-Test 9.2B The vapor pressure of benzene at 25°C is 94.6 Torr and its standard enthalpy of vaporization is 30.8 kJиmolϪ1 . Estimate the vapor pressure of benzene at 35°C. The vapor pressure of a liquid increases as the temperature increases. The Clausius–Clapeyron equation gives the quantitative dependence of the vapor pressure of a liquid on temperature. 9.4 Boiling Now consider what happens when we heat a liquid in a container that is open to the atmosphere—water heated in a kettle is an example. When the temperature is raised to the point at which the vapor pressure is equal to the atmospheric pressure (for instance, when water is heated to 100°C and the external pressure is 1 atm), vaporization occurs throughout the liquid, not just from its surface, and the liquid boils. At the boiling temperature any vapor formed can drive back the atmosphere and make room for itself. Thus, bubbles of vapor form in the liquid and rise rapidly to the surface. As described in Section 8.4, the normal boiling point, Tb, of a liquid is the temperature at which a liquid boils when the external pressure is 1 atm. In other words, the normal boiling point is the temperature at which the vapor pressure of the liquid is 1 atm. To find the normal boiling points of the compounds in Fig. 9.3, we draw a horizontal line at P ϭ 1 atm (101.325 kPa) and note the temperatures at which it intersects the curves. Thinking point: Can a liquid boil in a sealed container? Boiling occurs at a temperature higher than the normal boiling point when the pressure is greater than 1 atm, as it is in a pressure cooker. In this case, a higher temperature is needed to raise the vapor pressure of the liquid to the higher pressure. Boiling occurs at a lower temperature when the pressure is less than 1 atm, because now the vapor pressure matches the external pressure at a lower temperature. At the summit of Mt. Everest—where the pressure is about 240 Torr—water boils at only 70°C. The lower the vapor pressure at room temperature, the higher the boiling point. Therefore, a high normal boiling point is a sign of strong intermolecular forces. 338 CHAPTER 9 PHYSICAL EQUILIBRIA EXAMPLE 9.2 Estimating the boiling point of a liquid The vapor pressure of ethanol at 34.9°C is 13.3 kPa. Use the data in Table 7.3 to estimate the normal boiling point of ethanol. Anticipate There is less hydrogen bonding between ethanol molecules than between H2O molecules, so we should expect the boiling point of ethanol to be lower than that of water even though its molar mass is greater. PLAN Use the Clausius–Clapeyron equation to find the temperature at which the vapor pressure has risen to 1 atm (101.325 kPa). What should we assume? That ⌬Hvap° is constant over the temperature range of interest and that the vapor behaves as an ideal gas (so that the Clausius–Clapeyron equation is applicable). SOLVE From Table 7.3, ⌬Hvap° ϭ 43.5 kJиmolϪ1 (ϭ 4.35 ϫ 104 JиmolϪ1 ). Convert the given temperature to kelvins. T2 ϭ 34.9 ϩ 273.15 K ϭ 308.0 K Evaluate The calculated boiling point corresponds to 77°C (lower than the 100°C of water, as we anticipated); the experimental value is 78°C. The small error probably comes from assuming that the enthalpy of vaporization is a constant over the temperature range of the question and assuming that the vapor behaves as an ideal gas. Self-Test 9.3A The vapor pressure of acetone, C3H6O, at 7.7°C is 13.3 kPa, and its enthalpy of vaporization is 29.1 kJиmolϪ1 . Estimate the normal boiling point of acetone. [Answer: 62.3°C (actual: 56.2°C)] Self-Test 9.3B The vapor pressure of methanol, CH3OH, at 49.9°C is 400. Torr, and its enthalpy of vaporization is 35.3 kJиmolϪ1 . Estimate the normal boiling point of methanol. Boiling occurs when the vapor pressure of a liquid is equal to the external (atmospheric) pressure. Strong intermolecular forces usually lead to high normal boiling points. 9.5 Freezing and Melting A liquid solidifies (freezes) when its molecules have such low energies that they are unable to wriggle past their neighbors. In the solid, the molecules vibrate about their average positions but rarely move from place to place. The freezing temperature, the temperature at which the solid and liquid phases are in dynamic equilibrium, varies slightly as the pressure is changed, and the normal freezing point, Tf, of a liquid is the temperature at which it freezes at 1 atm. In practice, a liquid sometimes does not freeze until the temperature is a few degrees below its freezing point. A liquid that survives below its freezing point is said to be supercooled. As described in Section 8.4, the normal melting point of a solid is the temperature at which it melts at 1 atm. The melting temperature of a solid is the same as the freezing temperature of the liquid. For most substances, the density of the solid phase of a substance is greater than that of the liquid phase, because the molecules pack together more closely in the solid phase. Applied pressure helps to hold the molecules together, and so a high temperature must be reached before the molecules of a solid at high pressure can break apart. As a result, most solids melt at higher temperatures when subjected to pressure. However, except at very high pressures, the effect of pressure is usually quite small. Iron at 1 atm, for example, melts at 1800 K, but it melts at only a few degrees higher when the pressure is a thousand times as great. At the center of the Earth, however, the pressure is high enough for iron to be solid despite the high temperatures there, so the Earth’s inner core is believed to be solid. Water is highly unusual in that at 0°C the density of the liquid is greater than that of ice. We already know this fact from a common observation: ice floats on water. Therefore, at the melting point, the molar volume of liquid water is less than that of ice. This anomalous behavior is due to the hydrogen bonds in ice, which result in a very open structure (Fig. 9.5; also see Section 5.10). When ice melts, many of the hydrogen bonds collapse, thereby allowing the water molecules to pack together more closely. As 9.5 FREEZING AND MELTING 339 Record the values of the pressure at the two temperatures. P1 ϭ 101.325 kPa, P2 ϭ 13.3 kPa Take the reciprocal of the result to obtain T1. T1 ϭ 350. K 13.3 101 Vaporpressure(kPa) 308 350 Temperature (K) Rearrange the Clausius–Clapeyron equation to 1/T1 ϭ 1/T2 ϩ (R/⌬Hvap°) ln(P2/P1) and substitute the data. = 1 308.0 K + 8.3145 4.35 * 104 K ln 13.3 101.325 = 1 350. K 1 T1 = 1 308.0 K + 8.3145 JиK-1 иmol-1 4.35 * 104 Jиmol-1 ln 13.3 kPa 101.325 kPa FIGURE 9.5 The structure of ice; notice how the hydrogen bonds, which are strongest when the hydrogen atom is directly between two oxygen atoms, hold the water molecules apart from one another in a hexagonal array. The two gray spheres between the oxygen atoms indicate the two possible locations of the hydrogen atom in that region of the structure. Only one of the positions is occupied. a result, high pressure encourages the formation of the denser liquid and the melting point of ice decreases as the pressure is increased. The melting points of most liquids increase with pressure. Water’s hydrogen bonds make it anomalous: its melting point decreases with pressure. 9.6 Phase Diagrams A phase diagram is a map that shows which phase is the most stable at different pressures and temperatures. The phase diagram for water is shown in Fig. 9.6, and that for carbon dioxide is shown in Fig. 9.7. These graphs are examples of phase diagrams for a single substance (water or carbon dioxide) and hence are known as one-component phase diagrams. Any point in the region marked “solid” (or, specifically, “ice” for water) corresponds to conditions for which the solid phase of the substance is the most stable; similarly, the regions marked “liquid” and “vapor” (or “gas”) indicate the conditions under which liquid and vapor, respectively, are the most stable phase. We can see from the phase diagram for carbon dioxide, for instance, that a sample of carbon dioxide at 10°C and 2 atm will be a gas but, if the pressure is increased at constant temperature to 10 atm, then carbon dioxide will condense to a liquid. Sulfur has two solid phases (Fig. 9.8), rhombic and monoclinic, corresponding to the two ways in which its crown-like S8 molecules can stack together. Many substances have several solid phases: even water forms at least ten kinds of ice, depending on how the H2O molecules fit together, but only one of them is stable at ordinary pressures (Fig. 9.9). Ice-VIII, for instance, is stable only above 20 000 atm and 100°C. The lines separating the regions in a phase diagram are called phase boundaries. At any point on a boundary between two regions, the two neighboring phases coexist in dynamic equilibrium. If one of the phases is a vapor, the pressure corresponding to this equilibrium is just the vapor pressure of the substance. Therefore, the liquid–vapor phase boundary shows how the vapor pressure of the liquid varies with temperature. For example, the point at 80.°C and 0.47 atm in the phase diagram for water lies on the phase boundary between liquid and vapor (Fig. 9.10), and so we know that the vapor pressure of water at 80.°C is 0.47 atm. Similarly, the solid–vapor phase boundary shows how the vapor pressure of the solid varies with temperature (see Fig. 9.6). The solid–liquid boundary, the almost vertical line in Figs. 9.6 and 9.10, shows the pressures and temperatures at which solid and liquid water coexist in equilibrium. In other words, it shows how the melting temperature of ice (or the freezing temperature of water) varies with pressure. The steepness of the lines indicates that even large changes in pressure result in only small variations in melting temperature. The slope of the solid–liquid boundary reveals the relative densities of solid and liquid. A negative slope, such as that in the phase diagram for water (Fig. 9.6), implies that the liquid is the denser phase. Notice that as we increase the pressure of ice, it will eventually be converted to liquid. If the slope is positive, as for carbon dioxide (Fig. 9.7), then the solid is the denser phase and if we increase the pressure on liquid carbon dioxide, it will solidify. Self-Test 9.4A A given metal melts at 1650 K at 1 atm and at 1700 K at 100 atm. Predict which phase of this metal is more dense, the solid or liquid. Explain your conclusion. [Answer: The solid, because the solid–liquid boundary slopes to the right, showing that the solid is the stable phase at higher pressures.] Self-Test 9.4B From the phase diagram for sulfur (Fig. 9.8), predict which phase is more dense, liquid sulfur or monoclinic sulfur. Explain your conclusion. A triple point is a point where three phase boundaries meet on a phase diagram. For water, the triple point for the solid, liquid, and vapor phases lies at 4.6 Torr and 0.01°C (see Fig. 9.6). At this triple point, all three phases (ice, liquid, and vapor) coexist in 340 CHAPTER 9 PHYSICAL EQUILIBRIA Temperature (°C) Pressure(Torr) Liquid Vapor Ice 760 4.6 0 100 Triple point A B C FIGURE 9.6 The phase diagram for water (not to scale). The heavy blue lines define the boundaries of the regions of pressure and temperature at which each phase is the most stable. Note that the freezing point decreases slightly with increasing pressure. The triple point is the point at which three phase boundaries meet. The letters A and B are referred to in Example 9.3. Temperature (°C) Pressure(atm) Liquid Vapor Solid 5.1 1 −56 31 73 FIGURE 9.7 The phase diagram for carbon dioxide (not to scale). The liquid can exist only at pressures above 5.1 atm. Note the slope of the boundary between the solid and liquid phases; it shows that the freezing point rises as pressure is applied. This characteristic implies that the liquid is less dense than the solid. mutual dynamic equilibrium: solid is in equilibrium with liquid, liquid with vapor, and vapor with solid. The location of a triple point of a substance is a fixed property of that substance and cannot be changed by changing the conditions. The triple point of water is used to define the size of the kelvin: by definition, there are exactly 273.16 kelvins between absolute zero and the triple point of water. Because the normal freezing point of water is found to lie 0.01 K below the triple point, 0°C (strictly, 0.00°C) corresponds to 273.15 K. In Fig. 9.8, we see that sulfur can exist in any of four phases: two solid phases (rhombic and monoclinic sulfur), one liquid phase, and one vapor phase. There are three triple points in the diagram, where various combinations of these phases, such as monoclinic solid, liquid, and vapor or monoclinic solid, rhombic solid, and liquid, coexist. However, four phases in mutual equilibrium (such as the vapor, liquid, and rhombic and monoclinic solid forms of sulfur, all in mutual equilibrium) in a one– component system has never been observed, and thermodynamics can be used to prove that such a “quadruple point” cannot exist. A phase diagram can be used to explain the changes that take place when the pressure or temperature of a substance is changed. Imagine that we have a sample of water in a cylinder fitted with a piston, that the temperature is constant at 50°C, and that the weights on the piston exert a pressure of 1.0 atm (Fig. 9.11). The piston presses on the surface of the liquid, as in Fig. 9.11a. Now we gradually reduce the pressure by removing some of the weights (Fig. 9.11b). At first, nothing seems to happen. The high pressure is keeping all the water molecules in the liquid state, and the volume of a liquid changes very little with pressure. However, when so many weights have been removed that the pressure has fallen to 0.12 atm (93 Torr, the vapor pressure of water at that temperature), vapor begins to appear (Fig. 9.11c). We are now at the vapor–liquid boundary on the phase diagram. The pressure remains constant so long as the liquid and vapor phases are both present at equilibrium. We are free to pull the piston up by an arbitrary extent (Fig. 9.11d), but enough water will evaporate to maintain the pressure at 0.12 atm. When we pull the piston out far enough, the liquid phase disappears (Fig. 9.11e); we are now free to modify the pressure of the vapor at will without changing the temperature (Fig. 9.11f). 9.6 PHASE DIAGRAMS 341 50 100 150 Temperature (°C) 10−6 10−4 10−2 1 102 104 Pressure(atm) Rhombic Monoclinic Liquid Vapor 151°C 120°C96°C 200 FIGURE 9.8 The phase diagram for sulfur. Notice that there are two solid phases and three triple points. The pressure scale, which is logarithmic, covers a very wide range of values. 0 200 400 600 800 1 1012 109 106 103 XI X VIII VII VI VII I III Vapor Liquid Pressure(Pa) Temperature (K) FIGURE 9.9 The phase diagram for water drawn with a logarithmic scale for pressure, in order to show the different solid phases of water in the high-pressure region. Vapor pressure of liquid Solid–liquid boundary Liquid Solid Temperature (°C) Pressure(atm) 1 0.47 0.20 0.073 0.023 0.0060 0 20 40 60 80100 Vapor FIGURE 9.10 The liquid–vapor boundary curve is a plot of the vapor pressure of the liquid (in this case, water) as a function of temperature. The liquid and its vapor are in equilibrium at each point on the curve. At each point on the solid–liquid boundary curve (for which the slope is slightly exaggerated), the solid and liquid are in equilibrium. 342 CHAPTER 9 PHYSICAL EQUILIBRIA Liquid Vapor (f)(e)(d)(c)(b)(a) L V S Temperature Pressure FIGURE 9.11 The changes undergone by a liquid as its pressure is decreased at constant temperature. The large dot on the vertical line in the phase diagram traces the path taken by the system, which is described in the text. The blue region in the container is the liquid and the light green region above it is the vapor. EXAMPLE 9.3 Interpreting a phase diagram Use the phase diagram in Fig. 9.6 to describe the physical states and phase changes of water as the pressure on it is increased from 5 Torr to 800 Torr at 70°C. Anticipate Because the pressure is increasing, we should expect the vapor to condense. PLAN First, locate the initial and final conditions on the phase diagram. The region in which each of these points lie shows the stable phase of the sample under those conditions. If a point lies on one of the curves, then both phases are present in mutual equilibrium. SOLVE Although the phase diagram in Fig. 9.6 is not to scale, we can find the approximate locations of the points. Point A is at 5 Torr and 70°C; so it lies in the vapor region. Increasing the pressure takes the vapor to the liquid–vapor phase boundary, at which point liquid begins to form. At this pressure, liquid and vapor are in equilibrium and the pressure remains constant until all the vapor has condensed. The pressure is increased further to 800 Torr, which takes it to point B, in the liquid region. Evaluate As expected, the vapor condenses. Self-Test 9.5A The phase diagram for carbon dioxide is shown in Fig. 9.7. Describe the physical states and phase changes of carbon dioxide as it is heated at 2 atm from –155°C to 25°C. [Answer: Solid CO2 is heated until it begins to sublime at the solid–vapor boundary. The temperature remains constant until all the CO2 has vaporized. The vapor is then heated to 25°C.] Self-Test 9.5B Describe what happens when liquid carbon dioxide in a container at 60 atm and 25°C is released into a room at 1 atm and the same temperature. A phase diagram summarizes the regions of pressure and temperature at which each phase of a substance is most stable. The phase boundaries show the conditions under which two phases can coexist in dynamic equilibrium with each other. Three phases coexist in mutual equilibrium at a triple point. 9.7 Critical Properties A feature of the phase diagram in Fig. 9.12 is that the liquid–vapor boundary comes to an end at point C. To see what happens at that point, suppose that a vessel like the one shown in Fig. 9.13 contains liquid water and water vapor at 25°C and 24 Torr (the Temperature (°C) Pressure(atm) Liquid Vapor Ice 0 C Critical point 1 (24 Torr, 25°C) (15 atm, 200°C) (218 atm, 374°C) 100 200 A B 100 200 300 FIGURE 9.12 A version of the phase diagram for water with more detail close to the critical point. Pressures are in atmospheres, except for point A. vapor pressure of water at 25°C). The two phases are in equilibrium, and the system lies at point A on the liquid–vapor curve in Fig. 9.12. Now let’s raise the temperature, which moves the system from left to right along the phase boundary. At 100.°C, the vapor pressure is 760. Torr; and, at 200.°C, it has reached 11.7 kTorr (15.4 atm, point B). The liquid and vapor are still in dynamic equilibrium, but now the vapor is very dense because the pressure is so great. When the temperature has been increased to 374°C (point C), the vapor pressure has reached 218 atm—the container must be very strong! The density of the vapor is now so great that it is equal to that of the remaining liquid. At this stage, the surface separating the liquid from its vapor vanishes and a single uniform phase fills the container. Because a substance that fills any container that it occupies is by definition a gas, we have to conclude that this single uniform phase is a gas, despite its high density (we shall see in a moment that a better term is “supercritical fluid”). Provided the temperature is at 374°C or above, it is found that even if the pressure is increased by compressing the sample, no surface appears. That is, 374°C is the critical temperature, Tc, of water, the temperature at and above which there can be no transition from vapor to liquid. Similar considerations apply to other substances (Table 9.4); for instance, the critical temperature of carbon dioxide is 31°C; at this temperature and above CO2 gas will not condense to a liquid whatever the pressure. The pressure corresponding to the end of the liquid–vapor phase boundary is called the critical pressure, Pc, of the substance. The critical pressure of water is 218 atm; that of carbon dioxide is 73 atm. The critical temperature and critical pressure jointly define the critical point of the substance. A note on good practice: We can now be more specific about when to call a gaseous phase a vapor. A “vapor” is the gaseous phase of a substance that is below its critical temperature. A gas can be liquefied by applying pressure only if it is below its critical temperature (Fig. 9.14). For example, carbon dioxide can be liquefied by applying pressure only if its temperature is lower than 31°C. According to Table 9.4, the critical temperature of oxygen is –118°C, and so we know that it cannot exist as a liquid at room temperature whatever the pressure. The dense fluid that exists above the critical temperature and pressure of a substance is called a supercritical fluid. It may be so dense that, although it is formally a gas, it is as dense as a liquid phase and can act as a solvent for liquids and solids. There is currently considerable interest in supercritical fluids as solvents for chemical reactions, as they are an important aspect of green chemistry. The use of supercritical carbon dioxide avoids contamination with potentially harmful solvents and allows rapid extraction on account of the high mobility of the molecules through the fluid. For example, because supercritical carbon dioxide can dissolve organic compounds it is used to remove caffeine from coffee beans, to separate drugs from biological fluids for later analysis, and to extract perfumes from flowers and phytochemicals from herbs. Supercritical hydrocarbons are used to extract useful compounds from coal and fly ash 9.7 CRITICAL PROPERTIES 343 FIGURE 9.13 When the temperature of a liquid in a sealed, constant-volume container (left) is raised, the density of the liquid decreases and the density of the vapor increases (center). At the critical temperature, Tc, the density of the vapor becomes the same as the density of the liquid; at and above that temperature, a single uniform phase fills the container (right). FIGURE 9.14 When pressure is applied to a vapor below its critical temperature, the vapor may be liquefied. However, if the temperature is above the critical temperature (the vertical dotted line), an increase in pressure does not take the vapor into the liquid region. At high pressures above its critical temperature, the substance becomes a supercritical fluid. TABLE 9.4 Critical Temperatures and Pressures of Selected Substances Critical Critical temperature pressure Substance (°C) (atm) He –268 (5.2 K) 2.3 Ne –229 27 Ar –123 48 Kr –64 54 Xe 17 58 H2 –240 13 O2 –118 50 H2O 374 218 N2 –147 34 NH3 132 111 CO2 31 73 CH4 –83 46 C6H6 289 49 and a variety of supercritical fluids are being investigated for recovering petroleum from oil-rich tar sands. Thinking point: What might be some disadvantages of using supercritical fluids for solvent extraction? Self-Test 9.6A Identify trends in the data in Table 9.4 that indicate the relationship of the strength of London forces to the critical temperature. [Answer: Noble gases have higher critical temperatures as their atomic number increases; so critical temperature increases with the strength of London forces.] Self-Test 9.6B Identify trends in the data in Table 9.4 that indicate the effect of hydrogen bonding on the critical temperature. The vapor of a substance can be condensed to a liquid by the application of pressure only if it is below its critical temperature. SOLUBILITY The presence of a solute affects the physical properties of the solvent. For instance, when salt is spread on icy sidewalks, a mixture is created with a lower freezing point than that of pure water and the ice melts to form a salt solution. In this part of the chapter we explore the molecular nature of these effects and see how to treat them quantitatively. 9.8 The Limits of Solubility Let’s imagine that we could see at the molecular level what happens when we add a crystal of glucose to some water. The water molecules next to the surface of the crystal form hydrogen bonds to the glucose molecules. As a result, the surface glucose molecules are pulled toward the solution by water molecules but are held back by other glucose molecules. When the interactions with water molecules are comparable to the interactions with the other glucose molecules, the glucose molecules can drift off into the solvent, surrounded by water molecules. A similar process takes place when an ionic solid dissolves. The polar water molecules hydrate the ions (surround them in a 344 CHAPTER 9 PHYSICAL EQUILIBRIA FIGURE 9.15 The events that take place at the interface of a solid ionic solute and a solvent (water). Only the surface layer of ions is shown. When the ions at the surface of the solid become hydrated, they move off into the solution. The insets at the right show the ions alone. FIGURE 9.16 When a little glucose is stirred into 100 mL of water, all the glucose dissolves (left). However, when enough glucose is added, some undissolved glucose remains and the solution is saturated with glucose (right). Animation 9.15 closely held “shell,” Section 5.2) and pry them away from the predominately attractive forces within the crystal lattice (Fig. 9.15). Stirring and shaking speed the process because they bring more free water molecules to the surface of the solid and sweep the hydrated ions away. If we add only a small amount—20 g, for instance—of glucose to 100 mL of water at room temperature, it all dissolves. However, if we add 200 g, some glucose remains undissolved (Fig. 9.16). A solution is said to be saturated when the solvent has dissolved all the solute that it can and some undissolved solute remains. At this point the concentration of solid solute in a saturated solution has reached its greatest value and no more can dissolve. The molar solubility, s, of a substance is its molar concentration in a saturated solution. In other words, the molar solubility of a substance represents the limit of its ability to dissolve in a given quantity of solvent. In a saturated solution, any solid solute present still continues to dissolve, but the rate at which it dissolves exactly matches the rate at which the solute returns to the solid (Fig. 9.17). In a saturated solution, the dissolved and undissolved solute are in dynamic equilibrium with each other. The molar solubility of a substance is its molar concentration in a saturated solution. A saturated solution is one in which the dissolved and undissolved solute are in dynamic equilibrium with each other. 9.9 The Like-Dissolves-Like Rule Understanding the interplay of forces that takes place when a solute dissolves can help us answer some practical questions. Suppose, for instance, we need to remove some oil that has soiled a fabric. How can we select a good solvent for the oil? A good guide is the rule that like dissolves like. A polar liquid, such as water, is generally the best solvent for ionic and polar compounds. Conversely, nonpolar liquids, including hexane and tetrachloroethene, Cl2C≈CCl2, used for dry cleaning, are often better solvents for nonpolar compounds such as hydrocarbon oils, which are held together by London forces. We can explain the “like-dissolves-like” rule by examining the attractions between solute and solvent molecules. When a solute dissolves in a liquid solvent, the solute–solute attractions must be replaced by solute–solvent attractions, and dissolving can be expected to occur if the new interactions are similar to the original interactions (Fig. 9.18). For example, when the main cohesive forces in a solute are hydrogen 9.9 THE LIKE-DISSOLVES-LIKE RULE 345 FIGURE 9.17 The solute in a saturated solution is in dynamic equilibrium with the undissolved solute. If we could follow the solute particles (orange spheres), we would sometimes find them in solution and sometimes back within the solid. Red, green, and blue lines represent the paths of individual solute particles. The solvent molecules are not shown. Animation 9.17 Solubility was introduced in Section I. Separation of solute 2 1 3 Solution Dissolution Cavitiesoccupiedbysolute Formation of cavities Enthalpy FIGURE 9.18 A representation of the changes in molecular interactions and energy associated with the formation of a dilute solution. Step 1 is the separation of solute molecules from one another. In step 2, some of the solvent molecules move apart and leave cavities in the solvent. In step 3, the solute molecules occupy the cavities in the solvent, a process that releases energy. The overall energy change for the process is the sum of the energy changes, shown by the dark red arrow. In the actual dissolving process, these steps do not occur independently. 346 CHAPTER 9 PHYSICAL EQUILIBRIA bonds, the solute is more likely to dissolve in a hydrogen-bonded solvent than in other solvents. The molecules can slip into solution only if they can replace their strong solute–solute hydrogen bonds with strong solute–solvent hydrogen bonds. Glucose, for example, has hydrogen-bond-forming ßOH groups and dissolves readily in water but not in hexane. If the principal cohesive forces between solute molecules are London forces, then the best solvent is likely to be one that can mimic those forces. For example, a good solvent for nonpolar substances is the nonpolar liquid carbon disulfide, CS2. It is a far better solvent than water for sulfur because solid sulfur is a molecular solid of S8 molecules held together by London forces (Fig. 9.19). The sulfur molecules cannot penetrate into the strongly hydrogen–bonded structure of water, because they cannot replace those bonds with interactions of similar strength. The cleaning action of soaps and detergents relies on the like-dissolves-like rule. Soaps are the sodium salts of long-chain carboxylic acids, including sodium stearate (3). The anions of these acids have a polar carboxylate group (ßCO2 Ϫ ), called the head group, at one end of a nonpolar hydrocarbon chain. The head group is hydrophilic, or water attracting, whereas the nonpolar hydrocarbon tails are hydrophobic, or water repelling. Because the hydrophilic head group of the anion is able to dissolve in water and the hydrophobic hydrocarbon tails are able to dissolve in grease, soap is very effective at removing grease. The hydrocarbon tails sink into a blob of grease up to the head groups and the hydrophilic head groups remain on the surface of the blob. The casing of soap molecules, which is called a micelle, is soluble in water and so carries away the grease (Fig. 9.20). Soaps are made by heating sodium hydroxide with a fat such as coconut oil, olive oil, or beef fat, which contain esters formed between glycerol and fatty acids (see Section 19.7). The sodium hydroxide attacks the esters and forms the soluble soap. In the case of beef fat, stearic acid forms the soap sodium stearate, seen in (3). Soaps, however, form a scum in hard water (water that contains Ca2ϩ and Mg2ϩ ions). The scum is an impure precipitate of almost insoluble calcium and magnesium stearates. Modern commercial detergents are mixtures. Their most important component is a surfactant, or surface-active agent, which takes the place of the soap. Surfactant FIGURE 9.19 Sulfur, which is a solid with nonpolar molecules, does not dissolve in water (left), but it does dissolve in carbon disulfide (right), with which the S8 molecules have favorable London interactions. 3 Sodium stearate, NaCH3(CH2)16CO2 Naϩ Ϫ FIGURE 9.20 On the left, the hydrocarbon tails of a soap or surfactant molecule begin to dissolve in grease. (Schematic representations of the molecules, with the grease depicted as a gray blob and the polar heads of the surfactant molecules shown in red, are shown next to the space-filling models.) The water-attracting head groups remain on the surface where they can interact favorably with water (right). As more surfactant molecules dissolve in the grease, the whole blob, called a micelle, is suspended in water and is washed away. Hard water is discussed in Section 9.12. 9.10 PRESSURE AND GAS SOLUBILITY: HENRY’S LAW 347 molecules are organic compounds with a structure and action similar to those of soap. A difference is that they typically contain sulfur atoms in their polar groups (4). Detergents are used because they do not form precipitates with the ions in hard water. A general guide to the suitability of a solvent is the rule that like dissolves like. Soaps and detergents contain surfactant molecules that have both hydrophobic and hydrophilic regions. 9.10 Pressure and Gas Solubility: Henry’s Law Almost all aquatic organisms rely on the presence of dissolved oxygen for respiration. Although oxygen is nonpolar, it is very slightly soluble in water and the extent to which it dissolves depends on its pressure. We have already seen (in Section 4.2) that the pressure of a gas arises from the impacts of its molecules. When a gas is introduced into the same container as a liquid, the gas molecules can burrow into the liquid like meteorites plunging into the ocean. Because the rate at which the gas molecules strike the liquid increases as the pressure of a gas increases, we should expect the solubility of the gas—its molar concentration when the dissolved gas is in dynamic equilibrium with the free gas—to increase as its pressure increases. If the gas above the liquid is a mixture (like air), then the solubility of each component depends on that component’s partial pressure (Fig. 9.21). The straight lines in Fig. 9.21 show that the solubility of a gas is directly proportional to its partial pressure, P. This observation was first made in 1801 by the English chemist William Henry and is now known as Henry’s law. The law is normally written s ϭ kHP (2)* The constant kH, which is called Henry’s constant, depends on the gas, the solvent, and the temperature (Table 9.5). Molarsolubility(mol·L−1) 1.5 ϫ 10−3 1.0 ϫ 10−3 0.5 ϫ 10−3 Oxygen Nitrogen Helium 0 0 0.5 1 Partial pressure (atm) FIGURE 9.21 The variation of the molar solubilities of oxygen, nitrogen, and helium gases with partial pressure. Note that the solubility of each gas doubles when its partial pressure is doubled. EXAMPLE 9.4 Estimating the solubility of a gas in a liquid Verify that the concentration of oxygen in lake water is normally adequate to sustain aquatic life, which requires an O2 concentration of at least 0.13 mmolиLϪ1 . The partial pressure of oxygen is 0.21 atm at sea level. Anticipate We know that aquatic life is viable under normal circumstances, so we should expect to achieve the critical concentration, probably with a safety margin. PLAN Use Eq. 2 to calculate the concentration of oxygen. 4 A typical surfactant ion Ϫ TABLE 9.5 Henry’s Constants for Gases in Water at 20°C Gas kH (molؒL؊1 ؒatm؊1 ) Gas kH (molؒL؊1 ؒatm؊1 ) air 7.9 ϫ 10–4 hydrogen 8.5 ϫ 10–4 argon 1.5 ϫ 10–3 neon 5.0 ϫ 10–4 carbon dioxide 2.3 ϫ 10–2 nitrogen 7.0 ϫ 10–4 helium 3.7 ϫ 10–4 oxygen 1.3 ϫ 10–3 0.27 1.3 Solubility(mmol·LϪ1) 0.21 1 Pressure (atm) From s ϭ kHP, = 2.7 * 10-4 molиL-1 s = 11.3 * 10-3 molиL-1 иatm-1 2 * 10.21 atm2 SOLVE 348 CHAPTER 9 PHYSICAL EQUILIBRIA Evaluate The molar concentration of O2 is 0.27 mmolиLϪ1 , which is more than adequate to sustain life, as we anticipated. Self-Test 9.7A At the elevation, 2900 m, of Bear Lake in Rocky Mountain National Park, the partial pressure of oxygen is 0.14 atm. What is the molar solubility of oxygen in Bear Lake at 20.°C? [Answer: 0.18 mmolиLϪ1 ] Self-Test 9.7B Use the information in Table 9.5 to calculate the amount (in moles) of CO2 that will dissolve in enough water to form 900. mL of solution at 20.°C when the partial pressure of CO2 is 1.00 atm. The solubility of a gas is proportional to its partial pressure, because an increase in pressure corresponds to an increase in the rate at which gas molecules strike the surface of the solvent. 9.11 Temperature and Solubility Most substances dissolve more quickly at higher temperatures than at low ones. However, that does not necessarily mean that they are more soluble—that is, reach a higher concentration of solute—at higher temperatures. In a number of cases, the solubility turns out to be lower at higher temperatures. We must always distinguish the effect of temperature on the rate of a process from its effect on the final out- come. Near room temperature most gases become less soluble in water as the temperature is raised. The lower solubility of gases in warm water is responsible for the tiny bubbles that appear when cool water from the faucet is left to stand in a warm room. The bubbles consist of air that dissolved when the water was cooler; it comes out of solution as the temperature rises. In contrast, most ionic and molecular solids are more soluble in warm water than in cold (Fig. 9.22). We make use of this characteristic in the laboratory to dissolve a substance and to grow crystals by letting a saturated solution cool slowly. However, a few solids containing ions that are extensively hydrated in water, such as lithium carbonate, are less soluble at high temperatures than at low. A small number of compounds show a mixed behavior. For example, the solubility of Exceptions to the common observation that the solubilities of gases decrease as the temperature is raised include gases that react with water, such as carbon dioxide and ammonia. 200 400 600 800 1000 0 0 20 40 60 80 100 Temperature (°C) Temperature (°C) AgNO3 KI KNO3 Solubility(gsolute/100gsolvent) 0 10 20 30 40 50 0 20 40 60 80 100 Li2CO3 NaCl Na2SO4 Na2SO4·10H2O FIGURE 9.22 The variation with temperature of the solubilities of six substances in water. The graph on the right is expanded vertically to show the variation in solubilities of three ionic compounds more clearly. sodium sulfate decahydrate increases up to 32°C but then decreases as the temperature is raised further. The rate of dissolving, but not necessarily the solubility of a substance, increases at higher temperatures. Most gases are less soluble in warm water than in cold water; solids show a more varied behavior. 9.12 The Enthalpy of Solution The change in molar enthalpy when a substance dissolves is called the enthalpy of solution, ⌬Hsol. The change can be measured calorimetrically from the heat released or absorbed when the substance dissolves at constant pressure. However, because solute molecules interact with one another as well as with the solvent, to isolate the solute–solvent interactions we focus on the limiting enthalpy of solution, the enthalpy change accompanying the formation of such dilute solutions that the solute–solute interactions are negligible (Table 9.6). The data show that some solids, such as lithium chloride, dissolve exothermically, with a release of heat. Others, such as ammonium nitrate, dissolve endothermically. To gain insight into the values in Table 9.6, we can think of dissolving as a hypothetical two-step process (Fig. 9.23). In the first step, we imagine the ions separating from the solid to form a gas of ions. The change in molar enthalpy accompanying this highly endothermic step is the lattice enthalpy, ⌬HL, of the solid, which was introduced in Section 7.19 (see Table 7.6 for values). The lattice enthalpy of sodium chloride (787 kJиmolϪ1 ), for instance, is the molar enthalpy change for the process NaCl(s) Naϩ (g) ϩ ClϪ (g) We saw in Section 7.19 that compounds formed from small, highly charged ions (such as Mg2ϩ and O2Ϫ ) cohere strongly and that a lot of energy is needed to break up the lattice. Such compounds have high lattice enthalpies. Compounds formed from large ions with low charges, such as potassium iodide, typically have weak attractive forces and correspondingly low lattice enthalpies. In the second hypothetical step, we imagine the gaseous ions plunging into water and forming the final solution. The molar enthalpy of this step is called the enthalpy of hydration, ⌬Hhyd, of the compound (Table 9.7). Enthalpies of hydration are negative and comparable in value to the lattice enthalpies of the compounds. For sodium chloride, for instance, the enthalpy of hydration, the molar enthalpy change for the process Naϩ (g) ϩ ClϪ (g) Naϩ (aq) ϩ ClϪ (aq)¡ ¡ 9.12 THE ENTHALPY OF SOLUTION 349 EnthalpyEnthalpy Gas of ions Gas of ions Solid Solid Solution Solution ⌬HL ⌬Hhyd ⌬Hsol ⌬HL ⌬Hhyd ⌬Hsol (a) (b) FIGURE 9.23 The enthalpy of solution, ⌬Hsol, is the sum of the enthalpy change required to separate the molecules or ions of the solute (the lattice enthalpy, ⌬HL; step 1 in Fig. 9.18), and the enthalpy change accompanying their hydration (⌬Hhyd; steps 2 and 3 in Fig. 9.18). The outcome is finely balanced: (a) in some cases, it is exothermic; (b) in others, it is endothermic. For gaseous solutes, the lattice enthalpy is zero because the molecules are already widely separated. TABLE 9.6 Limiting Enthalpies of Solution, ⌬Hsol, at 25°C, in kilojoules per mole* Anion Cation fluoride chloride bromide iodide hydroxide carbonate sulfate nitrate lithium ϩ4.9 Ϫ37.0 Ϫ48.8 Ϫ63.3 Ϫ23.6 Ϫ18.2 Ϫ2.7 Ϫ29.8 sodium ϩ1.9 ϩ3.9 Ϫ0.6 Ϫ7.5 Ϫ44.5 Ϫ26.7 ϩ20.4 Ϫ2.4 potassium Ϫ17.7 ϩ17.2 ϩ19.9 ϩ20.3 Ϫ57.1 Ϫ30.9 ϩ34.9 ϩ23.8 ammonium Ϫ1.2 ϩ14.8 ϩ16.0 ϩ13.7 — — ϩ25.7 ϩ6.6 silver Ϫ22.5 ϩ65.5 ϩ84.4 ϩ112.2 — ϩ41.8 ϩ22.6 ϩ17.8 magnesium Ϫ12.6 Ϫ160.0 Ϫ185.6 Ϫ213.2 ϩ2.3 Ϫ25.3 Ϫ90.9 Ϫ91.2 calcium ϩ11.5 Ϫ81.3 Ϫ103.1 Ϫ119.7 Ϫ16.7 Ϫ13.1 Ϫ19.2 Ϫ18.0 aluminum Ϫ27 Ϫ329 Ϫ368 Ϫ385 — — — Ϫ350 *The value for silver iodide, for example, is the entry found where the row labeled “silver” intersects the column labeled “iodide.” is Ϫ784 kJиmolϪ1 . That is enough energy for 1 g of NaCl (as a gas of Naϩ and ClϪ ions) to raise the temperature of 100 mL of water by nearly 50°C. Hydration is always exothermic for ionic compounds because of the formation of ion–dipole attractions between the water molecules and the ions. It is also exothermic for molecules that can form hydrogen bonds with water, such as sucrose, glucose, acetone, and ethanol. Now we bring the two steps of the dissolving process together and calculate the enthalpy change for the overall process: ⌬Hsol ϭ ⌬HL ϩ ⌬Hhyd When we include the data, the limiting enthalpy of solution of sodium chloride, the enthalpy change for the process NaCl(s) Naϩ (aq) ϩ ClϪ (aq) is ⌬Hsol ϭ 787 kJиmolϪ1 Ϫ 784 kJиmolϪ1 ϭ ϩ3 kJиmolϪ1 Lattice Enthalpy of Enthalpy of enthalpy hydration solution Because the enthalpy of solution is positive, there is a net inflow of energy as heat when the solid dissolves (recall Fig. 9.23b). Sodium chloride therefore dissolves endothermically, but only to the extent of 3 kJиmolϪ1 . As this example shows, the overall change in enthalpy depends on a very delicate balance between the lattice enthalpy and the enthalpy of hydration. Thinking point: Why does sodium chloride dissolve in water spontaneously despite the fact that the dissolving is endothermic? High charge and small ionic radius both contribute to a high enthalpy of hydration. However, the same properties also contribute to high lattice enthalpy. It is therefore very difficult to make reliable predictions about solubilities on the basis of ion charge and radius. The best we can do is to use these properties to rationalize what is observed. With that limitation in mind, we can begin to understand the behavior of some everyday substances and the properties of some minerals. For example, nitrates have big, singly charged anions and hence low lattice enthalpies. Their hydration enthalpies, though, are quite large because water can form hydrogen bonds with the nitrate anions. As a result, they are rarely found in mineral deposits because they are soluble in groundwater, the water that trickles through the ground and washes away soluble substances. Carbonate ions are about the same size as nitrate ions, but they are doubly charged. As a result, carbonates commonly have higher lattice enthalpies than do nitrates, and it is much harder to break the ions out of solids such as limestone (calcium carbonate). Hydrogen ¡ 350 CHAPTER 9 PHYSICAL EQUILIBRIA TABLE 9.7 Enthalpies of Hydration, ⌬Hhyd, at 25°C, of Some Halides, in kilojoules per mole* Anion Cation F؊ Cl؊ Br؊ I؊ H؉ Ϫ1613 Ϫ1470 Ϫ1439 Ϫ1426 Li؉ Ϫ1041 Ϫ898 Ϫ867 Ϫ854 Na؉ Ϫ927 Ϫ784 Ϫ753 Ϫ740 K؉ Ϫ844 Ϫ701 Ϫ670 Ϫ657 Ag؉ Ϫ993 Ϫ850 Ϫ819 Ϫ806 Ca2؉ — Ϫ2337 — — *The entry where the row labeled Naϩ intersects the column labeled ClϪ , for instance, is the enthalpy change, Ϫ784 kJ·molϪ1 , for the process Naϩ (g) ϩ ClϪ (g) : Naϩ (aq) ϩ ClϪ (aq); the values here apply only when the resulting solution is very dilute. 9.13 THE GIBBS FREE ENERGY OF SOLUTION 351 Natural Unnatural FIGURE 9.24 The dissolution of a solid is a natural process that is usually accompanied by an increase in disorder. However, to decide whether the dissolution is spontaneous, the accompanying changes in the surroundings must be considered, too. The insets show the solute particles alone. carbonate ions (bicarbonate ions, HCO3 Ϫ ) have a single charge and their salts are more soluble than carbonates. The difference in solubility between carbonates and hydrogen carbonates is responsible for the behavior of “hard water,” which is water that contains dissolved calcium and magnesium salts. Hard water originates as rainwater, which dissolves carbon dioxide from the air and forms a very dilute solution of carbonic acid. CO2(g) ϩ H2O(l) H2CO3(aq) As the water runs over and through the ground, the carbonic acid reacts with the calcium carbonate of limestone or chalk and forms the more soluble hydrogen carbonate: CaCO3(s) ϩ H2CO3(aq) Ca2ϩ (aq) ϩ 2 HCO3 Ϫ (aq) These two reactions are reversed when water containing Ca(HCO3)2 is heated in a kettle or furnace: Ca2ϩ (aq) ϩ 2 HCO3 Ϫ (aq) CaCO3(s) ϩ H2O(l) ϩ CO2(g) The carbon dioxide is driven off and the calcium carbonate is deposited as the hard, insoluble deposit known as scale. Enthalpies of solution in dilute solutions can be expressed as the sum of the lattice enthalpy and the enthalpy of hydration of the compound. 9.13 The Gibbs Free Energy of Solution A negative enthalpy of solution tells us that energy is released as heat when a substance dissolves. However, to judge whether dissolving is spontaneous at constant temperature and pressure, we need to consider the change in Gibbs free energy, ⌬G ϭ ⌬H Ϫ T⌬S. In other words, we have to consider changes in the entropy of the system, not just the change in enthalpy. The disorder of a system typically increases when a solid dissolves (Fig. 9.24). Therefore, in most cases, we can expect the entropy of the system to increase when a solution forms. Because T⌬S is positive, this increase in disorder makes a negative contribution to ⌬G. If ⌬H is negative, we can be confident that ⌬G is negative overall. Therefore, we can expect most substances with negative enthalpies of solution to be soluble. In some cases, the entropy of the system is lowered when the solution forms because the solvent molecules form cagelike structures around the solute molecules. As a result, ⌬S is negative and the term ϪT⌬S makes a positive contribution to ⌬G. Even if ⌬H is negative, ⌬G might be positive. In other words, even if energy is released to the surroundings, the increase in the entropy of the surroundings may not be enough to overcome the decrease in entropy of the solution. In such a case ⌬G is positive and the substance does not dissolve. For this reason, some hydrocarbons, such as heptane, are insoluble in water even though they have weakly negative enthalpies of solution. If ⌬H is positive, ⌬G ϭ ⌬H Ϫ T⌬S can be negative only if T⌬S is positive and larger than ⌬H. That is, the solubilities of substances that dissolve endothermically depend on the balance of the entropy change of the system and that of the surroundings. A substance with a strongly positive enthalpy of solution is likely to be insoluble, because the entropy of the surroundings may decrease so much as energy leaves them and enters the solution that dissolving corresponds to an overall decrease in disorder. Understanding the contributions to the Gibbs free energy of dissolving helps us to explain the temperature dependence of solubility. The Gibbs energy becomes more ¡ ¡ ¡ Although we write the reaction as leading to the formation of H2CO3, a high proportion of dissolved carbon dioxide remains unreacted. Remember that ⌬G is a measure of the overall change in entropy: at constant temperature and pressure, ⌬S is the change in entropy of the system and Ϫ⌬H/T is the change in entropy of the surroundings (Section 8.9). 352 CHAPTER 9 PHYSICAL EQUILIBRIA negative and favorable to dissolving as the temperature increases only when ⌬S is positive. For most ionic substances, dissolving does indeed result in an increase in the entropy of the system and these substances are more soluble at higher temperatures (see Fig. 9.22). However, when a gas dissolves in a liquid, its molecules occupy much less space and there is a considerable reduction in the entropy of the system. In such a case ϪT⌬S is positive. Consequently, an increase in temperature causes ⌬G to rise and dissolving is less favorable. Because ⌬G for the dissolving of a solute depends on the concentration of the solute, even if ⌬G is negative at low concentrations, it may become positive at high concentrations (Fig. 9.25). A solute dissolves spontaneously only until ⌬G ϭ 0. At that point, dissolved and undissolved solute are in equilibrium—the solution is saturated. Dissolving depends on the balance between the change in entropy of the solution and the change in entropy of the surroundings. COLLIGATIVE PROPERTIES Some properties of a solution are essential to life. For example, osmosis, the tendency of a solvent to flow through a membrane into a solution, promotes the flow of nutrients through biological cell walls. When chemists started to study the physical properties of solutions quantitatively, they discovered that some properties, including osmosis, depend only on the relative amounts of solute and solvent and are independent of the chemical identity of the solute. Properties that depend on the relative numbers of solute and solvent molecules and not on the chemical identity of the solute are called colligative properties. The four colligative properties we shall consider are the lowering of the vapor pressure of the solvent, the raising of its boiling point, the lowering of its freezing point, and osmosis. All four properties involve an equilibrium between two phases of a solvent or (for osmosis) between two solutions with different concentrations. 9.14 Molality Two measures of concentration that are useful for the study of colligative properties, because they indicate the relative numbers of solute and solvent molecules, are mole fraction and molality. The measure of composition mole fraction, x, was first introduced in Section 4.8, where we saw that it is the ratio of the amount (in moles) of a species to the total amount of all the species present in a mixture. For our purposes we write or (3)* The molality, b, of a solute is the amount of solute species (in moles) in a solution divided by the mass of the solvent (in kilograms): or (4)* A note on good practice: The IUPAC symbol for molality is either m or b; we prefer the latter because it avoids confusion with m for mass (as in Eq. 4). The units of molality are moles of solute per kilogram of solvent (molиkgϪ1 ); these units are often (but unofficially) denoted m (for example, a 1 m NiSO4(aq) solution) and read “molal.” Because contexts differ, there is little chance of m for molality being confused with m for meter. Note that bsolute = nsolute msolvent Molality of solute = amount of solute (mol) mass of solvent (kg) xsolute = nsolute nsolute + nsolvent Mole fraction of solute = amount of solute (mol) total amount of solute and solvent (mol) Concentration of solute Precipitates Dissolves Gibbsfreeenergy,G FIGURE 9.25 At low concentrations of solute, dissolving is accompanied by a decrease in Gibbs free energy of the system; so it is spontaneous. At high concentrations, dissolving is accompanied by an increase in Gibbs free energy; so the reverse process, precipitation, is spontaneous. The concentration of a saturated solution corresponds to the state of lowest Gibbs free energy at the temperature of the experiment. The word colligative means “depending on the collection.” 9.14 MOLALITY 353 when we refer to the molality (or molarity) of a specific solute we include its chemical formula. Remember from Section A that units (such as m) are denoted by Roman letters that distinguish them from the physical quantity to which they refer (such as b). Like mole fraction but unlike molarity, the molality is independent of temperature. Note the emphasis on solvent in the definition. To prepare 1 m NiSO4(aq), we dissolve 1 mol NiSO4 in 1 kg of water (Fig. 9.26). FIGURE 9.26 The steps taken to prepare a solution of a given molality. First (left), the required masses of solute and solvent are measured out. Then (right), the solute is dissolved in the solvent. Compare this procedure with that for preparing a solution of given molarity (see Fig. G.8). EXAMPLE 9.5 Calculating the molality of a solute What is the molality of the sugar fructose (C6H12O6) in a solution prepared by dissolving 90.5 g of fructose in 250. g of water? PLAN Convert the mass of fructose into amount of C6H12O6 in moles, express the mass of water in kilograms, and then divide the amount of solute by the mass of solvent. SOLVE 0.502... mol 2.01 mol 1 kg 0.250 kg From bsolute ϭ nsolute(mol)/msolvent(kg) and nsolute ϭ msolute/Msolute, = 2.01 molиkg-1 b(C6H12O6) = (90.5 g)>(180.15 gиmol-1 ) 0.250 kg We report this molality as 2.01 m C6H12O6(aq). Self-Test 9.8A Calculate the molality of ZnCl2 in a solution prepared by dissolving 4.11 g of ZnCl2 in 150. g of water. [Answer: 0.201 molиkgϪ1 ] Self-Test 9.8B Calculate the molality of KClO3 in a solution prepared by dissolving 7.36 g of KClO3 in 200. g of water. TOOLBOX 9.1 HOW TO USE THE MOLALITY CONCEPTUAL BASIS The molality is the concentration of solute in moles per kilogram of solvent. Its value is independent of the temperature and is directly proportional to the relative numbers of solute and solvent molecules in the solution. To convert molarity to molality, we note that the former is defined in terms of the volume of the solution, so we convert that overall volume to the mass of solvent present. PROCEDURE When working with molality it is helpful to keep its definition (bsolute ϭ nsolute͞msolvent) in mind. 1 Calculating the mass of solute in a given mass of solvent from the molality Step 1 Calculate the amount of solute molecules, nsolute, present in a given mass of solvent, msolvent, by rearranging the equation defining molality (Eq. 4) into nsolute ϭ bsolute ϫ msolvent Step 2 Use the molar mass of the solute, Msolute, to find the mass of the solute from its amount: msolute ϭ nsoluteMsolute 2 Calculating the molality from a mole fraction Step 1 Consider a solution composed of a total of 1 mol of molecules. If the mole fraction of the solute is xsolute, the amount of solute molecules in a total of 1 mol of molecules is nsolute ϭ xsolute ϫ ntotal ϭ xsolute ϫ (1 mol) ϭ xsolute mol Step 2 If there is only one solute, the mole fraction of solvent molecules is 1 Ϫ xsolute. The amount of solvent molecules in a total of 1 mol of molecules is then nsolvent ϭ (1 Ϫ xsolute) mol. Convert this amount into mass in grams by using the molar mass of the solvent, Msolvent: msolvent ϭ nsolventMsolvent ϭ {(1 Ϫ xsolute) mol}Msolvent and then convert grams into kilograms. Step 3 Calculate the molality of the solute by dividing the amount of solute molecules (step 1) by the mass of solvent in kilograms (step 2). Example 9.6 shows how to carry out this conversion. 3 Calculating the mole fraction from the molality Step 1 Consider a solution containing exactly 1 kg of solvent. Convert that mass of solvent into an amount 354 CHAPTER 9 PHYSICAL EQUILIBRIA 78.3 g 0.150 mol Solvent Solute Step 3 Calculate the molality of solute from bsolute ϭ nsolute͞msolvent: = 1.92 molиkg-1 b(C6H6) = 0.150 mol 0.850 * 92.13 * 10-3 kg EXAMPLE 9.6 Calculating a molality from a mole fraction What is the molality of benzene, C6H6, dissolved in toluene, C6H5CH3, in a solution for which the mole fraction of benzene is 0.150? PLAN Use procedure 2 in Toolbox 9.1. SOLVE Step 1 Find the amount of solute molecules in a total of exactly 1 mol of solution molecules from nsolute ϭ xsolute ϫ ntotal: nbenzene ϭ 0.150 ϫ 1 mol ϭ 0.150 mol =0.850 mol 92.13 g 1 mol 0.0783 kg SolventStep 2 Find the mass of solvent present from msolvent ϭ{(1 Ϫ xsolute) mol}Msolvent and convert to kilograms: ϭ 0.850 ϫ 92.13 ϫ 10Ϫ3 kg (ϭ 0.0783 kg) mtoluene = (1 - 0.150) mol * (92.13 gиmol-1 ) * 1 kg 103 g of solvent molecules, nsolvent, by using the molar mass, Msolvent, of the solvent: We know the amount of solute molecules, nsolute, in 1 kg of solvent: nsolute ϭ bsolute ϫ (1 kg) Step 2 Calculate the mole fractions from the amounts of solvent and solute molecules: 4 Calculating the molality, given the molarity The conversion is more involved because the molality is defined in terms of the mass of solvent but the molarity is defined in terms of the volume of solution. To carry out the conversion we need to know the density of the solution. Step 1 Calculate the total mass of exactly 1 L (103 mL) of solution by using the density, d, of the solution (not the solvent): msolution ϭ d ϫ (103 mL) Step 2 The molarity, csolute, gives the amount of solute in 1 L of solution. nsolute ϭ csolute ϫ (1 L) Use the molar mass of the solute to convert that amount into the mass of solute present in 1 L of solution: msolute ϭ nsoluteMsolute ϭ csolute ϫ (1 L) ϫ Msolute Step 3 Subtract the mass of solute (step 2) from the total mass (step 1) to find the mass of solvent in 1 L of solution, msolvent ϭ msolution Ϫ msolute and express the mass of solvent in kilograms. Step 4 The molality is the amount of solute in 1 L of solution (given by the molarity) divided by the mass of the solvent in kilograms (step 3). See Example 9.7. xsolute = nsolute nsolute + nsolvent nsolvent = 1 kg Msolvent = 103 g Msolvent Self-Test 9.9A Calculate the molality of toluene dissolved in benzene, given that the mole fraction of toluene is 0.150. The molar mass of benzene is 78.11 g·molϪ1 . [Answer: 2.26 mol·kgϪ1 ] Self-Test 9.9B Calculate the molality of methanol in aqueous solution, given that the mole fraction of methanol is 0.250. 9.14 MOLALITY 355 EXAMPLE 9.7 Converting molarity into molality Find the molality of sucrose, C12H22O11, in 1.06 M C12H22O11(aq), which is known to have density 1.14 gиmLϪ1 . Anticipate The mass of 1 L of aqueous solution is close to 1 kg, so the numerical value of the molality can be expected to be close to that of the molarity, but with different units, of course. SOLVE Use procedure 4 in Toolbox 9.1. 1 L 1.14 kg 1.14 kg 1 L = ϫ Step 1 Find the mass of exactly 1 L (103 mL) of solution from m ϭ d ϫ (103 mL). msolution ϭ (1.14 gиmLϪ1 ) ϫ (103 mL) ϭ 1.14 ϫ 103 g 1 L 1 L 1.06 mol 1 mol 342.3 g 363 g= ϫ ϫ Step 2 Find the mass of solute in exactly 1 L of solution from msolute ϭ nsoluteMsolute ϭ csolute ϫ (1 L) ϫ Msolute. msucrose ϭ (1.06 molиLϪ1 ) ϫ (1 L) ϫ (342.3 gиmolϪ1 ) ϭ 1.06 ϫ 342.3 g ϭ 363 g 1.14 kg Ϫ 0.363 kg 0.78 kg = Step 3 Find the mass of water present in exactly 1 L of solution from mwater ϭ msolution Ϫ msolute. mwater ϭ 1140 Ϫ 363 g ϭ 7.8 ϫ 102 g, or 0.78 kg 0.78 kg 1.06 mol Step 4 From bsolute ϭ nsolute͞msolvent, = 1.4 molиkg-1 b(C12H22O11) = 1.06 mol 0.78 kg Evaluate As expected, the numerical value of the molality of the sucrose, 1.4 (in molиkgϪ1 ), is close to the numerical value of its molarity, 1.06 (in molиLϪ1 ). Self-Test 9.10A Battery acid is 4.27 M H2SO4(aq) and has a density of 1.25 g·cmϪ3 . What is the molality of H2SO4 in the solution? [Answer: 5.14 m H2SO4(aq)] Self-Test 9.10B The density of 1.83 M NaCl(aq) is 1.07 gиcmϪ3 . What is the molality of NaCl in the solution? The molality of a solute in a solution is the amount (in moles) of solute divided by the mass (in kilograms) of solvent used to prepare the solution. 9.15 Vapor-Pressure Lowering The French scientist François-Marie Raoult, who spent much of his life measuring vapor pressures, discovered that the vapor pressure of a solvent is proportional to its mole fraction in a solution. This statement, which is called Raoult’s law, is normally written P ϭ xsolventPpure (4)* where P is the vapor pressure of the solvent in the solution, xsolvent is the mole fraction of the solvent, and Ppure is the vapor pressure of the pure solvent (Fig. 9.27). What does this equation tell us? The vapor pressure of the solvent is directly proportional to the mole fraction of solvent molecules in the solution. For instance, if 9 out of 10 of the molecules present in a solution are solvent molecules, then the vapor pressure of the solvent is nine-tenths the vapor pressure of the pure solvent for the temperature of interest. 356 CHAPTER 9 PHYSICAL EQUILIBRIA Find the amount (in moles) of each species from the molar masses of solute and solvent and n ϭ m/M: (=5.549 mol) Amount of H2O = 100.0 g 18.02 gиmol-1 = 100.0 18.02 mol (=0.02921 mol) Amount of C12H22O12 = 10.00 g 342.3 gиmol-1 = 10.00 342.3 mol 17.45 Torr 17.54 Torr =ϫ Calculate the vapor pressure from P ϭ xsolventPpure and the vapor pressure of pure solvent (Table 9.3): = 17.45 Torr Pwater = 100.0>18.02 10.00>342.3 + 100.0>18.02 * 17.54 Torr EXAMPLE 9.8 Using Raoult’s law Calculate the vapor pressure of water at 20.°C in a solution prepared by dissolving 10.00 g of the nonelectrolyte sucrose, C12H22O11, in 100.0 g of water. Anticipate Expect a lower vapor pressure when the solute is present. However, the vapor pressure is not lowered very much by a solute, so we should expect a value slightly below that of pure water, which Table 9.3 shows is 17.54 Torr at 20.°C. PLAN Calculate the mole fraction of the solvent (water) in the solution and then apply Raoult’s law. To use Raoult’s law, we need the vapor pressure of the pure solvent (Table 9.2 or 9.3). SOLVE Calculate the mole fraction of solvent from xsolvent ϭ nsolvent͞(nsolute ϩ nsolvent): xwater = a 100.0 18.02 b mol a 10.00 342.3 b mol + a 100.0 18.02 b mol (=0.995) Evaluate As expected, the vapor pressure is slightly less than that of pure water. FIGURE 9.27 Raoult’s law predicts that the vapor pressure of a solvent in a solution should be proportional to the mole fraction of the solvent molecules. The horizontal axis shows the mole fraction of the red molecules of substance A in the pure solute, three different solutions, and pure solvent, pictured below the graph. The vapor pressure of pure A is marked as Ppure. The solute in this solution is nonvolatile, so it does not contribute to the vapor pressure. Vaporpressure,P 0 Ppure 0 0.25 0.5 0.75 1.0 Mole fraction of solvent, xA Self-Test 9.11A Calculate the vapor pressure of water at 90.°C for a solution prepared by dissolving 5.00 g of glucose (C6H12O6) in 100. g of water. The vapor pressure of pure water at 90.°C is 524 Torr. [Answer: 521 Torr] Self-Test 9.11B Calculate the vapor pressure of ethanol in kilopascals (kPa) at 19°C for a solution prepared by dissolving 2.00 g of cinnamaldehyde, C9H8O, in 50.0 g of ethanol, C2H5OH. The vapor pressure of pure ethanol at that temperature is 5.3 kPa. A hypothetical solution that obeys Raoult’s law exactly at all concentrations is called an ideal solution. In an ideal solution, the interactions between solute and solvent molecules are the same as the interactions between solvent molecules in the pure state and between solute molecules in the pure state. We could summarize this statement by saying that A–A, B–B, and A–B interactions are all the same in an ideal solution. Consequently, the solute molecules mingle freely with the solvent molecules. That is, for an ideal solution, the enthalpy of solution is zero. Solutes that form nearly ideal solutions are often similar in composition and structure to the solvent molecules. For instance, methylbenzene (toluene), C6H5CH3, forms nearly ideal solutions with benzene, C6H6. Real solutions do not obey Raoult’s law at all concentrations; but the lower the solute concentration, the more closely they resemble ideal solutions. Raoult’s law is another example of a limiting law (Section 4.4), which in this case becomes increasingly valid as the concentration of the solute approaches zero. A solution that does not obey Raoult’s law at a particular solute concentration is called a nonideal solution. Real solutions are approximately ideal at solute concentrations below about 0.1 M for nonelectrolyte solutions and 0.01 M for electrolyte solutions. The greater departure from ideality in electrolyte solutions arises from the interactions between ions, which occur over a long distance and hence have a pronounced effect. Unless stated otherwise, we shall assume that all the solutions that we meet are ideal. Thinking point: Laws are useful summaries of experience; but why are limiting laws useful? The lowering of the vapor pressure of a solvent due to the presence of a solute has a thermodynamic basis. We saw in Section 9.2 that at equilibrium, and in the absence of any solute, the molar Gibbs free energy of the vapor is equal to that of the pure liquid solvent. In an ideal solution, a solute increases the disorder and therefore the entropy of the liquid phase: we can no longer be sure that a molecule picked at random from the solution will be a solvent molecule. Because the entropy of the liquid phase is raised by a solute but the enthalpy is left unchanged, overall there is a decrease in the molar Gibbs free energy of the solvent. At equilibrium, the molar Gibbs free energy of the vapor must equal that of the solvent. Because the Gibbs free energy of the solvent has been lowered, for the two phases to remain in equilibrium it follows that the Gibbs free energy of the vapor must be lower, too. Because the Gibbs free energy of a gas depends on its pressure (recall Fig. 9.4), it follows that the vapor pressure also must be lower. In other words, the vapor pressure of the solvent is lower in the presence of the solute (Fig. 9.28). The vapor pressure of a solvent is reduced by the presence of a nonvolatile solute: in an ideal solution, the vapor pressure of the solvent is proportional to the mole fraction of solvent. 9.15 VAPOR-PRESSURE LOWERING 357 FIGURE 9.28 The vapor pressure of a solvent is lowered by a nonvolatile solute. The barometer tube on the left has a small volume of pure water floating on the mercury. That on the right has a small volume of 10 m NaCl(aq), which has a lower vapor pressure than pure water. Note that the column on the right is depressed less by the vapor in the space above the mercury than the one on the left, showing that the vapor pressure is lower when solute is present. Electrolyte solutions, which have ionic solutes, and nonelectrolyte solutions, which have intact molecular solutes, were introduced in Section I. Remember that G ‫؍‬ H ؊ TS; so if S increases, then G decreases. 9.16 Boiling-Point Elevation and Freezing-Point Depression Because the presence of a nonvolatile solute lowers the vapor pressure of the solvent, the boiling point of the solvent rises. This increase is called boiling-point elevation. The elevation of the boiling point has the same origin as vapor-pressure lowering and is also due to the effect of the solute on the entropy of the solvent. Figure 9.29a shows how the molar Gibbs free energies of the liquid and vapor phases of a pure solvent vary with temperature. We can understand the form of these diagrams by noting the following points based on the relation Gm ϭ Hm Ϫ TSm: • At low temperatures, Gm Hm, and so the line representing Gm of the vapor lies well above that for the liquid because the molar enthalpy of a vapor is considerably greater than that of a liquid. • The slope of the line is determined by the molar entropy Sm. (Remember that the equation of a straight line is y ϭ intercept ϩ slope ϫ x; here x is T, and the slope is ϪSm, a negative, downward, slope.) Because the molar entropy of the vapor is much greater than that of the liquid, the line for the vapor slopes down more sharply than that of the liquid. Above the boiling point, the molar Gibbs free energy of the vapor phase is lower than that of the liquid; therefore, the vapor is the more stable phase. We have already seen that the presence of a solute in the liquid phase of the solvent increases the entropy of the solvent and therefore (through Gm ϭ Hm Ϫ TSm again) lowers its Gibbs free energy. As shown in Fig. 9.29b, the lines representing the molar Gibbs free energies of the liquid solution and the vapor intersect at a higher temperature than they do for the pure solvent, and so the boiling point is higher in the presence of the solute. The increase is usually quite small and is of little practical importance in science. A 0.1 m aqueous sucrose solution, for instance, boils at 100.05°C. Of broader practical significance is freezing-point depression, the lowering of the freezing point of the solvent caused by a solute. For example, seawater freezes about 1°C lower than fresh water. People living in regions with cold winters make use of the depression of the freezing point when they spread salt on icy walkways and roads. The salt lowers the freezing point of water as it produces a salt solution. In the laboratory, chemists make use of the effect to judge the purity of a solid compound: if impurities are present, the compound’s melting point is lower than the accepted value. It is commonly said that antifreeze added to car engines is an example of the lowering of freezing point: it is, but it is not a colligative effect, as the concentration is far too high. It is better to think of the ethylene glycol molecules (HOCH2CH2OH, the common active component) as lying between the water molecules and preventing their linking together to form ice. Figure 9.30a shows how the molar Gibbs free energies of the liquid and solid phases of a pure solvent vary with temperature. The explanation of the layout of the lines is L 358 CHAPTER 9 PHYSICAL EQUILIBRIA Temperature, T Temperature, TMolarGibbsfreeenergy,Gm MolarGibbsfreeenergy,Gm Vapor Pure liquid Vapor Pure liquid Boiling-point elevation Boilingpoint Boilingpoint Solvent Boilingpoint (a) (b) FIGURE 9.29 (a) The molar Gibbs free energy of a liquid and its vapor both decrease with increasing temperature, but that of the vapor decreases more sharply. The vapor is the stable phase at temperatures higher than the point of intersection of the two lines (the boiling point). (b) When a nonvolatile solute is present, the molar Gibbs free energy of the solvent is lowered (an entropy effect), but that of the vapor is left unchanged. The point of intersection of the lines moves to a slightly higher temperature. similar to that for a liquid and its vapor, but the differences in position and slope are less pronounced: • At low temperatures, Gm Hm, and so the line representing Gm of the liquid lies above that for the solid (but not much because the enthalpies are not as different as for a liquid and a vapor). • Because the molar entropy of the liquid is greater than that of the solid, the line for the liquid slopes down more sharply than that of the solid (but not much because the entropies are not as different as for a liquid and a vapor). The solid is the more stable phase below the freezing point, where the molar Gibbs free energy of the solid is lower than that of the liquid. The presence of a solute in the liquid phase of the solvent raises the entropy of the solvent and hence lowers its Gibbs free energy (Fig. 9.30b). However, because the solute is insoluble in the solid solvent, the Gibbs free energy of the solid phase of the solvent is unchanged. The lines representing the molar Gibbs free energies of the liquid and solid phases of the solvent intersect at a lower temperature than they do for the pure solvent, and so the freezing point is lower in the presence of the solute. It is found empirically and can be justified thermodynamically that the freezingpoint depression for an ideal solution is proportional to the molality b of the solute. For a nonelectrolyte solution, Freezing-point depression: ⌬Tf ϭ kf ϫ bsolute (5a) The constant kf is called the freezing-point constant of the solvent; it is different for each solvent and must be determined experimentally (Table 9.8). The effect is quite small: for instance, for a 0.1 m C12H22O11(aq) (sucrose) solution, Freezing-point depression ϭ (1.86 K·kg·mol–1 ) ϫ (0.1 mol·kgϪ1 ) ϭ 0.2 K Hence the water in the solution freezes at Ϫ0.2°C. L 9.16 BOILING-POINT ELEVATION AND FREEZING-POINT DEPRESSION 359 Temperature, T Temperature, T MolarGibbsfreeenergy,Gm MolarGibbsfreeenergy,Gm (a) (b) Pure liquid Solvent Pure liquid Solid Freezingpoint Freezingpoint Freezing-point depression Freezingpoint FIGURE 9.30 (a) The molar Gibbs free energy of a solid and its liquid phase both decrease with increasing temperature, but that of the liquid decreases slightly more steeply. The liquid is the stable phase at temperatures higher than the point of intersection of the two lines. (b) When a solute is present, the molar Gibbs free energy of the solvent is lowered (an entropy effect), but that of the solid is left unchanged. The point of intersection of the lines moves to a lower temperature. TABLE 9.8 Boiling-Point and Freezing-Point Constants Freezing kf Boiling kb Solvent point (°C) (Kؒkgؒmol؊1 ) point (°C) (Kؒkgؒmol؊1 ) acetone Ϫ95.35 2.40 56.2 1.71 benzene 5.5 5.12 80.1 2.53 camphor 179.8 39.7 204 5.61 carbon tetrachloride Ϫ23 29.8 76.5 4.95 cyclohexane 6.5 20.1 80.7 2.79 naphthalene 80.5 6.94 217.7 5.80 phenol 43 7.27 182 3.04 water 0 1.86 100.0 0.51 Self-Test 9.12A Use the data in Table 9.8 to determine at what temperature a 0.20 mol·kg–1 solution of the analgesic codeine, C18H21NO3, in benzene will freeze. [Answer: 4.5°C] Self-Test 9.12B Use the data in Table 9.8 to determine at what temperature a 0.050 mol·kgϪ1 solution of the insecticide malathion, C10H19O6PS2, in camphor will freeze. In an electrolyte solution, each formula unit contributes two or more ions. Sodium chloride, for instance, dissolves to give Naϩ and Cl– ions, and both kinds of ions contribute to the depression of the freezing point. The cations and anions contribute nearly independently in very dilute solutions, and so the total solute molality is twice the molality of NaCl formula units. In place of Eq. 5a we write Freezing-point depression: ⌬Tf ϭ ikf ϫ bsolute (5b)* Here, i, the van ’t Hoff i factor, is determined experimentally. In a very dilute solution (less than about 10Ϫ3 molиLϪ1 ), when all ions are independent, i ϭ 2 for MX salts such as NaCl, i ϭ 3 for MX2 salts such as CaCl2, and so on. For dilute nonelectrolyte solutions, i ϭ 1. The i factor is so unreliable, however, that it is best to confine quantitative calculations of freezing-point depression to nonelectrolyte solutions. Even these solutions must be dilute enough to be approximately ideal. The i factor can be used to help determine the extent to which a substance is dissociated into ions in solution. For example, in dilute solution, HCl has i 1 in toluene and i 2 in water. These values suggest that HCl retains its molecular form in toluene but is fully deprotonated in water (deprotonation, the loss of a proton from an acid, is described in Section J). The strength of a weak acid in water can be estimated in this way. In an aqueous solution of a weak acid that is 5% deprotonated (5% of the acid molecules have given up their protons), each deprotonated molecule produces two ions and i ϭ 0.95 ϩ (0.05 ϫ 2) ϭ 1.05. Because the vapor pressure of a solvent is lowered by the presence of a solute, the elevation of the boiling point of a solvent by a solute can be expressed by an equation similar to Eq. 5b: Boiling-point elevation: ⌬Tb ϭ ikb ϫ bsolute (5c) The values of kb, some of which are listed in Table 9.8, must be determined experimentally. Although it is useful to be aware of the dependence of boiling point on concentration, this equation is rarely used because the effect is so small that it is difficult to measure. Cryoscopy is the determination of the molar mass of a solute by measuring the depression of freezing point that it causes when dissolved in a solvent. Camphor has been used as the solvent for organic compounds because it has a large freezing-point constant; consequently, solutes depress its freezing point significantly. However, this procedure is rarely used in modern laboratories because techniques such as mass spectrometry give far more reliable results (see Major Technique 6, following Chapter 18). The procedure is described in Toolbox 9.2 at the end of Section 9.17. The presence of a solute lowers the freezing point of a solvent; if the solute is nonvolatile, the boiling point is also raised. The freezing-point depression can be used to calculate the molar mass of the solute. If the solute is an electrolyte, the extent of its dissociation or (for an acid) deprotonation must also be taken into account. 9.17 Osmosis Osmosis is the flow of solvent through a membrane into a more concentrated solution. The phenomenon can be demonstrated in the laboratory when a solution and the pure solvent are separated by a semipermeable membrane, a membrane that permits only certain types of molecules or ions to pass through (Fig. 9.31). Cellulose acetate, for instance, allows water molecules to pass through it, but not solute molecules or ions with their bulky coating of hydrating water molecules. Initially, the heights of the solution L L 360 CHAPTER 9 PHYSICAL EQUILIBRIA The name “osmosis” comes from the Greek word for “push.” and the pure solvent shown in the illustration are the same. However, the level of the solution inside the tube begins to rise as pure solvent passes through the membrane into the solution. At equilibrium, the pressure exerted by the higher level of the column of solution is sufficiently great that the rate of flow of molecules through the membrane is the same in each direction, and so the net flow is zero. The pressure needed to stop the flow of solvent is called the osmotic pressure, ⌸ (the Greek uppercase letter pi). The greater the osmotic pressure, the greater the height of the solution needed to reduce the net flow to zero. Life depends on osmosis, which is the most important of all the colligative properties. Biological cell walls act as semipermeable membranes that allow water, small molecules, and hydrated ions to pass (Fig. 9.32). However, they block the passage of the enzymes and proteins that have been synthesized within the cell. The higher concentration of solutes within a cell compared to the solution outside the cell gives rise to an osmotic pressure, and water passes into the more concentrated solution in the interior of the cell, carrying small nutrient molecules with it. This influx of water also keeps the cell turgid (swollen). When the water supply is cut off, the turgidity is lost and the cell becomes dehydrated. In a plant, this dehydration results in wilting. Salted meat is preserved from bacterial attack by osmosis. In this case, the concentrated salt solution dehydrates—and kills—the bacteria by causing water to flow out of them. Because osmosis is a thermodynamic property, we can expect it to be related to the effect of the solute on the enthalpy and entropy of the solution: solvent flows until the molar Gibbs free energy of the solvent is the same on each side of the membrane. We have already seen several times that a solute lowers the molar Gibbs free energy of the solution below that of the pure solvent, and solvent therefore has a tendency to pass into the solution (Fig. 9.33). 9.17 OSMOSIS 361 Semipermeable membrane Solute Solvent FIGURE 9.31 An experiment to illustrate osmosis. Initially, the tube contained a sucrose solution and the beaker contained pure water: the initial heights of the two liquids were the same. At the stage shown here, water has passed into the solution through the membrane by osmosis, and the level of solution in the tube has risen above that of the pure water. The large inset shows the molecules of pure solvent (below the membrane) tending to join those in the solution (above the membrane) because the presence of solute molecules there has led to increased disorder. The small inset shows just the solute molecules; the arrow shows the direction of flow of solvent molecules. (a) (b) (c) FIGURE 9.32 (a) Red blood cells need to be in a solution of the correct solute concentration if they are to function properly. (b) When the solution is very dilute, too much water passes into them and they burst. (c) When the solution is too concentrated, water flows out of them and they shrivel up. The pressure exerted by a vertical column of liquid is proportional to its height: see Eq. 2 in Section 4.2. The same van ’t Hoff responsible for the i factor showed that the osmotic pressure of a dilute solution is related to the molarity, c, of the solute in the solution: ⌸ ϭ iRTcsolute (6)* where i is the i factor (Section 9.16), R is the gas constant, and T is the temperature. This expression is now known as the van ’t Hoff equation. Notice that the osmotic pressure depends only on temperature and the total molar concentration of solute. It is independent of the identities of both the solute and the solvent. However, in an apparatus like that shown in Fig. 9.31, the height to which the solvent is driven does depend on the identity of the solvent, because that height depends on its density (Fig. 9.34). The van ’t Hoff equation is used to determine the molar mass of a solute from osmotic pressure measurements. This technique, which is called osmometry, involves the determination of the osmotic pressure of a solution prepared by making up a known volume of solution having a known mass of solute with an unknown molar mass. If we know the mass of solute in a given volume of solution and have determined the amount of solute in that volume by using the osmotic pressure to determine the molarity, then we can work out the molar mass by dividing the mass by the amount (M ϭ m/n). Osmometry is very sensitive, even at low concentrations, and is commonly used to determine very large molar masses, such as those of polymers. Self-Test 9.13A What is the osmotic pressure of 0.0100 M KCl(aq) at 298 K? (Assume i ϭ 2.) [Answer: 0.489 atm] Self-Test 9.13B What is the osmotic pressure of a 0.120 M sucrose solution at 298 K? 362 CHAPTER 9 PHYSICAL EQUILIBRIA FIGURE 9.33 On the left of the semipermeable membrane is the pure solvent with its characteristic molar enthalpy, entropy, and Gibbs free energy. On the right is the solution. The molar Gibbs free energy of the solvent is lower in the solution (an entropy effect), and so there is a spontaneous tendency for the solvent to flow into the solution. SolutionPure solvent Solutionure solvent Gm Gm TSm TSm Hm Hm FIGURE 9.34 The pressure at the base of a column of fluid is equal to the product of the acceleration of free fall, g, the density, d, of the liquid, and the height, h, of the column. Density, d Pressure = gdh Height, h TOOLBOX 9.2 HOW TO USE COLLIGATIVE PROPERTIES TO DETERMINE MOLAR MASS CONCEPTUAL BASIS The lowering of freezing point and the generation of osmotic pressure both depend on the total concentration of solute particles. Therefore, by using these colligative properties to determine the amount of solute present, and knowing its mass, we can infer its molar mass. PROCEDURE 1 Cryoscopy Step 1 Convert the observed freezing-point depression, ⌬Tf, into solute molality b by writing Eq. 5b in the form Take the freezing-point constant from Table 9.8. Step 2 Calculate the amount of solute, nsolute (in moles), in the sample by multiplying the molality by the mass of solvent, msolvent (in kilograms): nsolute ϭ bsolute ϫ msolvent Step 3 Determine the molar mass of the solute by dividing the given mass of solute, msolute (in grams), by the calculated amount in moles (step 2). This procedure is illustrated in Example 9.9. 2 Osmometry Step 1 Convert the observed osmotic pressure into solute molarity (c, not molality) by writing Eq. 6 in the form In some cases, it may be necessary to calculate the osmotic pressure from the height, h, of the solution (in an apparatus like that in Fig. 9.31) by using ⌸ ϭ gdh, where d is the density of the solution and g is the acceleration of free fall (see inside back cover). Step 2 Because molarity is defined as csolute ϭ nsolute͞V, where nsolute is the amount of solute (in moles) and V is the volume of solution (in liters), calculate the amount of solute from: nsolute ϭ csoluteV Step 3 Determine the molar mass of the solute by dividing the given mass of solute, msolute (in grams), by its amount (step 2), as in the procedure for cryoscopy. This procedure is illustrated in Example 9.10. csolute = iRT Msolute = msolute nsolute bsolute = ¢Tf ikf ⌸ 9.17 OSMOSIS 363 EXAMPLE 9.9 Determining molar mass cryoscopically The addition of 0.24 g of sulfur to 100. g of the solvent carbon tetrachloride lowers the solvent’s freezing point by 0.28°C. Sulfur is known to exist in molecular form. What is the molar mass and molecular formula of sulfur? Anticipate You might already be aware that sulfur forms crownlike S8 molecules. PLAN Use the procedure for cryoscopy in Toolbox 9.2. Sulfur is a nonelectrolyte, so i ϭ 1. SOLVE EXAMPLE 9.10 Using osmometry to determine molar mass The osmotic pressure due to 2.20 g of polyethylene (PE) dissolved in enough benzene to produce 100.0 mL of solution was 1.10 ϫ 10–2 atm at 25°C. Calculate the average molar mass of the polymer, which is a nonelectrolyte. kf Step 1 Assume that i ϭ 1. Then find the molality of solute from bsolute ϭ ⌬T/ikf. = 0.28 29.8 molиkg-1 bsolute = 0.28 K 29.8 Kиkgиmol-1 = 1 kg 9.4 mmol 0.94 mmol 0.100 kg Step 2 Calculate the amount of solute present from nsolute ϭ bsolutemsolvent. = 0.100 * 0.28 29.8 mol n(Sx) = (0.100 kg) * 0.28 29.8 molиkg-1 0.24 g 0.0094 mol Step 3 Determine the molar mass of the solute from Msolute ϭ msolute͞nsolute. = 2.6 * 102 gиmol-1 M(Sx) = 0.24 g (0.100 * 0.28>29.8) mol Use the molar mass of atomic sulfur (32.01 g·mol–1 ) to find the value of x in the molecular formula Sx. = 8.1 x = 2.6 * 102 gиmol-1 32.1 gиmol-1 Evaluate Elemental sulfur is indeed composed of S8 molecules. Self-Test 9.14A When 250. mg of eugenol, the molecular compound responsible for the odor of oil of cloves, was added to 100. g of camphor, it lowered the freezing point of camphor by 0.62°C. Calculate the molar mass of eugenol. [Answer: 1.6 ϫ 102 g·molϪ1 (actual: 164.2 gиmolϪ1 )] Self-Test 9.14B When 200. mg of linalool, a fragrant molecular compound found in cinnamon oil from Sri Lanka, was added to 100. g of camphor, it lowered the freezing point of camphor by 0.51°C. What is the molar mass of linalool? 364 CHAPTER 9 PHYSICAL EQUILIBRIA ⌸ Step 1 From csolute ϭ ⌸/iRT, = 1.10 * 10-2 0.0821 * 298 molиL-1 (= 4.50 * 10-4 molиL-1 ) c = 1.10 * 10-2 atm (0.0821 LиatmиK-1 иmol-1 ) * (298 K) = 0.100 L 45.0 μmol 1 L 0.450 mmol Step 2 Find the amount of solute molecules in the solution from nsolute ϭ csoluteV. = 1.10 * 10-2 * 0.100 0.0821 * 298 mol (=4.50 * 10-5 mol) n(PE) = a 1.10 * 10-2 0.0821 * 298 molиL-1 b * (0.100 L) Anticipate Because so many atoms are linked together in each polymer molecule, we should expect a high molar mass. PLAN Use the procedure for osmometry in Toolbox 9.2. Because polyethylene is a nonelectrolyte, i ϭ 1. Use R in the units that match the data: in this case, liters and atmospheres. SOLVE 45.0 μmol 2.20 g Step 3 Find the molar mass from Msolute ϭ msolute͞nsolute. M(PE) = 2.20 g 1.10 * 10-2 * 0.100 0.0821 * 298 mol = 4.89 * 104 gиmol-1 Evaluate We report this molar mass as 48.9 kg·molϪ1 . As expected, the molar mass is very high. Self-Test 9.15A The osmotic pressure of 3.0 g of polystyrene dissolved in enough benzene to produce 150. mL of solution was 1.21 kPa at 25°C. Calculate the average molar mass of the sample of polystyrene. [Answer: 41 kg·molϪ1 ] Self-Test 9.15B The osmotic pressure of 1.50 g of polymethyl methacrylate dissolved in enough methylbenzene to produce 175 mL of solution was 2.11 kPa at 20°C. Calculate the average molar mass of the sample of polymethyl methacrylate. In reverse osmosis, a pressure greater than the osmotic pressure is applied to the solution side of the semipermeable membrane. This application of pressure increases the rate at which solvent molecules leave the solution and thus reverses the flow of solvent, forcing it to flow from the solution to pure solvent. Reverse osmosis is used to remove salts from seawater to produce fresh water for drinking and irrigation. The water is almost literally squeezed out of the salt solution through the membrane. The technological challenge is to fabricate new membranes that are strong enough to withstand high pressures and do not easily become clogged. Commercial plants use cellulose acetate membranes at pressures as high as 70 atm. Thinking point: Reverse osmosis is energy-intensive. Why? Osmosis is the flow of solvent through a semipermeable membrane into a solution; the osmotic pressure is proportional to the molar concentration of the solute. Osmometry is used to determine the molar masses of compounds with large molecules, such as polymers; reverse osmosis is used in water purification. BINARY LIQUID MIXTURES The following three sections of this chapter examine how the vapor pressure varies with composition when both components of a mixture are volatile and how that information can be used to separate them by distillation. Distillation, which we first encountered in Section G, is used to separate the many compounds that make up petroleum and to purify alternative fuels such as ethanol and methanol. 9.18 The Vapor Pressure of a Binary Liquid Mixture Consider an ideal binary mixture of the volatile liquids A and B. We could think of A as benzene, C6H6, and B as toluene (methylbenzene, C6H5CH3), for example, because these two compounds have similar molecular structures and so form nearly ideal solutions. Because the mixture can be treated as ideal, each component has a vapor pressure given by Raoult’s law: PA ϭ xA(l)PA* PB ϭ xB(l)PB* In these equations, xA(l) is the mole fraction of A in the liquid mixture and PA* is the vapor pressure of pure A; similarly, xB(l) is the mole fraction of B in the liquid and PB* is the vapor pressure of pure B. According to Dalton’s law (Section 4.8), the total pressure of the vapor, P, is the sum of these two partial pressures (Fig. 9.35): P ϭ PA ϩ PB ϭ xA(l)PA* ϩ xB(l)PB* Therefore, we can calculate the vapor pressure of a mixture of two volatile liquids if we know their individual vapor pressures at the temperature of interest and their mole fractions in the mixture. 9.18 THE VAPOR PRESSURE OF A BINARY LIQUID MIXTURE 365 Vaporpressure,P 0 PA,pure PB,pure PB PA P = PA + PB 0 0.25 0.5 0.75 1.0 Mole fraction of A, xA FIGURE 9.35 The vapor pressures of the two components of an ideal binary mixture obey Raoult’s law. The total vapor pressure is the sum of the two partial vapor pressures (Dalton’s law). The small rectangles below the graph represent the mole fraction of A (red squares). EXAMPLE 9.11 Predicting the vapor pressure of a mixture of two liquids What is the vapor pressure of each component at 25°C and the total vapor pressure of a mixture of benzene and toluene in which one-third of the molecules are benzene (so xbenzene(l) ϭ and xtoluene(l) ϭ )? The vapor pressures of benzene and toluene at 25°C are 94.6 and 29.1 Torr, respectively. Anticipate The vapor pressure of the mixture will lie between the values of the pure liquids, closer to the more abundant component, which in this case is toluene. So, we should expect a value between 29 and 95 Torr, but closer to 29 Torr. PLAN Use Raoult’s law to calculate the vapor pressure of each component, then Dalton’s law to calculate the total vapor pressure. SOLVE 2 3 1 3 94.6 29.1 31.5 19.4 Mole fraction of benzene 0 1 Vaporpressure(Torr) Mole fraction of benzene 0 Vaporpressure(Torr) 1 From Dalton’s law, P ϭ PA ϩ PB, Ptotal ϭ 31.5 ϩ 19.4 Torr ϭ 50.9 Torr From Raoult’s law in the form PA ϭ xA(l)PA* and PB ϭ xB(l)PA*, Pbenzene ϭ (94.6 Torr) ϭ 31.5 Torr Ptoluene ϭ (29.1 Torr)2 3 1 3 ϭ 19.4 Torr 366 CHAPTER 9 PHYSICAL EQUILIBRIA HOW DO WE DO THAT? To express the composition of the vapor in equilibrium with the liquid phase of a binary liquid mixture, we first note that the definition of partial pressure (PA ϭ xAP for component A) and Dalton’s law (P ϭ PA ϩ PB) allow us to express the composition of the vapor of a mixture of liquids A and B in terms of the partial pressures of the components: and likewise for xB(g). We can express the vapor pressure of the components and the total vapor pressure in terms of the composition of the liquid (by using Raoult’s law): In the last term we have used xB ϭ 1 Ϫ xA. This expression relates the composition of the vapor (in terms of the mole fraction of A in the vapor) in a binary mixture to the composition of the liquid (in terms of the mole fraction of A in the liquid). It is plotted for benzene and toluene in Fig. 9.36, and we see that xbenzene(g) Ͼ xbenzene(l), just as we anticipated. xA(g) = xA(l)PA* xA(l)PA* + xB(l)PB* = xA(l)PA* xA(l)PA* + (1 - xA(l))PB* xA(g) = PA P = PA PA + PB FIGURE 9.36 The composition of the vapor in equilibrium with a mixture of two volatile liquids (here, benzene and toluene) and its variation with the composition of the liquid. Note that the vapor is richer in the more volatile component (benzene) than the liquid mixture for each composition of the mixture. For instance, when the mole fraction of benzene is 0.333 in the liquid, in the vapor it is 0.619. Molefractioninvapor,xbenzene(g) 0 0.5 1 0.619 Mole fraction in liquid, xbenzene(l) 0 0.5 1 EXAMPLE 9.12 Predicting the composition of the vapor in equilibrium with a binary liquid mixture Find the mole fraction of benzene at 25°C in the vapor of a solution of benzene in toluene in which one-third of the molecules in the liquid are benzene. See Example 9.11 for data. Anticipate Benzene is more volatile than toluene, so we should expect the vapor to be richer in benzene than the liquid is. SOLVE xbenzene,vapor xbenzene,liquid 0 0 1 1From xA(g) ϭ xA(l)PA*͞{xA(l)PA* ϩ (1 – xB(l))PB*}, = 0.619 xbenzene(g) = 0.333 * 94.6 Torr 0.333 * 94.6 Torr + (1 - 0.333) * 29.1 Torr Evaluate As we expected, the vapor pressure of the mixture lies closer to that of toluene than that of benzene. Self-Test 9.16A What is the total vapor pressure at 25°C of a mixture of 3.00 mol C6H6 (benzene) and 2.00 mol C6H5CH3 (toluene)? [Answer: 68.4 Torr] Self-Test 9.16B What is the total vapor pressure at 25°C of a mixture of equal masses of benzene and toluene? The vapor of the mixture is richer than the liquid in the more volatile component (the component with the greater vapor pressure). Benzene, for instance, is more volatile than toluene, and so we can expect that the vapor in equilibrium with the liquid mixture will be richer in benzene than the liquid is. If we could express the composition of the vapor in terms of the composition of the liquid, we could confirm that the vapor is richer than the liquid in the more volatile component. Evaluate As expected, the vapor is richer in benzene than the liquid; in fact, the mole fraction of benzene in the vapor is nearly twice that in the liquid, as shown in Fig. 9.36. Self-Test 9.17A (a) Determine the vapor pressure at 25°C of a solution of toluene in benzene in which the mole fraction of benzene is 0.900. (b) Calculate the mole fractions of benzene and toluene in the vapor. [Answer: (a) 88.0 Torr; (b) 0.967 and 0.033] Self-Test 9.17B (a) Determine the vapor pressure at 25°C of a solution of benzene in toluene in which the mole fraction of benzene is 0.500. (b) Calculate the mole fractions of benzene and toluene in the vapor. The vapor of an ideal mixture of two volatile liquids is richer than the liquid in the more volatile component. The contribution of each component to the total vapor pressure and its mole fraction in the vapor can be calculated by combining Raoult’s law and Dalton’s law. 9.19 Distillation The normal boiling point of a binary liquid mixture is the temperature at which the total vapor pressure is equal to 1 atm. If we were to heat a sample of pure benzene at a constant pressure of 1 atm, it would boil at 80.1°C. Similarly, pure toluene boils at 110.6°C. Because, at a given temperature, the vapor pressure of a mixture of benzene and toluene is intermediate between that of toluene and benzene, the boiling point of the mixture will be intermediate between that of the two pure liquids. In Fig. 9.37, which is called a temperature–composition diagram, the lower curve shows how the normal boiling point of the mixture varies with the composition. The upper curve in Fig. 9.37 shows the composition of the vapor in equilibrium with the liquid mixture at the boiling point: it has been constructed by the same kind of calculation as in Example 9.12. To find the composition of the vapor, we simply look along the tie line, the horizontal line at the boiling point, and see where it cuts through the upper curve. So, if we heat a liquid mixture with the composition given by the vertical line through A in Fig. 9.37 (xbenzene(l) ϭ 0.45) at a constant pressure of 1 atm, the mixture boils at the temperature corresponding to point A. At this temperature, the composition of the vapor in equilibrium with the liquid is given by point B (xbenzene(g) ϭ 0.73). When a mixture of benzene and toluene molecules with xbenzene(l) ϭ 0.20 begins to boil (point A in Fig. 9.38), the initial composition of the vapor formed is given by point B (xbenzene(g) ϭ 0.45). If we were to cool the vapor until it condenses, the first drop of condensed vapor, the distillate, will have the composition of the vapor and is therefore richer in benzene than the original mixture; the liquid remaining in the pot is richer in toluene because some of the benzene has been lost. The separation is not very good: the distillate is still rich in toluene. However, if we take that drop of distillate and reheat it, it will boil at the temperature represented by point C, and the vapor above the boiling solution will have the composition D (xbenzene(g) ϭ 0.73), as indicated by the tie line. Note that the distillate from this second stage of distillation is even richer in benzene than the distillate from the first stage. If we continued these steps of boiling, condensation, and boiling again, we would eventually obtain a very tiny amount of nearly pure benzene. The process called fractional distillation uses a method of continuous redistillation to separate mixtures of liquids with similar boiling points, such as benzene and toluene: the mixture is heated and the rising vapor passes up through a tall column packed with material having a high surface area, such as glass beads (Fig. 9.39). The vapor begins to condense on the beads near the bottom of the column. However, as heating continues, the vapor condenses and vaporizes over and over as it rises; the liquid drips back into the boiling mixture. The vapor becomes richer in the component with the lower boiling point as it continues to rise through the column and passes out into the condenser. For example, in the case of benzene and toluene, the final distillate is nearly pure benzene, the more volatile of the components, whereas the liquid in the pot is nearly pure toluene. 9.19 DISTILLATION 367 Boiling point A BTie line Mole fraction in vapor, xbenzene(g) Mole fraction in liquid, xbenzene(l) 0 80.1 Temperature(°C) 0 0.5 1 110.6 FIGURE 9.37 A temperature–composition diagram for benzene and toluene. The lower, blue curve shows the boiling point of the mixture as a function of composition. Tie lines connected to the upper, orange curve give the composition of the vapor in equilibrium with the liquid at each boiling point. Thus, point B shows the vapor composition for a mixture that boils at point A. FIGURE 9.38 Some of the steps that represent fractional distillation of a mixture of two volatile liquids (benzene and toluene). The original mixture boils at A and its vapor has composition B. After condensation of the vapor, the resulting liquid boils at C and the vapor has composition D, and so on. 0 Mole fraction, xbenzene(l) 80.1 Temperature(°C) A B C D 0 0.5 1 110.6 Mole fraction in vapor Boiling point If the original sample consists of several volatile liquids, the component liquids appear in the distillate in succession in a series of fractions, or samples of the distillate that boil in specific temperature ranges. Giant fractionating columns are used in industry to separate complex mixtures such as crude petroleum (Fig. 9.40). We use the volatile fractions as natural gas (boiling below 0°C), gasoline (boiling in the range from 30°C to 200°C), and kerosene (from 180°C to 325°C). The less volatile fractions are used as diesel fuel (above 275°C). The residue that remains behind after distillation is asphalt, which is used for surfacing highways. Volatile liquids can be separated by fractional distillation. Liquid and vapor are in equilibrium at each point in the fractionating column, but their compositions vary with height. As a result, the lowest-boiling-point component can be removed from the top of the column before the next-higher-boiling-point component distills. 9.20 Azeotropes Most liquid mixtures are not ideal, and so their vapor pressures do not follow Raoult’s law (Fig. 9.41). In these cases, the temperature–composition curves are determined experimentally by analyzing the composition of the vapor (often, after condensing it to a liquid). Deviations from Raoult’s law can be correlated with the enthalpy of mixing, ⌬Hmix, the enthalpy difference between the mixture and the pure components. The enthalpy of mixing of ethanol and benzene is positive—the mixing process is endothermic because the interactions between ethanol and benzene molecules are less favorable than between each type of molecule separately—and this mixture has a vapor pressure higher than that predicted by Raoult’s law (a positive deviation). The enthalpy of mixing of acetone and chloroform is negative—the mixing process is exothermic because the interactions between acetone and chloroform molecules are stronger than those between molecules of chloroform or between molecules of acetone—and this mixture has a vapor pressure lower than that predicted by the law (a negative deviation). 368 CHAPTER 9 PHYSICAL EQUILIBRIA FIGURE 9.39 A schematic illustration of the process of fractional distillation. The temperature in the fractionating column decreases with height. The condensations and reboilings illustrated in Fig. 9.38 occur at increasing heights in the column. The less volatile component returns to the flask beneath the fractionating column, and the more volatile component escapes from the top, to be condensed and collected. Low-boiling-point component High-boiling-point component FIGURE 9.40 The height of this tall fractionating column at an oil refinery helps to achieve a good separation of the components of petroleum. Composition Composition Vaporpressure,P Vaporpressure,P Ethanol Benzene Acetone Chloroform (a) (b) FIGURE 9.41 A graphical illustration of the variation in the vapor pressures of (a) a mixture of ethanol and benzene and (b) a mixture of acetone and chloroform. Note that the mixture in part (a) shows a vapor-pressure maximum and therefore displays a positive deviation from Raoult’s law. The mixture in part (b) shows a minimum and hence displays a negative deviation from Raoult’s law. The enthalpy of mixing is the same as the enthalpy of solution, ⌬Hsol, but ⌬Hmix is used more commonly for the mixing of two liquids. Some deviations from Raoult’s law can make it impossible to separate liquids completely by distillation. The temperature–composition diagrams for mixtures of ethanol and benzene and of acetone and chloroform show why. A positive deviation from Raoult’s law means that the attractive forces between solute and solvent are lower than those between the molecules of the pure components. As a result, the boiling point of the mixture is lower than that predicted by Raoult’s law. For some pairs of components, the boiling point of the mixture is in fact lower than the boiling point of either constituent (Fig. 9.42). A mixture for which the lowest boiling temperature is below that of both pure components is called a minimum-boiling azeotrope, and the components cannot be separated by distillation: in a fractional distillation, a mixture with the azeotropic composition boils over first, not the more volatile pure liquid. The opposite behavior is found for a mixture of acetone in chloroform (Fig. 9.43). This maximum-boiling azeotrope boils at a higher temperature than either constituent and is the last fraction to be collected, not the less volatile of the pure liquids. The reduction in vapor pressure results from the fact that, although neither molecule can form hydrogen bonds in the pure state, the partially positive hydrogen atom in the highly polar chloroform molecule can form a hydrogen bond to the partially negative oxygen atom in the acetone molecule. Solutions in which intermolecular forces are stronger in the solution than in the pure components have negative deviations from Raoult’s law; some form maximumboiling azeotropes. Solutions in which intermolecular forces are weaker in the solution than in the pure components have positive deviations from Raoult’s law; some form minimum-boiling azeotropes. THE IMPACT ON BIOLOGY AND MATERIALS The complexity and versatility of materials made by nature are the envy of scientists. We are only beginning to be able to create materials that have the strong yet porous structure of bone or the strength and flexibility of spider silk (Section 19.13). However, some materials are not strong: they are soft and flexible. These materials, some of which are described in the following two sections, are also important to industry and medicine and some are vital to life. 9.20 AZEOTROPES 369 FIGURE 9.42 The temperature– composition diagram of a minimumboiling azeotrope (such as ethanol and benzene). When this mixture is fractionally distilled, the (more volatile) azeotropic mixture is obtained as the initial distillate. Temperature Ethanol Benzene Composition Vapor composition Boiling point Minimum- boiling azeotrope FIGURE 9.43 The temperature– composition diagram showing a maximum-boiling azeotrope (such as acetone and chloroform). When this mixture is fractionally distilled, the (less volatile) azeotropic mixture is left in the flask. Composition Temperature Boiling point Vapor composition Maximum- boiling azeotrope AcetoneChloroform The name “azeotrope” is formed from Greek words meaning “boiling without change.” 370 CHAPTER 9 PHYSICAL EQUILIBRIA TABLE 9.9 The Classification of Colloids* Dispersed Dispersion Technical phase medium name Examples solid gas aerosol smoke liquid gas aerosol hairspray, mist, fog solid liquid sol or gel printing ink, paint liquid liquid emulsion milk, mayonnaise gas liquid foam fire-extinguisher foam solid solid solid dispersion ruby glass (Au in glass); some alloys liquid solid solid emulsion bituminous road paving; ice cream gas solid solid foam insulating foam *Based on R. J. Hunter, Foundations of Colloid Science, Vol. 1 (Oxford: Oxford University Press, 1987). FIGURE 9.45 A cross section of a liposome, a tiny sac enclosed by a bilayer membrane formed from surfactant-like phospholipid molecules. Animation 9.45 FIGURE 9.44 Laser beams are invisible. However, they can be traced when they pass through smoky or misty environments because the light scatters from the particles suspended in the air. 9.21 Colloids A colloid is a dispersion of large particles (from 1 nm to 1 μm in diameter) in a solvent. Colloidal particles are much larger than most molecules but are too small to be seen with an optical microscope. As a result, colloids have properties between those of a solution and those of a heterogeneous mixture. The small particles give the colloid a homogeneous appearance but are large enough to scatter light. The light scattering explains why milk is white, not transparent, and why searchlight and laser beams are more visible in fog, smoke, and clouds than in clear, dry air (Fig. 9.44). Many foods are colloids, as are clay particles, smoke, and the fluids in living cells. Some self-assembling materials are colloids that form orderly structures spontaneously (see Box 15. 2). Colloids are classified according to the phases of their components (Table 9.9). A colloid that is a suspension of solids in a liquid is called a sol, and a suspension of one liquid in another is called an emulsion. For example, muddy water is a sol in which tiny flakes of clay are dispersed in water; mayonnaise is an emulsion in which small droplets of water are suspended in vegetable oil. Foam is a suspension of a gas in a liquid or solid. Foam rubber, Styrofoam, soapsuds, and aerogels (insulating ceramic foams that have densities nearly as low as that of air) are foams. Zeolites (Section 14.15) are a type of solid foam in which the openings in the solid are comparable in size to molecules. A solid emulsion is a suspension of a liquid or solid phase in a solid. For example, opals are solid emulsions formed when partly hydrated silica fills the interstices between close-packed microspheres of silica aggregates. Gelatin desserts are a type of solid emulsion called a gel, which is soft but holds its shape. Photographic emulsions are gels that also contain solid colloidal particles of light-sensitive materials such as silver bromide. Many liquid crystalline arrays can be considered colloids. Cell membranes form a two-dimensional colloidal structure (Fig. 9.45). Aqueous colloids can be classified as hydrophilic or hydrophobic, depending on the strength of the molecular interactions between the suspended substance and water. Suspensions of fat in water (such as milk) and water in fat (such as mayonnaise and hand lotions) are hydrophobic colloids, because fat molecules have little attraction for water molecules. Gels and puddings are examples of hydrophilic colloids. The macromolecules of the proteins in gelatin and the starch in pudding have many hydrophilic groups that attract water. The giant protein molecules in gelatin uncoil in hot water, and their numerous polar groups form hydrogen bonds with the water. When the mixture cools, the protein chains link together again, but now they have entwined to form a three-dimensional web that encloses many water molecules, as well as molecules of sugar, dye, and flavoring agents. The result is a gel: an open network of protein chains that holds the water in a flexible solid structure. Clusters of metal atoms can form colloidal suspensions. Colloidal clusters of copper, silver, and gold in glass are responsible for some of the vivid colors of stained glass in medieval cathedrals (Fig. 9.46). Even aqueous suspensions of metal clusters are known (Fig. 9.47). FIGURE 9.46 The colors of stained glass are created by incorporating colloidal particles of selected materials into molten glass. 9.22 BIO-BASED AND BIOMIMETIC MATERIALS 371 FIGURE 9.47 The stability of colloids is illustrated by this violet liquid, which is a colloid of metallic gold that has survived since it was prepared by Michael Faraday in 1857. FIGURE 9.48 Hyaluronic acid has the consistency of a soft gel. It absorbs water easily and bonds with the proteins in the skin, making it useful in the repair of wounds and joint injuries. Many precipitates, such as Fe(OH)3, form initially as colloidal suspensions. The tiny particles are kept from settling out by Brownian motion, the motion of small particles resulting from constant bombardment by solvent molecules. The sol is further stabilized by the adsorption of ions on the surfaces of the particles. The ions attract a layer of water molecules that prevents the particles from adhering to one another. Colloids are suspensions of particles typically too small to be seen with a microscope but large enough to scatter light. 9.22 Bio-based and Biomimetic Materials Bio-based materials are materials that are taken from or made from natural materials in living things. Examples include packing pellets made from corn and soybeans, polylactic acid (a polymer used to make plastic packaging), and various kinds of pharmaceuticals. One example of a colloidal bio-based pharmaceutical material is hyaluronic acid (5). This compound occurs naturally in the body, where it is a major component of the fluid that lubricates joints and plays an important role in the repair of tissues, especially in the skin. Because the molecules of hyaluronic acid contain many ßOH groups, it can form hydrogen bonds to water and form a colloid. As a result, as it moves through the body large numbers of water molecules move with it. 5 Hyaluronic acid O CH3 n − 1 OH O O OH OH COOH OH O O HN CH2OH O O OH COOH OH O OH HN CH2OH O CH3 OH This property makes it useful in regions of the body that require lubrication, such as joints, and in the healing of wounds and connective tissue (Fig. 9.48). Hyaluronic acid is widely used in sports medicine to heal joint injuries by reducing inflammation. Because hyaluronic acid is easily metabolized in the stomach, it must be injected into the region where it is needed. Biomimetic materials are materials that are modeled after naturally occurring materials. Gels or flexible polymers (Chapter 19) modeled after natural membranes and tissues are biomimetic materials with remarkable properties. Some can be made to crawl on their own like tiny nanometer worms, others pulsate to an internally generated rhythm, and still others respond in seemingly lifelike ways to stimuli. Controlled-release drug delivery systems can be made from liquid crystals (Section 5.15). Surfactant compounds called phospholipids are found in fats and form the membranes of living cells. These molecules are liquid crystals similar to detergent molecules (Section 9.9). The membranes of living cells are double layers of phospholipid molecules that line up with their hydrocarbon tails pointing into the membrane and their polar head groups forming the membrane surface. This structure separates the contents of the cell from the intercellular fluid. It is possible to coax phospholipids to form artificial membranes that close up to form tiny bags, called liposomes, which are much smaller than living cells (see Fig. 9.45). If the liposomes are formed in a solution containing a drug, some drug molecules become encapsulated. This behavior has led to the study of liposomes as a way of delivering drugs into different organs and regions of the body (Box 9.1). Biomimetic materials are modeled after naturally occurring biological materials. 372 CHAPTER 9 PHYSICAL EQUILIBRIA The administration of drugs to ease disease and chronic, severe pain or to provide benefits such as hormone replacement therapy is difficult because drugs taken orally may lose much of their potency in the harsh conditions of the digestive system. In addition, they are distributed throughout the entire body, not just where they are needed, and side effects can be significant. Recently, however, techniques have been developed to deliver drugs gradually over time, to the exact location in the body where they are needed, and even at the time when they are needed. Transdermal patches are applied to the skin. The drug is mixed with the adhesive for the patch, and so it lies next to the skin. The skin can readily absorb many chemicals and so can absorb drugs such as nitroglycerin (for heart disease), morphine derivatives (for constant, severe pain), estrogen (for hormone FRONTIERS OF CHEMISTRY: DRUG DELIVERYBOX 9.1 ❑ 1 Use the Clausius–Clapeyron equation to estimate the vapor pressure or boiling point of a liquid (Examples 9.1 and 9.2). ❑ 2 Interpret a one-component phase diagram (Example 9.3). ❑ 3 Predict relative solubilities from molecular polarity (Section 9.9). ❑ 4 Use Henry’s law to calculate the solubility of a gas (Example 9.4). ❑ 5 Interpret enthalpies of solution in terms of lattice enthalpies and enthalpies of hydration (Section 9.12). ❑ 6 Calculate the molality of a solute (Example 9.5). ❑ 7 Convert between molality and mole fraction or molarity (Toolbox 9.1 and Examples 9.6 and 9.7). ❑ 8 Calculate the vapor pressure of a solvent in a solution by using Raoult’s law (Example 9.8). ❑ 9 Determine molar mass cryoscopically (Toolbox 9.2 and Example 9.9). ❑ 10 Use osmometry to find the molar mass of a solute (Toolbox 9.2 and Example 9.10). ❑ 11 Calculate the vapor pressure and vapor composition for a solution of two liquids (Examples 9.11 and 9.12). ❑ 12 Interpret a two-component phase diagram and discuss fractional distillation (Sections 9.18, 9.19, and 9.20). ❑ 13 Identify colloids and explain their properties (Section 9.21). ❑ 14 Describe the structure of cell membranes (Section 9.22). SKILLS YOU SHOULD HAVE MASTERED Examples of implants used to insert living cells into the body. The cells continually produce enzymes, hormones, or painkillers needed by the body. Often a long, thin plastic tail is attached as a tether to allow easy retrieval of the implant. replacement therapy), or nicotine (for easing symptoms that result when a patient stops smoking). Implants provide a means of delivering drugs over a longer period of time at a controlled rate inside the body. Subcutaneous (under the skin) implants are used to provide appropriate doses of psychoactive medications, birth-control drugs, painkillers, and other medications that must be administered frequently. The implants last for as long as a month and can be easily replaced or renewed. When the location of the drug release is critical, implants can be placed deeper into the body. For example, implants can be introduced into the brain or spinal column to provide effective relief from pain or to protect neurons from degeneration. The implant is contained inside a cylinder of porous foam through which the drug is released. Some implants contain living animal cells that have been engineered to produce natural hormones or painkillers that are released to the body as they are produced. In other types of implants, membranes allow a gradual release of the drug. Controlled-release drug delivery systems mimic nature. Molecules called lipids are found in fats and also form the membranes of living cells. A lipid molecule is similar in structure to the surfactant molecules in detergents: it has a polar head and a nonpolar hydrocarbon tail. Some lipids assemble themselves spontaneously into liquid crystal structures in water (Section 9.22); in these structures, sheets consisting of rows of molecules are lined up next to one another. The sheets can be coaxed into forming liposomes (see Fig. 9.45). Liposomes are similar to micelles but are formed from a double layer of molecules, with polar heads forming each surface, like the membrane of a living cell. When a drug is present in the aqueous solution in which liposomes are being formed, some of the drug is encapsulated inside each liposome, which becomes a tiny container for the drug. The liposomes can then be injected into the body, where they stick only to certain types of cells—cancer cells, for instance. Compared with oral or intravenous medicine, a smaller dosage is required and side effects are greatly reduced. EXERCISES 373 Nanotechnology has led to very efficient versions of liposomes. Tiny hollow spheres only nanometers in diameter hold even tinier capsules of medicine. The spheres are made of silica covered with gold nanoparticles and when they are coated with antibodies they attach to tumor cells. The spheres are sensitive to light of specific wavelengths and when the light is applied, they either heat up and destroy the tumor, or burst, releasing the drugs within the capsules directly into the tumor. Phases and Phase Transitions 9.1 Suppose you were to collect 1.0 L of air by passing it slowly through water at 20.°C and into a container. Estimate the mass of water vapor in the collected air, assuming that the air is saturated with it. 9.2 A bottle of mercury at 25°C was left unstoppered in a chemical supply room measuring 3.0 m by 3.0 m by 2.5 m. What mass of mercury vapor would be present if the air became saturated with it? The vapor pressure of mercury at 25°C is 0.227 Pa. 9.3 Use the vapor-pressure curve in Fig. 9.3 to estimate the boiling point of water when the atmospheric pressure is (a) 60. kPa; (b) 160. kPa. 9.4 Use the vapor-pressure curve in Fig. 9.3 to estimate the boiling point of benzene when the atmospheric pressure is (a) 50. kPa; (b) 80. kPa. 9.5 The vapor pressure of boron trichloride at Ϫ28°C is 17.0 kPa and its enthalpy of vaporization is 23.77 kJиmolϪ1 . What is the boiling point of boron trichloride? 9.6 The vapor pressure of dimethyl ether at –58°C is 18.1 kPa and its enthalpy of vaporization is 21.51 kJиmolϪ1 . What is the boiling point of dimethyl ether? 9.7 Arsine, AsH3, is a highly toxic compound used in the electronics industry for the production of semiconductors. Its vapor pressure is 35 Torr at Ϫ111.95°C and 253 Torr at Ϫ83.6°C. EXERCISES An electron microscope image of a drug capsule as it bursts open, revealing the tiny microcapsules inside. The image has been digitally colored. Smart gels (see Box 15.2) are being investigated for drug delivery in situations in which the drug dosage must be modified according to conditions in the body. For example, the amount of insulin that a nondiabetic person needs is delivered by the body according to the level of blood sugar. However, a diabetic person must take insulin at specified times of the day and the same amount each time. If the blood sugar is already low, a hypoglycemic reaction, and possibly coma, can result. An insulin delivery system that would be responsive to blood sugar levels and provide the correct dosage when it is needed is now being investigated. The system makes use of a smart gel in which molecules of insulin have been trapped. The gel incorporates into its structure molecules of phenylboronic acid, to which glucose (blood sugar) molecules are attracted. If the blood sugar is high, more and more glucose molecules stick to the gel and cause it to swell. When the level of glucose rises above a certain concentration, the gel swells so much that it becomes porous, releasing insulin into the blood. HOW MIGHT YOU CONTRIBUTE? Both basic and applied research are needed for effective drug delivery systems. Basic research on the self-assembly of molecules may allow more innovative solutions in the future. Applied research may have more immediate benefits. For example, the optimal drug delivery system must be designed for each specific drug. Coatings for implants or nanospheres that are nontoxic and are similar in nature to body tissues need to be developed. Both the length of time during which a drug delivery system can remain active inside the body and the stability of the system need to be increased. Related Exercise: 9.121 For Further Reading: C. M. Henry, “Special delivery,” Chemical and Engineering News (September 18, 2000), pp. 49–64. M. J. Lysaght and P. Aebischer, “Encapsulated cells as therapy,” Scientific American (April 1999), pp. 76–82. S. Morrissey, “Nanotech meets medicine,” Chemical and Engineering News (May 16, 2005), p. 30. ? This implant containing live hamster cells was inserted into the spinal column of a patient for 17 weeks. After removal, the cells were still alive and secreting the hormone required to keep the patient healthy. Using these data, calculate (a) the standard enthalpy of vaporization; (b) the standard entropy of vaporization; (c) the standard Gibbs free energy of vaporization; (d) the normal boiling point of arsine. 9.8 The vapor pressure of chlorine dioxide, ClO2, is 155 Torr at Ϫ22.75°C and 485 Torr at 0.00°C. Calculate (a) the standard enthalpy of vaporization; (b) the standard entropy of vaporization; (c) the standard Gibbs free energy of vaporization; (d) the normal boiling point of ClO2. 9.9 The normal boiling point of iodomethane, CH3I, is 42.43°C, and its vapor pressure at 0.00°C is 140. Torr. Calculate (a) the standard enthalpy of vaporization of iodomethane; (b) the standard entropy of vaporization of iodomethane; (c) the vapor pressure of iodomethane at 25.0°C. 9.10 The normal boiling point of trimethylphosphine, P(CH3)3, is 38.4°C, and its vapor pressure at Ϫ45.21°C is 13 Torr. Calculate (a) the standard enthalpy of vaporization of trimethylphosphine; (b) the standard entropy of vaporization of trimethylphosphine; (c) the vapor pressure of trimethylphosphine at 15.0°C. 9.11 Use data from Table 7.3 to calculate the vapor pressure of methanol at 25.0°C. 9.12 Use data from Table 7.3 to calculate the vapor pressure of ammonia at 235 K. 9.13 Use Fig. 9.6 to predict the state of a sample of water under the following conditions: (a) 1 atm, 200.°C; (b) 100. atm, 50.0.°C; (c) 3 Torr, 10.0°C. 9.14 Use Fig. 9.7 to predict the state of a sample of CO2 under the following conditions: (a) 6 atm, –80.°C; (b) 1 atm, Ϫ56°C; (c) 80. atm, 25°C; (c) 5.1 atm, Ϫ56°C. 9.15 The phase diagram for helium is shown here. (a) What is the maximum temperature at which superfluid helium-II can exist? (b) What is the minimum pressure at which solid helium can exist? (c) What is the normal boiling point of helium-I? (d) Can solid helium sublime? 9.16 The phase diagram for carbon, shown here, indicates the extreme conditions that are needed to form diamonds from graphite. (a) At 2000 K, what is the minimum pressure needed before graphite changes into diamond? (b) What is the minimum temperature at which liquid carbon can exist at pressures below 10 000 atm? (c) At what pressure does graphite melt at 3000 K? (d) Are diamonds stable under normal conditions? If not, why is it that people can wear them without having to keep them under high pressure? 9.17 Use the phase diagram for helium in Exercise 9.15 (a) to describe the phases in equilibrium at each of helium’s two triple points; (b) to decide which liquid phase is the more dense, helium-I or helium-II. 9.18 Use the phase diagram for carbon in Exercise 9.16 (a) to describe the phase transitions that carbon would undergo if compressed at a constant temperature of 2000 K from 100 atm to 1 ϫ 106 atm; (b) to rank the diamond, graphite, and liquid phases of carbon in order of increasing density. 9.19 Use the phase diagram for carbon dioxide (Fig. 9.7) to predict what would happen to a sample of carbon dioxide gas at –50°C and 1 atm if its pressure were suddenly increased to 73 atm at constant temperature. What would be the final physical state of the carbon dioxide? 9.20 A new substance developed in a laboratory has the following properties: normal melting point, 83.7°C; normal boiling point, 177°C; triple point, 200. Torr and 38.6°C. (a) Sketch the approximate phase diagram and label the solid, liquid, and gaseous phases and the solid–liquid, liquid–gas, and solid–gas phase boundaries. (b) Sketch an approximate heating curve for a sample at constant pressure, beginning at 500. Torr and 25°C and ending at 200.°C. Solubility 9.21 Which would be the better solvent, water or benzene, for each of the following substances: (a) KCl; (b) CCl4; (c) CH3COOH? 9.22 Which would be the better solvent, water or tetrachloromethane, for each of the following substances: (a) NH3; (b) HNO3; (c) N2? 9.23 The following groups are found in some organic molecules. Which are hydrophilic and which are hydrophobic: (a) ßNH2; (b) ßCH3; (c) ßBr; (d) ßCOOH? 9.24 The following groups are found in some organic molecules. Which are hydrophilic and which are hydrophobic: (a) ßOH; (b) ßCH2CH3; (c) ßCONH2; (d) ßCl? 9.25 State the molar solubility in water of (a) O2 at 50. kPa; (b) CO2 at 500. Torr; (c) CO2 at 0.10 atm. The temperature in each case is 20.°C, and the pressures are partial pressures of the gases. Use the information in Table 9.5. 9.26 Calculate the solubility in water (in milligrams per liter) of (a) air at 0.80 atm; (b) He at 0.80 atm; (c) He at 36 kPa. The temperature is 20.°C in each case, and the pressures are partial pressures of the gases. Use the information in Table 9.5. 0 1000 2000 3000 4000 5000 Temperature (K) 0 5 10 15 20 25 30 Pressure(GPa) Diamond Graphite Liquid 10 000 atm 100 10 1 0.1 0.01 1 2 3 4 5 6 Temperature (K) Pressure(atm) Solid Liquid (helium-I) Liquid (helium-II) Gas 374 CHAPTER 9 PHYSICAL EQUILIBRIA 9.27 The minimum mass concentration of oxygen required for fish life is 4 mg·L–1 . (a) Assume the density of lake water to be 1.00 g·mL–1 , and express this concentration in parts per million (which is equivalent to milligrams of O2 per kilogram of water, mg·kg–1 . (b) What is the minimum partial pressure of O2 that would supply the minimum mass concentration of oxygen in water to support fish life at 20.°C? (c) What is the minimum atmospheric pressure that would give this partial pressure, assuming that oxygen exerts about 21% of the atmospheric pressure? See Table 9.5. 9.28 The volume of blood in the body of a certain deep-sea diver is about 6.00 L. Blood cells make up about 55% of the blood volume, and the remaining 45% is the aqueous solution called plasma. What is the maximum volume of nitrogen measured at 1.00 atm and 37°C that could dissolve in the diver’s blood plasma at a depth of 93 m, where the pressure is 10.0 atm? (This is the volume that could come out of solution suddenly, causing the painful and dangerous condition called the bends, if the diver were to ascend too quickly.) Assume that Henry’s constant for nitrogen at 37°C (body temperature) is 5.8 ϫ 10–4 mol·L–1 ·atm–1 . 9.29 The carbon dioxide gas dissolved in a sample of water in a partly filled, sealed container has reached equilibrium with its partial pressure in the air above the solution. Explain what happens to the solubility of the CO2 if (a) the partial pressure of the CO2 gas is doubled by the addition of more CO2; (b) the total pressure of the gas above the liquid is doubled by the addition of nitrogen. 9.30 Explain what happens to the solubility of the CO2 in Exercise 9.29 if (a) the partial pressure of CO2(g) is increased by compressing the gas to a third of its original volume; (b) the temperature is raised. 9.31 A soft drink is made by dissolving CO2 gas at 3.60 atm in a flavored solution and sealing the solution in aluminum cans at 20.°C. What amount of CO2 is contained in a 420-mL can of the soft drink? At 20.°C the Henry’s law constant for CO2 is 2.3 ϫ 10–2 mol·L–1 ·atm–1 . 9.32 A soft drink is made by dissolving CO2 gas at 4.00 atm in a flavored solution and sealing the solution in aluminum cans at 20.°C. What amount (in moles) of CO2 is contained in a 360.-mL can of the soft drink? At 20.°C the Henry’s law constant for CO2 is 2.3 ϫ 10–2 mol·L–1 ·atm–1 . 9.33 Lithium sulfate dissolves exothermically in water. (a) Is the enthalpy of solution for Li2SO4 positive or negative? (b) Write the chemical equation for the dissolving process. (c) Which is larger for lithium sulfate, the lattice enthalpy or the enthalpy of hydration? 9.34 The enthalpy of solution of ammonium nitrate in water is positive. (a) Does NH4NO3 dissolve endothermically or exothermically? (b) Write the chemical equation for the dissolving process. (c) Which is larger for NH4NO3, the lattice enthalpy or the enthalpy of hydration? 9.35 Calculate the heat evolved or absorbed when 10.0 g of (a) NaCl; (b) NaI; (c) AlCl3; (d) NH4NO3 is dissolved in 100. g of water. Assume that the enthalpies of solution in Table 9.6 are applicable and that the specific heat capacity of the solution is 4.18 J·K–1 ·g–1 . 9.36 Determine the temperature change when 10.0 g of (a) KCl; (b) MgBr2; (c) KNO3; (d) NaOH is dissolved in 100. g of water. Assume that the specific heat capacity of the solution is 4.18 J·K–1 ·g–1 and that the enthalpies of solution in Table 9.6 are applicable. Colligative Properties 9.37 Calculate (a) the molality of sodium chloride in a solution prepared by dissolving 25.0 g of NaCl in 500.0 g of water; (b) the mass (in grams) of NaOH that must be mixed with 345 g of water to prepare 0.18 m NaOH(aq); (c) the molality of urea, CO(NH2)2, in a solution prepared by dissolving 0.978 g of urea in 285 mL of water. 9.38 Calculate (a) the molality of KOH in a solution prepared from 4.25 g of KOH and 55.0 g of water; (b) the mass (in grams) of ethylene glycol, HOC2H4OH, that should be added to 0.85 kg of water to prepare 0.35 m HOC2H4OH(aq); (c) the molality of an aqueous 4.12% by mass HCl solution. 9.39 A 5.00% by mass K3PO4 aqueous solution has a density of 1.043 gиcm–3 . Determine (a) the molality; (b) the molarity of potassium phosphate in the solution. 9.40 Calculate the concentrations of each of the following solutions: (a) the molality of 13.63 g of sucrose, C12H22O11, dissolved in 612 mL of water; (b) the molality of CsCl in a 10.00% by mass aqueous solution; (c) the molality of acetone in an aqueous solution with a mole fraction for acetone of 0.197. 9.41 Calculate the concentrations of each of the following solutions: (a) the molality of chloride ions in an aqueous solution of magnesium chloride in which is 0.0120; (b) the molality of 6.75 g of sodium hydroxide dissolved in 325 g of water; (c) the molality of 15.00 M HCl(aq) with a density of 1.0745 g·cm–3 . 9.42 Calculate the concentrations of each of the following solutions: (a) the molality of chloride ions in an aqueous solution of iron(III) chloride for which is 0.0312; (b) the molality of hydroxide ions in a solution prepared from 3.24 g of barium hydroxide dissolved in 258 g of water.; (c) the molality of 12.00 M NH3(aq) with a density of 0.9519 g·cm–3 . 9.43 (a) Calculate the mass of CaCl2·6H2O needed to prepare 0.125 m CaCl2(aq) by using 500. g of water. (b) What mass of NiSO4·6H2O must be dissolved in 500. g of water to produce 0.22 m NiSO4(aq)? 9.44 A 10.0% by mass H2SO4(aq) solution has a density of 1.07 g·cm–3 . (a) How many milliliters of solution contain 8.37 g of H2SO4? (b) What is the molality of H2SO4 in solution? (c) What mass (in grams) of H2SO4 is in 250. mL of solution? 9.45 Two beakers, one containing 0.010 m NaCl (aq) and the other containing pure water, are placed inside a bell jar and sealed. The beakers are left until the water vapor has come to equilibrium with any liquid in the container. The levels of the liquid in each beaker at the beginning of the experiment are the same, as pictured below. Draw the levels of the liquid in each beaker after equilibrium has been reached. Explain your reasoning. 0.010 m NaCl(aq) Water xFeCl3 xMgCl2 EXERCISES 375 9.46 Two beakers, one containing 0.010 m NaCl(aq) and the other containing 0.010 m AlCl3(aq), are placed inside a bell jar and sealed. The beakers are left until the water vapor has come to equilibrium with any liquid in the container. The levels of the liquid in each beaker at the beginning of the experiment are the same, as pictured below. Draw the levels of the liquid in each beaker after equilibrium has been reached. Explain your reasoning. 9.47 Calculate the vapor pressure of the solvent in each of the following solutions. Use Table 9.3 to find the vapor pressure of water in (a) an aqueous solution at 100.°C in which the mole fraction of sucrose is 0.100; (b) an aqueous solution at 100.°C in which the molality of sucrose is 0.100 mol·kg–1 . 9.48 What is the vapor pressure of the solvent in each of the following solutions: (a) the mole fraction of glucose is 0.050 in an aqueous solution at 80.°C; (b) an aqueous solution at 25°C is 0.10 m urea, CO(NH2)2, a nonelectrolyte? Use the data in Table 9.3 for the vapor pressure of water at various temperatures. 9.49 Benzene, C6H6, has a vapor pressure of 94.6 Torr at 25°C. A nonvolatile compound was added to 0.300 mol C6H6(l) at 25°C and the vapor pressure of the benzene in the solution decreased to 75.0 Torr. What amount (in moles) of solute molecules was added to the benzene? 9.50 Benzene has a vapor pressure of 100.0 Torr at 26°C. A nonvolatile compound was added to 0.300 mol C6H6(l) at 26°C and the vapor pressure of the benzene in the solution decreased to 60.0 Torr. What amount (in moles) of solute molecules were added to the benzene? 9.51 When 8.05 g of an unknown compound X was dissolved in 100. g of benzene, the vapor pressure of the benzene decreased from 100.0 Torr to 94.8 Torr at 26°C. What is (a) the mole fraction and (b) the molar mass of X? 9.52 The normal boiling point of ethanol is 78.4°C. When 9.15 g of a soluble nonelectrolyte was dissolved in 100. g of ethanol, the vapor pressure of the solution at that temperature was 7.40 ϫ 102 Torr. (a) What are the mole fractions of ethanol and solute? (b) What is the molar mass of the solute? 9.53 (a) What is the normal boiling point of an aqueous solution that has a vapor pressure of 751 Torr at 100.°C? (b) Determine the normal boiling point of a benzene solution that has a vapor pressure of 740. Torr at 80.1°C, the normal boiling point of pure benzene. 9.54 (a) What is the normal boiling point of an aqueous solution that has a freezing point of –1.04°C? (b) The freezing point of a benzene solution is 2.0°C. The normal freezing point of benzene is 5.5°C. What is the expected normal boiling point of the solution? The normal boiling point of benzene is 80.1°C. 9.55 A 1.14-g sample of a molecular substance dissolved in 100. g of camphor freezes at 176.9°C. What is the molar mass of the substance? 9.56 When 1.32 g of a nonpolar solute was dissolved in 50.0 g of phenol, the latter’s freezing point was lowered by 1.454°C. Calculate the molar mass of the solute. 9.57 A 1.00% by mass NaCl(aq) solution has a freezing point of –0.593°C. (a) Estimate the van ’t Hoff i factor from the data. (b) Determine the total molality of all solute species. (c) Calculate the percentage dissociation of NaCl in this solution. (The molality calculated from the freezing-point depression is the sum of the molalities of the undissociated ion pairs, the Na+ ions, and the Cl– ions.) 9.58 A 1.00% by mass MgSO4(aq) solution has a freezing point of –0.192°C. (a) Estimate the van ’t Hoff i factor from the data. (b) Determine the total molality of all solute species. (c) Calculate the percentage dissociation of MgSO4 in this solution. 9.59 Two unknown molecular compounds were being studied. A solution containing 5.00 g of compound A in 100. g of water froze at a lower temperature than a solution containing 5.00 g of compound B in 100. g of water. Which compound has the greater molar mass? Explain how you decided your answer. 9.60 Two unknown compounds were being studied. Compound C is molecular and compound D is known to ionize completely in dilute aqueous solutions. A solution containing 0.30 g of compound C in 100. g of water froze at the same temperature as a solution containing 0.30 g of compound D in 100. g of water. Which compound has the greater molar mass? Explain how you decided your answer. 9.61 Determine the freezing point of a 0.10 mol·kg–1 aqueous solution of a weak electrolyte that is 7.5% dissociated into two ions. 9.62 A 0.124 m CCl3COOH(aq) solution has a freezing point of Ϫ0.423°C. What is the percentage deprotonation of the acid? 9.63 What is the osmotic pressure at 20.°C of (a) 0.010 M C12H22O11(aq); (b) 1.0 M HCl(aq); (c) 0.010 M CaCl2(aq)? Assume complete dissociation of the CaCl2. 9.64 Which of the following solutions has the highest osmotic pressure at 50.°C: (a) 0.10 M KCl(aq); (b) 0.60 M CO(NH2)2(aq); (c) 0.30 M K2SO4(aq)? Justify your answer by calculating the osmotic pressure of each solution. 9.65 An aqueous solution of the sugar mannitol (C6H12O6) with a concentration of 180 mg mL–1 is commonly used in veterinary medicine as an osmotic diuretic, which helps to remove water from living cells by osmosis. (a) What is the molarity of mannitol in the solution? (b) What is the osmotic pressure of the solution at 25°C? 9.66 A dextrose/saline aqueous solution doctors commonly use to replace fluids in the body contains 1.75 gиLϪ1 NaCl and 40.0 gиLϪ1 dextrose (C6H12O6). (a) What is the molarity of all solutes in this solution? (b) What is the osmotic pressure of the solution at 25°C? Assume total dissociation of the NaCl. 9.67 A 0.40-g sample of a polypeptide dissolved in 1.0 L of an aqueous solution at 27°C gave rise to an osmotic pressure of 3.74 Torr. What is the molar mass of the polypeptide? 9.68 When 0.10 g of insulin is dissolved in 0.200 L of water, the osmotic pressure is 2.30 Torr at 20.°C. What is the molar mass of insulin? 9.69 A 0.20-g sample of a polymer, dissolved in 0.100 L of toluene, has an osmotic pressure of 6.3 Torr at 20.°C. What is the molar mass of the polymer? ? 0.010 m NaCl(aq) 0.010 m AlCl3(aq) 376 CHAPTER 9 PHYSICAL EQUILIBRIA 9.70 A solution prepared by adding 0.50 g of a polymer to 0.200 L of toluene (methylbenzene, a common solvent) showed an osmotic pressure of 0.582 Torr at 20.°C. What is the molar mass of the polymer? 9.71 Calculate the osmotic pressure at 20.°C of each of the following solutions; assume complete dissociation for any ionic solutes: (a) 0.050 M C12H22O11(aq); (b) 0.0010 M NaCl(aq); (c) a saturated aqueous solution of AgCN of solubility 23 μg/100. g of water. 9.72 Calculate the osmotic pressure at 20°C of each of the following solutions; assume complete dissociation of ionic compounds: (a) 3.0 ϫ 10–3 M C6H12O6(aq); (b) 2.0 ϫ 10–3 M CaCl2(aq); (c) 0.010 M K2SO4(aq). 9.73 Catalase, a liver enzyme, dissolves in water. A 10.0-mL solution containing 0.166 g of catalase exhibits an osmotic pressure of 1.2 Torr at 20.°C. What is the molar mass of catalase? 9.74 Intravenous medications are often administered in 5.0% glucose, C6H12O6(aq), by mass. What is the osmotic pressure of such solutions at 37°C (body temperature)? Assume that the density of the solution is 1.0 g·mL–1 . Binary Liquid Mixtures 9.75 Benzene, C6H6, and toluene, C6H5CH3, form an ideal solution. The vapor pressure of benzene is 94.6 Torr and that of toluene is 29.1 Torr at 25°C. Calculate the vapor pressure of each of the following solutions and the mole fraction of each substance in the vapor phase above those solutions at 25°C: (a) 1.50 mol C6H6 mixed with 0.50 mol C6H5CH3; (b) 15.0 g of benzene mixed with 64.3 g of toluene. 9.76 Hexane, C6H14, and cyclohexane, C6H12, form an ideal solution. The vapor pressure of hexane is 151 Torr and that of cyclohexane is 98 Torr at 25.0°C. Calculate the vapor pressure of each of the following solutions and the mole fraction of each substance in the vapor phase above those solutions at 25°C: (a) 0.25 mol C6H14 mixed with 0.65 mol C6H12; (b) 10.0 g of hexane mixed with 10.0 g of cyclohexane. 9.77 1,1-Dichloroethane,CH3CHCl2,hasavaporpressureof 228Torr at 25°C; at the same temperature, 1,1-dichlorotetrafluoroethane, CF3CCl2F, has a vapor pressure of 79 Torr. What mass of 1,1dichloroethane must be mixed with 100.0 g of 1,1dichlorotetrafluoroethane to give a solution with vapor pressure 157 Torr at 25°C? Assume ideal behavior. 9.78 Butanone, CH3CH2COCH3, has a vapor pressure of 100. Torr at 25°C; at the same temperature, propanone, CH3COCH3, has a vapor pressure of 222 Torr. What mass of propanone must be mixed with 350.0 g of butanone to give a solution with a vapor pressure of 135 Torr? Assume ideal behavior. 9.79 Which of the following mixtures would you expect to show a positive deviation, negative deviation, or no deviation (that is, form an ideal solution) from Raoult’s law? Explain your conclusion. (a) methanol, CH3OH, and ethanol, CH3CH2OH; (b) HF and H2O; (c) hexane, C6H14, and H2O. 9.80 Which of the following mixtures would you expect to show a positive deviation, negative deviation, or no deviation (that is, form an ideal solution) from Raoult’s law? Explain your conclusion. (a) HBr and H2O; (b) formic acid, HCOOH, and benzene; (c) cyclopentane, C5H10, and cyclohexane, C6H12. Impact on Biology and Materials 9.81 Distinguish between a foam and a sol. Give at least one example of each. 9.82 Distinguish between an emulsion and a gel. Give at least one example of each. 9.83 Some colloidal suspensions, such as that in Fig. 9.47, appear at first glance to be solutions. What quick, simple procedure can you use to distinguish colloids from solutions? 9.84 Puddings contain large starch molecules that cause the mixture to thicken by a mechanism similar to that by which gelatin thickens. Which is the best description of how puddings thicken? Explain your choice. (a) The starch molecules in pudding are insoluble in water and precipitate when mixed with water. (b) The strands of the starch molecules connect to each other by forming covalent bonds with each other. (c) The starch molecules form hydrogen bonds with water and encapsulate the water in a network. (d) The water molecules hydrate the starch molecules in pudding and the heat of hydration causes the starch molecules to decompose. Integrated Exercises 9.85 Are the water molecules oriented in the same way or differently around the cations and anions when sodium chloride dissolves? Explain your conclusion. 9.86 When sodium chloride dissolves in water, can a chloride ion be removed from the crystal by one water molecule, or are several required to remove it? Explain your answer. 9.87 Complete the following statements about the effect of intermolecular forces on the physical properties of a substance. (a) The higher the boiling point of a liquid, the (stronger, weaker) are its intermolecular forces. (b) Substances with strong intermolecular forces have (high, low) vapor pressures. (c) Substances with strong intermolecular forces typically have (high, low) surface tensions. (d) The higher the vapor pressure of a liquid, the (stronger, weaker) are its intermolecular forces. (e) Because nitrogen, N2, has (strong, weak) intermolecular forces, it has a (high, low) critical temperature. (f) Substances with high vapor pressures have correspondingly (high, low) boiling points. (g) Because water has a high boiling point, it must have (strong, weak) intermolecular forces and a correspondingly (high, low) enthalpy of vaporization. 9.88 Hydrogen peroxide, H2O2, is a syrupy liquid with a vapor pressure lower than that of water and a boiling point of 152°C. Account for the differences between these properties and those of water. 9.89 Explain the effect that an increase in temperature has on each of the following properties: (a) viscosity; (b) surface tension; (c) vapor pressure; (d) evaporation rate. 9.90 Explain how the vapor pressure of a liquid is affected by each of the following changes in conditions: (a) an increase in temperature; (b) an increase in surface area of the liquid; (c) an increase in volume above the liquid; (d) the addition of air to the volume above the liquid. 9.91 You have two beakers: one is filled with tetrachloromethane and the other with water. You also have two compounds, butane (CH3CH2CH2CH3) and calcium chloride. (a) In which liquid will butane dissolve? Sketch the local environment of the solute in the solution. (b) In which solvent will calcium chloride dissolve? Sketch the local environment of the solute in the solution. EXERCISES 377 9.92 Use the phase diagram for compound X below to answer these questions: (a) Is X a solid, liquid, or gas at normal room temperatures? (b) What is the normal melting point of X? (c) What is the vapor pressure of liquid X at Ϫ50°C? (d) What is the vapor pressure of solid X at Ϫ100°C? 9.93 Relative humidity at a particular temperature is defined as The vapor pressure of water at various temperatures is given in Table 9.3. (a) What is the relative humidity at 30.°C when the partial pressure of water is 25.0 Torr? (b) Explain what would be observed if the temperature of the air were to fall to 25°C. 9.94 Suppose that 10.0 g of an organic compound used as a component of mothballs is dissolved in 80.0 g of benzene. The freezing point of the solution is 1.20°C. (a) What is an approximate molar mass of the organic compound? (b) An elemental analysis of that substance indicated that the empirical formula is C3H2Cl. What is its molecular formula? (c) Using the atomic molar masses from the periodic table, calculate a more accurate molar mass of the compound. 9.95 When a molar mass is determined from freezing-point depression, it is possible to make each of the following errors (among others). In each case, predict whether the error would cause the reported molar mass to be greater or less than the actual molar mass. (a) There was dust on the balance, causing the mass of solute to appear greater than it actually was. (b) The water was measured by volume, assuming a density of 1.00 g·cm–3 , but the water was warmer and less dense than assumed. (c) The thermometer was not calibrated accurately, and so the temperature of the freezing point was actually 0.5°C higher than recorded. (d) The solution was not stirred sufficiently, and so not all the solute dissolved. 9.96 An elemental analysis of epinephrine resulted in the following composition: 59.0% carbon, 26.2% oxygen, 7.15% hydrogen, and 7.65% nitrogen by mass. When 0.64 g of epinephrine was dissolved in 36.0 g of benzene, the freezing point decreased by 0.50°C. (a) Determine the empirical formula of epinephrine. (b) What is the molar mass of epinephrine? (c) Deduce the molecular formula of epinephrine. 9.97 Interpret the following verse from the Coleridge’s Rime of the Ancient Mariner: Water, water, every where, And all the boards did shrink, Water, water every where, Nor any drop to drink. 9.98 The vapor pressure of ethanol at 25°C is 58.9 Torr. A sample of ethanol vapor at 25°C and 58.9 Torr partial pressure is in equilibrium with a very small amount of liquid ethanol in a 10.0-L container also containing dry air, at a total pressure of 750.0 Torr. The volume of the container is then reduced at constant temperature to 5.0 L. (a) What is the partial pressure of ethanol in the smaller volume? Explain your reasoning. (b) What is the total pressure of the mixture? 9.99 The height of a column of liquid that can be supported by a given pressure is inversely proportional to its density. An aqueous solution of 0.010 g of a protein in 10. mL of water at 20.°C shows a rise of 5.22 cm in the apparatus shown in Fig. 9.31. Assume the density of the solution to be 0.998 g·cm–3 and the density of mercury to be 13.6 g·cm–3 . (a) What is the molar mass of the protein? (b) What is the freezing point of the solution? (c) Which colligative property is best for measuring the molar mass of these large molecules? Give reasons for your answer. 9.100 A 0.020 M C6H12O6(aq) solution (glucose) is separated from a 0.050 M CO(NH2)2(aq) solution (urea) by a semipermeable membrane at 25°C. For both compounds i ϭ 1. (a) Which solution has the higher osmotic pressure? (b) Which solution becomes more dilute with the passage of H2O molecules through the membrane? (c) To which solution should an external pressure be applied to maintain an equilibrium flow of H2O molecules across the membrane? (d) What external pressure (in atm) should be applied in part (c)? 9.101 Organic chemists once used freezing-point and boiling-point measurements to determine the molar masses of compounds that they had synthesized. When 0.30 g of a nonvolatile solute is dissolved in 30.0 g of CCl4, the boiling point of the solution is 77.19°C. What is the molar mass of the compound? 9.102 A sample consisting of 155 mg of a purified protein is dissolved in 10.0 mL of ethanol. This solution is placed in a device for measuring osmotic pressure and rises to a final height of 32.5 cm above the level of pure ethanol. The experiment is performed at 1.00 atm and 298 K. The density of ethanol at 298 K is 0.79 g·cm–3 . What is the molar mass of the protein? Assume that the density of the solution is the same as that of pure ethanol. See Exercise 9.99. 9.103 (a) From data in Appendix 2A, derive a numerical form of the Clausius–Clapeyron equation for methanol. (b) Using this equation, plot the appropriate quantities that should give a straight-line relation between vapor pressure and temperature. (c) Estimate the vapor pressure of methanol at 0.0°C. (d) Estimate the normal boiling point of methanol. 9.104 (a) From data in Appendix 2A and Table 7.3, derive a numerical form of the Clausius–Clapeyron equation for benzene. (b) Using this equation, plot the appropriate quantities that should give a straight-line relation between vapor pressure and temperature. (c) Estimate the boiling point of benzene when the external pressure is 0.655 atm. (d) Calculate Sm° for gaseous benzene. 9.105 Colligative properties can be sources of insight into not only the properties of solutions, but also the properties of the solute. For example, acetic acid, CH3COOH, behaves differently in two different solvents. (a) The freezing point of a 5.00% by mass aqueous acetic acid solution is –1.72°C. What is the molar mass of the solute? Explain any discrepancy between the experimental and the expected molar mass. (b) The freezing-point depression Relative humidity = partial pressure of water vapor pressure of water * 100% 40 80 120 160 200 101.325 kPa Solid Liquid Vapor −200 −150 −100 −50 0 50 100 Temperature (°C) Pressure(kPa) 0 378 CHAPTER 9 PHYSICAL EQUILIBRIA associated with a 5.00% by mass solution of acetic acid in benzene is 2.32°C. What is the experimental molar mass of the solute in benzene? What can you conclude about the nature of acetic acid in benzene? 9.106 It is standard practice in chemical laboratories to distill high-boiling-point substances under reduced pressure. Trichloroacetic acid has a standard enthalpy of vaporization of 57.814 kJ·mol–1 and a standard entropy of vaporization of 124 J·K–1 ·mol–1 . Use this information to determine the pressure that one would need to achieve to distill trichloroacetic acid at 80.°C. 9.107 The vapor pressure of phosphoryl chloride difluoride (OPClF2) has been measured as a function of temperature: Temperature (K) Vapor pressure (Torr) 190. 3.2 228 68 250. 240. 273 672 (a) Plot ln P against T –1 (this project is best done with the aid of a computer or a graphing calculator that can calculate a leastsquares fit to the data). (b) From the plot (or a linear equation derived from it) in part (a), determine the standard enthalpy of vaporization of OPClF2; (c) the standard entropy of vaporization of OPClF2; and (d) the normal boiling point of OPClF2. (e) If the pressure of a sample of OPClF2 is reduced to 15 Torr, at what temperature will the sample boil? 9.108 From literature sources, find the critical pressures and temperatures of methane, methylamine (CH3NH2), ammonia, and tetrafluoromethane. Discuss the suitability of using each of these solvents for a supercritical extraction at room temperature in an autoclave that can withstand pressures of 100. atm. 9.109 From literature sources, find the critical temperatures for the gaseous hydrocarbons methane, ethane, propane, and butane. Explain the trends observed. 9.110 Consider an apparatus in which A and B are two 1.00-L flasks joined by a stopcock C. The volume of the stopcock is negligible. Initially, A and B are evacuated, the stopcock C is closed, and 1.50 g of diethyl ether, C2H5OC2H5, is introduced into flask A. The vapor pressure of diethyl ether is 57 Torr at Ϫ45°C, 185 Torr at 0.°C, 534 Torr at 25°C, and negligible below Ϫ86°C. (a) If the stopcock is left closed and the flask is brought to equilibrium at Ϫ45°C, what will be the pressure of diethyl ether in flask A? (b) If the temperature is raised to 25°C, what will be the pressure of diethyl ether in the flask? (c) If the temperature of the assembly is returned to Ϫ45°C and the stopcock C is opened, what will be the pressure of diethyl ether in the apparatus? (d) If flask A is maintained at Ϫ45°C and flask B is cooled with liquid nitrogen (boiling point, Ϫ196°C) with the stopcock open, what changes will take place in the apparatus? Assume ideal behavior. 9.111 The apparatus in Exercise 9.110 is again evacuated. Then 35.0 g of chloroform, CHCl3, is placed in flask A and 35.0 g of acetone, CH3COCH3, is placed in flask B. The system is allowed to come to equilibrium at 25°C with the stopcock closed. The vapor pressures of chloroform and acetone at 25°C are 195 Torr and 222 Torr, respectively. (a) What is the pressure in each flask at equilibrium? (b) The stopcock is now opened. What will be the final composition of the gas and liquid phases in each flask once the system reaches equilibrium, assuming ideal behavior? (c) Acetone and chloroform solutions show negative deviations from Raoult’s law. How will this behavior affect the answers given in part (b)? 9.112 Pentane is a liquid with a vapor pressure of 512 Torr at 25°C; at the same temperature, the vapor pressure of hexane is only 151 Torr. What composition must the liquid phase have if the gas-phase composition is to have equal partial pressures of pentane and hexane? 9.113 Using the Clausius–Clapeyron Equation Living Graph on the Web site for this book, plot on the same set of axes the lines for ⌬Hvap ϭ 15, 20., 25, and 30. Is the vapor pressure of a liquid more sensitive to changes in temperature if ⌬Hvap is small or large? Explain your conclusion. 9.114 A pair of amino acids is separated in a column in which the stationary phase is saturated with water and the carrier solvent is methanol, CH3OH. The more polar the acid, the more strongly it is adsorbed by the stationary phase. The amino acids that were separated in this column are (a) HOOCCHNH2CH2COOH and (b) HOOCCHNH2CH(CH3)2. Which amino acid would you expect to be eluted first? Explain your reasoning. Refer to Major Technique 4 on chromatography, which follows this chapter. 9.115 Compounds A and B were extracted from a sample of Martian soil. A mixture of 0.52 mg of A and 2.30 mg of B in 1.00 mL of solution was separated by gas chromatography. The areas of the two peaks were 5.44 cm2 for A and 8.72 cm2 for B. A second solution contained an extract with an unknown amount of A. To determine the concentration of A in the solution, 2.00 mg of B was added to 2.0 mL of the solution, which was then introduced into a gas chromatograph. Peak areas of 3.52 cm2 for A and 7.58 cm2 for B were measured. What is the concentration of A in the second solution? Refer to Major Technique 4, which follows this chapter. 9.116 Pure liquid naphthalene freezes at 80.2°C at 1 atm. When 1.00 mol of any nonelectrolyte solute is dissolved in 1.00 kg of naphthalene, the new freezing point of the solution (at 1 atm) is 73.2°C. When 14.8 g of sulfur is dissolved in 575 g of naphthalene, the new freezing point of the solution is 79.5°C. What are the molar mass and the molecular formula of the sulfur species in solution? 9.117 Human blood has an osmotic pressure relative to water of approximately 7.7 atm at body temperature (37°C). In a hospital, intravenous glucose (C6H12O6) solutions are often given. If a technician must mix 500. mL of a glucose solution for a patient, what mass of glucose should be used? 9.118 In heavy water, D2O, deuterium atoms replace the hydrogen atoms. The hydrogen bonds in heavy water are stronger than those in normal water. (a) How will the vapor pressure of a sample of H2O be affected if 10% of the water molecules are replaced by D2O molecules? (b) Calculate the molality of the D2O in the solution. 9.119 What volume of 0.010 M NaOH(aq) is required to react completely with 30. g of an aqueous acetic acid solution in which the mole fraction of acetic acid is 0.15? EXERCISES 379 9.120 The combustion analysis of L-carnitine, an organic compound thought to build muscle strength, yielded 52.16% C, 9.38% H, 8.69% N, and 29.78% O. The osmotic pressure of a 100.00-mL solution of 0.322 g of L-carnitine was found to be 0.501 atm at 32°C. Assuming that L-carnitine does not ionize in methanol, determine (a) the molar mass of L-carnitine; (b) the molecular formula of L-carnitine. 9.121 Pentanol, an organic compound with the formula CH3CH2CH2CH2CH2OH, has molecules with a nonpolar hydrocarbon chain of medium length attached to a polar ßOH group. It is insoluble in water. However, if surfactant is added, the molecules of the three compounds form a layered structure that suspends the pentanol in the water. Propose a structure for the layered structure, describing the arrangement of the water, pentanol, and detergent molecules. 9.122 Hydrogen bonding typically occurs between a highly electronegative atom and a hydrogen atom attached to another electronegative atom. (a) Draw the Lewis structures for CHCl3 and (CH3)2CO and orient the structures to show the hydrogen bonding between the pair: (b) Which hydrogen atom is considered to have a low electron density and therefore to be a center of positive partial charge, and why? Chemistry Connections 9.123 Sports drinks provide water to the body in the form of an isotonic solution (one having the same total molar concentration of solutes as human blood). These drinks contain electrolytes such as NaCl and KCl as well as sugar and flavoring. One of the main flavoring agents in sport drinks is citric acid, shown below. (a) Indicate the hybridization of each C atom in citric acid. (b) Can citric acid take part in hydrogen bonding? (c) Predict from a consideration of intermolecular forces whether citric acid is a gas, liquid, or solid at 25°C and whether it is soluble in water. (d) Normal saline solution is an isotonic solution containing 0.9% NaCl by mass in water. Assuming complete dissociation of the NaCl, what is the total molar concentration of all solutes in an isotonic solution? Assume a density of 1.00 g·cm–3 for the solution. (e) If you decide to make up 500.0 mL of a sports drink with 1.0 g of NaCl and glucose, what mass of glucose do you need to add to the NaCl and water to make the solution isotonic (see part d)? Assume a density of 1.00 g·cm–3 for the solution. (f) A paramedic treating injuries in a remote area has 300.0 mL of a 1.00% by mass solution of boric acid, B(OH)3, that needs to be made isotonic (assume that the density is 1.00 g·cm–3 ). What mass of NaCl should be added? Assume that the NaCl is completely dissociated in the solution and that the volume of the solution does not change on addition of the NaCl. Take into account the 0.007% deprotonation of boric acid. CH2 CH2 HOOC C COOH HO COOH Citric acid 380 CHAPTER 9 PHYSICAL EQUILIBRIA CHROMATOGRAPHYMAJOR TECHNIQUE 4 Because the scent of a flower may be due to hundreds of different compounds, it is difficult for perfume manufacturers to duplicate floral scents. Establishing the identities and relative amounts of the components of a fragrance was actually impossible until the development of chromatography. Related techniques are used in forensic laboratories to match samples of fluids, by food manufacturers to test product quality, and to search for evidence of life on other planets. All these techniques depend on subtle differences in intermolecular forces to separate compounds. Solvent Extraction If an aqueous solution of a compound is shaken with another liquid that is immiscible (mutually insoluble) with water, some of the compound may dissolve in the other solvent. For example, molecular iodine, I2, is very slightly soluble in water but is highly soluble in tetrachloromethane, CCl4, which is immiscible with water. When tetrachloromethane is added to water containing iodine, most of the iodine dissolves in the CCl4. The solute is said to partition itself between the two solvents. Solvent extraction is used to obtain plant flavors and aromas from aqueous slurries of the plant that have been crushed in a blender. In some cases, the solids themselves are subjected to extraction by a solvent. For example, in one process used to decaffeinate coffee, the coffee beans are mixed with activated charcoal and a high-pressure stream of “supercritical carbon dioxide” (carbon dioxide at high pressure and above its critical temperature) is passed over them at approximately 90°C. A supercritical solvent is a highly mobile fluid with a very low viscosity. The carbon dioxide removes the soluble caffeine preferentially without extracting the flavoring agents and evaporates without leaving a harmful residue. Liquid Chromatography In the early part of the twentieth century, the Russian botanist M. S. Tsvet found a way to separate the many pigments in flowers and leaves. He ground up the plant materials and dissolved the pigments, then poured the solution over the top of a vertical tube of ground chalk. The different pigments trickled through the chalk at different rates, producing colored bands in the tube, inspiring the name chromatography (“color writing”). The separation occurred because the different pigments were absorbed to different extents by the chalk. Chromatography is one of the most powerful and widely used means for separating mixtures, because it is often inexpensive and it can be used to provide quantitative as well as qualitative information. The simplest method is paper chromatography. A drop of solution is placed near the bottom edge of the stationary phase, an absorbent support, such as a strip of paper. The mobile phase, a fluid solvent, is added below the spot and the solvent is absorbed on the support. As the mobile phase rises up the stationary phase by capillary action, the materials in the spot are carried upward at a rate that depends on how strongly they are adsorbed on (adhere to) the stationary phase (Fig. 1). The more strongly the solute is adsorbed on the stationary phase, the longer it will take to travel up the support. The same concepts apply to column chromatography, where the stationary phase is normally small particles of silica, SiO2, or alumina, Al2O3. These substances are not very reactive and have specially prepared surfaces to increase their adsorption ability. The column is saturated with solvent, and a small volume of solution containing the solutes is poured onto the top. As soon as it has soaked in, more solvent is added. The solutes travel slowly down the column and are eluted (removed as fractions) at the bottom (Fig. 2). If the mobile phase is less polar than the stationary phase, the less polar solutes will be eluted first and the more polar ones last. To improve the separation of the solutes in a mixture, high-performance liquid chromatography (HPLC) was developed. In this technique, the mobile phase is forced under pressure through a long, narrow column, yielding an excellent separation in a relatively short time. HPLC has become the primary means of monitoring the use of therapeutic drugs and of detecting drug abuse; it is also used to separate the compounds contributing to the fragrances of flowers. a b (a) (b) FIGURE 1 Two stages in a paper chromatography separation of a mixture of two components. (a) Before separation; (b) after separation. The relative values of the distances a and b are used to identify the components. FIGURE 2 A column chromatography experiment. The mixture is placed on top of the column (left). As the solvent passes through the support, the mixture is washed down the column and separates into bands. 381 (continued) Self-Test M4.1A A pair of amino acids is separated in a column in which the stationary phase is saturated with water and the mobile phase is methanol, CH3OH. The more polar the acid, the more strongly it is adsorbed by the stationary phase. The amino acids that were separated in this column are (a) HOOCCH(NH2)CH2OH and (b) HOOCCH(NH2)CH3. Which amino acid will be retained in the column the longest? [Answer: Compound (a) has more polar groups, because it has an ϪOH group, and so will be retained longer on the column.] Self-Test M4.1B Inorganic cations can be separated by liquid chromatography according to their ability to form complexes with chloride ions. For the separation, the stationary phase is saturated with water and the mobile phase is a solution of HCl in acetone. The relative solubilities of the following chlorides in concentrated hydrochloric acid are CuCl2 Ͼ CoCl2 Ͼ NiCl2. What is the order of elution of these compounds? Gas Chromatography Volatile compounds can be separated in a gas chromatograph, in which the mobile phase is usually a relatively unreactive carrier gas such as helium, nitrogen, or hydrogen. The principles are the same as those for liquid chromatography, but the output is more often a chromatogram, rather than a series of eluted samples (Fig. 3). The chromatogram shows when each solute was eluted, and the peak areas tell how much of each component is present. The identity of the solute producing each peak can be determined by comparing its location against a database of known compounds. As the vapor leaves the tube, the compounds in the sample are detected by a device such as a thermal conductivity detector. This instrument continuously measures the thermal conductivity (the ability to conduct heat) of the carrier gas, which changes when a solute is present. The detection techniques are very sensitive, allowing tiny amounts of solutes to be detected. Many environmental monitoring and forensic applications have been developed. Gas Chromatography–Mass Spectrometry Some detectors can give additional information about the elutes (the eluted solutes). One example is the gas chromatograph–mass spectrometer (GC-MS), which produces a mass spectrum of each compound as well as its mass and location in the chromatogram.* This powerful means of detection can be used when standard samples are not available to help determine the identities of the solutes. A beam of ions bombards each compound as it emerges from the chromatograph. The compound breaks up into ions of different masses, providing a spread of narrow peaks instead of one peak for each compound. The relative amount of each fragment is determined and used to help identify the compound. The GC-MS instrument can be very compact and used in mobile equipment. A GC-MS device was used on the Viking Lander on the first Mars mission to search for organic compounds that would have provided evidence of life (none was detected). Related Exercises: 9.114 and 9.115 *Mass spectrometry is the subject of Major Technique 6, following Chapter 18. Elution time Detectorsignal Lindane Heptachlor Aldrin Dieldrin FIGURE 3 A gas chromatogram of a mixture of pesticides from farmland. The relative heights of the peaks indicate the relative abundances of the compounds. In gas–liquid partition chromatography (GLPC), the stationary phase is a liquid that coats the particles in the tube or the walls of the tube. Often the tube itself is very narrow and long, perhaps 100 m, and has to be coiled (Fig. 4). Solutes are separated, as in liquid chromatography, by their relative solubility in the gas and liquid phases. In gas–solid adsorption chromatography, solid particles coat the inside of the narrow tube. The Detector Sample injection Carrier gas Oven Packed column FIGURE 4 A schematic representation of the arrangement in a gas chromatograph. The coiled column, which is packed with the stationary phase, may be as long as 100 m. solute vapors are separated by their relative attraction for the solid particles. In both cases, it is relative polarity that determines the distances between peaks. 382 CHROMATOGRAPHY (continued)MAJOR TECHNIQUE 4 383 What Are the Key Ideas? Instead of going to completion, reactions proceed until the composition of a reaction mixture corresponds to minimum Gibbs free energy. This composition is described by an equilibrium constant that is characteristic of the reaction. The equilibrium is dynamic and responds to changes in the conditions. Why Do We Need to Know This Material? The dynamic equilibrium toward which every chemical reaction tends is such an important aspect of the study of chemistry that the next four chapters deal with it. We need to know the composition of a reaction mixture at equilibrium because it tells us how much product we can expect. To control the yield of a reaction, we need to understand the thermodynamic basis of equilibrium and how the position of equilibrium is affected by conditions such as temperature and pressure. The response of equilibria to changes in conditions has considerable economic and biological significance: the regulation of chemical equilibrium affects the yields of products in industrial processes, and living cells struggle to avoid sinking into equilibrium. What Do We Need to Know Already? The concepts of chemical equilibrium are related to those of physical equilibrium (Sections 9.1–9.3). Because chemical equilibrium depends on the thermodynamics of chemical reactions, we shall need to use the Gibbs free energy of reaction (Section 8.13) and standard enthalpies of formation (Section 7.18). Chemical equilibrium calculations require a thorough knowledge of molar concentration (Section G), reaction stoichiometry (Section L), and the gas laws (Chapter 4). E arly in the twentieth century, the looming prospect of World War I created a desperate need for nitrogen compounds because nitrates normally used for agriculture were being made into explosives. Almost all the nitrates used for fertilizers and explosives were quarried from deposits in Chile, and the limited supply could not keep up with the demand. Moreover, shipping channels were vulnerable to attack, which threatened to cut off the supply altogether. Although nitrogen is abundant in air, the methods used at the time to convert nitrogen into compounds were too costly to employ on a large scale. Any nation that could develop an economical process to fix atmospheric nitrogen—that is, to combine it with other elements—would have all the nitrogen compounds it needed. Scientists on both sides of the conflict were urgently seeking ways to fix nitrogen. Finally, through determination, application, and—as so often happens in research—a bit of luck, the German chemist Fritz Haber in collaboration with the chemical engineer Carl Bosch found an economical way to harvest the nitrogen of the air and to provide an abundant source of compounds for both agriculture and armaments. One difficulty Haber faced is that the reactions used to produce compounds from nitrogen do not go to completion, but appear to stop after only some of the reactants have been used up. At this point the mixture of reactants and products has reached chemical equilibrium, the stage in a chemical reaction when there is no further tendency for the composition of the reaction mixture—the concentrations or partial pressures of the reactants and products—to change. To achieve the greatest conversion of nitrogen into its compounds, Haber had to understand how a reaction approaches and eventually reaches equilibrium and then use that knowledge—as we shall see in Section 10.12— to improve the yield by changing the conditions of the reaction. Like physical equilibria, all chemical equilibria are dynamic equilibria, with the forward and reverse reactions occurring at the same rate. In Chapter 9, we considered several physical processes, including vaporizing and dissolving, that reach dynamic equilibrium. This chapter shows how to apply the same ideas to chemical changes. It REACTIONS AT EQUILIBRIUM 10.1 The Reversibility of Reactions 10.2 Equilibrium and the Law of Mass Action 10.3 The Thermodynamic Origin of Equilibrium Constants 10.4 The Extent of Reaction 10.5 The Direction of Reaction EQUILIBRIUM CALCULATIONS 10.6 The Equilibrium Constant in Terms of Molar Concentrations of Gases 10.7 Alternative Forms of the Equilibrium Constant 10.8 Using Equilibrium Constants THE RESPONSE OF EQUILIBRIA TO CHANGES IN CONDITIONS 10.9 Adding and Removing Reagents 10.10 Compressing a Reaction Mixture 10.11 Temperature and Equilibrium 10.12 Catalysts and Haber’s Achievement 10.13 The Impact on Biology: Homeostasis 383 Chapter 10 CHEMICAL EQUILIBRIA also shows how to use thermodynamics to describe equilibria quantitatively, which puts enormous power into our hands—the power to control the direction of a reaction and the yield of products. We first show that a single quantity, the equilibrium constant, characterizes the composition of a reaction mixture at equilibrium. Then we explore how the equilibrium constant arises from thermodynamics and see how it is related to the free energy of the reaction. We then see how to use the equilibrium constant to calculate the equilibrium composition of a reaction mixture. Finally, we develop thermodynamic arguments to deduce how the composition of a reaction mixture at equilibrium responds to changes in the conditions under which the reaction is taking place. REACTIONS AT EQUILIBRIUM To say that chemical equilibrium is dynamic means that when a reaction has reached equilibrium, the forward and reverse reactions continue to take place, but with reactants being formed as fast as they are consumed. As a result, the composition of the reaction mixture remains constant. To develop these ideas we first establish that reactions can take place in their reverse direction as soon as some products have accumulated. Then we see how to relate the equilibrium composition to the thermodynamic properties of the system. 10.1 The Reversibility of Reactions Some reactions, such as the explosive reaction of hydrogen and oxygen, appear to proceed to completion, but others seem to stop at an early stage. For example, consider the reaction that took place when Haber heated nitrogen and hydrogen under pressure in the presence of a small amount of the metal osmium: N2(g) ϩ 3 H2(g) 2 NH3(g) (A) The reaction does produce ammonia rapidly at first, but eventually the reaction seems to stop (Fig. 10.1). As the graph shows, no matter how long we wait, no more product forms. The reaction has reached equilibrium. Like phase changes, chemical reactions tend toward a dynamic equilibrium in which, although there is no net change, the forward and reverse reactions are still taking place, but at matching rates. What actually happens when the formation of ammonia appears to stop is that the rate of the reverse reaction, 2 NH3(g) N2(g) ϩ 3 H2(g) (B)¡ ¡ 384 CHAPTER 10 CHEMICAL EQUILIBRIA And, we might add, to change the course of history. The metal acts as a catalyst for this reaction, a substance that helps to make a reaction go faster (Section 14.14). Osmium is too expensive to be used commercially: in the industrial process, iron is used instead. FIGURE 10.1 (a) In the synthesis of ammonia, the concentrations of N2 and H2 decrease with time and that of NH3 increases until they finally settle into values corresponding to a mixture in which all three are present and there is no further net change. (b) If the experiment is repeated with pure ammonia, it decomposes, and the composition settles down into a mixture of ammonia, nitrogen, and hydrogen. (The two graphs correspond to experiments at two different temperatures, and so they correspond to different equilibrium compositions.) Time H2 (reactant) N2 (reactant) NH3 (product) (a) Time(b) H2 (product) N2 (product) NH3 (reactant) Molarconcentration Molarconcentration increases as more ammonia is formed. At equilibrium, the ammonia is decomposing as fast as it is being formed. Just as we did for phase transitions, we express this state of dynamic equilibrium by replacing the arrow in the equation with equilibrium “harpoons”: N2(g) ϩ 3 H2(g) #¢4 2 NH3(g) (C) All chemical equilibria are dynamic equilibria. Although there is no further net change at equilibrium, the forward and reverse reactions are still taking place. As we shall see later in the chapter, dynamic equilibria respond to changes in temperature and pressure, and the addition of even a small amount of additional reagent can result in a change in overall composition. A reaction that is simply not taking place (such as a mixture of hydrogen and oxygen at room temperature and pressure) does not respond to small changes in the conditions and therefore is not at equilibrium. Thinking point: Can you think of an experiment to show that a chemical equilibrium is dynamic? Think, perhaps, about using radioactive isotopes. We can use these characteristics to decide if the three systems in Fig. 10.2 are at equilibrium. All three systems appear to be unchanging. However, when methane, CH4, burns with a steady flame to form carbon dioxide gas and water (Fig. 10.2a), the combustion reaction is not at equilibrium because the composition is not constant (reactants continue to be added and the products dissipate instead of reacting). The sample of glucose does not change (Fig. 10.2b), even if we leave it for a very long time. However, the glucose is not at equilibrium with the products of its combustion (carbon dioxide and water); it survives only because the rate of its combustion is immeasurably slow at room temperature. The gas-phase reaction (Fig. 10.2c), however, is at equilibrium because, as well as the composition being constant, additional experiments show that NO2 is ceaselessly forming N2O4 and that N2O4 is decomposing into NO2 at the same rate. The criteria that identify a dynamic chemical equilibrium are: 1 The forward reaction and its reverse are both taking place. 2 They are doing so at equal rates (so there is no net change). Chemical reactions reach a state of dynamic equilibrium in which the rates of forward and reverse reactions are equal and there is no net change in composition. 10.2 Equilibrium and the Law of Mass Action In 1864, before Haber began his work, the Norwegians Cato Guldberg (a mathematician) and Peter Waage (a chemist) had discovered the mathematical relation that summarizes the composition of a reaction mixture at equilibrium. As an example of their approach, look at the data in Table 10.1 for the reaction between SO2 and O2: 2 SO2(g) ϩ O2(g) #¢4 2 SO3(g) (D) 10.2 EQUILIBRIUM AND THE LAW OF MASS ACTION 385 (a) (b) (c) FIGURE 10.2 (a) Methane burns in air with a steady flame but, because matter is being added and removed, the reaction is not at equilibrium. (b) This sample of glucose in air is unchanging in composition, but it is not yet in equilibrium with its combustion products; the reaction proceeds far too slowly at room temperature. (c) Nitrogen dioxide (a brown gas) and dinitrogen tetroxide (a colorless volatile solid) are in equilibrium in this vessel. We can tell that they are by changing the temperature slightly and seeing the composition adjust to a new value. Lab Video 10.2 386 CHAPTER 10 CHEMICAL EQUILIBRIA In each of these five experiments, a mixture with different initial compositions of the three gases was prepared and allowed to reach equilibrium at 1000. K. The compositions of the equilibrium mixtures and the total pressure P were then determined. At first, there seemed to be no pattern in the data. However, Guldberg and Waage noticed an extraordinary relation: the value of the quantity was nearly the same for every experiment, regardless of the initial compositions. Here, PJ is the equilibrium partial pressure of gas J and P° ϭ 1 bar, the standard pressure. Note that K is unitless, because the units of PJ are canceled by the units of P° in each term. From now on, though, to keep the notation simple, we shall write simply with the PJ understood to be the numerical value of the pressure in bars. Within experimental error, Guldberg and Waage obtained the same value of K whatever the initial composition of the reaction mixture. This remarkable result shows that K is characteristic of the composition of the reaction mixture at equilibrium at a given temperature. It is known as the equilibrium constant for the reaction. The law of mass action summarizes this result: it states that, at equilibrium, the composition of the reaction mixture can be expressed in terms of an equilibrium constant where, for any reaction between gases that can be treated as ideal, (1a) with each partial pressure raised to a power equal to the corresponding stoichiometric coefficient in the balanced chemical equation for the reaction. We shall not in general write “equilibrium” on expressions for K. Thus, if we are interested in the reaction a A(g) ϩ b B(g) #¢4 c C(g) ϩ d D(g) (E) and if all the gases are treated as ideal, we write (1b)* with the numerical values of the partial pressures being those at equilibrium (in bar). K = (PC)c (PD)d (PA)a (PB)b K = e partial pressures of products partial pressures of reactants f equilibrium K = (PSO3 )2 (PSO2 )2 PO2 K = (PSO3 >P°)2 (PSO2 >P°)2 (PO2 >P°) TABLE 10.1 Equilibrium Data and the Equilibrium Constant for the Reaction 2 SO2(g) ؉ O2(g) T 2 SO3(g) at 1000. K PSO2 (bar) PO2 (bar) PSO3 (bar) K* 0.660 0.390 0.0840 0.0415 0.0380 0.220 0.00360 0.0409 0.110 0.110 0.00750 0.0423 0.950 0.880 0.180 0.0408 1.44 1.98 0.410 0.0409 *Average K: 0.0413 EXAMPLE 10.1 Writing the expression for an equilibrium constant Write the equilibrium constant for the ammonia synthesis reaction, reaction C. PLAN Write the equilibrium constant with the partial pressure of the product in the numerator, raised to a power equal to its coefficient in the balanced equation. Do the same for the reactants, but place their partial pressures in the denominator: SOLVE 10.2 EQUILIBRIUM AND THE LAW OF MASS ACTION 387 From K ϭ (PC)c (PD)d ͞(PA)a (PB)b , K = (PNH3 )2 PN2 (PH2 )3 2 3 K = ϩ As already explained, each PJ in this expression should be interpreted as PJ/P°. Self-Test 10.1A Write the expression for the equilibrium constant for the reaction 4 NH3(g) ϩ 5 O2(g) #4 4 NO(g) ϩ 6 H2O(g). [Answer: K ϭ (PNO)4 (PH2O)6 /(PNH3 )4 (PO2 )5 ] Self-Test 10.1B Write the expression for the equilibrium constant for 2 H2S(g) ϩ 3 O2(g) #4 2 SO2(g) ϩ 2 H2O(g). We use a different measure of concentration when writing expressions for the equilibrium constants of reactions that involve species other than gases. Thus, for a species J that forms an ideal liquid or solid solution, the partial pressure in the expression for K is replaced by the molarity [J] relative to the standard molarity c° ϭ 1 molиLϪ1 . Although K should be written in terms of the dimensionless ratio [J]/c°, it is common practice to write K in terms of [J] alone and to interpret each [J] as the molarity with the units struck out. It has been found empirically, and is justified by thermodynamics, that pure liquids or solids should not appear in K. So, even though CaCO3(s) and CaO(s) occur in the equilibrium CaCO3(s) #¢4 CaO(s) ϩ CO2(g) (F) neither appears in the equilibrium constant, which is K ϭ PCO2 ͞P° (or, more simply, K ϭ PCO2 ). We can summarize these empirical rules by introducing the concept of the activity, aJ, of a substance J: Substance Activity Simplified form Ideal gas aJ ϭ PJ/P° aJ ϭ PJ Solute in a dilute solution aJ ϭ [J]/c° aJ ϭ [J] Pure solid or liquid aJ ϭ 1 aJ ϭ 1 Note that all activities are pure numbers and thus are unitless. When using the simplified form of the equilibrium constant, the activity is the numerical value of the pressure in bar or the numerical value of the molarity in moles per liter. At this stage, activities are simply quantities introduced to facilitate writing the expression for K. In advanced work, activities are used to take into account deviations from ideal behavior and to accommodate real gases and real solutions, where intermolecular interactions are important. In those cases the activity of a substance may differ from the calculated pressure or concentration. However, for the low-pressure gases and dilute solutions that concern us here, we can ignore the interactions between molecules and regard activities as providing a simple, uniform way of writing general expressions for equilibrium constants and other quantities that we shall meet shortly. We have to remember, though, that because we are assuming ideal behavior, our expressions are approximations. Thinking point: How might intermolecular and interionic interactions affect the value of an activity? The use of activities allows us to write a general expression for the equilibrium constant for any reaction: (2a)K = e activities of products activities of reactants f equilibrium More specifically, for a generalized version of reaction E, with phases not specified: a A(g) ϩ b B(g) #¢4 c C(g) ϩ d D(g) (2b)* Because activities are unitless, so too is K. A note on good practice: In some cases you will see an equilibrium constant denoted KP to remind you that it is expressed in terms of partial pressures. However, the subscript P is unnecessary because, by definition, equilibrium constants for gas-phase reactions are expressed in terms of partial pressures. Chemical equilibria with reactants and products that are all in the same phase are called homogeneous equilibria. Equilibria C, D, and E are homogeneous. Equilibria in systems having more than one phase are called heterogeneous equilibria. Equilibrium F is heterogeneous; so too is the equilibrium between water vapor and liquid water in a closed system: H2O(l) #¢4 H2O(g) (G) In this reaction, there is a gas phase and a liquid phase. Likewise, the equilibrium between a solid and its saturated solution is heterogeneous: Ca(OH)2(s) #¢4 Ca2ϩ (aq) ϩ 2 OH– (aq) (H) The equilibrium constants for heterogeneous reactions are also given by the general expression in Eq. 2: all we have to remember is that the activity of a pure solid or liquid is 1. For instance, for the calcium hydroxide equilibrium (reaction H), because the calcium hydroxide is a pure solid. The calcium hydroxide must be present for the equilibrium to exist, but it does not appear in the expression for the equilibrium constant. Remember that each [J] represents the molar concentration of J with the units struck out. Similarly, in the equilibrium between solid nickel, gaseous carbon monoxide, and gaseous nickel carbonyl used in the purification of nickel, Ni(s) ϩ 4 CO(g) #¢4 Ni(CO)4(g) As for the calcium hydroxide equilibrium, solid nickel must be present for the equilibrium to exist, but it does not appear in the expression for the equilibrium constant. Self-Test 10.2A Write the equilibrium constant for the equilibrium between atmospheric oxygen and oxygen dissolved in water, O2(g) #4 O2(aq). [Answer: K ϭ [O2]͞PO2 ] Self-Test 10.2B Write the equilibrium constant for the equilibrium Zn(s) ϩ 2 HCl(aq) #4 ZnCl2(aq) ϩ H2(g). Some reactions in solution involve the solvent as a reactant or product. When the solution is very dilute, the change in solvent concentration due to the reaction is insignificant. In such cases, the solvent is treated as a pure substance and ignored when writing K. In other words, For a nearly pure solvent: asolvent ϭ 1 A final point is that, when a reaction involves fully dissociated ionic compounds in solution, then the equilibrium constant should be written for the net ionic equation, by using the activity for each type of ion. K = aNi(CO)4 aNi (aCO)4 = PNi(CO)4 (PCO)4 K = aCa2+(aOH-)2 aCa(OH)2 = [Ca2+ ][OH- ]2 K = 1aC2c 1aD2d 1aA2a 1aB2b 388 CHAPTER 10 CHEMICAL EQUILIBRIA $%& 1 for a pure solid $%& 1 Self-Test 10.3A Write the equilibrium constant for the reaction of silver nitrate with sodium hydroxide: 2 AgNO3(aq) ϩ 2 NaOH(aq) #4 Ag2O(s) ϩ 2 NaNO3(aq) ϩ H2O(l). Remember to use the net ionic equation. [Answer: K ϭ 1/[Agϩ ]2 [OH– ]2 ] Self-Test 10.3B Write the equilibrium constant K for P4(s) ϩ 5 O2(g) #4 P4O10(s). Each reaction has its own characteristic equilibrium constant, with a value that can be changed only by varying the temperature (Table 10.2). The extraordinary empirical result, which we justify in the next section, is that, regardless of the initial composition of a reaction mixture, the composition tends to adjust until the activities give rise to the characteristic value of K for the reaction and temperature (Fig. 10.3). 10.2 EQUILIBRIUM AND THE LAW OF MASS ACTION 389 TABLE 10.2 Equilibrium Constants for Various Reactions Reaction T (K)* K Kc † H2(g) ϩ Cl2(g) #¢4 2 HCl(g) 300 4.0 ϫ 1031 4.0 ϫ 1031 500 4.0 ϫ 1018 4.0 ϫ 1018 1000 5.1 ϫ 108 5.1 ϫ 108 H2(g) ϩ Br2(g) #¢4 2 HBr(g) 300 1.9 ϫ 1017 1.9 ϫ 1017 500 1.3 ϫ 1010 1.3 ϫ 1010 1000 3.8 ϫ 104 3.8 ϫ 104 H2(g) ϩ I2(g) #¢4 2 HI(g) 298 794 794 500 160 160 700 54 54 2 BrCl(g) #¢4 Br2(g) ϩ Cl2(g) 300 377 377 500 32 32 1000 5 5 2 HD(g) #¢4 H2(g) ϩ D2(g) 100 0.52 0.52 500 0.28 0.28 1000 0.26 0.26 F2(g) #¢4 2 F(g) 500 3.0 ϫ 10Ϫ11 7.3 ϫ 10Ϫ13 1000 1.0 ϫ 10Ϫ2 1.2 ϫ 10Ϫ4 1200 0.27 2.7 ϫ 10Ϫ3 Cl2(g) #¢4 2 Cl(g) 1000 1.0 ϫ 10-5 1.2 ϫ 10Ϫ7 1200 1.7 ϫ 10–3 1.7 ϫ 10Ϫ5 Br2(g) #¢4 2 Br(g) 1000 3.4 ϫ 10Ϫ5 4.1 ϫ 10Ϫ7 1200 1.7 ϫ 10Ϫ3 1.7 ϫ 10Ϫ5 I2(g) #¢4 2 I(g) 800 2.1 ϫ 10Ϫ3 3.1 ϫ 10Ϫ5 1000 0.26 3.1 ϫ 10Ϫ3 1200 6.8 6.8 ϫ 10Ϫ2 N2(g) ϩ 3 H2(g) #¢4 2 NH3(g) 298 6.8 ϫ 105 4.2 ϫ 108 400 41 4.5 ϫ 104 500 3.6 ϫ 10Ϫ2 62 2 SO2(g) ϩ O2(g) #¢4 2 SO3(g) 298 4.0 ϫ 1024 9.9 ϫ 1025 500 2.5 ϫ 1010 1.0 ϫ 1012 700 3.0 ϫ 104 1.7 ϫ 106 N2O4(g) #¢4 2 NO2(g) 298 0.15 6.1 ϫ 10Ϫ3 400 47.9 1.44 500 1.7 ϫ 103 41 *Three significant figures † Kc is the equilibrium constant in terms of molar concentrations of gases (Section 10.6). FIGURE 10.3 Whether we start with pure reactants or with pure products, a reaction mixture will always tend toward a mixture of reactants and products that has a composition in accord with the equilibrium constant for the reaction at the temperature of the experiment. Reactants Equilibrium Products The equilibrium composition of a reaction mixture is described by the equilibrium constant, which is equal to the activities of the products (raised to powers equal to their stoichiometric coefficients in the balanced chemical equation for the reaction) divided by the activities of the reactants (raised to powers equal to their stoichiometric coefficients). 10.3 The Thermodynamic Origin of Equilibrium Constants Guldberg and Waage’s description of equilibrium was entirely empirical. Now, though, chemists know that the law of mass action is a consequence of thermodynamics and that the apparently mysterious form of K arises from thermodynamic considerations and ultimately from the expression for the entropy of mixing of reactants and products as the latter are formed. The Gibbs free energy of a reaction mixture depends on the partial pressures or concentrations of reactants and products. Therefore, the tendency of a reaction to go in the forward or the reverse direction is determined by those pressures or concentrations. Every chemical reaction has a tendency to proceed spontaneously toward equilibrium, but the direction of reaction depends on the composition of the reaction mixture. At constant temperature and pressure: • In a reaction mixture that has not yet produced enough products to reach equilibrium, the spontaneous direction of change is toward more products and ⌬G Ͻ 0 for the forward reaction. • In a reaction mixture that has excess products, the reverse reaction is spontaneous and ⌬G Ͼ 0 for the forward reaction (so that ⌬G Ͻ 0 for the reverse reaction). • For the reaction at equilibrium, there is no tendency for spontaneous change in either the forward or the reverse direction and ⌬G ϭ 0. Clearly, ⌬G changes as the proportions of reactants and products change; the composition of the reaction mixture at equilibrium is the composition at which ⌬G is zero (Fig. 10.4). As we can see from the graph, at any point during the reaction the sign of ⌬G is indicated by the slope of the curve, which shows how G varies with composition at that point: to the left of the equilibrium composition, the slope is negative and so the forward reaction is spontaneous; to the right of equilibrium, the slope is positive and so the reverse reaction is spontaneous; at equilibrium, at the minimum of the curve, the slope is zero. The value of ⌬G at a particular stage of the reaction is the difference in the molar Gibbs free energies of the products and the reactants at the partial pressures or concentrations that they have at that stage, weighted by the stoichiometric coefficients interpreted as amounts in moles: Units: kilojoules (3a) (This is Eq. 18 of Chapter 8.) We shall sometimes find it useful to interpret the n that appear in Eq. 3a as pure numbers (rather than amounts in moles), so that if n ϭ 2 mol, in this convention we would use n ϭ 2. To signal that we are using this “molar” convention (“molar” because the units of ⌬G then become kilojoules per mole), we attach a subscript r to ⌬G (r for reaction) and write Units: kilojoules per mole (3b) We shall explain later in this section (in the “How Do We Do That?” box) exactly when and why it is necessary to use this “molar” convention. The molar Gibbs free energies of the reactants and products change during the course of the reaction, so ⌬G changes too. It is very important to distinguish this Gibbs free energy of reaction, ⌬G, from the standard Gibbs free energy of reaction, ⌬G°, which does not change during the course of a reaction: • ⌬G is the difference in molar Gibbs free energies of the products and the reactants at a specified stage of the reaction. ¢Gr = anGm(products) - anGm(reactants) ¢G = anGm(products) - anGm(reactants) 390 CHAPTER 10 CHEMICAL EQUILIBRIA FIGURE 10.4 The variation of Gibbs free energy of a reaction mixture with composition. A reaction mixture has a spontaneous tendency to change in the direction of decreasing Gibbs free energy. Note that ⌬G is the slope of the line at each composition, whereas ⌬G° is the difference between the standard Gibbs free energies of the pure reactants and the pure products. ΔG° ΔG < 0 ΔG > 0 ΔG = 0 Equilibrium Progress of reaction Gibbsfreeenergy,G Pure reactants Pure products • ⌬G° is the difference in molar Gibbs free energies of the products and the reactants in their standard states and can be calculated from the standard Gibbs free energies of formation: (3c) (This is Eq. 20 of Chapter 8.) We could write this expression in the molar convention too, as , in which case the n would be interpreted as pure numbers. A note on good practice: Recall that the standard state of a pure substance is its pure form at a pressure of 1 bar (Section 7.15). For a solute, the standard state is for a concentration of 1 molиLϪ1 . Pure solids and liquids may always be regarded as being in their standard states provided the pressure is close to 1 bar. To find how ⌬G changes with composition, we need to know how the molar Gibbs free energy of each substance varies with its partial pressure, if it is a gas, or with its concentration, if it is a solute. We have already seen (in Section 9.3) that the molar Gibbs free energy of an ideal gas J is related to its partial pressure, PJ, by Gm(J) ϭ Gm°(J) ϩ RT ln(PJ/P°) (4a) Note that, because ln 1 ϭ 0, Gm(J) has its standard value, Gm°(J), when PJ ϭ 1 bar. Thermodynamic arguments (which we do not reproduce here) show that a similar expression applies to solutes and pure substances. In each case, we can write the molar Gibbs free energy of a substance J as Gm(J) ϭ Gm°(J) ϩ RT ln aJ (4b)* with the activity defined as in Section 10.2. For a gas that behaves ideally, Eq. 4b is the same as Eq. 4a. For a solute in an ideal solution, aJ ϭ [J]/c° and Eq. 4b becomes Gm(J) ϭ Gm°(J) ϩ RT ln ([J]͞c°) (4c) Note that Gm(J) has its standard value, Gm°(J), when [J] ϭ 1 molиLϪ1 . For a pure solid or liquid aJ ϭ 1, so Gm(J) ϭ Gm°(J) (4d) That is, for a pure solid or liquid, the molar Gibbs free energy always has its standard value (provided the pressure is 1 bar). We are now ready to find the value of ⌬G at any stage of a reaction from the composition of the reaction mixture at that point. ¢Gr° ¢G° = an¢Gf °(products) - an¢Gf° (reactants) 10.3 THE THERMODYNAMIC ORIGIN OF EQUILIBRIUM CONSTANTS 391 HOW DO WE DO THAT? To keep the units straight, we need to use the “molar” convention for this calculation (in which the n are pure numbers and we write the subscript r on ⌬G) and to use the stoichiometric coefficients in reaction E as pure numbers. To find an expression for ⌬Gr, we substitute Eq. 4 for each substance into Eq. 3a. For example, for the general reaction E, ⌬Gr ϭ {cGm(C) ϩ dGm(D)} Ϫ {aGm(A) ϩ bGm(B)} ϭ {c[Gm°(C) ϩ RT ln aC] ϩ d[Gm°(D) ϩ RT ln aD]} – {a[Gm°(A) ϩ RT ln aA] ϩ b[Gm°(B) ϩ RT ln aB]} ϭ {cGm°(C) ϩ dGm°(D)} Ϫ {aGm°(A) ϩ bGm°(B)} ϩ RT{(c ln aC ϩ d ln aD) Ϫ (a ln aA ϩ b ln aB)} Notice that the combination of the first four terms in the final equation is the standard Gibbs free energy of reaction, ⌬Gr° (Eq. 19 of Chapter 8): ⌬Gr° ϭ {cGm°(C) ϩ dGm°(D)} Ϫ {aGm°(A) ϩ bGm°(B)} Therefore, ⌬Gr ϭ ⌬Gr° ϩ RT{(c ln aC ϩ d ln aD) Ϫ (a ln aA ϩ b ln aB)} 392 CHAPTER 10 CHEMICAL EQUILIBRIA We can also tidy up the four logarithmic terms: From s ln x ϭ ln xs , (c ln aC ϩ d ln aD) Ϫ (a ln aA ϩ b ln aB) ϭ (ln aC c ϩ ln aD d ) Ϫ (ln aA a ϩ ln aB b ) From ln x ϩ ln y ϭ ln xy, (ln aC c ϩ ln aD d ) Ϫ (ln aA a ϩ ln aB b ) ϭ ln aC c aD d Ϫ ln aA a aB b From ln x Ϫ ln y ϭ ln (x͞y), ln aC c aD d Ϫ ln aA a aB b ϭ ln (aC c aD d /aA a aB b ) Overall, therefore, Now we can bring our work together and write: A note on good practice: Notice that by using the “molar” convention, the units match: RT is a molar energy (in joules per mole), and so too are the two Gibbs free energy terms. You should always use the molar convention when RT appears in an equation but is not multiplied by an amount in moles. The expression that we have just derived may be written ⌬Gr ϭ ⌬Gr° ϩ RT ln Q (5)* with the reaction quotient Q defined as (6) Equation 5 shows how the Gibbs free energy of reaction varies with the activities (the partial pressures of gases or molarities of solutes) of the reactants and products. The expression for Q has the same form as the expression for K, but the activities refer to any stage of the reaction. Q = (aC)c (aD)d (aA)a (aB)b ¢Gr = ¢Gr° + RT ln (aC)c (aD)d (aA)a (aB)b (c ln aC + d ln aD) - (a ln aA + b ln aB) = ln (aC)c (aD)d (aA)a (aB)b (a) From Q = (100.)2 (100.)2 * (100.) = 1.00 * 10-2 Q = (aSO3 )2 >(aSO2 )2 (aO2 ) = (PSO3 )2 >(PO2 )2 (PO2 ), EXAMPLE 10.2 Calculating the Gibbs free energy of reaction from the reaction quotient The standard Gibbs free energy of reaction for 2 SO2(g) ϩ O2(g) : 2 SO3(g) is ⌬Gr° ϭ Ϫ141.74 kJиmolϪ1 at 25.00°C. (a) What is the Gibbs free energy of reaction when the partial pressure of each gas is 100. bar? (b) What is the spontaneous direction of the reaction under these conditions? PLAN Calculate the reaction quotient and substitute it and the standard Gibbs free energy of reaction into Eq. 5. If ⌬Gr Ͻ 0, the forward reaction is spontaneous at the given composition. If ⌬Gr Ͼ 0, the reverse reaction is spontaneous at the given composition. If ⌬Gr ϭ 0, there is no tendency to react in either direction; the reaction is at equilibrium. At 298.15 K, RT ϭ 2.479 kJ·molϪ1 . SOLVE (b) Because the Gibbs free energy of reaction is negative, the formation of products is spontaneous (as indicated by the green region in the diagram) at this composition and temperature. Self-Test 10.4A The standard Gibbs free energy of reaction for H2(g) ϩ I2(g) : 2 HI(g) is ⌬Gr° ϭ Ϫ21.1 kJ·molϪ1 at 500. K (at which temperature RT ϭ 4.16 kJ·molϪ1 ). What is the value of ⌬Gr at 500. K when the partial pressures of the gases are bar, bar, and PHI ϭ 0.065 bar? What is the spontaneous direction of the reaction? [Answer: Ϫ45 kJ·molϪ1 ; toward products] Self-Test 10.4B The standard Gibbs free energy of reaction for N2O4(g) : 2 NO2(g) is ⌬Gr° ϭ ϩ4.73 kJ·molϪ1 at 298 K. What is the value of ⌬Gr when the partial pressures of the gases are bar and bar? What is the spontaneous direction of the reaction? Now we come to the most important point in this chapter. At equilibrium, the activities (the partial pressures or molarities) of all the substances taking part in the reaction have their equilibrium values. At this point the expression for Q (in which the activities have their equilibrium values) has become the equilibrium constant, K, of the reaction. That is, At equilibrium, Q ϭ K (7) Thermodynamics has explained the puzzling form of K: it is a direct consequence of Eq. 4b, which shows how the Gibbs free energy of a substance depends on its activity, and is simply the value of Q when all the species have their equilibrium values. We can now take another important step. We know that at equilibrium ⌬Gr ϭ 0 and have just seen that at equilibrium Q ϭ K. It follows from Eq. 5 that, at equilibrium, 0 ϭ ⌬Gr° ϩ RT ln K and therefore that ⌬Gr° ϭ –RT ln K (8)* This fundamentally important equation links thermodynamic quantities—which are widely available from tables of thermodynamic data—and the composition of a system at equilibrium. Note that: • If ⌬Gr° is negative, then ln K must be positive and therefore K Ͼ 1; products are favored at equilibrium. • If ⌬Gr° is positive, then ln K must be negative and therefore K Ͻ 1; reactants are favored at equilibrium. A note on good practice: Always write Eq. 8 with the standard state symbol. Note too that, for the units to match on both sides (joules per mole), and as signaled by the presence of RT not multiplied by an amount in moles, we have to use the “molar” convention for the standard Gibbs free energy. PNO2 = 2.10PN2O4 = 0.80 PI2 = 0.88 PH2 = 1.5 10.3 THE THERMODYNAMIC ORIGIN OF EQUILIBRIUM CONSTANTS 393 From ⌬Gr ϭ ⌬Gr° ϩ RT ln Q, ⌬Gr ϭ Ϫ141.74 kJиmolϪ1 ϩ (2.479 kJ·molϪ1 ) ln (1.00 ϫ 10–2 ) ϭ Ϫ153.16 kJиmolϪ1 Q 0 ⌬G 0.0100 K Evaluate As expected, the equilibrium constant is less than one. A note on good practice: Exponential functions (inverse logarithms, ex ) are very sensitive to the value of x, so carry out all the arithmetic in one step to avoid rounding errors. Self-Test 10.5A Use the thermodynamic data in Appendix 2A to calculate K from the value of ⌬Gr° for the reaction N2O4(g) : 2 NO2(g) at 298 K. [Answer: K ϭ 0.15] Self-Test 10.5B Use the thermodynamic data in Appendix 2A to calculate K from the value of ⌬Gr° for the reaction 2 NO(g) ϩ O2(g) : 2 NO2(g) at 298 K. We can now begin to acquire some insight into why some reactions have large equilibrium constants and others have small ones. It follows from ⌬Gr° ϭ ⌬Hr° Ϫ T⌬Sr° and ⌬Gr° ϭ ϪRT ln K that When we take inverse logarithms of both sides and use exϩy ϭ ex ey , we obtain K ϭ eϪ⌬Hr°/RT ϩ ⌬Sr°/R ϭ eϪ⌬Hr°/RT e⌬Sr°/R (9) We see that K can be expected to be small if ⌬Hr° is positive. An endothermic reaction is therefore likely to have K Ͻ 1 and is unlikely to form much product. Only if ⌬Sr° is large and positive can we expect K Ͼ 1 for an endothermic reaction. Conversely, if a reaction is strongly exothermic, then ⌬Hr° is large and negative. Now we can expect K Ͼ 1 and the products to be favored. In other words, we can expect strongly exothermic reactions to go to completion. ln K = - ¢Gr° RT = - ¢Hr° RT + ¢Sr° R 394 CHAPTER 10 CHEMICAL EQUILIBRIA EXAMPLE 10.3 Predicting the value of K from the standard Gibbs free energy of reaction At 25.00°C, the standard Gibbs free energy of reaction for H2(g) ϩ I2(s) : HI(g) is ϩ1.70kJ·molϪ1 ;calculatetheequilibriumconstantforthisreaction. Anticipate Because the standard Gibbs free energy of the reaction is positive, we should expect the equilibrium constant to be less than 1. PLAN Use Eq. 8, with the temperature in kelvins. SOLVE 1 2 1 2 From ⌬Gr° ϭ ϪRT ln K in the form ln K ϭ Ϫ⌬Gr°/RT, first converting the units of ⌬Gr° to joules per mole and temperature to kelvins, = -0.685 = - 1.70 * 103 8.3145 * 298.15 ln K = - 1.70 * 103 J.mol-1 (8.3145 J.K-1 mol-1 ) * (298.15 K) Take the inverse logarithm (eln x ϭ x) K ϭ 0.50 K 0 1 ⌬GrЊ/RT 0.5 ϩ1.7kJ·molϪ1 The reaction quotient, Q, has the same form as K, the equilibrium constant, except that Q uses the activities evaluated at an arbitrary stage of the reaction. The equilibrium constant is related to the standard Gibbs free energy of reaction by ⌬Gr° ‫؍‬ ؊RT ln K. 10.4 The Extent of Reaction When ⌬Gr° for a reaction is strongly negative, the reaction goes nearly to completion before it reaches equilibrium and the equilibrium reaction mixture consists mainly of products. Because the concentrations or partial pressures of products appear in the numerator of K and those of reactants in the denominator, the numerator will be large and the denominator small. Therefore, the value of K is large. In contrast, when ⌬Gr° for a reaction is strongly positive, equilibrium is reached after very little reaction has taken place, the numerator is small and the denominator large; therefore, K is small. For instance, consider the reaction H2(g) ϩ Cl2(g) #¢4 2 HCl(g) Experiment shows that K ϭ 4.0 ϫ 1018 at 500. K. Such a large value for K tells us that the system reaches equilibrium only when most of the reactants have been converted into HCl. In fact, this reaction essentially goes to completion. Now consider the equilibrium N2(g) ϩ O2(g) #¢4 2 NO(g) Experiment gives K ϭ 3.4 ϫ 10–21 at 800. K. The very small value of K tells us that equilibrium is reached when only a small amount of product has formed. The reactants N2 and O2 are the dominant species in the system at equilibrium. We can summarize these remarks as follows for chemical equations written with the smallest whole-number stoichiometric coefficients (Fig. 10.5): • Large values of K (larger than about 103 ): the equilibrium favors the products. • Intermediate values of K (approximately in the range 10–3 to 103 ): neither reactants nor products are strongly favored at equilibrium. • Small values of K (smaller than about 10–3 ): the equilibrium favors the reactants. The following example shows how to use the equilibrium constant to calculate an equilibrium concentration. K = (PNO)2 PN2 PO2 K = (PHCl)2 PH2 PCl2 10.4 THE EXTENT OF REACTION 395 Because equilibrium constants must be raised to a power when a chemical equation is multiplied by a factor, and therefore change in magnitude, these rules are only general guidelines. FIGURE 10.5 The size of the equilibrium constant indicates whether the reactants or the products are favored. In this diagram, the reactants are represented by blue cubes and the products by yellow cubes. Note that reactants are favored when K is small (top), products are favored when K is large (bottom), and reactants and products are in equal abundance when K ϭ 1. K = 10−3 K = 103 K = 1 Reactants Products EXAMPLE 10.4 Calculating an equilibrium composition Suppose that, in an equilibrium mixture of HCl, Cl2, and H2, the partial pressure of H2 is 4.2 mPa and that of Cl2 is 8.3 mPa. What is the partial pressure of HCl at 500. K, given K ϭ 4.0 ϫ 1018 for H2(g) ϩ Cl2(g) #4 2 HCl(g)? Anticipate Because the equilibrium constant is large, we should expect a high equilibrium partial pressure for the product, HCl. PLAN At equilibrium, the partial pressures of the reactants and products (in bar, 1 bar ϭ 105 Pa) satisfy the expression for K. Therefore, rearrange the expression to give the one unknown concentration, and substitute the data. SOLVE First convert the units of partial pressures to bars using 1 bar ϭ 105 Pa: PH2 ϭ 4.2 ϫ 10–8 bar, PCl2 ϭ 8.3 ϫ 10–8 bar. Write the expression for the equilibrium constant from the chemical equation given. 396 CHAPTER 10 CHEMICAL EQUILIBRIA From K ϭ (PHCl)2 /PH2 PCl2 in the form PHCl ϭ (KPH2 PCl2 )1/2 , PHCl ϭ {(4.0 ϫ 1018 ) ϫ (4.2 ϫ 10–8 ) ϫ (8.3 ϫ 10–8 )}1/2 ϭ 1.2 ϫ 102 Evaluate As expected, at equilibrium, the partial pressure of product in the system, 120 bar, is overwhelming relative to the tiny partial pressures of the reactants. Self-Test 10.6A Suppose that the equilibrium partial pressures of H2 and Cl2 are both 1.0 ␮Pa. What is the equilibrium partial pressure of HCl at 500. K, given K ϭ 4.0 ϫ 1018 ? [Answer: PHCl ϭ 20. mbar] Self-Test 10.6B Suppose that the equilibrium partial pressures of N2 and O2 in the reaction N2(g) ϩ O2(g) #4 2 NO(g) at 800. K are both 52 kPa. What is the partial pressure (in pascals) of NO at equilibrium if K ϭ 3.4 ϫ 10–21 at 800. K? If K is large, products are favored at equilibrium (the equilibrium “lies to the right”); if K is small, reactants are favored (the equilibrium “lies to the left”). 10.5 The Direction of Reaction Now suppose that the system treated in Example 10.4 is not at equilibrium. For example, we may be given the concentrations of reactants and products for some arbitrary stage of a reaction. Can we tell whether it is at equilibrium or whether it has a tendency to form more products or to decompose into reactants? To answer this question, we first need the equilibrium constant. We may have to determine it experimentally or calculate it from standard Gibbs free energy data. Then we calculate the reaction quotient, Q, from the actual composition of the reaction mixture, as described in Section 10.3. To predict whether that mixture of reactants and products will tend to produce more products or more reactants, we compare Q with K: • If Q Ͻ K, ⌬G is negative; the concentrations or partial pressures of the products are too low relative to those of the reactants for equilibrium. Hence, the reaction has a tendency to proceed toward products. • If Q ϭ K, ⌬G is zero; the mixture has its equilibrium composition and has no tendency to change in either direction. • If Q Ͼ K, ⌬G is positive; the reverse reaction is spontaneous and the products tend to decompose into the reactants. This pattern is summarized in Fig. 10.6. The same pattern is seen when we plot the Gibbs free energy of a reaction mixture against its changing composition, as we did in Fig. 10.4. Reaction tends to proceed toward the composition at the lowest point of the curve, because that is the direction of decreasing Gibbs free energy. The composition at the lowest point of the curve—the point of minimum Gibbs free energy—corresponds to equilibrium. For a system at equilibrium, any change would lead to a reaction mixture with a greater Gibbs free energy, and so neither the forward nor the reverse reaction is spontaneous. When the minimum value of the Gibbs free energy lies very close to pure products, the equilibrium composition strongly favors products and “goes to completion” (Fig. 10.7a). When the Gibbs free energy minimum lies very close to the pure reactants, the equilibrium composition strongly favors the reactants and the reaction “does not go” (Fig. 10.7b). A note on good practice: Whether or not a reaction is spontaneous depends on the composition, so it is better to say that K Ͼ 1 for a reaction with a negative ⌬Gr° rather than that it is spontaneous. However, for reactions with very large equilibrium constants, it is very unlikely that the mixture of reagents prepared in the laboratory will correspond to Q Ͼ K, and it is common to refer to such reactions as “spontaneous.” Reaction at equilibrium Q Q QK Reactants tend to form products Products tend to decompose into reactants FIGURE 10.6 The relative sizes of the reaction quotient Q and the equilibrium constant K indicate the direction in which a reaction mixture tends to change. The arrows show that when Q Ͻ K, reactants form products (left) and when Q Ͼ K, products form reactants (right). There is no tendency to change once the reaction quotient has become equal to the equilibrium constant. Animation 10.6 Because Q Ͻ K, we conclude that the reaction will tend to form more product and consume reactants. Self-Test 10.7A A mixture of H2, N2, and NH3 with partial pressures 22 kPa, 44 kPa, and 18 kPa, respectively, was prepared and heated to 500. K, at which temperature K ϭ 3.6 ϫ 10Ϫ2 for reaction C. Decide whether ammonia tends to form or decompose. [Answer Q ϭ 6.9; tends to decompose] Self-Test 10.7B For the reaction N2O4(g) #4 2 NO2(g) at 298 K, K ϭ 0.15. A mixture of N2O4 and NO2 with initial partial pressures of 2.4 and 1.2 bar, respectively, was prepared at 298 K. Which compound will tend to increase its partial pressure? A reaction has a tendency to form products if Q Ͻ K and to form reactants if Q Ͼ K. EQUILIBRIUM CALCULATIONS We have seen that the value of an equilibrium constant tells us whether we can expect a high or low concentration of product at equilibrium. The constant also allows us to predict the spontaneous direction of reaction in a reaction mixture of any composition. In the following three sections, we see how to express the equilibrium constant in terms of molar concentrations of gases as well as partial pressures and how to predict the equilibrium 10.5 THE DIRECTION OF REACTION 397 FIGURE 10.7 (a) A reaction that has the potential to go to completion (K Ͼ 1) is one in which the minimum of the freeenergy curve (the position of equilibrium) lies close to pure products. (b) A reaction that has little tendency to form products (K Ͻ 1) is one in which the minimum of the free-energy curve lies close to pure reactants. ΔG° < 0 ΔG° > 0 Equilibrium, K > 1 Equilibrium, K < 1 Progress of reaction Progress of reaction Gibbsfreeenergy,G Gibbsfreeenergy,G Pure reactants Pure products Pure reactants Pure products (a) (b) EXAMPLE 10.5 Predicting the direction of reaction A mixture of hydrogen, iodine, and hydrogen iodide, each at 55 kPa, was introduced into a container heated to 783 K. At this temperature, K ϭ 46 for H2(g) ϩ I2(g) #4 2 HI(g). Predict whether HI has a tendency to form or to decompose into H2(g) and I2(g). PLAN If Q Ͼ K, the products need to decompose into reactants until their concentrations match K. The opposite is true if Q Ͻ K: in that case, more products need to form. Therefore, we need to calculate Q and compare it with K. SOLVE Substitute the data, noting that 55 kPa is equivalent to 0.55 bar, in the reaction quotient. Gibbsenergy ReactionR P Q = 1 K = 46 From Q ϭ (PHI)2 /PH2 PI2, Q = (0.55)2 0.55 * 0.55 = 1.0 compositionof areactionmixture,giventhevalueof theequilibriumconstantforthereaction. Such information is critical to the success of many industrial processes and is fundamental to the discussion of acids and bases in the following chapters. 10.6 The Equilibrium Constant in Terms of Molar Concentrations of Gases The equilibrium constant in Eq. 2 is defined in terms of activities, and the activities are interpreted in terms of the partial pressures or concentrations. Gases always appear in K as the numerical values of their partial pressures in bar and solutes always appear as the numerical values of their molarities. Often, however, in areas such as kinetics and atmospheric chemistry, we want to discuss gas-phase equilibria in terms of molar concentrations (the amount of gas molecules in moles divided by the volume of the container, [J] ϭ nJ/V), not partial pressures. To do so, we introduce the equilibrium constant Kc, which for reaction E is defined as (10) with each molar concentration raised to a power equal to the stoichiometric coefficient of the species in the chemical equation. As usual, we have replaced [J]/c° by [J] itself, which represents the numerical value of the molar concentration of the gas J. For example, for the ammonia synthesis equilibrium, reaction C, (11) We are free to choose either K or Kc to report the equilibrium constant of a reaction. However, it is important to remember that calculations of an equilibrium constant from thermodynamic tables of data (standard Gibbs free energies of formation, for instance) and Eq. 8 give K, not Kc. In some cases, we need to know Kc after we have calculated K from thermodynamic data, and so we need to be able to convert between these two constants. Kc = [NH3]2 [N2][H2]3 Kc = [C]c [D]d [A]a [B]b 398 CHAPTER 10 CHEMICAL EQUILIBRIA HOW DO WE DO THAT? The overall strategy for finding the relation between K and Kc is to replace the partial pressures that appear in K by the molar concentrations and thereby generate Kc. For this calculation, we write activities as PJ/P° and [J]/c° and keep track of the units by keeping P° and c° in our expressions. Our starting point is Eq. 1b in its complete form: The molar concentration of a gas J is [J] ϭ nJ/V. We assume ideal gas behavior and write the ideal gas law PJV ϭ nJRT as When this expression is substituted for each gas in the expression for K, we obtain At this point we recognize that Kc, Eq. 10, in its complete form can be written as follows: and therefore [C]c [D]d [A]a [B]b = Kc (c°)a+b-(c+d) Kc = ([C]>c°)c ([D]>c°)d ([A]>c°)a ([B]>c°)b = (c°)a+b [C]c [D]d (c°)c+d [A]a [B]b = (c°)a+b-(c+d) [C]c [D]d [A]a [B]b (PC)c (PD)d (PA)a (PB)b = (RT[C])c (RT[D])d (RT[A])a (RT[B])b = (RT)c+d-(a+b) [C]c [D]d [A]a [B]b PJ = nJRT V = RT nJ V = RT[J] K = (PC>P°)c (PD>P°)d (PA>P°)a (PB>P°)b = (P°)a+b (PC)c (PD)d (P°)c+d (PA)a (PB)b = (P°)a+b-(c+d) (PC)c (PD)d (PA)a (PB)b When we substitute this expression into the equation for the ratio of partial pressures we obtain We conclude that A useful way to remember the general form of the expression that we have derived is to write it as (12a)* where ⌬n is the difference of stoichiometric coefficients for gas-phase species in the chemical equation, calculated as ⌬n ϭ nproducts Ϫ nreactants (so ⌬n ϭ 2 Ϫ (1 ϩ 3) ϭ Ϫ2 for reaction C). If no gases take part in the reaction or if ⌬n ϭ 0, then K ϭ Kc. The same relation holds between Q and Qc, the reaction quotient in terms of concentrations. Equation 12a is commonly written more succinctly as K ϭ (RT)⌬n Kc (12b) but the full version clarifies the units and should be used in calculations. Some values of Kc are listed in Table 10.2. Thinking point: Suppose the gases involved in a reaction behave as real gases with significant intermolecular attractions. Would the value of Kc calculated from Eq. 12 be too high, too low, or the same as the actual value? K = a c°RT P° b ¢n Kc K = (P°)a+b-(c+d) (c°RT)c+d-(a+b) Kc = a c°RT P° b c+d-(a+b) Kc (PC)c (PD)d (PA)a (PB)b = (RT)c+d-(a+b) Kc (c°)a+b-(c+d) = (c°RT)c+d-(a+b) Kc 10.6 THE EQUILIBRIUM CONSTANT IN TERMS OF MOLAR CONCENTRATIONS OF GASES 399 EXAMPLE 10.6 Converting between K and Kc At 400.°C, the equilibrium constant K for 2 SO2(g) ϩ O2(g) #4 2 SO3(g) is 3.1 ϫ 104 . What is the value of Kc at this temperature? PLAN Because P° ϭ 1 bar and c° ϭ 1 molиLϪ1 , it is sensible to use R expressed in bars and liters, R ϭ 8.3145 ϫ 10Ϫ2 L·bar·KϪ1 иmolϪ1 , and to note that Then, Eq. 12a can be written as To use this equation, identify the value of ⌬n for the reaction, convert the temperature to the Kelvin scale, and rearrange it to solve for Kc. What should we assume? That the gases are ideal. SOLVE K = a T 12.03 K b ¢n Kc P° Rc° = 1 bar (8.3145 LиbarиK-1 mol-1 ) * (1 molиL-1 ) = 12.03 K From the chemical equation, ⌬n ϭ 2 Ϫ (2 ϩ 1) ϭ Ϫ1 and T ϭ 400. ϩ 273.15 K ϭ 673 K From K ϭ (T/12.03 K)⌬n Kc in the form Kc ϭ (T/12.03 K)Ϫ⌬n K, Kc = a 673 K 12.03 K b * (3.1 * 104 ) = 1.7 * 106 Self-Test 10.8A The equilibrium constant for the ammonia synthesis (reaction C) is K ϭ 41 at 127°C. What is the value of Kc at that temperature? [Answer: ⌬n ϭ Ϫ2; so Kc ϭ 4.5 ϫ 104 ] 400 CHAPTER 10 CHEMICAL EQUILIBRIA Self-Test 10.8B At 127°C, the equilibrium constant for N2O4(g) #4 2 NO2(g) is K ϭ 47.9. What is the value of Kc at that temperature? For thermodynamic calculations, gas-phase equilibria are expressed in terms of K but, for practical calculations, they may be expressed in terms of molar concentrations by using Eq. 12. 10.7 Alternative Forms of the Equilibrium Constant The powers to which the activities are raised in the expression for an equilibrium constant must match the stoichiometric coefficients in the chemical equation, which is normally written with the smallest whole numbers for coefficients. Therefore, if we change the stoichiometric coefficients in a chemical equation (for instance, by multiplying through by a factor), then we must make sure that the equilibrium constant corresponds to that change. For example, at 700 K, H2(g) ϩ I2(g) #¢4 2 HI(g) If we rewrite the chemical equation by multiplying through by 2, the equilibrium constant becomes 2 H2(g) ϩ 2 I2(g) #¢4 4 HI(g) In general: • If we multiply a chemical equation by a factor n, we raise K (and Kc) to the nth power. Now suppose we reverse the original equation for the reaction: 2 HI(g) ¬sR¬ H2(g) ϩ I2(g) This equation still describes the same equilibrium; but we write the equilibrium constant for this equation as In general: • The equilibrium constant for an equilibrium written in one direction is the reciprocal of the equilibrium constant for the equilibrium written in the opposite direction. A note on good practice: As these examples have shown, it is important to specify the chemical equation to which the equilibrium constant applies. If a chemical equation can be expressed as the sum of two or more chemical equations, • The equilibrium constant for the overall reaction is the product of the equilibrium constants for the component reactions. For example, consider the three gas-phase reactions 2 P(g) ϩ 3 Cl2(g) #¢4 2 PCl3(g) PCl3(g) ϩ Cl2(g) #¢4 PCl5(g) 2 P(g) ϩ 5 Cl2(g) #¢4 2 PCl5(g) K3 = (PPCl5 )2 (PP)2 (PCl2 )5 K2 = PPCl5 PPCl3 PCl2 K1 = (PPCl3 )2 (Pp)2 (PCl2 )3 Kc3 = [H2][I2] [HI]2 = 1 Kc1 = 1 54 = 0.019 Kc2 = [HI]4 [H2]2 [I2]2 = (54)2 = 2.9 * 103 Kc1 = [HI]2 [H2][I2] = 54 The third reaction is the following sum of the first two reactions (notice that we multiplied the second one by a factor of 2): 2 P(g) ϩ 3 Cl2(g) #¢4 2 PCl3(g) 2 PCl3(g) ϩ 2 Cl2(g) #¢4 2 PCl5(g) 2 P(g) ϩ 5 Cl2(g) #¢4 2 PCl5(g) and the equilibrium constant, K3, of the overall reaction can be written K1 K2 2 Notice that, because we multiplied the second reaction by two to obtain the sum, its equilibrium constant has been raised to the second power. Self-Test 10.9A At 500. K, K for H2(g) ϩ D2(g) #4 2 HD(g) is 3.6. What is the value of K for 4 HD(g) #4 2 H2(g) ϩ 2 D2(g)? [Answer: 0.077] Self-Test 10.9B At 500. K, Kc for F2(g) #4 2 F(g) is 7.3 ϫ 10Ϫ13 . What is the value of Kc for F2(g) #4 F(g)? Table 10.3 summarizes the relations between equilibrium constants for the same reaction written in different ways. 10.8 Using Equilibrium Constants The equilibrium constant of a reaction contains information about the equilibrium composition at the given temperature. However, in many cases, we know only the initial composition of the reaction mixture and are given apparently incomplete information about the equilibrium composition. In fact, the missing information can usually be inferred by using the reaction stoichiometry. The easiest way to proceed is to draw up an equilibrium table, a table showing the initial composition, the changes needed to reach equilibrium in terms of some unknown quantity x, and the final equilibrium composition. The procedure is summarized in Toolbox 10.1 and illustrated in the examples that follow. 1 2 K3 = (PPCl5 )2 (PP)2 (PCl2 )5 = (PPCl3 )2 (PP)2 (PCl2 )3 * (PPCl5 )2 (PPCl3 )2 (PCl2 )2 = K1K2 2 10.8 USING EQUILIBRIUM CONSTANTS 401 $+%+& $+%+& TABLE 10.3 Relations Between Equilibrium Constants* Equilibrium Chemical equation constant a A ϩ b B #¢4 c C ϩ d D K1 c C ϩ d D #¢4 a A ϩ b B K2 ϭ 1/K1 ϭ K1 Ϫ1 na A ϩ nb B #¢4 nc C ϩ nd D K3 ϭ K1 n *For a reaction that can be expressed as the sum of other reactions, the equilibrium constant is the product of the equilibrium constants of the component reactions TOOLBOX 10.1 HOW TO SET UP AND USE AN EQUILIBRIUM TABLE CONCEPTUAL BASIS The composition of a reaction mixture tends to adjust until the molar concentrations or partial pressures of gases ensure that Qc ϭ Kc and Q ϭ K. A change in the abundance of any one component is linked to changes in the others by the reaction stoichiometry. PROCEDURE Step 1 Write the equilibrium constant for the balanced chemical equation (the equation must be given, because the stoichiometric coefficients are needed to write K). Then set up an equilibrium table as shown here, with columns labeled by the species taking part in the reaction. In the first row, show the initial composition (molar concentration or partial pressure) of each species, but ignore pure liquids and solids. The first line in the table shows how the reaction system was prepared before reaction began. As always, use molar concentrations (in moles per liter) and partial pressures (in bars) but strike out the units. Omit pure solids and liquids. Species 1 Species 2 Species 3 . . . Initial . . .composition Change in . . .composition Final . . .composition Step 2 In the second row, write the changes in the composition that are needed for the reaction to reach equilibrium. When we do not know the changes, write one of them as x or a multiple of x and then use the stoichiometry of the balanced equation to express the other changes in terms of that x. Step 3 In the third row, write the equilibrium compositions in terms of x by adding the change in composition (from step 2) to the initial value for each substance (from step 1). 402 CHAPTER 10 CHEMICAL EQUILIBRIA Pressure(bar) 6.21 Volume (L) 0.933 mol From PJ ϭ nJRT/V, ϭ 6.21 bar = (0.933 mol) * (8.3145 * 10-2 LиbarиK-1 mol-1 ) * (800. K) 10.0 L PO2 Although a change in composition may be positive (an increase) or negative (a decrease), the value of each concentration or partial pressure itself must be positive. Step 4 Use the equilibrium constant to determine the value of x, the unknown change in molar concentration or partial pressure. A note on good practice: A good habit to adopt is to check the answer by substituting the equilibrium composition into the expression for K. An approximation technique can greatly simplify calculations when the change in composition (x) is less than about 5% of the initial value. To use it, assume that x is negligible when added to or subtracted from a number. Thus, we can replace all expressions like A ϩ x or A – 2x, by A. When x occurs on its own (not added to or subtracted from another number), it is left unchanged. So, an expression such as (0.1 – 2x)2 x simplifies to (0.1)2 x, provided that 2x ϽϽ 0.1 (specifically, if 2x Ͻ 0.005). At the end of the calculation, it is important to verify that the calculated value of x is indeed smaller than 5% of the initial values. If it is not, then we must solve the equation without making an approximation. The approximation procedure is illustrated in Example 10.7. In some cases, the full equation for x is a quadratic equation of the form ax2 ϩ bx ϩ c ϭ 0 When the approximation procedure is invalid, we use the exact solutions of this equation, which are We have to decide which of the two solutions given by this expression is valid (the one with the ϩ sign or the one with the – sign in front of the square root) by seeing which solution is chemically possible. See Example 10.8 for an illustration of this procedure. For some reactions, the equation for x in terms of K may be a higher-order polynomial. If an approximation is not valid, one approach to solving the equation is to use a graphing calculator or mathematical software to find the roots of the equation. The web site for this textbook has tools that can be used to solve such equations. x = -b ; (b2 - 4ac)1>2 2a EXAMPLE 10.7 Calculating the equilibrium composition by approximation Under certain conditions, nitrogen and oxygen react to form dinitrogen oxide, N2O. Suppose that a mixture of 0.482 mol N2 and 0.933 mol O2 is transferred to a reaction vessel of volume 10.0 L and allowed to form N2O at 800. K; at this temperature K ϭ 3.2 ϫ 10Ϫ28 for the reaction 2 N2(g) ϩ O2(g) #4 2 N2O(g). Calculate the partial pressures of the gases in the equilibrium mixture. Anticipate Because the equilibrium constant is so small, we should expect that equilibrium will be reached when only a very small amount of product has formed. PLAN Use the procedure in Toolbox 10.1. What should we assume? That the amount of product formed will be so small that the change in partial pressures of the reactants is negligible. SOLVE The equilibrium constant for the reaction is K ϭ (PN2O)2 /(PN2 )2 PO2 . The initial partial pressures are Pressure(bar) 3.21 Volume (L) 0.482 mol From PJ ϭ nJRT/V, ϭ 3.21 bar = (0.482 mol) * (8.3145 * 10-2 LиbarиK-1 mol-1 ) * (800. K) 10.0 L PN2 The stoichiometry of the reaction implies that, if the partial pressure of O2 decreases by x, then the partial pressure of N2 decreases by 2x and that of N2O increases by 2x. Because there is no N2O present initially, the equilibrium table, with all partial pressures in bar, is N2 O2 N2O Step 1 Initial partial pressure 3.21 6.21 0 Step 2 Changes in partial pressure Ϫ2x Ϫx ϩ2x Step 3 Equilibrium partial pressure 3.21 Ϫ 2x 6.21 Ϫ x 2x Step 4 From K ϭ (PN2O)2 ͞(PN2 )2 (PO2 ) When rearranged, this equation is a cubic equation (an equation in x3 ), which can be solved with a graphing calculator or mathematical software. However, because K is very small, we suppose that x will turn out to be so small that we can use the approximation procedure: K = (2x)2 (3.21 - 2x)2 * (6.21 - x) 10.8 USING EQUILIBRIUM CONSTANTS 403 and therefore PN2O ϭ 0 Replace 3.21 Ϫ 2x by 3.21 and 6.21 Ϫ x by 6.21. K L (2x)2 (3.21)2 * (6.21) Rearrange into an equation for x. x L e (3.21)2 * (6.21) * K 4 f 1/2 Substitute the value of K. x L e (3.21)2 * (6.21) * (3.2 * 10-28 ) 4 f 1/2 = 7.2 * 10-14 The value of 2x is very small compared with 3.21 (far smaller than 5% of it), and so the approximation is valid. We conclude that, at equilibrium: 6.21 bar O2 N2 3.21 bar ϫ 1013 1.4 N2O From PN2 ϭ 3.21 Ϫ 2x bar, PN2 ϭ 3.21 bar From PO2 ϭ 6.21 Ϫ x bar, PO2 ϭ 6.21 bar From PN2O ϭ 2x bar, PN2O ϭ 1.4 ϫ 10Ϫ13 bar Evaluate As expected, very little product has formed. When substituted into the full expression for the equilibrium constant, these values give K ϭ 3.1 ϫ 10Ϫ28 , in good agreement with the experimental value. Self-Test 10.10A The initial partial pressures of nitrogen and hydrogen in a rigid, sealed vessel are 0.010 and 0.020 bar, respectively. The mixture is heated to a temperature at which K ϭ 0.11 for N2(g) ϩ 3 H2(g) #4 2 NH3(g). What are the equilibrium partial pressures of each substance in the reaction mixture? [Answer: N2: 0.010 bar; H2: 0.020 bar; NH3: 9.4 ϫ 10Ϫ5 bar] Self-Test 10.10B Hydrogen chloride gas is added to a reaction vessel containing solid iodine until its partial pressure reaches 0.012 bar. At the temperature of the experiment, K ϭ 3.5 ϫ 10Ϫ32 for 2 HCl(g) ϩ I2(s) #4 2 HI(g) ϩ Cl2(g). Assume that some I2 remains at equilibrium. What are the equilibrium partial pressures of each gaseous substance in the reaction mixture? 404 CHAPTER 10 CHEMICAL EQUILIBRIA EXAMPLE 10.8 Calculating the equilibrium composition by using a quadratic equation Suppose that we place 3.12 g of PCl5 in a reaction vessel of volume 500. mL and allow the sample to reach equilibrium with its decomposition products phosphorus trichloride and chlorine at 250.°C, when K ϭ 78.3 for the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g). All three substances are gases at 250°C. Find the composition of the equilibrium mixture in moles per liter. Anticipate Because the equilibrium constant is neither very small nor very large, we should expect that the partial pressures of reactants and products at equilibrium will be similar to each other. PLAN Use the general procedure set out in Toolbox 10.1. SOLVE The equilibrium constant for the reaction is K ϭ PPCl3 PCl2 ͞PPCl5 . First, we calculate the initial partial pressure of PCl5 (the initial partial pressures of PCl2 and Cl2 are zero): From nJ ϭ mJ/MJ, the amount of PCl5 added is: nPCl5 = 3.12 g 208.24 gиmol-1 = 3.12 208.24 mol (= 0.0150 mol) Pressure(bar) 1.30 Volume (L) 15.0 mmol, 523 K From PJ ϭ nJRT/V, the initial partial pressure of PCl5 is therefore = 1.30 bar * (8.3145 * 10-2 LиbarиK-1 mol-1 ) * (523 K) 0.500 L PPCl5 = a 3.12 208.24 molb Use PPCl5 ϭ 1.30 in the expression for K and let the change in its partial pressure be Ϫx. Construct the following table, with all partial pressures in bars. PCl5 PCl3 Cl2 Step 1 Initial partial pressure 1.30 0 0 Step 2 Change in partial pressure Ϫx ϩx ϩx Step 3 Equilibrium partial pressure 1.30 Ϫ x x x From K ϭ PPCl3 PCl2 ͞PPCl5 , K = x2 1.30 - x Rearrange the equation: x2 ϩ Kx Ϫ 1.30K ϭ 0 Substitute the value of K: x2 ϩ 78.3x Ϫ 102 ϭ 0 Ϫ79.6 1.28 0 x Solve for x by using the quadratic formula x ϭ {Ϫb Ϯ (b2 Ϫ 4ac)1/2 }/2a. = -79.6 or 1.28 x = -78.3 ; {(78.3)2 - 4 * (-102)}1/2 2 10.8 USING EQUILIBRIUM CONSTANTS 405 Because the partial pressures must be positive and because x is the partial pressure of PCl3, we select 1.28 as the solution. It follows that, at equilibrium: PCl3 PCl5 0.02 1.28 bar 1.28 bar Cl2 From PPCl5 ϭ 1.30 – x bar, PPCl5 ϭ 1.30 Ϫ 1.28 bar ϭ 0.02 bar From PPCl3 ϭ x bar, PPCl3 ϭ 1.28 bar From PCl2 ϭ x bar, PCl2 ϭ 1.28 bar Evaluate As expected, the equilibrium concentrations of reactants and products have similar values. Figure 10.8 illustrates how the reaction approaches equilibrium. Self-Test 10.11A Bromine monochloride, BrCl, decomposes into bromine and chlorine and reaches the equilibrium 2 BrCl(g) #4 Br2(g) ϩ Cl2(g), for which K ϭ 32 at 500. K. If initially pure BrCl is present at a concentration of 3.30 mbar, what is its partial pressure in the mixture at equilibrium? [Answer: 0.3 mbar] Self-Test 10.11B Chlorine and fluorine react at 2500. K to produce ClF and reach the equilibrium Cl2(g) ϩ F2(g) #4 2 ClF(g) with K ϭ 20. If a gaseous mixture with PCl2 ϭ 0.200 bar, PF2 ϭ 0.100 bar, and PClF ϭ 0.100 bar is allowed to come to equilibrium at 2500. K, what is the partial pressure of ClF in the equilibrium mixture? To calculate the equilibrium composition of a reaction mixture, set up an equilibrium table in terms of changes in the concentrations of reactants and products, express the equilibrium constant in terms of those changes, and solve the resulting equation. THE RESPONSE OF EQUILIBRIA TO CHANGES IN CONDITIONS Because chemical equilibria are dynamic, they respond to changes in the conditions under which a reaction is taking place. When we disturb an equilibrium by adding or removing a reactant, the value of ⌬G is changed and the composition shifts until ⌬G ϭ 0 again. The composition also might change in response to a change in pressure or temperature. In the following sections, we shall see how Haber used this responsiveness to control the equilibrium between ammonia, nitrogen, and hydrogen to increase the production of ammonia. We can predict how the composition of a reaction mixture at equilibrium tends to change when the conditions are changed by following the general principle identified by the French chemist Henri Le Chatelier (Fig. 10.9): Le Chatelier’s principle: When a stress is applied to a system in dynamic equilibrium, the equilibrium tends to adjust to minimize the effect of the stress. This empirical principle is no more than a rule of thumb. It provides neither an explanation nor a quantitative prediction. However, we shall see that it is consistent with thermodynamics; and, as we develop it, we shall see the powerful quantitative conclusions that can be drawn from thermodynamics. 10.9 Adding and Removing Reagents We start by considering changes in the composition of a system. Let’s suppose that the ammonia synthesis reaction (reaction C) has reached equilibrium. Now suppose that we pump in more hydrogen gas. According to Le Chatelier’s principle, the increase in the concentration of hydrogen molecules will tend to be minimized by the reaction of hydrogen with nitrogen. As a result, additional ammonia will be formed. If, instead of Time Partialpressure(bar) 0 0.5 1 1.5 1.28 0.02 PCl5 PCl3, Cl2 1.30 FIGURE 10.8 The approach of the composition of the reaction mixture to equilibrium when PCl5 decomposes in a closed container. Note that the curves for Cl2 and PCl3 are superimposed, as they increase by the same amount. FIGURE 10.9 Henri Le Chatelier (1850–1936). hydrogen, we were to add some ammonia, then the reaction would tend instead to form reactants at the expense of the added ammonia (Fig. 10.10). Thinking point: Suppose one of the products of a reaction at equilibrium is a pure solid. How will the equilibrium be affected if some of the solid is removed? If all the solid is removed? We can explain these responses thermodynamically by considering the relative sizes of Q and K (Fig. 10.11). When reactants are added, the reaction quotient Q falls below K, because the reactant concentrations in the denominator of Q increase. As we have seen, when Q Ͻ K, the reaction mixture responds by forming products until Q is restored to K. Likewise, when products are added, Q rises above K, because products appear in the numerator. Then, because Q Ͼ K, the reaction mixture responds by forming reactants at the expense of products until Q ϭ K again. It is important to understand that K is a constant that is not altered by changing concentrations. Only the value of Q changes, and always in a way that brings its value closer to that of K. 406 CHAPTER 10 CHEMICAL EQUILIBRIA Time Molarconcentration Hydrogen Nitrogen Ammonia Hydrogen added Ammonia added FIGURE 10.10 These graphs show the changes in composition that can be expected when additional hydrogen and then ammonia are added to an equilibrium mixture of nitrogen, hydrogen, and ammonia. Note that the addition of hydrogen results in the formation of ammonia, whereas the addition of ammonia results in the decomposition of some of the added ammonia as reactants are formed. In each case, the mixture settles into a composition in accord with the equilibrium constant of the reaction. Reactants added Products form Products added Reactants form (a) K = 1 Q Ͻ K K = 1 (b) K = 1 Q Ͼ K K = 1 FIGURE 10.11 (a) When a reactant (blue) is added to a reaction mixture at equilibrium, Q Ͻ K and products have a tendency to form. (b) When a product (yellow) is added instead, Q Ͼ K and reactants tend to be formed. For this reaction, we have used K ϭ 1 for the equilibrium blue #4 yellow. Animation 10.11 EXAMPLE 10.9 Predicting the effect of adding or removing reactants and products Consider the equilibrium 4 NH3(g) ϩ 3 O2(g) #¢4 2 N2(g) ϩ 6 H2O(g) Predict the effect on each equilibrium concentration of (a) the addition of N2; (b) the removal of NH3; (c) the removal of H2O. Anticipate Because the addition of a reactant or the removal of a product cause a shift toward the formation of product, and vice versa, we should expect that (a) and (b) will shift the equilibrium toward reactants whereas (c) will shift the reaction toward products. PLAN Consider how each change will affect the value of Q and what change is then needed to re-establish equilibrium. SOLVE For this reaction Q = (PN2 )2 (PH2O)6 (PNH3 )4 (PO2 )3 (a) The addition of N2 (a product) to the equilibrium mixture increases Q above K, so the equilibrium adjusts as reactants are formed at the expense of products. (b) When NH3 is removed from the system at equilibrium, Q rises above K so, once again, the equilibrium adjusts as reactants are formed at the expense of products. (c) The removal of H2O reduces Q below K, so more products form at the expense of reactants. Self-Test 10.12A Consider the equilibrium SO3(g) ϩ NO(g) #4 SO2(g) ϩ NO2(g). Predict the effect on the equilibrium of (a) the addition of NO; (b) the addition of NO2; (c) the removal of SO2. Answer: The equilibrium tends to shift toward (a) products; (b) reactants; (c) products.] Self-Test 10.12B Consider the equilibrium CO(g) ϩ 2 H2(g) #4 CH3OH(g). Predict the effect on the equilibrium of (a) the addition of H2; (b) the removal of CH3OH; (c) the removal of CO. Le Chatelier’s principle suggests a good way of ensuring that a reaction goes on generating a substance: simply remove products as they are formed. In its continuing hunt for equilibrium, the reaction generates more product. Industrial processes rarely reach equilibrium, for just this reason. In the commercial synthesis of ammonia, for instance, ammonia can be continuously removed by circulating the equilibrium mixture through a refrigeration unit in which only the ammonia condenses. Therefore, the hydrogen and nitrogen continue to react to form more product. 10.9 ADDING AND REMOVING REAGENTS 407 EXAMPLE 10.10 Calculating the equilibrium composition after addition of a reagent Suppose that the equilibrium mixture for the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g) considered in Example 10.8 is perturbed by adding 0.0100 mol Cl2(g) to the container (of volume 500. mL); then the system is once again allowed to reach equilibrium. Use this information and data from Example 10.8 to calculate the new composition of the equilibrium mixture. Anticipate Because a product has been added, we expect the reaction to respond by producing more reactants. PLAN The general procedure is like that set out in Toolbox 10.1. Write the expression for the equilibrium constant, and then set up an equilibrium table. In this case, use as the initial partial pressures those found immediately after addition of the reagent, but before the reaction has responded. Obtain the initial equilibrium concentrations and the value of K from Example 10.8. SOLVE From Example 10.8 the initial equilibrium partial pressures of the components are PPCl5 ϭ 0.02 bar, PPCl3 ϭ 1.28 bar, and PCl2 ϭ 1.28 bar. The 0.0100 mol Cl2(g) added to the container corresponds to an additional partial pressure of chlorine of Pressure(bar) 0.870 Volume (L) 10.0 mmol, 523 K From PJ ϭ nJRT/V, ϭ 0.870 bar = (0.0100 mol) * (8.3145 * 10-2 LиbarиK-1 mol-1 ) * (523 K) 0.500 L PCl2 The total partial pressure of chlorine immediately after the addition of the chlorine gas is therefore 1.28 ϩ 0.870 bar ϭ 2.15 bar. We draw up the following table, with all partial pressures in bar, noting a decrease for partial pressures of the products and an increase for the partial pressure of the reactant. PCl5 PCl3 Cl2 Step 1 Initial partial pressure 0.02 1.28 2.15 Step 2 Change in partial pressure ϩx Ϫx Ϫx Step 3 Equilibrium partial pressure 0.02 ϩ x 1.28 Ϫ x 2.15 Ϫ x Now we use the equilibrium constant to find x: From K ϭ PPCl3 PCl2 ͞PPCl5 , K = (1.28 - x) * (2.15 - x) 0.02 + x = 2.75 - 3.43x + x2 0.02 + x A note on good practice: Rounding to the correct number of significant figures should be carried out only at the end of a calculation to minimize rounding errors at intermediate stages of the calculation. Accordingly, although the product of 78.3 ϫ 0.02, where 0.02 is a measured quantity with 1 sf, should be rounded to 2, we have retained it as 1.57. 408 CHAPTER 10 CHEMICAL EQUILIBRIA Rearrange the equation with K ϭ 78.3: 78.3(0.02 ϩ x) ϭ 2.75 – 3.43x ϩ x2 1.57 ϩ 78.3x ϭ 2.75 – 3.43x ϩ x2 Hence, x2 – 81.7x ϩ 1.18 ϭ 0 78.3 = 2.75 - 3.43x + x2 0.02 + x 81.70.0144 0 x Solve by using the quadratic formula. x ϭ 81.7 and 0.0144 PCl3 1.27 bar 2.14 bar PCl5 0.03 Cl2 We select x ϭ 0.0144. It follows that, at equilibrium: From PPCl5 ϭ 0.02 ϩ x bar, PPCl5 ϭ 0.02 ϩ 0.01 bar ϭ 0.03 bar From PPCl3 ϭ 1.28 – x bar, PPCl3 ϭ 1.28 – 0.01 bar ϭ 1.27 bar From PCl2 ϭ 2.15 – x bar, PCl2 ϭ 2.15 – 0.01 bar ϭ 2.14 bar Evaluate As anticipated, the partial pressure of reactant has increased and the partial pressures of the products have decreased from their initial values (Fig. 10.12). Self-Test 10.13A Suppose that the equilibrium mixture in Example 10.7 is perturbed by adding 3.00 mol N2(g) and then the system is once again allowed to reach equilibrium. Use this information and data from Example 10.7 to calculate the new composition of the equilibrium mixture. [Answer: 23.2 bar N2; 6.21 bar O2; 1.0 ϫ 10Ϫ12 bar N2O] Self-Test 10.13B Nitrogen, hydrogen, and ammonia gases have reached equilibrium in a container of volume 1.00 L at 298 K. Equilibrium partial pressures are 0.080 atm N2, 0.050 atm H2, and 2.60 atm NH3. For N2(g) ϩ 3 H2(g) #4 2 NH3(g), K ϭ 6.8 ϫ 105 . Calculate the new equilibrium partial pressures if half the NH3 is removed from the container and equilibrium is reestablished. When the equilibrium composition is perturbed by adding or removing a reactant or product, reaction tends to occur in the direction that restores the value of Q to that of K. 10.10 Compressing a Reaction Mixture A gas-phase equilibrium may respond to compression—a reduction in volume—of the reaction vessel. According to Le Chatelier’s principle, the composition will tend to change in a way that minimizes the resulting increase in pressure. For instance, in the dissociation of gaseous I2 to form I atoms, I2(g) #4 2 I(g), 1 mol of gaseous reactant molecules produces 2 mol of gaseous product molecules. The forward reaction increases the number of particles in the container and hence the total pressure of the system and the reverse reaction decreases it. It follows that, when the mixture is compressed, the equilibrium composition will tend to shift in favor of the reactant, I2, because that response minimizes the increase in pressure (Fig. 10.13). Expansion of the system Time Partialpressure(bar) 0 0.5 1 1.5 0.02 PCl5 2 2.5 0.03 1.27 2.142.15 1.28 PCl3 Cl2 FIGURE 10.12 The response of the equilibrium mixture illustrated in Fig. 10.8 to the addition of chlorine. The curves for Cl2 and PCl3 are superimposed until the additional Cl2 has been added. Compression Expansion FIGURE 10.13 Le Chatelier’s principle predicts that, when a reaction at equilibrium is compressed, the number of molecules in the gas phase will tend to decrease. This diagram illustrates the effect of compression and expansion on the dissociation equilibrium of a diatomic molecule. Note the increase in the relative concentration of diatomic molecules as the system is compressed and the decrease when the system expands. would result in the opposite response, a tendency for I2 to dissociate to free atoms. In the formation of ammonia, 2 mol of gas molecules are produced from 4 mol of gas molecules. Therefore, Haber realized that, to increase the yield of ammonia, he needed to carry out the synthesis with highly compressed gases. The actual industrial process uses pressures of 250 atm and more (Fig. 10.14). 10.10 COMPRESSING A REACTION MIXTURE 409 FIGURE 10.14 One of the high-pressure vessels used for the catalytic synthesis of ammonia. The vessel must be able to withstand internal pressures of greater than 250 atm. EXAMPLE 10.11 Predicting the effect of compression on an equilibrium Predict the effect of compression on the equilibrium composition of the reaction mixtures in which the equilibria (a) 2 NO2(g) #4 N2O4(g) and (b) H2(g) ϩ I2(g) #4 2 HI(g) have been established. PLAN Reaction will take place in the direction that reduces the increase in pressure and fewer gas molecules generate a lower pressure. Therefore, compare the number of reactant gas molecules with the number of product gas molecules. SOLVE (a) In the forward reaction, two NO2 molecules combine to form one N2O4 molecule. Hence, compression favors the formation of N2O4. (b) Because neither direction corresponds to a reduction of gas-phase molecules, compressing the mixture should have no effect on the composition of the equilibrium mixture. (In practice, there will be a small effect due to the nonideality of the gases.) Self-Test 10.14A Predict the effect of compression on the equilibrium composition of the reaction CH4(g) ϩ H2O(g) #4 CO(g) ϩ 3 H2(g). [Answer: Reactants favored] Self-Test 10.14B Predict the effect of compression on the equilibrium composition of the reaction CO2(g) ϩ H2O(l) #4 H2CO3(aq). We can justify the effect of compression on an equilibrium mixture mathematically by showing that compressing a system will change Q, and the reaction tends to adjust in the direction that restores the value of Q to that of K. HOW DO WE DO THAT? Suppose we want to discover the effect of compression on the equilibrium in Example 10.11a. We write the equilibrium constant in its complete form (to be careful with units) as 2 NO2(g) #¢4 N2O4(g) Next, we express K in terms of the volume of the system: K = PN2O4 >P° (PNO2 >P°)2 From PJ ϭ nJRT/V, K = nN2O4 RT>VP° (nNO2 RT>VP°)2 = nN2O4 P°V (nNO2 )2 RT As it should be, this K remains unitless. Now, because P°/RT is a constant at constant temperature, for K to remain constant when the volume (V) of the system is reduced, the ratio nN2O4 ͞(nNO2 )2 must increase. That is, the amount of NO2 must decrease and the amount of N2O4 must increase. Therefore, as we have seen before, as the volume of the system is decreased, the equilibrium shifts to a smaller total number of gas molecules. Conversely, if the system were expanded, the equilibrium would shift in the direction of a larger total number of gas molecules. Suppose that we were to increase the total pressure inside a reaction vessel by pumping in argon or some other inert gas at constant volume. The reacting gases continue to occupy the same volume, and so their individual molar concentrations and partial pressures remain unchanged despite the presence of an inert gas. In this case, therefore, provided that the gases can be regarded as ideal, the equilibrium composition is unaffected despite the fact that the total pressure has increased. Compression of a reaction mixture at equilibrium tends to drive the reaction in the direction that reduces the number of gas-phase molecules; increasing the pressure by introducing an inert gas has no effect on the equilibrium composition. 10.11 Temperature and Equilibrium The equilibrium constant is unchanged when concentrations or pressures change. However, we can see from Table 10.2 that the equilibrium constant does change with temperature. For an exothermic reaction, the formation of products is found experimentally to be favored by lowering the temperature. Conversely, for an endothermic reaction, the products are favored by an increase in temperature. Le Chatelier’s principle is consistent with these observations. We can imagine the heat generated in an exothermic reaction as helping to offset lowering the temperature. Similarly, we can imagine the heat absorbed in an endothermic reaction as helping to offset an increase in temperature. In other words, raising the temperature of a reaction mixture at equilibrium will shift the reaction in the endothermic direction. An example is the decomposition of carbonates. A reaction such as CaCO3(s) #¢4 CaO(s) ϩ CO2(g) is strongly endothermic in the forward direction, and an appreciable partial pressure of carbon dioxide is present at equilibrium only if the temperature is high. For instance, at 800°C, the partial pressure is 0.22 atm at equilibrium. If the heating takes place in an open container, this partial pressure is never reached, because equilibrium is never reached. The gas drifts away, and the calcium carbonate decomposes completely, leaving a solid residue of CaO. However, if the surroundings are already so rich in carbon dioxide that its partial pressure exceeds 0.22 atm, then virtually no decomposition occurs: for every CO2 molecule that is formed, one is converted back into carbonate. This dynamic process is probably what happens on the hot surface of Venus (Fig. 10.15), where the partial pressure of carbon dioxide is about 87 atm. This high pressure has led to speculation that the planet’s surface is rich in carbonates, despite its high temperature (about 500°C). 410 CHAPTER 10 CHEMICAL EQUILIBRIA FIGURE 10.15 A radar image of the surface of Venus. Although the rocks are very hot, the partial pressure of carbon dioxide in the atmosphere is so great that carbonates may be abundant. EXAMPLE 10.12 Predicting the effect of temperature on an equilibrium One stage in the manufacture of sulfuric acid is the formation of sulfur trioxide by the reaction of SO2 with O2 in the presence of a vanadium(V) oxide catalyst. Predict how the equilibrium composition for the sulfur trioxide synthesis will tend to change when the temperature is raised. Anticipate Raising the temperature of an equilibrium mixture will tend to shift its composition in the endothermic direction of the reaction. Combustion reactions are all exothermic, so we should expect the equilibrium of this reaction (which can be viewed as the combustion of sulfur dioxide) to shift in favor of reactants. PLAN We need to verify that the reaction is exothermic. To find the standard reaction enthalpy, use the standard enthalpies of formation given in Appendix 2A. SOLVE The chemical equation is 2 SO2(g) ϩ O2(g) #¢4 2 SO3(g) The standard reaction enthalpy of the forward reaction is ⌬H° ϭ (2 mol) ϫ ⌬Hf°(SO3, g) Ϫ (2 mol) ϫ ⌬Hf°(SO2, g) ϭ 2(Ϫ395.72 kJ) Ϫ 2(Ϫ296.83 kJ) ϭ Ϫ197.78 kJ Evaluate Because the formation of SO3 is exothermic, the reverse reaction is endothermic. Hence, raising the temperature of the equilibrium mixture favors the decomposition of SO3 to SO2 and O2; as a consequence, the pressures of SO2 and O2 will increase and that of SO3 will decrease, as we anticipated. V2O5 Self-Test 10.15A Predict the effect of raising the temperature on the equilibrium composition of the reaction N2O4(g) #4 2 NO2(g). See Appendix 2A for data. [Answer: The pressure of NO2 will increase.] Self-Test 10.15B Predict the effect of lowering the temperature on the equilibrium composition of the 2 CO(g) ϩ O2(g) #4 2 CO2(g). See Appendix 2A for data. The effect of temperature on the equilibrium composition arises from the dependence of the equilibrium constant on the temperature. The relation between the equilibrium constant and the standard Gibbs free energy of reaction in Eq. 8 applies to any temperature. Therefore, we should be able to use it to relate the equilibrium constant at one temperature to its value at another temperature. 10.11 TEMPERATURE AND EQUILIBRIUM 411 HOW DO WE DO THAT? To find the quantitative relation between the equilibrium constants for the same reaction at two temperatures T1 and T2, we note that Eq. 8 allows us to write the relation between standard Gibbs free energies of reaction and the equilibrium constants K1 and K2 at the two temperatures: ⌬Gr,1° ϭ ϪRT1 ln K1 ⌬Gr,2° ϭ ϪRT2 ln K2 These two expressions rearrange to Subtraction of the second from the first gives At this point, we introduce the definition of ⌬Gr° in terms of ⌬Hr° and ⌬Sr°: ⌬Gr,1° ϭ ⌬Hr,1° Ϫ T1⌬Sr,1° ⌬Gr,2° ϭ ⌬Hr,2° Ϫ T2⌬Sr,2° which gives It is usually reasonable to assume that ⌬Hr° and ⌬Sr° are both approximately independent of temperature over the range of temperatures of interest. When we make that approximation, the reaction entropies cancel, and we are left with A note on good practice: Notice that we have used the “molar” convention for the thermodynamic functions, as this convention is required by Eq. 8. The expression that we have just derived is a quantitative version of Le Chatelier’s principle for the effect of temperature. It is normally rearranged (by multiplying through by Ϫ1 and then using ln a Ϫ ln b ϭ ln (a/b)) into the van ’t Hoff equation: (13)*ln K2 K1 = ¢Hr° R e 1 T1 - 1 T2 f ln K1 - ln K2 = - ¢Hr° R e 1 T1 - 1 T2 f = - 1 R e ¢Hr,1° T1 - ¢Hr,2° T2 - ¢Sr,1° + ¢Sr,2°f ln K1 - ln K2 = - 1 R e ¢Hr,1° - T1¢Sr,1° T1 ¢Hr,2° - T2¢Sr,2° T2 f ln K1 - ln K2 = - 1 R e ¢Gr,1° T1 - ¢Gr,2° T2 f ln K1 = - ¢Gr,1° RT1 ln K2 = - ¢Gr,2° RT2 This equation is sometimes called the van ’t Hoff isochore, to distinguish it from van ’t Hoff’s osmotic pressure equation (Section 9.17). An isochore is the plot of an equation for a constantvolume process. In this expression, K1 is the equilibrium constant when the temperature is T1 and K2 is the equilibrium constant when the temperature is T2. What does this equation tell us? If the reaction is endothermic, then ⌬Hr° is positive. If T2 Ͼ T1, then 1͞T2 Ͻ 1͞T1 and the term in braces is also positive. Therefore, ln (K2͞K1) is positive, which implies that K2͞K1 Ͼ 1 and therefore that K2 Ͼ K1. In other words, an increase in temperature favors the formation of product if the reaction is endothermic. We predict the opposite effect for an exothermic reaction because ⌬Hr° is then negative. Therefore, the van ’t Hoff equation accounts for Le Chatelier’s principle for the effect of temperature on an equilibrium. One word of warning: when using the van ’t Hoff equation for reactions involving gases, the equilibrium constants must be K, not Kc. If we want a new value for Kc for a gas-phase reaction, we convert from Kc into K at the initial temperature (by using Eq. 12), use the van ’t Hoff equation to calculate the value of K at the new temperature, and then convert that K into the new Kc by using Eq. 12 at the new temperature. 412 CHAPTER 10 CHEMICAL EQUILIBRIA EXAMPLE 10.13 Predicting the value of an equilibrium constant at a different temperature The equilibrium constant K for the synthesis of ammonia (reaction C) is 6.8 ϫ 105 at 298 K. Predict its value at 400. K. Anticipate The synthesis of ammonia is exothermic, and so we expect the equilibrium constant to be smaller at the higher temperature. PLAN To use the van ’t Hoff equation, we need the standard reaction enthalpy, which can be calculated from the standard enthalpies of formation in Appendix 2A. Equation 13 requires us to use the “molar” convention. What should we assume? That the gases are ideal and that the reaction enthalpy is constant over the temperature range of interest. SOLVE The standard reaction enthalpy for the forward reaction in C is ⌬Hr° ϭ 2⌬Hf°(NH3, g) ϭ 2(Ϫ46.11 kJиmolϪ1 ) ϭ Ϫ92.22 kJиmolϪ1 or Ϫ92.22 ϫ 103 JиmolϪ1 From ln(K2͞K1) ϭ (⌬Hr°͞R){(1͞T1) Ϫ (1͞T2)}, Take antilogarithms (ex ). K2 ϭ K1eϪ9.49 ϭ (6.8 ϫ 105 ) ϫ eϪ9.49 ϭ 51 = -9.49 ln K2 K1 = -9.222 * 104 Jиmol-1 8.3145 JиK-1 иmol-1 * a 1 298 K - 1 400. K b $+++%+++&Ϫ92.22 kJиmolϪ1 Equilibriumconstant,K 6.8 ϫ 10 5 51 298 400 Temperature (K) Evaluate The equilibrium constant at 400. K is smaller, as expected, and is close to the experimental value of 41 in Table 10.2. It is not exactly the same because ⌬Hr° may change slightly over the temperature range in question. Self-Test 10.16A The equilibrium constant K for 2 SO3(g) #4 2 SO2(g) ϩ O2(g) is 2.5 ϫ 10Ϫ25 at 298 K. Predict its value at 500. K. [Answer: 2.5 ϫ 10Ϫ11 ] Self-Test 10.16B The equilibrium constant K for PCl5(g) #4 PCl3(g) ϩ Cl2(g) is 78.3 at 523 K. Predict its value at 800. K. Raising the temperature of an exothermic reaction favors the formation of reactants; raising the temperature of an endothermic reaction favors the formation of products. The van ’t Hoff equation expresses the effect quantitatively. 10.12 Catalysts and Haber’s Achievement A catalyst is a substance that increases the rate of a chemical reaction without being consumed itself. We shall see a lot more of catalysts later, when we consider reaction rates in Chapter 14. However, it is important to be aware at this stage that a catalyst has no effect on the equilibrium composition of a reaction mixture. A catalyst can speed up the rate at which a reaction reaches equilibrium, but it does not affect the composition at equilibrium. It acts by providing a faster route to the same destination. A catalyst speeds up both the forward and the reverse reactions to the same extent. Therefore, the dynamic equilibrium is unaffected. The thermodynamic justification of this observation is based on the fact that the equilibrium constant depends only on the temperature and the value of ⌬Gr°. A standard Gibbs free energy of reaction depends only on the identities of the reactants and products and is independent of the rate of the reaction or the presence of any substances that do not appear in the overall chemical equation for the reaction. The fact that a catalyst is present to provide a different route between reactants and products has no effect on the value of ⌬Gr° and therefore no effect on the value of K. We have seen how Haber’s understanding of chemical equilibrium enabled him to increase the yield of ammonia (Fig. 10.16). He realized that he had to compress the gases and remove the ammonia as it was formed. As we have seen, compression shifts the equilibrium composition in favor of ammonia, which increases the yield of product. Removing the ammonia also encourages more to be formed. In addition, Haber realized that he should run the reaction at as low a temperature as possible: low temperature favors the formation of product because the reaction is exothermic. However, nitrogen and hydrogen combine too slowly at low temperatures, and so Haber solved this problem by developing an appropriate catalyst (he used osmium and later uranium). The process was brought to an industrial scale by the chemical engineer Carl Bosch, who identified a cheaper catalyst (iron) and overcame the enormous problems of working at high pressure, which makes even hydrogen corrosive. Their process is still in use throughout the world. In the United States alone, it accounts for almost the entire annual production of about 1.6 ϫ 1010 kg of ammonia (Fig. 10.17). A catalyst does not affect the equilibrium composition of a reaction mixture. 10.13 The Impact on Biology: Homeostasis Because a living being is not a closed system, true equilibrium in living systems can be reached only for very fast reactions such as those between acids and bases. In general, however, our bodies maintain certain relatively constant characteristics such as temperature and levels of certain chemicals in the blood. A beneficial environment in the body is maintained through the process of homeostasis, the maintenance of constant internal conditions. Homeostasis is not a true equilibrium, because there are usually slight variations above and below the desired point. However, it responds to changes in conditions in the same way as a system in chemical equilibrium and so is governed by Le Chatelier’s principle. An important homeostatic biological process that involves chemical equilibria is the transport of oxygen. Most of the oxygen in the blood is carried by hemoglobin (Hb). 10.13 THE IMPACT ON BIOLOGY: HOMEOSTASIS 413 FIGURE 10.16 Fritz Haber (1868–1934). 3 10 5 5 27 14 9 8 19 Urea Ammonium nitrate Direct application Other Explosives Ammonium sulfate Ammonium hydrogen phosphate Fibers Mixed Fertilizer FIGURE 10.17 The Haber process is still used to produce almost all the ammonia manufactured in the world. This pie chart shows how the ammonia is used. The figures are percentages. Note that 80%—as shown by the green band—is used as fertilizer, either directly or after conversion into another compound. When blood flows through lung tissues, about 98% of the hemoglobin molecules pick up oxygen molecules and a small amount of additional oxygen simply dissolves in the blood plasma (the solution in which blood cells are suspended). However, when blood enters the small blood vessels called capillaries in muscle tissue far from the lungs, the hemoglobin molecules are surrounded by tissues that are depleted in oxygen. The equilibrium Hb(aq) ϩ O2(aq) #¢4 HbO2(aq) is shifted toward reactants as some of the hemoglobin molecules release their oxygen molecules to re-establish the equilibrium compositions. When a person is exercising heavily, muscles use an additional mechanism to encourage the hemoglobin molecules to release oxygen in the muscle tissue. Hydrogen ions from acids can cause the oxygen molecules in hemoglobin to be released; so, when lactic acid is produced by working muscle tissue, additional oxygen molecules are released from the hemoglobin. Figure 10.18 shows how the O2 uptake by hemoglobin and myoglobin (Mb), the oxygen storage protein, varies with partial pressure of oxygen. The shape of the Hb saturation curve means that Hb can load O2 almost as fully in the lungs as Mb and unload it more completely than Mb in different regions of the organism. In the lungs, where PO2 105 Torr, 98% of the molecules have taken up O2, resulting in almost complete saturation. In resting muscular tissue, the concentration of O2 corresponds to a partial pressure of about 40 Torr, at which value 75% of the Hb molecules are saturated with oxygen. This figure implies that sufficient oxygen is still available should a sudden surge of activity take place. If the local partial pressure falls to 20 Torr, the fraction of Hb molecules saturated falls to about 10%. Note that the steepest part of the curve falls in the range of typical tissue oxygen partial pressure. Myoglobin, on the other hand, begins to release O2 only when PO2 has fallen below about 20 Torr, and so it acts as a reserve to be drawn on only when the Hb oxygen has been used up. Overloading the body’s coping mechanisms can lead to failure to maintain homeostasis. The result can be sudden and even fatal illness. Mountain climbers encounter low oxygen conditions at high altitudes and, if they climb vigorously, their lungs may not be able to provide sufficient oxygen to maintain homeostasis. For this reason, mountain climbers spend some time in high-altitude base camps before climbing, so that their bodies can adjust by producing more hemoglobin molecules. Homeostasis, a mechanism similar to chemical equilibrium, allows living organisms to control biological processes at a constant level. L 414 CHAPTER 10 CHEMICAL EQUILIBRIA Fractionalsaturation 1.0 0 0.5 0 50 Resting tissue Lung Mb Hb 100 150 Oxygen partial pressure, P/Torr FIGURE 10.18 The variation of the extent of saturation of myoglobin (Mb) and hemoglobin (Hb) with the partial pressure of oxygen. The different shapes of the curves account for the different biological functions of the two proteins. ❑ 1 Distinguish homogeneous and heterogeneous equilibria and write equilibrium constants for both types of reaction from a balanced equation (Example 10.1 and Self-Tests 10.2 and 10.5). ❑ 2 Relate the Gibbs free energy of reaction to the composition of the reaction mixture (Example 10.2). ❑ 3 Calculate an equilibrium constant from a standard Gibbs free energy (Example 10.3). ❑ 4 Calculate an equilibrium concentration (Example 10.4). ❑ 5 Predict the direction of a reaction, given K and the concentrations of reactants and products (Example 10.5). ❑ 6 Convert between K and Kc (Example 10.6). ❑ 7 Calculate the effect on K of reversing a reaction or multiplying the chemical equation by a factor (Section 10.7). ❑ 8 Use an equilibrium table to carry out equilibrium calculations (Toolbox 10.1 and Examples 10.7, 10.8, and 10.10). ❑ 9 Use Le Chatelier’s principle to predict how the equilibrium composition of a reaction mixture is affected by adding or removing reagents, compressing or expanding the mixture, or changing the temperature (Examples 10.9, 10.11, and 10.12). ❑ 10 Predict the value of K at a different temperature (Example 10.13). SKILLS YOU SHOULD HAVE MASTERED The Equilibrium Constant 10.1 State whether the following statements are true or false. If false, explain why. (a) A reaction stops when equilibrium is reached. (b) An equilibrium reaction is not affected by increasing the concentrations of products. (c) If one starts with a higher pressure of reactant, the equilibrium constant will be larger. (d) If one starts with higher concentrations of reactants, the equilibrium concentrations of the products will be larger. 10.2 Determine whether the following statements are true or false. If false, explain why. EXERCISES (a) In an equilibrium reaction, the reverse reaction begins only when all reactants have been converted to products. (b) The equilibrium concentrations will be the same whether one starts with pure reactants or pure products. (c) The rates of the forward and reverse reactions are the same at equilibrium. (d) If the Gibbs free energy is greater than the standard Gibbs free energy of reaction, the reaction proceeds forward to equilibrium. 10.3 Depict the progress of the reaction graphically (as in Fig. 10.1) for the decomposition of PCl5 to give PCl3 and Cl2, using the values given in Example 10.8. 10.4 Depict the progress of the reaction graphically (as in Fig. 10.1) for the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g), using the conditions described in Example 10.10, starting from the point where additional Cl2 is added and continuing until equilibrium is restored. 10.5 The following flasks show the dissociation of a diatomic molecule, X2, over time. (a) Which flask represents the point in time at which the reaction has reached equilibrium? (b) What percentage of the X2 molecules have decomposed at equilibrium? (c) Assuming that the initial pressure of X2 was 0.10 bar, calculate the value of K for the decomposition. 10.6 The flask below contains atoms of A (red) and B (yellow). They react as follows: 2 A(g) ϩ B(g) #4 A2B(g), K ϭ 0.25. Draw a picture of the flask after it has reached equilibrium. 10.7 Balance the following equations using the smallest wholenumber coefficients, then write the equilibrium expression Kc for each reaction: (a) CH4(g) ϩ O2(g) #4 CO2(g) ϩ H2O(g) (b) I2(g) ϩ F2(g) #4 IF5(g) (c) NO2(g) ϩ F2(g) #4 FNO2(g) 10.8 Balance the following equations using the smallest wholenumber coefficients, then write the equilibrium expression Kc for each reaction: (a) CH4(g) ϩ Cl2(g) #4 CHCl3(g) ϩ HCl(g) (b) NH3(g) ϩ ClF3(g) #4 HF(g) ϩ N2(g) ϩ Cl2(g) (c) N2(g) ϩ O2(g) #4 N2O3(g) 10.9 A 0.10-mol sample of pure ozone, O3, is placed in a sealed 1.0-L container and the reaction 2 O3(g) #4 3 O2(g) is allowed to reach equilibrium. A 0.50-mol sample of pure ozone is placed in a second 1.0-L container at the same temperature and allowed to reach equilibrium. Without doing any calculations, predict which of the following will be different in the two containers at equilibrium. Which will be the same? (a) Amount of O2; (b) concentration of O2; (c) the ratio [O2]/[O3]; (d) the ratio [O2]3 /[O3]2 ; (e) the ratio [O3]2 /[O2]3 . Explain each of your answers. 10.10 A 0.10-mol sample of H2(g) and a 0.10-mol sample of Br2(g) are placed into a 2.0-L container. The reaction H2(g) ϩ Br2(g) #4 2 HBr(g) is then allowed to come to equilibrium. A 0.20-mol sample of HBr is placed into a second 2.0-L sealed container at the same temperature and allowed to reach equilibrium with H2 and Br2. Which of the following will be different in the two containers at equilibrium? Which will be the same? (a) Amount of Br2; (b) concentration of H2; (c) the ratio [HBr]/[H2][Br2]; (d) the ratio [HBr]/[Br2]; (e) the ratio [HBr]2 /[H2][Br2]; (f) the total pressure in the container. Explain each of your answers. 10.11 Use the following data, which were collected at 460.°C and are equilibrium partial pressures, to determine K for the reaction H2(g) ϩ I2(g) #4 2 HI(g): PH2 (bar) PI2 (bar) PHI (bar) 6.47 ϫ 10Ϫ3 0.594 ϫ 10Ϫ3 0.0137 3.84 ϫ 10Ϫ3 1.52 ϫ 10Ϫ3 0.0169 1.43 ϫ 10Ϫ3 1.43 ϫ 10Ϫ3 0.0100 10.12 Determine K from the following equilibrium data collected at 24°C for the reaction NH4HS(s) #4 NH3(g) ϩ H2S(g): PNH3 (bar) PH2S (bar) 0.307 0.307 0.364 0.258 0.539 0.17 10.13 Write the reaction quotient Q for (a) 2 BCl3(g) ϩ 2 Hg(l) : B2Cl4(s) ϩ Hg2Cl2(s) (b) P4S10(s) ϩ 16 H2O(l) : 4 H3PO4(aq) ϩ 10 H2S(aq) (c) Br2(g) ϩ 3 F2(g) : 2 BrF3(g) 10.14 Write the reaction quotient Qc for (a) NCl3(g) ϩ 3 H2O(l) : NH3(g) ϩ 3 HOCl(aq) (b) P4(s) ϩ 3 KOH(aq) ϩ 3 H2O(l) : PH3(aq) ϩ3 KH2PO2(aq) (c) CO3 2Ϫ (aq) ϩ 2 H3Oϩ (aq) : CO2(g) ϩ 3 H2O(l) 10.15 (a) Calculate the reaction Gibbs free energy of I2(g) : 2 I(g) at 1200. K (K ϭ 6.8) when the partial pressures of I2 and I are 0.13 bar and 0.98 bar, respectively. (b) What is the spontaneous direction of the reaction? Explain briefly. 10.16 Calculate the reaction Gibbs free energy of PCl3(g) ϩ Cl2(g) : PCl5(g) at 230.°C when the partial pressures of PCl3, Cl2, and PCl5 are 0.13 bar, 0.51 bar, and 1.42 bar, respectively. What is the spontaneous direction of change, given that K ϭ 49 at 230.°C? 10.17 (a) Calculate the reaction Gibbs free energy of N2(g) ϩ 3 H2(g) : 2 NH3(g) when the partial pressures of N2, H2, and NH3 are 4.2 bar, 1.8 bar, and 21 bar, respectively, and the temperature is 400. K. For this reaction, K ϭ 41 at 400. K. (b) Indicate whether this reaction mixture is likely to form reactants, is likely to form products, or is at equilibrium. 10.18 (a) Calculate the reaction Gibbs free energy of H2(g) ϩ I2(g) : 2 HI(g) at 700. K when the partial pressures of H2, I2, and HI are 0.35 bar, 0.18 bar, and 2.85 bar, respectively. For this reaction, K ϭ 54 at 700. K. (b) Indicate whether this reaction mixture is likely to form reactants, is likely to form products, or is at equilibrium. EXERCISES 415 10.19 Calculate the equilibrium constant at 25°C for each of the following reactions, using data in Appendix 2A: (a) the combustion of hydrogen: 2 H2(g) ϩ O2(g) #4 2 H2O(g) (b) the oxidation of carbon monoxide: 2 CO(g) ϩ O2(g) #4 2 CO2(g) (c) the decomposition of limestone: CaCO3(s) #4 CaO(s) ϩ CO2(g) 10.20 Calculate the equilibrium constant at 25°C for each of the following reactions, by using data in Appendix 2A: (a) the synthesis of trichloromethane (chloroform) from natural gas (methane). ⌬Gr°(CH3Cl, g) ϭ 48.5 kJиmolϪ1 CH4(g) ϩ Cl2(g) #4 CH3Cl(g) ϩ HCl(g) (b) the hydrogenation of acetylene to ethane: C2H2(g) ϩ 2 H2(g) #4 C2H6(g) (c) the final step in the industrial production of nitric acid: 3 NO2(g) ϩ H2O(l) #4 2 HNO3(aq) ϩ NO(g) (d) the reaction of hydrazine and oxygen in a rocket: N2H4(l) ϩ O2(g) #4 N2(g) ϩ 2 H2O(l) 10.21 Calculate the standard Gibbs free energy of each of the following reactions: (a) I2(g) #4 2 I(g), K ϭ 6.8 at 1200. K (b) Ag2CrO4(s) #4 2 Agϩ (aq) ϩ CrO4 2Ϫ (aq), K ϭ 1.1 ϫ 10Ϫ12 at 298 K 10.22 Calculate the standard Gibbs free energy for each of the following reactions: (a) H2(g) ϩ I2(g) #4 2 HI(g), K ϭ 54 at 700. K (b) CCl3COOH(aq) ϩ H2O(l) #4 CCl3CO2 Ϫ (aq) ϩ H3Oϩ (aq), K ϭ 0.30 at 298 K 10.23 If Q ϭ 1.0 for the reaction N2(g) ϩ O2(g) : 2 NO(g) at 25°C, will the reaction have a tendency to form products or reactants or will it be at equilibrium? 10.24 If Q ϭ 1.0 ϫ 1040 for the reaction C(s) ϩ O(g) : CO(g) at 25°C, will the reaction have a tendency to form products or reactants or will it be at equilibrium? 10.25 Use the information in Table 10.2 to determine the value of K at 300 K for the reaction 2 BrCl(g) ϩ H2(g) #4 Br2(g) ϩ 2 HCl(g). 10.26 Use the information in Table 10.2 to determine the value of K at 500 K for the reaction 2 NH3(g) ϩ 3 Br2(g) #4 N2(g) ϩ 6 HBr(g). 10.27 In a gas-phase equilibrium mixture of H2, I2, and HI at 500. K, [HI] ϭ 2.21 ϫ 10Ϫ3 molиLϪ1 and [I2] ϭ 1.46 ϫ 10Ϫ3 molиLϪ1 . Given the value of the equilibrium constant in Table 10.2, calculate the concentration of H2. 10.28 In a gas-phase equilibrium mixture of H2, Cl2, and HCl at 1000. K, [HCl] ϭ 1.45 mmolиLϪ1 and [Cl2] ϭ 2.45 mmolиLϪ1 . Use the information in Table 10.2 to calculate the concentration of H2. 10.29 In a gas-phase equilibrium mixture of PCl5, PCl3, and Cl2 at 500. K, PPCl5 ϭ 1.18 bar, PCl2 ϭ 5.43 bar. What is the partial pressure of PCl3, given that K ϭ 25 for the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g)? 10.30 In a gas-phase equilibrium mixture of SbCl5, SbCl3, and Cl2 at 500. K, PSbCl5 ϭ 0.072 bar and PSbCl3 ϭ 5.02 mbar. Calculate the equilibrium partial pressure of Cl2, given that K ϭ 3.5 ϫ 10Ϫ4 for the reaction SbCl5(g) #4 SbCl3(g) ϩ Cl2(g). 10.31 For the reaction H2(g) ϩ I2(g) #4 2 HI(g), K ϭ 160. at 500. K. An analysis of a reaction mixture at 500. K showed that it had the composition PH2 ϭ 0.20 bar, PI2 ϭ 0.10 bar, and PHI ϭ 0.10 bar. (a) Calculate the reaction quotient. (b) Is the reaction mixture at equilibrium? (c) If not, is there a tendency to form more reactants or more products? 10.32 Analysis of a reaction mixture showed that it had the composition 0.624 molиLϪ1 N2, 0.315 molиLϪ1 H2, and 0.222 molиLϪ1 NH3 at 800. K, at which temperature Kc ϭ 0.278 for N2(g) ϩ 3 H2(g) #4 2 NH3(g). (a) Calculate the reaction quotient Qc. (b) Is the reaction mixture at equilibrium? (c) If not, is there a tendency to form more reactants or more products? 10.33 A 0.500-L reaction vessel at 700. K contains 1.20 mmol SO2(g), 0.50 mmol O2(g), and 0.10 mmol SO3(g). At 700. K, Kc ϭ 1.7 ϫ 106 for the equilibrium 2 SO2(g) ϩ O2(g) #4 2 SO3(g). (a) Calculate the reaction quotient Qc. (b) Will more SO3(g) tend to form? 10.34 Given that Kc ϭ 62 for the reaction N2(g) ϩ 3 H2(g) #4 2 NH3(g) at 500. K, calculate whether more ammonia will tend to form when a mixture of composition 2.23 mmolиLϪ1 N2, 1.24 mmolиLϪ1 H2, and 0.112 mmolиLϪ1 NH3 is present in a container at 500. K. 10.35 Determine Kc for each of the following equilibria from the value of K: (a) 2 NOCl(g) #4 2 NO(g) ϩ Cl2(g), K ϭ 1.8 ϫ 10Ϫ2 at 500. K (b) CaCO3(s) #4 CaO(s) ϩ CO2(g), K ϭ 167 at 1073 K 10.36 Determine Kc for each of the following equilibria from the value of K: (a) 2 SO2(g) ϩ O2(g) #4 2 SO3(g), K ϭ 3.4 at 1000. K (b) NH4HS(s) #4 NH3(g) ϩ H2S(g), K ϭ 9.4 ϫ 10Ϫ2 at 24°C 10.37 For the reaction N2(g) ϩ 3 H2(g) #4 2 NH3(g) at 400. K, K ϭ 41. Find the value of K for each of the following reactions at the same temperature: (a) 2 NH3(g) #4 N2(g) ϩ 3 H2(g) (b) N2(g) ϩ H2(g) #4 NH3(g) (c) 2 N2(g) ϩ 6 H2(g) #4 4 NH3(g) 10.38 The equilibrium constant for the reaction 2 SO2(g) ϩ O2(g) #4 2 SO3(g) has the value K ϭ 2.5 ϫ 1010 at 500. K. Find the value of K for each of the following reactions at the same temperature. (a) SO2(g) ϩ O2(g) #4 SO3(g) (b) SO3(g) #4 SO2(g) ϩ O2(g) (c) 3 SO2(g) ϩ O2(g) #4 3 SO3(g) 10.39 When 0.0172 mol HI is heated to 500. K in a 2.00-L sealed container, the resulting equilibrium mixture contains 1.90 g of HI. Calculate K for the decomposition reaction 2 HI(g) #4 H2(g) ϩ I2(g). 10.40 When 1.00 g of gaseous I2 is heated to 1000. K in a 1.00-L sealed container, the resulting equilibrium mixture contains 0.830 g of I2. Calculate Kc for the dissociation equilibrium I2(g) #4 2 I(g). 10.41 A 25.0-g sample of ammonium carbamate, NH4(NH2CO2), was placed in an evacuated 0.250-L flask and kept at 25°C. At equilibrium, 17.4 mg of CO2 was present. What is the value of Kc for the decomposition of ammonium carbamate into ammonia and carbon dioxide? The reaction is NH4(NH2CO2)(s) #4 2 NH3(g) ϩ CO2(g). 10.42 Carbon monoxide and water vapor, each at 200. Torr, were introduced into a 250.-mL container. When the mixture reached equilibrium at 700.°C, the partial pressure of CO2(g) was 88 Torr. Calculate the value of K for the equilibrium CO(g) ϩ H2O(g) #4 CO2(g) ϩ H2(g). 3 2 1 2 1 2 3 2 1 2 416 CHAPTER 10 CHEMICAL EQUILIBRIA 10.43 Consider the reaction 2 NO(g) #4 N2(g) ϩ O2(g). If the initial partial pressure of NO(g) is 1.0 bar, and x is the equilibrium concentration of N2(g), what is the correct equilibrium relation? (a) K ϭ x2 ͞(1.0 Ϫ x); (b) K ϭ x2 ; (c) K ϭ x2 ͞(1.0 Ϫ 2x)2 ; (d) K ϭ 4x3 ͞(1.0 Ϫ 2x)2 ; (e) K ϭ 2x͞(1.0 Ϫ x)2 . 10.44 Consider the reaction 2 NO2(g) #4 2 NO(g) ϩ O2(g). If the initial partial pressure of NO2(g) is 3.0 bar, and x is the equilibrium concentration of O2(g), what is the correct equilibrium relation? (a) K ϭ x3 ; (b) K ϭ 2x2 ͞(3.0 Ϫ 2x)2 ; (c) K ϭ 4x3 ͞(3.0 Ϫ 2x)2 ; (d) K ϭ x2 ͞(3.0 Ϫ x); (e) K ϭ 2x/(3.0 Ϫ x)2 . 10.45 (a) A sample of 2.0 mmol Cl2(g) was sealed into a 2.0-L reaction vessel and heated to 1000. K to study its dissociation into Cl atoms. Use the information in Table 10.2 to calculate the equilibrium composition of the mixture. (b) If 2.0 mmol F2 was placed into the reaction vessel instead of the chlorine, what would be its equilibrium composition at 1000. K? (c) Use your results from parts (a) and (b) to determine which is thermodynamically more stable relative to its atoms at 1000. K, Cl2 or F2. 10.46 (a) A sample of 5.0 mmol Cl2(g) was sealed into a 2.0-L reaction vessel and heated to 1200. K, and the dissociation equilibrium was established. What is the equilibrium composition of the mixture? Use the information in Table 10.2. (b) If 5.0 mol Br2 is placed into the reaction vessel instead of the chlorine, what would be the equilibrium composition at 1200. K? (c) Use your results from parts (a) and (b) to determine which is thermodynamically more stable relative to its atoms at 1200. K, Cl2, or Br2. 10.47 For the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g), Kc ϭ 1.1 ϫ 10Ϫ2 at 400. K. (a) Given that 1.0 g of PCl5 is placed in a 250.-mL reaction vessel, determine the molar concentrations in the mixture at equilibrium. (b) What percentage of the PCl5 has decomposed at equilibrium at 400. K? 10.48 For the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g), Kc ϭ 0.61 at 500. K. (a) Calculate the equilibrium molar concentrations of the components in the mixture when 3.6 g of PCl5 is placed in a 300.-mL reaction vessel and allowed to come to equilibrium. (b) What percentage of the PCl5 has decomposed at equilibrium at 500. K? 10.49 When solid NH4HS and 0.400 mol NH3(g) were placed in a 2.0-L vessel at 24°C, the equilibrium NH4HS(s) #4 NH3(g) ϩ H2S(g), for which Kc ϭ 1.6 ϫ 10Ϫ4 , was reached. What are the equilibrium concentrations of NH3 and H2S? 10.50 When solid NH4HS and 0.200 mol NH3(g) were placed into a 2.0-L vessel at 24°C, the equilibrium NH4HS(s) #4 NH3(g) ϩ H2S(g), for which Kc ϭ 1.6 ϫ 10Ϫ4 , was reached. What are the equilibrium concentrations of NH3 and H2S? 10.51 The equilibrium constant Kc for the reaction N2(g) ϩ O2(g) #4 2 NO(g) at 1200°C is 1.00 ϫ 10Ϫ5 . Calculate the equilibrium molar concentrations of NO, N2, and O2 in a 1.00-L reaction vessel that initially held 0.114 mol N2 and 0.114 mol O2. 10.52 The equilibrium constant Kc for the reaction N2(g) ϩ O2(g) #4 2 NO(g) at 1200°C is 1.00 ϫ 10Ϫ5 . Calculate the equilibrium molar concentrations of NO, N2, and O2 in a 10.00-L reaction vessel that initially held 0.0140 mol N2 and 0.214 mol O2. 10.53 A reaction mixture that consisted of 0.400 mol H2 and 1.60 mol I2 was introduced into a 3.00-L flask and heated. At equilibrium, 60.0% of the hydrogen gas had reacted. What is the equilibrium constant K for the reaction H2(g) ϩ I2(g) #4 2 HI(g) at this temperature? 10.54 A reaction mixture that consisted of 0.20 mol N2 and 0.20 mol H2 was introduced into a 25.0-L reactor and heated. At equilibrium, 5.0% of the nitrogen gas had reacted. What is the value of the equilibrium constant Kc for the reaction N2(g) ϩ 3 H2(g) #4 2 NH3(g) at this temperature? 10.55 The equilibrium constant Kc for the reaction 2 CO(g) ϩ O2(g) #4 2 CO2(g) is 0.66 at 2000.°C. If 0.28 g of CO and 0.032 g of O2(g) are placed in a 2.0-L reaction vessel and heated to 2000.°C, what will the equilibrium composition of the system be? (You may wish to use graphing software or a calculator to solve the cubic equation.) 10.56 In the Haber process for ammonia synthesis, K ϭ 0.036 for N2(g) ϩ 3 H2(g) #4 2 NH3(g) at 500. K. If a 2.0-L reactor is charged with 0.025 bar of N2 and 0.015 bar of H2, what will the equilibrium partial pressures in the mixture be? 10.57 At 500. K, the equilibrium constant for the reaction Cl2(g) ϩ Br2(g) #4 2 BrCl(g) is Kc ϭ 0.031. If the equilibrium composition is 0.495 molиLϪ1 Cl2 and 0.145 molиLϪ1 BrCl, what is the equilibrium concentration of Br2? 10.58 The equilibrium constant for the reaction PCl3(g) ϩ Cl2(g) #4 PCl5(g) is K ϭ 3.5 ϫ 104 at 760.°C. At equilibrium, the partial pressure of PCl5 was 1.3 ϫ 102 bar and that of PCl3 was 9.56 bar. What was the equilibrium partial pressure of Cl2? 10.59 A reaction mixture consisting of 2.00 mol CO and 3.00 mol H2 is placed in a 10.0-L reaction vessel and heated to 1200. K. At equilibrium, 0.478 mol CH4 was present in the system. Determine the value of Kc for the reaction CO(g) ϩ 3 H2(g) #4 CH4(g) ϩ H2O(g) at 1200. K. 10.60 A mixture consisting of 1.000 mol H2O(g) and 1.000 mol CO(g) is placed in a 10.00-L reaction vessel at 800. K. At equilibrium, 0.665 mol CO2(g) is present as a result of the reaction CO(g) ϩ H2O(g) #4 CO2(g) ϩ H2(g). What are (a) the equilibrium concentrations for all substances and (b) the value of Kc at 800. K? 10.61 A reaction mixture is prepared by mixing 0.100 mol SO2, 0.200 mol NO2, 0.100 mol NO, and 0.150 mol SO3 in a 5.00-L reaction vessel. The reaction SO2(g) ϩ NO2(g) #4 NO(g) ϩ SO3(g) is allowed to reach equilibrium at 460.°C, when Kc ϭ 85.0. What is the equilibrium concentration of each substance? 10.62 A 0.100-mol sample of H2S is placed in a 10.0-L reaction vessel and heated to 1132°C. At equilibrium, 0.0285 mol H2 is present. Calculate the value of Kc for the reaction 2 H2S(g) #4 2 H2(g) ϩ S2(g) at 1132°C. 10.63 The equilibrium constant Kc ϭ 0.56 for the reaction PCl3(g) ϩ Cl2(g) #4 PCl5(g) at 250.°C. On analysis, 1.50 mol PCl5, 3.00 mol PCl3, and 0.500 mol Cl2 were found to be present in a 0.500-L reaction vessel at 250.°C. (a) Is the reaction at equilibrium? (b) If not, in which direction does it tend to proceed? (c) What is the equilibrium composition of the reaction system? 10.64 An 0.865-mol sample of PCl5 is placed in a 500.-mL reaction vessel. What is the concentration of each substance when the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g) has reached equilibrium at 250°C (when Kc ϭ 1.80)? 10.65 At 25°C, K ϭ 3.2 ϫ 10Ϫ34 for the reaction 2 HCl(g) #4 H2(g) ϩ Cl2(g). If a 1.0-L reaction vessel is filled with HCl at 0.22 bar, what are the equilibrium partial pressures of HCl, H2, and Cl2? EXERCISES 417 10.66 If 4.00 L of HCl(g) at 1.00 bar and 273 K and 26.0 g of I2(s) are transferred to a 12.00-L reaction vessel and heated to 25°C, what will the equilibrium concentrations of HCl, HI, and Cl2 be? Kc ϭ 1.6 ϫ 10Ϫ34 at 25°C for 2 HCl(g) ϩ I2(s) #4 2 HI(g) ϩ Cl2(g). 10.67 A 3.00-L reaction vessel is filled with 0.342 mol CO, 0.215 mol H2, and 0.125 mol CH3OH. Equilibrium is reached in the presence of a zinc oxide-chromium(III) oxide catalyst and, at 300.°C, Kc ϭ 1.1 ϫ 10Ϫ2 for the reaction CO(g) ϩ 2 H2(g) #4 CH3OH(g). (a) As the reaction approaches equilibrium, will the concentration of CH3OH increase, decrease, or remain unchanged? (b) What is the equilibrium composition of the mixture? 10.68 For the reaction 2 NH3(g) #4 N2(g) ϩ 3 H2(g), Kc ϭ 0.395 at 350.°C. A 25.6-g sample of NH3 is placed in a 5.00-L reaction vessel and heated to 350.°C. What are the equilibrium concentrations of NH3, N2, and H2? 10.69 The reaction 2 HCl(g) #4 H2(g) ϩ Cl2(g) has K ϭ 3.2 ϫ 10Ϫ34 at 298 K. The initial partial pressures are H2, 1.0 bar; HCl, 2.0 bar; and Cl2, 3.0 bar. At equilibrium there is 1.0 mol H2(g). What is the volume of the container? (Don’t be surprised at the large size of the volume.) 10.70 Suppose that, in the same reaction as in Exercise 10.69, the total pressure at equilibrium is found to be 3.0 bar and the Cl:H atom ratio is 1:3. What are the partial pressures of the three gases? The Response of Equilibria to Changes in Conditions 10.71 Consider the equilibrium CO(g) ϩ H2O(g) #4 CO2(g) ϩ H2(g). (a) If the partial pressure of CO2 is increased, what happens to the partial pressure of H2? (b) If the partial pressure of CO is decreased, what happens to the partial pressure of CO2? (c) If the concentration of CO is increased, what happens to the concentration of H2? (d) If the concentration of H2O is decreased, what happens to the equilibrium constant for the reaction? 10.72 Consider the equilibrium CH4(g) ϩ 2 O2(g) #4 CO2(g) ϩ 2 H2O(g). (a) If the partial pressure of CO2 is increased, what happens to the partial pressure of CH4? (b) If the partial pressure of CH4 is decreased, what happens to the partial pressure of CO2? (c) If the concentration of CH4 is increased, what happens to the equilibrium constant for the reaction? (d) If the concentration of H2O is decreased, what happens to the concentration of CO2? 10.73 The four gases NH3, O2, NO, and H2O are mixed in a reaction vessel and allowed to reach equilibrium in the reaction 4 NH3(g) ϩ 5 O2(g) #4 4 NO(g) ϩ 6 H2O(g). Certain changes (see the following table) are then made to this mixture. Considering each change separately, state the effect (increase, decrease, or no change) that the change has on the original equilibrium values of the quantity in the second column (or K, if that is specified). The temperature and volume are constant. Change Quantity (a) add NO amount of H2O (b) add NO amount of O2 (c) remove H2O amount of NO (d) remove O2 amount of NH3 (e) add NH3 K (f) remove NO amount of NH3 (g) add NH3 amount of O2 10.74 The four substances HCl, I2, HI, and Cl2 are mixed in a reaction vessel and allowed to reach equilibrium in the reaction 2 HCl(g) ϩ I2(s) #4 2 HI(g) ϩ Cl2(g). Certain changes (which are specified in the first column in the following table) are then made to this mixture. Considering each change separately, state the effect (increase, decrease, or no change) that the change has on the original equilibrium value of the quantity in the second column (or K, if that is specified). The temperature and volume are constant. Change Quantity (a) add HCl amount of HI (b) add I2 amount of Cl2 (c) remove HI amount of Cl2 (d) remove Cl2 amount of HCl (e) add HCl K (f) remove HCl amount of I2 (g) add I2 K 10.75 State whether reactants or products will be favored by an increase in the total pressure (resulting from compression) on each of the following equilibria. If there is no change, explain why that is so. (a) 2 O3(g) #4 3 O2(g) (b) H2O(g) ϩ C(s) #4 H2(g) ϩ CO(g) (c) 4 NH3(g) ϩ 5 O2(g) #4 4 NO(g) ϩ 6 H2O(g) (d) 2 HD(g) #4 H2(g) ϩ D2(g) (e) Cl2(g) #4 2 Cl(g) 10.76 State what happens to the concentration of the indicated substance when the total pressure on each of the following equilibria is increased (by compression): (a) NO2(g) in 2 Pb(NO3)2(s) #4 2 PbO(s) ϩ 4 NO2(g) ϩ O2(g) (b) NO(g) in 3 NO2(g) ϩ H2O(l) #4 2 HNO3(aq) ϩ NO(g) (c) HI(g) in 2 HCl(g) ϩ I2(s) #4 2 HI(g) ϩ Cl2(g) (d) SO2(g) in 2 SO2(g) ϩ O2(g) #4 2 SO3(g) (e) NO2(g) in 2 NO(g) ϩ O2(g) #4 2 NO2(g) 10.77 Consider the equilibrium 3 NH3(g) ϩ 5 O2(g) #4 4 NO(g) ϩ 6 H2O(g). (a) What happens to the partial pressure of NH3 when the partial pressure of NO is increased? (b) Does the partial pressure of O2 decrease when the partial pressure of NH3 is decreased? 10.78 Consider the equilibrium 2 SO2(g) ϩ O2(g) #4 2 SO3(g). (a) What happens to the partial pressure of SO3 when the partial pressure of SO2 is decreased? (b) If the partial pressure of SO2 is increased, what happens to the partial pressure of O2? 10.79 Predict whether each of the following equilibria will shift toward products or reactants with a temperature increase: (a) N2O4(g) #4 2 NO2(g), ⌬H° ϭ ϩ57 kJ (b) X2(g) #4 2 X(g), where X is a halogen (c) Ni(s) ϩ 4 CO(g) #4 Ni(CO)4(g), ⌬H° ϭ Ϫ161 kJ (d) CO2(g) ϩ 2 NH3(g) #4 CO(NH2)2(s) ϩ H2O(g), ⌬H° ϭ Ϫ90 kJ 10.80 Predict whether each of the following equilibria will shift toward products or reactants with a temperature increase: (a) CH4(g) ϩ H2O(g) #4 CO(g) ϩ 3 H2(g), ⌬H° ϭ ϩ206 kJ (b) CO(g) ϩ H2O(g) #4 CO2(g) ϩ H2(g), ⌬H° ϭ Ϫ41 kJ (c) 2 SO2(g) ϩ O2(g) #4 2 SO3(g), ⌬H° ϭ Ϫ198 kJ 10.81 A reactor for the production of ammonia by the Haber process is found to be at equilibrium with ϭ 3.11 bar, ϭ 1.64 bar, and ϭ 23.72 bar. If the partial pressure of N2 is increased by 1.57 bar, what will be the partial pressure of each gas once equilibrium is re-established? 10.82 In a laboratory studying the extraction of iron metal from iron ore, the following reaction was carried out at 1270 K in a PNH3 PH2 PN2 418 CHAPTER 10 CHEMICAL EQUILIBRIA reaction vessel of volume 10.0 L: FeO(s) ϩ CO(g) #4 Fe(s) ϩ CO2(g). At equilibrium the partial pressure of CO was 4.24 bar and that of CO2 was 1.71 bar. The pressure of the CO2 was reduced to 0.62 bar by reacting some of it with NaOH and the system was allowed to reach equilibrium again. What will be the partial pressure of each gas once equilibrium is re-established? 10.83 A reaction used in the production of gaseous fuels from coal, which is mainly carbon, is C(s) ϩ H2O(g) #4 CO(g) ϩ H2(g). (a) Evaluate K At 900 K, given that the standard Gibbs free energies of formation of CO(g) and H2O(g) at 900 K are Ϫ191.28 kJиmolϪ1 and Ϫ198.08 kJиmolϪ1 , respectively. (b) A 5.20-kg sample of graphite and 125 g of water were placed into a 10.0-L container and heated to 900 K. What are the equilibrium concentrations? 10.84 The volume of the container used for the reaction in Exercise 10.83 is expanded to 20.0 L and equilibrium was reestablished. (a) Without doing a calculation, predict whether the equilibrium concentration of H2 will have increased or decreased and explain how you decided. (b) Calculate the new equilibrium concentrations and evaluate your prediction. (c) To maximize the production of H2, should the reaction be run at low or high pressures? At a low or high temperature? Justify your answers. 10.85 A gaseous mixture consisting of 2.23 mmol N2 and 6.69 mmol H2 in a 500.-mL container was heated to 600. K and allowed to reach equilibrium. Will more ammonia be formed if that equilibrium mixture is then heated to 700. K? For N2(g) ϩ 3 H2(g) #4 2 NH3(g), K ϭ 1.7 ϫ 10Ϫ3 at 600. K and 7.8 ϫ 10Ϫ5 at 700. K. 10.86 A gaseous mixture consisting of 1.1 mmol SO2 and 2.2 mmol O2 in a 250-mL container was heated to 500. K and allowed to reach equilibrium. Will more sulfur trioxide be formed if that equilibrium mixture is cooled to 298 K? For the reaction 2 SO2(g) ϩ O2(g) #4 2 SO3(g), K ϭ 2.5 ϫ 1010 at 500. K and 4.0 ϫ 1024 at 298 K. 10.87 At 500.°C, Kc ϭ 0.061 for N2(g) ϩ 3 H2(g) #4 2 NH3(g). If analysis shows that the composition is 3.00 molиLϪ1 N2, 2.00 molиLϪ1 H2, and 0.500 molиLϪ1 NH3, is the reaction at equilibrium? If not, in which direction does the reaction tend to proceed to reach equilibrium? 10.88 At 2500. K, the equilibrium constant is Kc ϭ 20. for the reaction Cl2(g) ϩ F2(g) #4 2 ClF(g). An analysis of a reaction vessel at 2500. K revealed the presence of 0.18 molиLϪ1 Cl2, 0.31 molиLϪ1 F2, and 0.92 molиLϪ1 ClF. Will ClF tend to form or to decompose as the reaction proceeds toward equilibrium? 10.89 Calculate the equilibrium constant at 25°C and at 150.°C for each of the following reactions, using data available in Appendix 2A: (a) NH4Cl(s) #4 NH3(g) ϩ HCl(g) (b) H2(g) ϩ D2O(l) #4 D2(g) ϩ H2O(l) 10.90 Calculate the equilibrium constant at 25°C and at 100.°C for each of the following reactions, using data available in Appendix 2A: (a) HgO(s) #4 Hg(l) ϩ O2(g) (b) propene (C3H6, g) #4 cyclopropane (C3H6, g) 10.91 By combining the relation for Kc in terms of K with the van ’t Hoff equation, find the analog of the van ’t Hoff equation for Kc. 10.92 The vaporization of a liquid can be treated as a special case of an equilibrium. How does the vapor pressure of a liquid vary with temperature? Hint: Devise a version of the van’t Hoff equation that applies to vapor pressure by first writing the equilibrium constant K for vaporization. Integrated Exercises 10.93 Dissociation of a diatomic molecule, X2(g) #4 2 X(g) occurs at 500 K. Picture 1 shows the equilibrium state of the dissociation and picture 2 shows the equilibrium state in the same container after a change has occurred. Which of the following changes will produce the change shown? (a) Increasing the temperature. (b) Adding X atoms. (c) Decreasing the volume. (d) Adding a catalyst. Explain your selections. 10.94 At 25°C, K ϭ 47.9 for N2O4(g) #4 2 NO2(g). (a) If 0.020 mol of N2O4 and 0.010 mol of NO2 are placed in a 2.00-L reaction vessel and the reaction is allowed to reach equilibrium, what are the equilibrium concentrations of N2O4 and NO2? (b) An additional 0.010 mol of NO2 is added to the flask. How will this change affect the concentration of N2O4? (c) Justify your conclusion by calculating the new equilibrium concentrations of NO2 and N2O4. 10.95 The overall photosynthesis reaction is 6 CO2(g) ϩ 6 H2O(l) : C6H12O6(aq) ϩ 6 O2(g), and ⌬H° ϭ ϩ2802 kJ. Suppose that the reaction is at equilibrium. State the effect that each of the following changes will have on the equilibrium composition (tends to shift toward the formation of reactants, tends to shift toward the formation of products, or has no effect). (a) The partial pressure of O2 is increased. (b) The system is compressed. (c) The amount of CO2 is increased. (d) The temperature is increased. (e) Some of the C6H12O6 is removed. (f) Water is added. (g) The partial pressure of CO2 is decreased. 10.96 A certain enzyme-catalyzed reaction in a biochemical cycle has an equilibrium constant that is 10 times the equilibrium constant of the next step in the cycle. If the standard Gibbs free energy of the first reaction is Ϫ200. kJиmolϪ1 , what is the standard Gibbs free energy of the second reaction? 10.97 The following plot shows how the partial pressures of reactant and products vary with time for the decomposition of compound A into compounds B and C. All three compounds are gases. Use this plot to do the following: (a) Write a balanced chemical equation for the reaction. (b) Calculate the equilibrium constant for the reaction. (c) Calculate the value of Kc for the reaction at 25°C. A C B Time 0 10 20 30 Partialpressure,kPa 1 2 EXERCISES 419 10.98 The following plot shows a system composed of compounds A and B in a rigid, constant-volume flask. The system was initially at equilibrium, then a change occurred. (a) Describe the change that occurred and how it affected the system. (b) Write the chemical equation for the reaction that occurred. (c) Calculate the value of K for the reaction. 10.99 At 1565 K, the equilibrium constants for the reactions (1) 2 H2O(g) #4 2 H2(g) ϩ O2(g) and (2) 2 CO2(g) #4 2 CO(g) ϩ O2(g) are 1.6 ϫ 10Ϫ11 and 1.3 ϫ 10Ϫ10 , respectively. (a) What is the equilibrium constant for the reaction (3) CO2(g) ϩ H2(g) #4 H2O(g) ϩ CO(g) at that temperature? (b) Show that the manner in which equilibrium constants are calculated is consistent with the manner in which the ⌬Gr° values are calculated when combining two or more equations by determining ⌬Gr° for reactions (1) and (2) and using those values to calculate ⌬Gr° and K3 for reaction (3). 10.100 1.50 mol NH3 decomposed in the reaction 2 NH3(g) #4 N2(g) ϩ 3 H2(g) in a 1.0-L flask at a certain temperature. At equilibrium, 0.20 mol NH3 remains. (a) Calculate K for the reaction. (b) Use the information in Table 10.2 to estimate the temperature at which the reaction occurred. 10.101 0.020 mol NO2 was introduced into a 1.00-L flask and the reaction 2 NO2(g) #4 N2O4(g) was allowed to come to equilibrium at 298 K. (a) Using information in Table 10.2 calculate the equilibrium concentrations of the two gases. (b) The volume of the flask is reduced to half its original volume. Calculate the new equilibrium concentrations of the gases. 10.102 0.100 mol SO3 was introduced into a 2.00-L flask and the reaction 2 SO2(g) ϩ O2(g) #4 2 SO3(g) was allowed to come to equilibrium at 700 K. (a) Using information in Table 10.2 calculate the equilibrium concentrations of the three gases. (b) The volume of the flask is increased to 6.00-L. Calculate the new equilibrium concentrations of the gases. 10.103 Let ␣ be the fraction of PCl5 molecules that have decomposed to PCl3 and Cl2 in the reaction PCl5(g) #4 PCl3(g) ϩ Cl2(g) in a constant-volume container; then the amount of PCl5 at equilibrium is n(1 Ϫ ␣), where n is the amount present initially. Derive an equation for K in terms of ␣ and the total pressure P, and solve it for ␣ in terms of P. Calculate the fraction decomposed at 556 K, at which temperature K ϭ 4.96, and the total pressure is (a) 0.50 bar; (b) 1.00 bar. 10.104 The three compounds methylpropene, cis-2-butene, and trans-2-butene are isomers with formula C4H8, with ⌬Gf° ϭ ϩ58.07, ϩ65.86, and ϩ62.97 kJиmolϪ1 , respectively. In the presence of a suitable metal catalyst, these three compounds can be interconverted to give an equilibrium gaseous mixture. What will be the percentage of each isomer present at 25°C once equilibrium is established? 10.105 (a) What is the standard Gibbs free energy of the reaction CO(g) ϩ H2O(g) #4 CO2(g) ϩ H2(g) when K ϭ 1.00? (b) From data available in Appendix 2A, estimate the temperature at which K ϭ 1.00. (c) At this temperature, a cylinder is filled with CO(g) at 10.00 bar, H2O(g) at 10.00 bar, H2(g) at 5.00 bar, and CO2(g) at 5.00 bar. What will be the partial pressure of each of these gases when the system reaches equilibrium? (d) If the cylinder were filled instead with CO(g) at 6.00 bar, H2O(g) at 4.00 bar, H2(g) at 5.00 bar, and CO2(g) at 10.00 bar, what would the partial pressures be at equilibrium? 10.106 Consider the equilibrium A(g) #4 2 B(g) ϩ 3 C(g) at 25°C. When A is loaded into a cylinder at 10.0 atm and the system is allowed to come to equilibrium, the final pressure is found to be 15.76 atm. What is ⌬Gr° for this reaction? 10.107 (a) Calculate the Gibbs free energies of formation of the halogen atoms X(g) at 1000. K from data available in Table 10.2. (b) Show how these data correlate with the X¬X bond strength by plotting the Gibbs free energy of formation of the atoms against the bond dissociation energy and atomic number. Rationalize any trends you observe. 10.108 The gas phosphine, PH3, decomposes by the reaction 2 PH3(g) : 2 P(s) ϩ 3 H2(g). In an experiment, pure phosphine was placed in a rigid, sealed 1.00-L flask at 0.64 bar and 298 K. After equilibrium was attained, the total pressure in the flask was found to be 0.93 bar. (a) Calculate the equilibrium partial pressures of H2 and PH3. (b) Calculate the mass (in grams) of P produced once equilibrium was reached. (c) Calculate K for this reaction. 10.109 (a) Calculate K at 25°C for the reaction Br2(g) #4 2 Br(g) from the thermodynamic data provided in Appendix 2A. (b) What is the vapor pressure of liquid bromine? (c) What is the partial pressure of Br(g) above the liquid in a bottle of bromine at 25°C? (d) A student wishes to add 0.0100 mol Br2 to a reaction and will do so by filling an evacuated flask with Br2 vapor from a reservoir that contains only bromine liquid in equilibrium with its vapor. The flask will be sealed and then transferred to the reaction vessel. What volume container should the student use to deliver 0.010 mol Br2(g) at 25°C? 10.110 A reaction vessel is filled with Cl2(g) at 1.00 bar and Br2(g) at 1.00 bar, which are allowed to react at 1000. K to form BrCl(g) according to the equation Br2(g) ϩ Cl2(g) #4 2 BrCl(g), K ϭ 0.2. Construct a plot of the Gibbs free energy of this system as a function of partial pressure of BrCl as the reaction approaches equilibrium. 10.111 The Claus process, which is used to remove sulfur found as sulfur dioxide in petroleum, is based on the reaction 2 H2S(g) ϩ SO2(g) #4 3 S(s) ϩ 2 H2O(g). (a) Use data from Appendix 2A to determine the equilibrium constant of this reaction at 25 C. (b) Certain changes (see the following table) are then made to this mixture. Considering each change separately, state the effect (increase, decrease, or no change) that the change has on the original equilibrium values of the quantity in the second column ° Concentration Time A B 420 CHAPTER 10 CHEMICAL EQUILIBRIA (or K, if that is specified). The temperature and volume are constant unless otherwise specified. Change Quantity (a) add S amount of H2O (b) add H2S amount of SO2 (c) remove H2O amount of SO2 (d) remove SO2 amount of S (e) add SO2 K (f) decrease volume amount of SO2 (g) increase temperature amount of SO2 10.112 Using data from Table 10.2 and standard graphing software, determine the enthalpy and entropy of the equilibrium N2O4(g) #4 2 NO2(g) and estimate the NßN bond enthalpy in N2O4. How does this value compare with the mean NßN bond enthalpy in Table 7.8? 10.113 The distribution of Naϩ ions across a typical biological membrane is 10. mmolиLϪ1 inside the cell and 140 mmolиLϪ1 outside the cell. At equilibrium the concentrations would be equal, but in a living cell the ions are not at equilibrium. What is the Gibbs free energy difference for Naϩ ions across the membrane at 37°C (normal body temperature)? The concentration differential must be maintained by coupling to reactions that have at least that difference of Gibbs free energy. 10.114 ATP is a compound that provides energy for biochemical reactions in the body when it undergoes hydrolysis. For the hydrolysis of ATP at 37°C (normal body temperature) ⌬Hr° ϭ Ϫ20. kJиmolϪ1 and ⌬Sr° ϭ ϩ34 JиKϪ1 иmolϪ1 . Assuming that these quantities are independent of temperature, calculate the temperature at which the equilibrium constant for the hydrolysis of ATP becomes greater than 1. 10.115 The reaction N2O4 #4 2 NO2 is allowed to reach equilibrium in chloroform solution at 25°C. The equilibrium concentrations are 0.405 molиLϪ1 N2O4 and 2.13 molиLϪ1 NO2. (a) Calculate K for the reaction. (b) An additional 1.00 mol NO2 is added to 1.00 L of the solution and the system is allowed to reach equilibrium again at the same temperature. Use Le Chatelier’s principle to predict the direction of change (increase, decrease, or no change) for N2O4, NO2, and Kc after the addition of NO2. (c) Calculate the final equilibrium concentrations after the addition of NO2 and confirm that your predictions in part (b) were valid. If they do not agree, check your procedure and repeat it if necessary. 10.116 In order to generate the starting material for a polymer that is used in water bottles, hydrogen is removed from the ethane in natural gas to produce ethene in the catalyzed reaction C2H6(g) #4 H2(g) ϩ C2H4(g). Use the information in Appendix 2A to calculate the equilibrium constant for the reaction at 298 K. (a) If the reaction is begun by adding the catalyst to a flask containing C2H6 at 10.0 bar, what will be the partial pressure of the C2H4 at equilibrium? (b) Identify three steps the manufacturer can take to increase the yield of product. 10.117 Determine the vapor pressure of heavy water, D2O, and of normal water at 25°C by using data in Appendix 2A. How do these values compare with each other? Using your knowledge of intermolecular forces, explain the reason for the difference observed. 10.118 A chemist needs to prepare the compound PH3BCl3 by using the reaction PH3(g) ϩ BCl3(g) : PH3BCl3(s) for which K ϭ 19.2 at 60.°C. (a) Write the expression for K. (b) What is the value of Kc for this reaction? (c) Some solid PH3BCl3 was added to a closed 500.-mL vessel at 60.°C that already contains 0.0128 mol PH3. What is the equilibrium concentration of PH3? (d) At 70.°C, K ϭ 26.2. Is the reaction endothermic or exothermic? Explain your reasoning. (e) What is the new value of Kc? (f) Can the reactants in the preceding reaction be classified as acids or bases? Explain your answer. 10.119 It is possible to choose a different standard state (after all, molecules don’t know what their standard state is) for the pressure or concentration of chemical species. The standard state corresponding to data presented in Appendix 2A is for 1 bar or 1 M, as appropriate. Calculate ⌬Gf° for each of the following species if the standard state condition were changed to that listed (the temperature remains at 298 K): (a) HI(g), standard state corresponds to 1 atm (b) CO(g), standard state corresponds to 1 atm (c) HCN(g), standard state corresponds to 1 Torr (d) CH4(g), standard state corresponds to 1 Pa 10.120 Cyclohexane (C) and methylcyclopentane (M) are isomers with the chemical formula C6H12. The equilibrium constant for the rearrangement C #4 M in solution is 0.140 at 25°C. (a) A solution of 0.0200 molиLϪ1 cyclohexane and 0.100 molиLϪ1 methylcyclopentane is prepared. Is the system at equilibrium? If not, will it will form more reactants or more products? (b) What are the concentrations of cyclohexane and methylcyclohexane at equilibrium? (c) If the temperature is raised to 50.°C, the concentration of cyclohexane becomes 0.100 molиLϪ1 when equilibrium is re-established. Calculate the new equilibrium constant. (d) Is the reaction exothermic or endothermic at 25°C? Explain your conclusion. 10.121 Use the Living Graph “Variation of Equilibrium Constant” on the Web site for this book to construct a plot from 250 K to 350 K for reactions with standard reaction Gibbs free energies of ϩ11 kJиmolϪ1 to ϩ15 kJиmolϪ1 in increments of 1 kJиmolϪ1 . Which equilibrium constant is most sensitive to changes in temperature? 10.122 (a) Use graphing software, such as that found on the Web site for this book, and data at 1000. K and 1200. K from Table 10.2, to plot the van ’t Hoff equations for the dissociation of the diatomic halogens into the atoms, X2(g) #4 2 X(g). (b) From the graphs, determine the enthalpies and entropies of dissociation. (c) Use these data to calculate the molar entropies of the gaseous halogen atoms X(g). 10.123 The two air pollutants SO3 and NO can react in the atmosphere as follows: SO3(g) ϩ NO(g) : SO2(g) ϩ NO2(g). (a) Predict the effect of the following changes to the amount of NO2 when the reaction has come to equilibrium in a stainless steel bulb equipped with entrants for chemicals: (i) the amount of NO is increased; (ii) the SO2 is removed by condensation; (iii) the pressure is tripled by pumping in helium. (b) Given that at a certain temperature K ϭ 6.0 ϫ 103 , calculate the amount (in moles) of NO that must be added to a 1.00-L vessel containing 0.245 mol SO3(g) to form 0.240 mol SO2(g) at equilibrium. Chemistry Connections 10.124 Reactions between gases in the atmosphere are not at equilibrium, but for a thorough understanding of them we need to EXERCISES 421 study both the rates at which they take place and their behavior under equilibrium conditions. (a) The equilibrium for the depletion of ozone in the stratosphere is summarized by the equation 2 O3(g) #4 3 O2(g). From values in Appendix 2A, determine the standard Gibbs free energy and the standard entropy for the reaction. (b) What is the equilibrium constant of the reaction in part (a) at 25°C? What is the significance of your answer with regard to ozone depletion? (c) A reaction that destroys ozone in the stratosphere is O3(g) ϩ O(g) #4 2 O2(g). Calculate the value of the equilibrium constant for this reaction at 25°C given that at that temperature the reaction is catalyzed (accelerated) by NO2 molecules in a two-step process: NO2(g) ϩ O(g) #4 NO(g) ϩ O2(g) K ϭ 7 ϫ 10103 NO(g) ϩ O3(g) #4 NO2(g) ϩ O2(g) K ϭ 5.8 ϫ 10Ϫ34 (d) Use your answer to part (c) to find the standard Gibbs free energy of formation of O atoms. (e) The temperature dependence of the equilibrium constant of the reaction N2(g) ϩ O2(g) #4 2 NO(g), which makes an important contribution to the concentration of atmospheric nitrogen oxides, can be expressed as ln K ϭ 2.5 Ϫ (21 700 K)/T. What is the standard enthalpy of the forward reaction at 298 K? Will this reaction proceed further at the very low temperatures of the stratosphere or at the very high temperatures in an internal combustion engine? (f) An equimolar mixture of N2 and O2 was heated to a certain temperature until the reaction in part (e) came to equilibrium. The equilibrium reaction mixture was found to contain an equal number of moles of each reactant and product. At what temperature was the reaction carried out? (g) An equimolar mixture of N2 and O2 with a total pressure of 4.00 bar was allowed to come to equilibrium in the reaction in part (e) at 1200. K. What will be the partial pressure of each reactant and product at equilibrium? 422 CHAPTER 10 CHEMICAL EQUILIBRIA 423 What Are the Key Ideas? Brønsted acids are proton donors; Brønsted bases are proton acceptors. The composition of a solution of an acid or base immediately adjusts to satisfy the values of the equilibrium constants for all the proton transfer reactions taking place. Why Do We Need to Know This Material? Chapter 10 developed the concepts of chemical equilibria in gaseous systems; this chapter extends those ideas to aqueous systems, which are important throughout chemistry and biology. Equilibria between acids, bases, and water in plant and animal cells are vital for the survival of individual organisms. To sustain human societies and protect our ecosystems, we also need these ideas to understand the acidity of rain, natural waters such as lakes and rivers, and municipal water supplies. What Do We Need to Know Already? This chapter builds on the introduction to acids and bases in Section J. It also extends the principles of thermodynamics (Chapters 7 and 8) and chemical equilibrium (Chapter 10) to aqueous systems. To a smaller extent, it uses the concepts of hydrogen bonding (Section 5.5), bond polarity (Section 2.12), and bond strength (Sections 2.14 and 2.15). T wo of the most important classes of compounds in the whole of chemistry are the acids and bases. They are involved in huge numbers of reactions, in laboratory synthetic and analytical procedures, in industry, and in living organisms. It is not much of an exaggeration to say that most of the processes that go on inside our bodies are the reactions of acids and bases: one could take the view that life is one long titration. In this chapter, we see what acids and bases are and why they vary in strength. We shall use thermodynamics, particularly equilibrium constants, to describe the strengths of acids and bases quantitatively and thereby develop our insight into their behavior. We then use our knowledge of equilibria involving acids and bases to examine systems in which more than one equilibrium is taking place simultaneously, as occurs in many natural systems of ecological and biological importance. THE NATURE OF ACIDS AND BASES When chemists see a pattern in the reactions of certain substances, they formulate a definition of a class of substance that captures the pattern. Then, by identifying a substance as belonging to that class, they immediately know a great deal about its behavior. Classification of this kind opens the door to understanding rather than just memorizing the properties of individual substances. The reactions of the substances we call “acids” and “bases” are an excellent illustration of this approach. The pattern in these reactions was first identified in aqueous solutions, and led to the Arrhenius definitions of acids and bases (Section J). However, chemists discovered that similar reactions take place in nonaqueous solutions and even in the absence of solvent. The original definitions had to be replaced by more general definitions that encompassed this new knowledge. 11.1 Brønsted–Lowry Acids and Bases In 1923, the Danish chemist Johannes Brønsted proposed that An acid is a proton donor. A base is a proton acceptor. THE NATURE OF ACIDS AND BASES 11.1 Brønsted–Lowry Acids and Bases 11.2 Lewis Acids and Bases 11.3 Acidic, Basic, and Amphoteric Oxides 11.4 Proton Exchange Between Water Molecules 11.5 The pH Scale 11.6 The pOH of Solutions WEAK ACIDS AND BASES 11.7 Acidity and Basicity Constants 11.8 The Conjugate Seesaw 11.9 Molecular Structure and Acid Strength 11.10 The Strengths of Oxoacids and Carboxylic Acids THE pH OF SOLUTIONS OF WEAK ACIDS AND BASES 11.11 Solutions of Weak Acids 11.12 Solutions of Weak Bases 11.13 The pH of Salt Solutions POLYPROTIC ACIDS AND BASES 11.14 The pH of a Polyprotic Acid Solution 11.15 Solutions of Salts of Polyprotic Acids 11.16 The Concentrations of Solute Species 11.17 Composition and pH AUTOPROTOLYSIS AND pH 11.18 Very Dilute Solutions of Strong Acids and Bases 11.19 Very Dilute Solutions of Weak Acids 423 Chapter 11 ACIDS AND BASES The term proton in these definitions refers to the hydrogen ion, Hϩ . An acid is a species containing an acidic hydrogen atom, which is a hydrogen atom that can be transferred as its nucleus, a proton, to another species acting as a base. The same definitions were proposed independently by the English chemist Thomas Lowry, and the theory based on them is called the Brønsted–Lowry theory of acids and bases. A proton donor is commonly referred to as a Brønsted acid and a proton acceptor as a Brønsted base. Whenever we refer to an “acid” or a “base” in this chapter, we shall mean a Brønsted acid and a Brønsted base. A substance can act as an acid only if a base is present to accept its acidic protons. An acid does not simply release its acidic proton: the proton is transferred to the base through direct contact. For example, HCl is a Brønsted acid. In the gas phase, an HCl molecule remains intact. However, when HCl dissolves in water, each HCl molecule immediately transfers an Hϩ ion to a neighboring H2O molecule, which here is acting as a base (Fig. 11.1). This process is a proton transfer reaction, a reaction in which a proton is transferred from one species to another. We say that the HCl molecule becomes deprotonated: HCl(aq) ϩ H2O(l) H3Oϩ (aq) ϩ ClϪ (aq) Because at equilibrium virtually all the HCl molecules have donated their protons to water, HCl is classified as a strong acid. The proton transfer reaction essentially goes to completion. The H3Oϩ ion is called the hydronium ion. It is strongly hydrated in solution, and there is some evidence that a better representation of the species is H9O4 ϩ (or even larger clusters of water molecules attached to a proton). A hydrogen ion in water is sometimes represented as Hϩ (aq), but we must remember that Hϩ does not exist by itself in water and that H3Oϩ is a better representation because it indicates that a Brønsted base (H2O) has accepted a proton. Another example of an acid is hydrogen cyanide, HCN, which transfers its proton to water when it dissolves to form the solution known as hydrocyanic acid, HCN(aq). However, only a small fraction of the HCN molecules donate their protons, and so, as described in Section J, we classify HCN as a weak acid in water. We write the proton transfer reaction as an equilibrium: HCN(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CNϪ (aq) Like all chemical equilibria, this equilibrium is dynamic and we should think of protons as ceaselessly exchanging between HCN and H2O molecules, with a constant but low concentration of CNϪ and H3Oϩ ions. The proton transfer reaction of a strong acid, such as HCl, in water is also dynamic, but the equilibrium lies so strongly in favor of products that we represent it just by its forward reaction with a single arrow. In Section J we saw that an Arrhenius acid is a compound that produces hydronium ions in water and an Arrhenius base is a compound that produces hydroxide ions in water. The Brønsted definition is more general because it includes the possibility that an ion is an acid (an option not allowed by the Arrhenius definition). For instance, a hydrogen carbonate ion, HCO3 Ϫ , one of the species present in natural waters, can act as an acid and donate a proton to an H2O molecule (Fig. 11.2): HCO3 Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CO3 2Ϫ (aq) This reaction proceeds to completion if the CO3 2Ϫ ions are removed by precipitation with Ca2ϩ ions to form a precipitate of calcium carbonate. In the absence of ions that remove the CO3 2Ϫ ions, though, the equilibrium remains strongly in favor of the reactants because a positively charged proton can be removed from the negatively charged HCO3 Ϫ ion only with difficulty. In the Brønsted–Lowry theory, the strength of an acid depends on the extent to which it donates protons to the solvent. We can therefore summarize the distinction between strong and weak acids as follows: A strong acid is fully deprotonated in solution. A weak acid is only partly deprotonated in solution. ¡ 424 CHAPTER 11 ACIDS AND BASES FIGURE 11.2 Stalactites hang from the roof of a cave and stalagmites grow from the floor. Both are made of insoluble calcium carbonate formed from the soluble hydrogen carbonate ions in groundwater. HCl H2O ClϪ H3Oϩ H2O H Oϩ HCl H FIGURE 11.1 When an HCl molecule dissolves in water, a hydrogen bond forms between the H atom of HCl (the acid) and the O atom of a neighboring H2O molecule (the base). The nucleus of the hydrogen atom is pulled out of the HCl molecule to become part of a hydronium ion. Animation 11.1 The strength of an acid depends on the solvent and an acid that is strong in water may be weak in another solvent or vice versa (see Section 11.8). However, because almost all reactions in living tissues and most reactions in laboratories take place in water, unless otherwise specified, the solvent used in this chapter is water. A Brønsted base possesses a lone pair of electrons to which a proton can bond. For example, an oxide ion is a Brønsted base. When CaO dissolves in water, the strong electric field of the small, highly charged O2Ϫ ion pulls a proton out of a neighboring H2O molecule (Fig. 11.3). In the process, a coordinate covalent bond forms between the proton and a lone pair of electrons on the oxide ion. By accepting a proton, the oxide ion has become protonated. Every oxide ion present accepts a proton from water, and so O2Ϫ is an example of a strong base in water, a species that is fully protonated. That is, the following reaction goes essentially to completion: O2Ϫ (aq) ϩ H2O(l) 2 OHϪ (aq) Another example of a Brønsted base is ammonia. When an NH3 molecule is present in water, the lone pair of electrons on the N atom accepts a proton from H2O: NH3(aq) ϩ H2O(l) #¢4 NH4 ϩ (aq) ϩ OHϪ (aq) The fact that the NH3 molecule is electrically neutral means that it has much less protonpulling power than the oxide ion. As a result, only a very small proportion of the NH3 molecules are converted into NH4 ϩ ions (Fig. 11.4). Ammonia is therefore an example of a weak base. All amines, organic derivatives of ammonia, such as methylamine, CH3NH2, are weak bases in water. Because the proton transfer equilibrium in an aqueous solution of ammonia is dynamic, we should imagine the protons as ceaselessly exchanging between NH3 and H2O molecules with a constant, low concentration of NH4 ϩ and OHϪ ions. The proton transfer to the strong base O2Ϫ is also dynamic, but the equilibrium lies so strongly in favor of products that, as for a strong acid, we represent it just by its forward reaction with a single arrow. We can summarize the distinction between strong and weak bases as follows: A strong base is completely protonated in solution. A weak base is only partially protonated in solution. As for acids, the strength of a base depends on the solvent; a base that is strong in water may be weak in another solvent and vice versa. The common strong bases in aqueous solution are listed in Table J.1. A note on good practice: The oxides and hydroxides of the alkali and alkaline earth metals are not Brønsted bases: the oxide and hydroxide ions they contain are the bases (the cations are spectator ions). However, for convenience, and using the Arrhenius definitions, chemists often refer to the compounds themselves as bases. The species produced by proton transfer in aqueous solution may also donate a proton to or accept a proton from water and thus be classified as an acid or a base. For example, the CNϪ ion produced when HCN is deprotonated can accept a proton from a neighboring H2O molecule and form HCN again. Therefore, according to the Brønsted definition, CNϪ is a base: it is called the “conjugate base” of the acid HCN. In general, a conjugate base of an acid is the species left when the acid donates a proton: donates Hϩ Acid ∫∫∫∫∫B conjugate base Because HCN is the acid that forms when a proton is transferred to a cyanide ion, HCN is the “conjugate acid” of the base CNϪ . In general, a conjugate acid of a base is the species formed when the base accepts a proton: accepts Hϩ Base ∫∫∫∫∫B conjugate acid ¡ 11.1 BRØNSTED–LOWRY ACIDS AND BASES 425 A coordinate covalent bond is a bond in which both bonding electrons come from the same atom (Section 2.11). OHϪ OHϪ O2Ϫ H2O OHϪ H O O2Ϫ FIGURE 11.3 When an oxide ion is present in water, it exerts such a strong attraction on the nucleus of a hydrogen atom in a neighboring water molecule that the hydrogen ion is pulled out of the molecule as a proton. As a result, the oxide ion forms two hydroxide ions. OHϪ NH3 NH4 ϩ ϩ Ϫ FIGURE 11.4 In this molecular portrayal of the structure of a solution of ammonia in water at equilibrium, we see that NH3 molecules are still present because only a small percentage of them have been protonated by transfer of hydrogen ions from water. In a typical solution, only about 1 in 100 NH3 molecules is protonated. The inset at the left shows only the solute species. Animation 11.4 Self-Test 11.1A What is (a) the conjugate acid of OH– ; (b) the conjugate base of HPO4 2Ϫ ? [Answer: (a) H2O; (b) PO4 3Ϫ ] Self-Test 11.1B What is (a) the conjugate acid of H2O; (b) the conjugate base of NH3? The Brønsted definitions of acids and bases also apply to species in nonaqueous solvents and even to gas-phase reactions where there is no solvent. For example, when acetic acid is dissolved in liquid ammonia, proton transfer takes place and the following equilibrium is reached: CH3COOH(am) ϩ NH3(l) #¢4 CH3CO2 – (am) ϩ NH4 ϩ (am) (The label “am” indicates a species dissolved in liquid ammonia.) An example of proton transfer in the gas phase is the reaction of hydrogen chloride and ammonia gases. They produce the fine powder of ammonium chloride often seen coating surfaces in chemical laboratories (Fig. 11.5): HCl(g) ϩ NH3(g) NH4Cl(s) A Brønsted acid is a proton donor and a Brønsted base is a proton acceptor. The conjugate base of an acid is the base formed when the acid has donated a proton. The conjugate acid of a base is the acid that forms when the base has accepted a proton. A strong acid is fully deprotonated in solution; a weak acid is only partially deprotonated in solution. A strong base is completely protonated in solution; a weak base is only partially protonated in solution. 11.2 Lewis Acids and Bases The Brønsted–Lowry theory focuses on the transfer of a proton from one species to another. However, the concepts of acids and bases have a much wider significance than the transfer of protons. Even more substances can be classified as acids or bases under the definitions developed by G. N. Lewis: A Lewis acid is an electron pair acceptor. A Lewis base is an electron pair donor. When a Lewis base donates an electron pair to a Lewis acid, the two species share the pair and become joined by a coordinate covalent bond. A proton (Hϩ ) is an electron pair acceptor. It is therefore a Lewis acid because it can attach to (“accept”) a lone pair of electrons on a Lewis base. In other words, a Brønsted acid is a supplier of one particular Lewis acid, a proton. ¡ 426 CHAPTER 11 ACIDS AND BASES EXAMPLE 11.1 Writing the formulas of conjugate acids and bases Write the formulas of (a) the conjugate base of HCO3 Ϫ and (b) the conjugate acid of O2Ϫ . PLAN To proceed systematically, remove an Hϩ ion to form a conjugate base and add an Hϩ ion to form a conjugate acid. SOLVE The conjugate base of an acid has one less Hϩ ion than the acid; the conjugate acid of a base has one more Hϩ ion than that of the base. (a) The conjugate base of HCO3 Ϫ is CO3 2Ϫ . (b) The conjugate acid of O2Ϫ is OHϪ . 2Ϫ 2Ϫ Ϫ Ϫ (a) (b) Acid Base FIGURE 11.5 The white powder is ammonium chloride formed by gaseous ammonia and hydrogen chloride gas escaping from concentrated hydrochloric acid. The Lewis theory is more general than the Brønsted–Lowry theory. For instance, metal atoms and ions can act as Lewis acids, as in the formation of Ni(CO)4 from nickel atoms (the Lewis acid) and carbon monoxide (the Lewis base), but they are not Brønsted acids. Likewise, a Brønsted base is a special kind of Lewis base, one that can use a lone pair of electrons to form a coordinate covalent bond to a proton. For instance, an oxide ion is a Lewis base. It forms a coordinate covalent bond to a proton, a Lewis acid, by supplying both the electrons for the bond: The black curved arrows show the direction in which the electrons can be thought to move; the red curved arrow shows the proton transfer. Similarly, when the Lewis base ammonia, NH3, dissolves in water, some of the molecules accept protons from water molecules: The Lewis definition of a base is broader than the Brønsted definition. That is, although every Brønsted base is a Lewis base, not every Lewis base is a Brønsted base. For instance, carbon monoxide is an important Lewis base in its reactions with metals, but it is not a Brønsted base because it does not accept protons. A note on good practice: The entities that are regarded as acids and bases are different in each theory. In the Lewis theory, the proton is an acid; in the Brønsted theory, the species that supplies the proton is the acid. In both the Lewis and Brønsted theories, the species that accepts a proton is a base; in the Arrhenius theory, the compound that supplies the proton acceptor is the base (Fig. 11.6). Many nonmetal oxides are Lewis acids that react with water to give Brønsted acids. An example is the reaction of CO2 with water: In this reaction, the C atom of CO2, the Lewis acid, accepts an electron pair from the O atom of a water molecule, the Lewis base, and a proton migrates from an H2O oxygen atom to a CO2 oxygen atom. The product, an H2CO3 molecule, is a Brønsted acid. O HO C O H HO O HC O∫B N O H HH H H N H H H H ϩ ∫B O Hϩ Ϫ O O O H 2Ϫ H H O HϩßB Ϫ Ϫ 11.2 LEWIS ACIDS AND BASES 427 Bronsted acid (any proton donor) Arrhenius acid (a compound that supplies H+ in water) + + Lewis acid (any electron pair acceptor) Example: H+ .... / Arrhenius base (a compound that supplies OH− in water) − .. Bronsted base (any proton acceptor) / Lewis base (any electron pair donor) .. FIGURE 11.6 The left-hand column illustrates the action of acids in the Arrhenius, Brønsted, and Lewis definitions. The right-hand column shows the action of the corresponding bases. In each case the rounded rectangles enclose the acid or base and the small white circles represent hydrogen ions. The green square represents an accompanying ion. The Arrhenius definition includes any accompanying ion, whereas the Brønsted definition may apply either to a compound or, as here, to an ion. Notice that only the Arrhenius definition requires the presence of water (the blue background). 428 CHAPTER 11 ACIDS AND BASES Although the Lewis definitions are natural extensions of the Brønsted definitions, they are too broad for most of our present purposes. Because proton transfer plays a very special role in chemistry we shall focus on it in the rest of the chapter. However, in Chapter 16 we shall see that the Lewis definitions do have a very important role to play and they will then move to center stage. Self-Test 11.2A Identify (a) the Brønsted acids and bases in both reactants and products in the proton transfer equilibrium HNO2(aq) ϩ HPO4 2Ϫ (aq) #4NO2 Ϫ (aq) ϩ H2PO4 Ϫ (aq). (b) Which species (not necessarily shown explicitly) are Lewis acids and which are Lewis bases? [Answer: (a) Brønsted acids, HNO2, H2PO4 Ϫ ; Brønsted bases, HPO4 2Ϫ and NO2 Ϫ ; (b) Lewis acid, Hϩ ; Lewis bases, HPO4 2Ϫ and NO2 Ϫ ] Self-Test 11.2B Identify (a) the Brønsted acids and bases in both reactants and products in the proton transfer equilibrium HCO3 Ϫ (aq) ϩ NH4 ϩ (aq) #4 H2CO3(aq) ϩ NH3(aq). (b) Which species (not necessarily shown explicitly) are Lewis acids and which are Lewis bases? A Lewis acid is an electron pair acceptor; a Lewis base is an electron pair donor. A proton is a Lewis acid that attaches to a lone pair provided by a Lewis base. 11.3 Acidic, Basic, and Amphoteric Oxides An acidic oxide is an oxide that reacts with water to form a solution of a Brønsted acid: an example is CO2, which forms H2CO3, as we saw in Section 11.2. Acidic oxides are molecular compounds, such as CO2, which are Lewis acids that react with bases. Carbon dioxide, for instance, reacts with the OHϪ present in aqueous sodium hydroxide: 2 NaOH(aq) ϩ CO2(g) Na2CO3(aq) ϩ H2O(l) We can glimpse the underlying complexity of this apparently simple reaction by noting that it involves the attack on CO2 of OHϪ acting as a Lewis base and proton transfer to another OHϪ ion acting as a Brønsted base (although these processes are being shown together here, they do not take place in one step): The white crust often seen on pellets of sodium hydroxide is a mixture of sodium carbonate formed in this way and of sodium hydrogen carbonate formed in a similar reaction: NaOH(aq) ϩ CO2(g) NaHCO3(aq) A basic oxide is an oxide that reacts with water to form a solution of hydroxide ions, as in the reaction CaO(s) ϩ H2O(l) Ca(OH)2(aq) Basic oxides are ionic compounds that can react with acids to give a salt and water. For instance, magnesium oxide, a basic oxide, reacts with hydrochloric acid: MgO(s) ϩ 2 HCl(aq) MgCl2(aq) ϩ H2O(l) In this reaction, the base O2Ϫ accepts two protons from the hydronium ions present in the hydrochloric acid solution. Metals typically form basic oxides and nonmetals typically form acidic oxides, but what about the elements that lie on the diagonal frontier between the metals and nonmetals? Along this frontier, from beryllium to polonium, metallic character blends into nonmetallic character and the oxides of these elements have both acidic and basic ¡ ¡ ¡ O C O H O O C O Lewis acid Lewis base and Brønsted acid Brønsted base ∫B Ϫ Ϫ H H H ϩ Ϫ Ϫ O O O ¡ FIGURE 11.7 The elements in and close to the diagonal line of metalloids typically form amphoteric oxides (indicated by the red lettering). BeO Al2O3 Ga2O3 In2O3 GeO2 SnO SnO2 PbO PbO2 Bi2O3 Sb2O3 As2O3 13/III 14/IV 15/V 16/VI2 B Si Te Po character (Fig. 11.7). Substances that react with both acids and bases are classified as amphoteric, from the Greek word for “both.” For example, aluminum oxide, Al2O3, is amphoteric. It reacts with acids: Al2O3(s) ϩ 6 HCl(aq) 2 AlCl3(aq) ϩ 3 H2O(l) and with bases: 2 NaOH(aq) ϩ Al2O3(s) ϩ 3 H2O(l) 2 Na[Al(OH)4](aq) The product of the second reaction is sodium aluminate, which contains the aluminate ion, Al(OH)4 Ϫ . Other main-group elements that form amphoteric oxides are shown in Fig.11.7. The acidic, amphoteric, or basic character of the oxides of the d-block metals depends on their oxidation state (Fig. 11.8; also see Chapter 16). Metals form basic oxides, nonmetals form acidic oxides; the elements on a diagonal line from beryllium to polonium and several d-block metals form amphoteric oxides. 11.4 Proton Exchange Between Water Molecules An important implication of the Brønsted definitions of acids and bases is that the same substance may be able to function as both an acid and a base. For example, we have seen that a water molecule accepts a proton from an acid molecule (such as HCl or HCN) to form an H3Oϩ ion. So water is a base. However, a water molecule can donate a proton to a base (such as O2Ϫ or NH3) and become an OHϪ ion. So water is also an acid. We describe water as amphiprotic, meaning that an H2O molecule can act both as a proton donor and as a proton acceptor. A note on good practice: Distinguish between amphoteric and amphiprotic. Aluminum metal is amphoteric (it reacts with both acids and bases), but it has no hydrogen atoms to donate as protons, and is not amphiprotic. Because water is amphiprotic—because it is both a Brønsted acid and a Brønsted base—proton transfer between water molecules occurs even in pure water, with one molecule acting as a proton donor and a neighboring molecule acting as a base: 2 H2O(l) #¢4 H3Oϩ (aq) ϩ OHϪ (aq) (A) In more detail, the forward reaction is The reaction is very fast in both directions, and so is always at equilibrium in water and in aqueous solutions. In every glass of water, protons from the hydrogen atoms are ceaselessly migrating between the molecules. This type of reaction, in which one molecule transfers a proton to another molecule of the same kind, is called autoprotolysis (Fig. 11.9). The equilibrium constant for reaction A is K = aH3O+ aOH- (aH2O)2 O H H O H H H ϩ ∫B ϩO H H O H Ϫ ¡ ¡ 11.4 PROTON EXCHANGE BETWEEN WATER MOLECULES 429 FIGURE 11.8 Certain elements of the d-block form amphoteric oxides, particularly in oxidation states intermediate in their range (as shown here for Period 4). Sc Ti V Cr Mn Fe Co Ni Cu Zn 3 4 5 6 7 8 9 10 11 12 43 4 4 4 4, 3 3 3 2 2 FIGURE 11.9 As a result of autoprotolysis, pure water consists of hydronium ions and hydroxide ions as well as water molecules. The concentration of ions that results from autoprotolysis is only about 10Ϫ7 molиLϪ1 , and so only about 1 molecule in 200 million is ionized. The inset at the left shows only the ions. Animation 11.9 OHϪ H3Oϩ ϩ Ϫ In dilute aqueous solutions (the only ones we consider in this chapter), the solvent, water, is very nearly pure, and so its activity may be taken to be 1. The resulting expression is called the autoprotolysis constant of water and is written Kw: (1a) As we saw in Section 10.2, the activity of a solute J in a dilute solution is approximately equal to the molar concentration relative to the standard molar concentration, [J]/c°, with c° ϭ 1 molиLϪ1 , and so a practical form of this expression is Kw ϭ [H3Oϩ ][OHϪ ] (1b)* where, as in Chapter 10, we have simplified the appearance of the expression by replacing [J]/c° by [J], the value of the molarity in moles per liter with the units struck out. In pure water at 25°C, the molar concentrations of H3Oϩ and OHϪ are equal (because the liquid is electrically neutral overall) and are known by experiment to be 1.0 ϫ 10Ϫ7 molиLϪ1 . Therefore, at 25°C, Kw ϭ (1.0 ϫ 10Ϫ7 ) ϫ (1.0 ϫ 10Ϫ7 ) ϭ 1.0 ϫ 10Ϫ14 The concentrations of H3Oϩ and OHϪ are very low in pure water, which explains why pure water is such a poor conductor of electricity. To imagine the very tiny extent of autoprotolysis, think of each letter in this book as a water molecule. We would need to search through more than 50 books to find one ionized water molecule. Unless otherwise stated, all the calculations in this chapter will be for 25°C. Thinking point: The autoprotolysis reaction is endothermic; do you expect Kw to increase or decrease with increasing temperature? It is important to remember that Kw is fundamentally no different from the equilibrium constants that were discussed in Chapter 10. Because Kw is an equilibrium constant, the product of the concentrations of H3Oϩ and OHϪ ions in any aqueous solution is always equal to Kw. We can increase the concentration of H3Oϩ ions by adding acid, and the concentration of OHϪ ions will immediately respond by decreasing to preserve the value of Kw. Alternatively, we can increase the concentration of OHϪ ions by adding base, and the concentration of H3Oϩ ions will decrease correspondingly. The autoprotolysis equilibrium links the concentrations of H3Oϩ and OHϪ ions rather like a seesaw: when one goes up, the other must go down (Fig. 11.10). Kw = aH3O+ aOH- 430 CHAPTER 11 ACIDS AND BASES Kw is also widely called the autoionization constant and sometimes the ion product constant of water. K Ca Sc Rb Sr Y Cs Ba Lu Decide whether the compound is fully dissociated in solution. Because barium is an alkaline earth metal, Ba(OH)2 dissociates almost completely in water to provide Ba2ϩ and OHϪ ions. EXAMPLE 11.2 Calculating the concentrations of ions in a solution of a metal hydroxide What are the concentrations of H3Oϩ and OHϪ in 0.0030 M Ba(OH)2(aq) at 25°C? Anticipate Because the compound provides OHϪ ions, they will be present in overwhelming concentration, but nevertheless there must be a tiny concentration of H3Oϩ ions to maintain the value of Kw. PLAN Most hydroxides of Groups 1 and 2 can be treated as fully dissociated into ions in solution. Decide from the chemical formula how many OHϪ ions are provided by each formula unit and calculate the concentrations of these ions in the solution. To find the concentration of H3Oϩ ions, use the water autoprotolysis constant Kw ϭ [H3Oϩ ][OHϪ ]. SOLVE H3O concentration OH− concentration FIGURE 11.10 The product of the concentrations of hydronium and hydroxide ions in water (pure water and aqueous solutions) is a constant. If the concentration of one type of ion increases, the other must decrease to keep the product of the ion concentrations constant. Animation 11.10 11.5 THE pH SCALE 431 Find the mole ratio of hydroxide ion to barium hydroxide. Ba(OH)2(s) Ba2ϩ (aq) ϩ 2 OH– (aq) 1 mol Ba(OH)2 ϴ 2 mol OHϪ ¡ Calculate the hydroxide ion concentration from the solute concentration. [OHϪ ] ϭ 2 ϫ 0.0030 molиLϪ1 ϭ 0.0060 molиLϪ1 10 000 10000 H2O H3Oϩ 10 000 Rearrange Kw ϭ [H3Oϩ ][OHϪ ] to find the concentration of H3Oϩ ions. [H3O+ ] = Kw [OH- ] = 1.0 * 10-14 0.0060 = 1.7 * 10-12 Evaluate The concentration of H3Oϩ ions is 1.7 pmolиLϪ1 (1 pmol ϭ 10Ϫ12 mol), which is very small, as we expected; but it is not zero. Self-Test 11.3A Estimate the concentrations of (a) H3Oϩ and (b) OH– at 25°C in 6.0 ϫ 10Ϫ5 M HI(aq). [Answer: (a) 60. ␮mol·L–1 ; (b) 0.17 nmol·L–1 ] Self-Test 11.3B Estimate the concentrations of (a) H3Oϩ and (b) OHϪ at 25°C in 2.2 ϫ 10Ϫ3 M NaOH(aq). In aqueous solutions, the concentrations of H3O؉ and OH؊ ions are related by the autoprotolysis equilibrium; if one concentration is increased, then the other must decrease to maintain the value of Kw. 11.5 The pH Scale One difficulty with describing the concentrations of acids and bases quantitatively is that the concentration of H3Oϩ ions can vary over many orders of magnitude: in some solutions, it is higher than 1 molиLϪ1 and, in others, it is lower than 10Ϫ14 molϪ LϪ1 . Chemists avoid the awkwardness of working with such a wide range of values by reporting the hydronium ion concentration in terms of the pH of the solution, the negative logarithm (to the base 10) of the hydronium ion activity: pH ϭ Ϫlog (2a) where (for solutions so dilute that they may be treated as ideal) ϭ [H3Oϩ ]/c°. As in Chapter 10, we simplify the appearance of this expression by interpreting [H3Oϩ ] as the molar concentration of H3Oϩ in moles per liter with the units struck out and write pH ϭ Ϫlog[H3Oϩ ] (2b)* For example, the pH of pure water, in which the concentration of H3Oϩ ions is 1.0 ϫ 10Ϫ7 molиLϪ1 at 25°C, is pH ϭ Ϫlog(1.0 ϫ 10Ϫ7 ) ϭ 7.00 Thinking point: Do you expect the pH of pure water to increase or decrease with increasing temperature? A note on good practice: The number of digits following the decimal point in a pH value is equal to the number of significant figures in the corresponding molar concentration, because the digits preceding the decimal point simply report the power of 10 in the data (as in log 105 ϭ 5). aH3O+ aH3O+ The pH scale was introduced by the Danish chemist Søren Sørensen in 1909 in the course of his work on quality control in the brewing of beer and is now used throughout science, medicine, agriculture, and engineering. The negative logarithm is used so that most pH values are positive numbers. The negative sign in the definition of pH means that the higher the concentration of H3Oϩ ions, the lower the pH: • The pH of a basic solution is greater than 7. • The pH of pure water is 7. • The pH of an acidic solution is less than 7. Notice that, as the concentration of hydronium ions increases, the pH decreases. Because pH is a common logarithm (to the base 10), a change of one pH unit means that the concentration of H3Oϩ ions has changed by a factor of 10. For example, when the concentration of H3Oϩ increases by a factor of 10 from 10Ϫ5 molиLϪ1 to 10Ϫ4 molиLϪ1 , the pH decreases from 5 to 4. Most solutions used in chemistry have a pH ranging from 0 to 14, but values outside this range are possible. Thinking point: Can a pH be negative? If so, what would that signify? 432 CHAPTER 11 ACIDS AND BASES EXAMPLE 11.3 Calculating a pH from a concentration What is the pH of (a) human blood, in which the concentration of H3Oϩ ions is 4.0 ϫ 10Ϫ8 molиLϪ1 ; (b) 0.020 M HCl(aq); (c) 0.040 M KOH(aq)? Anticipate The concentration of H3Oϩ ions in blood is lower than in pure water, so we should expect pH Ͼ 7; in HCl(aq), an acid, we should expect pH Ͻ 7, and in KOH(aq), a base, we should expect pH Ͼ 7. PLAN The pH is calculated from Eq. 2b. For strong acids, the concentration of H3Oϩ is equal to the molarity of the acid. For strong bases, first find the concentration of OHϪ , then convert that concentration into [H3Oϩ ] by using [H3Oϩ ][OHϪ ] ϭ Kw, as described in Example 11.2. SOLVE 14 7 1 pH BasicAcidic 7.40 (a) From pH ϭ Ϫlog [H3Oϩ ], pH ϭ Ϫlog (4.0 ϫ 10Ϫ8 ) ϭ 7.40 (b) HCl is a strong acid, so it is completely deprotonated in water. [H3Oϩ ] ϭ [HCl] ϭ 0.020 molиLϪ1 14 7 1 pH BasicAcidic 1.70 From pH ϭ Ϫlog [H3Oϩ ], pH ϭ Ϫlog 0.020 ϭ 1.70 (c) Because KOH provides one OHϪ ion per formula unit, [OH– ] ϭ [KOH] ϭ 0.040 mol·L–1 14 7 1 pH Basic Acidic Pure water 11.5 THE pH SCALE 433 Find [H3Oϩ ] from [H3Oϩ ][OHϪ ] ϭ Kw in the form [H3Oϩ ] ϭ Kw͞[OHϪ ]. [H3O+ ] = Kw [OH- ] = 1.0 * 10-14 0.040 = 2.5 * 10-13 14 7 1 pH BasicAcidic 12.60 From pH ϭ Ϫlog [H3Oϩ ], pH ϭ Ϫlog (2.5 ϫ 10–13 ) ϭ 12.60 Evaluate The calculated pH values are in line with what we expected. Self-Test 11.4A Calculate the pH of (a) household ammonia, in which the OHϪ concentration is about 3 ϫ 10Ϫ3 molиLϪ1 ; (b) 6.0 ϫ 10Ϫ5 M HClO4(aq). [Answer: (a) 11.5; (b) 4.22] Self-Test 11.4B Calculate the pH of 0.077 M NaOH(aq). The approximate value of the pH of an aqueous solution can be determined very quickly by using a strip of universal indicator paper, which turns different colors at different pH values. More precise measurements are made with a pH meter (Fig. 11.11). This instrument consists of a voltmeter connected to two electrodes that dip into the solution. The difference in electrical potential between the electrodes is proportional to the hydronium ion activity (as will be explained in Section 13.10); so, once the scale on the meter has been calibrated, the pH can be read directly. To convert a pH into a concentration of H3Oϩ ions, we reverse the sign of the pH and then take its antilogarithm: [H3Oϩ ] ϭ 10ϪpH molиLϪ1 (3) FIGURE 11.11 A pH meter is a voltmeter that measures the pH electrochemically. The two samples are (a) orange juice and (b) lemon juice. Notice that the lemon juice has a lower pH and hence a higher concentration of hydronium ions.(a) (b) EXAMPLE 11.4 Calculating the hydronium ion concentration from the pH What is the hydronium ion concentration in a solution with pH ϭ 4.83? Anticipate Because the pH is less than 7, the pH of pure water, the solution must be acidic and we should expect a concentration of H3Oϩ ions greater than 10–7 mol·L–1 . PLAN To calculate the precise value from Eq. 3, we first change the sign of the pH and then take its antilogarithm. 434 CHAPTER 11 ACIDS AND BASES From [H3Oϩ ] ϭ 10–pH mol·L–1 , [H3Oϩ ] ϭ 10–4.83 mol·L–1 ϭ 1.5 ϫ 10–5 molиL–1 Evaluate As expected, the concentration is higher than in pure water, by a factor of more than 100. Self-Test 11.5A The pH of stomach fluids is about 1.7. What is the concentration of H3Oϩ ions in the stomach? [Answer: 2 ϫ 10Ϫ2 molиLϪ1 ] Self-Test 11.5B The pH of pancreatic fluids, which help to digest food once it has left the stomach, is about 8.2. What is the approximate concentration of H3Oϩ ions in pancreatic fluids? Figure 11.12 shows the results of measuring the pH of a selection of liquids and beverages. Fresh lemon juice, as we have seen, has a pH of 2.5, corresponding to an H3Oϩ concentration of 3 mmol·L–1 (with 1 mmol ϭ 10–3 mol). Natural (unpolluted) rain, with an acidity due largely to dissolved carbon dioxide, typically has a pH of about 5.7. In the United States, the Environmental Protection Agency (EPA) defines waste as “corrosive” if its pH is either lower than 3.0 (highly acidic) or higher than 12.5 (highly basic). Lemon juice, with a pH of about 2.5, would be regarded as corrosive; so would solutions of 1 M NaOH(aq), for which the pH is 14. The pH scale is used to report H3O؉ concentration: pH ‫؍‬ ؊log [H3O؉ ]; pH Ͼ 7 denotes a basic solution, pH Ͻ 7 an acidic solution; a neutral solution has pH ‫؍‬ 7. 11.6 The pOH of Solutions Many quantitative expressions relating to acids and bases are greatly simplified and therefore much easier to remember when we use logarithms. The quantity pX is a generalization of pH: pX ϭ Ϫlog X (4) For example, pOH is defined as pOH ϭ Ϫlog aOHϪ (5a) which, for the same reasons as those for pH, is normally simplified to pOH ϭ Ϫlog[OHϪ ] (5b)* The pOH is convenient for reporting the concentration of OH– ions in solution. For example, in pure water, where [OHϪ ] ϭ 1.0 ϫ 10Ϫ7 molиLϪ1 , the pOH is 7.00. Similarly, by pKw we mean pKw ϭ Ϫlog Kw ϭ Ϫlog(1.0 ϫ 10Ϫ14 ) ϭ 14.00 (at 25°C) The values of pH and pOH for a given solution are related. To find that relation, we start with the expression for the autoprotolysis constant of water written as [H3Oϩ ][OHϪ ] ϭ Kw. Then we take logarithms of both sides: log [H3Oϩ ][OHϪ ] ϭ log Kw Now we use log ab ϭ log a ϩ log b to obtain: log [H3Oϩ ] ϩ log [OHϪ ] ϭ log Kw Multiplication of both sides of the equation by Ϫ1 gives Ϫlog [H3Oϩ ] Ϫ log [OHϪ ] ϭ Ϫlog Kw SOLVE FIGURE 11.12 Typical pH values of some common aqueous solutions. The rust-colored regions indicate the pH ranges for liquids regarded as corrosive. 14 Corrosive Corrosive 13 12 11 10 9 8 7 6 5 4 3 2 1 Lemon juice Vinegar Soda Wine Acid rainBeer Tomato juice Tap water Urine Saliva Milk Blood Detergents pH Household ammonia which is the same as pH ϩ pOH ϭ pKw (6a)* Because pKw ϭ 14.00 at 25°C, at this temperature pH ϩ pOH ϭ 14.00 (6b) Equation 6 shows that the pH and pOH of a solution have complementary values: if one increases, the other decreases such that their sum remains constant (Fig. 11.13). The pH and pOH of a solution are related by the expression pH ؉ pOH ϭ pKw. WEAK ACIDS AND BASES Solutions of different acids having the same concentration might not have the same pH. For instance, the pH of 0.10 M CH3COOH(aq) is close to 3; but that of 0.10 M HCl(aq) is close to 1. We have to conclude that the concentration of H3Oϩ ions in 0.10 M CH3COOH(aq) is lower than that in 0.10 M HCl(aq). Similarly, we find that the concentration of OHϪ ions is lower in 0.10 M NH3(aq) than it is in 0.10 M NaOH(aq). The explanation must be that in water CH3COOH is not fully deprotonated and NH3 is not fully protonated. That is, acetic acid and ammonia are, respectively, a weak acid and a weak base. The incomplete deprotonation of CH3COOH explains why solutions of HCl and CH3COOH with the same molarity react with a metal at different rates (Fig. 11.14). Most acids and bases that exist in nature are weak. For example, the natural acidity of river water is generally due to the presence of carbonic acid (H2CO3, from dissolved CO2), hydrogen phosphate ions, HPO4 2– , dihydrogen phosphate ions, H2PO4 – (from fertilizer runoff), and carboxylic acids arising from the degradation of plant tissues. Similarly, most naturally occurring bases are weak. Some arise from the decomposition (in the absence of air) of compounds containing nitrogen. For example, the odor of dead fish is due to amines, which are weak bases. In this part of the chapter, we develop a quantitative measure of the strengths of weak acids and bases. We then use this information to explore how acid strength is related to molecular structure. 11.7 Acidity and Basicity Constants When we visualize the molecular composition of a solution of a weak acid in water, we think of a solution that contains • the acid molecules or ions; • small concentrations of H3Oϩ ions and the conjugate base of the acid; and 11.7 ACIDITY AND BASICITY CONSTANTS 435 FIGURE 11.13 The numbers along the top of the rectangle are values of pH for a range of solutions. Directly below each pH value is the pOH value of the same solution. Notice that the sum of the pH and pOH values for a given solution is always 14. Most values of pH and pOH lie in the range from 1 to 14, but pH and pOH values can lie outside this range and even be negative. pH pOH 7 Neutral 654 8 9 10 Acidic Basic . . .. . . 7 8910 6 5 4 . . .. . . Lemon juice, which contains citric acid, is often added to fish dishes to help eliminate the smell of some of these amines. FIGURE 11.14 The same mass of magnesium metal has been added to solutions of HCl, a strong acid (left), and CH3COOH, a weak acid (right). Although the acid solutions were prepared with the same concentrations, the rate of hydrogen evolution, which depends on the concentration of hydronium ions, is much greater in the strong acid. • a very, very small concentration of OH– ions that maintain the autoprotolysis equilibrium. All these species are in ceaseless dynamic equilibrium. Similarly, for a solution of a weak base, we visualize • the base molecules or ions; • small concentrations of OHϪ ions and the conjugate acid of the base; and • a very, very small concentration of H3Oϩ ions that maintain the autoprotolysis equilibrium. Because conjugate acids and bases are in equilibrium in solution, we can use the equilibrium constant for proton transfer between the solute and the solvent as an indicator of their strengths. For example, for acetic acid in water, CH3COOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CH3CO2 Ϫ (aq) (B) the equilibrium constant is (7) Because the solutions that we are considering are dilute and the water is almost pure, the activity of H2O can be set equal to 1. The resulting expression is called the acidity constant, Ka, of acetic acid. If we make the further approximation of replacing the activities of the solute species by the numerical values of their molar concentrations, we can write the acidity constant expression for acetic acid as The experimental value of Ka for acetic acid at 25°C is 1.8 ϫ 10Ϫ5 . This small value tells us that only a small proportion of CH3COOH molecules donate their protons when dissolved in water. About 99 of 100 CH3COOH molecules remain intact in 1 M CH3COOH(aq) (the actual value depends on the concentration of acid, as we shall see). This value is typical of weak acids in water (Fig. 11.15). In general, the acidity constant of an acid HA is HA(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ AϪ (aq) (8)* Table 11.1 lists the acidity constants of some other weak acids in aqueous solution. We can also write an equilibrium constant for the proton transfer equilibrium of a base in water. For aqueous ammonia, for instance, NH3(aq) ϩ H2O(l) #¢4 NH4 ϩ (aq) ϩ OH– (aq) (C) Ka = [H3O+ ][A- ] [HA] Ka = [H3O+ ][CH3CO - 2 ] [CH3COOH] K = aH3O + aCH3CO2 - aCH3COOHaH2O 436 CHAPTER 11 ACIDS AND BASES Ka is also widely called the acid ionization constant or acid dissociation constant. TABLE 11.1 Acidity Constants at 25°C* Acid Ka pKa Acid Ka pKa trichloroacetic acid, CCl3COOH 3.0 ϫ 10Ϫ1 0.52 formic acid, HCOOH 1.8 ϫ 10Ϫ4 3.75 benzene sulfonic acid, C6H5SO3H 2.0 ϫ 10Ϫ1 0.70 benzoic acid, C6H5COOH 6.5 ϫ 10Ϫ5 4.19 iodic acid, HIO3 1.7 ϫ 10Ϫ1 0.77 acetic acid, CH3COOH 1.8 ϫ 10Ϫ5 4.75 sulfurous acid, H2SO3 1.5 ϫ 10Ϫ2 1.81 carbonic acid, H2CO3 4.3 ϫ 10Ϫ7 6.37 chlorous acid, HClO2 1.0 ϫ 10Ϫ2 2.00 hypochlorous acid, HClO 3.0 ϫ 10Ϫ8 7.53 phosphoric acid, H3PO4 7.6 ϫ 10Ϫ3 2.12 hypobromous acid, HBrO 2.0 ϫ 10Ϫ9 8.69 chloroacetic acid, CH2ClCOOH 1.4 ϫ 10Ϫ3 2.85 boric acid, B(OH)3 † 7.2 ϫ 10Ϫ10 9.14 lactic acid, CH3CH(OH)COOH 8.4 ϫ 10Ϫ4 3.08 hydrocyanic acid, HCN 4.9 ϫ 10Ϫ10 9.31 nitrous acid, HNO2 4.3 ϫ 10Ϫ4 3.37 phenol, C6H5OH 1.3 ϫ 10Ϫ10 9.89 hydrofluoric acid, HF 3.5 ϫ 10Ϫ4 3.45 hypoiodous acid, HIO 2.3 ϫ 10Ϫ11 10.64 *The values for Ka listed here have been calculated from pKa values with more significant figures than shown so as to minimize rounding errors. Values for polyprotic acids—those capable of donating more than one proton—refer to the first deprotonation. † The proton transfer equilibrium is B(OH)3 ϩ 2 H2O(l) #4 H3Oϩ (aq) ϩ B(OH)4 Ϫ (aq). H3Oϩ HA HA HA AϪ ϩ Ϫ FIGURE 11.15 In a solution of a weak acid, only some of the acidic hydrogen atoms are present as hydronium ions (the red sphere), and the solution contains a high proportion of the original acid molecules (HA, gray spheres). The green sphere represents the conjugate base of the acid and the blue spheres are water molecules. The inset at the left shows only the solute species. Animation 11.15 the equilibrium constant is In dilute solutions, the water is almost pure and its activity can be set equal to 1. With this approximation, we obtain the basicity constant, Kb. If we make the further approximation of replacing the activities of the solute species by the numerical values of their molar concentrations, we can write the basicity constant expression for ammonia as The experimental value of Kb for ammonia in water at 25°C is 1.8 ϫ 10–5 . This small value tells us that normally only a small proportion of the NH3 molecules are present as NH4 ϩ . Equilibrium calculations show that only about 1 in 100 molecules are protonated in a typical solution (Fig. 11.16). In general, the basicity constant for a base B in water is B(aq) ϩ H2O(l) #¢4 HBϩ (aq) ϩ OHϪ (aq) (9)* The value of Kb tells us how far the reaction proceeds to the right. The smaller the value of Kb the weaker is the ability of the base to accept a proton. Table 11.2 lists the basicity constants of some weak bases in aqueous solution. Acidity and basicity constants are commonly reported as their negative logarithms, by defining pKa ϭ Ϫlog Ka pKb ϭ Ϫlog Kb (10)* When thinking about the strengths of acids and bases we should note that: • The weaker the acid, the smaller the value of Ka and the greater the value of pKa. For example, the pKa of trichloroacetic acid is 0.5, whereas that of acetic acid, a much weaker acid, is nearly 5. Similar remarks apply to bases: • The weaker the base, the smaller the value of Kb and the greater the value of pKb. Values of pKa and pKb are included in Tables 11.1 and 11.2. The proton-donating strength of an acid is measured by its acidity constant; the proton-accepting strength of a base is measured by its basicity constant. The smaller the constants, the weaker the respective strengths. The larger the value of pK, the weaker the acid or base. Kb = [HB+ ][OH- ] [B] Kb = [NH + 4 ][OH _ ] [NH3] K = aNH4 + aOH- aH2OaNH3 11.7 ACIDITY AND BASICITY CONSTANTS 437 TABLE 11.2 Basicity Constants at 25°C* Base Kb pKb Base Kb pKb urea, CO(NH2)2 1.3 ϫ 10Ϫ14 13.90 ammonia, NH3 1.8 ϫ 10Ϫ5 4.75 aniline, C6H5NH2 4.3 ϫ 10Ϫ10 9.37 trimethylamine, (CH3)3N 6.5 ϫ 10Ϫ5 4.19 pyridine, C5H5N 1.8 ϫ 10Ϫ9 8.75 methylamine, CH3NH2 3.6 ϫ 10Ϫ4 3.44 hydroxylamine, NH2OH 1.1 ϫ 10Ϫ8 7.97 dimethylamine, (CH3)2NH 5.4 ϫ 10Ϫ4 3.27 nicotine, C10H14N2 1.0 ϫ 10Ϫ6 5.98 ethylamine, C2H5NH2 6.5 ϫ 10Ϫ4 3.19 morphine, C17H19O3N 1.6 ϫ 10Ϫ6 5.79 triethylamine, (C2H5)3N 1.0 ϫ 10Ϫ3 2.99 hydrazine, NH2NH2 1.7 ϫ 10Ϫ6 5.77 *The values for Kb listed here have been calculated from pKb values with more significant figures than shown so as to minimize rounding errors. B B B OHϪ HBϩ ϩ Ϫ FIGURE 11.16 In a solution of a weak base, only a small proportion of the base molecules (B, represented here by gray spheres) have accepted protons from water molecules (the blue spheres) to form HBϩ ions (the red sphere) and OHϪ ions (green sphere). The inset at the left shows only the solute species. Animation 11.16 Kb is also widely called the base ionization constant. 11.8 The Conjugate Seesaw Hydrochloric acid is classified as a strong acid because it is fully deprotonated in water. It follows that its conjugate base, ClϪ , must be a very, very weak proton acceptor (weaker, in fact, than H2O). Conversely, acetic acid is a weak acid. Its conjugate base, the acetate ion, CH3CO2 Ϫ , must be a relatively good proton acceptor, because it readily forms CH3COOH molecules in water. Similarly, because methylamine, CH3NH2, is a stronger base than ammonia (see Table 11.2), the conjugate acid of methylamine— the methylammonium ion, CH3NH3 ϩ —must be a weaker proton donor (and therefore a weaker acid) than NH4 ϩ . In general, • the stronger the acid, the weaker its conjugate base; and • the stronger the base, the weaker its conjugate acid. To express the relative strengths of an acid and its conjugate base (a “conjugate acid–base pair”), we consider the special case of the ammonia proton transfer equilibrium, reaction C, for which the basicity constant was given earlier (Kb ϭ [NH4 ϩ ][OH– ]/[NH3]). The proton transfer equilibrium of ammonia’s conjugate acid, NH4 ϩ , in water is NH4 ϩ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ NH3(aq) Multiplication of the two equilibrium constants, Ka for NH4 ϩ and Kb for NH3, gives We recognize Kw on the right; so we can write Ka ϫ Kb ϭ Kw (11a)* We can express Eq. 11a in another way by taking logarithms of both sides of the equation: log Ka ϩ log Kb ϭ log Kw Multiplication throughout by –1 turns this expression into pKa ϩ pKb ϭ pKw (11b)* These expressions apply to any conjugate acid–base pair, with Ka the acidity constant of the acid and Kb the basicity constant of its conjugate base. Self-Test 11.6A Write the chemical formula for the conjugate acid of the base pyridine, C5H5N, and calculate its pKa. [Answer: C5H5NHϩ , 5.25] Self-Test 11.6b Write the chemical formula for the conjugate base of the acid HIO3 and calculate its pKb. Equation 11—in either form—confirms the seesaw relation between the strengths of acids and of their conjugate bases. Equation 11a tells us that if an acid has a large Ka, then its conjugate base must have a small Kb. Similarly, if a base has a large Kb, then its conjugate acid must have a small Ka. Equation 11b tells us that if pKa of an acid is large, then the pKb of its conjugate base is small, and vice versa. This reciprocal relation is summarized in Fig. 11.17 and Table 11.3. For example, because pKb for ammonia in water is 4.75, the pKa of NH4 ϩ is pKa ϭ pKw Ϫ pKb ϭ 14.00 Ϫ 4.75 ϭ 9.25 This value shows that NH4 ϩ is a weaker acid than boric acid (pKa ϭ 9.14) but stronger than hydrocyanic acid (HCN, pKa ϭ 9.31). Consequently, as we shall verify in Section 11.13, solutions of ammonium salts such as NH4Cl are acidic. Ka * Kb = [H3O+ ][NH3] [NH + 4 ] * [NH + 4 ][OH- ] [NH3] = [H3O+ ][OH- ] Ka = [H3O+ ][NH3] [NH + 4 ] 438 CHAPTER 11 ACIDS AND BASES Chlorous acid pKa pKb Ammonia 2.00 12.00 4.75 9.25 9.25 4.7510.56 3.44 7.53 6.47 Methylamine Hypochlorous acid Acetic acid FIGURE 11.17 As shown here for five conjugate acid–base pairs, the sum of the pKa of an acid (pink) and the pKb of its conjugate base (blue) is constant and equal to pKw, which is 14.00 at 25°C. Although the proton transfer in a solution of a strong acid is actually an equilibrium, the proton-donating power of a strong acid, HA, is so much greater than that of H3Oϩ that proton transfer to water effectively goes to completion. As a result, the solution contains only H3Oϩ ions and A– ions; there are virtually no HA molecules left. In other words, the only acid species present in an aqueous solution of a strong acid, other than the H2O molecules, is the H3Oϩ ion. Because all strong acids in water behave as though they were solutions of the acid H3Oϩ , we say that strong acids are leveled in water to the strength of the acid H3Oϩ . 11.8 THE CONJUGATE SEESAW 439 Sulfuric acid is a special case, because loss of its first acidic hydrogen leaves a conjugate base that is itself a weak acid, the HSO4 Ϫ ion. TABLE 11.3 Conjugate Acid–Base Pairs Arranged by Strength pKa Acid name Acid formula Base formula Base name pKb Strong acid Very weak base hydroiodic acid HI IϪ iodide ion perchloric acid HClO4 ClO4 Ϫ perchlorate ion hydrobromic acid HBr BrϪ bromide ion hydrochloric acid HCl ClϪ chloride ion sulfuric acid H2SO4 HSO4 Ϫ hydrogen sulfate ion chloric acid HClO3 ClO3 Ϫ chlorate ion nitric acid HNO3 NO3 Ϫ nitrate ion hydronium ion H3Oϩ H2O water 1.92 hydrogen sulfate ion HSO4 Ϫ SO4 2Ϫ sulfate ion 12.08 3.37 nitrous acid HNO2 NO2 Ϫ nitrite ion 10.63 3.45 hydrofluoric acid HF FϪ fluoride ion 10.55 4.75 acetic acid CH3COOH CH3CO2 Ϫ acetate ion 9.25 6.37 carbonic acid H2CO3 HCO3 Ϫ hydrogen carbonate ion 7.63 6.89 hydrosulfuric acid H2S HSϪ hydrogen sulfide ion 7.11 9.25 ammonium ion NH4 ϩ NH3 ammonia 4.75 9.31 hydrocyanic acid HCN CNϪ cyanide ion 4.69 10.25 hydrogen carbonate ion HCO3 Ϫ CO3 2Ϫ carbonate ion 3.75 methylammonium ion CH3NH3 ϩ CH3NH2 methylamine 3.44 water H2O OHϪ hydroxide ion ammonia NH3 NH2 Ϫ amide ion hydrogen H2 HϪ hydride ion methane CH4 CH3 Ϫ methide ion hydroxide ion OHϪ O2Ϫ oxide ion Very weak acid Strong base EXAMPLE 11.5 Deciding which of two species is the stronger acid or base Decide which member of each of the following pairs is the stronger acid or base in water: (a) acid: HF or HIO3; (b) base: NO2 Ϫ or CNϪ . PLAN The greater the Ka of a weak acid, the stronger is the acid and the weaker is its conjugate base. Similarly, the greater the Kb of a weak base, the stronger is the base and the weaker is its conjugate acid. SOLVE Compare the relevant Ka and Kb (or pKa and pKb) values in Tables 11.1 and 11.2. 0 10pKa HIO3 HF Weaker acid (a) Because Ka(HIO3) Ͼ Ka(HF), or pKa(HIO3) Ͻ pKa(HF), HIO3 is a stronger acid than HF. 440 CHAPTER 11 ACIDS AND BASES Self-Test 11.7A Use Tables 11.1 and 11.2 to decide which species in each of the following pairs is the stronger acid or base: (a) acid: HF or HIO; (b) base: C6H5CO2 Ϫ or CH2ClCO2 Ϫ ; (c) base: C6H5NH2 or (CH3)3N; (d) acid: C6H5NH3 ϩ or (CH3)3NHϩ . [Answer: Stronger acids: (a) HF; (d) C6H5NH3 ϩ . Stronger bases: (b) C6H5CO2 Ϫ ; (c) (CH3)3N.] Self-Test 11.7B Use Tables 11.1 and 11.2 to decide which species in each of the following pairs is the stronger acid or base: (a) base: C5H5N or NH2NH2; (b) acid: C5H5NHϩ or NH2NH3 ϩ ; (c) acid: HIO3 or HClO2; (d) base: ClO2 Ϫ or HSO3 Ϫ . The stronger the acid, the weaker its conjugate base; the stronger the base, the weaker its conjugate acid. 11.9 Molecular Structure and Acid Strength Chemists commonly interpret trends in the properties of compounds by considering the structures of their molecules. However, there are two reasons why the relative strengths of acids and bases are difficult to predict. First, Ka and Kb are equilibrium constants, and so they are related to the Gibbs free energy of the proton transfer reaction. Their values therefore depend on considerations of entropy as well as energy. Second, the solvent plays a significant role in the proton transfer reactions, and so we cannot expect to relate acid strength solely to the acid molecule itself. However, although absolute values are difficult to predict, we can look for trends among series of compounds with similar structures and in the same solvent (normally water). Because acid strength in aqueous solutions depends on the breaking of the HßA bond and the formation of an HßOH2 ϩ bond, we might suspect that one factor in determining strength is the ease with which these bonds can be broken and formed. Thinking point: Do you think that the entropy of the system will increase or decrease when an acid molecule is deprotonated in water? First, we consider binary acids, acids composed of hydrogen and one other element, such as HCl and H2S and, in general, HA. Because the enthalpy change for a process does not depend on the path, we can break down the enthalpy change for the transfer of a proton from HA to H2O in solution into the following hypothetical sequence (Fig. 11.18): Step Reaction Enthalpy change removal of HA from solution: HA(aq) : HA(g) Ϫ⌬Hsolv(HA) dissociation of HA: HA(g) : H(g) ϩ A(g) ⌬HB(HßA) ionization of H: H(g) : Hϩ (g) ϩ e– (g) I(H) electron attachment to A: A(g) ϩ e– (g) : A– (g) –Ea(A) hydration of Hϩ : Hϩ (g) ϩ H2O(l) : H3Oϩ (aq) ⌬Hhyd(Hϩ ) hydration of A– : A– (g) : A– (aq) ⌬Hhyd(A– ) The enthalpy change for the overall process HA(aq) ϩ H2O(l) : H3Oϩ (aq) ϩ AϪ (aq) is therefore ⌬H ϭ Ϫ⌬Hsolv(HA) ϩ ⌬HB(HßA) ϩ I(H) Ϫ Ea(A) ϩ ⌬Hhyd(Hϩ ) ϩ ⌬Hhyd(AϪ ) HNO2 HCN 0 10pKa Weaker acid (b) Because Ka(HNO2) Ͼ Ka(HCN), or pKa(HNO2) Ͻ pKa(HCN), HNO2 is a stronger acid than HCN. Because the stronger acid has the weaker conjugate base, NO2 Ϫ is a weaker base than CNϪ . Hence, CNϪ is the stronger base. Here is an opportunity for you to come up with a theory. ϪΔHsolv(HA) ΔHB(H_A) ΔHhyd(AϪ ) ΔHhyd(Hϩ ) H _ (aq) ϩ A _ (aq) Hϩ (aq) ϩ AϪ (g) H(g) ϩ A(g) Hϩ (g) ϩ AϪ (g) HA(g) HA(aq) Hϩ (g) ϩ eϪ (g) ϩ A(g) ϪEa(A) I(H) ΔH FIGURE 11.18 The thermodynamic cycle for the analysis of contributions to the strengths of binary acids. 11.9 MOLECULAR STRUCTURE AND ACID STRENGTH 441 Table 11.4 lists the values for a number of binary acids, including H2O (the value for its removal from solution, Ϫ⌬Hsolv, corresponds to its vaporization), and the resulting value of ⌬H for proton transfer to water molecules. Notice that here NH3 is included in its role as an acid that can lose Hϩ to form NH2 Ϫ . Our task is to try to identify the contributions that account for the trends in acid strength. We have to bear in mind, as remarked above, that we should really be considering Gibbs free energies, but the role of entropy is hard to estimate. Any discrepancies between what we identify and what we observe might be due to the neglect of entropy considerations. We therefore take the cautious view that as the enthalpy of proton transfer (the value of ⌬H in the table) becomes more negative (proton transfer becoming more exothermic), the acid strength of HA increases. First, consider trends across a period (the top row and bottom two rows of Table 11.4, which refer to N, O, and F in Period 2). We know that acid strength increases in the order NH3 Ͻ H2O Ͻ HF, and we see that ⌬H follows this trend: NH3 H2O HF ⌬H (kJиmolϪ1 ) ϩ125 ϩ44 Ϫ15 The dominant contribution to the relative strengths of acids across a period appears to be the trend in electron affinities across the period (see the blue numbers in the table). One way to interpret the role of electron affinity is to note its role in the definition of electronegativity (Section 2.12) and bond polarity. First, we note that the stronger the hydrogen bond that HA forms with the O atom of an H2O molecule, the more likely it is that the proton will be transferred. We know that the more polar the HßA bond, the greater the partial positive charge on the H atom—therefore the stronger the H2O···HßA hydrogen bond and the more readily HA loses its proton. Because the polarity of the HßA bond increases with the electron affinity and the electronegativity of A, we can understand that the greater the electronegativity of A, the stronger the acid HA. For instance, the electronegativity difference is 0.8 for the NßH bond and 1.8 for FßH (see Fig. 2.12); therefore, the FßH bond is markedly more polar than the NßH bond. This difference is consistent with the observation that HF, but not NH3, is an acid in water. Now consider the relative strengths of the binary acids within the same group. We know that in Group VII/17 the acid strengths are in the order HF Ͻ HCl Ͻ HBr Ͻ HI. The values of ⌬H almost follow this trend: HF HCl HBr HI ⌬H (kJиmolϪ1 ) Ϫ15 Ϫ41 Ϫ51 Ϫ43 The enthalpy for proton transfer from HI to water is not consistent with the experimentally measured trend: that might be an entropy effect. The dominant contribution to the relative strengths of acids down a group appears to be the trend in bond enthalpies (see the red numbers in the table). The enthalpies of hydration of A– admittedly change a lot, but they change in a way that is opposite to the observed trend in TABLE 11.4 Contributions to the Enthalpy of Proton Transfer of Binary Acids (all values in kJиmolϪ1 )* Acid ⌬Hsolv(HA) ⌬HB(HßA) I(H) Ea(A) ⌬Hhyd(Hϩ ) ⌬Hhyd(AϪ ) ⌬H HF Ϫ49 565 1312 328 Ϫ1103 Ϫ510 Ϫ15 HCl ?Ϫ35 431 1312 349 Ϫ1103 Ϫ367 Ϫ41 HBr ?Ϫ35 366 1312 325 Ϫ1103 Ϫ336 Ϫ51 HI ?Ϫ35 299 1312 295 Ϫ1103 Ϫ291 Ϫ43 H2O Ϫ41 492 1312 178 Ϫ1103 Ϫ520 ϩ44 NH3 Ϫ34 453 1312 71 Ϫ1103 Ϫ500 ϩ125 *We have grayed out contributions that are constant for all the acids. The colors are explained in the text. The values preceded with ? are estimates. The electron affinities are for the negative ions. 442 CHAPTER 11 ACIDS AND BASES strengths (hydration gets less exothermic on descending the group), so the trend in bond enthalpies must dominate even that trend. Acid strengths of binary acids across a period correlate with electron affinities; acid strengths down a group correlate with bond strength. 11.10 The Strengths of Oxoacids and Carboxylic Acids We can learn more about the effect of structure on acidity by considering the oxoacids. These acids form structurally related families, and so we can examine the effect of different central atoms with the same number of O atoms (as in HClO3 and HBrO3). Alternatively, we can look at the influence of different numbers of O atoms attached to the same central atom (as in HClO3 and HClO4). For the binary acids we examined contributions to the enthalpies of proton transfer, but there is little data available on electron affinities of polyatomic species, so instead we shall build on the correlations with bond polarity established in Section 11.9. The high polarity of the OßH bond is one reason why the proton of an ßOH group in an oxoacid molecule is acidic. For example, phosphorous acid, H3PO3, has the structure (HO)2PHO (1): it can donate the protons from its two ßOH groups but not the proton attached directly to the phosphorus atom. The difference in behavior can be traced to the much lower electronegativity of phosphorus (2.2) relative to that of oxygen (3.4). In nearly all common inorganic oxoacids, however, all the hydrogen atoms are attached to oxygen atoms. Let’s consider a family of oxoacids in which the number of O atoms is constant, as in the hypohalous acids HClO, HBrO, and HIO. By referring to Table 11.5, we see that, the greater the electronegativity of the halogen, the stronger the oxoacid. A partial explanation of this trend is that electrons are withdrawn slightly from the OßH bond as the electronegativity of the halogen increases. As these bonding electrons move toward the central atom, the OßH bond becomes more polar, and so the molecule becomes a stronger acid. A halogen that has a high electronegativity also weakens the conjugate base by making the electrons in the molecule less accessible to an incoming proton. Now let’s consider a family of oxoacids in which the number of oxygen atoms varies, as in the chlorine oxoacids HClO, HClO2, HClO3, and HClO4 or in the sulfur oxoacids H2SO3 and H2SO4. When we refer to Table 11.6, we see that the greater the number of oxygen atoms attached to the central atom, the stronger the acid. Because 1 Phophorous acid, H3PO3 TABLE 11.5 Correlation of Acid Strength and Electronegativity Electronegativity Acid, HXO Structure* of atom X pKa hypochlorous acid, HClO 3.2 7.53 hypobromous acid, HBrO 3.0 8.69 hypoiodous acid, HIO 2.7 10.64 *The red arrows indicate the direction of the shift of electron density away from the OßH bond. O HI O HBr O HCl the oxidation number of the central atom increases as the number of O atoms increases, we can also conclude that, the greater the oxidation number of the central atom, the stronger the acid. The effect of the number of O atoms on the strengths of organic acids is similar. For example, we have seen (Section D) that alcohols are organic compounds in which an ßOH group is attached to a carbon atom, as in ethanol (2). Carboxylic acids, on the other hand, have two O atoms attached to the same carbon atom: one is a doubly bonded terminal O atom and the other is the O atom of an ßOH group, as in acetic acid (3). Although carboxylic acids are weak acids, they are much stronger acids than alcohols, partly as a result of the electron–withdrawing power of the second O atom. In fact, alcohols have such weak proton–donating power that usually they are not regarded as oxoacids. The strength of a carboxylic acid is also increased relative to that of an alcohol by electron delocalization in the conjugate base. The second O atom of the carboxyl group, ßCOOH, provides an additional electronegative atom over which the negative charge of the conjugate base can spread. This electron delocalization stabilizes the carboxylate anion, ßCO2 Ϫ (4). Moreover, because the charge is spread over several atoms, it is less effective at attracting a proton. A carboxylate ion is therefore a much weaker base than the conjugate base of an alcohol (for example, the ethoxide ion, CH3CH2OϪ ). A note on good practice: The formula of a carboxylic acid is written RCOOH, because the two O atoms are distinct (one is part of an OH group); the formula of a carboxylate ion, however, is written RCO2 – because the two O atoms are equivalent. 11.10 THE STRENGTHS OF OXOACIDS AND CARBOXYLIC ACIDS 443 TABLE 11.6 Correlation of Acid Strength and Oxidation Number Oxidation number Acid Structure* of Cl atom pKa hypochlorous acid, HClO ϩ1 7.53 chlorous acid, HClO2 ϩ3 2.00 chloric acid, HClO3 ϩ5 strong perchloric acid, HCIO4 ϩ7 strong *The red arrows indicate the direction of the shift of electron density away from the OßH bond. The Lewis structures shown are the ones with the most favorable formal charges, but it is unlikely that the bond orders are as high as these structures suggest. O O HCl O O O O HCl O O O HCl O HCl 2 Ethanol, CH3CH2OH 3 Acetic acid, CH3COOH Ϫ 4 Acetate ion, CH3CO2 Ϫ The strengths of carboxylic acids also vary with the total electron withdrawing power of the atoms bonded to the carboxyl group. Because hydrogen is less electronegative than chlorine (2.2 and 3.2, respectively), the ßCH3 group bonded to ßCOOH in acetic acid is less electron withdrawing than the ßCCl3 group in trichloroacetic acid. Therefore, we expect CCl3COOH to be a stronger acid than CH3COOH. In agreement with this prediction, the pKa of acetic acid is 4.75, whereas that of trichloroacetic acid is 0.52. 444 CHAPTER 11 ACIDS AND BASES EXAMPLE 11.6 Predicting relative acid strength from molecular structure Predict from their molecular structures which acid in each of the following pairs is the stronger: (a) H2S and H2Se; (b) H2SO4 and H2SO3; (c) H2SO4 and H3PO4. PLAN Identify the relevant trends in the summary in Table 11.7. SOLVE (a) Sulfur and selenium are in the same group, and we expect the HßSe bond to be weaker than the HßS bond. Thus, H2Se can be expected to be the stronger acid. (b) H2SO4 has the greater number of O atoms bonded to the S atom and the oxidation number of sulfur is ϩ6, whereas in H2SO3 the sulfur has an oxidation number of only ϩ4. TABLE 11.7 Correlations of Molecular Structure and Acid Strength* Acid type Trend binary The more polar the HßA bond, the stronger the acid. This effect is dominant for acids of the same period. The weaker the HßA bond, the stronger the acid. This effect is dominant for acids of the same group. oxoacid The greater the number of O atoms attached to the central atom (the greater the oxidation number of the central atom), the stronger the acid. For the same number of O atoms attached to the central atom, then the greater the electronegativity of the central atom, the stronger the acid. carboxylic The greater the electronegativities of the groups attached to the carboxyl group, the stronger the acid. *In each diagram, the vertical orange arrow indicates the corresponding increase in acid strength. 11.11 SOLUTIONS OF WEAK ACIDS 445 (c) Both acids have four O atoms bonded to the central atom, but the electronegativity of sulfur is greater than that of phosphorus. Thus, H2SO4 is expected to be the stronger acid. The initial concentration is sometimes called either the analytical concentration or the formal concentration (F). Thus, H2SO4 is expected to be the stronger acid, as we anticipated. TOOLBOX 11.1 HOW TO CALCULATE THE pH OF A SOLUTION OF A WEAK ACID CONCEPTUAL BASIS Because a proton transfer equilibrium is established as soon as a weak acid is dissolved in water, the concentrations of acid, hydronium ion, and conjugate base of the acid must satisfy the acidity constant of the acid. We can calculate any of these quantities by setting up an equilibrium table like that in Toolbox 10.1. PROCEDURE Step 1 Write the chemical equation and Ka for the proton transfer equilibrium. Set up a table with columns labeled by the acid (HA), H3Oϩ , and the conjugate base of the acid (AϪ ). In the first row below the headings, show the initial concentration of each species. Self-Test 11.8A For each of the following pairs, predict which acid is stronger: (a) H2S and HCl; (b) HNO2 and HNO3; (c) H2SO3 and HClO3. [Answer: (a) HCl; (b) HNO3; (c) HClO3] Self-Test 11.8B List the following carboxylic acids in order of increasing strength: CHCl2COOH, CH3COOH, and CH2ClCOOH. The greater the number of oxygen atoms and the more electronegative the atoms present in the molecules of an acid, the stronger the acid. These trends are summarized in Table 11.7. THE pH OF SOLUTIONS OF WEAK ACIDS AND BASES The rest of this chapter is a variation on a theme introduced in Chapter 10: the use of equilibrium constants to calculate the equilibrium composition of solutions of acids, bases, and salts. We shall see how to predict the pH of solutions of weak acids and bases and how to calculate the extent of deprotonation of a weak acid and the extent of protonation of a weak base. We shall also see how to calculate the pH of a solution of a salt in which the cation or anion of the salt may itself be a weak acid or base. 11.11 Solutions of Weak Acids Our first task is to calculate the pH of a solution of a weak acid, such as acetic acid in water. The initial concentration of the acid is its concentration as prepared, as if no acid molecules had donated any protons. For a strong acid HA, the H3Oϩ concentration in solution is the same as the initial concentration of the strong acid, because all the HA molecules are deprotonated. However, to find the H3Oϩ concentration in a solution of a weak acid HA, we have to take into account the equilibrium between the acid HA, its conjugate base AϪ , and water (Eq. 8). We can expect the pH to be somewhat greater than it would be for a strong acid. The technique, which is based on the use of an equilibrium table like those introduced in Chapter 10, is set out in Toolbox 11.1 The calculation summarized in Toolbox 11.1 also allows us to predict the percentage deprotonation, the percentage of HA molecules that are deprotonated in the solution: Percentage deprotonated ϭ (12a)* To express the percentage deprotonation in terms of the pH of the solution, we use the equality [H3Oϩ ] ϭ [AϪ ], which follows from the stoichiometric relation 1 mol AϪ ϴ 1 mol H3Oϩ for the deprotonation reaction in Eq. 8. Then Percentage deprotonated ϭ (12b)* A small percentage of deprotonated molecules indicates that the acid HA is very weak. [H3O+ ] [HA]initial * 100% concentration of Ainitial concentration of HA * 100% 446 CHAPTER 11 ACIDS AND BASES For this step, assume that no acid molecules have been deprotonated. Step 2 In the second row, write the changes in the concentration needed for the reaction to reach equilibrium. We do not know the number of acid molecules that lose their protons, and so we assume that the concentration of the acid decreases by x molиLϪ1 as a result of deprotonation. The reaction stoichiometry gives us the other changes in terms of x. Step 3 In the third row write the equilibrium concentrations by adding the change in concentration (step 2) to the initial concentration for each substance (step 1). Conjugate Acid, HA H3Oϩ base, AϪ Step 1 Initial [HA]initial 0 0 concentration Step 2 Change in Ϫx ϩx ϩx concentration Step 3 Equilibrium [HA]initial Ϫ x x x concentration Although a change in concentration may be positive (an increase) or negative (a decrease), the value of the concentration itself must always be positive. Step 4 Use the value of Ka to calculate the value of x. The calculation of x can often be simplified, as shown in Toolbox 10.1, by ignoring changes of less than 5% of the initial concentration of the acid. However, at the end of the calculation, we must check that x is consistent with the approximation, by calculating the percentage of acid deprotonated. If this percentage is greater than about 5%, then the exact expression for Ka must be solved for x. An exact calculation requires solving a quadratic equation, as explained in Toolbox 10.1. If the pH is greater than 6, the acid is so dilute or so weak that the autoprotolysis of water contributes significantly to the pH. In such cases, we must use the procedures described in Sections 11.18 and 11.19, which take that autoprotolysis into account. We can ignore the contribution of the autoprotolysis of water in an acidic solution only when the calculated H3Oϩ concentration is substantially (about 10 times) higher than 10Ϫ7 molиLϪ1 , corresponding to a pH of 6 or less. Although we calculate the pH to the number of significant figures appropriate to the data, the answers are often considerably less reliable than that. One reason for this poor reliability is that we are ignoring interactions between the ions in solution. This procedure is illustrated in Examples 11.7 and 11.8. EXAMPLE 11.7 Calculating the pH and percentage deprotonation of a weak acid Calculate the pH and percentage deprotonation of CH3COOH molecules in 0.080 M CH3COOH(aq), given that Ka for acetic acid is 1.8 ϫ 10Ϫ5 . Anticipate Because the solution is that of an acid, expect pH Ͻ 7. Because the acid is weak, expect only a small percentage deprotonation. PLAN Following the procedure in Toolbox 11.1, we write the proton transfer equilibrium, CH3COOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CH3CO2 Ϫ (aq) and construct the equilibrium table, with concentrations in moles per liter. What should we assume? There are two assumptions. (1) Deprotonation is so slight that the equilibrium concentration of the acid is approximately the same as its initial concentration. (2) The autoprotolysis of water does not contribute significantly to the pH. SOLVE First, we set up the equilibrium table: Species CH3COOH H3Oϩ CH3CO2 Ϫ Step 1 Initial concentration 0.080 0 0 Step 2 Change in concentration Ϫx ϩx ϩx Step 3 Equilibrium concentration 0.080 Ϫ x x x Ka = [H3O+ ][CH3CO2 - ] [CH3COOH] 11.11 SOLUTIONS OF WEAK ACIDS 447 Step 4 Substitute the equilibrium concentrations into Ka. Ka = 1.8 * 10-5 = x * x 0.080 - x Assume that x ϽϽ 0.080. 1.8 * 10-5 L x2 0.080 Solve for x (which must be positive). x L 20.080 * (1.8 * 10-5 ) = 1.2 * 10-3 14 7 1 pH BasicAcidic 2.92 From x ϭ [H3Oϩ ] and pH ϭ Ϫlog [H3Oϩ ]; pH Ϸ Ϫlog(1.2 ϫ 10Ϫ3 ) ϭ 2.92 Deprotonated (%)From percentage deprotonated ϭ ([H3Oϩ ]͞[HA]initial) ϫ 100% with [HA]initial ϭ 0.080, Percentage deprotonated ϭ = 1.5% 1.2 * 10-3 0.080 * 100% Evaluate As anticipated, the pH is less than 7 and the percentage deprotonated is small. The blue square in the grid in the final picture represents the percentage of the acid molecules that are deprotonated. We see that x is less than 5% of 0.10, and the approximation is valid. Because the pH Ͻ 6, the assumption that the autoprotolysis of water can be ignored is valid. Self-Test 11.9A Calculate the pH and percentage deprotonation of 0.50 M aqueous lactic acid. See Table 11.1 for Ka. Be sure to check any approximation to see whether it is valid. [Answer: 1.69; 4.1%] Self-Test 11.9B Calculate the pH and percentage deprotonation of 0.22 M aqueous chloroacetic acid. Be sure to check any approximation to see whether it is valid. EXAMPLE 11.8 Calculating the Ka and pKa of a weak acid from the pH The pH of a 0.010 M aqueous solution of mandelic acid, C6H5CH(OH)COOH, an antiseptic, is 2.95. What are the Ka and pKa of mandelic acid? Anticipate Mandelic acid is a carboxylic acid, and so is a weak acid; therefore, expect Ka ϽϽ 1. PLAN Calculate the hydronium ion concentration from the pH and then calculate the value of Ka from the initial concentration of the acid and the hydronium ion concentration. What should we assume? As in Example 11.7, we assume that the extent of deprotonation is so small that the equilibrium concentration of the acid is approximately the same as its initial concentration; we also assume that the autoprotolysis of water does not contribute significantly to the pH. SOLVE From [H3Oϩ ] ϭ 10ϪpH , [H3Oϩ ] ϭ 10Ϫ2.95 molиLϪ1 ϭ 0.0011 molиLϪ1 448 CHAPTER 11 ACIDS AND BASES Note relations between equilibrium concentrations. [H3Oϩ ] ϭ [AϪ ]; [HA] ϭ [HA]initial Ϫ [H3Oϩ ] Use Ka in the form Ka ϭ [H3Oϩ ][AϪ ]/[HA] ϭ [H3Oϩ ]2 /([HA]initial Ϫ [H3Oϩ ]) and substitute the data. Ka = (0.0011)2 0.010 - 0.0011 = 1.4 * 10-4 From pKa ϭ Ϫlog Ka, pKa ϭ Ϫlog 1.4 ϫ 10Ϫ4 ϭ 3.85 Evaluate As expected, Ka ϽϽ 1. Self-Test 11.10A The pH of a 0.20 M aqueous solution of crotonic acid, C3H5COOH, which is used in medicinal research and in the manufacture of synthetic vitamin A, is 2.69. What is the Ka of crotonic acid? [Answer: 2.1 ϫ 10Ϫ5 ] Self-Test 11.10B The pH of a 0.50 M aqueous solution of the metabolic intermediate homogentisic acid is 2.35. What is the Ka of homogentisic acid, C7H5(OH)2COOH? To calculate the pH and percentage deprotonation of a solution of a weak acid, set up an equilibrium table and determine the H3O؉ concentration by using the acidity constant. 11.12 Solutions of Weak Bases In the treatment of weak acids, we found that the percentage deprotonated gave an indication of acid strength. Similarly, when we describe the strengths of weak bases, it is useful to know the percentage protonated, the percentage of base molecules that have been protonated: Percentage protonated ϭ (13)* Here[B]initialistheinitialmolarconcentrationof base,itsconcentrationbasedontheassumption that no protonation has occurred (its “analytical” or “formal” concentration). = [HB+ ] [B]initial * 100% concentration of HB+ initial concentration of B * 100% TOOLBOX 11.2 HOW TO CALCULATE THE pH OF A SOLUTION OF A WEAK BASE CONCEPTUAL BASIS Proton transfer equilibrium is established as soon as a weak base is dissolved in water, and so we can calculate the hydroxide ion concentration from the initial concentration of the base and the value of its basicity constant. Because the hydroxide ions are in equilibrium with the hydronium ions, we can use the pOH and pKw to calculate the pH. PROCEDURE Step 1 Write the proton transfer equilibrium as in Eq. 9 and set up a table with columns labeled by the base B, its conjugate acid BHϩ , and OHϪ . In the first row, show the initial concentration of each species. For the initial values, assume that no base molecules have been protonated. Step 2 Write the changes in the concentrations that are needed for the reaction to reach equilibrium. Assume that the concentration of the base decreases by x molиLϪ1 as a result of protonation. The reaction stoichiometry gives us the other changes in terms of x. Step 3 Write the equilibrium concentrations by adding the change in concentration (step 2) to the initial concentration for each substance (step 1). EXAMPLE 11.9 Calculating the pH and percentage protonation of a weak base Calculate the pH and percentage protonation of a 0.20 M aqueous solution of methylamine, CH3NH2. The Kb for CH3NH2 is 3.6 ϫ 10Ϫ4 . Anticipate Because the amine is a weak base (like all amines), we should expect pH Ͼ 7 and only a small percentage protonation. PLAN Proceed as in Toolbox 11.2. What should we assume? As in Example 11.7, we make two assumptions. (1) The base is so weak that it undergoes little protonation, so the equilibrium concentration of the base is approximately the same as its initial concentration. (2) The autoprotolysis of water does not contribute significantly to the pH. SOLVE First, write the proton transfer equilibrium and the corresponding equilibrium table, with all concentrations in moles per liter: H2O(l) ϩ CH3NH2(aq) #¢4 CH3NH3 ϩ (aq) ϩ OHϪ (aq) Kb ϭ CH3NH2 CH3NH3 ϩ OHϪ Step 1 Initial concentration 0.20 0 0 Step 2 Change in concentration Ϫx ϩx ϩx Step 3 Equilibrium concentration 0.20 Ϫ x x x [CH3NH3 + ][OH- ] [CH3NH2] 11.12 SOLUTIONS OF WEAK BASES 449 B BHϩ OHϪ Step 1 Initial [B]initial 0 0 concentration Step 2 Change in –x ϩx ϩx concentration Step 3 Equilibrium [B]initial Ϫ x x x concentration Although a change in concentration may be positive (an increase) or negative (a decrease), the concentration itself must always be positive. Step 4 Use the value of Kb to calculate the value of x. The calculation of x can often be simplified, as explained in Toolbox 11.1. We ignore contributions from the autoprotolysis of water to the hydroxide ion concentration if the concentration of hydroxide ions is greater than 10–6 mol·L–1 . Step 5 Determine the pOH of the solution and then calculate the pH from the pOH by using Eq. 6b. This procedure is illustrated in Example 11.9. As in Toolbox 11.1, although we calculate the pH to the number of significant figures appropriate to the data, the answers are often considerably less reliable than that. Step 4 Substitute the equilibrium concentrations into the expression for Kb. Kb ϭ 3.6 ϫ 10Ϫ4 ϭ x * x 0.20 - x Assume that x ϽϽ 0.20. 3.6 * 10-4 L x2 0.20 Solve for x. x L 20.20 * (3.6 * 10-4 ) = 8.5 * 10-3 Check the assumption that x ϽϽ 0.20 8.5 ϫ 10Ϫ3 ϽϽ 0.20, so the approximation is valid From pOH ϭ Ϫlog [OH– ], with [OH– ] ϭ x, pOH ഠ Ϫlog(8.5 ϫ 10Ϫ3 ) ϭ 2.07 450 CHAPTER 11 ACIDS AND BASES 14 7 1 pH BasicAcidic 11.9 Step 5 From pH ϭ pKw Ϫ pOH, pH Ϸ 14.00 Ϫ 2.07 ϭ 11.93 Protonated (%)From Eq. 13, with [HBϩ ] ϭ x and [B]initial ϭ 0.20, Percentage protonated ϭ = 4.2% 8.5 * 10-3 0.20 * 100% Evaluate As anticipated, the pH is greater than 7 and the percentage protonated is small. That is, 4.2% of the methylamine is present as the protonated form, CH3NH3 ϩ . Because the pH is greater than 8, the assumption that this equilibrium dominates the pH and that autoprotolysis can be ignored is valid. Self-Test 11.11A Estimate the pH and percentage of base that has been protonated in 0.15 M NH2OH(aq), aqueous hydroxylamine. [Answer: 9.61; 0.027%] Self-Test 11.11B Estimate the pH and percentage of base that has been protonated in 0.012 M C10H14N2(aq), nicotine. To calculate the pH of a solution of a weak base, set up an equilibrium table to calculate pOH from the value of Kb and convert that pOH into pH by using pH ؉ pOH ‫؍‬ 14.00. 11.13 The pH of Salt Solutions We saw in Section J that a salt is produced by the neutralization of an acid by a base. However, if we measure the pH of a solution of a salt, we do not in general find the “neutral” value (pH ϭ 7). For instance, if we neutralize 0.3 M CH3COOH(aq) with 0.3 M NaOH(aq), the resulting solution of sodium acetate has pH ϭ 9.0. How can this be? The Brønsted–Lowry theory provides the explanation. According to this theory, an ion may be an acid or a base. The acetate ion, for instance, is a base, and the ammonium ion is an acid. The pH of a solution of a salt depends on the relative acidity and basicity of its ions. Table 11.8 lists some cations that are acidic in water. They fall into four general categories: • All cations that are the conjugate acids of weak bases produce acidic solutions. Conjugate acids of weak bases, such as NH4 ϩ , act as proton donors, and so we can expect them to form acidic solutions. • Small, highly charged metal cations that can act as Lewis acids in water, such as Al3ϩ and Fe3ϩ , produce acidic solutions, even though the cations themselves have no hydrogen ions to donate (Fig. 11.19). The protons come from the water molecules that hydrate these metal cations in solution (Fig. 11.20). The water molecules act as Lewis bases and share electrons with the metal cations. This partial loss of electrons weakens the OßH bonds and allows one or more hydrogen ions to be lost from the water molecules. Small, highly charged cations exert the greatest pull on the electrons and so form the most acidic solutions. • Cations of Group 1 and 2 metals, as well as those of charge ϩ1 from other groups, are such weak Lewis acids that the hydrated ions do not act as acids. FIGURE 11.19 These four solutions show that hydrated cations can be significantly acidic. The flasks contain, from left to right, pure water, 0.1 M Al2(SO4)3(aq), 0.1 M Ti2(SO4)3(aq), and 0.1 M CH3COOH(aq). All four tubes contain a few drops of universal indicator, which changes color from green in a neutral solution through yellow to red with increasing acidity. The superimposed numbers are the pH values of each solution. These metal cations are too large or have too low a charge to have an appreciable polarizing effect on the hydrating water molecules that surround them, and so the water molecules do not readily release their protons. These cations are sometimes called “neutral cations,” because they have so little effect on the pH. Notice that no cations are basic. Cations cannot readily accept protons, because the positive charge of the cation repels the positive charge of the incoming protons. • Very few anions that contain hydrogen produce acidic solutions. It is difficult for a positively charged proton to leave a negatively charged anion. The few anions that do act as acids include H2PO4 Ϫ and HSO4 Ϫ . Table 11.9 summarizes the properties of common anions in solution. • All anions that are the conjugate bases of weak acids produce basic solutions. For example, formic acid, HCOOH, the acid in ant venom, is a weak acid, and so the formate ion acts as a base in water: H2O(l) ϩ HCO2 – (aq) #¢4 HCOOH(aq) ϩ OH– (aq) Formate ions and the other ions listed in the last row of Table 11.9 act as bases in water. • The anions of strong acids—which include Cl– , Br– , I– , NO3 – , and ClO4 – —are such weak bases that they have no significant effect on the pH of a solution. These anions are considered “neutral” in water. 11.13 THE pH OF SALT SOLUTIONS 451 TABLE 11.8 Acidic Character and Ka Values of Common Cations in Water* Character Examples Ka pKa Acidic conjugate acids of anilinium ion, C6H5NH3 ϩ 2.3 ϫ 10Ϫ5 4.64 weak bases pyridinium ion, C5H5NHϩ 5.6 ϫ 10Ϫ6 5.24 ammonium ion, NH4 ϩ 5.6 ϫ 10Ϫ10 9.25 methylammonium ion, CH3NH3 ϩ 2.8 ϫ 10Ϫ11 10.56 small, highly charged Fe3ϩ as Fe(H2O)6 3ϩ 3.5 ϫ 10Ϫ3 2.46 metal cations Cr3ϩ as Cr(H2O)6 3ϩ 1.3 ϫ 10Ϫ4 3.89 Al3ϩ as Al(H2O)6 3ϩ 1.4 ϫ 10Ϫ5 4.85 Cu2ϩ as Cu(H2O)6 2ϩ 3.2 ϫ 10Ϫ8 7.49 Ni2ϩ as Ni(H2O)6 2ϩ 9.3 ϫ 10Ϫ10 9.03 Fe2ϩ as Fe(H2O)6 2ϩ 8 ϫ 10Ϫ11 10.1 Neutral Group 1 and 2 cations Liϩ , Naϩ , Kϩ , Mg2ϩ , Ca2ϩ metal cations with Agϩ charge ϩ1 Basic none *As in Table 11.1, the experimental pKa values have more significant figures than shown here, and the Ka values have been calculated from these better data. Acidic H atom H3Oϩ 3ϩ Electron drift Acid H at 3ϩ Electron drift H Oϩ 2ϩ Metal cation FIGURE 11.20 In water, Al3ϩ cations are hydrated by water molecules that can act as Brønsted acids. Although, for clarity, only four water molecules are shown here, a metal cation typically has six H2O molecules attached to it. The acidity of the ion arises from the transfer of a hydrogen ion from one of the hydrating water molecules to a water molecule in the solution. TABLE 11.9 Acidic and Basic Character of Common Anions in Water Character Examples Acidic very few HSO4 Ϫ , H2PO4 Ϫ Neutral conjugate bases of strong acids ClϪ , BrϪ , IϪ , NO3 Ϫ , ClO4 Ϫ Basic conjugate bases of weak acids FϪ , O2Ϫ , OHϪ , S2Ϫ , HSϪ , CNϪ , CO3 2Ϫ , PO4 3Ϫ , NO2 Ϫ , CH3CO2 Ϫ , other carboxylate ions To determine whether the solution of a salt will be acidic, basic, or neutral, we must consider both the cation and the anion. First we examine the anion to see whether it is the conjugate base of a weak acid. If the anion is neither acidic nor basic, we examine the cation to see whether it is an acidic metal ion or the conjugate acid of a weak base. If one ion is an acid and the other a base, as in NH4F, then the pH is affected by the reactions of both ions with water and both equilibria must be considered, as in Section 11.19. Self-Test 11.12A Use Tables 11.8 and 11.9 to decide whether aqueous solutions of the salts (a) Ba(NO2)2; (b) CrCl3; (c) NH4NO3 are acidic, neutral, or basic. [Answer: (a) Basic; (b) acidic; (c) acidic] Self-Test 11.12B Decide whether aqueous solutions of (a) Na2CO3; (b) AlCl3; (c) KNO3 are acidic, neutral, or basic. To calculate the pH of a salt solution, we can use the equilibrium table procedure described in Toolboxes 11.1 and 11.2—an acidic cation is treated as a weak acid and a basic anion as a weak base. However, often we must first calculate the Ka or Kb for the acidic or basic ion. Examples 11.10 and 11.11 illustrate the procedure. 452 CHAPTER 11 ACIDS AND BASES EXAMPLE 11.10 Calculating the pH of a salt solution with an acidic cation Estimate the pH of 0.15 M NH4Cl(aq). Anticipate Because NH4 ϩ is a weak acid and Cl– is neutral, we should expect pH Ͻ 7. PLAN We treat the solution as that of a weak acid, using an equilibrium table as in Toolbox 11.1 to calculate the composition and hence the pH. First, write the chemical equation for proton transfer to water and the expression for Ka. Obtain the value of Ka from Kb for the conjugate base by using Ka ϭ Kw͞Kb (Eq. 11a). The initial concentration of the acidic cation is equal to the concentration of the cation that the salt would produce if the salt were fully dissociated and the cation retained all its acidic protons. What should we assume? We make two assumptions. (1) The extent of deprotonation is so small that the concentration of NH4 ϩ is insignificantly changed. (2) The autoprotolysis of water does not affect the pH significantly. SOLVE The equilibrium to consider is NH4 ϩ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ NH3(aq) In Table 11.2, we find Kb ϭ 1.8 ϫ 10Ϫ5 for NH3. First, we construct the following equilibrium table, with all concentrations in moles per liter: Species NH4 ϩ H3Oϩ NH3 Step 1 Initial concentration 0.15 0 0 Step 2 Change in concentration –x ϩx ϩx Step 3 Equilibrium concentration 0.15 Ϫ x x x Ka = [H3O+ ][NH3] [NH + 4 ] Step 4 From Ka ϭ Kw/Kb, Ka = 1.0 * 10-14 1.8 * 10-5 = 5.6 * 10-10 Substitute the equilibrium concentrations into the expression for Ka and assume that x ϽϽ 0.15: 5.6 * 10-10 = x * x 0.15 - x L x2 0.15 Evaluate As we anticipated, the pH is less than 7. The approximation that x is less than 5% of 0.15 is valid (by a large margin). Moreover, the H3Oϩ concentration (9.2 ␮molиLϪ1 ) is substantially larger than that generated by the autoprotolysis of water (0.10 ␮molиLϪ1 ), and so ignoring the latter contribution is valid (but only just). Self-Test 11.13A Estimate the pH of 0.10 M CH3NH3Cl(aq), aqueous methylammonium chloride; the cation is CH3NH3 ϩ . [Answer: 5.78] Self-Test 11.13B Estimate the pH of 0.10 M NH4NO3(aq). 11.13 THE pH OF SALT SOLUTIONS 453 1 x 10Ϫ2 10 Ϫ4 10Ϫ6 Solve for x. = 9.2 * 10-6 x L 20.15 * (5.6 * 10-10 ) 14 7 1 pH BasicAcidic 5.04 From pH ϭ –log [H3Oϩ ] with [H3Oϩ ] ϭ x, pH Ϸ –log(9.2 ϫ 10Ϫ6 ) ϭ 5.04 EXAMPLE 11.11 Calculating the pH of a salt solution with a basic anion Estimate the pH of 0.15 M Ca(CH3CO2)2(aq). Anticipate The CH3CO2 Ϫ ion is the conjugate base of a weak acid; so the solution will be basic and we should expect pH Ͼ 7. PLAN Use the procedure in Toolbox 11.2, taking the initial concentration of base from the concentration of added salt. Calculate Kb for the basic anion from Ka for its conjugate acid. Convert pOH into pH by using pH ϩ pOH ϭ 14.00. What should we assume? As in Example 11.10, we need to make two assumptions. (1) Because the protonation of the weak base is so small, the concentration of acetate ions retains its initial value. (2) The autoprotolysis of water does not affect the pH significantly. SOLVE The proton transfer equilibrium is H2O(l) ϩ CH3CO2 Ϫ (aq) #¢4 CH3COOH(aq) ϩ OHϪ (aq) The initial concentration of CH3CO2 Ϫ is 2 ϫ 0.15 molиLϪ1 ϭ 0.30 molиLϪ1 , because each formula unit of salt provides two CH3CO2 Ϫ ions. Table 11.1 gives the Ka of CH3COOH as 1.8 ϫ 10Ϫ5 . First, we construct the equilibrium table: CH3CO2 Ϫ CH3COOH OHϪ Step 1 Initial concentration 0.30 0 0 Step 2 Change in concentration Ϫx ϩx ϩx Step 3 Equilibrium concentration 0.30 Ϫ x x x Kb = [CH3COOH][OH- ] [CH3CO - 2 ] Step 4 Find the Kb of the CH3CO2 Ϫ ion from Kb ϭ Kw/Ka. Kb = 1.0 * 10-14 1.8 * 10-5 = 5.6 * 10-10 Evaluate As expected, the pH is greater than 7. The OHϪ concentration arising from the proton transfer equilibrium (13 ␮molиLϪ1 ) is much larger than that arising from the autoprotolysis of water (0.10 ␮molиLϪ1 ), and so it is valid to ignore autoprotolysis. Self-Test 11.14A Estimate the pH of 0.10 M KC6H5CO2(aq), potassium benzoate; see Table 11.1 for data. [Answer: 8.59] Self-Test 11.14B Estimate the pH of 0.020 M KF(aq); see Table 11.1 for data. Salts that contain the conjugate acids of weak bases produce acidic aqueous solutions; so do salts that contain small, highly charged metal cations. Salts that contain the conjugate bases of weak acids produce basic aqueous solutions. POLYPROTIC ACIDS AND BASES A polyprotic acid is a compound that can donate more than one proton. Many common acids are polyprotic, including sulfuric acid, H2SO4, and carbonic acid, H2CO3, each of which can donate two protons, and phosphoric acid, H3PO4, which can donate three protons. Polyprotic acids play a critical role in biological systems, because many enzymes can be regarded as polyprotic acids that carry out their vital functions by donating one proton after another. A polyprotic base is a species that can accept more than one proton. Examples include the CO3 2Ϫ and SO3 2Ϫ anions, both of which can accept two protons, and the PO4 3Ϫ anion, which can accept three protons. A polyprotic acid is viewed as donating its protons in a succession of deprotonation steps. For example, a carbonic acid molecule can lose one proton to form HCO3 Ϫ , and then that ion can donate the remaining proton to form CO3 2Ϫ . We shall see how to take this succession of deprotonations into account when assessing the pH of the solution of a polyprotic acid or one of its salts. In addition, we shall see how the relative concentrations of the ions in solution, such as PO4 3Ϫ , HPO4 2Ϫ , and H2PO4 Ϫ , depend on the pH of the solution. 454 CHAPTER 11 ACIDS AND BASES Substitute the equilibrium concentrations into the expression for Kb and assume that x is less than 5% of 0.30 (that is, x Ͻ 0.015). 5.6 * 10-10 = x * x 0.30 - x L x2 0.30 1 x 10 Ϫ4 10 Ϫ6 10Ϫ2Solve for x. = 1.3 * 10-5 x L 20.30 * (5.6 * 10-10 ) Check the assumption that x Ͻ 0.015. 1.3 ϫ 10Ϫ5 Ͻ 0.015 From pOH ϭ Ϫlog [OHϪ ] with [OHϪ ] ϭ x, pOH Ϸ Ϫlog (1.3 ϫ 10Ϫ5 ) ϭ 4.89 14 7 1 pH BasicAcidic 9.11 From pH ϭ pKw Ϫ pOH, pH Ϸ 14.00 Ϫ 4.89 ϭ 9.11 Thinking point: Do you think that successive deprotonations of a polyprotic acid will result in stronger or weaker acids? 11.14 The pH of a Polyprotic Acid Solution Carbonic acid is an important natural component of the environment because it is formed whenever carbon dioxide dissolves in lake water or seawater. In fact, the oceans provide one of the critical mechanisms for maintaining a constant concentration of carbon dioxide in the atmosphere. Carbonic acid takes part in two successive proton transfer equilibria: H2CO3(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ HCO3 Ϫ (aq) Ka1 ϭ 4.3 ϫ 10Ϫ7 HCO3 Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CO3 2Ϫ (aq) Ka2 ϭ 5.6 ϫ 10Ϫ11 The conjugate base of H2CO3 in the first equilibrium, HCO3 Ϫ , acts as an acid in the second equilibrium. That ion produces in turn its own conjugate base, CO3 2Ϫ . Protons are donated successively by polyprotic acids, with the acidity constant decreasing significantly, usually by a factor of about 103 or more, with each proton lost (Table 11.10): Ka1 ϾϾ Ka2 ϾϾ Ka3 ϾϾ . . . The decrease can be traced to the attraction between opposite charges: it is harder to separate a positively charged proton from a negatively charged ion (such as HCO3 Ϫ ) than from the original uncharged molecule (H2CO3). Sulfuric acid, for example, is a strong acid, but its conjugate base, the hydrogen sulfate ion, HSO4 Ϫ , is a weak acid. Sulfuric acid is the only common polyprotic acid for which the first deprotonation is complete. The second deprotonation adds to the H3Oϩ concentration slightly, and so the overall pH will be slightly lower than that due to the first deprotonation alone. For example, in 0.010 M H2SO4(aq) the first deprotonation is complete: H2SO4(aq) ϩ H2O(l) H3Oϩ (aq) ϩ HSO4 Ϫ (aq) It results in an H3Oϩ concentration equal to the initial concentration of the acid, 0.010 molиLϪ1 . This value corresponds to pH ϭ 2.0. However, the conjugate base, HSO4 Ϫ , also contributes protons to the solution, and so the second proton transfer equilibrium needs to be taken into account: HSO4 Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ SO4 2Ϫ (aq) Ka2 ϭ 0.012 Therefore, to calculate the pH of a solution of sulfuric acid, we set up an equilibrium table in which the initial concentrations are those due to the first deprotonation: [HSO4 Ϫ ] ϭ 0.010 molиLϪ1 , [H3Oϩ ] ϭ 0.010 molиLϪ1 , and [SO4 2Ϫ ] ϭ 0. Then we solve for the new value of the hydronium ion concentration: In this way, we find x ϭ 4.3 ϫ 10Ϫ3 , [H3Oϩ ] ϭ 0.014 molиLϪ1 , and pH ϭ 1.9, which is slightly lower than the pH ϭ 2.0 that we calculated on the basis of the first deprotonation alone. 0.012 = (0.010 + x) * x 0.010 - x Ka2 = [H3O+ ][SO 2- 4 ] [HSO - 4 ] ¡ 11.14 THE pH OF A POLYPROTIC ACID SOLUTION 455 TABLE 11.10 Acidity Constants of Polyprotic Acids Acid Ka1 pKa1 Ka2 pKa2 Ka3 pKa3 sulfuric acid, H2SO4 strong 1.2 ϫ 10Ϫ2 1.92 oxalic acid, (COOH)2 5.9 ϫ 10Ϫ2 1.23 6.5 ϫ 10–5 4.19 sulfurous acid, H2SO3 1.5 ϫ 10Ϫ2 1.81 1.2 ϫ 10–7 6.91 phosphorous acid, H3PO3 1.0 ϫ 10Ϫ2 2.00 2.6 ϫ 10–7 6.59 phosphoric acid, H3PO4 7.6 ϫ 10Ϫ3 2.12 6.2 ϫ 10–8 7.21 2.1 ϫ 10Ϫ13 12.68 tartaric acid, C2H4O2(COOH)2 6.0 ϫ 10Ϫ4 3.22 1.5 ϫ 10–5 4.82 carbonic acid, H2CO3 4.3 ϫ 10Ϫ7 6.37 5.6 ϫ 10–11 10.25 hydrosulfuric acid, H2S 1.3 ϫ 10Ϫ7 6.89 7.1 ϫ 10Ϫ15 14.15 456 CHAPTER 11 ACIDS AND BASES Self-Test 11.15A Estimate the pH of 0.050 M H2SO4(aq). [Answer: 1.23] Self-Test 11.15B Estimate the pH of 0.10 M H2SO4(aq). The parent acids of common polyprotic acids other than sulfuric are weak and the acidity constants of successive deprotonation steps are normally widely different. As a result, except for sulfuric acid, to calculate the pH of a polyprotic acid, we just use Ka1 and take only the first deprotonation into account; that is, we treat the acid as a monoprotic weak acid (see Toolbox 11.1). Subsequent deprotonations do take place, but provided Ka2 is less than about Ka1/1000, they do not affect the pH significantly and can be ignored. Estimate the pH of a polyprotic acid for which all deprotonations are weak by using only the first deprotonation equilibrium and assuming that further deprotonation is insignificant. An exception is sulfuric acid, the only common polyprotic acid that is a strong acid in its first deprotonation. 11.15 Solutions of Salts of Polyprotic Acids The conjugate base of a polyprotic acid is amphiprotic: it can act as either an acid or a base because it can either donate its remaining acidic hydrogen atom as a proton or accept a proton and revert to the original acid. For example, a hydrogen sulfide ion, HSϪ , in water acts as both an acid and a base: HSϪ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ S2Ϫ (aq) Ka2 ϭ 7.1 ϫ 10Ϫ15 pKa2 ϭ 14.15 HSϪ (aq) ϩ H2O(l) #¢4 H2S(aq) ϩ OHϪ (aq) Kb1 ϭ Kw/Ka1 ϭ 7.7 ϫ 10Ϫ8 pKb1 ϭ 7.11 Because HSϪ is amphiprotic, it is not immediately apparent whether an aqueous solution of NaHS will be acidic or basic. However, we can use the pKa and pKb values of the HSϪ ion to conclude that: • HSϪ is such a weak acid that the basic character of S2Ϫ will dominate, and pH Ͼ 7. • HSϪ is a weak base; again pH Ͼ 7. The first conclusion arises from the large pKa2 of H2S. The second conclusion arises from pKb1 having an intermediate value and therefore (by the relation in Eq. 11b) the pKa1 of H2S also having an intermediate value. This reasoning suggests that the pH will be high if both pKa1 and pKa2 are relatively large. Indeed, if we make some reasonable assumptions we can use (14)* This formula is reliable provided S ϾϾ Kw/Ka2 and S ϾϾ Ka1, where S is the initial (that is, analytical or formal) concentration of the salt. If these criteria are not satisfied, a much more complicated expression must be used: it and its derivation, including the derivation of this simplified version, can be found on the Web site for this text. pH = 1 2(pKa1 + pKa2) If values of Ka1 and Ka2 for a polyprotic acid are close together, then the calculations are more complicated, as both equilibria must be considered. Exceptions are HSO4 ؊ , which is an extremely weak base, and HPO3 2Ϫ , which does not act as an acid because its proton is not acidic (Section 11.10). EXAMPLE 11.12 Estimating the pH of a solution of an amphiprotic salt Estimate the pH of (a) 0.20 M NaH2PO4(aq); (b) 0.20 M Na2HC6H5O7(aq), a salt of citric acid, H3C6H5O7. For citric acid, pKa2 ϭ 5.95, and pKa3 ϭ 6.39. PLAN Use Eq. 14 to determine the pH of the salts of the diprotic conjugate base (H2AϪ ) of a triprotic acid (H3A) and the monoprotic conjugate base (HAϪ ) of a diprotic acid (H2A). However, when the solute is a salt of an anion that has lost two protons, such as HC6H5O7 2Ϫ , we must adjust the expression to use the appropriate neighboring pKas. What should we assume? We need to verify that S ϾϾ Kw/Ka2 and S ϾϾ Ka1. SOLVE (a) For H3PO4, Ka1 ϭ 7.6 ϫ 10Ϫ3 and Ka2 ϭ 6.2 ϫ 10Ϫ8 , and so pKa1 ϭ 2.12 and pKa2 ϭ 7.21. Therefore, for the solution of H2PO4 Ϫ , 11.16 THE CONCENTRATIONS OF SOLUTE SPECIES 457 Self-Test 11.16A Estimate the pH of 0.10 M NaHCO3(aq). [Answer: 8.31] Self-Test 11.16B Estimate the pH of 0.50 M KH2PO4(aq). Suppose we need to estimate the pH of an aqueous solution of a fully deprotonated polyprotic acid molecule. An example is a solution of sodium sulfide, in which sulfide ions, S2Ϫ , are present; another example is a solution of potassium phosphate, which contains PO4 3Ϫ ions. In such a solution, the anion acts as a base: it accepts protons from water. For such a solution, we can use the techniques for calculating the pH of a basic anion illustrated in Example 11.11. The Ka to use in the calculation is for the deprotonation that produces the ion being studied. For S2Ϫ , we would use Ka2 for H2S; and for PO4 3Ϫ , we would use Ka3 for H3PO4. The pH of the aqueous solution of an amphiprotic salt can be estimated from the average of the pKas of the salt and its conjugate acid. The pH of a solution of a salt of the final conjugate base of a polyprotic acid is found from the reaction of the anion with water. 11.16 The Concentrations of Solute Species Environmental chemists studying the pollution caused by fertilizers in runoff from fields or mineralogists studying the formation of sedimentary rocks as groundwater trickles through rock formations may need to know not only the pH but also the concentrations of each of the ions present in the solution. For example, they may need to Check that S ϾϾ Kw/Ka2 and S ϾϾ Ka1. S ϭ 0.20, Ka1 ϭ 7.6 ϫ 10Ϫ3 , so S ϾϾ Ka1 Therefore, the use of Eq. 14 is valid. S = 0.20, Kw Ka2 = 1.0 * 10-14 6.2 * 10-8 = 1.6 * 10-7 , so S W Kw Ka2 14 7 1 pH BasicAcidic 4.66 From pH ϭ (2.12 ϩ 7.21) ϭ 4.66 1 2 pH = 1 2(pKa1 + pKa2), (b) For citric acid, pKa2 ϭ 5.95 and pKa3 ϭ 6.39. Therefore, for the solution of HC6H5O7 2Ϫ , Check that S ϾϾ Kw/Ka3 and S ϾϾ Ka2. Therefore, the use of Eq. 14 is valid. Ka2 = 1.1 * 10-6 , so S W Ka2S = 0.20, S = 0.20, Kw Ka3 = 1.0 * 10-14 4.1 * 10-7 = 2.4 * 10-8 , so S W Kw Ka3 14 7 1 pH BasicAcidic 6.17 From = 6.17 pH = 1 2(5.95 + 6.39) pH = 1 2(pKa2 + pKa3), know the concentration of sulfite ion in a solution of sulfurous acid or the concentrations of phosphate and hydrogen phosphate ions in a solution of phosphoric acid. The calculations described in Toolbox 11.1 tell us the pH—the hydrogen ion concentration— but for a polyprotic acid they do not give the concentrations of all the solute species in solution, which for H3PO4 includes H3PO4, H2PO4 Ϫ , HPO4 2Ϫ , and PO4 3Ϫ . To calculate them, we need to take into account all the proton transfer equilibria taking place in the solution. To simplify the calculations, we start by judging the relative concentration of each species in solution and identify terms that can be ignored. To make this judgment, we use the general rule that concentrations of species present in the greater amount are not significantly affected by concentrations of species present in the smaller amount, especially if the difference in concentrations is large. 458 CHAPTER 11 ACIDS AND BASES TOOLBOX 11.3 HOWTO CALCULATETHE CONCENTRATIONS OF ALL SPECIES IN A POLYPROTIC ACID SOLUTION CONCEPTUAL BASIS We assume that the polyprotic acid is the solute species present in largest amount. We also assume that only the first deprotonation contributes significantly to [H3Oϩ ] and that the autoprotolysis of water does not contribute significantly to [H3Oϩ ] or [OHϪ ]. PROCEDURE FOR A DIPROTIC ACID Step 1 From the deprotonation equilibrium of the acid (H2A), determine the concentrations of the conjugate base (HAϪ ) and H3Oϩ , as illustrated in Example 11.7. Step 2 Find the concentration of A2Ϫ from the second deprotonation equilibrium (that of HAϪ ) by substituting the concentrations of H3Oϩ and HAϪ from step 1 into the expression for Ka2. Step 3 Find the concentration of OHϪ by dividing Kw by the concentration of H3Oϩ . PROCEDURE FOR A TRIPROTIC ACID Step 1 From the deprotonation equilibrium of the acid (H3A), determine the concentrations of the conjugate base (H2AϪ ) and H3Oϩ . Step 2 Find the concentration of HA2Ϫ from the second deprotonation equilibrium (that of H2AϪ ) by substituting the concentrations of H3Oϩ and H2AϪ from step 1 into the expression for Ka2. Step 3 Find the concentration of A3Ϫ from the deprotonation equilibrium of HA2Ϫ by substituting the concentrations of H3Oϩ and HA2Ϫ from step 2 into the expression for Ka3. The concentration of H3Oϩ is the same in all three calculations because only the first deprotonation makes a significant contribution to its value. Step 4 Find the concentration of OHϪ by dividing Kw by the concentration of H3Oϩ . This procedure is illustrated in Example 11.13. EXAMPLE 11.13 Calculating the concentrations of all solute species in a polyprotic acid solution Calculate the concentrations of all solute species in 0.10 M H3PO4(aq). Anticipate Because successive deprotonations result in ever weaker acids, we expect the concentrations to lie in the order H3PO4 Ͼ H2PO4 Ϫ Ͼ HPO4 2Ϫ Ͼ PO4 3Ϫ , with very, very little of the completely deprotonated species. PLAN Follow the procedure in Toolbox 11.3. What should we assume? That only the first deprotonation affects the pH and that the autoprotolysis of water has no significant effect on the pH. SOLVE Step 1 The primary proton transfer equilibrium is H3PO4(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ H2PO4 Ϫ (aq) and the first acidity constant, from Table 11.10, is 7.6 ϫ 10Ϫ3 . The equilibrium table, with the concentrations in moles per liter, is H3PO4 H3O؉ H2PO4 Ϫ Initial concentration 0.10 0 0 Change in concentration Ϫx ϩx ϩx Equilibrium concentration 0.10 Ϫ x x x The little illustrations display the percentage composition of species in the solution: blue for H2PO4 Ϫ , green for H3PO4, and (below) yellow for HPO4 2Ϫ . Step 2 Now we use Ka2 ϭ 6.2 ϫ 10Ϫ8 to find the concentration of HPO4 2Ϫ . Because Ka2 ϽϽ Ka1, we can safely assume that the H3Oϩ concentration calculated in step 1 is unchanged by the second deprotonation. The proton transfer equilibrium is H2PO4 Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ HPO4 2Ϫ (aq) We set up the equilibrium table with concentrations in moles per liter, using the results from step 1 for the concentrations of H3Oϩ and H2PO4 Ϫ : H2PO4 Ϫ H3Oϩ HPO4 2Ϫ Initial concentration (from step 1) 2.4 ϫ 10Ϫ2 2.4 ϫ 10Ϫ2 0 Changes in concentration Ϫx ϩx ϩx Equilibrium concentration 2.4 ϫ 10Ϫ2 – x 2.4 ϫ 10Ϫ2 ϩ x x 11.16 THE CONCENTRATIONS OF SOLUTE SPECIES 459 From Ka1 ϭ [H3Oϩ ] [H2AϪ ]͞[H3A], assuming that x ϽϽ 0.10, decide if it is valid to approximate the expression. solves to x Ϸ 0.028, which is 28% of 0.10, too large for the approximation. Ka1 = 7.6 * 10-3 = x * x 0.10 - x L x2 0.10 Because the value of x is in fact larger than 5% of 0.10, we must use the full quadratic equation. (7.6 ϫ 10Ϫ3 ) ϫ (0.10 Ϫ x) ϭ x2 Rearrange the equation. x2 ϩ (7.6 ϫ 10Ϫ3 )x Ϫ 7.6 ϫ 10Ϫ4 ϭ 0 Ϫ3.2ϫ10Ϫ2 2.4ϫ10Ϫ2 x Solve for x with the quadratic formula. x ϭ 2.4 ϫ 10Ϫ2 or Ϫ3.2 ϫ 10Ϫ2 Reject the negative root. x ϭ 2.4 ϫ 10Ϫ2 ; therefore, [H3Oϩ ] ϭ 2.4 ϫ 10Ϫ2 molиLϪ1 10Ϫ3 0.1 H2 PO4 Ϫ From [H2PO4 Ϫ ] ϭ [H3Oϩ ], [H2PO4 Ϫ ] ϭ 2.4 ϫ 10Ϫ2 molиLϪ1 10 Ϫ3 0.1 H2 PO4 Ϫ H3 PO4 It follows from the equilibrium table that [H3PO4] Ϸ 0.10 Ϫ 0.024 molиLϪ1 ϭ 0.08 molиLϪ1 (0.076 rounded to 0.08) Step 3 The loss of the final proton from HPO4 2Ϫ produces the phosphate ion, PO4 3Ϫ : HPO4 2Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ PO4 3Ϫ (aq) The equilibrium constant is Ka3 ϭ 2.1 ϫ 10Ϫ13 , a very small value. We assume that the concentration of H3Oϩ calculated in step 1 and the concentration of HPO4 2Ϫ calculated in step 2 are unaffected by the additional deprotonation. The equilibrium table is HPO4 2Ϫ H3Oϩ PO4 3Ϫ Initial concentration (from step 2) 6.2 ϫ 10Ϫ8 2.4 ϫ 10Ϫ2 0 Changes in concentration Ϫx ϩx ϩx Equilibrium concentration 6.2 ϫ 10Ϫ8 Ϫ x 2.4 ϫ 10Ϫ2 ϩ x x 460 CHAPTER 11 ACIDS AND BASES From Ka2 ϭ [H3Oϩ ][HA2Ϫ ]/[H2AϪ ], assuming that x ϽϽ 2.4 ϫ 10Ϫ2 . Ka2 ϭ 6.2 ϫ 10Ϫ8 ϭ x = (2.4 * 10-2 + x) * x 2.4 * 10-2 - x L 2.4 * 10-2 * x 2.4 * 10-2 Check the assumption that x ϽϽ 2.4 ϫ 10Ϫ2 . 6.2 ϫ 10Ϫ8 ϽϽ 2.4 ϫ 10Ϫ2 HPO4 2Ϫ From [HPO4 2Ϫ ] ϭ x Ϸ Ka2, [HPO4 2Ϫ ] ϭ 6.2 ϫ 10Ϫ8 molиLϪ1 From Ka3 ϭ [H3Oϩ ][A3Ϫ ]/[HA2Ϫ ]; because Ka3 is so small, assume that x ϽϽ 6.2 ϫ 10Ϫ8 and simplify the equation. Ka3 ϭ 2.1 ϫ 10Ϫ13 ϭ (2.4 * 10-2 + x) * x 6.2 * 10-8 - x L 2.4 * 10-2 * x 6.2 * 10-8 Solve for x. x L (2.1 * 10-13 ) * (6.2 * 10-8 ) 2.4 * 10-2 = 5.4 * 10-19 From [PO4 3Ϫ ] ϭ x, [PO4 3Ϫ ] Ϸ 5.4 ϫ 10Ϫ19 molиLϪ1 Step 4 From [OHϪ ] ϭ Kw/[H3Oϩ ], [OH] = 1.0 * 10-14 2.4 * 10-2 = 4.2 * 10-13 At this point, we can summarize the concentrations of all the solute species in 0.10 M H3PO4(aq) in order of decreasing concentration: Species: H3PO4 H3Oϩ H2PO4 Ϫ HPO4 2Ϫ OHϪ PO4 3Ϫ Concentration (molؒL؊1 ): 0.08 2.4 ϫ 10Ϫ2 2.4 ϫ 10Ϫ2 6.2 ϫ 10Ϫ8 4.2 ϫ 10Ϫ13 5.4 ϫ 10Ϫ19 Evaluate We can conclude that the second deprotonation proceeds only to a small extent. The HPO4 2Ϫ ion is deprotonated only to a very tiny extent, too small to illustrate with a diagram, and our assumption that H3Oϩ is unaffected by the third deprotonation is justified. Self-Test 11.17A Calculate the concentrations of all solute species in 0.20 M H2S(aq). [Answer: With concentrations in molиLϪ1 : H2S, 0.20; HSϪ , 1.6 ϫ 10Ϫ4 ; H3Oϩ , 1.6 ϫ 10Ϫ4 ; OHϪ , 6.2 ϫ 10Ϫ11 ; S2Ϫ , 7.1 ϫ 10Ϫ15 ] Self-Test 11.17B Protonated glycine (ϩ NH3CH2COOH) is a diprotic amino acid with Ka1 ϭ 4.5 ϫ 10Ϫ3 and Ka2 ϭ 1.7 ϫ 10Ϫ10 . Calculate the concentrations of all solute species in 0.50 M NH3CH2COOHCl(aq). The concentrations of all species in a solution of a polyprotic acid can be calculated by assuming that species present in smaller amounts do not affect the concentrations of species present in larger amounts. 11.17 Composition and pH Sometimes we need to know how the concentrations of the ions present in a solution of a polyprotic acid vary with pH. This information is particularly important in the study of natural waters, such as rivers and lakes (Box 11.1). For example, if we were examining carbonic acid in rainwater, then, at low pH (when hydronium ions are abundant), we would expect the fully protonated species (H2CO3) to be dominant; at high pH (when hydroxide ions are abundant), we expect the fully deprotonated species (CO3 2Ϫ ) to be dominant; at intermediate pH, we expect the intermediate species (HCO3 Ϫ , in this case) to be dominant (Fig. 11.21). We can verify these expectations quantitatively. 11.17 COMPOSITION AND pH 461 0 0.2 0.4 0.6 0.8 1.0 Fractionofspecies,f(X) 0 2 4 6 8 10 12 14 pH H2CO3 HCO3 − pKa2pKa1 CO3 2− 6.37 10.25 −(pKa1 pKa2)1 2 FIGURE 11.21 The fractional composition of the species in carbonic acid as a function of pH. Note that the more fully protonated species are dominant at lower pH. Living Graph 11.21 HOW DO WE DO THAT? To see how the concentrations of species present in a solution vary with pH, we take the carbonic acid system as an example. Consider the following proton transfer equilibria: H2CO3(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ HCO3 Ϫ (aq) HCO3 Ϫ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CO3 2Ϫ (aq) We can express the composition of the solution in terms of the fraction, f(X), of each species X present, where X could be H2CO3, HCO3 Ϫ , or CO3 2Ϫ , and f(X) = [X] [H2CO3] + [HCO3 ] + [CO 2- 3 ] Ka2 = [H3O+ ][CO 2- 3 ] [HCO - 3 ] Ka1 = [H3O+ ][HCO - 3 ] [H2CO3] 462 CHAPTER 11 ACIDS AND BASES Acid Rain and the Gene Pool The human impact on the environment affects many areas of our lives and future. One example is the effect of acid rain on biodiversity, the diversity of living things. In the prairies that extend across the heartlands of North America and Asia, native plants have evolved that can survive even nitrogen-poor soil and drought. By studying prairie plants, scientists hope to breed food plants that will be hardy sources of food in times of drought. However, acid rain is making some of these plants extinct. Acid rain is a regional phenomenon. The areas in different colors on the map shown here indicate constant values of the pH of rain. Notice that the pH of rain decreases downwind (generally, east) of heavily populated areas. The low pH in heavily industrialized and populated areas is caused by the acidic oxides sulfur dioxide, SO2, and the nitrogen oxides, NO and NO2. Rain unaffected by human activity contains mostly weak acids and has a pH of about 5.7. The primary acid present is carbonic acid, H2CO3, a weak acid that results when atmospheric carbon dioxide dissolves in water. The major pollutants in acid rain are strong acids that arise from human activities. Atmospheric nitrogen and oxygen can react to form NO, but the endothermic reaction is spontaneous only at the high temperatures of automobile internal combustion engines and electrical power stations: N2(g) ϩ O2(g) #¢4 2 NO(g) Nitric oxide, NO, is not very soluble in water, but it can be oxidized further in air to form nitrogen dioxide: 2 NO(g) ϩ O2(g) 2 NO2(g) The NO2 reacts with water, forming nitric acid and nitric oxide: 3 NO2(g) ϩ 3 H2O(l) 2 H3Oϩ (aq) ϩ 2 NO3 Ϫ (aq) ϩ NO(g) The catalytic converters now used in automobiles can reduce NO to harmless N2. They are required in the United States for all new cars and trucks (see Section 14.15). ¡ ¡ WHAT HAS THIS TO DO WITH . . . THE ENVIRONMENT?BOX 11.1 Eastern gama grass is a variety of a prairie plant that produces seeds rich in protein. It is the subject of sustainable agriculture research because it produces an abundance of seeds and yet is a perennial plant that is resistant to drought. It will turn out to be helpful to express f(X) in terms of the ratio of each species to the intermediate species, HCO3 Ϫ . So we divide the numerator and denominator by [HCO3 Ϫ ] and get All three concentration ratios can be written in terms of the hydronium ion concentration. We simply rearrange the expressions for the first and second acidity constants: then substitute them into the expression for f(X) and rearrange it to obtain: f(CO 2- 3 ) = Ka1Ka2 [H3O+ ]2 + [H3O+ ]Ka1 + Ka1Ka2 f(HCO - 3 ) = [H3O+ ]Ka1 [H3O+ ]2 + [H3O+ ]Ka1 + Ka1Ka2 , f(H2CO3) = [H3O+ ]2 [H3O+ ]2 + [H3O+ ]Ka1 + Ka1Ka2 [H2CO3] [HCO - 3 ] = [H3O+ ] Ka1 ; [CO 2- 3 ] [HCO - 3 ] = Ka2 [H3O+ ] f(X) = [X]/[HCO - 3 ] [H2CO3]/[HCO - 3 ] + 1 + [CO 2- 3 ]/[HCO - 3 ] 11.17 COMPOSITION AND pH 463 Sulfur dioxide is produced as a by-product of the burning of fossil fuels. It may combine with water directly to form sulfurous acid, a weak acid: SO2(g) ϩ H2O(l) H2SO3(aq) Alternatively, in the presence of particulate matter and aerosols, sulfur dioxide may react with atmospheric oxygen to form sulfur ¡ trioxide, which forms sulfuric acid, a strong acid, in water: 2 SO2(g) ϩ O2(g) 2 SO3(g) SO3(g) ϩ 2 H2O(l) H3O+ (aq) ϩ HSO4 Ϫ (aq) Acid rain affects plants by changing the conditions in the soil. For example, nitric acid deposits nitrates, which fertilize the land. The nitrates allow fast-growing weeds such as quack grass to replace valuable prairie species. If these species were to become extinct, their genetic material would no longer be available for agricultural research. Research on air pollution is complex. Forests and prairies cover vast areas, and the interplay of regional air pollutants is so subtle that it may take years to sort out all the environmental stresses. Controls being put in place are beginning to reduce the acidity of rain in North AmericaandEurope.However,biologistshavefoundthattheyarenot enough for some sensitive environments. More stringent controls may beneededforustomaintainourqualityof lifewithoutlosingourprecious heritage of native plants. We can also help by using automobiles lessandbicyclesmoreorbytakingpublictransportationwhenwecan. Related Exercise: 11.137 For Further Reading: J. P. Grime, “Biodiversity and ecosystem function: The debate deepens,” Science, vol. 277, 1997, pp. 1260–1261. T. Larssen et al., “Acid rain in China,” Environmental Science & Technology, vol. 40, 2006, pp. 418–425. J. Krajcik, “Acid rain: Long-term data show lingering effects from acid rain,” Science, vol. 13, April 13, 2001, pp. 195–196. US Environmental Protection Agency, “Acid rain,” http://www.epa.gov/ acidrain/. US Geological Service, “Acid rain, atmospheric deposition, and precipitation chemistry,” http://bqs.usgs.gov/acidrain/. Environment Canada, “Acid rain,” http://www.ec.gc.ca/acidrain/. ¡ ¡ Precipitation over North America gradually becomes more acidic from west to east, especially in industrialized areas of the Northeast. This acid rain may be a result of the release of nitrogen and sulfur oxides into the atmosphere. The colors and numbers (see key) indicate pH measured at field laboratories in 2007. Additional maps may be found on the National Atmospheric Deposition Program/National Trends Network web site, http://nadp.sws.uiuc.edu/isopleths/annualmaps.asp. Lab pH 5.2 - 5.3 5.1 - 5.2 5.0 - 5.1 4.9 - 5.0 4.8 - 4.9 4.7 - 4.8 4.6 - 4.7 4.5 - 4.6 4.4 - 4.5 4.3 - 4.4 < 4.3 5.3 4.7 5.4 5.4 5.7 4.5 4.5 4.5 4.5 4.5 4.5 5.3 5.3 5.7 5.5 4.8 5.4 5.2 5.4 5.1 4.9 5.7 4.6 4.6 4.6 4.6 4.7 4.7 4.7 5.2 4.8 5.6 4.95.4 4.8 6.4 5.6 5.2 5.2 5.4 5.3 5.4 5.3 4.8 4.9 4.8 5.4 4.9 4.5 4.5 6.1 6.1 4.8 4.8 4.8 4.7 4.8 4.74.7 4.8 5.0 4.5 5.8 4.8 5.3 5.3 4.8 5.1 4.8 4.9 5.4 5.1 5.1 5.3 5.6 5.3 4.7 4.6 4.6 4.9 4.95.1 5.1 5.4 5.4 5.6 6.0 5.3 5.3 5.4 4.9 5.8 5.0 4.8 4.8 5.0 4.9 4.7 4.8 4.9 4.7 4.9 5.5 5.4 4.7 5.1 4.8 4.7 5.3 4.7 4.9 4.7 5.2 5.4 4.7 4.6 4.6 4.6 4.6 4.6 4.6 4.8 4.7 4.7 5.2 5.15.3 5.2 5.6 5.2 5.1 4.8 4.9 5.4 5.2 4.7 4.6 4.6 4.6 4.6 4.6 4.7 5.9 4.8 5.8 6.0 5.86.1 5.3 6.0 4.7 4.6 4.6 4.3 4.5 4.5 4.54.5 4.5 5.46.3 5.3 5.3 5.3 5.5 5.7 5.9 4.6 4.64.8 5.6 5.2 5.4 5.0 5.2 5.2 5.7 4.5 4.7 5.2 5.5 5.0 5.3 5.1 5.3 5.3 5.2 5.0 5.1 4.7 4.8 4.8 4.6 4.4 4.4 4.4 4.4 4.4 4.4 4.4 4.4 5.0 5.6 We have found expressions for the fractions, f, of species in a solution of carbonic acid. They are easily generalized to any diprotic acid H2A: (15a) where H ϭ [H3Oϩ ]2 ϩ [H3Oϩ ]Ka1 ϩ Ka1Ka2 (15b) What do these equations tell us? At high pH, the concentration of hydronium ions is very low; therefore the numerators in f(H2A) and f(HAϪ ) are very small, and so these species are in very low abundance, as we expected. At low pH, the concentration of hydronium ions is high; therefore the numerator in f(H2A) is large, and this species dominates. The shapes of the curves predicted by Eq. 15 are shown for H2CO3 in Fig. 11.21. We see that f(HCO3 Ϫ ) Ϸ 1 at intermediate pH. The maximum value of f(HCO3 Ϫ ) is at Note that the fully protonated form (H2CO3) is dominant when pH Ͻ pKa1 and the fully deprotonated form (CO3 2Ϫ ) becomes dominant when pH Ͼ pKa2. Similar calculations can be carried out for triprotic acids (Fig. 11.22). pH = 1 2(pKa1 + pKa2) f(H2A) = [H3O+ ]2 H , f(HA) = [H3O+ ]Ka1 H , f(A2) = Ka1Ka2 H Thinking point: The expressions in Eq. 15 have a symmetry. Can you identify it and use it to write down the corresponding expression for a triprotic acid? The fraction of deprotonated species increases as the pH is increased, as summarized in Figs. 11.21 and 11.22. AUTOPROTOLYSIS AND pH Suppose we were asked to estimate the pH of 1.0 ϫ 10Ϫ8 M HCl(aq). If we used the techniques of Example 11.3 to calculate the pH from the concentration of the acid itself, we would find pH ϭ 8.00. That value, though, is absurd, because it lies on the basic side of neutrality, whereas HCl is an acid! The error stems from there being two sources of hydronium ions, whereas we have considered only one. At very low acid concentrations, the supply of hydronium ions from the autoprotolysis of water is close to the supply provided by the very low concentration of HCl, and both supplies must be taken into account. The following two sections explain how to take autoprotolysis into account, first for strong acids and bases and then for weak ones. 11.18 Very Dilute Solutions of Strong Acids and Bases We have to include the contribution of autoprotolysis to pH only when the concentration of strong acid or base is less than about 10Ϫ6 molиLϪ1 . To calculate the pH in such a case, we need to consider all species in solution. As an example, consider a solution of HCl, a strong acid. Other than water, the species present are H3Oϩ , OHϪ , and ClϪ . There are three unknown concentrations. To find them, we need three equations. The first equation takes charge balance into account, the requirement that the solution must be electrically neutral overall. That is, the concentration of cations must equal that of anions. Because there is only one type of cation, H3Oϩ , the concentration of H3Oϩ ions must equal the sum of the concentrations of the two types of anions, ClϪ and OHϪ . The charge-balance relation [H3Oϩ ] ϭ [ClϪ ] ϩ [OHϪ ] then tells us that [OHϪ ] ϭ [H3Oϩ ] Ϫ [ClϪ ] The second equation takes material balance into account, the requirement that all the added solute must be accounted for even though it is now present as ions. Because HCl is a strong acid, the concentration of ClϪ ions in the solution is equal to the concentration of the HCl added initially (all the HCl molecules are deprotonated). If we denote the numerical value of that initial concentration by [HCl]initial, the materialbalance relation is [ClϪ ] ϭ [HCl]initial. We can combine it with the preceding equation to write [OHϪ ] ϭ [H3Oϩ ] Ϫ [HCl]initial 464 CHAPTER 11 ACIDS AND BASES 0 0.2 0.4 0.6 0.8 1.0 Fractionofspecies,f(X) 0 2 4 6 8 10 12 14 pH H3PO4 H2PO4 − HPO4 2− PO4 3− pKa2 pKa3pKa1 7.21 2.12 12.68 FIGURE 11.22 The fractional composition of the species in phosphoric acid as a function of pH. As in Fig. 11.20, the more fully protonated the species, the lower the pH at which it is dominant. If an ion is doubly charged, we multiply its concentration by 2 in the charge-balance equation, and by 3 for triply charged ions. 11.18 VERY DILUTE SOLUTIONS OF STRONG ACIDS AND BASES 465 The third equation is the expression for the autoprotolysis constant, Kw (Eq. 1). We can substitute the preceding expression for [OHϪ ] into the expression for Kw: Kw ϭ [H3Oϩ ][OHϪ ] ϭ [H3Oϩ ]([H3Oϩ ] Ϫ [HCl]initial) and rearrange it into a quadratic equation: [H3Oϩ ]2 Ϫ [HCl]initial[H3Oϩ ] Ϫ Kw ϭ 0 (16) As shown in Example 11.14, we can use the quadratic formula to solve this equation for the concentration of hydronium ions. Now consider a very dilute solution of a strong base, such as NaOH. Apart from water, the species present in solution are Naϩ , OHϪ , and H3Oϩ . As we did for HCl, we can write down three equations relating the concentrations of these ions by using charge balance, material balance, and the autoprotolysis constant. Because the cations present are hydronium ions and sodium ions, the charge-balance relation is [OHϪ ] ϭ [H3Oϩ ] ϩ [Naϩ ] The concentration of sodium ions is the same as the initial concentration of the NaOH, [NaOH]initial, and so the material-balance relation is [Naϩ ] ϭ [NaOH]initial. It follows that [OHϪ ] ϭ [H3Oϩ ] ϩ [NaOH]initial The autoprotolysis constant now becomes Kw ϭ [H3Oϩ ]([H3Oϩ ] ϩ [NaOH]initial) (17) The concentration of hydronium ions can be obtained by solving this equation with the quadratic formula. EXAMPLE 11.14 Calculating the pH of a very dilute aqueous solution of a strong acid What is the pH of 8.0 ϫ 10Ϫ8 M HCl(aq)? Anticipate Although the acid is very dilute, it is an acid, and we should expect a pH of slightly less than 7. PLAN Let [HCl]initial ϭ 8.0 ϫ 10Ϫ8 molиLϪ1 and [H3Oϩ ] ϭ x; substitute them in Eq. 16. SOLVE From [H3Oϩ ]2 Ϫ [HCl]initial[H3Oϩ ] Ϫ Kw ϭ 0, x2 Ϫ (8.0 ϫ 10Ϫ8 )x Ϫ (1.0 ϫ 10Ϫ14 ) ϭ 0 Ϫ6.8ϫ10 Ϫ8 1.5ϫ10 Ϫ7 x From the quadratic formula, ϭ 1.5 ϫ 10Ϫ7 or Ϫ6.8 ϫ 10Ϫ8 x = (8.0 * 10-8 ) ; 2(-8.0 * 10-8 )2 - 4(1)(-1.0 * 10-14 ) 2(1) 14 7 1 pH BasicAcidic 6.82 Reject the negative root and use pH ϭ Ϫlog x. pH ϭ Ϫlog(1.5 ϫ 10Ϫ7 ) ϭ 6.82 Evaluate As expected, the pH is slightly less than 7. Self-Test 11.18A What is the pH of 1.0 ϫ 10Ϫ7 M HNO3(aq)? [Answer: 6.79] Self-Test 11.18B What is the pH of 2.0 ϫ 10Ϫ7 M NaOH(aq)? In very dilute solutions of strong acids and bases, the pH is significantly affected by the autoprotolysis of water. The pH is determined by solving three simultaneous equations: the charge-balance equation, the material-balance equation, and the expression for Kw. 11.19 Very Dilute Solutions of Weak Acids Autoprotolysis also contributes to the pH of very dilute solutions of weak acids. In fact, some acids, such as hypoiodous acid, HIO, are so weak and undergo so little deprotonation that to find the pH of these solutions, we must always take into account the autoprotolysis of water. 466 CHAPTER 11 ACIDS AND BASES HOW DO WE DO THAT? The calculation of pH for very dilute solutions of a weak acid HA is similar to that for strong acids in Section 11.18. It is based on the fact that, apart from water, there are four species in solution—namely, HA, AϪ , H3Oϩ , and OHϪ . Because there are four unknowns, we need four equations to find their concentrations. Two relations that we can use are the autoprotolysis constant of water and the acidity constant of the acid HA: Kw ϭ [H3Oϩ ][OHϪ ] Charge balance provides a third equation: [H3Oϩ ] ϭ [OHϪ ] ϩ [AϪ ] Material balance provides the fourth equation: the total concentration of A groups (for instance, F atoms if the acid added is HF) must be equal to the initial concentration of the acid: [HA]initial ϭ [HA] ϩ [AϪ ] To find an expression for the concentration of hydronium ions in terms of the initial concentration of the acid, we rearrange the charge-balance relation to express the concentration of AϪ in terms of [H3Oϩ ]: [AϪ ] ϭ [H3Oϩ ] Ϫ [OHϪ ] Then we express [OHϪ ] in terms of the hydronium ion concentration by using the autoprotolysis expression: When we substitute this expression into the material-balance equation, we obtain Now we substitute these expressions for [HA] and [AϪ ] into Ka to obtain Ka = [H3O+ ]a[H3O+ ] - Kw [H3O+ ] b [HA]initial - [H3O+ ] + Kw [H3O+ ] = [HA]initial - [H3O+ ] + Kw [H3O+ ] [HA] = [HA]initial - [A] = [HA]initial - a[H3O+ ] - Kw [H3O+ ] b [A] = [H3O+ ] - Kw [H3O+ ] Ka = [H3O+ ][A- ] [HA] The expression we just derived is certainly intimidating, but many experimental conditions allow it to be simplified. For example, in many solutions of weak acids, [H3Oϩ ] Ͼ 10Ϫ6 (that is, pH Ͻ 6). Under these conditions, Kw/[H3Oϩ ] Ͻ 10Ϫ8 and we can ignore this term in both the numerator and the denominator: (18a) However, when the acid is so dilute or so weak that [H3Oϩ ] Յ 10Ϫ6 (that is, when the pH lies between 6 and 7), then we must solve the full expression for Ka, which can be rearranged into [H3Oϩ ]3 ϩ Ka[H3Oϩ ]2 Ϫ (Kw ϩ Ka[HA]initial)[H3Oϩ ] Ϫ KaKw ϭ 0 (18b) This is a cubic equation in [H3Oϩ ]. To solve this equation, it is best to use a graphing calculator or mathematical software like that on the Web site for this text. Ka = [H3O+ ]2 [HA]initial - [H3O+ ] 11.19 VERY DILUTE SOLUTIONS OF WEAK ACIDS 467 Remember that [H3Oϩ ] is really [H3Oϩ ]/c°. EXAMPLE 11.15 Estimating the pH of a dilute aqueous solution of a weak acid when the autoprotolysis of water must be considered. Use Eq. 18b to estimate the pH of a 1.0 ϫ 10Ϫ4 M aqueous phenol solution. Anticipate Phenol, C6H5OH, is a weak acid, so expect pH Ͻ 7; but the pH will be only slightly less than 7 because the solution is so dilute. PLAN Because Eq. 18b is complicated, first find the numerical factor of the third term and the numerical value of the fourth term. For simplicity, write x ϭ [H3Oϩ ]. SOLVE Find Ka for phenol in Table 11.1. Ka ϭ 1.3 ϫ 10Ϫ10 Evaluate Kw ϩ Ka[HA]initial. Kw ϩ Ka[HA]initial ϭ 1.0 ϫ 10Ϫ14 ϩ (1.3 ϫ 10Ϫ10 ) ϫ (1.0 ϫ 10Ϫ4 ) ϭ 2.3 ϫ 10Ϫ14 Evaluate KaKw. KaKw ϭ (1.3 ϫ 10Ϫ10 ) ϫ (1.0 ϫ 10Ϫ14 ) ϭ 1.3 ϫ 10Ϫ24 Substitute the values into Eq. 18b with [H3Oϩ ] ϭ x, x3 ϩ (1.3 ϫ 10Ϫ10 )x2 Ϫ (2.3 ϫ 10Ϫ14 )x Ϫ (1.3 ϫ 10Ϫ24 ) ϭ 0 Ϫ1.517 Ϫ0.001 1.516 y To simplify the coefficients, write x ϭ y ϫ 10Ϫ7 and divide the resulting equation through by 10Ϫ21 . y3 ϩ 0.0013y2 Ϫ 2.3y Ϫ 0.0013 ϭ 0 Find the positive root. The only positive root is y ϭ 1.516; so x ϭ 1.5 ϫ 10Ϫ7 14 7 1 pH BasicAcidic 6.82 From pH ϭ Ϫlog [H3Oϩ ] and [H3Oϩ ] ϭ x, pH ϭ Ϫlog(1.5 ϫ 10Ϫ7 ) ϭ 6.82 Evaluate As expected, the pH is slightly less than 7. Self-Test 11.19A Use Eq. 18b and the information in Table 11.1 to estimate the pH of 2.0 ϫ 10Ϫ4 M HCN(aq). [Answer: 6.48] Self-Test 11.19B Use Eq. 18b and the information in Table 11.1 to estimate the pH of 1.0 ϫ 10Ϫ2 M HIO(aq). In aqueous solutions of very weak acids, the autoprotolysis of water must be taken into account if the hydronium ion concentration is less than 10؊6 molؒL؊1 . The expressions for Kw and Ka are combined with the equations for charge balance and material balance to find the pH. 468 CHAPTER 11 ACIDS AND BASES ❑ 1 Write the formulas for conjugate acids and bases (Example 11.1). ❑ 2 Identify Brønsted and Lewis acids and bases in a chemical reaction (Self-Test 11.2). ❑ 3 Calculate the concentrations of ions in a solution of a strong acid or base (Example 11.2). ❑ 4 Calculate the pH and pOH of a solution of a strong acid or base (Example 11.3 and Section 11.6). ❑ 5 Calculate the H3Oϩ concentration in a solution from its pH (Example 11.4). ❑ 6 Show how the Ka and pKa of an acid are related to the Kb and pKb of its conjugate base (Section 11.8). ❑ 7 Use Ka values to predict the relative strengths of two acids or two bases (Example 11.5). ❑ 8 Predict the relative strengths of acids from molecular structures (Example 11.6). ❑ 9 Calculate the pH and percentage deprotonation of a weak acid (Toolbox 11.1 and Example 11.7). ❑ 10 Calculate the value of Ka for a weak acid (Example 11.8). ❑ 11 Calculate the pH and percentage protonation of a weak base (Toolbox 11.2 and Example 11.9). ❑ 12 Calculate the pH of an electrolyte solution (Examples 11.10 and 11.11). ❑ 13 Calculate the pH of a solution of a polyprotic acid (Section 11.14 and Example 11.13). ❑ 14 Estimate the pH of a solution of an amphiprotic salt (Example 11.12). ❑ 15 Calculate the concentrations of all species in a polyprotic acid solution (Toolbox 11.3 and Example 11.13). ❑ 16 Find the pH of an aqueous solution of strong acid or base that is so dilute that the autoprotolysis of water significantly affects the pH (Example 11.14). ❑ 17 Find the pH of an aqueous solution of a weak acid for which the autoprotolysis of water significantly affects the pH (Example 11.15). SKILLS YOU SHOULD HAVE MASTERED Proton Transfer Reactions 11.1 Write the formulas for the conjugate acids of (a) CH3NH2, methylamine; (b) NH2NH2, hydrazine; (c) HCO3 Ϫ ; and the conjugate bases of (d) HCO3 Ϫ ; (e) C6H5OH, phenol; (f) CH3COOH. 11.2 Write the formulas for the conjugate acids of (a) C2O4 2Ϫ , the oxalate ion; (b) C6H5NH2, aniline; (c) NH2OH, hydroxylamine; and the conjugate bases of (d) H2O2, hydrogen peroxide; (e) HNO2; (f) HCrO4 Ϫ . 11.3 Write the proton transfer equilibria for the following acids in aqueous solution and identify the conjugate acid–base pairs in each one: (a) H2SO4; (b) C6H5NH3 ϩ , anilinium ion; (c) H2PO4 Ϫ ; (d) HCOOH, formic acid; (e) NH2NH3 ϩ , hydrazinium ion. 11.4 Write the proton transfer equilibria for the following bases in aqueous solution and identify the conjugate acid–base pairs in each one: (a) CNϪ ; (b) NH2NH2, hydrazine; (c) CO3 2Ϫ ; (d) HPO4 2Ϫ ; (e) CO(NH2)2, urea. 11.5 Identify (a) the Brønsted acid and base in the following reaction, and (b) the conjugate base and acid formed: HNO3(aq) ϩ HPO4 2Ϫ (aq) #¢4 NO3 Ϫ (aq) ϩ H2PO4 Ϫ (aq) 11.6 Identify (a) the Brønsted acid and base in the following reaction, and (b) the conjugate base and acid formed: HSO3 Ϫ (aq) ϩ CH3NH3 ϩ (aq) #¢4 H2SO3(aq) ϩ CH3NH2(aq) 11.7 Below are the molecular models of two oxoacids. Write the name of each acid and then draw the model of its conjugate base. (Red ϭ O, light gray ϭ H, green ϭ Cl, and blue ϭ N.) 11.8 Below are the molecular models of two oxoacids. Write the name of each acid and then draw the model of its conjugate base. (Red ϭ O, light gray ϭ H, green ϭ Cl, and blue ϭ N.) (b)(a) (b)(a) EXERCISES EXERCISES 469 11.9 Which of the following reactions can be classified as reactions between Brønsted acids and bases? For those that can be so classified, identify the acid and the base. (Hint: It may help to write the net ionic equations.) (a) NH4I(aq) ϩ H2O(l) : NH3(aq) ϩ H3Oϩ (aq) ϩ IϪ (aq) (b) NH4I(s) NH3(g) ϩ HI(g) (c) CH3COOH(aq) ϩ NH3(aq) : CH3CONH2(aq) ϩ H2O(l) (d) NH4I(am) ϩ KNH2(am) : KI(am) ϩ 2 NH3(l) (Note: “am” indicates that liquid ammonia is the solvent.) 11.10 Which of the following reactions can be classified as reactions between Brønsted acids and bases? For those that can be so classified, identify the acid and the base. (Hint: It may help to write the net ionic equations.) (a) KOH(aq) ϩ CH3I(aq) : CH3OH(aq) ϩ KI(aq) (b) AgNO3(aq) ϩ HCl(aq) : AgCl(s) ϩ HNO3(aq) (c) 2 NaHCO3(am) ϩ 2 NH3(l) : Na2CO3(s) ϩ (NH4)2CO3(am) (Note: “am” indicates that liquid ammonia is the solvent.) (d) H2S(aq) ϩ Na2S(s) : 2 NaHS(aq) 11.11 Write the two proton transfer equilibria that demonstrate the amphiprotic character of (a) HCO3 Ϫ ; (b) HPO4 2Ϫ . Identify the conjugate acid–base pairs in each equilibrium. 11.12 Write the two proton transfer equilibria that show the amphiprotic character of (a) H2PO3 Ϫ ; (b) NH3. Identify the conjugate acid–base pairs in each equilibrium. 11.13 The two strands of the nucleic acid DNA are held together by four organic bases. The structure of one of these bases, thymine, is shown below. (a) How many protons can this base accept? (b) Draw the structure of each conjugate acid that can be formed. (c) Mark with an asterisk any structure that can show amphiprotic behavior in aqueous solution. 11.14 The two strands of the nucleic acid DNA are held together by four organic bases. The structure of one of these bases, cytosine, is shown below. (a) How many protons can this base accept? (b) Draw the structure of each conjugate acid that can be formed. (c) Mark with an asterisk any structure that can show amphiprotic behavior in aqueous solution. Lewis Acids and Bases 11.15 Draw the Lewis structure for each of the following species and identify each as a Lewis acid or Lewis base: (a) NH3; (b) BF3; (c) Agϩ ; (d) FϪ ; (e) HϪ . 11.16 Draw the Lewis structure for each of the following species and identify each as a Lewis acid or Lewis base: (a) Hϩ ; (b) Al3ϩ ; (c) CNϪ ; (d) NO2 Ϫ ; (e) CH3OϪ (the C atom is the central atom). 11.17 Write the Lewis structure of each reactant, identify the Lewis acid and the Lewis base, and then write the Lewis structure of the product (a complex) for the following Lewis acid–base reactions: (a) PF5 ϩ FϪ : (b) ClϪ ϩ SO2 : 11.18 Write the Lewis structure of each reactant, identify the Lewis acid and the Lewis base, and then write the Lewis structure of the product (a complex) for the following Lewis acid–base reactions: (a) FϪ ϩ BrF3 : (b) FeCl3 ϩ ClϪ : 11.19 State whether the following oxides are acidic, basic, or amphoteric: (a) BaO; (b) SO3; (c) As2O3; (d) Bi2O3. 11.20 State whether the following oxides are acidic, basic, or amphoteric: (a) SO2; (b) CaO; (c) P4O10; (d) TeO2. Strong Acids and Bases 11.21 The concentration of HCl in hydrochloric acid is reduced to 12% of its initial value by dilution. What is the difference in the pH values of the two solutions? 11.22 The concentration of Ca(OH)2 in an aqueous solution is reduced to 5.2% of its initial value by dilution. What is the difference in the pH values of the two solutions? 11.23 Calculate the molarity of OHϪ in solutions with the following concentrations of H3Oϩ : (a) 0.020 molиLϪ1 ; (b) 1.0 ϫ 10Ϫ5 molиLϪ1 ; (c) 3.1 mmolиLϪ1 . 11.24 Estimate the molarity of H3Oϩ in solutions with the following concentrations of OHϪ : (a) 0.024 molиLϪ1 ; (b) 4.5 ϫ 10Ϫ5 molиLϪ1 ; (c) 1.60 mmolиLϪ1 . 11.25 The value of Kw for water at body temperature (37°C) is 2.1 ϫ 10Ϫ14 . (a) What is the molarity of H3Oϩ ions and the pH of neutral water at 37°C? (b) What is the molarity of OHϪ in neutral water at 37°C? 11.26 The concentration of H3Oϩ ions at the freezing point of water is 3.9 ϫ 10Ϫ8 molиLϪ1 . (a) Calculate Kw and pKw at 0.0°C. (b) What is the pH of neutral water at 0.0°C? 11.27 Calculate the initial molarity of Ba(OH)2 and the molarities of Ba2ϩ , OHϪ , and H3Oϩ in an aqueous solution that contains 0.43 g of Ba(OH)2 in 0.100 L of solution. 11.28 Calculate the initial molarity of KNH2 and the molarities of Kϩ , NH2 Ϫ , OHϪ , and H3Oϩ in an aqueous solution that contains 0.60 g of KNH2 in 0.250 L of solution. 11.29 A careless laboratory technician wants to prepare 200.0 mL of a 0.025 M HCl(aq) solution, but uses a 250.0-mL volumetric flask by mistake. (a) What would the pH of the desired solution have been? (b) What will be the actual pH of the solution as prepared? 11.30 A careless laboratory technician prepares 300.0 mL of 0.0175 M KOH(aq) and pipets 25.0 mL of the solution into a beaker. The beaker is allowed to stand in a warm place for two days before use, during which time some of the water evaporates and the volume is reduced to 18.0 mL. (a) What would the pH of the solution as initially prepared have been? (b) What will be the actual pH of the solution after the evaporation? 11.31 The pH of several solutions was measured in the research laboratories of a food company; convert each of the following pH values into the molarity of H3Oϩ ions: (a) 3.3 (the pH of sour Cytosine NH2 NH N O Thymine O NH NH O ¡ ¢ orange juice); (b) 6.7 (the pH of a saliva sample); (c) 4.4 (the pH of beer); (d) 5.3 (the pH of a coffee sample). 11.32 The pH of several solutions was measured in a hospital laboratory; convert each of the following pH values into the molarity of H3Oϩ ions: (a) 4.8 (the pH of a urine sample); (b) 0.7 (the pH of a sample of fluid extracted from a stomach); (c) 7.4 (the pH of blood); (d) 8.1 (the pH of exocrine pancreatic secretions). 11.33 Calculate the pH and pOH of each of the following aqueous solutions of strong acid or base: (a) 0.0146 M HNO3(aq); (b) 0.11 M HCl(aq); (c) 0.0092 M Ba(OH)2(aq); (d) 2.00 mL of 0.175 M KOH(aq) after dilution to 0.500 L; (e) 13.6 mg of NaOH dissolved in 0.350 L of solution; (f) 75.0 mL of 3.5 ϫ 10Ϫ4 M HBr(aq) after dilution to 0.500 L. 11.34 Calculate the pH and pOH of each of the following aqueous solutions of strong acid or base: (a) 0.0356 M HI(aq); (b) 0.0725 M HCl(aq); (c) 3.46 ϫ 10Ϫ3 M Ba(OH)2(aq); (d) 10.9 mg of KOH dissolved in 10.0 mL of solution; (e) 10.0 mL of 5.00 M NaOH(aq) after dilution to 2.50 L; (f) 5.0 mL of 3.5 ϫ 10Ϫ4 M HClO4(aq) after dilution to 25.0 mL. 11.35 A student added solid Na2O to a 200.0-mL volumetric flask, which was then filled with water, resulting in 200.0 mL of NaOH solution. 5.00 mL of the solution was then transferred to another volumetric flask and diluted to 500.0 mL. The pH of the diluted solution is 13.25. What is the concentration of hydroxide ion in (a) the diluted solution? (b) the original solution? (c) What mass of Na2O was added to the first flask? 11.36 A student added solid K2O to a 500.0 mL volumetric flask, which was then filled with water, resulting in 500.0 mL of KOH solution. 10.0 mL of the solution was then transferred to another volumetric flask and diluted to 300.0 mL. The pH of the diluted solution is 14.12. What is the concentration of hydroxide ion in (a) the diluted solution? (b) the original solution? (c) What mass of K2O was added to the first flask? Weak Acids and Bases 11.37 Give the Ka value of each of the following acids: (a) phosphoric acid, H3PO4, pKa1 ϭ 2.12; (b) phosphorous acid, H3PO3, pKa1 ϭ 2.00; (c) selenous acid, H2SeO3, pKa1 ϭ 2.46; (d) hydrogen selenate ion, HSeO4 Ϫ , pKa2 ϭ 1.92. (e) List the acids in order of increasing strength. 11.38 Give the pKb values of the following bases: (a) ammonia, NH3, Kb ϭ 1.8 ϫ 10Ϫ5 ; (b) deuterated ammonia, ND3, Kb ϭ 1.1 ϫ 10Ϫ5 ; (c) hydrazine, NH2NH2, Kb ϭ 1.7 ϫ 10Ϫ6 ; (d) hydroxylamine, NH2OH, Kb ϭ 1.1 ϫ 10Ϫ8 . (e) List the bases in order of increasing strength. 11.39 For each of the following weak acids, write the proton transfer equilibrium equation and the expression for the equilibrium constant Ka. Identify the conjugate base, write the appropriate proton transfer equation, and write the expression for the basicity constant Kb. (a) HClO2; (b) HCN; (c) C6H5OH. 11.40 For each of the following weak bases, write the proton transfer equilibrium equation and the expression for the equilibrium constant Kb. Identify the conjugate acid, write the appropriate proton transfer equation, and write the expression for the acidity constant Ka. (a) (CH3)2NH, dimethylamine; (b) C14H10N2, nicotine; (c) C6H5NH2, aniline. 11.41 Using data available in Tables 11.1 and 11.2, place the following acids in order of increasing strength: HNO2, HClO2, ϩ NH3OH, (CH3)2NH2 ϩ . 11.42 Using data available in Tables 11.1 and 11.2, place the following acids in order of increasing strength: HCOOH, (CH3)3NHϩ , N2H5 ϩ , HF. 11.43 Using data in Tables 11.1 and 11.2, place the following bases in order of increasing strength: FϪ , NH3, CH3CO2 Ϫ , C5H5N (pyridine). 11.44 Using data in Tables 11.1 and 11.2, place the following bases in order of increasing strength: CNϪ , (C2H5)3N, N2H4 (hydrazine), BrOϪ . 11.45 Label each of the following species as a strong or weak acid. Refer to Tables 11.1, 11.2, and 11.3. (a) HClO3; (b) H2S; (c) HSO4 Ϫ ; (d) CH3NH3 ϩ ; (e) HCO3 Ϫ ; (f) HNO3; (g) CH4. 11.46 Label each of the following species as a strong or weak base. Refer to Tables 11.1, 11.2, and 11.3. (a) O2Ϫ ; (b) BrϪ ; (c) HSO4 Ϫ ; (d) HCO3 Ϫ ; (e) CH3NH2; (f) H2; (g) CH3 Ϫ . 11.47 The values of Ka for phenol and 2,4,6-trichlorophenol (see following structures) are 1.3 ϫ 10Ϫ10 and 1.0 ϫ 10Ϫ6 , respectively. Which is the stronger acid? Account for the difference in acid strength. 11.48 The value of pKb for aniline is 9.37 and that for 4-chloroaniline is 9.85 (see the following structures). Which is the stronger base? Account for the difference in base strength. 11.49 Arrange the following bases in order of increasing strength on the basis of the pKa values of their conjugate acids, which are given in parentheses: (a) ammonia (9.26); (b) methylamine (10.56); (c) ethylamine (10.81); (d) aniline (4.63) (see Exercise 11.48). Is there a simple pattern of strengths? 11.50 Arrange the following bases in order of increasing strength on the basis of the pKa values of their conjugate acids, which are given in parentheses: (a) aniline (4.63) (see Exercise 11.48); (b) 2-hydroxyaniline (4.72); (c) 3-hydroxyaniline (4.17); (d) 4-hydroxyaniline (5.47). Is there a simple pattern of strengths? NH2 OH 4-Hydroxyaniline NH2 OH 3-Hydroxyaniline OH NH2 2-Hydroxyaniline NH2 Cl 4-Chloroaniline NH2 Aniline Cl OH Cl Cl 2,4,6-Trichlorophenol OH Phenol 470 CHAPTER 11 ACIDS AND BASES EXERCISES 471 11.51 The pKa of HIO(aq), hypoiodous acid, is 10.64 and that of HIO3(aq), iodic acid, is 0.77. Account for the difference in acid strength. 11.52 The pKa of HClO(aq), hypochlorous acid, is 7.53 and that of HBrO(aq), hypobromous acid, is 8.69. Account for the difference in acid strength. 11.53 Determine which acid in each of the following pairs is stronger and explain why: (a) HF or HCl; (b) HClO or HClO2; (c) HBrO2 or HClO2; (d) HClO4 or H3PO4; (e) HNO3 or HNO2; (f) H2CO3 or H2GeO3. 11.54 Determine which acid in each of the following pairs is stronger and explain why: (a) H3AsO4 or H3PO4; (b) HBrO3 or HBrO; (c) H3PO4 or H3PO3; (d) H2Te or H2Se; (e) H2S or HCl; (f) HClO or HIO. 11.55 Suggest an explanation for the different strengths of (a) acetic acid and trichloroacetic acid; (b) acetic acid and formic acid. 11.56 Suggest an explanation for the different strengths of (a) ammonia and methylamine; (b) hydrazine and hydroxylamine. The pH of Solutions of Weak Acids and Bases Refer to Tables 11.1 and 11.2 for the appropriate Ka and Kb values for the following exercises. 11.57 Calculate the pH, pOH, and percentage deprotonation of each of the following aqueous solutions: (a) 0.20 M CH3COOH(aq); (b) 0.20 M CCl3COOH(aq); (c) 0.20 M HCOOH(aq). (d) Explain any differences in pH on the basis of molecular structure. 11.58 Lactic acid is produced by muscles during exercise. Calculate the pH, pOH, and percentage deprotonation of each of the following aqueous solutions of lactic acid, CH3CH(OH)COOH: (a) 0.15 M; (b) 1.5 ϫ 10Ϫ3 M; (c) 1.5 ϫ 10Ϫ5 M. 11.59 (a) When the pH of 0.10 M HClO2(aq) was measured, it was found to be 1.2. What are the values of Ka and pKa of chlorous acid? (b) The pH of a 0.10 M propylamine, C3H7NH2, aqueous solution was measured as 11.86. What are the values of Kb and pKb of propylamine? 11.60 (a) The pH of 0.015 M HNO2(aq) was measured as 2.63. What are the values of Ka and pKa of nitrous acid? (b) The pH of 0.10 M C4H9NH2(aq), butylamine, was measured as 12.04. What are the values of Kb and pKb of butylamine? 11.61 Calculate the pH, pOH, and percentage protonation of solute in each of the following aqueous solutions: (a) 0.057 M NH3(aq); (b) 0.162 M NH2OH(aq); (c) 0.35 M (CH3)3N(aq); (d) 0.0073 M codeine, given that the pKa of its conjugate acid is 8.21. 11.62 Calculate the pOH, pH, and percentage protonation of solute in each of the following aqueous solutions: (a) 0.082 M C5H5N(aq), pyridine; (b) 0.0103 M C10H14N2(aq), nicotine; (c) 0.060 M quinine, given that the pKa of its conjugate acid is 8.52; (d) 0.045 M strychnine, given that the Ka of its conjugate acid is 5.49 ϫ 10Ϫ9 . 11.63 Find the initial concentration of the weak acid or base in each of the following aqueous solutions: (a) a solution of HClO with pH ϭ 4.60; (b) a solution of hydrazine, NH2NH2, with pH ϭ 10.20. 11.64 Find the initial concentration of the weak acid or base in each of the following aqueous solutions: (a) a solution of HClO with pH ϭ 5.1; (b) a solution of pyridine, C5H5N, with pH ϭ 9.1. 11.65 The percentage deprotonation of benzoic acid in a 0.110 M solution is 2.4%. What is the pH of the solution and the Ka of benzoic acid? 11.66 The percentage deprotonation of veronal (diethylbarbituric acid) in a 0.020 M aqueous solution is 0.14%. What is the pH of the solution and what is the Ka of veronal? 11.67 The percentage protonation of octylamine (an organic base) in a 0.100 M aqueous solution is 6.7%. What is the pH of the solution and what is the Kb of octylamine? 11.68 An aqueous solution is 35.0% by mass methylamine (CH3NH2) and has a density of 0.85 gиcmϪ3 . (a) Draw the Lewis structures of a methylamine molecule and its conjugate acid. (b) If 50.0 mL of this solution is diluted to 1000.0 mL, what is the pH of the resulting solution? 11.69 Write the equilibrium constant for the following reaction and calculate the value of K at 298 K for the reaction HNO2(aq) ϩ NH3(aq) #4 NH4 ϩ (aq) ϩ NO2 Ϫ (aq) using the data in Tables 11.1 and 11.2. 11.70 Write the equilibrium constant for the reaction HIO3(aq) ϩ NH2NH2(aq) #4 NH2NH3 ϩ (aq) ϩ IO3 Ϫ (aq) and calculate the value of K at 298 K using the data in Tables 11.1 and 11.2. 11.71 Determine whether an aqueous solution of each of the following salts has a pH equal to, greater than, or less than 7. If pH Ͼ 7 or pH Ͻ 7, write a chemical equation to justify your answer. (a) NH4Br; (b) Na2CO3; (c) KF; (d) KBr; (e) AlCl3; (f) Cu(NO3)2. 11.72 Determine whether an aqueous solution of each of the following salts has a pH equal to, greater than, or less than 7. If pH Ͼ 7 or pH Ͻ 7, write a chemical equation to justify your answer. (a) K2C2O4, potassium oxalate; (b) Ca(NO3)2; (c) CH3NH3Cl, methylamine hydrochloride; (d) K3PO4; (e) FeCl3; (f) C5H5NHCl, pyridinium chloride. 11.73 Rank the following solutions in order of increasing pH: (a) 1.0 ϫ 10Ϫ5 M HCl(aq); (b) 0.20 M CH3NH3Cl(aq); (c) 0.20 M CH3COOH(aq); (d) 0.20 M C6H5NH2(aq). Justify your ranking. 11.74 Rank the following solutions in order of increasing pH: (a) 1.0 ϫ 10Ϫ5 M NaOH(aq); (b) 0.20 M NaNO2(aq); (c) 0.20 M NH3(aq); (d) 0.20 M NaCN(aq). Justify your ranking. 11.75 Calculate the pH of each of the following solutions: (a) 0.63 M NaCH3CO2(aq); (b) 0.19 M NH4Cl(aq); (c) 0.055 M AlCl3(aq); (d) 0.65 M KCN(aq). 11.76 Calculate the pH of each of the following solutions: (a) 0.25 M CH3NH3Cl(aq); (b) 0.13 M Na2SO3(aq); (c) 0.071 M FeCl3(aq). 11.77 A 15.5-g sample of CH3NH3Cl is dissolved in water to make 450. mL of solution. What is the pH of the solution? 11.78 A 7.8-g sample of C6H5NH3Cl is dissolved in water to make 350. mL of solution. Determine the percentage deprotonation of the cation. 11.79 During the analysis of an unknown acid HA, a 0.010 M solution of the sodium salt of the acid was found to have a pH of 10.35. Use Table 11.1 to write the formula of the acid. 11.80 During the analysis of an unknown weak base B, a 0.10 M solution of the nitrate salt of the base was found to have a pH of 3.13. Use Table 11.2 to write the formula of the base. 472 CHAPTER 11 ACIDS AND BASES 11.81 (a) A 150.-mL sample of 0.020 M NaCH3CO2(aq) is diluted to 0.500 L. What is the concentration of acetic acid at equilibrium? (b) What is the pH of a solution resulting from the dissolution of 2.16 g of NH4Br in water to form 0.400 L of solution? 11.82 (a) A 25.0-mL sample of 0.250 M KCN(aq) is diluted to 100.0 mL. What is the concentration of hydrocyanic acid at equilibrium? (b) A 1.59-g sample of NaHCO3 is dissolved in water to form 200.0 mL of solution. What is the pH of the solution? 11.83 A 3.38-g sample of the sodium salt of alanine, NaCH3CH(NH2)CO2, is dissolved in water, and then the solution is diluted to 50.0 mL. For alanine, Ka1 ϭ 4.57 ϫ 10Ϫ3 , Ka2 ϭ 1.30 ϫ 10Ϫ10 . What is the pH of the resulting solution? 11.84 The drug amphetamine, C6H5CH2CH(CH3)NH2, Kb ϭ 7.8 ϫ 10Ϫ4 , is usually marketed as the hydrogen bromide salt, C6H5CH2CH(CH3)NH3 ϩ BrϪ , because it is much more stable in this solid form. Determine the pH of a solution made by dissolving 6.48 g of the salt to form 200.0 mL of solution. Polyprotic Acids and Bases Refer to Table 11.9 for the Ka values needed for the following exercises. 11.85 Calculate the pH of 0.15 M H2SO4(aq) at 25°C. 11.86 Calculate the pH of 0.010 M H2SeO4(aq), given that Ka1 is very large and Ka2 ϭ 1.2 ϫ 10Ϫ2 . 11.87 Calculate the pH of each of the following diprotic acid solutions at 25°C, ignoring second deprotonations only when the approximation is justified: (a) 0.010 M H2CO3(aq); (b) 0.10 M (COOH)2(aq); (c) 0.20 M H2S(aq). 11.88 Calculate the pH of each of the following diprotic acid solutions at 25°C, ignoring second deprotonations only when that approximation is justified: (a) 0.10 M H2S(aq); (b) 0.15 M H2C4H4O6(aq), tartaric acid; (c) 1.1 ϫ 10Ϫ3 M H2TeO4(aq), telluric acid, for which Ka1 ϭ 2.1 ϫ 10Ϫ8 and Ka2 ϭ 6.5 ϫ 10Ϫ12 . 11.89 Estimate the pH of (a) 0.15 M NaHSO3(aq); (b) 0.050 M NaHSO3(aq). 11.90 Estimate the pH of (a) 0.125 M NaHCO3(aq); (b) 0.250 M KHCO3(aq). 11.91 Citric acid, which is extracted from citrus fruits and pineapples, undergoes three successive deprotonations with pKa values of 3.14, 5.95, and 6.39. Estimate the pH of (a) a 0.15 M aqueous solution of the monosodium salt; (b) a 0.075 M aqueous solution of the disodium salt. 11.92 Like sulfuric acid, a certain diprotic acid, H2A, is a strong acid in its first deprotonation and a weak acid in its second deprotonation. A solution that is 0.020 M H2A(aq) has a pH of 1.66. What is the value of Ka2 for this acid? 11.93 Calculate the concentrations of H2CO3, HCO3 Ϫ , CO3 2Ϫ , H3Oϩ , and OHϪ present in 0.0456 M H2CO3(aq). 11.94 Calculate the concentrations of H2SO3, HSO3 Ϫ , SO3 2Ϫ , H3Oϩ , and OHϪ present in 0.125 M H2SO3(aq). 11.95 Calculate the concentrations of H2CO3, HCO3 Ϫ , CO3 2Ϫ , H3Oϩ , and OHϪ present in 0.0456 M Na2CO3(aq). 11.96 Calculate the concentrations of H2SO3, HSO3 Ϫ , SO3 2Ϫ , H3Oϩ , and OHϪ present in 0.125 M Na2SO3(aq). 11.97 For each of the following polyprotic acids, state which species (H2A, HAϪ , or A2Ϫ ) you expect to be the form present in highest concentration in aqueous solution at pH ϭ 6.50: (a) phosphorous acid; (b) oxalic acid; (c) hydrosulfuric acid. 11.98 For each of the following polyprotic acids, state which species (H2A, HAϪ , or A2Ϫ of the diprotic acid or H3A, H2AϪ , HA2Ϫ , or A3Ϫ for triprotic acids) you expect to be the form present in highest concentration in aqueous solution at pH ϭ 5.0: (a) tartaric acid; (b) hydrosulfuric acid; (c) phosphoric acid. 11.99 A large volume of 0.150 M H2SO3(aq) is treated with a solid, strong base to adjust the pH to 5.50. Assume that the addition of the base does not significantly affect the volume of the solution. Estimate the concentrations of H2SO3, HSO3 Ϫ , and SO3 2Ϫ present in the final solution. 11.100 A large volume of 0.250 M H2S(aq) is treated with a solid, strong base to adjust the pH to 9.35. Assume that the addition of the base does not significantly affect the volume of the solution. Estimate the concentrations of H2S, HSϪ , and S2Ϫ present in the final solution. 11.101 Calculate the pH of each of the following acid solutions at 25°C; ignore second deprotonations only when that approximation is justified. (a) 1.0 ϫ 10Ϫ4 M H3BO3(aq), boric acid acts as a monoprotic acid; (b) 0.015 M H3PO4(aq); (c) 0.10 M H2SO3(aq). 11.102 Calculate the molarities of (COOH)2, HOOCCO2 Ϫ , (CO2)2 2Ϫ , H3Oϩ , and OHϪ in 0.12 M (COOH)2(aq). 11.103 Calculate the concentrations of all phosphate species in H3PO4(aq) that has pH ϭ 2.25, given that the total concentration of all four forms of the dissolved phosphates is 15 mmolиLϪ1 . 11.104 Ammonium acetate is prepared by the reaction of equal amounts of ammonium hydroxide and acetic acid. Determine the concentration of all solute species present in 0.100 M NH4CH3CO2(aq). Autoprotolysis and pH 11.105 Calculate the pH of 6.55 ϫ 10Ϫ7 M HClO4(aq). 11.106 Calculate the pH of 7.49 ϫ 10Ϫ8 M HI(aq). 11.107 Calculate the pH of 9.78 ϫ 10Ϫ8 M KOH(aq). 11.108 Calculate the pH of 8.23 ϫ 10Ϫ7 M NaNH2(aq). For Exercises 11.109 through 11.114, we suggest that you use a graphing calculator to solve the equation or suitable computer software to solve the set of simultaneous equations. 11.109 At what concentration is it necessary to take into account the autoprotolysis of water when calculating the pH of an aqueous acetic acid solution? 11.110 At what concentration is it necessary to take into account the autoprotolysis of water when calculating the pH of an aqueous chloroacetic acid solution? Account for any difference between this value and the answer to Exercise 10.109. 11.111 (a) Calculate the pH of 1.00 ϫ 10Ϫ4 M and 1.00 ϫ 10Ϫ6 M HBrO(aq), ignoring the effect of the autoprotolysis of water. (b) Repeat the calculations, taking into account the autoprotolysis of water. 11.112 (a) Calculate the pH of 2.50 ϫ 10Ϫ4 M and 2.50 ϫ 10Ϫ6 M phenol(aq), ignoring the effect of the autoprotolysis of water. EXERCISES 473 (b) Repeat the calculations, taking into account the autoprotolysis of water. 11.113 (a) Calculate the pH of 8.50 ϫ 10Ϫ5 M and 7.37 ϫ 10Ϫ6 M HCN(aq), ignoring the effect of the autoprotolysis of water. (b) Repeat the calculations, taking into account the autoprotolysis of water. 11.114 (a) Calculate the pH of 1.89 ϫ 10Ϫ5 M and 9.64 ϫ 10Ϫ7 M HClO(aq), ignoring the effect of the autoprotolysis of water. (b) Repeat the calculations, taking into account the autoprotolysis of water. Integrated Exercises 11.115 The images below represent the solutes in the solutions of three acids (water molecules are not shown, hydrogen atoms and hydronium ions are represented by small gray spheres, conjugate bases by large colored spheres). (a) Which acid is a strong acid? (b) Which acid has the strongest conjugate base? (c) Which acid has the highest pKa? Explain each of your answers. 11.116 The images below represent the solutes in the solutions of three salts (water molecules are not shown, hydrogen atoms and ions are represented by small gray spheres, hydroxide ions by red and gray spheres, cations by pink spheres and anions by green spheres). (a) Which salt has a cation that is the conjugate acid of a weak base? (b) Which salt has an anion that is the conjugate base of a weak acid? (c) Which salt has an anion that is the conjugate base of a strong acid? Explain each of your answers. 11.117 Hydronium and hydroxide ions appear to move through water much faster than other kinds of ions. Explain this observation. 11.118 Which of the following best describes the composition of a solution labeled “0.10 M H2SO4(aq)”? (a) [H2SO4] ϭ 0.10 M (b) [H3Oϩ ] Ͼ 0.10 M, [SO4 2Ϫ ] ϭ 0.10 M (c) [H3Oϩ ] ϭ 0.20 M, [SO4 2Ϫ ] ϭ 0.10 M (d) [H3Oϩ ] Ͼ 0.10 M, [HSO4 2Ϫ ] Ͻ 0.10 M (e) [H3Oϩ ] ϭ 0.10 M, [HSO4 2Ϫ ] ϭ 0.10 M 11.119 A combustion analysis of 1.200 g of an anhydrous sodium salt gave 0.942 g of CO2, 0.0964 g of H2O, and 0.246 g of Na. The molar mass of the salt is 112.02 gиmolϪ1 . (a) What is the chemical formula of the salt? (b) The salt contains carboxylate groups (ϪCO2 Ϫ ), and the carbon atoms are bonded together. Draw the Lewis structure of the anion. (c) Next, 1.50 g of this sodium salt was dissolved in water and diluted to 50.0 mL. Identify the dissolved substance: Is it an acid, a base, or is it amphiprotic? Calculate the pH of the solution. 11.120 Decide on the basis of the information in Table 11.3 whether carbonic acid is a strong or weak acid in liquid ammonia solvent. Explain your answer. 11.121 Draw the Lewis structure of boric acid, B(OH)3. (a) Is resonance important for its description? (b) The proton transfer equilibrium for boric acid is given in a footnote to Table 11.1. In that reaction does boric acid act as a Lewis acid, a Lewis base, or neither? Justify your answer by using Lewis structures of boric acid and its conjugate base. 11.122 Dinitrogen monoxide, N2O, reacts with water to form hyponitrous acid, H2N2O2(aq), in a Lewis acid–base reaction. (a) Write the chemical equation for the reaction. (b) Draw the Lewis structures of N2O and H2N2O2 (the atoms are attached in the order HONNOH). (c) Identify the Lewis acid and Lewis base. 11.123 Acetic acid is used as a solvent for some reactions between acids and bases. (a) Nitrous acid and carbonic acids are both weak acids in water. Will either of them act as a strong acid in acetic acid? Explain your answer. (b) Will ammonia act as a strong or weak base in acetic acid? Explain your answer. 11.124 Sections 11.9 and 11.10 discuss the relationship between molecular structure and the strengths of acids. The same ideas can be applied to bases. (a) Explain the relative strengths of the Brønsted bases OHϪ , NH2 Ϫ , and CH3 Ϫ (see Table 11.3). (b) Explain why NH3 is a weak base in water, but PH3 forms essentially neutral solutions. (c) If you were ranking the species in (a) or (b) as Lewis bases, would your rankings be the same or different? Explain your reasoning. 11.125 Use the thermodynamic data available in Appendix 2A to calculate the acidity constant of HF(aq). 11.126 The acidity of soil is determined by mixing a sample of soil with water and measuring the pH of the resulting slurry. Scientists have found that mixing the soil into 0.10 M CaCl2(aq) instead of water provides more consistent results. Would you expect the pH of the slurry with CaCl2 to differ from that measured using pure water? If so, how? If not, why not? 11.127 The autoprotolysis constant, Khw, for heavy water at 25°C is 1.35 ϫ 10Ϫ15 . (a) Write the chemical equation for the autoprotolysis (more precisely, the autodeuterolysis, because a deuteron is being transferred) of D2O. (b) Evaluate pKhw for D2O at 25°C. (c) Calculate the molarities of D3Oϩ and ODϪ in pure heavy water at 25°C. (d) Evaluate the pD and pOD of heavy water at 25°C. (e) Find the relation between pD, pOD, and pKhw. 11.128 The pKhw for the autoprotolysis of heavy water, D2O, is 13.8330 at 30.°C. Assuming ⌬Hr° for this reaction to be independent of temperature and using information from Exercise 11.127, calculate ⌬Sr° for the autoprotolysis reaction. Suggest an interpretation of the sign. Suggest a reason why the autoprotolysis constant of heavy water differs from that of ordinary water. 11.129 Use Table 11.1 to determine the percentage deprotonation of 1.00 M aqueous lactic acid. At what temperature will the solution freeze? (Assume that the density of the solution is 1.00 gиcmϪ3 .) 11.130 Is the osmotic pressure of 0.10 M H2SO4(aq) the same as, less than, or greater than that of 0.10 M HCl(aq)? Calculate the osmotic pressure of each solution to support your conclusion. (3)(2)(1) (3)(2)(1) 11.131 Estimate the enthalpy of deprotonation of formic acid at 25°C, given that Ka ϭ 1.765 ϫ 10Ϫ4 at 20°C and 1.768 ϫ 10Ϫ4 at 30°C. 11.132 (a) The value of Kw at 40°C is 3.8 ϫ 10Ϫ14 . What is the pH of pure water at 40°C? (b) Use data from part (a) and Exercise 11.25 and the values for the autoprotolysis of water at 25°C to determine graphically the enthalpy and entropy of the autoprotolysis of water. (c) Suggest an interpretation of the sign of ⌬S°. (d) Write an equation that describes the pH of pure water as a function of temperature. 11.133 The two acidity constants of oxalic acid, HOOCCOOH, differ by a factor of about 1000: pKa1 ϭ 1.23 and pKa2 ϭ 4.19. However, the two acidity constants of adipic acid, HOOC(CH2)4COOH, are close together: pKa1 ϭ 4.43 and pKa2 ϭ 5.41. Explain why the difference in acidity constants is so much greater for oxalic acid. 11.134 Although many chemical reactions take place in water, it is often necessary to use other solvents; liquid ammonia (normal boiling point, Ϫ33°C) has been used extensively. Many of the reactions that take place in water have analogous reactions in liquid ammonia. (a) Write the chemical equation for the autoprotolysis of NH3. (b) What are the formulas of the acid and base species that result from the autoprotolysis of liquid ammonia? (c) The autoprotolysis constant, Kam, of liquid ammonia has the value 1 ϫ 10Ϫ33 at Ϫ35°C. What is the value of pKam at that temperature? (d) What is the molarity of NH4 ϩ ions in liquid ammonia? (e) Evaluate pNH4 and pNH2, which are the analogs of pH and pOH, in liquid ammonia at Ϫ35°C. (f) Determine the relation between pNH4, pNH2, and pKam. 11.135 Recall from Section 10.13 that hemoglobin (Hb) molecules in blood carry O2 molecules from the lungs, where the concentration of oxygen is high, to the tissues where it is low. In the tissues the equilibrium H3Oϩ (aq) ϩ HbO2 Ϫ (aq) #4 HHb(aq) ϩ H2O(l) ϩ O2(aq) releases oxygen. When muscles work hard, they produce lactic acid as a by-product. (a) What effect will the lactic acid have on the concentration of HbO2 Ϫ ? (b) When the hemoglobin returns to the lungs, where oxygen concentration is high, how does the concentration of HbO2 Ϫ change? 11.136 The structures below show a hydrated d-metal ion. Draw the structure of the conjugate base of this complex. Chemistry Connections 11.137 Rainwater is naturally slightly acidic due to the dissolved carbon dioxide. Acid rain results when acidic sulfur and nitrogen oxides produced during the combustion of coal and oil react with rainwater (see Box 11.1). (a) The partial pressure of CO2 in air saturated with water vapor at 25°C and 1.00 atm is 3.04 ϫ 10Ϫ4 atm. Henry’s constant for CO2 in water is 2.3 ϫ 10Ϫ2 molиLϪ1 иatmϪ1 ; and, for carbonic acid, pKa1 ϭ 6.37. Assuming that all the dissolved CO2 can be thought of as H2CO3, verify by calculation that the pH of “normal” rainwater is about 5.7. (b) Scientists investigating acid rain measured the pH of a water sample from a lake and found it to be 4.8. The total concentration of dissolved carbonates in the lake is 4.50 mmolиLϪ1 . Determine the molar concentrations of the carbonate species CO3 2Ϫ , HCO3 Ϫ , and H2CO3 in the lake. (c) Suppose that 1.00 tonne (1 t ϭ 103 kg) of coal that is 2.5% sulfur by mass is burned in a coal-fired plant. What mass of SO2 is produced? (d) What is the pH of rainwater when the SO2 generated in part (c) dissolves in a volume of water equivalent to 2.0 cm of rainfall over 2.6 km2 ? (The pKa1 of sulfurous acid is 1.81. Consider the water to be initially pure and at a pH of 7.) (e) If the SO2 in part (c) is first oxidized to SO3 before the rainfall, what would the pH of the same rainwater be? (f) One process used to clean SO2 from the emissions of coal-fired plants is to pass the stack gases along with air through a wet calcium carbonate slurry, where the following reaction takes place: CaCO3(s) ϩ SO2(g) ϩ O2(g) : CaSO4(s) ϩ CO2(g). What mass of limestone (CaCO3) is needed to remove 50.0 kg sulfur dioxide from stack gases if the removal process is 90% efficient? 474 CHAPTER 11 ACIDS AND BASES What Are the Key Ideas? The concentrations of dissolved ions satisfy the equilibrium constants for the reactions in which they participate. Why Do We Need to Know This Material? The techniques described in this chapter provide the tools that we need to analyze and control the concentrations of ions in solution. Many reactions are carried out in solution, and so this material is fundamental to understanding chemistry. The ionic compounds released into waterways by individuals, industry, and agriculture can impair the quality of our water supplies. However, these hazardous ions can be identified and removed if we add the right reagents. Aqueous equilibria govern the stabilization of the pH in blood, seawater, and other solutions encountered in biology, medicine, and the environment. What Do We Need to Know Already? This chapter develops the ideas in Chapters 10 and 11 and applies them to equilibria involving ions in aqueous solution. To prepare for the sections on titrations, review Section L. For the discussion of solubility equilibria, review Section I. The discussion of Lewis acids and bases in Section 12.13 is based on Section 11.2. A primary goal of this chapter is to learn how to manage the pH of solutions of acids, bases, and their salts. The control of pH is crucial for the ability of organisms—including ourselves—to survive, because even minor drifts from the optimum value of the pH can cause enzymes to change their shape and cease to function. The information in this chapter is used in industry to control the pH of reaction mixtures and to purify water. In agriculture it is used to maintain the soil at an optimal pH. In the laboratory it is used to interpret the change in pH of a solution during a titration, one of the most common quantitative analytical techniques. It also forms the basis of qualitative analysis, the identification of the substances and ions present in a sample. All these applications involve equilibria between species in solution, especially between species that can exchange protons. The common theme throughout this chapter is that all these equilibria can be treated in a similar way: 1 Identify the solute species present in the solution. 2 Identify the stoichiometric relations between the concentrations of solute species (often by setting up an equilibrium table). 3 Use those relations together with equilibrium constants to calculate the equilibrium concentrations of the solute species. These three simple steps constitute a powerful and widely used technique. Initially we apply them to show how the pH of a solution can be kept nearly constant at a chosen value. Then we use them to show how to predict the pH of a solution at any stage of a titration. Next, we apply them to characterize equilibria between ions in solution. Finally, we consider how all these ideas can be combined to analyze the composition of aqueous solutions of ionic compounds. MIXED SOLUTIONS AND BUFFERS We have seen how to estimate the pH of a solution of a weak acid or base (Chapter 11), but suppose a salt of the acid or base is also present. How does that salt affect the pH of the solution? Suppose we have some dilute hydrochloric acid and add to it appreciable concentrations of the conjugate base of HCl, the Cl– ion, as sodium chloride. Because HCl is a strong acid, its conjugate base is very weak and so has no measurable effect on pH. The pH of 0.10 M HCl(aq) is about 1.0, even after 0.10 mol NaCl has MIXED SOLUTIONS AND BUFFERS 12.1 Buffer Action 12.2 Designing a Buffer 12.3 Buffer Capacity TITRATIONS 12.4 Strong Acid–Strong Base Titrations 12.5 Strong Acid–Weak Base and Weak Acid–Strong Base Titrations 12.6 Acid–Base Indicators 12.7 Stoichiometry of Polyprotic Acid Titrations SOLUBILITY EQUILIBRIA 12.8 The Solubility Product 12.9 The Common-Ion Effect 12.10 Predicting Precipitation 12.11 Selective Precipitation 12.12 Dissolving Precipitates 12.13 Complex Ion Formation 12.14 Qualitative Analysis 475 Chapter 12 AQUEOUS EQUILIBRIA 476 CHAPTER 12 AQUEOUS EQUILIBRIA Added base Added acid HA AϪ OHϪ H3Oϩ FIGURE 12.1 A solution can act as a buffer if it contains a weak acid, HA, which donates protons when a strong base is added, and the conjugate base, AϪ , which accepts protons when a strong acid is added. In the inset, for clarity water molecules are represented by the blue background. Source of Hϩ Sink for Hϩ FIGURE 12.2 A buffer solution contains a weak base that acts as a sink for the protons supplied by a strong acid and a weak acid that acts as a source of protons to supply to a strong base being added. The joint action of the source and sink keeps the pH constant when strong acid or base is added. The inset highlights the buffer action by representing the water molecules as a blue background. been added to a liter of the solution. Now suppose instead that the solution contains acetic acid to which sodium acetate has been added (the acetate ion, CH3CO2 Ϫ , is the conjugate base of CH3COOH). Because CH3CO2 Ϫ is a base, we can predict that adding acetate ions (as sodium acetate) to a solution of acetic acid will increase the pH of the solution. Similarly, suppose we have a solution of ammonia and add ammonium chloride to it. The NH4 ϩ ion acts as a weak acid in water; therefore, we can predict that adding ammonium ions (as ammonium chloride, for instance) to a solution of ammonia will lower the pH of the solution. As we shall see, such “mixed solutions”—solutions that contain a weak acid or a weak base and one of its salts—provide a means of stabilizing the pH of aqueous solutions such as blood plasma, seawater, detergents, sap, and reaction mixtures. 12.1 Buffer Action The most important type of mixed solution is a buffer, a solution in which the pH resists change when small amounts of strong acids or bases are added. Buffers are used to calibrate pH meters, to culture bacteria, and to control the pH of solutions in which chemical reactions are taking place. They are also administered intravenously to hospital patients. Human blood plasma is buffered to pH ϭ 7.4; the ocean is buffered to about pH ϭ 8.4 by a complex buffering process that depends on the presence of hydrogen carbonates and silicates. A buffer consists of an aqueous solution of a weak acid and its conjugate base supplied as a salt, or a weak base and its conjugate acid supplied as a salt. Examples are a solution of acetic acid and sodium acetate and a solution of ammonia and ammonium chloride. When a drop of strong acid is added to pure water, the pH changes significantly. However, when the same amount is added to a buffer, the pH hardly changes at all. To understand why not, consider the dynamic equilibrium between a weak acid and its conjugate base in water: CH3COOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CH3CO2 Ϫ (aq) To prepare a buffer that makes use of this equilibrium, we need a solution that consists of similar amounts of acid (CH3COOH) and its salt (NaCH3CO2). When a few drops of a strong acid are added to such a solution, the newly arrived H3Oϩ ions transfer protons to the CH3CO2 Ϫ ions to form CH3COOH and H2O molecules (Fig. 12.1). Because the added H3Oϩ ions are removed by the CH3CO2 Ϫ ions, the pH remains almost unchanged. In effect, the acetate ions act as a “sink” for protons. If a small amount of strong base is added instead, the incoming OHϪ ions remove protons from the CH3COOH molecules to produce CH3CO2 Ϫ ions and H2O molecules. In this case, the acetic acid molecules act as a source of protons. Because the added OHϪ ions are removed by the CH3COOH molecules, the concentration of OHϪ ions remains nearly unchanged. Consequently, the H3Oϩ concentration (and the pH) is also left nearly unchanged. Now consider the equilibrium NH3(aq) ϩ H2O(l) #¢4 NH4 ϩ (aq) ϩ OHϪ (aq) To prepare a buffer that makes use of this equilibrium, we prepare a solution that contains similar amounts of base (NH3) and its salt (NH4Cl). When a few drops of a solution of strong base are added to this solution, the incoming OHϪ ions remove protons from NH4 ϩ ions to form NH3 and H2O molecules. When instead a few drops of a strong acid are added, the incoming protons attach to NH3 molecules to make NH4 ϩ ions and hence are removed from the solution. In each case, the pH is left almost unchanged. Thinking point: Could an aqueous solution of glycine, Ϫ O2CCH2NH3 ϩ , which contains both acidic and basic groups, act as a buffer? A buffer is a mixture of a weak conjugate acid–base pair that stabilizes the pH of a solution by providing both a source and a sink for protons (Fig. 12.2). 12.2 Designing a Buffer Suppose we need to make up a buffer with a particular pH. For instance, we might be culturing bacteria and need to maintain a precise pH to sustain their metabolism. To choose the most appropriate buffer system, we need to know the value of the pH at which a given buffer stabilizes a solution. A mixture of a weak acid and its salt will act as a buffer at pH Ͻ 7 (the acidic side of neutrality) and is known as an acid buffer. A mixture of a weak base and its salt will act as a buffer at pH Ͼ 7 (the basic side of neutrality) and is known as a basic buffer. To find the precise pH at which a mixed solution of given composition will act as a buffer we carry out an equilibrium calculation very similar to those in Chapter 11, as shown in the following example. 12.2 DESIGNING A BUFFER 477 EXAMPLE 12.1 Calculating the pH of a buffer solution Suppose we are culturing bacteria that require an acid environment and want to prepare a buffer close to pH ϭ 4. We prepare a buffer solution that is 0.040 M NaCH3CO2(aq) and 0.080 M CH3COOH(aq) at 25°C. What is the pH of the solution? Anticipate If the weak acid were present alone, we would expect pH Ͻ 7. Because some conjugate base is also present, we should expect the pH to be slightly higher than the acidonly value but still less than 7. In Example 11. 7 we calculated pH ϭ 2.92 for the acid alone, so expect a pH higher than this value. PLAN First, identify the weak acid and its conjugate base. Then, write the proton transfer equilibrium between them and rearrange the expression for Ka to give [H3Oϩ ]. Finally, calculate the pH. What should we assume? That the extent of protonation of acetate ions and the deprotonation of acetic acid molecules is so small that the concentrations of both species are nearly the same as their initial values. SOLVE The acid is CH3COOH and its conjugate base is CH3CO2 Ϫ . The equilibrium to consider is CH3COOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CH3CO2 Ϫ (aq) From Table 11.1, pKa ϭ 4.75 and Ka ϭ 1.8 ϫ 10Ϫ5 . Find the equilibrium concentration of H3Oϩ ions from Ka ϭ [H3Oϩ ][CH3CO2 Ϫ ]͞ [CH3COOH]. [H3O+ ] = Ka * [CH3COOH] [CH3CO - 2 ] Approximate the conjugate acid and base concentrations by their initial values. [H3O+ ] L (1.8 * 10-5 ) * 0.080 0.040 14 7 1 pH BasicAcidic 4.44 2.92 From pH ϭ –log [H3Oϩ ], = 4.44 pH L -loge (1.8 * 10-5 ) * 0.080 0.040 f Evaluate As expected, the solution is less acidic than it would be if only the acid were present (pH ϭ 2.92) and acts as an acid buffer at pH 4. Self-Test 12.1A Calculate the pH of a buffer solution that is 0.15 M HNO2(aq) and 0.20 M NaNO2(aq). [Answer: 3.49] L Self-Test 12.1B Calculate the pH of a buffer solution that is 0.040 M NH4Cl(aq) and 0.030 M NH3(aq). The point of using a buffer is to stabilize a solution against changes in pH when a strong base or a strong acid is added. The next example shows how to calculate the effect of added acid or base on the pH of an acid buffer. 478 CHAPTER 12 AQUEOUS EQUILIBRIA EXAMPLE 12.2 Calculating the pH change of a buffered solution Suppose we dissolve 1.2 g of sodium hydroxide (0.030 mol NaOH) in 500. mL of the buffer solution described in Example 12.1. Calculate the pH of the resulting solution and the change in pH. Assume that the volume of the solution remains unchanged. Anticipate Because the buffer solution contains a weak acid that will react with the strong base, we should expect only a small change in the pH from the 4.44 of the initial solution. PLAN We solve this problem in two stages. First, we calculate the concentrations of acid and conjugate base by noting that the OHϪ ions added to the buffer solution react with some of the acid of the buffer system, decreasing the amount of acid and correspondingly increasing the amount of conjugate base. Then we rearrange the expression for Ka to obtain the pH of the solution, just as in Example 12.1. What should we assume? That the equilibrium concentrations of the acid and its conjugate base are nearly the same as their initial concentrations and that the neutralization reaction goes to completion. SOLVE The proton transfer equilibrium is CH3COOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ CH3CO2 Ϫ (aq) We use the data in Example 12.1, including Ka ϭ 1.8 ϫ 10Ϫ5 . The OHϪ from the added NaOH reacts with some of the CH3COOH according to CH3COOH(aq) ϩ OHϪ (aq) #¢4 CH3CO2 Ϫ (aq) ϩ H2O(l) Step 1 Find the new concentration of acid. Ka = [H3O+ ][CH3CO2 - ] [CH3COOH] 0.500 L =× 80. mmol·LϪ1 40. mmol Find the initial amount of CH3COOH in the solution from nJ ϭ V[J]. n(CH3COOH)initial ϭ (0.500 L) ϫ (0.080 molиLϪ1 ) ϭ 0.040 mol Calculate the amount of CH3COOH that reacts by using 1 mol CH3COOH ϴ 1 mol OHϪ . n(CH3COOH)reacts ϭ (0.030 mol OHϪ ) ϫ ϭ 0.030 mol CH3COOH 1 mol CH3COOH 1 mol OH- Ϫ 40. mmol 30. mmol 10. mmol Calculate the amount of CH3COOH remaining from nfinal ϭ ninitial Ϫ nreacts. n(CH3COOH)final ϭ 0.040 Ϫ 0.030 mol ϭ 0.010 mol Evaluate As expected, the pH of the solution changes only slightly, from about 4.4 to about 5.4. Self-Test 12.2A Suppose that 0.0200 mol NaOH(s) is dissolved in 300. mL of the buffer solution of Example 12.1. Calculate the pH of the resulting solution and the change in pH. [Answer: 5.65, an increase of 1.21] Self-Test 12.2B Suppose that 0.0100 mol HCl(g) is dissolved in 500. mL of the buffer solution of Example 12.1. Calculate the pH of the resulting solution and the change in pH. Buffers are often prepared with equal molar concentrations of the conjugate acid and base because then there are adequate supplies of the “source” and “sink” species that 12.2 DESIGNING A BUFFER 479 10. mmol 0.500 L = 20. mmol·LϪ1 From [J] ϭ nJ/V, [CH3COOH] ϭ Step 2 Find the new concentration of the conjugate base. = 0.020 molиL-1 0.010 mol 0.500 L 20. mmol 0.500 L = 40. mmol·LϪ1 × 50. mmol 0.500 L = 0.10 mol·LϪ1 Find the initial amount of CH3CO2 Ϫ in the solution from nJ ϭ V[J]. n(CH3CO2 Ϫ )initial ϭ (0.500 L) ϫ (0.040 molиLϪ1 ) ϭ 0.020 mol From [J] ϭ nJ/V, [CH3CO2 Ϫ ] ϭ Step 3 Calculate the pH. = 0.10 molиL-1 0.050 mol 0.500 L 14 7 1 pH BasicAcidic 5.44 4.44 From pH ϭ –log [H3Oϩ ], L 5.44 pH L -log(3.6 * 10-6 ) Calculate [H3Oϩ ] from [H3Oϩ ] ϭ Ka[CH3COOH]͞[CH3CO2 Ϫ ]. = 3.6 * 10-6 [H3O+ ] L (1.8 * 10-5 ) * 0.020 0.10 ϩ 50. mmol 20. mmol 30. mmol Add the change in the amount of CH3CO2 Ϫ due to the reaction. n(CH3CO2 Ϫ )final ϭ 0.020 ϩ 0.030 mol ϭ 0.050 mol can stabilize the solution against change in either direction. The pH of these “equimolar” solutions is very easy to predict. Consider the equilibrium HA(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ AϪ (aq) (A) The values of [HA] and [AϪ ] that appear in Ka are the equilibrium concentrations of acid and base in the solution, not the concentrations added initially. However, a weak acid HA typically loses only a tiny fraction of its protons, and so [HA] is negligibly different from the concentration of the acid used to prepare the buffer, [HA]initial. Likewise, only a tiny fraction of the weakly basic anions AϪ accept protons, and so [AϪ ] is negligibly different from the initial concentration of the base used to prepare the buffer, [AϪ ]initial. Because the two initial concentrations are the same, we can write It follows that when [HA]initial ϭ [AϪ ]initial, pH ϭ pKa (1)* This very simple result makes it easy to make an initial choice of a buffer: we just select an acid that has a pKa close to the pH that we require and prepare an equimolar solution with its conjugate base. When we prepare a buffer for pH Ͼ 7 we have to remember that the acid is supplied by the salt, that the conjugate base is the base itself, and that the pKa is that of the conjugate acid of the base (and hence related to the pKb of the base by pKa ϩ pKb ϭ pKw). Mixtures in which the conjugate acid and base have unequal concentrations— such as those considered in Examples 12.1 and 12.2—are buffers, but they may be less effective than those in which the concentrations are nearly equal (see Section 12.3). Table 12.1 lists some typical buffer systems. Self-Test 12.3A Which of the buffer systems listed in Table 12.1 would be a good choice to prepare a buffer with pH close to 5? [Answer: CH3COOH/CH3CO2 Ϫ ] Self-Test 12.3B Which of the buffer systems listed in Table 12.1 would be a good choice to prepare a buffer with pH close to 10? We can lower the pH of an acid buffer solution by adding some weak acid. To raise the pH of an acid buffer we need to add some more of the acid’s conjugate base by adding more salt. Alternatively, we could add some strong base (NaOH, for instance), to convert some of the acid to the salt. Commercially available buffer solutions can be purchased for virtually any desired pH. A buffer solution commonly used to calibrate pH meters contains 0.025 M Na2HPO4(aq) and 0.025 M KH2PO4(aq) and has pH ϭ 6.87 at 25°C. However, the method demonstrated in Example 12.1 would give pH ϭ 7.2 for this solution. Because our calculations interpret activities as molarities, not effective molarities, they ignore ion–ion interactions; so the values calculated are only approximate but are a reasonably good guide (and a good starting point for more elaborate calculations). Many chemical reactions in our bodies take place in buffered environments. Biochemists studying these reactions commonly need to make quick estimates of pH by employing a form of the expression for Ka that gives the pH directly for any composition of the mixture, not just an equimolar mixture. For the equilibrium in reaction A, we can rearrange the expression for Ka into from which it follows, by taking the negative logarithms of both sides, that pH pKa Ϫlog[H3Oϩ ] ϭ Ϫlog Ka - log [HA] [A- ] [H3O+ ] = Ka * [HA] [A- ] Ka L [H3O+ ][A- ]initial [HA]initial = [H3O+ ] Ka = [H3O+ ][A- ] [HA] 480 CHAPTER 12 AQUEOUS EQUILIBRIA TABLE 12.1 Typical Buffer Systems Composition pKa Acid buffers CH3COOH/CH3CO2 – 4.75 HNO2/NO2 – 3.37 HClO2/ClO2 – 2.00 Base buffers NH4 + /NH3 9.25 (CH3)3NH+ /(CH3)3N 9.81 H2PO4 – /HPO4 2– 7.21 $++%++& $+%+& Then, from log x ϭ –log(1/x), As we have discussed, [HA] can be approximated by [HA]initial (which we shall write [acid]initial) and [AϪ ] by [AϪ ]initial (which we shall write [base]initial); the result is the Henderson–Hasselbalch equation: (2)* For an acetic acid/acetate buffer the expression takes the form Equation 2 can also be used for a basic buffer, with pKa that of the conjugate acid of the base. For example, in the case of an ammonia buffer, we would use the pKa of NH4 ϩ and identify “base” with NH3 and “acid” with NH4 ϩ . If only pKb is available, we calculate pKa by using Eq. 11b of Chapter 11 (pKa ϩ pKb ϭ pKw). Therefore, for an ammonia/ammonium buffer we would write A note on good practice: Keep in mind the approximations required for the use of the Henderson–Hasselbalch equation (that the concentrations of both the weak acid and its conjugate base are much greater than the hydronium ion concentration). Because the equation uses molar concentration instead of activities, it also ignores the interactions between ions and the numerical values it predicts must be treated with caution. In practice, the Henderson–Hasselbalch equation is used to make rapid estimates of the pH of a mixed solution intended to be used as a buffer, and then the pH is adjusted to the precise value required by adding more acid or base and monitoring the solution with a pH meter. pH = pKa(NH4 + ) + log [NH3]initial [NH4 + ]initial pH = pKa + log [CH3CO2 - ]initial [CH3COOH]initial pH = pKa + log [base]initial [acid]initial pH = pKa - log [HA] [A- ] = pKa + log [A- ] [HA] 12.2 DESIGNING A BUFFER 481 EXAMPLE 12.3 Selecting the composition for a buffer solution with a given pH Calculate the ratio of the molarities of CO3 2Ϫ and HCO3 Ϫ ions required to achieve buffering at pH ϭ 9.50. The pKa2 of H2CO3 is 10.25. Anticipate Because the desired pH is lower than the pKa2 of H2CO3, we need the logarithm to be negative. That will be the case when the ratio of concentrations is less than 1. PLAN Rearrange the Henderson–Hasselbalch equation to solve for the ratio of the weak acid to its conjugate base. What should we assume? As usual, we assume that activities can be approximated by molarities. As we have already illustrated, we also begin by assuming that the equilibrium concentrations of acid and its conjugate base can be approximated by their initial values. SOLVE In the equilibrium HCO3 Ϫ ϩ H2O(l) #4 H3Oϩ (aq) ϩ CO3 2Ϫ , the acid is HCO3 Ϫ and its conjugate base is CO3 2Ϫ . From Section 11.16, we know that we can ignore any H2CO3 formed. From pH ϭ pKa ϩ log([base]initial͞[acid]initial), log [base] [acid] = pH - pKa Evaluate The solution acts as a buffer with a pH close to 9.50 if it is prepared by mixing the solutes in the ratio 0.18 mol CO3 2Ϫ to 1.0 mol HCO3 Ϫ . As expected, the ratio of concentrations is less than 1. Self-Test 12.4A Calculate the ratio of the molarities of acetate ions and acetic acid needed to buffer a solution at pH ϭ 5.25. The pKa of CH3COOH is 4.75. [Answer: 3.2:1] Self-Test 12.4B Calculate the ratio of the molarities of benzoate ions and benzoic acid (C6H5COOH) needed to buffer a solution at pH ϭ 3.50. The pKa of C6H5COOH is 4.19. The pH of a buffer solution is close to the pKa of the weak acid component when the acid and base have similar concentrations. 12.3 Buffer Capacity Just as a sponge can hold only so much water, a buffer can mop up only so many hydronium ions. Its proton sources and sinks become exhausted if too much strong acid or base is added to the solution. Buffer capacity is the maximum amount of acid or base that can be added before the buffer loses its ability to resist large changes in pH. A buffer with a high capacity is able to maintain its buffering action against the addition of strong acid or base better than can one with only a small capacity. The buffer is exhausted when most of the weak base has been converted into its conjugate acid or when most of the weak acid has been converted into its conjugate base. A concentrated buffer solution has a greater capacity than the same volume of a more dilute solution of the same buffer. Buffer capacity also depends on the relative concentrations of weak acid and base. Broadly speaking, a buffer is found experimentally to have a high capacity for stabilizing against the addition of acid when the amount of weak base present is at least 10% of the amount of weak acid. Otherwise, the weak base is used up quickly as strong acid is added. Similarly, a buffer has a high capacity for stabilizing against the addition of base when the amount of weak acid present is at least 10% of the amount of weak base, because otherwise the weak acid is used up quickly as strong base is added. We can use these percentages to express the range of buffer action in terms of the pH of the solution. The Henderson–Hasselbalch equation shows us that, when the acid is 10 times as abundant as the base ([acid] ϭ 10[base]), the pH of the solution is (3a) Likewise, when the base is 10 times as abundant as the acid ([base] ϭ 10[acid]), the pH is (3b) We see that the experimentally determined concentration range converts into a pH range of Ϯ1. That is, the buffer acts most effectively when the pH is within a range of Ϯ1 unit of pKa (Fig. 12.3). For instance, because the pKa of H2PO4 Ϫ is 7.21, a pH = pKa + log 10[acid] [acid] = pKa + log 10 = pKa + 1 pH = pKa + log [base] 10[base] = pKa + log 1 10 = pKa - 1 482 CHAPTER 12 AQUEOUS EQUILIBRIA 0 Volume of base added 2 4 6 8 10 12 14 pH S pKa+1 pKa pKa−1 FIGURE 12.3 This plot shows how the pH of a weak acid changes as a strong base is added. When the conjugate acid and base are present at similar concentrations the curve is nearly horizontal, showing that the pH changes very little as more strong base or strong acid is added. As the inset shows, the pH lies between pKa Ϯ 1 across the buffer region. S denotes the stoichiometric point (Section L). Use the initial concentration of CO3 2Ϫ for the base and that of HCO3 Ϫ for the acid and substitute the values of pH and pKa. log [CO3 2- ] [HCO3 - ] = 9.50 - 10.25 = -0.75 10.25 0.18 1 [Base]/[Acid] 9.50 pH Now use x ϭ 10log x : = 0.18 [CO3 2- ] [HCO3 - ] = 10-0.75 KH2PO4/K2HPO4 buffer can be expected to be most effective between about pH ϭ 6.2 and pH ϭ 8.2. The composition of blood plasma, in which the concentration of HCO3 Ϫ ions is about 20 times that of H2CO3, seems to be outside the range for optimum buffering. However, the principal waste products of living cells are carboxylic acids, such as lactic acid. Plasma, with its relatively high concentration of HCO3 Ϫ ions, can absorb a significant surge of hydrogen ions from these carboxylic acids. The high proportion of HCO3 Ϫ also helps us to withstand disturbances that lead to excess acid, such as disease and shock due to burns (Box 12.1). The capacity of a buffer is determined by its concentration and pH. A more concentrated buffer can react with more added acid or base than can a less concentrated one. A buffer solution is generally most effective when the pH is in the range pKa ؎ 1. TITRATIONS As we saw in Section L, titration involves the addition of a solution, called the titrant, from a buret to a flask containing a sample called the analyte. For example, if an environmental chemist is monitoring acid mine drainage and needs to know the concentration of acid in the water, a sample of the effluent from the mine would be the analyte and a solution of base of known concentration would be the titrant. At the stoichiometric point, the amount of OHϪ (or H3Oϩ ) added as titrant is equal to the amount of H3Oϩ (or OHϪ ) initially present in the analyte. We use the techniques in this chapter to identify the roles of different species in determining the pH of the analyte solution at any stage of a titration and to select the appropriate indicator for the titration. 12.4 Strong Acid–Strong Base Titrations When a strong acid is mixed with a strong base in water, a neutralization reaction occurs for which the net ionic equation is H3Oϩ (aq) ϩ OHϪ (aq) 2 H2O(l) However, it is best to use the full chemical equation when working with titrations to ensure the correct stoichiometry. For example, if hydrochloric acid is used to neutralize Ca(OH)2, we must take into account the fact that each formula unit of Ca(OH)2 provides two OHϪ ions: 2 HCl(aq) ϩ Ca(OH)2(aq) CaCl2(aq) ϩ 2 H2O(l) A plot of the pH of the analyte solution against the volume of titrant added during a titration is called a pH curve. The shape of the pH curve in Fig. 12.4 is typical of titrations in which a strong acid is added to a strong base. Initially, the pH falls slowly. Then, at the stoichiometric point, there is a sudden decrease in pH through 7. At this point, an indicator changes color or an automatic titrator responds electronically to the sudden change in pH. Titrations typically end at this point. However, if we were to continue the titration, we would find that the pH falls slowly toward the value of the acid itself as the dilution due to the original analyte solution becomes less and less important. Figure 12.5 shows a pH curve for a titration in which the analyte is a strong acid and the titrant is a strong base. This curve is the mirror image of the curve for the titration of a strong base with a strong acid. ¡ ¡ 12.4 STRONG ACID–STRONG BASE TITRATIONS 483 A B C D S E 0 2 4 6 8 10 12 14 0 10 20 30 Volume of acid added (mL) pH Strongacid Strong base FIGURE 12.4 The variation of pH during the titration of a strong base, 25.00 mL of 0.250 M NaOH(aq), with a strong acid, 0.340 M HCl(aq). The stoichiometric point (S) occurs at pH ϭ 7. The other points on the pH curve are explained in Example 12.4 in the text. S 0 2 4 6 8 10 12 14 0 10 20 30 Volume of base added (mL) pH Strongbase Strong acid FIGURE 12.5 The variation of pH during a typical titration of a strong acid (the analyte) with a strong base (the titrant). The stoichiometric point (S) occurs at pH ϭ 7. 484 CHAPTER 12 AQUEOUS EQUILIBRIA Physiological Buffers Buffer systems are so vital to the existence of living organisms that the most immediate threat to the survival of a person with severe injury or burns is a change in blood pH. One of a paramedic’s first steps in saving a life is to administer intravenous fluids. Metabolic processes normally maintain the pH of human blood within a narrow range (7.35–7.45). To control blood pH, the body uses primarily the carbonic acid/hydrogen carbonate (bicarbonate) ion system. The normal ratio of HCO3 – to H2CO3 in the blood is 20:1, with most of the carbonic acid in the form of dissolved CO2. When the concentration of HCO3 – increases further relative to that of H2CO3, blood pH rises. If the pH rises above the normal range, the condition is called alkalosis. Conversely, blood pH decreases when the ratio decreases; and when blood pH falls below the normal range, the condition is called acidosis. Because these conditions are life threatening and death can result within minutes, it is critical that the cause of the pH imbalance be identified and treated quickly. WHAT HAS THIS TO DO WITH . . . STAYING ALIVE?BOX 12.1 In many cases of asthma, chemicals can facilitate respiration by opening constricted bronchial passages. Metabolic acidosis is caused by the release into the bloodstream of excessive amounts of lactic acid and other acidic by-products of metabolism. These acids enter the bloodstream, react with hydrogen carbonate ion to produce H2CO3, and shift the ratio HCO3 – /H2CO3 to a lower value. Heavy exercise, diabetes, and fasting can all produce metabolic acidosis. The normal response of the body is to increase the rate of breathing to eliminate some of the CO2. Thus, we pant heavily when running uphill. Metabolic acidosis can also result when a person is severely burned. Blood plasma leaks from the circulatory system into the injured area, producing edema (swelling) and reducing the blood volume. If the burned area is large, this loss of blood volume may be sufficient to reduce blood flow and oxygen supply to all the body’s tissues. Lack of oxygen, in turn, causes the tissues to produce an excessive amount of lactic acid and leads to metabolic acidosis. To minimize the decrease in pH, the injured person breathes harder to eliminate the excess CO2. However, if blood volume drops below levels for which the body can compensate, a vicious circle ensues in which blood flow decreases still further, blood pressure falls, CO2 excretion diminishes, and acidosis becomes more severe. People in this state are said to be in shock and will die if not treated promptly. The dangers of shock are avoided or treated by intravenous infusion of large volumes of a salt-containing solution that is isotonic with blood (has the same osmotic pressure as blood), usually one known as lactated Ringer’s solution. The added liquid increases blood volume and blood flow, thereby improving oxygen delivery. The [HCO3 – ]/[H2CO3] ratio then increases toward normal and allows the severely injured person to survive. Respiratory alkalosis is the rise in pH associated with excessive respiration. Hyperventilation, which can result from anxiety or high fever, is a common cause. The body may control blood pH during hyperventilation by fainting, which results in slower respiration. An intervention that may prevent fainting is to have a hyperventilating person breathe into a paper bag, which allows much of the respired CO2 to be taken up again. Metabolic alkalosis is the increase in pH resulting from illness or chemical ingestion. Repeated vomiting or the overuse of diuretics can cause metabolic alkalosis. Once again the body compensates, this time by decreasing the rate of respiration. Related Exercises: 12.101 and 12.102 For Further Reading: J. C. Charles and R. L. Heilman, “Metabolic acidosis,” Hospital Physician, March 2005, pp. 37–42. J. Squires, “Artificial blood,” Science, vol. 295, Feb. 8, 2002, pp. 1002–1005. Lynn Taylor and Norman P. Curthoys, “Glutamine metabolism: Role in Acid–Base Balance,” Biochemistry and Molecular Biology Education, vol. 32, no. 5, 2004, pp. 291–304. This box includes contributions from B. A. Pruitt, M.D., and A. D. Mason, M.D., U.S. Army Institute of Surgical Research. Patients who have suffered traumatic injuries must receive an immediate intravenous solution to combat the symptoms of shock and help maintain the pH of blood. The body maintains blood pH by two primary mechanisms: respiration and excretion. Carbonic acid concentration is controlled by respiration: as we exhale, we deplete our system of CO2 and hence deplete it of H2CO3, too. This decrease in acid concentration raises the blood pH. Breathing faster and more deeply increases the amount of CO2 exhaled and hence decreases the carbonic acid concentration in the blood, which in turn raises the blood pH. Hydrogen carbonate ion concentration is controlled by its rate of excretion in urine. Respiratory acidosis results when decreased respiration raises the concentration of CO2 in the blood. Asthma, pneumonia, emphysema, or inhaling smoke can all cause respiratory acidosis. So can any condition that reduces a person’s ability to breathe. Respiratory acidosis is usually treated with a mechanical ventilator, to assist the victim’s breathing. The improved exhalation increases the excretion of CO2 and raises blood pH. EXAMPLE 12.4 Calculating points on the pH curve for a strong acid–strong base titration Suppose we are carrying out a titration in which the analyte initially consists of 25.00 mL of 0.250 M NaOH(aq) and the titrant is 0.340 M HCl(aq). Calculate (a) the pH of the original analyte solution and (b) the new pH after the addition of 5.00 mL of the acid titrant. Anticipate We should expect the pH to decrease slightly from its initial value as acid is added. PLAN For part (a) determine the pOH of the solution and convert it to the pH. For part (b) follow the procedure outlined in Toolbox 12.1. What should we assume? That there is so much acid or base present that the autoprotolysis of water does not contribute to the pH. SOLVE (a) Initially, the pOH of the analyte is pOH ϭ –log 0.250 ϭ 0.602, and so the pH of the solution is pH ϭ 14.00 Ϫ 0.602 ϭ 13.40. This is point A in Fig. 12.4. (b) We now follow the procedure in Toolbox 12.1. 12.4 STRONG ACID–STRONG BASE TITRATIONS 485 TOOLBOX 12.1 HOW TO CALCULATE THE pH DURING A STRONG ACID–STRONG BASE TITRATION CONCEPTUAL BASIS The variation of pH during the titration of a strong acid with a strong base is governed by the major species in solution. Because the conjugate base of the strong acid has little effect on the pH, the pH is determined by whichever is in excess, the strong acid or the strong base. PROCEDURE First, use the reaction stoichiometry to find the amount of excess acid or base. Step 1 Calculate the amount of H3Oϩ ions (if the analyte is a strong acid) or OHϪ ions (if the analyte is a strong base) in the original analyte solution from the product of the analyte’s molarity and its volume. Use nJ ϭ V[J], where J is H3Oϩ or OHϪ . Step 2 Calculate the amount of OHϪ ions (if the titrant is a strong base) or H3Oϩ ions (if the titrant is a strong acid) in the volume of titrant added from the product of the titrant’s molarity and its volume. Use nJ ϭ V[J], where J is OHϪ or H3Oϩ . Step 3 Write the chemical equation for the neutralization reaction and use the reaction stoichiometry to find the amount of H3Oϩ ions (or OHϪ ions if the analyte is a strong base) that remains in the analyte solution after all the added titrant reacts. Then subtract from the initial amount the amount of H3Oϩ or OHϪ ions that has reacted. Next, determine the concentration. Step 4 Use the remaining amount of H3Oϩ (or OHϪ ) and the total volume of the combined solutions, V ϭ Vanalyte ϩ Vtitrant, to find the molarity of the H3Oϩ (or OHϪ ) ions in the solution from [J] ϭ nJ/V. Finally, calculate the pH. Step 5 If acid is in excess, take the negative logarithm of the H3Oϩ molarity to find the pH. If base is in excess, find the pOH, and then convert pOH into pH by using the relation pH ϩ pOH ϭ pKw. This procedure is illustrated in Example 12.4. 6.25 mmol OH Ϫ Step 1 Find the amount of OHϪ ions initially present from nJ ϭ V[J]. n(OHϪ ) ϭ (25.00 ϫ 10Ϫ3 L) ϫ (0.250 mol·LϪ1 ) ϭ 6.25 ϫ 10Ϫ3 mol ϭ 6.25 mmol 1.70 mmol H3 O ϩ Step 2 Find the amount of H3Oϩ ions supplied by the titrant from nJ ϭ V[J]. n(H3Oϩ ) ϭ (5.00 ϫ 10Ϫ3 L) ϫ (0.340 molиLϪ1 ) ϭ 1.70 ϫ 10Ϫ3 mol ϭ 1.70 mmol This is point B in Fig. 12.4. Evaluate Note that the pH has fallen, as expected, but only by a very small amount. This small change is consistent with the shallow slope of the pH curve at the start of the titration. Self-Test 12.5A What is the pH of the solution that results from the addition of a further 5.00 mL of the HCl(aq) titrant to the analyte? [Answer: 12.91, point C] Self-Test 12.5B What is the pH of the solution that results from the addition of yet another 2.00 mL of titrant to the analyte? Experimentally, we know that the pH changes abruptly close to the stoichiometric point. Suppose we reach the stoichiometric point in the titration described in Example 12.4 and then add an additional 1.00 mL of HCl(aq). To find out by how much the pH changes, we work through the steps in Toolbox 12.1 as in Example 12.4, except that now the acid is in excess. We find that, after the addition, the pH has fallen to 2.1 (point D in Fig. 12.4). This point is well below the pH (of 7) at the stoichiometric point, although only 1 mL more acid has been added. In the titration of a strong acid with a strong base or of a strong base with a strong acid, the pH changes slowly initially, changes rapidly through pH ‫؍‬ 7 at the stoichiometric point, and then changes slowly again. 12.5 Strong Acid–Weak Base and Weak Acid–Strong Base Titrations In many titrations, one solution—either the analyte or the titrant—contains a weak acid or base and the other solution contains a strong base or acid. For example, if we want to know the concentration of formic acid, the weak acid found in ant venom (1), we can titrate it with sodium hydroxide, a strong base. Alternatively, to find the concentration of ammonia, a weak base, we titrate it with hydrochloric acid, a strong acid. Weak acids are not normally titrated with weak bases, because the stoichiometric point is too difficult to locate. 486 CHAPTER 12 AQUEOUS EQUILIBRIA Step 3 Write the balanced equation for the neutralization reaction. HCl(aq) ϩ NaOH(aq) NaCl(aq) ϩ H2O(l)¡ Step 4 Find the concentration of OHϪ ions from the total volume of the solution and [J] ϭ nJ/V. [OH] = 4.55 * 10-3 mol (25.00 + 5.00) * 10-3 L = 0.152 molиL-1 4.55 mmol OH Ϫ Find the amount of OHϪ remaining from 1 mol NaOH ϴ 1 mol HCl, after reaction of all the added H3Oϩ ions. n(OHϪ )final ϭ 6.25 Ϫ 1.70 mmol ϭ 4.55 mmol 14 7 1 pH BasicAcidic 13.18 13.40Step 5 Calculate the pH from pOH ϭ Ϫlog [OHϪ ] and then pH ϭ pKw Ϫ pOH. pOH ϭ Ϫlog(0.152) ϭ 0.82, pH ϭ 14.00 Ϫ 0.82 ϭ 13.18 1 Formic acid Figures 12.6 and 12.7 show the different pH curves that are found experimentally for these two types of titrations. Notice that the stoichiometric point does not occur at pH ϭ 7. Moreover, although the pH changes reasonably sharply near the stoichiometric point, it does not change as abruptly as it does in a strong acid–strong base titration. The pH at the stoichiometric point depends on the type of salt produced in the neutralization reaction. In the titration of formic acid, HCOOH, with sodium hydroxide the following reaction takes place: HCOOH(aq) ϩ NaOH(aq) NaHCO2(aq) ϩ H2O(l) At the stoichiometric point the solution consists of sodium formate, NaHCO2, and water. Because Naϩ ions have virtually no effect on pH and the formate ion, HCO2 Ϫ (2), is a base, overall the solution is basic and pH Ͼ 7. The same is true for the stoichiometric point of the titration of any weak acid with strong base. At the stoichiometric point of the titration of aqueous ammonia with hydrochloric acid, the solute is ammonium chloride. Because ClϪ ions have virtually no effect on the pH and NH4 ϩ is an acid, we expect pH Ͻ 7. The same is true for the stoichiometric point of the titration of any weak base with strong acid. ¡ 12.5 STRONG ACID–WEAK BASE AND WEAK ACID–STRONG BASE TITRATIONS 487 S 0 2 4 6 8 10 12 14 0 10 20 30 Volume of acid added (mL) pH Strongacid Weak base FIGURE 12.7 A typical pH curve for the titration of a weak base with a strong acid. The stoichiometric point (S) occurs at pH Ͻ 7 because the salt formed by the neutralization reaction has an acidic cation. S A 0 2 4 6 8 10 12 14 0 10 20 30 Volume of base added (mL) pH Strongbase Weak acid B C D FIGURE 12.6 The pH curve for the titration of a weak acid with a strong base: 25.00 mL of 0.100 M HCOOH(aq) with 0.150 M NaOH(aq). The stoichiometric point (S) occurs at pH Ͼ 7 because the anion HCO2 Ϫ is a base. The other points on the curve are explained in the text and in Example 12.6. 2 Formate ion Ϫ EXAMPLE 12.5 Estimating the pH at the stoichiometric point of the titration of a weak acid with a strong base Estimate the pH at the stoichiometric point of the titration of 25.00 mL of 0.100 M HCOOH(aq) with 0.150 M NaOH(aq). Anticipate Decide whether the salt present at the stoichiometric point provides an ion that acts as a weak base or as a weak acid. If the former, expect pH Ͼ 7; if the latter, expect pH Ͻ 7. In this case, the anion of the salt is basic, so we should expect pH Ͼ 7. PLAN To calculate the pH at the stoichiometric point, proceed as in Example 11.10 or 11.11, noting that the amount of salt at the stoichiometric point is equal to the initial amount of acid and the volume is the total volume of the combined analyte and titrant solutions. The Kb of a weak base is related to the Ka of its conjugate acid by Ka ϫ Kb ϭ Kw; Ka is listed in Table 11.1. What should we assume? That the autoprotolysis of water has no significant effect on the pH. SOLVE The salt present at the stoichiometric point, sodium formate, provides basic formate ions, and so we expect pH Ͼ 7. From Table 11.1, Ka ϭ 1.8 ϫ 10Ϫ4 for formic acid; therefore, Kb ϭ Kw/Ka ϭ 5.6 ϫ 10Ϫ11 . 488 CHAPTER 12 AQUEOUS EQUILIBRIA 2.50 mmol OH Ϫ Find the initial amount of HCOOH in the analyte from nJ ϭ V[J] n(HCOOH) ϭ (2.500 ϫ 10Ϫ2 L) ϫ (0.100 molиLϪ1 ) ϭ 2.50 ϫ 10Ϫ3 mol, or 2.50 mmol The amount of HCO2 Ϫ in the solution at the stoichiometric point is the same as the amount of OHϪ added. n(HCO2 Ϫ ) ϭ 2.50 mmol 2.50 mmol H3 O ϩ 16.7 mL Find the volume of titrant containing this amount of OHϪ ions, from V ϭ nJ/[J]. = 1.67 * 10-2 L or 16.7 mL Vadded = 2.50 * 10-3 mol 0.150 molиL-1 2.50 mmol HCO2 Ϫ 41.7 mL Find the total volume of the solution at the stoichiometric point from Vfinal ϭ Vinitial ϩ Vadded. Vfinal ϭ 25.00 ϩ 16.7 mL ϭ 41.7 mL Find the concentration of HCO2 Ϫ ions at the stoichiometric point from [J] ϭ nJ/V. [HCO2 ] = 2.50 * 10-3 mol 4.17 * 10-2 L = 0.0600 molиL-1 Find the amount of OHϪ required to react with the HCOOH from the reaction stoichiometry, 1 mol OHϪ ϴ 1 mol HCOOH. n(OHϪ ) ϭ (2.50 ϫ 10Ϫ3 mol HCOOH) ϫ ϭ 2.50 ϫ 10Ϫ3 mol OHϪ (or 2.50 mmol OHϪ ) 1 mol OH- 1 mol HCOOH Now that we know the composition of the solution at the stoichiometric point, we can calculate the pH of the solution as described in Toolbox 11.2. The equilibrium to consider is HCO2 Ϫ (aq) ϩ H2O(l) #¢4 HCOOH(aq) ϩ OHϪ (aq) The equilibrium table, with all concentrations in moles per liter, is HCO2 Ϫ HCOOH OHϪ Step 1 Initial molarity 0.0600 0 0 Step 2 Change in molarity Ϫx ϩx ϩx Step 3 Equilibrium molarity 0.0600 Ϫ x x x Kb = [HCOOH][OH- ] [HCO2 - ] It follows from step 3 that the concentration of OHϪ is 1.8 ␮molиLϪ1 , which is about 18 times as great as the concentration of OHϪ ions from the autoprotolysis of water (0.10 ␮molиLϪ1 ), and so ignoring the latter is reasonable. Now we can write pOH ϭ Ϫlog(1.8 ϫ 10Ϫ6 ) ϭ 5.74 and therefore, 12.5 STRONG ACID–WEAK BASE AND WEAK ACID–STRONG BASE TITRATIONS 489 14 7 1 pH BasicAcidic 8.26 From pH ϩ pOH ϭ pKw, pH ϭ 14.00 Ϫ 5.74 ϭ 8.26 or about 8.3 Step 4 From Kb ϭ [HCOOH][OHϪ ]/[HCO2 Ϫ ], 5.6 * 10-11 = x * x 0.0600 - x Provided x ϽϽ 0.0600, the approximate form of this expression is: 5.6 * 10-11 L x2 0.0600 The solution is: x (5.6 ϫ 10Ϫ11 ϫ 0.0600)1/2 ϭ 1.8 ϫ 10Ϫ6 L Evaluate At the stoichiometric point, pH Ͼ 7 as we expected. Self-Test 12.6A Calculate the pH at the stoichiometric point of the titration of 25.00 mL of 0.010 M HClO(aq) with 0.020 M KOH(aq). See Table 11.1 for Ka. [Answer: 9.67] Self-Test 12.6B Calculate the pH at the stoichiometric point of the titration of 25.00 mL of 0.020 M NH3(aq) with 0.015 M HCl(aq). (For NH4 ϩ , Ka ϭ 5.6 ϫ 10Ϫ10 .) Now consider the overall shape of the pH curve. The slow change in pH about halfway to the stoichiometric point indicates that the solution acts as a buffer in that region (see Fig. 12.3). At the halfway point of the titration, [HA] ϭ [AϪ ] and pH ϭ pKa. In fact, one way to prepare a buffer is to neutralize half the amount of weak acid present with strong base. The flatness of the curve near pH ϭ pKa illustrates very clearly the ability of a buffer solution to stabilize the pH of the solution. Moreover, we can now see how to determine pKa: plot the pH curve during a titration, identify the pH halfway to the stoichiometric point, and set pKa equal to that pH (Fig. 12.8). To obtain the pKb of a weak base, we find pKa in the same way but then find pKb from pKa ϩ pKb ϭ pKw. The values recorded in Tables 11.1 and 11.2 were obtained in this way. Well after the stoichiometric point in the titration of a weak acid with a strong base, the pH depends only on the concentration of excess strong base. For example, suppose we went on to add several liters of strong base from a giant buret. The presence of salt produced by the neutralization reaction would be negligible relative to the concentration of excess base. The pH would be that of the nearly pure titrant (the original base solution). We have already seen how to estimate the pH of the initial analyte when only weak acid or weak base is present (point A in Fig. 12.6, for instance), as well as the pH at the stoichiometric point (point S). Between these two points lie points corresponding to a mixed solution of some weak acid (or base) and some salt. We can therefore use the techniques described in Toolbox 12.2 and Example 12.6 to account for the shape of the curve. S 7 Volume of base added pH Strongbase Weak acid pKa of weak acid pH of solution of weak acid pH of salt solution pH of titrant (strong base) Stoichiometricpoints Halfwaytostoichiometricpoint FIGURE 12.8 The pKa of an acid can be determined by carrying out a titration of the weak acid with a strong base and locating the pH of the solution after the addition of half the volume of base needed to reach the stoichiometric point. The pH at that point is equal to the pKa of the acid. TOOLBOX 12.2 HOW TO CALCULATE THE pH DURING A TITRATION OF A WEAK ACID OR A WEAK BASE CONCEPTUAL BASIS The pH is governed by the major solute species present in solution. As strong base is added to a solution of a weak acid, a salt of the conjugate base of the weak acid is formed. This salt affects the pH and needs to be taken into account, as in a buffer solution. Table 12.2 outlines the regions encountered during a titration and the primary equilibrium to consider in each region. PROCEDURE The procedure is like that in Toolbox 12.1, except that an additional step is required to calculate the pH from the proton transfer equilibrium. Use the reaction stoichiometry to find the amount of excess acid or base. Begin by writing the chemical equation for the reaction, then: Step 1 Calculate the amount of weak acid or base in the original analyte solution. Use nJ ϭ Vanalyte[J]. Step 2 Calculate the amount of OHϪ ions (or H3Oϩ ions if the titrant is an acid) in the volume of titrant added. Use nJ ϭ Vtitrant[J]. Step 3 Use the reaction stoichiometry to calculate the following amounts: • Weak acid/strong base titration: the amount of conjugate base formed in the neutralization reaction, and the amount of weak acid remaining. • Weak base/strong acid titration: the amount of conjugate acid formed in the neutralization reaction, and the amount of weak base remaining. Determine the concentration. Step 4 Find the “initial” molarities of the conjugate acid and base in solution after neutralization, but before any reaction with water is taken into account. Use [J] ϭ nJ/V, where V is the total volume of the solution, V ϭ Vanalyte ϩ Vtitrant. Determine the pH. Step 5 Use an equilibrium table to find the H3Oϩ concentration in a weak acid or the OHϪ concentration in a weak base. Alternatively, if the concentrations of conjugate acid and base calculated in step 4 are both large relative to the concentration of hydronium ions, use them in the expression for Ka or the Henderson–Hasselbalch equation to determine the pH. In each case, if the pH is less than 6 or greater than 8, assume that the autoprotolysis of water does not significantly affect the pH. If necessary, convert between Ka and Kb by using Kw ϭ Ka ϫ Kb. This procedure is illustrated in Example 12.6. TABLE 12.2 Summary of Weak Acid and Weak Base Titration Equilibria Point in titration Primary species Proton transfer equilibrium Related Toolbox 1 Weak acid HA titrated with strong base initial HA HA(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ AϪ (aq) 11.1 buffer region HA, A– HA(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ A– (aq) 12.2 stoichiometric point* AϪ AϪ (aq) ϩ H2O(l) #¢4 HA(aq) ϩ OH– (aq) 11.2 2 Weak base B titrated with strong acid initial B B(aq) ϩ H2O(l) #¢4 HBϩ (aq) ϩ OH– (aq) 11.2 buffer region B, HBϩ B(aq) ϩ H2O(l) #¢4 HBϩ (aq) ϩ OH– (aq) 12.2 stoichiometric point† HBϩ HBϩ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ B(aq) 11.1 *This is a solution of a salt with a basic anion. † This is a solution of a salt with an acidic cation. 12.5 STRONG ACID–WEAK BASE AND WEAK ACID–STRONG BASE TITRATIONS 491 EXAMPLE 12.6 Calculating the pH before the stoichiometric point in a weak acid–strong base titration Calculate the pH of (a) 0.100 M HCOOH(aq) and (b) the solution resulting when 5.00 mL of 0.150 M NaOH(aq) is added to 25.00 mL of the acid. Use Ka ϭ 1.8 ϫ 10Ϫ4 for HCOOH. Anticipate When the strong base is added, some of the weak acid is neutralized, so we expect the pH to rise from (a) to (b). PLAN For (a) we use the procedure in Toolbox 11.1. For (b) we find the pH using the procedure in Toolbox 12.2. What should we assume? That the autoprotolysis of water does not contribute significantly to the pH; also, the weak acid formic acid undergoes only a small degree of deprotonation. SOLVE 14 7 1 pH BasicAcidic 2.37 (a) From [H3Oϩ ] ϭ (Ka[HA])1/2 and pH ϭ Ϫlog [H3Oϩ ], pH ϭ Ϫlog (1.8 ϫ 10–4 ϫ 0.100)1/2 ϭ 2.37 2.50 mmol HCOOH Step 1 Find the initial amount of HCOOH from nJ ϭ V[J]. n(HCOOH) ϭ (2.500 ϫ 10Ϫ2 L) ϫ (0.100 molиLϪ1 ) ϭ 2.50 ϫ 10Ϫ3 mol (2.50 mmol) 0.750 mmol OH Ϫ 5.00 mL Step 2 Find the amount of OH– added from nJ ϭ V[J] n(OHϪ ) ϭ (5.00 ϫ 10Ϫ3 L) ϫ (0.150 molиLϪ1 ) ϭ 7.50 ϫ 10Ϫ4 mol (0.750 mmol) 0.750 mmol HCO2 Ϫ 1.75 mmol HCOOH 30.00 mL Step 3 Find the amounts of HCOOH and HCO2 – after neutralization from 1 mol OH– ϴ 1 mol HCOOH and 1 mol OH– ϴ 1 mol HCO2 – . 0.750 mmol OHϪ produces 0.750 mmol HCO2 Ϫ and leaves 2.50 Ϫ 0.750 mmol ϭ 1.75 mmol HCOOH (b) The chemical equation is HCOOH(aq) ϩ H2O(l) #4 H3Oϩ (aq) ϩ HCO2 – (aq). Step 4 Find the concentrations of acid and conjugate base from [J] ϭ nJ/V, where the total volume is V ϭ Vanalyte ϩ Vtitrant. [HCO2 ] = 7.50 * 10-4 mol (25.00 + 5.00) * 10-3 L = 0.0250 molиL-1 [HCOOH] = 1.75 * 10-3 mol (25.00 + 5.00) * 10-3 L = 0.0583 molиL-1 Step 5 Now we evaluate the pH. The proton transfer equilibrium for HCOOH in water is HCOOH(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ HCO2 – (aq) From Table 11.1, the pKa for formic acid is 3.75. Assuming little change in the concentrations of acid and base due to the deprotonation of HCOOH, we write 492 CHAPTER 12 AQUEOUS EQUILIBRIA 14 7 1 pH BasicAcidic 3.38 From pH ϭ pKa ϩ log ([HCO2 Ϫ ]͞[HCOOH]), = 3.38 pH = 3.75 + log 0.0250 0.0583 Evaluate pH ϭ 3.38 corresponds to [H3Oϩ ] ϭ 4.2 ϫ 10–4 , point B in Fig. 12.6 and, as expected, the contribution of autoprotolysis is negligible. As predicted, the pH of the mixed solution (3.38) is higher than that of the original acid (2.37). Self-Test 12.7A Calculate the pH of the solution after the addition of another 5.00 mL of 0.150 M NaOH(aq). [Answer: 3.93, point D] Self-Test 12.7B Calculate the pH of the solution after the addition of yet another 5.00 mL of 0.150 M NaOH(aq). Figure 12.8 summarizes the changes in pH of a solution during a titration of a weak acid by a strong base. Half way to the stoichiometric point, the pH is equal to the pKa of the acid. The pH is greater than 7 at the stoichiometric point of the titration of a weak acid and strong base. The pH is less than 7 at the stoichiometric point of the titration of a weak base and strong acid. 12.6 Acid–Base Indicators A simple, reliable, and fast method of determining the pH of a solution and of monitoring a titration is with a pH meter, which uses a special electrode to measure H3Oϩ concentration. An automatic titrator uses an internal pH meter to monitor the pH of the analyte solution continuously. It detects the stoichiometric point by responding to the characteristic rapid change in pH (Fig. 12.9). Another common technique is to use an indicator to detect the stoichiometric point. An acid–base indicator is a water-soluble organic dye with a color that depends on the pH. The sudden change in pH that occurs at the stoichiometric point of a titration is signaled by a sharp change in color of the dye as it responds to the pH. FIGURE 12.9 A commercially available automatic titrator. The stoichiometric point of the titration is detected by the sudden change in pH that occurs in its vicinity; the pH is monitored electronically. The pH curve can be plotted as the reaction proceeds, as shown on the monitor screen. An acid–base indicator changes color with pH because it is a weak acid that has one color in its acid form (HIn, where In stands for indicator) and another color in its conjugate base form (In– ). The color change results because the proton in HIn changes the structure of the molecule in such a way that the light absorption characteristics of HIn are different from those of In– . When the concentration of HIn is much greater than that of In– , the solution has the color of the acid form of the indicator. When the concentration of In– is much greater than that of HIn, the solution has the color of the base form of the indicator. Because it is a weak acid, an indicator takes part in a proton transfer equilibrium: HIn(aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ In– (aq) The end point of an indicator is the point at which the concentrations of its acid and base forms are equal: [HIn] ϭ [In– ]. When we substitute this equality into the expression for KIn, we see that at the end point [H3Oϩ ] ϭ KIn. That is, the color change occurs when pH ϭ pKIn (4)* The color starts to change perceptibly about 1 pH unit before pKIn and is effectively complete about 1 pH unit after pKIn. Table 12.3 gives the values of pKIn for a number of common indicators. One common indicator is phenolphthalein (Fig. 12.10). The acid form of this large molecule (3) is colorless; its conjugate base form (4) is pink. The structure of the base form of phenolphthalein allows electrons to be delocalized across all three of the benzenelike rings, and the increase in delocalization is part of the reason for the change in color. The pKIn of phenolphthalein is 9.4, and so the end point occurs in slightly basic solution. Litmus, another common indicator, has pKIn ϭ 6.5; it is red for pH Ͻ 5 and blue for pH Ͼ 8. There are many naturally occurring indicators. For instance, a single compound is responsible for the colors of red poppies and blue cornflowers: the pH of the sap is different in the two plants. The color of hydrangeas also depends on the acidity of their sap and can be controlled by modifying the acidity of the soil (Fig. 12.11). The end point is a property of the indicator; the stoichiometric point is a property of the chemical reaction taking place during the titration. It is important to select an indicator with an end point close to the stoichiometric point of the titration (Fig. 12.12). In practice, the pKIn of the indicator should be within about 1 pH unit of the stoichiometric point: pKIn Ϸ pH(at the stoichiometric point) Ϯ 1 Ka = [H3O+ ][In- ] [HIn] 12.6 ACID–BASE INDICATORS 493 TABLE 12.3 Indicator Color Changes* pH range of Color of Color of Indicator pKIn color change acid form base form thymol blue 1.7 1.2 to 2.8 red yellow methyl orange 3.4 3.2 to 4.4 red yellow bromophenol blue 3.9 3.0 to 4.6 yellow blue bromocresol green 4.7 3.8 to 5.4 yellow blue methyl red 5.0 4.8 to 6.0 red yellow litmus 6.5 5.0 to 8.0 red blue bromothymol blue 7.1 6.0 to 7.6 yellow blue phenol red 7.9 6.6 to 8.0 yellow red thymol blue 8.9 8.0 to 9.6 yellow blue phenolphthalein 9.4 8.2 to 10.0 colorless pink alizarin yellow R 11.2 10.1 to 12.0 yellow red alizarin 11.7 11.0 to 12.4 red purple *The colors of the acid and base forms are only a symbolic representation of the actual colors. FIGURE 12.10 The stoichiometric point of an acid–base titration may be detected by the color change of an indicator. Here we see the colors of solutions containing a few drops of phenolphthalein at (from left to right) pH of 7.0, 8.5, 9.4 (its end point), 9.8, and 12.0. At the end point, the concentrations of the conjugate acid and base forms of the indicator are equal. 3 4 Ϫ Ϫ Ϫ Phenolphthalein can be used for titrations with a stoichiometric point near pH ϭ 9, such as a titration of a weak acid with a strong base. Methyl orange changes color between pH ϭ 3.2 and pH ϭ 4.4 and can be used in the titration of a weak base with a strong acid. Ideally, indicators for strong acid–strong base titrations should have end points close to pH ϭ 7; however, in strong acid–strong base titrations, the pH changes rapidly over several pH units, and even phenolphthalein can be used. Table 12.3 includes the pH ranges over which several indicators can be used. Acid–base indicators are weak acids that change color close to pH ϭ pKIn; an indicator should be chosen so that its end point is close to the stoichiometric point of the titration. 12.7 Stoichiometry of Polyprotic Acid Titrations Because many biological systems use polyprotic acids and their anions to control pH, we need to be familiar with pH curves for polyprotic titrations and to be able to calculate the pH during such a titration. The titration of a polyprotic acid proceeds in the same way as that of a monoprotic acid, but there are as many stoichiometric points in the titration as there are acidic hydrogen atoms. We therefore have to keep track of the major species in solution at each stage, as described in Sections 11.16 and 11.17 and summarized in Figs. 11.21 and 11.22. Suppose we are titrating the triprotic acid H3PO4 with a solution of NaOH. The experimentally determined pH curve is shown in Fig. 12.13. Notice that there are three stoichiometric points (B, D, and F) and three buffer regions (A, C, and E). In pH calculations for these systems, we assume that, as we add the hydroxide solution, initially NaOH reacts completely with the acid to form the diprotic conjugate base H2PO4 – : H3PO4(aq) ϩ OH– (aq) H2PO4 – (aq) ϩ H2O(l) (B) At point A, the system is in the first buffer region and pH ϭ pKa1. The pH in the first buffer region is determined by the proton transfer equilibrium between H3PO4 molecules and H2PO4 – ions produced in the titration. Once all the acid H3PO4 molecules have lost their first acidic protons, the system is at B and the primary species in solution are H2PO4 – and sodium ions. Point B is the first stoichiometric point, and to reach it we need to supply 1 mol NaOH for each mole of H3PO4. ¡ 494 CHAPTER 12 AQUEOUS EQUILIBRIA 0 2 4 6 8 10 12 14 Volume of acid or base added Strong acid, strong base Weak acid, strong base Strong acid, weak base pH Methyl orange Litmus Phenolphthalein Stoichiometric points FIGURE 12.12 Ideally, an indicator should have a sharp color change close to the stoichiometric point of the titration, which is at pH ϭ 7 for a strong acid–strong base titration. However, the change in pH is so abrupt that phenolphthalein can be used. Phenolphthalein can also be used to detect the stoichiometric point of a weak acid– strong base titration, but methyl orange can not. However, methyl orange can be used for a weak base–strong acid titration. Phenolphthalein would be inappropriate in this case, because its color change occurs well away from the stoichiometric point. Lab Video 12.12 FIGURE 12.11 The color of these hydrangeas depends on the acidity of the soil in which they are growing: acid soil results in blue flowers, alkaline soil results in pink flowers. Lab Video 12.11 As we continue to add base, it reacts with the H2PO4 – to form that acid’s conjugate base, HPO4 2– : H2PO4 – (aq) ϩ OH– (aq) HPO4 2– (aq) ϩ H2O(l) (C) At point C, the system is in the second buffer region and pH ϭ pKa2. Further base takes us to the second stoichiometric point, D. The primary species in solution are now HPO4 2– and sodium ions, which form a solution of Na2HPO4(aq). To reach the second stoichiometric point, an additional mole of NaOH is required for each mole of H3PO4 originally present. A total of 2 mol NaOH for each mole of H3PO4 has now been added. Additional base reacts with HPO4 2– to produce PO4 3– : HPO4 2– (aq) ϩOH– (aq) PO4 3– (aq) ϩ H2O(l) (D) At point E, the system is in the third buffer region and pH ϭ pKa3. When this reaction is complete, the primary species in solution are PO4 3– ions and sodium ions. To reach this stoichiometric point (F in the plot), we have to add another mole of OH– for each mole of H3PO4 initially present. At this point, a total of 3 mol OH– has been added for each mole of H3PO4. Notice that the third stoichiometric point (point F) is indistinct, largely because Ka3 is comparable to Kw. As a result, it is not detected in titrations. Figure 12.14 shows the pH curve of a diprotic acid, such as oxalic acid, H2C2O4. There are two stoichiometric points (B and D) and two buffer regions (A and C). The major species present in solution at each point are indicated. Note that it takes twice as much base to reach the second stoichiometric point as it does to reach the first. Self-Test 12.8A What volume of 0.010 M NaOH(aq) is required to reach (a) the first stoichiometric point and (b) the second stoichiometric point in a titration of 25.00 mL of 0.010 M H2SO3(aq)? [Answer: (a) 25 mL; (b) 50. mL] Self-Test 12.8B What volume of 0.020 M NaOH(aq) is required to reach (a) the first stoichiometric point and (b) the second stoichiometric point in a titration of 30.00 mL of 0.010 M H3PO4(aq)? ¡ ¡ 12.7 STOICHIOMETRY OF POLYPROTIC ACID TITRATIONS 495 FIGURE 12.13 The variation of the pH of the analyte solution during the titration of a triprotic acid (phosphoric acid). The major species present in solution at the first two stoichiometric points (B and D) and at points when half the titrant required to reach a stoichiometric point has been added (A, C, and E) are shown. Compare this diagram with Fig. 11.22. The labels SP1, SP2, and SP3 denote the volumes of base required to reach the three stoichiometric points. Points A through F are explained in the text. 2 4 6 8 10 12 14 A B C E F 2.12 7.21 12.68 SP1 SP2 SP3 Volume of base added HPO4 2− H2PO4 −/HPO4 2− H3PO4/H2PO4 − D pH H2PO4 − HPO4 2−/PO4 3− SOLUBILITY EQUILIBRIA Up to this point, we have focused on aqueous equilibria involving proton transfer. Now we apply the same principles to the equilibrium that exists between a solid salt and its dissolved ions in a saturated solution. We can use the equilibrium constant for the dissolution of a substance to predict the solubility of a salt and to control precipitate formation. These methods are used in the laboratory to separate and analyze mixtures of salts. They also have important practical applications in municipal wastewater treatment, the extraction of minerals from seawater, the formation and loss of bones and teeth, and the global carbon cycle. We can predict the pH at any point in the titration of a polyprotic acid with a strong base by using the reaction stoichiometry to recognize what stage we have reached in the titration. We then identify the principal solute species at that point and the principal proton transfer equilibrium that determines the pH. Self-Test 12.9A A sample of 0.200 M H3PO4(aq) of volume 25.0 mL was titrated with 0.100 M NaOH(aq). Identify the primary species in solution after the addition of the following volumes of NaOH solution: (a) 70.0 mL; (b) 100.0 mL. [Answer: (a) Between first and second stoichiometric points, Naϩ from the base, H2PO4 – , and HPO4 2– ; (b) at the second stoichiometric point, Naϩ and HPO4 2– .] Self-Test 12.9B A sample of 0.100 M H2S(aq) of volume 20.0 mL was titrated with 0.300 M NaOH(aq). Identify the primary species in solution after the addition of the following volumes of NaOH solution: (a) 5.0 mL; (b) 13.4 mL. The titration of a polyprotic acid has a stoichiometric point corresponding to the removal of each acidic hydrogen atom. The pH of a solution of a polyprotic acid undergoing a titration is estimated by considering the primary species in solution and the proton transfer equilibrium that determines the pH. 496 CHAPTER 12 AQUEOUS EQUILIBRIA B A 1.23 0 2 4 6 8 10 12 14 SP1 SP2 Volume of base added pH C D 4.19 H2C2O4/HC2O4 − HC2O4 −/C2O4 2− HC2O4 − C2O4 2−FIGURE 12.14 The variation of the pH of the analyte solution during the titration of a diprotic acid (oxalic acid) and the major species present in solution at the two stoichiometric points (B and D) and at points when half the titrant required to reach a stoichiometric point has been added (A and C). Compare this diagram with Fig. 11.21. The labels SP1 and SP2 denote the volumes of base required to reach the two stoichiometric points. 12.8 THE SOLUBILITY PRODUCT 497 12.8 The Solubility Product The equilibrium constant for the solubility equilibrium between an ionic solid and its dissolved ions is called the solubility product, Ksp, of the solute. For example, the solubility product for bismuth sulfide, Bi2S3, is defined as Bi2S3(s) #¢4 2 Bi3ϩ (aq) ϩ 3 S2Ϫ (aq) Because the concentrations of ions in a solution of a sparingly soluble salt are low, we assume, just as we did for solutions of weak acids and bases (Section 11.7), that we can approximate Ksp by using molar concentrations: Ksp ϭ [Bi3ϩ ]2 [S2Ϫ ]3 Solid Bi2S3 does not appear in the expression for Ksp, because it is a pure solid and its activity is 1 (Section 10.2). A solubility product is used in the same way as any other equilibrium constant. However, because ion–ion interactions, even in dilute electrolyte solutions, can complicate its interpretation, a solubility product is generally meaningful only for sparingly soluble salts. Another complication that arises when dealing with nearly insoluble compounds is that dissociation of the ions is rarely complete, and a saturated solution of PbI2, for instance, contains substantial concentrations of Pb2ϩ IϪ and Pb2ϩ (IϪ )2 ion clusters. At best, the calculations that we are about to describe are only estimates. One of the simplest ways to determine Ksp is to measure the molar solubility of the compound, the molar concentration of the compound in a saturated solution, but more advanced and accurate methods are also available. Table 12.4 gives some experimental values. In the following calculations, we use s to denote the numerical value of the molar solubility expressed in moles per liter; for example, if the molar solubility of a compound is 65 ␮molиLϪ1 (that is, 6.5 ϫ 10Ϫ5 molиLϪ1 ), then we write s ϭ 6.5 ϫ 10Ϫ5 . Ksp = (aBi3 + )2 (aS2-)3 Ksp is also called the solubility product constant and, most simply, the solubility constant. Electrochemical methods for determining solubility products are discussed in section 13.8. TABLE 12.4 Solubility Products at 25°C Compound Formula Ksp Compound Formula Ksp aluminum hydroxide Al(OH)3 1.0 ϫ 10Ϫ33 lead(II) fluoride PbF2 3.7 ϫ 10Ϫ8 antimony sulfide Sb2S3 1.7 ϫ 10Ϫ93 iodate Pb(IO3)2 2.6 ϫ 10Ϫ13 barium carbonate BaCO3 8.1 ϫ 10Ϫ9 iodide PbI2 1.4 ϫ 10Ϫ8 fluoride BaF2 1.7 ϫ 10Ϫ6 sulfate PbSO4 1.6 ϫ 10Ϫ8 sulfate BaSO4 1.1 ϫ 10Ϫ10 sulfide PbS 8.8 ϫ 10Ϫ29 bismuth sulfide Bi2S3 1.0 ϫ 10Ϫ97 magnesium ammonium phosphate MgNH4PO4 2.5 ϫ 10Ϫ13 calcium carbonate CaCO3 8.7 ϫ 10Ϫ9 carbonate MgCO3 1.0 ϫ 10Ϫ5 fluoride CaF2 4.0 ϫ 10Ϫ11 fluoride MgF2 6.4 ϫ 10Ϫ9 hydroxide Ca(OH)2 5.5 ϫ 10Ϫ6 hydroxide Mg(OH)2 1.1 ϫ 10Ϫ11 sulfate CaSO4 2.4 ϫ 10Ϫ5 mercury(I) chloride Hg2Cl2 2.6 ϫ 10Ϫ18 chromium(III) iodate Cr(IO3)3 5.0 ϫ 10Ϫ6 iodide Hg2I2 1.2 ϫ 10Ϫ28 copper(I) bromide CuBr 4.2 ϫ 10Ϫ8 mercury(II) sulfide, black HgS 1.6 ϫ 10Ϫ52 chloride CuCl 1.0 ϫ 10Ϫ6 sulfide, red HgS 1.4 ϫ 10Ϫ53 iodide CuI 5.1 ϫ 10Ϫ12 nickel(II) hydroxide Ni(OH)2 6.5 ϫ 10Ϫ18 sulfide Cu2S 2.0 ϫ 10Ϫ47 silver bromide AgBr 7.7 ϫ 10Ϫ13 copper(II) iodate Cu(IO3)2 1.4 ϫ 10Ϫ7 carbonate Ag2CO3 6.2 ϫ 10Ϫ12 oxalate CuC2O4 2.9 ϫ 10Ϫ8 chloride AgCl 1.6 ϫ 10Ϫ10 sulfide CuS 1.3 ϫ 10Ϫ36 hydroxide AgOH 1.5 ϫ 10Ϫ8 iron(II) hydroxide Fe(OH)2 1.6 ϫ 10Ϫ14 iodide AgI 8 ϫ 10Ϫ17 sulfide FeS 6.3 ϫ 10Ϫ18 sulfide Ag2S 6.3 ϫ 10Ϫ51 iron(III) hydroxide Fe(OH)3 2.0 ϫ 10Ϫ39 zinc hydroxide Zn(OH)2 2.0 ϫ 10Ϫ17 lead(II) bromide PbBr2 7.9 ϫ 10Ϫ5 sulfide ZnS 1.6 ϫ 10Ϫ24 chloride PbCl2 1.6 ϫ 10Ϫ5 498 CHAPTER 12 AQUEOUS EQUILIBRIA Evaluate As expected, Ksp is very small. Self-Test 12.10A The molar solubility of lead(II) iodate, Pb(IO3)2, at 25°C is 40. ␮molиLϪ1 . What is the value of Ksp for lead(II) iodate? [Answer: 2.6 ϫ 10Ϫ13 ] Self-Test 12.10B The molar solubility of silver bromide, AgBr, at 25°C is 0.88 ␮molиLϪ1 . What is the value of Ksp for silver bromide? Write the chemical equation. Ag2CrO4(s) #¢4 2 Agϩ (aq) ϩ CrO4 2Ϫ (aq) Write the expression for the solubility product. Ksp ϭ [Agϩ ]2 [CrO4 2Ϫ ] From 2 mol Agϩ ϴ 1 mol Ag2CrO4 and 65 ␮molиLϪ1 ϭ 6.5 ϫ 10Ϫ5 molиLϪ1 , [Agϩ ] ϭ 2s ϭ 2 ϫ (6.5 ϫ 10Ϫ5 ) From 1 mol CrO4 2Ϫ ϴ 1 mol Ag2CrO4, [CrO4 2Ϫ ] ϭ s ϭ 6.5 ϫ 10Ϫ5 From Ksp ϭ [Agϩ ]2 [CrO4 2Ϫ ] ϭ (2s)2 (s) ϭ 4s3 , Ksp ϭ 4 ϫ (6.5 ϫ 10Ϫ5 )3 ϭ 1.1 ϫ 10Ϫ12 EXAMPLE 12.7 Determining the solubility product The molar solubility of silver chromate, Ag2CrO4, is 65 ␮mol·LϪ1 at 25°C. Determine the value of Ksp for silver chromate at 25°C. Anticipate Because the molar solubility is low, we should expect Ksp to be a very small number. PLAN First, we write the chemical equation for the equilibrium and the expression for the solubility product. To evaluate Ksp, we need to know the molarity of each type of ion formed by the salt. We determine the molarities from the molar solubility and the stoichiometric relations between the species. What should we assume? That the salt dissociates completely in water and that the anion is not protonated by water. SOLVE EXAMPLE 12.8 Estimating the molar solubility from the solubility product According to Table 12.4, Ksp ϭ 5.0 ϫ 10Ϫ6 for chromium(III) iodate in water at 25°C. Estimate the molar solubility of the compound at 25°C. PLAN Set up the solubility product in terms of the molar solubility, taking into account the stoichiometric relations as given by the chemical equation for the equilibrium, then solve for the molar solubility. What should we assume? That the salt dissociates completely in water and that the anion is not protonated by water. SOLVE Assume complete dissociation. Write the chemical equation. Cr(IO3)3(s) #¢4 Cr3ϩ (aq) ϩ 3 IO3 Ϫ (aq) Write the expression for the solubility product. Ksp ϭ [Cr3ϩ ][IO3 Ϫ ]3 12.9 THE COMMON-ION EFFECT 499 From 1 mol Cr3ϩ ϴ 1 mol Cr(IO3)3, [Cr3ϩ ] ϭ s From 3 mol IO3 Ϫ ϴ 1 mol Cr(IO3)3, [IO3 Ϫ ] ϭ 3s Write the expression for Ksp in terms of s. Ksp ϭ [Cr3ϩ ][IO3 Ϫ ]3 ϭ s ϫ (3s)3 ϭ 27s4 From s ϭ (Ksp/27)1/4 , s ϭ {(5.0 ϫ 10Ϫ6 )͞27}1/4 ϭ 0.021 A note on good practice: A quick way to evaluate the fourth root is to take the square root twice in succession. The molar solubility of Cr(IO3)3 is therefore 0.021 mol·LϪ1 . Self-Test 12.11A The solubility product of silver sulfate, Ag2SO4, is 1.4 ϫ 10Ϫ5 . Estimate the molar solubility of the salt. [Answer: 15 mmolиLϪ1 ] Self-Test 12.11B The solubility product of lead(II) fluoride, PbF2, is 3.7 ϫ 10Ϫ8 . Estimate the molar solubility of the salt. The solubility product is the equilibrium constant for the equilibrium between an undissolved salt and its ions in a saturated solution. 12.9 The Common-Ion Effect Sometimes we have to precipitate one ion of a sparingly soluble salt. For example, heavy metal ions such as lead and mercury can be removed from municipal wastewater by precipitating them as the hydroxides. However, because the ions are in dynamic equilibrium with the solid salt, some heavy metal ions remain in solution. How can we remove more of the ions? We can use Le Chatelier’s principle as a guide. This principle tells us that, if we add a second salt or an acid that supplies one of the same ions—a “common ion”—to a saturated solution of a salt, then the equilibrium will tend to adjust by decreasing Cation (a) Anion FIGURE 12.15 If the concentration of one of the ions of a slightly soluble salt is increased, the concentration of the other decreases to maintain a constant value of Ksp. (a) The cations (pink) and anions (green) in solution. (b) When more anions are added (together with their accompanying spectator ions, which are not shown), the concentration of cations decreases. In other words, the solubility of the original compound is reduced by the presence of a common ion. In the insets, the blue background represents the solvent (water). (b) the concentration of the added ions (Fig. 12.15). That is, the solubility of the original salt is decreased, and it precipitates. We can conclude that the addition of excess OHϪ ions to the water supply should precipitate more of the heavy metal ions as their hydroxides. In other words, the addition of OHϪ ions reduces the solubility of the heavy metal hydroxide. The decrease in solubility caused by the addition of a common ion is called the common-ion effect. We can gain a quantitative understanding of the common-ion effect by considering how a change in the concentration of one of the ions affects the solubility product. Suppose we have a saturated solution of silver chloride in water: AgCl(s) #¢4 Agϩ (aq) ϩ ClϪ (aq) Ksp ϭ [Agϩ ][ClϪ ] Experimentally, Ksp ϭ 1.6 ϫ 10Ϫ10 at 25°C, and the molar solubility of AgCl in water is 13 ␮molиLϪ1 . If we add sodium chloride to the solution, the concentration of ClϪ ions increases. For the equilibrium constant to remain constant, the concentration of Agϩ ions must decrease. Because there is now less Agϩ in solution, the solubility of AgCl is lower in a solution of NaCl than it is in pure water. A similar effect occurs whenever two salts having a common ion are mixed (Fig. 12.16). The prediction of the numerical value of the common-ion effect is difficult. Because ions interact with one another strongly, simple equilibrium calculations are rarely valid: the activities of ions can differ markedly from their molarities. However, we can still get an idea of the size of the common-ion effect by solving the Ksp expression for the concentration of the ion other than the common ion. Thinking point: Could the addition of a salt without a common ion affect the solubility of a sparingly soluble salt? 500 CHAPTER 12 AQUEOUS EQUILIBRIA FIGURE 12.16 (a) A saturated solution of zinc acetate in water. (b) When additional acetate ions are added (as a single crystal of solid sodium acetate in the spatula shown in part (a), the solubility of the zinc acetate is significantly reduced and more zinc acetate precipitates. EXAMPLE 12.9 Estimating the effect of a common ion on solubility Estimate the solubility of silver chloride in 1.0 ϫ 10Ϫ4 M NaCl(aq) at 25°C. Anticipate Due to the presence of a common ion, we should expect the solubility of AgCl in NaCl(aq) to be lower than in pure water. PLAN Set up the solubility product and solve for the concentration of silver ions. What should we assume? That the concentration of chloride ions from the AgCl is insignificant compared to the concentration of the chloride ions in the sodium chloride solution. 12.10 PREDICTING PRECIPITATION 501 From Ksp ϭ [Agϩ ][ClϪ ], [Ag+ ] = Ksp [Cl- ] It follows that silver chloride will dissolve in 1.0 ϫ 10Ϫ4 M NaCl(aq), in which [ClϪ ] ϭ 1.0 ϫ 10Ϫ4 mol·LϪ1 , until the concentration of Agϩ ions is given by: 13 1.6 Solubility (␮mol·L Ϫ1 ) 0.10 mmol·LϪ1 [Cl Ϫ ]0 With [ClϪ ] ϭ 1.0 ϫ 10Ϫ4 molиLϪ1 and Ksp ϭ 1.6 ϫ 10Ϫ10 , = 1.6 * 10-6 [Ag+ ] = 1.6 * 10-10 1.0 * 10-4 Evaluate The concentration of Agϩ ions, and hence the solubility of AgCl formula units, is 1.6 ␮molиLϪ1 , which is about 10 times less than the solubility of AgCl in pure water, as expected. Self-Test 12.12A What is the approximate molar solubility of calcium carbonate in 0.20 M CaCl2(aq)? [Answer: 44 nmol·LϪ1 ] Self-Test 12.12B What is the approximate molar solubility of silver bromide in 0.10 M CaBr2(aq)? The common-ion effect is the reduction in solubility of a sparingly soluble salt by the addition of a soluble salt that has an ion in common with it. 12.10 Predicting Precipitation Sometimes it is important to know under what conditions a precipitate will form. For example, if we are analyzing a mixture of ions, we may want to precipitate only one type of ion to separate it from the mixture. In Section 10.5, we saw how to predict the direction in which a reaction will take place by comparing the values of Q, the reaction quotient, and K, the equilibrium constant. Exactly the same techniques can be used to decide whether a precipitate is likely to form when two electrolyte solutions are mixed. In this case, the equilibrium constant is the solubility product, Ksp, and the reaction quotient is denoted Qsp. When the concentrations of the ions are high, Qsp is greater than Ksp, precipitation occurs, and the value of Qsp drops to equal Ksp (Fig. 12.17). SOLVE For a given concentration of ClϪ ions, the concentration of Agϩ ions must satisfy Ksp. Qsp Ͻ Ksp Qsp Ͼ KspQsp ϭ Ksp Solid Dissolve Precipitate FIGURE 12.17 The relative magnitudes of the solubility quotient, Qsp, and the solubility product, Ksp, are used to decide whether a salt will dissolve (left) or precipitate (right). When the concentrations of the ions in solution are low (left) Qsp is smaller than Ksp; when the ion concentrations are high (right), Qsp is larger than Ksp. 502 CHAPTER 12 AQUEOUS EQUILIBRIA Evaluate The value of Qsp is considerably higher than Ksp, and so, as predicted, a precipitate forms (Fig. 12.18). Self-Test 12.13A Does a precipitate of silver chloride form when 200. mL of 1.0 ϫ 10Ϫ4 M AgNO3(aq) and 900. mL of 1.0 ϫ 10Ϫ6 M KCl(aq) are mixed? Assume complete dissociation. [Answer: No (Qsp ϭ 1.5 ϫ 10Ϫ11 ; Qsp Ͻ Ksp)] Self-Test 12.13B Does a precipitate of barium fluoride form when 100. mL of 1.0 ϫ 10Ϫ3 M Ba(NO3)2(aq) is mixed with 200. mL of 1.0 ϫ 10Ϫ3 M KF(aq)? Ignore possible protonation of FϪ . A salt precipitates if Qsp is greater than Ksp. 12.11 Selective Precipitation It is sometimes possible to separate different cations from a solution by adding a soluble salt containing an anion with which they form salts with very different solubilities. For example, seawater is a mixture of many different ions. It is possible to precipitate magnesium ions from seawater by adding hydroxide ions. However, other cations are also present in seawater. Their individual concentrations and the relative solubilities of their hydroxides determine which will precipitate first if a certain amount of hydroxide is added. Optimum separation of two compounds is achieved when Qsp for one species exceeds its Ksp but Qsp for the second species is significantly less than its Ksp. Example 12.11 illustrates a strategy for predicting the order of precipitation. EXAMPLE 12.10 Predicting whether a precipitate will form when two solutions are mixed Suppose we mix equal volumes of 0.2 M Pb(NO3)2(aq) and KI(aq) at 25°C. Will lead(II) iodide precipitate? Anticipate Because the concentrations of the Pb2ϩ and IϪ ions are high and the solubility product of PbI2 is low, we should expect precipitation to occur. PLAN First calculate the new values of the ions in the mixed solution, before reaction occurs. In this case, because equal volumes are mixed together, the new volume is twice each initial volume, and so the new molarities are half their original values. What should we assume? That the lead(II) iodide is fully dissociated in aqueous solution. SOLVE We know from Table 12.4 that Ksp ϭ 1.4 ϫ 10Ϫ8 for PbI2 at 25°C. Write the chemical equation and its equilibrium constant. PbI2(s) #¢4 Pb2ϩ (aq) ϩ 2 IϪ (aq), Ksp ϭ [Pb2ϩ ][IϪ ]2 Pb2ϩ Pb2ϩ IϪ IϪ Calculate the new molarities of the ions. Pb2ϩ (aq): (0.2 mol·LϪ1 )͞2 ϭ 0.1 mol·LϪ1 IϪ (aq): (0.2 mol·LϪ1 )͞2 ϭ 0.1 mol·LϪ1 From Qsp ϭ [Pb2ϩ ][IϪ ]2 , Qsp ϭ 0.1 ϫ (0.1)2 ϭ 1 ϫ 10Ϫ3 FIGURE 12.18 When a few drops of lead(II) nitrate solution are added to a solution of potassium iodide, yellow lead(II) iodide immediately precipitates. Lab Video 12.18 12.11 SELECTIVE PRECIPITATION 503 EXAMPLE 12.11 Predicting the order of precipitation A sample of seawater contains, among other solutes, the following concentrations of soluble cations: 0.050 mol·LϪ1 Mg2ϩ (aq) and 0.010 mol·LϪ1 Ca2ϩ (aq). (a) Use the information in Table 12.4 to determine the order in which each ion precipitates as solid NaOH is added, and give the concentration of OHϪ when precipitation of each begins. Assume no volume change on addition of the NaOH and that the temperature is 25°C. (b) If the first compound to precipitate is X(OH)2, calculate the concentration of X2ϩ ions remaining in solution when the second ion precipitates. Anticipate In (a), because Ksp(Mg(OH)2) is so much smaller than Ksp(Ca(OH)2), and the formulas similar, we should expect that Mg(OH)2 will precipitate first. In (b), because much of X2ϩ has precipitated as X(OH)2 and is no longer in solution, we should expect its concentration to be very small when the second ion precipitates. PLAN A salt begins to precipitate when the concentrations of its ions are such that Qsp Ͼ Ksp. (a) Calculate the value of [OHϪ ] required for each salt to precipitate by writing the expression for Ksp for each salt and then substituting the data provided. (b) Calculate the remaining concentration of the first cation to precipitate by substituting the value of [OHϪ ] into Ksp for that hydroxide. SOLVE (a) Write the chemical equation and Ksp for the dissolving of Ca(OH)2: Ca(OH)2(s) #¢4 Ca2ϩ (aq) ϩ 2 OHϪ (aq) Ksp ϭ [Ca2ϩ ][OHϪ ]2 and from Table 12.4, Ksp ϭ 5.5 ϫ 10Ϫ6 . Then: 23 mmol·LϪ1Find [OHϪ ] from Ksp ϭ [Ca2ϩ ][OHϪ ]2 in the form [OHϪ ] ϭ {Ksp/[Ca2ϩ ]}1/2 . = 0.023 [OH] = a 5.5 * 10-6 0.010 b 1/2 15 ␮mol·LϪ1Find [OHϪ ] from Ksp ϭ [Mg2ϩ ][OHϪ ]2 in the form [OHϪ ] ϭ {Ksp/[Mg2ϩ ]}1/2 . = 1.5 * 10-5 [OH] = a 1.1 * 10-11 0.050 b 1/2 Write the chemical equation and Ksp for the dissolving of Mg(OH)2: Mg(OH)2(s) #¢4 Mg2ϩ (aq) ϩ 2 OHϪ (aq) Ksp ϭ [Mg2ϩ ][OHϪ ]2 From Table 12.4, Ksp ϭ 1.1 ϫ 10Ϫ11 . Evaluate We conclude that the hydroxides precipitate in the order Mg(OH)2 at 1.5 ϫ 10Ϫ5 mol·LϪ1 OHϪ (aq) and Ca(OH)2 at 0.023 mol·LϪ1 OHϪ (aq). (b) Find the concentration of magnesium ions when [OHϪ ] ϭ 0.023: Find [Mg2ϩ ] from Ksp ϭ [Mg2ϩ ][OHϪ ]2 in the form [Mg2ϩ ] ϭ Ksp/[OHϪ ]2 . Evaluate The concentration of magnesium ions remaining when Ca(OH)2 begins to precipitate is indeed very small. [Mg2+ ] = 1.1 * 10-11 (0.023)2 = 2.1 * 10-8 Self-Test 12.14A Potassium carbonate is added to a solution containing the following concentrations of cations: 0.030 mol·LϪ1 Mg2ϩ (aq) and 0.0010 mol·LϪ1 Ca2ϩ (aq). (a) Use the information in Table 12.4 to determine the order in which each ion precipitates as the concentration of K2CO3 is increased and give the concentration of CO3 2Ϫ when precipitation of each begins. (b) Calculate the concentration of the first ion to precipitate that remains in solution when the second ion precipitates. [Answer: (a) CaCO3 precipitates first, at 8.7 ␮molиLϪ1 CO3 2Ϫ , then MgCO3 at 0.33 mmol·LϪ1 CO3 2Ϫ ; (b) 26 ␮molиLϪ1 Ca2ϩ ] Self-Test 12.14B Chloride ion is added to a solution containing the following concentrations of soluble salts: 0.020 mol·LϪ1 Pb(NO3)2(aq) and 0.0010 mol·LϪ1 AgNO3(aq). (a) Use the information in Table 12.4 to determine the order in which each ion precipitates as the concentration of chloride ion is increased and give the concentration of ClϪ when precipitation of each begins. (b) Calculate the concentration of the first ion to precipitate that remains in solution when the second ion precipitates. A mixture of ions in solution can be separated by adding an oppositely charged ion with which they form salts having very different solubilities. 12.12 Dissolving Precipitates When a precipitate has been formed during the qualitative analysis of the ions present in a solution, it may be necessary to dissolve the precipitate again to identify the cation or anion. One strategy is to remove one of the ions from the solubility equilibrium so that the precipitate will continue to dissolve in a fruitless chase for equilibrium. Suppose, for example, that a solid hydroxide such as iron(III) hydroxide is in equilibrium with its ions in solution: Fe(OH)3(s) #¢4 Fe3ϩ (aq) ϩ 3 OHϪ (aq) To dissolve more of the solid, we can add acid. The H3Oϩ ions from the acid remove the OHϪ ions by converting them into water, and the Fe(OH)3 dissolves. Many carbonate, sulfite, and sulfide precipitates can be dissolved by the addition of acid, because the anions react with the acid to form a gas that bubbles out of solution. For example, in a saturated solution of zinc carbonate, solid ZnCO3 is in equilibrium with its ions: ZnCO3(s) #¢4 Zn2ϩ (aq) ϩ CO3 2Ϫ (aq) The CO3 2Ϫ ions react with acid to form CO2: CO3 2Ϫ (aq) ϩ 2 HNO3(aq) CO2(g) ϩ H2O(l) ϩ 2 NO3 Ϫ (aq) The dissolution of carbonates by acid is an undesired result of acid rain, which has damaged the appearance of many historic marble and limestone monuments (Fig. 12.19; marble and limestone are forms of calcium carbonate). An alternative procedure for removing an ion from solution is to change its identity by changing its oxidation state. The metal ions in very insoluble heavy metal sulfide precipitates can be dissolved by oxidizing the sulfide ion to elemental sulfur. For example, copper(II) sulfide, CuS, takes part in the equilibrium CuS(s) #¢4 Cu2ϩ (aq) ϩ S2Ϫ (aq) However, when nitric acid is added, the sulfide ions are oxidized to elemental sulfur: 3 S2Ϫ (aq) ϩ 8 HNO3(aq) 3 S(s) ϩ 2 NO(g) ϩ 4 H2O(l) ϩ 6 NO3 Ϫ (aq) This complicated oxidation removes the sulfide ions from the equilibrium, and Cu2ϩ ions dissolve as Cu(NO3)2. Some precipitates dissolve when the temperature is changed. This strategy is used to purify precipitates. The mixture is heated to dissolve the solid and filtered to remove insoluble impurities. The solid is then allowed to re-form as the solution cools and is removed from the solution in a second filtration. Complex ion formation (Section 12.13) can also be used to dissolve metal ions. ¡ ¡ 504 CHAPTER 12 AQUEOUS EQUILIBRIA FIGURE 12.19 The state of the carving on Cleopatra’s Needle has deteriorated as a result of the action of acid rain: (a) after 3500 years in the Egyptian desert; (b) after a further 90 years in Central Park, New York City. The solubility of a solid can be increased by removing one of its ions from solution; acid can be used to dissolve a hydroxide, sulfide, sulfite, or carbonate precipitate; and nitric acid can be used to oxidize metal sulfides to sulfur and a soluble salt. Some solids can be dissolved by changing the temperature. 12.13 Complex Ion Formation The solubility of a salt can be increased by finding a way to hide away the ions in solution, because then the dissolution process continues in a vain attempt to reach equilibrium. To remove an ion, we can use the fact that many metal cations are Lewis acids (Section 11.2). When a Lewis acid and a Lewis base react, they form a coordinate covalent bond and the product is called a coordination complex. In this section, we consider complexes in which the Lewis acid is a metal cation, such as Agϩ . An example is the formation of Ag(NH3)2 ϩ when an aqueous solution of the Lewis base ammonia is added to a solution of silver ions: Agϩ (aq) ϩ 2 NH3(aq) Ag(NH3)2 ϩ (aq) If enough ammonia is added to a precipitate of silver halide, all the precipitate dissolves. A similar procedure is used to remove the silver halide emulsion from an exposed photographic film after it has been developed. In this case, the reagent used to form the complex is the thiosulfate ion, S2O3 2Ϫ : Agϩ (aq) ϩ 2 S2O3 2Ϫ (aq) Ag(S2O3)2 3Ϫ (aq) Complex formation removes some of the Agϩ ions from solution. As a result, to preserve the value of Ksp, more silver chloride dissolves. Formation of a complex increases the solubility of a sparingly soluble compound. To treat complex formation quantitatively, we note that complex formation and the dissolving of the salt are both at equilibrium; so we can write AgCl(s) #¢4 Agϩ (aq) ϩ ClϪ (aq) Ksp ϭ [Agϩ ][ClϪ ] (E) Agϩ (aq) ϩ 2 NH3(aq) #¢4 Ag(NH3)2 ϩ (aq) (F) The equilibrium constant for the formation of a complex ion is called the formation constant, Kf. At 25°C, Kf ϭ 1.6 ϫ 107 for reaction F. Values for some other complexes are given in Table 12.5, and Example 12.12 shows how to use them. Kf = [Ag(NH3)2 + ] [Ag+ ][NH3]2 ¡ ¡ 12.13 COMPLEX ION FORMATION 505 TABLE 12.5 Formation Constants of Complexes in Water at 25°C Equilibrium Kf Ag+ (aq) + 2 CN– (aq) #¢4 Ag(CN)2 – (aq) 5.6 ϫ 108 Ag+ (aq) + 2 NH3(aq) #¢4 Ag(NH3)2 + (aq) 1.6 ϫ 107 Au+ (aq) + 2 CN– (aq) #¢4 Au(CN)2 – (aq) 2.0 ϫ 1038 Cu2+ (aq) + 4 NH3(aq) #¢4 Cu(NH3)4 2+ (aq) 1.2 ϫ 1013 Hg2+ (aq) + 4 Cl– (aq) #¢4 HgCl4 2– (aq) 1.2 ϫ 105 Fe2+ (aq) + 6 CN– (aq) #¢4 Fe(CN)6 4– (aq) 7.7 ϫ 1036 Ni2+ (aq) + 6 NH3(aq) #¢4 Ni(NH3)6 2+ (aq) 5.6 ϫ 108 EXAMPLE 12.12 Calculating molar solubility in the presence of complex formation Calculate the molar solubility of silver chloride in 0.10 M NH3(aq), given that Ksp ϭ 1.6 ϫ 10Ϫ10 for silver chloride and Kf ϭ 1.6 ϫ 107 for the ammonia complex of Agϩ ions, Ag(NH3)2 ϩ . Anticipate Because silver ions form a complex with ammonia, we should expect that the solubility of silver chloride will be greater in the ammonia solution than in water. What should we assume? That the reaction of ammonia with water does not significantly affect this equilibrium. PLAN First, we write the chemical equation for the equilibrium between the solid solute and the complex in solution as the sum of the equations for the solubility and complex formation equilibria. The equilibrium constant for the overall equilibrium is therefore the product of the equilibrium constants for the two processes. Then, we set up an equilibrium table and solve for the equilibrium concentrations of ions in solution. SOLVE The overall equilibrium is the sum of reactions E and F: AgCl(s) ϩ 2 NH3(aq) #¢4 Ag(NH3)2 ϩ (aq) ϩ ClϪ (aq) The equilibrium constant of the overall reaction is the product of the equilibrium constants for the two reactions: Because 1 mol AgCl 1 mol ClϪ , the molar solubility of AgCl is given by the equation s ϭ [ClϪ ]. From the balanced overall equation, we see that [ClϪ ] ϭ [Ag(NH3)2 ϩ ] in the saturated solution. The equilibrium table, with all concentrations in moles per liter, is NH3 Ag(NH3)2 ϩ ClϪ Step 1 Initial molarity 0.10 0 0 Step 2 Change in molarity Ϫ2x ϩx ϩx Step 3 Equilibrium molarity 0.10 Ϫ 2x x x Now determine the value of K and substitute the information from the table. ϴ K = Ksp * Kf = [Ag(NH3) + 2 ][Cl- ] [NH3]2 506 CHAPTER 12 AQUEOUS EQUILIBRIA From K ϭ Ksp ϫ Kf, K ϭ (1.6 ϫ 10Ϫ10 ) ϫ (1.6 ϫ 107 ) ϭ 2.6 ϫ 10Ϫ3 Find [ClϪ ] from K ϭ [Ag(NH3)2 ϩ ][ClϪ ]͞[NH3]2 . K = x * x (0.10 - 2x)2 = 2.6 * 10-3 Take the square root of each side. x 0.10 - x = 5.1 * 10-2 4.6 0.10 0.013 Solubility (mmol·L Ϫ1 ) [NH3 ] (mol·L Ϫ1 ) Solve for x. x ϭ 5.1 ϫ 10Ϫ2 ϫ (0.10 Ϫ 2x) Hence x ϭ 4.6 ϫ 10Ϫ3 Evaluate From step 3, x ϭ [Ag(NH3)2 ϩ ] ϭ 4.6 ϫ 10Ϫ3 . Hence, the molar solubility of silver chloride in 0.10 M NH3(aq) is 4.6 mmolиLϪ1 , more than 100 times the molar solubility of silver chloride in pure water (13 ␮molиLϪ1 ), as expected. Self-Test 12.15A Use data from Tables 12.4 and 12.5 to calculate the molar solubility of silver bromide in 1.0 M NH3(aq). [Answer: 3.5 mmolиLϪ1 ] Self-Test 12.15B Use data from Tables 12.4 and 12.5 to calculate the molar solubility of copper(II) sulfide in 1.2 M NH3(aq). The solubility of a salt increases if the salt can form a complex ion with other species in the solution. 12.14 Qualitative Analysis Complex formation, selective precipitation, and control of the pH of a solution all play important roles in the qualitative analysis of the ions present in aqueous solutions. There are many different schemes of analysis, but they follow the same general principles. Let’s think through a simple procedure for the identification of five cations by following the steps that might be used in the laboratory. We shall see how each step makes use of solubility equilibria. Suppose we have a solution that contains lead(II), mercury(I), silver, copper(II), and zinc ions. The method is outlined in Fig. 12.20, which includes additional cations, and is illustrated in Fig. 12.21. Most chlorides are soluble; so, when hydrochloric acid is added to a mixture of salts, only certain chlorides precipitate (see Table 12.4). Silver and mercury(I) chlorides have such small values of Ksp that, even with low concentrations of ClϪ ions, the chlorides precipitate. Lead(II) chloride, which is slightly soluble, will precipitate if the chloride ion concentration is high enough. The hydronium ions provided by the acid play no role in this step; they simply accompany the chloride ions. At this point, the precipitate can be separated from the solution by using a centrifuge to compact the solid and then decanting (pouring off) the solution. The solution now contains copper(II) and zinc ions, whereas the solid consists of PbCl2, Hg2Cl2, and AgCl. Because PbCl2 is slightly soluble, if the precipitate is rinsed with hot water, the lead(II) chloride dissolves and the solution is separated from the precipitate. If sodium chromate is then added to that solution, the presence of lead can be verified because any lead(II) ions present will precipitate as yellow lead(II) chromate: Pb2ϩ (aq) ϩ CrO4 2Ϫ (aq) PbCrO4(s) At this point, the silver and mercury(I) chlorides remain as precipitates. To separate the Agϩ and Hg2 2ϩ ions, aqueous ammonia is added to the solid mixture. The silver precipitate dissolves as the soluble complex ion Ag(NH3)2 ϩ forms: Agϩ (aq) ϩ 2 NH3(aq) Ag(NH3)2 ϩ (aq)¡ ¡ 12.14 QUALITATIVE ANALYSIS 507 HCl(aq) Hg2Cl2 PbCl2 AgCl H2S(g) Decant Decant Sb2S3 HgS CuS CdS Bi2S3 NH3(aq) ZnS NiS MnS FeS FIGURE 12.20 Part of a simple qualitative analysis scheme used to separate certain cations. In the first step, three cations are separated as insoluble chlorides. In the second step, cations that form highly insoluble sulfides are removed by precipitation at a low pH; and, in the third step, the remaining cations are precipitated as the sulfides at a higher pH. FIGURE 12.21 Steps in the analysis of five cations by selective precipitation. (a) The original solution contains Pb2ϩ , Hg2 2ϩ , Agϩ , Cu2ϩ , and Zn2ϩ ions (left). Addition of HCl precipitates AgCl, Hg2Cl2, and PbCl2, which can be removed by decanting or filtration (right), as shown in Fig. 12.22. (b) Addition of H2S to the solution remaining from the first step (left) precipitates CuS, which can be removed (right). (c) Making the solution from the second step (left) basic by adding ammonia precipitates ZnS (right). Lab Video 12.21 and mercury(I) reacts with ammonia to form a gray solid consisting of a mixture of mercury(II) ions precipitated as white HgNH2Cl(s) and black metallic mercury (Fig. 12.22): Hg2Cl2(s) ϩ 2 NH3(aq) Hg(l) ϩ HgNH2Cl(s) ϩ NH4 ϩ (aq) ϩ ClϪ (aq) At this point, any Hg2 2ϩ has precipitated and any Agϩ present is in solution. The solution is separated from the solid, and the presence of silver ion in the solution is verified by addition of nitric acid. This acid pulls the ammonia out of the complex as NH4 ϩ , allowing white silver chloride to precipitate: Ag(NH3)2 ϩ (aq) ϩ ClϪ (aq) ϩ 2 H3Oϩ (aq) AgCl(s) ϩ 2 NH4 ϩ (aq) ϩ 2 H2O(l) Sulfides with widely different solubilities and solubility products can be selectively precipitated by adding S2Ϫ ions to the solution removed from the chlorides in the first step (see Fig. 12.20). Some metal sulfides (such as CuS, HgS, and Sb2S3) have extremely small solubility products and precipitate if there is the merest trace of S2Ϫ ions in the solution. Such a very low concentration of S2Ϫ ions is achieved by adding hydrogen sulfide, H2S, to an acidified solution. A higher hydronium ion concentration shifts the equilibrium H2S(aq) ϩ 2 H2O(l) #¢4 2 H3Oϩ (aq) ϩ S2Ϫ (aq) to the left, which ensures that almost all the H2S is in its fully protonated form and hence that very little S2Ϫ is present. Nevertheless, even that very low concentration will result in the precipitation of highly insoluble solids if the appropriate cations are present. To verify the presence of Zn2ϩ ions in the solution remaining after the first two steps, we add H2S followed by ammonia. The base removes the hydronium ion from the H2S equilibrium, which shifts the equilibrium in favor of S2Ϫ ions. The higher concentration of S2Ϫ ions increases the Qsp values of any remaining metal sulfides, such as ZnS or MnS, above their Ksp values, and they precipitate. Qualitative analysis involves the separation and identification of ions by selective precipitation, complex formation, and the control of pH. ¡ ¡ 508 CHAPTER 12 AQUEOUS EQUILIBRIA FIGURE 12.22 When ammonia is added to a silver chloride precipitate, the precipitate dissolves. However, when ammonia is added to a precipitate of mercury(I) chloride, mercury metal and mercury(II) ions are formed in a redox reaction and the mass turns gray. Left to right: silver chloride in water, silver chloride in aqueous ammonia, mercury(I) chloride in water, and mercury(I) chloride in aqueous ammonia. ❑ 1 Calculate the pH of a buffer solution (Example 12.1). ❑ 2 Calculate the pH change when acid or base is added to a buffer solution (Example 12.2). ❑ 3 Specify the composition of a buffer solution with a given pH (Example 12.3). ❑ 4 Interpret the features of the pH curve for the titration of a strong or weak acid with a strong base and a strong or weak base with a strong acid (Sections 12.4 and 12.5). ❑ 5 Calculate the pH at any point in a strong base–strong acid titration (Toolbox 12.1 and Example 12.4). ❑ 6 Calculate the pH at any point in a strong base–weak acid and weak base–strong acid titration (Toolbox 12.2 and Examples 12.5 and 12.6). ❑ 7 Select an appropriate indicator for a given titration (Section 12.6). ❑ 8 Identify the primary species in solution and the principal proton transfer equilibrium at any point in the titration of a polyprotic acid (Self-Test 12.9). ❑ 9 Estimate a solubility product from molar solubility and vice versa (Examples 12.7 and 12.8). ❑ 10 Describe the common-ion effect and assess its magnitude (Example 12.9). ❑ 11 Predict whether a salt will precipitate given the concentrations of its ions in water (Example 12.10). ❑ 12 Predict the order of precipitation of a series of salts (Example 12.11). ❑ 13 Calculate molar solubility in the presence of complex ion formation (Example 12.12). ❑ 14 Use a simple qualitative analysis scheme and justify the steps in terms of solubility equilibria (Section 12.14). SKILLS YOU SHOULD HAVE MASTERED EXERCISES 509 The values of Ka and Kb for weak acids and bases may be found in Tables 11.1 and 11.2. Mixed Solutions and Buffers 12.1 Explain what happens to (a) the concentration of H3Oϩ ions in an acetic acid solution when solid sodium acetate is added; (b) the percentage deprotonation of benzoic acid in a benzoic acid solution when hydrochloric acid is added; (c) the pH of the solution when solid ammonium chloride is added to aqueous ammonia. 12.2 Explain what happens to (a) the pH of a solution of phosphoric acid after the addition of solid sodium dihydrogen phosphate; (b) the percentage deprotonation of HCN in a hydrocyanic acid solution after the addition of hydrobromic acid; (c) the concentration of H3Oϩ ions when pyridinium chloride is added to an aqueous solution of the base pyridine. 12.3 A solution of equal concentrations of glyceric acid and sodium glycerate was found to have pH ϭ 3.52. (a) What are pKa and Ka for glyceric acid? (b) What would the pH be if the concentration of acid was twice that of the salt? 12.4 A solution of equal concentrations of barbituric acid and sodium barbiturate was found to have pH ϭ 4.01. (a) What are the values of pKa and Ka of barbituric acid? (b) What would the pH be if the concentration of acid was twice that of the salt? 12.5 What is the concentration of hydronium ions in (a) a solution that is 0.075 M HCN(aq) and 0.060 M NaCN(aq); (b) a solution that is 0.20 M NH2NH2(aq) and 0.30 M NaCl(aq); (c) a solution that is 0.015 M HCN(aq) and 0.030 M NaCN(aq); (d) a solution that is 0.125 M NH2NH2(aq) and 0.125 M NH2NH3Br(aq)? 12.6 What is the concentration of hydronium ions in (a) a solution that is 0.12 M HBrO(aq) and 0.160 M NaBrO(aq); (b) a solution that is 0.250 M CH3NH2(aq) and 0.150 M CH3NH3Cl(aq); (c) a solution that is 0.160 M HBrO(aq) and 0.320 M NaBrO(aq); (d) a solution that is 0.250 M CH3NH2(aq) and 0.250 M NaBr(aq)? 12.7 Determine the pH and pOH of (a) a solution that is 0.50 M NaHSO4(aq) and 0.25 M Na2SO4(aq); (b) a solution that is 0.50 M NaHSO4(aq) and 0.10 M Na2SO4(aq); (c) a solution that is 0.50 M NaHSO4(aq) and 0.50 M Na2SO4(aq). 12.8 Calculate the pH and pOH of (a) a solution that is 0.17 M Na2HPO4(aq) and 0.25 M Na3PO4(aq); (b) a solution that is 0.66 M Na2HPO4(aq) and 0.42 M Na3PO4(aq); (c) a solution that is 0.12 M Na2HPO4(aq) and 0.12 M Na3PO4(aq). 12.9 Calculate the pH of the solution that results from mixing (a) 30.0 mL of 0.050 M HCN(aq) with 70.0 mL of 0.030 M NaCN(aq); (b) 40.0 mL of 0.030 M HCN(aq) with 60.0 mL of 0.050 M NaCN(aq); (c) 25.0 mL of 0.105 M HCN(aq) with 25.0 mL of 0.105 M NaCN(aq). 12.10 Calculate the pH of the solution that results from mixing (a) 0.200 L of 0.050 M (CH3)2NH(aq) with 0.320 L of 0.040 M (CH3)2NH2Cl(aq); (b) 72.0 mL of 0.015 M (CH3)2NH(aq) with 20.0 mL of 0.200 M (CH3)2NH2Cl(aq); (c) 150.0 mL of 0.060 M (CH3)2NH(aq) with 30.0 mL of 0.080 M (CH3)2NH2Cl(aq). 12.11 A buffer solution of volume 100.0 mL is 0.100 M CH3COOH(aq) and 0.100 M NaCH3CO2(aq). (a) What are the pH and the pH change resulting from the addition of 10.0 mL of 0.950 M NaOH(aq) to the buffer solution? (b) What are the pH and the pH change resulting from the addition of 20.0 mL of 0.100 M HNO3(aq) to the initial buffer solution? 12.12 A buffer solution of volume 100.0 mL is 0.150 M Na2HPO4(aq) and 0.100 M KH2PO4(aq). (a) What are the pH and the pH change resulting from the addition of 80.0 mL of 0.0100 M NaOH(aq) to the buffer solution? (b) What are the pH and the pH change resulting from the addition of 10.0 mL of 1.0 M HNO3(aq) to the initial buffer solution? 12.13 The pH of 0.40 M HF(aq) is 1.93. Calculate the change in pH when 0.356 g of sodium fluoride is added to 50.0 mL of the solution. Ignore any change in volume. 12.14 The pH of 0.50 M HBrO(aq) is 4.50. Calculate the change in pH when 6.80 g of sodium hypobromite is added to 100. mL of the solution. Ignore any change in volume. 12.15 Sodium hypochlorite, NaClO, is the active ingredient in many bleaches. Calculate the ratio of the concentrations of ClOϪ and HClO in a bleach solution having a pH adjusted to 6.50 by the use of strong acid or strong base. 12.16 Aspirin (shown here as acetylsalicylic acid, Ka ϭ 3.2 ϫ 10Ϫ4 ) is a product of the reaction of salicylic acid with acetic anhydride. Calculate the ratio of the concentrations of the acetylsalicylate ion to acetylsalicylic acid in a solution that has a pH adjusted to 4.13 by the use of strong acid or strong base. 12.17 Predict the pH region in which each of the following buffers will be effective, assuming equal molarities of the acid and its conjugate base: (a) sodium lactate and lactic acid; (b) sodium benzoate and benzoic acid; (c) potassium hydrogen phosphate and potassium phosphate; (d) potassium hydrogen phosphate and potassium dihydrogen phosphate; (e) hydroxylamine and hydroxylammonium chloride. 12.18 Predict the pH region in which each of the following buffers will be effective, assuming equal molarities of the acid and its conjugate base: (a) sodium nitrite and nitrous acid; (b) sodium formate and formic acid; (c) sodium carbonate and sodium hydrogen carbonate; (d) ammonia and ammonium chloride; (e) pyridine and pyridinium chloride. 12.19 Use Tables 11.1, 11.2, and 11.9 to suggest a conjugate acid–base system that would be an effective buffer at a pH close to (a) 2; (b) 7; (c) 3; (d) 12. 12.20 Use Tables 11.1, 11.2, and 11.9 to suggest a conjugate acid– base system that would be an effective buffer at a pH close to (a) 4; (b) 9; (c) 5; (d) 11. Acetylsalicylic acid COOH O O CH3 OH Salicylic acid COOH EXERCISES 510 CHAPTER 12 AQUEOUS EQUILIBRIA 12.21 (a) What must be the ratio of the concentrations of CO3 2Ϫ and HCO3 Ϫ ions in a buffer solution having a pH of 11.0? (b) What mass of K2CO3 must be added to 1.00 L of 0.100 M KHCO3(aq) to prepare a buffer solution with a pH of 11.0? (c) What mass of KHCO3 must be added to 1.00 L of 0.100 M K2CO3(aq) to prepare a buffer solution with a pH of 11.0? (d) What volume of 0.200 M K2CO3(aq) must be added to 100. mL of 0.100 M KHCO3(aq) to prepare a buffer solution with a pH of 11.0? 12.22 (a) What must be the ratio of the molarities of PO4 3Ϫ and HPO4 2Ϫ ions in a buffer solution having a pH of 12.0? (b) What mass of K3PO4 must be added to 1.00 L of 0.100 M K2HPO4(aq) to prepare a buffer solution with a pH of 12.0? (c) What mass of K2HPO4 must be added to 1.00 L of 0.100 M K3PO4(aq) to prepare a buffer solution with a pH of 12.0? (d) What volume of 0.150 M K3PO4(aq) must be added to 50.0 mL of 0.100 M K2HPO4(aq) to prepare a buffer solution with a pH of 12.0? Titrations 12.23 (a) Sketch the titration curve for the titration of 5.00 mL 0.010 M NaOH(aq) with 0.005 M HCl(aq), indicating the pH of the initial and final solutions and the pH at the stoichiometric point. What volume of HCl has been added at (b) the stoichiometric point; (c) the halfway point of the titration? 12.24 (a) Sketch the titration curve for the titration of 5.00 mL 0.010 M HCl(aq) with 0.010 M Ca(OH)2(aq), indicating the pH of the initial and final solutions and the pH at the stoichiometric point. What volume of titrant has been added at (b) the stoichiometric point; (c) the halfway point of the titration? 12.25 Calculate the volume of 0.150 M HCl(aq) required to neutralize (a) one-half and (b) all the hydroxide ions in 25.0 mL of 0.110 M NaOH(aq). (c) What is the molarity of Naϩ ions at the stoichiometric point? (d) Calculate the pH of the solution after the addition of 20.0 mL of 0.150 M HCl(aq) to 25.0 mL of 0.110 M NaOH(aq). 12.26 Calculate the volume of 0.125 M HCl(aq) required to neutralize (a) one-half and (b) all the hydroxide ions in 25.0 mL of 0.305 M KOH(aq). (c) What is the molarity of ClϪ ions at the stoichiometric point? (d) Calculate the pH of the solution after the addition of 35.0 mL of 0.125 M HCl(aq) to 25.0 mL of 0.305 M KOH(aq). 12.27 Suppose that 4.25 g of an unknown monoprotic weak acid, HA, is dissolved in water. Titration of the solution with 0.350 M NaOH(aq) required 52.0 mL to reach the stoichiometric point. After the addition of 26.0 mL, the pH of the solution was found to be 3.82. (a) What is the molar mass of the acid? (b) What is the value of pKa for the acid? 12.28 Suppose that 0.483 g of an unknown monoprotic weak acid, HA, is dissolved in water. Titration of the solution with 0.250 M NaOH(aq) required 42.0 mL to reach the stoichiometric point. After the addition of 21.0 mL, the pH of the solution was found to be 3.75. (a) What is the molar mass of the acid? (b) What is the value of pKa for the acid? Can you identify the acid? 12.29 Calculate the pH at each stage in the titration for the addition of 0.150 M HCl(aq) to 25.0 mL of 0.110 M NaOH(aq): (a) initially; (b) after the addition of 5.0 mL of acid; (c) after the addition of a further 5.0 mL; (d) at the stoichiometric point; (e) after the addition of 5.0 mL of acid beyond the stoichiometric point; (f) after the addition of 10.0 mL of acid beyond the stoichiometric point. 12.30 Calculate the pH at each stage in the titration in which 0.116 M HCl(aq) is added to 25.0 mL of 0.215 M KOH(aq): (a) initially; (b) after the addition of 5.0 mL of acid; (c) after the addition of a further 5.0 mL; (d) at the stoichiometric point; (e) after the addition of 5.0 mL of acid beyond the stoichiometric point; (f) after the addition of 10.0 mL of acid beyond the stoichiometric point. 12.31 Suppose that 1.436 g of impure sodium hydroxide is dissolved in 300. mL of aqueous solution and that 25.00 mL of this solution is titrated to the stoichiometric point with 34.20 mL of 0.0695 M HCl(aq). What is the percentage purity of the original sample? 12.32 Suppose that 1.652 g of impure barium hydroxide is dissolved in enough water to produce 200. mL of solution and that 25.0 mL of this solution is titrated to the stoichiometric point with 14.7 mL of 0.0825 M HCl(aq). What is the percentage purity of the original sample? 12.33 Suppose that 25.0 mL of 0.10 M CH3COOH(aq) is titrated with 0.10 M NaOH(aq). (a) What is the initial pH of the 0.10 M CH3COOH(aq) solution? (b) What is the pH after the addition of 10.0 mL of 0.10 M NaOH(aq)? (c) What volume of 0.10 M NaOH(aq) is required to reach halfway to the stoichiometric point? (d) Calculate the pH at that halfway point. (e) What volume of 0.10 M NaOH(aq) is required to reach the stoichiometric point? (f) Calculate the pH at the stoichiometric point. 12.34 Suppose that 30.0 mL of 0.20 M C6H5COOH(aq) is titrated with 0.30 M KOH(aq). (a) What is the initial pH of the 0.20 M C6H5COOH(aq)? (b) What is the pH after the addition of 15.0 mL of 0.30 M KOH(aq)? (c) What volume of 0.30 M KOH(aq) is required to reach halfway to the stoichiometric point? (d) Calculate the pH at the halfway point. (e) What volume of 0.30 M KOH(aq) is required to reach the stoichiometric point? (f) Calculate the pH at the stoichiometric point. 12.35 Suppose that 15.0 mL of 0.15 M NH3(aq) is titrated with 0.10 M HCl(aq). (a) What is the initial pH of the 0.15 M NH3(aq)? (b) What is the pH after the addition of 15.0 mL of 0.10 M HCl(aq)? (c) What volume of 0.10 M HCl(aq) is required to reach halfway to the stoichiometric point? (d) Calculate the pH at the halfway point. (e) What volume of 0.10 M HCl(aq) is required to reach the stoichiometric point? (f) Calculate the pH at the stoichiometric point. (g) Use Table 12.3 to select an indicator for the titration. 12.36 Suppose that 50.0 mL of 0.25 M CH3NH2(aq) is titrated with 0.35 M HCl(aq). (a) What is the initial pH of the 0.25 M CH3NH2(aq)? (b) What is the pH after the addition of 15.0 mL of 0.35 M HCl(aq)? (c) What volume of 0.35 M HCl(aq) is required to reach halfway to the stoichiometric point? (d) Calculate the pH at the halfway point. (e) What volume of 0.35 M HCl(aq) is required to reach the stoichiometric point? (f) Calculate the pH at the stoichiometric point. (g) Use Table 12.3 to select an indicator for the titration. 12.37 Following is the titration curve for the neutralization of 25 mL of a monoprotic acid with a strong base. Answer the following questions about the reaction and explain your reasoning in each case. (a) Is the acid strong or weak? (b) What is the initial hydronium ion concentration of the acid? (c) What is Ka for the acid? (d) What is the initial concentration of the acid? (e) What is the concentration of base in the titrant? (f) Use Table 12.3 to select an indicator for the titration. EXERCISES 511 12.38 Below is the titration curve for the neutralization of 25 mL of a base with a strong monoprotic acid. Answer the following questions about the reaction and explain your reasoning in each case. (a) Is the base strong or weak? (b) What is the initial hydroxide ion concentration of the base? (c) What is Kb for the base? (d) What is the initial concentration of the base? (e) What is the concentration of acid in the titrant? (f) Use Table 12.3 to select an indicator for the titration. 12.39 Which of the following indicators (see Table 12.3) could you use for a titration of 0.20 M CH3COOH(aq) with 0.20 M NaOH(aq): (a) methyl orange; (b) litmus; (c) thymol blue; (d) phenolphthalein? Explain your selections. 12.40 Which of the following indicators (see Table 12.3) could you use for a titration of 0.20 M NH3(aq) with 0.20 M HCl(aq): (a) bromocresol green; (b) methyl red; (c) phenol red; (d) thymol blue? Explain your selections. 12.41 Use Table 12.3 to suggest suitable indicators for the titrations described in Exercises 12.33 and 12.35. 12.42 Use Table 12.3 to suggest suitable indicators for the titrations described in Exercises 12.34 and 12.36. Polyprotic Acid Titrations 12.43 What volume of 0.275 M KOH(aq) must be added to 75.0 mL of 0.137 M H3AsO4(aq) to reach (a) the first stoichiometric point; (b) the second stoichiometric point; (c) the third stoichiometric point? 12.44 What volume of 0.123 M NaOH(aq) must be added to 125 mL of 0.197 M H2SO3(aq) to reach (a) the first stoichiometric point; (b) the second stoichiometric point? 12.45 What volume of 0.255 M HNO3(aq) must be added to 35.5 mL of 0.158 M Na2HPO3(aq) to reach (a) the first stoichiometric point; (b) the second stoichiometric point? 12.46 What volume of 0.0848 M HCl(aq) must be added to 88.8 mL of 0.233 M Na3PO4(aq) to reach (a) the first stoichiometric point; (b) the second stoichiometric point; (c) the third stoichiometric point? 12.47 (a) Sketch the titration curve for the titration of 5.00 mL 0.010 M H2S2O3(aq) with 0.010 M KOH(aq), identifying the initial and final points, the stoichiometric points, and each of the halfway points. (b) What volume of KOH has been added at each stoichiometric point? (c) Determine the pH at each stoichiometric point. For H2S2O3(aq), pKa1 ϭ 0.6 and pKa2 ϭ 1.74. 12.48 (a) Sketch the titration curve for the titration of 5.00 mL 0.010 M H3AsO4(aq) with 0.010 M KOH(aq), identifying the initial and final points, the stoichiometric points, and each of the halfway points. (b) What volume of KOH has been added at each stoichiometric point? (c) Determine the pH at each stoichiometric point. For H3AsO4(aq), pKa1 ϭ 2.25 and pKa2 ϭ 6.77. 12.49 Suppose that 0.122 g of phosphorous acid, H3PO3, is dissolved in water and that the total volume of the solution is 50.0 mL. (a) Estimate the pH of this solution. (b) Estimate the pH of the solution that results when 5.00 mL of 0.175 M NaOH(aq) is added to the phosphorous acid solution. (c) Estimate the pH of the solution if an additional 5.00 mL of 0.175 M NaOH(aq) is added to the solution in part (b). 12.50 Suppose that 0.242 g of oxalic acid, (COOH)2, is dissolved in 50.0 mL of water. (a) Estimate the pH of this solution. (b) Estimate the pH of the solution that results when 15.0 mL of 0.150 M NaOH(aq) is added to the oxalic acid solution. (c) Estimate the pH of the solution that results if an additional 5.00 mL of NaOH(aq) solution is added to the solution from part (b). 12.51 Estimate the pH of the solution that results when each of the following solutions is added to 50.0 mL of 0.275 M Na2HPO4(aq): (a) 50.0 mL of 0.275 M HCl(aq); (b) 75.0 mL of 0.275 M HCl(aq); (c) 25.0 mL of 0.275 M HCl(aq). 12.52 Estimate the pH of the solution that results when 75.0 mL of 0.0995 M Na2CO3(aq) is mixed with (a) 25.0 mL of 0.130 M HNO3(aq); (b) 65.0 mL of 0.130 M HNO3(aq). Solubility Equilibria The values for the solubility products of some sparingly soluble salts are listed in Table 12.4. 12.53 Determine Ksp for each of the following sparingly soluble substances, given their molar solubilities: (a) AgBr, 8.8 ϫ 10Ϫ7 molиLϪ1 ; (b) PbCrO4, 1.3 ϫ 10Ϫ7 molиLϪ1 ; (c) Ba(OH)2, 0.11 molиLϪ1 ; (d) MgF2, 1.2 ϫ 10Ϫ3 molиLϪ1 . For the purpose of this calculation, ignore any reaction of the anion with water and the autoprotolysis of water. 12.54 Determine Ksp for each of the following sparingly soluble compounds, given their molar solubilities: (a) AgI, 9.1 ϫ 10Ϫ9 molиLϪ1 ; (b) Ca(OH)2, 0.011 molиLϪ1 ; (c) Ag3PO4, 2.7 ϫ 10Ϫ6 molиLϪ1 ; (d) Hg2Cl2, 5.2 ϫ 10Ϫ7 mol·LϪ1 . For the purpose of this calculation, ignore any reaction of the anion with water and the autoprotolysis of water. 12.55 The molarity of CrO4 2Ϫ in a saturated Tl2CrO4 solution is 6.3 ϫ 10Ϫ5 molиLϪ1 . What is the Ksp of Tl2CrO4? 12.56 The molar solubility of cerium(III) hydroxide, Ce(OH)3, is 5.2 ϫ 10Ϫ6 molиLϪ1 . What is the Ksp of cerium(III) hydroxide? For the purpose of this calculation, ignore the autoprotolysis of water. 0 0 5 10 Volume of basic solution (mL) 15 20 2 4 6 pH 8 10 12 14 0 0 5 10 Volume of basic solution (mL) 15 20 2 4 6 pH 8 10 12 14 512 CHAPTER 12 AQUEOUS EQUILIBRIA 12.57 Calculate the molar solubility in water of (a) BiI3 (Ksp ϭ 7.71 ϫ 10Ϫ19 ); (b) CuCl; (c) CaCO3. For the purpose of this calculation, ignore any reaction of the anion with water. 12.58 Calculate the molar solubility in water of (a) PbBr2; (b) Ag2CO3; (c) Fe(OH)2. For the purpose of this calculation, ignore any reaction of the anion with water and the autoprotolysis of water. 12.59 Use the data in Table 12.4 to calculate the molar solubility of each sparingly soluble substance in its respective solution: (a) silver chloride in 0.20 M NaCl(aq); (b) mercury(I) chloride in 0.150 M NaCl(aq); (c) lead(II) chloride in 0.025 M CaCl2(aq); (d) iron(II) hydroxide in 2.5 ϫ 10Ϫ3 M FeCl2(aq). For the purpose of this calculation, ignore the autoprotolysis of water. 12.60 Use the data in Table 12.4 to calculate the solubility of each sparingly soluble substance in its respective solution: (a) silver bromide in 0.040 M NaBr(aq); (b) magnesium carbonate in 2.0 ϫ 10Ϫ3 M Na2CO3(aq); (c) lead(II) sulfate in 0.15 M Na2SO4(aq); (d) nickel(II) hydroxide in 0.215 M NiSO4(aq). For the purpose of this calculation, ignore the autoprotolysis of water. 12.61 Use the data in Table 12.4 to calculate the solubility of each of the following sparingly soluble substances in its respective solution: aluminum hydroxide at (a) pH ϭ 7.0; (b) pH ϭ 4.5; zinc hydroxide at (c) pH ϭ 7.0; (d) pH ϭ 6.0. 12.62 Use the data in Table 12.4 to calculate the solubility of each of the following sparingly soluble compounds in its respective solution: iron(III) hydroxide at (a) pH ϭ 11.0; (b) pH ϭ 3.0; iron(II) hydroxide at (c) pH ϭ 8.0; (d) pH ϭ 6.0. 12.63 (a) What molarity of Agϩ ions is required for the formation of a precipitate in 1.0 ϫ 10Ϫ5 M NaCl(aq)? (b) What mass (in micrograms) of solid AgNO3 needs to be added for the onset of precipitation in 100. mL of the solution in part (a)? 12.64 Iodide ions can be used to precipitate lead(II) ions from 0.0030 M Pb(NO3)2(aq). (a) What minimum iodide ion concentration is required for the onset of PbI2 precipitation? (b) What mass (in grams) of KI must be added for PbI2 to form? 12.65 Determine the pH required for the onset of precipitation of Ni(OH)2 from (a) 0.060 M NiSO4(aq); (b) 0.030 M NiSO4(aq). 12.66 Decide whether a precipitate will form when each of the following pairs of solutions are mixed: (a) 5.0 mL of 0.10 M K2CO3(aq) and 1.00 L of 0.010 M AgNO3(aq); (b) 3.3 mL of 1.0 M HCl(aq), 4.9 mL of 0.0030 M AgNO3(aq), and enough water to dilute the solution to 50.0 mL. For the purpose of this calculation, ignore any reaction of the anion with water. 12.67 Suppose that there are typically 20 average-sized drops in 1.0 mL of an aqueous solution. Will a precipitate form when 1 drop of 0.010 M NaCl(aq) is added to 10.0 mL of (a) 0.0040 M AgNO3(aq); (b) 0.0040 M Pb(NO3)2(aq)? 12.68 Assume 20 drops per milliliter. Will a precipitate form if (a) 7 drops of 0.0029 M K2CO3(aq) are added to 25.0 mL of 0.0018 M CaCl2(aq); (b) 10 drops of 0.010 M Na2CO3(aq) are added to 10.0 mL of 0.0040 M AgNO3(aq)? For the purpose of this calculation, ignore any reaction of the anion with water. 12.69 The concentrations of magnesium, calcium, and nickel(II) ions in an aqueous solution are 0.0010 mol·LϪ1 . (a) In what order do they precipitate when solid KOH is added? (b) Determine the pH at which each salt precipitates. 12.70 Suppose that two hydroxides, MOH and MЈ(OH)2, both have Ksp ϭ 1.0 ϫ 10Ϫ12 and that initially both cations are present in a solution at concentrations of 0.0010 mol·LϪ1 . Which hydroxide precipitates first, and at what pH, when solid NaOH is added? 12.71 We wish to separate magnesium ions and barium ions by selective precipitation. Which anion, fluoride or carbonate, would be the better choice for achieving this precipitation? Why? 12.72 We wish to separate barium ions from calcium ions by selective precipitation. Which anion, fluoride or carbonate, would be the better choice for achieving this precipitation? Why? 12.73 In the process of separating Pb2ϩ ions from Cu2ϩ ions as sparingly soluble iodates, what is the Pb2ϩ concentration when Cu2ϩ just begins to precipitate as sodium iodate is added to a solution that is initially 0.0010 M Pb(NO3)2(aq) and 0.0010 M Cu(NO3)2(aq)? 12.74 A chemist attempts to separate barium ions from lead ions by using the sulfate ion as a precipitating agent. (a) What sulfate ion concentrations are required for the precipitation of BaSO4 and PbSO4 from a solution containing 0.010 M Ba2ϩ (aq) and 0.010 M Pb2ϩ (aq)? (b) What is the concentration of barium ions when the lead sulfate begins to precipitate? 12.75 Consider the two equilibria CaF2(s) #¢4 Ca2ϩ (aq) ϩ 2 FϪ (aq) Ksp ϭ 4.0 ϫ 10Ϫ11 FϪ (aq) ϩ H2O(l) #¢4 HF(aq) ϩ OHϪ (aq) Kb(FϪ ) ϭ 2.9 ϫ 10Ϫ11 (a) Write the chemical equation for the overall equilibrium and determine the corresponding equilibrium constant. Determine the solubility of CaF2 at (b) pH ϭ 7.0; (c) pH ϭ 3.0. 12.76 Consider the two equilibria BaF2(s) #¢4 Ba2ϩ (aq) ϩ 2 FϪ (aq) Ksp ϭ 1.7 ϫ 10Ϫ6 FϪ (aq) ϩ H2O(l) #¢4 HF(aq) ϩ OHϪ (aq) Kb(FϪ ) ϭ 2.9 ϫ 10Ϫ11 (a) Write the chemical equation for the overall equilibrium and determine the corresponding equilibrium constant. Determine the solubility of BaF2 at (b) pH ϭ 7.0; (c) pH ϭ 5.0. 12.77 Calculate the solubility of silver bromide in 0.10 M KCN(aq). Refer to Tables 12.4 and 12.5. 12.78 Precipitated silver chloride dissolves in ammonia solutions as a result of the formation of Ag(NH3)2 ϩ . What is the solubility of silver chloride in 1.0 M NH3(aq)? Refer to Tables 12.4 and 12.5. 12.79 You find a bottle of a pure silver halide that could be AgCl or AgI. Develop a simple chemical test that would allow you to distinguish which compound was in the bottle. 12.80 Which of the following compounds, if either, will dissolve in 1.00 M HNO3(aq): (a) Bi2S3(s); (b) FeS(s)? Substantiate your answer by giving an appropriate calculation. 12.81 A metal alloy sample is believed to contain silver, bismuth, and nickel. Explain how it could be determined qualitatively that all three of these metals are present. 12.82 Zinc(II) readily forms the complex ion Zn(OH)4 2Ϫ . Explain how this fact can be used to distinguish a solution of ZnCl2 from MgCl2. EXERCISES 513 Integrated Exercises 12.83 A buffer solution containing equal amounts of acetic acid and sodium acetate is prepared. What concentration of the buffer must be prepared to prevent a change in the pH by more than 0.20 pH units after the addition of 1.00 mL of 6.00 M HCl(aq) to 100.0 mL of the buffer solution? 12.84 You require 0.150 L of a buffer with pH ϭ 3.00. On the shelf is a bottle of trichloracetic acid/sodium trichloracetate buffer with pH ϭ 2.95. The label also says [trichloracetate ion] ϭ 0.200 M. What mass of which substance (trichloracetic acid or sodium trichloracetate) should you add to 0.150 L of the buffer to obtain the desired pH? 12.85 Malonic acid, HOOCCH2COOH, a diprotic acid with pKa1 ϭ 2.8 and pKa2 ϭ 5.7, is titrated with KOH(aq). (a) What is the pH when [HOOCCH2COOH] ϭ [HOOCCH2CO2 Ϫ ]? (b) What is the pH when [HOOCCH2CO2 Ϫ ] ϭ [Ϫ O2CCH2CO2 Ϫ ]? (c) Which is the predominant species at pH ϭ 4.2? 12.86 A species that can accept two protons is classified as dibasic. The dibasic molecule 1,2-ethanediamine, H2NC2H4NH2, which has pKb1 ϭ 3.19 and pKb2 ϭ 6.44, is titrated with HCl(aq). (a) What is the pH when [H2NC2H4NH2] ϭ [H2NC2H4NH3 ϩ ]? (b) What is the pH when [H2NC2H4NH3 ϩ ] ϭ [ϩ H3NC2H4NH3 ϩ ]? (c) Which is the predominant species at pH ϭ 4.8? 12.87 Novocaine, which is used by dentists as a local anesthetic, is a weak base with pKb ϭ 5.05. Blood has a pH of 7.4. What is the ratio of the concentration of novocaine to that of its conjugate acid in the bloodstream? 12.88 To simulate blood conditions, a phosphate buffer system with a pH ϭ 7.40 is desired. What mass of Na2HPO4 must be added to 0.500 L of 0.10 M NaH2PO4(aq) to prepare such a buffer? 12.89 A buffer is prepared by adding 55.0 mL of 0.15 M HNO3(aq) to 45.0 mL of 0.65 M NaC6H5CO2(aq). Determine the solubility of PbF2 in this buffer solution. 12.90 A buffer is prepared by adding 25.0 mL of 0.12 M HCl(aq) to 55.0 mL of 0.52 M NaCH3CO2(aq). What is the solubility of BaF2 in this buffer solution? 12.91 For some diprotic acids, such as oxalic acid, the titration curve has two distinct stoichiometric points, but in other cases, such as tartaric acid, only one stoichiometric point, with a rise that is not very steep, can be observed. Explain the differences in these two titration curves. 12.92 A 25.0-mL sample of 0.150 M Na2CO3(aq) is titrated with 0.100 M HCl(aq). What is the pH of the solution at each stoichiometric point in the titration? 12.93 Which sulfide precipitates first when sulfide ions are added to a solution containing equal concentrations of Co2ϩ , Cu2ϩ , and Cd2ϩ ? For CoS, Ksp ϭ 5 ϫ 10Ϫ22 . Explain your conclusions. 12.94 You decide to use sulfide precipitation to separate the copper(II) ions from the manganese(II) ions in a solution that is 0.20 M Cu2ϩ (aq) and 0.20 M Mn2ϩ (aq). Determine the minimum sulfide ion concentration that will result in the precipitation of one cation (identify the cation) but not the other. 12.95 In a precipitation titration the concentration of an ion is measured as it forms a precipitate. For example, the concentration of CO3 2Ϫ ions in a 25.0-mL sample was determined by titrating with 0.110 M AgNO3(aq). Before the stoichiometric point, the Agϩ ions react immediately with the CO3 2Ϫ ions, but after the stoichiometric point the concentration of Agϩ ion increases rapidly. (a) The stoichiometric point is reached after the addition of 36.2 mL of the AgNO3(aq). What is the concentration of CO3 2Ϫ ions in the sample? (b) The concentration of Ag ion is followed by using a special electrode and measuring pAg (–log [Agϩ ]). Sketch the plot of pAg against volume of AgNO3(aq) and determine the value of pAg at the stoichiometric point. 12.96 What volume (in liters) of a saturated mercury(II) sulfide, HgS, solution contains an average of one mercury(II) ion, Hg2ϩ ? 12.97 In an attempt to determine the concentration of sulfur dioxide in the air near a power plant, two students set up a bubbler that passes air through 50.00 mL of 1.0 ϫ 10Ϫ4 M NaOH(aq). The temperature is 22°C, and the atmospheric pressure 753 Torr. The air is pumped for 2.5 h at a flow rate of 3.0 L·hϪ1 . The students then returned to the laboratory and titrated the solution with 1.5 ϫ 10Ϫ4 M HCl(aq) with phenolphthalein indicator to see how much NaOH was left unreacted. They found that 30.2 mL of HCl(aq) was required to reach the stoichiometric point. (a) Write the balanced chemical equation for the reaction of SO2 and water. (b) What amount of NaOH (in mol) had reacted with the SO2? (c) What was the concentration of sulfur dioxide in the air, in parts per million? 12.98 Consider the equilibria ZnS(s) #¢4 Zn2ϩ (aq) ϩ S2Ϫ (aq) S2Ϫ (aq) ϩ H2O(l) #¢4 HSϪ (aq) ϩ OHϪ (aq) HSϪ (aq) ϩ H2O(l) #¢4 H2S(aq) ϩ OHϪ (aq) Write the chemical equation for the overall equilibrium and determine the corresponding equilibrium constant. (b) Determine the solubility of ZnS in a saturated H2S solution (0.1 M H2S(aq)) adjusted to pH ϭ 7.0. (c) Determine the solubility of ZnS in a saturated H2S solution (0.1 M H2S(aq)) adjusted to pH ϭ 10.0. 12.99 Using data available in the tables and appendices, calculate the standard Gibbs free energy of formation of PbF2(s). 12.100 Silver iodide is very insoluble in water. A common method for increasing its solubility is to increase the temperature of the solution containing the solid. Estimate the solubility of AgI at 85°C. 12.101 The main buffer in the blood consists primarily of hydrogen carbonate ions (HCO3 Ϫ ) and H3Oϩ ions in equilibrium with water and CO2: H3Oϩ (aq) ϩ HCO3 Ϫ (aq) #¢4 2 H2O(l) ϩ CO2(aq) K ϭ 7.9 ϫ 10Ϫ7 This reaction assumes that all H2CO3 produced decomposes completely to CO2 and H2O. Suppose that 1.0 L of blood is removed from the body and brought to pH ϭ 6.1. (a) If the concentration of HCO3 Ϫ is 5.5 ␮molиLϪ1 , calculate the amount (in moles) of CO2 present in the solution at this pH. (b) Calculate the change in pH that occurs when 0.65 ␮mol H3Oϩ is added to this sample of blood at this pH (that is, pH ϭ 6.1). See Box 12.1. 12.102 The pH of the blood is maintained by a finely tuned buffering system, consisting primarily of hydrogen carbonate ion (HCO3 Ϫ ) and H3Oϩ in equilibrium with water and CO2. H3Oϩ (aq) ϩ HCO3 Ϫ (aq) #¢4 H2CO3(aq) ϩ H2O(l) H3Oϩ (aq) ϩ HCO3 Ϫ (aq) #¢4 2 H2O(l) ϩ CO2(g) 514 CHAPTER 12 AQUEOUS EQUILIBRIA During exercise, CO2 is produced at a rapid rate in muscle tissue. (a) How does exercise affect the pH of blood? (b) Hyperventilation (rapid and deep breathing) can occur during intense exertion. How does hyperventilation affect the pH of the blood? (c) The normal first-aid treatment for hyperventilation is to have the patient breathe into a paper bag. Explain briefly why this treatment works and tell what effect the paper-bag treatment has on the pH of the blood. See Box 12.1. 12.103 A buffer solution of volume 300.0 mL is 0.200 M CH3COOH(aq) and 0.300 M NaCH3CO2(aq). (a) What is the initial pH of this solution? (b) What mass of NaOH would have to be dissolved in this solution to bring the pH to 6.0? 12.104 A buffer solution of volume 300.0 mL is 0.400 M NH3(aq) and 0.200 M NH4Cl(aq). (a) What is the initial pH of this solution? (c) What volume of HCl gas at 2.00 atm and 25°C would have to be dissolved in this solution to bring the pH to 8.0? Chemistry Connections 12.105 Soluble nontoxic salts such as Fe2(SO4)3 are often used during water purification to remove soluble toxic contaminants, because they form gelatinous hydroxides that encapsulate the contaminants and allow them to be filtered from the water. (a) Calculate the molar solubility in water of Fe(OH)3 at 25°C. (b) What is the concentration of hydroxide ion in a saturated solution of Fe(OH)3? Calculate the pH of the solution. (c) Discuss whether your result in part (b) is reasonable for a solution of a basic hydroxide. Explain what assumptions were made in your calculations and evaluate the validity of the assumptions. (d) A simplified equation for the reaction of Fe3ϩ ions with water is Fe3ϩ (aq) ϩ 6 H2O(l) #4 Fe(OH)3(s) ϩ 3 H3Oϩ (aq). Use the data in Table 12.4 and Kw to calculate the equilibrium constant for this reaction. (e) If 10.0 g of Fe2(SO4)3 is dissolved in enough water to make up 1.00 L of aqueous solution and the pH of the solution is raised to 8.00 by addition of NaOH, what mass of solid Fe(OH)3 will form? (f) To test for the ability of Fe2(SO4)3 to remove chloride ions from water, a standard aqueous solution containing 24.72 g of NaCl in 1.000 L of solution was prepared. A 25.00-mL sample of the NaCl solution was then combined with the mixture described in part (e) and stirred. The Fe(OH)3 precipitate containing encapsulated chloride ion was removed by filtration, then dissolved in acid. An aqueous solution of AgNO3 was then added to the resulting solution and the solid AgCl formed filtered and dried. The mass of AgCl was 0.604 g. What percentage of the chloride ion in the 25.00-mL sample had been removed from the solution? What Are the Key Ideas? The tendency of electrons to be transferred in a chemical reaction depends on the species involved and their concentrations. When the process is spontaneous and reduction and oxidation occur at different locations, the reaction can do work and drive electrons through an external circuit. Why Do We Need to Know This Material? The topics described in this chapter may one day unlock a virtually inexhaustible supply of clean energy supplied daily by the Sun. The key is electrochemistry, the study of the interaction of electricity and chemical reactions. The transfer of electrons from one species to another is one of the fundamental processes underlying life, photosynthesis, fuel cells, and the refining of metals. An understanding of how electrons are transferred helps us to design ways to use chemical reactions to generate electricity and to use electricity to bring about chemical reactions. Electrochemical measurements also allow us to determine the values of thermodynamic quantities. What Do We Need to Know Already? This chapter extends the thermodynamic discussion presented in Chapter 8. In particular, it builds on the concept of Gibbs free energy (Section 8.12), its relation to maximum nonexpansion work (Section 8.14), and the dependence of the reaction Gibbs free energy on the reaction quotient (Section 10.3). For a review of redox reactions, see Section K. To prepare for the quantitative treatment of electrolysis, review stoichiometry in Section L. T he nature of electricity was unknown until the late eighteenth century, when the Italian scientist Luigi Galvani discovered that by touching the muscles of dead animals, mainly frogs, with rods bearing electric charges, he could make their muscles twitch. He believed that electricity came from the muscles themselves. However, at the end of that century another Italian, Alessandro Volta, suggested that the electricity came from the fact that the muscles were between two different metals when touched by the rods. He proved that the electricity came from metals by constructing a tower of alternating discs of different metals in layers separated by paper strips soaked in a solution of sodium chloride (Fig. 13.1). This apparatus, a “voltaic pile,” was the first electrical storage device, a simple battery, but because it opened a door to a new understanding of the structure of matter, it amazed the scientists and even the rulers of the day. Those early observations have evolved into the branch of chemistry called electrochemistry. This subject deals not only with the use of spontaneous chemical reactions to produce electricity but also with the use of electricity to drive nonspontaneous reactions forward. Electrochemistry also provides techniques for monitoring chemical reactions and for measuring properties of solutions such as the pKa of an acid and the thermodynamic characteristics of reactions. Electrochemistry even allows us to monitor the activity of our brain and heart (perhaps while we are trying to master chemistry), the pH of our blood, and the presence of pollutants in our water supply. REPRESENTING REDOX REACTIONS An electric current is the flow of electrons through a circuit. When the current is generated chemically, the electrons emerge from a location where oxidation takes place and travel to a location where reduction occurs. Because oxidation and reduction are involved in the generation of an electric current, redox reactions (Section K) are central to the discussion of electrochemistry. In this chapter we take a closer look at them and see how they and other types of reactions can be used to generate electricity. REPRESENTING REDOX REACTIONS 13.1 Half-Reactions 13.2 Balancing Redox Equations GALVANIC CELLS 13.3 The Structure of Galvanic Cells 13.4 Cell Potential and Reaction Gibbs Free Energy 13.5 The Notation for Cells 13.6 Standard Potentials 13.7 The Electrochemical Series 13.8 Standard Potentials and Equilibrium Constants 13.9 The Nernst Equation 13.10 Ion-Selective Electrodes ELECTROLYTIC CELLS 13.11 Electrolysis 13.12 The Products of Electrolysis THE IMPACT ON MATERIALS 13.13 Applications of Electrolysis 13.14 Corrosion 13.15 Practical Cells 515 Chapter 13 ELECTROCHEMISTRY For a quantitative discussion of redox reactions we need to be able to write balanced chemical equations. Some redox reactions can be tricky to balance, and special techniques, which we describe in Sections 13.1 and 13.2, have been developed to simplify the procedure. The chapter begins with a review of redox reactions, which are particularly important for understanding the chemical production of electricity, a topic that occupies the major part of this chapter. Redox reactions are also important in the final part of the chapter, which discusses the use of electricity to bring about chemical reactions. 13.1 Half-Reactions The key to writing and balancing equations for redox reactions is to think of the reduction and oxidation processes separately. We saw in Section K that oxidation is the loss of electrons and reduction the gain of electrons. A half-reaction is the oxidation or reduction part of a reaction considered alone. An oxidation half-reaction shows the removal of electrons from a species that is being oxidized in a redox reaction. For example, Volta used silver and zinc plates in one of his voltaic piles to carry out the reaction Zn(s) ϩ 2 Agϩ (aq) Zn2ϩ (aq) ϩ 2 Ag(s) To show the oxidation of zinc explicitly we write Zn(s) Zn2ϩ (s) ϩ 2 eϪ An oxidation half-reaction is a conceptual way of reporting an oxidation: the electrons are never actually free. In an equation for an oxidation half-reaction, the electrons released always appear on the right of the arrow. Their state is not given, because they are in transit and do not have a definite physical state. The reduced and oxidized species in a half-reaction jointly form a redox couple. In this example, the redox couple consists of Zn2ϩ and Zn, and is denoted Zn2ϩ /Zn. A redox couple has the form Ox/Red, where Ox is the oxidized form of the species and Red is the reduced form. A note on good practice: Distinguish a conceptual half-reaction from an actual ionization, where the electron is removed and which we would write, for example, as Na(g) : Naϩ (g) ϩ eϪ (g), with the state of the electron specified. Now consider reduction. To show the addition of electrons to a species, we write the corresponding half-reaction for electron gain. For example, to show the reduction of Agϩ ions to Ag metal we write Agϩ (aq) ϩ eϪ Ag(s) This half-reaction, too, is conceptual: the electrons are not actually free. In the equation for a reduction half-reaction, the electrons gained always appear on the left of the arrow. In this example, the redox couple is Agϩ /Ag. Half-reactions express the two contributions (oxidation and reduction) to an overall redox reaction. 13.2 Balancing Redox Equations Balancing the chemical equation for a redox reaction by inspection can be a real challenge, especially for one taking place in aqueous solution, when water may participate and we must include H2O and either Hϩ or OHϪ . In such cases, it is easier to simplify the equation by separating it into its reduction and oxidation half-reactions, balance the half-reactions separately, and then add them together to obtain the balanced equation for the overall reaction. When adding the equations for half-reactions, we match the number of electrons released by oxidation with the number used in reduction, because electrons are neither created nor destroyed in chemical reactions. The procedure is outlined in Toolbox 13.1 and illustrated in Examples 13.1 and 13.2. ¡ ¡ ¡ 516 CHAPTER 13 ELECTROCHEMISTRY FIGURE 13.1 Volta used this stack of alternating disks of two different metals separated by paper soaked in salt water to produce the first sustained electric current. In redox reactions, it is conventional to write Hϩ rather than H3Oϩ . EXAMPLE 13.1 Balancing a redox equation in acidic solution Permanganate ions, MnO4 Ϫ , react with oxalic acid, H2C2O4, in acidic aqueous solution, producing manganese(II) ions and carbon dioxide. The skeletal equation (with states added) is MnO4 Ϫ (aq) ϩ H2C2O4(aq) Mn2ϩ (aq) ϩ CO2(g) Balance the net ionic equation for this reaction. PLAN To balance the equation, work through the procedure for an acidic solution set out in Toolbox 13.1. SOLVE Reduction half-reaction: ¡ 13.2 BALANCING REDOX EQUATIONS 517 TOOLBOX 13.1 HOW TO BALANCE COMPLICATED REDOX EQUATIONS CONCEPTUAL BASIS When balancing redox equations, we express the gain of electrons (reduction) and the loss of electrons (oxidation) as separate half-reactions, and then balance both atoms and charge in each of the two half-reactions. When we combine the half-reactions, the number of electrons released in the oxidation must equal the number used in the reduction. PROCEDURE In general, first balance the half-reactions separately, then combine them. Step 1 Identify the species being oxidized and the species being reduced from the changes in their oxidation numbers. Step 2 Write the two skeletal (unbalanced) equations for the oxidation and reduction half-reactions. Step 3 Balance all elements in the half-reactions except O and H. Step 4 In acidic solution, balance O by using H2O and then balance H by using Hϩ . In basic solution, balance O by using H2O; then balance H by adding H2O to the side of each half-reaction that needs H and adding OHϪ to the other side. When we add . . . OHϪ . . . : . . . H2O . . . to a halfreaction, we are effectively adding one H atom to the right. When we add . . . H2O . . . : . . . OHϪ . . . , we are effectively adding one H atom to the left. Note that one H2O molecule is added for each H atom needed. If necessary, cancel like species on opposite sides of the arrow. Step 5 Balance the electric charges by adding electrons to the left for reductions and to the right for oxidations until the charges on the two sides of the arrow are the same. Step 6 If necessary, multiply each half-reaction by the factor required to give equal numbers of electrons in the two half-reactions, and then add the two equations and include physical states. In some cases it is possible to simplify the half-reactions before they are combined. Finally, simplify the appearance of the complete equation by canceling species that appear on both sides of the arrow and check to make sure that charges as well as numbers of atoms balance. Examples 13.1 and 13.2 illustrate this procedure. Ϫ2 Ϫ 2ϩ Ϫ2 Ϫ2 Ϫ2ϩ7 ϩ2 Step 1 Identify the species being reduced. The oxidation number of Mn decreases from ϩ7 to ϩ2, so the Mn in the MnO4 Ϫ ion is reduced. Ϫ 2ϩ Step 2 Write the skeletal equation for reduction. MnO4 Ϫ Mn2ϩ ¡ 518 CHAPTER 13 ELECTROCHEMISTRY Ϫ 2ϩ Step 4 Balance the O atoms by adding H2O. MnO4 Ϫ Mn2ϩ ϩ 4 H2O¡ Ϫ 2ϩ 8ϩ Balance the H atoms by adding Hϩ . MnO4 Ϫ ϩ 8 Hϩ Mn2ϩ ϩ 4 H2O¡ Ϫ 2ϩϩ 5 eϪ 8ϩ Step 5 Balance the net charges by adding electrons. Net charge on the left is ϩ7 and on the right ϩ2; we need 5 electrons on the left to bring it to ϩ2. MnO4 Ϫ ϩ 8 Hϩ ϩ 5 eϪ Mn2ϩ ϩ 4 H2O¡ Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2 ϩ1 ϩ3 ϩ4 ϩ3ϩ1 Step 1 Identify the species being oxidized. The oxidation number of carbon increases from ϩ3 to ϩ4, so the C atoms in the oxalic acid are oxidized. Step 2 Write the skeletal equation for the species being oxidized. H2C2O4 CO2¡ Step 3 Balance all elements except H and O. H2C2O4 2 CO2¡ Oxidation half-reaction: Ϫ 2ϩ Step 3 Balance all elements except H and O. MnO4 Ϫ Mn2ϩ ¡ A note on good practice: At this point, check that the number of electrons lost or gained in each half-reaction is the same as the change in oxidation number of the element oxidized or reduced. Now bring the two half-reactions together. 13.2 BALANCING REDOX EQUATIONS 519 Step 4 Balance the O atoms by adding H2O (none required). H2C2O4 2 CO2¡ 2ϩ Balance the H atoms by adding Hϩ . H2C2O4 2 CO2 ϩ 2 Hϩ ¡ 2 ϩ 2 eϪ ϩ 5 eϪ Ϫ 2ϩ 2ϩ 8ϩ 5 10 e Ϫ Step 6 Write the overall equation. First, balance electrons. Five electrons are gained in one half-reaction and two lost in the other, so we need 10 in each half-reaction. Multiply the reduction half-reaction by 2 and multiply the oxidation half-reaction by 5. 2 MnO4 Ϫ ϩ 16 Hϩ ϩ 10 eϪ 2 Mn2ϩ ϩ 8 H2O 5 H2C2O4 10 CO2 ϩ 10 Hϩ ϩ 10 eϪ ¡ ¡ Add the equations and cancel electrons. 2 MnO4 Ϫ ϩ 5 H2C2O4 ϩ 16 Hϩ 2 Mn2ϩ ϩ 8 H2O ϩ 10 CO2 ϩ 10 Hϩ ¡ Cancel 10 Hϩ ions on each side and include physical states. 2 MnO4 Ϫ (aq) ϩ 5 H2C2O4(aq) ϩ 6 Hϩ (aq) ∫∫B 2 Mn2ϩ (aq) ϩ 8 H2O(l) ϩ 10 CO2(g) 2ϩ ϩ 2 e Ϫ Step 5 Balance the net charges by adding electrons. Net charge on the left is 0 and on the right ϩ2; we need 2 electrons on the right to bring it to 0. H2C2O4 2 CO2 ϩ 2 Hϩ ϩ 2 eϪ ¡ Self-Test 13.1A Copper reacts with dilute nitric acid to form copper(II) nitrate and the gas nitric oxide, NO. Write the net ionic equation for the reaction. [Answer: 3 Cu(s) ϩ 2 NO3 Ϫ (aq) ϩ 8 Hϩ (aq) : 3 Cu2ϩ (aq) ϩ 2 NO(g) ϩ 4 H2O(l)] Self-Test 13.1B Acidified potassium permanganate solution reacts with sulfurous acid, H2SO3(aq), to form sulfuric acid and manganese(II) ions. Write the net ionic equation for the reaction. In acidic aqueous solution, H2SO3 is present as electrically neutral molecules and sulfuric acid is present as HSO4 Ϫ ions. 520 CHAPTER 13 ELECTROCHEMISTRY Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2 Ϫ2ϩ7 ϩ4 Ϫ Step 1 Identify the species being reduced. The oxidation number of Mn changes from ϩ7 in MnO4 Ϫ to ϩ4 in MnO2, so the Mn in MnO4 Ϫ is reduced. Ϫ Step 2 Write the skeletal equation for reduction. MnO4 Ϫ MnO2¡ Ϫ Step 3 The Mn atoms are balanced. MnO4 Ϫ MnO2¡ Ϫ Step 4 Balance the O atoms by adding H2O. MnO4 Ϫ MnO2 ϩ 2 H2O¡ Ϫ Balance the H atoms by adding (for each H atom needed) one H2O molecule to the side of each equation that needs hydrogen and one OHϪ ion to the opposite side. Here, four H atoms are needed on the left side. MnO4 Ϫ ϩ 4 H2O MnO2 ϩ 2 H2O ϩ 4 OHϪ ¡ Ϫ Cancel like species on opposite sides of the arrow (in this case, 2 H2O). MnO4 Ϫ ϩ 2 H2O MnO2 ϩ 4 OHϪ ¡ EXAMPLE 13.2 Balancing a redox equation in basic solution The products of the reaction between bromide ions and permanganate ions, MnO4 Ϫ , in basic aqueous solution are solid manganese(IV) oxide, MnO2, and bromate ions. Balance the net ionic equation for the reaction. PLAN Work through the procedure for a basic solution set out in Toolbox 13.1. SOLVE Reduction half-reaction: Oxidation half-reaction: 13.2 BALANCING REDOX EQUATIONS 521 Ϫ Ϫ Ϫ2 Ϫ2 Ϫ2 Ϫ1 ϩ5 Step 1 Identify the species being oxidized. The oxidation number of Br increases from Ϫ1 in BrϪ to ϩ5 in BrO3 Ϫ , and so BrϪ is oxidized. Ϫ Ϫ Step 2 Write the skeletal equation for oxidation. BrϪ BrO3 Ϫ ¡ Ϫ Ϫ Step 3 The Br atoms are balanced. BrϪ BrO3 Ϫ ¡ Ϫ Ϫ Step 4 Balance the O atoms by adding H2O. BrϪ ϩ 3 H2O BrO3 Ϫ ¡ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Balance the H atoms by adding (for each H atom needed) one H2O molecule to the side of each equation that needs hydrogen and one OHϪ ion to the opposite side. Here, the right side needs H atoms. BrϪ ϩ 3 H2O ϩ 6 OHϪ BrO3 Ϫ ϩ 6 H2O ¡ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Cancel like species on opposite sides of the arrow (in this case, 3 H2O). BrϪ ϩ 6 OHϪ BrO3 Ϫ ϩ 3 H2O¡ Ϫ Ϫ Ϫ Ϫ Ϫ ϩ 3 e Ϫ Step 5 Balance charge by adding electrons. Net charge on the left is Ϫ1 and on the right it is Ϫ4; we need 3 electrons on the left to bring it to Ϫ4. MnO4 Ϫ ϩ 2 H2O ϩ 3 eϪ MnO2 ϩ 4 OHϪ ¡ A note on good practice: As before, at this point check that the number of electrons lost or gained in each half-reaction is the same as the change in oxidation number of the element oxidized or reduced. Now bring the two half-reactions together. 522 CHAPTER 13 ELECTROCHEMISTRY 2 2Ϫ 6 eϪ ϩ 3 eϪ ϩ 6 eϪ ϪϪ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ ϪϪϪ Ϫ Step 6 Write the overall equation. Because 6 electrons are lost and 3 gained, we need 6 in each halfreaction. Multiply the reduction half-reaction by 2. 2 MnO4 Ϫ ϩ 4 H2O ϩ 6 eϪ 2 MnO2 ϩ 8 OHϪ The oxidation half-reaction remains unchanged. BrϪ ϩ 6 OHϪ BrO3 Ϫ ϩ 3 H2O ϩ 6 eϪ ¡ ¡ Add the equations and cancel electrons. 2 MnO4 Ϫ ϩ BrϪ ϩ 6 OHϪ ϩ 4 H2O 2 MnO2 ϩ BrO3 Ϫ ϩ 8 OHϪ ϩ 3 H2O¡ Cancel 3 H2O and 6 OHϪ , then include the physical states. 2 MnO4 Ϫ (aq) ϩ BrϪ (aq) ϩ H2O(l) 2 MnO2(s) ϩ BrO3 Ϫ (aq) ϩ 2 OHϪ (aq)¡ Self-Test 13.2A An alkaline (basic) solution of hypochlorite ions reacts with solid chromium(III) hydroxide to produce aqueous chromate ions and chloride ions. Write the net ionic equation for the reaction. [Answer: 2 Cr(OH)3(s) ϩ4 OHϪ (aq) ϩ3 ClOϪ (aq) : 2 CrO4 2Ϫ (aq) ϩ5 H2O(l) ϩ3 ClϪ (aq)] Self-Test 13.2B When iodide ions react with iodate ions in basic aqueous solution, triiodide ions, I3 Ϫ , are formed. Write the net ionic equation for the reaction. (Note that the same product is obtained in each half-reaction.) The chemical equation for a reduction half-reaction is added to the equation for an oxidation half-reaction to form the balanced chemical equation for the overall redox reaction. GALVANIC CELLS Whenever we turn on a portable media player or a laptop computer, we are completing a circuit that allows a chemical reaction to take place in a battery, a direct descendant of Volta’s pile of metals and paper. A battery is an example of an electrochemical cell. In general, an electrochemical cell is a device in which an electric current—a flow of electrons through a circuit—is either produced by a spontaneous chemical reaction or used to bring about a nonspontaneous reaction. A galvanic cell is an electrochemical cell in which a spontaneous chemical reaction is used to generate an electric current. Technically, a battery is a collection of galvanic cells joined in series; so the voltage that it produces—its ability to push an electric current through a circuit—is the sum of the voltages of each cell. 13.3 The Structure of Galvanic Cells To see how a spontaneous reaction can be used to generate an electric current consider the redox reaction between zinc metal and copper(II) ions: Zn(s) ϩ Cu2ϩ (aq) Zn2ϩ (aq) ϩ Cu(s) (A)¡ Galvanic cells are also known as voltaic cells. The formal term for “voltage” is “potential difference”, measured in volts: 1 V ‫؍‬ 1 JؒC؊1 (see Section 13.4). Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ ϩ 6 eϪStep 5 Balance charge by adding electrons. Net charge on the left is Ϫ7 and on the right it is Ϫ1; we need 6 electrons on the right to bring it to Ϫ7. BrϪ ϩ 6 OHϪ BrO3 Ϫ ϩ 3 H2O ϩ 6 eϪ ¡ If we were to place a piece of zinc metal into an aqueous copper(II) sulfate solution, we would see a layer of metallic copper begin to deposit on the surface of the zinc (as in Fig. K.5). If we could watch the reaction at the atomic level, we would see that, as the reaction takes place, electrons are transferred from the Zn atoms to adjacent Cu2ϩ ions in the solution. These electrons reduce the Cu2ϩ ions to Cu atoms, which stick to the surface of the zinc or form a finely divided solid deposit in the beaker. The piece of zinc slowly disappears and the blue color of the solution is lost as the Zn atoms give up electrons and form colorless Zn2ϩ ions that drift off into the solution, replacing the Cu2ϩ ions. The Gibbs free energy of the system decreases as electrons are transferred and the reaction approaches equilibrium. However, although energy is released as heat, no electrical work is done. Now suppose we separate the reactants but provide a pathway for the electrons to travel from the zinc metal to the copper(II) ions. The reaction will still occur, even though the reactants are not in contact. As the reaction proceeds, the electrons can do work—for example, drive an electric motor—as they pass from the species being oxidized to the species being reduced. This process is what happens in a galvanic cell. A galvanic cell consists of two electrodes, or metallic conductors, which make electrical contact with the contents of the cell but not with each other, and an electrolyte, an ionically conducting medium, inside the cell. In an ionic conductor an electric current is carried by the movement of ions. The electrolyte is typically an aqueous solution of an ionic compound. Oxidation takes place at one electrode as the species being oxidized releases electrons into the metallic conductor. Reduction takes place at the other electrode, where the species that is undergoing reduction collects electrons from the metallic conductor (Fig. 13.2). We can think of the overall chemical reaction as pushing electrons on to one electrode from the oxidation process taking place there and pulling them off the other electrode for the reduction taking place at it. This push–pull process sets up a flow of electrons in the external circuit joining the two electrodes, and that current can be used to do electrical work. The electrode at which oxidation takes place is called the anode. The electrode at which reduction takes place is called the cathode. Electrons are released by the oxidation half-reaction at the anode, travel through the external circuit, and reenter the cell at the cathode, where they are used in the reduction half-reaction. A commercial galvanic cell has its cathode marked with a ϩ sign and its anode with a Ϫ sign. Think of the ϩ sign as indicating the electrode at which the electrons enter the cell and the Ϫ sign as indicating the electrode at which the electrons leave the cell. The Daniell cell is an early example of a galvanic cell that makes use of the oxidation of copper by zinc ions, as in reaction A. The British chemist John Daniell invented it in 1836, when the growth of telegraphy created an urgent need for a cheap, reliable, steady source of electric current. Daniell set up the arrangement shown in Fig. 13.3, in which the two reactants are separated: the zinc metal is immersed in a solution of zinc sulfate and the copper electrode is immersed in a solution of copper(II) sulfate. For the electrons to travel from Zn atoms to Cu2ϩ ions and bring about the spontaneous reaction, they must pass from the zinc metal through the wire that serves as the external circuit, then through the copper electrode into the copper(II) solution. The Cu2ϩ ions are converted into Cu atoms at the cathode by the reduction half-reaction Cu2ϩ (aq) ϩ 2 eϪ : Cu(s). At the same time zinc atoms are converted into Zn2ϩ ions at the anode by the oxidation half-reaction Zn(s) : Zn2ϩ (aq) ϩ 2 eϪ . As Cu2ϩ ions are reduced, the solution at the cathode becomes negatively charged and the solution at the anode begins to develop a positive charge as additional Zn2ϩ ions enter the solution. To prevent this charge buildup, which would quickly stop the flow of electrons, the two solutions are in contact through a porous wall: ions provided by the electrolyte solutions move between the two compartments and complete the electrical circuit. The electrodes in the Daniell cell are made of the metals involved in the reaction. However, not all electrode reactions include a conducting solid as a reactant or product. For example, to use the reduction 2 Hϩ (aq) ϩ 2 eϪ : H2(g) at an electrode, a chemically inert metallic conductor, such as an unreactive metal or graphite, must carry the electrons into or out of the electrode compartment. Platinum is customarily used as the electrode for hydrogen: the gas is bubbled over the metal immersed in a solution 13.3 THE STRUCTURE OF GALVANIC CELLS 523 The term “electrolyte” was first introduced in Section I to refer to the solute. In the discussion of electrochemical cells, the term is commonly used to refer to the ionically conducting medium, which can be a liquid or solid. Electrons ϩϪ Ions Oxidation Reduction Anode Cathode ϩ Ϫ FIGURE 13.2 In an electrochemical cell, a reaction takes place in two separate regions. Oxidation takes place at one electrode (the anode), and the electrons released travel through the external circuit to the other electrode, the cathode, where they cause reduction. The circuit is completed by the ions that carry the electric charge through the solution. Animation 13.2 Porous pot ϩϪ Zinc Copper Zinc sulfate Copper(II) sulfate Zn2ϩ Cu2ϩ FIGURE 13.3 The Daniell cell consists of copper and zinc electrodes dipping into solutions of copper(II) sulfate and zinc sulfate, respectively. The two solutions make contact through the porous barrier, which allows ions to pass through and complete the electric circuit. that contains hydrogen ions. This arrangement is called a hydrogen electrode. The entire compartment with metal conductor and electrolyte solution is commonly referred to as “the electrode” or more formally as a half-cell. In a galvanic cell, a spontaneous chemical reaction draws electrons into the cell through the cathode, the site of reduction, and releases them at the anode, the site of oxidation. 13.4 Cell Potential and Reaction Gibbs Free Energy A reaction with a lot of pushing-and-pulling power generates a high potential difference (colloquially, a high voltage). A reaction with little pushing-and-pulling power generates only a small potential difference (a low voltage). An exhausted battery is a cell in which the reaction is at equilibrium; it has lost its power to move electrons and has a potential difference of zero. The SI unit of potential (and potential difference) is the volt (V). A volt is defined so that a charge of one coulomb (1 C) falling through a potential difference of one volt (1 V) releases one joule (1 J) of energy: 1 VиC ϭ 1 J To express these ideas quantitatively it is helpful to note that electrical potential is analogous to gravitational potential. The maximum work that a falling weight can do is equal to its mass times the difference in gravitational potential. Similarly, the maximum work that an electron can do is equal to its charge times the difference in electrical potential through which it falls. Electrical work is a type of nonexpansion work because it involves moving electrons rather than changing the volume of the system. In Section 8.14 we established that at constant temperature and pressure, the maximum nonexpansion work that a system can do is equal to the change in the Gibbs free energy. We need to bring these two concepts together by finding the relation between the Gibbs free energy of a reaction (a thermodynamic property) and the potential difference (an electrochemical property) produced by that reaction. 524 CHAPTER 13 ELECTROCHEMISTRY One coulomb is the magnitude of the charge delivered by a current of one ampere flowing for one second: 1 C ‫؍‬ 1 Aиs. HOW DO WE DO THAT? We established in Section 8.14 (Eq. 21) that the change in Gibbs free energy is the maximum nonexpansion work that a reaction can do at constant pressure and temperature: ⌬G ϭ we The work done when an amount n of electrons (in moles) travels through a potential difference E is their total charge times the potential difference. The charge of one electron is Ϫe; the charge per mole of electrons is ϪeNA, where NA is Avogadro’s constant. Therefore, the total charge is ϪneNA and the work done is we ϭ total charge ϫ potential difference ϭ (ϪneNA) ϫ E Faraday’s constant, F, is the magnitude of the charge per mole of electrons (the product of the elementary charge e and Avogadro’s constant NA): F ϭ eNA ϭ (1.602 177 ϫ 10Ϫ19 C) ϫ {6.0223 ϫ 1023 (mol eϪ )Ϫ1 } ϭ 9.6485 ϫ 104 Cи(mol eϪ )Ϫ1 Faraday’s constant is normally abbreviated to F ϭ 9.6485 ϫ 104 CиmolϪ1 (or 96.485 kCиmolϪ1 ). We can now write the preceding expression for work as we ϭ ϪnFE When this equation is combined with the thermodynamic equation relating Gibbs free energy and nonexpansion work, we obtain ⌬G ϭ ϪnFE The units of ⌬G are joules (or kilojoules), with a value that depends not only on E, but also on the amount n (in moles) of electrons transferred in the reaction. Thus, in reaction A, n ϭ 2 mol. As in the discussion of the relation between Gibbs free energy and equilibrium constants (Section 10.3), we shall sometimes need to use this relation in its “molar” form, with n interpreted as a pure number. ⌬Gr ϭ ϪnFE The units of ⌬Gr are joules (or kilojoules) per mole. The subscript r is always the signal that we are using this “molar” form. The relation that we have derived, ⌬G ϭ ϪnFE (1a) relates the thermodynamic information that we have been compiling since Chapter 7 to the electrochemical information in this chapter. When using the molar convention for the reaction Gibbs energy, we add the subscript “r” and write ⌬Gr ϭ ϪnFE (1b) where n is a pure number with the unit “mol” struck out. We see from this equation that E provides an experimental criterion of spontaneity: if the potential difference is positive, then the reaction Gibbs free energy is negative, and the cell reaction has a spontaneous tendency to form products. If the potential difference is negative, then the reverse of the cell reaction is spontaneous, and the cell reaction has a spontaneous tendency to form reactants. There is a hidden assumption in the derivation of Eq. 1. Maximum nonexpansion work is obtained when a cell is operating reversibly. Therefore, Eq. 1 applies only when the pushing power of the cell is balanced against an external matching source of potential. In practice, that means using a voltmeter with such a high resistance that the potential difference is measured without drawing any current. The potential difference under these conditions is the maximum potential that can be produced. It is called the cell potential (which is still widely called the electromotive force, emf, of the cell). From now on, Ecell will always be taken to represent this potential difference. A working cell, one actually producing current, such as the cell in a media player, will produce a potential difference smaller than that predicted by Eq. 1. 13.4 CELL POTENTIAL AND REACTION GIBBS FREE ENERGY 525 Remember the definition of reversibility in Section 7.3, which requires the pushing force of the system to be balanced against an equal and opposite force. EXAMPLE 13.3 Calculating the reaction Gibbs free energy The potential of the Daniell cell for certain concentrations of copper and zinc ions is 1.04 V. What is the reaction Gibbs free energy under those conditions? Anticipate Because the cell generates an electric current, we should expect to find that the Gibbs free energy of reaction is negative, corresponding to a spontaneous reaction. PLAN Use Eq. 1 to determine the reaction Gibbs free energy from the cell potential. SOLVE From the chemical equation for the cell reaction (reaction A), we see that n ϭ 2 mol. Reaction ⌬G: Ϫ201 kJ ⌬GЊ: Ϫ212 kJ Gibbsfreeenergy From ⌬G ϭ ϪnFEcell, ⌬G ϭ Ϫ(2 mol) ϫ (9.6485 ϫ 104 CиmolϪ1 ) ϫ (1.04 V) ϭ Ϫ2.01 ϫ 105 CиV Evaluate Because 1 CиV ϭ 1 J, we can conclude that the Gibbs free energy of reaction A under these conditions is Ϫ201 kJ; because this value is negative, as we expected, the reaction is spontaneous in the forward direction for this composition of the cell. A note on good practice: The value of n depends on the balanced equation. Check to ensure that n matches the number of moles of electrons transferred in the balanced equation. Self-Test 13.3A The reaction taking place in a nicad cell is Cd(s) ϩ 2 Ni(OH)3(s) : Cd(OH)2(s) ϩ 2 Ni(OH)2(s), and the cell potential when fully charged is 1.25 V. What is the reaction Gibbs free energy? (See Table 13.2.) [Answer: Ϫ241 kJ] Self-Test 13.3B The reaction taking place in the silver cell used in some cameras and wristwatches is Ag2O(s) ϩ Zn(s) : 2 Ag(s) ϩ ZnO(s), and the cell potential when new is 1.6 V. What is the reaction Gibbs free energy? (See Table 13.2.) We shall often employ Eq. 1 for the standard reaction Gibbs free energy, ⌬G°, when it becomes ⌬G° ϭ ϪnFEcell° (2)* In this expression, Ecell° is the standard cell potential, the cell potential measured when all the species taking part are in their standard states. In practice, this condition means that all gases are at 1 bar, all participating solutes are at 1 molиLϪ1 , and all liquids and solids are pure. For example, to measure the standard potential of the Daniell cell, we use 1 M CuSO4(aq) and a pure copper electrode in one electrode compartment and 1 M ZnSO4(aq) and a pure zinc electrode in the other. The value of Ecell is the same, regardless of how we write the equation, but the value of ⌬G depends on the stoichiometric coefficients in the chemical equation. When we multiply all the coefficients by 2 the value of ⌬G doubles. However, multiplying all the coefficients by 2 also doubles the value of n, and so Ecell ϭ Ϫ⌬G/nF remains the same. That is, although the reaction Gibbs free energy changes when the chemical equation is multiplied by a factor, Ecell (and its standard value, Ecell°) does not change: ⌬G° Ecell° Zn(s) ϩ Cu2ϩ (aq) Zn2ϩ (aq) ϩ Cu(s) Ϫ212 kJ ϩ1.10 V 2 Zn(s) ϩ 2 Cu2ϩ (aq) 2 Zn2ϩ (aq) ϩ 2 Cu(s) Ϫ424 kJ ϩ1.10 V A practical implication of this conclusion is that the cell potential is independent of the size of the cell. To get a higher potential than predicted by Eq. 1, we have to construct a battery by joining cells in series: the potential is then the sum of the potentials of the individual cells (see Section 13.15 for some examples). Cell potential and reaction Gibbs free energy are related by Eq. 1 (⌬G ‫؍‬ ؊nFEcell), and their standard values are related by Eq. 2 (⌬G° ‫؍‬ ؊nFEcell°). The magnitude of the cell potential is independent of how the chemical equation is written. 13.5 The Notation for Cells Chemists use a special notation to specify the structure of electrode compartments in a galvanic cell. The two electrodes in the Daniell cell, for instance, are denoted Zn(s)͉Zn2ϩ (aq) and Cu2ϩ (aq)͉Cu(s). Each vertical line represents an interface between phases—in this case, between solid metal and ions in solution in the order reactant͉product. The structure of a cell is expressed in a symbolic cell diagram, by using the conventions specified by IUPAC and used by chemists throughout the world. The diagram for the Daniell cell, for instance, is Zn(s)͉Zn2ϩ (aq)͉Cu2ϩ (aq)͉Cu(s) In the Daniell cell, zinc sulfate and copper(II) sulfate solutions meet inside the porous barrier to complete the circuit. However, when different ions mingle together, they can affect the cell voltage. To keep solutions from mixing, chemists use a salt bridge to join the two electrode compartments and complete the electrical circuit. A salt bridge typically consists of a gel containing a concentrated aqueous salt solution in an inverted U-tube (Fig. 13.4). The bridge allows a flow of ions, and so it completes the electrical circuit, but the ions are chosen so that they do not affect the cell reaction (often KCl is ¡ ¡ 526 CHAPTER 13 ELECTROCHEMISTRY Ions Voltmeter ϩϪ Electrons Salt bridge Oxidation: Zn(s) Zn2ϩ (aq) ϩ 2 eϪ Reduction: Cu2ϩ (aq) ϩ 2 eϪ Cu(s) Anode Cathode ϩ1.10 V FIGURE 13.4 In a galvanic cell electrons produced by oxidation at the anode (–) travel through the external circuit and reenter the cell at the cathode (+), where they cause reduction. The circuit is completed inside the cell by migration of ions through the salt bridge. When the cell potential is measured, no current actually flows: the voltmeter measures the tendency of the electrons to flow from one electrode to the other. More precisely, all the solutes should be at unit activity, not unit molarity. Activities differ appreciably from molarities in electrolyte solution because ions interact over long distances. However, we ignore this complication here. used). In a cell diagram, a salt bridge is shown by a double vertical line (ʈ), and so the arrangement in Fig. 13.4 is denoted Zn(s)͉Zn2ϩ (aq)ʈCu2ϩ (aq)͉Cu(s) Thinking point: Are there any salts that you definitely would not want to use in a salt bridge? Any inert metallic component of an electrode is written as the outermost component of that electrode in the cell diagram. For example, a hydrogen electrode constructed with platinum is denoted Hϩ (aq)͉H2(g)͉Pt(s) when it is the right-hand electrode in a cell diagram and Pt(s)͉H2(g)͉Hϩ (aq) when it is the left-hand electrode. An electrode consisting of a platinum wire dipping into a solution of iron(II) and iron(III) ions is denoted either Fe3ϩ (aq), Fe2ϩ (aq)͉Pt(s) or Pt(s)͉Fe3ϩ (aq),Fe2ϩ (aq). In this case, the oxidized and reduced species are both in the same phase, and so a comma rather than a line is used to separate them. Pairs of ions in solution are normally written in the order Ox,Red. Self-Test 13.4A Write the diagram for a cell with a hydrogen electrode on the left and an iron(III)/iron(II) electrode on the right. The two electrode compartments are connected by a salt bridge and platinum is used as the conductor at each electrode. [Answer: Pt(s)͉H2(g)͉Hϩ (aq)ʈFe3ϩ (aq),Fe2ϩ (aq)͉Pt(s)] Self-Test 13.4B Write the diagram for a cell that has an electrode consisting of a manganese wire dipping into a solution of manganese(II) ions on the left, a salt bridge, and a copper(II)/copper(I) electrode on the right with a platinum wire. As already remarked, the cell potential is measured with an electronic voltmeter (Fig. 13.5), and we identify the cathode by noting which terminal of the cell is positive. If the cathode is the electrode that we have placed on the right of the cell diagram, then by convention the cell potential is reported as positive, as in electrons |————————————— ↓ Zn(s)͉Zn2ϩ (aq)ʈCu2ϩ (aq)͉Cu(s) Ecell ϭ ϩ1.10 V Anode (Ϫ) Cathode (ϩ) (The cell potential depends on the concentrations of the ions, as we explore later; here we have reported the value observed when the two solutions have equal cation concentrations.) In this case, the electrons can be thought of as tending to travel through the external circuit from the left of the cell as written (the anode) to the right (the cathode). However, if the cathode is found to be the electrode that we have written on the left of the cell diagram, then the cell potential is reported as negative, as in electrons ↓ —————————————| Cu(s)͉Cu2ϩ (aq)ʈZn2ϩ (aq)͉Zn(s) Ecell ϭ Ϫ1.10 V Cathode (ϩ) Anode (Ϫ) 13.5 THE NOTATION FOR CELLS 527 When it is important to emphasize the spatial arrangement of an electrode, the order may reflect that arrangement, as in Cl؊ (aq)͉Cl2(g)͉Pt(s). FIGURE 13.5 The cell potential is measured with an electronic voltmeter, a device designed to draw negligible current so that the composition of the cell does not change during the measurement. The display shows a positive value when the ϩ terminal of the meter is connected to the cathode of the galvanic cell, which is also a ϩ terminal. The salt bridge completes the electric circuit within the cell. Lab Video 13.5 Formerly, cell potentials were measured with a device called a potentiometer, but electronic devices are more reliable and easier to interpret. In summary, the sign of the cell potential reported in conjunction with a cell diagram is the same as the sign of the right-hand electrode in the diagram: • A positive cell potential indicates that the right-hand electrode in the cell diagram is the cathode. • A negative cell potential indicates that the right-hand electrode in the cell diagram is the anode. A particular cell diagram corresponds to a specific direction of writing the corresponding cell reaction. Solely for the purpose of writing the cell reaction corresponding to a given cell diagram, we suppose that the right-hand electrode in the diagram is the site of reduction and that the left-hand electrode is the site of oxidation, and write the corresponding half-reactions. Thus, for the cell written as Zn(s)͉Zn2ϩ (aq)ʈCu2ϩ (aq)͉Cu(s), we write Zn(s)͉Zn2ϩ (aq)ʈCu2ϩ (aq)͉Cu(s) Left (L) Right (R) Zn(s) Zn2ϩ (aq) ϩ 2 eϪ Cu2ϩ (aq) ϩ 2 eϪ Cu(s) (oxidation) (reduction) Overall (R ϩ L): Zn(s) ϩ Cu2ϩ (aq) Zn2ϩ (aq) ϩ Cu(s) Ecell ϭϩ1.10 V Because Ecell Ͼ 0, and therefore ⌬G Ͻ 0 for this reaction, the cell reaction as written is spontaneous for the concentrations of ions that we chose. For the alternative way of writing the cell diagram, Cu(s)͉Cu2ϩ (aq)ʈZn2ϩ (aq)͉Zn(s), we would have Cu(s)͉Cu2ϩ (aq)ʈZn2ϩ (aq)͉Zn(s) Left (L) Right (R) Cu(s) Cu2ϩ (aq) ϩ 2 eϪ Zn2ϩ (aq) ϩ2 eϪ Zn(s) (oxidation) (reduction) Overall (L ϩ R): Zn2ϩ (aq) ϩ Cu(s) Zn(s) ϩ Cu2ϩ (aq) Ecell ϭ Ϫ1.10 V Because Ecell Ͻ 0, and therefore ⌬G Ͼ 0, the reverse of the cell reaction as written is spontaneous for the chosen concentrations of ions. The general procedure for writing the chemical equation for the reaction corresponding to a given cell diagram is set out in Toolbox 13.2. ¡ ¡¡ ¡ ¡¡ 528 CHAPTER 13 ELECTROCHEMISTRY TOOLBOX 13.2 HOW TO WRITE A CELL REACTION CORRESPONDING TO A CELL DIAGRAM CONCEPTUAL BASIS A cell diagram corresponds to a specific cell reaction in which the right-hand electrode in the cell diagram is treated as the site of reduction and the left-hand electrode is treated as the site of oxidation. The sign of the cell potential then distinguishes whether the resulting reaction is spontaneous in the direction written (E Ͼ 0) or whether the reverse reaction is spontaneous (E Ͻ 0). PROCEDURE Step 1 Write the equation for the electrode on the right of the cell diagram as a reduction half-reaction (remember: Right for Reduction). Step 2 Write the equation for the electrode on the left of the cell diagram as an oxidation half-reaction. Step 3 Multiply one or both equations by a factor if necessary to equalize the number of electrons, and then add the two equations. If the cell potential is positive, then the reaction is spontaneous as written. If the cell potential is negative, then the reverse reaction is spontaneous. This procedure is illustrated in Example 13.4. EXAMPLE 13.4 Writing a cell reaction Write the reaction for the cell Pt(s)͉H2(g)͉HCl(aq)͉Hg2Cl2(s)͉Hg(l). PLAN Follow the procedure set out in Toolbox 13.2. SOLVE 13.6 STANDARD POTENTIALS 529 ClϪ ͉Hg2Cl2͉Hg Step 1 Write the equation for the reduction at the right-hand electrode. Hg2Cl2(s) ϩ 2 eϪ 2 Hg(l) ϩ 2 ClϪ (aq)¡ Pt͉H2͉HϩStep 2 Write the equation for the oxidation at the left-hand electrode. H2(g) Hϩ (aq) ϩ eϪ ¡ 1 2 Pt͉H2͉HCl͉Hg2Cl2͉Hg HCl(aq) as H ϩ (aq) and Cl Ϫ (aq) Add the half-reactions together. Hg2Cl2(s) ϩ H2(g) 2 Hg(l) ϩ 2 ClϪ (aq) ϩ 2 Hϩ (aq)¡ Step 3 To balance electrons, multiply the oxidation half-reaction by 2. H2(g) 2 Hϩ (aq) ϩ 2 eϪ ¡ If the concentrations in the cell are such that it is reported as having a positive potential (that is, the mercury/mercury(I) chloride electrode is found to be positive), then mercury(I) ions are being reduced and the reaction is spontaneous as written. If the concentrations are such that the potential is found to be negative (that is, the hydrogen electrode is found to be positive), then the reverse of the reaction that we have derived would be spontaneous. Self-Test 13.5A (a) Write the chemical equation for the reaction corresponding to the cell Pt(s)͉H2(g)͉Hϩ (aq)ʈCo3ϩ (aq),Co2ϩ (aq)͉Pt(s). (b) Given that the cell potential is positive, is the cell reaction spontaneous as written? [Answer: (a) H2(g) ϩ 2 Co3ϩ (aq) : 2 Hϩ (aq) ϩ2 Co2ϩ (aq); (b) yes] Self-Test 13.5B (a) Write the chemical equation for the reaction corresponding to the cell Hg(l)͉Hg2Cl2(s)͉HCl(aq)ʈHg2(NO3)2(aq)͉Hg(l). (b) Given that the cell potential is positive, is the cell reaction spontaneous as written? An electrode is designated by representing the interfaces between phases by a vertical line. A cell diagram depicts the physical arrangement of species and interfaces, with any salt bridge denoted by a double vertical line. The sign with which the cell potential is reported is the same as the measured sign of the right-hand electrode in the cell diagram. A positive cell potential indicates that the cell reaction is spontaneous as written. 13.6 Standard Potentials There are thousands of possible galvanic cells that can be studied. However, instead of having to learn about all these different cells, it is much simpler to learn about the smaller number of electrodes that are combined to form the cells. Under standard conditions (all solutes present at 1 molиLϪ1 ; all gases at 1 bar), we can think of each electrode as making a characteristic contribution to the cell potential called its standard potential, E°. Each standard potential is a measure of the electron-pulling power of a single electrode. In a galvanic cell, the electrodes pull in opposite directions, so the Standard potentials are also called standard electrode potentials. Because they are always written for reduction half-reactions, they are also sometimes called standard reduction potentials. overall pulling power of the cell, the cell’s standard potential, is the difference of the standard potentials of the two electrodes (Fig. 13.6). That difference is always written as Ecell° ϭ E°(electrode on right of cell diagram) Ϫ E°(electrode on left of cell diagram) (3a) or, more succinctly, Ecell° ϭ ER° Ϫ EL° (3b) If Ecell° Ͼ 0, then the corresponding cell reaction is spontaneous under standard conditions (that is, as explained in Section 10.3, K Ͼ 1 for the reaction) and the electrode on the right of the cell diagram serves as the cathode. For example, for the cell Fe(s)͉Fe2ϩ (aq)ʈAgϩ (aq)͉Ag(s), corresponding to 2 Agϩ (aq) ϩ Fe(s) 2 Ag(s) ϩ Fe2ϩ (aq) we write Ecell° ϭ E°(Agϩ /Ag) Ϫ E°(Fe2ϩ /Fe) and find Ecell° ϭ ϩ 1.24 V at 25°C. Because Ecell° Ͼ 0, the cell reaction has K Ͼ 1, with products dominant at equilibrium, and iron metal can reduce silver ions. If we had written the cell in the opposite order, Ag(s)͉Agϩ (aq)ʈFe2ϩ (aq)͉Fe(s), corresponding to 2 Ag(s) ϩ Fe2ϩ (aq) ∫∫BAgϩ (aq) ϩ Fe(s) we would have written Ecell° ϭ E°(Fe2ϩ /Fe) Ϫ E°(Agϩ /Ag) and would have found Ecell° ϭ Ϫ1.24 V. We would report that for this reaction K Ͻ 1, with reactants dominant at equilibrium. However, the conclusion is the same: iron has a tendency to reduce silver. A note on good practice: Although Ecell° Ͼ 0 is often said to signify a spontaneous reaction, it actually signifies that the reaction is spontaneous only when the reactants and products all have their standard values. At other compositions, the reverse reaction might be spontaneous. It is much better to regard Ecell° Ͼ 0 as signifying that K Ͼ 1 for the reaction and Ecell° Ͻ 0 as signifying that K Ͻ 1, because the equilibrium constant is a fixed characteristic of the reaction. Whether or not the forward reaction is positive then depends on the relative sizes of Q and K, as explained in Chapter 10. A problem with compiling a list of standard potentials is that we know only the overall cell potential, not the contribution of a single electrode. A voltmeter placed between the two electrodes of a galvanic cell measures the difference of their potentials, not the individual values. To provide numerical values for individual standard potentials, we arbitrarily set the standard potential of one particular electrode, the hydrogen electrode, equal to zero at all temperatures: 2 Hϩ (g) ϩ 2 eϪ H2(g) E° ϭ 0 In redox couple notation, E°(Hϩ /H2) ϭ 0 at all temperatures. A hydrogen electrode in its standard state, with hydrogen gas at 1 bar and the hydrogen ions present at 1 molиLϪ1 (strictly, unit activity), is called a standard hydrogen electrode (SHE). The standard hydrogen electrode is then used to define the standard potentials of all other electrodes: The standard potential of a couple is the standard potential of a cell (including the sign) in which the couple forms the right-hand electrode in the cell diagram and a hydrogen electrode forms the left-hand electrode in the cell diagram. For example, for the cell Pt(s)͉H2(g)͉Hϩ (aq)ʈCu2ϩ (aq)͉Cu(s) ¡ ¡ 530 CHAPTER 13 ELECTROCHEMISTRY Potential due to anode Cell potential Potential due to cathode Anode Cathode FIGURE 13.6 The cell potential can be thought of as the difference of the two potentials produced by the two electrodes. we find that the standard cell potential is 0.34 V with the copper electrode the cathode, and so Ecell° ϭ ϩ 0.34 V. Because the hydrogen electrode contributes zero to the standard cell potential, the cell potential is attributed entirely to the copper electrode, and we write Cu2ϩ (aq) ϩ 2 eϪ Cu(s) E°(Cu2ϩ ͞Cu) ϭ ϩ0.34 V The standard potential of an electrode is a measure of the tendency of the associated half-reaction to occur relative to the reduction of Hϩ ions. For example, because the cell reaction Cu2ϩ (aq) ϩ H2(g) Cu(s) ϩ2 Hϩ (aq) has K Ͼ 1 (because Ecell° Ͼ 0), we can consider the oxidizing ability of Cu2ϩ (aq), as represented by the reduction half-reaction Cu2ϩ (aq) ϩ 2 eϪ : Cu(s), to be greater than the oxidizing ability of Hϩ (aq), as represented by 2 Hϩ (aq) ϩ 2 eϪ : H2(g). Consequently, Cu2ϩ ions can be reduced to metallic copper by hydrogen gas, in the sense that K Ͼ 1 for the reaction. In general (Fig. 13.7): The more positive the potential, the greater the electron-pulling power of the reduction half-reaction and, therefore, the more strongly oxidizing the redox couple (the stronger the tendency for the half-reaction to occur as a reduction). Now consider the cell Pt(s)͉H2(g)͉Hϩ (aq)ʈZn2ϩ (aq)͉Zn(s) and the corresponding cell reaction Zn2ϩ (aq) ϩ H2(g) Zn(s) ϩ 2 Hϩ (aq) The magnitude of the standard cell potential is 0.76 V, but in this case the hydrogen electrode is found to be the cathode: therefore, the standard cell potential is reported as Ϫ0.76 V. Because the entire potential is attributed to the zinc electrode, we write Zn2ϩ (aq) ϩ 2 eϪ Zn(s) E°(Zn2ϩ ͞Zn) ϭ Ϫ0.76 V The negative standard potential means that the Zn2ϩ /Zn electrode is the anode in a cell with Hϩ /H2 as the other electrode and, therefore, that the reverse of the cell reaction, specifically Zn(s) ϩ 2 Hϩ (aq) Zn2ϩ (aq) ϩ H2(g) has Ecell° Ͼ 0 and therefore K Ͼ 1. We can conclude that the reducing ability of Zn(s) in the half-reaction Zn(s) : Zn2ϩ (aq) ϩ 2 eϪ is greater than the reducing ability of H2(g) in the half-reaction H2(g) : 2 Hϩ (aq) ϩ 2 eϪ . Consequently, zinc metal can reduce Hϩ ionsinacidicsolutiontohydrogengasunderstandardconditions.Ingeneral(Fig.13.8): The more negative the potential, the greater the electron-donating power of the oxidation half-reaction and therefore the more strongly reducing the redox couple (that is, the stronger the tendency for the half-reaction to occur as an oxidation). Table 13.1 lists a number of standard electrode potentials measured at 25°C (the only temperature we consider here); a longer list can be found in Appendix 2B. The standard potentials of elements vary in a complicated way through the periodic table (Fig. 13.9). However, the most negative—the most strongly reducing—are usually found toward the left of the periodic table, and the most positive—the most strongly oxidizing—are found toward the upper right. ¡ ¡ ¡ ¡ ¡ (a) Weakly oxidizing ϩ1 V (b) Strongly oxidizing ϩ2 V eϪ eϪ Anode Anode Oxidation ofcouple Oxidation ofcouple FIGURE 13.7 (a) A couple that has a small positive potential has only a small tendency to be reduced and so has a weak electron-pulling power (is a weak acceptor of electrons) relative to hydrogen ions; hence it is a weak oxidizing agent. (b) A couple with a high positive potential has strong pulling power (is a strong acceptor of electrons) and is a strong oxidizing agent. Animation 13.7 (a) Weakly reducing Ϫ1 V Ϫ2 V (b) Strongly reducing eϪ eϪ Cathode Cathode Reduction ofcouple Reduction ofcouple FIGURE 13.8 (a) A couple that has a small negative potential has only a small tendency to be oxidized and so has a poor pushing power (is a weak donor of electrons) relative to hydrogen; hence it is a weak reducing agent. (b) A couple with a large negative potential has strong pushing power (is a strong donor of electrons) and is a strong reducing agent. Animation 13.8 In Appendix 2B, standard potentials are listed both by numerical value and alphabetically, to make it easy to find the one you want. EXAMPLE 13.5 Determining the standard potential of an electrode The standard potential of a zinc electrode is Ϫ0.76 V, and the standard potential of the cell Zn(s)͉Zn2ϩ (aq)ʈSn4ϩ (aq), Sn2ϩ (aq)͉Pt(s) is ϩ0.91 V. What is the standard potential of the Sn4ϩ /Sn2ϩ electrode? 2 3 4 5 6 7 17/VII 18/VIII 16/VI15/V14/IV13/III1 2 Li Be K Na Mg Ca Rb Sr Cs Ba H Al Ga In Tl CB Si Ge Sn Pb N P As Sb Bi O S Se Te Po F Cl Br I At Ne He Ar Kr Xe Rn Ra -3.05 -1.85 -2.93 -2.71 -2.36 -2.87 -2.93 -2.89 -2.92 -2.91 0 -1.66 -0.49 -0.34 -0.34 -0.14 -0.13 +0.20 +1.23 -0.48 -0.67 -0.84 +2.87 +1.36 +1.09 +0.54 -2.92 Fr FIGURE 13.9 The variation of standard potentials through the main groups of the periodic table. Note that the most negative values are in the s block and that the most positive values are close to fluorine. TABLE 13.1 Standard Potentials at 25°C* Species Reduction half-reaction E° (V) Oxidized form is strongly oxidizing F2/FϪ F2(g) ϩ 2 eϪ ∫∫B 2 FϪ (aq) ϩ2.87 Auϩ /Au Auϩ (aq) ϩ eϪ ∫∫B Au(s) ϩ1.69 Ce4ϩ /Ce3ϩ Ce4ϩ (aq) ϩ eϪ ∫∫B Ce3ϩ (aq) ϩ1.61 MnO4 Ϫ ,Hϩ /Mn2ϩ ,H2O MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 5 eϪ ∫∫B Mn2ϩ (aq) ϩ 4 H2O(l) ϩ1.51 Cl2/ClϪ Cl2(g) ϩ 2 eϪ ∫∫B 2 ClϪ (aq) ϩ1.36 Cr2O7 2Ϫ ,Hϩ /Cr3ϩ ,H2O Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq) ϩ 6 eϪ ∫∫B 2 Cr3ϩ (aq) ϩ 7 H2O(l) ϩ1.33 O2,Hϩ /H2O O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ ∫∫B 2 H2O(l) ϩ1.23; ϩ0.82 at pH ϭ 7 Br2/BrϪ Br2(l) ϩ 2 eϪ ∫∫B 2 BrϪ (aq) ϩ1.09 NO3 Ϫ ,Hϩ /NO,H2O NO3 Ϫ (aq) ϩ 4 Hϩ (aq) ϩ 3 eϪ ∫∫B NO(g) ϩ 2 H2O(l) ϩ0.96 Agϩ /Ag Agϩ (aq) ϩ eϪ ∫∫B Ag(s) ϩ0.80 Fe3ϩ /Fe2ϩ Fe3ϩ (aq) ϩ eϪ ∫∫B Fe2ϩ (aq) ϩ0.77 I2/IϪ I2(s) ϩ 2 eϪ ∫∫B 2 IϪ (aq) ϩ0.54 O2,H2O/OHϪ O2(g) ϩ 2 H2O(l) ϩ 4 eϪ ∫∫B 4 OHϪ (aq) ϩ0.40; ϩ0.82 at pH ϭ 7 Cu2ϩ /Cu Cu2ϩ (aq) ϩ 2 eϪ ∫∫B Cu(s) ϩ0.34 AgCl/Ag,ClϪ AgCl(s) ϩ eϪ ∫∫B Ag(s) ϩ ClϪ (aq) ϩ0.22 Hϩ /H2 2 Hϩ (aq) ϩ 2 eϪ ∫∫B H2(g) 0, by definition Fe3ϩ /Fe Fe3ϩ (aq) ϩ 3 eϪ ∫∫B Fe(s) Ϫ0.04 O2,H2O/HO2 Ϫ ,OHϪ O2(g) ϩ H2O(l) ϩ 2 eϪ ∫∫B HO2 Ϫ (aq) ϩ OHϪ (aq) Ϫ0.08 Pb2ϩ /Pb Pb2ϩ (aq) ϩ 2 eϪ ∫∫B Pb(s) Ϫ0.13 Sn2ϩ /Sn Sn2ϩ (aq) ϩ 2 eϪ ∫∫B Sn(s) Ϫ0.14 Fe2ϩ /Fe Fe2ϩ (aq) ϩ 2 eϪ ∫∫B Fe(s) Ϫ0.44 Zn2ϩ /Zn Zn2ϩ (aq) ϩ 2 eϪ ∫∫B Zn(s) Ϫ0.76 H2O/H2,OHϪ 2 H2O(l) ϩ 2 eϪ ∫∫B H2(g) ϩ 2 OHϪ (aq) Ϫ0.83; Ϫ0.42 at pH ϭ 7 Al3ϩ /Al Al3ϩ (aq) ϩ 3 eϪ ∫∫B Al(s) Ϫ1.66 Mg2ϩ /Mg Mg2ϩ (aq) ϩ 2 eϪ ∫∫B Mg(s) Ϫ2.36 Naϩ /Na Naϩ (aq) ϩ eϪ ∫∫B Na(s) Ϫ2.71 Kϩ /K Kϩ (aq) ϩ eϪ ∫∫B K(s) Ϫ2.93 Liϩ /Li Liϩ (aq) ϩ eϪ ∫∫B Li(s) Ϫ3.05 Reduced form is strongly reducing *For a more extensive table, see Appendix 2B. 532 CHAPTER 13 ELECTROCHEMISTRY Anticipate Because the cell potential is positive, the cell reaction is spontaneous as written under standard conditions, which means that the right hand electrode (tin) will act as the cathode. Therefore, tin(IV) has a stronger potential to be reduced than zinc and we should expect that the standard potential of the Sn4ϩ /Sn2ϩ electrode will be more positive than that of zinc. PLAN To determine the standard potential of an electrode from the potential of a standard cell in which the other electrode has a known standard potential, we use Eq. 3 rearranged into ER° ϭ Ecell° ϩ EL°. SOLVE 13.6 STANDARD POTENTIALS 533 Evaluate As expected, the Sn4ϩ /Sn2ϩ electrode has the more positive standard potential. Self-Test 13.6A The standard potential of the Agϩ ͞Ag couple is ϩ0.80 V, and the standard potential of the cell Pt(s)͉I2(s)͉IϪ (aq)ʈAgϩ (aq)͉Ag(s) is ϩ0.26 V at the same temperature. What is the standard potential of the I2͞IϪ couple? [Answer: ϩ0.54 V] Self-Test 13.6B The standard potential of the Fe2ϩ /Fe couple is Ϫ0.44 V and the standard potential of the cell Fe(s)͉Fe2ϩ (aq)ʈPb2ϩ (aq)͉Pb(s) is ϩ0.31 V. What is the standard potential of the Pb2ϩ /Pb couple? In some cases, we find that available tables of data do not contain the standard potential that we need but do contain closely related values for the same element. For instance, we might require the standard potential of the Ce4ϩ /Ce couple, whereas we know only the values for the Ce3ϩ /Ce and Ce4ϩ /Ce3ϩ couples. In such cases, the potential of a couple cannot in general be determined by adding or subtracting the standard potentials directly. Instead, we calculate the values of ⌬G° for each half-reaction and combine them into the ⌬G° for the desired half-reaction. We then convert that value of ⌬G° into the corresponding standard potential by using Eq. 2. Ϫ0.76 V 0.91 V ϩ0.15 V From Eq. 3, Ecell° ϭ ER° Ϫ EL°, Ecell° ϭ E°(Sn4ϩ /Sn2ϩ ) Ϫ E°(Zn2ϩ /Zn) ϭ ϩ0.91 V Rearrange Eq. 3 into ER° ϭ Ecell° ϩ EL°: E°(Sn4ϩ /Sn2ϩ ) ϭ Ecell° ϩ E°(Zn2ϩ ͞Zn) ϭ 0.91 V Ϫ 0.76 V ϭ ϩ0.15 V EXAMPLE 13.6 Calculating the standard potential of a couple from two related couples Use the information in Appendix 2B to determine the standard potential for the redox couple Ce4ϩ /Ce, for which the reduction half-reaction is Ce4ϩ (aq) ϩ 4 eϪ Ce(s) (B) PLAN Use the alphabetical listing in Appendix 2B to find half-reactions that can be combined to give the desired half-reaction. Combine these half-reactions and their Gibbs free energies of reaction. Convert the Gibbs free energies into standard potentials by using Eq. 2 and then simplify the resulting expressions. SOLVE From the data in Appendix 2B, Ce3ϩ (aq) ϩ 3 eϪ Ce(s) E° ϭ Ϫ2.48 V (C) Ce4ϩ (aq) ϩ eϪ Ce3ϩ (aq) E° ϭ ϩ1.61 V (D)¡ ¡ ¡ Note that this value is not the same as the sum of the potentials for half-reactions C and D (Ϫ0.87). Self-Test 13.7A Use the data in Appendix 2B to calculate the standard potential of the couple Au3ϩ (aq)/Auϩ (aq). [Answer: ϩ1.26 V] Self-Test 13.7B Use the data in Appendix 2B to calculate the standard potential of the couple Mn3ϩ (aq)/Mn(s). The standard potential of an electrode is the standard potential of a cell in which the electrode on the left in the cell diagram is a hydrogen electrode. A metal with a negative standard potential has a thermodynamic tendency to reduce hydrogen ions in solution; the ions of a metal with a positive standard potential have a tendency to be reduced by hydrogen gas. 13.7 The Electrochemical Series When redox couples are ordered by their standard potentials, we have a list of oxidizing and reducing agents ordered by their strengths. As we have seen, the more negative the standard potential of a couple, the greater its reducing strength. Only a couple with a negative potential can reduce hydrogen ions under standard conditions (that is, have K Ͼ 1 for the reduction of hydrogen ions). A couple with a positive potential, such as Au3ϩ /Au, cannot reduce hydrogen ions under standard conditions in the sense that such a reaction would have K Ͻ 1, and commonly K ϽϽ 1 for the reduction of hydrogen ions (Fig. 13.10). When Table 13.1 is viewed as a table of relative strengths of oxidizing and reducing agents, it is called the electrochemical series. The species on the left of each equation in Table 13.1 are potentially oxidizing agents. They can themselves be reduced. Species on the right of the equations are potentially reducing agents. An oxidized species in the list (on the left of the equation) has a tendency (in the sense that K Ͼ 1) to oxidize a reduced species that lies below it. For example, Cu2ϩ ions oxidize zinc metal. A reduced species (on the right of the equation) has a tendency to reduce an oxidized species that lies above it. For example, zinc metal reduces Hϩ ions to hydrogen gas. 534 CHAPTER 13 ELECTROCHEMISTRY ⌬GЊ(B) ⌬GЊ(D) ⌬GЊ(C) ϪFE(B) ϪFE(D) ϪFE(C) Add the reaction Gibbs free energies to get the overall reaction Gibbs free energy. ⌬G°(B) ϭ ⌬G°(C) ϩ ⌬G°(D) From ⌬Gr° ϭ ϪnFE°, Ϫ4FE°(B) ϭ Ϫ3FE°(C) ϩ {ϪFE°(D)} Divide by Ϫ4F. E°(B) = 3E°(C) + E°(D) 4 Insert the data. E°(B) = 3(-2.48 V) + 1.61 V 4 = -1.46 V Strongly oxidizing 0 Strongly reducing Cannot reduce Hϩ Can reduce Hϩ Hϩ /H2 Standardpotential FIGURE 13.10 The significance of standard potentials. Only couples with negative standard potentials (and hence lying below hydrogen in the electrochemical series) can reduce hydrogen ions under standard conditions. The reducing power increases as the standard potential decreases. The higher the position of a species on the left side of an equation in Table 13.1, the greater its oxidizing strength. For example, F2 is a strong oxidizing agent, whereas Liϩ is a very, very poor oxidizing agent. It also follows that, the lower the standard potential, the greater the reducing strength of the reduced species on the right side of an equation in Table 13.1. For example, lithium metal is the strongest reducing agent in the table. Self-Test 13.8A Can lead produce zinc metal from aqueous zinc sulfate under standard conditions? [Answer: No, because lead lies above zinc in Table 13.1.] Self-Test 13.8B Can chlorine gas oxidize water to oxygen gas under standard conditions in basic solution? We can use the electrochemical series to predict whether a reaction has K Ͼ 1 or K Ͻ 1. A cell reaction that has K Ͼ 1 has Ecell° Ͼ 0. The standard cell potential is positive when the standard potential for the reduction half-reaction is more positive than that for the oxidation half-reaction. 13.7 THE ELECTROCHEMICAL SERIES 535 EXAMPLE 13.7 Calculating the standard cell potential for a redox reaction Acidified aqueous permanganate solutions and acidified aqueous dichromate solutions are powerful oxidizing agents. Suppose solutions of the two reagents are prepared and serve as the two half-cells in a galvanic cell with platinum electrodes that generates a current in an external circuit. (a) Determine the standard potential of the cell constructed from these half-cells. (b) Write the net ionic equation for the cell having a positive standard potential. (c) Write the cell diagram for the reaction. Anticipate The permanganate standard potential lies above that of the dichromate ion in Table 13.1. Therefore, we should expect that under standard conditions the permanganate ion will act as the oxidizing agent in the reaction and the dichromate ion the reducing agent. PLAN Find the standard potentials of the two reduction half-reactions in Appendix 2B. The couple with the higher standard potential will act as an oxidizing agent (and be the site of reduction). That couple will be the right-hand electrode in the cell diagram corresponding to a spontaneous reaction under standard conditions. To calculate the standard potential of the cell, subtract the standard potential of the oxidation half-reaction (the one with the lower standard potential) from that of the reduction half-reaction. To write the cell reaction, follow the procedure in Toolbox 13.2. SOLVE ϩ1.51 V ϩ1.33 V Mn Cr (a) Find the two standard potentials in Appendix 2B. MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 5 eϪ Mn2ϩ (aq) ϩ 4 H2O(l) E° ϭ ϩ1.51 V Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq) ϩ 6 eϪ 2 Cr3ϩ (aq) ϩ 7 H2O(l) E° ϭ ϩ1.33 V ¡ ¡ ϩ1.51 Vϩ1.33 V Cr Mn The half-reaction with the higher value of E° occurs at the cathode in a cell reaction with a positive potential. E°(MnO4 Ϫ ,Hϩ /Mn2ϩ ,H2O) Ͼ E°(Cr2O7 2Ϫ ,Hϩ /Cr3ϩ ,H2O) Therefore, MnO4 Ϫ serves as the cathode under standard conditions. 536 CHAPTER 13 ELECTROCHEMISTRY ϩ0.18 V ϩϪ MnCr Find the standard potential from E° ϭ E°(for reduction) Ϫ E°(for oxidation). E° ϭ 1.51 V Ϫ 1.33 V ϭ ϩ0.18 V (b) To construct the cell reaction, combine the two half-reactions, leaving the permanganate half-reaction as a reduction and reversing the dichromate half-reaction. To match numbers of electrons, multiply the manganese half-reaction by 6 and the chromium half-reaction by 5: 10 Cr3ϩ (aq) ϩ 35 H2O(l) 5 Cr2O7 2Ϫ (aq) ϩ 70 Hϩ (aq) ϩ 30 eϪ 6 MnO4 Ϫ (aq) ϩ 48 Hϩ (aq) ϩ 30 eϪ 6 Mn2ϩ (aq) ϩ 24 H2O(l) Their net sum gives the cell reaction: 6 MnO4 Ϫ (aq) ϩ 11 H2O(l) ϩ 10 Cr3ϩ (aq) ∫∫B 6 Mn2ϩ (aq) ϩ 22 Hϩ (aq) ϩ 5 Cr2O7 2Ϫ (aq) (c) Write the cell diagram with the cathode on the right-hand side: Pt(s)͉Cr2O7 2Ϫ (aq),Cr3ϩ (aq),Hϩ (aq)ʈHϩ (aq),MnO4 Ϫ (aq),Mn2ϩ (aq)͉Pt(s) Evaluate As expected, the permanganate ion is the oxidizing agent in the cell reaction and the dichromate ion the reducing agent. Self-Test 13.9A Which metal, zinc or nickel, is the stronger reducing agent in aqueous solution under standard conditions? (a) Evaluate the standard potential of the appropriate cell; (b) specify the cell with a cell diagram; (c) write the net ionic equation for the spontaneous reaction; (d) state your answer to the question. [Answer: (a) ϩ0.53 V; (b) Zn(s)͉Zn2ϩ (aq)ʈNi2ϩ (aq)͉Ni(s); (c) Zn(s) ϩ Ni2ϩ (aq) : Zn2ϩ (aq) ϩ Ni(s); (d) zinc] Self-Test 13.9B Which is the stronger oxidizing agent, Cu2ϩ or Agϩ , in aqueous solution under standard conditions? Evaluate the standard potential of the appropriate cell, specify the cell with a cell diagram, and write the net ionic equation for the corresponding cell reaction. The oxidizing and reducing power of a redox couple determines its position in the electrochemical series. The strongest oxidizing agents are at the top left of the table; the strongest reducing agents are at the bottom right of the table. 13.8 Standard Potentials and Equilibrium Constants One of the most useful applications of standard potentials is in the calculation of equilibrium constants from electrochemical data. Perhaps surprisingly, the reactions need not be redox reactions: the techniques that we develop here can be applied to any kind of reaction, including neutralization and precipitation reactions, provided that they can be expressed as the difference of two reduction half-reactions. For example, even a “reaction” as simple as the expansion of a gas can be expressed as the difference of two reduction half-reactions: R: 2 Hϩ (aq) ϩ 2 eϪ H2(g, P2) L: 2 Hϩ (aq) ϩ 2 eϪ H2(g, P1) R Ϫ L: H2(g, P1) H2(g, P2) We saw in Section 10.3 that the standard reaction Gibbs free energy, ⌬Gr° (remember that the r signifies the molar convention) is related to the equilibrium constant of the ¡ ¡ ¡ ¡ ¡ reaction by ⌬Gr° ϭ ϪRT ln K. In this chapter, we have seen that the standard reaction Gibbs free energy is related to the standard potential of a galvanic cell by ⌬Gr° ϭ ϪnFEcell°, with n a pure number. When we combine the two equations, we get nFEcell° ϭ RT ln K (4) This expression can be rearranged to allow us to calculate the equilibrium constant from the standard cell potential: ln K ϭ (5)* A note on good practice: Equation 5 was derived on the basis of the “molar” convention for writing the reaction Gibbs free energy; that means that the n must be interpreted as a pure number. That convention keeps the units straight: FEcell° has the units joules per mole, so does RT, so the ratio FEcell°͞RT is a pure number and, with n a pure number, the right hand side is a pure number too (as it must be, if it is to be equal to a logarithm). Because the magnitude of K increases exponentially with Ecell°, a reaction with a large positive Ecell° has K ϾϾ 1. A reaction with a large negative Ecell° has K ϽϽ 1. Thinking point: What is the value of K for a reaction that has Ecell° ϭ 0? The fact that we can calculate Ecell° from standard potentials allows us to calculate equilibrium constants for any reaction that can be expressed as two half-reactions. The reaction does not need to be spontaneous nor does it have to be a redox reaction. Toolbox 13.3 summarizes the steps and Example 13.8 shows the steps in action. nFE° RT 13.8 STANDARD POTENTIALS AND EQUILIBRIUM CONSTANTS 537 TOOLBOX 13.3 HOW TO CALCULATE EQUILIBRIUM CONSTANTS FROM ELECTROCHEMICAL DATA CONCEPTUAL BASIS The logarithm of the equilibrium constant of a reaction is proportional to the standard potential of the corresponding cell. We can expect a cell reaction with a large positive potential to have a strong tendency to take place, and therefore to produce a high proportion of products at equilibrium. Therefore, we expect K Ͼ 1 when E° Ͼ 0 (and often K ϾϾ 1). The opposite is true for a cell reaction with a negative standard potential. PROCEDURE The procedure for calculating an equilibrium constant from electrochemical data is as follows. Step 1 Write the balanced equation for the reaction. Then find two reduction half-reactions in Appendix 2B that combine to give that equation. Reverse one of the half-reactions and add them together. Step 2 Identify the numerical (unitless) value of n from the change in oxidation numbers or by examining the halfreactions (after multiplication by appropriate factors) for the number of electrons transferred in the balanced equation. Step 3 To obtain Ecell°, subtract the standard potential of the half-reaction that was reversed (oxidation) from the standard potential of the half-reaction that was left as a reduction: E° ϭ E°(for reduction) Ϫ E°(for oxidation). Alternatively, write a cell diagram for the reaction; in that case, Ecell° ϭ ER° Ϫ EL°. Step 4 Use the relation ln K ϭ nFEcell°/RT to calculate the value of K (with n a pure number). At 25.00°C (298.15 K), RT/F ϭ 0.025 693 V; so, at that temperature, This procedure is illustrated in Example 13.8. ln K = nEcell° 0.025 693 V EXAMPLE 13.8 Calculating the equilibrium constant for a reaction Calculate the equilibrium constant at 25.00°C for the reaction AgCl(s) : Agϩ (aq) ϩ ClϪ (aq). The equilibrium constant for this reaction is actually the solubility product, Ksp ϭ [Agϩ ][ClϪ ], for silver chloride (Section 12.8). Anticipate Because silver chloride is almost insoluble, we expect Ksp to be very small (and Ecell° therefore to be negative). PLAN Follow the procedure in Toolbox 13.3. SOLVE 538 CHAPTER 13 ELECTROCHEMISTRY ϩ0.22 Vϩ0.80 V AgCl/Ag,Cl Ϫ Ag ϩ /Ag Step 1 Find the two reduction half-reactions required for the cell reaction. R: AgCl(s) ϩ eϪ Ag(s) ϩ ClϪ (aq) E° ϭ ϩ0.22 V L: Agϩ (aq) ϩ eϪ Ag(s) E° ϭ ϩ0.80 V¡ ¡ ϩ0.22 Vϩ0.80 V Ϫ0.58 V AgCl/Ag,ClϪ Ag ϩ /Ag Step 3 Find Ecell° from Ecell° ϭ E°(for reduction) Ϫ E°(for oxidation). Ecell° ϭ 0.22 V Ϫ 0.80 V ϭ Ϫ0.58 V Reverse the second half-reaction. Ag(s) Agϩ (aq) ϩ eϪ ¡ Add this equation to the reduction half-reaction and cancel species that appear on both sides of the equation. AgCl(s) Agϩ (aq) ϩ ClϪ (aq)¡ Step 2 From the half-reactions note the stioichiometric coefficient for the number of electrons transferred. n ϭ 1 From ln K ϭ nFEcell°/RT ϭ nEcell°/(RT/F) with K identified with Ksp and RT/F ϭ 0.025 693 V at 298 K: ln Ksp = (1) * (-0.58 V) 0.025 693 V = - 0.58 0.025 693 Take the antilogarithm (ex ) of ln Ksp. Ksp ϭ eϪ0.58/0.025 693 ϭ 1.6 ϫ 10Ϫ10 Evaluate The value of Ksp is indeed very small; it is also the same as that listed in Table 12.4. Many of the solubility products listed in tables were determined from potential measurements and calculations like this one. Self-Test 13.10A Use Appendix 2B to calculate the solubility product of mercury(I) chloride, Hg2Cl2. [Answer: 2.6 ϫ 10Ϫ18 ] Self-Test 13.10B Use the tables in Appendix 2B to calculate the solubility product of cadmium hydroxide, Cd(OH)2. The equilibrium constant of a reaction can be calculated from standard potentials by combining the equations for the half-reactions to give the cell reaction of interest and determining the standard potential of the corresponding cell. 13.9 The Nernst Equation As a reaction proceeds toward equilibrium, the concentrations of its reactants and products change and ⌬G approaches zero. Therefore, as reactants are consumed in a working electrochemical cell, the cell potential also decreases until finally it reaches 13.9 THE NERNST EQUATION 539 HOW DO WE DO THAT? To establish how the cell potential depends on concentration, we first note that the potential is proportional to the reaction Gibbs free energy (Eq. 2). We already know how ⌬Gr varies with composition: ⌬Gr ϭ ⌬Gr° ϩ RT ln Q where Q is the reaction quotient for the cell reaction (Eq. 5 of Section 10.3). Because ⌬Gr ϭ ϪnFEcell and ⌬Gr° ϭ ϪnFEcell°, it follows at once that ϪnFEcell ϭ ϪnFEcell° ϩ RT ln Q At this point, we divide through by ϪnF to get an expression for Ecell in terms of Q, which is given below. The equation for the concentration dependence of the cell potential that we have derived, (6a)* (with n a pure number) is called the Nernst equation for the German electrochemist Walther Nernst, who first derived it. At 298.15 K, RT/F ϭ 0.025 693 V; so at that temperature the Nernst equation takes the form (6b)* It is sometimes convenient to use this equation with common logarithms, in which case we make use of the relation ln x ϭ ln 10 ϫ log x ϭ 2.303 log x. At 298.15 K, (6c)* The Nernst equation is widely used to estimate the potentials of cells under nonstandard conditions. In biology it is used, among other things, to estimate the potential difference across biological cell membranes, such as those of neurons. Ecell = Ecell° RT ln 10 nF log Q = Ecell° - 0.059 17 V n log Q Ecell = Ecell° - 0.025 693 V n ln Q Ecell = Ecell° - RT nF ln Q EXAMPLE 13.9 Using the Nernst equation to predict a cell potential Calculate the potential of a Daniell cell at 25°C in which the concentration of Zn2ϩ ions is 0.10 molиLϪ1 and that of the Cu2ϩ ions is 0.0010 molиLϪ1 . PLAN Write the balanced equation for the cell reaction and the corresponding expression for Q, and note the value of n. Then determine Ecell° from the standard potentials in Table 13.1 or Appendix 2B. Determine the value of Q for the stated conditions. Calculate the cell potential by substituting these values into the Nernst equation, Eq. 6b. SOLVE The Daniell cell and the corresponding cell reaction are Zn(s)͉Zn2ϩ (aq)ʈCu2ϩ (aq)͉Cu(s) Cu2ϩ (aq) ϩ Zn(s) Zn2ϩ (aq) ϩ Cu(s)¡ zero. A “dead” battery is one in which the cell reaction has reached equilibrium. At equilibrium, a cell generates zero potential difference across its electrodes and the reaction can no longer do work. To describe this behavior quantitatively, we need to find how the cell potential varies with the concentrations of species in the cell. Set up the reaction quotient. Q = aZn2 + aCu2 + = [Zn2+ ] [Cu2+ ] = 0.10 0.0010 From the balanced equation, note the value of n. n ϭ 2 Self-Test 13.11A Calculate the potential of the cell Zn(s)͉Zn2ϩ (aq, 1.50 molиLϪ1 )ʈ Fe2ϩ (aq, 0.10 molиLϪ1 )͉Fe(s). [Answer: ϩ0.29 V] Self-Test 13.11B Calculate the potential of the cell Ag(s)͉Agϩ (aq, 0.0010 molиLϪ1 )ʈ Agϩ (aq, 0.010 molиLϪ1 )͉Ag(s). An important application of the Nernst equation is the measurement of concentration. In a concentration cell, the two electrodes are identical except for their concentrations. For such a cell, there is no driving force for change when the two concentrations are the same (which is the case when they are in their standard states), and so Ecell° ϭ 0. Therefore, at 25°C the potential corresponding to the cell reaction is related to Q by Ecell ϭ Ϫ(0.025 693 V/n) ln Q. For example, a concentration cell having two Agϩ /Ag electrodes is Ag(s)͉Agϩ (aq, L)ʈAgϩ (aq, R)͉Ag(s) Agϩ (aq, R) Agϩ (aq, L) The cell reaction has n ϭ 1 and Q ϭ [Agϩ ]L/[Agϩ ]R. If the concentration of Agϩ in the right-hand electrode is 1 molиL–1 , Q is equal to [Agϩ ]L, and the Nernst equation is Ecell ϭ –(0.025 693 V) ln [Agϩ ]L Therefore, by measuring Ecell, we can infer the concentration of Agϩ in the left-hand electrode compartment. If the concentration of Agϩ ions in the left-hand electrode is less than that in the right, then Ecell Ͼ 0 for the cell as specified and the right-hand electrode will be found to be the cathode. ¡ 540 CHAPTER 13 ELECTROCHEMISTRY Zn Cu ϩ1.10 V ϩ0.34V Ϫ0.76V ϩϪ Determine the value of Ecell° ϭ ER° Ϫ EL°. Ecell° ϭ 0.34 Ϫ (Ϫ0.76) V ϭ ϩ1.10 V 1.10 1 100 E(V) Q 1.04 From Ecell ϭ Ecell° Ϫ (RT/nF) ln Q, ϭ 1.10 V Ϫ 0.059 V ϭ ϩ1.04 V Ecell = 1.10 V - 0.025 693 V 2 ln 0.10 0.0010 EXAMPLE 13.10 Using the Nernst equation to find a concentration Each electrode compartment of a galvanic cell contains a silver electrode and 10.0 mL of 0.10 M AgNO3(aq); they are connected by a salt bridge. You now add 10.0 mL of 0.10 M NaCl(aq) to the left-hand electrode compartment. Almost all the silver precipitates as silver chloride but a little remains in solution as a saturated solution of AgCl. The measured cell potential is Ecell ϭ ϩ0.42 V. What is the concentration of Agϩ in the saturated solution? Anticipate Because silver chloride is very insoluble, we should expect a very low concentration. PLAN The cell is a concentration cell in which the concentration of Agϩ in one compartment is determined by the solubility of AgCl. Use the Nernst equation, Eq. 6, to find the concentration of Agϩ in the compartment with the precipitate. The standard cell potential is 0 (in their standard states the electrodes are identical). At 25.00°C, RT/F ϭ 0.025 693 V. SOLVE The cell and the corresponding cell reaction are Ag(s)͉Agϩ (aq, L)ʈAgϩ (aq, R)͉Ag(s) Agϩ (aq, R) Agϩ (aq, L)¡ Evaluate The concentration of Agϩ ions in the saturated solution is 8.0 nmolиL–1 ; as expected, this is a very low value. Self-Test 13.12A Calculate the molar concentration of Y3ϩ in a saturated solution of YF3 by using a cell constructed with two yttrium electrodes. The electrolyte in one compartment is 1.0 M Y(NO3)3(aq). In the other compartment you have prepared a saturated solution of YF3. The measured cell potential is ϩ0.34 V at 298 K. [Answer: 5.7 ϫ 10–18 molиL–1 ] Self-Test 13.12B Calculate the potential of a cell constructed with two silver electrodes. The electrolyte in one compartment is 1.0 M AgNO3(aq). In the other compartment NaOH has been added to a AgNO3 solution until the pH ϭ 12.5 at 298 K. The dependence of cell potential on composition is expressed by the Nernst equation, Eq. 6. 13.10 Ion-Selective Electrodes An important application of the Nernst equation is the measurement of pH (and, through pH, acidity constants). The pH of a solution can be measured electrochemically with a device called a pH meter. The technique makes use of a cell in which one electrode is sensitive to the H3Oϩ concentration and another electrode serves as a reference. An electrode sensitive to the concentration of a particular ion is called an ion-selective electrode. One combination of electrodes that could be used to determine pH is a hydrogen electrode connected through a salt bridge to a calomel electrode. The reduction halfreaction for the calomel electrode is Hg2Cl2(s) ϩ 2 e– 2 Hg(l) ϩ 2 Cl– (aq) E° ϭ ϩ0.27 V The overall cell reaction is Hg2Cl2(s) ϩ H2(g) 2 Hϩ (aq) ϩ 2 Hg(l) ϩ 2 Cl– (aq) Provided that the pressure of hydrogen is 1 bar, we can write the reaction quotient as Q ϭ [Hϩ ]2 [Cl– ]2 . To find the concentration of hydrogen ions, we write the Nernst equation: Ecell = Ecell° - RT 2F ln ([H+ ]2 [Cl- ]2 ) Q = [H+ ]2 [Cl- ]2 PH2 ¡ ¡ 13.10 ION-SELECTIVE ELECTRODES 541 0.5 0 E(V) 1 ϫ 10Ϫ5 8 ϫ 10Ϫ8 0 Q ϩ0.42 V From Ecell ϭ Ecell° – (RT/nF) ln Q rearranged into ln Q ϭ –Ecell/(RT/nF), ln Q = -0.42 V 0.025 693 V = -16.34 Set up the reaction quotient, Q. Q = [Ag+ ]L [Ag+ ]R = [Ag+ ]L 0.10 From the balanced equation, note the value of n. n ϭ 1 From Q ϭ elnQ , Q ϭ e–16.34 From [Agϩ ]L ϭ Q[Agϩ ]R, [Agϩ ]L ϭ eϪ16.34 ϫ 0.10 ϭ 8.0 ϫ 10–9 Calomel is the common name for mercury(I) chloride, Hg2Cl2. Note that the compound contains the diatomic cation Hg2 2؉ . We apply ln (ab) ϭ ln a ϩ ln b, then use ln a2 ϭ 2 ln a to obtain Ecell ϭ Ecell° Ϫ (RT/F) ln [ClϪ ] Ϫ (RT/F ) ln [Hϩ ] The ClϪ concentration of a calomel electrode is fixed at the time of manufacture by saturating the solution with KCl, and so [ClϪ ] is a constant. We can therefore combine the first two terms on the right into a single constant, EcellЈϭ Ecell° Ϫ (RT/F) ln [Cl– ]: Ecell ϭ EcellЈ Ϫ (RT/F) ln [Hϩ ] Then, because ln x ϭ ln 10 ϫ log x, and (RT/F) ln 10 ϭ (0.026 93 V) ϫ 2.303 ϭ 0.0592 V at 25°C, Ecell ϭ EcellЈ – (RT/F) ln 10 ϫ log [Hϩ ] ϭ EcellЈ ϩ (0.0592 V) ϫ pH Therefore, by measuring the cell potential, Ecell, we can determine the pH. The value of EcellЈ is established by calibrating the cell, which requires measuring E for a solution of known pH. A glass electrode, a thin-walled glass bulb containing an electrolyte, is much easier to use than a hydrogen electrode and has a potential that varies linearly with the pH of the solution outside the glass bulb (Fig. 13.11). Often there is a calomel electrode built into the probe that makes contact with the test solution through a miniature salt bridge. A pH meter therefore usually has only one probe, which forms a complete electrochemical cell once it is dipped into a solution. The meter is calibrated with a buffer of known pH, and the measured cell potential is then automatically converted into the pH of the solution, which is displayed. Commercially available electrodes used in pX meters are sensitive to other ions, such as Naϩ , Ca2ϩ , NH4 ϩ , CN– , or S2– . They are used to monitor industrial processes and in pollution control. The pH or concentrations of ions can be measured by using an electrode that responds selectively to only one species of ion. ELECTROLYTIC CELLS Redox reactions that have a positive Gibbs free energy of reaction are not spontaneous, but an electric current can be used to make them take place. For example, there is no common spontaneous chemical reaction in which fluorine is a product, and so the element cannot be isolated by any common chemical reaction. It was not until 1886 that the French chemist Henri Moissan found a way to force the formation of fluorine by passing an electric current through an anhydrous molten mixture of potassium fluoride and hydrogen fluoride. Fluorine is still prepared commercially by the same process. In the next two sections we study electrolysis, the process of driving a reaction in a nonspontaneous direction by using an electric current. First, we see how electrochemical cells are constructed for electrolysis and how to predict the potential needed to bring electrolysis about. Then, we examine the products of electrolysis and see how to predict the amount of products to expect for a given flow of electric current. 13.11 Electrolysis An electrochemical cell in which electrolysis takes place is called an electrolytic cell. The arrangement of components in electrolytic cells is different from that in galvanic cells. Typically, the two electrodes share the same compartment, there is only one electrolyte, and concentrations and pressures are far from standard. As in all electrochemical cells, Ecell = Ecell° - RT 2F ln ([Cl- ]2 ) - RT 2F ln ([H+ ]2 ) 542 CHAPTER 13 ELECTROCHEMISTRY FIGURE 13.11 A glass electrode in a protective plastic sleeve (left) is used to measure pH. It is used in conjunction with a thermometer (right) in pH meters such as this one. the current is carried through the electrolyte by the ions present. For example, when copper metal is refined electrolytically, the anode is impure copper, the cathode is pure copper, and the electrolyte is an aqueous solution of CuSO4. As the Cu2ϩ ions in solution migrate toward the cathode, where they are reduced and deposited as Cu atoms, more Cu2ϩ ions are produced by oxidation of copper metal at the anode. Figure 13.12 shows schematically the layout of an electrolytic cell used for the commercial production of magnesium metal from molten magnesium chloride (the Dow process). As in a galvanic cell, oxidation takes place at the anode and reduction takes place at the cathode, electrons travel through the external wire from anode to cathode, cations move through the electrolyte toward the cathode, and anions move toward the anode. But unlike in a galvanic cell, in which the current is spontaneously generated, in an electrolytic cell a current must be supplied by an external electrical power source for reaction to occur. That power source can be a galvanic cell, which provides the current that drives electrons through the wire in a predetermined direction. The result is to force oxidation at one electrode and reduction at the other. For example, the following half-reactions are made to take place in the Dow process: Anode reaction: 2 ClϪ (melt) Cl2(g) ϩ 2 eϪ Cathode reaction: Mg2ϩ (melt) ϩ 2 eϪ Mg(l) where “melt” signifies the molten salt. A rechargeable battery functions as a galvanic cell when it is doing work and as an electrolytic cell when it is being recharged. To drive a reaction in a nonspontaneous direction, the external supply must generate a potential difference greater than the potential difference that would be produced by the reverse reaction. For example, because 2 H2(g) ϩ O2(g) 2 H2O(l) Ecell ϭ ϩ1.23 V at pH ϭ 7, spontaneous to achieve the nonspontaneous reverse reaction 2 H2O(l) 2 H2(g) ϩ O2(g) Ecell ϭ –1.23 V at pH ϭ 7, nonspontaneous under standard conditions (other than for the Hϩ concentration) we must apply at least 1.23 V from the external source to overcome the reaction’s natural pushing power in the opposite direction. In practice, the applied potential difference must usually be substantially greater than the cell potential to reverse a spontaneous cell reaction and achieve a significant rate of product formation. The additional potential difference, which varies with the type of electrode, is called the overpotential. For platinum electrodes, the overpotential for the production of water from hydrogen and oxygen is about 0.6 V; so about 1.8 V (that is, 0.6 ϩ 1.23 V) is actually required to electrolyze water when platinum electrodes are used. Much contemporary research on electrochemical cells involves attempts to reduce the overpotential and hence to increase the efficiency of electrolytic processes. When carrying out an electrolysis in solution, we must consider the possibility that other species present might be oxidized or reduced by the electric current. For example, suppose that we want to electrolyze water to produce hydrogen and oxygen. Pure water does not carry a current because the concentration of ions (H3Oϩ and OH– ) in it is very low. Therefore, we must add an ionic solute with ions that are less easily oxidized or reduced than water: O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ 2 H2O(l) E ϭ ϩ0.82 V at pH ϭ 7 To reverse this half-reaction and bring about the oxidation of water, we need an applied potential difference of at least 0.82 V. Suppose the added salt is sodium chloride. When Cl– ions are present at 1 mol·L–1 in water, is it possible that they, and not the water, will be oxidized? From Table 13.1, the standard potential for the reduction of chlorine is ϩ1.36 V: Cl2(g) ϩ 2 eϪ 2 ClϪ (aq) E° ϭ ϩ1.36 V To reverse this reaction and oxidize chloride ions, we have to supply at least 1.36 V. Because only 0.82 V is needed to force the oxidation of water but 1.36 V is needed to ¡ ¡ ¡ ¡ ¡ ¡ 13.11 ELECTROLYSIS 543 FIGURE 13.12 A schematic representation of the electrolytic cell used in the Dow process for magnesium. The electrolyte is molten magnesium chloride. As the current generated by the external source passes through the cell, chloride ions are oxidized to chlorine gas at the anode and magnesium ions are reduced to magnesium metal at the cathode. Electrons Anode Cathode ϩ Ϫ ϩ Ϫ Oxidation: 2ClϪ(melt) Cl2(g) ϩ 2eϪ Reduction: Mg2ϩ(melt) ϩ 2eϪ Mg(s) Mg2ϩ ClϪ The anode (the site of oxidation) of an electrolytic cell is labeled ؉ and the cathode (the site of reduction) is labeled ؊, the opposite of a galvanic cell. The ؉ sign indicates that the electrode is pulling electrons away from the electroactive species undergoing oxidation. force the oxidation of ClϪ , it appears that oxygen should be the product at the anode. However, the overpotential for oxygen production can be very high, and in practice chlorine also might be produced. At the cathode, we want the half-reaction 2 Hϩ (aq) ϩ 2 eϪ : H2(g) to take place. At pH ϭ 7, the potential required for the reduction of hydrogen ions is 0.41 V. Hydrogen, rather than sodium metal, will be produced at the cathode, because the potential required to reduce sodium ions is significantly higher (ϩ2.71 V). The most common salt used for the electrolysis of water is sodium sulfate, because neither ion reacts during electrolysis and the salt is inexpensive. 544 CHAPTER 13 ELECTROCHEMISTRY EXAMPLE 13.11 Deciding which species will be produced at an electrode Suppose that an aqueous solution with pH ϭ 7 and containing I– ions at 1 mol·L–1 is being electrolyzed. Will O2 or I2 be produced at the anode? PLAN Decide which oxidation requires the lower potential. Then, provided the overpotentials are similar, that couple will be preferentially oxidized. SOLVE From Table 13.1, I2(s) ϩ 2 e– 2 IϪ (aq) E° ϭ ϩ0.54 V so we know that at least 0.54 V is needed to oxidize IϪ . We have seen that at least 0.82 V is needed to oxidize water: O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ 2 H2O(l) E ϭ ϩ0.82 V at pH ϭ 7 Therefore, provided that the overpotentials are similar, we expect IϪ ions to be oxidized in preference to water. Self-Test 13.13A Predict the products resulting from the electrolysis of 1 M AgNO3(aq). [Answer: Cathode, Ag; anode, O2] Self-Test 13.13B Predict the products resulting from the electrolysis of 1 M NaBr(aq). The potential supplied to an electrolytic cell must be at least as great as that of the cell reaction to be reversed. If there is more than one reducible species in solution, the species with the greater potential for reduction is preferentially reduced. The same principle applies to oxidation. 13.12 The Products of Electrolysis We saw in Section L how to calculate the maximum amount of product that can be formed from a given amount of a reactant. Now we shall see how to calculate the amount of product formed by a given amount of electricity (1). The calculation is based on observations made by Michael Faraday (Fig.13.13) and summarized—in more modern language than he used—as follows: Faraday’s law of electrolysis: The amount of product formed or reactant consumed by an electric current is stoichiometrically equivalent to the amount of electrons supplied. To find the amount (in moles) of product that can be formed by an electrical current passed for a given time, we need to take into account the amount of product that can be formed by a given amount of electrons. For instance, copper is refined electrolytically by using an impure form of copper metal called blister copper as the anode in an electrolytic cell (Fig. 13.14). The current supply drives the oxidation of the blister copper to copper(II) ions, Cu2ϩ , which are then reduced to pure copper metal at the cathode in the reaction Cu2ϩ (aq) ϩ 2 eϪ : Cu(s). To calculate the amount of Cu produced by using 4.0 mol eϪ we write the mole ratio from this half-reaction, 2 mol eϪ 1 mol Cu, and then convert the amount of electrons to an amount of Cu atoms: ϭ 2.0 mol Cu Amount of Cu (mol) = (4.0 mol e) * 1 mol Cu 2.0 mol e- ϴ ¡ ¡ FIGURE 13.13 Michael Faraday (1791–1867). 1 Moles of eϪ Moles of B Reaction stoichiometry Molar mass or molar volume Mass or volume of product Mole ratioFaraday's constant Time and current Self-Test 13.14A What amount (in moles) of Al(s) can be produced from Al2O3 if 5.0 mol eϪ is supplied? [Answer: 1.7 mol Al] Self-Test 13.14B What amount (in moles) of Cr(s) can be produced from CrO3 if 12.0 mol eϪ is supplied? The quantity, Q , of electricity passed through the electrolysis cell is measured in coulombs. It is determined by measuring the current, I, and the time, t, for which the current flows and is calculated from Charge supplied (C) ϭ current (A) ϫ time (s) or Q ϭ It (7) For example, because 1 A·s ϭ 1 C, if 2.00 A is passed for 125 s, the charge supplied to the cell is Q ϭ (2.00 A) ϫ (125 s) ϭ 250. Aиs ϭ 250. C To determine the amount of electrons supplied by a given charge, we use Faraday’s constant, F, the magnitude of the charge per mole of electrons (Section 13.4). Because the charge supplied is Q ϭ nF, where n is the amount of electrons (in moles), it follows that (8)* So, by measuring the current and the time for which it flows, we can determine the amount of electrons supplied. By combining the amount of electrons supplied with the mole ratio from the stoichiometry of the electrode reaction, we can deduce the amount of product obtained (see 1). n = Q F = It F In this context, Q is the charge supplied: don’t confuse it with the reaction quotient Q ! Oxidation: Cu(s) Cu2ϩ (aq) ϩ 2 eϪ Reduction: Cu2ϩ (aq) ϩ 2 eϪ Cu(s) Electrons ϩ Ϫ Anode Cathode Cu2ϩ Lab Video 13.14 EXAMPLE 13.12 Calculating the amount of product formed by electrolysis Aluminum is produced by electrolysis of its oxide dissolved in molten cryolite (Na3AlF6). Find the mass of aluminum that can be produced in 1.00 day in an electrolytic cell operating continuously at 1.00 ϫ 105 A. The cryolite does not react. Anticipate In this industrial-scale process, with a high current acting for a long time, we should expect to generate many kilograms of aluminum. PLAN Use the first procedure in Toolbox 13.4. TOOLBOX 13.4 HOW TO PREDICT THE RESULT OF ELECTROLYSIS CONCEPTUAL BASIS The number of electrons required to reduce a species is related to the stoichiometric coefficients in the reduction halfreaction. The same is true of oxidation. Therefore, we can set up a stoichiometric relation between the reduced or oxidized species and the amount of electrons required to carry out the reaction. The amount of electrons required is calculated from the current and the length of time for which the current flows. PROCEDURE To determine the amount of product that can be produced: Step 1 Identify the stoichiometric relation between electrons and the species of interest from the applicable half-reaction. Step 2 Calculate the amount (in moles) of electrons supplied from Eq. 8, n ϭ It͞F. Use the stoichiometric relation from step 1 to convert n into the amount of substance. If required, use the molar mass to convert the amount of substance into mass (or molar volume to convert into volume). This procedure is illustrated in Example 13.12. To determine the time required for a given amount of product to be produced: Step 1 Identify the stoichiometric relation between electrons and the species of interest from the applicable half-reaction. Step 2 If required, use the molar mass to convert mass into amount (in moles). Use the stoichiometric relation from step 1 to convert amount of substance into amount of electrons passed, n (in moles). Step 3 Substitute n, the current, and Faraday’s constant into Eq. 8 rearranged to t ϭ Fn͞I and solve for time. This procedure is illustrated in Example 13.13. FIGURE 13.14 A schematic representation showing the electrolytic process for refining copper. The anode is impure copper. The Cu2ϩ ions produced by oxidation of the anode migrate to the cathode, where they are reduced to pure copper metal. A similar arrangement is used for electroplating objects. Evaluate As expected, a large mass of aluminum (805 kg) is produced. The fact that the production of 1 mol Al requires 3 mol eϪ accounts for the very high consumption of electricity characteristic of aluminum-production plants. Self-Test 13.15A Determine the mass (in grams) of magnesium metal that can be obtained from molten magnesium chloride, by using a current of 7.30 A for 2.11 h. What volume of chlorine gas at 25°C and 1.00 atm will be produced at the anode? [Answer: 6.98 g; 7.03 L] Self-Test 13.15B What mass of chromium metal can be obtained from a 1 M solution of CrO3 in dilute sulfuric acid, by using a current of 6.20 A for 6.00 h? 546 CHAPTER 13 ELECTROCHEMISTRY Step 1 Write the half-reaction for the reduction and find the amount of electrons required to reduce 1 mol metal. Al3ϩ (melt) ϩ 3 eϪ Al(l) 3 mol eϪ 1 mol Alϴ¡ SOLVE Step 2 From m ϭ nM and n ϭ It͞F, using M(Al) ϭ 26.98 gиmolϪ1 , 3600 s ϭ 1 h, and 24 h ϭ 1 d, and remembering the stoichiometric relation between Al and the electrons: = 8.05 * 105 g Al * 1 mol Al 3 mol e- * 26.98 g Al 1 mol Al = (1.00 * 105 Cиs-1 ) * (24.0 * 3600 s) 9.65 * 104 Cи(mol e- )-1 m(Al) = n(e) * 1 mol Al 3 mol e- * 26.98 g Al 1 mol Al Current and time Amount of eϪ Amount of Al Mole ratio M Mass of Al EXAMPLE 13.13 Calculating the time required to produce a given mass of product How many hours are required to plate 25.00 g of copper metal from 1.00 M CuSO4(aq), by using a current of 3.00 A? PLAN Use the second procedure in Toolbox 13.4. SOLVE Step 1 Find the stoichiometric relation between electrons and the species of interest from the half-reaction for the electrolysis. Cu2ϩ (aq) ϩ 2 eϪ Cu(s) 2 mol eϪ 1 mol Cuϴ¡ Step 2 To find n(eϪ ), convert grams of Cu into moles of Cu and moles of Cu into moles of eϪ . = 25.00 * 2 63.54 mol e- n(e) = (25.00 g Cu) * 1 mol Cu 63.54 g Cu * 2 mol e- 1 mol Cu Amount of eϪ Amount of Cu Mole ratio M Mass of Cu Step 3 Use t ϭ Fn͞I and convert seconds to hours. = 7.0 h * 25.00 * 2 63.54 mol e- * 1 h 3600 s t = 9.6485 * 104 Cи(mol e- )-1 3.00 Cиs-1 Amount of eϪ Amount of Cu Current and time Mole ratio M Mass of Cu Self-Test 13.16A Determine the time, in hours, required to electroplate 7.00 g of magnesium metal from molten magnesium chloride, by using a current of 7.30 A. [Answer: 2.12 h] Self-Test 13.16B How many hours are required to plate 12.00 g of chromium metal from a 1 M solution of CrO3 in dilute sulfuric acid, by using a current of 6.20 A? The amount of product in an electrolysis reaction is calculated from the stoichiometry of the half-reaction, the current, and the time for which the current flows. THE IMPACT ON MATERIALS Electrochemical cells play important roles in both the purification and the preservation of metallic materials. Redox reactions are used throughout the chemical industry to extract metals from their ores. However, redox reactions also corrode the artifacts that industry produces. What redox reactions achieve, redox reactions can destroy. 13.13 Applications of Electrolysis We have already described the refining of copper and the electrolytic extraction of aluminum, magnesium, and fluorine. Another important industrial application of electrolysis is the production of sodium metal by the Downs process, the electrolysis of molten rock salt (Fig. 13.15): Cathode reaction: 2 Naϩ (melt) ϩ 2 eϪ 2 Na(l) Anode reaction: 2 ClϪ (melt) Cl2(g) ϩ 2 eϪ Sodium chloride is plentiful as the mineral rock salt, but the solid does not conduct electricity because the ions are locked into place. Sodium chloride must be molten for electrolysis to occur. The electrodes in the cell are made of inert materials such as carbon, and the cell is designed to keep the sodium and chlorine produced by the electrolysis out of contact with each other and away from air. In a modification of the Downs process, the electrolyte is an aqueous solution of sodium chloride (see Section 15.6). The products of this chloralkali process are chlorine and aqueous sodium hydroxide. Thinking point: In the Downs process CaCl2 is added to the NaCl to reduce the latter’s melting point. Why then is calcium metal not produced at the cathode? Electroplating is the electrolytic deposition of a thin film of metal on an object (Fig. 13.16). The object to be electroplated (either metal or graphite-coated plastic) ¡ ¡ 13.13 APPLICATIONS OF ELECTROLYSIS 547 Chlorine Sodium chloride Molten sodium Ring-shaped steel cathode Molten NaCl and CaCl2 Grid Graphite anode FIGURE 13.15 In the Downs process, molten sodium chloride is electrolyzed with a graphite anode (at which the ClϪ ions are oxidized to chlorine) and a steel cathode (at which the Naϩ ions are reduced to sodium). The sodium and chlorine are kept apart by the hoods surrounding the electrodes. Calcium chloride is present to lower the melting point of sodium chloride to an economical temperature. FIGURE 13.16 Chromium plating lends decorative flair as well as electrochemical protection to the steel of this motorcycle. Large quantities of electricity are needed for chromium plating because six electrons are required to produce each atom of chromium from chromium(VI) oxide. constitutes the cathode, and the electrolyte is an aqueous solution of a salt of the plating metal. Metal is deposited on the cathode by reduction of ions in the electrolyte solution. These cations are supplied either by the added salt or from oxidation of the anode, which is made of the plating metal. Electrolysis is used industrially to produce aluminum and magnesium; to extract metals from their salts; to prepare chlorine, fluorine, and sodium hydroxide; to refine copper; and in electroplating. 13.14 Corrosion Corrosion is the unwanted oxidation of a metal. It cuts short the lifetimes of steel products such as bridges and automobiles, and replacing corroded metal parts costs billions of dollars a year. Corrosion is an electrochemical process, and the electrochemical series is a source of insight into why corrosion occurs and how to prevent it. The main culprit in corrosion is water. One half-reaction that we have to take into account is 2 H2O(l) ϩ 2 eϪ H2(g) ϩ 2 OHϪ (aq) E° ϭ Ϫ0.83 V This standard potential is for an OHϪ concentration of 1 molиLϪ1 , which corresponds to pH ϭ 14, a strongly basic solution. However, from the Nernst equation, we can calculate that, at pH ϭ 7, this couple has E ϭ Ϫ0.42 V. Any metal with a standard potential more negative than Ϫ0.42 V can therefore reduce water at pH ϭ 7: that is, at this pH, any such metal can be oxidized by water. Because E° ϭ Ϫ0.44 V for Fe2ϩ (aq) ϩ 2 eϪ : Fe(s), iron has only a very slight tendency to be oxidized by water at pH ϭ 7. For this reason, iron can be used for pipes in water supply systems and can be stored in oxygen-free water without rusting (Fig. 13.17). The rusting of iron in the environment occurs when iron is exposed to damp air, with both oxygen and water present. Then the half-reaction O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ 2 H2O(l) E° ϭ ϩ1.23 V must be taken into account. The potential of this half-reaction at pH ϭ 7 and p(O2) ϭ 0.2 bar is ϩ0.81 V, which lies well above the value for iron. Hence, iron can reduce oxygen in aqueous solution at pH ϭ 7. In other words, oxygen and water can jointly oxidize iron metal to iron(II) ions. They can also subsequently work together to oxidize the iron(II) ions to iron(III), because E° ϭ ϩ0.77 V for Fe3ϩ (aq) ϩ eϪ : Fe2ϩ (aq). Let’s look in more detail at the processes. A drop of water on the surface of iron can act as the electrolyte for corrosion in a tiny electrochemical cell (Fig. 13.18). At the edge of the drop, dissolved oxygen oxidizes the iron in the process 2 Fe(s) 2 Fe2ϩ (aq) ϩ 4 eϪ O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ 2 H2O(l) Overall: 2 Fe(s) ϩ O2(g) ϩ 4 Hϩ (aq) 2 Fe2ϩ (aq) ϩ 2 H2O(l) (E) The electrons withdrawn from the metal by this oxidation can be restored from another part of the conducting metal—in particular, from iron lying beneath the oxygen-poor region in the center of the drop. The iron atoms there give up their electrons to the iron atoms at the edge of the drop, form Fe2ϩ ions, and drift away into the surrounding water. This process results in the formation of tiny pits in the surface of the iron. The Fe2ϩ ions are then oxidized further to Fe3ϩ by the dissolved oxygen: 2 Fe2ϩ (aq) 2 Fe3ϩ (aq) ϩ 2 eϪ O2(g) ϩ 2 Hϩ (aq) ϩ 2 eϪ H2O(l) Overall: 2 Fe2ϩ (aq) ϩ O2(g) ϩ 2 Hϩ (aq) 2 Fe3ϩ (aq) ϩ H2O(l) (F) These ions then precipitate as a hydrated iron(III) oxide, Fe2O3иH2O, the brown, insoluble substance that in its impure form we call rust. The oxide ions can be regarded as ¡ 1 2 ¡ 1 2 ¡ ¡ ¡ ¡ ¡ ¡ 548 CHAPTER 13 ELECTROCHEMISTRY FIGURE 13.17 Iron nails stored in oxygen-free water (left) do not rust, because the oxidizing power of water itself is weak. When oxygen is present (as a result of air dissolving in the water, right), oxidation is thermodynamically spontaneous and rust soon forms. Oxidation Oxidation Regeneration of H+ (aq) (c) (b) (a) DepositionProton transfer Rust Anode Iron Cathode O2(g) O2(g) AirWater droplet O2(g) H+ (aq) H+ (aq) Fe2+ (aq) Fe3+ (aq) Fe3+ (aq) Fe2+ (aq) H+ (aq) Fe(s) H2O(l) H2O(l) H2O(l) e− e− FIGURE 13.18 The mechanism of rust formation in a drop of water. (a) Oxidation of the iron occurs at a location out of contact with the oxygen of the air. The surface of the metal acts as an anode in a tiny galvanic cell, with the metal at the outer edge of the drop serving as the cathode. (b) Further oxidation of Fe2ϩ results in the formation of Fe3ϩ ions. (c) Protons are removed from H2O as oxide ions combine with Fe3ϩ ions to deposit as rust. These protons are recycled, as indicated by the dotted line. coming from deprotonation of water molecules and as immediately forming the hydrated solid by precipitation with the Fe3ϩ ions produced in reaction F: 4 H2O(l) ϩ 2 Fe3ϩ (aq) 6 Hϩ (aq) ϩ Fe2O3иH2O(s) (G) This step restores the Hϩ (aq) ions needed for reaction E, and so hydrogen ions function as a catalyst. The removal of Fe3ϩ ions from solution drives the reaction forward. The overall process is the sum of reactions E, F, and G: 2 Fe(s) ϩ O2(g) ϩ H2O(l) Fe2O3иH2O(s) Water is more highly conducting when it has dissolved ions, and the formation of rust is then accelerated. That is one reason why the salt air of coastal cities and salt used for de-icing highways is so damaging to exposed metal. Because corrosion is electrochemical, we can use our knowledge of redox reactions to combat it. The simplest way to prevent corrosion is to protect the surface of the metal from exposure to air and water by painting. A method that achieves greater protection is to galvanize the metal, coating it with an unbroken film of zinc (Fig. 13.19). Zinc lies below iron in the electrochemical series; so, if a scratch exposes the metal beneath, the more strongly reducing zinc releases electrons to the iron. As a result, the zinc, not the iron, is oxidized. The zinc itself survives exposure on the unbroken surface because it is passivated, protected from further reaction, by a protective oxide. In general, the oxide of any metal that takes up more space than does the metal that it replaces acts as a protective oxide, an oxide that protects the metal from further oxidation. Zinc and chromium both form low-density protective oxides that can protect iron from oxidation. It is not possible to galvanize large metal structures, such as ships, underground pipelines, gasoline storage tanks, and bridges, but cathodic protection can be used. For example, a block of a more strongly reducing metal than iron, typically zinc or magnesium, can be buried in moist soil and connected to an underground pipeline (Fig. 13.20). The block of magnesium is oxidized preferentially and supplies electrons to the iron for the reduction of oxygen. The block, which is called a sacrificial anode, protects the pipeline and is inexpensive to replace. For similar reasons, automobiles generally have negative ground systems as part of their electrical circuitry, which means that the body of the car is connected to the anode of the battery. The decay of the anode in the battery is the sacrifice that helps preserve the vehicle itself. A common means of protecting the steel bodies of automobiles and trucks is through cationic electrodeposition coatings. In this process, a corrosion-resistant primer is deposited electrochemically on the automobile body, which serves as the cathode for the process. For many years lead(IV) oxide was used to provide this corrosion protection. However, lead is toxic and concerns for environmental pollution stimulated research into alternative metals for cationic electrodeposition coatings. Eventually it was ¡ 3 2 ¡ 13.14 CORROSION 549 FIGURE 13.19 Steel girders are galvanized by immersion in a bath of molten zinc. Electrons Pipeline Magnesium FIGURE 13.20 In the cathodic protection of a buried pipeline or other large metal construction, the artifact is connected to a number of buried blocks of metal, such as magnesium or zinc. The sacrificial anodes (the magnesium block in this illustration) supply electrons to the pipeline (the cathode of the cell), thereby preserving it from oxidation. discovered that yttrium oxide also offers corrosion resistance and, in fact, is twice as effective as lead. Yet yttrium is nontoxic and its oxide is a ceramic. Thus, the oxide is insoluble in water and is not spread into the environment through waterways. Self-Test 13.17A Which of the following procedures helps to prevent the corrosion of an iron rod in water: (a) decreasing the concentration of oxygen in the water; (b) painting the rod? [Answer: Both] Self-Test 13.17B Which of the following elements can act as a sacrificial anode for iron: (a) copper; (b) aluminum; (c) tin? The corrosion of iron is accelerated by the presence of oxygen, moisture, and salt. Corrosion can be inhibited by coating the surface with paint or zinc or by using cathodic protection. 13.15 Practical Cells An important application of galvanic cells is their use as the portable power sources called batteries. An ideal battery should be inexpensive, portable, safe to use, and environmentally benign. It should also maintain a potential difference that is stable with the passage of time (Table 13.2). Both the mass and the volume of a battery are critical parameters. The electrolyte in a battery uses as little water as possible, both to reduce leakage of the electrolyte and to keep the mass low. Much of the research on batteries deals with raising the specific energy (the energy that it can generate divided by its mass), typically expressed in kilowatt-hours per kilogram, kWиhиkgϪ1 . A primary cell is a galvanic cell with the reactants sealed inside at manufacture. It cannot be recharged; when it runs down, it is discarded. A fuel cell is like a primary cell, but the reactants are continuously supplied (Box 13.1). 550 CHAPTER 13 ELECTROCHEMISTRY 1 kW·h ‫؍‬ (103 J·s؊1 ) ؋ (3600 s) ‫؍‬ 3.6 ؋ 106 J ‫؍‬ 3.6 MJ exactly. TABLE 13.2 Reactions in Commercial Batteries* Primary cells dry Zn(s)͉ZnCl2(aq), NH4Cl(aq)͉MnO(OH)(s)͉MnO2(s)͉graphite 1.5 V Anode: Zn(s) Zn2ϩ (aq) ϩ 2 eϪ followed by Zn2ϩ (aq) ϩ 4 NH3(aq) [Zn(NH3)4]2ϩ (aq) Cathode: MnO2(s) ϩ H2O(l) ϩ eϪ MnO(OH)(s) ϩ OHϪ (aq) followed by NH4 ϩ (aq) ϩ OHϪ (aq) H2O(l) ϩ NH3(aq) alkaline Zn(s)͉ZnO(s)͉OHϪ (aq)͉Mn(OH)2(s)͉MnO2(s)͉graphite 1.5 V Anode: Zn(s) ϩ 2 OHϪ (aq) ZnO(s) ϩ H2O(l) ϩ 2 eϪ Cathode: MnO2(s) ϩ 2 H2O(l) ϩ 2 eϪ Mn(OH)2(s) ϩ 2 OHϪ (aq) silver Zn(s)͉ZnO(s)͉KOH(aq)͉Ag2O(s)͉Ag(s)͉steel 1.6 V Anode: Zn(s) ϩ 2 OHϪ (aq) ZnO(s) ϩ H2O(l) ϩ 2 eϪ Cathode: Ag2O(s) ϩ H2O(l) ϩ 2 eϪ 2 Ag(s) ϩ 2 OHϪ (aq) Secondary cells lead–acid Pb(s)͉PbSO4(s)͉Hϩ (aq), HSO4 Ϫ (aq)͉PbO2(s)͉PbSO4(s)͉Pb(s) 2 V Anode: Pb(s) ϩ HSO4 Ϫ (aq) PbSO4(s) ϩ Hϩ (aq) ϩ 2 eϪ Cathode: PbO2(s) ϩ 3 Hϩ (aq) ϩ HSO4 Ϫ (aq) ϩ 2 eϪ PbSO4(s) ϩ 2 H2O(l) nicad Cd(s)͉Cd(OH)2(s)͉KOH(aq)͉Ni(OH)3(s)͉Ni(OH)2(s)͉Ni(s) 1.25 V Anode: Cd(s) ϩ 2 OHϪ (aq) Cd(OH)2(s) ϩ 2 eϪ Cathode: 2 Ni(OH)3(s) ϩ 2 eϪ 2 Ni(OH)2(s) ϩ 2 OHϪ (aq) NiMH M(s)͉MH(s)͉KOH(aq)͉NiOOH(s)͉Ni(OH)2(s)͉Ni(s) 1.2 V Anode: MH(s)† ϩ OHϪ (aq) M(s) ϩ H2O(l) ϩ eϪ Cathode: NiOOH(s) ϩ H2O(l) ϩ eϪ Ni(OH)2(s) ϩ OHϪ sodium–sulfur Na(l)͉Naϩ (ceramic electrolyte),S2Ϫ (ceramic electrolyte)͉S8(l) 2.2 V Anode: 2 Na(l) 2 Naϩ (electrolyte) ϩ 2 eϪ Cathode: S8(l) ϩ 16 eϪ 8 S2Ϫ (electrolyte) *Cell notation is described in Section 13.5. † The metal in a nickel–metal hydride battery is usually a complex alloy of several metals, such as Cr, Ni, Co, V, Ti, Fe, and Zr. ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ 13.15 PRACTICAL CELLS 551 A dry cell is the primary cell used in most common applications, such as portable media players, remote controls, and flashlights (Fig. 13.21). Its familiar cylindrical zinc container serves as the anode; in the center is the cathode, a carbon rod. The interior of the container is lined with paper that serves as the porous barrier. The electrolyte is a moist paste of ammonium chloride, manganese(IV) oxide, finely granulated carbon, and an inert filler, usually starch. The ammonia provided by the ammonium ions forms the complex ion Zn(NH3)4 2ϩ with the Zn2ϩ ions and prevents their buildup and a consequent reduction of the potential. Two primary cells that provide a more stable and longer-lasting potential than the dry cell are the alkaline cell and silver cell. An alkaline cell is similar to a dry cell but uses an alkaline electrolyte, with which the zinc electrode does not readily react when the battery is not in use. As a result, alkaline cells have longer lives than dry cells. They are used in smoke detectors and backup power supplies. A silver cell has a cathode made of solid Ag2O and Ag. The relatively high potential of a silver cell, with its solid reactants and products, is maintained with great reliability over long periods of time and the cell can be manufactured in very small sizes. These features make it desirable for medical implants such as pacemakers, for hearing aids, and for cameras. Secondary cells are galvanic cells that must be charged before they can be used; this type of cell is normally rechargeable. The batteries used in portable computers and automobiles are secondary cells. In the charging process, an external source of electricity reverses the spontaneous cell reaction and creates a nonequilibrium mixture of reactants. After charging, the cell can again produce electricity. The lead-acid cell of an automobile battery is a secondary cell that contains several grids that act as electrodes (Fig. 13.22). Although it has a low specific energy, because the total surface area of these grids is large, the battery can generate large currents for short periods, such as the time needed for starting an engine. The electrodes are initially a hard lead–antimony alloy covered with a paste of lead(II) sulfate. The electrolyte is dilute sulfuric acid. During the first charging, some of the lead(II) sulfate is reduced to lead on one of the electrodes; that electrode will act as the anode during discharge. Simultaneously, during charging, lead(II) sulfate is oxidized to lead(IV) oxide on the electrode that will later act as the cathode during discharge. The lead–acid cell, which has a potential of 2 V, is used in a series of six cells to provide a 12-V source of power for starting the engine in most vehicles and as the main power source in many electric vehicles. Hybrid vehicles make use of the rechargeable nickel–metal hydride (NiMH) cell to supplement energy provided by burning gasoline. In this type of battery, hydrogen is stored in the form of a metal hydride, using a heterogeneous alloy of several metals, commonly including titanium, vanadium, chromium, and nickel. The advantages include low mass, high energy density (the energy that it can generate divided by its volume), long shelf life, high current load capability, rapid charging, and good capacity (long time between charges). Because the materials are nontoxic, disposal of the batteries does not generate environmental problems. The lithium-ion cell is used in laptop computers and many media players, because it can be recharged many times. This type of battery has an electrolyte consisting of polypropylene oxide or polyethylene oxide mixed with molten lithium salts and then allowed to cool. The resulting rubbery materials serve as good conductors of Liϩ ions. The low mass density of lithium gives it the highest available energy density, and lithium’s very negative electrode potential provides a cell potential as high as 4 V. A sodium–sulfur cell is one of the more startling batteries (Fig. 13.23). It has liquid reactants (sodium and sulfur) and a solid electrolyte (a porous aluminum oxide ceramic); it must operate at a temperature of about 320°C; and it is highly dangerous in case of breakage. Because sodium has a low density, these cells have a very high specific energy. Their most common application is to power electric vehicles. Once the vehicle is operating, the heat generated by the battery is sufficient to maintain the temperature. Practical galvanic cells can be classified as primary cells (reactants are sealed inside in a charged state), secondary cells (can be recharged), and fuel cells. Carbon rod (cathode) Zinc cup (anode) MnO2, carbon black, and NH4Cl (electrolyte) FIGURE 13.21 A commercial dry cell. The dry cell is also called the Leclanché cell, for Georges Leclanché, the French engineer who invented it in about 1866. The electrolyte is a moist paste. Anode grid Cathode grid Separator FIGURE 13.22 A lead–acid battery consists of a number of cells in series. A series of six cells produces about 12 V. FIGURE 13.23 A sodium–sulfur battery used in an electric vehicle. 552 CHAPTER 13 ELECTROCHEMISTRY ❑ 1 Balance chemical equations for redox reactions by the half-reaction method (Toolbox 13.1 and Examples 13.1 and 13.2). ❑ 2 Estimate the reaction Gibbs free energy from a cell potential (Example 13.3). ❑ 3 Write the cell diagram for a redox reaction (Self-Test 13.4). ❑ 4 Write the chemical equation for a cell reaction, given the cell diagram (Toolbox 13.2 and Example 13.4). ❑ 5 Determine the standard potential of an electrode from a cell potential (Example 13.5). ❑ 6 Calculate the standard potential of a redox couple from two others relating to different oxidation states (Example 13.6). ❑ 7 Predict the spontaneous direction of a redox reaction by using the electrochemical series (Example 13.7). ❑ 8 Calculate the equilibrium constant for a reaction from the standard cell potential (Toolbox 13.3 and Example 13.8). ❑ 9 Use the Nernst equation to predict a cell potential for an arbitrary composition of the cell (Examples 13.9 and 13.10). ❑ 10 Predict the likely products of electrolysis of an aqueous solution from standard potentials (Example 13.11). ❑ 11 Calculate the amount of product produced from electrolysis or the time required for electrolysis (Toolbox 13.4 and Examples 13.12 and 13.13). ❑ 12 Describe corrosion and means for protecting iron from corrosion (Section 13.14). ❑ 13 Describe the operation of commercial practical cells (Section 13.15). SKILLS YOU SHOULD HAVE MASTERED Spacecraft need a source of electrical power and astronauts need enough water for drinking and washing. Because the mass of spacecraft that are built to lift off from planets must be kept as low as possible, most batteries—which usually provide energy from the oxidation of a metal—would be too heavy. Electricity can be obtained from combustion reactions by burning a fuel to create heat, which runs a generator. However, producing electricity from burning fuels is very inefficient because energy is wasted as heat. An answer to the problem already existed. Francis Bacon, a British scientist and engineer, had developed an idea proposed by Sir William Grove in 1839. A fuel cell generates electricity directly from a chemical reaction, as in a battery, but uses reactants that are supplied continuously, as in an engine. A fuel cell that runs on hydrogen and oxygen is currently installed on the space shuttle (see Fig. L.1). An advantage of this fuel cell is that the only product of the cell reaction, water, can be used for life support. In a simple version of a fuel cell, a fuel such as hydrogen gas is passed over a platinum electrode, oxygen is passed over the other, similar electrode, and the electrolyte is aqueous potassium hydroxide. A porous membrane that is permeable to ions separates the two electrode compartments. Many varieties of fuel cells are possible, and in some the electrolyte is a solid polymer membrane or a ceramic (see Section 6.11). Three of the most promising fuel cells are the alkali fuel cell, the phosphoric acid fuel cell, and the methanol fuel cell. The hydrogen–oxygen cell used in the space shuttle is called an alkali fuel cell, because it has an alkaline electrolyte: Anode: 2 H2(g) ϩ 4 OHϪ (aq) 4 H2O(l) ϩ 4 eϪ Electrolyte: KOH(aq) Cathode: O2(g) ϩ 4 eϪ ϩ 2 H2O(l) 4 OHϪ (aq) Although its cost prohibits its use in many applications, the alkali fuel cell is the primary fuel cell used in the aerospace industry. ¡ ¡ FRONTIERS OF CHEMISTRY: FUEL CELLSBOX 13.1 eϪ Cathode Anode Hydrogen Oxygen Ions Ions Carbon particle Catalyst particle Polymer electrolyte Membrane eϪeϪ A proton exchange membrane is used in both hydrogen and methanol fuel cells. It allows protons but not electrons to travel through it: the protons flow through the porous membrane to the cathode, where they combine with oxygen to form water, while the electrons flow through an external circuit. Several layers of cells are combined to generate the power required. An acid electrolyte may also be used, as in a phosphoric acid fuel cell: Anode: 2 H2(g) 4 Hϩ (aq) ϩ 4 eϪ Electrolyte: H3PO4(aq) Cathode: O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ 2 H2O(l) This fuel cell has shown promise for combined heat and power systems (CHP systems). In such systems, the waste heat is used to heat buildings or to do work. Efficiency in a CHP plant can reach 80%. These plants could replace heating plants and power sources in colleges and universities, hotels, and apartment buildings. Although hydrogen gas is an attractive fuel, it has disadvantages for mobile applications: it is difficult to store and dangerous to handle. One possibility for portable fuel cells is to store the hydrogen in nanotubes made of carbon, silicon, or compounds ¡ ¡ EXERCISES 553 such as WS2 or TiO2. Hydrogen molecules are readily adsorbed on the surfaces of these materials and nanotubes have very large surface areas. Carbon nanofibers in herringbone patterns have been shown to store huge amounts of hydrogen and to result in energy densities twice that of gasoline. Another option is the use of organometallic materials or inorganic hydrides, such as sodium aluminum hydride, NaAlH4, doped with titanium. Until these materials have been developed, one attractive fuel is methanol, which is easy to handle and is rich in hydrogen atoms: Anode: CH3OH(l) ϩ 6 OHϪ (aq) 5 H2O(l) ϩ CO2(g) ϩ 6 eϪ Electrolyte: polymeric materials Cathode: O2(g) ϩ 4 eϪ ϩ 2 H2O(l) 4 OHϪ (aq) A disadvantage of methanol is the phenomenon of “electro-osmotic drag” in which protons moving through the polymer proton exchange electrolyte membrane that separates the anode and cath- ¡ ¡ This automobile is powered by a hydrogen fuel cell with a proton exchange membrane. Its operation is pollution free, because the only product of the combustion is water. ode carry water and methanol with them into the cathode compartment. In the cathode, the potential is sufficient to oxidize CH3OH to CO2, thereby reducing the efficiency of the cell. One solution might be to find a material for the cathode that is selective to oxygen reduction so that any methanol that leaks in is not oxidized. An exciting emerging technology is the biofuel cell. A biofuel cell is like a conventional fuel cell; however, in place of a platinum catalyst, it uses enzymes or even whole organisms. The electricity is extracted through organic molecules that can support the transfer of electrons. One application is as the power source for medical implants, such as pacemakers, perhaps by using the glucose present in the bloodstream as the fuel. HOW MIGHT YOU CONTRIBUTE? Fuel cell technologies developed for aerospace have the potential to change the way we live on Earth. Automobiles powered by hydrogen fuel cells are already being manufactured (see the illustration). However, there are many obstacles that must be overcome before fuel cells reach their potential to provide us with pollution-free energy. The hydrogen fuel cells are the most attractive, because of their use of a renewable fuel. Hydrogen can be obtained from the water in the oceans. The challenge is to extract it from seawater by using solar energy and to find safe means of transportation and storage. Many practical problems with fuel cells also need to be solved, such as controlling corrosion by electrolytes and reducing the cell size and operating temperature. The development of biofuel cells is also potentially of great significance. Related Exercises: 13.69–13.72. For Further Reading: Breakthrough Technologies Institute, “The Online Fuel Cell Information Center,” http://www.fuelcells.org/. S. Ritter, “Sunny forecast for fuel cells,” Chemical and Engineering News, vol. 86, August 4, 2008, p. 7. D. Castelvecchi, “Is your phone out of juice? Biological fuel cell turns drinks into power,” Science News, vol. 171, March 31, 2007, p. 197. S. M. Kwan & K. L. Yeung, “Zeolite micro fuel cell,” Chemical Communications, 2008, p. 3631. ? Assume a temperature of 25°C (298 K) for the following exercises unless instructed otherwise. Redox Equations 13.1 The following redox reaction is used in acidic solution in the Breathalyzer test to determine the level of alcohol in the blood: Hϩ (aq) ϩ Cr2O7 2– (aq) ϩ C2H5OH(aq) ∫B Cr3ϩ (aq) ϩ C2H4O(aq) ϩ H2O(l) (a) Identify the elements undergoing changes in oxidation state and indicate the initial and final oxidation numbers for these elements. (b) Write and balance the oxidation half-reaction. (c) Write and balance the reduction half-reaction. (d) Combine the half-reactions to produce a balanced redox equation. 13.2 The following redox reaction is used to prepare orthotelluric acid: Te(s) ϩ ClO3 Ϫ (aq) ϩ H2O(l) H6TeO6(aq) ϩ Cl2(g) (a) Identify the elements undergoing changes in oxidation state and indicate the initial and final oxidation numbers for these elements. (b) Write and balance the oxidation half-reaction. (c) Write and balance the reduction half-reaction. (d) Combine the half-reactions to produce a balanced redox equation. 13.3 Balance each of the following skeletal equations by using oxidation and reduction half-reactions. All the reactions take place in acidic solution. Identify the oxidizing agent and reducing agent in each reaction. (a) Reaction of thiosulfate ion with chlorine gas: Cl2(g) ϩ S2O3 2Ϫ (aq) : ClϪ (aq) ϩ SO4 2Ϫ (aq) (b) Action of the permanganate ion on sulfurous acid: MnO4 Ϫ (aq) ϩ H2SO3(aq) : Mn2ϩ (aq) ϩ HSO4 Ϫ (aq) (c) Reaction of hydrosulfuric acid with chlorine: H2S(aq) ϩ Cl2(g) : S(s) ϩ ClϪ (aq)¡ EXERCISES 554 CHAPTER 13 ELECTROCHEMISTRY (d) Reaction of chlorine in water: Cl2(g) : HClO(aq) ϩ ClϪ (aq) 13.4 Balance each of the following skeletal equations by using oxidation and reduction half-reactions. All the reactions take place in acidic solution. Identify the oxidizing agent and reducing agent in each reaction. (a) Reaction of the selenite ion with chlorate ion: SeO3 2Ϫ (s) ϩ ClO3 Ϫ (aq) : SeO4 2Ϫ (aq) ϩ Cl2(g) (b) Formation of propanone (acetone), which is used in nail polish remover, from isopropanol (rubbing alcohol) by the action of dichromate ion: C3H7OH(aq) ϩ Cr2O7 2Ϫ (aq) : Cr3ϩ (aq) ϩ C3H6O(aq) (c) Reaction of gold with selenic acid: Au(s) ϩ SeO4 2Ϫ (aq) : Au3ϩ (aq) ϩ SeO3 2Ϫ (aq) (d) Preparation of stibnine from antimonic acid: H2SbO3 2Ϫ (s) ϩ Zn(s) : SbH3(aq) ϩ Zn2ϩ (aq) 13.5 Balance each of the following skeletal equations by using oxidation and reduction half-reactions. All the reactions take place in basic solution. Identify the oxidizing agent and reducing agent in each reaction. (a) Action of ozone on bromide ions: O3(aq) ϩ BrϪ (aq) : O2(g) ϩ BrO3 Ϫ (aq) (b) Reaction of bromine in water: Br2(l) : BrO3 Ϫ (aq) ϩ BrϪ (aq) (c) Formation of chromate ions from chromium(III) ions: Cr3ϩ (aq) ϩ MnO2(s) : Mn2ϩ (aq) ϩ CrO4 2Ϫ (aq) (d) Reaction of elemental phosphorus to form phosphine, PH3, a poisonous gas with the odor of decaying fish: P4(s) : H2PO2 Ϫ (aq) ϩ PH3(g) 13.6 Balance each of the following skeletal equations by using oxidation and reduction half-reactions. All the reactions take place in basic solution. Identify the oxidizing agent and reducing agent in each reaction. (a) Production of chlorite ions from dichlorine heptoxide: Cl2O7(g) ϩ H2O2(aq) : ClO2 Ϫ (aq) ϩ O2(g) (b) Action of permanganate ions on sulfide ions: MnO4 Ϫ (aq) ϩ S2Ϫ (aq) : S(s) ϩ MnO2(s) (c) Reaction of hydrazine with chlorate ions: N2H4(g) ϩ ClO3 Ϫ (aq) : NO(g) ϩ ClϪ (aq) (d) Reaction of plumbate ions and hypochlorite ions: Pb(OH)4 2Ϫ (aq) ϩ ClOϪ (aq) : PbO2(s) ϩ ClϪ (aq) 13.7 The compound P4S3 is oxidized by nitrate ions in acid solution to give phosphoric acid, sulfate ions, and nitric oxide, NO. Write the balanced equation for each half-reaction and the overall equation for the reaction. 13.8 Iron(II) hydrogen phosphite, FeHPO3, is oxidized by hypochlorite ions in basic solution. The products are chloride ion, phosphate ion, and iron(III) hydroxide. Write the balanced equation for each half-reaction and the overall equation for the reaction. Galvanic Cells 13.9 Calculate the standard reaction Gibbs free energy for the following cell reactions: (a) 2 Ce4ϩ (aq) ϩ 3 IϪ (aq) : 2 Ce3ϩ (aq) ϩ I3 Ϫ (aq), Ecell° ϭ ϩ1.08 V (b) 6 Fe3ϩ (aq) ϩ 2 Cr3ϩ (aq) ϩ 7 H2O(l) : 6 Fe2ϩ (aq) ϩ Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq), Ecell° ϭ Ϫ1.29 V 13.10 Calculate the standard reaction Gibbs free energy for the following cell reactions: (a) 3 Cr3ϩ (aq) ϩ Bi(s) : 3 Cr2ϩ (aq) ϩ Bi3ϩ (aq), Ecell° ϭ Ϫ0.61 V (b) Mg(s) ϩ 2 H2O(l) : Mg2ϩ (aq) ϩ H2(g) ϩ 2 OHϪ (aq), Ecell° ϭ ϩ2.36 V 13.11 Write the half-reactions and the balanced equation for the cell reaction for each of the following galvanic cells: (a) Ni(s)|Ni2ϩ (aq)||Agϩ (aq)|Ag(s) (b) C(gr)|H2(g)|Hϩ (aq)||ClϪ (aq)|Cl2(g)|Pt(s) (c) Cu(s)|Cu2ϩ (aq)||Ce4ϩ (aq),Ce3ϩ (aq)|Pt(s) (d) Pt(s)|O2(g)|Hϩ (aq)||OHϪ (aq)|O2(g)|Pt(s) (e) Pt(s)|Sn4ϩ (aq),Sn2ϩ (aq)||ClϪ (aq)|Hg2Cl2(s)|Hg(l) 13.12 Write the half-reactions and the balanced equation for the cell reaction for each of the following galvanic cells: (a) Cu(s)|Cu2ϩ (aq)||Cuϩ (aq)|Cu(s) (b) Cr(s)|Cr2ϩ (aq)||Au3ϩ (aq)|Au(s) (c) Ag(s)|AgI(s)|IϪ (aq)||ClϪ (aq)|AgCl(s)|Ag(s) (d) Hg(l)|Hg2Cl2(s)|ClϪ (aq)||ClϪ (aq)|AgCl(s)|Ag(s) (e) Hg(l)|Hg2 2ϩ (aq)||MnO4 Ϫ (aq),Mn2ϩ (aq),Hϩ (aq)|Pt(s) 13.13 Write the half-reactions, the balanced equation for the cell reaction, and the cell diagram for each of the following skeletal equations: (a) Ni2ϩ (aq) ϩ Zn(s) : Ni(s) ϩ Zn2ϩ (aq) (b) Ce4ϩ (aq) ϩ IϪ (aq) : I2(s) ϩ Ce3ϩ (aq) (c) Cl2(g) ϩ H2(g) : HCl(aq) (d) Auϩ (aq) : Au(s) ϩ Au3ϩ (aq) 13.14 Write the half-reactions, the balanced equation for the cell reaction, and the cell diagram for each of the following skeletal equations: (a) Mn(s) ϩ Ti2ϩ (aq) : Mn2ϩ (aq) ϩ Ti(s) (b) Fe3ϩ (aq) ϩ H2(g) : Fe2ϩ (aq) ϩ Hϩ (aq) (c) Cuϩ (aq) : Cu(s) ϩ Cu2ϩ (aq) (d) MnO4 Ϫ (aq) ϩ Hϩ (aq) ϩ ClϪ (aq) : Cl2(g) ϩ Mn2ϩ (aq) ϩ H2O(l) 13.15 Write the half-reactions and devise a galvanic cell (write a cell diagram) to study each of the following reactions: (a) AgBr(s) #4 Agϩ (aq) ϩ BrϪ (aq), a solubility equilibrium (b) Hϩ (aq) ϩ OHϪ (aq) : H2O(l), the Brønsted neutralization reaction (c) Cd(s) ϩ 2 Ni(OH)3(s) : Cd(OH)2(s) ϩ 2 Ni(OH)2(s), the reaction in the nickel–cadmium cell 13.16 Write balanced half-reactions and devise a galvanic cell (write a cell diagram) to study each of the following reactions: (a) Pb(NO3)2(aq) ϩ K2SO4(aq) : PbSO4(s) ϩ 2 KNO3(aq), a precipitation reaction (b) OHϪ (aq, concentrated) : OHϪ (aq, dilute) (c) Na(s) ϩ S(s) : Naϩ (l) ϩ S2Ϫ (l), the reaction in a sodium–sulfur cell 13.17 (a) Write balanced half-reactions for the redox reaction of an acidified solution of potassium permanganate and iron(II) chloride. (b) Write the balanced equation for the cell reaction and devise a galvanic cell to study the reaction (write its cell diagram). 13.18 (a) Write balanced half-reactions for the redox reaction between sodium perchlorate and copper(I) nitrate in an acidic solution. (b) Write the balanced equation for the cell reaction and devise a galvanic cell to study the reaction (write its cell diagram). 13.19 Predict the standard potential of each of the following galvanic cells: (a) Pt(s)|Cr3ϩ (aq),Cr2ϩ (aq)||Cu2ϩ (aq)|Cu(s) (b) Ag(s)|AgI(s)|IϪ (aq)||ClϪ (aq)|AgCl(s)|Ag(s) (c) Hg(l)|Hg2Cl2(s)|ClϪ (aq)||Hg2 2ϩ (aq)|Hg(l) (d) C(gr)|Sn4ϩ (aq),Sn2ϩ (aq)||Pb4ϩ (aq),Pb2ϩ (aq)|Pt(s) 13.20 Predict the standard potential of each of the following galvanic cells: (a) Pt(s)|Fe3ϩ (aq),Fe2ϩ (aq)||Agϩ (aq)|Ag(s) (b) U(s)|U3ϩ (aq)|| V2ϩ (aq)|V(s) (c) Sn(s)|Sn2ϩ (aq)||Sn4ϩ (aq), Sn2ϩ (aq)|Pt(s) (d) Cu(s)|Cu2ϩ (aq)||Auϩ (aq)|Au(s) 13.21 For each reaction that is spontaneous under standard conditions, write a cell diagram, determine the standard cell potential, and calculate ⌬G° for the reaction: (a) 2 NO3 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 6 Hg(l) : 3 Hg2 2ϩ (aq) ϩ 2 NO(g) ϩ 4 H2O(l) (b) 2 Hg2ϩ (aq) ϩ 2 BrϪ (aq) : Hg2 2ϩ (aq) ϩ Br2(l) (c) Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq) ϩ 6 Pu3ϩ (aq) : 6 Pu4ϩ (aq) ϩ 2 Cr3ϩ (aq) ϩ 7 H2O(l) 13.22 Predict the standard cell potential and calculate the standard reaction Gibbs free energy for galvanic cells having the following cell reactions: (a) 3 Zn(s) ϩ 2 Bi3ϩ (aq) : 3 Zn2ϩ (aq) ϩ 2 Bi(s) (b) 2 H2(g) ϩ O2(g) : 2 H2O(l) in acidic solution (c) 2 H2(g) ϩ O2(g) : 2 H2O(l) in basic solution (d) 3 Auϩ (aq) : 2 Au(s) ϩ Au3ϩ (aq) 13.23 A student was given a standard Cu(s)|Cu2ϩ (aq) half-cell and another half-cell containing an unknown metal M immersed in 1.00 M M(NO3)2(aq). When the copper was connected as the anode at 25°C, the cell potential was found to be Ϫ0.689 V. What is the reduction potential for the unknown M2ϩ /M couple? 13.24 A student was given a standard Fe(s)|Fe2ϩ (aq) half-cell and another half-cell containing an unknown metal M immersed in 1.00 M MNO3(aq). When these two half-cells were connected at 25°C, the complete cell functioned as a galvanic cell with Ecell ϭ ϩ1.24 V. The reaction was allowed to continue overnight and the two electrodes were weighed. The iron electrode was found to be lighter and the unknown metal electrode was heavier. What is the standard potential of the unknown Mϩ ͞M couple? 13.25 Arrange the following metals in order of increasing strength as reducing agents for species in aqueous solution: (a) Cu, Zn, Cr, Fe; (b) Li, Na, K, Mg; (c) U, V, Ti, Al; (d) Ni, Sn, Au, Ag. 13.26 Arrange the following species in order of increasing strength as oxidizing agents for species in aqueous solution: (a) Co2ϩ , Cl2, Ce4ϩ , In3ϩ ; (b) NO3 Ϫ , ClO4 Ϫ , HBrO, Cr2O7 2Ϫ , all in acidic solution; (c) O2, O3, HClO, and HBrO, all in acidic solution; (d) O2, O3, ClOϪ , BrOϪ , all in basic solution. 13.27 Using data available in Appendix 2B, calculate the standard potential for the half-reaction U4ϩ (aq) ϩ 4 eϪ : U(s). 13.28 Using data available in Appendix 2B, calculate the standard potential for the half-reaction Ti3ϩ (aq) ϩ 3 eϪ : Ti(s). 13.29 Suppose that each of the following pairs of redox couples is joined to form a galvanic cell that generates a current under standard conditions. Identify the oxidizing agent and the reducing agent, write a cell diagram, and calculate the standard cell potential. (a) Co2ϩ ͞Co and Ti3ϩ ͞Ti2ϩ ; (b) La3ϩ ͞La and U3ϩ ͞U; (c) Hϩ ͞H2 and Fe3ϩ ͞Fe2ϩ ; (d) O3͞O2,OHϪ and Agϩ ͞Ag. 13.30 Suppose that each of the following pairs of redox couples is joined to form a galvanic cell that generates a current under standard conditions. Identify the oxidizing agent and the reducing agent, write a cell diagram, and calculate the standard cell potential. (a) Pt2ϩ ͞Pt and AgF͞Ag,FϪ ; (b) Cr3ϩ ͞Cr2ϩ and I3 Ϫ ͞IϪ ; (c) Hϩ ͞H2 and Ni2ϩ ͞Ni; (d) O3͞O2, OHϪ and O3,Hϩ ͞O2. 13.31 Identify the reactions with K Ͼ 1 in the following list and, for each such reaction, identify the oxidizing agent and calculate the standard cell potential. (a) Cl2(g) ϩ 2 BrϪ (aq) : 2 ClϪ (aq) ϩ Br2(l) (b) MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 5 Ce3ϩ (aq) : 5 Ce4ϩ (aq) ϩ Mn2ϩ (aq) ϩ 4 H2O(l) (c) 2 Pb2ϩ (aq) : Pb(s) ϩ Pb4ϩ (aq) (d) 2 NO3 Ϫ (aq) ϩ 4 Hϩ (aq) ϩ Zn(s) : Zn2ϩ (aq) ϩ 2 NO2(g) ϩ 2 H2O(l) 13.32 Identify the reactions with K Ͼ 1 among the following reactions and, for each such reaction, write balanced reduction and oxidation half-reactions. For those reactions, show that K Ͼ 1 by calculating the standard Gibbs free energy of the reaction. Use the smallest whole-number coefficients to balance the equations. (a) Mg2ϩ (aq) ϩ Cu(s) : ? (b) Al(s) ϩ Pb2ϩ (aq) : ? (c) Hg2 2ϩ (aq) ϩ Ce3ϩ (aq) : ? (d) Zn(s) ϩ Sn2ϩ (aq) : ? (e) O2(g) ϩ Hϩ (aq) ϩ Hg(l) : ? 13.33 (a) The standard Gibbs free energy of formation of Tl3ϩ (aq) is ϩ215 kJ·molϪ1 at 25°C. Calculate the standard potential of the Tl3ϩ ͞Tl couple. (b) Will Tlϩ disproportionate in aqueous solution? 13.34 The standard potential of the Al3ϩ /Al couple is Ϫ1.66 V. Calculate the standard Gibbs free energy of formation for Al3ϩ (aq). Account for any differences between the standard Gibbs free energy of formation of Tl3ϩ (aq) (see Exercise 13.33) and that of Al3ϩ (aq). 13.35 Determine the equilibrium constants for the following reactions: (a) Mn(s) ϩ Ti2ϩ (aq) #4 Mn2ϩ (aq) ϩ Ti(s) (b) In3ϩ (aq) ϩ U3ϩ (aq) #4 In2ϩ (aq) ϩ U4ϩ (aq) 13.36 Determine the equilibrium constants for the following reactions: (a) 2 Fe3ϩ (aq) ϩ H2(g) #4 2 Fe2ϩ (aq) ϩ 2 Hϩ (aq) (b) 2 Cr(s) ϩ O2(g) ϩ 2 H2O(l) #4 2 Cr2ϩ (aq) ϩ 4 OHϪ (aq) 13.37 Calculate the reaction quotient, Q, for the cell reaction, given the measured values of the cell potential. Balance the chemical equations by using the smallest whole-number coefficients. (a) Pt(s)|Sn4ϩ (aq), Sn2ϩ (aq)||Pb4ϩ (aq), Pb2ϩ (aq)|C(gr), E ϭ ϩ1.33 V. (b) Pt(s)|O2(g)|Hϩ (aq)||Cr2O7 2Ϫ (aq), Hϩ (aq), Cr3ϩ (aq)|Pt(s), E ϭ ϩ0.10 V. 13.38 Calculate the reaction quotient, Q, for the cell reaction, given the measured values of the cell potential. Balance the chemical equations by using the smallest whole-number coefficients. (a) Ag(s)|Agϩ (aq)||ClO4 Ϫ (aq),Hϩ (aq),ClO3 Ϫ (aq)|Pt(s), E ϭ ϩ0.40 V. (b) C(gr)|Cl2(g)|ClϪ (aq)||Au3ϩ (aq)|Au(s), E ϭ 0.00 V. 13.39 Calculate E for each of the following concentration cells: (a) Cu(s)|Cu2ϩ (aq, 0.0010 mol·LϪ1 )||Cu2ϩ (aq, 0.010 molиLϪ1 )| Cu(s) EXERCISES 555 (b) Pt(s)|H2(g, 1 bar)|Hϩ (aq, pH ϭ 4.0)||Hϩ (aq, pH ϭ 3.0)|H2 (g, 1 bar)|Pt(s) 13.40 Determine the unknown concentration of the ion in each of the following cells: (a) Pb(s)|Pb2ϩ (aq, ?)||Pb2ϩ (aq, 0.10 mol·LϪ1 )|Pb(s), E ϭ ϩ0.050 V. (b) Pt(s)|Fe3ϩ (aq, 0.10 mol·LϪ1 ),Fe2ϩ (aq, 1.0 molиLϪ1 )|| Fe3ϩ (aq, ?),Fe2ϩ (aq, 0.0010 molиLϪ1 )|Pt(s), E ϭ ϩ0.10 V. 13.41 Determine the potential of each of the following cells: (a) Pt(s)|H2(g, 1.0 bar)|HCl(aq, 0.075 M)||HCl(aq, 1.0 molиLϪ1 )| H2(g, 1.0 bar)|Pt(s) (b) Zn(s)|Zn2ϩ (aq, 0.37 mol·LϪ1 )||Ni2ϩ (aq, 0.059 molиLϪ1 )|Ni(s) (c) Pt(s)|Cl2(g, 250 Torr)|HCl(aq, 1.0 M)||HCl(aq, 0.85 M)|H2(g, 125 Torr)|Pt(s) (d) Sn(s)|Sn2ϩ (aq, 0.277 molиLϪ1 )||Sn4ϩ (aq, 0.867 molиLϪ1 ), Sn2ϩ (aq, 0.55 molиLϪ1 )|Pt(s) 13.42 Determine the potential of each of the following cells: (a) Cr(s)|Cr3ϩ (aq, 0.37 molиLϪ1 )||Pb2ϩ (aq, 9.5 ϫ 10Ϫ3 molиLϪ1 )|Pb(s) (b) Pt(s)|H2(g, 2.0 bar)|Hϩ (pH ϭ 3.5)||ClϪ (aq, 0.75 molиLϪ1 )|Hg2Cl2(s)|Hg(l) (c) C(gr)|Sn4ϩ (aq, 0.059 mol·LϪ1 ),Sn2ϩ (aq, 0.059 mol·LϪ1 )|| Fe3ϩ (aq, 0.15 molиLϪ1 ),Fe2ϩ (aq, 0.15 molиLϪ1 )|Pt(s) (d) Ag(s)|AgI(s)|IϪ (aq, 0.025 molиLϪ1 )||ClϪ (aq, 0.67 molиLϪ1 )| AgCl(s)|Ag(s) 13.43 Determine the unknown quantity in each of the following cells: (a) Pt(s)|H2(g, 1.0 bar)|Hϩ (pH ϭ ?)||ClϪ (aq, 1.0 molиLϪ1 )| Hg2Cl2(s)|Hg(l), E ϭ ϩ0.33 V. (b) C(gr)|Cl2(g, 1.0 bar)|ClϪ (aq, ?)||MnO4 Ϫ (aq, 0.010 mol·LϪ1 ), Hϩ (pH ϭ 4.0), Mn2ϩ (aq, 0.10 mol·LϪ1 )|Pt(s), E ϭ Ϫ0.30 V. 13.44 Determine the unknown quantity in each of the following cells: (a) Pt(s)|H2(g, 1.0 bar)|Hϩ (pH ϭ ?)||ClϪ (aq,1.0 mol·LϪ1 )| AgCl(s)|Ag(s), E ϭ ϩ0.40 V. (b) Pb(s)|Pb2ϩ (aq, ?)||Ni2ϩ (aq, 0.20 mol·LϪ1 )|Ni(s), E ϭ ϩ0.050 V. 13.45 A tin electrode in 0.015 M Sn(NO3)2(aq) is connected to a hydrogen electrode in which the pressure of H2 is 1.0 bar. If the cell potential is 0.061 V at 25°C, what is the pH of the electrolyte at the hydrogen electrode? 13.46 A lead electrode in 0.010 M Pb(NO3)2(aq) is connected to a hydrogen electrode in which the pressure of H2 is 1.0 bar. If the cell potential is 0.057 V at 25°C, what is the pH of the electrolyte at the hydrogen electrode? 13.47 (a) Using data from Appendix 2B, calculate the solubility product of Hg2Cl2. (b) Compare this number with the value listed in Table 12.4 and comment on the difference. 13.48 (a) The standard potential of the reduction of Ag2CrO4 to Ag(s) and chromate ions is ϩ0.446 V. Write the balanced halfreaction for the reduction of silver chromate. (b) Using the data from part (a) and Appendix 2B, calculate the solubility product of Ag2CrO4(s). 13.49 Consider the cell Ag(s)|Agϩ (aq, 5.0 mmol·LϪ1 )||Agϩ (aq, 0.15 mol·LϪ1 )|Ag(s). Can this cell do work? If so, what is the maximum work that it can perform (per mole of Ag)? 13.50 Consider the cell Ag(s)|Agϩ (aq, 2.1 ϫ 10Ϫ4 mol·LϪ1 )|| Pb2ϩ (aq, 0.10 mol·LϪ1 )|Pb(s). (a) Can this cell do work? If so, what is the maximum work that it can perform (per mole of Pb)? (b) What is the value of ⌬H for the cell reaction and what is the sign of ⌬S? 13.51 Suppose the reference electrode for Table 13.1 were the standard calomel electrode, Hg2Cl2/Hg,ClϪ ([ClϪ ] ϭ 1.00 mol·LϪ1 ) with its E° set equal to 0. Under this system, what would be the potential for (a) the standard hydrogen electrode; (b) the standard Cu2ϩ /Cu redox couple? 13.52 Consider the question posed in Exercise 13.51 except that a saturated calomel electrode (the solution is saturated with KCl instead of having [ClϪ ] ϭ 1.00 mol·LϪ1 ) is used in place of the standard calomel electrode. How will this replacement change the answers given in Exercise 13.51? The solubility of KCl is 35 gи(100 mL H2O)Ϫ1 . Electrolysis For the exercises in this section, base your answers on the potentials listed in Table 13.1 or Appendix 2B, with the exception of the reduction and oxidation of water at pH ‫؍‬ 7: 2 H2O(l) ϩ 2 eϪ ∫B H2(g) ϩ 2 OHϪ (aq) E ϭ Ϫ0.42 V at pH ϭ 7 O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ ∫B 2 H2O(l) E ϭ ϩ0.82 V at pH ϭ 7 Ignore other factors such as passivation and overpotential. 13.53 A 1.0 M NiSO4(aq) solution was electrolyzed by using inert electrodes. Write (a) the cathode reaction; (b) the anode reaction. (c) With no overpotential or passivity at the electrodes, what is the minimum potential that must be supplied to the cell for the onset of electrolysis? 13.54 A 1.0 M KBr(aq) solution was electrolyzed by using inert electrodes. Write (a) the cathode reaction; (b) the anode reaction. (c) With no overpotential or passivity at the electrodes, what is the minimum potential that must be supplied to the cell for the onset of electrolysis? 13.55 Aqueous solutions of (a) Mn2ϩ ; (b) Al3ϩ ; (c) Ni2ϩ ; (d) Au3ϩ with concentrations of 1.0 mol·LϪ1 are electrolyzed at pH ϭ 7. Determine whether the metal ion or water will be reduced at the cathode. 13.56 The anode of an electrolytic cell was constructed from (a) Cr; (b) Pt; (c) Cu; (d) Ni. Determine whether oxidation of the electrode or of water will take place at the anode when the electrolyte consists of a 1.0 M solution of the oxidized metal ions at pH ϭ 7. 13.57 A total charge of 4.5 kC is passed through an electrolytic cell. Determine the quantity of substance produced in each case: (a) the mass (in grams) of bismuth metal from a bismuth nitrate solution; (b) the volume (in liters at 273 K and 1.00 atm) of hydrogen gas from a sulfuric acid solution; (c) the mass of cobalt (in grams) from a cobalt(III) chloride solution. 13.58 A total charge of 96.5 kC is passed through an electrolytic cell. Determine the quantity of substance produced in each case: (a) the mass (in grams) of silver metal from a silver nitrate solution; (b) the volume (in liters at 273 K and 1.00 atm) of chlorine gas from a brine solution (concentrated aqueous sodium chloride solution); (c) the mass of copper (in grams) from a copper(II) chloride solution. 556 CHAPTER 13 ELECTROCHEMISTRY 13.59 (a) How much time is required to electroplate 1.50 g of silver from a silver nitrate solution by using a current of 13.6 mA? (b) When the same current is used for the same length of time, what mass of copper can be electroplated from a copper(II) sulfate solution? 13.60 (a) When a current of 324 mA is used for 7.0 h, what volume (measured in liters at 298 K and 1.0 atm) of fluorine gas can be produced from a molten mixture of potassium and hydrogen fluorides? (b) With the same current and time period, how many liters of oxygen gas at 298 K and 1.0 atm can be produced from the electrolysis of water? 13.61 (a) What current is required to produce 2.5 g of chromium metal from chromium(VI) oxide in 12 h? (b) What current is required to produce 2.5 g of sodium metal from molten sodium chloride in the same period? 13.62 What current is required to electroplate 6.66 μg of gold in 30.0 min from a gold(III) chloride aqueous solution? (b) How much time is required to electroplate 6.66 μg of chromium from a potassium dichromate solution, by using a current of 100 mA? 13.63 When a ruthenium chloride solution was electrolyzed for 500 s with a 120-mA current, 31.0 mg of ruthenium was deposited. What is the oxidation number of ruthenium in the ruthenium chloride? 13.64 A 4.9-g sample of manganese was produced from a manganese nitrate aqueous solution when a current of 350 mA was passed for 13.7 h. What is the oxidation number of manganese in the manganese nitrate? 13.65 A current of 15.0 A electroplated 50.0 g of hafnium metal from an aqueous solution in 2.00 h. What is the oxidation number of hafnium in the solution? 13.66 A mass loss of 12.57 g occurred in 6.00 h at a titanium anode when a current of 4.70 A was used in an electrolytic cell. What is the oxidation number of the titanium in solution? 13.67 Copper from a 200.0-mL solution of copper(II) sulfate is plated on to the cathode of an electrolytic cell. (a) Hydronium ions are generated at one of the electrodes. Is this electrode the anode or cathode? (b) How many moles of H3Oϩ are generated if a current of 0.120 A is applied to the cell for 30.0 h? (c) If the pH of the solution was initially 7.0, what will be the pH of the solution after the electrolysis? Assume no change in the volume of solution. 13.68 Thomas Edison was faced with the problem of measuring the electricity that each of his customers had used. His first solution was to use a zinc “coulometer,” an electrolytic cell in which the quantity of electricity is determined by measuring the mass of zinc deposited. Only some of the current used by the customer passed through the coulometer. (a) What mass of zinc would be deposited in 1 month (of 31 days) if 1.0 mA of current passed through the cell continuously? (b) An alternative solution to this problem is to collect the hydrogen produced by electrolysis and measure its volume. What volume would be collected at 298 K and 1.00 bar under the same conditions? (c) Which method would be more practical? Impact on Materials 13.69 The “aluminum–air fuel cell” is used as a reserve battery in remote locations. In this cell aluminum reacts with the oxygen in air in basic solution. (a) Write the oxidation and reduction half-reactions for this cell. (b) Calculate the standard cell potential. See Box 13.1. 13.70 A fuel cell in which hydrogen reacts with nitrogen instead of oxygen is proposed. (a) Write the chemical equation for the reaction in water, which produces aqueous ammonia. (b) What would be the maximum free energy output of the cell for the consumption of 28.0 kg nitrogen? (c) Is this type of fuel cell thermodynamically feasible? See Box 13.1. 13.71 The body functions as a kind of fuel cell that uses oxygen from the air to oxidize glucose: C6H12O6(aq) ϩ 6 O2(g) 6 CO2(g) ϩ 6 H2O(l) During normal activity, a person uses the equivalent of about 10 MJ of energy a day. Assume that this value represents ⌬G, and estimate the average current through your body in the course of a day, assuming that all the energy that we use arises from the reduction of O2 in the glucose oxidation reaction. See Box 13.1. 13.72 A photoelectrochemical cell is an electrochemical cell that uses light to carry out a chemical reaction. This type of cell is being considered for the production of hydrogen from water. The silicon electrodes in a photoelectrochemical cell react with water: SiO2(s) ϩ 4 Hϩ (aq) ϩ 4 eϪ ∫B Si(s) ϩ 2 H2O(l) E° ϭ Ϫ0.84 V Calculate the standard cell potential for the reaction between silicon and water in a cell that also produces hydrogen from water and write the balanced equation for the cell reaction. See Box 13.1. 13.73 What is (a) the electrolyte and (b) the oxidizing agent in the mercury cell shown here? (c) Write the overall cell reaction for a mercury cell. 13.74 What is (a) the electrolyte and (b) the oxidizing agent during discharge in a lead–acid battery? (c) Write the reaction that takes place at the cathode during the charging of the lead–acid battery. 13.75 (a) Write the cell reaction for the lead–acid battery. (b) Explain how each of the following change in a lead–acid battery during discharge: pH; amount of PbO2; total amount of lead in the battery. 13.76 The density of the electrolyte in a lead–acid battery is measured to assess its state of charge. Explain how the density indicates the state of charge of the battery. 13.77 (a) What is the electrolyte in a nickel–cadmium cell? (b) Write the reaction that takes place at the anode when the cell is being charged. (See Table 13.2.) 13.78 (a) Why are lead–antimony grids used as electrodes in the lead–acid battery rather than smooth plates? (b) What is the reducing agent in the lead–acid battery? (c) The lead–acid cell potential is about 2 V. How, then, does a car battery produce 12 V for its electrical system? Steel cathodeZinc anode HgO in KOH and Zn(OH)2 + ¡ EXERCISES 557 13.79 A chromium-plated steel bicycle handlebar is scratched. Will rusting of the iron in the steel be encouraged or retarded by the chromium? 13.80 A solution is prepared by dissolving 1 mol each of Cu(NO3)2, Ni(NO3)2, and AgNO3 in 1.0 L of water. Using only data from Appendix 2B, identify the metals (if any) that when added to these solutions (a) will leave the Ni2ϩ ions unaffected but will cause Cu and Ag to plate out of solution; (b) will leave the Ni2ϩ and Cu2ϩ ions in solution but will cause Ag to plate out of solution; (c) will leave all three metals ions in solution; (d) will leave Ni2ϩ and Agϩ ions in solution but will cause Cu to plate out of solution. 13.81 Suppose that 2.69 g of a silver salt (AgX) is dissolved in 550 mL of water. With a current of 3.5 A, 395.0 s was needed to plate out all the silver. (a) What is the mass percentage of silver in the salt? (b) What is the formula of the salt? 13.82 Three electrolytic cells containing solutions of CuNO3, Sn(NO3)2, and Fe(NO3)3, respectively, are connected in series. A current of 3.5 A is passed through the cells until 3.05 g of copper has been deposited in the first cell. (a) What masses of tin and iron are deposited? (b) For how long did the current flow? 13.83 (a) What is the approximate chemical formula of rust? (b) What is the oxidizing agent in the formation of rust? (c) How does the presence of salt accelerate the rusting process? 13.84 (a) What is the electrolyte solution in the formation of rust? (b) How are steel (iron) objects protected by galvanizing and by sacrificial anodes? (c) Suggest two metals that could be used in place of zinc for galvanizing iron. 13.85 (a) Suggest two metals that could be used for the cathodic protection of a titanium pipeline. (b) What factors other than relative positions in the electrochemical series need to be considered in practice? (c) Often copper piping is connected to iron pipes in household plumbing systems. What is a possible effect of the copper on the iron pipes? 13.86 (a) Can aluminum be used for the cathodic protection of a steel underground storage container? (b) Which of the metals zinc, silver, copper, and magnesium cannot be used as a sacrificial anode in the protection of a buried iron pipeline? Explain your answer. (c) What is the electrolyte solution for the cathodic protection of an underground pipeline by a sacrificial anode? Integrated Exercises 13.87 Indicate for each of the following statements whether it applies to Ecell°, to Ecell, to both, or to neither. (a) Decreases as the cell reaction progresses. (b) Changes with temperature. (c) Doubles when the coefficients of the equation are doubled. (d) Can be calculated from K. (e) Is a measure of how far the cell reaction is from equilibrium. Justify your answers. 13.88 State how the oxidizing strength of each of the following oxidizing agents would be affected by raising the pH (stronger, weaker, or no change): (a) Br2; (b) MnO4 – ; (c) NO3 – ; (d) ClO4 Ϫ ; (e) Cu2ϩ . Justify your answers. 13.89 Volta discovered that when he used different metals in his “pile” some combinations had a stronger effect than others. From that information he constructed an electromotive series. How would Volta have ordered the following metals, if he put the most strongly reducing metal first: Fe, Ag, Au, Zn, Cu, Ni, Co, Al? 13.90 Arrange the following metals in order of increasing strength as reducing agents: U, V, Ti, Ni, Sn, Cr, Rb. 13.91 A galvanic cell has the following cell reaction: M(s) ϩ 2 Zn2ϩ (aq) : 2 Zn(s) ϩ M4ϩ (aq). The standard potential of the cell is ϩ0.16 V. What is the standard potential of the M4ϩ ͞M redox couple? 13.92 Using data in Appendix 2B, calculate the standard potential for the half-reaction Ti4ϩ (aq) ϩ 4 e– : Ti(s). 13.93 Ksp for Cu(IO3)2 is 1.4 ϫ 10–7 . Using this value and data available in Appendix 2B, calculate E° for the half-reaction Cu(IO3)2(s) ϩ 2 e– : Cu(s) ϩ 2 IO3 – (aq). 13.94 Ksp for Ni(OH)2 is 6.5 ϫ 10–18 . Using this value and data from Appendix 2B, calculate E° for the half-reaction Ni(OH)2(s) ϩ 2 e– : Ni(s) ϩ 2 OH– (aq). 13.95 A voltaic cell functions only when the electrical circuit is complete. In the external circuit the current is carried by the flow of electrons through a metal wire. Explain how the current is carried through the cell itself. 13.96 A technical handbook contains tables of thermodynamic quantities for common reactions. If you want to know whether a certain cell reaction has a positive standard potential, which of the following properties would give you that information directly (on inspection)? Which would not? Explain your answer. (a) ⌬G°; (b) ⌬H°; (c) ⌬S°; (d) ⌬U°; (e) K. 13.97 Answer the following questions and, for each “yes” response, write a balanced cell reaction and calculate the standard cell potential. (a) Can the oxygen present in air oxidize silver metal in acidic solution under standard conditions? (b) Can the oxygen in air oxidize silver metal in basic solution under standard conditions? 13.98 One stage in the extraction of gold from rocks involves dissolving the metal from the rock with a basic solution of sodium cyanide that has been thoroughly aerated. This stage results in the formation of soluble Au(CN)2 – ions. The next stage is to reduce gold to the metal by the addition of zinc dust, forming Zn(CN)4 2– . Write the balanced equations for the half-reactions and the overall redox equation for both stages. 13.99 (a) If you were to construct a concentration cell in which one half-cell contains 1.0 M CrCl3 and the other half-cell 0.0010 M CrCl3, and both electrodes were chromium, at which electrode would reduction spontaneously take place? How will each of the following changes affect the cell potential? Justify your answers. (b) Adding 100 mL pure water to the anode compartment. (c) Adding 100 mL 1.0 M NaOH(aq) to the cathode compartment (Cr(OH)3 is insoluble). (d) Increasing the mass of the chromium electrode in the anode compartment. 13.100 Dental amalgam, a solid solution of silver and tin in mercury, is used for filling tooth cavities. Two of the reduction half-reactions that the filling can undergo are 3 Hg2 2ϩ (aq) ϩ 4 Ag(s) ϩ 6 e– 2 Ag2Hg3(s) E° ϭ ϩ0.85 V Sn2ϩ (aq) ϩ 3 Ag(s) ϩ 2 e– Ag3Sn(s) E° ϭ –0.05 V Suggest a reason why, when you accidentally bite on a piece of aluminum foil with a tooth containing a silver filling, you may feel ¡ ¡ 558 CHAPTER 13 ELECTROCHEMISTRY pain. Write a balanced chemical equation to support your suggestion. 13.101 Suppose that 25.0 mL of a solution of Agϩ ions of unknown concentration is titrated with 0.015 M KI(aq) at 25°C. A silver electrode is immersed in this solution, and its potential is measured relative to a standard hydrogen electrode. A total of 16.7 mL of KI(aq) was required to reach the stoichiometric point, when the potential was 0.325 V. (a) What is the molar concentration of Agϩ in the solution? (b) Determine Ksp for AgI from these data. 13.102 Suppose that 35.0 mL of 0.012 M Cuϩ (aq) is titrated with 0.010 M KBr(aq) at 25°C. A copper electrode is immersed in this solution, and its potential is measured relative to a standard hydrogen electrode. What volume of the KBr solution must be added to reach the stoichiometric point and what will the potential be at that point? Ksp(CuBr) ϭ 5.2 ϫ 10–9 . 13.103 Use the data in Appendix 2B and the fact that, for the halfreaction F2(g) ϩ 2 Hϩ (aq) ϩ 2 e– : 2 HF(aq), E° ϭ ϩ3.03 V, to calculate the value of Ka for HF. 13.104 The following items are obtained from the stockroom for the construction of a galvanic cell: two 250-mL beakers and a salt bridge, a voltmeter with attached wires and clips, 200 mL of 0.0080 M CrCl3(aq), 200 mL of 0.12 M CuSO4(aq), a piece of copper wire, and a chrome-plated piece of metal. (a) Describe the construction of the galvanic cell. (b) Write the reduction halfreactions. (c) Write the overall cell reaction. (d) Write the cell diagram for the galvanic cell. (e) What is the expected cell potential? 13.105 (a) Considering the dependence of the Gibbs free energy of reaction on potential and on temperature, derive an equation for the temperature dependence of Ecell°. (b) Use your equation to predict the standard potential for the formation of water from hydrogen and oxygen in a fuel cell at 80°C. Assume that ⌬H° and ⌬S° are independent of temperature. 13.106 (a) What is the standard cell potential (Ecell°) for the reaction below at 298 K? (b) What is the standard cell potential for the reaction at 335 K? (c) What is the cell potential for the reaction at 335 K when [Zn2ϩ ] ϭ 2.0 ϫ 10–4 molиL–1 and [Pb2ϩ ] ϭ 1.0 mol·L–1 ? (See Exercise 13.105.) Pb2ϩ (aq) ϩ Zn(s) Zn2ϩ (aq) ϩ Pb(s) 13.107 In a neuron (a nerve cell), the concentration of Kϩ ions inside the cell is about 20 to 30 times as great as that outside. What potential difference between the inside and the outside of the cell would you expect to measure if the difference is due only to the imbalance of potassium ions? 13.108 (a) The potential of the cell Zn(s)|Zn2ϩ (aq, ?)|| Pb2ϩ (aq, 0.10 mol·L–1 )|Pb(s) is ϩ0.661 V. What is the molarity of Zn2ϩ ions? (b) Write an equation that gives the Zn2ϩ ion concentration as a function of cell potential, assuming that all other aspects of the cell remain constant. 13.109 (a) Using data available in Appendix 2B, determine the standard potential for the redox reaction 2 Agϩ (aq) ϩ 2 I– (aq) : 2 Ag(s) ϩ I2(s). Is this process spontaneous under standard conditions? (b) When equal volumes of 2.0 M AgNO3(aq) and 2.0 M NaI(aq) are mixed, the redox reaction described in part (a) does not take place. Instead, a precipitate of AgI is formed. Why doesn’t the redox reaction take place? Support your answer with an appropriate calculation. 13.110 What is the standard potential for the reduction of oxygen to water in (a) an acidic solution? (b) a basic solution? (c) Is MnO4 – more stable in an acidic or a basic aerated solution (a solution saturated with oxygen gas at 1 atm)? Explain your conclusion. 13.111 When a pH meter was standardized with a boric acid–borate buffer with a pH of 9.40, the cell was ϩ0.060 V. When the buffer was replaced with a solution of unknown hydronium ion concentration, the cell potential was ϩ0.22 V. What is the pH of the solution? 13.112 Show how a silver–silver chloride electrode (silver in contact with solid AgCl and a solution of Cl– ions) and a hydrogen electrode can be used to measure (a) pH; (b) pOH. 13.113 What range (in volts) does a voltmeter need to have in order to measure pH in the range of 1 to 14 at 25°C if the voltage is zero when pH ϭ 7? 13.114 The entropy change of a cell reaction can be determined from the change of the cell potential with temperature. (a) Show that ⌬S° ϭ nF(Ecell,2° – Ecell,1°)͞(T2 – T1). Assume that ⌬S° and ⌬H° are constant over the temperature range considered. (b) Calculate ⌬S° and ⌬H° for the cell reaction Hg2Cl2(s) ϩ H2(g) :2 Hg(l) ϩ 2 Hϩ (aq) ϩ 2 Cl– (aq), given that E° ϭ ϩ0.2699 V at 293 K and ϩ0.2669 V at 303 K. 13.115 A silver concentration cell is constructed with the electrolyte at both electrodes being initially 0.10 M AgNO(aq) at 25°C. The electrolyte at one electrode is diluted by a factor of 10 five times and the cell potential measured each time. (a) Plot the potential of this cell on a graph as a function of ln[Agϩ ]anode. (b) Calculate the value of the slope of the line. To what term in the Nernst equation does this value correspond? Is the value you determined from the plot consistent with the value you would calculate from the values in that term? If not consistent, calculate your percentage error. (c) What is the value of the y-intercept? To what term in the Nernst equation does this value correspond? 13.116 Consider the electroplating of a metal ϩ1 cation from a solution of unknown concentration according to the half-reaction Mϩ (aq) ϩ e– : M(s), with a standard potential E°. When the half-cell is connected to an appropriate oxidation half-cell and current is passed through it, the Mϩ cation begins plating out at E1. To what value (E2) must the applied potential be adjusted, relative to E1, if 99.99% of the metal is to be removed from the solution? 13.117 Using only data given in Appendix 2B, calculate the acidity constant for HBrO. 13.118 The absolute magnitudes of the standard potentials of two metals M and X were determined to be (1) Mϩ (aq) ϩ e– : M(s) |E°| ϭ 0.25 V (2) X2ϩ (aq) ϩ 2 e– : X(s) |E°| ϭ 0.65 V When the two electrodes are connected, current flows from M to X in the external circuit. When the electrode corresponding to halfreaction 1 is connected to the standard hydrogen electrode (SHE), current flows from M to SHE. (a) What are the signs of E° of the two half-reactions? (b) What is the standard cell potential for the cell constructed from these two electrodes? 13.119 An aqueous solution of Na2SO4 was electrolyzed for 30.0 min; 25.0 mL of oxygen was collected at the anode over water at 22°C and a total pressure of 722 Torr. Determine the current ¡ EXERCISES 559 that was used to produce the gas. See Table 9.3 for the vapor pressure of water. 13.120 A brine solution is electrolyzed by using a current of 2.0 A. How much time is required to collect 20.0 L of chlorine if the gas is collected over water at 20.0°C and the total pressure is 770. Torr? Assume that the water is already saturated with chlorine, and so no more dissolves. See Table 9.3 for the vapor pressure of water. Chemistry Connections 13.121 Many important biological reactions involve electron transfer. Because the pH of bodily fluids is close to 7, the “biological standard potential” of an electrode, E*, is measured at pH ϭ 7. (a) Calculate the biological standard potential for (i) the reduction of hydrogen ions to hydrogen gas; (ii) the reduction of nitrate ions to NO gas. (b) Calculate the biological standard potential E* for the reduction of the biomolecule NADϩ to NADH in aqueous solution. The reduction half-reaction under thermodynamic standard conditions is NADϩ (aq) ϩ Hϩ (aq) ϩ 2 e– : NADH(aq), with E° ϭ Ϫ0.099 V. (c) The pyruvate ion, CH3C(≈O)CO2 – , is formed during the metabolism of glucose in the body. The ion has a chain of three carbon atoms. The central carbon atom has a double bond to a terminal oxygen atom and one of the end carbon atoms is bonded to two oxygen atoms in a carboxylate group. Draw the Lewis structure of the pyruvate ion and assign a hybridization scheme to each carbon atom. (d) The lactate ion has a similar structure to the pyruvate ion, except that the central carbon is now attached to an –OH group: CH3CH(OH)CO2 – . Draw the Lewis structure of the lactate ion and assign a hybridization scheme to the central carbon atom. (e) During exercise the pyruvate ion is converted to lactate ion in the body by coupling to the half reaction for NADH given in part (b). For the half-reaction pyruvate ϩ 2 Hϩ ϩ 2 e– : lactate, E* ϭ Ϫ0.190 V. Write the cell reaction for the spontaneous reaction that occurs between these two biological couples and calculate E* and E° for the overall reaction. (f) Calculate the standard Gibbs free energy of reaction for the overall reaction in part (e). (g) Calculate the equilibrium constant at 25°C for the overall reaction in part (e). 560 CHAPTER 13 ELECTROCHEMISTRY 561 What Are the Key Ideas? The rates of chemical reactions can be described by simple expressions that enable us to predict the composition of a reaction mixture at any time; these expressions also suggest the steps by which the reaction takes place. Why Do We Need to Know This Material? Chemical kinetics provides us with tools that we can use to study the rates of chemical reactions on both the macroscopic and the atomic levels. At the atomic level, chemical kinetics is a source of insight into the nature and mechanisms of chemical reactions. At the macroscopic level, information from chemical kinetics allows us to model complex systems, such as the processes taking place in the human body and the atmosphere. The development of catalysts, which are substances that speed up chemical reactions, is a branch of chemical kinetics crucial to the chemical industry, to the solution of major problems such as world hunger, and to the development of new fuels. What Do We Need to Know Already? It might be helpful to review the kinetic model of gases (Section 4.10) and equilibrium constants (Section 10.2). I n the previous four chapters we used thermodynamics to predict the spontaneous direction and extent of chemical change. However, thermodynamics does not tell us how fast the reaction goes. Some spontaneous reactions—such as the decomposition of benzene into carbon and hydrogen—do not seem to proceed at all, whereas other reactions—such as proton transfer reactions—reach equilibrium very rapidly. In this chapter, we examine the intimate details of how reactions proceed, what determines their rates, and how to control those rates. The study of the rates of chemical reactions is called chemical kinetics. When studying thermodynamics, we consider only the initial and final states of a chemical process (its origin and destination) and ignore what happens between them (the journey itself, with all its obstacles). In chemical kinetics, we focus on the journey—the changes that take place in the course of reactions and the speed of each step. This chapter begins by looking at how the rates of reactions are determined experimentally and summarized by succinct expressions known as rate laws. We then see how to use rate laws to predict the concentrations of reactants and products at any stage of a reaction and to gain insight about how reactions occur. Finally, we see how substances called catalysts accelerate reactions and control biological processes. REACTION RATES What do we mean by the “rate” of a chemical reaction? Informally, we consider a reaction to be fast if the products are formed rapidly, as occurs in a precipitation reaction or an explosion (Fig. 14.1). A reaction is slow if the products are formed over a long period of time, as happens in corrosion or the decay of organic material (Fig. 14.2). Our first task is to set up a quantitative definition of the rate of a chemical reaction. 14.1 Concentration and Reaction Rate In everyday life, a rate is defined as the change in a property divided by the time that it takes for that change to take place. For instance, the speed of an automobile, the rate of change of its position, is defined as distance traveled divided by the time taken. We get the average speed if we divide the length of the journey by the total time for the journey; we get the instantaneous speed by reading the speedometer at some point on the journey. In chemistry, we express rates in terms of how quickly reactants are used up or products are formed. That is, we define the reaction rate as the change in concentration of one of REACTION RATES 14.1 Concentration and Reaction Rate 14.2 The Instantaneous Rate of Reaction 14.3 Rate Laws and Reaction Order CONCENTRATION AND TIME 14.4 First-Order Integrated Rate Laws 14.5 Half-Lives for First-Order Reactions 14.6 Second-Order Integrated Rate Laws REACTION MECHANISMS 14.7 Elementary Reactions 14.8 The Rate Laws of Elementary Reactions 14.9 Chain Reactions 14.10 Rates and Equilibrium MODELS OF REACTIONS 14.11 The Effect of Temperature 14.12 Collision Theory 14.13 Transition State Theory ACCELERATING REACTIONS 14.14 Catalysis 14.15 Industrial Catalysts 14.16 Living Catalysts: Enzymes 561 Chapter 14 CHEMICAL KINETICS the reactants or products divided by the time interval over which the change takes place. Because the rate may change as time passes, we denote the average reaction rate as the change in molar concentration of a reactant R, ⌬[R] ϭ Ϫ , divided by the time interval ⌬t ϭ t2 Ϫ t1: (1a)* Because reactants are used up in a reaction, the concentration of R decreases as time passes; thus, ⌬[R] is negative. The minus sign in Eq. 1a is included to ensure that the rate is positive, which is the normal convention in chemical kinetics. If we follow the concentration of a product P, we express the rate as (1b)* In this expression, ⌬[P] is the change in molar concentration of P during the interval ⌬t: it is a positive quantity because products are formed as time goes on. A note on good practice: In chemical kinetics, the square brackets denote molar concentration, with the units molиLϪ1 retained. Average rate of formation of P = ¢[P] ¢t Average rate of consumption of R = - ¢[R] ¢t [R]t1 [R]t2 562 CHAPTER 14 CHEMICAL KINETICS FIGURE 14.2 Some reactions are very slow, as in the gradual buildup of corrosion on the prow of the Titanic on the cold floor of the Atlantic Ocean. FIGURE 14.1 Reactions proceed at widely different rates. Some, such as explosions of dynamite, are very fast. Charges have been set off to demolish this old building. The chemical reaction in each explosion is over in a fraction of a second; the gases produced expand more slowly. EXAMPLE 14.1 Calculating an average reaction rate Suppose we are studying the reaction 2 HI(g) : H2(g) ϩ I2(g) and find that, in an interval of 100. s, the concentration of HI decreases from 4.00 mmolиLϪ1 to 3.50 mmolиLϪ1 . What is the average reaction rate? PLAN Substitute the data into Eq. 1a. SOLVE Concentration Time 100. s 0.50 mmol·LϪ1 From Average rate of consumption of R ϭ Ϫ⌬[R]͞⌬t, Average rate of consumption of HI ϭ 5.0 ϫ 10Ϫ3 (mmol HI)иLϪ1 иsϪ1 = (3.50 - 4.00)(mmol HI)иL-1 100. s In the plot, the slope of the straight blue line gives the average rate. A note on good practice: It is best to choose multiples of units that minimize the powers of 10 shown explicitly. In this case, because 10–3 mmol ϭ 1 ␮mol, it would be good practice to report the rate as 5.0 (␮mol HI)иLϪ1 иsϪ1 . Self-Test 14.1A When the reaction 2 HI(g) : H2(g) ϩ I2(g) was carried out at a high temperature, the concentration of HI decreased from 6.00 mmolиLϪ1 to 4.20 mmolиLϪ1 in 200. s. What was the average reaction rate? [Answer: 9.00 (␮mol HI)иLϪ1 иsϪ1 ] Self-Test 14.1B Hemoglobin (Hb) carries oxygen through our bodies by forming a complex with it: Hb(aq) ϩ O2(aq) : HbO2(aq). In a solution of hemoglobin exposed to oxygen, the concentration of hemoglobin fell from 1.2 nmolиLϪ1 (1 nmol ϭ 10Ϫ9 mol) to 0.80 nmolиLϪ1 in 0.10 ␮s. What was the average rate at which hemoglobin reacted with oxygen in that solution, in millimoles per liter per microsecond? In Example 14.1, the reaction rate was reported in the units micromoles per liter per second (μmolиLϪ1 иsϪ1 ), but other units for time (such as minutes or even hours) are commonly encountered for slower reactions. Note, too, that, when we report a reaction rate, we must specify the species to which the rate refers, because species are consumed or produced at rates related to the stoichiometry of the reaction. For example, in the reaction in Example 14.1, two HI molecules are used to make one H2 molecule. Therefore, the rate of consumption of HI is twice the rate of formation of H2 and we conclude that To avoid the ambiguity associated with several ways of reporting a reaction rate, we can report a single unique average rate of a reaction without specifying the species. The unique average rate of the reaction a A ϩ b B : c C ϩ d D is any of the following four equal quantities: Unique average reaction rate (2)* Division by the stoichiometric coefficients takes care of the stoichiometric relations between the reactants and products. There is no need to specify the species when reporting the unique average reaction rate, because the value of the rate is the same, regardless of which species is indicated. However, the unique average rate does depend on the coefficients used in the balanced equation, and so the chemical equation should be specified when reporting the unique rate. Thinking point: By what factor does the unique average reaction rate change if the coefficients in a chemical equation are doubled? Self-Test 14.2A The average rate of the reaction N2(g) ϩ 3 H2(g) : 2 NH3(g) over a certain period is reported as 1.15 (mmol NH3)иLϪ1 иhϪ1 . (a) What is the average rate over the same period in terms of the consumption of H2? (b) What is the unique average rate? [Answer: (a) 1.72 (mmol H2)иLϪ1 иhϪ1 ; (b) 0.575 mmolиLϪ1 иhϪ1 ] Self-Test 14.2B Consider the reaction in Example 14.1. What is (a) the average rate of formation of H2 in the same reaction and (b) the unique average rate, both over the same period? The experimental technique that we employ to measure a rate of reaction depends on how rapidly the reaction takes place. Some biologically important reactions, such as the growth of hair, may take weeks to show significant changes, but other reactions, such as the explosion of nitroglycerin, are very rapid. Special techniques have to be used when the reaction is so fast that it is over in seconds. There are two main considerations. One is to initiate the reaction at a very precise time. The other is to monitor the concentration at precise instants after the reaction has been initiated. Some reactions can be initiated by a flash of light. Because lasers can produce very short pulses at precisely known times they are often used to study the rates of such = - 1 a ¢[A] ¢t = - 1 b ¢[B] ¢t = 1 c ¢[C] ¢t = 1 d ¢[D] ¢t - ¢[H2] ¢t = 1 2 ¢[HI] ¢t 14.1 CONCENTRATION AND REACTION RATE 563 reactions. Spectrometry—the determination of concentrations by measuring the absorption of light by species (see Major Technique 2, following Chapter 3)—can respond very quickly to concentration changes and is often used in combination with a laser flash to study very fast reactions. For instance, suppose we are studying the effect of a chlorofluorocarbon on the concentration of ozone, a blue gas that absorbs light of certain wavelengths. We could use a spectrometer to monitor the light absorbed by the ozone at one of those wavelengths and calculate the molar concentration of O3 molecules from the intensity of absorption. By using pulsed lasers chemists can study reactions that are complete in less than a picosecond (1 ps ϭ 10Ϫ12 s). The newest techniques can even monitor reactions that are complete after a few femtoseconds (1 fs ϭ 10Ϫ15 s, Box 14.1) and chemists are now investigating processes even on an attosecond timescale (1 as ϭ 10Ϫ18 s). On that time scale, atoms seem hardly to be moving and are caught red-handed in the act of reaction. Reactions that are initiated by mixing the reagents can be studied by the stoppedflow technique, in which solutions of the reactants are forced into a mixing chamber very rapidly and within a few milliseconds the formation of products is observed spectroscopically (Fig. 14.3). This procedure is commonly used to study biologically important reactions. The average rate of a reaction is the change in concentration of a species divided by the time over which the change takes place; the unique average rate is the average rate divided by the stoichiometric coefficient of the species monitored. Spectroscopic techniques are widely used to study reaction rates, particularly for fast reactions. 564 CHAPTER 14 CHEMICAL KINETICS The events that happen to an atom in a chemical reaction are on a time scale of approximately 1 femtosecond (1 fs ϭ 10Ϫ15 s), the time that it takes for a bond to stretch or bend and, perhaps, break. If we could follow atoms on that time scale, we could make a movie of the changes in molecules as they take part in a chemical reaction. The new field of femtochemistry, the study of very fast chemical processes, is bringing us closer to realizing that dream. Lasers can emit very intense but short pulses of electromagnetic radiation, and so they can be used to study processes on very short time scales. So far, the technique has been applied only to very simple reactions. For example, it is possible to watch the ion pair Naϩ IϪ decompose in the gas phase into separate Na and I atoms. At the start, the sodium ion and iodide ion are held together by the coulombic attraction of opposite charges. The pair is then struck by a femtosecond pulse of radiation from a laser. That pulse excites an electron from the IϪ ion on to the Naϩ ion, thereby creating an NaI molecule in which the two atoms are held together by a covalent bond. The molecule has a lot of energy, and the bond length varies as the atoms swing in and out. At this point, a second femtosecond pulse is fired at the molecule. The radiation in the second pulse has a frequency that can be absorbed by the molecule only when the atoms have a particular separation. If the pulse is absorbed, we know that the atoms of the vibrating molecule have that special internuclear separation. The illustration shows a typical result. The absorption reaches a maximum whenever the Na–I bond length returns to the length to which the second pulse is tuned. The peaks show that the sodium atom moves away from the iodine atom (corresponding to the dips in the curve), only to be recaptured (at the maxima) again. The separation of the maxima is about 1.3 ps, and so the Na atom takes that long to swing out and be recaptured by the I atom. We can see that the peaks progressively decrease in intensity, showing that some Na atoms escape from their I atom partners on each swing. It takes about 10 swings outward before an Na atom can be sure of escaping. When sodium bromide is studied by these methods, the sodium atom escapes after about one swing, showing that an Na atom can escape more readily from a Br atom than from an I atom. HOW DO WE KNOW . . . WHAT HAPPENS TO ATOMS DURING A REACTION?BOX 14.1 Na absorption NaI absorption Intensity −2 0 2 4 6 8 Time delay (ps) The femtosecond spectrum of the gas-phase NaI molecule as it dissociates into the separate atoms. A peak in the lower spectrum is observed whenever the bond distance in NaI reaches a certain value. FIGURE 14.3 In a stopped-flow experiment, the driving syringes on the left push reactant solutions into the mixing chamber, and the stopping syringe on the right stops the flow. The progress of the reaction is then monitored spectroscopically as a function of time. Spectrometer Stopping syringe Driving syringes Mixing chamber 14.2 The Instantaneous Rate of Reaction Most reactions slow down as the reactants are used up. To determine the reaction rate at a given instant in the course of the reaction, we need to make two concentration measurements as close together in time as possible. In other words, to determine the rate at a single instant we determine the slope of the tangent to the plot of concentration against time at the time of interest (Fig. 14.4). This slope, which changes in the course of the reaction, is called the instantaneous rate of the reaction (Fig. 14.5). From now on, whenever we speak of a reaction rate, we shall always mean an instantaneous rate. The definitions in Eqs.1 and 2 can easily be adapted to refer to the instantaneous rate of a reaction. 14.2 THE INSTANTANEOUS RATE OF REACTION 565 Concentrationofreactant Time Tangent A B FIGURE 14.4 The rate of reaction is the change in concentration of a reactant (or product) divided by the time interval over which the change occurs (the slope of the line AB, for instance). The instantaneous rate is the slope of the tangent to the curve at the time of interest. Molarconcentration(mol·L−1 ) 0 0.05 0.1 0 10 3020 Time (weeks) 0.076 mol·L−1 , 0 weeks 5 weeks 0 mol·L−1 , 12 weeks 0 0.05 0.1 0 10 3020 Time (weeks) 0.045 mol·L−1 , 0 weeks 10 weeks 0 mol·L−1 , 17 weeks FIGURE 14.5 Determination of the rate of deterioration of penicillin during storage at two different times. Note that the rate (the slope of the tangent to the curve) at 5 weeks is greater than the rate at 10 weeks, when less penicillin is present. HOW DO WE DO THAT? To set up expressions for the instantaneous rate of a reaction, we consider the time interval ⌬t to be so brief that t and t ϩ ⌬t are very close together; we determine the concentration of a reactant or product at each of those times and find the average rate from Eq. 1. Then we decrease the interval still further and repeat the calculation. We can imagine continuing the process until the interval ⌬t has become infinitely small (denoted dt) and the change in molar concentration of a reactant R has become infinitesimal (denoted d[R]). Then we define the instantaneous rate as For a product P, we write The terms d[R]͞dt and d[P]͞dt are the mathematical expressions for the slope of the tangent drawn to a curve at the time of interest. Similarly, the unique instantaneous rate of a reaction is defined as in Eq. 2, but with differential coefficients in place of ⌬[R]͞⌬t and ⌬[P]͞⌬t: Because it is difficult to draw a tangent accurately by eye, it is better to use a computer to analyze graphs of concentration against time. A superior method—which we meet in Section 14.4—is to report rates by using a procedure that, although based on these definitions, avoids the use of tangents altogether. Reaction rate = - 1 a d[A] dt = - 1 b d[B] dt = 1 c d[C] dt = 1 d d[D] dt Rate of formation of P = d[P] dt Rate of consumption of R = - d[R] dt The instantaneous reaction rate is the slope of a tangent drawn to the graph of concentration as a function of time; for most reactions the instantaneous rate changes as the reaction proceeds. 14.3 Rate Laws and Reaction Order Patterns in reaction rate data can often be identified by examining the initial rate of reaction, the instantaneous rate right at the start of a reaction (Fig. 14.6). The advantage of examining the initial rate is that the presence of products later in the reaction may affect the rate; the interpretation of the rate is then quite complicated. There are no products present at the start of the reaction, and so any pattern due solely to the reactants themselves is easier to find. For example, suppose we were to measure different amounts of solid dinitrogen pentoxide, N2O5, into five flasks of the same volume, immerse all the flasks in a water bath at 65°C to vaporize the solid completely, and then use spectrometry to monitor the concentration of N2O5 remaining in each flask as it decomposes: 2 N2O5(g) 4 NO2(g) ϩ O2(g) (A) Each flask has a different initial concentration of N2O5. We determine the initial rate of reaction in each flask by plotting the concentration as a function of time for each flask and drawing the tangent to each curve at t ϭ 0 (the black lines in Fig. 14.6). We find higher initial rates of decomposition of the vapor—steeper tangents—in the flasks with higher initial concentrations of N2O5. Is there a pattern in the data? One way to find out is to plot the initial rate against concentration and examine the type of curve obtained. In this case, by plotting the initial rate against the initial concentration of N2O5 we get a straight line, which tells us that the initial rate is proportional to the initial concentration (Fig. 14.7): Initial rate of consumption of N2O5 [N2O5]initial If we introduce a constant k, we can write this proportionality as an equality: Initial rate of consumption of N2O5 ϭ k ϫ [N2O5]initial The constant k is called the rate constant for the reaction and is characteristic of the reaction (different reactions have different rate constants) and the temperature at which r ¡ 566 CHAPTER 14 CHEMICAL KINETICS FIGURE 14.6 The orange curves show how the concentration of N2O5 changes with time for five different initial concentrations. The initial rate of consumption of N2O5 can be determined by drawing a tangent (black line) to each curve at the start of the reaction. MolarconcentrationofN2O5(mol·L−1 ) 0 0.02 0.04 0.06 0.08 Time 1 2 3 5 4 0 4 5 3 2 1 InitialrateofconsumptionofN2O5(mol·L−1 ·s−1 ) 4 10−4 3 10−4 2 10−4 1 10−4 Molar concentration N2O5 (mol·L−1 ) 0.040 0.08 0.069 mol·L−1 3.6 10−4 mol·L−1 ·s−1 FIGURE 14.7 This graph was obtained by plotting the five initial rates from Fig. 14.6 against the initial concentration of N2O5. The initial rate is directly proportional to the initial concentration. This graph also illustrates how we can determine the value of the rate constant k by calculating the slope of the straight line from two points. the reaction takes place. The experimental value of k for this reaction at 65°C, the slope of the straight line in Fig. 14.7, is 5.2 ϫ 10Ϫ3 sϪ1 . We have found that the initial rate of reaction A is proportional to the initial concentration of N2O5. If we were to follow the reaction rate in one of the flasks as the reaction proceeds we would also find that as the concentration of N2O5 falls, the rate falls too. More specifically, we would find that the rate at any instant is directly proportional to the concentration of N2O5 remaining at that instant, with the same constant of proportionality, k. We therefore conclude that, at any stage of the reaction, and provided products do not participate in the reaction, Rate of consumption of N2O5 ϭ k[N2O5] where [N2O5] is the molar concentration of N2O5 at any instant. This equation is an example of a rate law, an expression for the instantaneous reaction rate in terms of the concentration of a species at any instant. Each reaction has its own characteristic rate law andrateconstantkthatisindependentof theconcentrationsof thereactants(Table14.1). Other reactions have rate laws that may depend differently on concentration. When we make similar measurements on the reaction 2 NO2(g) 2 NO(g) ϩ O2(g) (B) we do not get a straight line if we plot rate against concentration of NO2 (Fig. 14.8a). However, if we plot the rate against the square of the concentration of NO2, then we do get a straight line (Fig. 14.8b). This result shows that the rate is proportional to the square of the concentration and therefore that the rate at any stage can be written Rate of consumption of NO2 ϭ k[NO2]2 From the slope of the straight line in Fig. 14.8b, k ϭ 0.54 LиmolϪ1 иsϪ1 at 300.°C. ¡ 14.3 RATE LAWS AND REACTION ORDER 567 TABLE 14.1 Rate Laws and Rate Constants Reaction Rate law* Temperature (K)† Rate constant Gas phase H2 ϩ I2 ∫∫B 2 HI k[H2][I2] 500 4.3 ϫ 10Ϫ7 L·molϪ1 ·sϪ1 600 4.4 ϫ 10Ϫ4 700 6.3 ϫ 10Ϫ2 800 2.6 2 HI ∫∫B H2 ϩ I2 k[HI]2 500 6.4 ϫ 10Ϫ9 L·molϪ1 ·sϪ1 600 9.7 ϫ 10Ϫ6 700 1.8 ϫ 10Ϫ3 800 9.7 ϫ 10Ϫ2 2 N2O5 ∫∫B 4 NO2 ϩ O2 k[N2O5] 298 3.7 ϫ 10Ϫ5 sϪ1 318 5.1 ϫ 10Ϫ4 328 1.7 ϫ 10Ϫ3 338 5.2 ϫ 10Ϫ3 2 N2O ∫∫B 2 N2 ϩ O2 k[N2O] 1000 0.76 sϪ1 1050 3.4 2 NO2 ∫∫B 2 NO ϩ O2 k[NO2]2 573 0.54 LиmolϪ1 ·sϪ1 C2H6 ∫∫B 2 CH3 k[C2H6] 973 5.5 ϫ 10Ϫ4 sϪ1 cyclopropane ∫∫B propene k[cyclopropane] 773 6.7 ϫ 10Ϫ4 sϪ1 Aqueous solution H3Oϩ ϩ OHϪ ∫∫B 2 H2O k[Hϩ ][OHϪ ] 298 1.5 ϫ 1011 LиmolϪ1 иsϪ1 CH3Br ϩ OHϪ ∫∫B CH3OH ϩ BrϪ k[CH3Br][OHϪ ] 298 2.8 ϫ 10Ϫ4 LиmolϪ1 иsϪ1 C12H22O11 ϩ H2O ∫∫B 2 C6H12O6 k[C12H22O11][Hϩ ] 298 1.8 ϫ 10Ϫ4 LиmolϪ1 иsϪ1 *For the unique instantaneous rate. † Three significant figures. The rate laws for the decomposition reactions of N2O5 and NO2 are different, but each has the form Rate ϭ constant ϫ [concentration]a (3) with a ϭ 1 for the decomposition of N2O5 and a ϭ 2 for the decomposition of NO2. The decomposition of N2O5 is an example of a first-order reaction, because its rate is proportional to the first power of the concentration (that is, a ϭ 1). The decomposition of NO2 is an example of a second-order reaction, because its rate is proportional to the second power of the concentration (that is, a ϭ 2). Doubling the concentration of a reactant in a first-order reaction doubles the reaction rate. Doubling the concentration of the reactant in any second-order reaction increases the reaction rate by a factor of 22 ϭ 4. Most of the reactions that we shall consider are either first or second order in each reactant, but some reactions have other orders (different values of a in Eq. 3). For example, ammonia decomposes into nitrogen and hydrogen on a hot platinum wire: 2 NH3(g) N2(g) ϩ 3 H2(g) (C) Experiments show that the decomposition takes place at a constant rate until all the ammonia has been consumed (Fig. 14.9). Its rate law is therefore Rate of consumption of NH3 ϭ k This decomposition is an example of a zero-order reaction, a reaction for which the rate is independent of concentration of the reactant (provided some is present). ¡ 568 CHAPTER 14 CHEMICAL KINETICS Zero-order reactions are so called because Rate ‫؍‬ k ϫ (concentration)0 ‫؍‬ k. 0 0.002 0.001 0.003 0.004 0.005 0.006 RateofconsumptionofNO2(mol·L−1 ·s−1 ) [NO2] (mol·L−1 ) 10.080.060.040.020 0 0.002 0.001 0.003 0.004 0.005 0.006 RateofconsumptionofNO2(mol·L−1 ·s−1 ) 10.0080.004 [NO2]2 (mol2 ·L−2 ) 0.002 0.0060 (b)(a) FIGURE 14.8 (a) When the rates of disappearance of NO2 are plotted against its concentration, a straight line is not obtained. (b) However, a straight line is obtained when the rates are plotted against the square of the concentration, indicating that the rate is directly proportional to the square of the concentration. Time Concentrationofreactant Time Reactionrate (b)(a) FIGURE 14.9 (a) The concentration of the reactant in a zero-order reaction falls at a constant rate until the reactant is exhausted. (b) The rate of a zero-order reaction is independent of the concentration of the reactant and remains constant until all the reactant has been consumed, when the rate falls abruptly to zero. We can summarize the rate laws for the three most common orders of reaction as follows: 14.3 RATE LAWS AND REACTION ORDER 569 Order in A Rate law 0 Rate ϭ k 1 Rate ϭ k[A] 2 Rate ϭ k[A]2 The “Rate” in each expression is the instantaneous rate, and [A] is the concentration of the reactant at the instant of interest. A very important point is the following: The rate law for a reaction is experimentally determined and cannot in general be inferred from the chemical equation for the reaction. For instance, both the decomposition of N2O5, reaction A, and that of NO2, reaction B, have a stoichiometric coefficient of 2 for the reactant, but one reaction is first order and the other is second order. Many reactions have rate laws that depend on the concentrations of more than one reactant. An example is the redox reaction between persulfate ions and iodide ions: S2O8 2Ϫ (aq) ϩ 3 IϪ (aq) 2 SO4 2Ϫ (aq) ϩ I3 Ϫ (aq) (D) The rate law of this reaction is found to be Rate of consumption of S2O8 2Ϫ ϭ k[S2O8 2Ϫ ][IϪ ] We say that the reaction is first order with respect to S2O8 2Ϫ (or “in” S2O8 2Ϫ ) and first order in IϪ . Doubling either the S2O8 2Ϫ ion concentration or the IϪ ion concentration doubles the reaction rate. Doubling both concentrations quadruples the reaction rate. We say that the overall order of this reaction is 2. In general, if Rate ϭ k[A]a [B]b · · · (4)* then the overall order is the sum of the powers a ϩ b ϩ · · ·. The units of k depend on the overall order of the reaction and ensure that k ϫ (concentration)a has the same units as the rate, namely concentration/time. Thus, when the concentration is expressed in moles per liter and the rate is expressed in molиLϪ1 иsϪ1 , the units of k are as follows: Overall order: 1 2 3 Units of k: sϪ1 LиmolϪ1 иsϪ1 L2 иmolϪ2 иsϪ1 and so on. If the concentrations are expressed as partial pressures in kilopascals and the rate is reported in kPa·sϪ1 , then the units of k are: Overall order: 1 2 3 Units of k: sϪ1 kPaϪ1 ·sϪ1 kPaϪ2 ·sϪ1 Self-Test 14.3A When the NO concentration is doubled, the rate of the reaction 2 NO(g) ϩ O2(g) : 2 NO2(g) increases by a factor of 4. When both the O2 and the NO concentrations are doubled, the rate increases by a factor of 8. What are (a) the reactant orders, (b) the overall order of the reaction, and (c) the units of k if the rate is expressed in moles per liter per second? [Answer: (a) Second order in NO, first order in O2; (b) third order overall; (c) L2 иmolϪ2 иsϪ1 ] Self-Test 14.3B When the concentration of 2-bromo-2-methylpropane, C4H9Br, is doubled, the rate of the reaction C4H9Br(aq) ϩ OHϪ (aq) : C4H9OH(aq) ϩ BrϪ (aq) increases by a factor of 2. When both the C4H9Br and the OHϪ concentrations are doubled, the rate increase is the same, a factor of 2. What are (a) the reactant orders, (b) the overall order of the reaction, and (c) the units of k if the rate is expressed in moles per liter per second? ¡ The rate laws of reactions are empirical expressions, expressions established experimentally, and we should not be surprised if the orders we find are not simple positive whole numbers. For instance, orders can be negative, as in (concentration)Ϫ1 , corresponding to order Ϫ1. Because [A]Ϫ1 ϭ 1/[A], a negative order implies that the concentration appears in the denominator of the rate law. Increasing the concentration of that species, usually a product, slows down the reaction because the species participates in a reverse reaction. An example is the decomposition of ozone, O3, in the upper atmosphere: 2 O3(g) 3 O2(g) (E) The experimentally determined rate law for this reaction is This rate law tells us that the reaction is slower in regions of the atmosphere where O2 molecules are abundant than where they are not so abundant. Later on we shall see that this rate law is an important clue to how the reaction takes place. Some reactions have fractional orders. For example, the oxidation of sulfur dioxide to sulfur trioxide in the presence of platinum, 2 SO2(g) ϩ O2(g) 2 SO3(g) is found to have the rate law and an overall order of . The presence of [SO3] in the denominator means that the reaction slows down as the concentration of product builds up. 1 - 1 2 = 1 2 Rate = k [SO2] [SO3]1/2 = k[SO2][SO3]-1/2 ¡ Pt Rate = k [O3]2 [O2] = k[O3]2 [O2]-1 ¡ 570 CHAPTER 14 CHEMICAL KINETICS Note that a rate law may depend on the concentrations of products as well as those of reactants. EXAMPLE 14.2 Determining the reaction orders and rate law from experimental data Four experiments were conducted to discover how the initial rate of consumption of BrO3 Ϫ ions in the reaction BrO3 Ϫ (aq) ϩ 5 BrϪ (aq) ϩ 6 H3Oϩ (aq) : 3 Br2(aq) ϩ 9 H2O(l) varies as the concentrations of the reactants are changed. (a) Use the experimental data in the following table to determine the order of the reaction with respect to each reactant and the overall order. (b) Write the rate law for the reaction and determine the value of k. Initial concentration (molиLϪ1 ) Initial rate Experiment BrO3 Ϫ BrϪ H3Oϩ ((mmol BrO3 Ϫ )иLϪ1 иsϪ1 ) 1 0.10 0.10 0.10 1.2 2 0.20 0.10 0.10 2.4 3 0.10 0.30 0.10 3.5 4 0.20 0.10 0.15 5.5 PLAN Suppose that the concentration of a substance A is increased but no other concentrations change. From the generic rate law, Rate ϭ k[A]a [B]b , we know that as the concentration of A increases by the factor f, the rate increases by f a . To isolate the effect of each substance, if possible, compare experiments that differ in the concentration of only one substance at a time. SOLVE (a) Order in BrO3 Ϫ : By comparing experiments 1 and 2, we see that, when the other concentrations are held constant but the concentration of BrO3 Ϫ is doubled (f ϭ 2), the rate also doubles, and so f a ϭ (2)a ϭ 2. Therefore, a ϭ 1 and the reaction is first order in BrO3 Ϫ . Order in BrϪ : By comparing experiments 1 and 3, we see that, when the other concentrations are held constant but the concentration of BrϪ is changed by a factor of 3.0 (f ϭ 3.0), the rate changes by a factor of 3.5/1.2 ϭ 2.9. Allowing for experimental error, we can deduce that f b ϭ (3.0)b ϭ 3, and so b ϭ 1 and the reaction is first order in BrϪ . Order in H3Oϩ : When the concentration of hydronium ions is increased from experiment 2 to experiment 4 by a factor of 1.5 (f ϭ 1.5), the rate increases by a factor of ϭ 2.3 when all other concentrations are held constant. Therefore, fc ϭ (1.5)c ϭ 2.3. To solve the relation 1.5c ϭ 2.3 (and in general fc ϭ x), take logarithms of both sides: 5.5 2.4 14.3 RATE LAWS AND REACTION ORDER 571 From f c ϭ x, c ln f ϭ ln x, and hence c ϭ (ln x)/(ln f ), The reaction is second order in H3Oϩ . We can check our result by verifying that (1.5)2 ϭ 2.3. The overall order is 1 ϩ 1 ϩ 2 ϭ 4. (b) The rate law is Rate of consumption of BrO3 Ϫ ϭ k[BrO3 Ϫ ][BrϪ ][H3Oϩ ]2 We find k by substituting the values from one of the experiments into the rate law and solving for k. For example, in experiment 4, we note that the rate of reaction is 5.5 mmolиLϪ1 иsϪ1 ϭ 5.5 ϫ 10Ϫ3 molиLϪ1 иsϪ1 ; then we set up the rate law and solve for k: c = ln 2.3 ln 1.5 = 2.0 From k ϭ (Rate of consumption of BrO3 Ϫ )/[BrO3 Ϫ ][BrϪ ][H3Oϩ ]2 , = 12 L3 иmol-3 иs-1 k = 5.5 * 10-3 molиL-1 иs-1 (0.20 molиL-1 ) * (0.10 molиL-1 ) * (0.15 molиL-1 )2 Evaluate The mean value of k calculated from the four experiments is 12 L3 ·molϪ3 ·sϪ1 . Self-Test 14.4A The reaction 2 NO(g) ϩ O2(g) : 2 NO2(g) occurs when automobile exhaust releases NO into the atmosphere. Write the rate law for the consumption of NO and determine the value of k, given the following data: Initial concentration (molиLϪ1 ) Initial rate Experiment NO O2 ((mol NO)иLϪ1 иsϪ1 ) 1 0.012 0.020 0.102 2 0.024 0.020 0.408 3 0.024 0.040 0.816 [Answer: Rate of consumption of NO ϭ k[NO]2 [O2]; with the use of Experiment 1, k ϭ 3.5 ϫ 104 L2 ·molϪ2 ·sϪ1 .] Self-Test 14.4B The highly toxic gas carbonyl chloride, COCl2 (phosgene), is used to synthesize many organic compounds. Use the following data to write the rate law and determine the value of k for the reaction used to produce carbonyl chloride: CO(g) ϩ Cl2(g) : COCl2(g) at a certain temperature: Initial concentration (molиLϪ1 ) Initial rate Experiment CO Cl2 ((mol COCl2)иLϪ1 иsϪ1 ) 1 0.12 0.20 0.121 2 0.24 0.20 0.241 3 0.24 0.40 0.682 Hint: One of the orders is not an integer. The order of a reaction is the power to which the concentration of the species is raised in the rate law; the overall order is the sum of the individual orders. CONCENTRATION AND TIME We often want to know how the concentration of a reactant or product varies with time. For example, how long will it take for a pollutant to decay? How much of the alternative fuel methanol can be produced in an hour from coal in an industrial process? How much of a sample of penicillin will be left after 6 months? These questions can be answered by using formulas derived from the experimental rate law for the reactions. An integrated rate law gives the concentration of reactants or products at any time after the start of the reaction. Finding the integrated rate law from a rate law is very much like calculating the distance that a car will have traveled from its speed at each moment of the journey. The integrated rate law for a zero-order reaction is easy to find. Because the rate is constant (at k), the difference in concentration of a reactant from its initial value, [A]0, is proportional to the time for which the reaction is in progress, and we can write [A]0 Ϫ [A] ϭ kt or [A] ϭ [A]0 Ϫ kt As shown in Fig. 14.9a, a plot of concentration against time is a straight line of slope Ϫk; the reaction comes to an end when t ϭ [A]0/k, because then all the reactant has been consumed ([A] ϭ 0). In the next two sections, we concentrate on first- and second-order rate laws, but the techniques can be used for other reaction orders, too. 14.4 First-Order Integrated Rate Laws Our aim is to find an expression for the concentration of a reactant A at a time t, given that the initial molar concentration of A is [A]0 and that the reaction has been found to be first order in A. 572 CHAPTER 14 CHEMICAL KINETICS 2 HOW DO WE DO THAT? To find the concentration of reactant A in a first-order reaction at any time after it has begun, we begin by writing the rate law for the consumption of A as Rate of consumption of A ϭ Ϫ Because an instantaneous rate is a derivative of concentration with respect to time, we can use the techniques of integral calculus to find the change in [A] as a function of time. First, we divide both sides by [A] and multiply through by Ϫdt: Now we integrate both sides between the limits t ϭ 0 (when [A] ϭ [A]0) and the time of interest, t (when [A] ϭ [A]t): t To evaluate the integral on the left, we use the standard form and obtain Ϫ (ln [A]0 ϩ constant) ϭ ln[A]t Ϫ ln [A]0 ϭ ln [A]t [A]0 L [A]t [A]0 d[A] [A] = (ln [A]t + constant) L dx x = ln x + constant L [A]t [A]0 d[A] [A] = -k L t 0 dt = -kt d[A] [A] = -kdt d[A] dt = k[A] We conclude that ln When we take (natural) antilogarithms of both sides, we obtain [A]t͞[A]0 ϭ eϪkt , and therefore [A]t ϭ [A]0eϪkt The two equations that we have derived, (5a)* [A]t ϭ [A]0eϪkt (5b)* are two forms of the integrated rate law for a first-order reaction. The variation of concentration with time predicted by Eq. 5b is shown in Fig. 14.10. This behavior is called exponential decay because the concentration of A depends on an exponential function of time. Initially the concentration changes rapidly, but it changes more slowly as time goes on and the reactant is used up. ln [A]t [A]0 = -kt [A]t [A]0 = -kt 14.4 FIRST-ORDER INTEGRATED RATE LAWS 573 Time Molarconcentrationofreactant,[A] [A]0 k large k small FIGURE 14.10 The graph of the concentration of a reactant in a firstorder reaction is an exponential decay, as shown here. The larger the rate constant, the faster the decay from the same initial concentration. EXAMPLE 14.3 Calculating a concentration from a first-order integrated rate law What concentration of N2O5 remains 10.0 min (600. s) after the start of its decomposition at 65°C (in reaction A) when its initial concentration was 0.040 molиLϪ1 ? See Table 14.1 for the rate law. Anticipate Because the reactant decays with time, we should expect a concentration that is lower than the initial value, but to assess the change we must do the calculation. PLAN First identify the order of the reaction. If the reaction is first order in the specified reactant, use the exponential form of the first-order rate law (Eq. 5b) to find the new concentration of the reactant. SOLVE The reaction and its rate law are 2 N2O5(g) 4 NO2(g) ϩ O2(g) Rate of decomposition of N2O5 ϭ k[N2O5], with k ϭ 5.2 ϫ 10Ϫ3 sϪ1 . Therefore, the reaction is first order in N2O5. ¡ Concentration Time 600. s 40. mmol·LϪ1 1.8 mmol·L Ϫ1 From [A]t ϭ [A]0eϪkt , [N2O5]t ϭ (0.040 molиLϪ1 ) ϫ eϪ(5.2ϫ10Ϫ3 sϪ1 ) ϫ (600. s) ϭ 0.0018 molиLϪ1 Evaluate We can conclude that after 600. s, the concentration of N2O5 will have fallen from its initial value of 0.040 molиLϪ1 to 0.0018 molиLϪ1 (1.8 mmolиLϪ1 ). Self-Test 14.5A The rate law for the decomposition 2 N2O(g) : 2 N2(g) ϩ O2(g) is Rate of decomposition of N2O ϭ k[N2O]. Calculate the concentration of N2O remaining after the reaction has continued at 780°C for 100. ms, if the initial concentration of N2O is 0.20 molиLϪ1 and k ϭ 3.4 sϪ1 . [Answer: 0.14 molиLϪ1 ] Self-Test 14.5B Calculate the concentration of cyclopropane, C3H6 (1), remaining after the conversion into its isomer propene (2): C3H6(g) : CH3ßCH≈CH2(g) has continued at 773 K for 200. s, if the initial concentration of C3H6 is 0.100 molиLϪ1 and k ϭ 6.7 ϫ 10Ϫ4 sϪ1 . The rate law is Rate of conversion of C3H6 ϭ k[C3H6]. An important application of an integrated rate law is to confirm that a reaction is in fact first order and to measure its rate constant. From Eq. 5a, we can write ln [A]t ϭ ln [A]0 Ϫ kt (6) This equation has the form of an equation for a straight line (see Appendix 1E): y ϭ intercept ϩ slope ϫ x Therefore, if we plot ln [A]t as a function of t, we should get a straight line with slope Ϫk and intercept ln [A]0. 574 CHAPTER 14 CHEMICAL KINETICS We mentioned in Section 14.2 that there is a better way of determining rate constants than trying to draw tangents to curves: this is it. EXAMPLE 14.4 Measuring a rate constant When cyclopropane (C3H6, see 1) is heated to 500.°C (773 K), it changes into an isomer, propene (see 2). The following data show the concentration of cyclopropane at a series of times after the start of the reaction. Confirm that the reaction is first order in C3H6 and calculate the rate constant. t (min) 0 5 10. 15 [C3H6]t (molؒL؊1 ) 1.50 ϫ 10Ϫ3 1.24 ϫ 10Ϫ3 1.00 ϫ 10Ϫ3 0.83 ϫ 10Ϫ3 PLAN We need to plot the natural logarithm of the reactant concentration as a function of t. If we get a straight line, the reaction is first order and the slope of the graph is Ϫk. If the plot is not linear, then the reaction is not first order in the specified reactant. We could use a spreadsheet program or the Living Graph “Determination of Rate Constant (firstorder rate law)” on the Web site for this book to make the plot. SOLVE For the graphical procedure, begin by setting up the following table: t(min) 0 5 10. 15 ln [C3H6]t Ϫ6.50 Ϫ6.69 Ϫ6.91 Ϫ7.09 The points are plotted in Fig. 14.11. The graph is a straight line, confirming that the reaction is first order in cyclopropane. When we use points A and B on the plot, the slope of the line is Therefore, because k ϭ Ϫslope, k ϭ 0.040 minϪ1 . Evaluate The value we have calculated is equivalent to k ϭ 6.7 ϫ 10Ϫ4 sϪ1 , the value in Table 14.1. A note on good practice: Be sure to determine and include the appropriate units for k. Self-Test 14.6A Data on the decomposition of N2O5 at 25°C are t(min) 0 200. 400. [N2O5]t (molиLϪ1 ) 15.0 ϫ 10Ϫ3 9.6 ϫ 10Ϫ3 6.2 ϫ 10Ϫ3 600. 800. 1000. 4.0 ϫ 10Ϫ3 2.5 ϫ 10Ϫ3 1.6 ϫ 10Ϫ3 Confirm that the reaction is first order and find the value of k for the reaction N2O5(g) : products. [Answer: The plot of ln [N2O5] against time is linear, and so the reaction is first order; k ϭ 2.2 ϫ 10Ϫ3 minϪ1 .] Slope = (-7.02) - (-6.56) (13.3 - 1.7) min = -0.040 min-1 B A −6.50 −6.75 −7.00 ln[C3H8] Time (min) 50 1510 −6.56, 1.7 min −7.02, 13.3 min FIGURE 14.11 We can test for a firstorder reaction by plotting the natural logarithm of the reactant concentration against time. The graph is linear if the reaction is first order. The slope of the line, which is calculated here for the system in Example 14.4 by using the points A and B, is equal to the negative of the rate constant. Living Graph 14.11 1 Cyclopropane, C3H6 2 Propene, C3H6 Self-Test 14.6B Azomethane, CH3N2CH3, decomposes to ethane and nitrogen gas in the reaction CH3N2CH3(g) : CH3CH3(g) ϩ N2(g). The reaction was followed at 460. K by measuring the partial pressure of azomethane over time: t (s) 0. 1000. 2000. (Torr) 8.20 ϫ 10Ϫ2 5.72 ϫ 10Ϫ2 3.99 ϫ 10Ϫ2 3000. 4000. 2.78 ϫ 10Ϫ2 1.94 ϫ 10Ϫ2 Confirm that the reaction is first order of the form Rate ϭ kP, where P is the partial pressure of azomethane, and find the value of k. PCH3N2CH3 14.4 FIRST-ORDER INTEGRATED RATE LAWS 575 EXAMPLE 14.5 Predicting how long it will take for a concentration to change A sample of N2O5 is allowed to decompose as in reaction A, 2 N2O5(g) : 4 NO2(g) ϩ O2(g). How long will it take for the concentration of N2O5 to decrease from 20. mmol·LϪ1 to 2.0 mmol·LϪ1 at 65°C? Use the data in Table 14.1. PLAN First, identify the order of the reaction in N2O5 by referring to Section 14.3 or Table 14.1. If the reaction is first order, rearrange Eq. 5a into an equation for t in terms of the given concentrations. Then substitute the numerical value of the rate constant and the concentration data and evaluate t. SOLVE The reaction is first order with k ϭ 5.2 ϫ 10Ϫ3 sϪ1 at 65°C (338 K). Therefore, From ln ([A]t/[A]0) ϭ Ϫkt rearranged into t ϭ (1/k) ln ([A]0/[A]t), = 4.4 * 102 s ln 20. mmolиL-1 2.0 mmolиL-1 t = 1 5.2 * 10-3 s-1 Concentration Time 440 s 20. mmol·LϪ1 2.0 mmol·L Ϫ1 Self-Test 14.7A How long does it take for the concentration of A to decrease to 1.0% of its initial value in a first-order reaction of the form A : products with k ϭ 1.0 sϪ1 ? [Answer: 4.6 s] Self-Test 14.7B Cyclopropane isomerizes to propene in a first-order process. How long does it take for the concentration of cyclopropane to decrease from 1.0 mol·LϪ1 to 0.0050 molиLϪ1 at 500.°C? Use the data in Table 14.1. We have seen that some rate laws depend on the concentration of more than one species. For instance, oxidation of iodide ions by persulfate ions (reaction D) follows the rate law Rate of consumption of S2O8 2Ϫ ϭ k[S2O8 2Ϫ ][IϪ ] In such cases, we can simplify the analysis by ensuring that one species remains effectively at the same concentration throughout the reaction and so can be treated as a constant. One way to do this is to start with persulfate ions in such a high concentration that their concentration barely changes in the course of the reaction. For instance, the concentration of persulfate ions might be 100 times as great as the concentration of iodide ions; so, even when all the iodide ions have been oxidized, the persulfate concentration is almost the same as it was at the beginning of the reaction. Because [S2O8 2Ϫ ] is virtually constant, we can write the rate law as Rate of consumption of S2O8 2Ϫ ϭ kЈ[IϪ ] where kЈ ϭ k[S2O8 2Ϫ ], another constant. We have turned the actual second-order reaction into a pseudo-first-order reaction, a reaction that is effectively first order. The rate law for a pseudo-first-order reaction is much easier to analyze than the true rate law because it depends on the concentration of only one substance and the variation of iodide ion concentration with time can be treated in the same way as a true first-order reaction. Then, by knowing the concentration of S2O8 2Ϫ ions we have used in the experiment, we can deduce the value of the overall rate constant from k ϭ kЈ/[S2O8 2Ϫ ], In a first-order reaction, the concentration of reactant decays exponentially with time. To verify that a reaction is first order, plot the natural logarithm of its concentration as a function of time and expect a straight line; the slope of the straight line is ؊k. 14.5 Half-Lives for First-Order Reactions The half-life, t1/2, of a substance is the time needed for its concentration to fall to onehalf its initial value. Knowing the half-lives of pollutants such as chlorofluorocarbons allows us to assess their environmental impact. If their half-lives are short, they may not survive long enough to reach the stratosphere, where they can destroy ozone. Halflives are also important in planning storage systems for radioactive materials, because the decay of radioactive nuclei is a first-order process (see Section 17.7). We already know that the higher the value of k, the more rapid the consumption of a reactant. Therefore, we should be able to deduce a relation for a first-order reaction that shows that the greater the rate constant, the shorter the half-life. 576 CHAPTER 14 CHEMICAL KINETICS HOW DO WE DO THAT? To find the relation between the rate constant and the half-life of a first-order reaction, we begin by rearranging Eq. 5a into an expression for the time needed to reach a given concentration: From ln ([A]t/[A]0) ϭ Ϫkt, t = 1 k ln [A]0 [A]t Concentration Time Now set t ϭ t1/2 and [A]t ϭ [A]0, = 1 k ln 2 t1/2 = 1 k ln [A]0 1 2 [A]0 1 2 Concentration Time [A]0 1 2 [A]0 t½ Notice that the initial concentration has canceled. We have shown that, for the rate law Rate of consumption of A ϭ k[A], (7)* with ln 2 ϭ 0.693 . . . . As we anticipated, the greater the value of the rate constant k, the shorter the half-life for the reaction (Fig. 14.12). Note that the half-life of a firstorder reaction depends only on the rate constant and not on the concentration. Therefore, it has the same value at all stages of the reaction: whatever the reactant concentration might be at any stage of the reaction, it takes the same time (t1/2) for that concentration to halve. t1/2 = ln 2 k −[A]0 [A]0 Molarconcentrationofreactant,[A] Time, t k small k large 1 2 t long t short ½ ½½ FIGURE 14.12 The change in concentration of the reactant in two firstorder reactions plotted on the same graph. When the first-order rate constant is large, the half-life of the reactant is short, because the exponential decay of the concentration of the reactant is then fast. Evaluate The concentration of mercury in the urine is therefore 0.05 mg·LϪ1 . As expected, this is a very small value. A note on good practice: Note that, because exponential functions ex are so sensitive to the value of x, we avoid rounding errors by leaving the numerical calculation to a single final step. Self-Test 14.8A In 1972, grain treated with methyl mercury was released for human consumption in Iraq, resulting in 459 deaths. The half-life of methyl mercury in body tissues is 70. d. How many days are required for the amount of methyl mercury to drop to 10.% of the original value after ingestion? [Answer: 230 d] Self-Test 14.8B Soil at the Rocky Flats Nuclear Processing Facility in Colorado was found to be contaminated with radioactive plutonium-239, which has a half-life of 24 ka (2.4 ϫ 104 years). The soil was loaded into drums for storage. How many years must pass before the radioactivity drops to 20.% of its initial value? The concentration of the reactant does not appear in Eq. 7: for a first-order reaction, the half-life is independent of the initial concentration of the reactant. That is, it is constant: regardless of the initial concentration of reactant, half the reactant will have been consumed in the time given by Eq. 7. It follows that the concentration of A can be used as its “initial” concentration at any stage of the reaction: if at some stage the concentration of A happens to be [A], then after a further time t1/2, the concentration of A will have fallen to [A]; after a further t1/2 it will have fallen to ; and so on (Fig. 14.13). In general, at any stage of the reaction, the concentration remaining after n half-lives is [A]. For example, in Example 14.6, because 30 days corresponds to 5 half-lives, after that interval [A]t ϭ [A]0, or [A]0/32, which evaluates to 3%, the same as the result obtained in the example. A1 2 B5 A1 2 Bn 1 4 1 2 14.5 HALF-LIVES FOR FIRST-ORDER REACTIONS 577 EXAMPLE 14.6 Using a half-life to calculate the amount of reactant remaining In 1989 a teenager in Ohio was poisoned by breathing vapors from spilled mercury. The mercury level in his urine, which is proportional to its concentration in his body, was found to be 1.54 mgиLϪ1 . Mercury(II) is eliminated from the body by a first-order process that has a half-life of 6 days (6 d). What would be the concentration of mercury(II) in the patient’s urine in milligrams per liter after 30 d if therapeutic measures were not taken? Anticipate Thirty days is five half-lives, so we should expect that most of the mercury will have been eliminated. PLAN The level of mercury(II) in the urine can be predicted by using the integrated first-order rate law, Eq. 5b. To use this equation, we need the rate constant. Therefore, start by calculating the rate constant from the half-life (Eq. 7) and substitute the result into Eq. 5b. SOLVE From t1/2 ϭ (ln 2)/k in the form k ϭ (ln 2)/t1/2, k = ln 2 6 d = ln 2 6 d-1 From [A] ϭ [A]0eϪkt , [A]t ϭ [A]0eϪ{(ln 2)/6 dϪ1 }ϫ(30 d) ϭ (1.54 mgиLϪ1 )eϪ{(ln 2)ϫ30/6} ϭ 0.05 mgиLϪ1 6 12 18 24 30 36 Concentration Time (d) t t t [A]0 −[A]0 1 2 −[A]0 1 4 −[A]0 1 8 Molarconcentrationofreactant,[A] Time, t ½ ½ ½ FIGURE 14.13 For first-order reactions, the half-life is the same whatever the concentration at the start of the chosen period. Therefore, it takes one half-life to fall to half the initial concentration, two half-lives to fall to one-fourth the initial concentration, three half-lives to fall to one-eighth, and so on. The boxes portray the composition of the reaction mixture at the end of each half-life; the red squares represent the reactant A and the yellow squares represent the product. Self-Test 14.9A Calculate (a) the number of half-lives and (b) the time required for the concentration of N2O to fall to one-eighth of its initial value in a first-order decomposition at 1000. K. Consult Table 14.1 for the rate constant. [Answer: (a) 3 half-lives; (b) 2.7 s] Self-Test 14.9B Calculate (a) the number of half-lives and (b) the time required for the concentration of C2H6 to fall to one-sixteenth of its initial value as it dissociates into CH3 radicals at 973 K. Consult Table 14.1 for the rate constant. The half-life of a first-order reaction is characteristic of the reaction and independent of the initial concentration. It is inversely proportional to the rate constant of the reaction. 14.6 Second-Order Integrated Rate Laws Now we derive the integrated rate law for second-order reactions with the rate law Rate of consumption of A ϭ k[A]2 578 CHAPTER 14 CHEMICAL KINETICS HOW DO WE DO THAT? To obtain the integrated rate law for a second-order reaction, we recognize that the rate law is a differential equation and write it as After division by [A]2 and multiplication by Ϫdt, this equation becomes To integrate this equation, we use the same limits as in the first-order case: t This time we need the integral constant and write the integral on the left as Thus, we obtain which can be rearranged into The two equations that we have derived are (8a)* (8b)* Equation 8b is plotted in Fig. 14.14. We see that the concentration of the reactant decreases rapidly at first but then changes more slowly than it would for a first-order [A]t = [A]0 1 + kt[A]0 1 [A]t - 1 [A]0 = kt [A]t = [A]0 1 + kt[A]0 1 [A]t - 1 [A]0 = kt, = 1 [A]0 - 1 [A]t L [A]t [A]0 d[A] [A]2 = a - 1 [A]t + constantb - a - 1 [A]0 + constantb L dx x2 = - 1 x + L [A]t [A]0 d[A] [A]2 = -k L t 0 dt = -kt d[A] [A]2 = -kdt - d[A] dt = k[A]2 2 Time Molarconcentrationofreactant,[A] [A]0 k large k small FIGURE 14.14 The characteristic shapes of the time dependence of the concentration of a reactant during a second-order reaction. The larger the rate constant, k, the greater is the dependence of the rate on the concentration of the reactant. The lower gray lines are the curves for first-order reactions with the same initial rates as for the corresponding second-order reactions. Note how the concentrations for second-order reactions fall away much less rapidly at longer times than those for first-order reactions do. reaction with the same initial rate. This slowing down of second-order reactions has important environmental consequences: because many pollutants degrade by secondorder reactions, they remain at low concentration in the environment for long periods. Equation 8a can be written in the form of a linear equation: (8c)* Therefore, to determine whether a reaction is second order in a reactant, we plot the inverse of the concentration against the time and see whether we get a straight line. If the line is straight, then the reaction is second order and the slope of the line is equal to k (Fig. 14.15). As we have seen for first- and second-order rate laws, each integrated rate law can be rearranged into an equation that, when plotted, gives a straight line and the rate constant can then be obtained from the slope of the plot. Table 14.2 summarizes the relationships to use. 1 [A]t = 1 [A]0 + k t 14.6 SECOND-ORDER INTEGRATED RATE LAWS 579 y # intercept # slope# (a) (b)Time, t Slope = −k Slope = k Time, t ln[A] ln [A]0 1/[A]0 1/[A] FIGURE 14.15 The plots that allow the determination of reaction order. (a) If a plot of ln [A] against time is a straight line, the reaction is first order. (b) If a plot of 1/[A] against time is a straight line, the reaction is second order. Living Graph 14.15 TABLE 14.2 Rate Law Summary Order of reaction 0 1 2 Rate law Rate ϭ k Rate ϭ k[A] Rate ϭ k[A]2 Integrated rate law [A]t ϭ Ϫkt ϩ [A]0 [A]t ϭ [A]0eϪkt Plot to determine order Slope of the line plotted Ϫk Ϫk k Half-life (not used) (not used) t1/2 = 1 k[A]0 t1/2 = ln 2 k L 0.693 k t1/2 = [A]0 2k 1 [A]t = 1 [A]0 + kt [A]t = [A]0 1 + [A]0t t [A]0 −k ln[A]t [A]t ln [A]0 t −k 1/[A]t 1/[A]0 t k A second-order reaction has a long tail of low concentration at long reaction times. The half-life of a second-order reaction is inversely proportional to the concentration of the reactant. REACTION MECHANISMS Knowing how a reaction takes place at the molecular level provides answers to many important questions. For example, what controls the rate of formation of the DNA double helix from its individual strands? What molecular events convert ozone into oxygen or turn a mixture of fuel and air into carbon dioxide and water when it ignites in an engine? In the following sections we see how to use the rate law for a reaction as a window into these changes. 14.7 Elementary Reactions We stressed in Section 14.3 that we cannot in general write a rate law from a chemical equation. The reason is that all but the simplest reactions are the outcome of several, and sometimes many, steps called elementary reactions. Each elementary reaction describes a distinct event, often a collision of particles. To describe how a reaction takes place, we propose a reaction mechanism, a sequence of elementary reactions or steps that we believe take place as reactants are transformed into products. Although several different mechanisms might be proposed for a reaction, rate measurements can be used to eliminate some of them. For example, in the decomposition of ozone in reaction E (Section 14.3), 2 O3(g) : 3 O2(g), we could imagine the reaction taking place two different ways: One-step mechanism: Two O3 molecules collide and rearrange into three O2 molecules (Fig. 14.16): O3 ϩ O3 O2 ϩ O2 ϩ O2 Two-step mechanism: In the first step, an O3 molecule is energized by solar radiation and dissociates into an O atom and an O2 molecule. In the second step, the O atom attacks another O3 molecule to produce two more O2 molecules (Fig. 14.17): Step 1 O3 O2 ϩ O Step 2 O ϩ O3 O2 ϩ O2 The free O atom in the second mechanism is a reaction intermediate, a species that plays a role in a reaction but does not appear in the chemical equation for the overall reaction: it is produced in one step but is used up in a later step. The two equations for the elementary reactions add together to give the equation for the overall reaction. A note on good practice: The chemical equations for elementary reaction steps are written without the state symbols. They differ from the overall chemical equation, which summarizes bulk behavior, because they show how individual atoms and molecules take part in the reaction. We do not use stoichiometric coefficients for elementary reactions. Instead, to emphasize that we are depicting individual molecules, we write the formula as many times as required. Elementary reactions are classified according to their molecularity, the number of reactant molecules, atoms, or ions taking part in a specified elementary reaction. The equation for the first step in the two-step mechanism for the decomposition of ozone (O3 : O2 ϩ O) is an example of a unimolecular reaction, because only one reactant molecule participates. We can picture an ozone molecule as acquiring energy from sunlight and vibrating so vigorously that it shakes itself apart. In the second step of the two-step mechanism, the O atom produced by the dissociation of O3 goes on to attack another O3 molecule (O ϩ O3 : O2 ϩ O2). This elementary reaction is an example of a bimolecular reaction, because two reactant species come together to react. The molecularity of a unimolecular reaction is 1 and that of a bimolecular reaction is 2. ¡ ¡ ¡ 580 CHAPTER 14 CHEMICAL KINETICS FIGURE 14.16 A representation of a proposed one-step mechanism for the decomposition of ozone in the atmosphere. This reaction takes place in a single bimolecular collision. Step 1 Step 2 FIGURE 14.17 An alternative, two-step mechanism for the decomposition of ozone. In the first step, an energized ozone molecule shakes off an oxygen atom. In the second step, that oxygen atom attacks another ozone molecule. Any forward reaction that can take place is also accompanied, in principle at least, by the corresponding reverse reaction. Therefore, the unimolecular decay of O3 in step 1 of the two-step mechanism is accompanied by the formation reaction O2 ϩ O O3 The reverse of the reaction in step 1 is bimolecular. Similarly, the bimolecular attack of O on O3 in step 2 of the two-step mechanism is accompanied by its bimolecular reverse reaction O2 ϩ O2 O ϩ O3 These two equations add up to give the reverse of the overall equation, 3 O2(g) : 2 O3(g). The forward and reverse reactions jointly provide a mechanism for reaching dynamic equilibrium between the reactants and the products in the overall process. The reverse of the single elementary step in the one-step mechanism is O2 ϩ O2 ϩ O2 O3 ϩ O3 This step is an example of a termolecular reaction, an elementary reaction requiring the simultaneous collision of three molecules. Termolecular reactions are uncommon, because it is very unlikely that three molecules will collide simultaneously with one another under normal conditions. Self-Test 14.10A What is the molecularity of each elementary reaction: (a) C2N2 : CN ϩ CN; (b) NO2 ϩ NO2 : NO ϩ NO3? [Answer: (a) Unimolecular; (b) bimolecular] Self-Test 14.10B What is the molecularity of each elementary reaction: (a) C2H5Br ϩ OHϪ : C2H5OH ϩ BrϪ ; (b) Br2 : Br ϩ Br? Many reactions take place by a series of elementary reactions. The molecularity of an elementary reaction is the number of reactant particles that take part in the step. 14.8 The Rate Laws of Elementary Reactions To verify that a proposed reaction mechanism agrees with experimental data, we construct the overall rate law implied by the mechanism and check to see whether it is consistent with the experimentally determined rate law. However, although the constructed rate law and the experimental rate law may be the same, the proposed mechanism may still be incorrect because some other mechanism may also lead to the same rate law. Kinetic information can only support a proposed mechanism; it can never prove that a mechanism is correct. The acceptance of a suggested mechanism is more like the process of proof in an ideal court of law than a proof in mathematics, with evidence being assembled to give a convincing, consistent picture. To construct an overall rate law from a mechanism, we write the rate law for each of the elementary reactions that have been proposed; then combine them—in a way we shall explain—into an overall rate law. Because an elementary reaction shows how that step of the reaction occurs, we can write its rate law (but not the rate law for the overall reaction) from its chemical equation, with each power of concentration ([A], [A]2 , etc.) in the rate law being the same as the number of particles of a given type participating in the step, as summarized in Table 14.3. ¡ ¡ ¡ 14.8 THE RATE LAWS OF ELEMENTARY REACTIONS 581 TABLE 14.3 Rate Laws of Elementary Reactions Molecularity Elementary reaction Rate law 1 A ∫∫B products rate ϭ k[A] 2 A ϩ B ∫∫B products rate ϭ k[A][B] A ϩ A ∫∫B products rate ϭ k[A]2 3 A ϩ B ϩ C ∫∫B products rate ϭ k[A][B][C] A ϩ A ϩ B ∫∫B products rate ϭ k[A]2 [B] A ϩ A ϩ A ∫∫B products rate ϭ k[A]3 To see how this works in practice, let’s write the rate laws for the steps in a mechanism proposed for the gas-phase oxidation of NO to NO2. Its overall rate law has been determined experimentally: 2 NO(g) ϩ O2(g) 2 NO2(g) Rate of formation of NO2 ϭ k[NO]2 [O2] The following mechanism has been proposed for the reaction. Step 1 A fast bimolecular dimerization and its reverse: NO ϩ NO N2O2 Rate of formation of N2O2 ϭ k1[NO]2 N2O2 NOϩ ⌵O Rate of formation of N2O2 ϭ k1Ј[N2O2] Step 2 A slow bimolecular reaction in which an O2 molecule collides with the dimer: O2 ϩ N2O2 NO2 ϩ NO2 Rate of consumption of N2O2 ϭ k2[N2O2][O2] The reverse of step 2 is too slow to include. To evaluate the plausibility of this mechanism, we need to construct the overall rate law it implies. First, we identify any elementary reaction that results in the overall product (NO2) and write the equation for the net rate of product formation. In this case, NO2 is formed only in step 2, and so Rate of formation of NO2 ϭ 2k2[N2O2][O2] The factor of 2 appears in the rate law because two NO2 molecules are formed from each N2O2 molecule consumed. This expression is not yet an acceptable rate law for the overall reaction because it includes the concentration of an intermediate, N2O2, and intermediates do not appear in the overall rate law for a reaction. To eliminate the concentration of the intermediate N2O2 we proceed as follows. First, we write the expression for its net rate of formation. According to the mechanism, N2O2 is formed in the forward reaction in step 1, removed in the reverse reaction, and removed in step 2. Therefore the net rate of its formation is Step 1 Step 1, reverse Step 2 Net rate of formation of N2O2 ϭ k1[NO]2 Ϫ k1Ј[N2O2] Ϫ k2[N2O2][O2] Now we make the steady-state approximation, that any intermediate remains at a constant, low concentration. The justification for this approximation is that the intermediate is so reactive that it reacts as soon as it is formed. Because the concentration of the intermediate is constant, its net rate of formation is zero, and the previous equation becomes k1[NO]2 Ϫ k1Ј[N2O2] Ϫ k2[N2O2][O2] ϭ 0 This equation, which can be written k1[NO]2 Ϫ (k1Ј ϩ k2[O2])[N2O2] ϭ 0 can be rearranged to find the concentration of N2O2: Now that we have an expression for [N2O2], we can substitute that expression into the rate law: Rate of formation of NO2 ϭ 2k2[N2O2][O2] ϭ (9) The rate law that we have derived is not the same as the experimental one. We have stressed that a reaction mechanism is plausible only if its predictions are in line with experimental results; so should we discard our proposal? Before doing so, it is always wise to explore whether under certain conditions the predictions do in fact agree with experimental data. In this case, if the rate of step 2 is very slow relative to the rapid equilibrium in step 1—so that k1Ј[N2O2] ϾϾ k2[N2O2][O2], which implies that k1Ј ϾϾ k2[O2] when we cancel the [N2O2] on each side of the inequality—we can ignore 2k1k2[NO]2 [O2] k1¿ + k2[O2] [N2O2] = k1[NO]2 k1¿ + k2[O2] ¡ ¡ ¡ ¡ 582 CHAPTER 14 CHEMICAL KINETICS 14.8 THE RATE LAWS OF ELEMENTARY REACTIONS 583 the term k2[O2] in the denominator of Eq. 9. With this approximation, the rate law simplifies to Rate of formation of NO2 ϭ (10a) which agrees with the experimentally determined rate law if we write (10b) The proposed mechanism is therefore consistent with experiment. The assumption that the rate of consumption of the intermediate in the slow step is insignificant relative to its rates of formation and decomposition in the first step is called a pre-equilibrium condition. A pre-equilibrium arises when an intermediate is formed and sustained in a rapid formation reaction and its reverse. The calculation of the rate law is then much simpler. For instance, if we propose that the first step in the NO oxidation gives rise to a pre-equilibrium, we would write NO ϩ NO #¢4 N2O2 This equilibrium implies that [N2O2] ϭ K[NO]2 . The rate of formation of NO2 is therefore Rate of formation of NO2 ϭ 2k2[N2O2][O2] ϭ 2k2K[NO]2 [O2] As before, the mechanism gives rise to an overall third-order rate law, in agreement with experiment. Although this procedure is much simpler than the steady-state approach, it is less flexible: it is more difficult to extend to more complex mechanisms and the conditions under which the approximation is valid are harder to establish. The slowest elementary step in a sequence of reactions that governs the overall rate of formation of products—in our example, the reaction between O2 and the intermediate N2O2 in step 2—is called the rate-determining step of the reaction (Fig. 14.18). A rate-determining step is like a slow ferry on the route between two cities. The rate at which the traffic arrives at its destination is governed by the rate at which it is ferried across the river, because that part of the journey is much slower than any of the others. Steps that follow the rate-determining step take place as soon as the intermediate has been formed and have a negligible effect on the overall rate. Therefore, they can be ignored when writing the overall rate law from the mechanism. In simple cases, we can identify the rate-determining step by considering the experimental rate law. For example, the reaction (CH3)3CBr(sol) ϩ OHϪ (sol) (CH3)3COH(sol) ϩ BrϪ (sol) takes place in an organic solvent (“sol”) with the rate law Rate ϭ k[(CH3)3CBr]. We can write a two-step mechanism for the reaction: (CH3)3CBr (CH3)3Cϩ ϩ BrϪ (CH3)3Cϩ ϩ OHϪ (CH3)3COH In this mechanism, the rate law for the first step is Rate ϭ k[(CH3)3CBr], the same as the experimental rate law. Because the reaction is zero order in OHϪ , the hydroxide ion concentration does not affect the rate and we can assume that the first step is the slow step. As soon as (CH3)3Cϩ is formed, it is immediately converted into the alcohol. Recall that elementary reactions following the rate-determining step do not contribute to the rate law derived from the mechanism. ¡ ¡ ¡ K = [N2O2] [NO]2 k = 2k1k2 k1¿ 2k1k2 k1¿ [NO]2 [O2] Reactants Fast Slow Potential energy Intermediates Products FIGURE 14.18 The rate-determining step in a reaction is an elementary reaction that governs the rate at which products are formed in a multistep series of reactions. The narrow neck representing the rate-determining step in the drawing is like a ferry that cannot handle the busy traffic on a highway. The superimposed “reaction profile” shows the energy requirements of each step. The step that requires the most energy is the slowest (see Section 14.12). EXAMPLE 14.7 Setting up an overall rate law from a proposed mechanism As remarked in Section 14.3, the following rate law has been determined for the decomposition of ozone in reaction E (Section 14.3), 2 O3(g) : 3 O2(g): Rate of decomposition of O3 ϭ k [O3]2 [O2] The following mechanism has been proposed: Step 1 O3 ∫∫Bb∫∫ O2 ϩ O Step 2 O ϩ O3 ∫∫Bb∫∫ O2 ϩ O2 Measurements of the rates of the elementary forward reactions show that the slow step is the second step, the attack of O on O3. The reverse reaction in the second step, O2 ϩ O2 : O ϩ O3, is so slow that it can be ignored. Derive the rate law implied by the mechanism, and confirm that it matches the observed rate law. A note on good practice: Be careful to distinguish the sign h (paired regular arrows), which signifies only that both forward and reverse reactions may occur, from the sign #4 (paired single-barbed arrows), which signifies that the reactions are at equilibrium. PLAN Construct the rate laws for the elementary reactions and combine them into the overall rate law for the decomposition of the reactant. If necessary, use the steady-state approximation for any intermediates and simplify it by using arguments based on rapid preequilibria and the existence of a rate-determining step. SOLVE The rate laws for the elementary reactions are 584 CHAPTER 14 CHEMICAL KINETICS Write the rate law for the net rate of decomposition of O3: Net rate of decomposition of O3 ϭ k1[O3] Ϫ k1Ј[O2][O] ϩ k2[O][O3] To eliminate the O atom concentration from this expression, we consider the net rate of formation of O atoms and use the steady-state approximation to set that net rate equal to zero: Net rate of formation of O ϭ k1[O3] Ϫ k1Ј[O2][O] Ϫ k2[O][O3] ϭ 0 This equation solves to [O] = k1[O3] k1¿[O2] + k2[O3] When we substitute this expression into the rate law for net rate of decomposition of ozone, we get Net rate of decomposition of O3 ϭ k1[O3] Ϫ Thinking point: Verify for yourself that the three expressions in the first line do combine to give the final expression. = 2k1k2[O3]2 k1¿[O2] + k2[O3] k1k1¿[O2][O3] k1¿[O2] + k2[O3] + k1k2[O3]2 k1¿[O2] + k2[O3] Because step 2 is slow relative to the fast pre-equilibrium, we can make the approximation k2[O][O3] ϽϽ k1Ј[O2][O], or equivalently by canceling the [O], k2[O3] ϽϽ k1Ј[O2], and simplify this expression to ϭ with k ϭ 2k1k2/k1Ј. 2k1k2[O3]2 k1¿[O2] = k [O3]2 [O2] , Net rate of decomposition of O3 Step 1 (forward) O3 O2 ϩ O Rate of decomposition of O3 ϭ k1[O3] (fast) (reverse) O2 ϩ O O3 Rate of formation of O3 ϭ k1Ј[O2][O] (fast) Step 2 (forward) O ϩ O3 O2 ϩ O2 Rate of consumption of O3 ϭ k2[O][O3] (slow) (reverse) O2 ϩ O2 O ϩ O3 Rate of formation of O3 ϭ k2Ј[O2]2 (very slow, ignore) ¡ ¡ ¡ ¡ 14.9 CHAIN REACTIONS 585 Evaluate This equation has exactly the same form as that of the observed rate law. Because the mechanism is consistent with both the balanced equation and the experimental rate law, we can consider it plausible. Self-Test 14.11A Consider the following mechanism for the formation of a DNA double helix from its strands A and B: A ϩ B ∫Bb∫ unstable helix (fast, k1 and k1Ј both large) Unstable helix stable double helix (slow, k2 very small) Derive the rate equation for the formation of the stable double helix and express the rate constant of the overall reaction in terms of the rate constants of the individual steps. [Answer: Rate ϭ k[A][B], k ϭ k1k2/k1Ј] Self-Test 14.11B The proposed two-step mechanism for a reaction is H2A ϩ B : BHϩ ϩ HAϪ and its reverse, both of which are fast, followed by HAϪ ϩ B : BHϩ ϩ A2Ϫ , which is slow. Find the rate law with HAϪ treated as the intermediate and write the equation for the overall reaction. The rate law of an elementary reaction is written from the equation for the reaction. A rate law is often derived from a proposed mechanism by imposing the steady-state approximation or assuming that there is a pre-equilibrium. To be plausible, a mechanism must be consistent with the experimental rate law. 14.9 Chain Reactions In a chain reaction, a highly reactive intermediate reacts to produce another highly reactive intermediate, which reacts to produce another, and so on (Fig. 14.19). In many cases, the reaction intermediate—which in this context is called a chain carrier—is a radical, and the reaction is called a radical chain reaction. In a radical chain reaction, one radical reacts with a molecule to produce another radical, that radical goes on to attack another molecule to produce yet another radical, and so on. The ideas presented in the preceding sections apply to chain reactions, too, but they often result in very complex rate laws, which we will not derive. The formation of HBr in the reaction H2(g) ϩ Br2(g) 2 HBr(g) takes place by a chain reaction. The chain carriers are hydrogen atoms (H·) and bromine atoms (Br·). The first step in any chain reaction is initiation, the formation of chain carriers from a reactant. Often heat (denoted ⌬) or light (denoted h␯) is used to generate the chain carriers: Br2(g) ⌬ or h␯ ∫∫∫B Brи ϩ Brи Once chain carriers have been formed, the chain can propagate in a reaction in which one carrier reacts with a reactant molecule to produce another carrier. The elementary reactions for the propagation of the chain are Brи ϩ H2 HBr ϩ Hи Hи ϩ Br2 HBr ϩ Brи The chain carriers—radicals here—produced in these reactions can go on to attack other reactant molecules (H2 and Br2), thereby allowing the chain to continue. The elementary reaction that ends the chain, a process called termination, takes place when chain carriers combine to form products. Two examples of termination reactions are: Brи ϩ Brи Br2 Hи ϩ Brи HBr In some cases, a chain propagates explosively. Explosions can be expected when chain branching occurs—that is, when more than one chain carrier is formed in a propagation ¡ ¡ ¡ ¡ ¡ ¡ Initiator Reactant Reactant Product Product Carrier FIGURE 14.19 In a chain reaction, the product of one step in a reaction is a highly reactive reactant in a subsequent step, which in turn produces reactive species that can take part in other reaction steps. step. Reactions that are explosively fast are often chain reactions. The characteristic pop that occurs when a mixture of hydrogen and oxygen is ignited is a consequence of chain branching. The two gases combine in a radical chain reaction in which the initiation step may be the formation of hydrogen atoms: Initiation: H2 Hи ϩ Hи After the reaction has been initiated, two new radicals are formed when one hydrogen atom attacks an oxygen molecule: Branching: Hи ϩ O2 HOи ϩ иOи The oxygen atom, with valence electron configuration 2s2 2px 2 2py 1 2pz 1 , has two electrons with unpaired spins (its Lewis symbol is , which we abbreviate to иOи). Two radicals are also produced when the oxygen atom attacks a hydrogen molecule: Branching: ·O· ϩ H2 HO· ϩ H· As a result of these branching processes, the chain produces an increasingly larger number of radicals that can take part in even more branching steps. The reaction rate increases rapidly, and an explosion typical of many combustion reactions may occur (Fig. 14.20). Chain reactions begin with the initiation of a reactive intermediate that propagates the chain and concludes with termination when radicals combine. Branching chain reactions can be explosively fast. 14.10 Rates and Equilibrium At equilibrium, the rates of the forward and reverse reactions are equal. Because the rates depend on rate constants and concentrations, we ought to be able to find a relation between rate constants for elementary reactions and the equilibrium constant for the overall reaction. ¡ Ozz yy ¡ ¡ ¢ 586 CHAPTER 14 CHEMICAL KINETICS FIGURE 14.20 This flame front was caught during the fast combustion— almost a miniature explosion—that occurs inside an internal combustion engine every time a spark plug ignites the mixture of fuel and air. HOW DO WE DO THAT? To deduce the relation between rate constants and equilibrium constants, we note that the equilibrium constant for a chemical reaction in solution that has the form A ϩ B #4 C ϩ D is Suppose that experiments show that both the forward reaction and the reverse reaction are elementary second-order reactions. Then we would write the following rate laws: A ϩ B C ϩ D Rate ϭ k[A][B] C ϩ D A ϩ B Rate ϭ kЈ[C][D] At equilibrium, these two rates are equal, and so we can write k[A][B] ϭ kЈ[C][D] It follows that, at equilibrium, Comparison of this expression with the expression for the equilibrium constant then shows that If the reaction involves gas-phase species and the rate law is expressed in terms of molar concentrations, then instead of K use Kc. K = k k¿ [C][D] [A][B] = k k¿ ¡ ¡ K = [C][D] [A][B] We have deduced that for a reaction A ϩ B #4 C ϩ D that proceeds in a single bimolecular step in each direction, (11)* That is, the equilibrium constant for a reaction is equal to the ratio of the rate constants for the forward and reverse elementary reactions that contribute to the overall reaction. We can now see from a consideration of kinetic data alone, with no knowledge of the Gibbs free energy of the reaction, when to expect a large equilibrium constant: K ϾϾ 1 (and products are favored) when k for the forward direction is much larger than kЈ for the reverse direction. In this case, the fast forward reaction builds up a high concentration of products before reaching equilibrium (Fig. 14.21). In contrast, K ϽϽ 1 (and reactants are favored) when k is much smaller than kЈ. Now the reverse reaction destroys the products rapidly, and so their concentrations are very low. We derived the relation between the equilibrium constant and the rate constant for a single-step reaction. However, suppose that a reaction has a complex mechanism in which the elementary reactions have rate constants k1, k2, . . . and the reverse elementary reactions have rate constants k1Ј, k2Ј, . . . . Then, by an argument similar to that for the singlestep reaction, the overall equilibrium constant is related to the rate constants as follows: (12) The equilibrium constant for an elementary reaction is equal to the ratio of the forward and reverse rate constants of the reaction or, for multistep reactions, the ratio of the product of the forward rate constants to the product of the reverse rate constants. MODELS OF REACTIONS Rate laws and rate constants are windows into the molecular processes of chemical change. We have seen how rate laws reveal details of the mechanisms of reactions; here, we build models of the molecular processes that account for the values of the rate constants. 14.11 The Effect of Temperature The rates of chemical reactions depend on temperature. The qualitative observation is that most reactions go faster as the temperature is raised (Fig. 14.22). An increase of 10°C from room temperature typically doubles the rate of reaction of organic species in solution. That is one reason why we cook foods: heating accelerates reactions that lead to the breakdown of cell walls and the decomposition of proteins. We refrigerate foods to slow down the natural chemical reactions that lead to their decomposition. How a reaction rate varies with temperature is summarized by the temperature dependence of the rate constant. In the late nineteenth century, the Swedish chemist Svante Arrhenius found that the plot of the logarithm of the rate constant (ln k) against the inverse of the absolute temperature (1/T) is a straight line. In other words, he established that The intercept is denoted ln A; and, for reasons that will become clear in Section 14.12, the slope is denoted ϪEa/R, where R is the gas constant. With this notation, the empirical Arrhenius equation is (13a)* An alternative form of this expression, which is obtained by taking antilogarithms of both sides, is k ϭ AeϪEa͞RT (13b)* ln k = ln A - Ea RT ln k = intercept + slope * 1 T K = k1 k1¿ * k2 k2¿ * Á K = k k¿ 14.11 THE EFFECT OF TEMPERATURE 587 (a) K Ͼ 1 (b) K Ͻ 1 Slow (kЈ small) Fast (kЈ large) Fast (k large) Slow (k small) Reactants Reactants Products Products FIGURE 14.21 The equilibrium constant for a reaction is equal to the ratio of the rate constants for the forward and reverse reactions.(a)Whentheforwardrateconstant (k)islargecomparedtothereverserate constant,theforwardratematchesthe reverseratewhenthereactionhasneared completionandtheconcentrationof reactantsislow.(b)Conversely,ifthereverse rateconstant(kЈ)islargerthantheforwardrate constant,thentheforwardandreverserates areequalwhenlittlereactionhastakenplace andtheconcentrationofproductsislow. FIGURE 14.22 Reaction rates almost always increase with temperature. The beaker on the left contains magnesium in cold water and that on the right contains magnesium in hot water. An indicator has been added to show the formation of an alkaline solution as magnesium reacts. The use of the gas constant does not mean that the Arrhenius equation applies only to gases: it applies to a wide range of reactions in solution, too. The two constants, A and Ea, are known as the Arrhenius parameters for the reaction and are found from experiment; A is called the pre-exponential factor, and Ea is the activation energy. Both A and Ea are nearly independent of temperature but have values that depend on the reaction being studied. 588 CHAPTER 14 CHEMICAL KINETICS EXAMPLE 14.8 Measuring an activation energy The rate constant for the second-order reaction between bromoethane and hydroxide ions in water, C2H5Br(aq) ϩ OHϪ (aq) : C2H5OH(aq) ϩ BrϪ (aq), was measured at several temperatures, with the results shown here: Temperature (°C) 25 30. 35 40. 45 50. k (Lؒmol؊1 ·s؊1 ) 8.8 ϫ 10Ϫ5 1.6 ϫ 10Ϫ4 2.8 ϫ 10Ϫ4 5.0 ϫ 10Ϫ4 8.5 ϫ 10Ϫ4 1.40 ϫ 10Ϫ3 Find the activation energy of the reaction. Anticipate Activation energies of organic reactions are typically between 10 and 100 kJиmolϪ1 , so we should expect a value within that range. PLAN Activation energies are found from the Arrhenius equation (Eq. 13). We plot ln k against 1/T, with T in kelvins. Because the slope is equal to ϪEa/R, to find the activation energy we multiply the slope of the graph by ϪR with R ϭ 8.3145 JиKϪ1 ·molϪ1 . A spreadsheet, curve-fitting program, or the Living Graph “Variation of Rate Constant with Temperature” on the Web site for this book is very useful for this type of calculation. SOLVE The table to use for drawing the graph is Temperature (°C) 25 30. 35 40. 45 50. T (K) 298 303 308 313 318 323 1/T (K؊1 ) 3.35 ϫ 10Ϫ3 3.30 ϫ 10Ϫ3 3.25 ϫ 10Ϫ3 3.19 ϫ 10Ϫ3 3.14 ϫ 10Ϫ3 3.10 ϫ 10Ϫ3 k (L·molϪ1 ؒs؊1 ) 8.8 ϫ 10Ϫ5 1.6 ϫ 10Ϫ4 2.8 ϫ 10Ϫ4 5.0 ϫ 10Ϫ4 8.5 ϫ 10Ϫ4 1.40 ϫ 10Ϫ3 ln k Ϫ9.34 Ϫ8.74 Ϫ8.18 Ϫ7.60 Ϫ7.07 Ϫ6.57 The points are plotted in Fig. 14.23. We calculate the slope from any two points, such as those marked A and B: = -1.07 * 104 K Slope = (-8.74) - (-6.60) {(3.30 * 10-3 ) - (3.10 * 10-3 )}K-1 = - 2.14 2.0 * 10-4 K-1 Because the slope is equal to ϪEa/R, from Ea ϭ ϪR ϫ slope, Ea ϭ Ϫ(8.3145 JиKϪ1 иmolϪ1 ) ϫ (Ϫ1.07 ϫ 104 K) ϭ 8.9 ϫ 104 JиmolϪ1 Evaluate The value we have calculated corresponds to 89 kJиmolϪ1 , which is in line with the range we anticipated. Self-Test 14.12A The rate constant for the second-order gas-phase reaction HO(g) ϩ H2(g) : H2O(g) ϩ H(g) varies with the temperature as shown here: Temperature (°C) 100. 200. 300. 400. k (Lؒmol؊1 ·sϪ1 ) 1.1 ϫ 10Ϫ9 1.8 ϫ 10Ϫ8 1.2 ϫ 10Ϫ7 4.4 ϫ 10Ϫ7 Determine the activation energy. [Answer: 42 kJ·molϪ1 ] −8.0 −6.5 −9.5 Logarithmofrateconstant,lnk 3.0 1/Temperature, 1/T (103 K−1) 3.1 3.43.2 A B 3.3 FIGURE 14.23 An Arrhenius plot is a graph of ln k against 1/T. If, as here, the line is straight, then the reaction is said to show Arrhenius behavior in the temperature range studied. This plot has been constructed from the data in Example 14.8. Living Graph 14.23 Self-Test 14.12B The rate of a reaction increased from 3.00 molиLϪ1 иsϪ1 to 4.35 molиLϪ1 иsϪ1 when the temperature was raised from 18°C to 30.°C. What is the activation energy of the reaction? Reactions that give a straight line when ln k is plotted against 1/T are said to show Arrhenius behavior. A wide range of reactions show Arrhenius behavior. Even tropical fireflies flash more quickly on hot nights than on cold nights, and their rate of flashing is Arrhenius-like over a small range of temperatures. We can conclude that the biochemical reactions responsible for the flashing have rate constants that increase with temperature in accord with Eq. 13. Some Arrhenius parameters are listed in Table 14.4. Because the slope of an Arrhenius plot is proportional to Ea, it follows that the higher the activation energy, the stronger the temperature dependence of the rate constant. Reactions with low activation energies (about 10 kJ·molϪ1 , with not very steep Arrhenius plots) have rates that increase only slightly with temperature. Reactions with high activation energies (above approximately 60 kJ·molϪ1 , with steep Arrhenius plots) have rates that depend strongly on the temperature (Fig. 14.24). The Arrhenius equation is used to predict the value of a rate constant at one temperature from its value at another temperature. 14.11 THE EFFECT OF TEMPERATURE 589 TABLE 14.4 Arrhenius Parameters Reaction A Ea (kJؒmol؊1 ) First order, gas phase cyclopropane ∫∫B propene 1.6 ϫ 1015 sϪ1 272 CH3NC ∫∫B CH3CN 4.0 ϫ 1013 sϪ1 160 C2H6 ∫∫B 2 CH3 2.5 ϫ 1017 sϪ1 384 N2O ∫∫B N2 ϩ O 8.0 ϫ 1011 sϪ1 250 2 N2O5 ∫∫B 4 NO2 ϩ O2 4.0 ϫ 1013 sϪ1 103 Second order, gas phase O ϩ N2 ∫∫B NO ϩ N 1 ϫ 1011 LиmolϪ1 иsϪ1 315 OH ϩ H2 ∫∫B H2O ϩ H 8 ϫ 1010 LиmolϪ1 иsϪ1 42 2 CH3 ∫∫B C2H6 2 ϫ 1010 LиmolϪ1 иsϪ1 0 Second order, in aqueous solution C2H5Br ϩ OHϪ ∫∫B C2H5OH ϩ BrϪ 4.3 ϫ 1011 LиmolϪ1 иsϪ1 90 CO2 ϩ OHϪ ∫∫B HCO3 Ϫ 1.5 ϫ 1010 LиmolϪ1 иsϪ1 38 C12H22O11 ϩ H2O ∫∫B 2 C6H12O6 1.5 ϫ 1015 LиmolϪ1 иsϪ1 108 1/Temperature lnk Hot Cold Low activation energy High activation energy FIGURE 14.24 The dependence of the rate constant on temperature for two reactions with different activation energies. The higher the activation energy, the more strongly the rate constant depends on temperature. HOW DO WE DO THAT? The Arrhenius equations for the two temperatures, which we call T and TЈ, when the rate constant for the reaction has the values k and kЈ, respectively, are We eliminate ln A by subtracting the second equation from the first: The expression that we have derived can easily be rearranged into (14)ln k¿ k = Ea R a 1 T - 1 T¿ b ln k¿ - ln k = - Ea RT¿ + Ea RT At temperature T: ln k = ln A - Ea RT At temperature T¿: ln k¿ = ln A - Ea RT¿ By examining this expression we can draw the following conclusions about the temperature dependence of the rate constant: When TЈ Ͼ T, the right-hand side is positive, so ln (kЈ/k) is positive, which means that kЈ Ͼ k. That is, the rate constant increases with temperature. For fixed values of T and TЈ, ln (kЈ/k) is large when Ea is large; so the increase in rate constant is large when the activation is large. Both conclusions are in line with our interpretation of the Arrhenius equation itself. 590 CHAPTER 14 CHEMICAL KINETICS EXAMPLE 14.9 Using the activation energy to predict a rate constant The hydrolysis of sucrose is a part of the digestive process. To investigate how strongly the rate depends on our body temperature, calculate the rate constant for the hydrolysis of sucrose at 35.0°C, given that k ϭ 1.0 mLиmolϪ1 ·sϪ1 at 37.0°C (normal body temperature) and that the activation energy of the reaction is 108 kJ·molϪ1 . Anticipate We should expect a lower rate constant at the lower temperature. PLAN Use Eq. 14 with T ϭ 310.0 K and TЈ ϭ 308.0 K and express R in kilojoules per kelvin per mole to cancel the units of Ea. SOLVE 310.0 K 308.0 K ln(rateconstant) 1/Temperature From = -0.27 * a 1 310.0 K - 1 308.0 K b ln k¿ k = 108 kJиmol-1 8.3145 * 10-3 kJиK-1 иmol-1 ln (k¿>k) = (Ea>R)(1>T - 1>T¿), 310.0 K 308.0 K Rateconstant Temperature 1.0 mL·molϪ1 ·s Ϫ1 0.76 mL·mol Ϫ1 ·s Ϫ1 From x ϭ eln x , k¿ k = e-0.27 Finally, because k ϭ 1.0 mLиmolϪ1 иsϪ1 , kЈ ϭ (1.0 mLиmolϪ1 иsϪ1 ) ϫ eϪ0.27 ϭ 0.76 mLиmolϪ1 иsϪ1 at 35°C. Evaluate As expected, the rate constant at the lower temperature is lower. The high activation energy of the reaction means that its rate is very sensitive to temperature. A note on good practice: We have evaluated the exponent (Ϫ0.27) in this example to avoid writing a cumbersome expression for kЈ/k; our recommended good practice of doing the numerical calculation in one final step does not, in this instance, change the final result (to 2sf). Self-Test 14.13A The rate constant for the second-order reaction between CH3CH2Br and OHϪ in water is 0.28 mL·molϪ1 ·sϪ1 at 35.0°C. What is the value of the rate constant at 50.0°C? See Table 14.4 for data. [Answer: 1.4 mL·molϪ1 ·sϪ1 ] Self-Test 14.13B The rate constant for the first-order isomerization of cyclopropane, C3H6, to propene, CH3CH≈CH2, is 6.7 ϫ 10Ϫ4 sϪ1 at 500.°C. What is its value at 300.°C? See Table 14.4 for data. An Arrhenius plot of ln k against 1/T is used to determine the Arrhenius parameters of a reaction; a large activation energy signifies a high sensitivity of the rate constant to changes in temperature. 14.12 Collision Theory We are now ready to build a model of how chemical reactions take place at the molecular level. Specifically, our model must account for the temperature dependence of rate constants, as expressed by the Arrhenius equation; it should also reveal the significance of the Arrhenius parameters A and Ea. Reactions in the gas phase are conceptually simpler than those in solution, and so we begin with them. First, we assume that a reaction can take place only if reactants meet. In a gas that meeting is a collision, and so the model that we are building is called the collision theory of reactions. In this model, we suppose that molecules behave like defective billiard balls: they bounce apart if they collide at low speed, but they might smash into pieces when the impact is really energetic. If two molecules collide with less than a certain kinetic energy, they simply bounce apart. If they meet with more than that kinetic energy, reactant bonds can break and new bonds can form, resulting in products (Fig. 14.25). We denote the minimum kinetic energy needed for reaction by Emin. To set up a quantitative theory based on this qualitative picture, we need to know the rate at which molecules collide and the fraction of those collisions that have at least the energy Emin required for reaction to occur. The collision frequency (the number of collisions per second) between A and B molecules in a gas at a temperature T can be calculated from the kinetic model of a gas (Section 4.10): (15) in which NA is Avogadro’s constant and ␴ (sigma) is the collision cross section, the area that a molecule presents as a target during a collision. The bigger the collision cross section, the greater the collision frequency, because big molecules are easier targets than small molecules. The quantity is the mean relative speed, the mean speed at which the molecules approach each other in a gas. The mean relative speed is calculated by multiplying each possible speed by the fraction of molecules that have that speed and then adding all the products together. When the temperature is T and the molar masses are MA and MB, this mean relative speed is (16)* The collision frequency is greater the higher the relative speeds of the molecules, and therefore the higher the temperature. Although the mean relative speed of the molecules increases with temperature, and the collision frequency therefore increases as well, Eq. 16 shows that the mean relative speed increases only as the square root of the temperature. This dependence is far too weak to account for observations. If we used Eq. 16 to predict the temperature dependence of reaction rates, we would conclude that an increase in temperature of 10°C at about room temperature (from 273 K to 283 K) increases the collision frequency by a factor of only 1.02, whereas experiments show that many reaction rates double over that range. Another factor must be affecting the rate. To find this factor, we need a measure of the fraction of molecules that collide with a kinetic energy equal to or greater than a certain minimum energy, Emin, because only these energetic collisions can result in reaction. Because kinetic energy is proportional to the square of the speed, this fraction can be obtained from the Maxwell distribution of speeds (Section 4.11). Figure 14.26 shows the kind of result we can expect. As indicated for a specific reaction by the shaded area under the blue curve, at a low temperature very few molecules have enough kinetic energy to react. At higher temperatures, a much larger fraction of molecules can react, as represented by the shaded area under the red curve. We need to bring this fraction into our equations. vrel = a 8RT ␲m b 1/2 m = MAMB MA + MB vrel Collision frequency = svrelNA 2 [A][B] 14.12 COLLISION THEORY 591 (b) (a) E Ͻ Emin E Ͼ Emin FIGURE 14.25 (a) In the collision theory of chemical reactions, reaction may take place only when two molecules collide with a kinetic energy at least equal to a minimum value, Emin (which later we identify with the activation energy). (b) Otherwise, they simply bounce apart. Low temperature Fractionofmolecules High temperature Emin Kinetic energy FIGURE 14.26 The fraction of molecules that collide with a kinetic energy that is at least equal to a certain minimum value, Emin (which later we show to be the activation energy, Ea), is given by the shaded areas under each curve. Note that this fraction increases rapidly as the temperature is raised. 592 CHAPTER 14 CHEMICAL KINETICS HOW DO WE DO THAT? To find how the fraction of molecules that collide with at least an energy Emin affects the rate of an elementary reaction, we need to know that, at a temperature T, the fraction of collisions with at least the energy Emin is equal to eϪEmin/RT , where R is the gas constant. That result comes from an expression known as the Boltzmann distribution, which we do not derive here. The rate of reaction is the product of this factor and the collision frequency: The rate law of an elementary reaction that depends on collisions of A with B is Rate ϭ k[A][B], where k is the rate constant. We can therefore identify the expression for the rate constant as We have deduced that, according to collision theory, the rate constant is (17) This exponential temperature dependence for k is much stronger than the weak temperature dependence of the collision frequency itself. By comparing Eq. 17 with Eq. 13b, we can identify the term NA 2 as the pre-exponential factor, A, and Emin as the activation energy, Ea. That is, we can conclude that • A is a measure of the rate at which molecules collide. • The activation energy, Ea, is the minimum kinetic energy required for a collision to result in reaction. We now understand why some thermodynamically spontaneous reactions do not take place at a measurable rate: they have such high activation energies that hardly any of the collisions between reactants result in reaction. A mixture of hydrogen and oxygen can survive for years: the activation energy for the production of radicals is very high, and no radicals are formed until a spark or flame is brought into contact with the mixture. The dependence of the rate constant on temperature, its sensitivity to the activation energy, and the fact that the equilibrium constant is equal to the ratio of the forward and reverse rate constants (Eq. 11, K ϭ k/kЈ), jointly provide a kinetic explanation for the temperature dependence of the equilibrium constant. To see what is involved, we need to introduce the concept of a diagram called a reaction profile which is used to represent the energy changes that occur during a reaction (Fig. 14.27). Then, with that diagram in mind and remembering that a high activation energy indicates a high sensitivity of the rate constant to temperature: • If the reaction is endothermic in the forward direction, the activation energy is higher for the forward direction than for the reverse direction. The higher activation energy means that the rate constant of the forward reaction depends more strongly on temperature than does the rate constant of the reverse reaction. Therefore, when the temperature is raised, the rate constant for the forward reaction increases more than that of the reverse reaction. As a result, K ϭ k/kЈ will increase and the products will become more favored. • If the reaction is exothermic in the forward direction, the activation energy is lower for the forward direction than for the reverse direction. The lower activation energy means that the rate constant of the forward reaction depends less strongly on temperature than does the rate constant of the reverse reaction. Therefore, when the temperature is raised, the rate constant for the forward reaction increases less than that of the reverse reaction. As a result, K ϭ k/kЈ will decrease and the products will become less favored. Both conclusions are in accord with Le Chatelier’s principle. Now that we have a model, we must check its consistency with various experiments. Sometimes such inconsistencies result in the complete rejection of a model. More often, they indicate that we need to refine the model. In the present case, the results of careful svrel k = svrelNA 2 e-Emin>RT k = rate of reaction [A][B] = svrelNA 2 [A][B] * e-EminR/T [A][B] = svrelNA 2 e-Emin/RT = svrelNA 2 [A][B] * e-Emin>RT Rate of reaction = collision frequency * fraction with sufficient energy Ea(forward)Ea(forward) Ea(reverse) Potentialenergy Progress of reaction(a) Reactants Products Endothermic Exothermic More responsive to temperature Progress of reaction Potentialenergy (b) Reactants Products Ea(reverse) More responsive to temperature FIGURE 14.27 (a) The activation energy for an endothermic reaction is larger in the forward direction than in the reverse, and so the rate of the forward reaction is more sensitive to temperature and the equilibrium shifts toward products as the temperature is raised. (b) The opposite is true for an exothermic reaction, in which case the reverse reaction is more sensitive to temperature and the equilibrium shifts toward reactants as the temperature is raised. experiments show that the collision model of reactions is not complete, because the experimental rate constant is normally smaller than predicted by collision theory. We can improve the model by realizing that the relative orientation of the molecules when they collide also might matter. For example, the results of experiments of the kind described in Box 14.2 have shown that, in the gas-phase reaction of chlorine atoms with HI molecules, HI ϩ Cl : HCl ϩ I, the Cl atom reacts with the HI molecule only if it approaches from a favorable direction (Fig. 14.28). A dependence on relative orientation is called the steric requirement of the reaction. It is normally taken into account by introducing an empirical factor, P, called the steric factor, and changing Eq. 17 to Steric Collision Energy requirement rate requirement (18)*k = P * svrelN 2 A * e-Emin>RT 14.12 COLLISION THEORY 593 $+%+& $+%+&# When molecules collide, old bonds give way to new ones and atoms in one molecule become part of another. Is there any way of finding out experimentally what is happening at this climactic stage of a reaction? Molecular beams provide the answer. We first met molecular beams in Box 4.1, where we saw how a velocity selector is constructed. A molecular beam consists of a stream of molecules moving in the same direction with the same speed. A beam may be directed at a gaseous sample or into the path of a second beam, consisting of molecules of a second reactant. The molecules may react when the beams collide; the experimenters can then detect the products of the collision and the direction at which the products emerge from the collision. They also use spectroscopic techniques to determine the vibrational and rotational excitation of the products. By repeating the experiment with molecules having different speeds and different states of rotational or vibrational excitation, chemists can learn more about the collision itself. For example, experimenters have found that, in the reaction between a Cl atom and an HI molecule, the best direction of attack is within a cone of half-angle 30° surrounding the H atom (see Fig. 14.28). In a “sticky” collision, the reactant molecules orbit around each other for one revolution or more. As a result, the product molecules emerge in random directions because any “memory” of the approach direction is lost. However, a rotation takes time—about 1 ps. If the reaction is over before that, the product molecules will emerge in a specific direction that depends on the direction of the collision. In the collision of K and I2, for example, most of the products are thrown off in the forward direction. This observation is consistent with the “harpoon mechanism” that had been proposed for this reaction. In this mechanism, an electron flips across from the K atom to the I2 molecule when they are quite far apart, and the resulting K+ ion extracts one of the atoms of the negatively charged I2 – ion. We can think of the electron as a harpoon, the electrostatic attraction as the line attached to the harpoon, and I2 as a whale. Because the crucial “harpooning” occurs at large distances and there is no actual collision, the products are thrown off in approximately the same direction as the reactants were traveling. The reaction between a K atom and a CH3I molecule takes place by a different mechanism. A collision leads to reaction only if the two reactants approach each other very closely. In this mechanism, the K atom effectively bumps into a brick wall, and the KI product bounces out in the backward direction. HOW DO WE KNOW . . . WHAT HAPPENS DURING A MOLECULAR COLLISION?BOX 14.2 In the harpoon mechanism for the reaction between potassium and iodine to form potassium iodide, as a K atom approaches an I2 molecule (a), an electron passes from the K atom to the I2 molecule (b). The charge difference now tethers the two ions together (c and d) until an IϪ ion separates and leaves with the Kϩ ion (e). (e) I K I2 KI (d) (c) (b) (a) ϩ ϩ ϩ Ϫ Ϫ Ϫ Table 14.5 lists some values of P. All the values shown are less than 1 because the steric requirement reduces the probability of reaction. For collisions between complex species, the steric requirement may be severe, and P is very small. In such cases, the reaction rate is considerably less than the rate at which high-energy collisions occur. Thinking point: Why might the harpoon mechanism described in Box 14.2 result in a value of P greater than 1? According to the collision theory of gas-phase reactions, a reaction takes place only if the reactant molecules collide with a kinetic energy of at least the activation energy, and they do so in the correct relative orientation. 14.13 Transition State Theory Althoughcollisiontheoryappliestogas-phasereactions,wecanextendsomeof itsconcepts to explain why the Arrhenius equation also applies to reactions in solution. There, molecules do not speed through space and collide, but jostle through the solvent and stay in one another’s vicinity for relatively long periods. The more general theory that accounts both for this behavior and for reactions in gases is called transition state theory (which is also known as activated complex theory). This theory improves on collision theory by suggesting a way of calculating the rate constant even when steric requirements are significant. In transition state theory we imagine two molecules approaching each other and being distorted as they come close enough to affect each other. In the gas phase, that meeting and distortion are equivalent to the “collision” of collision theory. In solution, the approach is a jostling zigzag walk among solvent molecules, and the distortion might not take place until after the two reactant molecules have met and received a particularly vigorous kick from the solvent molecules around them (Fig. 14.29). In either case, the collision or the kick does not immediately tear the molecules apart. Instead, the encounter results in the formation of an activated complex, an arrangement of the two molecules that can either go on to form products or fall apart again into the unchanged reactants. An activated complex is also commonly called a transition state. In the activated complex, the original bonds have lengthened and weakened, and the new bonds are only partly formed. For example, in the proton transfer reaction between the weak acid HCN and water, the activated complex can be pictured as consisting of an HCN molecule with its hydrogen atom in the process of forming a hydrogen bond to the oxygen atom of a water molecule and poised midway between the two molecules. At this point, the hydrogen atom could re-form HCN or leave as the product H3Oϩ . In transition state theory, the activation energy is a measure of the energy of the activated complex relative to that of the reactants. The reaction profile in Fig. 14.30 shows how the energy of the reaction mixture changes as the reactants meet, form the activated complex, and then go on to form products. A reaction profile shows the potential energy of the reactants and products, their total energy arising from their relative location, not their relative speed. Now consider what happens when reactants approach each other with a certain kinetic energy. As the reactants approach, they lose kinetic energy as they “climb” up the left side of the barrier (that is, as their potential energies increase due to the repulsion resulting from their closer approach and the distortions of their bonds). If 594 CHAPTER 14 CHEMICAL KINETICS No reaction I Reaction H Cl Cone of successful attack FIGURE 14.28 Whether a reaction takes place when two species collide in the gas phase depends on their relative orientations. In the reaction between a Cl atom and an HI molecule, for example, only those collisions in which the Cl atom approaches the HI molecule from a direction that lies inside the cone indicated here lead to reaction, even though the energy of collisions in other relative orientations may exceed the activation energy. TABLE 14.5 The Steric Factor, P Reaction P NOCl ϩ NOCl ∫∫B NO + NO ϩ Cl2 0.16 NO2 ϩ NO2 ∫∫B NO ϩ NO ϩ O2 5.0 ϫ 10Ϫ2 ClO ϩ ClO ∫∫B Cl2 ϩ O2 2.5 ϫ 10Ϫ3 H2 ϩ C2H4 ∫∫B C2H6 1.7 ϫ 10Ϫ6 FIGURE 14.29 This sequence of images shows the reactant molecules in solution as they meet, then either move apart, or acquire enough energy by impacts from the solvent molecules to form an activated complex, which may go on to form products. Animation 14.29 the initial kinetic energy of the reactants is less than Ea, they cannot climb to the top of the potential barrier, and they “roll” back down on the left and separate again. If their initial kinetic energy is at least Ea, they can form the activated complex, pass over the top of the barrier, and roll down the other side, where they separate as products. A potential energy surface can help us visualize the energy changes in the course of a reaction as a function of the locations of the atoms. In this three-dimensional plot, the z-axis is a measure of the total potential energy of the reactants and products and the x- and y-axes represent interatomic distances. For example, the plot in Fig. 14.31 shows the potential energy changes that occur in the attack of a bromine atom on a hydrogen molecule and the reverse process, the attack of a hydrogen atom on an HBr molecule: H2 ϩ Brи HBr ϩ Hи HBr ϩ Hи H2 ϩ Brи The low-energy locations corresponding to the reactants and products are separated by a barrier over which there is a path of minimum potential energy and which the kinetic energy of the approaching molecules must overcome. The actual path of the encounter depends on the total energies of the particles, but we can gain insight into the reaction process by examining potential energy changes alone. For example, suppose the HßH bond remained the same length as the Br atom approached. That would take the system to point A, a state of very high potential energy. In fact, at normal temperatures, the colliding species might not have enough kinetic energy to reach this point. The path that involves lowest potential energy is the one up the foot of the valley, over the “saddle point” (the saddle-shaped region) at the top of the pass, and down the foot of the valley on the other side of the pass. Only the lowest-energy path is available: the HßH bond must lengthen as the new HßBr bond begins to form. As in collision theory, the rate of the reaction depends on the rate at which reactants can climb to the top of the barrier and form the activated complex. The resulting expression for the rate constant is very similar to the one given in Eq. 15, and so this more general theory also accounts for the form of the Arrhenius equation and the observed dependence of the reaction rate on temperature. In transition state theory, a reaction takes place only if two molecules acquire enough energy, perhaps from the surrounding solvent, to form an activated complex and cross an energy barrier. ACCELERATING REACTIONS We have seen that the rates of many reactions increase if we increase the concentration of reactants or the temperature. Similarly, the rate of a heterogeneous reaction can be increased by increasing the surface area of a reactant (Fig. 14.32). But suppose we want to increase the rate for a given concentration or surface area without raising the temperature? These sections describe an alternative. 14.14 Catalysis One way to increase the rate of a reaction is to use a catalyst, a substance that increases the rate without being consumed in the reaction (Fig. 14.33). The name comes from the Greek words meaning “breaking down by coming together.” In many cases, only a small amount of catalyst is necessary, because it acts over and over again. This is why small amounts of chlorofluorocarbons can have such a devastating effect on the ozone layer in the stratosphere—they break down into radicals that catalyze the destruction of ozone (Box 14.3). A catalyst speeds up a reaction by providing an alternative pathway—a different reaction mechanism—between reactants and products. This new pathway has a lower ¡ ¡ Activation energy, Ea Reactants Products Progress of reaction Potentialenergy Activation barrier FIGURE 14.30 A reaction profile for an exothermic reaction. In the activated complex theory of reaction rates, it is supposed that the potential energy (the energy due to position) increases as the reactant molecules approach each other and reaches a maximum as they form an activated complex. It then decreases as the atoms rearrange into the bonding pattern characteristic of the products and these products separate. Only molecules with enough energy can cross the activation barrier and react to form products. H−H distance H−Br distance H2 + BrH + HBr A FIGURE 14.31 The contours of a potential energy surface for the reaction between a hydrogen molecule and a bromine atom (on the right). The atoms have been constrained to approach and depart in a straight line. The path of lowest potential energy (blue) is up one valley, across the pass—the saddleshaped high point—and down the floor of the other valley to the products (on the left). The path shown in red would take the atoms to very high potential energies. activation energy than the original pathway (Fig. 14.34). At the same temperature, a greater fraction of reactant molecules can cross the lower barrier of the catalyzed path and turn into products than when no catalyst is present. Although the reaction takes place more quickly, a catalyst has no effect on the equilibrium composition. Both forward and reverse reactions are accelerated on the catalyzed path, leaving the equilibrium constant unchanged. In some cases the original reaction with a slow rate-determining step may continue in parallel with the catalyzed reaction. However, the rate is determined by the faster path, which governs the overall rate of formation of products. A very slow elementary reaction does not control the rate if it can be sidestepped by a faster one on an alternative (usually catalyzed) path (Fig. 14.35). A homogeneous catalyst is a catalyst that is in the same phase as the reactants. For reactants that are gases, a homogeneous catalyst is also a gas. If the reactants are in a liquid solution, a homogeneous catalyst is dissolved in the solution. Dissolved bromine is a homogeneous liquid-phase catalyst for the decomposition of aqueous hydrogen peroxide: 2 H2O2(aq) 2 H2O(l) ϩ O2(g) In the absence of bromine or another catalyst, a solution of hydrogen peroxide can be stored for a long time at room temperature; however, bubbles of oxygen form as soon as a drop of bromine is added. Bromine’s role in this reaction is believed to be its reduction to BrϪ in one step, followed by oxidation back to Br2 in a second step: Br2(aq) ϩ H2O2(aq) 2 BrϪ (aq) ϩ 2 Hϩ (aq) ϩ O2(g) 2 BrϪ (aq) ϩ H2O2(aq) ϩ 2 Hϩ (aq) Br2(aq) ϩ 2 H2O(l) When we add the two steps, both the catalyst, Br2, and the intermediate, BrϪ , cancel, leaving the overall equation as 2 H2O2(aq) : 2 H2O(l) ϩ O2(g). Hence, although Br2 molecules have participated in the reaction, they are not consumed and can be used over and over again. Although a catalyst does not appear in the balanced equation for a reaction, the concentration of a homogeneous catalyst does appear in the rate law. For example, the reaction between the triiodide ion and the azide ion is very slow unless a catalyst such as carbon disulfide is present: CS2 I3 Ϫ (aq) ϩ 2 N3 Ϫ (aq) 3 IϪ (aq) ϩ 3 N2(g) The mechanism for the reaction has two steps: Step 1 Carbon disulfide forms a reactive intermediate, a complex with azide ions: CS2 ϩ N3 Ϫ S2CN3 Ϫ (slow)¡ ¡ ¡ ¡ ¡ FIGURE 14.32 Iron pots and pans can be heated in a flame without catching fire. However, a powder of finely divided iron filings oxidizes rapidly in air to form Fe2O3, because the powder presents a much greater surface area for reaction. Lab Video 14.32 FIGURE 14.33 A small amount of catalyst—in this case, potassium iodide in aqueous solution—can accelerate the decomposition of hydrogen peroxide to water and oxygen. (a) The slow inflation of the balloon when no catalyst is present. (b) Its rapid inflation when a catalyst is present. The Chinese characters for catalyst, which translate as “marriage broker,” capture the sense quite well. Ea(original path) Ea(catalyzed path) Progress of reaction Potentialenergy Products Reactants FIGURE 14.34 A catalyst provides a new reaction pathway with a lower activation energy, thereby allowing more reactant molecules to cross the barrier and form products. 14.15 INDUSTRIAL CATALYSTS 597 Step 2 The complex then reacts rapidly with triiodide ion in a series of fast elementary reactions that can be summarized as 2 S2CN3 Ϫ ϩ I3 Ϫ 2 CS2 ϩ 3 N2 ϩ 3 IϪ (fast) The rate law derived from this mechanism is the same as the experimental rate law: Rate of consumption of I3 Ϫ ϭ k[CS2][N3 Ϫ ] Notice that the rate law is first order in the catalyst, carbon disulfide, but zero order in triiodide ion, which appears only in the fast step following the slow step. A heterogeneous catalyst is a catalyst present in a phase different from that of the reactants. The most common heterogeneous catalysts are finely divided or porous solids used in gas-phase or liquid-phase reactions. They are finely divided or porous so that they will provide a large surface area for the elementary reactions that provide the catalytic pathway. One example is the iron catalyst used in the Haber process for ammonia. Another is finely divided nickel, which is used in the hydrogenation of ethene: H2C≈CH2(g) ϩ H2(g) H3CßCH3(g) The reactant is adsorbed on the catalyst’s surface. As a reactant molecule attaches to the surface of the catalyst, its bonds are weakened and the reaction can proceed more quickly because the bonds are more easily broken (Fig. 14.36). One important step in the reaction mechanism of the Haber process for the synthesis of ammonia is the adsorption of N2 molecules on the iron catalyst and the weakening of the strong NΩN triple bond. Self-Test 14.14A How does a catalyst affect (a) the rate of the reverse reaction; (b) ⌬H for the reaction? [Answer: (a) Increases it; (b) has no effect] Self-Test 14.14B How does a homogeneous catalyst affect (a) the rate law; (b) the equilibrium constant? Catalysts participate in reactions but are not themselves used up; they provide a reaction pathway with a lower activation energy. Catalysts are classified as either homogeneous or heterogeneous. 14.15 Industrial Catalysts The catalytic converters of automobiles use catalysts to bring about the complete and rapid combustion of unburned fuel (Fig. 14.37). The mixture of gases leaving an engine includes carbon monoxide, unburned hydrocarbons, and the nitrogen oxides collectively referred to as NOx. Air pollution is decreased if the carbon compounds are oxidized to carbon dioxide and the NOx reduced, by another catalyst, to nitrogen. The challenge is to find a catalyst—or a mixture of catalysts—that will accelerate both the ¡ ¡ RDS RDS Reactants (c) (b) (a) ProductsIntermediates FIGURE 14.35 (a) If the rate-determining step (RDS) is the second step, the rate law for that step determines the rate law for the overall reaction. The orange curve shows the “reaction profile” for such a mechanism, with a lot of energy required for the slow step. The rate law derived from such a mechanism takes into account steps that precede the RDS. (b) If the rate-determining step is the first step, the rate law for that step must match the rate law for the overall reaction. Later steps do not affect the rate or the rate law. (c) If two routes to the product are possible, the faster one (in this case, the lower one) determines the rate of the reaction; in the mechanism forming the upper route, the slow step (thinner line) is not an RDS. FIGURE 14.36 The reaction between ethene, CH2≈CH2, and hydrogen on a catalytic metal surface. In this sequence of images, we see the ethene molecule approaching the metal surface to which hydrogen molecules have already adsorbed: when they adsorb, they dissociate and stick to the surface as hydrogen atoms. Next, after the ethene molecule also sticks to the surface, it meets a hydrogen atom and forms a bond. At this stage, the ·CH2CH3 radical is attached to the surface by one of its carbon atoms until it meets another hydrogen atom; then ethane is formed and escapes from the surface. Animation 14.36 oxidation and the reduction reactions and be active when the car is first started and the engine is cool. Microporous catalysts are heterogeneous catalysts used in catalytic converters and for many other specialized applications, because of their very large surface areas and reaction specificity. Zeolites, for example, are microporous aluminosilicates (see Section 6.7) with three-dimensional structures riddled with hexagonal channels connected by tunnels (Fig. 14.38). The enclosed nature of the active sites in zeolites gives them a special advantage over other heterogeneous catalysts, because an intermediate can be held in place inside the channels until the products form. Moreover, the channels allow products to grow only to a particular size. One successful application of zeolites is the catalyst ZSM-5, which is used to convert methanol to gasoline. The pores of the zeolite are just large enough to allow Protecting the Ozone Layer Every year our planet is bombarded with enough energy from the Sun to destroy all life. Only the ozone in the stratosphere protects us from that onslaught. The ozone, though, is threatened by modern life styles. Chemicals used as coolants and propellants, such as chlorofluorocarbons (CFCs), and the nitrogen oxides in jet exhausts have been found to create holes in Earth’s protective ozone layer, particularly over Antarctica. Because they act as catalysts, even small amounts of these chemicals can cause large changes in the vast reaches of the stratosphere. Ozone forms in the stratosphere in two steps. First, O2 molecules or other oxygen-containing compounds are broken apart into atoms by sunlight, a process called photodissociation: sunlight, ␭ Ͻ 340 nm O2 O ϩ O Then the O atoms, which are reactive radicals with two unpaired electrons, react with the more abundant O2 molecules to form ozone. The ozone molecules are created in such a highenergy state that their vibrational motions would quickly tear them apart unless another molecule, such as O2 or N2, collides with them first. The other molecule, indicated as M, carries off some of the energy: O ϩ O2 O3* O3* ϩ M O3 ϩ M where * denotes a high-energy state. The net reaction, the sum of these two elementary reactions (after multiplying them by 2) and the reaction presented earlier, is 3 O2 : 2 O3. Some of the ozone is decomposed by ultraviolet radiation: UV, ␭ Ͻ 340 nm O3 O ϩ O2 The oxygen atom produced in this step can react with oxygen molecules to produce more ozone, and so the ozone concentration in the stratosphere normally remains constant, with seasonal variations. Because the decomposition of ozone absorbs ultraviolet radiation, ozone helps to shield the Earth from radiation damage. Warnings of the possibility that androgenic (humangenerated) chemicals can threaten the ozone in the stratosphere began to appear in 1970 and 1971, when Paul Crutzen determined experimentally that NO and NO2 molecules catalyze the destruction of ozone. Nitrogen monoxide (nitric oxide), NO, is produced naturally in the atmosphere by lightning, but it is also a by-product of combustion in automobile and airplane engines. The NO is then oxidized by the oxygen in air to nitrogen dioxide, NO2. Mario Molina and Sherwood Rowland used Crutzen’s work and other data in 1974 to build a model of the stratosphere that explained how chlorofluorocarbons could threaten the ozone layer.1 In 1985, ozone levels over Antarctica were indeed found to be decreasing and had dropped to the lowest ever observed; by the year 2000, the ozone hole extended to Chile. These losses are now known to be global in extent and it has been postulated that they may be contributing to global warming in the Southern Hemisphere. ∫∫∫∫∫∫B ¡ ¡ ∫∫∫∫∫∫∫∫∫B WHAT HAS THIS TO DO WITH . . . THE ENVIRONMENT?BOX 14.3 Area(106 km2 ) 18 0 6 12 24 30 Aug Max 1998–2007 Mean 1998–2007 Min 1998–2007 2008 2007 2006 Sep Oct Nov Dec Variation in the area of the ozone hole over Antarctica from August through December over three years and the overall variation over a decade (shaded). Support Catalyst CO2, H2O, N2, O2, H2S CO, hydrocarbons, NOx, N2, O2, SO2 FIGURE 14.37 The catalytic converter of an automobile is made from a mixture of catalysts bonded to a honeycomb ceramic support. product hydrocarbons consisting of about eight carbon atoms to escape, so the chains do not grow too long and equilibrium is never reached. Zeolite catalysts that adsorb harmful pollutants preferentially have been developed for use in industry and in catalytic converters for vehicles. In catalytic converters, they trap nitrogen oxides so that they can be reduced to harmless nitrogen gas. Catalysts with a different formulation trap incompletely burned hydrocarbons and oxidize them to carbon dioxide. Catalysts can be poisoned, or inactivated. A common cause of such poisoning is the adsorption of a molecule so tightly to the catalyst that it seals the surface of the catalyst against further reaction. Some heavy metals, especially lead, are very potent poisons for heterogeneous catalysts, which is why lead-free gasoline must be used in engines fitted with catalytic converters. The elimination of lead has the further benefit of decreasing the amount of poisonous lead in the environment. Microporous catalysts are heterogenous catalysts such as zeolites that have large surface areas. Susan Solomon and James Anderson showed that CFCs produce chlorine atoms and chlorine oxide under the conditions of the ozone layer and identified the CFCs emanating from everyday objects, such as cans of hair spray, refrigerators, and air conditioners, as primary culprits in the destruction of stratospheric ozone. The CFC molecules are not very polar, and so they do not dissolve in rain or the oceans. Instead, they rise to the stratosphere, where they are exposed to ultraviolet radiation from the Sun. They readily dissociate in the presence of this radiation and form chlorine atoms, which destroy ozone by various mechanisms, one of which is Clи ϩ O3 ClOи ϩ O2 ClOи ϩ иOи Clи ϩ O2 The O atoms are produced when ozone is decomposed by ultraviolet light, as described previously. Notice that the net reaction, O3 + O : O2 + O2, does not involve chlorine. Chlorine atoms act as continuously regenerated catalysts, and so even a low abundance can do a lot of damage. Most nations signed the Montreal Protocol of 1987 and the amendments added in 1992, which required the more dangerous CFCs to be phased out by 1996. The concentration of ozone in the stratosphere is measured by NASA’s Total Ozone Mapping Spectrometer (TOMS). The TOMS data show that the levels of compounds that deplete ozone are decreasing and that the ozone hole has been shrinking, although in 2008 that trend reversed and it began to grow again. It is thought that if the Montreal Protocol continues to be observed and there are no major volcanic eruptions (which release dust that accelerates the destruction of ozone), the ozone levels in the stratosphere may return to protective levels. Related Exercises: 14.47, 14.61, 14.99 For Further Reading: C. Baird and M. Cann, “Stratospheric chemistry: the ozone layer,” Environmental Chemistry, 4th edition (New York: W. H. Freeman and Company, 2008). F. S. Rowland, “Stratospheric ozone depletion,” Philosophical Transactions of the Royal Society B, vol. 361, 2006, pp. 769–790. D. J. Karoly, “Atmospheric science: Ozone and climate change,” Science, vol. 302, 2003, pp. 236–237. NASA, “Ozone Hole Watch,” http://ozonewatch.gsfc.nasa.gov/. 1 Crutzen, Molina, and Rowland were awarded the 1995 Nobel prize in chemistry “for their work in atmospheric chemistry, particularly concerning the formation and decomposition of ozone.” ¡ ¡ Dobson units (DU) March 2003 March 2004 March 2005 100 125 150 175 200 225 250 275 300 325 350 375 400 425 450 475 500 These maps of stratospheric ozone concentration over the North Pole show ozone levels from 2003 to 2005. Normal ozone concentration at temperate latitudes is about 350 DU. FIGURE 14.38 The structure of the ZSM-5 zeolite catalyst. Reactants diffuse through the channels, which are narrow enough to hold intermediates in positions favorable for reaction. 14.16 Living Catalysts: Enzymes Living cells contain thousands of different kinds of catalysts, each of which is necessary to life. Many of these catalysts are proteins called enzymes, large molecules with a slotlike active site, where reaction takes place (Fig. 14.39). The substrate, the molecule on which the enzyme acts, fits into the slot as a key fits into a lock (Fig. 14.40). However, unlike an ordinary lock, a protein molecule distorts slightly as the substrate molecule approaches, and its ability to undergo the correct distortion also determines whether the “key” will fit. This refinement of the original lock-and-key model is known as the induced-fit mechanism of enzyme action. Once in the active site, the substrate undergoes reaction. The product is then released for use in the next stage, which is controlled by another enzyme, and the original enzyme molecule is free to receive the next substrate molecule. One example of an enzyme is the amylase present in your mouth. The amylase in saliva helps to break down starches in food into the more easily digested glucose. If you chew a cracker long enough, you can notice the increased sweetness. The kinetics of enzyme reactions were first studied by the German chemists Leonor Michaelis and Maud Menten in the early part of the twentieth century. They found that, when the concentration of substrate is low, the rate of an enzyme-catalyzed reaction increases with the concentration of the substrate, as shown in the plot in Fig. 14.41. However, when the concentration of substrate is high, the reaction rate depends only on the concentration of the enzyme. In the Michaelis–Menten mechanism of enzyme reaction, the substrate, S, and the bound enzyme–substrate complex, ES, form and separate: E ϩ S ∫∫Bb∫∫ ES forward: second order, Rate ϭ k1[E][S] reverse: first order, Rate ϭ k1Ј[ES] The complex decays with first-order kinetics, releasing the enzyme to act again: ES E ϩ product forward: first order, Rate ϭ k2[ES] When the overall rate law is worked out (see Exercise 14.94), we find that (19a)* where [E]0 is the total concentration of enzyme (bound plus unbound) and the Michaelis constant, KM, is (19b)* When we plot the rate given by Eq. 19a against the concentration of substrate, we get a curve exactly like the one observed. KM = k1¿ + k2 k1 Rate of formation of product = k2[E]0[S] KM + [S] ¡ FIGURE 14.39 The lysozyme molecule is a typical enzyme molecule. Lysozyme is present in a number of places in the body, including tears and the mucus in the nose. One of its functions is to attack the cell walls of bacteria and destroy them. This “ribbon” representation shows only the general arrangement of the atoms to emphasize the overall shape of the molecule; the ribbon actually consists of amino acids linked together (Section 19.13). Substrate “key” Enzyme “lock” Active site Product FIGURE 14.40 In the lock-and-key model of enzyme action, the correct substrate is recognized by its ability to fit into the active site like a key into a lock. In a refinement of this model, the enzyme changes its shape slightly as the key enters. 600 CHAPTER 14 CHEMICAL KINETICS SKILLS YOU SHOULD HAVE MASTERED 601 0 0 Substrate concentration, [S] 4 20168 1 2 4 10 12 Raterelativetomaximum 0.8 0.6 0.4 0.2 1.0 FIGURE 14.41 A plot of the rate of an enzyme-catalyzed reaction (relative to its maximum value, k2[E]0, when S is in very high concentration) as a function of concentration of substrate for various values of KM. At low substrate concentrations, the rate of reaction is directly proportional to the substrate concentration (as indicated by the black line for KM ϭ 10). At high substrate concentrations, the rate becomes constant at k2[E]0 once the enzyme molecules are “saturated” with substrate. The units of [S] are the same as those of KM. Poison (a) (b) FIGURE 14.42 (a) An enzyme poison (represented by the blue sphere) can act by attaching so strongly to the active site that it blocks the site, thereby taking the enzyme out of action. (b) Alternatively, the poison molecule may attach elsewhere, so distorting the enzyme molecule and its active site that the substrate no longer fits. ❑ 1 Determine the order of a reaction, its rate law, and its rate constant from experimental data (Examples 14.1 and 14.2 and Self-Tests 14.2 and 14.3). ❑ 2 Calculate a concentration, time, or rate constant by using an integrated rate law (Examples 14.3, 14.4, and 14.5). ❑ 3 For a first-order process, calculate the rate constant, elapsed time, and amount remaining from the half-life (Example 14.6 and Self-Test 14.9). ❑ 4 Deduce a rate law from a mechanism (Example 14.7). ❑ 5 Show how the equilibrium constant is related to the forward and reverse rate constants of the elementary reactions contributing to an overall reaction (Section 14.10). ❑ 6 Use the Arrhenius equation and temperature dependence of a rate constant to determine an activation energy (Example 14.8). ❑ 7 Use the activation energy to find the rate constant at a given temperature (Example 14.9). ❑ 8 Show how collision theory and transition state theory account for the temperature dependence of reactions (Sections 14.12 and 14.13). ❑ 9 Describe the action of catalysts in terms of a reaction profile (Section 14.14). ❑ 10 Write a rate law for the action of enzymes (Section 14.16). SKILLS YOU SHOULD HAVE MASTERED One form of biological poisoning mirrors the effect of lead on a catalytic converter. The activity of an enzyme is destroyed if an alien substrate attaches too strongly to the enzyme’s active site, because then the site is blocked and made unavailable to the true substrate (Fig. 14.42). As a result, the chain of biochemical reactions in the cell stops, and the cell dies. The action of nerve gases is believed to stem from their ability to block the enzyme-controlled reactions that allow impulses to travel through nerves. Arsenic, that favorite of fictional poisoners, acts in a similar way. After ingestion as As(V) in the form of arsenate ions (AsO4 3Ϫ ), it is reduced to As(III), which binds to enzymes and inhibits their action. Enzymes are biological catalysts that function by modifying substrate molecules to promote reaction. Exercises marked require calculus. All rates are unique reaction rates unless otherwise stated. Reaction Rates 14.1 Complete the following statements relating to the production of ammonia by the Haber process, for which the overall reaction is N2(g) ϩ 3 H2(g) : 2 NH3(g). (a) The rate of consumption of N2 is _________________ times the rate of consumption of H2. (b) The rate of formation of NH3 is _________________ times the rate of consumption of H2. (c) The rate of formation of NH3 is _________________ times the rate of consumption of N2. 14.2 Complete the following statements for the reaction 6 Li(s) ϩ N2(g) : 2 Li3N(s). The rate of consumption of N2 is _________________ times the rate of formation of Li3N. (b) The rate of formation of Li3N is _________________ times the rate of consumption of Li. (c) The rate of consumption of N2 is _________________ times the rate of consumption of Li. 14.3 (a) The rate of formation of dichromate ions is 0.14 molиLϪ1 иsϪ1 in the reaction 2 CrO4 2Ϫ (aq) ϩ 2 Hϩ (aq) : Cr2O7 2Ϫ (aq) ϩ H2O(l). What is the rate of reaction of chromate ions in the reaction? (b) What is the unique rate of the reaction? 14.4 (a) In the reaction 3 ClOϪ (aq) : 2 ClϪ (aq) ϩ ClO3 Ϫ (aq), the rate of formation of ClϪ is 3.6 molиLϪ1 иminϪ1 . What is the rate of reaction of ClOϪ ? (b) What is the unique rate of the reaction? 14.5 (a) Nitrogen dioxide, NO2, decomposes at 6.5 mmolиLϪ1 иsϪ1 by the reaction 2 NO2(g) : 2 NO(g) ϩ O2(g). Determine the rate of formation of O2. (b) What is the unique rate of the reaction? 14.6 Manganate ions, MnO4 2Ϫ , react at 2.0 molиLϪ1 иminϪ1 in acidic solution to form permanganate ions and manganese(IV) oxide: 3 MnO4 2Ϫ (aq) ϩ 4 Hϩ (aq) : 2 MnO4 Ϫ (aq) ϩ MnO2(s) ϩ 2 H2O(l). (a) What is the rate of formation of permanganate ions? (b) What is the rate of reaction of Hϩ (aq)? (c) What is the unique rate of the reaction? 14.7 The decomposition of gaseous hydrogen iodide, 2 HI(g) :H2(g) ϩ I2(g), gives the data shown here for 700. K. Time (s) 0. 1000. 2000. 3000. 4000. 5000. [HI] (mmolؒL؊1 ) 10.0 4.4 2.8 2.1 1.6 1.3 (a) Use a graphing calculator or standard graphing software, such as that on the Web site for this book, to plot the concentration of HI as a function of time. (b) Estimate the rate of decomposition of HI at each time. (c) Plot the concentrations of H2 and I2 as a function of time on the same graph. 14.8 The decomposition of gaseous dinitrogen pentoxide in the reaction 2 N2O5(g) : 4 NO2(g) ϩ O2(g) gives the data shown here at 298 K. (a) Using a graphing calculator or standard graphing software, such as that on the Web site for this book, plot the concentration of N2O5 as a function of time. (b) Estimate the rate of decomposition of N2O5 at each time. (c) Plot the concentrations of NO2 and O2 as a function of time on the same graph. Time (s) 0. 1.11 2.22 3.33 4.44 [N2O5] (mmolиLϪ1 ) 2.15 1.88 1.64 1.43 1.25 Rate Laws and Reaction Order Rate constants are listed in Table 14.1. 14.9 Express the units for rate constants when the concentrations are in moles per liter and time is in seconds for (a) zero-order reactions; (b) first-order reactions; (c) second-order reactions. 14.10 Because partial pressures are proportional to concentrations, rate laws for gas-phase reactions can also be expressed in terms of partial pressures, for instance, as Rate ϭ kPX for a first-order reaction of a gas X. What are the units for the rate constants when partial pressures are expressed in torr and time is expressed in seconds for (a) zero-order reactions; (b) first-order reactions; (c) second-order reactions? 14.11 Dinitrogen pentoxide, N2O5, decomposes by a first-order reaction. What is the initial rate of decomposition of N2O5 when 3.45 g of N2O5 is confined in a 0.750-L container and heated to 65°C? For this reaction, k ϭ 5.2 ϫ 10Ϫ3 sϪ1 in the rate law (for the rate of decomposition of N2O5). 14.12 Ethane, C2H6, dissociates into methyl radicals by a firstorder reaction at elevated temperatures. If 120. mg of ethane is confined to a 500.-mL reaction vessel and heated to 700°C, what is the initial rate of ethane decomposition if k ϭ 5.5 ϫ 10Ϫ4 sϪ1 in the rate law (for the rate of dissociation of C2H6)? 14.13 When 0.52 g of H2 and 0.19 g of I2 are confined to a 750.-mL reaction vessel and heated to 700. K, they react by a second-order process (first order in each reactant), with k ϭ 0.063 LиmolϪ1 иsϪ1 in the rate law (for the rate of formation of HI). (a) What is the initial reaction rate? (b) By what factor does the reaction rate increase if the concentration of H2 present in the mixture is doubled? 14.14 When 420. mg of NO2 is confined to a 150.-mL reaction vessel and heated to 300°C, it decomposes by a second-order process. In the rate law for the decomposition of NO2, k ϭ 0.54 LиmolϪ1 иsϪ1 . (a) What is the initial reaction rate? (b) How does the reaction rate change (and by what factor) if the mass of NO2 present in the container is increased to 750. mg? 14.15 In the reaction CH3Br(aq) ϩ OHϪ (aq) : CH3OH(aq) ϩ BrϪ (aq), when the OHϪ concentration alone was doubled, the rate doubled; when the CH3Br concentration alone was increased by a factor of 1.2, the rate increased by a factor of 1.2. Write the rate law for the reaction. 14.16 In the reaction 4 Fe2ϩ (aq) ϩ O2(g) ϩ 4 H3Oϩ (aq) : 4 Fe3ϩ (aq) ϩ 6 H2O(l), when the Fe2ϩ concentration alone was doubled, the rate increased by a factor of 8; when both the Fe2ϩ and the O2 concentrations were increased by a factor of 2, the rate increased by a factor of 16. When the concentrations of all three reactants were doubled, the rate increased by a factor of 32. What is the rate law for the reaction? 14.17 The following rate data were collected for the reaction 2 A(g) ϩ 2 B(g) ϩ C(g) : 3 G(g) ϩ 4 F(g): EXERCISES C 602 CHAPTER 14 CHEMICAL KINETICS EXERCISES 603 Initial concentration (mmolؒL؊1 ) Initial rate Experiment [A]0 [B]0 [C]0 ((mmol G)иL؊1 ؒs؊1 ) 1 10. 100. 700. 2.0 2 20. 100. 300. 4.0 3 20. 200. 200. 16 4 10. 100. 400. 2.0 5 4.62 0.177 12.4 ? (a) What is the order for each reactant and the overall order of the reaction? (b) Write the rate law for the reaction. (c) Determine the reaction rate constant. (d) Predict the initial rate for Experiment 5. 14.18 The following kinetic data were obtained for the reaction A(g) ϩ 2 B(g) : product. Initial concentration (molؒL؊1 ) Initial rate Experiment [A]0 [B]0 (molиL؊1 ؒs؊1 ) 1 0.60 0.30 12.6 2 0.20 0.30 1.4 3 0.60 0.10 4.2 4 0.17 0.25 ? (a) What is the order with respect to each reactant, and the overall order of the reaction? (b) Write the rate law for the reaction. (c) From the data, determine the value of the rate constant. (d) Use the data to predict the reaction rate for Experiment 4. 14.19 The following data were obtained for the reaction A ϩ B ϩ C : products: Initial concentration (mmolؒL؊1 ) Initial rate Experiment [A]0 [B]0 [C]0 ((mmol A)ؒL؊1 ؒs؊1 ) 1 1.25 1.25 1.25 8.7 2 2.5 1.25 1.25 17.4 3 1.25 3.02 1.25 50.8 4 1.25 3.02 3.75 457 5 3.01 1.00 1.15 ? (a) Write the rate law for the reaction. (b) What is the order of the reaction? (c) Determine the value of the rate constant. (d) Use the data to predict the reaction rate for Experiment 5. 14.20 The following kinetic data were obtained for the reaction 3 A(g) ϩ C(g) : product: Initial concentration (molؒL؊1 ) Initial rate Experiment [A]0 [C]0 (molؒL؊1 ؒs؊1 ) 1 1.72 2.44 0.68 2 3.44 2.44 5.44 3 1.72 0.10 2.8 ϫ 10Ϫ2 4 2.91 1.33 ? (a) What is the order with respect to each reactant, and the overall order of the reaction? (b) Write the rate law for the reaction. (c) From the data, determine the value of the rate constant. (d) Use the data to predict the reaction rate for Experiment 4. Integrated Rate Laws 14.21 Beta blockers are drugs that are used to manage hypertension. It is important for doctors to know how rapidly a beta blocker is eliminated from the body. A certain beta blocker is eliminated in a first-order process with a rate constant of 7.6 ϫ 10Ϫ3 minϪ1 . at normal body temperature (37°). A patient is given 20. mg of the drug. What mass of the drug remains in the body 5.0 h after administration? 14.22 In the brewing of beer, ethanal, which smells like green apples, is an intermediate in the formation of ethanol. Ethanal decomposes in the following first-order reaction: CH3CHO(g) :CH4(g) ϩ CO(g). At an elevated temperature the rate constant for the decomposition is 1.5 ϫ 10Ϫ3 sϪ1 . What concentration of ethanal, which had an initial concentration of 0.120 mol·LϪ1 , remains 20.0 min after the start of its decomposition at this temperature? 14.23 Determine the rate constant for each of the following firstorder reactions, in each case expressed for the rate of loss of A: (a) A : B, given that the concentration of A decreases to one-half its initial value in 1000. s; (b) A : B, given that the concentration of A decreases from 0.67 mol·LϪ1 to 0.53 mol·LϪ1 in 25 s; (c) 2 A : B ϩ C, given that [A]0 ϭ 0.153 mol·LϪ1 and that after 115 s the concentration of B rises to 0.034 mol·LϪ1 . 14.24 Determine the rate constant for each of the following firstorder reactions: (a) 2 A : B ϩ C, given that the concentration of A decreases to one-fourth its initial value in 61 min; (b) 2 A : B ϩ C, given that [A]0 ϭ 0.021 mol·LϪ1 and that after 45 s the concentration of B increases to 0.00125 mol·L–1 ; (c) 2 A : 3 B ϩ C, given that [A]0 ϭ 0.060 mol·LϪ1 and that after 10.8 min the concentration of B rises to 0.040 mol·LϪ1 . In each case, write the rate law for the rate of loss of A. 14.25 Dinitrogen pentoxide, N2O5, decomposes by first-order kinetics with a rate constant of 3.7 ϫ 10Ϫ5 sϪ1 at 298 K. (a) What is the half-life (in hours) for the decomposition of N2O5 at 298 K? (b) If [N2O5]0 ϭ 0.0567 molиLϪ1 , what will be the concentration of N2O5 after 3.5 h? (c) How much time (in minutes) will elapse before the N2O5 concentration decreases from 0.0567 mol·LϪ1 to 0.0135 mol·LϪ1 ? 14.26 Dinitrogen pentoxide, N2O5, decomposes by first-order kinetics with a rate constant of 0.15 sϪ1 at 353 K. (a) What is the half-life (in seconds) for the decomposition of N2O5 at 353 K? (b) If [N2O5]0 ϭ 0.0567 molиLϪ1 , what will be the concentration of N2O5 after 2.0 s? (c) How much time (in minutes) will elapse before the N2O5 concentration decreases from 0.0567 mol·LϪ1 to 0.0135 mol·LϪ1 ? 14.27 The half-life for the first-order decomposition of A is 355 s. How much time must elapse for the concentration of A to decrease to (a) [A]0; (b) one-fourth of its initial concentration; (c) 15% of its initial concentration; (d) one-ninth of its initial concentration? 14.28 The first-order rate constant for the photodissociation of A is 6.85 ϫ 10–2 min–1 . Calculate the time needed for the concentration of A to decrease to (a) [A]0; (b) 10.% of its initial concentration; (c) one-third of its initial concentration. 14.29 For the first-order reaction A : 3 B ϩ C, when [A]0 ϭ 0.015 mol·LϪ1 , the concentration of B increases to 0.018 mol·LϪ1 in 3.0 min. (a) What is the rate constant for the reaction expressed as the rate of loss of A? (b) How much more time would be needed for the concentration of B to increase to 0.030 mol·LϪ1 ? 1 8 1 8 14.30 Pyruvic acid is an intermediate in the fermentation of grains. During fermentation the enzyme pyruvate carboxylase causes the pyruvate ion to release carbon dioxide. In one experiment a 200.-mL aqueous solution of the pyruvate in a sealed, rigid 500.-mL flask at 293 K had an initial concentration of 3.23 mmol·LϪ1 . Because the concentration of the enzyme was kept constant, the reaction was pseudo-first order in pyruvate ion. The elimination of CO2 by the reaction was monitored by measuring the partial pressure of the CO2 gas. The pressure of the gas was found to rise from zero to 100. Pa in 522 s. What is the rate constant of the pseudo-first order reaction? 14.31 The data below were collected for the reaction 2 HI(g) : H2(g) ϩ I2(g) at 580 K. Time (s) 0 1000. 2000. 3000. 4000. [HI] (molؒL؊1 ) 1.0 0.11 0.061 0.041 0.031 (a) Using a graphing calculator or graphing software, such as that on the Web site for this book, plot the data in an appropriate fashion to determine the order of the reaction. (b) From the graph, determine the rate constant for (i) the rate law for the loss of HI and (ii) the unique rate law. 14.32 The data below were collected for the reaction H2(g) ϩ I2(g) : 2 HI(g) at 780 K. (a) Using a graphing calculator or graphing software, such as that on the Web site for this book, plot the data in an appropriate fashion to determine the order of the reaction. (b) From the graph, determine the rate constant for the rate of consumption of I2. Time (s) 0 1.0 2.0 3.0 4.0 [I2] (mmolиL؊1 ) 1.00 0.43 0.27 0.20 0.16 14.33 The half-life for the second-order reaction of a substance A is 50.5 s when [A]0 ϭ 0.84 molиLϪ1 . Calculate the time needed for the concentration of A to decrease to (a) one-sixteenth; (b) onefourth; (c) one-fifth of its original value. 14.34 Determine the rate constant for each of the following second-order reactions: (a) 2 A : B ϩ 2 C, given that the concentration of A decreases from 2.50 mmol·LϪ1 to 1.25 mmol·LϪ1 in 100 s; (b) A : C ϩ 2 D, given that [A]0 ϭ 0.300 mol·LϪ1 and that the concentration of C increases to 0.010 mol·LϪ1 in 200. s. In each case, express your results in terms of the rate law for the loss of A. 14.35 Sulfuryl chloride, SO2Cl2, decomposes by first-order kinetics, and k ϭ 2.81 ϫ 10Ϫ3 minϪ1 at a certain temperature. (a) Determine the half-life for the reaction. (b) Determine the time needed for the concentration of SO2Cl2 to decrease to 10% of its initial concentration. (c) If 14.0 g of SO2Cl2 is sealed in a 2500.-L reaction vessel and heated to the specified temperature, what mass will remain after 1.5 h? 14.36 Ethane, C2H6, forms ·CH3 radicals at 700.°C in a firstorder reaction, for which k ϭ 1.98 hϪ1 . (a) What is the half-life for the reaction? (b) Calculate the time needed for the amount of ethane to fall from 1.15 ϫ 10Ϫ3 mol to 2.35 ϫ 10Ϫ4 mol in a 500.-mL reaction vessel at 700.°C. (c) How much of a 6.88-mg sample of ethane in a 500.-mL reaction vessel at 700.°C will remain after 45 min? 14.37 Determine the time required for each of the following secondorder reactions to take place: (a) 2 A :B ϩ C, for the concentration of A to decrease from 0.10 mol·LϪ1 to 0.080 mol·LϪ1 , given that k ϭ 0.015 L·molϪ1 ·minϪ1 for the rate law expressed in terms of the loss of A; (b) A : 2 B ϩ C, when [A]0 ϭ 0.15 mol·LϪ1 , for the concentration of B to increase to 0.19 mol·LϪ1 , given that k ϭ 0.0035 L·molϪ1 ·minϪ1 in the rate law for the loss of A. 14.38 The second-order rate constant for the decomposition of NO2 (to NO and O2) at 573 K is 0.54 L·molϪ1 ·sϪ1 . Calculate the time for an initial NO2 concentration of 0.20 mol·LϪ1 to decrease to (a) one-half; (b) one-sixteenth; (c) one-ninth of its initial concentration. 14.39 Suppose a reaction has the form a A : products and we consider the unique rate of the reaction and write the rate law Rate ϭ k[A]. Derive an expression for the concentration of A at a time t and for the half-life of A in terms of a and k. 14.40 Suppose a reaction has the form a A : products and we consider the unique rate of the reaction and write the rate law Rate ϭ k[A]2 . Derive an expression for the concentration of A at a time t in terms of a and k. 14.41 Derive an expression for the half-life of the reactant A that decays by a third-order reaction with rate constant k. 14.42 Derive an expression for the half-life of the reactant A that decays by an nth-order reaction (with n Ͼ 1) with rate constant k. Reaction Mechanisms 14.43 Write the overall reaction for the mechanism proposed below and identify any reaction intermediates. Step 1 AC ϩ B AB ϩ C Step 2 AC ϩ AB A2B ϩ C 14.44 Write the overall reaction for the mechanism proposed below and identify any reaction intermediates. Step 1 C4H9Br C4H9 ϩ ϩ BrϪ Step 2 C4H9 ϩ ϩ H2O C4H9OH2 ϩ Step 3 C4H9OH2 ϩ ϩ H2O C4H9OH ϩ H3Oϩ 14.45 Write the overall reaction for the following proposed mechanism and identify any reaction intermediates: ¡ ¡ ¡ ¡ ¡ C 604 CHAPTER 14 CHEMICAL KINETICS C C C ¬ ¬ CH O H2C C OH ϩ HClStep 1 CH ϩ HO H2C C OH ϩ Cl © © © ¬ © ¬∫B 14.46 Lead(IV) acetate cleaves organic diols such as 2,3-dihydroxy- 2,3-dimethylbutane in aqueous solution to give ketones. Write the overall reaction for the following proposed mechanism and identify any reaction intermediates: ¬ © ¬ ¬ ¬ CHH2C C OHStep 3 HO Cl © ¬ ¬ ¬ CH2 O H2C CCl OH ¬ ∫B ¬ © ¬ ¬ ¬© ¬ CHH2C C OHClϪ ϩStep 2 CH HOϩ HO H2C CCl OH © ¬ ∫B EXERCISES 605 Write the rate law for the formation of NOBr implied by this mechanism. 14.50 The mechanism proposed for the oxidation of iodide ion by the hypochlorite ion in aqueous solution is as follows: Step 1 ClOϪ ϩ H2O HClO ϩ OHϪ and its reverse (both fast, equilibrium) Step 2 IϪ ϩ HClO HIO ϩ ClϪ (slow) Step 3 HIO ϩ OHϪ IOϪ ϩ H2O (fast) Write the rate law for the formation of HIO implied by this mechanism. 14.51 Three mechanisms for the reaction NO2(g) ϩ CO(g) : CO2(g) ϩ NO(g) have been proposed: (a) Step 1 NO2 ϩ CO : CO2 ϩ NO (b) Step 1 NO2 ϩ NO2 : NO ϩ NO3 (slow) Step 2 NO3 ϩ CO : NO2 ϩ CO2 (fast) (c) Step 1 NO2 ϩ NO2 : NO ϩ NO3 and its reverse (both fast, equilibrium) Step 2 NO3 ϩ CO : NO2 ϩ CO2 (slow) Which mechanism agrees with the following rate law: Rate ϭ k[NO2]2 ? Explain your reasoning. 14.52 When the rate of the reaction 2 NO(g) ϩ O2(g) : 2 NO2(g) was studied, the rate was found to double when the O2 concentration alone was doubled but to quadruple when the NO concentration alone was doubled. Which of the following mechanisms accounts for these observations? Explain your reasoning. (a) Step 1 NO ϩ O2 : NO3 and its reverse (both fast, equilibrium) Step 2 NO ϩ NO3 : NO2 ϩ NO2 (slow) (b) Step 1 NO ϩ NO : N2O2 (slow) Step 2 O2 ϩ N2O2 : N2O4 (fast) Step 3 N2O4 : NO2 ϩ NO2 (fast) Rates and Equilibrium 14.53 Determine whether each of the following statements is true or false. If a statement is false, explain why. (a) For a reaction with a very large equilibrium constant, the rate constant of the forward reaction is much larger than the rate constant of the reverse reaction. (b) At equilibrium, the rate constants of the forward and reverse reactions are equal. (c) Increasing the concentration of a reactant increases the rate of a reaction by increasing the rate constant in the forward direction. 14.54 Determine whether each of the following statements is true or false. If a statement is false, explain why. (a) The equilibrium constant for a reaction equals the rate constant for the forward reaction divided by the rate constant for the reverse reaction. (b) In a reaction that is a series of equilibrium steps, the overall equilibrium constant is equal to the product of all the forward rate constants divided by the product of all the reverse rate constants. (c) Increasing the concentration of a product increases the rate of the reverse reaction, and so the rate of the forward reaction must then increase, too. 14.55 Consider the reaction A hB, which is first order in each direction with rate constants k and kЈ. Initially, only A is present. Show that the concentrations approach their equilibrium values at a rate that depends on k and kЈ. 14.56 Repeat Exercise 14.55 for the same reaction taken to be second-order in each direction. ¡ ¡ ¡ 14.47 The contribution to the destruction of the ozone layer caused by high-flying aircraft has been attributed to the following mechanism: Step 1 O3 ϩ NO NO2 ϩ O2 Step 2 NO2 ϩ O NO ϩ O2 (a) Write the overall reaction. (b) Write the rate law for each step and indicate its molecularity. (c) What is the reaction intermediate? (d) A catalyst is a substance that accelerates the rate of a reaction and is regenerated in the process. What is the catalyst in the reaction? (See Box 14.3.) 14.48 A reaction was believed to occur by the following mechanism. Step 1 A2 A ϩ A Step 2 A ϩ A ϩ B A2B Step 3 A2B ϩ C A2 ϩ BC (a) Write the overall reaction. (b) Write the rate law for each step and indicate its molecularity. (c) What are the reaction intermediates? (d) A catalyst is a substance that accelerates the rate of a reaction and is regenerated in the process. What is the catalyst in the reaction? 14.49 The following mechanism has been proposed for the reaction between nitric oxide and bromine: Step 1 NO ϩ Br2 NOBr2 (slow) Step 2 NOBr2 ϩ NO NOBr ϩ NOBr (fast)¡ ¡ ¡ ¡ ¡ ¡ ¡ Step 2 OO ϩ Pb(CH3CO2)2 C C Pb H3C CH3 O O CC H3C CH3 OO H3C CH3 CH3H3C C O ®B © ¬ ¬ ¬ ¬ ¬ ¬ ¬ ¬ © © ¬ ¬ ¬ ¬ ¬ ¬ ¬ ¬¬ CH3H3C C O © ¬¬ HO OH C CStep 1 H3C CH3 OO H3C CH3 ϩ Pb(CH3CO2)4 ϩ 2 CH3COOH C C Pb H3C CH3 O O CC H3C CH3 OO H3C CH3 ®B¬ ¬ ¬ ¬ ¬ ¬ ¬ ¬ © ©¬ ¬ ¬ ¬ ¬¬ ¬ ¬¬ ¬ ¬ ¬ ¬ ¬ C C 606 CHAPTER 14 CHEMICAL KINETICS The Effect of Temperature 14.57 (a) Using a graphing calculator or standard graphing software, such as that on the Web site for this book, make an appropriate Arrhenius plot of the data shown here for the conversion of cyclopropane into propene and calculate the activation energy for the reaction. (b) What is the value of the rate constant at 600°C? T (K) 750. 800. 850. 900. k (s؊1 ) 1.8 ϫ 10Ϫ4 2.7 ϫ 10Ϫ3 3.0 ϫ 10Ϫ2 0.26 14.58 (a) Using a graphing calculator or standard graphing software, such as that on the Web site for this book, make an appropriate Arrhenius plot of the data shown here for the decomposition of iodoethane into ethene and hydrogen iodide, C2H5I(g) : C2H4(g) ϩ HI(g), and determine the activation energy for the reaction. (b) What is the value of the rate constant at 400°C? T (K) 660 680 720 760 k (sϪ1 ) 7.2 ϫ 10Ϫ4 2.2 ϫ 10Ϫ3 1.7 ϫ 10Ϫ2 0.11 14.59 The rate constant of the first-order reaction 2 N2O(g) : 2 N2(g) ϩ O2(g) is 0.76 sϪ1 at 1000. K and 0.87 sϪ1 at 1030. K. Calculate the activation energy of the reaction. 14.60 The rate constant of the second-order reaction 2 HI(g) : H2(g) ϩ I2(g) is 2.4 ϫ 10Ϫ6 L·molϪ1 ·sϪ1 at 575 K and 6.0 ϫ 10Ϫ5 L·molϪ1 ·sϪ1 at 630. K. Calculate the activation energy of the reaction. 14.61 The rate constant of the reaction O(g) ϩ N2(g) : NO(g) ϩ N(g), which takes place in the stratosphere, is 9.7 ϫ 1010 L·molϪ1 ·sϪ1 at 800.°C. The activation energy of the reaction is 315 kJ·molϪ1 . Determine the rate constant at 700.°C. (See Box 14.3.) 14.62 The rate constant of the reaction between CO2 and OHϪ in aqueous solution to give the HCO3 Ϫ ion is 1.5 ϫ 1010 L·molϪ1 ·sϪ1 at 25°C. Determine the rate constant at blood temperature (37°C), given that the activation energy for the reaction is 38 kJ·molϪ1 . 14.63 The rate constant for the decomposition of N2O5 at 45°C is k ϭ 5.1 ϫ 10Ϫ4 sϪ1 . The activation energy for the reaction is 103 kJ·molϪ1 . Determine the value of the rate constant at 50°C. 14.64 Ethane, C2H6, dissociates into methyl radicals at 700.°C with a rate constant k ϭ 5.5 ϫ 10Ϫ4 sϪ1 . Determine the rate constant at 800.°C, given that the activation energy of the reaction is 384 kJ·molϪ1 . 14.65 For the reversible, one-step reaction , 2 A hB ϩ C, the forward rate constant for the formation of B is 265 L·molϪ1 ·minϪ1 and the rate constant for the reverse reaction is 392 L·molϪ1 ·minϪ1 . The activation energy for the forward reaction is 39.7 kJ·molϪ1 and that of the reverse reaction is 25.4 kJ·molϪ1 . (a) What is the equilibrium constant for the reaction? (b) Is the reaction exothermic or endothermic? (c) What will be the effect of raising the temperature on the rate constants and the equilibrium constant? 14.66 For the reversible, one-step reaction A ϩ B h C ϩ D, the forward rate constant is 52.4 L·molϪ1 ·hϪ1 and the rate constant for the reverse reaction is 32.1 L·molϪ1 ·hϪ1 . The activation energy was found to be 35.2 kJ·molϪ1 for the forward reaction and 44.0 kJ·molϪ1 for the reverse reaction. (a) What is the equilibrium constant for the reaction? (b) Is the reaction exothermic or endothermic? (c) What will be the effect of raising the temperature on the rate constants and the equilibrium constant? Catalysis 14.67 The presence of a catalyst provides a reaction pathway in which the activation energy of a certain reaction is reduced from 125 kJ·molϪ1 to 75 kJ·molϪ1 . (a) By what factor does the rate of the reaction increase at 298 K, all other factors being equal? (b) By what factor would the rate change if the reaction were carried out at 350. K instead? 14.68 The presence of a catalyst provides a reaction pathway in which the activation energy of a certain reaction is reduced from 88 kJ·molϪ1 to 53 kJ·molϪ1 . (a) By what factor does the rate of the reaction increase at 300. K, all other factors being equal? (b) By what factor would the rate change if the reaction were carried out at 400. K instead? 14.69 A reaction rate increases by a factor of 1000. in the presence of a catalyst at 25°C. The activation energy of the original pathway is 98 kJ·molϪ1 . What is the activation energy of the new pathway, all other factors being equal? In practice, the new pathway also has a different pre-exponential factor. 14.70 A reaction rate increases by a factor of 500. in the presence of a catalyst at 37°C. The activation energy of the original pathway is 106 kJ·molϪ1 . What is the activation energy of the new pathway, all other factors being equal? In practice, the new pathway also has a different pre-exponential factor. 14.71 The hydrolysis of an organic nitrile, a compound containing a ∫CΩN group, in basic solution, is proposed to proceed by the following mechanism. Write a complete balanced equation for the overall reaction, list any intermediates, and identify the catalyst in this reaction. 14.72 Consider the following mechanism for the hydrolysis of ethyl acetate. Write a complete balanced equation for the overall reaction, list any intermediates, and identify the catalyst in this reaction. O CH2 O CH3C ϩ OHϪ Step 1 CH3CH2OϪ ϩ H2O ®B CH3CH2OH ϩ OHϪ Step 2 ϩ CH3CH2OϪ OH O CH3C CH3 ®B¬ © ¬ ¬ ©¬ ¬ ¬ Step 3 NH2 O R C NH OH R C¬ ¬ ¬ ¬ © © ®B ϩ H2O ϩ OHϪ Step 2 NH OH R C NϪ OH R C ¬ © ¬¬ ¬ © ®B R C N ϩ OHϪ Step 1 NϪ OH R C¬ Ω ¬ © ¬ ®B EXERCISES 607 14.73 Determine which of the following statements about catalysts are true. If the statement is false, explain why. (a) In an equilibrium process, a catalyst increases the rate of the forward reaction but leaves the rate of the reverse reaction unchanged. (b) A catalyst is not consumed in the course of a reaction. (c) The pathway for a reaction is the same in the presence of a catalyst as in its absence, but the rate constants are decreased in both the forward and the reverse directions. (d) A catalyst must be carefully chosen to shift the equilibrium toward the products. 14.74 Determine which of the following statements about catalysts are true. If the statement is false, explain why. (a) A heterogeneous catalyst works by binding one or more of the molecules undergoing reaction to the surface of the catalyst. (b) Enzymes are naturally occurring proteins that serve as catalysts in biological systems. (c) The equilibrium constant for a reaction is greater in the presence of a catalyst. (d) A catalyst changes the pathway of a reaction in such a way that the reaction becomes more exothermic. 14.75 The Michaelis–Menten rate equation for enzyme reactions is typically written as the rate of formation of product (Eq. 19a). This equation implies that 1/Rate (where rate is the rate of formation of product) depends linearly on the inverse of the substrate concentration [S]. This relation allows KM to be determined. Derive this equation and sketch 1/Rate against 1/[S]. Label the axes, the y-intercept, and the slope with their corresponding functions. 14.76 The Michaelis constant (KM) is an index of the stability of an enzyme–substrate complex. Does a high Michaelis constant indicate a stable or an unstable enzyme–substrate complex? Explain your reasoning. Integrated Exercises 14.77 Each of the following steps is an elementary reaction. Write its rate law and indicate its molecularity: (a) NO ϩ NO : N2O2; (b) Cl2 : Cl ϩ Cl; (c) NO2 ϩ NO2 : NO ϩ NO3; (d) Which of these reactions might be radical chain initiating? 14.78 Each of the following is an elementary reaction. Write its rate law and indicate its molecularity. (a) O ϩ CF2Cl2 : ClO ϩ CF2Cl; (b) OH ϩ NO2 ϩ N2 : HNO3 ϩ N2; (c) ClOϪ ϩ H2O : HClO ϩ OHϪ ; (d) Which of these reactions might be radical chain propagating? 14.79 In some reactions, two or more different products can be formed by different pathways. If the product formed by the faster reaction predominates, the reaction is considered to be under kinetic control. If the predominant product is the more thermodynamically stable, the reaction is considered to be under thermodynamic control. In the reaction of HBr with the reactive intermediate CH3CH£CHCH2 ϩ , at low temperatures the predominant product is CH3CHBrCH£CH2, but at high temperatures, the predominant product is CH3CH£CHCH2Br. (a) Which product is formed by the pathway with the larger activation energy? (b) Does kinetic control predominate at low or high temperatures? Explain your answers. 14.80 An organic compound A can decompose by either of two kinetically controlled pathways to form products B or C (see Exercise 14.79). The activation energy for the formation of B is greater than that for the formation of C. Will the ratio [B]/[C] increase or decrease as the temperature is increased? Explain your answer. 14.81 The equilibrium constant for the second-order attachment of a substrate to the active site of an enzyme was found to be 326 at 310 K. At the same temperature, the rate constant for the second-order attachment is 7.4 ϫ 107 LиmolϪ1 ·sϪ1 . What is the rate constant for the loss of unreacted substrate from the active site (the reverse of the attachment reaction)? 14.82 Compounds A and B are unstable and each decomposes by a first-order process. At 398 K, the rate constant for the decomposition of A is 3.6 ϫ 10Ϫ5 sϪ1 . Separate containers of A and B were prepared, with initial concentrations of 0.120 (mol A)иLϪ1 and 0.240 (mol B)иLϪ1 . After 5.0 h, it was found that the concentration of A was three times the concentration of B. (a) What was the concentration of A at that time? (b) What is the rate constant for the decomposition of B at 398 K? 14.83 The first-order decomposition of compound X, a gas, is carried out and the data are represented in the following pictures. The green spheres represent the compound; the decomposition products are not shown. The times at which the images were taken are shown below each flask. (a) Determine the half-life of the reaction. (b) Draw the appearance of the molecular image at 8 s. 14.84 Determine the molecularity of the following elementary reactions: (a) ᭺ ϩ ᭹ß᭹ : ᭺ß᭹ ϩ ᭹ (b) ᭺ß᭺ : ᭺ ϩ ᭺ (c) ᭺ ϩ ᭺ ϩ ᭹ : ᭹ ϩ ᭺—᭺ 14.85 The following rate laws were each derived from an elementary reaction. In each case, write the chemical equation for the reaction, determine its molecularity, and draw a proposed structure for the activated complex: (a) Rate ϭ k[CH3CHO] (Products are CH3 and CHO.) (b) Rate ϭ k[I]2 [Ar] (Products are I2 and Ar; the role of the Ar is to remove energy as the product forms.) (c) Rate ϭ k[O2][NO] (Products are NO2 and O.) 14.86 The half-life for the (first-order) decomposition of azomethane, CH3N£NCH3, in the reaction CH3N£NCH3(g) : N2(g) ϩ C2H6(g) is 1.02 s at 300°C. A 45.0-mg sample of azomethane is placed in a 300.-mL reaction vessel and heated to 300°C. (a) What mass (in milligrams) of azomethane remains after 10. s? (b) Determine the partial pressure exerted by the N2(g) in the reaction vessel after 3.0 s. 14.87 All radioactive decay processes follow first-order kinetics. The half-life of the radioactive isotope tritium (3 H, or T) is 12.3 years. How much of a 25.0-mg sample of tritium would remain after 10.9 years? 14.88 The following mechanism has been proposed for the formation of hydrazine, N2(g) ϩ 2 H2(g) : N2H4(g): Step 1 N2 ϩ H2 N2H2 Step 2 H2 ϩ N2H2 N2H4 The rate law for the reaction is Rate ϭ k[N2][H2]2 . Which step is the slow step? Show your work. 14.89 The hydrolysis of sucrose (C12H22O11) produces fructose and glucose: C12H22O11(aq) ϩ H2O(l) : C6H12O6(glucose, aq) ϩ ¡ ¡ 0 5.00 s 10.0 s 608 CHAPTER 14 CHEMICAL KINETICS C6H12O6(fructose, aq). Two mechanisms are proposed for this reaction. (i) C12H22O11 C6H12O6 ϩ C6H10O5 (slow) C6H10O5 ϩ H2O C6H12O6 (fast) (ii) C12H22O11 ϩ H2O C6H12O6 ϩ C6H12O6 (slow) Under what conditions can these two mechanisms be distinguished by using kinetic data? 14.90 Ketones can react with themselves in a process known as aldol condensation. The mechanism for this reaction in acidic solution is shown here. Write the overall reaction, identify any intermediates, and determine the role of the hydrogen ion. 14.91 The rate law of the reaction 2 NO(g) ϩ 2 H2(g) : N2(g) ϩ 2 H2O(g) is Rate ϭ k[NO]2 [H2], and the mechanism that has been proposed is Step 1 NO ϩ NO N2O2 Step 2 N2O2 ϩ H2 N2O ϩ H2O Step 3 N2O ϩ H2 N2 ϩ H2O (a) Which step in the mechanism is likely to be rate determining? Explain your answer. (b) Sketch a reaction profile for the overall reaction, which is known to be exothermic. Label the activation energies of each step and the overall reaction enthalpy. 14.92 (a) Using a graphing calculator or graphing software, such as that on the Web site for this book, calculate the activation energy for the acid hydrolysis of sucrose to give glucose and fructose from an Arrhenius plot of the data shown here. (b) Calculate the rate constant at 37°C (body temperature). (c) From data in Appendix 2A, calculate the enthalpy change for this reaction, assuming that the solvation enthalpies of the sugars are negligible. Draw an energy profile for the overall process. Temperature (°C) k (sϪ1 ) 24 4.8 ϫ 10Ϫ3 28 7.8 ϫ 10Ϫ3 32 13 ϫ 10Ϫ3 36 20. ϫ 10Ϫ3 40. 32 ϫ 10Ϫ3 ¡ ¡ ¡ ¬ ¬ © CH2H3C C ¬ O CH3 CH3 C ¬ OH ¬ ¬ © CH2H3C C ¬ OHϩ CH3 CH3 C ¬ OH ¬ ¬ Step 4 ϩ Hϩ®B®B OH ¬© ¬ ¬Step 3 CH2H3C C ¬ © CH3H3C C ¬ ϩ OHϩ © CH2H3C C ¬ OHϩ CH3 CH3 C ¬ OH ¬ ¬ ®B CH2H3C C ¬ © ®B®BStep 2 ϩ Hϩ CH3H3C C OH © ¬ ¬ OHϩ ¬ © CH3H3C C ¬ ¬ Step 1 ϩ Hϩ CH3H3C C O OHϩ © ¬ ¬ ®B ¡ ¡ ¡ 14.93 Raw milk sours in about 4 h at 28°C but in about 48 h in a refrigerator at 5°C. What is the activation energy for the souring of milk? 14.94 (a) From the following mechanism, derive Eq. 19a, which Michaelis and Menten proposed to represent the rate of formation of products in an enzyme-catalyzed reaction. (b) Show that the rate is independent of substrate concentration at high concentrations of substrate. E ϩ S ∫∫Bb∫∫ ES k1, k1Ј ES E ϩ P k2 where E is the free enzyme, S is the substrate, ES is the enzyme–substrate complex, and P is the product. Note that the steady-state concentration of free enzyme will be equal to the initial concentration of the enzyme less the amount of enzyme that is present in the enzyme–substrate complex: [E] ϭ [E]0 Ϫ [ES]. 14.95 For the enzyme-catalyzed conversion of a certain substrate, KM ϭ 0.038 molиLϪ1 at 25ºC. When the substrate concentration is 0.156 molиL–1 , the rate of the reaction is 1.21 mmolиLϪ1 sϪ1 . The maximum rate of the conversion reaction is reached at high substrate concentrations (see Exercise 14.94). Calculate the maximum rate of this enzyme-catalyzed reaction. 14.96 A gas composed of molecules of diameter 0.5 nm takes part in a chemical reaction at 300. K and 1.0 atm with another gas (present in large excess) consisting of molecules of about the same size and mass to form a gas-phase product at 300. K. The activation energy for the reaction is 25 kJ·molϪ1 . Use collision theory to calculate the ratio of the reaction rate at 320. K to that at 300. K. 14.97 Refer to the illustration below. (a) How many steps does this reaction have? (b) Which is the rate-determining step in this reaction? (c) Which step is the fastest? (d) How many intermediates must form in the reaction? (e) A catalyst is added that accelerates the third step only. What effect, if any, will the catalyst have on the rate of the overall reaction? 14.98 The second-order reactions in Table 14.4 show wide variations in activation energy. In an activated complex, the reactant bonds are lengthened while the product bonds are beginning to form. Consider what bonds need to be stretched to form the activated complex for each reaction and use bond enthalpies (Sections 2.14, 2.15, and 7.20) to explain the differences in activation energies. 14.99 The following mechanism has been suggested to explain the contribution of chlorofluorocarbons to the destruction of the ozone layer: Step 1 O3 ϩ Cl ClO ϩ O2 Step 2 ClO ϩ O Cl ϩ O2¡ ¡ Progress of reaction Potentialenergy ¡ EXERCISES 609 (a) What is the reaction intermediate and what is the catalyst? (b) Identify the radicals in the mechanism. (c) Identify the steps as initiating, propagating, or terminating. (d) Write a chainterminating step for the reaction. (See Box 14.3.) 14.100 Models of population growth are analogous to chemical reaction rate equations. In the model developed by Malthus in 1798, the rate of change of the population N of Earth is dN/dt ϭ births – deaths. The numbers of births and deaths are proportional to the population, with proportionality constants b and d. Derive the integrated rate law for population change. How well does it fit the approximate data for the population of Earth over time given below? Year 1750 1825 1922 1960 1974 1987 2000 N/109 0.5 1 2 3 4 5 6 14.101 The half-life of a substance taking part in a third-order reaction A : products is inversely proportional to the square of the initial concentration of A. How can this half-life be used to predict the time needed for the concentration to fall to (a) onehalf; (b) one-fourth; (c) one-sixteenth of its initial value? 14.102 Suppose that a pollutant is entering the environment at a steady rate R and that, once there, its concentration decays by a first-order reaction. Derive an expression for (a) the concentration of the pollutant at equilibrium in terms of R and (b) the half-life of the pollutant species when R ϭ 0. 14.103 Which of the following plots will be linear? (a) [A] against time for a reaction first order in A; (b) [A] against time for a reaction zero order in A; (c) ln[A] against time for a reaction first order in A; (d) 1/[A] against time for a reaction second order in A; (e) k against temperature; (f) initial rate against [A] for a reaction first order in A; (g) half-life against [A] for a reaction zero order in A; (h) half-life against [A] for a reaction second order in A. 14.104 The pre-equilibrium and the steady-state approximations are two different approaches to deriving a rate law from a proposed mechanism. For the following mechanism, determine the rate law (a) by the pre-equilibrium approximation and (b) by the steady-state approximation. (c) Under what conditions do the two methods give the same answer? (d) What will the rate laws become at high concentrations of BrϪ ? CH3OH ϩ Hϩ CH3OH2 ϩ (fast equilibrium) CH3OH2 ϩ ϩ BrϪ CH3Br ϩ H2O (slow) 14.105 (a) What is the overall reaction for the following mechanism? ClOϪ ϩ H2O HClO ϩ OHϪ (fast equilibrium) HClO ϩ IϪ HIO ϩ ClϪ (very slow) HIO ϩ OHϪ IOϪ ϩ H2O (fast equilibrium) (b) Write the rate law based on this mechanism. (c) How will the reaction rate depend on the pH of the solution? (d) How would the rate law differ if the reactions were carried out in an organic solvent? Δ ¡ Δ ¡ Δ 14.106 The following schematic reaction profile is for the reaction A : D. (a) Is the overall reaction exothermic or endothermic? Explain your answer. (b) How many intermediates are there? Identify them. (c) Identify each activated complex and reaction intermediate. (d) Which step is rate determining? Explain your answer. (e) Which step is the fastest? Explain your answer. 14.107 The decomposition of A has the rate law Rate ϭ k[A]a . Show that for this reaction the ratio t1/2/t3/4, where t1/2 is the halflife and t3/4 is the time for the concentration of A to decrease to of its initial concentration, can be written as a function of a alone and can therefore be used to make a quick assessment of the order of the reaction in A. 14.108 To prepare a 15-kg dog for surgery, 150 mg of the anesthetic phenobarbitol is administered intravenously. The reaction in which the anesthetic is metabolized (decomposed in the body) is first order in phenobarbitol and has a half-life of 4.5 h. After about 2 hours, the drug begins to lose its effect. However, the surgical procedure requires more time than had been anticipated. What mass of phenobarbitol must be re-injected to restore the original level of the anesthetic in the dog? Chemistry Connections 14.109 Cyanomethane, commonly known as acetonitrile, CH3CN, is a toxic volatile liquid that is used as a solvent to purify steriods and to extract fatty acids from fish oils. Acetonitrile can be synthesized from methyl isonitrile by the isomerization reaction CH3NC(g) : CH3CN(g). (a) Draw the Lewis structures of methyl isonitrile and cyanomethane; assign a hybridization scheme to each C atom and indicate whether each molecule is polar or nonpolar. (b) Estimate ⌬H° for the isomerization reaction by using the mean bond enthalpies in Table 7.8. Which isomer is the more stable? (c) The isomerization reaction obeys the first-order rate law, Rate ϭ k[CH3NC] in the presence of argon. The activation energy for this reaction is 161 kJ·molϪ1 and the rate constant at 500. K is 6.6 ϫ 10Ϫ4 sϪ1 . Calculate the rate constant at 300. K and the time (in seconds) needed for the concentration of CH3NC to decrease to 75% of its initial value at 300. K. (d) Draw a reaction profile for the isomerization reaction. (e) Calculate the temperature at which the concentration of CH3NC will decrease to 75% of its original concentration in 1.0 h. (f) What purpose does the excess argon in part (c) serve? (g) At low concentrations of Ar, the rate is no longer first order in [CH3NC]; suggest an explanation. 3 4 Reaction coordinate Potentialenergy A D B C C C COMPUTATIONMAJOR TECHNIQUE 5 Computers have had an enormous impact on the practice of chemistry, where they are used to control apparatus, record and manipulate data, and explore the structures and properties of atoms and molecules. Computer modeling is applied to solids as well as to individual molecules and is useful for predicting the behavior of a material, for example, for indicating which crystal structure of a compound is energetically most favorable, and for predicting phase changes. In this section we concentrate on the use of computers in the exploration of molecular structure. In this context, they are used both to explore practical problems such as predicting the pharmacological activity of compounds and to achieve a deep understanding of the changes that take place during chemical reactions. In semi-empirical methods, complicated integrals are set equal to parameters that provide the best fit to experimental data, such as enthalpies of formation. Semi-empirical methods are applicable to a wide range of molecules with a virtually limitless number of atoms, and are widely popular. The quality of results is very dependent on using a reasonable set of experimental parameters that have the same values across structures, and so this kind of calculation has been very successful in organic chemistry, where there are just a few different elements and molecular geometries. In the more fundamental ab initio methods, an attempt is made to calculate structures from first principles, using only the atomic numbers of the atoms present and their general arrangement in space. Such an approach is intrinsically more reliable than a semi-empirical procedure but it is much more demanding computationally. A currently popular alternative to the ab initio method is density functional theory, in which the energy is expressed in terms of the electron density rather than the wavefunction itself. The advantage of this approach is that it is less demanding computationally, requires less computer time, and in some cases— particularly for d-metal complexes—gives better agreement with experimental values than other procedures. The raw output of a molecular structure calculation is a list of the coefficients of the atomic orbitals in each LCAO (linear combination of atomic orbitals) molecular orbital and the energies of the orbitals. The software commonly calculates dipole moments too. Various graphical representations are used to simplify the interpretation of the coefficients. Thus, a typical graphical representation of a molecular orbital uses stylized shapes (spheres for s-orbitals, for instance) to represent the basis set and then scales their size to indicate the value of the coefficient in the LCAO. Different signs of the wavefunctions are typically represented by different colors. The total electron density at any point (the sum of the squares of the occupied wavefunctions evaluated at that point) is commonly represented by an isodensity surface, a surface of constant total electron density. An important aspect of a molecule, in addition to its geometrical shape and the energies of its orbitals, is the distribution of charge over its surface, because the charge distribution can strongly influence how one molecule (such as a potential drug) can attach to another (and dock into the active site of an enzyme, for instance). A common procedure begins with a calculation of the electrical potential at each point on an isodensity surface. The net potential is determined by subtracting the potential due to the electron density at that point from the potential due to the nuclei. The result is an electrostatic potential surface (an “elpot surface”) in which net positive potential is shown in one color and net negative potential is shown in another, with intermediate gradations of color. The software can also depict a solvent-accessible surface, which represents the shape of the molecule by imagining a sphere representing a solvent molecule rolling across the surface and plotting the locations of its center. Some graphical representations of fluoroethene, CH2=CHF: (a) the isodensity surface showing the general shape of the molecule, (b) the electrostatic potential surface showing the relatively negatively charged region (denoted red) close to the fluorine atom, (c) the highest-energy occupied molecular orbital showing the ␲-bond between the two carbon atoms and the partial involvement of a fluorine orbital, (d) the lowest-energy unoccupied orbital, which is the antibonding counterpart of the ␲-orbital. 610 Procedures are now available that allow for the presence of several solvent molecules around a solute molecule. This approach takes into account the effect of molecular interactions with the solvent on properties such as the enthalpy of formation and the shape adopted by a nonrigid molecule, such as a protein or a region of DNA. These studies are important for investigating the structures and reactions of biological molecules in their natural environment. Related Exercises: Exercises that use software to explore molecular structure are available on the Web site for this text. (a) (b) (c) (d) What Are the Key Ideas? The structures of atoms determine their properties; consequently, the behavior of elements is related to their locations in the periodic table. Why Do We Need to Know This Material? Knowledge of the family relationships of the elements helps us comprehend the nature of matter and allows us to design new materials. The elements in the first four main groups include carbon, the central element of life; silicon and germanium, which are used to create artificial intelligence; calcium, which is responsible for the rigidity of our bones and teeth; the space-age metals aluminum and beryllium; the alkali metals; and hydrogen, the fuel of the stars—and perhaps our future energy source on Earth. The elements in the last four groups of the periodic table include some that are vital to life, such as the nitrogen of proteins, the oxygen of the air, and the phosphorus of our bones, and so a familiarity with their properties helps us to understand living systems. What Do We Need to Know Already? The information in this chapter is organized around the principles of atomic structure and specifically the periodic table (Chapter 1). However, the chapter draws on all the preceding chapters, because it uses those principles to account for the properties of the elements. T his chapter and the next survey the properties of the elements and their compounds in relation to their locations in the periodic table. To prepare for this journey through the periodic table, we first review the trends in properties discussed in earlier chapters. We then start with the unique element hydrogen and move on to the elements of the main groups, working from left to right across the table. The same principles apply to the elements of the d- and f-blocks, but those elements have some unique characteristics (mainly their wide variety of oxidation states and their ability to act as Lewis acids), and so they are treated separately in Chapter 16. Although we concentrate on periodic trends, we also need to know details such as where specific elements are found in nature and how they are purified. In part, the usefulness and availability of an element reflects its abundance on Earth and specifically in the Earth’s crust, which may be quite different from its cosmic abundance. Figure 15.1 summarizes the abundances of the elements in three settings: the universe as a whole, the Earth’s crust, and the human body. PERIODIC TRENDS In Chapter 1, we saw that the members of each group have analogous valence-shell electron configurations, which give them similar properties. However, the element at the head of a group often has features that distinguish it from its congeners, the other members of the group. In these introductory sections, we review atomic properties that correlate with the position of an element in the periodic table. Then we investigate periodic trends in bonding by comparing examples of two types of compounds— hydrides and oxides. 15.1 Atomic Properties All the elements in a given main group have in common a characteristic valence electron configuration. The electron configuration controls the number of bonds that an atom of the element can form and affects its chemical and physical properties. Five atomic properties are principally responsible for the characteristic properties of each PERIODIC TRENDS 15.1 Atomic Properties 15.2 Bonding Trends HYDROGEN 15.3 The Element 15.4 Compounds of Hydrogen GROUP 1: THE ALKALI METALS 15.5 The Group 1 Elements 15.6 Compounds of Lithium, Sodium, and Potassium GROUP 2: THE ALKALINE EARTH METALS 15.7 The Group 2 Elements 15.8 Compounds of Beryllium, Magnesium, and Calcium GROUP 13/III: THE BORON FAMILY 15.9 The Group 13/III Elements 15.10 Group 13/III Oxides and Halides 15.11 Boranes and Borohydrides GROUP 14/IV: THE CARBON FAMILY 15.12 The Group 14/IV Elements 15.13 Oxides of Carbon and Silicon 15.14 Other Important Group 14/IV Compounds GROUP 15/V: THE NITROGEN FAMILY 15.15 The Group 15/V Elements 15.16 Compounds with Hydrogen and the Halogens 15.17 Nitrogen Oxides and Oxoacids 15.18 Phosphorus Oxides and Oxoacids GROUP 16/VI: THE OXYGEN FAMILY 15.19 The Group 16/VI Elements 15.20 Compounds with Hydrogen 15.21 Sulfur Oxides and Oxoacids GROUP 17/VII: THE HALOGENS 15.22 The Group 17/VII Elements 15.23 Compounds of the Halogens GROUP 18/VIII: THE NOBLE GASES 15.24 The Group 18/VIII Elements 15.25 Compounds of the Noble Gases 611 Chapter 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS element: atomic radius, ionization energy, electron affinity, electronegativity, and polarizability. All five properties are related to trends in the effective nuclear charge experienced by the valence electrons and their distance from the nucleus. As we saw in Section 1.12 and Fig. 1.45, valence electrons experience increasing effective nuclear charge on going across a period from left to right. The attraction of a valence electron to the nucleus weakens sharply when electrons enter a new shell, because valence electrons belong to shells that are successively farther from the nucleus and surround electron-rich cores. The valence electrons of elements in the upper right of the periodic table, near fluorine, experience the greatest attraction to their nuclei and those of elements in the lower left, near cesium, experience the least. As a result: • Atomic radii typically decrease from left to right across a period and increase down a group (Fig. 15.2; see also Figs. 1.46 and 1.47). As the nuclear charge experienced by the valence electrons increases across a period, the electrons are pulled closer to the nucleus, so decreasing the atomic radius. Down a group the valence electrons are progressively farther from the nucleus, which increases the atomic radius. Ionic radii follow similar periodic trends (see Fig. 1.48). • First ionization energies typically increase from left to right across a period and decrease down a group (Fig. 15.3; see also Figs. 1.50 and 1.51). The increase from left to right across a period is due to the increasing effective nuclear charge, which grips the electrons more tightly. The decrease in ionization energy down a group shows that it is easier to remove valence electrons from shells that are farther from the nucleus and hence shielded by a greater number of core electrons. • The highest electron affinities are found at the top right of the periodic table (see Fig. 1.54; the trends are too ill defined to depict simply). The electron affinity of an element is a measure of the energy released when an anion is formed. Except for the noble gases, elements near fluorine have the highest electron affinities, and so we can expect them to be present as anions in compounds with metallic elements. Once again, we see the effect of increasing effective nuclear charge: more energy is released when electrons attach to atoms in which they experience the higher effective nuclear charge. • Electronegativities typically increase from left to right across a period and decrease down a group (Fig. 15.4; see also Fig. 2.12). The greater the effective nuclear charge and the closer the electrons are to the nucleus, the stronger the pull on the electrons in a bond. The electronegativity of an element— a measure of the tendency of an atom to attract electrons to itself when part of a compound—is a useful guide to the type of bond that the element is likely to form. When there is a large difference in electronegativity between two elements, their 612 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS Al Fe Ca Mg Remaining elements Hydrogen He (a) Cosmic (b) Crustal Oxygen Silicon Na Hydrogen Oxygen Carbon Ca P Cl S Others (c) Human Ne Na Mg B Li C N O F FIGURE 15.1 These charts show the relative abundances of the principal elements in (a) the universe (the “cosmic abundances”); (b) the crust of the Earth; and (c) the human body. FIGURE 15.2 Atomic radius tends to decrease from left to right across a period and to increase down a group. This diagram and those in Figs. 15.3 through 15.5 are highly schematic representations of periodic trends, with the density of the red tint representing the value of the property: the denser the tint, the higher the value. Decrease Increase FIGURE 15.3 Ionization energy tends to increase from left to right across a period and to decrease down a group. atoms form ionic bonds with each other; when the difference is small, the bonds are covalent. • Polarizabilities typically decrease from left to right along a period and increase down a group (Fig. 15.5). Polarizability measures the ease with which an electron cloud can be distorted and is greatest for the electron-rich heavier atoms of a group and for negatively charged ions. On the other hand, high polarizing power—the ability to distort the electron cloud of a neighboring atom or ion—is commonly associated with small size and high positive charge. We saw in Section 2.13 that a highly polarizable atom or ion (such as iodine or the iodide ion) in combination with an atom or ion of high polarizing power (such as beryllium) is likely to have considerable covalent character in its bonds. Self-Test 15.1A Which of the elements carbon, aluminum, and germanium has atoms with the greatest polarizability? [Answer: Germanium] Self-Test 15.1B Which of the elements oxygen, gallium, and tellurium has the greatest electron affinity? Atomic radii decrease from left to right across a period and increase down a group; ionization energies increase across a period and decrease down a group; electron affinities and electronegativities are highest near fluorine; polarizabilities decrease from left to right across a period and increase down a group. 15.2 Bonding Trends The number of bonds an element can form (its “valence”) and their type are related to its position in the periodic table. We can usually predict the valence of an element in Period 2 from the number of electrons in the valence shell and the octet rule. For example, carbon, with four valence electrons, commonly forms four bonds; and oxygen, with six valence electrons and therefore needing two more to complete its octet, typically forms two bonds. Elements in Period 3 and higher periods can have higher valences than the octet rule suggests. These elements have access to empty d-orbitals and can use them to expand their valence shells past the usual octet of electrons, or they simply have atoms large enough to bond to more neighbors. Elements at the foot and toward the left of the p-block also have variable valence: they can display the inertpair effect and have an oxidation number 2 less than their group number suggests (Section 1.19). The radius of an atom helps to determine how many other atoms can bond to it. The small radii of Period 2 atoms, for instance, are largely responsible for the differences between their properties and those of their congeners. As described in Section 2.10, one reason that small atoms typically have low valences is that so few other atoms can pack around them. Nitrogen, for instance, never forms pentahalides, but phosphorus does. With few exceptions, only Period 2 elements form multiple bonds with themselves or other elements in the same period, because only they are small enough for their p-orbitals to have substantial ␲ overlap (Fig. 15.6). Periodic trends in bonding for main-group elements become apparent when we compare the binary compounds that they form with specific elements. All the main-group elements, with the exception of the noble gases and, possibly, indium and thallium, form binary compounds with hydrogen, so we can examine hydrides to look for periodic trends (Section 15.4). The formulas of hydrides of main-group elements are related directly to the group number and reveal the typical valences of the elements (Fig. 15.7): Group: Group 14/IV Group 15/V Group 16/VI Group 17/VII Element: C N O F Hydride: CH4 NH3 H2O HF Valence: 4 3 2 1 15.2 BONDING TRENDS 613 FIGURE 15.4 Electronegativity generally increases from left to right across a period and decreases down a group. Increase Decrease FIGURE 15.5 The polarizability of atoms tends to decrease from left to right across a period and to increase down a group. (a) (b) FIGURE 15.6 (a) The p-orbitals of Period 3 and heavier elements are held apart by the cores of the atoms (shown in gray) and have very little overlap with each other. (b) In contrast, the atoms of elements in Period 2 are small; consequently their p-orbitals can overlap effectively with each other and with those of elements in later periods. The nature of a binary hydride is related to the characteristics of the element bonded to hydrogen (Fig. 15.8). Strongly electropositive metallic elements form ionic compounds with hydrogen in which the latter is present as a hydride ion, HϪ . These ionic compounds are called saline hydrides (or saltlike hydrides). They are formed by all members of the s-block, with the exception of beryllium, and are made by heating the metal in hydrogen: 2 K(s) ϩ H2(g) 2 KH(s) The saline hydrides are white, high-melting-point solids with crystal structures that resemble those of the corresponding halides. The alkali metal hydrides, for instance, have the rock-salt structure (Fig. 5.41). The metallic hydrides are black, powdery, electrically conducting solids formed by heating certain of the d-block metals in hydrogen (Fig. 15.9): 2 Cu(s) ϩ H2(g) 2 CuH(s) Because the metallic hydrides release their hydrogen (as H2 gas) when heated or treated with acid, they are being investigated for storing and transporting hydrogen. Both saline and metallic hydrides have the high enthalpy densities (enthalpies of combustion per liter) desirable in a portable fuel. Nonmetals form covalent molecular hydrides, which consist of discrete molecules. These compounds are volatile and many are Brønsted acids. Some are gases—for example, ammonia, the hydrogen halides (HF, HCl, HBr, HI), and the lighter hydrocarbons such as methane, ethane, ethene, and ethyne. Liquid molecular hydrides include water and hydrocarbons such as octane and benzene. Broadly speaking (that is, there are exceptions), the pattern of hydrides to note is: Block: s-block d-block p-block Type: saline metallic molecular All the main-group elements except the noble gases also react with oxygen. Like hydrides, the resulting oxides also reveal periodic trends in the elements. The trend in bonding type is from soluble ionic oxides on the left of the periodic table, through insoluble, high-melting-point oxides on the left of the p block, to low-melting-point and often gaseous molecular oxides on the right. Metallic elements with low ionization energies commonly form basic ionic oxides. Elements with intermediate ionization energies, such as beryllium, boron, aluminum, and the metalloids, form amphoteric oxides (react with both acids and bases) that do not react with or dissolve in water, but do dissolve in both acidic and basic solutions. Many oxides of nonmetals are gaseous molecular compounds, such as CO2, NO, and SO3. Most can act as Lewis acids, because the electronegative oxygen atoms withdraw ¡ ¢ ¡ ¢ 614 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 13/III 18/VIII 1 2 14/IV 15/V 16/VI 17/VII FIGURE 15.7 The chemical formulas of the hydrides of the elements of the main groups display the valence characteristic of each group. 2 3 4 5 6 13/III 18/VIII 1 2 3 4 5 6 7 8 9 10 11 12 14/IV 15/V 16/VI 17/VII Saline Metallic Molecular Uncharacterized or unknown FIGURE 15.8 The different classes of binary hydrogen compounds and their distribution throughout the periodic table. FIGURE 15.9 In a metallic hydride, the tiny hydrogen atoms (the small spheres) occupy gaps—called interstices— between the larger metal atoms (the large spheres). Xenon forms an oxide, but by an indirect route. electrons from the central atom, enabling it to act as an electron pair acceptor. Oxides of nonmetals that react with water typically form acidic solutions and hence are called acid anhydrides. The familiar laboratory acids HNO3 and H2SO4, for instance, are derived from the anhydrides N2O5 and SO3, respectively. Even oxides that do not react with water can be regarded as the formal anhydrides of acids. A formal anhydride of an acid is the molecule obtained by striking out the elements of water (H, H, and O) from the molecular formula of the acid. Carbon monoxide, for instance, is the formal anhydride of formic acid, HCOOH, although CO does not react with cold water to form the acid. The general pattern of oxides to keep in mind is: Block: s-block d-block p-block Type: ionic ionic covalent Acid–base character basic basic to amphoteric amphoteric to acidic Self-Test 15.2A An element (“E”) in Period 4 forms a molecular hydride with the formula HE. Identify the element. [Answer: Bromine] Self-Test 15.2B An element (“E”) in Period 3 forms an amphoteric oxide with the formula E2O3. Identify the element. Valence and oxidation state are directly related to the valence-shell electron configuration of a group. Binary hydrides are classified as saline, metallic, or molecular. Oxides of metals tend to be ionic and to form basic solutions in water. Oxides of nonmetals are molecular and many are the anhydrides of acids. HYDROGEN Hydrogen is widely considered to be the fuel of our future, and so its properties are of great interest to scientists and engineers. It occupies a unique place in the periodic table. Although a hydrogen atom has the same valence electron configuration as atoms of the Group 1 elements, ns1 , and forms ϩ1 ions, the element has few other similarities to the alkali metals. Hydrogen is a nonmetal that resembles the halogens: it needs only one electron to complete its valence electron configuration, it can form Ϫ1 ions, and it exists as diatomic molecules (H2). However, the chemical properties of hydrogen are very different from those of the halogens. Because it does not fit clearly into either group of elements, we do not assign it to a group. 15.3 The Element Hydrogen is the most abundant element in the universe, accounting for 89% of all atoms (see Fig. 15.1). These atoms were formed in the first few seconds after the Big Bang, the event that marked the beginning of the universe. However, there is little free hydrogen on Earth because H2 molecules, being very light, move at such high average speeds that they escape from the Earth’s gravity. It takes heavier atoms to anchor hydrogen to the planet in compounds. Most of the Earth’s hydrogen is present as water, either in the oceans or trapped inside minerals and clays. Hydrogen is also found in the hydrocarbons that make up the fossil fuels: coal, petroleum, and natural gas. It takes energy to release hydrogen from these compounds and one of the challenges to achieving its potential as a fuel is to produce the gas by a means that takes less energy than can be obtained from burning it. Because water is its only combustion product, hydrogen burns without polluting the air or contributing significantly to the greenhouse effect (Box 15.1). Petroleum, coal, and natural gas are becoming increasingly rare, but there is enough water in the oceans to generate all the hydrogen fuel we shall ever need. Hydrogen is obtained from water by electrolysis, but that process requires electricity that has been generated elsewhere. Chemists are currently seeking ways of using sunlight to drive the water-splitting reaction, the photochemical decomposition of water into its elements: Water-splitting reaction: 2 H2O(l) light ∫∫∫B 2 H2(g) ϩ O2(g) ⌬G° ϭ ϩ474 kJ 15.3 THE ELEMENT 615 Be aware, though, that most periodic tables that you will come across assign hydrogen either to Group 1 or (less commonly) to both Group 1 and Group 17/VII. In the United States, so many vehicles operate on hydrogen fuel cells (see Box 13.1) that hydrogen refueling stations have opened in many cities, including Washington, DC. 616 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS The Greenhouse Effect Every year our planet receives from the Sun more than enough radiant energy to supply all our energy needs. About 55% of solar radiation is reflected away or used in natural processes. The remaining 45% is converted into thermal motion (heat), most of which escapes as infrared radiation with wavelengths between 4 and 50 μm. The greenhouse effect is the trapping of this infrared radiation by certain gases in the atmosphere. This effect warms the Earth, as if the entire planet were enclosed in a huge green- house.1 Oxygen and nitrogen, which make up roughly 99% of the atmosphere, do not absorb infrared radiation. However, water vapor and CO2 do. Even though these two gases make up only about 1% of the atmosphere, they trap enough radiation to raise the temperature of the Earth by 33°C. Without this naturally occurring greenhouse effect, the average surface temperature of the Earth would be well below the freezing point of water. The major greenhouse gases include water vapor, carbon dioxide, methane, dinitrogen oxide (nitrous oxide), ozone, and certain chlorofluorocarbons. Water is the most important greenhouse gas. It absorbs strongly near 6.3 μm and at wavelengths longer than 12 μm, as shown on the plot. The carbon dioxide in the atmosphere absorbs about half the infrared radiation with wavelengths of 14–16 μm (see graph). The concentration of water vapor in the atmosphere is thought to have remained steady over time, but concentrations of some other greenhouse gases are rising. From the year 1000 or earlier until about 1750, the CO2 concentration in the atmosphere remained fairly stable at about 280 ± 10 parts per million by volume (ppmv). Since then, the CO2 concentration has increased to 379 ppmv in 2005 (see the second graph). The concentration of methane, CH4, has more than doubled during this time and is now at its highest level in 160 000 years. Studies of air pockets in ice cores taken from Antarctica show that changes in the concentrations of both atmospheric carbon dioxide and methane over the past 160 000 years correlate well with changes in the global surface temperature. The rising BOX 15.1 Lightintensity 7.1 10.0 H2O CH4 O3 CO2 H2O Wavelength (μm) 16.7 The intensity of infrared radiation at various wavelengths that would be lost from Earth in the absence of greenhouse gases is shown by the smooth line. The jagged line is the intensity of the radiation actually emitted. The maximum wavelength of radiation absorbed by each greenhouse gas is indicated. concentrations of carbon dioxide and methane are therefore of some concern. Where is the additional CO2 coming from? Human activities are responsible. Some is generated when limestone, CaCO3, is heated and decomposed in cement making (see Section 6.8). Large amounts of CO2 are also released to the atmosphere by deforestation, which involves burning large areas of brush and trees. However, most of it comes from the burning of fossil fuels, which began on a large scale after 1850 and increased by about 80% from 1970 to 2004. The additional methane is coming mainly from the petroleum industry and from agriculture. The temperature of the surface of the Earth is rising about 0.2°C per decade (see graph). If current trends in population growth and energy use continue, by the middle of the twentyfirst century the concentration of CO2 in the atmosphere will be about twice its value prior to the Industrial Revolution. What are the likely consequences of this doubling of the CO2 concentration? 1 The actual insulation mechanism is different in a greenhouse. The glass not only inhibits the escape of infrared radiation but also keeps the warm air inside. At present, most commercial hydrogen is obtained as a by-product of petroleum refining in a sequence of two catalyzed reactions. The first is a reforming reaction, in which a hydrocarbon and steam are converted into carbon monoxide and hydrogen over a nickel catalyst: Reforming reaction: CH4(g) ϩ H2O(g) CO(g) ϩ 3 H2(g) The mixture of products, called synthesis gas, is the starting point for the manufacture of many other compounds, including methanol. The reforming reaction is followed by ¡ Ni WHAT HAS THIS TO DO WITH . . . THE ENVIRONMENT? 15.3 THE ELEMENT 617 The Intergovernmental Panel on Climate Change (IPCC) estimated in 2001 that, by the year 2100, the Earth will undergo an increase in temperature of 3°C, with a rise in sea level of about 0.5 m. A rise of 3°C may not sound like much. However, the temperature during the last ice age was only 6°C lower than at present. Furthermore, the rate of temperature change is likely to be faster than at any time in the past 10 000 years. Rapid climate changes may bring about droughts and storms and have detrimental effects on many of the Earth’s ecosystems. Computer projections of atmospheric CO2 concentration for the next 200 years predict escalating increases in CO2 concentration. Only about half the CO2 released by humans is absorbed by Earth’s natural systems. The other half increases the CO2 concentration in the atmosphere by about 1.5 ppmv per year. Two conclusions can be drawn from these facts. First, even if CO2 emissions were reduced to the amount emitted in 1990 and held constant at that level, the concentration of CO2 in the atmosphere would continue to increase at about 1.5 ppmv per year for the next century. Second, to maintain CO2 at its current concentration of 360 ppmv, we would have to reduce fossil fuel consumption by about 50% immediately. Alternatives to fossil fuels, such as hydrogen, are explored in Box 7.2 and Section 15.3. Coal, which is mostly carbon, can be converted into fuels with a lower proportion of carbon. Its conversion into methane, CH4, for instance, would reduce CO2 emissions per unit of energy. We can also work with nature by accelerating the uptake of carbon by the natural processes of the carbon cycle. For example, one proposed solution is to pump CO2 exhaust deep into the ocean, where it would dissolve to form carbonic acid and bicarbonate ions. Carbon dioxide can also be removed from power plant exhaust gases by passing the exhaust through an aqueous slurry of calcium silicate to produce harmless solid products: 2 CO2(g) ϩ H2O(l) ϩ CaSiO3(s) SiO2(s) ϩ Ca(HCO3)2(s) Related Exercises: 15.107–15.109 For Further Reading: P. Cox & C. Jones, “Climate change: Illuminating the modern dance of climate and CO2,” Science, vol. 321, 2008, pp. 1642Ϫ1644. Intergovernmental Panel on Climate Change, Climate Change 2007 Synthesis Report, IPCC, 2008. R. A. Kerr, “A worrying trend of less ice, higher seas,” Science, vol. 311, 2006, pp. 1698–1701. F. W. Zwiers and A. J. Weaver, “The causes of 20th century warming,” Science, vol. 290, 2000, pp. 2081–2083. US Environmental Protection Agency, “Climate Change,” http://www.epa.gov/climatechange/. ¡ Monthlytemperature (°C,relativeto1961−1990) −1.0 −0.8 −0.6 −0.4 −0.2 0 0.2 0.4 0.6 0.8 2010 2000 1990 1980 1970 1960 1950 1940 1930 1920 1910 1900 1890 1880 1870 1860 1850 Year Carbondioxideconcentration (ppmbyvolume) Emissionrate (1012 kgperyear) 800 260 300 340 380 1000 1200 1400 1600 1800 2000 1850 300 340 380 1900 1950 2000 0 2 4 6 Year Concentration of carbon dioxide in the atmosphere, over the past 1000 years as determined from ice-core measurements. The blue line shows the emission of CO2. The average change in surface temperature of the Earth from 1855 to 2002 compared to the average temperature during 1961–1990. the shift reaction, in which the carbon monoxide in the synthesis gas reacts with more water: Shift reaction: CO(g) ϩ H2O(g) CO2(g) ϩ H2(g) Hydrogen is prepared in small amounts in the laboratory by reducing hydrogen ions from a strong acid (such as hydrochloric acid) with a metal that has a negative standard potential, such as zinc: Zn(s) ϩ 2 Hϩ (aq) Zn2ϩ (aq) ϩ H2(g)¡ ¡ Fe/Cu Hydrogen is a colorless, odorless, tasteless gas (Table 15.1). Because H2 molecules are small and nonpolar, they can attract each other only by very weak London forces. As a result, hydrogen does not condense to a liquid until it is cooled to a very low temperature (20 K at 1 atm). One striking physical property of liquid hydrogen is its very low density (0.070 gиcmϪ3 ), which is less than one-tenth that of water (Fig. 15.10). This low density makes hydrogen a very lightweight fuel. Hydrogen has the highest specific enthalpy of any known fuel (the highest enthalpy of combustion per gram), and so liquid hydrogen is used with liquid oxygen to power the space shuttle’s main rocket engines. Each year, about half the 0.3 Mt (3 ϫ 108 kg) of hydrogen used in industry is converted into ammonia by the Haber process (Section 10.12). Through the reactions of ammonia, hydrogen finds its way into numerous other important nitrogen compounds such as hydrazine and sodium amide (see Section 15.16). Hydrogen is produced as a by-product of the refining of fossil fuels and by electrolysis of water. It has a low density and weak intermolecular forces. 15.4 Compounds of Hydrogen Hydrogen is unusual because it can form both a cation (Hϩ ), so resembling the alkali metals, and an anion (HϪ ), so resembling the halogens. Moreover, its intermediate electronegativity (2.2 on the Pauling scale) means that it can also form covalent bonds with all the nonmetals and metalloids. Because hydrogen forms compounds with so many elements (Table 15.2; also see Section 15.2), we shall meet more of its compounds when we study the other elements. The hydride ion, HϪ , is large, with a radius of 154 pm (1), falling between the fluoride and chloride ions in size. The large radius of the ion makes it highly polarizable and contributes to covalent character in its bonds to cations. However, the single positive charge of the hydrogen atomic nucleus can barely manage to keep control over the two electrons in the HϪ ion, and so they are easily lost. The low energy required for a hydride ion to lose an electron results in ionic hydrides being very powerful reducing agents, and E°(H2/HϪ ) ϭ Ϫ2.25 V. This value is similar to the standard potential for Naϩ /Na (E° ϭ Ϫ2.71 V) and, like sodium metal, hydride ions react with water as soon as they come into contact with it: NaH(s) ϩ H2O(l) NaOH(aq) ϩ H2(g)¡ 618 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS TABLE 15.1 Physical Properties of Hydrogen Valence configuration: 1s1 Normal form*: colorless, odorless gas Molar mass Abundance Melting Boiling Density† Z Name Symbol (gиmolϪ1 ) (%) point (°C) point (°C) (gиLϪ1 ) 1 hydrogen H 1.008 99.98 Ϫ259 (14 K) Ϫ253 (20 K) 0.089 1 deuterium 2 H or D 2.014 0.02 Ϫ254 (19 K) Ϫ249 (24 K) 0.18 1 tritium 3 H or T 3.016 radioactive Ϫ252 (21 K) Ϫ248 (25 K) 0.27 *Normal form means the state and appearance of the element at 25°C and 1 atm. † At 25°C and 1 atm. TABLE 15.2 Chemical Properties of Hydrogen Reactant Reaction with hydrogen Group 1 metals (M) 2 M(s) ϩ H2(g) 2 MH(s) Group 2 metals (M, not Be or Mg) M(s) ϩ H2(g) MH2(s) some d-block metals (M) 2 M(s) ϩ x H2(g) 2 MHx(s) oxygen O2(g) ϩ 2 H2(g) 2 H2O(l) nitrogen N2(g) ϩ 3 H2(g) 2 NH3(g) halogen (X2) X2(g,l,s) ϩ H2(g) 2 HX(g)¡ ¡ ¡ ¡ ¡ ¡ FIGURE 15.10 The two measuring cylinders contain the same mass of liquid. The cylinder on the left holds about 10 mL of water, that on the right liquid hydrogen at –253°C, which is onetenth as dense and consequently has a volume of about 100 mL. 1 Cl− (181 pm) H− (154 pm) F− (133 pm) Na+ (102 pm) Because this reaction produces hydrogen, saline hydrides are potentially useful as transportable sources of hydrogen fuel. Compounds with a bond between hydrogen and nitrogen, oxygen, or fluorine— elements with small, highly electronegative atoms—participate in the very strong intermolecular force known as hydrogen bonding (Section 5.5). A hydrogen bond is about 5% as strong as a covalent bond between the same types of atoms but about ten times stronger than other intermolecular interactions. For example, the H∫O bond enthalpy is 463 kJиmolϪ1 , whereas the OzzzH∫O hydrogen bond enthalpy is about 20 kJиmolϪ1 . There are several models of hydrogen bonding (Chapter 5); the simplest is as a coulombic interaction between the partial positive charge on a hydrogen atom and the partial negative charge of another atom, as in O␦Ϫ zzz␦ϩ H∫O. Thinking point: Deuterium, 2 H, differs from 1 H only in the mass of its nucleus. Can you think of how that difference might affect its properties and those of its compounds? Self-Test 15.3A What common binary compounds of hydrogen are powerful reducing agents? [Answer: The saline (ionic) hydrides] Self-Test 15.3B What are some of the properties of hydrogen that argue against its classification as a Group 1 element? The hydride ion has a large radius and is highly polarizable. Ionic hydrides are powerful reducing agents. Hydrogen can form hydrogen bonds to lone pairs of electrons on highly electronegative elements. GROUP 1: THE ALKALI METALS The members of Group 1 are called the alkali metals. The chemical properties of these elements are unique and strikingly similar. Nevertheless, there are differences, and the subtlety of some of these differences is the basis of the most subtle property of matter: consciousness. Our thinking, which relies on the transmission of signals along neurons, is achieved by the concerted action of sodium and potassium ions and their carefully regulated migration across membranes. So, even to learn about sodium and potassium, we have to make use of them in our brains. As in the discussion of hydrogen, in this section we examine the properties of the alkali metals in the context of the periodic table and focus on significant applications of the elements and selected compounds. The valence electron configuration of the alkali metals is ns1 , where n is the period number. Their physical and chemical properties are dominated by the ease with which the single valence electron can be removed (Table 15.3) 15.4 COMPOUNDS OF HYDROGEN 619 TABLE 15.3 Group 1 Elements: The Alkali Metals Valence configuration: ns1 Normal form*: soft, silver-gray metals Molar mass Melting Boiling Density Z Name Symbol (gиmolϪ1 ) point (°C) point (°C) (gиcmϪ3 ) 3 lithium Li 6.94 181 1347 0.53 11 sodium Na 22.99 98 883 0.97 19 potassium K 39.10 64 774 0.86 37 rubidium Rb 85.47 39 688 1.53 55 cesium Cs 132.91 28 678 1.87 87 francium Fr (223) 27 677 — *Normal form means the state and appearance of the element at 25°C and 1 atm. 15.5 The Group 1 Elements The alkali metals are the most violently reactive of all the metals. They are too easily oxidized to be found in the free state in nature and cannot be extracted from their compounds by ordinary chemical reducing agents. The metals are obtained by electrolysis of their molten salts, as in the electrolytic Downs process (Section 13.13) or, in the case of potassium, by exposing molten potassium chloride to sodium vapor: KCl(l) ϩ Na(g) 750°C ∫∫∫∫∫∫∫B NaCl(s) ϩ K(g) Although the equilibrium constant for this reaction is not particularly favorable, the reaction runs to the right because potassium is more volatile than sodium: the potassium vapor is driven off by the heat and condensed in a cooled collecting vessel. All the Group 1 elements are soft, lustrous, low-density metals (Fig. 15.11). Lithium, sodium, and potassium are the only metals that are less dense than water. Because the valence shell consists of a single electron, bonding in the metals is weak, leading to low melting and boiling points that decrease down the group (Fig. 15.12). Cesium, which melts at 28°C, is barely a solid at room temperature. Lithium is the hardest alkali metal, but it is softer than lead. Francium is intensely radioactive, and little is known about the properties of this very rare element. Lithium metal had few uses until after World War II, when thermonuclear weapons were developed (see Section 17.11). This application has had an effect on the molar mass of lithium. Because only lithium-6 could be used in these weapons, the proportion of lithium-7 and, as a result, the molar mass of commercially available lithium has increased. A growing application of lithium is in the rechargeable lithium-ion battery. Because lithium has the most negative standard potential of all the elements, it can produce a high potential when used in a galvanic cell. Furthermore, because lithium has such a low density, lithium-ion batteries are light. The first ionization energies of the alkali metals are low, and so in their compounds they exist as singly charged cations, such as Naϩ . As a result, most of their compounds are ionic. Because their ionization energies are so low, the standard potentials of the alkali metals are all negative. However, E° does not vary as smoothly as the ionization energy, because the lattice energy of the solid and the hydration energy of the ions play a role in determining E°; entropy effects also contribute. 620 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS (a) (b) (d)(c) FIGURE 15.11 The alkali metals of Group 1: (a) lithium; (b) sodium; (c) potassium; (d) rubidium and cesium. Francium has never been isolated in visible quantities. The first three elements were freshly cut and you can see how rapidly they have been corroded in moist air; rubidium and cesium are even more reactive and have to be stored (and photographed) in sealed, airless containers. 98 Li Na 181 64 39 Rb Cs 28 Fr 27 K FIGURE 15.12 The melting points of the alkali metals decrease down the group. The numerical values shown here are degrees Celsius. Because their standard potentials are so strongly negative, all the alkali metals are strong reducing agents that react with water: 2 Na(s) ϩ 2 H2O(l) 2 NaOH(aq) ϩ H2(g) The vigor of this reaction increases uniformly down the group (Fig. 15.13). The reaction of water with sodium and potassium is vigorous enough to ignite the hydrogen; with rubidium and cesium it is dangerously explosive. Rubidium and cesium are denser than water, and so they sink and react beneath the surface; the rapidly evolved hydrogen gas then forms a shock wave that can shatter the vessel. Lithium is the least active of the Group 1 metals in the reaction with water mainly because of the greater strength with which its atoms are bound together, but molten lithium is one of the most active metals known. The alkali metals also release their valence electrons when they dissolve in liquid ammonia, but the outcome is different. Instead of reducing the ammonia, the electrons occupy cavities formed by groups of NH3 molecules and give ink-blue metal–ammonia solutions (Fig. 15.14). These solutions of solvated electrons (and cations of the metal) are often used to reduce organic compounds. As the metal concentration is increased, the blue gives way to a metallic bronze, and the solutions begin to conduct electricity like liquid metals. All alkali metals react directly with almost all nonmetals except the noble gases. However, only lithium reacts with nitrogen, which it reduces to the nitride ion (N3Ϫ ): 6 Li(s) ϩ N2(g) 2 Li3N(s) The principal product of the reaction of the alkali metals with oxygen varies systematically down the group (Fig. 15.15). Lithium forms mainly the oxide, Li2O. Sodium ¡ ¡ 15.5 THE GROUP 1 ELEMENTS 621 FIGURE 15.13 The alkali metals react with water, producing gaseous hydrogen and a solution of the alkali metal hydroxide. (a) Lithium reacts slowly. (b) Sodium reacts so vigorously that the heat released melts the unreacted metal and ignites the hydrogen. (c) Potassium reacts even more vigorously. (a) (b) (c) FIGURE 15.14 The blue swirls in this flask of liquid ammonia formed when small pieces of sodium were added and dissolved. FIGURE 15.15 Although the alkali metals form a mixture of products when they react with oxygen, lithium gives mainly the oxide (left), sodium the very pale yellow peroxide (center), and potassium the yellow superoxide (right). forms predominantly the very pale yellow sodium peroxide, Na2O2, which contains the peroxide ion O2 2Ϫ , and potassium forms mainly the superoxide, KO2, which contains the superoxide ion, O2 Ϫ . Self-Test 15.4A Write the chemical equation for the reaction between lithium and oxygen. [Answer: 4 Li(s) ϩ O2(g) B 2 Li2O(s)] Self-Test 15.4B Write the chemical equation for the reaction between potassium and oxygen. The alkali metals are highly reactive metals and so they are usually found as singly charged cations. They react with water with increasing vigor down the group. 15.6 Compounds of Lithium, Sodium, and Potassium Lithium is typical of an element at the head of its group, in that it differs significantly from its congeners. The differences stem in part from the small size of the Liϩ cation, which gives it a strong polarizing power and hence a tendency to form bonds with significant covalent character. A further consequence of the small size of a Liϩ ion is strong ion–dipole interactions, with the result that many lithium salts form hydrates. Lithium has a diagonal relationship with magnesium and is found in magnesium minerals, where it replaces the magnesium ion. Lithium compounds are used in ceramics, lubricants, and medicine. Small daily doses of lithium carbonate are an effective treatment for bipolar (manic-depressive) disorder; but scientists still do not fully understand why. Lithium soaps—the lithium salts of long-chain carboxylic acids—are used as thickeners in lubricating greases for high-temperature applications because they have higher melting points than more conventional sodium and potassium soaps. Two factors that make sodium compounds important are their low cost and their high solubility in water. Sodium chloride is readily mined as rock salt, which is a deposit of sodium chloride left as ancient oceans evaporated; it is also obtained from the evaporation of brine (salt water) from present-day seas and salt lakes (Fig. 15.16). Sodium chloride is used in large quantities in the electrolytic production of chlorine and sodium hydroxide from brine. Sodium hydroxide, NaOH, is a soft, waxy, white, corrosive solid that is sold commercially as lye. It is an important industrial chemical because it is an inexpensive starting material for the production of other sodium salts. The amount of electricity used to electrolyze brine to produce NaOH in the chloralkali process is second only to the amount used to extract aluminum from its ores. The process produces chlorine and hydrogen gases as well as aqueous sodium hydroxide (Fig. 15.17). The net ionic equation for the reaction is 2 ClϪ (aq) ϩ 2 H2O(l) ∫∫∫∫∫∫∫∫B Cl2(g) ϩ 2 OHϪ (aq) ϩ H2(g) 622 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.16 An evaporation pond. The blue color is due to a dye added to the brine to increase heat absorption and hence speed up evaporation. electrolysis Sodium hydrogen carbonate, NaHCO3 (sodium bicarbonate), is commonly called bicarbonate of soda or baking soda. The rising action of baking soda in batter depends on the reaction of a weak acid, HA, with the hydrogen carbonate ions: HCO3 Ϫ (aq) ϩ HA(aq) AϪ (aq) ϩ H2O(l) ϩ CO2(g) The release of gas causes the batter to rise. The weak acids are provided by the recipe, generally in the form of lactic acid from sour milk or buttermilk, citric acid from lemons, or the acetic acid in vinegar. Baking powder contains a solid weak acid as well as the hydrogen carbonate, and carbon dioxide is released when water is added. Sodium carbonate decahydrate, Na2CO3и10H2O, was once widely used as washing soda. It is still sometimes added to water to precipitate Mg2ϩ and Ca2ϩ ions as carbonates, as in Ca2ϩ (aq) ϩ CO3 2Ϫ (aq) CaCO3(s) and to provide an alkaline environment that helps to remove grease from fabrics. Anhydrous sodium carbonate, or soda ash, is used in large amounts in the glass industry as a source of sodium oxide, into which it decomposes when heated (Section 6.10). Thinking point. Why is calcium carbonate much less soluble than sodium carbonate? Potassium compounds have many similarities to sodium compounds. The principal mineral sources of potassium are carnallite, KClиMgCl2и6H2O, and sylvite, KCl, which is incorporated directly into some fertilizers as a source of essential potassium. Potassium compounds are generally more expensive than the corresponding sodium compounds, but in some applications their advantages outweigh their expense. For example, potassium nitrate, KNO3, releases oxygen when heated, in the reaction 2 KNO3(s) ⌬ ∫∫B 2 KNO2(s) ϩ O2(g) and is used to facilitate the ignition of matches. It is less hygroscopic (water absorbing) than the corresponding sodium compounds, because the potassium cation is larger and is less strongly hydrated by H2O molecules. Self-Test 15.5A Use Table 13.1 to determine the minimum potential difference that must be applied under standard conditions to carry out the chloralkali process. [Answer: 2.19 V] Self-Test 15.5B Like KO2, cesium superoxide, CsO2, can be used to remove exhaled CO2 and generate oxygen from water. Explain why KO2 is preferred for this purpose on spacecraft. Lithium resembles magnesium, and its compounds show covalent character. Sodium compounds are soluble in water, plentiful, and inexpensive. Potassium compounds are generally less hygroscopic than sodium compounds. GROUP 2: THE ALKALINE EARTH METALS Calcium, strontium, and barium are called the alkaline earth metals, because their “earths”—the old name for oxides—are basic (alkaline). The name alkaline earth metal is often extended to all the members of Group 2 (Table 15.4). ¡ ¡ 15.6 COMPOUNDS OF LITHIUM, SODIUM, AND POTASSIUM 623 FIGURE 15.17 A diaphragm cell for the electrolytic production of sodium hydroxide from brine (aqueous sodium chloride solution), represented by the blue color. The diaphragm prevents the chlorine produced at the titanium anodes from mixing with the hydrogen and the sodium hydroxide formed at the steel cathodes. The liquid (cell liquor) is drawn off and the water is partly evaporated. The unconverted sodium chloride crystallizes, leaving the sodium hydroxide dissolved in the cell liquor. Hydrogen Titanium anode Cell liquor Steel cathode Diaphragm Brine Chlorine TABLE 15.4 Group 2 Elements Valence configuration: ns2 Normal form*: soft, silver-gray metals Molar mass Melting Boiling Density Z Name Symbol (gиmolϪ1 ) point (°C) point (°C) (gиcmϪ3 ) 4 beryllium Be 9.01 1285 2470 1.85 12 magnesium Mg 24.31 650 1100 1.74 20 calcium Ca 40.08 840 1490 1.53 38 strontium Sr 87.62 770 1380 2.58 56 barium Ba 137.33 710 1640 3.59 88 radium Ra (226) 700 1500 5.00 *Normal form means the state and appearance of the element at 25°C and 1 atm. Magnesium is uniquely important for humanity, because it is, in effect, the doorway to life: it is present in every chlorophyll molecule and hence enables photosynthesis to take place. Calcium is the element of rigidity and construction: it is the cation in the bones of our skeletons, the shells of shellfish, and the concrete, mortar, and limestone of buildings (see Sections 6.6 and 6.8). 15.7 The Group 2 Elements The valence electron configuration of the atoms of the Group 2 elements is ns2 . The second ionization energy is low enough to be recovered from the lattice enthalpy (Fig. 15.18). Hence, the Group 2 elements occur with an oxidation number of ϩ2, as the cation M2ϩ , in all their compounds. Apart from a tendency toward nonmetallic character in beryllium, the elements have all the chemical characteristics of metals, such as forming basic oxides and hydroxides. All the Group 2 elements are too reactive to occur in the uncombined state in nature (Fig. 15.19). Instead, they are generally found in compounds as doubly charged cations. The element beryllium occurs mainly as beryl, 3BeOиAl2O3и6SiO2, sometimes in crystals so big that they weigh several tons. The gemstone emerald is a form of beryl; its green color is caused by Cr3ϩ ions present as impurities (Fig. 15.20). Magnesium occurs in seawater and as the mineral dolomite, CaCO3иMgCO3. Calcium also occurs as CaCO3 in compressed deposits of the shells of ancient marine organisms and exoskeletons of tiny one-celled organisms; these deposits include limestone, calcite, and chalk (a softer variety of calcium carbonate). Beryllium is obtained by electrolytic reduction of molten beryllium chloride. The element’s low density makes it useful for the construction of missiles and satellites. Beryllium is also used as windows for x-ray tubes: because Be atoms have so few electrons, thin sheets of the metal are transparent to x-rays and allow the rays to escape. Beryllium is added in small amounts to copper: the small Be atoms pin the Cu atoms together in an interstitial alloy that is more rigid than pure copper but still conducts electricity well. These hard, electrically conducting alloys are formed into nonsparking tools for use in oil refineries and grain elevators, where there is a risk of explosion. Beryllium–copper alloys are also used in the electronics industry to form tiny nonmagnetic parts and contacts that resist deformation and corrosion. Metallic magnesium is produced by either chemical or electrolytic reduction of its compounds. In chemical reduction, first magnesium oxide is obtained from the thermal decomposition of dolomite. Then ferrosilicon, an alloy of iron and silicon, is used to reduce the MgO at about 1200°C. At this temperature, the magnesium produced is immediately vaporized and carried away. The electrolytic method uses seawater as its principal raw material: magnesium hydroxide is precipitated by adding 624 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.18 The first (front row) and second (back row) ionization energies (in kilojoules per mole) of the Group 2 elements. Although the second ionization energies are larger than the first, they are not enormous, and both valence electrons are lost from each atom in all the compounds of these elements. 1760 1450 1145 1060 966 900 736 590 548 502 Be Mg Ca Sr Ba FIGURE 15.19 The elements of Group 2: (a) beryllium; (b) magnesium; (c) calcium; (d) strontium; and (e) barium. The four central elements of the group (magnesium through barium) were discovered by Humphry Davy in a single year (1808). The two outer elements were discovered later: beryllium in 1828 (by Friedrich Wöhler) and radium (which is not shown here) in 1898 (by Pierre and Marie Curie). (a) (b) (c) (d) (e) slaked lime (Ca(OH)2, see Section 15.8), the precipitate is filtered off and treated with hydrochloric acid to produce magnesium chloride, and the dried molten salt is electrolyzed. Magnesium is a silver-white metal that is protected from extensive oxidation in air by a film of white oxide, which gives the metal a dull gray coat. Its density is only twothirds that of aluminum, and the pure metal is very soft. However, its alloys have great strength, and they are used in applications requiring lightness and toughness—in airplanes, for instance. The use of magnesium alloys in automobiles increased by a factor of 5 between 1989 and 1995 as manufacturers sought to reduce the weight of vehicles. However, don’t expect to be driving a magnesium car soon: magnesium is more expensive than steel and more difficult to work. It melts at a low temperature and is deformed by the heat produced when it is machined. Water cannot be used to cool the tools because magnesium reacts with hot water to produce hydrogen. Magnesium burns vigorously in air with a brilliant white flame, partly because it reacts with the nitrogen and carbon dioxide in air as well as with oxygen. Because the reaction is accelerated when burning magnesium is sprayed with water or exposed to carbon dioxide, neither water nor CO2 fire extinguishers should ever be used on a magnesium fire. They will only make the fire worse! The true alkaline earth metals—calcium, strontium, and barium—are obtained either by electrolysis or by reduction with aluminum in a version of the thermite process (see Fig. 7.8): 3 BaO(s) ϩ 2 Al(s) ⌬ ∫∫B Al2O3(s) ϩ 3 Ba(s) As in Group 1, reactions of the Group 2 metals with oxygen and water increase in vigor going down the group. Beryllium, magnesium, calcium, and strontium are partly passivated in air by a protective surface layer of oxide. Barium, however, does not form a protective oxide and may ignite in moist air. All the Group 2 elements with the exception of beryllium react with water; for example, Ca(s) ϩ 2 H2O(l) Ca2ϩ (aq) ϩ 2 OHϪ (aq) ϩ H2(g) Beryllium does not react with water, even when red hot: its protective oxide film survives even at high temperatures. Magnesium reacts with hot water (see Fig. 14.22), and calcium reacts with cold water (Fig. 15.21). The metals reduce hydrogen ions to hydrogen gas, but neither beryllium nor magnesium dissolves in nitric acid, because both become passivated by a film of oxide. The alkaline earth metals can be detected in burning compounds by the colors that they give to flames. Calcium burns orange-red, strontium crimson, and barium yellowgreen. Fireworks are often made from their salts (typically nitrates and chlorates, because the anions then provide an additional supply of oxygen) together with magnesium powder. Self-Test 15.6A Write the chemical equation for the reaction that would occur if you tried to put out a magnesium fire with water. [Answer: Mg(s) ϩ 2 H2O(l) : Mg2ϩ (aq) ϩ 2 OHϪ (aq) ϩ H2(g)] Self-Test 15.6B Write the chemical equation for the reaction of barium with oxygen. Beryllium shows a hint of nonmetallic character, but the other Group 2 elements are all reactive metals. The vigor of reaction with water and oxygen increases down the group. 15.8 Compounds of Beryllium, Magnesium, and Calcium Beryllium, at the head of Group 2, resembles its diagonal neighbor aluminum in its chemical properties. It is the least metallic element of the group, and many of its compounds have properties commonly attributed to covalent bonding. Beryllium is amphoteric and reacts with both acids and alkalis. Like aluminum, beryllium reacts with ¡ 15.8 COMPOUNDS OF BERYLLIUM, MAGNESIUM, AND CALCIUM 625 FIGURE 15.20 An emerald is a crystal of beryl with some Cr3ϩ ions, which are responsible for the green color. FIGURE 15.21 Calcium reacts gently with cold water to produce hydrogen and calcium hydroxide, Ca(OH)2. water in the presence of sodium hydroxide; the products are the beryllate ion, Be(OH)4 2Ϫ , and hydrogen: Be(s) ϩ 2 OHϪ (aq) ϩ 2 H2O(l) Be(OH)4 2Ϫ (aq) ϩ H2(g) Beryllium compounds are very toxic and must be handled with great caution. Their properties are dominated by the highly polarizing character of the Be2ϩ ion and its small size. The strong polarizing power results in moderately covalent compounds, and its small size limits to four the number of groups that can attach to the ion. These two features together are responsible for the prominence of the tetrahedral BeX4 unit (2), like that in the beryllate ion. A tetrahedral unit is also found in the solid chloride (3) and hydride. Beryllium hydride was once thought to consist of chains of BeH2 groups, but it is now known to have a network structure (Fig. 15.22). The chloride is made by the action of chlorine on the oxide in the presence of carbon: BeO(s) ϩ C(s) ϩ Cl2(g) ∫∫∫∫∫B BeCl2(g) ϩ CO(g) The Be atoms in BeCl2 act as Lewis acids and accept electron pairs from the Cl atoms of the neighboring linear BeCl2 groups, forming a chain of tetrahedral BeCl4 units in the solid. Magnesium has more pronounced metallic properties than beryllium; its compounds are primarily ionic, with some covalent character. Magnesium oxide, MgO, is formed when magnesium burns in air, but the product is contaminated by magnesium nitride. To prepare the pure oxide, the hydroxide or the carbonate is heated. Magnesium oxide dissolves only very slightly in water. One of its most striking properties is that it is refractory (able to withstand high temperatures); it melts at 2800°C. This high stability can be traced to the small ionic radii of the Mg2ϩ and O2Ϫ ions and hence to their very strong electrostatic interaction with each other. The oxide has two other useful characteristics: it conducts heat very well, and it conducts electricity poorly. All three properties make it useful as an insulator in electric heaters. Magnesium hydroxide, Mg(OH)2, is a base. It is not very soluble in water but forms instead a white colloidal suspension, a mist of small particles dispersed through a liquid (see Section 9.21), which is known as milk of magnesia and used as a stomach antacid. Because this base is relatively insoluble, it is not absorbed from the stomach but remains to act on whatever acids are present. Hydroxides have an advantage over hydrogen carbonates (which also are used as antacids) in that their neutralization does not lead to the formation of carbon dioxide and its consequence, belching. Milk of magnesia must be used sparingly as an antacid, because the salt produced by the neutralization of milk of magnesia in the stomach is magnesium chloride, which can act as a purgative. Magnesium sulfate, as Epsom salts, MgSO4и7H2O, is another common purgative. The magnesium ions inhibit the absorption of water from the intestine. The resulting increased flow of water through the intestine triggers the mechanism that results in defecation. Arguably the most important compound of magnesium is chlorophyll. This green organic compound consists of large molecules that capture light from the Sun and channel its energy into photosynthesis. One function of the Mg2ϩ ion, which lies just above the plane of the ring (4), appears to be to keep the ring rigid. This rigidity helps to ensure that the energy captured from the incoming photon is not lost as heat before it has been used to bring about a chemical reaction. Magnesium also plays an important role in energy generation in living cells. For example, it is involved in the contraction of muscles. ¡ 626 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 2 BeX4 unit 3 Beryllium chloride, BeCl2 FIGURE 15.22 The network structure of beryllium hydride is based on tetrahedral BeX4 units. Be H 600–800°C 4 Chlorophyll Mg The most common compound of calcium is calcium carbonate, CaCO3, which occurs naturally in a variety of forms such as chalk and limestone. These minerals, which are described in Section 6.6, are the compressed remains of shells and skeletons of marine life. Calcium carbonate decomposes to calcium oxide, CaO, or quicklime, when heated: CaCO3(s) ⌬ ∫∫B CaO(s) ϩ CO2(g) Calcium oxide is called quicklime because it reacts so exothermically and rapidly with water: CaO(s) ϩ H2O(l) Ca2ϩ (aq) ϩ 2 OHϪ (aq) The product, calcium hydroxide, is commonly known as slaked lime because, as calcium hydroxide, the thirst of lime for water has been quenched (slaked). Slaked lime is the form in which lime is normally sold because quicklime can set fire to moist wood and paper. In fact, the wooden boats that were once used to transport quicklime sometimes caught fire in the heat of reaction when water seeped into their holds. An aqueous solution of calcium hydroxide, which is slightly soluble in water, is called lime water. It is used as a test for carbon dioxide, with which it reacts to form a cloudy suspension of the much less soluble calcium carbonate: Ca(OH)2(aq) ϩ CO2(g) CaCO3(s) ϩ H2O(l) Quicklime is produced in enormous quantities throughout the world. About 40% of this output is used in metallurgy. In ironmaking (Section 16.3), it is used as a Lewis base; its O2Ϫ ion reacts with silica, SiO2, impurities in the ore to form a liquid slag: CaO(s) ϩ SiO2(s) ⌬ ∫B CaSiO3(l) About 50 kg of lime is needed to produce 1 tonne (103 kg) of iron. Slaked lime is used as an inexpensive base in industry, as well as to adjust the pH of soils in agriculture. Perhaps surprisingly, it is also used to remove Ca2ϩ ions from hard water containing Ca(HCO3)2. Its role here is to convert HCO3 Ϫ into CO3 2Ϫ by providing OHϪ ions: HCO3 Ϫ (aq) ϩ OHϪ (aq) CO3 2Ϫ (aq) ϩ H2O(l) As the concentration of CO3 2Ϫ ions rises, Ca2ϩ ions precipitate in the reaction Ca2ϩ (aq) ϩ CO3 2Ϫ (aq) CaCO3(s) This reaction removes the Ca2ϩ ions that were present initially and those that were added as lime; overall, the Ca2ϩ ion concentration is reduced. Thinking point: Why is calcium hydrogen carbonate (bicarbonate) more soluble than calcium carbonate? Teeth are generally denser than bone and are protected by a hard enamel coating. Tooth enamel is a hydroxyapatite, Ca5(PO4)3OH. Tooth decay begins when acids attack the enamel: Ca5(PO4)3OH(s) ϩ 4 H3Oϩ (aq) 5 Ca2ϩ (aq) ϩ 3 HPO4 2Ϫ (aq) ϩ 5 H2O(l) The principal agents of tooth decay are the carboxylic acids produced when bacteria act on the remains of food. A more resistant coating forms when the OHϪ ions in the apatite are replaced by FϪ ions. The resulting mineral is called fluorapatite: Ca5(PO4)3OH(s) ϩ FϪ (aq) Ca5(PO4)3F(s) ϩ OHϪ (aq) The addition of fluoride ions to domestic water supplies (in the form of NaF) is now widespread and has resulted in a dramatic decrease in dental cavities. Fluoridated toothpastes, containing either tin(II) fluoride or sodium monofluorophosphate (MFP, Na2FPO3), are also recommended to strengthen tooth enamel. Self-Test 15.7A Explain why beryllium compounds have covalent characteristics. [Answer: The small size and high charge on the beryllium ion make it highly polarizing.] ¡ ¡ ¡ ¡ ¡ ¡ 15.8 COMPOUNDS OF BERYLLIUM, MAGNESIUM, AND CALCIUM 627 Self-Test 15.7B Is the reaction between CaO and SiO2 a redox reaction or a Lewis acid–base reaction? If redox, identify the oxidizing and reducing agents. If Lewis acid–base, identify the acid and the base. Beryllium compounds have a pronounced covalent character, and the structural unit is commonly tetrahedral. The small size of the magnesium cation results in a thermally stable oxide with low solubility in water. Calcium compounds are common in structural materials because the small, highly charged Ca2؉ ion results in rigid structures. GROUP 13/III: THE BORON FAMILY Now we move into the p-block of the periodic table and encounter the complex but fascinating world of the nonmetals. Here, close to the center of the periodic table, we meet strange properties, because the elements are neither so electropositive that they easily lose electrons nor so electronegative that they easily gain them. Group 13/III is the first group of the p block. Its members have an ns2 np1 electron configuration (Table 15.5), and so we expect a maximum oxidation number of ϩ3. The oxidation numbers of B and Al are ϩ3 in almost all their compounds. However, the heavier elements in the group are more likely to keep their s-electrons (the inert-pair effect, Section 1.19); so the oxidation number ϩ1 becomes increasingly important down the group, and thallium(I) compounds are as common as thallium(III) compounds. We shall concentrate on the two most important members of the group, boron and aluminum. 15.9 The Group 13/III Elements Boron forms perhaps the most extraordinary structures of all the elements. It has a high ionization energy and is a metalloid that forms covalent bonds, like its diagonal neighbor silicon. However, because it has only three electrons in its valence shell and has a small atomic radius, it tends to form compounds that have incomplete octets (Section 2.11) or are electron deficient (Section 3.8). These unusual bonding characteristics lead to the remarkable properties that have made boron an essential element of modern technology and, in particular, nanotechnology. Boron is mined as borax and kernite, Na2B4O7иxH2O, with x ϭ 10 and 4, respectively. Large deposits from ancient hot springs are found in volcanic regions, such as the Mojave Desert region of California. In the extraction process, the ore is converted into boron oxide with acid and then reduced with magnesium to an impure brown, amorphous form of boron: B2O3(s) ϩ 3 Mg(s) ⌬ ∫B 2 B(s) ϩ 3 MgO(s) A product of higher purity is obtained by reducing a volatile boron compound, such as BCl3 or BBr3, with hydrogen on a heated filament (tantalum is used for the filament because it has a very high melting point): 2 BBr3(g) ϩ 3 H2(g) ⌬ ∫B 2 B(s) ϩ 6 HBr(g) 628 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS TABLE 15.5 Group 13/III Elements Valence configuration: ns2 np1 Molar mass Melting Boiling Density Z Name Symbol (gиmolϪ1 ) point (°C) point (°C) (gиcmϪ3 ) Normal form* 5 boron B 10.81 2300 3931 2.47 powdery brown metalloid 13 aluminum Al 26.98 660 2467 2.70 silver-white metal 31 gallium Ga 69.72 30 2403 5.91 silver metal 49 indium In 114.82 156 2080 7.29 silver-white metal 81 thallium Tl 204.38 304 1457 11.87 soft metal *Normal form means the state and appearance of the element at 25°C and 1 atm. Because of the expense, boron production remains quite low despite the element’s desirable properties of hardness and low density. Elemental boron exists in a variety of allotropic forms in which each atom strives to find ways to share eight electrons despite being so small and having only three electrons to contribute. It is most commonly found as either a gray-black nonmetallic, high-melting-point solid or a dark brown powder with an icosahedral (20-faced) structure based on clusters of 12 atoms (5). Because of the three-dimensional network formed by these bonds, boron is very hard and is chemically unreactive. When boron fibers are incorporated into plastics, the result is a very tough composite material that is stiffer than steel yet lighter than aluminum; this material is used in aircraft, missiles, and body armor (see Section 19.12). The element is attacked by only the strongest oxidizing agents. Aluminum is the most abundant metallic element in the Earth’s crust and, after oxygen and silicon, the third most abundant element (see Fig. 15.1). However, the aluminum content in most minerals is low, and the commercial source of aluminum, bauxite, is a hydrated, impure oxide, Al2O3иxH2O, where x can range from 1 to 3. Bauxite ore, which is red from the iron oxides that it contains (Fig. 15.23), is processed to obtain alumina, Al2O3, in the Bayer process. In this process, the ore is first treated with aqueous sodium hydroxide, which dissolves the amphoteric alumina as the aluminate ion, Al(OH)4 Ϫ . Carbon dioxide is then bubbled through the solution to remove OHϪ ions as HCO3 Ϫ and to convert some of the aluminate ions into aluminum hydroxide, which precipitates. The aluminum hydroxide is removed and dehydrated to the oxide by heating to 1200°C. Obtaining aluminum metal from the oxide was a challenge to early scientists and engineers. When it was first isolated, aluminum was a rare and expensive metal. During the nineteenth century, it so symbolized modern technology that the Washington Monument was given an expensive aluminum tip. That rarity and expense were transformed by electrochemistry. Aluminum metal is now obtained on a huge scale by the Hall process. In 1886, Charles Hall discovered that, by mixing the mineral cryolite, Na3AlF6, with alumina, he got a mixture that melts at a much more economical temperature, 950°C, instead of the 2050°C of pure alumina. The melt is electrolyzed in a cell that uses graphite (or carbonized petroleum) anodes and a carbonized steel-lined vat that serves as the cathode (Fig. 15.24). The electrolysis half-reactions are Cathode reaction: Al3ϩ (melt) ϩ 3 eϪ Al(l) Anode reaction: 2 O2Ϫ (melt) ϩ C(s, gr) CO2(g) ϩ 4 eϪ Overall reaction: 4 Al3ϩ (melt) ϩ 6 O2Ϫ (melt) ϩ 3 C(s, gr) 4 Al(l) ϩ 3 CO2(g) Note that the carbon electrode is consumed in the reaction. From the reaction stoichiometry, we can calculate that a current of 1 A must flow for 80 h to produce 1 mol Al (27 g of aluminum, about enough for two soft-drink cans). The very high energy consumption can be greatly reduced by recycling, which requires less than 5% of the electricity needed to extract aluminum from bauxite. Although a 12-ounce beverage can contains less than 14 g of aluminum, the energy that we are throwing away when we discard an aluminum can is equivalent to burning the amount of gasoline that would fill half the can. Note also that the production of 1 tonne of aluminum from alumina is accompanied by the release of more than 1 tonne of carbon dioxide into the atmosphere. Aluminum has a low density; it is a strong metal and an excellent electrical conductor. Although it is strongly reducing and therefore easily oxidized, aluminum is resistant to corrosion because its surface is passivated in air by a stable oxide film. The thickness of the oxide layer can be increased by making aluminum the anode of an electrolytic cell; the result is called anodized aluminum. Dyes may be added to the dilute sulfuric acid electrolyte used in the anodizing process to produce surface layers with different colors. Aluminum’s low density, wide availability, and corrosion resistance make it ideal for construction and for the aerospace industry. Aluminum is a soft metal, and so it is usually alloyed with copper and silicon for greater strength. Its lightness and good electrical conductivity have also led to its use for overhead power lines, and its negative ¡ ¡ ¡ 15.9 THE GROUP 13/III ELEMENTS 629 Here, perhaps, is an opportunity for another young chemist like Hall to transform the production of boron as Hall did for aluminum (described later in this section). FIGURE 15.23 The iron oxides in bauxite ore give it a red tint. Napoleon reserved his aluminum plates for his special guests: the rest had to make do with gold. FIGURE 15.24 In the Hall process, aluminum oxide is dissolved in molten cryolite and the mixture is electrolyzed in a cell with carbon anodes and a steel cathode. The molten aluminum flows out of the bottom of the cell. Steel anode Molten cryolite and alumina ϩ Ϫ Carbon anode Molten aluminum 5 B12 electrode potential has led to its use in fuel cells. Perhaps one day your automobile will not only be made of aluminum but fueled by it, too. Boron, at the head of Group 13/III, is best regarded as a nonmetal in most of its chemical properties. It has acidic oxides and forms an interesting and extensive range of binary molecular hydrides. Metallic character increases down the group, and even boron’s immediate neighbor aluminum is a metal. Nonetheless, aluminum is sufficiently far to the right in the periodic table to show a hint of nonmetallic character. Aluminum is amphoteric, reacting both with nonoxidizing acids (such as hydrochloric acid) to form aluminum ions: 2 Al(s) ϩ 6 Hϩ (aq) 2 Al3ϩ (aq) ϩ 3 H2(g) and with hot aqueous alkali to form aluminate ions: 2 Al(s) ϩ 2 OHϪ (aq) ϩ 6 H2O(l) 2 Al(OH)4 Ϫ (aq) ϩ 3 H2(g) Gallium, which is produced as a by-product in the Bayer process, has important uses in the electronics industry. It is a common doping agent for semiconductors and some of its compounds, such as GaAs, are used in light-emitting diodes to convert electricity into light. Thallium, at the bottom of Group 13/III, is a dangerously poisonous heavy metal that has been used as a rat poison. However, concern about its accumulation in the environment has spurred research into alternative pesticides. Boron is a hard metalloid with pronounced nonmetallic properties. Aluminum is a light, strong, amphoteric, reactive metallic element with a surface that becomes passivated when exposed to air. 15.10 Group 13/III Oxides and Halides Boron, a metalloid with largely nonmetallic properties, has acidic oxides. Aluminum, its metallic neighbor, has amphoteric oxides (like its diagonal neighbor in Group 2, beryllium). The oxides of both elements are important in their own right, as sources of the elements, and as the starting point for the manufacture of other compounds. Boric acid, B(OH)3, is a white solid that melts at 171°C. It is toxic to bacteria and many insects as well as humans and has long been used as a mild antiseptic and pesticide. Because the boron atom in B(OH)3 has an incomplete octet, it can act as a Lewis acid and form a bond by accepting a lone pair of electrons from an H2O molecule acting as a Lewis base: (OH)3B ϩ :OH2 (OH)3B∫OH2 The compound so formed is a weak monoprotic acid: B(OH)3OH2(aq) ϩ H2O(l) ¬sR¬ H3Oϩ (aq) ϩ B(OH)4 Ϫ (aq) pKa ϭ 9.14 The major use of boric acid is as the starting material for its anhydride, boron oxide, B2O3. Because it melts (at 450°C) to a liquid that dissolves many metal oxides, boron oxide (often as the acid) is used as a flux, a substance that cleans metals as they are soldered or welded. Boron oxide is also used to make fiberglass and borosilicate glass, a glass with a very low thermal expansion, such as Pyrex (see Section 6.10). Aluminum oxide, Al2O3, is known almost universally as alumina. It exists with a variety of crystal structures, many of which form important ceramic materials (see Section 6.11). Some impure forms of alumina are beautiful, rare, and highly prized (Fig. 15.25). A less dense and more reactive form of the oxide is ␥-alumina. This form absorbs water and is used as the stationary phase in chromatography. ␥-Alumina is produced by heating aluminum hydroxide. It is moderately reactive and is amphoteric, dissolving readily in bases to produce the aluminate ion and in acids to produce the hydrated Al3ϩ ion: Al2O3(s) ϩ 2 OHϪ (aq) ϩ 3 H2O(l) 2 Al(OH)4 Ϫ (aq) Al2O3(s) ϩ 6 H3Oϩ (aq) ϩ 3 H2O(l) 2 Al(H2O)6 3ϩ (aq)¡ ¡ ¡ ¡ ¡ 630 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS An oxidizing acid is an oxoacid in which the anion is an oxidizing agent; examples are HNO3 and HClO3. As described in Section 11.13, the strong polarizing effect of the small, highly charged Al3ϩ ion (a Lewis acid) on the water molecules around it (Lewis bases) gives the Al(H2O)6 3ϩ ion acidic properties: Al(H2O)6 3ϩ (aq) ϩ H2O(l) ¬sR¬ H3Oϩ (aq) ϩ Al(OH)(H2O)5 2ϩ (aq) One of the most important aluminum salts prepared by the action of an acid on alumina is aluminum sulfate, Al2(SO4)3: Al2O3(s) ϩ 3 H2SO4(aq) Al2(SO4)3(aq) ϩ 3 H2O(l) Aluminum sulfate is called papermaker’s alum and is used in the paper industry to coagulate cellulose fibers into a hard, nonabsorbent surface. True alums (from which aluminum takes its name) are mixed sulfates of formula Mϩ MЈ3ϩ (SO4)2и12H2O. They include potassium alum, KAl(SO4)2и12H2O (which is used in water and sewage treatment), and ammonium alum, NH4Al(SO4)2и12H2O (which is used for pickling cucumbers and as the Brønsted acid in baking powders). Sodium aluminate, NaAl(OH)4, is used along with aluminum sulfate in water purification. When mixed with aluminate ions, the acidic hydrated Al3ϩ cation from the aluminum sulfate produces aluminum hydroxide: Al3ϩ (aq) ϩ 3 Al(OH)4 Ϫ (aq) 4 Al(OH)3(s) The aluminum hydroxide is formed as a fluffy, gelatinous network that entraps impurities as it settles, and this precipitate can be removed by filtration (Fig. 15.26). The boron halides are useful industrial catalysts that are made either by direct reaction of the elements at a high temperature or from boron oxide. The most important is boron trifluoride, BF3, which is produced by the reaction between boron oxide, calcium fluoride, and sulfuric acid: B2O3(s) ϩ 3 CaF2(s) ϩ 3 H2SO4(l) ⌬ ∫∫B 2 BF3(g) ϩ 3 CaSO4(s) ϩ 3 H2O(l) Boron trichloride, BCl3, which is also widely used as a catalyst, is produced commercially by the action of chlorine gas on the oxide in the presence of carbon: B2O3(s) ϩ 3 C(s) ϩ 3 Cl2(g) ∫∫∫B 2 BCl3(g) ϩ 3 CO(g) The B atom has an incomplete octet in all its trihalides. The compounds consist of trigonal planar molecules with an empty 2p-orbital perpendicular to the molecular plane. The empty orbital allows the molecules to act as Lewis acids, which accounts for the catalytic action of BF3 and BCl3. ¡ ¡ 15.10 GROUP 13/III OXIDES AND HALIDES 631 (a) (b) (c) FIGURE 15.25 Some of the impure forms of ␣-alumina are prized as gems. (a) Ruby is alumina with Cr3ϩ in place of some Al3ϩ ions. (b) Sapphire is alumina with Fe3ϩ and Ti4ϩ impurities. (c) Topaz is alumina with Fe3ϩ impurities. FIGURE 15.26 Aluminum hydroxide, Al(OH)3, forms as a white, fluffy precipitate. The fluffy form of the solid captures impurities and is used in the purification of water. 500°C Aluminum chloride, AlCl3, another major industrial catalyst, is made by the action of chlorine on aluminum or on alumina in the presence of carbon: 2 Al(s) ϩ 3 Cl2(g) 2 AlCl3(s) Al2O3(s) ϩ 3 C(s) ϩ 3 Cl2(g) 2 AlCl3(s) ϩ 3 CO(g) Aluminum chloride is an ionic solid in which each Al3ϩ ion is coordinated to six ClϪ ions. However, it sublimes at 192°C to a vapor of Al2Cl6 molecules (6). In this molecule, the Al atom of one AlCl3 planar fragment acts as a Lewis acid and accepts an electron pair from a Cl atom of the other AlCl3 fragment, which is acting as a Lewis base. Self-Test 15.8A Explain how Al3ϩ forms acidic solutions. [Answer: In water Al3ϩ forms Al(H2O)6 3ϩ ; the highly charged Al3ϩ ion polarizes the water molecules, enabling one of them to donate a proton.] Self-Test 15.8B The compound B(OH)3 does not itself lose any protons in water. Why, then, is it called boric acid? Boron oxide is an acid anhydride. Aluminum shows some nonmetallic character in that its oxide is amphoteric. Boron and aluminum halides have incomplete octets and act as Lewis acids. 15.11 Boranes and Borohydrides Boron forms a remarkable series of binary compounds with hydrogen—the boranes. These compounds include diborane, B2H6, and more complex compounds such as decaborane, B10H14. Anionic versions of these compounds, the borohydrides, are known; the most important is BH4 Ϫ as sodium borohydride, NaBH4. Sodium borohydride is a white crystalline solid produced from the reaction between sodium hydride and boron trichloride dissolved in a nonaqueous solvent: 4 NaH ϩ BCl3 NaBH4 ϩ 3 NaCl Sodium borohydride is a very useful reducing agent. At pH ϭ 14 (strongly alkaline conditions), the potential of the half-reaction H2BO3 Ϫ (aq) ϩ 5 H2O(l) ϩ 8eϪ BH4 Ϫ (aq) ϩ 8 OHϪ (aq) is Ϫ1.24 V. Because this potential is well below that of the Ni2ϩ /Ni couple (Ϫ0.23 V), borohydride ions can reduce Ni2ϩ ions to metallic nickel. This reduction is the basis of the “chemical plating” of nickel. The advantage of this chemical plating over electroplating is that the item being plated does not have to be an electrical conductor. The boranes are an extensive series of binary compounds of boron and hydrogen, somewhat analogous to the hydrocarbons. The starting point for borane production is the reaction (in an organic solvent) of sodium borohydride with boron trifluoride: 4 BF3 ϩ 3 BH4 Ϫ 3 BF4 Ϫ ϩ 2 B2H6 The product B2H6 is diborane (7), a colorless gas that bursts into flame in air. On contact with water, it immediately reduces the hydrogen in the water: B2H6(g) ϩ 6 H2O(l) 2 B(OH)3(aq) ϩ 6 H2(g) When diborane is heated to a high temperature, it decomposes into hydrogen and pure boron: B2H6(g) ⌬ ∫∫B 2 B(s) ϩ 3 H2(g) This sequence of reactions is a useful route to the pure element, but more complex boranes form when the heating is less severe. When diborane is heated to 100°C, for instance, it forms decaborane, B10H14, a solid that melts at 100°C. Decaborane is stable in air, is oxidized by water only slowly, and is an example of the general rule that heavier boranes are less flammable than boranes of low molar mass. ¡ ¡ ¡ ¡ ¡ ¡ 632 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 6 Aluminum chloride dimer, Al2Cl6 7 Diborane, B2H6 The boranes are electron-deficient compounds (Section 3.8): we cannot write valid Lewis structures for them, because too few electrons are available. For instance, there are 8 atoms in diborane, so we need at least 7 bonds; however, there are only 12 valence electrons, and so we can form at most 6 electron-pair bonds. Molecular orbital theory readily overcomes this difficulty: the six electron pairs are regarded as delocalized over the entire molecule and their bonding power is shared by several atoms. In diborane, for instance, a single electron pair is delocalized over a B∫H∫B unit. It binds all three atoms together with bond order of for each of the B∫H bridging bonds. The molecule has two such bridging three-center bonds (8). Thinking point: Why are three-center bonds characteristic of boron and not other elements? Self-Test 15.9A Compare the reactions for the formation of BF3 and BCl3. Which reaction is a redox reaction? [Answer: The formation of BCl3] Self-Test 15.9B What is the oxidation number of boron in (a) NaBH4; (b) H2BO3 Ϫ ? The boranes are an extensive series of highly reactive electron-deficient binary compounds of boron and hydrogen. Borohydrides are useful reducing agents. GROUP 14/IV: THE CARBON FAMILY Carbon is central to life and natural intelligence. Silicon and germanium are central to electronic technology and artificial intelligence (Fig. 15.27). The unique properties of Group 14/IV elements make both types of intelligence possible. The half-filled valence shell of these elements gives them special properties that straddle the line between metals and nonmetals. Carbon, at the head of the group, forms so many compounds that it has its own branch of chemistry, organic chemistry (Chapters 18 and 19). 15.12 The Group 14/IV Elements The valence electron configuration is ns2 np2 for all members of the group. All four electrons are approximately equally available for bonding in the lighter elements, and carbon and silicon are characterized by their ability to form four covalent bonds. However, as in Group 13/III, the heavier elements display the inert-pair effect. On descending the group, the energy separation between the s- and p-orbitals increases and the s-electrons become progressively less available for bonding; in fact, the most common oxidation number for lead is ϩ2. The elements show increasing metallic character down the group (Table 15.6). Carbon has definite nonmetallic properties: it forms covalent compounds with nonmetals and ionic compounds with metals. The oxides of carbon and silicon are acidic. 1 2 15.12 THE GROUP 14/IV ELEMENTS 633 8 A three-center bond FIGURE 15.27 The elements of Group 14/IV. Back row, from left to right: silicon; tin. Front row: carbon (graphite); germanium; lead. Germanium is a typical metalloid in that it exhibits metallic or nonmetallic properties according to the other element present in the compound. Tin and, even more so, lead have definite metallic properties. However, even though tin is classified as a metal, it is not far from the metalloids in the periodic table, and it does have some amphoteric properties. For example, tin reacts with both hot concentrated hydrochloric acid and hot alkali: Sn(s) ϩ 2 H3Oϩ (aq) Sn2ϩ (aq) ϩ H2(g) ϩ 2 H2O(l) Sn(s) ϩ 2 OHϪ (aq) ϩ 2 H2O(l) Sn(OH)4 2Ϫ (aq) ϩ H2(g) Because carbon stands at the head of its group, we expect it to differ from the other members of the group. Some of the differences between carbon and silicon stem from the smaller atomic radius of carbon, which explains the wide occurrence of C¢C and C¢O double bonds relative to the rarity of Si¢Si and Si¢O double bonds. Silicon atoms are too large for the side-by-side overlap of p-orbitals necessary for ␲-bonds to form between them except in specially contrived arrangements in which other bridging groups of atoms press the two Si atoms together. Carbon dioxide, which consists of discrete O¢C¢O molecules, is a gas that we exhale. Silicon dioxide (silica), which consists of networks of ∫O∫Si∫O∫ groups, is a mineral that we stand on. Silicon compounds can also act as Lewis acids, whereas carbon compounds typically cannot. Because a silicon atom is bigger than a carbon atom and can expand its valence shell by using its d-orbitals, it can accommodate the lone pair of an attacking Lewis base. A carbon atom is smaller and has no available d-orbitals; so in general it cannot act as a Lewis acid. An exception to this behavior is when the carbon atom has multiple bonds, because then a ␲-bond can give way to the formation of a ␴-bond, as in the reaction between CO2 and O2Ϫ to form CO3 2Ϫ : Solid carbon exists as graphite, diamond, and other phases such as the fullerenes, which have structures related to that of graphite. Graphite is the thermodynamically most stable of these allotropes under ordinary conditions. In Chapter 6, we saw how the properties of the different allotropes of carbon are related to differences in bonding. Here we give an overview of the various allotropes and their properties. Coke is an impure form of carbon obtained from the solid residue remaining after the destructive distillation of coal; because it is inexpensive, it is used extensively in steel production. Soot and carbon black contain very small crystals of graphite and other forms of carbon. Carbon black, which is produced by heating gaseous hydrocarbons to nearly 1000°C in the absence of air, is used for reinforcing rubber, for pigments, O O C O C OO 2Ϫ O 2Ϫ ¡ ¡ 634 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS TABLE 15.6 Group 14/IV Elements Valence configuration: ns2 np2 Molar mass Melting Boiling Density Z Name Symbol (gиmolϪ1 ) point (°C) point (°C) (gиcmϪ3 ) Normal form* 6 carbon C 12.01 3370s† — 1.9–2.3 black nonmetal (graphite) 3.2–3.5 transparent nonmetal (diamond) orange nonmetal (fullerite) 14 silicon Si 28.09 1410 2620 2.33 gray metalloid 32 germanium Ge 72.61 937 2830 5.32 gray-white metalloid 50 tin Sn 118.71 232 2720 7.29 white lustrous metal 82 lead Pb 207.2 328 1760 11.34 blue-white lustrous metal *Normal form means the state and appearance of the element at 25°C and 1 atm. † The symbol s denotes that the element sublimes. and for printing inks, such as the ink on this page. Activated carbon, which is also called activated charcoal, consists of granules of microcrystalline carbon. It is produced by heating waste organic matter in the absence of air and then processing it to increase the porosity. The very high specific surface area (as much as about 2000 m2 иgϪ1 ) of the porous carbon enables it to remove organic impurities from liquids and gases by adsorption. It is used in air purifiers, gas masks, and aquarium water filters. On a larger scale, activated carbon is used in water purification plants to remove organic compounds from drinking water. Graphite consists of planar graphene sheets of sp2 hybridized carbon atoms in a hexagonal network (recall Fig. 6.9). The graphite found in nature is the result of changes in ancient organic remains. Pure graphite is produced in industry by passing a heavy electric current through rods of coke. In diamond, each carbon atom is sp3 hybridized and linked tetrahedrally to its four neighbors, with all electrons in C∫C ␴-bonds (recall Fig. 6.10). Chemists were greatly surprised when soccer-ball-shaped carbon molecules were first identified in 1985, particularly because they might be even more abundant than graphite and diamond! The C60 molecule (9) is named buckminsterfullerene after the American architect R. Buckminster Fuller, whose geodesic domes it resembles. Within 2 years, scientists had succeeded in making crystals of buckminsterfullerene; the solid samples are called fullerite (Fig. 15.28). The discovery of this molecule and others with similar structures, such as C70, opened up the prospect of a whole new field of chemistry. For instance, the interior of a C60 molecule is big enough to hold an atom of another element, and chemists are now busily preparing a whole new periodic table of these shrink-wrapped atoms. The fullerenes are members of the family of molecules resembling (and including) buckminsterfullerene. They are formed in smoky flames and by red giants (stars with low surface temperatures and large diameters), and so the universe might contain huge numbers of them. Graphite and diamond are network solids that are insoluble in all liquid solvents except some liquid metals. However, the fullerenes, which are molecular, can be dissolved by suitable solvents (such as benzene); buckminsterfullerene itself forms a red-brown solution. Fullerite currently has few uses, but some of the compounds of the fullerenes have great promise. For example, K3C60 is a superconductor below 18 K, and other fullerene compounds appear to be active against cancer and diseases such as AIDS. Carbon nanotubes consist of concentric tubes with walls like graphene sheets rolled into cylinders. These tiny structures form strong, conducting fibers with a large surface area. As a consequence, they have unusually interesting and promising properties that have become a major thrust of nanotechnology research. Section 6.19 describes some of the applications of nanomaterials produced when carbon and silicon are coaxed into desired configurations and Box 15.2 describes materials that result when molecules of carbon and silicon compounds assemble themselves into organized structures. Silicon is the second most abundant element in the Earth’s crust. It occurs widely in rocks as silicates, compounds containing the silicate ion, SiO3 2Ϫ , and as the silica, SiO2, of sand (Section 6.7). Pure silicon is obtained from quartzite, a granular form of quartz (another solid phase of SiO2), by reduction with high-purity carbon in an electric arc furnace: SiO2(s) ϩ 2 C(s) ⌬ ∫∫B Si(s) ϩ 2 CO(g) The crude product is exposed to chlorine to form silicon tetrachloride, which is then distilled and reduced with hydrogen to a purer form of the element: SiCl4(l) ϩ 2 H2(g) Si(s) ϩ 4 HCl(g) Further purification is necessary before silicon can be used in semiconductors. In one process, a large single crystal is grown by pulling a solid rod of the element slowly from the melt. The silicon is then purified by zone refining, in which a hot, molten zone is ¡ 15.12 THE GROUP 14/IV ELEMENTS 635 9 Buckminsterfullerene, C60 100 ␮m FIGURE 15.28 These small crystals are fullerite, in which buckminsterfullerene molecules are packed together in a close-packed lattice. 636 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS A major concern of scientists working with nanomaterials is how to coax molecules into organizing themselves into the desired nanoscale arrangements. Many biological processes operate at the nanoscale level. Proteins, for example, fold up into the shape that optimizes their function (see Section 19.13), cell membranes form spontaneously when certain molecules called lipids encounter water (see Box 9.1), and the DNA molecules of our genes replicate themselves every time a cell divides. Although the expression has a variety of definitions, the common meaning of self-assembly of molecules is the spontaneous formation of organized structures from individual parts. Self-assembly can be static or dynamic. In static self-assembly, the structure formed is stable and the process does not readily reverse. Two examples are the folding of polypeptide chains into a protein molecule and the formation of the double helix of DNA. Dynamic self-assembly involves interactions that dissipate energy and can easily be reversed. Two examples are oscillating chemical reactions and convection patterns. On the macroscopic scale, the coordinated motion of a school of fish or a flock of migrating birds is regarded as an example of dynamic selfassembly. However, the most promising area of self-assembly is in the intermediate realm between molecular and macroscopic, where it may become possible to design nanoscale sensors and machines to carry out specific tasks. In general, we can take advantage of self-assembly only where it already exists in nature. However, designing materials that can assemble themselves is a strategy that is beginning to result in materials that can respond to stimuli and act in seemingly intelligent ways. You might be using a self-assembled material the next time you use in-line skates. One brand of these skates contains a “smart gel” that is a liquid at normal temperatures but assembles itself into a firm, rubbery gel when exposed to body temperature. The gel fills the space between the lining of the skate boot and the sides and, once the skate has been secured, it sets to conform to the exact shape of the foot. Such a gel generally consists of an aqueous suspension of organic molecules with long chains containing different regions, some of which have strong intermolecular forces and some of which have weak intermolecular forces. The temperature determines how the chains are coiled. At low temperatures, the regions with strong intermolecular forces are turned inward, and so the molecules remain in liquid solution. However, at higher temperatures, FRONTIERS OF CHEMISTRY: SELF-ASSEMBLING MATERIALSBOX 15.2 Nonpolar medium Water(b) (c) (d) –CO2 − –NH3 + (a) These four types of forces are responsible for the adaptive behavior of smart gels. The different forces come into play when the network of polymer chains composing a gel is disturbed. (a) Charged ionic regions can attract or repel each other. (b) Nonpolar hydrophobic regions exclude water. (c) Hydrogen bonds may form from one chain to another. (d) Dipole–dipole interactions can attract or repel chains. In the Belousov–Zhabotinskii reaction, beautiful regular patterns form spontaneously as the result of the oscillating concentrations of reactants and products due to competing reactions. those regions are turned outward, where they can attract other chains to form a flexible, but firm, network. Another type of gel expands and contracts as its structure changes in response to electrical signals and is being investigated for use in artificial limbs that would respond and feel like real ones. One material being studied for use in artificial muscle contains a mixture of polymers, silicone oil (a polymer with a Ϫ(∫O∫Si∫O∫Si∫)n∫ backbone and hydrocarbon side chains), and salts. When exposed to an electric field, the molecules of the soft gel rearrange themselves so that the material contracts and stiffens. If struck, the stiffened material can break but, on softening, the gel is reformed. The transition between gel and solid state is therefore reversible. HOW MIGHT YOU CONTRIBUTE? The properties of self-assembled materials need to be studied and categorized. For example, how do molecules recognize one another in a mixture? In addition, strategies to promote selfassembly need to be designed. Simple two-dimensional assemblies have been created, and these techniques need to be expanded to three dimensions. Applications are emerging in nanotechnology, in the fields of microelectronics and robotics, and in medicine, where biosensor arrays have shown high selectivity for individual toxins and bioagents. Related Exercise: 15.121 For Further Reading: R. Dagani, “Intelligent gels,” Chemical and Engineering News, June 9, 1997, pp. 26–27. R. F. Service, “How far can we push chemical self-assembly?” Science, vol. 309, 2005, p. 95. G. Whitesides and B. Grzybowski, “Self-assembly at all scales,” Science, vol. 295, March 29, 2002, pp. 2418–2421. ? dragged from one end of a cylindrical sample to the other, collecting impurities as it goes (Fig. 15.29). The result is “ultrapure” silicon, which has fewer than one impurity atom per billion Si atoms. An alternative technique is the decomposition of silane, SiH4, by an electric discharge. This method produces an amorphous form of silicon with a significant hydrogen content. Amorphous silicon is used in photovoltaic devices, which produce electricity from sunlight. Germanium was not known until 1886 and has the distinction of having been predicted by Mendeleev before it was discovered (see Box 1.2). It is recovered from the flue dust of industrial plants processing zinc ores (in which it occurs as an impurity). It is used mainly—and increasingly—in the semiconductor industry to create very fast integrated circuits. Tin and lead are obtained very easily from their ores and have been known since antiquity. Tin occurs chiefly as the mineral cassiterite, SnO2, and is obtained from it by reduction with carbon at 1200°C: SnO2(s) ϩ C(s) ∫∫∫B Sn(l) ϩ CO2(g) The principal lead ore is galena, PbS. It is roasted in air, which converts it into PbO, and this oxide is then reduced with coke: 2 PbS(s) ϩ 3 O2(g) ⌬ ∫∫B 2 PbO(s) ϩ 2 SO2(g) PbO(s) ϩ C(s) Pb(s) ϩ CO(g) Tin is expensive and not very strong, but it is resistant to corrosion. Its main use is in tinplating, which accounts for about 40% of its consumption. Tin is also used in alloys such as bronze (mostly copper, with about 2Ϫ10% tin) and pewter (about 91% or more tin, with antimony, copper, and for some applications lead or bismuth). Lead’s durability (its chemical inertness) and malleability make it useful in the construction industry. The inertness of lead under normal conditions can be traced to the passivation of its surface by oxides, chlorides, and sulfates (see Section 13.14). Passivated lead containers can be used for transporting hot concentrated sulfuric acid but not nitric acid, because lead nitrate is soluble. Another important property of lead is its high density, which makes it useful as a radiation shield because its numerous electrons absorb high-energy radiation. Lead was once commonly used in leaded gasoline (as tetraethyl lead, Pb(CH2CH3)4), but lead is a toxic heavy metal and that usage has declined as concern for the amount of lead in the environment has increased. The main use of lead today is for the electrodes of rechargeable storage batteries (see Section 13.15). Metallic character increases significantly down Group 14/IV. Carbon is the only member of Group 14/IV that commonly forms multiple bonds with itself; singly bonded silicon atoms can act as Lewis acids because a silicon atom can expand its valence shell. Carbon has an important series of allotropes: diamond, graphite, and the fullerenes. 15.13 Oxides of Carbon and Silicon We have already met carbon dioxide, CO2, many times throughout this book. It is formed when organic matter burns in a plentiful supply of air and during animal respiration. It is normally present in the atmosphere; but there is widespread and wellfounded concern that an increase in atmospheric carbon dioxide due to the combustion of fossil fuels is contributing to global warming (see Box 15.1). Carbon dioxide is the acid anhydride of carbonic acid, H2CO3, which forms when the gas dissolves in water. However, not all the dissolved molecules react to form the acid, and a solution of carbon dioxide in water is an equilibrium mixture of CO2, H2CO3, HCO3 Ϫ , and a very small amount of CO3 2Ϫ . Carbonated beverages are made by using high partial pressures of CO2 to produce high concentrations of carbon dioxide in water. When the partial pressure of the CO2 is reduced by removing a bottle cap or the seal, the equilibrium H2CO3(aq) #4 CO2(g) ϩ H2O(l) shifts from H2CO3 toward CO2 and the liquid effervesces. ¡ 15.13 OXIDES OF CARBON AND SILICON 637 1200°C Molten zone sweeps up impurities Molten zone that has collected impurities Impure material Pure material Electric heater FIGURE 15.29 In the technique of zone refining, a molten zone is passed repeatedly from one end of the solid sample to the other. The impurities collect in the zone and move along the solid with the heater, leaving a pure substance behind. Carbon monoxide, CO, is produced when carbon or organic compounds burn in a limited supply of air, as happens in cigarettes and badly tuned automobile engines. It is produced commercially as a component of synthesis gas by the re-forming reaction (Section 15.3). Carbon monoxide is the formal anhydride of formic acid, HCOOH, and the gas can be produced in the laboratory by the dehydration of formic acid with hot, concentrated sulfuric acid: HCOOH(l) ∫∫∫∫∫∫B CO(g) ϩ H2O(l) Although the reverse of this reaction cannot be carried out directly, carbon monoxide does react with hydroxide ions in hot alkali to produce formate ions: CO(g) ϩ OHϪ (aq) HCO2 Ϫ (aq) Carbon monoxide is a colorless, odorless, flammable, almost insoluble, very toxic gas that condenses to a colorless liquid at Ϫ90°C. It is not very reactive, largely because its bond enthalpy (1074 kJиmolϪ1 ) is higher than that of any other molecule. However, it is a Lewis base, and the lone pair on the carbon atom forms covalent bonds with d-block atoms and ions. Carbon monoxide is also a Lewis acid, because its empty antibonding ␲-orbitals can accept electron density from a metal (Fig. 15.30). This dual character makes carbon monoxide very useful for forming complexes, and numerous metal carbonyls are known (see Section 16.3). Complex formation is also responsible for carbon monoxide’s toxicity: it attaches more strongly than oxygen to the iron in hemoglobin and prevents it from accepting oxygen from the air in the lungs. As a result, the victim suffocates. Because it can be further oxidized, carbon monoxide is a reducing agent. It is used in the production of a number of metals, most notably iron in blast furnaces (Section 16.3): Fe2O3(s) ϩ 3 CO(g) ⌬ ∫B 2 Fe(l) ϩ 3 CO2(g) Silica, SiO2, is a hard, rigid network solid that is insoluble in water. It occurs naturally as quartz and as sand, which consists of small fragments of quartz, usually colored golden brown by iron oxide impurities. Some precious and semiprecious stones are impure silica (Fig. 15.31). Flint is silica colored black by carbon impurities. The structures and uses of some of the silicates are described in Section 6.7. Metasilicic acid, H2SiO3, and orthosilicic acid, H4SiO4, are weak acids. However, when a solution of sodium orthosilicate is acidified, instead of H4SiO4, a gelatinous precipitate of silica is produced: 4 H3Oϩ (aq) ϩ SiO4 4Ϫ (aq) ϩ x H2O(l) SiO2(s)иxH2O(gel) ϩ 6 H2O(l) After it is washed, dried, and granulated, this silica gel has a very high specific surface area (about 700 m2 иgϪ1 ) and is useful as a drying agent, a support for catalysts, a packing for chromatography columns, and a thermal insulator. ¡ ¡ 638 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 150°C, H2SO4 FIGURE 15.30 Carbon monoxide can bind to a d-metal atom in two ways: (a) by using the lone pair on the C atom to form a ␴-bond or (b) by using one of its empty antibonding ␲-orbitals to accept electrons donated from a d-orbital on the metal atom. C O (a) (b) FIGURE 15.31 Some impure forms of silica that are semiprecious stones: amethyst (left), in which the color is due to Fe3ϩ impurities; agate (center); and onyx (right). Self-Test 15.10A What is (a) the oxidation number and (b) the formal charge of carbon in CO (use the Lewis structure :CΩO:)? [Answer: (a) ϩ2; (b) Ϫ1.] Self-Test 15.10B What type of reaction is the reaction of carbon monoxide with hydroxide ion? Carbon has two important oxides: carbon dioxide and carbon monoxide. The former is the acid anhydride of carbonic acid, the parent acid of the hydrogen carbonates and the carbonates. Silica is a hard network material. The silicic acids are weak acids. 15.14 Other Important Group 14/IV Compounds Carbon is the only Group 14/IV element that forms both monatomic and polyatomic anions. There are three classes of carbides: saline carbides (saltlike carbides), covalent carbides, and interstitial carbides. Covalent and interstitial carbides, which are important industrial materials, were discussed in Section 6.9. The saline carbides are formed most commonly from the metals of Groups 1 and 2, aluminum, and a few other metals. The s-block metals form saline carbides when their oxides are heated with carbon. The anions present in saline carbides are either C2 2Ϫ or C4Ϫ . All the C4Ϫ carbides, which are called methides, produce methane and the corresponding hydroxide in water: Al4C3(s) ϩ 12 H2O(l) 4 Al(OH)3(s) ϩ 3 CH4(g) This reaction shows that the methide ion is a very strong Brønsted base. The species C2 2Ϫ is the acetylide ion, and the carbides that contain it are called acetylides. The acetylide ion is also a strong Brønsted base, and acetylides react with water to produce ethyne (acetylene) and the corresponding hydroxide. Calcium carbide, CaC2, is the most common saline carbide. It was once used in miners’ lanterns, in which water from a reservoir was allowed to drip slowly on to chunks of calcium carbide. The acetylene produced was then burned for the light it created. All Group 14/IV elements form liquid molecular tetrachlorides. The least stable is PbCl4, which decomposes to solid PbCl2 when it is warmed to about 50°C. Carbon tetrachloride, CCl4 (tetrachloromethane), was widely used as an industrial solvent; however, now that it is known to be carcinogenic, it is used primarily as the starting point for the manufacture of chlorofluorocarbons. Carbon tetrachloride is formed by the action of chlorine on methane: CH4(g) ϩ 4 Cl2(g) CCl4(g, l when cooled) ϩ 4 HCl(g) Silicon reacts directly with chlorine to form silicon tetrachloride, SiCl4 (this reaction was introduced in Section 15.12, as one step in the purification of silicon). This compound differs strikingly from CCl4 in that it reacts readily with water as a Lewis acid, accepting a lone pair of electrons from H2O: SiCl4(l) ϩ 2 H2O(l) SiO2(s) ϩ 4 HCl(aq) The cyanide ion, CNϪ , is the conjugate base of hydrogen cyanide, HCN. This acid is made by heating ammonia, methane, and air in the presence of a platinum catalyst: 2 CH4(g) ϩ 2 NH3(g) ϩ 3 O2(g) ∫∫∫∫∫B 2 HCN(g) ϩ 6 H2O(g) Cyanides are strong Lewis bases that form a range of complexes with d-block metal ions. They are also famous as poisons. When they are ingested, they combine with certain protein molecules—the cytochromes—involved in the transfer of electrons and the supply of energy in cells, and the victim dies. Because carbon bonds so readily with itself, there are huge numbers of hydrocarbons (see Chapter 18). Silicon forms a much smaller number of compounds with hydrogen, called the silanes. The simplest silane is silane itself, SiH4, the analog of methane. Silane is formed by the action of lithium aluminum hydride on silicon halides in ether: SiCl4 ϩ LiAlH4 SiH4 ϩ LiCl ϩ AlCl3¡ ¡ ¡ ¢ ¡ 15.14 OTHER IMPORTANT GROUP 14/IV COMPOUNDS 639 1100°C, Pt Silane is much more reactive than methane and bursts into flame on contact with air. Although it survives in pure water, it forms SiO2 when a trace of alkali is present: SiH4(g) ϩ 2 H2O(l) SiO2(s) ϩ 4 H2(g) The more complicated silanes, such as SiH3ßSiH2ßSiH3, the analog of propane, decompose on standing. Thinking point: Is the existence of alien life-forms based on silicon plausible? Self-Test 15.11A Both carbide ions, C2 2Ϫ and C4Ϫ , react as bases with water. Predict which carbide ion is the stronger base. Explain your answer. [Answer: The C4Ϫ ion, because it has a higher negative charge.] Self-Test 15.11B Explain the fact that SiH4 reacts with water containing OHϪ ions but CH4 does not. Carbon forms ionic carbides with the metals of Groups 1 and 2. Silicon compounds are more reactive than carbon compounds. They can act as Lewis acids. GROUP 15/V: THE NITROGEN FAMILY Atomsof theGroup15/Velementshavethevalenceelectronconfigurationns2 np3 (Table15.7). The chemical and physical properties of the elements vary sharply in this group, from the almost unreactive gas nitrogen, through the soft nonmetal phosphorus, which is so reactive that it ignites in air, to the important semiconducting materials arsenic and antimony and the largely metallic bismuth (Fig. 15.32). The range of oxidation states for Group 15/V elements is from Ϫ3 to ϩ5, but only nitrogen and phosphorus are found in each oxidation state. Metallic character increases down the group, but the only element considered to be metallic is bismuth, at the bottom of Group 15/V. Arsenic and antimony are metalloids. ¡ OH- 640 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS TABLE 15.7 The Group 15/V Elements Valence configuration: ns2 np3 Molar mass Melting Boiling Density Z Name Symbol (gиmolϪ1 ) point (°C) point (°C) (gиcmϪ3 ) Normal form* 7 nitrogen N 14.01 Ϫ210 Ϫ196 1.04† colorless gas 15 phosphorus P 30.97 44 280 1.82 white or red nonmetal 33 arsenic As 74.92 613s‡ — 5.78 gray metalloid 51 antimony Sb 121.76 631 1750 6.69 blue-white lustrous metalloid 83 bismuth Bi 208.98 271 1650 8.90 white-pink metal *Normal form means the appearance and state of the element at 25°C and 1 atm. † For the liquid at its boiling point. ‡ The letter s denotes that the element sublimes. FIGURE 15.32 The elements of Group 15/V. Back row, from left to right: liquid nitrogen, red phosphorus, arsenic. Front row: antimony and bismuth. Lab Video 15.32 15.15 The Group 15/V Elements Nitrogen is rare in the Earth’s crust, but elemental nitrogen is the principal component of our atmosphere (76% by mass). Pure nitrogen gas is obtained by the fractional distillation of liquid air. Air is cooled to below Ϫ196°C by repeated expansion and compression in a refrigerator like that described in Section 4.13. The liquid mixture is then warmed, and the nitrogen (b.p. Ϫ196°C) boils off while most of the argon (b.p. Ϫ186°C) and oxygen (b.p. Ϫ183°C) remain liquid. Nitrogen gas produced industrially is used primarily as a raw material for the synthesis of ammonia in the Haber process. Plants need nitrogen to grow. However, they cannot use N2 directly, because the strength of the NΩN bond (944 kJиmolϪ1 ) makes nitrogen gas almost as inert as the noble gases. To be available for organisms, nitrogen must first be “fixed,” or combined with other elements into more useful compounds. Once fixed, nitrogen can be converted into compounds for use as medicines, fertilizers, explosives, and plastics. Lightning converts some nitrogen into its oxides, which dissolve in rain and are then washed into the soil. Some bacteria also fix nitrogen in nodules on the roots of clover, beans, peas, alfalfa, and other legumes (Fig. 15.33). An intensely active field of research is the search for catalysts that can mimic these bacteria and fix nitrogen at ordinary temperatures. At present, the Haber synthesis of ammonia is the main industrial route for fixing nitrogen, but it requires costly high pressures (see Section 10.10). Like other elements at the head of a group, nitrogen differs in many ways from its congeners. For example, nitrogen is highly electronegative (␹ ϭ 3.0, about the same as for chlorine). Because of its high electronegativity, nitrogen is the only element in Group 15/V that forms hydrides capable of hydrogen bonding. Because its atoms are small, nitrogen can form multiple bonds with other Period 2 atoms by using its p-orbitals. As we shall see, its small size and the unavailability of d-orbitals account for many of the differences between the chemical and physical properties of nitrogen and those of its congeners. Another important chemical property of nitrogen is its wide range of oxidation numbers: compounds are known for each whole-number oxidation state from Ϫ3 (in NH3) to ϩ5 (in nitric acid and the nitrates). Nitrogen also occurs with fractional oxidation numbers, such as in the azide ion, N3 Ϫ . The properties of phosphorus, in Period 3, differ significantly from those of nitrogen. The atomic radius of phosphorus is nearly 50% larger than that of nitrogen, and so two phosphorus atoms are too big to approach each other closely enough for their 3p-orbitals to overlap and form ␲-bonds. Thus, whereas nitrogen can form multiply bonded structures such as N2O3 (10), phosphorus forms additional single bonds, as in P4O6 (11). The size of its atoms and the availability of 3d-orbitals means that phosphorus can form as many as six bonds (as in PCl6 Ϫ ), whereas nitrogen can form only four (see Section 2.10). Phosphorus is obtained from the apatites, which are mineral forms of calcium phosphate, Ca3(PO4)2. The rocks are heated in an electric furnace with carbon and sand: 2 Ca3(PO4)2(s) ϩ 6 SiO2(s) ϩ 10 C(s) P4(g) ϩ 6 CaSiO3(l) ϩ 10 CO(g) The phosphorus vapor condenses as white phosphorus, a soft, white, poisonous molecular solid consisting of tetrahedral P4 molecules (12). This allotrope is highly reactive, in part because of the strain associated with the 60° angles between the bonds. It is very dangerous to handle because it bursts into flame on contact with air and can cause severe burns. White phosphorus is normally stored under water. It changes into red phosphorus when heated in the absence of air. Red phosphorus is less reactive than the white allotrope; however, it can be ignited by friction and is used in the striking surfaces of matchbooks. The friction created by rubbing a match across the surface ignites the phosphorus, which, in turn, lights the highly flammable material in the match head. Red phosphorus is thought to consist of chains of linked P4 tetrahedra. Vapor rising from white phosphorus in moist air glows with a yellow-green light. The oxides produced by the reaction of phosphorus with the oxygen in air are formed in electronically excited states, and light is given off as electrons fall back into the ground state in the process called chemiluminescence (Section 6.15). ¡ ¢ -1 3 15.15 THE GROUP 15/V ELEMENTS 641 FIGURE 15.33 The bacteria that inhabit these nodules on the roots of a pea plant are responsible for fixing atmospheric nitrogen and making it available to the plant. The name phosphorus means “light bringer.” 10 Dinitrogen trioxide, N2O3 11 Phosphorus(III) oxide, P4O6 12 Phosphorus, P4 Lavoisier named the element azote, which means “lifeless.” Ironically, we now know that there would be no life as we know it without nitrogen. Arsenic and antimony are metalloids. They have been known in the pure state since ancient times because they are easily obtained from their ores (Fig. 15.34). In the elemental state, they are used primarily in the semiconductor industry and in the lead alloys used as electrodes in storage batteries. Gallium arsenide is used in lasers, including the lasers used in CD players. Metallic bismuth, with its large, weakly bonded atoms, has a low melting point and is used in alloys that serve as fire detectors in sprinkler systems: the alloy melts when a fire breaks out nearby, and the sprinkler system is activated. Like ice, solid bismuth is less dense than the liquid. As a result, molten bismuth does not shrink when it solidifies in molds, and so it is used to make low-temperature castings. Nitrogen is highly unreactive as an element, largely because of its strong triple bond. White phosphorus is highly reactive. The differences in properties between the nonmetals nitrogen and phosphorus can be traced to the larger atomic radius and lower electronegativity of phosphorus and the availability of d-orbitals in its valence shell. Metallic character increases down the group. 15.16 Compounds with Hydrogen and the Halogens By far the most important hydrogen compound of a Group 15/V element is ammonia, NH3, which is prepared in huge amounts by the Haber process. Small quantities of ammonia are present naturally in the atmosphere as a result of the bacterial decomposition of organic matter in the absence of air. This decomposition typically occurs in lake and river beds, in swamps, and in cattle feedlots. Ammonia is a pungent, toxic gas that condenses to a colorless liquid at Ϫ33°C. The liquid resembles water in its physical properties, including its ability to act as a solvent for a wide range of substances. Because the dipole moment of the NH3 molecule (1.47 D) is lower than that of the H2O molecule (1.85 D), salts with strong ionic character, such as KCl, cannot dissolve in ammonia. Salts with polarizable anions tend to be more soluble in ammonia than are salts with greater ionic character. For example, iodides are more soluble than chlorides in ammonia. Liquid ammonia undergoes much less extensive autoprotolysis than water: 2 NH3(am) #¢4 NH4 ϩ (am) ϩ NH2 Ϫ (am) Kam ϭ [NH4 ϩ ][NH2 Ϫ ] ϭ 1 ϫ 10Ϫ33 at Ϫ35°C Bases that would be fully protonated in water, such as the cyclopentadienide anion, C5H5 Ϫ , behave as very weak bases in ammonia. Ammonia is very soluble in water because the NH3 molecules can form hydrogen bonds to H2O molecules. Ammonia is a weak Brønsted base in water; it is also a reasonably strong Lewis base, particularly toward d-block elements. For example, it reacts with Cu2ϩ (aq) ions to give a deep-blue complex (Fig. 15.35): Cu2ϩ (aq) ϩ 4 NH3(aq) Cu(NH3)4 2ϩ (aq)¡ 642 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.34 The minerals (from left to right) orpiment, As2S3; stibnite, Sb2S3; and realgar, As4S4; are all ores that have been used as sources of Group 15/V elements. The pungency of heated ammonium chloride was known in antiquity to the Ammonians, the worshippers of the Egyptian god Ammon. Ammonium salts decompose when heated: (NH4)2CO3(s) 2 NH3(g) ϩ CO2(g) ϩ H2O(g) The pungent smell of decomposing ammonium carbonate once made it an effective “smelling salt,” a stimulant used to revive people who had fainted. The ammonium cation of an ammonium salt may be oxidized by an anion that has oxidizing character, such as a nitrate. The products depend on the temperature of the reaction: NH4NO3(s) 250°C ®®®B N2O(g) ϩ 2 H2O(g) 2 NH4NO3(s) Ͼ300°C ®®®B 2 N2(g) ϩ O2(g) ϩ 4 H2O(g) The explosive violence of the second reaction is the reason that ammonium nitrate is used as a component of dynamite. Ammonium nitrate has a high nitrogen content (33.5% by mass) and is highly soluble in water. These characteristics make it attractive as a fertilizer, which is its principal use. Hydrazine, NH2NH2, is an oily, colorless liquid. It is prepared by the gentle oxidation of ammonia with alkaline hypochlorite solution: 2 NH3(aq) ϩ ClOϪ (aq) aqueous alkali ®®®®®®B N2H4(aq) ϩ ClϪ (aq) ϩ H2O(l) Its physical properties are very similar to those of water; for instance, its melting point is 1.5°C and its boiling point is 113°C. However, its chemical properties are very different. It is dangerously explosive and is normally stored and used in aqueous solution. Hydrazine is used as a rocket fuel and to eliminate dissolved, corrosive oxygen from the water used in high-pressure, high-temperature steam furnaces: N2H4(aq) ϩ O2(g) N2(g) ϩ 2 H2O(l) Nitrogen has oxidation number ϩ3 in the highly reactive nitrogen halides. Nitrogen trifluoride, NF3, is the most stable halide; it does not react with water. However, NCl3 does react with water, forming ammonia and hypochlorous acid. Nitrogen triiodide, NI3, which is known only in combination with ammonia as the “ammoniate” NI3иNH3 (the analog of a hydrate), is so unstable that it decomposes explosively when lightly touched. Nitrides are solids that contain the nitride ion, N3Ϫ . Nitrides are stable only for small cations such as lithium or magnesium. Boron nitride, BN, is an important ceramic discussed in Section 6.9. Magnesium nitride, Mg3N2, is formed together with the oxide when magnesium is burned in air (Fig. 15.36): 3 Mg(s) ϩ N2(g) Mg3N2(s) Magnesium nitride, like all nitrides, reacts with water to produce ammonia and the corresponding hydroxide: Mg3N2(s) ϩ 6 H2O(l) 3 Mg(OH)2(s) ϩ 2 NH3(g) In this reaction, the nitride ion acts as a strong base, accepting protons from water to form ammonia. The azide ion is a highly reactive polyatomic anion of nitrogen, N3 Ϫ . Its most common salt, sodium azide, NaN3, is prepared from dinitrogen oxide and molten sodium amide: N2O(g) ϩ 2 NaNH2(l) 175°C ®®®B NaN3(s) ϩ NaOH(l) ϩ NH3(g) Sodium azide, like most azide salts, is shock sensitive. It is used in automobile air bags, where it decomposes to elemental sodium and nitrogen when detonated (see Section 4.7): 2 NaN3(s) 2 Na(s) ϩ 3 N2(g) The azide ion is a weak base and accepts a proton to form its conjugate acid, hydrazoic acid, HN3. Hydrazoic acid is a weak acid similar in strength to acetic acid. The hydrogen compounds of other members of Group 15/V are much less stable than ammonia and decrease in stability down the group. Phosphine, PH3, is a poisonous gas that smells faintly of garlic and bursts into flame in air if it is slightly impure. ¡ ¡ ¡ ¢ ¡ ¡ ¢ 15.16 COMPOUNDS WITH HYDROGEN AND THE HALOGENS 643 FIGURE 15.35 When aqueous ammonia is added to a copper(II) sulfate solution, first a light-blue precipitate of Cu(OH)2 forms (the cloudy region at the top, which appears dark because it is backlit). The precipitate disappears when more ammonia is added to form the dark blue complex Cu(NH3)4 2ϩ by a Lewis acid–base reaction. Animation 15.35 FIGURE 15.36 This sample of magnesium nitride was formed by burning magnesium in an atmosphere of nitrogen. When magnesium burns in air, the product is the oxide as well as the nitride. Lab Video 15.36 It is much less soluble than ammonia in water because PH3 cannot form hydrogen bonds to water. Aqueous solutions of phosphine are neutral, because the electronegativity of phosphorus is so low that the lone pair in PH3 is spread over the hydrogen atoms as well as the phosphorus atom; consequently, the molecule has only a very weak tendency to accept a proton (pKb ϭ 27.4). Because PH3 is the very weak parent acid of the strong Brønsted base P3Ϫ , phosphine can be prepared by protonating phosphide ions with a Brønsted acid. Even water is a sufficiently strong proton donor: 2 P3Ϫ (s) ϩ 6 H2O(l) 2 PH3(g) ϩ 6 OHϪ (aq) Phosphorus trichloride, PCl3, and phosphorus pentachloride, PCl5, are the two most important halides of phosphorus. The former is prepared by direct chlorination of phosphorus. Phosphorus trichloride, a liquid, is a major intermediate for the production of pesticides, oil additives, and flame retardants. Phosphorus pentachloride, a solid, is made by allowing phosphorus trichloride to react with more chlorine (recall Fig. 2.10). A typical reaction of the nonmetal halides is their reaction with water to give oxoacids, without a change in oxidation number: PCl3(l) ϩ 3 H2O(l) H3PO3(s) ϩ 3 HCl(g) This reaction is an example of a hydrolysis reaction, a reaction with water in which new elementϪoxygen bonds are formed. Another example is the reaction of PCl5 (phosphorus oxidation state ϩ5) with water to produce phosphoric acid, H3PO4 (also phosphorus oxidation state ϩ5): PCl5(s) ϩ 4 H2O(l) H3PO4(l) ϩ 5 HCl(g). This reaction is violent and dangerous. An interesting feature of phosphorus pentachloride is that it is an ionic solid of tetrahedral PCl4 ϩ cations and octahedral PCl6 Ϫ anions, but it vaporizes to a gas of trigonal bipyramidal PCl5 molecules (see Section 2.10). Phosphorus pentabromide is also molecular in the vapor and ionic as the solid; but, in the solid, the anions are simply BrϪ ions, presumably because six bulky Br atoms simply do not fit around a central P atom. Self-Test 15.12A Propose an explanation for the fact that the nitrogen trihalides become less stable as the molar mass of the halogen increases. [Answer: The N atom is small; as the molar mass of the halogen increases, fewer can fit easily around it.] Self-Test 15.12B (a) Write the Lewis structure for the azide ion and assign formal charges to the atoms. (b)You will find it possible to write a number of Lewis structures. Which is likely to make the biggest contribution to the resonance? (c) Predict the shape of the ion and its polarity. The important compounds of nitrogen with hydrogen are ammonia, hydrazine, and hydrazoic acid, the parent of the shock-sensitive azides. Phosphine forms neutral solutions in water; reaction of phosphorous halides with water produces oxoacids without change in oxidation number. 15.17 Nitrogen Oxides and Oxoacids Nitrogen forms several oxides, with oxidation numbers ranging from ϩ1 to ϩ5. All nitrogen oxides are acidic oxides and some are the acid anhydrides of the nitrogen oxoacids (Table 15.8). In atmospheric chemistry, where the oxides play an important two-edged role in both maintaining and polluting the atmosphere, they are referred to collectively as NOx (read “nox”). Dinitrogen oxide, N2O (oxidation number ϩ1), is commonly called nitrous oxide. It is formed by heating ammonium nitrate gently: NH4NO3(s) 250°C ®®®B N2O(g) ϩ 2 H2O(g) ¡ ¡ ¡ 644 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS Like many of the reactions in this book, this reaction is extremely hazardous. Don’t try it. Because it is tasteless, unreactive, nontoxic in small amounts, and soluble in fats, N2O is sometimes used as a foaming agent and propellant for whipped cream. Nitrogen oxide (or nitrogen monoxide), NO (oxidation number ϩ2), is commonly called nitric oxide. It is a colorless gas prepared industrially by the catalytic oxidation of ammonia: 4 NH3(g) ϩ 5 O2(g) ∫∫∫∫∫B 4 NO(g) ϩ 6 H2O(g) In the laboratory, nitrogen oxide can be prepared by reducing a nitrite with a mild reducing agent such as IϪ : 2 NO2 Ϫ (aq) ϩ 2 IϪ (aq) ϩ 4 Hϩ (aq) 2 NO(g) ϩ I2(aq) ϩ 2 H2O(l) Thinking point: Why can a strong reducing agent not be used? Nitrogen oxide is rapidly oxidized to nitrogen dioxide on exposure to air, a reaction that contributes to acid rain (see Box 11.1): 2 NO(g) ϩ O2(g) 2 NO2(g) Nitrogen oxide plays both harmful and beneficial roles in our lives. The conversion of atmospheric nitrogen into NO in hot airplane and automobile engines contributes to the problem of acid rain and the formation of smog, as well as to the destruction of the ozone layer (see Box 14.3). However, in small amounts in the body, nitrogen oxide acts as a neurotransmitter, helps to dilate blood vessels, and participates in other physiological changes. It is a subtle neurotransmitter because it is highly mobile, on account of its small size, but is quickly destroyed, on account of being a radical. Nitrogen dioxide, NO2 (oxidation number ϩ4), is a choking, poisonous, brown gas that contributes to the color and odor of smog. The molecule has an odd number of electrons, and in the gas phase it exists in equilibrium with its colorless dimer N2O4. Only the dimer exists in the solid phase, and so the brown gas condenses to a colorless solid. When it dissolves in water, NO2 disproportionates into nitric acid (oxidation number ϩ5) and nitrogen oxide (oxidation number ϩ2): 3 NO2(g) ϩ H2O(l) 2 HNO3(aq) ϩ NO(g) Nitrogen dioxide in the atmosphere undergoes the same reaction and contributes to the formation of acid rain. It also initiates a complex sequence of smog-forming photochemical reactions. The blue gas dinitrogen trioxide, N2O3 (Fig. 15.37, 10), in which the oxidation number of nitrogen is ϩ3, is the anhydride of nitrous acid, HNO2, and forms that acid when it dissolves in water: N2O3(g) ϩ H2O(l) 2 HNO2(aq) Nitrous acid, the parent acid of the nitrites, has not been isolated in pure form but is widely used in aqueous solution. Nitrites are produced by the reduction of nitrates with hot metal: KNO3(s) ϩ Pb(s) 350°C ®®®B KNO2(s) ϩ PbO(s) ¡ ¡ ¡ ¡ 15.17 NITROGEN OXIDES AND OXOACIDS 645 1000°C, Pt TABLE 15.8 The Oxides and Oxoacids of Nitrogen Oxidation Oxide Oxide Oxoacid Oxoacid number formula name formula name 5 N2O5 dinitrogen pentoxide HNO3 nitric acid 4 NO2* nitrogen dioxide — N2O4 dinitrogen tetroxide — 3 N2O3 dinitrogen trioxide HNO2 nitrous acid 2 NO nitrogen monoxide — nitric oxide 1 N2O dinitrogen monoxide H2N2O2 hyponitrous acid nitrous oxide *2 NO2 #4 N2O4. FIGURE 15.37 Dinitrogen trioxide, N2O3, condenses to a deep-blue liquid that freezes at –100°C to a pale-blue solid, as shown here. On standing, it turns green as a result of partial decomposition into nitrogen dioxide, a yellow-brown gas. Most nitrites are soluble in water and mildly toxic. Despite their toxicity, nitrites are used in the processing of meat products because they retard bacterial growth and form a pink complex with myoglobin that inhibits the oxidation of blood (a reaction that would otherwise turn the meat brown). Nitrites are responsible for the pink color of ham, sausages, and other cured meat. Nitric acid, HNO3 (oxidation number ϩ5) is used extensively in the production of fertilizers and explosives. It is made by the three-step Ostwald process: Step 1 Oxidation of ammonia; nitrogen’s oxidation number increases from Ϫ3 to ϩ2: Ϫ3 ϩ2 4 NH3(g) ϩ 5 O2(g) ∫∫∫∫∫∫∫∫∫B 4 NO(g) ϩ 6 H2O(g) Step 2 Oxidation of nitrogen oxide; nitrogen’s oxidation number increases from ϩ2 to ϩ4: ϩ2 ϩ4 2 NO(g) ϩ O2(g) 2 NO2(g) Step 3 Disproportionation in water; nitrogen’s oxidation number changes from ϩ4 to ϩ5 and ϩ2: ϩ4 ϩ5 ϩ2 3 NO2(g) ϩ H2O(l) 2 HNO3(aq) ϩ NO(g) Nitric acid, a colorless liquid that boils at 83°C, is normally used in aqueous solution. Concentrated nitric acid is often pale yellow as a result of partial decomposition of the acid to NO2. Because nitrogen has its highest oxidation number (ϩ5) in HNO3, nitric acid is an oxidizing agent as well as an acid. It is used to make the explosives nitroglycerin and trinitrotoluene (TNT). Much of its strength as an oxidizing agent is due to the formation of the strong bond in the N2 molecule to which it is reduced. Nitrogen forms oxides in each of its integer oxidation states from ؉1 to ؉5; the properties of the oxides and oxoacids are related to the oxidation number of nitrogen in the compound. 15.18 Phosphorus Oxides and Oxoacids The oxoacids and oxoanions of phosphorus are among the chemicals manufactured in the greatest amounts. Phosphate fertilizer production consumes two-thirds of all the sulfuric acid produced in the United States. The structures of the phosphorus oxides are based on the tetrahedral PO4 unit, which is similar to the structural unit in the oxides of its neighbor silicon (see Section 6.7). White phosphorus burns in a limited supply of air to form phosphorus(III) oxide, P4O6 (11): P4(s, white) ϩ 3 O2(g) P4O6(s) The molecules are tetrahedral, like P4, but an O atom lies between each pair of P atoms. Phosphorus(III) oxide is the anhydride of phosphorous acid, H3PO3 (13), and is converted into the acid by cold water: P4O6(s) ϩ 6 H2O(l) 4 H3PO3(aq) Although its formula suggests that it should be a triprotic acid, H3PO3 is in fact diprotic because one of the H atoms is attached directly to the P atom and the P–H bond is nonpolar (Section 11.10). When phosphorus burns in an ample supply of air, it forms phosphorus(V) oxide, P4O10 (14). This white solid reacts so vigorously with water that it is widely used in the laboratory as a drying agent. Phosphorus(V) oxide is the anhydride of phosphoric acid, H3PO4 (15): P4O10(s) ϩ 6 H2O(l) 4 H3PO4(aq) Phosphoric acid is used primarily for the production of fertilizers, in processed food to increase acidity, and in detergents. Many soft drinks owe their tart taste to the presence of low concentrations of phosphoric acid. Pure phosphoric acid, H3PO4, is a colorless ¡ ¡ ¡ ¡ ¡ 646 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 350°C, 5 atm, Pt/Rh 13 Phosphorous acid, H3PO 14 Phosphorus(V) oxide, P4O10 15 Phosphoric acid, H3PO4 solid with a melting point of 42°C; but in the laboratory, it is normally a syrupy liquid on account of the water that it has absorbed. In fact, phosphoric acid is usually purchased as 85% H3PO4. Its high viscosity can be traced to extensive hydrogen bonding. Although phosphorus has a high oxidation number (ϩ5), the acid shows appreciable oxidizing power only at temperatures above about 350°C; it may be used where nitric acid and sulfuric acid would be too strongly oxidizing. Phosphoric acid is the parent of the phosphates, which are of great commercial importance. Phosphate rock is mined in huge quantities in Florida and Morocco. After being crushed, it is treated with sulfuric acid to give a mixture of sulfates and phosphates called superphosphate, a major fertilizer: Ca3(PO4)2(s) ϩ 2 H2SO4(l) 2 CaSO4(s) ϩ Ca(H2PO4)2(s) When phosphoric acid is heated, it undergoes a condensation reaction, a reaction in which two molecules combine together with the elimination of a small molecule, normally that of water: The product, H4P2O7, is pyrophosphoric acid. Further heating gives even more complicated products that have chains and rings of PO4 groups. The products are called polyphosphoric acids. Polyphosphoric acids are far from being of only academic interest: they empower our actions and thoughts. The most important polyphosphate is adenosine triphosphate, ATP (16), which is found in every living cell. The triphosphate part of this molecule is a chain of three phosphate groups that are converted into adenosine diphosphate, ADP, in the body: HO P O O O HϩHO P OH OHOH HO P O O OH P O OH OH∫B ϩ H2O ¡ 15.18 PHOSPHORUS OXIDES AND OXOACIDS 647 16 Adenosine triphosphate, ATP (where the wiggly line indicates the rest of the molecule). Some energy is required to break the OßH bond in water and the relatively weak OßP bond in ATP, but more energy is released when the new OßH and OßP bonds form in the product (⌬G° ϭ Ϫ30 kJ at pH ϭ 7). This energy is used to power energy-demanding processes in cells. The oxides of phosphorus have structures based on the tetrahedral PO4 unit; P4O6 and P4O10 are the anhydrides of phosphorous acid and phosphoric acid, respectively. Polyphosphates are extended structures used (as ATP) by living cells to store and transfer energy. Self-Test 15.13A How does (a) the acidity of a nitrogen oxoacid and (b) its strength as an oxidizing agent change as the oxidation number of N increases from ϩ1 to ϩ5? [Answer: (a) Increases; (b) increases] Self-Test 15.13B What is the molarity of phosphoric acid in 85% (by mass) H3PO4(aq), which has a density of 1.7 gиmLϪ1 ? GROUP 16/VI: THE OXYGEN FAMILY Elements become increasingly nonmetallic toward the right-hand side of the periodic table; by Group 16/VI, even polonium, at the foot of the group, is best regarded as a metalloid (Table 15.9). Here, on the far right of the periodic table, the electron configurations are only a few electrons short of a closed-shell, noble-gas configuration, and O P O O O P OϪ OϪ OϪ ϩ H2PO4 Ϫ (aq) O P O O O P O OϪ OϪ O P OϪ OϪ ∫Bϩ H2O 648 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS the effective nuclear charge is high. As a result, when the elements in Group 16/VI form compounds with other nonmetals, they do so by sharing electrons to form covalent bonds. The atoms have the valence electron configuration ns2 np4 , and so they need only two more electrons to complete their valence shells. The members of the group are collectively called the chalcogens. 15.19 The Group 16/VI Elements Oxygen is the most abundant element in the Earth’s crust, and the free element accounts for 23% of the mass of the atmosphere. Oxygen is much more reactive than nitrogen, the other major component of our atmosphere. The combustion of all living organisms in oxygen is thermodynamically spontaneous; however, we do not burst into flame at normal temperatures, because combustion has a high activation energy. Oxygen is a colorless, tasteless, odorless gas of O2 molecules; the gas condenses to a pale-blue liquid at Ϫ183°C (Fig. 15.38). Although O2 has an even number of electrons, two of them are unpaired, making the molecule paramagnetic; in other words, O2 behaves like a tiny magnet and is attracted into a magnetic field. More than 2 ϫ 1010 kg of liquid oxygen is produced each year in the United States (about 80 kg per inhabitant) by fractional distillation of liquid air. The biggest consumer of oxygen is the steel industry, which needs about 1 t of oxygen (1 t ϭ 103 kg) to produce 1 t of steel. In steelmaking, oxygen is blown into molten iron to oxidize any impurities, particularly carbon (see Section 6.3). Elemental oxygen is also used for welding (to create a very hot flame in oxyacetylene torches) and in medicine. Physicians administer oxygen to relieve strain on the heart and lungs and as a stimulant. An allotrope of oxygen, ozone, O3 (17), is formed in the stratosphere by the effect of solar radiation on O2 molecules. Its total abundance in the atmosphere is equivalent to a layer that, at the ordinary conditions of 25°C and 1 bar, would cover the Earth to a thickness of only 3 mm, yet its presence in the stratosphere is vital to the maintenance of life on Earth (see Box 14.3). Ozone can be made in the laboratory by passing an electric discharge through oxygen. It is a blue gas that condenses at Ϫ112°C to an explosive blue liquid that looks like ink (Fig. 15.39). Its pungent smell can often be detected near electrical equipment and after lightning. Ozone is also present in smog, where it is produced by the reaction of oxygen molecules with oxygen atoms: O ϩ O2 O3 The oxygen atoms are produced by the photochemical decomposition of NO2, which is generated from emission products of automobile engines (Section 15.17): NO2 ∫∫∫∫∫∫B NO ϩ O Electronegativities decrease down Group 16 (Fig. 15.40), and atomic and ionic radii increase (Fig. 15.41). The differences between oxygen and sulfur are similar to those ¡ TABLE 15.9 The Group 16/VI Elements Valence configuration: ns2 np4 Molar Melting Boiling Density mass point point (g·cm–3 ) Z Name Symbol (g·mol–1 ) (°C) (°C) at 25°C Normal form* 8 oxygen O 16.00 Ϫ218 Ϫ183 1.14† colorless paramagnetic gas (O2) Ϫ192 Ϫ112 1.35† blue gas (ozone, O3) 16 sulfur S 32.06 115 445 2.09 yellow nonmetallic solid (S8) 34 selenium Se 78.96 220 685 4.79 gray nonmetallic solid 52 tellurium Te 127.60 450 990 6.25 silver-white metalloid 84 polonium‡ Po (209) 254 960 9.40 gray metalloid *Normal form means the appearance and state of the element at 25°C and 1 atm. † For the liquid at its boiling point. ‡ Radioactive. UV radiation Recall Section 3.10, where we saw that in O2 two unpaired electrons occupy two antibonding ␲-orbitals of the same energy. 17 Ozone, O3 FIGURE 15.38 Liquid oxygen is pale blue. (The gas itself is colorless.) The inset shows that the gas consists of diatomic molecules known formally as dioxygen. between nitrogen and phosphorus, and for similar reasons: sulfur has atoms that are 58% larger than those of oxygen, and it has a lower first ionization energy and electronegativity. The bonds that sulfur forms to hydrogen are much less polar than the bonds between oxygen and hydrogen. Consequently, SßH bonds do not take part in hydrogen bonding; as a result, H2S is a gas, whereas H2O is a liquid, despite the smaller number of electrons and hence weaker London forces. Sulfur also has weaker tendencies to form multiple bonds, tending to form additional single bonds to as many as six other atoms and using its d-orbitals to do so. Sulfur has a striking ability to catenate, or form chains of atoms. Oxygen’s ability to form chains is very limited, with H2O2, O3, the anions O2 Ϫ , O2 2Ϫ , and O3 Ϫ , and other peroxides the only examples. Sulfur’s ability is much more pronounced. It appears, for instance, in the existence of S8 rings, their fragments, and the long strands of “plastic sulfur” that form when sulfur is heated to about 200°C and suddenly cooled. The ßSßSß links that connect different parts of the chains of amino acids in proteins are another example of catenation. These “disulfide links” contribute to the shapes of proteins, including the keratin of our hair; thus, sulfur helps to keep us alive and, perhaps, curly haired (see Section 19.13). Sulfur is widely distributed as sulfide ores, which include galena, PbS; cinnabar, HgS; iron pyrite, FeS2; and sphalerite, ZnS (Fig. 15.42). Because these ores are so common, sulfur is a by-product of the extraction of a number of metals, especially copper. Sulfur is also found as deposits of the native element (called brimstone), which are formed by bacterial action on H2S. The low melting point of sulfur (115°C) is utilized in the Frasch process, in which superheated water is used to melt solid sulfur underground and compressed air pushes the resulting slurry to the surface. Sulfur is also commonly found in petroleum, and extracting it chemically has been made inexpensive and safe by the use of heterogeneous catalysts, particularly zeolites (see Section 14.15). One method 15.19 THE GROUP 16/VI ELEMENTS 649 FIGURE 15.39 Ozone is a blue gas that condenses to a dark-blue, highly unstable liquid. The inset shows that the gas consists of triatomic molecules. 3.4 2.6 2.6 2.1 2.0 O S Se Te Po FIGURE 15.40 The electronegativities of the Group 16/VI elements decrease down the group. O 140 66 S Te Se 184 198 221 137 117 104 FIGURE 15.41 The atomic and ionic radii of the Group 16/VI elements increase steadily down the group. The values shown are in picometers, and each anion (shown green) is substantially larger than its neutral parent atom. FIGURE 15.42 A collection of sulfide ores. From left to right: galena, PbS; cinnabar, HgS; pyrite, FeS2; sphalerite, ZnS. Pyrite has a lustrous golden color and has frequently been mistaken for gold; hence, it is also known as fool’s gold. Gold and fool’s gold are readily distinguished by their densities. used to remove sulfur in the form of H2S from petroleum and natural gas is the Claus process, in which some of the H2S is first oxidized to sulfur dioxide: 2 H2S(g) ϩ 3 O2(g) 2 SO2(g) ϩ 2 H2O(l) The SO2 is then used to oxidize the remainder of the hydrogen sulfide: 2 H2S(g) ϩ SO2(g) ∫∫∫∫∫∫B 3 S(s) ϩ 2 H2O(l) Sulfur is of major industrial importance. Most of the sulfur that is produced is used to make sulfuric acid, but an appreciable amount is used to vulcanize rubber (Sec-tion 19.12). Elemental sulfur is a yellow, tasteless, almost odorless, insoluble, nonmetallic molecular solid of crownlike S8 rings (18). The two common crystal forms of sulfur are monoclinic sulfur and rhombic sulfur (recall the sulfur phase diagram in Fig. 9.8). The more stable form under normal conditions is rhombic sulfur, which forms beautiful yellow crystals (Fig. 15.43). At low temperatures, sulfur vapor consists mainly of S8 molecules. At temperatures above 720°C, the vapor has a blue tint from the S2 molecules that form. The latter are paramagnetic, like O2. Selenium and tellurium occur in sulfide ores; they are also recovered from the anode sludge formed during the electrolytic refining of copper (see Section 16.4). Both elements have several allotropes, the most stable consisting of long zigzag chains of atoms. Although these allotropes look like silver-white metals, they are poor electrical conductors (Fig. 15.44). The conductivity of selenium is increased by exposure to light, and so it is used in solar cells, photoelectric devices, and photocopying machines. Selenium also occurs as a deep-red solid consisting of Se8 molecules. Polonium is a radioactive, low-melting metalloid. It is a useful source of ␣ particles (helium-4 nuclei; they are described in more detail in Section 15.24) and is used in antistatic devices in textile mills: the ␣ particles reduce static by counteracting the negative charges that tend to build up on the fast-moving fabric. Metallic character increases down Group 16/VI as electronegativity decreases. Oxygen and sulfur occur naturally in the elemental state; sulfur forms chains and rings with itself, but oxygen does not. 15.20 Compounds with Hydrogen By far the most important compound of oxygen and hydrogen is water, H2O. Municipal water supplies normally undergo several stages of purification (Fig. 15.45). Raw water is aerated by bubbling air through it to remove foul-smelling dissolved gases such as H2S, to oxidize some organic compounds to CO2, and to add oxygen. Adding slaked lime, Ca(OH)2, reduces acidity, precipitates Mg2ϩ , Fe3ϩ , Cu2ϩ , and other metal ions as hydroxides, and softens hard water (see Sections 9.12 and 15.8). After the lime is added, the water is pumped into a primary settling basin. Because the precipitates tend to form as a colloid (a very fine powder that remains suspended in the water, Section 9.21), either Fe2(SO4)3 or alum (specifically, Al2(SO4)3и18H2O) is added to coagulate and flocculate the precipitate so that it can be filtered. Coagulation is the irreversible aggregation of small particles into larger particles; flocculation is the reversible, loose aggregation of somewhat larger particles to form a fluffy gel. At this point the water is basic and carbon dioxide is often added to lower the pH, which promotes precipitation of the aluminum as Al(OH)3 so that it can be removed by filtration (Section 15.10). ¡ 650 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS Raw water Potable water pH adjustment Chlorine Aerator Sludge lagoon Lime Carbon dioxide Coagulant Activated charcoal Sand filter Secondary settling basin Primary settling basin FIGURE 15.45 Typical steps in the purification of drinking water. 300°C, Al2O3 18 Sulfur, S8 (b) FIGURE 15.43 One of the two most common forms of sulfur is the blocklike rhombic form (a). It differs from the needlelike monoclinic sulfur (b) in the manner in which the S8 rings are stacked together. Lab Video 15.43 FIGURE 15.44 Two of the Group 16/VI elements: selenium, which is a nonmetal, on the left and tellurium, a metalloid, on the right. (a) As the precipitate settles slowly in a secondary basin, it adsorbs any remaining suspended CaCO3, bacteria, and other particles, such as dirt and algae. Precipitates from the primary and secondary basins are combined in a sludge lagoon for disposal. The water is then passed through a sand filter to remove any remaining suspended particles. The pH of the water is checked again and made slightly basic to reduce acid corrosion of the pipes. At this point, a disinfectant, usually chlorine, is added. In the United States, the chlorine level is required to be greater than 1 g of Cl2 per 1000 kg (1 ppm by mass) of water at the point of consumption. In water, chlorine forms hypochlorous acid, which is highly toxic to bacteria: Cl2(g) ϩ 2 H2O(l) H3Oϩ (aq) ϩ ClϪ (aq) ϩ HClO(aq) Additional water purification steps, such as reverse osmosis may be required (Section 9.17), depending on the source and condition of the water. Because water is a common solvent we might think of it merely as a passive medium in which chemical reactions take place. However, water is a reactive compound, and an alien raised in a nonaqueous environment might consider it aggressively corrosive and be surprised at our survival. For instance, water is an oxidizing agent: 2 H2O(l) ϩ 2 eϪ 2 OHϪ (aq) ϩ H2(g) E ϭ Ϫ0.42 V at pH ϭ 7 One example is its reaction with the alkali metals, as in 2 Na(s) ϩ 2 H2O(l) 2 NaOH(aq) ϩ H2(g) However, unless the other reactant is a strong reducing agent, water acts as an oxidizing agent only at high temperatures, as in the re-forming reaction (Section 15.3). Water is a very mild reducing agent: 4 Hϩ (aq) ϩ O2(g) ϩ 4 eϪ 2 H2O(l) E ϭ ϩ0.82 V at pH ϭ 7 However, few substances besides fluorine are strong enough oxidizing agents to accept the electrons released in the reverse of this half-reaction. Water is also a Lewis base, because an H2O molecule can donate one of its lone pairs to a Lewis acid and form complexes such as Fe(H2O)6 3ϩ . Water’s ability to act as a Lewis base is also the origin of its ability to hydrolyze substances. The reaction between water and phosphorus pentachloride mentioned in Section 15.18 is an example. Hydrogen peroxide, H2O2 (19), is a very pale blue liquid that is appreciably denser than water (1.44 gиmLϪ1 at 25°C) but similar in other physical properties: its melting point is Ϫ0.4°C, and its boiling point is 152°C. Chemically, though, hydrogen peroxide and water differ greatly. The presence of the second oxygen atom makes H2O2 a very weak acid (pKa1 ϭ 11.75). Hydrogen peroxide is a stronger oxidizing agent than water. For example, H2O2 oxidizes Fe2ϩ and Mn2ϩ in acidic and basic solutions. It can also act as a reducing agent in the presence of more powerful oxidizing agents such as permanganate ions and chlorine (usually in basic solution). Hydrogen peroxide is normally sold for industrial use as a 30% by mass aqueous solution. When used as a hair bleach (as a 6% solution), it acts by oxidizing the pigments in the hair. A 3% H2O2 aqueous solution is used as a mild antiseptic in the home. Contact with blood catalyzes its disproportionation into water and oxygen gas, which cleanses the wound: 2 H2O2(aq) 2 H2O(l) ϩ O2(g) Because it oxidizes unpleasant effluents without producing any harmful by-products, H2O2 is also increasingly used as an oxidizing agent to control pollution. Self-Test 15.14A From the Lewis structures of the following molecules, determine which are paramagnetic and explain how you decided: (a) N2O3; (b) NO; (c) N2O. [Answer: (b) NO is paramagnetic, because it has an unpaired electron.] Self-Test 15.14B Write the half-reactions and the overall reaction for the oxidation of water by F2 in acidic solution. Determine the standard potential and ⌬G° for the reaction. ¡ ¡ ¡ ¡ ¡ 15.20 COMPOUNDS WITH HYDROGEN 651 19 Hydrogen peroxide, H2O2 Except for water, all the Group 16/VI binary compounds with hydrogen (the compounds H2E, where E is a Group 16/VI element) are toxic gases with offensive odors. They are insidious poisons because they paralyze the olfactory nerve and, soon after exposure, the victim cannot smell them. Rotten eggs smell of hydrogen sulfide, H2S, because egg proteins contain sulfur and give off the gas when they decompose. Another sign of the formation of sulfides in eggs is the pale green discoloration sometimes seen in hard-boiled eggs where the white meets the yolk: this color is a deposit of iron(II) sulfide. Hydrogen sulfide, H2S, is prepared either by protonation of the sulfide ion, a Brønsted base, in a reaction such as FeS(s) ϩ 2 HCl(aq) FeCl2(aq) ϩ H2S(g) or by direct reaction of the elements at 600°C. Hydrogen sulfide dissolves in water to give a solution of hydrosulfuric acid that, as a result of its oxidation by dissolved air, slowly becomes cloudy as S8 molecules form and then coagulate. Hydrosulfuric acid is a weak diprotic acid and the parent acid of the hydrogen sulfides (which contain the HSϪ ion) and the sulfides (which contain the S2Ϫ ion). The sulfides of the s-block elements are moderately soluble, whereas the sulfides of the heavy p- and d-block metals are generally very insoluble. The sulfur analog of hydrogen peroxide also exists and is an example of a polysulfane, a catenated molecular compound of composition HSßSnßSH, where n can take on values from 0 through 6. The polysulfide ions obtained from the polysulfanes include two ions found in lapis lazuli (Fig. 15.46). Water can act as a Lewis base, an oxidizing agent, and a weak reducing agent; hydrogen peroxide is a stronger oxidizing agent than water. Hydrogen sulfide is a weak acid; the polysulfanes exhibit the ability of sulfur to catenate. 15.21 Sulfur Oxides and Oxoacids Sulfur forms several oxides that in atmospheric chemistry are referred to collectively as SOx (read “sox”). The most important oxides and oxoacids of sulfur are the dioxide and trioxide and the corresponding sulfurous and sulfuric acids. Sulfur burns in air to form sulfur dioxide, SO2 (20), a colorless, choking, poisonous gas (recall Fig. C.1). About 7 ϫ 1010 kg of sulfur dioxide is produced annually from the decomposition of vegetation and from volcanic emissions. In addition, approximately 1 ϫ 1011 kg of naturally occurring hydrogen sulfide is oxidized each year to the dioxide by atmospheric oxygen: 2 H2S(g) ϩ 3 O2(g) 2 SO2(g) ϩ 2 H2O(g) Industry and transport contribute another 1.5 ϫ 1011 kg of the dioxide, of which about 70% comes from oil and coal combustion—mainly in electricity-generating plants. Because, like many other countries, the United States and Canada have increased restrictions on emissions of sulfur oxides, emissions of SO2 into the atmosphere in North America fell by about 54% between 1980 and 2007. The more stringent regulations that came into effect in the twenty-first century should allow for a further 50% reduction (see Box 11.1). Sulfur dioxide is the anhydride of sulfurous acid, H2SO3, which is the parent acid of the hydrogen sulfites (or bisulfites) and the sulfites: SO2(g) ϩ H2O(l) H2SO3(aq) Sulfurous acid is an equilibrium mixture of two molecules (21a and 21b); in (a) it resembles phosphorous acid, with one of the H atoms attached directly to the S atom. These molecules are also in equilibrium with molecules of SO2, each of which is surrounded by a cage of water molecules. The evidence for this equilibrium is that crystals of composition SO2иxH2O, with x about 7, are obtained when the solution is cooled. Such substances, in which a molecule occupies a cage formed by other molecules, are called clathrates. Methane, carbon dioxide, and the noble gases also form clathrates with water. ¡ ¡ ¡ 652 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.46 The blue stones in this ancient Egyptian ornament are lapis lazuli. This semiprecious stone is an aluminosilicate colored by S2 – and S3 – impurities. The blue color is due to S3 – and the hint of green to S2 – . 21 Sulfurous acid, H2SO3 (a) (b) 20 Sulfur dioxide, SO2 Sulfur dioxide is easily liquified under pressure and can therefore be used as a refrigerant. It is also a preservative for dried fruit and a bleach for textiles and flour, but its most important use is in the production of sulfuric acid. The oxidation number of sulfur in sulfur dioxide and the sulfites is ϩ4, an intermediate value in sulfur’s range from Ϫ2 to ϩ6. Hence, these compounds can act as either oxidizing agents or reducing agents. By far the most important reaction of sulfur dioxide is its slow oxidation to sulfur trioxide, SO3 (22), in which sulfur has the oxidation number ϩ6: 2 SO2(g) ϩ O2(g) 2 SO3(g) At normal temperatures, sulfur trioxide is a volatile liquid (its boiling point is 45°C), composed of trigonal planar SO3 molecules. In the solid and to some extent in the liquid, these molecules form trimers (unions of three molecules) of composition S3O9 (23) as well as larger clusters. Sulfuric acid, H2SO4, is produced commercially in the contact process, in which sulfur is first burned in oxygen and the SO2 produced is oxidized to SO3 over a V2O5 catalyst: S(s) ϩ O2(g) ®®®B SO2(g) 2 SO2(g) ϩ O2(g) ®®®®®B 2 SO3(g) Because sulfur trioxide forms a corrosive acid mist with water vapor, it is absorbed instead in 98% concentrated sulfuric acid to give the dense, oily liquid called oleum: SO3(g) ϩ H2SO4(l) H2S2O7(l) Oleum is then converted into the acid by reaction with water: H2S2O7(l) ϩ H2O(l) 2 H2SO4(l) Sulfuric acid is the inorganic chemical manufactured in the greatest amount worldwide, the annual production in the United States alone being more than 3 ϫ 1010 kg. The low cost of sulfuric acid leads to its widespread use in industry, particularly for the production of fertilizers, petrochemicals, dyestuffs, and detergents. About twothirds is used in the manufacture of phosphate and ammonium sulfate fertilizers (see Section 15.18). Sulfuric acid is a colorless, corrosive, oily liquid that boils (and decomposes) at about 300°C. It has three chemically important properties: it is a strong Brønsted acid, a dehydrating agent, and an oxidizing agent (Fig. 15.47). Sulfuric acid is a strong acid in the sense that its first deprotonation is almost complete at normal concentrations in water. Its conjugate base HSO4 Ϫ is a weak acid, with pKa ϭ 1.92 (Section 11.14). Sulfuric acid forms strong hydrogen bonds with water. The energy released when these bonds form can cause the mixture to boil violently. Sulfuric acid should always be diluted slowly and with great care, making sure to add the acid to the water, instead of the reverse, to avoid splashing concentrated acid. The powerful dehydrating ability of sulfuric acid is seen when a little concentrated acid is poured on sucrose, C12H22O11. A black, frothy mass of carbon forms as a result of the extraction of H2O (Fig. 15.48): C12H22O11(s) 12 C(s) ϩ 11 H2O(l)¡ ¡ ¡ ¡ 15.21 SULFUR OXIDES AND OXOACIDS 653 22 Sulfur trioxide, SO3 23 Sulfur trioxide trimer, S3O9 1000°C 500°C, V2O5 FIGURE 15.47 Sulfuric acid is an oxidizing agent. When some concentrated acid is poured on solid sodium bromide, NaBr, the bromide ions are oxidized to elemental bromine, which colors the mixture red-brown. (a) (b) (c) FIGURE 15.48 Sulfuric acid is a dehydrating agent. When concentrated sulfuric acid is poured on to sucrose (a), the sucrose, a carbohydrate, is dehydrated (b), leaving a frothy black mass of carbon (c). Lab Video 15.48 The froth is caused by the generation of the gases CO and CO2 in side reactions. Sulfur dioxide is the anhydride of sulfurous acid, and sulfur trioxide is the anhydride of sulfuric acid. Sulfuric acid is a strong acid, a dehydrating agent, and an oxidizing agent. Self-Test 15.15A What is the oxidation number of sulfur in (a) the dithionate ion, S2O6 2Ϫ ; (b) the thiosulfate ion, S2O3 2Ϫ ? [Answer: (a) ϩ5; (b) ϩ2] Self-Test 15.15B What is the oxidation number of sulfur in (a) S2Cl2; (b) oleum, H2S2O7? GROUP 17/VII: THE HALOGENS The unique properties of the halogens (Table 15.10), the members of Group 17/VII, can be traced to their valence configuration, ns2 np5 , which needs only one more electron to reach a closed-shell configuration. To complete the octet of valence electrons, in the elemental state all halogen atoms combine to form diatomic molecules, such as F2 and I2. With the exception of fluorine, the halogens can also lose valence electrons and their oxidation states can range from Ϫ1 to ϩ7. The elements form a family showing the smooth trends in physical properties that we would expect when London forces between molecules are the dominant intermolecular force. Because electronegativity decreases down the group (Fig. 15.49) and atomic and ionic radii increase smoothly down the group (Fig. 15.50), chemical properties show smooth trends as well, with the exception of some properties of fluorine. 15.22 The Group 17/VII Elements Fluorine, the first element of the group, is the halogen of greatest abundance in the Earth’s crust. It occurs widely in many minerals, including fluorspar, CaF2; cryolite, Na3AlF6; and the fluorapatites, Ca5(PO4)3F. Because fluorine is the most strongly oxidizing element (E° ϭ ϩ2.87 V), it cannot be obtained from its compounds by oxidation with another element. Fluorine is produced by electrolyzing an anhydrous molten mixture of potassium fluoride and hydrogen fluoride at about 75°C with a carbon anode. Fluorine is a reactive, almost colorless gas of F2 molecules. Most of the fluorine produced by industry is used to make the volatile solid UF6 used for processing nuclear fuel (Section 17.12). Much of the rest is used in the production of SF6 for electrical equipment. Fluorine has a number of peculiarities that stem from its high electronegativity, small size, and lack of available d-orbitals. It is the most electronegative element of all and has an oxidation number of Ϫ1 in all its compounds. Its high electronegativity and small size allow it to oxidize other elements to their highest oxidation numbers. The small size helps in this, because it allows several F atoms to pack around a central atom, as in IF7. TABLE 15.10 The Group 17/VII Elements Valence configuration: ns2 np5 Molar Melting Boiling Density mass point point (g·cm؊3 ) Z Name Symbol (g·mol؊1 ) (°C) (°C) at 25°C Normal form* 9 fluorine F 19.00 Ϫ220 Ϫ188 1.51† almost colorless gas 17 chlorine Cl 35.45 Ϫ101 Ϫ34 1.66† yellow-green gas 35 bromine Br 79.90 27 59 3.12 red-brown liquid 53 iodine I 126.90 114 184 4.95 purple-black nonmetallic solid 85 astatine‡ At (210) 300 350 — nonmetallic solid *Normal form means the appearance and state of the element at 25°C and 1 atm. † For the liquid at its boiling point. ‡ Radioactive. F Cl Br I 4.0 3.2 3.0 2.7 FIGURE 15.49 The electronegativities of the halogens decrease steadily down the group. 654 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS Because the fluoride ion is so small, the lattice enthalpies of its ionic compounds tend to be high (see Table 7.6). As a result, fluorides are less soluble than other halides. This difference in solubility is one of the reasons why the oceans are salty with chlorides rather than fluorides, even though fluorine is more abundant than chlorine in the Earth’s crust. Chlorides are more readily dissolved and washed out to sea. There are some exceptions to this trend in solubilities, including AgF, which is soluble; the other silver halides are insoluble. The exception arises because the covalent character of the silver halides increases from AgCl to AgI as the anion becomes larger and more polarizable. Silver fluoride, which contains the small and almost unpolarizable fluoride ion, is freely soluble in water because it is predominantly ionic. Chlorine is one of the chemicals manufactured in the greatest amount worldwide. It is obtained from sodium chloride by electrolysis of molten rock salt or brine (recall Sections 13.13 and 15.6). It is a pale yellow-green gas of Cl2 molecules that condenses at Ϫ34°C. It reacts directly with nearly all the elements (notable exceptions are carbon, nitrogen, oxygen, and the noble gases). It is a strong oxidizing agent and oxidizes metals to high oxidation states; for example, anhydrous iron(III) chloride, not iron(II) chloride, is formed when chlorine reacts with iron (Fig. 15.51): 2 Fe(s) ϩ 3 Cl2(g) 2 FeCl3(s) Chlorine is used in a number of industrial processes, including the manufacture of plastics, solvents, and pesticides. It is used as a bleach in the paper and textile industries and as a disinfectant in water treatment (Section 15.20). Chlorine is also used to produce bromine from brine wells through the oxidation of BrϪ ions (see Fig. K.2): 2 BrϪ (aq) ϩ Cl2(g) Br2(l) ϩ 2 ClϪ (aq) Air is bubbled through the solution to vaporize the bromine and drive it out. Bromine is a corrosive, red-brown fuming liquid of Br2 molecules that has a penetrating odor. Bromine is used widely in synthetic organic chemistry because of the ease with which it can be added to and removed from organic chemicals that are being used to carry out complicated syntheses. Organic bromides are incorporated into textiles as fire retardants and are used as pesticides; inorganic bromides, particularly silver bromide, are used in photographic emulsions. Iodine occurs as iodide ions in brines and as an impurity in Chile saltpeter. It was once obtained from seaweed, which contains high concentrations accumulated from seawater: 2000 kg of seaweed produce about 1 kg of iodine. The best modern source is the brine from oil wells; the oil itself was produced by the decay of marine organisms that had accumulated the iodine while they were alive. Elemental iodine is produced by oxidation with chlorine: Cl2(g) ϩ 2 IϪ (aq) I2(aq) ϩ 2 ClϪ (aq) ⌬G° ϭ Ϫ54.54 kJ The blue-black lustrous solid sublimes easily and forms a purple vapor. When iodine dissolves in organic solvents, it produces solutions having a variety of colors. These colors arise from the different interactions between the I2 molecules and the solvent (Fig. 15.52). The element is only slightly soluble in water, unless IϪ ions are present, in which case the soluble brown triiodide ion, I3 Ϫ , is formed. Iodine itself has few direct uses; but dissolved in alcohol, it is familiar as a mild oxidizing antiseptic. Because it is an essential trace element for living systems but scarce in inland areas, iodides are added to table salt (sold as “iodized salt”) in order to prevent an iodine deficiency. Astatine is a radioactive element that occurs in nature in uranium and thorium ores, but only to a minute extent. Samples are made by bombarding bismuth with ␣ particles in a cyclotron, which accelerates the particles to a very high speed. Astatine ¡ ¡ ¡ FIGURE 15.50 The atomic and ionic radii of the halogens increase steadily down the group as electrons occupy outer shells of the atoms. The values shown are in picometers. In all cases, the radii of the anions (represented by the green spheres) are larger than the atomic radii. F 133 181 196 220 114 133 58 99 I Cl Br 15.22 THE GROUP 17/VII ELEMENTS 655 FIGURE 15.51 Iron reacts vigorously and exothermically with chlorine to form anhydrous iron(III) chloride. isotopes do not exist long enough for its properties to be studied, but it is thought from spectroscopic measurements to have properties similar to those of iodine. Self-Test 15.16A (a) State the oxidation number of Cl in Cl2O7 and (b) write the chemical equation for its reaction with water. [Answer: (a) ϩ7; (b) Cl2O7(aq) ϩ H2O(l) : 2 HClO4(aq)] Self-Test 15.16B Explain the trends in the melting points and boiling points of the halogens. The halogens show smooth trends in chemical properties down the group; fluorine has some anomalous properties, such as its strength as an oxidizing agent and the lower solubilities of most fluorides. 15.23 Compounds of the Halogens The halogens form compounds among themselves. These interhalogens have the formulas XXЈ, XXЈ3, XXЈ5, and XXЈ7, where X is the heavier (and larger) of the two halogens. Only some of the possible combinations have been synthesized (Table 15.11). They are all prepared by direct reaction of the two halogens, the product formed being determined by the proportions of reactants used. For example, Cl2(g) ϩ 3 F2(g) 2 ClF3(g) Cl2(g) ϩ 5 F2(g) 2 ClF5(g) The physical properties of the interhalogens are intermediate between those of their parent halogens. Trends in the chemistry of the interhalogen fluorides can be related to the decrease in bond dissociation energy as the central halogen atom becomes heavier. The fluorides of the heavier halogens are all very reactive: bromine trifluoride gas is so reactive that even asbestos burns in it. The hydrogen halides, HX, can be prepared by the direct reaction of the elements: H2(g) ϩ X2(g) 2 HX(g) Fluorine reacts explosively by a radical chain reaction as soon as the gases are mixed. A mixture of hydrogen and chlorine also explodes when exposed to light. Bromine and iodine react with hydrogen much more slowly. A less hazardous laboratory source of the hydrogen halides is the action of a nonvolatile acid on a metal halide, as in CaF2(s) ϩ 2 H2SO4(aq, conc) Ca(HSO4)2(aq) ϩ 2 HF(g) Because BrϪ and IϪ are oxidized by sulfuric acid, phosphoric acid is used in the preparation of HBr and HI: KI(s) ϩ H3PO4(aq) ⌬ ∫∫B KH2PO4(aq) ϩ HI(g) ¡ ¡ ¡ ¡ 656 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.52 Solutions of iodine in a variety of solvents. From left to right, the first three solvents are tetrachloromethane (carbon tetrachloride), water, and potassium iodide solution, in which the brown I3 Ϫ ion forms. In the solution on the far right, some starch has been added to a solution of I3 Ϫ . The intense blue color that results has led to the use of starch as an indicator for the presence of iodine. TABLE 15.11 Known Interhalogens Interhalogen Normal form* XFn ClF colorless gas ClF3 colorless gas ClF5 colorless gas BrF pale-brown gas BrF3 pale-yellow liquid BrF5 colorless liquid IF unstable IF3 yellow solid IF5 colorless liquid IF7 colorless gas XCln BrCl red-brown gas ICl red solid I2Cl6 yellow solid XBrn IBr black solid *Normal form means the appearance and state of the compound at 25°C and 1 atm. All the hydrogen halides are colorless, pungent gases except hydrogen fluoride, which is a liquid at temperatures below 20°C. Its low volatility is a sign of extensive hydrogen bonding, and short zigzag chains of hydrogen-bonded molecules, up to about (HF)5, survive to some extent in the vapor. All the hydrogen halides dissolve in water to give acidic solutions. Hydrofluoric acid has the distinctive property of attacking glass and silica (see Fig. 6.22). The interiors of lamp bulbs are frosted by the vapors from an aqueous solution of hydrofluoric acid and ammonium fluoride (Fig. 15.53). Hydrogen fluoride is used to make fluorinated carbon compounds, such as Teflon (polytetrafluoroethylene) and the refrigerant R134a (CF3CH2F). Most fluoro-substituted hydrocarbons are relatively inert chemically: they are inert to oxidation by air, hot nitric acid, concentrated sulfuric acid, and other strong oxidizing agents. Consequently, Teflon is used to line chemical reactor vessels and to coat the surfaces of nonstick cookware. Because R134a does not contribute to global warming or the destruction of ozone in the stratosphere and is relatively unreactive and nontoxic, it is now the refrigerant most recommended for use in air conditioners in the United States. The acid strengths and oxidizing abilities of the halogen oxoacids increase with the oxidation number of the halogen (see Section 11.10). The hypohalous acids, HXO (halogen oxidation number ϩ1), are prepared by direct reaction of the halogen with water. For example, chlorine gas disproportionates in water to produce hypochlorous acid and hydrochloric acid: 0 ϩ1 Ϫ1 Cl2(g) ϩ H2O(aq) HClO(aq) ϩ HCl(aq) Hypohalite ions, XOϪ , are formed when a halogen is added to the aqueous solution of a base. Sodium hypochlorite, NaClO, is produced from the electrolysis of brine when the electrolyte is rapidly stirred, and the chlorine gas produced at the anode reacts with the hydroxide ion generated at the cathode. The chlorine gas disproportionates to produce hypochlorite and chloride ions: 0 ϩ1 Ϫ1 Cl2(g) ϩ 2 OHϪ (aq) ClOϪ (aq) ϩ ClϪ (aq) ϩ H2O(l) Because hypochlorites oxidize organic material, they are used in liquid household bleaches and as disinfectants. Their action as oxidizing agents stems partly from the decomposition of hypochlorous acid in solution: 2 HClO(aq) 2 Hϩ (aq) ϩ 2 ClϪ (aq) ϩ O2(g) The oxygen either bubbles out of the solution or attacks oxidizable material. Calcium hypochlorite is the main component of bleach powders and is used for purifying the ¡ ¡ ¡ 15.23 COMPOUNDS OF THE HALOGENS 657 (a) (b) FIGURE 15.53 When a mixture of hydrofluoric acid and ammonium fluoride is swirled inside a glass vial (a), reaction with the silica in the glass frosts the surface of the cover glass as well as the walls of the vial (b). Lab Video 15.53 water in home swimming pools. It is used for swimming pools in preference to sodium hypochlorite because the Ca2ϩ ions form insoluble calcium carbonate, which is removed by filtration; sodium would remain in solution and make the water too salty. Chlorate ions, ClO3 Ϫ (oxidation state ϩ5), form when chlorine reacts with hot concentrated aqueous alkali: 3 Cl2(g) ϩ 6 OHϪ (aq) ⌬ ∫∫B ClO3 Ϫ (aq) ϩ 5 ClϪ (aq) ϩ 3 H2O(l) They decompose when heated, to an extent that depends on whether a catalyst is present: 4 KClO3(s) ⌬ ∫∫B 3 KClO4(s) ϩ KCl(s) 2 KClO3(s) ⌬, MnO2 ®®®®®®B 2 KCl(s) ϩ 3 O2(g) The latter reaction is a convenient laboratory source of oxygen. Chlorates are useful oxidizing agents. Potassium chlorate is used as an oxidant in fireworks and in matches. The heads of safety matches consist of a paste of potassium chlorate, antimony sulfide, and sulfur, with powdered glass to create friction when the match is struck; as mentioned in Section 15.15, the striking strip contains red phosphorus, which ignites the match head. The principal use of sodium chlorate is as a source of chlorine dioxide, ClO2. The chlorine in ClO2 has oxidation number ϩ4, and so the chlorate must be reduced to form it. Sulfur dioxide is a convenient reducing agent for this reaction: 2 NaClO3(aq) ϩ SO2(g) ϩ H2SO4(aq, dilute) 2 NaHSO4(aq) ϩ 2 ClO2(g) Chlorine dioxide has an odd number of electrons and is a paramagnetic yellow gas. Despite the environmental damage it creates, it is often used to bleach paper pulp, because it can oxidize the various pigments in the pulp without degrading the wood fibers. The perchlorates, ClO4 Ϫ (oxidation state ϩ7), are prepared by electrolytic oxidation of aqueous chlorates: ClO3 Ϫ (aq) ϩ H2O(l) ClO4 Ϫ (aq) ϩ 2 Hϩ (aq) ϩ 2 eϪ Perchloric acid, HClO4, is prepared by the action of concentrated hydrochloric acid on sodium perchlorate, followed by distillation. It is a colorless liquid and the strongest of all common acids. Because chlorine has its highest oxidation number, ϩ7, in these compounds, they are powerful oxidizing agents; contact between perchloric acid and even a small amount of organic material can result in a dangerous explosion. One spectacular example of the oxidizing ability of perchlorates is their use in the booster rockets of space shuttles. The solid propellant consists of aluminum powder (the fuel), ammonium perchlorate (the oxidizing agent as well as a fuel), and iron(III) oxide (the catalyst). These reactants are mixed into a liquid polymer, which sets to a solid inside the rocket shell. A variety of products can form when the mixture is ignited. One of the reactions is 3 NH4ClO4(s) ϩ 3 Al(s) Fe2O3 ®®®B Al2O3(s) ϩ AlCl3(s) ϩ 6 H2O(g) ϩ 3 NO(g) The solid products form the thick clouds of white powder emitted by the solid rocket boosters during liftoff (Fig. 15.54). Self-Test 15.17A Which oxoacid of bromine is (a) the strongest acid? (b) the strongest oxidizing agent? Explain your answers. [Answer: For both (a) and (b), HBrO4, because it has the most O atoms] Self-Test 15.17B How does pH affect the oxidizing power of HClO3? The interhalogens have properties intermediate between those of the constituent halogens. Nonmetals form covalent halides; metals tend to form ionic halides. The oxoacids of chlorine are all oxidizing agents; both acidity and oxidizing strength of oxoacids increase as the oxidation number of the halogen increases. ¡ ¡ 658 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.54 The white smoke emitted by the shuttle booster rockets consists of powdered aluminum oxide and aluminum chloride. GROUP 18/VIII: THE NOBLE GASES The elements in Group 18/VIII, the noble gases, get their group name from their very low reactivity (Table 15.12). Experiments on the gases and, later, recognition of their closed-shell electron configurations (ns2 np6 ) prompted the belief that these elements were chemically inert. Indeed, no compounds of the noble gases were known until 1962. That year, the British chemist Neil Bartlett synthesized the first noble-gas compound, xenon hexafluoroplatinate, XePtF6. Soon after, chemists at Argonne National Laboratory made xenon tetrafluoride, XeF4, from a high-temperature mixture of xenon and fluorine. 15.24 The Group 18/VIII Elements All the Group 18/VIII elements occur in the atmosphere as monatomic gases; together they make up about 1% of its mass. Argon is the third most abundant gas in the atmosphere after nitrogen and oxygen (discounting the variable amount of water vapor). All the noble gases except helium and radon are obtained by the fractional distillation of liquid air. Helium, the second most abundant element in the universe after hydrogen, is rare on Earth because its atoms are so light that a large proportion of them reach high speeds and escape from the atmosphere; unlike hydrogen, they cannot be anchored to compounds. However, helium is found as a component of natural gases trapped under rock formations (notably in Texas), where it has collected as a result of the emission of ␣ particles by radioactive elements. An ␣ particle is a helium-4 nucleus (4 He2ϩ ), and an atom of the element forms when the particle picks up two electrons from its surroundings. Helium gas is twice as dense as hydrogen under the same conditions. Nevertheless, because its density is still very low and it is nonflammable, it is used to provide buoyancy in airships such as blimps. Helium is also used to dilute oxygen for use in hospitals and in deep-sea diving, to pressurize rocket fuels, as a coolant, and in helium–neon lasers. The element has the lowest boiling point of any substance (4.2 K), and it does not freeze to a solid at any temperature unless pressure is applied to hold the light, mobile atoms together. These properties and its chemical inertness make helium useful for cryogenics, the study of matter at very low temperatures, such as those used for the study of superconductivity (Section 6.14). Helium is the only substance known to have more than one liquid phase. Its phase diagram indicates the temperature and pressure ranges over which each phase is stable (Fig. 15.55). Below 2 K, liquid helium-II shows the remarkable property of superfluidity, the ability to flow without viscosity. Neon, which emits an orange-red glow when an electric current flows through it, is widely used in advertising signs and displays (Fig. 15.56). Argon is used to provide an inert atmosphere for welding (to prevent oxidation) and to fill some types of light bulbs, where it conducts heat away from the filament. Krypton gives an intense white light when an electric discharge is passed through it, and so it is used in airport runway lighting. Because krypton is produced by nuclear fission, its atmospheric abundance is one measure of 15.24 THE GROUP 18/VIII ELEMENTS 659 TABLE 15.12 The Group 18/VIII Elements (the Noble Gases) Valence configuration: ns2 np6 Normal form: colorless monatomic gas Molar mass Melting point Boiling point Z Name Symbol (gؒmol؊1 ) (°C) (°C) 2 helium He 4.00 — Ϫ269 (4.2 K) 10 neon Ne 20.18 Ϫ249 Ϫ246 18 argon Ar 39.95 Ϫ189 Ϫ186 36 krypton Kr 83.80 Ϫ157 Ϫ153 54 xenon Xe 131.29 Ϫ112 Ϫ108 86 radon* Rn (222) Ϫ71 Ϫ62 *Radioactive. Temperature (K) 3 62 51 4 Gas Solid Liquid (helium-II) Liquid (helium-I) 100 10 Pressure(atm) 0.01 0.1 1 FIGURE 15.55 The phase diagram for helium-4 shows the two liquid phases of helium. Helium-II, the low-temperature liquid phase, is a superfluid. worldwide nuclear activity. Xenon is used in halogen lamps for automobile headlights and in high-speed photographic flash tubes; it is also being investigated as an anesthetic. The radioactive gas radon seeps out of the ground as a product of radioactive decay processes deep in the Earth. There is now some concern that its accumulation in buildings and its nuclear decay products can lead to dangerously high levels of radiation. The noble gases are all found naturally as unreactive monatomic gases. Helium has two liquid phases; the lower-temperature liquid phase exhibits superfluidity. 15.25 Compounds of the Noble Gases The ionization energies of the noble gases are very high but decrease down the group (Fig. 15.57). Xenon’s ionization energy is low enough for electrons to be lost to very electronegative elements. No compounds of helium, neon, and argon exist, except under very special conditions, such as the capture of atoms of He and Ne inside a buckminsterfullerene cage. Krypton forms only one known stable neutral molecule, KrF2. In 1988, a compound with a KrßN bond was reported, but it is stable only below Ϫ50°C. This leaves xenon as the noble gas with the richest chemistry. It forms several compounds with fluorine and oxygen, and compounds with XeßN and XeßC bonds have been reported, such as (C6F5)2Xe. The starting point for the synthesis of xenon compounds is the preparation of xenon difluoride, XeF2, and xenon tetrafluoride, XeF4, by heating a mixture of the elements to 400°C at 6 atm. At higher pressures, fluorination proceeds as far as xenon hexafluoride, XeF6. All three fluorides are crystalline solids (Fig. 15.58). In the gas phase, all are molecular compounds. Solid xenon hexafluoride, however, is ionic, with a complex structure consisting of XeF5 ϩ cations bridged by FϪ anions. The xenon fluorides are used as powerful fluorinating agents (reagents for attaching fluorine atoms to other substances). The tetrafluoride will even fluorinate platinum metal: Pt(s) ϩ XeF4(s) Xe(g) ϩ PtF4(s) The xenon fluorides are used to prepare the xenon oxides and oxoacids and, in a series of disproportionations, to bring the oxidation number of xenon up to ϩ8. First, xenon tetrafluoride is hydrolyzed to xenon trioxide, XeO3 in a disproportionation reaction: 6 XeF4(s) ϩ 12 H2O(l) 2 XeO3(aq) ϩ 4 Xe(g) ϩ 3 O2(g) ϩ 24 HF(aq)¡ ¡ 660 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS FIGURE 15.56 The colors of this fluorescent lighting art by Tom Anthony are due to emission from noble-gas atoms. Neon is responsible for the red light; when it is mixed with a little argon, the color becomes blue-green. The yellow color is achieved by coating the inside of the glass with phosphors that give off yellow light when excited. He Ne Ar Kr Xe Rn 2370 2080 1520 1350 1170 1036 FIGURE 15.57 The ionization energies of the noble gases decrease steadily down the group. The values shown are in kilojoules per mole. FIGURE 15.58 Crystals of xenon tetrafluoride, XeF4. This compound was first prepared in 1962 by the reaction of xenon and fluorine at 6 atm and 400°C. Xenon trioxide, XeO3 (24), is the anhydride of xenic acid, H2XeO4 (25). It reacts with aqueous alkali to form a hydrogen xenate ion, HXeO4 Ϫ . This ion slowly disproportionates into xenon and the octahedral perxenate ion, XeO6 4Ϫ (26), in which the oxidation number of xenon is ϩ8. Aqueous perxenate solutions are yellow and are very powerful oxidizing agents as a result of the high oxidation number of xenon. When barium perxenate is treated with sulfuric acid, it is dehydrated to the anhydride of perxenic acid, xenon tetroxide, XeO4 (27), an explosively unstable gas. Xenon is the only noble gas known to form an extensive series of compounds with fluorine and oxygen; xenon fluorides are powerful fluorinating agents and xenon oxides are powerful oxidizing agents. Self-Test 15.18A Explain why the ease of compound formation increases down Group 18/VIII. [Answer: Ionization energy decreases down the group, and so it is easier for the heavier elements to share their electrons.] Self-Test 15.18B Predict the shape of the XeOF4 molecule. EXERCISES 661 24 Xenon trioxide, XeO3 25 Xenic acid, H2XeO4 26 Perxenate ion, XeO6 4Ϫ 4Ϫ 27 Xenon tetroxide, XeO4 ❑ 1 Predict and explain trends in the properties and formulas of the main-group elements. ❑ 2 Describe the names, properties, and reactions of the principal compounds of hydrogen and the Period 1 through 3 main group elements. ❑ 3 Describe and write balanced equations for the principal reactions used to produce hydrogen and the Period 1 through 3 main group elements. ❑ 4 Describe the major uses of hydrogen, sodium, potassium, beryllium, magnesium, boron, aluminum, carbon, and silicon. ❑ 5 Describe the reactions of the alkali metals with water and with nonmetals. ❑ 6 Distinguish the allotropes of carbon by their structures. ❑ 7 Explain the differences in reactivity between compounds of carbon and those of silicon. ❑ 8 Rationalize the properties of the oxides and oxoacids of the nonmetals in terms of the oxidation number of the nonmetal and the identification of acid anhydrides. ❑ 9 Describe how nitrogen is obtained from air and converted into useful compounds. ❑ 10 Describe the structures and properties of the nitrogen, phosphorus, and sulfur oxides. ❑ 11 Describe the acidic and basic character of water and hydrogen peroxide and compare their functions as oxidizing and reducing agents. ❑ 12 Explain the low reactivity of the noble gases and the fact that the ease of compound formation increases down the group. SKILLS YOU SHOULD HAVE MASTERED Periodic Trends These exercises are a review of principles covered in Chapter 1. See also Exercises 1.87–1.96. 15.1 State which atom of each of the following pairs is larger: (a) fluorine, nitrogen; (b) potassium, calcium; (c) gallium, arsenic; (d) chlorine, iodine. 15.2 State which atom of each of the following pairs is larger: (a) tellurium, tin; (b) silicon, lead; (c) calcium, rubidium; (d) germanium, oxygen. 15.3 State which atom of each of the following pairs is more electronegative: (a) sulfur, phosphorus; (b) selenium, tellurium; (c) sodium, cesium; (d) silicon, oxygen. EXERCISES 662 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 15.4 State which atom of each of the following pairs is less electronegative: (a) potassium, rubidium; (b) germanium, bromine; (c) oxygen, selenium; (d) aluminum, silicon. 15.5 Arrange the following atoms in order of increasing first ionization energy: oxygen, tellurium, selenium. 15.6 Arrange the following atoms in order of increasing first ionization energy: boron, thallium, gallium. 15.7 (a) Which atom has the greater electron affinity: phosphorus or antimony? (b) Explain your answer. 15.8 (a) Which atom has the greater electron affinity: germanium or selenium? (b) Explain your answer. 15.9 (a) Which of the following species has the greatest polarizability: chloride ions, bromine atoms, bromide ions? (b) Explain your answer. 15.10 (a) Which of the following species has the greatest polarizing power: rubidium ions, potassium atoms, sodium ions? (b) Explain your answer. Bonding Trends 15.11 Write the balanced equation for the reaction between potassium and hydrogen. 15.12 Write the balanced equation for the reaction between calcium and hydrogen. 15.13 Classify each of the following compounds as a saline, molecular, or metallic hydride: (a) LiH; (b) NH3; (c) HBr; (d) UH3. 15.14 Classify each of the following compounds as a saline, molecular, or metallic hydride: (a) B2H6; (b) SiH4; (c) CaH2; (d) PdHx, x Ͻ 1. 15.15 For each of the following oxides, state whether the compound is acidic, basic, or amphoteric: (a) NO2; (b) Al2O3; (c) B(OH)3; (d) MgO. 15.16 For each of the following oxides, state whether the compound is acidic, basic, or amphoteric: (a) Li2O; (b) Tl2O3; (c) Sb2O3; (d) SO3. 15.17 Give the formula for the formal anhydride of each acid: (a) H2CO3; (b) B(OH)3. 15.18 Give the formula for the acid corresponding to each of the following formal anhydrides: (a) N2O5; (b) P4O10; (c) SeO3. Hydrogen 15.19 Write a balanced chemical equation for (a) the hydrogenation of ethyne (acetylene, C2H2) to ethene (C2H4) by hydrogen (give the oxidation number of the carbon atoms in the reactant and product); (b) the shift reaction (sometimes called the water gas shift reaction, WGSR); (c) the reaction of barium hydride with water. 15.20 Write a balanced chemical equation for (a) the reaction between sodium hydride and water; (b) the formation of synthesis gas; (c) the hydrogenation of ethene, H2C≈CH2, and give the oxidation number of the carbon atoms in the reactant and product; (d) the reaction of magnesium with hydrochloric acid. 15.21 Identify the products and write a balanced equation for the reaction of hydrogen with (a) chlorine; (b) sodium; (c) phosphorus; (d) copper metal. 15.22 Identify the products and write a balanced equation for the reaction of hydrogen with (a) nitrogen; (b) fluorine; (c) cesium; (d) copper(II) ions. 15.23 The enthalpy of dissociation of hydrogen bonds, ⌬HHBond, is a measure of their strength. Explain the trend seen in the data for the following pure substances, which were measured in the gas phase: Substance NH3 H2O HF ⌬HHBond (kJؒmol؊1 ) 17 25 29 15.24 Methanoic acid, HCOOH, forms dimers in the gas phase. Propose a reason for this behavior. Group 1: The Alkali Metals 15.25 Explain why lithium differs from the other Group 1 elements in its chemical and physical properties. Give two examples to support your explanation. 15.26 (a) Write the valence electron configuration for the alkali metal atoms. (b) Explain why the alkali metals are strong reducing agents in terms of electron configurations, ionization energies, and the hydration of their ions. 15.27 Write the chemical equation for the reaction between (a) sodium and oxygen; (b) lithium and nitrogen; (c) sodium and water; (d) potassium superoxide and water. 15.28 Write the chemical equation for the reaction between (a) cesium and oxygen (cesium reacts with oxygen in the same way as potassium); (b) sodium oxide and water; (c) lithium and hydrochloric acid; (d) cesium and iodine. Group 2: The Alkaline Earth Metals 15.29 Write the chemical equation for the reaction between magnesium metal and hot water. 15.30 Write the chemical equation for the reaction between barium metal and hydrogen gas. 15.31 The compounds CaO and BaO are sometimes used as drying agents for organic solvents such as pyridine, C5H5N. The drying agent and the product of the drying reaction are both insoluble in the organic solvent. (a) Write the balanced chemical equation corresponding to the reaction that dries the solvent. (b) For CaO, determine the standard Gibbs free energy of the drying reaction. 15.32 Aluminum and beryllium have a diagonal relationship. Compare the chemical equations for the reaction of aluminum with aqueous sodium hydroxide to that of beryllium with aqueous sodium hydroxide. 15.33 Predict the products of each of the following reactions and then balance each equation: (a) Mg(OH)2 + HCl(aq) : (b) Ca(s) + H2O(l) : (c) BaCO3(s) : 15.34 Predict the products of each of the following reactions and then balance each equation: (a) Mg(s) + Br2(l) : (b) BaO(s) ϩ Al(s) : (c) CaO(s) ϩ SiO2(s) : EXERCISES 663 15.35 (a) Write the Lewis structures for BeCl2 and MgCl2. How does the Lewis structure of MgCl2 differ from that of BeCl2? (b) Predict the Cl—Be—Cl bond angle. (c) What hybrid orbitals are used in the bonding in BeCl2? 15.36 In the gas phase, BeCl2 forms a dimer by forming chlorineatom bridges like those in the AlCl3 dimer. Draw the Lewis structure for the BeCl2 dimer and assign formal charges. Group 13/III: The Boron Family 15.37 Write a balanced equation for the industrial preparation of aluminum from its oxide. 15.38 Write a balanced equation for the industrial preparation of impure boron. 15.39 Complete and balance the following skeletal equations: (a) B2O3(s) ϩ Mg(l) : (b) Al(s) ϩ Cl2(g) : (c) Al(s) ϩ O2(g) : 15.40 Complete and balance the following skeletal equations: (a) Al2O3(s) ϩ OHϪ (aq) : (b) Al2O3(s) ϩ H3Oϩ (aq) ϩ H2O(l) : (c) B(s) ϩ NH3(g) : 15.41 Suggest a Lewis structure for B4H10 and deduce the formal charges on the atoms. Hint: There are four BßHßB bridges. 15.42 The diatomic molecule BF can be obtained by the reaction between BF3 and B at a high temperature and low pressure. (a) Determine the electron configuration of the molecule in terms of the occupied molecular orbitals and calculate the bond order. (b) CO is isoelectronic with BF. How do the molecular orbitals in the two molecules differ? 15.43 Many gallium compounds have structures that are similar to those of the corresponding aluminum and boron compounds. Draw the Lewis structure and describe the shape of GaBr4 Ϫ . 15.44 Many gallium compounds have structures that are similar to those of the corresponding aluminum and boron compounds. Draw the Lewis structure and describe the shape of Ga2Cl6. Group 14/IV: The Carbon Family 15.45 Describe the sources of silicon and write balanced equations for the three steps in the industrial preparation of silicon. 15.46 Explain why the size of the silicon atom does not permit a silicon analog of the graphite structure. 15.47 Identify the oxidation number of germanium in the following compounds and ions: (a) GeO4 4Ϫ ; (b) K4Ge4Te10; (c) Ca3GeO5. 15.48 Identify the oxidation number of tin in the following compounds and ions: (a) Sn3(OH)4 2ϩ ; (b) K2SnO3; (c) K2Sn3O7. 15.49 Balance the following skeletal equations and classify them as acid–base or redox: (a) MgC2(s) ϩ H2O(l) : C2H2(g) ϩ Mg(OH)2(s) (b) Pb(NO)2(s) : PbO(s) ϩ NO2(g) ϩ O2(g) 15.50 Balance the following skeletal equations and classify them as acid–base or redox: (a) CH4(g) ϩ S8(s) : CS2(l) ϩ H2S(g) (b) Sn(s) ϩ KOH(aq) ϩ H2O(l) : K2Sn(OH)6(aq) ϩ H2(g) 15.51 Determine the values of ⌬Hr°, ⌬Sr°, and ⌬Gr° for the production of high-purity silicon by the reaction SiO2(s) ϩ 2 C(s, graphite) : Si(s) ϩ 2 CO(g) at 25°C and estimate the temperature at which the equilibrium constant becomes greater than 1. 15.52 Determine the values of ⌬Hr°, ⌬Sr°, and ⌬Gr° for the reaction 2 CO(g) ϩ O2(g) : 2 CO2(g) at 25°C and estimate the temperature at which the equilibrium constant becomes less than 1. Group 15/V 15.53 Nitrogen can be found in compounds with oxidation numbers ranging from Ϫ3 to ϩ5. For each of the possible integral oxidation numbers, give one example of a nitrogen compound or ion. 15.54 Give the oxidation number of phosphorus in (a) white phosphorus; (b) red phosphorus; (c) phosphine, PH3; (d) diphosphine, P2H4; (e) PCl3; (f) PF5; (g) phosphate ion, PO4 3Ϫ ; (h) hydrogen phosphite ion, HPO3 2Ϫ . 15.55 Urea, CO(NH2)2, reacts with water to form ammonium carbonate. Write the chemical equation and calculate the mass of ammonium carbonate that can be obtained from 4.0 kg of urea. 15.56 (a) Nitrous acid reacts with hydrazine in acidic solution to form hydrazoic acid, HN3. Write the chemical equation and determine the mass of hydrazoic acid that can be produced from 15.0 g of hydrazine. (b) Suggest a method for preparing sodium azide, NaN3. (c) Is the production of hydrazoic acid an oxidation or a reduction of hydrazine? 15.57 Lead azide, Pb(N3)2, is used as a detonator. (a) What volume of nitrogen at STP (1 atm, 0°C) does 1.5 g of lead azide produce when it decomposes into lead metal and nitrogen gas? (b) Would 1.5 g of mercury(II) azide, Hg(N3)2, which is also used as a detonator, produce a larger or smaller volume, given that its decomposition products are elemental mercury and nitrogen gas? (c) Metal azides in general are potent explosives. Why? 15.58 Sodium azide is used to inflate protective air bags in automobiles. What mass of solid sodium azide is needed to provide 100. L of N2(g) at 1.5 atm and 20.°C? 15.59 The common acid anhydrides of nitrogen are N2O, N2O3, and N2O5. Write the formulas of their corresponding acids and chemical equations for the formation of the acids by the reaction of the anhydrides with water. 15.60 The common acid anhydrides of phosphorus are P4O6 and P4O10. Write the formulas of their corresponding acids and chemical equations for the formation of the acids by the reaction of the anhydrides with water. 15.61 The normal boiling point of NH3 is Ϫ33°C and that of NF3, which has a greater molar mass, is Ϫ129°C. Explain this difference. 15.62 Explain the observations that NH3 is a weak Brønsted base in water whereas NF3 shows no signs of basicity. Group 16/VI 15.63 Write equations for (a) the burning of lithium in oxygen; (b) the reaction of sodium metal with water; (c) the reaction of fluorine gas with water; (d) the oxidation of water at the anode of an electrolytic cell. ⌬ 15.64 Write equations for the reaction of (a) sodium oxide and water; (b) sodium peroxide and water; (c) sulfur dioxide and water; (d) sulfur dioxide and oxygen, with the use of a vanadium pentoxide catalyst. 15.65 Complete and balance each of the following skeletal equations: (a) H2S(aq) ϩ O2(g) : (b) CaO(s) ϩ H2O(l) : (c) H2S(g) ϩ SO2(g) : 15.66 Complete and balance each of the following skeletal equations: (a) FeS(s) ϩ HCl(aq) : (b) H2(g) ϩ S8(s) : (c) BrϪ ϩ Cl2(g) : 15.67 Explain from structural considerations why the dipole moment of the NH3 molecule is lower than that of the H2O molecule. 15.68 Explain from structural considerations why water and hydrogen peroxide have similar physical properties but different chemical properties. 15.69 (a) Write the Lewis structure of H2O2 and predict the approximate H—O—O bond angle. Which of the following ions will be oxidized by hydrogen peroxide in acidic solution: (b) Cuϩ ; (c) Mn2ϩ ; (d) Agϩ ; (e) FϪ ? 15.70 (a) Draw the Lewis structure for oleum, (HO)2OSOSO(OH)2, prepared by treating sulfuric acid with SO3. (b) Determine the formal charges on the sulfur and oxygen atoms. (c) What is the oxidation number for sulfur in this compound? 15.71 If 2.00 g of sodium peroxide is dissolved to form 200. mL of an aqueous solution, what would be the pH of the solution? For H2O2, Ka1 ϭ 1.8 ϫ 10Ϫ12 and Ka2 is negligible. 15.72 What is the pH of 0.040 M NaHS(aq)? 15.73 Describe the trend in acidity of the binary hydrogen compounds of the Group 16/VI elements and account for the trend in terms of bond strength. 15.74 When lead(II) sulfide is treated with hydrogen peroxide, the possible products are either lead(II) sulfate or lead(IV) oxide and sulfur dioxide. (a) Write balanced equations for the two reactions. (b) Using data available in Appendix 2A, determine which possibility is more likely. Group 17/VII 15.75 Identify the oxidation number of the halogen in (a) hypoiodous acid; (b) ClO2; (c) dichlorine heptoxide; (d) NaIO3. 15.76 Identify the oxidation number of the halogen atoms in (a) iodine heptafluoride; (b) sodium periodate; (c) hypobromous acid; (d) sodium chlorite. 15.77 Write the balanced chemical equation for (a) the thermal decomposition of potassium chlorate without a catalyst; (b) the reaction of bromine with water; (c) the reaction between sodium chloride and concentrated sulfuric acid. (d) Identify each reaction as a Brønsted acid–base, Lewis acid–base, or redox reaction. 15.78 Write the balanced chemical equation for the reaction of chlorine with water in (a) a neutral aqueous solution; (b) a dilute basic solution; (c) a concentrated basic solution. (d) Verify that each reaction is a disproportionation reaction. 15.79 (a) Arrange the chlorine oxoacids in order of increasing oxidizing strength. (b) Suggest an interpretation of that order in terms of oxidation numbers. 15.80 (a) Arrange the hypohalous acids in order of increasing acid strength. (b) Suggest an interpretation of that order in terms of electronegativities. 15.81 Write the Lewis structure for Cl2O. Predict the shape of the Cl2O molecule and estimate the ClßOßCl bond angle. 15.82 Write the Lewis structure for BrF3. What is the hybridization of the bromine atom in the molecule? 15.83 Suggest reasons why the following interhalogens are not stable: (a) ICl5; (b) IF2; (c) ClBr3. 15.84 Chlorine can be found as the following oxoanions: ClO– , ClO2 Ϫ , ClO3 Ϫ , and ClO4 Ϫ in many chemical stockrooms. However, fluorine forms no stable oxoanions and iodine is never found as IO4 Ϫ . Explain these observations. 15.85 The interhalogen IFx can be made only by indirect routes. For example, xenon difluoride gas can react with iodine gas to produce IFx and xenon gas. In one experiment, xenon difluoride is introduced into a rigid container until a pressure of 3.6 atm is reached. Iodine vapor is then introduced until the total pressure is 7.2 atm. Reaction is then allowed to proceed at constant temperature until completion by solidifying the IFx as it is produced. The final pressure in the flask due to the xenon and excess iodine vapor is 6.0 atm. (a) What is the formula of the interhalogen? (b) Write the chemical equation for its formation. 15.86 The interhalogen ClFx has been used as a rocket fuel. It reacts with hydrazine to form the gases hydrogen fluoride, nitrogen, and chlorine. In one study of this reaction, ClFx gas is introduced into a rigid container until a pressure of 1.2 atm is reached. Gaseous hydrazine is then introduced until the total pressure is 3.0 atm. Reaction is then allowed to proceed at constant temperature until completion. The final pressure in the flask is 6.0 atm, which includes 0.9 atm due to excess hydrazine. (a) What is the formula of the interhalogen? (b) Write the chemical equation for its reaction with hydrazine. 15.87 Use data from Appendix 2B to determine whether chlorine gas will oxidize Mn2ϩ to form the permanganate ion in an acidic solution. 15.88 (a) Use the data in Appendix 2B to determine which is the stronger oxidizing agent, ozone or fluorine. (b) Does your answer depend on whether the reaction is carried out in acidic or basic solution? 15.89 The concentration of FϪ ions can be measured by adding an excess of lead(II) chloride solution and weighing the lead(II) chlorofluoride (PbClF) precipitate. Calculate the molar concentration of FϪ ions in 25.00 mL of a solution that gave a lead chlorofluoride precipitate of mass 0.765 g. 15.90 Suppose 25.00 mL of an aqueous solution of iodine was titrated with 0.0250 M Na2S2O3(aq), with starch as the indicator. The blue color of the starch–iodine complex disappeared when 27.65 mL of the thiosulfate solution had been added. What was the molar concentration of I2 in the original solution? The titration reaction is I2(aq) ϩ 2 S2O3 2Ϫ (aq) : 2 IϪ (aq) ϩ S4O6 2Ϫ (aq). 664 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 15.91 Calculate the heat released when ammonium perchlorate (1.00 kg) reacts with aluminum powder (1.00 kg) as rocket fuel: 3 NH4ClO4(s) ϩ 3 Al(s) : Al2O3(s) ϩ AlCl3(s) ϩ 6 H2O(g) ϩ 3 NO(g). 15.92 (a) Using data available in the Appendices, calculate the standard Gibbs free energy of the reaction Cl2(g) ϩ H2O(l) : HClO(aq) ϩ HCl(aq) at 298 K. (b) What is the equilibrium constant for this process? Group 18/VIII 15.93 What are the sources for the production of helium and argon? 15.94 What are the sources for the production of krypton and xenon? 15.95 Determine the oxidation number of the noble gas in (a) KrF2; (b) XeF6; (c) KrF4; (d) XeO4 2Ϫ . 15.96 Determine the oxidation number of the noble gas in (a) XeO3; (b) XeO6 4Ϫ ; (c) XeF2; (d) HXeO4 Ϫ . 15.97 Xenon tetrafluoride is a powerful oxidizing agent. In an acidic solution, it is reduced to xenon. Write the corresponding half-reaction. 15.98 Complete and balance each of the following reactions: (g) XeF6(s) ϩ H2O(l) : XeO3(aq) ϩ HF(aq) (h) Pt(s) ϩ XeF4(s) : (i) Kr(g) ϩ F2(g) electric discharge ®®®®®®®B 15.99 Predict the relative acid strengths of H2XeO4 and H4XeO6. Explain your conclusions. 15.100 Predict the relative oxidizing strengths of H2XeO4 and H4XeO6. Explain your conclusions. Integrated Exercises 15.101 (a) Using graphing software, such as that on the Web site for this book, plot standard potential against atomic number for the elements of Groups 1 and 2 (refer to Appendix 2B for data). (b) What generalizations can be deduced from the graph? 15.102 Using graphing software, such as that on the Web site for this book, and data from Appendix 2B, plot ionization energy against standard potential for the elements of Groups 1 and 2. What generalizations can be drawn from the graph? 15.103 Is there any chemical support for the view that hydrogen should be classified as a member of Group 1? Would it be better to consider hydrogen a member of Group 17/VII? Give evidence that supports each view. 15.104 What justification is there for regarding the ammonium ion as an analog of a Group 1 metal cation? Consider properties such as solubility, charge, and radius. The radius of NH4 ϩ is 151 pm. 15.105 Hydrogen burns in an atmosphere of bromine to give hydrogen bromide. If 135 mL of H2 gas at 273 K and 1.00 atm combines with a stoichiometric amount of bromine and the resulting hydrogen bromide dissolves to form 225 mL of an aqueous solution, what is the molar concentration of the resulting hydrobromic acid solution? 15.106 The saline hydrides all react rapidly with water. They also react similarly with liquid ammonia. (a) Write a balanced equation for the reaction of CaH2 with liquid ammonia. (b) Would it be best to classify this reaction as redox, Brønsted acid–base, or Lewis acid–base? Explain your answer. 15.107 Infrared radiation is absorbed only when there is a change in the dipole moment of the molecule as the molecule vibrates. Which of the following gases found in the atmosphere can absorb in the infrared region and so function as greenhouse gases: (a) CO; (b) NH3; (c) CF4; (d) O3; (e) Ar? Explain your reasoning. See Box 15.1. 15.108 Carbon dioxide absorbs infrared energy during bending or stretching motions that are accompanied by a change in dipole moment (from zero). Which of the transitions pictured in Fig. 2b of Major Technique 1, following Chapter 2, can absorb infrared radiation? Explain your reasoning. See Box 15.1. 15.109 Methanol, CH3OH, is a clean-burning liquid fuel being considered as a replacement for gasoline. Calculate the theoretical yield in kilograms of CO2 produced by the combustion of 1.00 L of methanol (of density 0.791 g·cmϪ3 ) and compare it with the 2.16 kg of CO2 generated by the combustion of 1.00 L of octane. Which fuel contributes more CO2 per liter to the atmosphere when burned? What other factors would you take into consideration when deciding which of the two fuels to use? See Box 15.1. 15.110 The standard enthalpy of formation of SiCl4(g) is Ϫ662.75 kJ·molϪ1 and its standard molar entropy is ϩ330.86 JиKϪ1 иmolϪ1 . Calculate the temperature at which the reduction of SiCl4(g) with hydrogen gas to Si(s) and HCl(g) becomes spontaneous. 15.111 (a) Examine the structures of diborane, B2H6, and Al2Cl6. Compare the bonding in these two compounds. How are they similar? (b) What are the differences, if any, in the types of bonds formed? (c) What is the hybridization of the Group 13/III element? (d) Are the molecules planar? If not, describe their shapes. 15.112 (a) Draw the Lewis structure and assign a hybridization scheme to the atoms in the P4 molecule. (b) Explain why the bonds in this molecule are thought to be strained. 15.113 Like elements, molecules have ionization energies. (a) Define the ionization energy of a molecule. (b) Predict which of these compounds has a higher ionization energy and justify your prediction: SiCl4 or SiI4. 15.114 Isoelectronic species have the same number of electrons. (a) Divide the following species into two isoelectronic groups: CNϪ , N2, NO2 Ϫ , C2 2Ϫ , O3. Which species in each group is likely to be (b) the strongest Lewis base; (c) the strongest reducing agent? 15.115 Isoelectronic species have the same number of electrons. (a) Divide the following species into three isoelectronic groups: NH3, NO, NO2 ϩ , N2O, H3Oϩ , O2 ϩ . (b) Which species in each group is likely to be (b) the strongest Lewis acid; (c) the strongest oxidizing agent? 15.116 The ground state of O2 has two unpaired ␲* electrons with parallel spins. There are two known low-lying excited states of O2. State A has the two ␲* electrons with the spins antiparallel but in different orbitals. State B has the two ␲* electrons paired in the same orbital. (a) The energies of the excited states are 94.72 kJиmolϪ1 and 157.85 kJ·molϪ1 above the ground state. Which state corresponds to which excitation energy? (b) What is the wavelength of the radiation absorbed in the transition from the ground state to the first excited state? EXERCISES 665 15.117 Thiosulfuric acid, H2S2O3, has a structure similar to that of sulfuric acid, except that the terminal oxygen atom has been replaced by a sulfur atom. How would you expect the physical and chemical properties of thiosulfuric acid and sulfuric acid to differ? 15.118 The concentration of ClϪ ions can be measured gravimetrically by precipitating silver chloride, with silver nitrate as the precipitating reagent in the presence of dilute nitric acid. The white precipitate is filtered off and its mass is determined. (a) Calculate the ClϪ ion concentration in 50.00 mL of a solution that gave a silver chloride precipitate of mass 1.972 g. (b) Why is the method inappropriate for measuring the concentration of fluoride ions? 15.119 Xenon fluorides are used as fluorinating agents for organic and inorganic compounds. Xenon tetrafluoride reacts with sulfur tetrafluoride to produce sulfur hexafluoride and xenon. What mass of sulfur hexafluoride can be produced from 330.0 g of xenon tetrafluoride and 250.0 g of sulfur tetrafluoride? 15.120 (a) When Xe and Pt are treated with fluorine gas under pressure at 200°C, the ionic solid XeF5 ϩ PtF6 Ϫ is formed. Write the Lewis structure for XeF5 ϩ and, from VSEPR theory, predict its shape. (b) When two molecules of XeF2 react with one molecule of AsF5, the resulting compound has the formula Xe2F3 ϩ AsF6 Ϫ . Predict the Lewis structure of the Xe2F3 ϩ ion. 15.121 (a) Consider the substances shown in parts (a), (c), and (d) in the second illustration in Box 15.2. (b) In which of these three parts of the figure will the interactions be the strongest? (c) In which will they be the weakest? 15.122 Chapter 15 has been organized by group. Discuss whether it would be helpful to organize the elements according to period and give examples of trends that could be displayed helpfully in that way. 15.123 The azide ion has an ionic radius of 148 pm and forms many ionic and covalent compounds that are similar to those of the halides. (a) Write the Lewis formula for the azide ion and predict the NßNßN bond angle. (b) On the basis of its ionic radius, where in Group 17/VII would you place the azide ion? (c) Compare the acidity of hydrazoic acid with those of the hydrohalic acids and explain any differences (for HN3, Ka ϭ 1.7 ϫ 10Ϫ5 ). (d) Write the formulas of three ionic or covalent azides. 15.124 The concentration of nitrate ion can be determined by a multistep process. A 25.00-mL sample of water from a rural well contaminated with NO3 Ϫ (aq) was made basic and treated with an excess of zinc metal, which reduces the nitrate ion to aqueous ammonia. The evolved ammonia gas was passed into 50.00 mL of 2.50 ϫ 10Ϫ3 M HCl(aq). The unreacted HCl(aq) was titrated to the stoichiometric point with 28.22 mL of 1.50 ϫ 10Ϫ3 M NaOH(aq). (a) Write balanced chemical equations for the three reactions. (b) What is the molar concentration of nitrate ion in the well water? 15.125 Account for the observation that solubility in water generally increases from chloride to iodide for ionic halides with low covalent character (such as the potassium halides) but decreases from chloride to iodide for ionic halides in which the bonds are significantly covalent (such as the silver halides). 15.126 Account for the observation that melting and boiling points generally decrease from fluoride to iodide for ionic halides but increase from fluoride to iodide for molecular halides. 15.127 The nitrosyl ion, NOϩ , is isoelectronic with N2 and has two fewer electrons than O2. The ion is stable and can be purchased as its hexafluorophosphate (PF6 Ϫ ) or tetrafluoroborate (BF4 Ϫ ) salt. (a) Draw its molecular orbital diagram and compare it with those of N2 and O2. (b) NOϩ is diamagnetic. Can we tell which orbital, the ␴2p or the ␲2p, is higher in energy from this information? 15.128 (a) Draw the molecular orbital energy-level diagram for O2. Using the diagram, determine the bond order and magnetic properties of O2. (b) What molecular property of oxygen is explained by its molecular orbital diagram but not by its Lewis structure? (c) Describe the nature of the highest occupied molecular orbital—is it bonding, antibonding, or nonbonding? (d) Predict the bond order and magnetic properties of the peroxide ion and the superoxide ion on the basis of molecular orbital theory. Chemistry Connections 15.129 The gas NO is released to the stratosphere by jet engines. Because it can contribute to the destruction of stratospheric ozone, its concentration is monitored closely. One monitoring technique measures the chemiluminescence given off by the reaction NO(g) ϩ O3(g) : NO2*(g) ϩ O2(g). The asterisk indicates that NO2 is produced in an excited state. The excited NO2 molecule gives off red light and infrared radiation as it returns to the ground state. Because both NO and NO2 may be present in the air sample, part of the sample is exposed to a reducing agent, which converts all of the NO2 to NO. Two samples are then analyzed, first air from the unreduced original sample, which gives the concentration of NO, then air from the reduced sample. The concentration of NO2 in the air is the difference of the two measurements. In one experiment, two samples were collected, one from a cloud and one from clear air. The following measurements were made at 9 km above the Pacific Ocean (ppt denotes parts per trillion, by molecules): Unreduced sample Reduced sample Cloud: 860 ppt 1110 ppt Clear air: 480 ppt 740 ppt (a) Determine the concentrations (in ppt) of NO and NO2 in each air sample. (b) In which part of the atmosphere is the concentration of NO greater? (c) Explain the difference, taking into account other sources of NO in the atmosphere besides airplanes. (d) Some of the NO molecules released by jet engines react with the hydroxyl radical, ·OH. Write the Lewis structure of the most likely product and state its name. (e) Is the product of the reaction in part (d) likely to be more stable than NO? Explain your reasoning. (f) In the stratosphere NO catalyzes the conversion of O3 to O2 in a two-step reaction with the intermediate NO2. The overall equation for the reaction is O3(g) ϩ O(g) : 2 O2(g) and the rate law for the reaction is Rate ϭ k [NO][O3]. Write an acceptable two-step mechanism for the reaction, indicating which step is the slow step. (g) At Ϫ30°C, the temperature of the air from which the samples were taken, the rate constant for the reaction in part (f) is 6 ϫ 10Ϫ15 cm3 ·moleculeϪ1 ·sϪ1 . If the concentration of ozone in the air from which the NO clear air sample was taken was 4 ϫ 10Ϫ12 molecules·cmϪ3 and the total pressure of the air was 220 mbar, what was the rate at which ozone was being destroyed in the air at Ϫ30°C? 666 CHAPTER 15 THE ELEMENTS: THE MAIN GROUP ELEMENTS 667 What Are the Key Ideas? The properties of the d-block elements are governed by the availability of d-orbitals, their variable valence, and their ability to act as Lewis acids and form a wide variety of complexes. Why Do We Need to Know This Material? The d-block metals are the workhorse elements of the periodic table. Iron and copper helped civilization rise from the Stone Age and are still our most important industrial metals. Other members of the block include the metals of new technologies, such as titanium for the aerospace industry and vanadium for catalysts in the petrochemical industry. The precious metals silver, platinum, and gold are prized as much for their appearance, rarity, and durability as for their usefulness. Compounds of d-block metals give color to paint, turn sunlight into electricity, serve as powerful oxidizing agents, and form the basis of some cancer treatments. What Do We Need to Know Already? This chapter draws on many of the principles introduced in the preceding chapters. In particular, it makes use of the electron configurations of atoms and ions (Sections 1.13 and 2.1) and the classification of species as Lewis acids and bases (Section 11.2). Molecular orbital theory (Sections 3.8 through 3.12) plays an important role in Section 16.12. T he transformation of the past by the Industrial Revolution was made possible by the development of steel, an iron alloy used for construction and transportation. Other d-block metals, both as the elements and in compounds, are transforming our present. Copper, for instance, is an essential component of some superconductors. The d-block metals will also help to shape our future. For example, vanadium and platinum are used in the development of catalysts to reduce pollution and in the continuing effort to make hydrogen a practical and economical fuel. The compounds of the d-block elements show a wide range of interesting properties. Some are vital to life. Iron is an essential component of mammalian blood. Compounds of cobalt, molybdenum, and zinc are found in vitamins and essential enzymes. Other compounds simply make life more interesting and colorful. The beautiful color of cobalt blue glass, the brilliant greens and blues of kiln-baked pottery, and many pigments used by artists make use of d-block compounds. We begin this chapter by summarizing the major periodic trends exhibited by the d-block elements and their compounds. Then we describe some of the properties and key reactions of selected elements. The d-block metals form a wide variety of complexes and, in the second half of the chapter, we describe their shapes and the two principal theories of their electronic structure. Some of the contributions of the d-block metals to the formulation of modern materials have already been described in Chapter 6. THE d-BLOCK ELEMENTS AND THEIR COMPOUNDS The elements in Groups 3 through 11 are called the transition metals because they represent a transition from the highly reactive metals of the s-block to the much less reactive metals of Group 12 and the p-block (Fig. 16.1). Note that the transition metals do not extend all the way across the d-block: the Group 12 elements (zinc, cadmium, and mercury) are not normally considered to be transition elements. Because their d-orbitals are full and except in rare instances do not participate in bonding, the Group 12 elements have properties that are more like those of main-group metals than those of transition metals. Just after the third row of the d-block has been started, following lanthanum, electrons begin to occupy the seven 4f-orbitals and the lanthanoids (the “rare earths”; THE d-BLOCK ELEMENTS AND THEIR COMPOUNDS 16.1 Trends in Physical Properties 16.2 Trends in Chemical Properties SELECTED ELEMENTS: A SURVEY 16.3 Scandium Through Nickel 16.4 Groups 11 and 12 COORDINATION COMPOUNDS 16.5 Coordination Complexes 16.6 The Shapes of Complexes 16.7 Isomers THE ELECTRONIC STRUCTURES OF COMPLEXES 16.8 Crystal Field Theory 16.9 The Spectrochemical Series 16.10 The Colors of Complexes 16.11 Magnetic Properties of Complexes 16.12 Ligand Field Theory 667 Chapter 16 THE ELEMENTS: THE d-BLOCK commonly known as the lanthanides) delay the completion of Period 6. These elements, together with the actinoids (commonly called the actinides), the analogous series in Period 7, are sometimes referred to as the inner transition metals. Electron transitions within the incompletely filled d-subshell are responsible for many of the colors shown by compounds of the d-block elements. Furthermore, many d-block compounds are paramagnetic (see Box 3.2). One of the challenges that we face in this chapter is to build a model of bonding that accounts for color and magnetism in a unified way. First, though, we consider the physical and chemical properties of the elements themselves. 16.1 Trends in Physical Properties The ground-state electron configurations of the atoms of d-block elements differ primarily in the occupation of the (n Ϫ 1)d-orbitals. According to the rules of the building-up principle, these orbitals are the last orbitals to be occupied. However, once they are occupied, they lie slightly lower in energy than the outer ns-orbitals. Because there are five d-orbitals in a given shell, and each one can accommodate up to two electrons, there are 10 elements in each row of the d block. The electron configurations of the d-block metals differ primarily in the occupation of these inner d-orbitals, and so the physical properties of the elements tend to be similar. All the d-block elements are metals. Most of these so-called “d-metals” are good electrical conductors. In fact, at room temperature silver is the best electrical conductor of all metals. Most of the d-metals are malleable, ductile, lustrous, and silver-white in color. Generally, their melting and boiling points are higher than those of the maingroup elements. There are a few notable exceptions: copper is red-brown, gold is yellow, and mercury has such a low melting point that it is a liquid at room temperature. The shapes of the d-orbitals affect the properties of the d-block elements in two ways (see Fig. 1.37): • The lobes of two d-orbitals on the same atom occupy markedly different regions of space. As a result, electrons in different d-orbitals are relatively far apart and repel one another only weakly. • The electron density in d-orbitals is low near the nucleus, and so they are not very effective at shielding other electrons from the positive nuclear charge. 668 CHAPTER 16 THE ELEMENTS: THE d-BLOCK s-block p-block f-block d-block 3 4 5 6 7 3 4 5 6 7 8 9 10 11 12 Lanthanides (lanthanoids) Mg Ca Sr Ba Sc Y La Ti Zr Hf V Nb Ta Cr Mo W Fe Ru Os Co Rh Ir Mn Transition metals Tc Re Ni Pd Pt Cu Ag Au Zn Cd Hg Ga Al Pr Pa CE Th Yb No Lu Lr In Tl Ra Actinides (actinoids) FIGURE 16.1 The orange rectangles identify the elements in the d-block of the periodic table. Note that the f-block, consisting of the inner transition metals, intervenes in Periods 6 and 7 as indicated by the purple bar. The horizontal gray bar designates the groups containing transition metals, Groups 3–11. Some periodic charts designate the elements La–Yb as the f-block. In this book, the elements Ce–Lu are designated as the f-block to be consistent with IUPAC conventions. One consequence of these two characteristics is the trend in atomic radii of the d-block metals, which decrease gradually across a period and then rise again (Fig. 16.2). Nuclear charge and number of d-electrons both increase from left to right across each row (from scandium to zinc, for instance). Because the repulsion between d-electrons is weak, initially the increasing nuclear charge can draw them inward, and so the atoms become smaller. Farther across the block, there are so many d-electrons that electron–electron repulsion increases more rapidly than the attraction from the nuclear charge, and the radii begin to increase again. Because these attractions and repulsions are finely balanced, the range of d-metal atomic radii is not very great. In fact, some of the atoms of one d-metal can easily replace atoms of another d-metal in a crystal lattice (Fig. 16.3). The d-metals can therefore form a wide range of alloys, including the many varieties of steel (see Sections 6.1–6.4). The atomic radii of the second row of d-metals (Period 5) are typically greater than those in the first row (Period 4). The atomic radii in the third row (Period 6), however, are about the same as those in the second row and smaller than expected. This effect is due to the lanthanide contraction, the decrease in radius along the first row of the f-block (Fig. 16.4). This decrease is due to the increasing nuclear charge along the period coupled with the poor shielding ability of f-electrons. When the d-block resumes (at hafnium), the atomic radius has fallen from 188 pm for lanthanum to 156 pm for hafnium. A technologically important effect of the lanthanide contraction is the high density of the Period 6 elements (Fig. 16.5). The atomic radii of these elements are comparable to those of the Period 5 elements, but their atomic masses are about twice as large; so more mass is packed into the same volume. A block of iridium, for example, contains about as many atoms as a block of rhodium of the same volume. However, each iridium atom is nearly twice as heavy as a rhodium atom, and so the density of the sample is nearly twice as great. In fact, iridium is one of the two densest elements; its neighbor osmium is the other. Another effect of the contraction is the low reactivity—the “nobility”— of gold and platinum. Because their valence electrons are relatively close to the nucleus, they are tightly bound and not readily available for chemical reactions. The atomic radii of the d-block metals are similar but tend to decrease across a series. The lanthanide contraction accounts for the smaller than expected radii and higher densities of the d-block atoms in Period 6. 16.2 Trends in Chemical Properties The d-block elements tend to lose their valence s-electrons when they form compounds. Most of them can also lose a variable number of d-electrons and exist in a variety of oxidation states. The only elements of the block that do not use their d-electrons in compound formation are the members of Group 12. Zinc and cadmium lose only their s-electrons; mercury loses a d-electron only in rare instances. The ability to exist in different oxidation states is responsible for many of the special chemical properties of these elements and plays a role in the action of many biomolecules. 16.2 TRENDS IN CHEMICAL PROPERTIES 669 FIGURE 16.3 Because the atomic radii of the d-block elements are so similar, the atoms of one element can replace the atoms of another element with minor modification of the atomic locations; consequently, d-block metals form a wide range of alloys. 161 181 188 145 160 156 132 143 143 135 136136 134 137 137137 134 136 138 138 125 128 133 160 149144 144 Group Period 3 4 5 6 4 5 6 7 8 9 10 11 12 125 125124 Sc Ti Y La Zr Hf Ta Nb V Cr Mo W Re Tc Mn Fe IrOs Ru Rh Co Ni Pd Cu Pt Au Ag Zn Cd Hg FIGURE 16.4 The atomic radii of the d-block elements (in picometers). Notice the similarity of all the values and, in particular, the close similarity between the second and the third rows as a result of the lanthanide contraction. 161 145 132 125 137 133 124 125 125 128 Sc Ti V Cr Mn Fe Co Ni Cu Zn FIGURE 16.2 The atomic radii (in picometers) of the elements of the first row of the d-block. Most d-block elements have more than one common oxidation state (Fig. 16.6). The distribution of oxidation states looks daunting at first sight, but if we examine the figure, we can see two patterns: 1 Elements close to the center of each row have the widest range of oxidation states. Except for mercury, the elements at the ends of each row of the d-block occur in only one oxidation state other than 0. All the other elements of each row are found in at least two oxidation states and manganese, at the center of its row, is found in seven oxidation states. 2 Elements in the second and third rows of the block are more likely to reach higher oxidation states than are those in the first row. Notice that ruthenium and osmium have all possible oxidation states and that even gold and mercury, which lie near the end of the block, can be found in three oxidation states. 670 CHAPTER 16 THE ELEMENTS: THE d-BLOCK Period 4 Period 5 Period 6 13.6 19.3 21.4 22.6 Ir 22.6 21.0 19.3 16.7 13.3 6.2 La Hf Ta W Re Os Pt Au Hg FIGURE 16.5 The densities (in grams per centimeter cubed, gиcmϪ3 ) of the d-metals at 25°C. The lanthanide contraction has a pronounced effect on the densities of the elements in Period 6 (front row in this illustration), which are among the densest of all the elements. 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 Sc Ti V Cr Mn Fe Co Ni Cu Zn Y Zr Nb Mo Tc Ru Rh Pd Ag Cd La Hf Ta W Re Os Ir Pt Au Hg FIGURE 16.6 The oxidation numbers of the d-block elements. The orange blocks mark the common oxidation numbers for each element; the green blocks mark the other known states. The pattern of oxidation states underlies trends in the chemical properties of the d-block elements. An element in a high oxidation state is easily reduced; therefore, the compound is likely to be a good oxidizing agent. For example, manganese has oxidation number ϩ7 in the permanganate ion, MnO4 Ϫ and this ion is a good oxidizing agent in acidic solution: MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 5 eϪ Mn2ϩ (aq) ϩ 4 H2O(l) E° ϭ ϩ1.51 V Compounds that contain the element in a low oxidation state, such as Cr2ϩ , are often good reducing agents: Cr3ϩ (aq) ϩ eϪ Cr2ϩ (s) E° ϭ Ϫ0.41 V The pattern of oxidation states correlates with the pattern of acid–base behavior of d-metal oxides. Although most d-metal oxides are basic, the oxides of a given element show a shift toward acidic character with increasing oxidation number, just as the oxoacids do (recall Section 11.10). The family of chromium oxides is a good example: CrO ϩ2 basic Cr2O3 ϩ3 amphoteric CrO3 ϩ6 acidic Chromium(VI) oxide, CrO3, is the anhydride of chromic acid, H2CrO4, the parent acid of the chromates. In this highly oxidized state, chromium is electron poor and the oxygen atoms attached to it are less likely to share electrons with a proton. The elements on the left of the d-block resemble the s-block metals in being much more difficult to extract from their ores than the metals on the right. Indeed, if we go to the right side of the d-block and move back across it from right to left, we encounter the elements in very roughly the order in which they were put to use as metals. On the far right are copper and zinc, which jointly were responsible for the Bronze Age. As metal workers discovered how to achieve higher temperatures, they found out how to reduce iron oxides, and the Bronze Age was succeeded by the Iron Age. The metals at the left of the block—for example, titanium—require such extreme conditions for their extraction—including the use of other active metals or electrolysis—that they became widely available only in the twentieth century, when these techniques were developed. Self-Test 16.1A Predict trends in ionization energies of the d-block metals. [Answer: Ionization energy increases from left to right across a row and decreases down a group.] Self-Test 16.1B Six of the d-block metals in Period 4 form ϩ1 ions. Predict trends in the radii of those ions. The range of oxidation states of a d-block element increases toward the center of the block. Compounds in which the d-block element has a high oxidation state tend to be oxidizing; those in which it has a low oxidation state tend to be reducing. The acidic character of oxides increases with the oxidation state of the element. SELECTED ELEMENTS: A SURVEY Although the physical properties of the d-block elements are similar, the chemical properties of these elements are so diverse that it is impossible to summarize them briefly. We can, however, illustrate some of the major trends in properties within the d-block by considering the properties of certain representative elements, particularly those in the first row of the block. 16.3 Scandium Through Nickel Table 16.1 summarizes the physical properties of the elements from scandium through nickel. Notice the similarities in their melting and boiling points, but the gradual increase in density. ¡ ¡ 16.3 SCANDIUM THROUGH NICKEL 671 Scandium, Sc, which was first isolated in 1937, is a reactive metal: it reacts with water about as vigorously as calcium does. It has few uses and is not thought to be essential to life. The small, highly charged Sc3ϩ ion is strongly hydrated in water (like Al3ϩ ), and the resulting [Sc(OH2)6]3ϩ complex is about as strong a Brønsted acid as acetic acid. A note on good practice: When water is part of a complex, its formula is written OH2 to emphasize that the water molecule links to the metal through the O atom. Titanium, Ti, a light, strong metal, is used where these properties are critical—in widely diverse applications such as jet engines and dental fixtures such as partial plates. Although titanium is relatively reactive, unlike scandium it is resistant to corrosion because it is passivated by a protective skin of oxide on its surface. The principal sources of the metal are the ores ilmenite, FeTiO3, and rutile, TiO2. Thinking point: Can you think of a reason why some metals are passivated by an oxide film but others not? Titanium requires strong reducing agents for extraction from its ores. It was not widely exploited commercially until demand from the aerospace industry increased in the last part of the twentieth century. The metal is obtained by first treating the ores with chlorine in the presence of coke (impure carbon obtained by heating coal in the absence of air) to form titanium(IV) chloride; the volatile chloride is then reduced by passing it through liquid magnesium: TiCl4(g) ϩ 2 Mg(l) ∫ 70 ∫ 0°C ∫∫B Ti(s) ϩ 2 MgCl2(s) The most common oxidation state of titanium is ϩ4, in which the atom has lost both its 4s-electrons and its two 3d-electrons. Its most important compound is titanium(IV) oxide, TiO2, which is almost universally known as titanium dioxide. This oxide is a brilliantly white (when finely powdered), nontoxic, stable solid used as the white pigment in paints and paper. It acts as a semiconductor in the presence of light, and so it is used to convert solar radiation into electrical energy in solar cells. Thinking point: Why is finely divided titanium oxide powder white? Titanium forms a series of oxoanions called titanates, which are prepared by heating TiO2 with a stoichiometric amount of the oxide or carbonate of a second metal. One of these compounds, barium titanate, BaTiO3, is piezoelectric, which means that it becomes electrically polarized when it is mechanically distorted. The ability to convert mechanical vibration into an electrical signal makes barium titanate useful for underwater sound detection. Vanadium, V, a soft silver-gray metal, is produced by reducing its oxide or chloride. For example, vanadium(V) oxide is reduced by calcium: V2O5(s) ϩ 5 Ca(l) 2 V(s) ϩ 5 CaO(s) Vanadium is used to make tough steels for automobile and truck springs. Because it is not economical to add the pure metal to iron, a ferroalloy of the metal, an alloy with iron and carbon, that is less expensive to produce, is used instead. ¡ ¢ 672 CHAPTER 16 THE ELEMENTS: THE d-BLOCK Square brackets are commonly used to indicate the presence of a d-metal complex. TABLE 16.1 Properties of the d-Block Elements Scandium Through Nickel Valence electron Melting Boiling Density, Z Name Symbol configuration point (°C) point (°C) (gؒcm؊3 ) 21 scandium Sc 3d1 4s2 1540 2800 2.99 22 titanium Ti 3d2 4s2 1660 3300 4.55 23 vanadium V 3d3 4s2 1920 3400 6.11 24 chromium Cr 3d5 4s1 1860 2600 7.19 25 manganese Mn 3d5 4s2 1250 2120 7.47 26 iron Fe 3d6 4s2 1540 2760 7.87 27 cobalt Co 3d7 4s2 1494 2900 8.80 28 nickel Ni 3d8 4s2 1455 2150 8.91 Vanadium(V) oxide, V2O5, commonly known as vanadium pentoxide, is the most important compound of vanadium. This orange-yellow solid is used as an oxidizing agent and as an oxidizing catalyst (a catalyst that accelerates oxidation) in the contact process for the manufacture of sulfuric acid (Section 15.21). The wide range of colors of vanadium compounds, including the blue of the vanadyl ion, VO2ϩ (Fig. 16.7), has led to their use as glazes in the ceramics industry. Chromium, Cr, is a bright, lustrous, corrosion-resistant metal. Its name, which comes from the Greek word for “color,” was inspired by its colorful compounds. The metal is obtained from the black mineral chromite, FeCr2O4, by reduction with carbon in an electric arc furnace: FeCr2O4(s) ϩ 4 C(s) Fe(l) ϩ 2 Cr(l) ϩ 4 CO(g) A less abundant source of chromium is the green mineral chrome ochre, Cr2O3, which is reduced to the metal by aluminum in the thermite process: Cr2O3(s) ϩ 2 Al(s) Al2O3(s) ϩ 2 Cr(l) Chromium metal is important in metallurgy, because it is used to make stainless steel and for chromium plating (Section 13.13). Chromium(IV) oxide, CrO2, a brown-black solid, is a ferromagnetic material that is used for coating “chrome” recording tapes. Sodium chromate, Na2CrO4, a yellow solid, is the source of most other chromium compounds, including fungicides, pigments, and ceramic glazes. The chromate ion changes into the orange dichromate ion, Cr2O7 2Ϫ , in the presence of acid (Fig. 16.8): 2 CrO4 2Ϫ (aq) ϩ 2 Hϩ (aq) Cr2O7 2Ϫ (aq) ϩ H2O(l)¡ ¡ ¢ ¡ ¢ 16.3 SCANDIUM THROUGH NICKEL 673 Ferromagnetism is described in Section 6.16. FIGURE 16.7 Many vanadium compounds form vividly colored solutions in water. They are also used in pottery glazes. The blue colors here are due to the vanadyl ion, VO2ϩ . 2؊ 2Ϫ 2؊ CrO4 2Ϫ CrO4 2Ϫ Cr2O7 2Ϫ FIGURE 16.8 The chromate ion, CrO4 2Ϫ , is yellow. When acid is added to a chromate solution, the ions form orange dichromate ions, Cr2O7 2Ϫ . In the laboratory, acidified solutions of dichromates, in which the oxidation number of chromium is ϩ6, are useful oxidizing agents: Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq) ϩ 6 eϪ 2 Cr3ϩ (aq) ϩ 7 H2O(l) E° ϭ ϩ1.33 V Manganese, Mn, is a gray metal that resembles iron. It is much less resistant to corrosion than chromium is and becomes coated with a thin brown layer of oxide when exposed to air. The metal is rarely used alone, but it is an important component of alloys. When it is added to iron as ferromanganese to make steel, it reacts with sulfur present as an impurity. Both FeS and MnS collect in the cracks between the grains of steel, but whereas FeS melts at a low temperature and allows the cracks to spread, MnS does not and its inclusion is not a problem. Manganese also increases iron’s hardness, toughness, and resistance to abrasion (Table 16.2). Another useful alloy is manganese bronze (39% by mass Zn, 1% Mn, a small amount of iron and aluminum, and the rest copper), which is very resistant to corrosion and is used for the propellers of ships. Manganese is also alloyed with aluminum to increase the stiffness of beverage cans, allowing them to be manufactured with thinner walls. A rich supply of manganese lies in nodules of ore that litter the ocean floors (Fig. 16.9). These nodules range in diameter from millimeters to meters and are lumps of the oxides of iron, manganese, and other elements. However, because this source is technically difficult to exploit, manganese is currently obtained by the thermite process from pyrolusite, a mineral form of manganese dioxide: 3 MnO2(s) ϩ 4 Al(s) 3 Mn(l) ϩ 2 Al2O3(s) Manganese lies near the center of its row (in Group 7) and occurs in a wide variety of oxidation states. The most stable state is ϩ2, but ϩ4, ϩ7, and, to a lesser extent, ϩ3 are common in manganese compounds. Its most important compound is manganese(IV) oxide, MnO2, commonly called manganese dioxide. This compound is a brown-black solid used in dry cells, as a decolorizer to conceal the green tint of glass, and as the starting point for the production of other manganese compounds. Potassium permanganate is a strong oxidizing agent in acidic solution and is used to oxidize organic compounds and as a mild disinfectant. Its usefulness stems not only from its thermodynamic tendency to oxidize other species but also from its ability to act by a variety of mechanisms; hence, it is likely to be able to find a path with low activation energy and act rapidly. Iron, Fe, the most widely used of all the d-metals, is the most abundant element on Earth and the second most abundant metal in the Earth’s crust (after aluminum). Its principal ores are the oxides hematite, Fe2O3, and magnetite, Fe3O4, which are used to make steel. The sulfide mineral pyrite, FeS2 (see Fig. 15.42), is widely available, but it is not used in steelmaking because the sulfur is difficult to remove. The production of steel (see Section 6.3) is so important to modern society that it is used as a measure of a country’s economic power. The process begins with the mining of iron ore, generally as the oxide Fe2O3, which is reduced through a series of redox and Lewis acid–base reactions. A mixture of iron ore, coke, and limestone ¡ ¢ ¡ 674 CHAPTER 16 THE ELEMENTS: THE d-BLOCK TABLE 16.2 Composition of Different Steels Element blended Typical into iron amount (%) Effect manganese 0.5 to 1.0 increases strength and hardness but lowers ductility 13 increases wear resistance nickel Ͻ5 increases strength and shock resistance Ͼ5 increases corrosion resistance (stainless) and hardness chromium variable increases hardness and wear resistance Ͼ12 increases corrosion resistance (stainless) vanadium variable increases hardness tungsten Ͻ20 increases hardness, especially at high temperatures FIGURE 16.9 Manganese nodules that litter the ocean floor are potentially a valuable source of the element. (calcium carbonate, see Section 6.6) is fed continuously into the top of a blast furnace (Fig. 16.10), which is approximately 40 m high. Each kilogram of iron produced requires about 1.75 kg of ore, 0.75 kg of coke, and 0.25 kg of limestone. The limestone undergoes thermal decomposition to calcium oxide (lime) and carbon dioxide. The calcium oxide, which contains the Lewis base O2Ϫ , helps to remove the acidic (nonmetal oxide) and amphoteric impurities from the ore: CaO(s) ϩ SiO2(s) CaSiO3(l) CaO(s) ϩ Al2O3(s) Ca(AlO2)2(l) 6 CaO(s) ϩ P4O10(s) 2 Ca3(PO4)2(l) The mixture of products, which is known as slag, is molten at the temperatures in the furnace and floats on the denser molten iron. It is drawn off and used to make rocklike material for the construction industry. Molten iron is produced through a series of reactions in the four main temperature zones of the furnace. At the bottom, in Zone A, preheated air is blown into the furnace under pressure, and the coke is oxidized to heat the furnace to 1900°C and provide carbon in the form of carbon dioxide. Higher up, the iron is reduced in stages to the metal, which melts and flows from Zone C to Zone A. Although the melting point of pure iron is 1540°C, iron mixed with 4% carbon melts at about 1015°C. As the carbon dioxide moves up through the furnace to Zone B, it reacts with some of the carbon provided by the coke, producing carbon monoxide. This reaction is endothermic and lowers the temperature to 1300°C. The carbon monoxide produced in this reaction rises to Zones C and D, where it reduces iron ore in a series of reactions, some of which are shown in Fig. 16.10. The iron runs out of the bottom of the furnace as molten pig iron, a highcarbon form of iron that must be further processed (see Section 6.3). Iron is quite reactive and corrodes in moist air. It is passivated by oxidizing acids such as HNO3 (Section 13.14) but reacts with nonoxidizing acids, evolving hydrogen and forming iron(II) salts. The colors of these salts vary from pale yellow to dark greenbrown. Iron(II) salts are readily oxidized to iron(III) salts. The oxidation is slow in acidic solution but rapid in basic solution, where insoluble iron(III) hydroxide, Fe(OH)3, is precipitated. Although [Fe(OH2)6]3ϩ ions are pale purple and Fe3ϩ ions give amethyst ¡ ¢ ¡ ¢ ¡ ¢ 16.3 SCANDIUM THROUGH NICKEL 675 Molten slag Zone A Zone B Zone C Zone D Exhaust gas Charge: ore, coke, and limestone Pig iron Slag 3 Fe2O3 + CO 2 Fe3O4 + CO2 Fe3O4 + CO 3 FeO + CO2 CaCO3 CaO + CO2 FeO + CO Fe + CO2 Fe2O3 + 3 CO 2 Fe+3 CO2 CO2 + C 2 CO 1300∞C C + O2 CO2 1900∞C 800∞C 1000∞C Molten iron Hot air and oxygen FIGURE 16.10 The reduction of iron ore takes place in a blast furnace containing a mixture of the ore with coke and limestone. Different reactions take place in different zones when the blast of air and oxygen is admitted. The ore, an oxide, is reduced to the metal by reduction with carbon monoxide produced in the furnace. its purple color, the colors of aqueous solutions of iron(III) salts are dominated by the conjugate base of [Fe(OH2)6]3ϩ , the yellow [FeOH(OH2)5]2ϩ ion: [Fe(OH2)6]3ϩ (aq) ϩ H2O(l) #¢4 H3Oϩ (aq) ϩ [FeOH(OH2)5]2ϩ (aq) Like some other d-block metals, such as nickel, iron can form compounds in which its oxidation number is zero. For example, when iron is heated in carbon monoxide, it reacts to form iron pentacarbonyl, Fe(CO)5, a yellow molecular liquid that boils at 103°C. A healthy adult human body contains about 3 g of iron, mostly as hemoglobin. Because about 1 mg is lost daily (in sweat, feces, and hair), and women lose about 20 mg in each menstrual cycle, iron must be ingested daily to maintain the balance. Iron deficiency, or anemia, results in reduced transport of oxygen to the brain and muscles, and an early symptom is chronic tiredness. Thinking point: Which common food sources provide iron in the diet? Cobalt ores are often found in association with copper(II) sulfide. Cobalt is a silvergray metal and is used mainly for alloying with iron. Alnico steel, an alloy of iron, nickel, cobalt, and aluminum, is used to make permanent magnets such as those in loudspeakers (see Section 6.4). Cobalt steels are hard enough to be used as surgical steels, drill bits, and lathe tools. The color of cobalt glass is due to a blue pigment that forms when cobalt(II) oxide is heated with silica and alumina. Nickel, Ni, is also used in alloys. It is a hard, silver-white metal used mainly for the production of stainless steel (see Section 6.3) and for alloying with copper to produce cupronickels, the alloys used for nickel coins (which are about 25% Ni and 75% Cu). Nickel is also used in nicad batteries and as a catalyst, especially for the addition of hydrogen to organic compounds, as in the hydrogenation of vegetable oils (Section 18.6). About 70% of the western world’s supply of nickel comes from iron and nickel sulfide ores that were brought close to the surface nearly 2 billion years ago by the violent impact of a huge meteorite at Sudbury, Ontario. The ore is first roasted (heated in air) to form nickel(II) oxide, which is reduced to the metal either electrolytically or by reaction with hydrogen gas in the first step of the Mond process: NiO(s) ϩ H2(g) Ni(s) ϩ H2O(g) The impure nickel is then refined by first exposing it to carbon monoxide, with which it forms nickel tetracarbonyl, Ni(CO)4: Ni(s) ϩ 4 CO(g) Ni(CO)4(g) Nickel tetracarbonyl is a volatile, poisonous liquid that boils at 43°C and can therefore be removed from impurities. Nickel metal is then obtained by heating the pure nickel tetracarbonyl to about 200°C, at which temperature it decomposes. Nickel’s most common oxidation state is ϩ2, and the green color of aqueous solutions of nickel salts is due to the presence of [Ni(OH2)6]2ϩ ions. The Period 4 d-block elements titanium through nickel are obtained chemically from their ores, with the ease of reduction increasing to the right in the periodic table. They have many industrial uses, particularly as alloys. 16.4 Groups 11 and 12 The elements close to the right-hand edge of the d-block have full d-orbitals. Group 11 contains the coinage metals—copper, silver, and gold—which have (n Ϫ 1)d10 ns1 valence electron configurations (Table 16.3). Group 12 contains zinc, cadmium, and mercury, with valence configurations (n Ϫ 1)d10 ns2 . The low reactivity of the coinage metals is partly due to the poor shielding abilities of the d-electrons and hence the tight grip that the nucleus can exert on the outermost electron. This effect is enhanced in Period 6 by the lanthanide contraction, which helps to account for the inertness of gold. ¡ ¡ ¢ 676 CHAPTER 16 THE ELEMENTS: THE d-BLOCK The slightly yellow hue of cupronickels is removed by the addition of small amounts of cobalt. Copper, Cu, is unreactive enough for some to be found as the metal, but most is produced from its sulfides, particularly the ore chalcopyrite, CuFeS2 (Fig. 16.11). The crushed and ground ore is separated from excess rock by froth flotation, a process that depends on the ability of sulfide ores to be wetted by oils but not by water. In this process, the powdered ore is combined with oil, water, and detergents (Fig. 16.12). Then air is blown through the mixture; the oil-coated sulfide mineral floats to the surface with the froth, and the unwanted copper-poor residue, which is called gangue, sinks to the bottom. Processes for extracting metals from their ores are generally classified as pyrometallurgical, when high temperatures are used (Fig. 16.13), or hydrometallurgical, when aqueous solutions are used. Copper is extracted by both methods. In pyrometallurgical extraction, the enriched ore is roasted: 2 CuFeS2(s) ϩ 3 O2(g) 2 CuS(s) ϩ 2 FeO(s) ϩ 2 SO2(g) The CuS is then smelted, a process in which metal ions are reduced by heating the molten ore with a reducing agent such as carbon (in the form of coke). At the same time, the sulfur is oxidized to SO2 by blowing compressed air through the mixture of ore, limestone, and sand: CuS(s) ϩ O2(g) Cu(l) ϩ SO2(g) The copper product is known as blister copper because of the appearance of air bubbles in the solidified metal. In the hydrometallurgical process, soluble Cu2ϩ ions are formed by the action of sulfuric acid on the ores. Then the metal is obtained by reducing these ions in aqueous solution either electrolytically or chemically, by using an inexpensive ¡ ¢ ¡ ¢ 16.4 GROUPS 11 AND 12 677 FIGURE 16.11 Three important copper ores (from left to right): chalcopyrite, CuFeS2; malachite, CuCO3иCu(OH)2; and chalcocite, Cu2S. TABLE 16.3 Properties of Elements in Groups 11 and 12 Valence electron Melting Boiling Density, Z Name Symbol configuration point (°C) point (°C) (gؒcm؊3 ) 29 copper Cu 3d10 4s1 1083 2567 8.93 47 silver Ag 4d10 5s1 962 2212 10.50 79 gold Au 5d10 6s2 1064 2807 19.28 30 zinc Zn 3d10 4s2 420 907 7.14 48 cadmium Cd 4d10 5s2 321 765 8.65 80 mercury Hg 5d10 6s2 Ϫ39 357 13.55 Froth- mineral mixture Water, detergent, oil, and ore Air Gangue FIGURE 16.12 In the froth flotation process, a stream of bubbles (white circles) is passed through a mixture of ore (gold circles), rock (brown rectangles), and detergent. The ore is buoyed up by the froth of bubbles and is removed from the top of the chamber. The unwanted gangue is washed away through the bottom of the container. reducing agent that has a more negative standard potential than that of copper, such as hydrogen or iron (see Section 15.3): Cu2ϩ (aq) ϩ H2(g) Cu(s) ϩ 2 Hϩ (aq) ⌬G° ϭ Ϫ65 kJ The reduction is thermodynamically favored, because the standard potential of the couple Cu2ϩ /Cu is positive (E° ϭ ϩ0.34 V). Metals with negative standard potentials, such as zinc (E° ϭ Ϫ0.76 V) and nickel (E° ϭ Ϫ0.23 V), cannot be extracted hydrometallurgically. The impure copper from either process is refined electrolytically: it is made into anodes and plated onto cathodes of pure copper. Other metals may be present in the impure copper and those with highly positive electrode potentials also are reduced. The rare metals—most notably, platinum, silver, and gold—obtained from the anode sludge are sold to recover much of the cost of the electricity used in the electrolysis. Copper alloys such as brass and bronze, which are harder and more resistant to corrosion than is copper, are important construction materials (see Section 6.4). Copper corrodes in moist air in the presence of oxygen and carbon dioxide: 2 Cu(s) ϩ H2O(l) ϩ O2(g) ϩ CO2(g) Cu2(OH)2CO3(s) The pale green product is called basic copper carbonate and is responsible for the green patina of copper and bronze objects (Fig. 16.14). The patina adheres to the surface, protects the metal from further oxidation, and has a pleasing appearance. Like all the coinage metals, copper forms compounds with oxidation number ϩ1. However, in water, copper(I) salts disproportionate into metallic copper and copper(II) ions. The latter exist as pale blue [Cu(OH2)6]2ϩ ions in water. Copper is essential in animal metabolism. In mammals, copper-bearing enzymes are necessary for healthy nerves and connective tissue. In some animals, such as the octopus and certain arthropods, it transports oxygen through the blood, a role performed by iron in mammals. As a result, the blood of these animals is green rather than red. Silver, Ag, is rarely found as the metal. Most is obtained as a by-product of the refining of copper and lead, and a considerable amount is recycled through the photographic industry; however, that amount is diminishing due to the growth of digital photography. Silver has a positive standard potential, and so it does not reduce Hϩ (aq) to hydrogen. Silver reacts readily with sulfur and sulfur compounds, producing the familiar black tarnish on silver dishes and cutlery. Silver(I) does not disproportionate in aqueous solution; and, in almost all its compounds, silver has oxidation number ϩ1. Apart from silver nitrate, AgNO3, and silver fluoride, silver salts are generally only sparingly soluble in water. Silver nitrate is the most important compound of silver and the starting point for the manufacture of silver halides for use in photography. ¡ ¡ 678 CHAPTER 16 THE ELEMENTS: THE d-BLOCK FIGURE 16.13 In this industrial-scale copper refinery, the molten impure copper produced by smelting is poured into molds. Next, the copper will be purified by electrolysis. FIGURE 16.14 Copper corrodes in air to form an attractive pale green layer of basic copper carbonate. This patina, or incrustation, passivates the surface, which helps to protect it from further corrosion. 16.4 GROUPS 11 AND 12 679 Gold, Au, is so inert that most of it is found in nature as the metal. Pure gold is classified as 24-carat gold. Its alloys with silver and copper, which differ in hardness and hue, are classified according to the proportion of gold that they contain (Fig. 16.15). For example, 10- and 14-carat golds contain, respectively, and parts by mass of gold. Gold is a highly malleable metal, and 1 g of gold can be worked into a leaf covering an area of about 1 m2 or pulled out into a wire more than 2 km long. Gold leaf provides a valuable decorative protection, such as that on dishes and books. Gold is too noble to react even with strong oxidizing agents such as nitric acid. Both the gold couples Auϩ (aq) ϩ eϪ Au(s) E° ϭ ϩ1.69 V Au3ϩ (aq) ϩ 3 eϪ Au(s) E° ϭ ϩ1.40 V lie above Hϩ /H2 and NO3 Ϫ ,Hϩ /NO,H2O: NO3 Ϫ (aq) ϩ 4 Hϩ (aq) ϩ 3 eϪ NO(g) ϩ 2 H2O(l) E° ϭ ϩ0.96 V However, gold does react with aqua regia, a mixture of concentrated nitric and hydrochloric acids, because the complex ion [AuCl4]Ϫ forms: Au(s) ϩ 6 Hϩ (aq) ϩ 3 NO3 Ϫ (aq) ϩ 4 ClϪ (aq) [AuCl4]Ϫ (aq) ϩ 3 NO2(g) ϩ 3 H2O(l) Despite the unfavorable equilibrium constant for the formation of Au3ϩ from gold, the reaction proceeds because any Au3ϩ ions formed are immediately complexed by ClϪ ions and removed from the equilibrium. In a process widely used in the refining of the metal, gold also reacts with sodium cyanide in an aerated aqueous solution to form the complex ion [Au(CN)2]Ϫ : 4 Au(s) ϩ 8 NaCN(aq) ϩ O2(aq) ϩ 2 H2O(l) 4 Na[Au(CN)2](aq) ϩ 4 NaOH(aq) Zinc, Zn, is found mainly as its sulfide, ZnS, in sphalerite, often in association with lead ores (see Fig. 15.42). The ore is concentrated by froth flotation, and the metal is extracted by roasting and then smelting with coke: 2 ZnS(s) ϩ 3 O2(g) 2 ZnO(s) ϩ 2 SO2(g) ZnO(s) ϩ C(s) Zn(l) ϩ CO(g) Zinc is used mainly for galvanizing iron; like copper, it is protected by a hard film of basic carbonate, Zn2(OH)2CO3, which forms on contact with air. Zinc and cadmium are both silvery, reactive metals that are similar to each other but differ sharply from mercury. Zinc is amphoteric (like its main-group neighbor aluminum). It reacts with acids to form Zn2ϩ ions and with alkalis to form the zincate ion, [Zn(OH)4]2Ϫ : Zn(s) ϩ 2 OHϪ (aq) ϩ 2 H2O(l) [Zn(OH)4]2Ϫ (aq) ϩ H2(g) Galvanized containers should therefore not be used for transporting alkalis. Cadmium, which is lower down the group and is more metallic, has a more basic oxide. Zinc and cadmium have an oxidation number of ϩ2 in all their compounds. Zinc is an essential element for human health. It is present in many enzymes and plays a role in the expression of DNA and in growth. Zinc is toxic only in very high amounts. However, cadmium is a deadly poison that disrupts metabolism by substituting for other essential metals in the body such as zinc and calcium, leading to soft bones and to kidney and lung disorders. Mercury, Hg, occurs mainly as HgS in the mineral cinnabar (see Fig. 15.42), from which it is separated by froth flotation and then roasting in air: HgS(s) ϩ O2(g) Hg(g) ϩ SO2(g) The volatile metal is separated by distillation and condensed. Mercury is the only metallic element that is liquid at room temperature (gallium and cesium are liquids on ¡ ¢ ¡ ¡ ¢ ¡ ¢ ¡ ¡ ¡ ¡ ¡ 14 24 10 24 FIGURE 16.15 The color of commercial gold depends on its composition. Left to right: 8-carat gold, 14-carat gold, white gold, 18-carat gold, and 24-carat gold. White gold consists of 6 parts Au and 18 parts Ag by mass. warm days). It has a long liquid range, from its melting point of Ϫ39°C to its boiling point of 357°C, and so it is well suited for its use in thermometers, silent electrical switches, and high-vacuum pumps. Because mercury lies above hydrogen in the electrochemical series, it is not oxidized by hydrogen ions. However, it does react with nitric acid: 3 Hg(l) ϩ 8 Hϩ (aq) ϩ 2 NO3 Ϫ (aq) 3 Hg2ϩ (aq) ϩ 2 NO(g) ϩ 4 H2O(l) In nearly all its compounds, mercury has the oxidation number ϩ1 or ϩ2. Its compounds with oxidation number ϩ1 are unusual in that the mercury(I) cation is the covalently bonded diatomic ion (Hg–Hg)2ϩ , written Hg2 2ϩ . Compounds containing mercury, particularly its organic compounds, are acutely poisonous. Mercury vapor is an insidious poison because its effect is cumulative. Frequent exposure to low levels of mercury vapor can allow mercury to accumulate in the body. The effects include impaired neurological function, hearing loss, and other ailments. Self-Test 16.2A Use standard Gibbs free energies of formation to calculate ⌬G° at 298 K for the reaction CuS(s) ϩ O2(g) : Cu(s) ϩ SO2(g). (⌬Gf°(CuS, s) ϭ Ϫ49.0 kJиmolϪ1 .) [Answer: ⌬G° ϭ Ϫ251.2 kJ] Self-Test 16.2B Calculate Ecell° for a cell powered by the reaction of mercury metal and nitric acid to form aqueous mercury(I) and gaseous NO. Metals in Groups 11 and 12 are easily reduced from their compounds and have low reactivity as a result of poor shielding of the nuclear charge by the d-electrons. Copper is extracted from its ores by either pyrometallurgical or hydrometallurgical processes. COORDINATION COMPOUNDS Many of the d-block elements form characteristically colored solutions in water. For example, although solid copper(II) chloride is brown and copper(II) bromide is black, their aqueous solutions are both light blue. The blue color is due to the hydrated copper(II) ions, [Cu(OH2)6]2ϩ , that form when the solids dissolve. As the formula suggests, these hydrated ions have a specific composition; they also have definite shapes and properties. They can be regarded as the outcome of a reaction in which the water molecules act as Lewis bases (electron pair donors, Section 11.2) and the Cu2ϩ ion acts as a Lewis acid (an electron pair acceptor). This type of Lewis acid–base reaction is characteristic of many cations of d-block elements. The hydrated ion [Cu(OH2)6]2ϩ is an example of a complex, a species consisting of a central metal atom or ion to which a number of molecules or ions are attached by coordinate covalent bonds. A coordination compound is an electrically neutral compound in which at least one of the ions present is a complex. However, the terms coordination compound (the overall neutral compound) and complex (one or more of the ions or neutral species present in the compound) are often used interchangeably. Coordination compounds include complexes in which the central metal atom is electrically neutral, such as Ni(CO)4, and ionic compounds, such as K4[Fe(CN)6]. Much research focuses on the structures, properties, and uses of the complexes formed between d-metal ions acting as Lewis acids and a variety of Lewis bases, partly because they participate in many biological reactions. Hemoglobin and vitamin B12, for example, are both complexes—the former of iron and the latter of cobalt (Box 16.1). Complexes of the d-metals are often brightly colored and magnetic and are used in chemistry for analysis, to dissolve ions (Section 12.13), in the electroplating of metals, and for catalysis. They are also the target of current research in solar-energy conversion, in atmospheric nitrogen fixation, and in pharmaceuticals. 16.5 Coordination Complexes The Lewis bases attached to the central metal atom or ion in a d-metal complex are known as ligands; they can be either ions or molecules. An example of an ionic ligand ¡ 680 CHAPTER 16 THE ELEMENTS: THE d-BLOCK The formation of coordinate covalent bonds is described in Sections 2.11 and 11.2. The name “ligand” comes from the Latin word meaning “to bind.” 16.5 COORDINATION COMPLEXES 681 Why We Need to Eat d-Metals Some of the critical enzymes in our cells are metalloproteins, large organic molecules made up of folded polymerized chains of amino acids that also include at least one metal atom. These metalloproteins are intensely studied by biochemists, because they control life and protect against disease. They have also been used to trace evolutionary paths. The d-block metals catalyze redox reactions, form components of membrane, muscle, skin, and bone, catalyze acid–base reactions, control the flow of energy and oxygen, and carry out nitrogen fixation. Hemoglobin, in which an iron atom lies as iron(II) at the center of a heme group, is the most familiar metalloprotein. Four nitrogen atoms from amine groups in the heme serve as the ligands in a square planar arrangement. The oxygen molecule serves as a fifth ligand, attaching itself directly to the iron atom and producing a modified square pyramidal shape about the iron atom. Carbon monoxide forms a much stronger bond to the iron atom than oxygen does—hence its high toxicity: the attached CO ligand prevents an O2 molecule from attaching to the iron, and the victim suffocates. Cobalt is a d-metal needed to prevent pernicious anemia and some kinds of mental illness. It is an essential part of a coenzyme required for the activity of vitamin B12 (which is also called cobalamin) and gives the vitamin its red color. The cobalt atom is found in an octahedral complex in which five of the ligands are attached through nitrogen atoms from organic amine groups and one ligand attaches through a —CH2— group. Cobalamin is the only biomolecule known to have a metal–carbon bond. The ease with which this bond is broken and the ability WHAT HAS THIS TO DO WITH . . . STAYING ALIVE?BOX 16.1 of the cobalt ion to change from one oxidation state to another are responsible for the importance of cobalamin as a biological catalyst. Zinc enzymes play several important roles in metabolism, including the expression of our genes, the digestion of food, the storage of insulin, and the building of collagen. In fact, zinc has so many functions in our systems that it has been called a “master hormone.” Its concentration in our bodies is about the same as that of iron, but the intracellular concentration of zinc declines with aging. It has even been suggested that aging is actually a result of the decline in intracellular zinc concentration. However, this decline cannot be slowed by eating more zinc; intracellular zinc concentrations are controlled by enzymes, not by the lack of zinc in the diet. Other d-metals are also vital to health. For example, chromium(III) plays a role in the regulation of glucose metabolism. Copper(I) is an essential nutrient for healthy cells and is the only biologically available Lewis acid with a ϩ1 charge. Related Exercise: 16.104 For Further Reading: J. J. R. Fraústo da Silva and R. J. P. Williams, The Biological Chemistry of the Elements: The Inorganic Chemistry of Life (Oxford: Oxford University Press, 1991). “Biological inorganic chemistry,” Chapter 27 in P. Atkins, T. Overton, J. Rourke, M. Weller, and F. Armstrong, Shriver & Atkins Inorganic Chemistry, 2010. National Institutes of Health Office of Dietary Supplements, “Dietary Supplement Fact Sheet: Zinc,” http://ods.od.nih.gov/FactSheets/ Zinc.asp, 2009. NH2 Co In cobalamin, vitamin B12, one of the six ligands forming an octahedral structure around a cobalt atom is an organic molecule attached through a carbon–cobalt bond (red). The bond is weak and easily broken. Molecular oxygen is transported throughout the body by attaching to the iron(II) atom in the heme group of hemoglobin. The iron(II) atom lies at the center of a square planar complex formed by nitrogen atoms. When the O2 molecule attaches to the iron, the plane of the heme group becomes distorted. Animation Box 16.1 O2 Fe is the cyanide ion. In the hexacyanoferrate(II) ion, [Fe(CN)6]4Ϫ , the CNϪ ions provide the electron pairs that form bonds to the Lewis acid Fe2ϩ . In the neutral complex Ni(CO)4, the Ni atom acts as the Lewis acid and the ligands are the CO molecules. Each ligand in a complex typically has at least one lone pair of electrons with which it bonds to the central atom or ion by forming a coordinate covalent bond. We say that the ligands coordinate to the metal when they form the complex in this way. In the chemical formula for a complex, we usually represent the ligands directly attached to the central ion by enclosing them and the central ion within rectangular brackets (the exceptions are neutral complexes). These ligands make up the coordination sphere of the central ion. The number of points at which ligands are attached to the central metal atom is called the coordination number of the complex (Fig. 16.16). The coordination number is 4 in Ni(CO)4 and 6 in [Fe(CN)6]4Ϫ . Because water is a Lewis base, it forms complexes with most d-block ions when they dissolve in it. Aqueous solutions of d-metal ions are usually solutions of their H2O complexes: Fe2ϩ (aq), for instance, is more accurately [Fe(OH2)6]2ϩ . Many complexes are prepared simply by mixing aqueous solutions of a d-metal ion with the appropriate Lewis base (Fig. 16.17); for example, [Fe(OH2)6]2ϩ (aq) ϩ 6 CNϪ (aq) [Fe(CN)6]4Ϫ (aq) ϩ 6 H2O(l) This is an example of a substitution reaction, a reaction in which one Lewis base takes the place of another. Here the CNϪ ions drive out H2O molecules from the coordination sphere of the [Fe(OH2)6]2ϩ complex and take their place. Replacement is less complete when certain other ions, such as ClϪ , are added to an iron(II) solution: [Fe(OH2)6]2ϩ (aq) ϩ ClϪ (aq) [FeCl(OH2)5]ϩ (aq) ϩ H2O(l) Because the color of a d-metal complex depends on the identity of the ligands as well as that of the metal, impressive changes in color often accompany substitution reactions (Fig. 16.18). The names of coordination compounds can become awesomely long because the identity and number of each type of ligand must be included. In most cases, chemists avoid the problem by using the chemical formula rather than the name itself. For instance, it is much easier to refer to [FeCl(OH2)5]ϩ than to pentaaquachloridoiron(II) ion, its formal name. However, names are sometimes needed, and they can be constructed and interpreted, in simple cases at least, by using the rules set out in Toolbox 16.1. Table 16.4 gives the names of common ligands and their abbreviations, which are used ¡ ¡ Coordination sphere Central metal ion Ligand (a) Co sp ) (b) (c) FIGURE 16.16 (a) Almost all sixcoordinate complexes are octahedral. Four-coordinate complexes are either (b) tetrahedral or (c) square planar. 2ϩ 4Ϫ 4Ϫ 2ϩ [Fe(OH2)6]2ϩ [Fe(CN)6]4Ϫ OH2 CN Fe CN CN CN NC NC OH2 OH2 OH2 Fe H2O H2O FIGURE 16.17 When potassium cyanide is added to a solution of iron(II) sulfate, the cyanide ions replace the H2O ligands of the [Fe(OH2)6]2ϩ complex (left) and produce a new complex, the hexacyanoferrate(II) ion, [Fe(CN)6]4Ϫ (right). The blue color is due to the polymeric compound called Prussian blue, which forms from the cyanoferrate ion. Further information on naming complexes can be found at http://old.iupac.org/publications/ books/seriestitles/nomenclature.html; refer to the “Red Book.” FIGURE 16.18 Some of the highly colored d-metal complexes. Left to right: aqueous solutions of [Fe(SCN)(OH2)5]2ϩ , [Co(SCN)4(OH2)2]2Ϫ , [Cu(NH3)4(OH2)2]2ϩ , and [CuBr4]2Ϫ . 16.5 COORDINATION COMPLEXES 683 TOOLBOX 16.1 HOW TO NAME d-METAL COMPLEXES AND COORDINATION COMPOUNDS CONCEPTUAL BASIS The aim of nomenclature is to be succinct but unambiguous. d-Metal complexes are identified by giving the names and numbers of the individual ligands. Because some names can be quite long, interpreting them is rather like eating a large bun: nibble it bite by bite, don’t try to swallow it in one gulp. The rules undergo periodic change in order to achieve greater clarity and consistency. The rules used here are consistent with the latest (2005) IUPAC recommendations. PROCEDURE The following rules are adequate for most common complexes; more elaborate rules are needed if the complex contains more than one metal atom. Note that some rules apply to naming the complex (formally, the “coordination entity”) and others to writing its chemical formula. A. Writing the formula 1. The chemical symbol of the central atom (usually a metal) is written first, followed by symbols for the ligands. The entire collection of symbols is placed between square brackets, with the overall charge denoted by a right-superscript. 2. The chemical symbols of ligands are written in alphabetical order; when different ligands contain the same element, those denoted by a single letter (e.g., O) take precedence over symbols represented by two or more letters (e.g., OH). If a particular point needs to be emphasized, then the order may be varied. Water as a ligand is denoted OH2 to emphasize that the O links to the metal atom. Examples: [FeCl(OH2)5]ϩ [Fe(NH3)5(OH2)]3ϩ 3. To avoid any ambiguity, the linking atom can be under- lined. Examples: [Fe(NCS)(OH2)5]2ϩ [Fe(NCS)(OH2)5]2ϩ B. Naming the complex 1. Name the ligands first and then the metal atom or ion. A Roman numeral denotes the oxidation number of the central metal ion. 2. Neutral ligands, such as H2NCH2CH2NH2 (ethylenediamine), have the same name as the molecule, except for H2O (aqua), NH3 (ammine), CO (carbonyl), and NO (nitrosyl). 3. Anionic ligands end in -o; for anions that end in -ide (such as chloride), -ate (such as sulfate), and -ite (such as nitrite), change the endings as follows: -ide -ido -ate -ato -ite -ito Examples: chlorido, sulfato, and nitrito. 4. Greek prefixes indicate the number of each type of ligand in the complex ion: 2 3 4 5 6 . . . di- tri- tetra- penta- hexa- . . . If the ligand already contains a Greek prefix (as in ethylenediamine) or if it is polydentate (able to attach at more than one binding site), then the following prefixes are used instead: 2 3 4 . . . bis- tris- tetrakis- . . . 5. Ligands are named in alphabetical order, ignoring the Greek prefix that indicates the number of each one present. [FeCl(OH2)5]ϩ pentaaquachloridoiron(II) ion [Cr(Cl)2(NH3)4]ϩ tetraamminedichloridochromium(III) ion (Note that in some cases the order of ligands in the name is not the same as the order in the formula.) 6. If there is an ambiguity in which atom is liked to the metal atom, then ␬E is added to the name in parentheses, where E denotes the connecting atoms (and ␬ is kappa): [Fe(NCS)(OH2)5]2ϩ thiocyanato(␬N)pentaaqua(III) iron [Fe(NCS)(OH2)5]2ϩ thiocyanato(␬S)pentaaqua(III) iron 7. If the complex has an overall negative charge (an anionic complex), the suffix -ate is added to the stem of the metal’s name. If the symbol of the metal originates from a Latin name (as listed in Appendix 2D), then the Latin stem is used. For example, the symbol for iron is Fe, from the Latin ferrum. Therefore, any anionic complex of iron ends with -ferrate followed by the oxidation number of the metal in Roman numerals: [Fe(CN)6]4Ϫ hexacyanidoferrate(II) ion [Ni(CN)4]2Ϫ tetracyanidonickelate(II) ion 8. The name of a coordination compound (as distinct from a complex cation or anion) is built in the same way as that of a simple compound, with the cation named before the anion: NH4[PtCl3(NH3)] ammonium amminetrichloridoplatinate(II) [Cr(NH3)4(OH)2]Br tetraamminedihydroxidochromium(III) bromide This procedure is illustrated in Example 16.1.¡¡¡ EXAMPLE 16.1 Naming complexes and coordination compounds (a) Name the coordination compound [Co(NH3)3(OH2)3]2(SO4)3. (b) Write the formula of sodium dichloridobis(oxalato)platinate(IV). PLAN Apply the rules in Toolbox 16.1. in the formulas of complexes. The rules have recently been changed, but as the older names are still in wide use, we give both. (a) There are three SO4 2Ϫ ions for every two complex ions. The complex cation must have a charge of ϩ3: [Co(NH3)3(OH2)3]3ϩ . 3ϩ (b) Two ClϪ ligands and two C2O4 2Ϫ ions are attached to Pt4ϩ . The charge on the complex is Ϫ2. All the ligands are neutral. Co is present as cobalt(III). There are three NH3 molecules (ammine) and three H2O molecules (aqua); ammine precedes aqua alphabetically. The cation is triamminetriaquacobalt(III), and the compound is triamminetriaquacobalt(III) sulfate. SOLVE TABLE 16.4 Common Ligands Formula* Name Neutral ligands OH2 aqua NH3 ammine NO nitrosyl CO carbonyl NH2CH2CH2NH2 ethylenediamine (en)† NH2CH2CH2NHCH2CH2NH2 diethylenetriamine (dien)‡ Anionic ligands FϪ fluorido ClϪ chlorido BrϪ bromido IϪ iodido OHϪ hydroxido O2Ϫ oxido CNϪ cyanido-␬C CNϪ isocyanido, cyanido-␬N NCSϪ thiocyanato-␬N NCSϪ isothiocyanato, thiocyanato-␬S NO2 Ϫ as ONOϪ nitrito-␬O NO2 Ϫ as NO2 Ϫ nitro, nitrito-␬N CO3 2Ϫ as OCO2 2Ϫ carbonato-␬O C2O4 2Ϫ as Ϫ O2CCO2 Ϫ oxalato (ox)† ethylenediaminetetraacetato (edta)§ SO4 2Ϫ as OSO3 2Ϫ sulfato *Ligand atoms that bond to the metal atom are in underlined in ambiquous cases. † Bidentate (attaches to two sites). ‡ Tridentate (attaches to three sites). § Hexadentate (attaches to six sites). ϪO OϪ OϪ OϪ N N O O O O Self-Test 16.3A (a) Name the compound [Fe(OH)(OH2)5]Cl2. (b) Write the formula of potassium diaquabis(oxalato)chromate(II). [Answer: (a) Pentaaquahydroxidoiron(III) chloride; (b) K2[Cr(OH2)2(ox)2]] Self-Test 16.3B (a) Name the compound [CoBr(NH3)5]SO4. (b) Write the formula of tetraamminediaquachromium(III) bromide. A complex is formed between a Lewis acid (the metal atom or ion) and a number of Lewis bases (the ligands). 16.6 The Shapes of Complexes The richness of coordination chemistry is enhanced by the variety of shapes that complexes can adopt. The most common complexes have coordination number 6. Almost all these species have their ligands at the vertices of a regular octahedron, with the metal ion at the center, and are called octahedral complexes (1). An example of an octahedral complex is the hexacyanidoferrate(II) ion, [Fe(CN)6]4Ϫ . The next most common coordination number is 4. Two shapes are typically found for this coordination number. In a tetrahedral complex, the four ligands are found at the vertices of a tetrahedron, as in the tetrachloridocobaltate(II) ion, [CoCl4]2Ϫ (2). An alternative arrangement, most notably for atoms and ions with d8 electron configurations such as Pt2ϩ and Au3ϩ , is for the ligands to lie at the corners of a square, giving a square-planar complex (3). Many other shapes are possible for complexes. The simplest are linear, with coordination number 2. An example is dimethylmercury(0), Hg(CH3)2 (4), which is a toxic compound formedbybacterialactiononaqueoussolutionsof Hg2ϩ ions.Coordinationnumbersashigh as 12 are found for members of the f-block, but they are rare in the d-block. One interesting type of d-metal compound in which there are 10 links between the ligands and the central metal ion is ferrocene, dicyclopentadienyliron(0), [Fe(C5H5)2] (5). Ferrocene is an aptly named “sandwich compound,” with the two planar cyclopentadienyl ligands the “bread” and the metal atom the “filling.” The formal name for a sandwich compound is a metallocene. Complexes of molybdenum and tungsten with eight ligands are known. These complexes have antiprismatic (6) or dodecahedral shapes (7). However, complexes with more than six ligands are rare. 16.6 THE SHAPES OF COMPLEXES 685 From Table 16.4, the symbol for oxalate is ox; Cl precedes ox alphabetically; the use of “bis” indicates that two oxalato ligands are present; “bis” is used instead of “di” because oxalate is polydentate (in this case, bidentate, with two points of connection). The complex anion is [PtCl2(ox)2]2Ϫ . The compound is Na2[PtCl2(ox)2]. 2 A tetrahedral complex 1 An octahedral complex Ligand Metal atom 3 A square-planar complex 4 Dimethylmercury(0) Hg 5 Ferrocene, Fe(C5H5)2 Fe 6 Square antiprism 7 Dodecahedral complex Some ligands are polydentate (“many toothed”) and can occupy more than one binding site simultaneously. For example, each end of the bidentate (that is, twotoothed) ethylenediamine molecule, NH2CH2CH2NH2 (8), has a nitrogen atom with a lone pair of electrons. This ligand is widely used in coordination chemistry and is abbreviated to en, as in tris(ethylenediamine)cobalt(III), [Co(en)3]3ϩ (9). The metal ion in [Co(en)3]3ϩ lies at the center of the three ligands as though pinched by three molecular claws. It is an example of a chelate (from the Greek word for “claw”), a complex containing one or more ligands that form a ring of atoms that includes the central metal atom. There are few hexadentate ligands, but a common example is the ethylenediaminetetraacetate ion, edta (the fully protonated acid is shown as 10; the red arrows show the points of attachment). This ligand forms complexes with many metal ions, including Pb2ϩ (11); hence, it is used as an antidote to lead poisoning. The production of some chelates releases toxic chemicals such as cyanides to the environment. However, new types of chelates that sequester d-block metals, bind with them, and remove them from solution, may provide solutions to some of society’s trickiest environmental problems. For example, the chelating agent sodium iminodisuccinate, which contains the hexadentate iminodisuccinate ion (12), can scavenge metal ions from solutions used to develop photographs and from drinking water and serves as a nontoxic additive to detergents. It is rapidly degraded to nontoxic products in the environment. Other environmentally friendly chelates accelerate the action of hydrogen peroxide and the combination is replacing chlorine bleaches in the production of paper, greatly reducing the release of toxic pollutants to the environment. Chelating ligands are quite common in nature. Mosses and lichens secrete chelating ligands to extract essential metal ions from the rocks on which they dwell. Chelate formation also lies behind the body’s strategy of producing a fever when infected by bacteria. The higher temperature kills bacteria by reducing their ability to synthesize a particular iron-chelating ligand. Complexes with coordination number 6 tend to be octahedral; those with coordination number 4 are either tetrahedral or square planar. Polydentate ligands can form chelates. 16.7 Isomers Many complexes and coordination compounds exist as isomers, compounds that contain the same numbers of the same atoms but in different arrangements. For example, the ions shown in (13a) and (13b) differ only in the positions of the ClϪ ligands, but they are distinct species, because they have different physical and chemical properties. Isomerism is of more than academic interest: for example, anticancer drugs based on complexes of platinum are active only if they are the correct isomer. The complex needs to have a particular shape to interact with DNA molecules. 8 Ethylenediamine, NH2CH2CH2NH2 9 [Co(en)3]3+ en en en Co 3ϩ 10 Ethylenediaminetetraacetic acid HO OH OH O O N N O O OH 11 An edta complex 12 Iminodisuccinate ion O Ϫ O OϪ NH O 13 Cl H3N NH3 NH3 (a) trans-[CoCl2(NH3)4]ϩ H3N ϩ Cl Co Cl H3N NH3 NH3 Cl (b) cis-[CoCl2(NH3)4]ϩ H3N ϩ Co Isomerism is very important in organic chemistry, and the topic is developed again in Section 18.2. Figure 16.19 summarizes the types of isomerism found in coordination complexes. The two major classes of isomers are structural isomers, in which the atoms are connected to different partners, and stereoisomers, in which the atoms have the same partners but are arranged differently in space. Structural isomers of coordination compounds are subdivided into ionization, hydrate, linkage, and coordination isomers. Ionization isomers differ by the exchange of a ligand with an anion or a neutral molecule outside the coordination sphere. For instance, [CoBr(NH3)5]SO4 and [Co(NH3)5SO4]Br are ionization isomers because the BrϪ ion is a ligand of the cobalt in the former but an accompanying anion in the latter. The isomers can be distinguished by their chemical properties, because an ion inside the complex is not available for reaction. Thus, the addition of a barium salt will result in the precipitation of barium sulfate from a solution of [CoBr(NH3)5]SO4, but not from a solution of [Co(NH3)5SO4]Br. Hydrate isomers differ by the exchange of an H2O molecule with another ligand in the coordination sphere (Fig. 16.20). For example, the solid hexahydrate of chromium(III) chloride, CrCl3и6H2O, may also be any of the three compounds [Cr(OH2)6]Cl3, [CrCl(OH2)5]Cl2иH2O, or [CrCl2(OH2)4]Clи2H2O. Hydrate isomers can often be distinguished by the stoichiometry of reactions in which the ion is exchanged with water. For example, 2 mol AgCl can be precipitated from 1 mol [CrCl(OH2)5]Cl2иH2O, but only 1 mol AgCl can be produced from 1 mol [CrCl2(OH2)4]Clи2H2O. Self-Test 16.4A When excess silver nitrate is added to 0.0010 mol CrCl3и6H2O in aqueous solution, 0.0010 mol AgCl is formed. Which hydrate isomer is present? [Answer: [CrCl2(OH2)4]Clи2H2O] Self-Test 16.4B When excess silver nitrate is added to 0.0010 mol CrCl3и6H2O in aqueous solution, 0.0030 mol AgCl is formed. Which hydrate isomer is present? Linkage isomers differ in the identity of the atom used by a given ligand to attach to the metal ion (Fig. 16.21). Common ligands that show linkage isomerism are SCNϪ versus NCSϪ , NO2 Ϫ versus ONOϪ , and CNϪ versus NCϪ , where the coordinating atom is written first in each pair. For example, NO2 Ϫ can form [CoCl(NH3)4(NO2)]ϩ and [CoCl(NH3)4(ONO)]ϩ . In the new system of nomenclature, the atom through which the ligand is coordinated is underlined, so these two complexes would be denoted [CoCl(NH3)4(NO2)]ϩ and [CoCl(NH3)4(NO2)]ϩ , respectively. The name used to specify the ligand is different in each case. For instance, nitro (modern name: nitrito-(␬N) signifies that the ligand is linked through the N atom and nitrito (modern name: nitrito␬O) that it is linked through an O atom. Table 16.4 lists the names to use for these so-called ambidentate ligands that can attach through atoms of different elements. 16.7 ISOMERS 687 Same atoms? Yes Yes Yes No No No Isomers Atoms linked to the same partners? Structural isomers Stereoisomers Complex identical to its mirror image? Ionization isomers Hydrate isomers Linkage isomers Coordination isomers Optical isomers Geometrical isomers FIGURE 16.19 The various types of isomerism in coordination compounds. (a) (b) FIGURE 16.20 Hydrate isomers. In part (a), the water molecule is simply part of the surrounding solvent; in part (b), the water molecule is present in the coordination sphere and a ligand (green sphere) is now present in the solution. (a) (b) FIGURE 16.21 Linkage isomers. In part (a), the ligand (here NCSϪ ) is attached through its N atom; but in part (b), it is attached through its S atom. Coordination isomers differ by the exchange of one or more ligands between a cationic complex and an anionic complex (Fig. 16.22). Thus, [Cr(NH3)6][Fe(CN)6] and [Fe(NH3)6][Cr(CN)6] are coordination isomers. Self-Test 16.5A Identify the type of isomer represented by each of the following pairs: (a) [Cu(NH3)4][PtCl4] and [Pt(NH3)4][CuCl4]; (b) [Cr(OH)2(NH3)4]Br and [CrBr(OH)(NH3)4]OH. [Answer: (a) Coordination; (b) ionization] Self-Test 16.5B Identify the type of isomer represented by each of the following pairs: (a) [Co(NCS)(NH3)5]Cl2 and [Co(NCS)(NH3)5]Cl2; (b) [CrCl(OH2)5]Cl2иH2O and [CrCl2(OH2)4]Clи2H2O. Although they are built from the same numbers and kinds of atoms, structural isomers have different chemical formulas, because the formulas show how the atoms are grouped in or outside the coordination sphere. Stereoisomers, on the other hand, have the same formulas, because their atoms have the same partners in the coordination spheres; only the spatial arrangement of the ligands differs. There are two types of stereoisomerism, geometrical and optical. In geometrical isomers, atoms are bonded to the same neighbors but have different locations relative to each other, as in (13a) and (13b): the complex with the ClϪ ligands on opposite sides of the central atom is called the trans isomer, and the complex with the ligands on the same side is called the cis isomer. Geometrical isomers can occur for square planar and octahedral complexes but not for tetrahedral complexes, because in the latter any pair of vertices is equivalent to any other pair. The chemical and physiological properties of geometrical isomers can differ greatly. For example, cis-[PtCl2(NH3)2] (14a) is used for chemotherapy treatment of cancer patients, but trans-[PtCl2(NH3)2] (14b) is therapeutically inactive. Optical isomers are nonsuperimposable mirror images of each other (Fig. 16.23). Both geometrical and optical isomerism can occur in an octahedral complex, as in [CoCl2(en)2]ϩ : the trans isomer (15a) is green, and the two alternative cis isomers (15b) and (15c), which are optical isomers of one another, are violet. Optical isomers can also occur whenever four different groups form a tetrahedral complex, but not if they form a square planar complex. FIGURE 16.22 The compounds in parts (a) and (b) are coordination isomers. In these compounds, a ligand has been exchanged between the cationic and anionic complexes. (a) (b) FIGURE 16.23 Optical isomers. The two complexes are each other’s mirror image; no matter how we rotate them, one complex cannot be superimposed on the other. 14 Cl (a) cis-[PtCl2(NH3)2] Pt NH3 Cl NH3 Cl (b) trans-[PtCl2(NH3)2] Pt NH3 H3N Cl 15 Cl ϩ en en Cl Co (a) trans-[CoCl2(en)2]ϩ ϩ en en Cl Cl Co (c) cis-[CoCl2(en)2]ϩ ϩ en en Cl Cl Co (b) cis-[CoCl2(en)2]ϩ A chiral complex is one that is not identical to its mirror image. Thus, all optical isomers are chiral. The cis isomers of [CoCl2(en)2]ϩ are chiral, and a chiral complex and its mirror image form a pair of enantiomers. The trans isomer is superimposable on its mirror image; complexes with this property are called achiral. Enantiomers differ in one physical property: chiral molecules display optical activity, the ability to rotate the plane of polarization of light (Box 16.2). In ordinary light, the plane of wave motion lies at random orientations around the direction of travel. In plane-polarized The name enantiomer comes from the Greek words meaning “both parts.” 16.7 ISOMERS 689 FIGURE 16.24 Plane-polarized light consists of radiation in which all the wave motion lies in one plane (as represented by the plane on the left). When such light passes through a solution of an optically active substance, the plane of the polarization is rotated through a characteristic angle that depends on the identity and concentration of the solute and the length of the path through the sample (right). Plane-polarized light wave Sample Rotated plane of polarization The electric field of plane-polarized light oscillates in a single plane. It can be prepared by passing ordinary, unpolarized light through a polarizer, which contains a material that allows the light to pass only if the electric field is aligned in a certain direction. An optically active substance, such as a chiral complex, rotates the plane of polarization of a beam of light by an angle that depends on the substance, its concentration, and the length of the sample cell. The light is passed through a sample cell about 10 cm long. To detect chirality, a solution of the chiral complex is placed in the cell. When the light emerges from the far end of the cell, the angle of its plane of polarization may have rotated from its original angle. To determine the angle, the light is passed through an analyzer that contains another polarizing filter. The filter is rotated until the intensity of the light that has passed through the polarizer, sample, and filter reaches its maximum. The angle of the plane of polarization is determined from the angle through which the filter was rotated to achieve this maximum setting. If the sample is not optically active, the light is not rotated by the sample and the maximum intensity is observed at an angle of 0°. The sample is optically active if the angle of rotation is different from 0°. The actual value depends on the identity of the complex, its concentration, the wavelength of the light, and the length of the sample cell. HOW DO WE KNOW . . . THAT A COMPLEX IS OPTICALLY ACTIVE?BOX 16.2 The determination of the angle of rotation is called polarimetry. In some cases, it can help a chemist follow a reaction. For example, if a reaction destroys the chirality of a complex, then the angle of optical rotation decreases with time as the concentration of the complex falls. Polarizer Angle of rotation Sample Analyzer A polarimeter is used to determine the optical activity of a substance by measuring the angle through which plane-polarized light is rotated by a sample. EXAMPLE 16.2 Identifying optical isomerism Which of the following complexes are chiral, and which form enantiomeric pairs? PLAN Draw the mirror image of each complex and mentally rotate it; judge whether any rotation will allow the mirror image to be superimposed on the original molecule. If not, then the complex is chiral. Determine which complexes form enantiomeric pairs by finding pairs in which the two complexes are the nonsuperimposable mirror images of each other. If imagining the three-dimensional structure is difficult, build simple paper models of the complexes. D B B C AB D B B A CB A B A C BC A B A B CC light, the wave lies in a single plane (Fig. 16.24). Plane-polarized light can be prepared by passing ordinary light through a special filter, such as the material used to make polarized sunglasses. One enantiomer of a chiral complex rotates the plane of polarization clockwise; its mirror-image partner rotates it by the same amount the other way. Achiral complexes are not optically active: they do not rotate the plane of polarization of polarized light. Some complexes are synthesized in the laboratory as racemic mixtures, or mixtures of enantiomers in equal proportions. Because enantiomers rotate the plane of polarization of light in opposite directions, a racemic sample is not optically active. (a) (b) (c) (d) SOLVE The mirror image of each complex is shown on the right of each pair. 690 CHAPTER 16 THE ELEMENTS: THE d-BLOCK (a) Rotating the mirror image about the vertical axis gives a structure identical to the original, and so superimposable on it. Not chiral (b) The mirror image is superimposable on the original. Not chiral (c) No rotation will allow the complex to be superimposed on its mirror image. Chiral (d) No rotation will allow the complex to be superimposed on its mirror image. Chiral When the mirror image of (c) is rotated by 90° around the vertical axis, it becomes the complex (d). (c) and (d) are a pair of enantiomers. Self-Test 16.6A Repeat Example 16.2 for the following complexes: [Answer: (a) Not chiral; (c) chiral; (b, d) chiral and enantiomeric] Self-Test 16.6B Repeat Example 16.2 for the following complexes: The varieties of isomerism are summarized in Fig. 16.19. Enantiomeric pairs of optical isomers rotate the plane of polarization of light in opposite directions. THE ELECTRONIC STRUCTURES OF COMPLEXES The striking feature of many coordination compounds is that they are colored or paramagnetic or both. How do these properties arise? To find out, we need to understand the electronic structures of complexes, the details of the bonding, and how their electrons are distributed. There are two major theories of bonding in d-metal complexes. “Crystal field theory” was first devised to explain the colors of solids, particularly ruby, which owes its color to Cr3ϩ ions, and then adapted to individual complexes. Crystal field theory is simple to apply and enables us to make useful predictions with very little labor. However, it does not account for all the properties of complexes. A more sophisticated approach, “ligand field theory” (Section 16.12), is based on molecular orbital theory and provides more detailed explanations. 16.8 Crystal Field Theory Crystal field theory takes a very simple view of the environment of the central metal atom (or ion): it supposes that each ligand can be represented by a point negative charge. These negative charges represent the ligand lone pairs directed toward the central metal atom (Fig. 16.25). Because the metal atom at the center of a complex is usually a positively charged ion, the negative charges representing the ligands are attracted to it. This attraction results in the formation of the complex. However, in most cases, there are still d-electrons on the central metal ion and the point charges representing the ligands interact with each electron to different extents that depend on the orientation of the d-orbital that it occupies. Crystal field theory explores these differences and uses them to account for the optical and magnetic properties of the complex. As an example, let’s consider an octahedral d1 complex, such as one containing a Ti3ϩ ion. In a free Ti3ϩ ion, all five 3d-orbitals have the same energy and the d-electron is equally likely to occupy any one of them. However, when a Ti3ϩ ion is dissolved in water, six H2O molecules surround it and form a [Ti(OH2)6]3ϩ complex. The six point charges representing the ligands lie on opposite sides of the central metal ion along the x-, y-, and z-axes. From Fig. 16.26, we can see that three of the orbitals (dxy, dyz, and dzx) have their lobes directed between the point charges. These three d-orbitals are called t2gorbitals. The other two d-orbitals (dz2 and dx2Ϫy2), have lobes that point directly toward the point charges, and are called eg-orbitals. Because the negative point charges representing the A C B B CD A B B B DC A C B A CB B C C B AA A C B B CB A A B B DC A B B D CB B D C B AA 16.8 CRYSTAL FIELD THEORY 691 The labels t2g and eg are derived from group theory, the mathematical theory of symmetry. The letter g indicates that the orbital does not change sign when we start from any point, pass through the nucleus, and end at the corresponding point on the other side of the nucleus. (a) (b) Ϫ Ϫ Ϫ Ϫ Ϫ Ϫ NH3 FIGURE 16.25 In the crystal field theory of complexes, the lone pairs of electrons that serve as the Lewis base sites on the ligands (a) are treated as equivalent to point negative charges (b). (a) (b) (c) (d) (a) (b) (c) (d) ligands repel electrons, the energy of the single d-electron is increased, but it is raised more if it occupies an eg-orbital than if it occupies a t2g-orbital. To express the fact that an electron in an octahedral complex has a different energy depending on which of the orbitals it occupies, we say that the three t2g-orbitals have a lower energy than the two eg-orbitals. The stability of a complex depends on the interaction energy between the central positive ion and its ligands. Typically the difference in energies of electrons in the t2g- and the eg-orbitals accounts only for about 10% of that energy, but it plays a major role in the optical and magnetic properties of the complex. The energy-level diagram for an octahedral complex in Fig. 16.27 helps to summarize these ideas. The energy separation between the two sets of orbitals is called the ligand field splitting, ⌬O (the O denotes octahedral). The three t2g-orbitals lie at an energy that is ⌬O below the average d-orbital energy in the complex, and the two eg-orbitals lie at an energy ⌬O above the average. Because the t2g-orbitals have the lower energy, we can predict that, in the ground state of the [Ti(OH2)6]3ϩ complex, the electron occupies one of them in preference to an eg-orbital and hence that the lowest energy electron configuration of the complex is t2g 1 . This ground-state configuration is represented by the box diagram in (16). The single d-electron of an octahedral [Ti(OH2)6]3ϩ complex can be excited from the t2g-orbital into an eg-orbital if it absorbs a photon of energy ⌬O (Fig. 16.28). The greater the splitting, the shorter the wavelength of the light that is absorbed by the complex. Therefore, we can use the wavelength of the electromagnetic radiation absorbed by a complex to determine the ligand field splitting. 3 5 2 5 692 CHAPTER 16 THE ELEMENTS: THE d-BLOCK z dxy eg-orbitals t2g-orbitals dzx dyzdx2 Ϫ y2dz2 x y eg 3 5 t2g ⌬O Ϫ⌬O 2 5 Ϫ⌬O Energy FIGURE 16.27 The energy levels of the d-orbitals in an octahedral complex with the ligand field splitting ⌬O. The horizontal line on the far left represents the average energy of the d-orbitals once the complex has formed; the lines on the right show the modification of their energies due to their different interactions with the ligands. Each orbital (represented by a box) can hold two electrons. FIGURE 16.26 In an octahedral complex with a central d-metal atom or ion, a dxy-orbital is directed between the ligand sites, and an electron that occupies it has a relatively low energy. The same lowering of energy occurs for dyz- and dzx-orbitals. A dz2-orbital points directly toward two ligands, and an electron that occupies it has a relatively high energy. The same rise in energy occurs for a dx2 Ϫy2-electron. Animation 16.26 16 t2g 1 t2g eg eg t2g ⌬O Energy FIGURE 16.28 When a complex is exposed to light with the correct frequency, an electron can be excited to a higher energy orbital and a photon of light is absorbed. Self-Test 16.7A The complex [Fe(OH2)6]3ϩ absorbs light of wavelength 700. nm. What is the value (in kilojoules per mole) of the ligand field splitting? [Answer: 171 kJиmolϪ1 ] Self-Test 16.7B The complex [Fe(CN)6]4Ϫ absorbs light of wavelength 305 nm. What is the value (in kilojoules per mole) of the ligand field splitting? The relative energies of the d-orbitals are different in complexes with different shapes. For example, in a tetrahedral complex, the three t2-orbitals point more directly at the ligands than the two e-orbitals do. As a result, in a tetrahedral complex, the t2-orbitals have a higher energy than the e-orbitals (Fig. 16.29). The ligand field splitting, ⌬T (where the T denotes tetrahedral), is generally smaller than in octahedral complexes, in part because there are fewer repelling ligands. Thinking point: Into what groups do you think the d-orbitals are split in a square-planar complex? In octahedral complexes, the eg-orbitals (dz2) and dx2؊y2) lie higher in energy than the t2g-orbitals (dxy, dyz, and dzx). The opposite is true in a tetrahedral complex, for which the ligand field splitting is smaller. 16.9 The Spectrochemical Series Different ligands affect the d-orbitals of a given metal atom or ion to different degrees and thus produce different values of the ligand field splitting. For example, the ligand field splitting is much greater in [Fe(CN)6]4Ϫ than it is in [Fe(OH2)6]2ϩ . The relative strengths of the splitting produced by a given ligand are much the same regardless of the identity of the d-metal in the complex. Thus, ligands can be arranged in a spectrochemical series according to the relative magnitudes of the ligand field splittings that they produce (Fig. 16.30). Ligands below the horizontal line in Fig. 16.30 produce only a small ligand field splitting, and so they are called weak-field ligands; ligands above 16.9 THE SPECTROCHEMICAL SERIES 693 t2 e ⌬T3 5 Ϫ⌬T 2 5 Ϫ⌬T Energy FIGURE 16.29 The energy levels of the d-orbitals in a tetrahedral complex with the ligand field splitting ⌬T. Each box (that is, orbital) can hold two electrons. The subscript g is not used to label the orbitals in a tetrahedral complex. EXAMPLE 16.3 Determining the ligand field splitting The complex [Ti(OH2)6]3ϩ absorbs light of wavelength 510. nm. What is the ligand field splitting in the complex in kilojoules per mole (kJиmolϪ1 )? PLAN Because a photon carries an energy h␯, where h is Planck’s constant and ␯ (nu) is the frequency of the radiation, it can be absorbed if h␯ ϭ ⌬O. The wavelength, ␭ (lambda), of light is related to the frequency by ␭ ϭ c/␯, where c is the speed of light (Section 1.2). Therefore, the wavelength of light absorbed and the ligand field splitting are related by ⌬O To report the ligand field splitting as a molar energy, multiply this expression by Avogadro’s constant: ⌬O SOLVE Because the wavelength absorbed is 510. nm (corresponding to 5.10 ϫ 10Ϫ7 m), it follows that the ligand field splitting is: = NAhc l = hc l The subscript g is not used to label the orbitals in a tetrahedral complex because there is no center of symmetry. 510 nm 235 kJ-molϪ1 From ⌬O ϭ NAhc/␭, ⌬O = 2.35 * 105 Jиmol-1 = 235 kJиmol-1 = (6.022 * 1023 mol-1 ) * (6.626 * 10-34 Jиs) * (2.998 * 108 mиs-1 ) 5.10 * 10-7 m the line produce a larger splitting and are called strong-field ligands. A CNϪ ion is therefore a strong-field ligand, whereas an H2O molecule is a weak-field ligand. Knowledge of relative ligand strengths allows us to understand the color of a complex ion and, as we shall see in Section 16.11, its magnetism as well. The replacement of one ligand by another gives us chemical control over color. Similarly, the substitution of weak-field ligands for strong-field ligands (or vice versa) acts like a chemical switch for turning paramagnetism on and off. The key idea is that the ligand field splitting affects the electron configuration of the complex. Because all five d-orbitals of an isolated metal atom or ion have the same energy, electrons occupy each orbital separately (Hund’s rule, Section 1.13 ) until five electrons have been accommodated. When the atom is part of a complex, we also have to take into account the difference in energies between the t2g and eg orbitals, because the order in which they are occupied depends on that difference. First, consider the metal atom or ion at the center of an octahedral complex. The energies of its d-orbitals are split by the ligands as shown in Fig. 16.27. The three t2g-orbitals all have the same energy and lie below the two eg-orbitals. The single d-electron of a d1 complex occupies one of the t2g-orbitals, and so the ground-state configuration is t2g 1 (see 16). The two d-electrons of a d2 complex occupy separate t2g-orbitals and give rise to the configuration t2g 2 (17). Similarly, a d3 complex will have the ground-state configuration t2g 3 (18). According to Hund’s rule, all these electrons have parallel spins, because that arrangement corresponds to the lowest energy. 694 CHAPTER 16 THE ELEMENTS: THE d-BLOCK Strong-field ligands Weak-field ligands CN− , CO en NH3 H2O ox OH− F− SCN− , Cl− Br− I− NO2 − FIGURE 16.30 The spectrochemical series. Strong-field ligands give rise to a large splitting between the t- and e-orbitals, whereas weak-field ligands give rise to only a small splitting. The horizontal line marks the approximate frontier between the two kinds of ligands. The changing color represents the increasing energy of light absorbed as the field strength increases. 17 t2g 2 t2g eg 18 t2g 3 t2g eg 19 t2g 4 t2g eg 20 t2g 3 eg 1 t2g eg A d4 octahedral complex presents a problem. The fourth electron could enter a t2g-orbital, resulting in a t2g 4 configuration. However, to do so, it would have to enter an orbital that is already half full; hence, it would experience a strong repulsion from the electron already there (19). To avoid this repulsion, it could occupy an empty eg-orbital to give a t2g 3 eg 1 configuration (20), but now it experiences a strong repulsion from the ligands. Which configuration has the lower energy depends on the ligands present. If ⌬O is large (as it is for strong-field ligands), the energy difference between the t2g- and eg-orbitals will be large and the configuration t2g 4 will have a lower energy than t2g 3 eg 1 . If ⌬O is small (as it is for weak-field ligands), t2g 3 eg 1 will be the lower energy configuration and hence the one adopted by the complex. A note on good practice: Note that a configuration with a single electron in an orbital is written with a superscript 1, as in t2g 3 eg 1 , not t2g 3 eg. Evaluate As expected, the number of unpaired electrons is greater for weak-field ligands than it is for strong-field ligands. Self-Test 16.8A Predict the electron configurations and the number of unpaired electrons of an octahedral d6 complex with (a) strong-field ligands and (b) weak-field ligands. [Answer: (a) t2g 6 , 0; (b) t2g 4 eg 2 , 4] Self-Test 16.8B Predict the electron configurations and the number of unpaired electrons of an octahedral d7 complex with (a) strong-field ligands and (b) weak-field ligands. Table 16.5 lists the configurations for d1 through d10 octahedral complexes, including the alternative configurations for d4 through d7 octahedral complexes. A dn complex 16.9 THE SPECTROCHEMICAL SERIES 695 EXAMPLE 16.4 Predicting the electron configuration of a complex Predict the electron configuration of an octahedral d5 complex with (a) strong-field ligands and (b) weak-field ligands, and state the number of unpaired electrons in each case. Anticipate (a) For strong-field ligands the energy levels are widely separated, and so we should expect the electrons to pair in the lower-energy orbitals, resulting in fewer unpaired electrons. (b) For weak-field ligands the energy levels are close together, so we should expect the electrons to be distributed across all the orbitals, resulting in the maximum number of unpaired electrons. PLAN Add electrons to the orbitals in accordance with the building-up principle, to obtain the lowest energy configuration. SOLVE (a) Because ⌬O is large, all five electrons enter the t2g-orbitals and four electrons must pair. t2g 5 ; 1 unpaired electron (b) Because ⌬O is small, the five electrons occupy all five orbitals without pairing. t2g 3 eg 2 ; 5 unpaired electrons TABLE 16.5 Electron Configurations of dn Complexes Number of Configuration d-electrons Octahedral complexes Tetrahedral complexes d1 t2g 1 e1 d2 t2g 2 e2 d3 t2g 3 e2 t2 1 Low spin High spin d4 t2g 4 t2g 3 eg 1 e2 t2 2 d5 t2g 5 t2g 3 eg 2 e2 t2 3 d6 t2g 6 t2g 4 eg 2 e3 t2 3 d7 t2g 6 eg 1 t2g 5 eg 2 e4 t2 3 d8 t2g 6 eg 2 e4 t2 4 d9 t2g 6 eg 3 e4 t2 5 d10 t2g 6 eg 4 e4 t2 6 with the maximum number of unpaired spins is called a high-spin complex. High-spin complexes are expected for weak-field ligands because the electrons can easily occupy both the t2g- and the eg-orbitals, and the greatest number of electrons then have parallel spins. A dn complex with the minimum number of unpaired spins is called a lowspin complex. We should expect a low-spin complex when the ligands are strong-field, because electrons enter the t2g-orbitals until they are completely full, even though they have to pair their spins. We can predict whether an octahedral complex is likely to be a high-spin or a low-spin complex by noting where the ligands lie in the spectrochemical series. If they are strong-field ligands, we expect a low-spin complex; if they are weakfield ligands, we expect a high-spin complex. Tetrahedral complexes are almost always high spin. We saw that ligand field splittings are smaller for tetrahedral than for octahedral complexes. Therefore, even if the ligands are classified as strong-field ligands for octahedral complexes, the splitting is so small in the corresponding tetrahedral complex that the t2-orbitals are energetically accessible. The electron configurations of d-block metal atoms and ions in complexes are obtained by applying the building-up principle to the d-orbitals, taking into account the strength of the ligand field splitting. Relative field-splitting strengths are summarized by the spectrochemical series. 16.10 The Colors of Complexes White light is a mixture of all wavelengths of electromagnetic radiation from about 400 nm (violet) to about 800 nm (red). When some of these wavelengths are removed from a beam of white light by passing the light through a sample, the emerging light is no longer white to the eye. For example, if red light is absorbed from white light, then the light that remains appears green. Conversely, if green is removed, then the light appears red. We say that red and green are each other’s complementary color—each is the color that white light appears when the other is removed (Fig. 16.31). We can see from the color wheel that, for example, if a substance looks blue (as does a copper(II) sulfate solution, for instance), then it is absorbing orange (580–620 nm) light. Conversely, if we know the wavelength (and therefore the color) of the light that a substance absorbs, then we can predict the color of the substance by noting the complementary color on the color wheel. Because [Ti(OH2)6]3ϩ absorbs 510-nm light, which is yellow-green light, the complex looks violet (Fig. 16.32). Because weak-field ligands generate small splittings, the complexes that they form absorb low-energy, long-wavelength radiation. The long wavelengths correspond to red light, and so these complexes exhibit colors near green. Because strong-field ligands result in large splittings, the complexes that they form should absorb high-energy, shortwavelength radiation, corresponding to the violet end of the visible spectrum. Such complexes can therefore be expected to have colors near orange and yellow (Fig. 16.33). 696 CHAPTER 16 THE ELEMENTS: THE d-BLOCK FIGURE 16.33 The effect on the color of the complex of substituting ligands with different ligand field strengths in octahedral cobalt(III) complexes in aqueous solution. Red Violet Blue GreenYellow Orange 430 400800 490 560 580 620 FIGURE 16.31 In a color wheel the color of light absorbed is opposite the color perceived. For example, a complex that absorbs orange light appears blue to the eye. FIGURE 16.32 Because [Ti(H2O)6]3ϩ absorbs yellow-green light (of wavelengths close to 510 nm), it looks violet in white light. 16.11 MAGNETIC PROPERTIES OF COMPLEXES 697 EXAMPLE 16.5 Predicting the magnetic properties of a complex Compare the magnetic properties of (a) [Fe(OH2)6]2ϩ ; (b) [Fe(CN)6]4Ϫ . Anticipate Because H2O is a weak-field ligand, we should expect the maximum number of unpaired electrons; hence, it is likely to be high spin and thus paramagnetic. The CNϪ ion is a strong-field ion and so its complexes are likely to be low spin and thus diamagnetic. PLAN To predict the magnetic properties of a complex, we need to know both the number of electrons on the central atom or ion and the position of the ligands in the spectrochemical series. Decide from their positions in the spectrochemical series whether the ligands are weak-field or strong-field. Then judge whether the complex is high spin or low spin. SOLVE (a) Determine the number of d-electrons. The Fe2ϩ ion is a d6 ion. CoMn NiFe RhTc Ru 97 108 3d64s2 Classify the ligand strength. H2O is a weak-field ligand. Strong Weak H2 O The colors that we have described arise from d–d transitions, in which an electron is excited from one d-orbital into another. In a charge-transfer transition an electron is excited from a ligand onto the metal atom or vice versa. Charge-transfer transitions are often very intense and are the most common cause of the familiar colors of d-metal complexes, such as the transition responsible for the deep purple of permanganate ions, MnO4 Ϫ (Fig. 16.34). Transitions between d-orbitals or between the ligands and the metal atom in complexes give rise to color; the wavelength of d–d transitions can be correlated with the magnitude of the ligand field splitting. 16.11 Magnetic Properties of Complexes As we saw in Box 3.2, a substance with unpaired electrons is paramagnetic and is pulled into a magnetic field. A substance without unpaired electrons is diamagnetic and is pushed out of a magnetic field. Many d-metal complexes have unpaired d-electrons and are therefore paramagnetic. We have just seen that a high-spin dn complex has more unpaired electrons than does a low-spin dn complex. A high-spin complex is therefore more strongly paramagnetic than a low-spin complex with the same number of d-electrons. Whether a complex is high spin or low spin depends on the ligands present. The d4 through d7 complexes of strong-field ligands have large energy gaps and so tend to be low spin and therefore only weakly paramagnetic or diamagnetic (Fig. 16.35). The d4 through d7 complexes of weak-field ligands have only a small energy gap between the t2g and eg orbitals and therefore tend to be high spin and strongly paramagnetic. FIGURE 16.34 In a ligand-to-metal charge-transfer transition, an energetically excited electron migrates from a ligand to the central metal ion. This type of transition is responsible for the intense purple of the permanganate ion, MnO4 Ϫ . t2g eg Energy (a) (b) FIGURE 16.35 (a) A strong-field ligand is likely to lead to a low-spin complex (in this case, the configuration is that of Fe3ϩ ). (b) Substituting weak-field ligands is likely to result in a high-spin complex. Evaluation As expected, the aqua complex is paramagnetic and the cyanido complex diamagnetic. Self-Test 16.9A What change in magnetic properties can be expected when NO2 Ϫ ligands in an octahedral complex are replaced by ClϪ ligands in (a) a d6 complex; (b) a d3 complex? [Answer: (a) The complex becomes paramagnetic; (b) there is no change in magnetic properties.] Self-Test 16.9B Compare the magnetic properties of [Ni(en)3]2+ with those of [Ni(OH2)6]2+ . The magnetic properties of a complex depend on the magnitude of the ligand field splitting. Strong-field ligands tend to form low-spin, weakly paramagnetic complexes; weak-field ligands tend to form high-spin, strongly paramagnetic complexes. 16.12 Ligand Field Theory Crystal field theory is based on a very primitive model of bonding. For example, ligands are not point charges: they are actual molecules or ions. The theory also leaves several questions unanswered. Why, for instance, is the electrically neutral molecule CO a strong-field ligand but the negatively charged ion ClϪ a weak-field ligand? To improve the model of bonding in complexes, chemists have turned to molecular orbital theory (Section 3.9). Ligand field theory describes bonding in complexes in terms of molecular orbitals built from the metal atom d-orbitals and ligand orbitals. In contrast to crystal field theory, which models the structure of the complex in terms of point charges, ligand field theory assumes, more realistically, that ligands are attached to the central metal atom or ion by covalent bonds. As we shall see, much of the work that we have done in connection with crystal field theory can be transferred into ligand field theory: the principal difference is the origin of the ligand field splitting. 698 CHAPTER 16 THE ELEMENTS: THE d-BLOCK For a strong-field ligand, predict a low-spin t2g 6 configuration. [Fe(CN)6]4Ϫ will have no unpaired electrons; therefore, diamagnetic. Classify the strength of the ligand. CNϪ is a strong-field ligand. Strong Weak CNϪ (b) Determine the number of d-electrons. The Fe2+ ion is a d6 ion. For a weak-field ligand, predict a high-spin t2g 4 eg 2 configuration. [Fe(OH2)6]2+ will have 4 unpaired electrons; therefore, paramagnetic. To describe the electronic structure of a complex, first we set up molecular orbitals from the available atomic orbitals in the complex, just as we would for a molecule. Consider an octahedral complex of a d-metal in Period 4, such as iron, cobalt, or copper. We need to consider the nine 4s-, 4p-, and 3d-orbitals of the central metal ion, because all these orbitals have similar energies. To simplify the discussion, we use only one atomic orbital on each of the ligands. For instance, for a ClϪ ligand, we use the Cl3p-orbital directed toward the metal atom; for an NH3 ligand, we use the sp3 lonepair orbital of the nitrogen atom. The six orbitals provided by the six ligands in an octahedral complex are represented by the tear-shaped lobes in Fig. 16.36. Each of these orbitals has cylindrical symmetry around the metal–ligand axis, and so each can form a ␴-orbital. There are nine valence orbitals on the metal atom and six on the ligands, giving 15 in all. We can therefore expect to find 15 molecular orbitals: it turns out, as we explain in a moment, that six are bonding, three are nonbonding, and six are antibonding. The energies of all 15 are displayed in Fig. 16.37, together with the labels that they are commonly given. Notice in Fig.16.37 that the t2g-orbitals on the metal atom have no partners among the ligands. There are simply no ligand orbitals to match them. Therefore, these three orbitals are nonbonding orbitals in the complex, whereas the eg orbitals are antibonding. Now we proceed exactly as we did in the discussion of diatomic molecules (Section 3.10): we use the building-up principle to work out the ground-state electron configuration. First, we need to count the available electrons. In a dn complex, n electrons are supplied by the metal; each ligand orbital supplies two electrons, and so 12 electrons are supplied by the ligands, giving 12 ϩ n in all. The first 12 electrons fill the six bonding orbitals. That leaves n electrons to be accommodated in the nonbonding and antibonding orbitals. At this point, notice that the next available orbitals (those in the upper, dark red box in Fig. 16.37) lie in exactly the same pattern as that encountered in crystal field theory. The only difference is that, in ligand field theory, we recognize the three t2gorbitals as nonbonding orbitals and the two eg-orbitals as antibonding between the metal and the ligands. That is, the ligand field splitting can be identified with the energy separation between nonbonding and antibonding orbitals. The remaining four orbitals are high-energy antibonding orbitals that are ordinarily unavailable to the electrons. From this point on, the analysis is the same as in crystal field theory. The order of filling these two sets of orbitals is exactly the same as in crystal field theory, and so is the discussion of optical and magnetic properties. If the ligand field splitting is large, then the t2g-orbitals are filled first, and we can expect a low-spin complex. If the ligand field splitting is small, then the eg-orbitals are occupied before spin-pairing begins in the t2g-orbitals, and we expect a high-spin complex. Although ligand field theory puts the discussion of bonding on a firmer basis, it has not yet explained all the puzzling features of crystal field theory. In particular, why is CO a strong-field ligand? Why is ClϪ a weak-field ligand despite its negative charge? We need to develop the model by considering the effects of other ligand orbitals. When we constructed the molecular orbitals, we considered only ligand orbitals that pointed directly at the central metal atom. Ligands also have orbitals perpendicular to the metal–ligand axis, which we can expect to contribute to bonding and antibonding ␲-orbitals. As Fig. 16.38 shows, a p-orbital on the ligand perpendicular to the axis of the metal–ligand bond can overlap with one of the t2g-orbitals to produce two new molecular orbitals, one bonding and one antibonding. The resulting bonding orbital lies below the energy of the original t2g-orbitals; the antibonding orbital lies above them. Now we count the number of electrons to accommodate. If the ligand is ClϪ , the Cl3p-orbital that we have used to build the metal–ligand ␲-orbital is full. It provides two electrons, which occupy a new molecular orbital, the bonding metal–ligand combination shown in Fig. 16.38a. The n d-electrons provided by the metal must therefore occupy the antibonding metal–ligand orbital. Because this molecular orbital is higher in energy than the original t2g-orbitals, the ligand field splitting is decreased by ␲-bonding. We see how ClϪ can be a weak-field ligand despite its negative charge. 16.12 LIGAND FIELD THEORY 699 Ligand ␴-orbital FIGURE 16.36 The tear-shaped objects are representations of the six ligand atomic orbitals that are used to build the molecular orbitals of an octahedral complex in ligand field theory. They might represent s- or p-orbitals on the ligands or hybrids of the two. Metal 4p 4s 3d Complex Ligand 12 electrons n electrons t1u t2g a1g a1g t1u eg eg FIGURE 16.37 The molecular orbital energy-level diagram for an octahedral complex. The 12 electrons provided by the six ligands fill the lowest six orbitals, which are all bonding orbitals. The n d-electrons provided by the central metal atom or ion are accommodated in the orbitals inside the upper box. The ligand field splitting is the energy separation of the nonbonding (t2g) and antibonding (eg) orbitals in the box. 700 CHAPTER 16 THE ELEMENTS: THE d-BLOCK ❑ 1 Explain trends in chemical and physical properties among the d-block elements (Sections 16.1 and 16.2). ❑ 2 Describe and write balanced equations for the principal reactions used to produce the elements in the first row (Period 4) of the d-block and in Groups 11 and 12 (Sections 16.3 and 16.4). ❑ 3 Describe the names, properties, and reactions of some of the principal compounds of the elements in the first row of the d-block (Sections 16.3 and 16.4). ❑ 4 Describe the operation of a blast furnace and how steel is made (Section 16.3). ❑ 5 Name and write formulas for d-metal complexes (Toolbox 16.1 and Example 16.1). ❑ 6 Identify pairs of ionization, linkage, hydrate, coordination, geometrical, and optical isomers (Self-Tests 16.4 and 16.5 and Example 16.2). ❑ 7 Determine the ligand field splitting from the wavelength of light absorbed by a complex (Example 16.3). ❑ 8 Use the spectrochemical series to predict the effect of a ligand on the color, electron configuration, and magnetic properties of a d-metal complex (Examples 16.4 and 16.5). ❑ 9 Describe bonding in d-metal complexes in terms of ligand field theory (Section 16.12). SKILLS YOU SHOULD HAVE MASTERED Trends in Properties You may find Appendix 2 helpful in answering these questions. 16.1 Which members of the d-block, those at the left or at the right of the block, are likely to have the more strongly negative standard potentials? Explain this observation. 16.2 Name five elements in the d-block that have positive standard potentials. 16.3 Identify the element with the larger atomic radius in each of the following pairs: (a) vanadium and titanium; (b) silver and gold; (c) vanadium and tantalum; (d) rhodium and iridium. 16.4 Identify the element with the larger atomic radius in each of the following pairs: (a) iron and chromium; (b) palladium and platinum; (c) tungsten and rhenium; (d) scandium and yttrium. 16.5 Identify the element with the higher first ionization energy in each of the following pairs: (a) iron and nickel; (b) nickel and copper; (c) osmium and platinum; (d) nickel and palladium; (e) hafnium and tantalum. 16.6 Identify the element with the higher first ionization energy in each of the following pairs: (a) manganese and cobalt; (b) manganese and rhenium; (c) chromium and zinc; (d) chromium and molybdenum; (e) palladium and platinum. 16.7 Explain why the density of mercury (13.55 gиcmϪ3 ) is significantly higher than that of cadmium (8.65 gиcmϪ3 ), whereas the density of cadmium is only slightly greater than that of zinc (7.14 gиcmϪ3 ). 16.8 Explain why the density of vanadium (6.11 gиcmϪ3 ) is significantly less than that of chromium (7.19 gиcmϪ3 ). Both vanadium and chromium crystallize in a body-centered cubic lattice. 16.9 (a) Describe the trend in the stability of oxidation states moving down a group in the d-block (for example, from chromium to molybdenum to tungsten). (b) How does this trend compare with the trend in the stabilities of oxidation states observed for the p-block elements on moving down a group? 16.10 Which oxoanion, CrO4 2Ϫ or WO4 2Ϫ , is expected to be the stronger oxidizing agent? Explain your choice. EXERCISES Now suppose the ligand is CO. The orbital that overlaps with the metal t2g-orbitals in this case is either the full bonding ␲-orbital or the empty antibonding ␲*-orbital of the CO molecule. It turns out that the latter orbital is closer in energy to the metal orbitals, and so it plays the dominant role in bond formation to the metal, as in Fig. 16.38b. There are no electrons from the ligand to accommodate because its ␲*-orbital is empty. The n d-electrons therefore enter the bonding metal–ligand orbital. Because this new molecular orbital is lower in energy than the original t2g-orbitals, the ligand field splitting is increased by ␲-bonding and CO is a strong-field ligand despite being electrically neutral. According to ligand field theory, the ligand field splitting is the energy separation between nonbonding and antibonding molecular orbitals built principally from d-orbitals. When ␲-bonding is possible, the ligand field splitting is decreased if the ligand supplies ␲-electrons and is increased if the ligand does not supply ␲-electrons. FIGURE 16.38 The effect of ␲-bonding on ligand field splitting. (a) In this case, the occupied ␲orbital of the ligand is close in energy to the ligand t2g orbitals and they overlap to form bonding and antibonding combinations. The ligand-field splitting is reduced. (b) In this case, the unoccupied antibonding ␲*-orbital of the ligand is close in energy to the ligand t2g orbitals and they overlap to form bonding and antibonding combinations. In this case, the ligand-field splitting is increased. (a) (b) t2g t2g ␲ ␲* ␲ eg ⌬O decreased ␲* ␲* t2g eg ⌬O increased ␲ EXERCISES 701 16.11 Which of the elements vanadium, chromium, and manganese is most likely to form an oxide with the formula MO3? Explain your answer. 16.12 Which of the elements scandium, molybdenum, and copper is most likely to form a chloride with the formula MCl4? Explain your answer. Selected Elements: A Survey 16.13 Predict the major products of each of the following reactions and then balance the skeletal equations: (a) TiCl4(s) ϩ Mg(s) (b) CoCO3(s) ϩ HNO3(aq) : (c) V2O5(s) ϩ Ca(l) 16.14 Predict the major products of each of the following reactions and then balance the skeletal equations: (a) FeCr2O4(s) ϩ C(s) (b) CrO4 2Ϫ (s) ϩ H3Oϩ (aq) : (c) MnO2(s) ϩ Al(s) 16.15 Give the systematic name and chemical formula of the principal component of (a) rutile; (b) hematite; (c) pyrolusite; (d) chromite. 16.16 Give the systematic name and chemical formula of the principal component of (a) magnetite; (b) malachite; (c) ilmenite; (d) chalcocite. 16.17 (a) What reducing agent is used in the production of iron from its ore? (b) Write chemical equations for the production of iron in a blast furnace. (c) What is the major impurity in the product of the blast furnace? 16.18 (a) What is the purpose of adding limestone to a blast furnace? (b) Write chemical equations that show the reactions of lime in a blast furnace. 16.19 Use Appendix 2B to determine whether an acidic sodium dichromate solution can oxidize (a) bromide ions to bromine and (b) silver(I) ions to silver(II) ions under standard conditions. 16.20 Use Appendix 2B to determine whether an acidic potassium permanganate solution can oxidize (a) chloride ions to chlorine and (b) mercury metal to mercury(I) ions under standard conditions. 16.21 Write the chemical equation that describes each of the following processes: (a) solid V2O5 reacts with acid to form the VO2ϩ ion; (b) solid V2O5 reacts with base to form the VO4 3Ϫ ion. 16.22 Write the chemical equation that describes each of the following processes: (a) the production of chromium by the thermite reaction; (b) the corrosion of copper metal by carbon dioxide in moist air; (c) the purification of nickel by using carbon monoxide. 16.23 By considering electron configurations, explain why gold and silver are less reactive than copper. 16.24 By considering electron configurations, suggest a reason why iron(III) is readily prepared from iron(II) but the conversion of nickel(II) and cobalt(II) into nickel(III) and cobalt(III) is much more difficult. 16.25 (a) Explain why the dissolution of a chromium(III) salt produces an acidic solution. (b) Explain why the slow addition of hydroxide ions to a solution containing chromium(III) ions first produces a gelatinous precipitate that subsequently dissolves with further addition of hydroxide ions. Write chemical equations showing these aspects of the behavior of chromium(III) ions. 16.26 Some of the atomic properties of manganese differ markedly from its neighbors. For example, at constant pressure it takes 400 kJ (2 sf) to atomize 1.0 mol Cr(s) and 420 kJ to atomize 1.0 mol Fe(s), but only 280 kJ to atomize 1.0 mol Mn(s). Propose an explanation, using the electron configurations of the gaseous atoms, for the lower enthalpy of atomization of manganese. Coordination Compounds 16.27 Name each of the following complex ions and determine the oxidation number of the metal: (a) [Fe(CN)6]4Ϫ ; (b) [Co(NH3)6]3ϩ ; (c) [Co(CN)5(OH2)]2Ϫ ; (d) [Co(SO4)(NH3)5]ϩ . 16.28 Name each of the following complex ions and determine the oxidation number of the metal: (a) [CrCl3(NH3)2(OH2)]ϩ ; (b) [Rh(en)3)]3ϩ ; (c) [Fe(ox)(Br)4]3Ϫ ; (d) [Ni(OH)(OH2)5]2ϩ . 16.29 Use the information in Table 16.4 to write the formula for each of the following coordination compounds: (a) potassium hexacyanidochromate(III); (b) pentaamminesulfatocobalt(III) chloride; (c) tetraamminediaquacobalt(III) bromide; (d) sodium bisoxalato(diaqua)ferrate(III). 16.30 Use the information in Table 16.4 to write the formula for each of the following coordination compounds: (a) tetraamminedihydroxidochromium(III) chloride; (b) sodium tetrachloridoplatinate(II); (c) triamminetrichloridonickel(IV) sulfate; (d) sodium tris(oxalato)rhodium(III); (e) lithium chloridohydroxidobis(oxalato)rhodate(III) octahydrate. 16.31 Which of the following ligands can be polydentate? If the ligand can be polydentate, give the maximum number of places on the ligand that can bind simultaneously to a single metal center: (a) HN(CH2CH2NH2)2; (b) CO3 2Ϫ ; (c) H2O; (d) oxalate. 16.32 Which of the following ligands can be polydentate? If the ligand can be polydentate, give the maximum number of places on the ligand that can bind simultaneously to a single metal center: (a) chloride ion; (b) cyanide ion; (c) ethylenediaminetetraacetate; (d) N(CH2CH2NH2)3. 16.33 Which of the following isomers of diaminobenzene can form chelating complexes? Explain. 16.34 Which of the following ligands do you expect to form chelating complexes? Explain. (a) Bipyridine (b) ortho-Phenanthroline (c) Pyrimidine 16.35 With the help of Table 16.4, determine the coordination number of the metal ion in each of the following complexes: (a) [NiCl4]2Ϫ ; (b) [Ag(NH3)2]ϩ ; (c) [PtCl2(en)2]2ϩ ; (d) [Cr(edta)]Ϫ . N NNNN N NH2 NH2 NH2 NH2 NH2 NH2 ¡ ¢ ¡ ¢ ¡ ¢ ¡ ¢ (a) (b) (c) 702 CHAPTER 16 THE ELEMENTS: THE d-BLOCK 16.36 With the help of Table 16.4, determine the coordination number of the metal ion in each of the following complexes: (a) [Ir(en)3)]3ϩ ; (b) [Fe(ox)3)]3Ϫ ; (c) [PtCl2(NH3)2]; (d) Fe(CO)5. 16.37 Identify the type of structural isomerism that exists in each of the following pairs of compounds: (a) [Co(NO2)(NH3)5]Br2 and [Co(ONO)(NH3)5]Br2 (b) [Pt(SO4)(NH3)4](OH)2 and [Pt(OH)2(NH3)4]SO4 (c) [CoCl(NCS)(NH3)4]Cl and [CoCl(NCS)(NH3)4]Cl (d) [CrCl(NH3)5]Br and [CrBr(NH3)5]Cl 16.38 Identify the type of structural isomerism that exists in each of the following pairs of compounds: (a) [Cr(en)3][Co(ox)3] and [Co(en)3][Cr(ox)3] (b) [CoCl2(NH3)4]ClиH2O and [CoCl(NH3)4(OH2)]Cl2 (c) [Co(CN)5(NCS)]3Ϫ and [Co(CN)5(NCS)]3Ϫ (d) [Pt(NH3)4][PtCl6] and [PtCl2(NH3)4][PtCl4] 16.39 Which of the following coordination compounds can have cis and trans isomers? If such isomerism exists, draw the two structures and name the compound: (a) [CoCl2(NH3)4]ClиH2O; (b) [CoCl(NH3)5]Br; (c) [PtCl2(NH3)2], a square planar complex. 16.40 Which of the following coordination compounds can have cis and trans isomers? If such isomerism exists, draw the two structures and label the compounds: (a) [Fe(OH)2(OH2)4]ϩ ; (b) [RuBr(NH3)4]2ϩ ; (c) [Co(NH3)3(OH2)3]3ϩ . 16.41 How many isomers are possible for [Cr(NO2)(NH3)5]Cl2? Consider all types of isomerism and draw each isomer. 16.42 How many isomers are possible for [CoCl(NCS) (OH2)4]ClиH2O? Consider all types of isomerism and draw each isomer. 16.43 Is either of the following complexes chiral? If both complexes are chiral, do they form an enantiomeric pair? 16.44 Is either of the following complexes chiral? If both complexes are chiral, do they form an enantiomeric pair? The Electronic Structures of Complexes 16.45 Determine the number of valence electrons present in each of the following metal ions: (a) Ti2ϩ ; (b) Tc2ϩ ; (c) Irϩ ; (d) Agϩ ; (e) Y3ϩ ; (f) Zn2ϩ . 16.46 Determine the number of valence electrons present in each of the following metal ions: (a) Co2ϩ ; (b) Mo4ϩ ; (c) Ru4ϩ ; (d) Pt2ϩ ; (e) Os3ϩ ; (f) V3ϩ . 16.47 Draw an orbital energy-level diagram (like those in Figs. 16.27 and 16.29 ) showing the configuration of d-electrons on the metal ion in each of the following complexes: (a) [Co(NH3)6]3ϩ ; (b) [NiCl4]2Ϫ (tetrahedral); (c) [Fe(OH2)6]3ϩ ; (d) [Fe(CN)6]3Ϫ . Predict the number of unpaired electrons for each complex. 16.48 Draw an orbital energy-level diagram (like those in Figs. 16.27 and 16.29) showing the configuration of d-electrons on the metal ion in each of the following complexes: (a) [Zn(OH2)6]2ϩ ; (b) [CoCl4]2Ϫ (tetrahedral); (c) [Co(CN)6]3Ϫ ; (d) [CoF6]3Ϫ . Predict the number of unpaired electrons for each complex. 16.49 The complexes (a) [Co(en)3]3ϩ and (b) [Mn(CN)6]3Ϫ have low-spin electron configurations. How many unpaired electrons, if any, are there in each complex? 16.50 The complexes (a) [FeF6]3Ϫ and (b) [Co(ox)3]4Ϫ have highspin electron configurations. How many unpaired electrons are there in each complex? 16.51 Explain the difference between a weak-field ligand and a strong-field ligand. What measurements can be used to classify them as such? 16.52 Describe the changes that may take place in a compound’s properties when weak-field ligands are replaced by strong-field ligands. 16.53 When the paramagnetic [Fe(CN)6]3Ϫ ion is reduced to [Fe(CN)6]4Ϫ , the ion becomes diamagnetic. However, when the paramagnetic [FeCl4]Ϫ ion is reduced to [FeCl4]2Ϫ , the ion remains paramagnetic. Explain these observations. 16.54 When the paramagnetic [Co(CN)6]4Ϫ ion is oxidized to [Co(CN)6]3Ϫ , the ion becomes diamagnetic. However, when the paramagnetic [Co(ox)3]4Ϫ is oxidized to [Co(ox)3]3Ϫ , the ion remains paramagnetic. Explain these observations. 16.55 Of the two complexes (a) [CoF6]3Ϫ and (b) [Co(en)3]3ϩ , one appears yellow and the other appears blue. Match the complex to the color and explain your choice. 16.56 Which of the complexes [Cu(OH2)6]2ϩ or [Cu(Br)6]4Ϫ absorbs at the longer wavelength? 16.57 The complex [Ni(NH3)6]2ϩ has a ligand field splitting of 209 kJиmolϪ1 and forms a purple solution. What is the wavelength and color of the absorbed light? 16.58 The complex [TiCl6]3Ϫ has a ligand field splitting of 160. kJиmolϪ1 and forms an orange solution. What is the wavelength and color of the absorbed light? 16.59 The complex [Co(CN)6]3Ϫ is pale yellow. (a) How many unpaired electrons are present in the complex? (b) If ammonia molecules replace the cyanide ions as ligands, will the wavelength of the radiation absorbed be longer or shorter? 16.60 In aqueous solution, water competes effectively with bromide ions for coordination to Cu2ϩ ions. The hexaaquacopper(II) ion is the predominant species in solution. However, in the presence of a large concentration of bromide ions, the solution becomes deep violet. This violet color is due to the presence of the tetrabromocuprate(II) ions, which are tetrahedral. This process is reversible, and so the solution becomes light blue again on dilution with water. (a) Write the formulas of the two complex ions of copper(II) that form. (b) Is the change in color from violet to blue on dilution expected? Explain your reasoning. 16.61 Suggest a reason why Zn2ϩ (aq) ions are colorless. Would you expect zinc compounds to be paramagnetic? Explain your answer. A C C B AB A A B C DA A C C D AB A B B A DC (a) (b) (a) (b) EXERCISES 703 16.62 Suggest a reason why copper(II) compounds are often colored but copper(I) compounds are colorless. Which oxidation number results in paramagnetic compounds? 16.63 Estimate the ligand field splitting for (a) [CrCl6]3Ϫ (␭max ϭ 740 nm), (b) [Cr(NH3)6]3ϩ (␭max ϭ 460 nm), and (c) [Cr(OH2)6]3ϩ (␭max ϭ 575 nm), where ␭max is the wavelength of the most intensely absorbed light. (d) Arrange the ligands in order of increasing ligand field strength. 16.64 Estimate the ligand field splitting for (a) [Co(CN)6]3Ϫ (␭max ϭ 295 nm), (b) [Co(NH3)6]3ϩ (␭max ϭ 435 nm), and (c) [Co(OH2)6]3ϩ (␭max ϭ 540 nm), where ␭max is the wavelength of the most intensely absorbed light. (d) Arrange the ligands in order of increasing ligand field strength. 16.65 Which d-orbitals on the metal ion are used to form ␴-bonds between octahedral metal ions and ligands? 16.66 Which d-orbitals on the metal ion are used to form ␲-bonds between octahedral metal ions and ligands? 16.67 Ligands that can interact with a metal center by forming a ␲-type bond are commonly called ␲-acids and ␲-bases. The definitions of ␲-acid and ␲-base are similar to those used for Lewis acidity. A ␲-acid is a ligand that can accept electrons by using ␲-orbitals, and a ␲-base donates electrons by using ␲-orbitals. On the basis of these definitions, describe each of the following ligands as either a ␲-acid, a ␲-base, or neither: (a) CNϪ ; (b) ClϪ ; (c) H2O; (d) en. (e) Place them in order of increasing ligand field splitting. 16.68 Describe each of the following ligands as either a ␲-acid, a ␲-base, or neither (see Exercise 16.67): (a) NH3; (b) ox; (c) FϪ ; (d) CO. (e) Place them in order of increasing ligand field splitting. 16.69 Is the best description of the t2g-orbitals in [Co(OH2)6]3ϩ (a) bonding, (b) antibonding, or (c) nonbonding? Explain how you reached that conclusion. 16.70 Is the best description of the t2g-orbitals in [Fe(CN)6]3Ϫ (a) bonding, (b) antibonding, or (c) nonbonding? Explain how you reached that conclusion. 16.71 Is the best description of the eg-orbitals in [Fe(OH2)6]3ϩ (a) bonding, (b) antibonding, or (c) nonbonding? Explain how you reached that conclusion. 16.72 Is the best description of the t2g-orbitals in [CoF6]3Ϫ (a) bonding, (b) antibonding, or (c) nonbonding? Explain how you reached that conclusion. 16.73 Using concepts of ligand field theory, explain why water is a weaker field ligand than ammonia. 16.74 Using concepts of ligand field theory, explain why ethylenediamine is a weaker field ligand than CO. Integrated Exercises 16.75 An analytical chemistry team analyzed a green mineral salt found in the glaze of an ancient pot. When they heated the mineral it gave off a colorless gas that turned limewater milky white. When they dissolved the mineral in sulfuric acid the same colorless gas was released and a blue solution formed. Suggest a possible formula for the compound and justify your conclusion. 16.76 An analytical chemistry team analyzed a yellow mineral salt found in the pigments in the studio of a Renaissance artist. When hydrochloric acid was added the mineral dissolved and formed an orange solution. The original salt was dissolved in water to form a yellow solution. When barium chloride was added to the solution a yellow solid formed. The solid was filtered and the water evaporated from the filtrate. The colorless chloride remaining was subjected to a flame test. It gave a bright yellow color to the flame. Suggest a possible formula for the compound and justify your conclusion. 16.77 Vanadium is used in steelmaking because it forms V4C3, which increases the strength of the steel and its resistance to wear. It is formed in the steel by adding V2O5 to iron ore as it is reduced by carbon during the refining process. (a) What is the likely oxidation state of vanadium in V4C3? (b) Write a balanced equation for the reaction of V2O5 with carbon to form V4C3 and CO2. 16.78 When 5.25 g of [Ni(OH2)x]Cl2 is heated, 2.387 g of water and 1.57 g of chlorine gas are collected. How many water molecules are present in the complex? 16.79 The compound Cr(OH)3 is very insoluble in water; therefore, electrochemical methods must be used to determine its Ksp. Given that the reduction of Cr(OH)3(s) to Cr(s) and hydroxide ions has a standard potential of Ϫ1.34 V, calculate the solubility product for Cr(OH)3. 16.80 The complex ion [Ni(NH3)6]2ϩ forms in a solution containing 0.16 M NH3(aq) and 0.010 M Ni2ϩ (aq). If the formation constant for [Ni(NH3)6]2ϩ is 1.0 ϫ 109 , what are the equilibrium concentrations? 16.81 (a) Draw all the possible isomers of the square planar complex [PtBrCl(NH3)2] and name each isomer. (b) How can the existence of these isomers be used to show that the complex is square planar rather than tetrahedral? 16.82 Draw the structures of all possible isomeric forms of [CrBrClI(NH3)3]. Which isomers are chiral? 16.83 Suggest a chemical test for distinguishing between (a) [Ni(SO4)(en)2]Cl2 and [NiCl2(en)2]SO4; (b) [NiI2(en)2]Cl2 and [NiCl2(en)2]I2. 16.84 Trigonal bipyramidal complexes in which a metal ion is surrounded by five ligands are more rare than octahedral or tetrahedral complexes, but many are known. Will trigonal bipyramidal compounds of the formula MX3Y2 exhibit isomerism? If so what types of isomerism are possible? 16.85 (a) Sketch the orbital energy-level diagrams for [MnCl6]4Ϫ and [Mn(CN)6]4Ϫ . (b) How many unpaired electrons are present in each complex? (c) Which complex absorbs the longer wavelengths of incident electromagnetic radiation? Explain your reasoning. 16.86 (a) Which types of ligands are ␲-acid ligands in general (see Exercise 16.67), strong-field or weak-field? (b) Which types of ligands are ␲-base ligands in general, strong-field or weak-field? 16.87 The trigonal prismatic structure shown in the illustration was once proposed for the [CoCl2(NH3)4] complex. Use the fact that only two isomers of the complex are known to rule out the prismatic structure. 16.88 A hexagonal planar structure was once proposed for the [CrCl3(NH3)3] complex. Use the fact that only two isomers of the complex are known to rule out the hexagonal planar structure. 16.89 Before the structures of octahedral complexes were determined, various means were used to explain the fact that d-metal ions could bind to a greater number of ligands than expected on the basis of their charges. For example, Co3ϩ can bind to six ligands, not just three. An early theory attempted to explain this behavior by postulating that once three ligands had attached to a metal ion of charge ϩ3, the others bonded to the attached ligands, forming chains of ligands. Thus, the compound [Co(NH3)6]Cl3, which we now know to have an octahedral structure, would have been described as Co(NH3—NH3—Cl)3. Show how the chain theory is not consistent with at least two properties of coordination compounds. 16.90 How many chelate rings are present in: (a) [Ru(ox)3]3Ϫ ; (b) [Fe(trien)]3ϩ (trien is triethylenetetramine); (c) [Cu(dien)2]2ϩ ? 16.91 Suggest the form that the orbital energy-level diagram would take for a square planar complex with the ligands in the xy plane, and discuss how the building-up principle applies. Hint: The dz2-orbital has more electron density in the xy plane than the dzx- or dyz-orbitals but less than the dxy-orbital. 16.92 Nickel(II) complexes with weak-field ligands such as the bromide ion have been found to be octahedral, but nickel(II) complexes with strong-field ligands have been found to be square planar. Explain these findings. (See Exercise 16.91.) 16.93 In a nickel-containing enzyme, various groups of atoms in the enzyme form a complex with the metal, which was found to be in the ϩ2 oxidation state and to have no unpaired electrons. What is the most probable geometry of the Ni2ϩ complex: (a) octahedral; (b) tetrahedral; (c) square planar (see Exercise 16.91)? Justify your answer by drawing the orbital energy-level diagram of the ion. 16.94 Is there a correlation between the ligand field strength of the halide ions FϪ , ClϪ , BrϪ , and IϪ and the electronegativity of the halogen? If so, can this correlation be explained by ligand field theory? Justify your answer. 16.95 The complexes [Co(NH3)6]2ϩ , [Co(OH2)6]2ϩ , and [CoCl4]2Ϫ form colored solutions. One is pink, one yellow, and the third blue. Use the spectrochemical series and the relative magnitudes of ⌬O and ⌬T to match each color to a complex. Explain your reasoning. 16.96 Two chemists prepared a complex and determined its formula, which they wrote as [CrCl3NH3]и2H2O. However, when they dissolved 2.11 g of the compound in water and added an excess of silver nitrate, 2.87 g of AgCl precipitated and they realized that the formula was incorrect. Write the correct formula of the compound and draw its structure, including all possible isomers. 16.97 A solid pink salt has the formula CoCl3и5NH3иH2O. When AgNO3 is added to the pink solution containing 0.0010 mol of the salt, 0.43 g of AgCl precipitates. Heating the salt produces a purple solid with the formula CoCl3и5NH3. (a) Write the correct formula and name of the pink salt. (b) When AgNO3 is added to a solution containing 0.0010 mol of the purple salt, 0.29 g of AgCl precipitates. Write the correct formula and name of the purple salt. 16.98 cis-Platin is an anticancer drug with a structure that can be viewed on the Web site. (a) What is the formula and systematic name for the compound cis-Platin? (b) Draw any isomers that are possible for this compound. Label any isomers that are optically active. (c) What is the coordination geometry of the platinum atom? 16.99 The Web site contains a molecular model of an iridium complex with formula IrCl(CO)2[P(C6H5)3]2. (a) View this structure and determine the coordination geometry of the iridium atom. (b) What is the oxidation number of the iridium atom? (c) Are isomers of this compound possible? If so, draw them. Label any that are optical isomers. 16.100 Use the information in Appendix 2B to determine the equilibrium constant for the disproportionation of mercury(I) ions in aqueous solution at 25°C to mercury metal and mercury(II) ions. 16.101 Use the information in Appendix 2B to determine the equilibrium constant for the disproportionation of copper(I) ions in aqueous solution at 25°C to copper metal and copper(II) ions. 16.102 Ligand field theory predicts that different types of metal ions will form more stable complexes with certain types of ligands. From your understanding of ligand field theory, predict what types of ligands (weak-field or strong-field) would form the more stable complexes with the early transition metals in their highest oxidation states. Likewise, predict the types of ligands that would form the more stable complexes of the late transition metals (those to the right of the d-block) in their lowest oxidation states. Explain the reasoning behind your choices. 16.103 The concentration of Fe2ϩ ions in an acid solution can be determined by a redox titration with either KMnO4 or K2Cr2O7. The reduction products of these reactions are Mn2ϩ and Cr3ϩ , and in each case the iron is oxidized to Fe3ϩ . In one titration of an acidified Fe2ϩ solution, 25.20 mL of 0.0210 M K2Cr2O7(aq) was required for complete reaction. If the titration had been carried out with 0.0420 M KMnO4(aq), what volume of the permanganate solution would have been required for complete reaction? Chemistry Connections 16.104 Hemoglobin contains one heme group per subunit. The heme group is an Fe2ϩ complex that is coordinated to the four N atoms in a porphyrin ligand in a square planar arrangement and to an N atom on the histidine residue (see Table 19.4) on the subunit. The hemoglobin molecule transports O2 through the body by using a bond between O2 and the Fe2ϩ ion at the center of the heme group. The Fe2ϩ ion can be viewed as having octahedral coordination, with one position unoccupied and available for bonding to oxygen. (See Box 16.1 and Section 10.13.) (a) Draw the structure of the heme group with the sixth site not coordinated. (b) The deoxygenated heme is a high-spin complex of the Fe2ϩ ion. When the oxygen molecule binds to the Fe2ϩ ion as the sixth ligand, the resulting octahedral complex is low-spin. Predict the number of unpaired electrons in (i) deoxygenated and (ii) oxygenated heme. (c) Other compounds can bond to the iron atom, displacing oxygen. Identify which of the following species cannot bond to the iron in a heme group and explain your reasoning: CO; ClϪ ; BF3; NO2 Ϫ . (d) Hemoglobin in both its oxygenated (HbO2) and deoxygenated (Hb) forms helps to maintain the pH of blood at an optimal level. Hemoglobin has several acidic protons, but the most important deprotonation is the first. At 25°C, for the deoxygenated form, HbH(aq) ϩ H2O(l) #4 HbϪ (aq) ϩ H3Oϩ (aq) and pKa1 ϭ 6.62. For the oxygenated form, HbO2H(aq) ϩ H2O(l) #4 HbO2 – (aq) ϩ H3Oϩ (aq) and pKa1 ϭ 8.18. Calculate the percentage of each form of hemoglobin that is deprotonated at the pH of blood, 7.4. (e) Use your answer to part (d) to determine how the oxygenation of hemoglobin affects the pH of blood. That is, will the pH increase, decrease, or stay the same as more hemoglobin molecules become oxygenated? Explain your reasoning. 704 CHAPTER 16 THE ELEMENTS: THE d-BLOCK 705 What Are the Key Ideas? Changes in the nucleus of an atom can transform the atom into another element and result in the release of energy. Why Do We Need to Know This Material? Nuclear chemistry is central to the development of nuclear energy. Chemistry provides techniques for preparing and recycling nuclear fuels and for the disposal of hazardous radioactive waste. Nuclear chemistry is used in medicine to treat cancer and to produce images of organs inside living bodies. It is used in chemistry to investigate reaction mechanisms and in archaeology to date ancient objects; nuclear chemistry is also part of the military strategies of many nations. Furthermore, this material informs the complex political, environmental, and economic debate about the deployment of nuclear energy. What Do We Need to Know Already? Nuclear processes can be understood in terms of atomic structure (Section B and Chapter 1) and energy changes (Chapter 7). The section on rates of radioactive decay builds on chemical kinetics (particularly Sections 14.4 and 14.5). W hen we study chemical reactions we treat the atomic nuclei as unchanging. However, nuclei can undergo changes, and nuclear chemistry explores the chemical consequences of those changes. One kind of change is nuclear fission, the fragmentation of large nuclei into smaller nuclei. Although fission is a source of energy, the resulting radioactive waste presents serious hazards to life. Another kind of change is nuclear fusion, the merging of small nuclei into larger ones. Fusion, too, is a source of energy, but the technique is technologically challenging and therefore expensive to develop. Nuclear processes are critical for the future of humanity, because they might prove to be the answer to one of our greatest challenges—the development of adequate energy supplies. The issues involved and chemistry’s contributions to their solution are the subjects of this chapter. This chapter has three main themes. First, we consider the pattern of nuclear stability and the manner in which unstable nuclei spontaneously undergo change. Changes in the composition of nuclei are the source of all the elements except hydrogen, and so we also discuss the origin of the elements. Next, we consider the effect of radiation on living beings and the uses to which nuclear radiation is put in chemistry. Finally, we consider nuclear energy and how chemistry is used to resolve the problems associated with its use. NUCLEAR DECAY Atomic nuclei are extraordinary particles. They contain all the protons in the atom crammed together in a tiny volume, despite their positive charges (Fig. 17.1). Yet most nuclei survive indefinitely despite the immense repulsive forces between their protons. In some nuclei, though, the repulsions that protons exert on one another overcome the force that holds the nucleons together. Fragments of the nucleus are then ejected, and the nucleus is said to “decay.” NUCLEAR DECAY 17.1 The Evidence for Spontaneous Nuclear Decay 17.2 Nuclear Reactions 17.3 The Pattern of Nuclear Stability 17.4 Predicting the Type of Nuclear Decay 17.5 Nucleosynthesis NUCLEAR RADIATION 17.6 The Biological Effects of Radiation 17.7 Measuring the Rate of Nuclear Decay 17.8 Uses of Radioisotopes NUCLEAR ENERGY 17.9 Mass–Energy Conversion 17.10 Nuclear Fission 17.11 Nuclear Fusion 17.12 The Chemistry of Nuclear Power 705 Chapter 17 NUCLEAR CHEMISTRY Neutron (n) Proton (p) FIGURE 17.1 This illustration represents a nucleus as a collection of tightly bonded protons (pink) and neutrons (gray). The diameter of a nucleus is about 10 fm (1 fm ϭ 10Ϫ15 m). 17.1 The Evidence for Spontaneous Nuclear Decay In 1896, the French scientist Henri Becquerel happened to store a lump of uranium oxide in a drawer that contained some photographic plates (Fig. 17.2). He was astonished to find that the plates had become darkened in certain areas even though they were covered with an opaque material. Becquerel realized that the uranium compound must give off some kind of radiation. Marie Sklodowska Curie (Fig. 17.3), a young Polish doctoral student, showed that the radiation, which she called radioactivity, was emitted by uranium regardless of the compound in which it was found. She concluded that the source must be the uranium atoms themselves. Together with her husband, Pierre, she went on to show that thorium, radium, and polonium are also radioactive. The origin of the rays was initially a mystery, because the existence of the atomic nucleus was unknown at the time. However, in 1898, Ernest Rutherford took the first step to discover their origin when he identified three different types of radioactivity by observing the effect of electric fields on radioactive emissions (Fig. 17.4). Rutherford called the three types ␣ (alpha), ␤ (beta), and ␥ (gamma) radiation. When Rutherford allowed the radiation to pass between two electrically charged electrodes, he found that one type was attracted to the negatively charged electrode. He proposed that the radiation attracted to the negative electrode consists of positively charged particles, which he called ␣ particles. From the charge and mass of the particles, he was able to identify them as helium atoms that had lost their two electrons. Once Rutherford had identified the atomic nucleus (in 1908, Section B), he realized that an ␣ particle must be a helium nucleus, He2ϩ . An ␣ particle is denoted 4 2␣, or simply ␣. We can think of it as a tightly bound cluster of two protons and two neutrons (Fig. 17.5). Rutherford found that a second type of radiation was attracted to the positively charged electrode. He proposed that this type of radiation consists of a stream of negatively charged particles. By measuring the charge and mass of these particles, he showed that they are electrons. The rapidly moving electrons emitted by nuclei are called ␤ particles and denoted ␤Ϫ . Because a ␤ particle has no protons or neutrons, its mass number is 0 and it can be written 0 Ϫ1e. A note on good practice: An electron emitted or captured by a nucleus does not have an atomic number, so its charge (Ϫ1) is written as a subscript preceding the symbol. We see later that this is a convenient bookkeeping device. 706 CHAPTER 17 NUCLEAR CHEMISTRY FIGURE 17.3 Marie Sklodowska Curie (1867–1934). FIGURE 17.2 Henri Becquerel discovered radioactivity when he noticed that an unexposed photographic plate left near some uranium oxide became fogged. This photograph shows one of his original plates annotated with his record of the event. Ϫ ϩ FIGURE 17.5 An ␣ particle has two positive charges and a mass number of 4. It consists of two protons and two neutrons and is the same as the nucleus of a helium-4 atom. FIGURE 17.4 The effects of an electric field on nuclear radiation. The direction of deflection shows that ␣ rays are positively charged, ␤ rays negatively charged, and ␥-rays uncharged. The third common type of radiation that Rutherford identified, ␥ radiation, is not affected by an electrical field. Like light, ␥ radiation is electromagnetic radiation but of much higher frequency—greater than about 1020 Hz and corresponding to wavelengths less than about 1 pm. It can be regarded as a stream of very high energy photons, each photon being emitted by a single nucleus as that nucleus discards energy. The frequencies, ␯, of ␥-rays are related to the energy discarded by the nucleus, ⌬E, by ␯ ϭ ⌬E/h (see Section 1.4). The frequency is very high because the energy difference between the excited and the ground nuclear states is very large. Both ␣ and ␤ radiation are often accompanied by ␥ radiation: the new nucleus may be formed with its nucleons in a high-energy arrangement, and a ␥-ray photon is emitted when nucleons settle down into a state of lower energy (Fig. 17.6). Since Rutherford’s work, scientists have identified other types of nuclear radiation. Some consist of rapidly moving particles, such as neutrons or protons. Others consist of rapidly moving antiparticles, particles with a mass equal to that of one of the subatomic particles but with an opposite charge. For example, the positron has the same mass as an electron but a positive charge; it is denoted ␤ϩ or ϩ 0 1e. When an antiparticle encounters its corresponding particle, both particles are annihilated and completely converted into energy. In electron capture, an electron in an atomic orbital is captured by the nucleus and a proton is converted into a neutron. Table 17.1 summarizes the properties of particles commonly found in nuclear radiation. The most common types of radiation emitted by radioactive nuclei are ␣ particles (the nuclei of helium atoms), ␤ particles (fast electrons ejected from the nucleus), and ␥-rays (high-frequency electromagnetic radiation). 17.2 Nuclear Reactions The discoveries of Becquerel, Curie, and Rutherford and Rutherford’s later development of the nuclear model of the atom (Section B) showed that radioactivity is produced by nuclear decay, the partial breakup of a nucleus. The change in the composition of a nucleus is called a nuclear reaction. Recall from Section B that nuclei are composed of protons and neutrons that are collectively called nucleons; a specific nucleus with a given atomic number and mass number is called a nuclide. Thus, 1 H, 2 H, and 16 O are three different nuclides; the first two being isotopes of the same element. Nuclei that change 17.2 NUCLEAR REACTIONS 707 High-energy arrangement Low-energy arrangement FIGURE 17.6 After a nucleus decays, the nucleons remaining in the nucleus may be left in a high-energy state, as shown by the expanded arrangement in the upper part of the illustration. As the nucleons adjust to a lower-energy arrangement (bottom), the excess energy is released as a ␥-ray photon. Animation 17.6 TABLE 17.1 Nuclear Radiation Degree of Mass Type penetration Speed* Particle† number Charge Example ␣ not penetrating 10% of c helium-4 nucleus, 4 ϩ2 226 88Ra ∫∫B 222 86Rn ϩ ␣ but damaging 4 2He2ϩ , 4 2␣, ␣ (Fig. 17.7) ␤ moderately Ͻ90% of c electron, 0 Ϫ1 3 1H ∫∫B 3 2He ϩ 0 Ϫ1e penetrating 0 Ϫ1e, ␤Ϫ , ␤, eϪ (Fig. 17.8) electron — — electron, 0 Ϫ1e, eϪ 0 Ϫ1 44 22Ti ϩ 0 Ϫ1e ∫∫B 44 21Sc capture‡ (Fig. 17.9) ␥ very penetrating; c photon, ␥ 0 0 60 27Co*§ ∫∫B 60 27Co ϩ ␥ often accompanies (Fig. 17.6) other radiation ␤ϩ moderately Ͻ90% of c positron, 0 ϩ1e, ␤ϩ 0 ϩ1 22 11Na ∫∫B 22 10Ne ϩ 0 ϩ1e penetrating (Fig. 17.10) p moderate or low 10% of c proton, 1 1Hϩ , 1 1p, p 1 ϩ1 53 27Co ∫∫B 52 26Fe ϩ 1 1p penetration n very penetrating Ͻ10% of c neutron, 1 0n, n 1 0 137 53I ∫∫B 136 53I ϩ 1 0n *c is the speed of light. † Alternative symbols are given for the particles; often it is sufficient to use the simplest (the one on the right). ‡ Electron capture is not nuclear radiation but is included for completeness. § An energetically excited state of a nucleus is usually denoted by an asterisk (*). their structure spontaneously and emit radiation are called radioactive. Often the result is a different nuclide. Nuclear reactions differ in some important ways from chemical reactions. First, different isotopes of the same element undergo essentially the same chemical reactions, but their nuclei undergo very different nuclear reactions. Second, some nuclear reactions, such as those in which ␣ or ␤ particles are emitted from the nucleus, leave behind a nucleus with a different number of protons. The product, which is called the daughter nucleus (Fig. 17.7), is therefore the nucleus of an atom of a different element. For example, when a radon-222 nucleus emits an ␣ particle, a polonium- 218 nucleus is formed. In this case, a nuclear transmutation, the conversion of one element into another, has taken place. Another important difference between nuclear and chemical reactions is that energy changes are very much greater for nuclear reactions than for chemical reactions. For example, the combustion of 1.0 g of methane produces about 52 kJ of energy as heat. In contrast, a nuclear reaction of 1.0 g of uranium-235 produces about 8.2 ϫ 107 kJ of energy, more than a million times as much. To predict the identity of a daughter nucleus, we note how the atomic number and mass number change when the parent nucleus ejects a particle. For example, when a radium-226 nucleus,withZϭ 88,undergoes␣ decay,itemitsan␣ particle,whichhasanuclear charge of ϩ2 and a mass number of 4. Because both total mass number and total nuclear charge are conserved in a nuclear reaction, the fragment remaining must be a nucleus of atomic number 86 (radon) and mass number 222; so the daughter nucleus is radon-222: 226 88Ra 222 86Rn ϩ 4 2␣ The expression for these changes is called a nuclear equation. The following examples show how to use nuclear equations to identify daughter nuclei. ¡ FIGURE 17.7 When a nucleus ejects an ␣ particle, the atomic number of the nuclide decreases by 2 and the mass number decreases by 4. The nucleons ejected from the upper nucleus are indicated by the gold boundary. Z, A ZϪ2, AϪ4 p n Animation 17.7 EXAMPLE 17.1 Predicting the outcome of ␣ and ␤ decay What nuclide is produced by (a) ␣ decay of polonium-211; (b) ␤ decay of sodium-24? Anticipate (a) In ␣ decay, two protons and two neutrons are lost. As a result, we should expect the mass number to decrease by 4 and the atomic number to decrease by 2 (see Fig. 17.7). (b) The loss of one negative charge when an electron is ejected from the nucleus (Fig. 17.8) can be interpreted as the conversion of a neutron into a proton within the nucleus: 1 0n 1 1p ϩ 0 Ϫ1e, or, more simply, n p ϩ ␤ We should expect the atomic number of the daughter nucleus to be greater by 1 than that of the parent nucleus, because it has one more proton, but the mass number to be unchanged, because the total number of nucleons in the nucleus should be the same. PLAN Write the nuclear equation for each reaction, representing the daughter nuclide as E, with atomic number Z and mass number A. Then find Z and A from the requirement that both mass number and atomic number are conserved in a nuclear reaction. SOLVE ¡¡ (a) Write the equation for the nuclear reaction. 211 84Po A ZE ϩ 4 2␣¡ Express mass and charge conservation. 211 ϭ A ϩ 4, or A ϭ 207 84 ϭ Z ϩ 2, Z ϭ 82 Identify the element. Z ϭ 82 corresponds to Pb. FIGURE 17.8 When a nucleus ejects a ␤ particle, the atomic number of the nuclide increases by 1 and the mass number remains unchanged. The neutron that we can regard as the source of the electron is indicated by the gold boundary in the upper nucleus. Animation 17.8 Z, A p n Zϩ1, A Evaluate As expected, the ␣ decay resulted in a nuclide having two fewer protons and two fewer neutrons; the ␤ decay produced a nuclide in which a proton was converted into a neutron, so there was no change in mass. Self-Test 17.1A Identify the nuclide produced by (a) ␣ decay of uranium-235, (b) ␤ decay of lithium-9. [Answer: (a) Thorium-231; (b) beryllium-9] Self-Test 17.1B Identify the nuclide produced by (a) ␣ decay of thorium-232, (b) ␤ decay of radium-228. 17.2 NUCLEAR REACTIONS 709 Write the nuclear equation. 211 84Po 207 82Pb ϩ 4 2␣¡ In Sn Sb Te Tl Pb Bi Po 49 50 51 52 81 82 83 84 113 114 115 116 BiBiBi 8383838383 Bib B 83 ␣ (b) Write the equation for the nuclear reaction. 24 11Na A ZE ϩ 0 Ϫ1e¡ Express mass and charge conservation. 24 ϭ A ϩ 0, or A ϭ 24, unchanged 11 ϭ Z Ϫ 1, Z ϭ 12 Identify the element. Z ϭ 12 corresponds to Mg Write the equation for the nuclear reaction. 24 11Na 24 12Mg ϩ 0 Ϫ1e¡ Li Be Na Mg K Ca Sc Ti 3 4 11 12 19 20 21 22 eϪ MMMMM EXAMPLE 17.2 Predicting the outcome of electron capture and positron emission What nuclide is produced when (a) calcium-41 undergoes electron capture; (b) oxygen-15 undergoes positron emission? Anticipate (a) In electron capture, a proton is turned into a neutron and, although there is no change in mass number, the atomic number should be reduced by 1 (Fig. 17.9). (b) A positron has the same tiny mass as an electron but a single positive charge. Positron emission can be thought of as the positive charge shrugged off by a proton as it is converted into a neutron. As a result, the atomic number decreases by 1 but there should be no change in mass number (Fig. 17.10). PLAN Write the nuclear equation for each reaction, representing the daughter nuclide as E, with atomic number Z and mass number A. Then find Z and A from the requirement that both mass number and atomic number are conserved in a nuclear reaction. SOLVE (a) Write the equation for the nuclear reaction. 41 20Ca ϩ 0 Ϫ1e A ZE¡ Z, A p n ZϪ1, A eϪ FIGURE 17.9 In electron capture, a nucleus captures one of the surrounding electrons. The effect is to convert a proton (outlined in gold) into a neutron (outlined in gold). As a result, the atomic number of the nuclide decreases by 1 but the mass number remains the same. ϩ Z, A p n ZϪ1, A FIGURE 17.10 In positron (␤ϩ ) emission, the nucleus ejects a positron. The effect is to convert a proton into a neutron. As a result, the atomic number of the nuclide decreases by 1 but the mass number remains the same. 710 CHAPTER 17 NUCLEAR CHEMISTRY Express mass and charge conservation. 41 ϩ 0 ϭ A, or A ϭ 41, unchanged 20 Ϫ 1 ϭ Z, Z ϭ 19 Identify the element. Z ϭ 19 corresponds to K. (b) Write the equation for the nuclear reaction. 15 8O A ZE ϩ 0 ϩ1e¡ Express mass and charge conservation. 15 ϭ A ϩ 0, or A ϭ 15, unchanged 8 ϭ Z ϩ 1, Z ϭ 7 Identify the element. Z ϭ 7 corresponds to N. Write the nuclear equation. 41 20Ca ϩ 0 Ϫ1e 41 19K¡ eϪ Li Be Na Mg K Ca Sc Ti 3 4 11 12 19 20 21 22 Write the nuclear equation. 15 8O 15 7N ϩ 0 ϩ1e¡ eϩ N O F Ne He P S Cl Ar 2 7 8 9 10 17 1815 16 N Evaluate As expected, in both electron capture and positron emission a proton has been converted into a neutron, so there was a decrease in atomic number but no change in mass. Self-Test 17.2A Identify the nuclide produced and write the nuclear equation for (a) electron capture by beryllium-7; (b) positron emission by sodium-22. [Answer: (a) 7 4Be ϩ 0 Ϫ1e : 7 3Li; (b) 22 11Na : 22 10Neϩ 0 ϩ1e] Self-Test 17.2B Identify the nuclide produced and write the nuclear equation for (a) electron capture by iron-55; (b) positron emission by carbon-11. Nuclear reactions may result in the formation of different elements. The transmutation of a nucleus can be predicted by noting the atomic numbers and the mass numbers in the nuclear equation for the process. 17.3 The Pattern of Nuclear Stability The nuclei of some elements are stable, but others decay the moment they are formed. It would be useful to know if there is a pattern to the stabilities and instabilities of nuclei, because such a pattern would allow us to make predictions about the modes of nuclear decay. One clue is that elements with even atomic numbers are consistently more abundant than neighboring elements with odd atomic numbers. We can see this difference in Fig. 17.11, which is a plot of the cosmic abundance of the elements against atomic number. The same pattern occurs on Earth. Of the eight elements present as 1% or more of the mass of the Earth, only one, aluminum, has an odd atomic number. Nuclei with even numbers of both protons and neutrons are more stable than those with any other combination. Conversely, nuclei with odd numbers of both protons and neutrons are the least stable (Fig. 17.12). Nuclei are more likely to be stable if they are built from certain numbers of either kind of nucleons. These numbers—namely, 2, 8, 20, 50, 82, 114, 126, and 184—are called magic numbers. For example, there are ten stable isotopes of tin (Z ϭ 50), the most of any element, but only two stable isotopes of its neighbor antimony (Z ϭ 51). The ␣ particle itself is a “doubly magic” nucleus, with two protons and two neutrons. We shall see later that a number of actinoids decay through a series of steps until they reach Pb, another doubly magic nuclide, with 126 neutrons and 82 protons. This pattern of nuclear stability is similar to the pattern of electron stability in atoms: the noble gas atoms have 2, 10, 18, 36, 54, and 86 electrons. Figure 17.13 is a plot of mass number against atomic number for known nuclides. Stable nuclei are found in a band of stability surrounded by a sea of instability, the region of unstable nuclides that decay with the emission of radiation. For atomic numbers up to about 20, the stable nuclides have approximately equal numbers of neutrons and protons, and so A is close to 2Z. For higher atomic numbers, all known nuclides— both stable and unstable—have more neutrons than protons, and so A Ͼ 2Z. 17.3 THE PATTERN OF NUCLEAR STABILITY 711 −2 0 2 4 6 8 10 log(relativeabundance) 20 40 60 80 Atomic number, Z Fe O XeSc Pb Bi Odd Z Even Z FIGURE 17.11 The variation in cosmic nuclear abundance with atomic number. Note that elements with even atomic numbers (brown curve) are consistently more abundant than neighboring elements with odd atomic numbers (blue curve). Protons Even Even Odd Odd 4 50 53 157 Neutrons FIGURE 17.12 The numbers of stable nuclides having even or odd numbers of neutrons and protons. With the exception of hydrogen, by far the greatest number of stable nuclides (157) have even numbers of both protons and neutrons. Only four stable nuclides have odd numbers of both protons and neutrons. 0 20 40 60 80 100 Z 0 40 80 120 160 200 240 A A = 140 Z = 60 150 Sea of instability Sea of instability Band of stability 84 68 A = 2Z FIGURE 17.13 The manner in which nuclear stability depends on the atomic number and the mass number. Nuclides along the narrow black band (the band of stability) are generally stable. Nuclides in the blue region are likely to emit a ␤ particle, and those in the red region are likely to emit an ␣ particle. Nuclei in the pink region are likely either to emit positrons or to undergo electron capture. The straight line indicates the position that nuclides would have if the numbers of neutrons and protons were equal (A ϭ 2Z). The inset shows a magnified view of the diagram near Z ϭ 60. 712 CHAPTER 17 NUCLEAR CHEMISTRY FIGURE 17.14 The protons in a nucleus repel one another electrically, but the strong force, which acts between all nucleons, holds the nucleus together. p n Attract Repel electrically Bismuth (Z ϭ 83) was thought to have a stable isotope, but in 2005 even that isotope was found to decay extremely slowly. FIGURE 17.15 Three different ways of reaching the band of stability (black). Nuclei that are neutron rich (blue region) tend to convert neutrons into protons by ␤ emission; nuclei that are proton rich (red) tend to reach stability (black) by emitting a positron, capturing an electron, or emitting a proton. Massnumber Atomic number β− emission β+ emission p emission The increase in the ratio of neutrons to protons with increasing atomic number can be explained by considering the role of the neutrons in helping to overcome the electrical repulsions between protons. The strong force that holds the protons and neutrons together in a nucleus is powerful enough to overcome the electrostatic repulsion between the protons, but it can act over only a very short distance—about the diameter of a nucleus (Fig. 17.14). Because neutrons are uncharged, they can contribute to the strong force without adding to the electrostatic repulsion. A lot of neutrons are needed to overcome the mutual repulsion of the protons in a nucleus of high atomic number, which explains why the band of stability curves upward. Nuclei with certain even numbers of protons and of neutrons are the most stable. 17.4 Predicting the Type of Nuclear Decay We can use Fig. 17.13 to predict the type of disintegration that a radioactive nuclide is likely to undergo. Nuclei that lie above the band of stability are neutron rich: they have a high proportion of neutrons. These nuclei tend to decay in such a way that the final n/p ratio is closer to that found in the band of stability. For example, a 14 6C nucleus can reach a more stable state by ejecting a ␤ particle, which reduces the n/p ratio as a result of the conversion of a neutron into a proton (Fig. 17.15): 14 6C 14 7N ϩ 0 Ϫ1e Nuclides that lie below the band of stability have a low proportion of neutrons and are classified as proton rich. These isotopes tend to decay in such a way that the atomic number is reduced. For example, proton-rich 29 15P is radioactive and decays by emitting a positron, a process that converts a proton into a neutron and raises the final n/p ratio: 29 15P 29 14S ϩ 0 ϩ1e As shown in Example 17.2, electron capture and proton emission also decrease the proton count of proton-rich nuclides. Very few nuclides with Z Ͻ 60 emit ␣ particles. All nuclei with Z Ͼ 82 are unstable and decay mainly by ␣-particle emission. They must discard protons to reduce their atomic number and generally need to lose neutrons, too. These nuclei decay in a stepby-step manner and give rise to a radioactive series, a characteristic sequence of nuclides (Fig. 17.16). First, one ␣ particle is ejected, then another ␣ particle or a ␤ particle is ejected, and so on, until a stable nucleus, such as an isotope of lead (with the magic atomic number 82) is formed. For example, the uranium-238 series ends at lead-206, the uranium-235 series ends at lead-207, and the thorium-232 series ends at lead-208. Self-Test 17.3A Which of the following processes, (a) electron capture, (b) proton emission, (c) ␤– emission, (d) ␤ϩ emission, might a 145 64Gd nucleus undergo to begin to reach stability? Refer to Figs. 17.13 and 17.15. [Answer: a, b, d] Self-Test 17.3B Which of the set of processes listed in Self-Test 17.3A might a 148 58Ce nucleus undergo to begin to reach stability? The pattern of nuclear stability can be used to predict the likely mode of radioactive decay: neutron-rich nuclei tend to reduce their neutron count; proton-rich nuclei tend to reduce their proton count. In general, only heavy nuclides emit ␣ particles. 17.5 Nucleosynthesis In order to study some nuclear processes, scientists may need to create certain nuclides that might not exist naturally. For example, 11 3Li is an unstable nuclide that has so many neutrons that the strong force allows its nucleus to expand about 10 times, to nearly the size of a radium nucleus. Such a nuclide can provide valuable information for nuclear theorists, but it must be synthesized, as it does not occur naturally. The process of forming elements is nucleosynthesis. This process occurs naturally. Hydrogen and helium were produced in the Big Bang; all other naturally occurring elements are descended from these two, as a ¡ ¡ result of nuclear reactions taking place either in stars or in space. Some elements—among them technetium and promethium—are found in only trace amounts on Earth. Although these elements were made in stars, their short lifetimes did not allow them to survive long enough to contribute to the formation of our planet. However, nuclides that are too unstable to be found on Earth can be made by artificial techniques, and scientists have added about 2700 different nuclides to the approximately 270 that occur naturally. To overcome the energy barriers to nuclear synthesis, particles must collide vigorously with one another (Fig. 17.17), as they do in the hot interiors of stars. Therefore, to make elements artificially, we need to simulate the conditions found inside a star. If it is traveling fast enough, a proton, an ␣ particle, or another positively charged nucleus has enough kinetic energy to overcome the electrostatic repulsion from the nucleus. The incoming particle penetrates into the nucleus, where it is captured by the strong force. The high speeds required can be achieved in a particle accelerator. The transmutation of elements—the conversion of one element into another, particularly of lead into gold—was the dream of the alchemists and one of the roots of modern chemistry. However, the alchemists had access only to chemical techniques, which proved ineffective because they involved energy changes far too weak to force nucleons into nuclei. Transmutation has now been recognized in nature and achieved in the laboratory, but by using methods undreamed of by the early alchemists. Rutherford achieved the first artificial nuclear transmutation in 1919. He bombarded nitrogen-14 nuclei with high-speed ␣ particles. The products of the transmutation were oxygen-17 and a proton: 14 7N ϩ 4 2␣ 17 8O ϩ 1 1p Such transmutation processes are commonly written simply as 14 7N(␣, p)17 8O or, in general, Target(incoming particle, ejected particle)product ¡ 17.5 NUCLEOSYNTHESIS 713 206 210 214 218 222 226 230 234 238 81 82 83 84 85 86 87 88 89 90 91 92 Z A U UPaTh Th Ra Rn Po Po Po Bi Bi Pb Pb Pb Tl α decay β decay 2.5 × 105 a 8 × 104 a 4.5 × 109 a 1600 a 3.8 d 3 min 20 min 200 μs 138 d FIGURE 17.16 The uranium-238 decay series. The times are the half-lives of the nuclides (see Section 17.7). The unit a, for annum, is the SI abbreviation for year. FIGURE 17.17 When a positively charged particle approaches a nucleus, it is repelled strongly. However, a very fast particle can reach the nucleus before the repulsion turns it aside, and a nuclear reaction may result. p p pn Repelling electric field Slow Fast 714 CHAPTER 17 NUCLEAR CHEMISTRY Nuclear Medicine Nuclear chemistry has transformed medical diagnosis, treatment, and research. Radioactive tracers are used to measure organ function, sodium-24 to monitor blood flow, and strontium-87 to study bone growth. However, the most dramatic effect of radioisotopes on diagnosis has been in the field of imaging. Technetium-99m (see Exercise 17.48; the m denotes a “metastable,” reasonably long-lived, state) is the most widely used radioactive nuclide in medicine, especially for bone scans. This isotope is highly active and gives off ␥-rays that pass through the body. The ␥-rays cause much less damage than ␣ particles would, and the isotope is so short-lived that the risk to the patient is minimal. Cobalt-60 is used for the gamma knife, a technique that is actually knife-less and that can destroy tumors in locations such as the brain when surgery is not possible. In gamma-knife therapy, about 200 ␥ rays are focused from different angles onto a tumor with a known location. Each ␥-ray by itself has a low amplitude and so causes little or no damage to the tissues through which it passes. However, at the intersection of 200 of these energetic rays, the radiation is very strong and sufficiently powerful to destroy the tumor cells. The process is painless and the patient can remain awake through the treatment. The patient’s head does not need to be shaved and recovery time is short. Positron emission tomography (PET) makes use of a shortlived positron emitter such as fluorine-18 to image human tissue WHAT HAS THIS TO DO WITH . . . STAYING ALIVE?BOX 17.1 with a degree of detail not possible with x-rays. It has been used extensively to study brain function (see illustrations) and in medical diagnosis. For example, when the hormone estrogen is labelled with fluorine-18 and injected into a cancer patient, the fluorinebearing compound is preferentially absorbed by the tumor. The positrons given off by the fluorine atoms are quickly annihilated when they meet electrons. The resulting ␥-rays are detected by a scanner that moves slowly over the part of the body containing the tumor. The growth of the tumor can be estimated quickly and accurately with this technique. A PET imaging facility must be located near a cyclotron so that the positron emitters can be incorporated into the desired compounds as soon as they are created. Several kinds of cancer therapy use radiation to destroy malignant cells. Boron neutron capture therapy is unusual in that boron-10, the isotope injected, is not radioactive. However, when boron-10 is bombarded with neutrons, it gives off highly destructive ␣ particles. In boron neutron capture therapy, the boron-10 is incorporated into a compound that is preferentially absorbed by tumors. The patient is then exposed to brief periods of neutron bombardment. As soon as the bombardment ceases, the boron-10 stops generating ␣ particles. Related exercises: 17.47, 17.48, 17.81, 17.82, 17.89, and 17.90 For Further Reading: P. Barry, “Unintended consequences of cancer therapies,” Science News, vol. 171, p. 334, May 26, 2007. V. Marx, “Molecular imaging,” Chemical and Engineering News, vol. 83(30), 2005, pp. 25–34. G. Miller, “Neuroscience: A better view of brain disorders,” Science, vol. 313, September 8, 2006, pp. 1376–1379. Passively viewing words Listening to words Generating verbsSpeaking words These four PET scans show how blood flow to different parts of the brain is affected by various activities. In this case, an oxygen isotope that is taken up by the hemoglobin in blood is used as a source of positrons. This patient is about to undergo a PET scan of brain function. A large number of nuclides have been synthesized on Earth. For instance, technetium was prepared (as technetium-97) for the first time on Earth in 1937 by the reaction between molybdenum and deuterium nuclei: 97 42Mo ϩ 2 1H 97 43Tc ϩ 2 1 0n, or 97 42Mo(d, 2n)97 43Tc where d denotes a deuteron, 2 Hϩ . Technetium is now moderately abundant because it accumulates in the decay products of nuclear power plants. Another isotope, technetium-99, has pharmaceutical applications, particularly for bone scans (Box 17.1). ¡ A neutron can get close to a target nucleus more easily than a proton can. Because a neutron has no charge and hence is not repelled by the nuclear charge, it need not be accelerated to such high speeds. An example of neutron-induced transmutation is the formation of cobalt-60, which is used in the radiation treatment of cancer. The three-step process starts from iron-58. First, iron-59 is produced: 58 26Fe ϩ 1 0n 59 26Fe The second step is the ␤ decay of iron-59 to cobalt-59: 59 26Fe 59 27Co ϩ 0 Ϫ1e In the final step, cobalt-59 absorbs another neutron from the incident neutron beam and is converted into cobalt-60: 59 27Co ϩ 1 0n 60 27Co The overall reaction is 58 26Fe ϩ 2 1 0n 60 27Co ϩ 0 Ϫ1e, or 58 26Fe(2n, ␤Ϫ )60 27Co Self-Test 17.4A Complete the following nuclear reactions: (a) ? ϩ 4 2␣ : 243 96Cm ϩ 1 0n; (b) 242 96Cm ϩ 4 2␣ : 245 98Cf ϩ ?. [Answer: (a) 240 94Pu; (b) 1 0n] Self-Test 17.4B Complete the following nuclear reactions: (a) 250 98Cf ϩ ? : 257 103Lr ϩ 4 1 0n; (b) ? ϩ 12 6C : 254 102No ϩ 4 1 0n. The transuranium elements are the elements following uranium in the periodic table. The elements from rutherfordium (Rf, Z ϭ 104) through meitnerium (Mt, Z ϭ 109) were formally named in 1997. The transmeitnerium elements, the elements beyond meitnerium (including hypothetical nuclides that have not yet been made) are named systematically, at least until they have been identified and there is international agreement on a permanent name. Their systematic names use the prefixes in Table 17.2, which identify their atomic numbers, with the ending -ium. Thus, element 110 was known as ununnilium until it was named darmstadtium (Ds) in 2003. New elements and isotopes of known elements are made by nucleosynthesis; the repulsive electrical forces of like-charged particles are overcome when very fast particles collide. NUCLEAR RADIATION Nuclear radiation is sometimes called ionizing radiation, because it is energetic enough to eject electrons from atoms. Hospitals use nuclear radiation to kill unwanted tissue, such as cancerous cells (see Box 17.1). Yet the same powerful effects that help to diagnose and cure illness can also damage healthy tissue. The damage depends on the strength of the source, the type of radiation, and the length of exposure. The three principal types of nuclear radiation have different abilities to penetrate matter (Table 17.3). 17.6 The Biological Effects of Radiation Relatively massive, highly charged ␣ particles interact so strongly with matter that they slow down, capture electrons from surrounding matter, and change into bulky helium atoms before traveling very far. They penetrate only the first layer of skin and can be stopped by glass, by clothing, even by a sheet of paper. Most ␣ radiation is absorbed by the surface layer of dead skin, where it can do little harm. However, ␣ particles can ¡ ¡ ¡ ¡ 17.6 THE BIOLOGICAL EFFECTS OF RADIATION 715 TABLE 17.2 Notation for the Systematic Nomenclature of Elements* Digit Prefix Abbreviation 0 nil n 1 un u 2 bi b 3 tri t 4 quad q 5 pent p 6 hex h 7 sep s 8 oct o 9 enn e *For instance, element 123 would be named unbitriium, Ubt. TABLE 17.3 Shielding Requirements of ␣, ␤, and ␥ Radiation Radiation Relative penetrating power Shielding required ␣ 1 paper, skin ␤ 100 3 mm aluminum ␥ 10 000 concrete, lead be extremely dangerous if inhaled or ingested. The energy of their impact can knock atoms out of molecules, which can lead to serious illness and death. For example, plutonium, considered to be one of the most toxic radioactive materials, is an ␣ emitter and can be handled safely with minimal shielding. However, it is easily oxidized to Pu4ϩ , which has chemical properties similar to those of Fe3ϩ . Plutonium can take the place of iron in the body and become absorbed into bone, where it destroys the body’s ability to produce red blood cells. The result is radiation sickness, cancer, and death. Second in penetrating power is ␤ radiation. These fast electrons can penetrate about 1 cm into flesh before their electrostatic interactions with the electrons and nuclei of molecules bring them to a standstill. Most penetrating of all is ␥ radiation. The high-energy ␥-ray photons can pass right through buildings and bodies and can cause damage by ionizing the molecules in their path. Protein molecules and DNA that have been damaged in this way can no longer function, and the result can be radiation sickness and cancer. Intense sources of ␥-rays must be surrounded by shields built from lead bricks or thick concrete to absorb this penetrating radiation. The absorbed dose of radiation is the energy deposited in a sample (in particular, the human body) when it is exposed to radiation. The SI unit of absorbed dose is the gray, Gy, which corresponds to an energy deposit of 1 J·kgϪ1 . The original unit used for reporting dose was the radiation absorbed dose (rad), the amount of radiation that deposits 10Ϫ2 J of energy per kilogram of tissue, and so 1 rad ϭ 10Ϫ2 Gy. A dose of 1 rad corresponds to a 65-kg person absorbing a total of 0.65 J, which is not very much energy: it is enough to boil only 0.2 mg of water. However, the energy of a particle of nuclear radiation is highly localized, like the impact of a subatomic bullet. As a result, the incoming particles can break individual bonds as they collide with molecules in their path. The extent of radiation damage to living tissue depends on the type of radiation and the type of tissue. We must therefore include the relative biological effectiveness, Q, when assessing the damage that a given dose of each type of radiation may cause. For ␤ and ␥ radiation, Q is set arbitrarily at about 1; but, for ␣ radiation, Q is close to 20. A dose of 1 Gy of ␥ radiation causes about the same amount of damage as 1 Gy of ␤ radiation, but 1 Gy of ␣ particles is about 20 times as damaging (even though these particles are the least penetrating). The precise figures depend on the total dose, the rate at which the dose accumulates, and the type of tissue, but these values are typical. The dose equivalent is the actual dose modified to take into account the different destructive powers of the various types of radiation in combination with various types of tissue. It is obtained by multiplying the actual dose (in gray) by the value of Q for the radiation type. The result is expressed in the SI unit called a sievert (Sv): Dose equivalent (Sv) ϭ Q ϫ absorbed dose (Gy) (1) The former (non-SI) unit of dose equivalent was the roentgen equivalent man (rem), which was defined in the same way as the sievert but with the absorbed dose in rad; thus, 1 rem ϭ 10Ϫ2 Sv. A dose of 0.3 Gy (30 rad) of ␥ radiation corresponds to a dose equivalent of 0.3 Sv (30 rem), enough to cause a reduction in the number of white blood cells (the cells that fight infection), but 0.3 Gy of ␣ radiation corresponds to 6 Sv (600 rem), which is enough to cause death if an ␣ emitter is ingested or inhaled. A typical average annual dose equivalent that we each receive from natural sources, called background radiation, is about 2 mSv·a–1 (where a, for annum, is the SI abbreviation for year), but this figure varies, depending on our life style and where we live. About 20% of background radiation comes from our own bodies. About 30% comes from cosmic rays (a mix of ␥-rays and high-energy subatomic particles from outer space) that continuously bombard the Earth, and 40% comes from radon seeping out of the ground. The remaining 10% is a result largely of medical diagnoses (a typical chest x-ray gives a dose equivalent of about 0.07 mSv). Emissions from nuclear power plants and other nuclear facilities contribute about 0.1% in countries where they are widely used. Human exposure to radiation is monitored by reporting the absorbed dose and the dose equivalent; the latter takes into account the effects of different types of radiation on tissues. 716 CHAPTER 17 NUCLEAR CHEMISTRY The principal source of radioactivity in the human body is potassium-40. About 35 000 potassium-40 nuclei disintegrated in your body while you were reading this sentence. 17.7 Measuring the Rate of Nuclear Decay Geiger counters and scintillation counters are used to measure the rate at which a radioactive nucleus decays (Box 17.2). Each click of a Geiger counter or flash of a phosphor in a scintillation counter indicates that one nuclear disintegration has been detected. The activity of a sample is the number of nuclear disintegrations in a given time interval divided by the length of the interval. The SI unit of activity is the becquerel (Bq): 1 Bq is equal to one nuclear disintegration per second. Another commonly used (non-SI) unit of radioactivity is the curie (Ci). It is equal to 3.7 ϫ 1010 nuclear disintegrations per second, the radioactive output of 1 g of radium-226. Because the curie is a very large unit, most activities are expressed in millicuries (mCi) or microcuries (␮Ci). Table 17.4 summarizes these units. The equation for the decay of a nucleus (parent nucleus : daughter nucleus ϩ radiation) has exactly the same form as a unimolecular elementary reaction (Section 14.7), with an unstable nucleus taking the place of a reactant molecule. This type of decay is expected for a process that does not depend on any external factors but only on the instability of the nucleus. The rate of nuclear decay depends only on the identity of the isotope, not on its chemical form or temperature. 17.7 MEASURING THE RATE OF NUCLEAR DECAY 717 The ability of nuclear radiation to eject electrons from atoms and ions can be used to measure its intensity. Becquerel first gauged the intensity of radiation by determining the degree to which it blackened a photographic film. The blackening results from the same redox processes as those of ordinary photography, such as Agϩ ϩ BrϪ ∫∫B Ag ϩ Br except that the initial oxidation of the bromide ions is caused by nuclear radiation instead of light. Becquerel’s technique is still used in film badges, which monitor the exposure of workers to radiation. A Geiger counter monitors radiation by detecting the ionization of a low-pressure gas, as shown in the illustration. The radiation ionizes atoms of the gas inside a cylinder and allows a brief flow of current between the electrodes. The resulting electrical signal can be recorded directly or converted into an audible click. The frequency of the clicks indicates the intensity of the radiation. A limitation of Geiger counters is that they do not respond well to ␥-rays. Only about 1% of the ␥-ray photons are detected, whereas all the ␤ particles incident on the counter are detected. Because the efficiency of a Geiger counter depends on the size of the tube, a counter used to monitor a wide range of activities usually contains two tubes of different sizes. A scintillation counter makes use of the fact that phosphors — phosphorescent substances such as sodium iodide and zinc sulfide (Section 6.15)—give a flash of light—a scintillation— when exposed to radiation. The counter also contains a photomultiplier tube, which converts light into an electrical signal. The intensity of the radiation is determined from the strength of the electronic signal. A dosimeter is used to collect cumulative evidence of exposure to radiation and is worn as a badge. Dosimeters contain a thermoluminescent material such as lithium fluoride. Any incident radiation knocks electrons out of the fluoride ions. The electrons migrate HOW DO WE KNOW . . . HOW RADIOACTIVE A MATERIAL IS?BOX 17.2 away from the fluorine atoms but are trapped in the crystal. When the crystal is heated, they fall back into the fluorine atoms and give off the difference in energy as light. The dose of radiation received is determined by the intensity of the light. Dosimeters can be used over a period of time ranging from one day to several weeks, because the excited electrons accumulate with continued exposure, allowing a long-term dosage to be evaluated. (a) Metal case Mica window To counting equipment Gas (b) Cathode Anode (a) A Geiger counter with a piece of uranium ore. (b) The detector in a Geiger counter contains a gas (often either argon and a little ethanol vapor or neon with some bromine vapor) in a cylinder with a high potential difference (500–1200 V) between the central wire and the walls. When radiation ionizes the gas, the ions allow current to flow briefly, resulting in the characteristic click. light 718 CHAPTER 17 NUCLEAR CHEMISTRY As in a unimolecular chemical reaction, the rate law for nuclear decay is first order. That is, the relation between the rate of decay and the number N of radioactive nuclei present is given by the law of radioactive decay: Activity ϭ rate of decay ϭ k ϫ N (2)* In this context, k is called the decay constant. The law tells us that the activity of a radioactive sample is proportional to the number of atoms in the sample. As we saw in Section 14.4, a first-order rate law implies an exponential decay. It follows that the number N of nuclei remaining after a time t is given by N ϭ N0eϪkt (3)* where N0 is the number of radioactive nuclei present initially (at t ϭ 0); this expression is plotted in Fig. 17.18. FIGURE 17.18 The exponential decay of the activity of a sample shows that the number of radioactive nuclei in the sample also decays exponentially with time. The curve is characterized by the half-life, t1/2. N0 Numberofnuclei,N 0 0 Time, t t1/2 1 2 N0 EXAMPLE 17.3 Using the law of radioactive decay One of the reasons why thermonuclear weapons have to be serviced regularly is the nuclear decay of the tritium that they contain. Suppose a tritium sample of mass 1.00 g is stored. What mass of that isotope will remain after 5.0 a (1 a ϭ 1 year)? The decay constant of tritium is 0.0564 a–1 . Anticipate Because the decay constant corresponds to a small fraction of the nuclei decaying per year, we should expect that most of the tritium will remain after 5 years. PLAN The total mass of isotope in a sample is proportional to the number of nuclei of that isotope that the sample contains; therefore, the time dependence of the mass of a radioactive isotope follows the same radioactive decay law as the number of nuclides in the sample. That is, because m ␣ N, in place of Eq. 3 we can write m ϭ m0e–kt where m is the total mass of the radioactive isotope at time t and m0 is its initial mass. SOLVE Property Unit name Symbol Definition activity becquerel Bq 1 disintegration per second curie Ci 3.7 ϫ 1010 disintegrations per second absorbed dose gray Gy 1 JиkgϪ1 radiation absorbed dose rad 10Ϫ2 JиkgϪ1 dose equivalent sievert Sv Q ϫ absorbed dose† roentgen equivalent man rem Q ϫ absorbed dose† *Former units are in red. † Q is the relative biological effectiveness of the radiation. Normally, Q Ͻ 1 SvиGyϪ1 for ␥, ␤, and most other radiation, but Q Ͻ 20 SvиGyϪ1 for ␣ radiation and fast neutrons. A further factor of 5 (that is, 5Q) is used for bone under certain circumstances. TABLE 17.4 Radiation Units* 1.0 g 0.75 g 0 5.0 Time (a) Mass From m ϭ m0e–kt , = 0.75 g m = 11.00 g2 * e-10.0564 a- 1 2*15.0 a2 Evaluate As expected, only a small amount of the isotope has decayed; 0.75 g remains after 5.0 years. Self-Test 17.5A The decay constant for fermium-254 is 210 s–1 . What mass of the isotope will be present if a sample of mass 1.00 ␮g is kept for 10. ms? [Answer: 0.12 ␮g] Self-Test 17.5B The decay constant for the nuclide neptunium-237 is 3.3 ϫ 10Ϫ7 aϪ1 . What mass of the isotope will be present if a sample of mass 5.0 ␮g survives for 1.0 Ma (1.0 million years)? Radioactive decay is normally discussed in terms of the half-life, t1/2, the time needed for half the initial number of nuclei to disintegrate. Just as we did in Section 14.5, we find the relation between t1/2 and k by setting N ϭ N0 and t ϭ t1/2 in Eq. 3: (4)* This equation shows that, the larger the value of k, the shorter the half-life of the nuclide. Nuclides with short half-lives are less stable than nuclides with long half-lives. They are more likely to decay in a given period of time and are “hotter” (more intensely radioactive) than nuclides with long half-lives. Thinking point: Might there be advantages in nuclear reactors producing intensely radioactive waste? Half-lives span a very wide range (Table 17.5). Consider strontium-90, for which the half-life is 28.1 a. This nuclide is present in nuclear fallout, the fine dust that settles from clouds of airborne particles after the explosion of a nuclear bomb, and may also be present in the accidental release of radioactive materials into the air. Because it is chemically very similar to calcium, strontium may accompany that element through the environment and become incorporated into bones; once there, it continues to emit radiation for many years. About 10 half-lives (for strontium-90, 281 a) must pass before the activity of a sample has fallen to 1/1000 of its initial value. Iodine-131, which was released in the accidental fire at the Chernobyl nuclear power plant, has a half-life of only 8.05 d, but it accumulates in the thyroid gland. Several cases of thyroid cancer were linked to iodine-131 exposure from the accident. Plutonium-239 has a half-life of 24 ka (24 000 years). Consequently, very long term storage facilities are required for plutonium waste, and land contaminated with plutonium cannot be inhabited again for thousands of years without expensive remediation efforts. The constant half-life of a nuclide is used to determine the ages of archaeological artifacts. In isotopic dating, we measure the activity of the radioactive isotopes that they contain. Isotopes used for dating objects include uranium-238, potassium-40, and tritium. However, the most important example is radiocarbon dating, which uses the ␤ decay of carbon-14, for which the half-life is 5730 a. Carbon-12 is the principal isotope of carbon, but a small proportion of carbon-14 is present in all living organisms. Its nuclei are produced when nitrogen nuclei in the atmosphere are bombarded by neutrons formed in the collisions of cosmic rays with other nuclei: 14 7N ϩ 1 0n 14 6C ϩ 1 1p Carbon-14 atoms are produced in the atmosphere at an almost constant rate and, as a result, the proportion of carbon-14 to carbon-12 atoms in the atmosphere tends to be constant over time. Carbon-14 atoms enter living organisms as 14 CO2 through photosynthesis and digestion. They leave the organisms by the normal processes of excretion and respiration and also because the nuclei decay at a steady rate. As a result, all living organisms have a fixed ratio (of about 1 to 1012 ) of carbon-14 atoms to carbon-12 atoms, and 1.0 g of naturally occurring carbon has an activity of 15 disintegrations per minute. When an organism dies, it no longer exchanges carbon with its surroundings. However, carbon-14 nuclei already inside the organism continue to decay with a constant half-life, and so the ratio of carbon-14 to carbon-12 decreases. The ratio observed in a sample of dead tissue can therefore be used to estimate the time since death. In the technique developed by Willard Libby in Chicago in the late 1940s, the proportion of carbon-14 in a sample is determined by monitoring the ␤ radiation from ¡ t1>2 = ln 2 k 1 2 17.7 MEASURING THE RATE OF NUCLEAR DECAY 719 TABLE 17.5 Half-Lives of Radioactive Isotopes* Nuclide Half-life, t1/2 tritium 12.3 a carbon-14 5.73 ka carbon-15 2.4 s potassium-40 1.26 Ga cobalt-60 5.26 a strontium-90 28.1 a iodine-131 8.05 d cesium-137 30.17 a radium-226 1.60 ka uranium-235 0.71 Ga uranium-238 4.5 Ga fermium-244 3.3 ms *d ϭ day, a ϭ year. Nuclear testing has increased the amount of carbon-14 in the air, and sensitive radiocarbon dating techniques take this increase into account. CO2 obtained by burning the sample. This procedure is illustrated in Example 17.4. In the modern version of the technique, which requires only a few milligrams of sample, the carbon atoms are converted into CϪ ions by bombardment of the sample with cesium atoms. The CϪ ions are then accelerated with electric fields, and the carbon isotopes are separated and counted with a mass spectrometer (Fig. 17.19). 720 CHAPTER 17 NUCLEAR CHEMISTRY FIGURE 17.19 In a modern carbon-14 dating measurement, a mass spectrometer is used to determine the proportion of carbon-14 nuclei in the sample relative to the number of carbon-12 nuclei. EXAMPLE 17.4 Interpreting carbon-14 dating A carbon sample of mass 1.00 g from wood found in an archaeological site in Arizona underwent 7.90 ϫ 103 carbon-14 disintegrations in a period of 20.0 h. In the same period, 1.00 g of carbon from a modern source underwent 1.84 ϫ 104 disintegrations. Calculate the age of the sample, given that the half-life of 14 C is 5.73 ka. Anticipate Because the half-life of 14 C is 5.73 ka and the activity of the sample has fallen to less than half that of the modern sample, we should expect that it is more than 5730 years old. PLAN First, we rearrange Eq. 3 to give an expression for the time and then express k in terms of t1/2 by using Eq. 4. We assume that the carbon-14 activity of the modern sample is the same as the original activity in the ancient sample. Therefore, N/N0 is equal to the ratio of the number of disintegrations in the ancient and modern samples. SOLVE From N ϭ N0e–kt , t = - 1 k lna N N0 b From t1/2 ϭ (ln 2)/k, t = - t1/2 ln 2 lna N N0 b Substitute the data. = 6.99 ka t = - 5.73 ka ln 2 * lna 7900 18 400 b 18 400 7900 t1/2 5.73 0 6.99 Time (ka) Counts Evaluate As expected, the sample is more than 5730 years old. We can conclude that approximately 7000 years have elapsed since the piece of wood was part of a living tree. 17.8 USES OF RADIOISOTOPES 721 Self-Test 17.6A A sample of carbon of mass 250. mg from wood found in a tomb in Israel underwent 2480 carbon-14 disintegrations in 20. h. Estimate the time since death, assuming the same activity for a modern sample as in Example 17.4. [Answer: 5.1 ka] Self-Test 17.6B A sample of carbon of mass 1.00 g from scrolls found near the Dead Sea underwent 1.4 ϫ 104 carbon-14 disintegrations in 20. h. Estimate the approximate time since the sheepskins composing the scrolls were removed from the sheep, assuming the same activity for a modern sample as in Example 17.4. The law of radioactive decay implies that the number of radioactive nuclei decreases exponentially with time with a characteristic half-life. Radioactive isotopes are used to determine the ages of objects. 17.8 Uses of Radioisotopes Radioisotopes are radioactive isotopes. They are used not only to cure disease (as described in Box 17.1), but also to preserve food, to trace mechanisms of reactions, and to power equipment in spacecraft. Radioactive tracers are isotopes that are used to track how substances change and move. For example, a sample of sugar can be labeled with carbon-14; that is, some carbon-12 atoms in sugar molecules are replaced by carbon-14 atoms, which can be detected by radiation counters. In this way, the progress through the body of even a tiny amount of sugar molecules, too small an amount to be detected by other means, can be monitored. Fertilizers labeled with radioactive nitrogen, phosphorus, or potassium are used to follow the mechanism of plant growth and the passage of these elements through the environment. Chemists and biochemists use tracers to help determine the mechanisms of reactions. For example, if water containing oxygen-18 is used in photosynthesis, the oxygen produced is oxygen-18: 6 CO2(g) ϩ 6 H2 18 O(l) C6H12O6(s, glucose) ϩ 6 18 O2(g) This result shows that the oxygen produced in photosynthesis comes from the water molecules, not the carbon dioxide molecules. Radioisotopes have important commercial applications. For example, americium- 241 is used in smoke detectors. Its role is to ionize any smoke particles, which then allow a current to flow and set off the alarm. Exposure to radiation is also used to sterilize food and inhibit the sprouting of potatoes. Radioisotopes that give off a lot of energy as heat are used to provide power in remote locations, where refueling of generators is not possible. The instruments in unmanned spacecraft, such as Voyager 2, are powered by radiation from isotopes with long half-lives, such as plutonium. Isotopes are also used to study the environment. Just as carbon-14 is used to date organic materials, geologists can determine the age of very old substances such as rocks by measuring the abundance in rocks of radioisotopes with longer half-lives. Uranium- 238 (t1/2 ϭ 4.5 Ga, 1 Ga ϭ 109 years) and potassium-40 (t1/2 ϭ 1.26 Ga) are used to date very old rocks. For example, potassium-40 decays by electron capture to form argon-40. The rock is placed under vacuum and crushed, and a mass spectrometer is used to measure the amount of argon gas that escapes. This technique was used to determine the age of rocks collected on the surface of the Moon; they were found to be 3.5–4.0 billion years old, about the same age as the oldest rocks on Earth. Radioisotopes are used as long-lasting power sources, to study the environment, and to track movement. They are used in biology to trace metabolic pathways, in chemistry to trace reaction mechanisms, and in geology to determine the ages of rocks. NUCLEAR ENERGY Nuclear reactions can release huge amounts of energy, and nuclear reactors are widely used to provide power. The benefits of nuclear power include the large quantity of energy that can be obtained from a small mass of fuel and the absence of chemical pollution of the kind associated with fossil fuels. However, like other powerful resources, nuclear energy presents us with great technical challenges and hazards. The following sections outline some of the principles. ¡ 17.9 Mass–Energy Conversion The energy released when the nucleons in a nucleus adopt a more stable arrangement can be calculated by comparing the masses of the nuclear reactants and the nuclear products. Einstein’s theory of relativity tells us that the mass of an object is a measure of its energy content: the greater the mass of an object, the greater its energy. Specifically, the total energy, E, and the mass, m, are related by Einstein’s famous equation E ϭ mc2 (5)* where c is the speed of light (3.00 ϫ 108 m·s–1 ). It follows from this relation that loss of energy is always accompanied by loss of mass. The mass loss that always accompanies the loss of energy is normally far too small to detect. Even in a strongly exothermic chemical reaction, such as one that releases 103 kJ of energy, the mass of the products and the reactants differ by only 10–8 g. In a nuclear reaction, the energy changes are very large, the mass loss is measurable, and we can calculate the energy released from the observed change in mass. The nuclear binding energy, Ebind, is the energy released when protons and neutrons come together to form a nucleus. All binding energies are positive, which means that a nucleus has a lower energy than its constituent nucleons; the greater the binding energy, the lower the energy of the nuclide. Binding energy is usually reported as the energy per nucleon, and another way to think of binding energy is as the average energy that must be supplied to separate a nucleon from a nucleus. We can use Einstein’s equation to calculate the nuclear binding energy from the difference in mass, ⌬m, between the nucleus and the separated nucleons. For example, iron-56 has 26 protons, each of mass mp, and 30 neutrons, each of mass mn. The difference in mass between the nucleus and the separate nucleons is ϭ m(56 26Fe) Ϫ (26mp ϩ 30 mn) We can calculate the binding energy from the difference in mass: (6)* The absolute value of the mass difference is used because all binding energies are positive. We report binding energies in electronvolts (eV) or, more specifically, millions of electronvolts (1 MeV ϭ 106 eV): 1 eV ϭ 1.602 18 ϫ 10Ϫ19 J Because the masses of nuclides are so small, they are normally reported as a multiple of the atomic mass constant, mu. The atomic mass constant is defined as exactly 1 /12 the mass of one atom of carbon-12: Current determinations of the mass of carbon-12 give mu ϭ 1.6605 ϫ 10Ϫ27 kg The mass of an atom in terms of the atomic mass constant is numerically the same as the molar mass in grams per mole. For instance, the molar mass of carbon-12 is exactly 12 g·molϪ1 , and the mass of a carbon-12 atom is exactly 12mu. A note on good practice: Distinguish the atomic mass constant mu from the atomic mass unit u. If the molar mass of the nuclide is M, the mass of the nuclide is written either (M/g molϪ1 )mu (no gap, a multiple of the constant) or (M/g molϪ1 ) u (a gap, a multiple of the unit). For instance, for 19 F, for which M ϭ 19.00 g molϪ1 , the mass of one atom is written as either 19.00mu or 19.00 u. The two are related by mu ϭ 1 u. The unit 1 u used to be written 1 amu and you might still encounter that form. When calculating for a nuclear reaction we use the mass of an atom of 1 H in place of the mass of each proton. This strategy allows us to use readily available isotope masses instead of the masses of bare atomic nuclei to calculate , because the number ofƒ¢mƒ ƒ¢mƒ mu = m112 C2 12 Ebind = ƒ ¢mƒ * c2 ¢m = am(products) - am(reactants) 722 CHAPTER 17 NUCLEAR CHEMISTRY electrons in the isotope will be the same as the total number of electrons in the 1 H atoms on the other side of the equation and the masses of the electrons cancel. The contribution to the total mass that is due to the electron–nucleus binding energy is only about mu/106 per proton, and so it can be ignored in elementary calculations. 17.9 MASS–ENERGY CONVERSION 723 EXAMPLE 17.5 Calculating the nuclear binding energy Calculate the nuclear binding energy in electronvolts for a helium-4 nucleus, given the following masses: 4 He, 4.0026mu; 1 H, 1.0078mu; n, 1.0087mu. Anticipate Because nuclear reactions can release huge amounts of energy, we should expect a large value for the nuclear binding energy. PLAN The nuclear binding energy is the energy released in the formation of the nucleus from its nucleons. Use H atoms instead of protons to account for the masses of the electrons in the He atom produced. Write the nuclear equation for the formation of the nuclide from hydrogen atoms and neutrons, and calculate the difference in masses between the products and the reactants; convert the result from a multiple of the atomic mass constant into kilograms. Then, use the Einstein relation to calculate the energy corresponding to this loss of mass and convert the units to electronvolts. SOLVE Write the nuclear equation. 2 1 H ϩ 2 1 n 4 He¡ Calculate the change in mass. ⌬m ϭ m(4 He) Ϫ (2mp ϩ 2mn) ϭ 4.0026mu Ϫ {2(1.0078) ϩ 2(1.0087)}mu ϭ Ϫ0.0304mu 2p 2n 0.304mu 4He Express the change in mass in kilograms. ¢m = -0.0304 * 1.6605 * 10-27 kg Calculate the binding energy from Ebind ϭ |⌬m| ϫ c2 , = 4.54 * 10-12 kgиm2 s-2 = 4.54 * 10-12 J * 13.00 * 108 mиs-1 22 Ebind = ƒ -0.0304 * 1.6605 * 10-27 kg ƒ Convert the binding energy to millions of electronvolts: Evaluate The value of the binding energy shows that 4.54 pJ (1 pJ ϭ 10Ϫ12 J) or 28.3 MeV is released when one 4 He nucleus forms from its nucleons. (Note that in the penultimate step we used 1 kg·m2 ·sϪ2 ϭ 1 J.) Although this may seem only a small energy, on the atomic scale it is very large, as expected. The total binding energy of 1 mol He atoms is 1.09 ϫ 1013 J, or 10.9 TJ. Self-Test 17.7A Calculate the binding energy of a carbon-12 nucleus in electronvolts. [Answer: 92.3 MeV] Self-Test 17.7B Calculate the binding energy of a uranium-235 nucleus in electronvolts. The mass of one uranium-235 atom is 235.0439mu. Figure 17.20 shows the binding energy per nucleon, Ebind/A, for the elements. The graph shows that nucleons are bonded together most strongly in the elements near iron and nickel. This high binding energy is one of the reasons why iron and nickel are so Ebind = 4.54 * 10-12 J * 1 eV 1.602 * 10-19 J * 1 MeV 106 eV = 28.3 MeV A 0 40 80 120 160 200 240 6Li 2H 235U12C 16O 56Fe 4He Bindingenergypernucleon FIGURE 17.20 The variation of the nuclear binding energy per nucleon. The maximum binding energy per nucleon occurs near iron and nickel. Their nuclei have the lowest energies of all because their nucleons are the most tightly bound. (The vertical axis is Ebind/A.) 724 CHAPTER 17 NUCLEAR CHEMISTRY EXAMPLE 17.6 Calculating the energy released during fission When uranium-235 nuclei are bombarded with neutrons, they can split apart in a variety of ways, like glass balls that shatter into pieces of different sizes. In one process, uranium-235 forms barium-142 and krypton-92: 235 92U ϩ 1 0n 142 56Ba ϩ 92 36Kr ϩ 2 1 0n Calculate the energy (in joules) released when 1.0 g of uranium-235 undergoes this fission reaction. The masses of the particles are 235 92U, 235.04mu; 142 56Ba, 141.92mu; 92 36Kr, 91.92mu; n, 1.0087mu. Anticipate Fission processes are used to produce energy; therefore, we should expect that a large amount of energy will be released. PLAN If we know the mass loss, we can find the energy released by using Einstein’s equation. Therefore, we must calculate the total mass of the particles on each side of the nuclear equation, take the difference, and substitute the mass difference into Eq. 6. Then we determine the number of nuclei in the sample from N ϭ m(sample)/m(atom) and, finally, multiply the energy released from the fission of one nucleus by that number to find the energy released by the sample. SOLVE ¡ Calculate mass of products. m(products) ϭ m(Ba) ϩ m(Kr) ϩ 2m(n) ϭ {141.92 ϩ 91.92 ϩ 2(1.0087)}mu ϭ 235.86mu Calculate mass of reactants. m(reactants) ϭ m(U) ϩ m(n) ϭ 235.04mu ϩ 1.0087mu ϭ 236.05mu Express this change in kilograms. ¢m = -0.19 * 1.6605 * 10-27 kg Calculate the change in mass. ⌬m ϭ 235.86mu Ϫ 236.05mu ϭ Ϫ0.19mu 2n n 92 Kr 0.19mu 235 U 142 Ba abundant in meteorites and on a rocky planet such as Earth. The binding energy per nucleon is less for all other nuclides. We can infer that nuclei of light atoms become more stable when they “fuse” together and that heavy nuclei become more stable when they undergo “fission” and split into lighter nuclei. Nuclear binding energies are determined by applying Einstein’s formula to the mass difference between the nucleus and its components. Iron and nickel have the highest binding energy per nucleon. 17.10 Nuclear Fission In 1938, Lise Meitner, Otto Hahn, and Fritz Strassmann realized that, by bombarding heavy atoms such as uranium with neutrons, they could “split” the atoms into smaller fragments in fission reactions, releasing huge amounts of energy. We can estimate the energy that would be released by using Einstein’s equation, as we did in Example 17.5. Notice that we do not cancel neutrons, although they appear on both sides of the equation. Like equations for elementary chemical reactions, nuclear equations show the specific process. 17.10 NUCLEAR FISSION 725 Calculate the change in energy for the fission of one nucleus from ⌬E ϭ ⌬mc2 . ⌬E ϭ (Ϫ0.19 ϫ 1.6605 ϫ 10Ϫ27 kg) ϫ (3.00 ϫ 108 mиsϪ1 )2 ϭ (Ϫ0.19 ϫ 1.6605 ϫ 10Ϫ27 ) ϫ (3.00 ϫ 108 )2 J (ϭ Ϫ2.8 ϫ 10–11 J) Find the number of atoms, N, in the sample from N ϭ m(sample)/m(atom). = 1.0 * 10-3 235.04 * 1.6605 * 10-27 (= 2.6 * 1021 )N = 1.0 * 10-3 kg 235.04mu Calculate the total energy change of the sample from ⌬E(total) ϭ N⌬mc2 . = -7.3 * 1010 J * 5-0.19 * 1.6605 * 10-27 * 13.00 * 108 22 6 J¢E = 1.0 * 10-3 235.04 * 1.6605 * 10-27 Evaluate The energy released is large, as expected; 73 GJ is 1.3 million times as much energy as would be produced by burning 1.0 g of methane, the main component of natural gas. Self-Test 17.8A Another mode in which uranium-235 can undergo fission is 235 52U ϩ 1 0n 135 52Te ϩ 100 40Zr ϩ 1 0n Calculate the energy released when 1.0 g of uranium-235 undergoes fission in this way. The masses needed are 235 92U, 235.04mu; n, 1.0087mu; 135 52Te, 134.92mu; 100 40Zr, 99.92mu. [Answer: 77 GJ] Self-Test 17.8B A nuclear reaction that can cause great destruction is one of many that take place in the 235 U atomic bomb: 235 92U ϩ 1 0n 138 56Ba ϩ 86 36Kr ϩ 12 1 0n How much energy is released when 1.0 g of uranium-235 undergoes fission in this manner? The additional masses needed are 138 56Ba, 137.91mu; 86 36Kr, 85.91mu. Spontaneous nuclear fission takes place when the natural oscillations of a heavy nucleus cause it to break into two nuclei of similar mass (Fig. 17.21). We can think of the nucleus as distorting into a dumbbell shape and then breaking into two smaller nuclei. An example is the spontaneous disintegration of americium-244 into iodine and molybdenum: 244 95Am 134 53I ϩ 107 42Mo ϩ 3 1 0n Fission does not occur in precisely the same way in every instance. For example, more than 200 isotopes of 35 different elements have been identified among the fission products of uranium-235, with most products having mass numbers close to 90 or 130 (Fig. 17.22). Induced nuclear fission is fission caused by bombarding a heavy nucleus with neutrons (Fig. 17.23). The nucleus breaks into two fragments when struck by a projectile. Nuclei that can undergo induced fission are called fissionable. For most nuclei, fission takes place only if the impinging neutrons travel so rapidly that they can smash into the nucleus and drive it apart with the shock of impact; uranium-238 undergoes fission in this way. Fissile nuclei, however, are nuclei that can be nudged into breaking apart even by slow neutrons. They include uranium-235, uranium-233, and plutonium-239—the fuels of nuclear power plants. Once nuclear fission has been induced, it can continue, even if the supply of neutrons from outside is discontinued, provided that the fission produces more neutrons. Such self-sustaining fission takes place in uranium-235, which undergoes numerous fission processes, including 235 92U ϩ 1 0n 141 56Ba ϩ 92 36Kr ϩ 3 1 0n If the three product neutrons strike three other fissile nuclei, then after the next round of fission there will be nine neutrons, which can induce fission in nine more nuclei. In the language of Section 14.9, neutrons are carriers in a branched chain reaction (Fig. 17.24). ¡ ¡ ¡ ¡ (a) (b) FIGURE 17.21 In spontaneous nuclear fission, the oscillations of the heavy nucleus (a) in effect tear the nucleus apart, thereby forming two or more smaller nuclei of similar mass (b). Here, two neutrons are released. FIGURE 17.22 The fission yield of uranium-235. Note that the majority of fission products lie in the regions close to A ϭ 90 and 130 and that relatively few nuclides corresponding to symmetrical fission (A close to 117) are formed. Fissionyield 9070 110 130 150 Mass number, A Neutrons produced in a chain reaction are moving very fast, and most escape into the surroundings without colliding with another fissionable nucleus. However, if a large enough number of uranium nuclei are present in the sample, enough neutrons can be captured to sustain the chain reaction. In that case, there is a critical mass, a mass of fissionable material above which so few neutrons escape from the sample that the fission chain reaction is sustained. If a sample is supercritical, with a mass in excess of the critical value, then the reaction is not only self-sustaining but difficult to control and may result in an explosion. The critical mass for a solid sphere of pure plutonium of normal density is about 15 kg, about the size of a grapefruit. The critical mass is smaller if the metal is compressed by detonating a conventional explosive that surrounds it. Then the nuclei are pressed closer together and become more effective at blocking the escape of neutrons. The critical mass can be as low as 5 kg for highly compressed plutonium. A sample that has less than the critical mass for its density is said to be subcritical. In a nuclear weapon, the fissile material is initially subcritical. The challenge is to produce a supercritical mass so rapidly that the chain reaction takes place uniformly throughout the metal. Supercriticality can be achieved by shooting two subcritical blocks toward each other (as was done in the bomb that fell on Hiroshima) or by implosion of a single subcritical mass (the technique used in the bomb that destroyed Nagasaki). A strong neutron emitter, typically polonium, helps to initiate the chain reaction. Explosive fission cannot occur in a nuclear reactor, because the fuel is not dense enough. Instead, reactors sustain a much slower, controlled chain reaction by making efficient use of a limited supply of neutrons and slowing the neutrons down. The fuel is shaped into long rods and inserted into a moderator, a material that slows down the neutrons as they pass between fuel rods; the slower neutrons have a greater probability of collision with a nucleus (Fig. 17.25). Slow neutrons have three significant roles: they do not induce the fission of fissionable (as distinct from fissile) material; they are most effectively absorbed by the fissile uranium-235; and they are more easily controlled. The first moderator used was graphite. Heavy water, D2O, is also an effective neutron moderator, but light-water reactors (LWRs) use ordinary water as a moderator. They are the most common type of nuclear reactor in the United States (Fig. 17.26). If the rate of the chain reaction exceeds a certain level, the reactor will become too hot and begin to melt. Control rods—rods made from neutron-absorbing elements, such as boron or cadmium, and inserted between the fuel rods—help to control the number of available neutrons and the rate of nuclear reaction. One of the many problems of nuclear power is the availability of fuel: uranium- 235 reserves are only about 0.7% those of the nonfissile uranium-238, and the separation of the isotopes is costly (Section 17.12). One solution is to synthesize fissile nuclides from other elements. In a breeder reactor, a reactor that is used to create nuclear fuel, the neutrons are not moderated. Their high speeds result in the formation of not only uranium-235 but also some fissile plutonium-239, which can be used as fuel (or for warheads). However, breeder reactors are more hazardous to operate than nuclear power plants. They run very hot, and the fast reactions require more careful control than reactors used for nuclear power generation. Nuclear energy can be extracted by arranging for a nuclear chain reaction to take place in a critical mass of fissionable material, with neutrons as the chain carriers. A moderator is used to reduce the speeds of the neutrons in a reactor that uses fissile material. 17.11 Nuclear Fusion Although fission reactors do not generate chemical pollution, they do produce highly hazardous radioactive waste. However, another kind of nuclear reaction being investigated for power generation is essentially free of long-lived radioactive waste products, and its abundant fuel is readily extracted from seawater. The reaction is the fusion of hydrogen nuclei to form helium nuclei. From the plot in Fig. 17.20, we can see that there is a large increase in nuclear binding energy on going from light elements such as deuterium to heavier elements. Consequently, energy is released when deuterium nuclei fuse together to form nuclei of 726 CHAPTER 17 NUCLEAR CHEMISTRY FIGURE 17.24 A self-sustaining chain reaction, in which neutrons are the chain carriers, takes place when induced fission produces more than one neutron per fission event. These newly produced neutrons can stimulate fission in increasingly greater numbers of other nuclei. Animation 17.24 n FIGURE 17.23 In induced nuclear fission, the impact of an incoming neutron causes the nucleus to break apart. Fission products n n n those elements. Unfortunately, the strong electrical repulsion between protons makes it difficult for them to approach each other closely enough to fuse together. The nuclei of the heavier isotopes of hydrogen fuse together more readily, because the additional neutrons contribute to the strong force and help to capture the approaching protons. To achieve the high kinetic energies needed for successful collisions, fusion reactors need to operate at temperatures above 108 K. One fusion scheme uses deuterium (D, 2 H) and tritium (T, 3 H) in the following sequence of nuclear reactions: D ϩ D 3 He ϩ n D ϩ D T ϩ p D ϩ T 4 He ϩ n D ϩ 3 He 4 He ϩ p Overall reaction: 6 D 2 4 He ϩ 2 p ϩ 2 n The overall reaction releases 3 ϫ 108 kJ for each gram of deuterium consumed. That energy corresponds to the energy generated when the Hoover Dam operates at full capacity for about an hour. Additional tritium is supplied to facilitate the process. Because tritium has a very low natural abundance and is radioactive, it is generated by bombarding lithium-6 with neutrons in the immediate surroundings of the reaction zone: 6 Li ϩ n T ϩ 4 He Nuclear fusion is very difficult to achieve because the charged nuclei must be hurled at each other with enormous kinetic energies. One way of accelerating nuclei to sufficiently high speeds is to heat them with a fission explosion: this method is used to produce a thermonuclear explosion, an explosion due to nuclear fusion. In “hydrogen bombs,” a fission bomb (using uranium or plutonium) ignites a lithium-6 fusion bomb. Fusion bombs can be of varying destructive capacities, because there is no critical mass to maintain. Typical fusion bombs have a destructive capacity greater than 200 times that of the fission bombs that were dropped on Hiroshima and Nagasaki in World War II. A more constructive approach to nuclear fusion—one that achieves a controlled release of nuclear energy—is to heat a plasma, or ionized gas, by passing an electric current through it. The very fast ions in the plasma are kept away from the walls of the container with magnetic fields. This method of achieving fusion is the subject of intense research and is beginning to show signs of success (Fig. 17.27). Nuclear fusion makes use of the energy released when light nuclei fuse together to form heavier nuclei. ¡ ¡ ¡ ¡ ¡ ¡ 17.11 NUCLEAR FUSION 727 Steam generatorHeat exchanger Control rods Pressure vessel Hot Cool Pump Core Steam to turbine From turbine Containment vessel FIGURE 17.25 A schematic representation of one type of nuclear reactor in which water acts as a moderator for the nuclear reaction. In this pressurized water reactor (PWR), the coolant is water under pressure. The fission reactions produce heat, which boils water in the steam generator; the resulting steam turns the turbines that generate electricity. FIGURE 17.26 The reactor core of a typical light-water reactor (LWR) nuclear power plant is immersed in water. 17.12 The Chemistry of Nuclear Power Chemistry is the key to the safe use of nuclear power. It is used in the preparation of the fuel itself, the recovery of important fission products, and the safe disposal or utilization of nuclear waste. Uranium is the fuel of nuclear reactors. The most important of its minerals is pitchblende, UO2 (Fig. 17.28), much of which is obtained from strip mines in New Mexico and Wyoming. Uranium is refined to reduce the ore to the metal and to enrich it; that is, to increase the abundance of a specific isotope—in this case, uranium-235. The natural abundance of uranium-235 is about 0.7%; for use in a nuclear reactor, this fraction must be increased to about 3%. The enrichment procedure uses the small mass difference between the hexafluorides of uranium-235 and uranium-238 to separate them. The first procedure to be developed converts the uranium into uranium hexafluoride, UF6, which can be vaporized readily. The different effusion rates of the two isotopic fluorides are then used to separate them. From Graham’s law of effusion (rate of effusion 1/(molar mass)1/2 ; Section 4.9), the rates of effusion of 235 UF6 (molar mass, 349.0 g·mol–1 ) and 238 UF6 (molar mass, 352.1 g·mol–1 ) should be in the ratio Because the ratio is so close to 1, the vapor must be allowed to effuse repeatedly through porous barriers consisting of screens with large numbers of minute holes. In practice, it is allowed to do so thousands of times. Because the effusion process is technically demanding and uses a lot of energy, scientists and engineers continue to look for alternative enrichment procedures. One of these approaches uses a centrifuge that rotates samples of uranium hexafluoride vapor at very high speed. This rotation causes the heavier 238 UF6 molecules to be thrown outward and collected as a solid on the outer parts of the rotor, leaving a high proportion of 235 UF6 closer to the axis of the rotor, from where it can be removed. Spent nuclear fuel remains radioactive and consists of a mixture of uranium and fission products. Nuclear reactor waste can be processed and some of it reused, but the percentage processed depends on the price of uranium. When the price is high, as it is in the early twenty-first century, much of the nuclear waste is processed for reuse. The processing of nuclear waste is complex. Any remaining uranium-235 must be recovered, any plutonium produced must be extracted, and the largely useless but radioactive fission products must be stored safely (Fig. 17.29). The highly radioactive fission (HRF) products from used nuclear fuel rods must be stored until their level of Rate of effusion of 235 UF6 Rate of effusion of 238 UF6 = A 352.1 349.0 = 1.004 r 728 CHAPTER 17 NUCLEAR CHEMISTRY FIGURE 17.27 Research into controlled nuclear fusion is being carried out in several countries. Here we see the Tokomak fusion test reactor at the Princeton Plasma Physics Laboratory. FIGURE 17.28 Pitchblende is a common uranium ore. It is a variety of uranite, UO2. radioactivity is no longer dangerous (about 10 half-lives). Generally they are buried underground, but even burial of radioactive wastes is not without problems. Metal storage drums can corrode and allow liquid radioactive waste to seep into aquifers that supply drinking water (Fig. 17.30). Leakage can be minimized by incorporating the HRF products into a glass—a solid, complex network of silicon and oxygen atoms. Most of the fission products are oxides of the type that form one of the components of glass—they are network formers (see Section 6.10); that is, they promote the formation of a relatively disorderly Si–O network rather than inducing crystallization into an orderly array of atoms. Crystallization is dangerous because crystalline regions easily fracture, exposing the incorporated radioactive materials to moisture. Water could dissolve them and carry them away from the storage area. An alternative is to incorporate radioactive waste into hard ceramic materials (Section 6.11). An example is Synroc, a fracture-resistant titanate-based ceramic that can accept radioactive waste products into its lattice. Uranium is extracted by a series of reactions that lead to uranium hexafluoride; the isotopes are then separated by a variety of procedures. Some radioactive waste is currently converted into glass or ceramic materials for storage underground. SKILLS YOU SHOULD HAVE MASTERED 729 FIGURE 17.29 Containers of high-level waste products, including cesium-137 and strontium-90, glow under a protective layer of water. If the canisters were unshielded, the radiation that they emit would be great enough to cause death within about 4 s. FIGURE 17.30 This 35-year-old drum of radioactive waste has corroded and leaked radioactive materials into the soil. The drum was located in one of the nuclear waste disposal sites at the U.S. Department of Energy’s Hanford, Washington, nuclear manufacturing and research facility. Several storage sites at this facility became seriously contaminated and had to be cleaned and reconfigured for more stable storage. ❑ 1 Write, complete, and balance nuclear equations (Examples 17.1 and 17.2). ❑ 2 Use the band of stability to predict the types of decay that a given radioactive nucleus is likely to undergo (Self-Test 17.3). ❑ 3 Distinguish ␣, ␤, and ␥ radiation by their response to an electric field, penetrating power, and relative biological effectiveness (Sections 17.1 and 17.6). ❑ 4 Predict the amount of a radioactive sample that will remain after a given time period, given the decay constant or half-life of the sample (Example 17.3). ❑ 5 Use the half-life of an isotope to determine the age of an object (Example 17.4). ❑ 6 Calculate the nuclear binding energy of a given nuclide (Example 17.5). ❑ 7 Calculate the energy released during a nuclear reaction (Example 17.6). ❑ 8 Distinguish nuclear fission from nuclear fusion and predict which nuclides undergo each type of process (Sections 17.10 and 17.11). ❑ 9 Describe some ways of storing radioactive waste (Section 17.12). SKILLS YOU SHOULD HAVE MASTERED 730 CHAPTER 17 NUCLEAR CHEMISTRY Note that the SI symbol for 1 year is 1 a and that it takes the usual prefixes, as in 1 ka ϭ 103 a and 1 Ga ϭ 109 a. Exercises labeled require calculus Radioactive Decay 17.1 When the nucleons rearrange in the following daughter nuclei, the energy changes by the amount shown and a ␥-ray is emitted. Determine the frequency and wavelength of the ␥-ray in each case: (a) cobalt-60, 1.33 MeV; (b) arsenic-80, 1.64 MeV; (c) iron-59, 1.10 MeV. (1 MeV ϭ 1.602 ϫ 10Ϫ13 J.) 17.2 Determine the frequency and wavelength of the ␥-ray emitted in the decay of each of following nuclides: (a) iron-53, 3.04 MeV; (b) vanadium-52, 1.43 MeV; (c) scandium-44, 0.27 MeV. (1 MeV ϭ 1.602 ϫ 10Ϫ13 J.) 17.3 Isotones are nuclides that have the same number of neutrons. Which isotopes of argon and calcium are isotones of potassium-40? 17.4 Which isotopes of krypton and selenium are isotones (see Exercise 17.3) of bromine-80? 17.5 Write the balanced nuclear equation for each of the following decays: (a) ␤Ϫ decay of tritium; (b) ␤ϩ decay of yttrium-83; (c) ␤Ϫ decay of krypton-87; (d) ␣ decay of protactinium-225. 17.6 Write the balanced nuclear equation for each of the following decays: (a) ␣ decay of californium-250; (b) positron decay of rubidium- 76; (c) electron capture by arsenic-73; (d) ␤Ϫ decay of chromium-56. 17.7 Write the balanced nuclear equation for each of the following decays: (a) ␤ϩ decay of boron-8; (b) ␤Ϫ decay of nickel-63; (c) ␣ decay of gold-185; (d) electron capture by beryllium-7. 17.8 Write the balanced nuclear equation for each of the following decays: (a) ␤Ϫ decay of uranium-233; (b) proton emission of cobalt-56; (c) ␤ϩ decay of holmium-158; (d) ␣ decay of polonium-212. 17.9 Determine the particle emitted and write the balanced nuclear equation for each of the following nuclear transformations: (a) sodium-24 to magnesium-24; (b) 128 Sn to 128 Sb; (c) lanthanum-140 to barium-140; (d) 228 Th to 224 Ra. 17.10 Determine the particle emitted and write the balanced nuclear equation for each of the following nuclear transformations: (a) gadolinium-148 to samarium-144; (b) fluorine-17 to oxygen-17; (c) silver-112 to cadmium-112; (d) plutonium-238 to uranium-234. 17.11 Complete the following equations for nuclear reactions: (a) 11 B ϩ ? : 2 n ϩ 13 N (b) ? ϩ D : n ϩ 36 Ar (c) 96 Mo ϩ D : ? ϩ 97 Tc (d) 45 Sc ϩ n : ␣ ϩ ? 17.12 Complete the following equations for nuclear decay reactions: (a) 12 O : 2 p ϩ ? (b) 17 C : ? ϩ n ϩ ␤Ϫ (c) 148 Ba : 147 La ϩ ? ϩ n (d) 18 Ne : ␤ϩ ϩ ? The Pattern of Nuclear Stability 17.13 The following nuclides lie outside the band of stability. Predict whether each is most likely to undergo ␤Ϫ decay, ␤ϩ decay, or ␣ decay, and identify the daughter nucleus: (a) copper-68; (b) cadmium-103; (c) berkelium-243; (d) dubnium-260. 17.14 The following nuclides lie outside the band of stability. Predict whether each is most likely to undergo ␤Ϫ decay, ␤ϩ decay, or ␣ decay, and identify the daughter nucleus: (a) copper-60; (b) xenon-140; (c) americium-246; (d) neptunium-240. 17.15 Identify the daughter nuclides in each step of the radioactive decay of uranium-235, if the string of particle emissions is ␣, ␤, ␣, ␤, ␣, ␣, ␣, ␤, ␣, ␤, ␣. Write a balanced nuclear equation for each step. 17.16 Neptunium-237 undergoes an ␣, ␤, ␣, ␣, ␤, ␣, ␣, ␣, ␤, ␣, ␤ sequence of radioactive decays. Write a balanced nuclear equation for each step. Nucleosynthesis 17.17 Complete the following nuclear equations: (a) 14 7N ϩ ? : 17 8O ϩ 1 1p (b) ? ϩ 1 0 n : 249 97Bk ϩ 0 Ϫ1e (c) 243 95Am ϩ 1 0n : 244 96Cm ϩ ? ϩ ␥ (d) 13 6C ϩ 1 0n : ? ϩ ␥ 17.18 Complete the following nuclear equations: (a) ? ϩ 1 1p : 21 11Na ϩ ␥ (b) 1 1H ϩ 1 1p : 2 1H ϩ ? (c) 15 7N ϩ 1 1p : 12 6C ϩ ? (d) 20 10Ne ϩ ? : 24 12Mg ϩ ␥ 17.19 Complete the following equations for nuclear transmutation: (a) 20 10Ne ϩ 4 2␣ : ? ϩ 16 8O (b) 20 10Ne ϩ 20 10Ne : 16 8O ϩ ? (c) 44 20Ca ϩ ? : ␥ ϩ 48 22Ti (d) 27 13Al ϩ 2 1H : ? ϩ 28 13Al 17.20 Complete the following equations for nuclear transmutation: (a) ? ϩ ␥ : 0 Ϫ1e ϩ 20 10Ne (b) 44 22Ti ϩ 0 Ϫ1e : 0 ϩ1e ϩ ? (c) 241 95Am ϩ ? : 4 1 0n ϩ 248 100Fm (d) ? ϩ 1 0n B 0 Ϫ1e ϩ 244 96Cm 17.21 One explanation for the existence of elements heavier than iron is the rapid neutron-capture process (r-process). In the r-process proposed to occur in supernovae, many high-speed neutrons smash into an iron nucleus. Some of these neutrons are rapidly captured, resulting in a highly unstable nucleus that immediately decays. In each decay step a neutron is converted into a proton. Write the overall nuclear equation for the absorption of six neutrons by an iron-56 nucleus and their decay to six protons. 17.22 It has been claimed that the neon present in meteorites was generated by nuclear reactions. One such reaction occurs when a silicon-28 atom is bombarded by cosmic ray protons. When one of these energetic protons is absorbed, the result is an isotope of neon, three protons, a neutron, and an ␣ particle. Identify the isotope of neon formed and write the nuclear equation for the process. 17.23 Write a nuclear equation for each of the following processes: (a) oxygen-17 produced by ␣-particle bombardment of nitrogen-14; (b) americium-240 produced by neutron bombardment of plutonium-239. EXERCISES C EXERCISES 731 17.24 Write a nuclear equation for each of the following transformations: (a) 257 Rf produced by the bombardment of californium-245 with carbon-12 nuclei; (b) the first synthesis of 266 Mt by the bombardment of bismuth-209 with iron-58 nuclei. Given that the first decay of meitnerium is by ␣ emission, what is the daughter nucleus? 17.25 What will be the systematic name and atomic symbol given to (a) element 126; (b) element 136; (c) element 200? 17.26 What will be the systematic name and atomic symbol given to (a) element 118; (b) element 127; (c) element 202? Nuclear Radiation 17.27 The activity of a certain radioactive source is 5.3 ϫ 105 Bq. Express this activity in curies. 17.28 The activity of a sample containing carbon-14 is 54.8 Bq. Express this activity in microcuries. 17.29 Determine the number of disintegrations per second for radioactive sources of each of the following activities: (a) 2.5 ␮Ci; (b) 142 Ci; (c) 7.2 mCi. 17.30 A certain Geiger counter is known to respond to only 1 of every 1000 radiation events from a sample. Calculate the activity of each radioactive source in curies, given the following data: (a) 591 clicks in 100. s; (b) 2.7 ϫ 104 clicks in 1.5 h; (c) 159 clicks in 1.0 min. 17.31 A 2.0-kg sample absorbs an energy of 1.5 J as a result of its exposure to ␤ radiation. Calculate the dose in rads and the dose equivalent in rems and in sieverts. 17.32 A 1.5-g sample of muscle tissue absorbs 2.6 J of energy as a result of its exposure to ␣ radiation. Calculate the dose in rads and the dose equivalent in rems and in sieverts. 17.33 Someone is exposed to a source of ␤ radiation that results in a dose rate of 1.0 radиdϪ1 . Given that nausea begins after a dose equivalent of about 100 rem, after what period will that symptom of radiation sickness be apparent? 17.34 Someone is exposed to a source of ␣ radiation that results in a dose rate of 2.0 mradиdϪ1 . If nausea begins after a dose equivalent of about 100 rem, after what period will nausea become apparent? The Rate of Nuclear Decay 17.35 Determine the decay constant for (a) tritium, t1/2 ϭ 12.3 a; (b) lithium-8, t1/2 ϭ 0.84 s; (c) nitrogen-13, t1/2 ϭ 10.0 min. 17.36 Determine the half-life of (a) potassium-40, k ϭ 5.3 ϫ 10Ϫ10 aϪ1 ; (b) cobalt-60, k ϭ 0.132 aϪ1 ; (c) nobelium-255, k ϭ 3.85 ϫ 10Ϫ3 sϪ1 . 17.37 The activity of a sample of a radioisotope was found to be 2150 disintegrations per minute. After 6.0 h the activity was found to be 1324 disintegrations per minute. What is the half-life of the radioisotope? 17.38 (a) A sample of pure cobalt-60 has an activity of 1 ␮Ci. (a) How many atoms of cobalt-60 are present in the sample? (b) What is the mass in grams of the sample? 17.39 (a) What percentage of a carbon-14 sample remains after 3.00 ka? (b) Determine the percentage of a tritium sample that remains after 12.0 a. 17.40 (a) What percentage of a strontium-90 sample remains after 8.5 a? (b) Determine the percentage of an iodine-131 sample that remains after 6.0 d. 17.41 Potassium-40, which is presumed to have existed at the formation of the Earth, is used for dating minerals. If three-fifths of the original potassium-40 exists in a rock, how old is the rock? 17.42 A piece of wood, found in an archaeological dig, has a carbon-14 activity that is 62% of the current carbon-14 activity. How old is the piece of wood? 17.43 A 250.-mg sample of carbon from a piece of cloth excavated from an ancient tomb in Nubia undergoes 1.50 ϫ 103 disintegrations in 10.0 h. If a current 1.00-g sample of carbon shows 921 disintegrations per hour, how old is the piece of cloth? 17.44 A current 1.00-g sample of carbon shows 921 disintegrations per hour. If 1.00 g of charcoal from an archaeological dig in a limestone cave in Slovenia shows 5.50 ϫ 103 disintegrations in 24.0 h, what is the age of the charcoal sample? 17.45 Use the law of radioactive decay to determine the activity of (a) a 1.0-mg sample of radium-226 (t1/2 ϭ 1.60 ka); (b) a 2.0-mg sample of strontium-90 (t1/2 ϭ 28.1 a); (c) a 0.43-mg sample of promethium-147 (t1/2 ϭ 2.6 a). The mass of each nuclide as a multiple of the atomic mass constant (mu) is equal to its mass number, within two significant figures. 17.46 Use the law of radioactive decay to determine the activity of (a) a 1.0-g sample of 235 UO2 (t1/2 ϭ 7.1 ϫ 108 a); (b) a 1.0-g sample of cobalt that is 1.0% 60 Co (t1/2 ϭ 5.26 a); (c) a 5.0-mg sample of thallium-200 (t1/2 ϭ 26.1 h). The mass of each nuclide as a multiple of the atomic mass constant (mu) is equal to its mass number, within two significant figures. 17.47 Deoxyglucose labeled with fluorine-18 is commonly used in PET scans to locate tumors. Fluorine-18 has a half-life of 109 min. How long will it take for the level of fluorine-18 in the body to drop to 10% of its initial value? 17.48 Technetium-99m (the m signifies a “metastable,” or moderately stable, species) is generated in nuclear reactors and shipped to hospitals for use in medical imaging. The radioisotope has a half-life of 6.01 h. If a 165-mg sample of technetium-99m is shipped from a nuclear reactor to a hospital 125 kilometers away in a truck that averages 50.0 kmиhϪ1 , what mass of technetium- 99m will remain when it arrives at the hospital? 17.49 A 1.40-g sample containing radioactive cobalt was kept for 2.50 a, at which time it was found to contain 0.266 g of 67 Co. The half-life of 67 Co is 5.27 a. What percentage (by mass) of the original sample was 67 Co? 17.50 A radioactive sample contains 3.25 ϫ 1018 atoms of a nuclide that decays at a rate of 3.4 ϫ 1013 disintegrations per 15 min. (a) What percentage of the nuclide will have decayed after 150 d? (b) How many atoms of the nuclide will remain in the sample? (c) What is the half-life of the nuclide? 17.51 A radioactive isotope X with a half-life of 27.4 d decays into another radioactive isotope Y with a half-life of 18.7 d, which decays into the stable isotope Z. Set up and solve the rate laws for the amounts of the three nuclides as a function of time, and plot your results as a graph. 17.52 Suppose that the nuclide Y in Exercise 17.51 is needed for medical research and that 2.00 g of nuclide X was supplied at t ϭ 0. At what time will Y be most abundant in the sample? C C Uses of Radioisotopes 17.53 A chemist is studying the mechanism of the following hydrolysis reaction of the organic ester methyl acetate: CH3COOCH3 ϩ H2O : CH3COOH ϩ CH3OH. The question arises whether the O atom in the product methanol comes from the methyl acetate or from the water. Propose an experiment using isotopes that would allow the chemist to determine the origin of the oxygen atom. 17.54 The blood volume in a cancer patient was measured by injecting 5.0 mL of Na2SO4(aq) labeled with 35 S (t1/2 ϭ 87.4 d). The activity of the sample was 300 ␮Ci. After 30. min, 10.0 mL of blood was withdrawn from the man and the activity of that sample was found to be 0.025 ␮Ci. Report the blood volume of the patient. 17.55 What would you expect to happen to the vibrational frequency of the C—H bond of methane if the hydrogen atoms, which are normally present as 1 H, are replaced by 2 H? See Major Technique 1, Infrared Spectroscopy. 17.56 Normal water, H2O, is necessary for life, but heavy water, D2O, is toxic. Suggest a reason for this difference. The pKa of deuterium oxide is 14.955 at 25°C. 17.57 The biological half-life of a radioisotope is the time required for the body to excrete half of the radioisotope. The effective half-life is the time required for the amount of a radioisotope in the body to be reduced to half its original amount, as a result of both the decay of the radioisotope and its excretion. Sulfur-35 (t1/2 ϭ 87.4 d) is used in cancer research. The biological half-life of sulfur-35 in the human body is 90. d. What is the effective half-life of sulfur-35? 17.58 Barium-140 (t1/2 ϭ 12.8 d) released in the fire at the Chernobyl nuclear plant has been found in some agricultural products in the region. The biological half-life of barium-140 in the human body is 65 d. What is the effective half-life (see Exercise 17.57) of barium-140? Nuclear Energy 17.59 Calculate the energy in joules that is equivalent to (a) 1.0 g of matter; (b) one electron; (c) 1.0 pg of matter; (d) one proton. 17.60 Calculate the energy in joules that is equivalent to (a) 1.00 kg of matter; (b) 1.00 lb of matter (1 lb ϭ 454 g); (c) one neutron; (d) one hydrogen atom. 17.61 The Sun emits radiant energy at the rate of 3.9 ϫ 1026 JиsϪ1 . What is the rate of mass loss (in kilograms per second) of the Sun? 17.62 (a) For the fusion reaction 6 D : 2 4 He ϩ 2 1 H ϩ 2 n, 3 ϫ 108 kJ of energy is released by a certain sample of deuterium. What is the mass loss (in grams) for the reaction? (b) What was the mass of deuterium converted? The molar mass of deuterium is 2.014 gиmolϪ1 . 17.63 Calculate the binding energy per nucleon (JиnucleonϪ1 ) for (a) 62 Ni, 61.928 346mu; (b) 239 Pu, 239.0522mu; (c) 2 H, 2.0141mu; (d) 3 H, 3.016 05mu. (e) Which nuclide is the most stable? 17.64 Calculate the binding energy per nucleon (JиnucleonϪ1 ) for (a) 98 Mo, 97.9055mu; (b) 151 Eu, 150.9196mu; (c) 56 Fe, 55.9349mu; (d) 232 Th, 232.0382mu. (e) Which nuclide is the most stable? 17.65 Calculate the energy released per gram of starting material in the fusion reaction represented by each of the following equations. (a) D ϩ D 3 He ϩ n (D, 2.0141mu; 3 He, 3.0160mu) (b) 3 He ϩ D 4 He ϩ 1 H (1 H, 1.0078mu; 4 He, 4.0026mu) (c) 7 Li ϩ 1 H 2 4 He (7 Li, 7.0160mu) (d) D ϩ T 4 He ϩ n (T, 3.0160mu) 17.66 Calculate the energy released per gram of starting material in the nuclear reaction represented by each of the following equations. (a) 7 Li ϩ 1 H n ϩ 7 Be (1 H, 1.0078mu; 7 Li, 7.0160mu; 7 Be, 7.0169mu) (b) 59 Co ϩ D 1 H ϩ 60 Co (59 Co, 58.9332mu; 60 Co, 59.9529mu; D, 2.0141mu) (c) 40 K ϩ ␤ 40 Ar (40 K, 39.9640mu; 40 Ar, 39.9624mu; ␤, 0.0005mu) (d) 10 B ϩ n 4 He ϩ 7 Li (10 B, 10.0129mu; 4 He, 4.0026mu) 17.67 Sodium-24 (23.990 96mu) decays to magnesium-24 (23.985 04mu). (a) Write a nuclear equation for the decay. (b) Determine the change in energy that accompanies the decay. (c) Calculate the change in the binding energy per nucleon. 17.68 (a) How much energy is emitted in each ␣ decay of plutonium-234? (234 Pu, 234.0433mu; 230 U, 230.0339mu). (b) The half-life of plutonium-234 is 8.8 h. How much heat is released by the ␣ decay of a 1.00-␮g sample of plutonium-234 in a 24-h period? 17.69 Each of the following equations represents a fission reaction. Complete and balance the equations: (a) 244 95Am 134 53I ϩ 107 42Mo ϩ 3 ? (b) 235 92U ϩ 1 0n ? ϩ 138 52Te ϩ 2 1 0n (c) 235 92U ϩ 1 0n 101 42Mo ϩ 132 50Sn ϩ ? 17.70 Complete each of the following nuclear equations for fission reactions: (a) 239 94Pu ϩ 1 0n 98 42Mo ϩ 138 52Te ϩ ? (b) 239 94Pu ϩ 1 0n 100 43Tc ϩ ? ϩ 4 1 0n (c) 239 94Pu ϩ 1 0n ? ϩ 49 139 In ϩ 3 1 0n Integrated Exercises 17.71 State whether the following statements are true or false. If false, explain why. (a) The dose equivalent is lower than the actual dose of radiation because it takes into account the differential effects of different types of radiation. (b) Exposure to 1 ϫ 108 Bq of radiation would be much more hazardous than exposure to 10 Ci of radiation. (c) Spontaneous radioactive decay follows firstorder kinetics. (d) Fissile nuclei can undergo fission when struck with slow neutrons, whereas fast neutrons are required to split fissionable nuclei. 17.72 State whether the following statements are true or false. If false, explain why. (a) A subcritical mass of fissionable material is unstable and likely to explode. (b) In order for fusion to occur, the colliding particles must have high kinetic energy. (c) Highly reactive fission products are considered to be no longer dangerous after two half-lives. (d) The larger the binding energy per nucleon, the more stable is the nucleus. ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ ¡ 732 CHAPTER 17 NUCLEAR CHEMISTRY EXERCISES 733 17.73 (a) How many radon-222 nuclei (t1/2 ϭ 3.82 d) decay per minute to produce an activity of 4 pCi? (b) A bathroom in the basement of a home measures 2.0 m ϫ 3.0 m ϫ 2.5 m. If the activity of radon-222 in the room is 4.0 pCiиLϪ1 , how many nuclei decay during a shower lasting 5.0 min? 17.74 Tritium undergoes ␤ decay, and the emitted ␤ particle has an energy of 0.0186 MeV (1 MeV ϭ 1.602 ϫ 10Ϫ13 J). If a 1.0-g sample of tissue absorbs 10% of the decay products of 1.0 mg of tritium, what dose equivalent does the tissue absorb? 17.75 It is found that 2.0 ϫ 10Ϫ5 mol 222 Rn (t1/2 ϭ 3.82 d) has seeped into a closed basement with a volume of 2.0 ϫ 103 m3 . (a) What is the initial activity of the radon in picocuries per liter (pCiиLϪ1 )? (b) How many atoms of 222 Rn will remain after 1 day (24 h)? (c) How long will it take for the radon to decay to below the EPA recommended level of 4 pCiиLϪ1 ? 17.76 Explain why containers of radioactive waste are more susceptible to corrosion than containers of nonradioactive waste with the same chemical reactivity. 17.77 Uranium-238 decays through a series of ␣ and ␤ emissions to lead-206, with an overall half-life for the entire process of 4.5 Ga. How old is a uranium-bearing ore that is found to have a 238 U/206 Pb ratio of (a) 1.00 and (b) 1.25? 17.78 A planet on which life is based on silicon instead of carbon has been discovered. However, a meteor strike destroyed most of the life on the planet. To determine how long ago the meteor strike occurred, the activity of silicon-32, which has a half-life of 1.6 ϫ 102 a, was measured in samples from the fossil remains of life forms killed in the meteor strike and in existing life forms. Activity in the fossil samples was found to be 0.015% of the activity in the living samples. How long ago did the meteor strike occur? 17.79 Sodium-24 is used for monitoring blood circulation. (a) If 2.0 mg of sodium-24 has an activity of 17.3 Ci, what is its decay constant and its half-life? (b) What mass of the sodium-24 sample remains after 2.0 d? The mass of a sodium-24 atom is 24mu. 17.80 A radioactive sample contains 32 P (half-life, 14.28 d), 33 S (half-life, 87.2 d), and 59 Fe (half-life, 44.6 d). After 90 d, a sample that originally weighed 8.00 g contains 0.0254 g of 32 P, 1.466 g of 33 S, and 0.744 g of 59 Fe. What was the percentage composition (by mass) of the original sample? 17.81 Radiopharmaceuticals have one of two general functions: (1) they may be used to detect or image biological problems such as tumors and (2) they may be used to treat an illness. Which type of radiation (␣, ␤, or ␥) would be the most suitable for (a) detection and (b) therapy? Justify your selections. (c) From standard literature sources, find at least two radionuclides that have been used for imaging body tissues. (d) What are the half-lives of these radionuclides? See Box 17.1. 17.82 Radioactive metal ions that have short half-lives are being intensely studied as pharmaceuticals. The strategy is to attach a well-designed ligand to the metal ion so that the complex very selectively aggregates in one particular type of body tissue. What properties of the ligand are important to the design of effective radiopharmaceutical therapeutic agents? See Box 17.1. 17.83 Technetium-99m is produced by a sequence of reactions in which molybdenum-98 is bombarded with neutrons to form molybdenum-99, which undergoes ␤ decay to technetium-99m. (a) Write the balanced nuclear equations for this sequence. (b) Compare the neutron-to-proton ratio of the final daughter product with that of technetium-99m. Which is closer to the band of stability? 17.84 Actinium-225 decays by successive emission of three ␣ particles. (a) Write the nuclear equations for the three decay processes. (b) Compare the neutron-to-proton ratio of the final daughter product with that of actinium-225. Which is closer to the band of stability? 17.85 Some airports have installed radiation detectors so that radioactive materials which could be used to make a bomb can be detected. The 12-year old boy next door asks you to explain how such a large object as a nuclear bomb could be carried on an airplane. Explain in words a 12-year old would understand what materials would have to be transported, what minimum mass of radioactive material would be required (the critical mass), and what the volume of that minimum mass would be. 17.86 A nuclear waste storage facility is being proposed for your county and you have been asked to prepare a recommendation for how highly radioactive fission products should be processed and stored. In your recommendation discuss the benefits and drawbacks of at least three modes of nuclear waste storage. 17.87 What volume of helium at 1.0 atm and 298 K will be collected if 2.5 g of 222 Rn is stored in a container able to expand to maintain constant pressure for 15 d? (222 Rn decays to 218 Po with a half-life of 3.824 d.) 17.88 Why is the boiling point of heavy water greater than that of ordinary water? (a) Propose a model that allows you to estimate the difference or, from the known difference, to estimate any unknown parameters in the model. (b) Use your model to estimate the boiling point of “extraheavy water,” T2O. 17.89 A positron has the same mass as that of an electron, but the opposite charge. When a positron emitted in a PET scan encounters an electron, annihilation occurs in the body: electromagnetic energy is produced and no matter remains. How much energy (in joules) is produced in the encounter? See Box 17.1. 17.90 Do nuclei that are positron emitters lie above or below the band of stability? Which of the following isotopes might be suitable for PET scans? Explain your reasoning and write the equation for the decay: (a) 18 O; (b) 13 N; (c) 11 C; (d) 20 F; (e) 15 O. See Box 17.1. 17.91 The radioactivity from a sample of Na2 14 CO3 was measured by noting the time required for the count of disintegrations to reach 8000. Five times were recorded: 21.25, 23.46, 20.97, 22.54, and 23.01 min. Background radiation was measured by noting the time required for 500 counts to be registered. Three times were recorded: 5.26, 5.12, and 4.95 min. What is the average level of radioactivity in the Na2 14 CO3 sample, corrected for background radiation, in (a) disintegrations per minute; (b) microcuries? 17.92 (a) Using a standard graphing program such as that found on the Web site for this text, plot the fraction of 14 C remaining in a 4.00 ϫ 104 -year-old archaeological sample as a function of time. For convenience, use intervals of 1000 a. (b) Plot the natural logarithm of the fraction of 14 C remaining as a function of time. (c) After what period of time will less than 1.00% of the original 14 C in the sample remain? Chemistry Connections 17.93 A person with pernicious anemia lacks “intrinsic factor,” a compound required for the absorption of vitamin B12 and its storage in the liver. The diagnosis is confirmed with the Schilling test. In this test the patient is given a small dose of vitamin B12 labeled with radioactive 57 Co or 58 Co, followed by a saturating dose of nonlabeled B12, which releases the stored B12. If the patient has intrinsic factor, a 24-hour urine sample will contain 13Ϫ15% of the labeled B12. If intrinsic factor is absent, less than 6% will be excreted. The patient is then given instrinsic factor and the test is repeated for comparison. In one administration of the Schilling test, the patient was given a capsule containing 0.5 ␮Ci of 58 CoB12, followed by 1.0 mg of nonlabeled B12. 1200 mL of urine was collected over the next 24 hours. A 3.0-mL sample of the urine gave 83 cpm (counts per minute) and a 3.0-mL standard sample containing 0.4 nCi per mL gave 910 cpm. The test was repeated one week later with the administration of 30. mg of intrinsic factor. The 3.0-mL sample of urine from the second test gave 120 cpm. The half-life of 58 Co is 72 days. (a) Calculate the percentage of 58 Co excreted with and without the intrinsic factor. Assume that the first test did not contaminate the second test. (b) What would be the activity of the 58 CoB12 in the original capsule if it were stored for 7 days? (c) If the biological half-life of B12 is 180 days, what is the effective half-life of 58 CoB12 in the body? See Exercise 17.57. (d) Use the effective half life of 58 CoB12 to determine what fraction of the counts in the second test would be due to the dose given in the first test. (e) The radioisotope 58 Co decays to another radioisotope, 59 Fe. The total mass of iron in the patient was 2.5 g. If all the 59 Fe produced in the first test were incorporated into hemoglobin, what percentage of the total iron would be 59 Fe the day after the first test? Ignore the decay of 59 Fe. 734 CHAPTER 17 NUCLEAR CHEMISTRY 735 What Are the Key Ideas? Large numbers of different hydrocarbons arise from the ability of carbon atoms to form long chains and rings with one another; the types of carbon–carbon bonds present give the hydrocarbons characteristic properties. Why Do We Need to Know This Material? All life on Earth is based on carbon; so is the fuel we burn, our food, and the clothes we wear. Therefore, to understand a major part of the everyday world, we need to be familiar with the chemistry of this extraordinary element. Compounds of carbon and hydrogen are the foundation of the petrochemical industry; petroleum products are used to generate electricity and to heat our homes. They are also used to make the flexible, strong polymeric and composite materials that make modern communication and transportation possible. What Do We Need to Know Already? This chapter draws on the introduction to organic formulas and nomenclature in Sections C and D, the structure of molecules (Chapters 2 and 3), intermolecular forces (Sections 5.3–5.5), reaction enthalpy (Section 7.13), reaction mechanisms (Sections 14.7–14.9), and isomers (Section 16.7). T wo elements, carbon and hydrogen, are the basis of nearly all our fuels, including not only petroleum products but their alternatives. Carbon, the focus of this chapter and the next, is also the basis of many materials essential to modern technology. Understanding the compounds that carbon forms and their reactions is therefore important not only to our technological and medical advances but also to our very survival. Carbon forms such a huge variety of compounds that an entire field of chemistry, organic chemistry, is devoted to its study. Carbon atoms are so adaptable because they can string together to form chains and rings of endless variety. This versatility allows the element to form thousands of complicated biomolecules that contribute to the structure and function of every organism on Earth. Synthetic carbon-based materials also have a wide range of properties, from the softness of fabrics and artificial skin to the tough composite materials used in experimental aircraft. This chapter deals with hydrocarbons, compounds built from only carbon and hydrogen. There are two broad classes of hydrocarbons: an aromatic hydrocarbon has a benzene ring as a part of its molecular structure; an aliphatic hydrocarbon does not. The compound shown as (1) is aromatic; compound (2) is aliphatic. We can describe more complex molecules as having an “aromatic region” consisting of benzenelike rings and an “aliphatic region” containing chains of carbon atoms. In Chapter 19, we shall see that aromatic and aliphatic hydrocarbons can be regarded as the basic framework for all organic compounds. ALIPHATIC HYDROCARBONS The different types of aliphatic hydrocarbons are distinguished by the type of bonding between the carbon atoms, such as whether all the bonds are single or whether some are multiple. The types of bonds determine the types of reactions that the hydrocarbon can undergo. H3C CH2 CH2 CH3 CH2 2 Pentane, C5H12 CH2CH3 1 Ethylbenzene, C6H5CH2CH3 ALIPHATIC HYDROCARBONS 18.1 Types of Aliphatic Hydrocarbons 18.2 Isomers 18.3 Properties of Alkanes 18.4 Alkane Substitution Reactions 18.5 Properties of Alkenes 18.6 Electrophilic Addition AROMATIC COMPOUNDS 18.7 Nomenclature of Arenes 18.8 Electrophilic Substitution IMPACT ON TECHNOLOGY: FUELS 18.9 Gasoline 18.10 Coal 735 Chapter 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS 18.1 Types of Aliphatic Hydrocarbons A saturated hydrocarbon is an aliphatic hydrocarbon with no multiple carbon–carbon bonds; an unsaturated hydrocarbon has one or more double or triple carbon–carbon bonds. More hydrogen atoms can be added to compounds in which there are multiple bonds, but compounds with only single bonds are “saturated” with hydrogen. Compound (3) is saturated; compounds (4) and (5) are unsaturated. 736 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS H3C CH2 CH2 CH2 CH3CH2 3 Hexane, C6H14 H3C CH2 CH2 CH CH3CH 4 2-Hexene, C6H12 H3C CH2 CH CH2 CH3CH 5 3-Hexene, C6H12 Because many organic molecules are very complicated, we need a simple way to represent their structures. It is often sufficient to give a condensed structural formula, which shows how the atoms are grouped together (see Section C). For instance, we write CH3CH2CH2CH3 for butane and CH3CH(CH3)CH3 for methylpropane. The parentheses around the CH3 group show that it is attached to the carbon atom on its left (or, if the formula begins with the parenthetical group, the carbon atom on its right). When several groups of atoms are repeated, we collect them together; so we can write butane as CH3(CH2)2CH3 and methylpropane as (CH3)3CH. A line structure (introduced in Section C) represents a chain of carbon atoms as a zigzag line. The end of each short line in the zigzag represents a carbon atom. Because carbon nearly always has a valence of 4 in organic compounds, we do not need to show the CßH bonds. We just fill in the correct number of hydrogen atoms mentally, as we see for methylbutane (6), isoprene (7), and propyne (8). As explained in Section 2.7, a benzene ring is represented by a circle inside a hexagon, and we need to remember that one hydrogen atom is attached to each carbon atom. H3C CH2 CH3 CH3 CH 6 Methylbutane, (CH3)2CHCH2CH3 H2C H3C CH2 7 Isoprene, CH2ϭC(CH3)CHϭCH2 C C H H3C C CH 8 Propyne, CH3C CHϭϭ Self-Test 18.1A Draw (a) the line structure of aspirin (9a) and (b) the structural formula for CH3(CH2)2C(CH3)2CH2C(CH3)3. [Answer: (a) (9b); (b) (10)] 9 Acetylsalicylic acid (aspirin) OH (b) O O O OH (a) O O C O C H3C H C C C C C CH3 CH3 CH3 CH3 CH3 CH3H H H H H 10 Self-Test 18.1B Write (a) the structural formula of carvone (11a) and (b) the condensed structural formula for (11b). 18.1 TYPES OF ALIPHATIC HYDROCARBONS 737 11a Carvone O H3C C C C C C CH2CH3 H H CH3 H HH CH3 H H H 11b 12 Methane, CH4 Saturated hydrocarbons are called alkanes. As we saw in Section 3.5, the bonds to each carbon atom in an alkane are single bonds that lie in a tetrahedral arrangement, with sp3 hybridization. The simplest alkane is methane, CH4 (12). The formulas of other alkanes are derived from CH4 by inserting CH2 groups between pairs of atoms. Although we write alkanes in two dimensions as linear structures with 90° angles, as in (11b), they really consist of tetrahedral arrangements of bonds at each carbon atom. Moreover, because all the C∫C bonds are single, the different parts of an alkane molecule can rotate relative to each other. In liquids and gases, the chains of atoms in an alkane molecule are in constant motion, at some instants rolled up into a ball (13) and at others stretched out into a zigzag (14). 14 Decane, C10H2213 Decane, C10H22 To name an alkane in which the carbon atoms form a single chain, we combine a prefix denoting the number of carbon atoms with the suffix -ane (Table 18.1). For example, CH3∫CH3 (more simply, CH3CH3) is ethane and CH3∫CH2∫CH3 (that is, CH3CH2CH3) is propane. Cyclopropane, C3H6 (15), and cyclohexane, C6H12 (16), are cycloalkanes, alkanes that contain rings of carbon atoms. With C4H10, we find another reason for the variety of compounds that carbon can form: the same atoms can bond together in different arrangements. Four carbon atoms can link together in a chain to form butane (17) or in a Y-shape to form methylpropane (18). As we saw in Section 16.7, different compounds with the same molecular formula are called isomers. Thus, butane and methylpropane are isomers with the same molecular formula, C4H10. 15 Cyclopropane, C3H6 16 Cyclohexane, C6H12 17 Butane, C4H10 18 Methylpropane, C4H10 The name “isomer” comes from the Greek words for “equal parts,” suggesting that isomers are built from the same kit of parts. The simplest unsaturated hydrocarbon is ethene, C2H4 or H2C¢CH2, commonly called ethylene (19). It is the parent of the alkenes, a series of compounds with formulas derived from H2C¢CH2 by inserting CH2 groups. For example, the next member of the family is propene, H∫CH2∫CH¢CH2 (more simply, CH3CH¢CH2). The name of an alkene is the same as the name of the corresponding alkane, except that it ends in -ene. The location of the double bond is specified by numbering the carbon atoms in the chain and writing the lower of the two numbers of the carbon atoms joined by the double bond. Thus, CH3CH2CH¢CH2 is 1-butene and CH3CH¢CHCH3 is 2-butene (see Toolbox 18.1). The term alkene also includes hydrocarbons with more than one double bond, as in CH2¢CH∫CH¢CH2, 1,3-butadiene. The alkynes are hydrocarbons that have at least one carbon–carbon triple bond. The simplest is ethyne, HCΩCH, which is commonly called acetylene (20). Alkynes are named like the alkenes but with the suffix -yne. 738 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS TOOLBOX 18.1 HOW TO NAME ALIPHATIC HYDROCARBONS CONCEPTUAL BASIS Because the types of carbon–carbon bonds present in the molecule tend to dominate its properties, an aliphatic hydrocarbon is first classified as an alkane, alkene, or alkyne. Then the longest chain of carbon atoms is used to form the “root” of the name. Other hydrocarbon groups attached to the longest chain are named as side chains. PROCEDURE The following rules for naming hydrocarbons have been adopted by the International Union for Pure and Applied Chemistry (IUPAC). Alkanes The names of straight-chain alkanes are given in Table 18.1: they all end in -ane. Name a hydrocarbon side chain as a substituent by changing the ending -ane to -yl (as in the last two columns in Table 18.1). Example: CH3CH2ß is the ethyl group The names of branched-chain hydrocarbons and hydrocarbon derivatives are based on the name of the longest continuous carbon chain in the molecule (which might not be shown in a horizontal line). Example: A cyclic (ring) hydrocarbon is designated by the prefix cyclo-. Example: To indicate the position of a branch or substituent, the carbon atoms in the longest chain are numbered consecutively from one end to the other, starting at the end that will give the lower number(s) to the substituent(s). Examples: CH3CH2CH2CHCH2CH3 CH2CH3 3-Ethylhexane CH3C(CH3)2CH2CH3 2,2-Dimethylbutane 1 1 2 2 3 3 4 4 6 6 5 5 4 4 3 3 2 2 1 1 H2C CH2 CH2 is cyclopropane CH3 CH3CH CH2 CH3 is a methylbutane 19 Ethene, C2H4 TABLE 18.1 Alkane Nomenclature Number of Name of Name of carbon atoms Formula alkane alkyl group Formula 1 CH4 methane methyl CH3∫ 2 CH3CH3 ethane ethyl CH3CH2∫ 3 CH3CH2CH3 propane propyl CH3CH2CH2∫ 4 CH3(CH2)2CH3 butane butyl CH3(CH2)2CH2∫ 5 CH3(CH2)3CH3 pentane pentyl CH3(CH2)3CH2∫ 6 CH3(CH2)4CH3 hexane hexyl CH3(CH2)4CH2∫ 7 CH3(CH2)5CH3 heptane heptyl CH3(CH2)5CH2∫ 8 CH3(CH2)6CH3 octane octyl CH3(CH2)6CH2∫ 9 CH3(CH2)7CH3 nonane nonyl CH3(CH2)7CH2∫ 10 CH3(CH2)8CH3 decane decyl CH3(CH2)8CH2∫ 11 CH3(CH2)9CH3 undecane undecyl CH3(CH2)9CH2∫ 12 CH3(CH2)10CH3 dodecane dodecyl CH3(CH2)10CH2∫ 20 Ethyne, C2H2 CH3 CH3 CH3CH3 C CH2H3C –CH 21 18.1 TYPES OF ALIPHATIC HYDROCARBONS 739 EXAMPLE 18.1 Naming alkanes and cycloalkanes (a) Name the compound shown as (21) and (b) write the structural formula of 2-ethyl-1,1- dimethylcyclohexane. PLAN Use the procedure in Toolbox 18.1. SOLVE (a) Count carbon atoms in the longest chain. The longest carbon chain (in red) of (21) has 5 carbon atoms. the molecule is a substituted pentane. CH3 CH3 CH3CH3 C CH2H3C CH Identify and count substituents. There are 3 methyl groups (CH3∫) on the longest chain. The molecule is a trimethylpentane. CH3 CH3 CH3CH3 C CH2H3C CH Number the backbone carbon atoms to give the lowest numbers to the substituents. 2,2,4-trimethylpentane CH3 CH3 CH3CH3 C CH2H3C CH 5 4321 (b) Draw the longest chain of carbon atoms first. “Cyclohexane” tells us that the molecule has a ring of 6 carbon atoms. C C C C C C Number the carbon atoms and add the substituents according to the numbers given in the name. Add 2 methyl groups to one carbon atom, which becomes carbon atom 1. Then add an ethyl group to carbon atom 2. H3C CH3 CH2CH3C 1 2 C CH C C C The prefixes di-, tri-, tetra-, penta-, hexa-, and so on, indicate how many of each substituent are in the molecule. Numbers set off by hyphens specify to which carbon atoms the groups are attached. Examples: The substituents are listed in alphabetical order (disregarding the Greek prefixes) and attached to the root name. The names of substituents other than hydrocarbon groups are discussed more fully in Chapter 19 (see Toolbox 19.1). Example 18.1 demonstrates how to name alkanes. Alkenes and alkynes Double bonds in hydrocarbons are indicated by changing the suffix -ane to -ene, and triple bonds are indicated by changing the suffix to -yne. The position of the multiple bond is given by the number of the first (lower-numbered) carbon atom involved in the multiple bond. If more than one multiple bond of the same type is present, the number of these bonds is indicated by a Greek prefix. Then follow the rules for naming alkanes. Examples: CH3∫CH2∫CH2∫CΩCH 1-Pentyne CH3∫CH2∫CH¢CH∫CH3 2-Pentene CH2¢CH∫CH2∫CH¢CH2 1,4-Pentadiene When numbering atoms in the chain, the lowest numbers are given preferentially to (a) groups of atoms named by suffixes (see Toolbox 19.1), (b) double bonds, (c) triple bonds, and (d) groups named by prefixes. Example 18.2 illustrates how to name alkenes. 1-Ethyl-2-methylcyclopentane C CH2C H2C CH2 CH3 H CH2CH3 H1 2 34 5 1 2 34 5H3C CH3C C CH3 CH3 CH3 H 1 2 3 4 2,2,3-Trimethylbutane Self-Test 18.2A (a) Name the compound shown as (22) and (b) write the structural formula of 5-ethyl-2,2-dimethyloctane. [Answer: (a) 3-Ethyl-4-methylhexane; (b) (23)] 740 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS Add hydrogen atoms as needed to give each carbon atom a valence of four. H3C CH3 CH2CH3C H2C CH H2C CH2 CH2 EXAMPLE 18.2 Naming alkenes (a) Name the alkene CH3CH2CH¢CH2 and (b) write the condensed structural formula for 5-methyl-1,3-hexadiene. PLAN Use the procedure in Toolbox 18.1. SOLVE (a) From Toolbox 18.1, CH3CH2CH¢CH2 is 1-butene (not 3-butene). (b) 5-Methyl-1,3-hexadiene has two double bonds, at the first and third carbon atoms, with a methyl group on the fifth carbon atom: CH2¢CHCH¢CHCH(CH3)CH3. Self-Test 18.3A (a) Name the alkene (CH3)2CHCH¢CH2 and (b) write the condensed structural formula for 2-methylpropene. [Answer: (a) 3-Methyl-1-butene; (b) CH2¢C(CH3)2] Self-Test 18.3B (a) Name the alkene (CH3CH2)2CHCH¢CHCH3 and (b) write the structural formula for cyclopropene. Saturated hydrocarbons have only single bonds; unsaturated hydrocarbons have one or more multiple bonds. Alkanes are saturated hydrocarbons. Alkenes and alkynes are unsaturated hydrocarbons: the former have carbon–carbon double bonds and the latter have triple bonds. 18.2 Isomers Figure 18.1 summarizes the types of isomerism that are found in organic compounds. Molecules that are structural isomers are built from the same atoms, but the atoms are connected differently; that is, the molecules have a different connectivity. For example, we can insert a ∫CH2∫ group into the C3H8 molecule in two different ways to give two different compounds with the formula C4H10: Although the ∫CH2∫ group could be inserted in other places, the free rotation about single C–C bonds in hydrocarbons allows the resulting molecules to be twisted into one or the other of these two isomers. Both compounds are gases, but butane (24) condenses at Ϫ1°C, whereas methylpropane (25) condenses at Ϫ12°C. Two molecules that differ only by rotation about one or more bonds may look different on paper, but they are not isomers of each other; they are different conformations of the same molecule. Example 18.3 illustrates how to tell if two molecules are different isomers or different conformations of the same isomer. 22 CH2 H3C H3C CH CH CH2 CH2 CH3 CH3 23 C CH2 CH3 CH3 CH2 CH2CH3CH3 CH2 CH2CHH3C FIGURE 18.1 A summary of the types of isomerism in organic compounds. Same atoms, different partners Structural isomers Optical isomers Geometrical isomers Same atoms, same partners different arrangements in space Same atoms, same partners; nonsuperimposable mirror images Self-Test 18.2B Name the compound (CH3)2CHCH2CH(CH2CH3)2 and write the structural formula of 3,3,5-triethylheptane. 18.2 ISOMERS 741 EXAMPLE 18.3 Writing the formulas of structural isomers Draw two-dimensional structural formulas for all the isomeric alkanes of formula C5H12. PLAN Isomers cannot be changed into one another simply by rotating either the entire formula or parts of the formula on the page. One approach is to insert ∫CH2∫ groups into different parts of the formulas of the two C4H8 molecules given earlier (as 24 and 25), then discard formulas that repeat those already obtained. It is often easier to identify different conformations of the same isomer by building molecular models that allow rotation about single bonds. SOLVE From butane, we can form C H H H H H C C H H H C H C H H H (b) C H H H H H H H H HCH H H C C C (a) From methylpropane, we can form Molecules (b) and (c) are identical. The atoms of molecule (e) are joined together in the same arrangement as that in (b) and (c), but the structure looks different because it has been rotated 180° and twisted; so (b), (c), and (e) are the same. There are therefore only three distinct isomers with formula C5H12: (a), (b), and (d). Self-Test 18.4A Write the condensed structural formulas for the five isomeric alkanes of molecular formula C6H14. [Answer: CH3(CH2)4CH3; CH3(CH2)2CH(CH3)CH3; CH3CH2CH(CH3)CH2CH3; CH3CH2C(CH3)2CH3; CH3CH(CH3)CH(CH3)CH3] Self-Test 18.4B Halogen atoms can substitute for hydrogen atoms in hydrocarbons. Write the condensed structural formulas for the four isomers with the molecular formula C4H9Br. H H H H H C C C H H C H H CH H H (d) C H H H H H C C H H H C H C H H H (c) H H H H HH C C C H C H H C H H H (e) H3C CH2 CH3 CH2 24 Butane, C4H10 H3C CH CH3 25 Methylpropane, C4H10 CH3 In stereoisomers, the molecules have the same connectivity but the atoms are arranged differently in space. One class of stereoisomers are geometrical isomers, in which atoms have different arrangements on either side of a double bond or above and below the ring of a cycloalkane or cycloalkene (Fig. 18.2). Geometrical isomers of organic molecules are distinguished by the prefixes cis- and trans-. For example, in the upper part of the illustration, we can see that there are two different 2-butenes: in the cis isomer both methyl groups are on the same side of the double bond and in the trans isomer the methyl groups are across the double bond. Geometrical isomers have the same molecular formula and structural formula but different properties. Self-Test 18.5A Identify (26a) and (26b) as cis or trans. [Answer: (26a) is trans-2-pentene; (26b) is cis-2-pentene] Self-Test 18.5B Identify (27a) and (27b) as cis or trans. Another type of stereoisomerism is optical isomerism. Optical isomers are each other’s nonsuperimposable mirror images. To understand this definition, consider 3-methylhexane, CH3CH2CH(CH3)CH2CH2CH3, and its mirror image (Fig. 18.3). No matter how we twist and turn the molecules, we cannot superimpose the mirrorimage molecule on the original molecule. It is like trying to superimpose your right hand on your left hand. A chiral molecule, such as 3-methylhexane, is a molecule that is not identical to its mirror image. A chiral molecule and its mirror image form a pair of enantiomers, or mirror-image isomers. Although they have the same composition, the two enantiomers are, in fact, two distinct compounds. In organic compounds, optical isomers occur whenever four different groups are attached to the same carbon atom, which is then called a “chiral carbon atom.” The alkane 3-methylpentane (28), does not have a chiral carbon atom. It is an example of an achiral molecule, a molecule that can be superimposed on its mirror image. Enantiomers have identical chemical properties, except when they react with other chiral compounds. Because many biochemical substances are chiral, one consequence of this difference in reactivity is that enantiomers may have different odors and pharmacological activities. To be effective, the molecule has to fit into a cavity, or slot, of a certain shape, either in an odor receptor in the nose or in an enzyme. Only one member of the enantiomeric pair may be able to fit. Enantiomers differ in one physical property: chiral molecules display optical activity, the ability to rotate the plane of polarization of light (Section 16.7 and Box 16.2). If a chiral molecule rotates the plane of polarization clockwise, then its mirror-image partner rotates it through the same angle in the opposite direction. Often organic compounds synthesized in the laboratory are racemic mixtures, or mixtures of enantiomers in equal proportions (Section 16.7). In contrast, reactions in living cells commonly lead to only one enantiomer. It is a remarkable feature of nature that almost all naturally occurring amino acids in animals have the same handedness. 742 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS FIGURE 18.2 Two pairs of geometrical isomers. In geometrical isomerism two groups take different positions across a double bond, as in part (a); or different positions above and below a ring, as in part (b). Note that the neighbors of each atom in a pair of isomers are the same, but the arrangement of the atoms in space is different. (The compound in part (a) is 2-butene when the green sphere is CH3 and the white sphere is H.) (a) (b) cis trans cis trans EXAMPLE 18.4 Deciding whether a compound is chiral A bromoalkane is formed from an alkane when a bromine atom replaces a hydrogen atom. Decide whether the bromoalkanes (a) CH3CH2CHBrCH3 and (b) CH3CHBrCH3 are chiral. PLAN Identify carbon atoms as chiral if they have four different groups attached. 26 (a) (b) 27 (a) (b) 28 3-Methylpentane, C6H14 FIGURE 18.3 The molecule of 3-methylhexane on the right is the mirror image of the one on the left. Each group is represented by a sphere of a different color. The molecule on the left cannot be superimposed on the one on the right, and so these two molecules are distinct optical isomers. CH3 H CH3CH2 CH3CH2CH2 CH3CH2CH2 CH3CH2 H3 CH3 H 18.3 PROPERTIES OF ALKANES 743 SOLUTION A note on good practice: Dashed and solid wedge-shaped bonds are commonly used when displaying organic structures to convey a sense of the three-dimensional shapes. The dashed wedge-shaped bonds go into the page and the solid wedge-shaped bonds come toward us. The thin solid lines are in the plane of the paper. Self-Test 18.6A A chlorofluorocarbon molecule contains Cl and F atoms as well as C and H. Which of the following chlorofluorocarbons is chiral: (a) CH3CF2Cl; (b) CH3CHFCl; (c) CH2FCl? [Answer: (b)] Self-Test 18.6B In an alcohol, an ßOH group is attached to a C atom. Which of the following alcohols is chiral: (a) CH3CH2OH; (b) CH3CH(OH)CH3; (c) CH3CH(OH)CH2CH3? Structural isomers have identical molecular formulas, but their atoms are linked to different neighbors. Geometrical isomers have the same molecular and structural formulas but different arrangements in space. Molecules with four different groups attached to a single carbon atom are chiral; they are optical isomers. 18.3 Properties of Alkanes The electronegativities of carbon and hydrogen (2.6 and 2.2, respectively) are so similar and rotation about bonds so free that hydrocarbon molecules are best regarded as nonpolar. The dominant interaction between alkane molecules is therefore the London force (Section 5.4). Because the strength of this interaction increases with the number of electrons in the molecule, we can expect the alkanes in petroleum, their major source, to become less volatile with increasing molar mass and therefore to be separable by fractional distillation, as described in Section 9.19 (Fig. 18.4). The lightest members, methane through butane, are gases at room temperature. Pentane is a volatile liquid, and hexane through undecane (C11H24) are moderately volatile liquids that are present in gasoline, which is discussed further in Section 18.9. All alkanes are insoluble in water. Because their densities are lower than that of water, they float on the surface of water. Even a small oil spill at sea can form an organic layer on the surface of the ocean and spread over a huge area. Thinking point: How could you estimate the area that 1 L of gasoline might spread over on water? Alkanes with long, unbranched chains tend to have higher melting points, boiling points, and enthalpies of vaporization than those of their branched isomers. The difference arises because, compared with unbranched molecules, the atoms of neighboring branched molecules cannot get as close together (Fig. 18.5). As a result, molecules with branched chains have weaker intermolecular forces than their unbranched isomers. C* H CH2CH3 CH3 Br Draw the compounds. Mark carbon atoms as chiral (*) if they have four different groups attached. (a) The C atom marked * is attached to four different groups and hence is chiral; therefore the molecule is not superimposable on its mirror image. The molecule is chiral. (b) No atom is chiral. The molecule is superimposable on its mirror image. The molecule is achiral. C H CH3 CH3 Br (a) CH3CH2CHBrCH3 (b) CH3CHBrCH3 FIGURE 18.4 The melting and boiling points of the unbranched alkanes from CH4 to C16H34. −200 −100 0 100 200 300 1 4 8 12 16 Number of carbon atoms Temperature(°C) Boiling point Melting point Self-Test 18.7A Which compound has the higher boiling point: (a) CH3CH2CH2CH2CH3 or (b) (CH3)2CHCH2CH3? Why? [Answer: (a), because it is not branched and so has stronger London forces.] Self-Test 18.7B Which compound has the higher boiling point: (a) CH3CH2CH2CH2CH3 or (b) CH3CH2CH2CH3? Why? The alkanes were once called the paraffins, from Latin words meaning “little affinity.” As this name suggests, they are not very reactive. They are unaffected by concentrated sulfuric acid, by boiling nitric acid, by strong oxidizing agents such as potassium permanganate, and by boiling aqueous sodium hydroxide. One reason for their resistance to chemical onslaught is thermodynamic: the C–C and C∫H bonds are strong (their mean bond enthalpies are 348 kJиmolϪ1 and 412 kJиmolϪ1 , respectively), and so there is little energy advantage in replacing them with most other bonds. The most notable exceptions are C¢O (743 kJиmolϪ1 ), CßO (360 kJиmolϪ1 ), and CßF (484 kJиmolϪ1 ) bonds. In addition to the catalyzed reactions used in the refining of petroleum (see Sections 18.5 and 18.9), alkanes undergo two common reactions: oxidation and substitution (Section 18.4). The alkanes are commonly used as fuels, because their combustion to carbon dioxide and water is highly exothermic (Section 7.17): CH4(g) ϩ 2 O2(g) CO2(g) ϩ 2 H2O(g) ⌬H° ϭ Ϫ890 kJ In this reaction, the strong carbon–hydrogen bonds are replaced by the even stronger OßH bonds (463 kJиmolϪ1 ), and the oxygen–oxygen bond (496 kJиmolϪ1 ) is replaced by two very strong C¢O bonds. The excess energy is given off as heat. The strength of the London forces between alkane molecules increases as the molar mass of the molecules increases; hydrocarbons with unbranched chains pack together more closely than their branched isomers and so it takes more energy to separate their molecules. Alkanes are not very reactive, but they do undergo oxidation (combustion) and substitution reactions. 18.4 Alkane Substitution Reactions Alkanes are used as the raw materials for the synthesis of many more reactive compounds. Starting with alkanes obtained from the refining of petroleum, organic chemists introduce reactive groups of atoms into the molecules in the process called functionalization. The functionalization of alkanes can be achieved by a substitution reaction, a reaction in which an atom or group of atoms replaces an atom (in alkanes, a hydrogen atom) in the original molecule (Fig. 18.6). An example of a substitution reaction is that between methane and chlorine. A mixture of these two gases survives indefinitely in the dark but, when exposed to ultraviolet radiation or heated to more than 300°C, the gases react explosively: CH4(g) ϩ Cl2(g) ∫∫∫∫∫∫B CH3Cl(g) ϩ HCl(g) Chloromethane (CH3Cl) is only one of the products; dichloromethane (CH2Cl2), trichloromethane (CHCl3), and tetrachloromethane (CCl4) also form, especially at high concentrations of chlorine. ¡ 744 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS (b) (a) FIGURE 18.5 (a) The atoms in neighboring straight-chain alkanes, represented by the tubelike structures, can lie close together. (b) Fewer of the atoms of neighboring branched alkane molecules can get so close together overall, and so the London forces are weaker and branched alkanes are more volatile. Animation 18.5 light or heat Substitution FIGURE 18.6 In an alkane substitution reaction, an incoming atom or group of atoms (represented by the red sphere) replaces a hydrogen atom in the alkane molecule. The results of kinetic studies suggest that alkane substitution reactions typically proceed by a radical chain mechanism (Section 14.9). The initiation step in the chlorination of methane is the dissociation of chlorine: Cl2 ∫∫∫∫B Clи ϩ Clи Chlorine atoms (each of which has one unpaired electron) are highly reactive; they attack methane molecules and extract a hydrogen atom, leaving a methyl radical behind: Clи ϩ CH4 HCl ϩ иCH3 Recall from Section 2.9 that most radicals are very reactive. Because one of the products is another radical, this reaction is a propagation step (a step in which one reactive radical intermediate produces another). In a second propagation step, the methyl radical may react with a chlorine molecule: Cl2 ϩ иCH3 CH3Cl ϩ Clи A termination step is reached when two radicals combine to form a nonradical product, as in Clи ϩ иCl Cl2 The product of substitution reactions of alkanes with the halogens is typically a complex mixture of haloalkanes (halogenated alkanes). One way to limit the production of the more highly substituted alkanes is to use a large excess of the alkane; then most reactions take place with the original hydrocarbon rather than with any haloalkanes produced in the reaction. Alkane substitution takes place by a radical chain mechanism. 18.5 Properties of Alkenes The carbon–carbon double bond in alkenes is more reactive than carbon–carbon single bonds and gives alkenes their characteristic properties. As we saw in Section 3.4, a double bond consists of a ␴-bond and a ␲-bond. Each carbon atom in a double bond is sp2 hybridized and uses the three hybrid orbitals to form three ␴-bonds. The unhybridized p-orbitals on each carbon atom overlap each other and form a ␲-bond. As we saw in Section 3.7, although a double carbon–carbon bond is stronger than a single carbon–carbon bond, the carbon–carbon ␲-bond is relatively weak because the overlap responsible for the formation of the ␲-bond is less extensive than that responsible for the formation of the ␴-bond and the enhanced electron density does not lie directly between the two nuclei. A consequence of this weakness is the reaction most characteristic of alkenes, the replacement of the ␲-bond by two new ␴-bonds, which is discussed in Section 18.6. The C¢C group and all four atoms attached to it lie in the same plane and are locked into that arrangement by the resistance to twisting of the ␲-bond (Fig. 18.7). Because alkene molecules cannot roll up into a ball as compactly as alkanes or rotate into favorable positions, they cannot pack together as closely as alkanes; so alkenes have lower melting points than alkanes of similar molar mass. Most alkenes used in industry are produced during the refining of petroleum. One of the first refining steps is a reaction that converts some of the abundant alkanes into the more reactive alkenes: CH3CH3(g) ∫∫∫∫B CH2¢CH2(g) ϩ H2(g) This step is an example of an elimination reaction, a reaction in which two groups or atoms on neighboring carbon atoms are removed from a molecule, leaving a multiple bond (Fig. 18.8). Another route commonly used in the laboratory to produce alkenes is the dehydrohalogenation of haloalkanes, the removal of a hydrogen atom and a halogen atom from neighboring carbon atoms: CH3CH2CHBrCH3 ϩ CH3CH2OϪ ∫∫∫∫∫∫∫B CH3CH¢CHCH3 ϩ CH3CH2OH ϩ BrϪ ¡ ¡ ¡ 18.5 PROPERTIES OF ALKENES 745 Section 3.7 describes the basis for the resistance to rotation of the C¢C bond. light or heat FIGURE 18.7 The ␲-bond (represented by the yellow electron clouds) in an alkene molecule makes the molecule resistant to twisting around a double bond. Consequently, all six atoms (the two C atoms that form the bond and the four atoms attached to them) lie in the same plane. Animation 18.7 Cr2O3 ethanol at 70°C The states of reactants and products are often not given for organic reactions, because the reaction may take place at the surface of a catalyst or it may take place in a nonaqueous solvent, as here. The reaction is another example of an elimination reaction and is carried out in hot ethanol, with sodium ethoxide, NaCH3CH2O (the ionic compound Naϩ CH3CH2OϪ ), as the reagent. Some CH3CH2CH¢CH2 is also formed in this reaction. The results of kinetic studies suggest that dehydrohalogenation occurs by the attack of the ethoxide ion (CH3CH2OϪ ) on a hydrogen atom attached to the carbon atom next to the carbon atom carrying the bromine atom. The ethoxide ion, acting as a very strong base, pulls an Hϩ ion out of the molecule to form ethanol, CH3CH2OßH, leaving the carbon atom with a lone pair of electrons and a negative charge. The carbon atom uses those electrons to form a second bond to its neighbor as the bromine atom is effectively squeezed out of the molecule as a BrϪ ion: Curved arrows like the ones here are often used to illustrate organic reaction mechanisms. They show the direction in which electron pairs move as they form new bonds. The double bonds in alkenes can be generated by elimination reactions. 18.6 Electrophilic Addition The most characteristic chemical reaction of an alkene is an addition reaction, in which atoms supplied by the reactant form ␴-bonds to the two atoms originally joined by the double bond (Fig. 18.9). In the process, the ␲-bond is lost. An example is halogenation, the addition of two halogen atoms at a double bond, as in the formation of 1,2- dichloroethane: CH2¢CH2 ϩ Cl2 CH2Cl∫CH2Cl¡ Br H CH3CH2OϪ BrϪ CH3CH2OH ϩ Br H CH3CH2O Ϫ 746 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS FIGURE 18.8 In an elimination reaction, two atoms or groups (the red and gold spheres) attached to neighboring carbon atoms are eliminated from the molecule, leaving a double bond between the two carbon atoms. Animation 18.8 Elimination FIGURE 18.9 In an addition reaction, the atoms provided by an incoming molecule form bonds to the carbon atoms originally joined by a multiple bond. Animation 18.9 Addition The addition of hydrogen chloride to give chloroethane is an example of a hydrohalogenation reaction: CH2¢CH2 ϩ HCl CH3∫CH2Cl The model that organic chemists have built of the mechanism of alkene addition reactions is quite different from that of alkane substitution reactions. The crucial difference between the two types of molecules arises from the high density of electrons in the region of the double bond (Fig. 18.10). Because electrons are negatively charged, this region represents an accumulation of negative charge that can attract a positively charged reactant. A reactant that is attracted to a region of high electron density is called an electrophile. The mechanism of alkene addition is by electrophilic attack on the carbon atoms that make up the double bond. An electrophile may be a positively charged species or it may be a species that has a partial positive charge or can acquire one in the course of the reaction. An example is the bromination of ethene. When ethene (or any other alkene) is bubbled through a solution of bromine, the solution is decolorized as the bromine reacts to form dibromoethane (this reaction is illustrated in Fig. 2.9). Bromine molecules are polarizable; and, as a Br2 molecule approaches the high electron density of an alkene double bond, a partial positive charge is induced on the Br atom closer to the double bond (Fig. 18.11). This separation of charges means that a Br2 molecule can act as an electrophile. As it moves in for the attack, the partially positively charged Br atom becomes more and more like Brϩ , and its partner becomes more like BrϪ . The bond between the two Br atoms snaps, and the Brϩ ion forms a bridge between the two carbon atoms of the alkene, giving a cyclic “bromonium ion”: Almost immediately, a BrϪ ion swoops in for the attack, attracted by the positive charge of the bromonium ion. It forms a bond to one carbon atom, and the bond from that carbon atom to the bromine atom already present breaks as the bromine atom moves onto the second carbon atom, giving 1,2-dibromoethane: With the use of a solid-state catalyst, hydrogen can be added to carbon–carbon double bonds in a hydrogenation reaction: H2(g) ϩ · · ·C¢C· · · catalyst · · ·CH∫CH· · · This reaction is used in the food industry to convert vegetable oils into shortening (Fig. 18.12). Oil and solid fat molecules both have long hydrocarbon chains, but oils have more double bonds. Because double bonds resist twisting, oil molecules do not pack together well, and so the oil is liquid at ordinary temperatures. When some of the double bonds are replaced by single bonds, the chains become much more flexible, and so the molecules pack together better and form a solid. Self-Test 18.8A Write the condensed structural formula of the product of the addition of hydrogen to 2-butene: CH3CH¢CHCH3 ϩ H2 product. [Answer: CH3CH2CH2CH3] Self-Test 18.8B Write the condensed structural formula of the compound formed by the addition of hydrogen chloride to 2-butene. The mechanism of addition to alkenes is electrophilic attack. ¡ Br ϩ Br Br BrϪ Br␦ϩ Br␦Ϫ Br BrϪ ϩ ¡ 18.6 ELECTROPHILIC ADDITION 747 FIGURE 18.10 (a) The electrostatic potential diagram for an ethane molecule: the blue regions show where the positive charge of the nuclei outweighs the negative charge of the electrons, and the red regions show where the opposite is true. (b) The electron distribution in an ethene molecule shows the negative region of charge associated with the accumulation of electrons in the region of the double bond. Animation 18.10 (a) (b) FIGURE 18.11 As a bromine molecule approaches a double bond in an alkene, the atom closer to the ethene molecule acquires a partial positive charge (the light blue region). The computation that produced this image was carried out for the point at which the bromine molecule is so close to the double bond that a carbon–bromine bond is starting to form. Br2 ␦ϩ ∫∫∫B FIGURE 18.12 When the runny oil (top) is hydrogenated, it is converted into a solid fat (bottom). Hydrogen adds to the carbon–carbon double bonds, converting them into single bonds. The resulting more flexible molecules can pack together more closely and form a solid. AROMATIC COMPOUNDS Aromatic hydrocarbons, which originally got their name from the distinctive odors many of them have, are called arenes. They all contain an aromatic ring, usually the six-membered ring of benzene, which was introduced in Sections 2.7, 3.7, and 3.12. An abundant source of arenes is coal, which is a very complex mixture of compounds, many of which consist of extensive networks containing aromatic rings (Section 18.10). 18.7 Nomenclature of Arenes The parent compound of aromatic hydrocarbons is benzene, C6H6 (29). When the benzene ring is named as a substituent, it is called the phenyl group, as in 2-phenylbutane, CH3CH(C6H5)CH2CH3. In general, aromatic hydrocarbon groups are called aryl groups. Aromatic compounds also include the fused-ring analogs of benzene, such as naphthalene, C10H8 (30), and anthracene, C14H10 (31), obtained by the distillation of coal. In an older but still widely used system of nomenclature, when there is a substituent in location 1 of a benzene ring, locations 2, 3, and 4 are denoted ortho- (abbreviated o-), meta- (m-), and para- (p-), respectively. Thus, (32) is ortho-dinitrobenzene. In systematic nomenclature, the locations of substituents on the aromatic ring are identified by numbering the carbon atoms from 1 to 6 around the ring, selecting the direction that corresponds to the lower substituent numbers. In this system, (32) is 1,2dinitrobenzene (ßNO2 is the nitro group). However, (33) is 2,4,6-trinitrophenol because the compound C6H5OH is phenol, and so the carbon atom attached to the ßOH group is numbered 1. 748 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS EXAMPLE 18.5 Sample Exercise: Naming an aromatic compound Name (a) compound (34) and the three dimethylbenzenes (xylenes), in which the second methyl group is on carbon atom (b) 2; (c) 3; (d) 4. PLAN Name the compounds by counting around the ring in the direction that gives the smallest numbers to the substituents. SOLVE (a) 1-Ethyl-3-methylbenzene; (b)1,2-dimethylbenzene (o-xylene); (c) 1,3-dimethylbenzene (m-xylene); (d) 1,4-dimethylbenzene (p-xylene) CH2CH3 CH3 34 OH NO2 O2N NO2 1 2 3 4 5 6 33 2,4,6-Trinitrophenol NO2 NO2 1 2 3 4 5 6 32 1,2-Dinitrobenzene 31 Anthracene, C14H10 30 Naphthalene, C10H8 29 Benzene, C6H6 CH2CH3 1 2 3 4 5 6 CH3 (a) CH3 1 2 CH3 CH3 1 3 CH3 CH3 CH3 1 4 (b) (c) (d) Self-Test 18.9A Name compound (35). [Answer: 1-Ethyl-3-propylbenzene] Self-Test 18.9B Name compound (36). Aromatic compounds are named by giving the substituents on the benzene ring the lowest numbers. When the benzene ring is itself named as a substituent, it is called a phenyl group. CH2CH2CH3 CH2CH3 35 CH2CH3 CH2CH2CH3 CH3H3C 36 18.8 ELECTROPHILIC SUBSTITUTION 749 18.8 Electrophilic Substitution Arenes are unsaturated but, unlike the alkenes, they are not very reactive. Whereas alkenes commonly take part in addition reactions, arenes undergo predominantly substitution reactions, with the ␲-bonds of the ring left intact. For example, bromine immediately adds to a double bond of an alkene but reacts with benzene only in the presence of a catalyst—typically, iron(III) bromide—and it does not affect the bonding in the ring. Instead, one of the bromine atoms replaces a hydrogen atom to give bromobenzene, C6H5Br: C6H6 ϩ Br2 ∫∫∫∫B C6H5Br ϩ HBr The mechanism of substitution on an electron-rich benzene ring is electrophilic substitution, electrophilic attack on an atom and the replacement of one atom by another or by a group of atoms. The fact that substitution occurs rather than addition to the double bonds can be traced to the stability of the delocalized ␲-electrons in the ring. Delocalization gives the electrons such low energy—that is, they are bound so tightly— that they are unavailable for forming new ␴-bonds (see Sections 2.7 and 3.12). The bromination of benzene illustrates the difference between electrophilic addition to alkenes and electrophilic substitution of arenes. First, to achieve the bromination of benzene it is necessary to use a catalyst, such as iron(III) bromide. The catalyst acts as a Lewis acid, binding to the bromine molecule (a Lewis base) and ensuring that the outer bromine atom has a pronounced partial positive charge: :BrßBr: ϩ FeBr3 ␦ϩ :BrßBrßFeBr3 ␦Ϫ (For simplicity, we show only one lone pair on each bromine atom.) The outer bromine atom of the complex is now primed to act as a strong electrophile (Fig. 18.13). Electrophilic substitution begins like electrophilic addition, with an attack on a region of high electron density to form a positively charged intermediate: However, because the delocalized ␲-electrons constitute such a stable arrangement, the hydrogen atom shown can be pulled from the ring as Hϩ by a bromine atom in the FeBr4 Ϫ complex. Delocalization is regained and the products are C6H5Br and HBr: The iron(III) bromide catalyst is released in this step and is free to activate another bromine molecule. One of the most extensively studied examples of electrophilic substitution is the nitration of benzene. A mixture of nitric acid and concentrated sulfuric acid converts benzene slowly into nitrobenzene. The actual nitrating agent is the electrophile NO2 ϩ (the nitronium ion, ONOϩ ), a linear triatomic ion: HNO3 ϩ H2SO4 NO2 ϩ ϩ HSO4 Ϫ ϩ H2O The accepted mechanism of the reaction is NO2 ϩ NO2 NO2 ϩ ϩ Hϩ H ¡ BrH Br ϩ Br FeBr3 Ϫ ϩ HBr ϩ FeBr3 H H Br ϩ ␦ϩ Br Br ␦Ϫ FeBr3 ϩ FeBr4 Ϫ ␦Ϫ ¡ FIGURE 18.13 The catalyst FeBr3 acts by forming a complex with a bromine molecule. As a result, the bromine atom not directly attached to the iron atom acquires a partial positive charge (the blue region). This partial charge enhances the ability of the bromine molecule to act as an electrophile. Br Br Br Br Fe ␦ϩ Br FeBr3 In the second step, the hydrogen ion is pulled out of the ring by the HSO4 Ϫ ion acting as a Brønsted base. As in the bromination reaction, the restoration of the delocalization of the ␲-electrons facilitates the removal of the hydrogen ion. Certain groups attached to an aromatic ring can donate electrons into its delocalized molecular orbitals. Examples of these electron-donating substituents include ßNH2 and ßOH. Electrophilic substitution of benzene is much faster when an electrondonating substituent is present. For example, the nitration of phenol, C6H5OH, proceeds so quickly that it requires no catalyst. Moreover, when the products are analyzed, the only products are found to be 2-nitrophenol (ortho-nitrophenol, 37) and 4nitrophenol (para-nitrophenol, 38). Why is the meta position such an unattractive location for substitution, and why does phenol react much faster than benzene? An electrophile is attracted to regions of high electron density. Therefore, to account for the fast reaction of phenol, the electron density must be greater in the ring when the electron-donating ßOH substituent is present. To account for the dominance of the ortho and para products, electron density must be relatively high at the ortho and para positions. A molecular orbital calculation, such as those described in Major Technique 5, shows that there is indeed a higher concentration of electrons in the ring in phenol, especially at the ortho and para positions, than in benzene, largely because the O atom has lone pairs of electrons that can participate in ␲-bonding with the carbon atoms (Fig. 18.14). Long before their theories were supported by computations, organic chemists found a way to use resonance structures to explain the product distribution in electrophilic substitution. Thus, the Lewis structure for phenol is regarded as a resonance hybrid of the following structures: The curved arrows show how one resonance structure relates to another. Notice that the formal negative charge is located on the ortho and para positions, exactly where reaction takes place most quickly. Other ortho- and para-directing groups include ßNH2, ßCl, and ßBr. All have an atom with a lone pair of electrons next to the ring, and all accelerate reaction. Thinking point: Can you suggest a molecular orbital explanation of this directing effect? We have seen how an ßOH group can accelerate a reaction. Are there substituents that can slow down the electrophilic substitution of benzene? One way to reduce the electron density in the benzene ring and to make it less attractive to electrophiles is to substitute a highly electronegative substituent, which can withdraw electrons partially, for a hydrogen atom on the benzene ring. Alternatively, we can use a substituent that removes electrons by resonance. A number of substituents, such as the carboxyl group (ßCOOH), have both effects. For instance, the nitration of benzoic acid, C6H5COOH, is found to be much slower than the nitration of benzene; moreover, most of the product is the meta nitro compound: COOH NO2 COOH NO2 COOH NO2 COOH ϩ ϩ 18.5% 8.00% 1.5% ϩ HHHH Ϫ Ϫ Ϫ O ϩ O ϩ OO 750 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS OH NO2 37 o-Nitrophenol OH NO2 38 p-Nitrophenol FIGURE 18.14 The presence of an –OH group in phenol alters the distribution of electrons in the benzene ring. The blue regions denote relatively positively charged parts of the molecule and the green, yellow, and red regions denote progressively more negatively charged regions. Note how the electron-rich green regions spread over the carbon and hydrogen atoms much more in phenol than in benzene; so these atoms are more susceptible to electrophilic attack. A more detailed analysis shows that the ortho and para carbon atoms have the greatest accumulation of negative charge. Benzene Phenol O The electronegative O atoms of the carboxylic acid group withdraw electrons from the whole ring, thereby reducing its overall electron density. Moreover, resonance preferentially removes electrons from the ortho and para positions. To focus on the essentials, only the lone pairs of electrons involved in resonance are shown: As a result of both effects, the reaction rate is lowered, especially at the ortho and para positions, and the meta position is left as the most likely place for attack. Other meta-directing electron-withdrawing substituents include ßNO2, –CF3, and ßCΩN. Notice that none of these substituents has a lone pair of electrons on the atom next to the ring. Aromatic rings are much less reactive than their double-bond character would suggest; they commonly undergo substitution rather than addition. Electrophilic substitution of benzene with electron-donating substituents is accelerated and takes place at the ortho and para positions preferentially. Electrophilic substitution of benzene with electron-withdrawing substituents takes place at a reduced rate and primarily at the meta positions. IMPACT ON TECHNOLOGY: FUELS As we have seen, the primary sources of hydrocarbons are the fossil fuels petroleum and coal. Aliphatic hydrocarbons are obtained primarily from petroleum, which is a mixture of aliphatic and aromatic hydrocarbons, together with some organic compounds containing sulfur and nitrogen (Fig. 18.15). Coal is another major source of aromatic hydrocarbons. 18.9 Gasoline The hydrocarbons in petroleum are separated by fractional distillation (Table 18.2). Kerosene, a fuel used in jet and diesel engines, contains a number of alkanes having formulas in the range C10 to C16. Lubricating oils are mixtures in the range C17 to C22. The heavier members of the series include the paraffin waxes and asphalt. However, the primary use of petroleum is for gasoline production, and the gasoline fraction (from C5 to C11 hydrocarbons) is too small to meet the demand. In addition, the straight-chain alkanes make poor gasoline. Therefore, petroleum is refined to increase both the quantity and the quality of gasoline. The quantity of gasoline that can be obtained from petroleum is increased by cracking, or breaking down long hydrocarbon chains, and by alkylation, or combining small molecules to make larger ones. In cracking, the less volatile fractions are exposed to high temperatures in the presence of a catalyst, often a modified zeolite (see Section 14.15). For example, fuel oil can be converted into a mixture of octene and octane isomers: C16H34 ⌬, catalyst C8H16ϩ C8H18 Alkylation also requires a catalyst to achieve the desired chain length. Octane, for instance, can be synthesized from a mixture of butane and butene: C4H10 ϩ C4H8 ∫∫∫∫B C8H18 Ϫ C OH C OH C OH C OH ϩ ϩ ϩ O Ϫ OOO 18.9 GASOLINE 751 FIGURE 18.15 Because fossil fuel reserves are limited, they must be extracted from wherever they are found. This platform is used to extract petroleum from beneath the ocean. The natural gas accompanying it cannot easily be transported, and so it is burned off. TABLE 18.2 Hydrocarbon Constituents of Petroleum Hydrocarbons Boiling range (°C) Fraction C1 to C4 Ϫ160 to 0 natural gas and propane C5 to C11 30 to 200 gasoline C10 to C16 180 to 400 kerosene, fuel oil C17 to C22 350 and above lubricants C23 to C34 low-melting-point solids paraffin wax C35 upward soft solids asphalt ∫∫∫∫∫B Fractional distillation is discussed in more detail in Section 9.19. catalyst The quality of gasoline, which determines how smoothly it burns, is measured by the octane rating. For example, the straight-chain molecule octane, CH3(CH2)6CH3, burns so poorly that it has an octane rating of –19, but its isomer 2,2,4-trimethylpentane, which is commonly called isooctane, has an octane rating of 100. The octane rating is improved by increasing the branching of the molecules and by introducing unsaturation and rings. In isomerization, straight-chain hydrocarbons are converted into their branched-chain isomers. For example: CH3(CH2)6CH3 AlCl3 CH3C(CH3)2CH2CH(CH3)CH3 Aromatization is the conversion of an alkane into an arene: CH3(CH2)5CH3 Al2O3, Cr2O3 CH3C6H5 ϩ 4 H2 The product of this reaction, toluene (methylbenzene), has an octane rating of 120. The quality of gasoline is also improved by the addition of ethanol, which has an octane rating of 120. The use of ethanol helps to reduce the demand for petroleum. Unlike petroleum, of which there are limited reserves on Earth, ethanol is a renewable fuel that can be regenerated every year (see Box 7.2). Petroleum consists mainly of hydrocarbons, which are separated by molar mass in fractional distillation during the refining process. 18.10 Coal As reserves of petroleum decline worldwide, interest in making better use of coal is growing. The thought of an automobile that runs on coal is strange, but the use of gasoline substitutes derived from coal is a real possibility. Unfortunately, the increased usage of coal raises environmental concerns. Coal contains a much lower ratio of hydrogen to carbon than petroleum and is harder to purify, to work, and to transport. Although both coal and petroleum contribute to the greenhouse effect, the use of coal is potentially more damaging. When it burns, coal also releases a large amount of pollution in the form of particulate matter (primarily ash) and sulfur and nitrogen oxides. Much of the research on coal is aimed at converting it into more useful fuels. Coal contains many aromatic rings (Fig. 18.16). Coal is the end product of the decay of swamp vegetation in anaerobic conditions (with a very low concentration of 752 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS ∫∫∫B ∫∫∫∫∫∫B OH OH O O O O O OS OH HHO COOH S S NH2 CH3 H N OH O S OHO OH OH FIGURE 18.16 A highly schematic representation of a part of the structure of coal. When coal is heated in the absence of oxygen, the structure breaks up and a complex mixture of products—many of them aromatic—is obtained. Types of Hydrocarbons 18.1 Draw Lewis structures of the following molecules and identify each as an alkane, alkene, or alkyne: (a) CH3CCCH3; (b) CH3CH2CH2CH3; (c) CH2CHCH2CH3; (d) CH3CHCHCH2CCCH3; (e) CH2CHCH2CHCH2. 18.2 Give the molecular formula and identify each of the following molecules as being an alkane, alkene, or alkyne: 18.3 Give the molecular formulas corresponding to the following stick figures and identify each as an alkane, an alkene, an alkyne, or an aromatic hydrocarbon 18.4 Give the molecular formulas corresponding to the following stick figures and identify each as an alkane, an alkene, an alkyne, or an aromatic hydrocarbon: 18.5 Give the molecular formulas corresponding to the following stick figures and identify each as an alkane, an alkene, an alkyne, or an aromatic hydrocarbon: EXERCISES oxygen). Oxygen and hydrogen are gradually lost through the coalification process. As coalification proceeds, hydrogen is released and the aromatic structures increase. When coal is destructively distilled—heated in the absence of oxygen so that it decomposes and vaporizes—its sheetlike molecules break up, and the fragments include aromatic hydrocarbons and their derivatives. Coal gas, which is given off first, contains carbon monoxide, hydrogen, methane, and small amounts of other gases. The complex liquid mixture that remains is called coal tar. A large number of pharmaceuticals, dyes, and fertilizers come from coal tar. Benzene is the raw material for many plastics, detergents, and pesticides. Naphthalene is used to make synthetic indigo (the dye in blue jeans), ammonia is used as fertilizer, and pitch, which contains the heaviest tars, is used for waterproofing and rustproofing. Coal gas is the starting point for a number of alternative fuels. The mixture of carbon monoxide and hydrogen can be used as is, but that mixture is highly toxic. Therefore, coal gas is used to make gaseous fuels such as gaseous methane and hydrogen and liquid fuels such as methanol. These fuels are highly desired because they burn cleanly, producing little air pollution. Coal is primarily aromatic in nature. EXERCISES 753 ❑ 1 Distinguish alkanes, alkenes, alkynes, and arenes by differences in bonding, structure, and reactivity. ❑ 2 Name simple hydrocarbons (Toolbox 18.1 and Examples 18.1, 18.2, and 18.5). ❑ 3 Identify two molecules, given their structural formulas, as structural, geometrical, or optical isomers (Section 18.2). ❑ 4 Write the formulas of isomeric molecules (Example 18.3). ❑ 5 Judge whether a compound is chiral (Example 18.4). ❑ 6 Describe general trends in the physical properties of alkanes (Section 18.3). ❑ 7 Predict the products of given elimination, addition, and substitution reactions (Sections 18.4, 18.6, and 18.8). ❑ 8 Explain why ortho- and para-directing groups accelerate electrophilic substitution on the benzene ring and identify such groups (Section 18.8). ❑ 9 Describe the primary processes used in the refining of petroleum (Section 18.9). SKILLS YOU SHOULD HAVE MASTERED (a) (b) (c) (d) (a) (b) (c) (d) (a) (b) (c) (d) CH2CCH2 (a) (b) (c) (d) 18.6 Give the molecular formulas corresponding to the following stick figures and identify each as an alkane, an alkene, an alkyne, or an aromatic hydrocarbon: Nomenclature of Hydrocarbons 18.7 Name each of the following compounds as an unbranched alkane: (a) C3H8; (b) C4H10; (c) C7H16; (d) C10H22. 18.8 Name each of the following compounds as an unbranched alkane: (a) C9H20; (b) C6H14; (c) C11H24; (d) C12H26. 18.9 Name the following substituents: (a) CH3ß; (b) CH3(CH2)3CH2ß; (c) CH3CH2CH2ß; (d) CH3CH2CH2CH2CH2CH2ß. 18.10 Name the following substituents: (a) CH3(CH2)8CH2ß; (b) CH3CH2ß; (c) CH3CH2CH2CH2ß; (d) CH3CH2CH2CH2CH2CH2CH2CH2ß. 18.11 Give the systematic name of (a) CH3CH2CH3; (b) CH3CH3; (c) CH3(CH2)3CH3; (d) (CH3)2CHCH(CH3)2. 18.12 Give the systematic name of (a) CH3CH2CH(CH3)CH2CH3; (b) CH3CH(CH2CH3)CH(CH3)CH3; (c) (CH3)3C(CH2)3CH(CH3)2; (d) CH3C(CH3)2C(CH3)2CH3. 18.13 Name compound (a) CH3CH¢CHCH(CH3)2; (b) CH3CH2CH(CH3)C(C6H5)(CH3)2. 18.14 Name compound (a) CH2¢CHCH2CH(C6H5)(CH2)4CH3; (b) (CH3)2CHCH(CH3)CHClCΩCCH3. 18.15 Write the shortened (condensed) structural formula of (a) 3-methyl-1-pentene; (b) 4-ethyl-3,3-dimethylheptane; (c) 5,5-dimethyl-1-hexyne; (d) 3-ethyl-2,4-dimethylpentane. 18.16 Write the shortened (condensed) structural formula of (a) 4-ethyl-2,2-dimethylhexane; (b) 3-ethyl-4-methyl-1-pentene; (c) cis-4-ethyl-3-heptene; (d) trans-4-methyl-2-hexene. 18.17 Write the structural formula of (a) 4,4-dimethylnonane; (b) 4-propyl-5,5-diethyl-1-decyne; (c) 2,2,4-trimethylpentane; (d) trans-3-hexene. 18.18 Write the structural formula of (a) 3,4,9-trimethyldecane; (b) 2,3,5-trimethyl-4-propylheptane; (c) 1,3-dimethylcyclohexane; (d) 5-ethyl-3-heptene. 18.19 Draw stick structures to represent each of the following molecules: (a) nonane, CH3(CH2)7CH3; (b) cyclopropane, C3H6; (c) cyclohexene, C6H10. 18.20 Draw stick structures to represent each of the following species: (a) 2,2,3,3-tetramethylhexane, CH3C(CH3)2C(CH3)2CH2CH2CH3; (b) the trityl cation, (C6H5)3C+ ; (c) butadiene, CH2CHCHCH2. Isomers 18.21 Write the structural formulas for and name (a) at least 10 alkene isomers having the formula C6H12; (b) at least 10 cycloalkane isomers having the formula C6H12. 18.22 Write the structural formulas for and name all the isomers (including geometrical isomers) of the alkenes (a) C4H8; (b) C5H10. 18.23 Identify each of the following pairs as structural isomers, geometrical isomers, or not isomers: (a) butane and cyclobutane; (b) cyclopentane and pentene; (c) (d) 18.24 Identify each of the following pairs as structural isomers, geometrical isomers, or not isomers: (a) 1-chlorohexane and chlorocyclohexane; (b) (c) 18.25 A branched hydrocarbon C4H10 reacts with chlorine in the presence of light to give two branched structural isomers with the formula C4H9Cl. Write the structural formulas of (a) the hydrocarbon; (b) the isomeric products. 18.26 A branched hydrocarbon C6H14 reacts with chlorine in the presence of light to give only two structural isomers with the formula C6H13Cl. Write the structural formulas of (a) the hydrocarbon; (b) the two isomeric products. 18.27 Indicate which of the following molecules are optical isomers and identify the chiral carbon atoms in those that are: (a) CH3CHBrCH2CH3; (b) CH3CH2CHCl2; (c) 1-bromo-2chloropropane; (d) 1,2-dichloropentane. 18.28 Indicate which of the following molecules are optical isomers and identify the chiral carbon atoms in those that are: (a) CH3CHBrCH2Br; (b) CH3CH2CHClCH2CH3; (c) 2-bromo-2methylpropane; (d) 2,3-dimethylpentane. Alkanes 18.29 Why do branched-chain alkanes have lower melting points and boiling points than unbranched alkanes with the same number of carbon atoms? 18.30 Arrange the following compounds in order of increasing boiling point: CH3CH2CH2CH2CH3, CH3CH2CH(CH3)2, C(CH3)4. Explain your reasoning. 18.31 Using data available in Appendix 2A, write balanced equations and calculate the heat released when (a) 1.00 mol and (b) 1.00 g of each of the following compounds is burned in excess oxygen: propane, butane, and pentane. Is there a trend in the amount of heat released per mole of molecules or per gram of compound? If so, what is it? 18.32 Write the balanced chemical equation for the complete fluorination of methane to tetrafluoromethane. Using bond enthalpies, estimate the enthalpy of this reaction. The Cl Cl Cl Cl and and and and 754 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS (a) (b) (c) (d) corresponding reaction using chlorine is much less exothermic. To what can this difference be attributed? 18.33 How many different products containing two carbon atoms are possible in the reaction of chlorine with ethane? Do any of the products exist as optical isomers? 18.34 How many different products that retain the threemembered ring are possible in the reaction of chlorine with cyclopropane? Do any of the products exist as stereoisomers? Alkenes 18.35 Identify the type and number of bonds on carbon atom 2 in (a) pentane; (b) 2-pentene; (c) 2-pentyne. 18.36 Predict the geometry and hybridization of the orbitals used in bonding on carbon atom 2 in (a) pentane; (b) 2-pentene; (c) 2-pentyne. 18.37 Draw the structures of cis-1,2-dichloropropene and trans- 1,2-dichloropropene. Which of these molecules is polar? 18.38 Draw the structure of 1,3-pentadiene. Use valence-bond and molecular orbital pictures to describe the bonding for the ␴-framework and ␲-orbitals, respectively. 18.39 Two structural isomers can result when hydrogen bromide reacts with 2-pentene. (a) Write their structural formulas. (b) What name is given to this type of reaction? 18.40 (a) Write a balanced equation for the production of 2,3-dibromobutane from 2-butyne. (b) What name is given to this type of reaction? 18.41 (a) Write a balanced equation for the reaction of bromocyclohexane with sodium ethoxide in ethanol. (b) Draw structural formulas of the cyclic reactant and product. (c) What name is given to this type of reaction? 18.42 Draw stick structures of the possible products for the reaction of sodium ethoxide with (a) 1-bromobutane; (b) 2-bromobutane. 18.43 Compare the reaction enthalpies for the halogenation of ethene by chlorine, bromine, and iodine. What trend, if any, exists in these numbers? Use bond enthalpies to estimate the enthalpies of reaction. 18.44 Compare the reaction enthalpies for the hydrohalogenation of ethene by HX, where X¢Cl, Br, I. What trend, if any, exists in these numbers? Use bond enthalpies to estimate the enthalpies of reaction. Aromatic Compounds 18.45 Name the following compounds: 18.46 Name the following compounds: 18.47 Write the structural formula of (a) methylbenzene, more commonly known as toluene; (b) p-chlorotoluene; (c) 1,3-dimethylbenzene; (d) 4-chloromethylbenzene. 18.48 Write the structural formula of (a) p-xylene; (b) 1,2-dibromobenzene; (c) 3-phenylpropene; (d) 2-ethyl-1,4-dimethylbenzene. 18.49 (a) Draw all the isomeric dichloromethylbenzenes. (b) Name each one and indicate which are polar and which are nonpolar. 18.50 (a) Draw all the isomeric diaminodichlorobenzenes. (b) Name each one and indicate which are polar and which are nonpolar. 18.51 Draw resonance structures of cyanobenzene (C6H5CN) that show how it functions as a meta-directing substituent. 18.52 One can prepare bromonitrobenzenes either by nitrating bromobenzene or by brominating nitrobenzene. Will these two reactions give the same product (or product distribution)? If not, how will the products differ? 18.53 How many different compounds can be produced when naphthalene, C10H8 (30), undergoes electrophilic aromatic substitution by a single electrophile (denoted E)? Draw stick figures to represent them. 18.54 The structure of benzaldehyde is Do you expect the aldehyde functional group (CHO) to act as a meta-directing or as an ortho, para-directing group? Explain. Fuels 18.55 Why are hydrocarbons having between one and four carbon atoms not suitable for gasoline? 18.56 What are the major problems associated with using coal as a fuel? 18.57 Propene and butane can be combined by the process called alkylation to form a straight-chain hydrocarbon used in gasoline. Write a chemical equation for the reaction. 18.58 The compound C18H38 is a component of fuel oil that can be converted by a cracking process into two compounds suitable for use in gasoline. The compounds have the formulas CnH2n+2 and CnH2n, with the value of n being the same in each. Each compound has a straight chain of carbon atoms, with no branches. Write possible structural formulas for the two compounds and name them. Integrated Exercises 18.59 Classify each of the following reactions as addition or substitution and write its chemical equation: (a) chlorine reacts with methane when exposed to light; (b) bromine reacts with ethene in the absence of light. 18.60 Classify each of the following reactions as addition or substitution and write its chemical equation: (a) hydrogen reacts with 2-pentene in the presence of a nickel catalyst; (b) hydrogen chloride reacts with propene. O H C CH2CH3 CH2CH2CH3 CH2CH3 CH2CH2CH3 CH2CH3 CH3 CH3 CH3 CH3 CH3 CH2CH3 CH3 EXERCISES 755 (a) (b) (a) (b) 756 CHAPTER 18 ORGANIC CHEMISTRY I: THE HYDROCARBONS 18.61 The dehydrohalogenation of haloalkanes to produce alkenes is always carried out in a nonaqueous solvent, usually ethanol. Give two reasons why water cannot be used as the solvent for the reaction. 18.62 View the animation of the alkene addition mechanism associated with Fig. 18.9 on the Web site for this book. (a) In the addition of HCl to propene an intermediate is formed. Is that intermediate positively or negatively charged? How is the charge eliminated? (b) Write a two-step mechanism for the reaction. 18.63 Propane torches are used for minor home repairs, but welders must use torches that burn acetylene (ethyne). (a) Write chemical equations for the combustion of propane and ethyne. (b) Calculate the enthalpy of combustion for each fuel per gram and per mole. (c) Use your data in part (b) to explain why welders do not use propane torches. 18.64 Consider the reaction between propene and hydrogen. (a) Calculate the equilibrium constant at 298 K. (b) Does K increase or decrease as the temperature is raised? 18.65 Give the systematic name of each of the following compounds. If geometrical isomers are possible, write the names of each one: (a) CH2¢C(CH3)2; (b) CH3CH¢C(CH3)CH2CH3; (c) HCΩCCH2CH2CH2CH3; (d) CH3CH2CΩCCH2CH3; (e) CH3CH2CH2CΩCCH3. 18.66 Give the systematic name of each of the following compounds. If geometrical isomers are possible, write the names of each one: (a) CH3CH2CH¢CHCH3; (b) CH3C(CH3)¢CHCH3; (c) (CH3)2C¢CHCH2CH3; (d) HCΩCCH2CH(CH2CH2CH3)CH3; (e) CH3CH2CΩCCH(CH3)CH2CH3. 18.67 The structure of decalin can be found on the Web site for this book. (a) From an examination of this structure, determine the chemical formula of decalin. (b) From what aromatic hydrocarbon may decalin be produced by complete hydrogenation? (c) Are isomers possible for decalin? If so, draw the appropriate Lewis structures. 18.68 Nonsystematic names for organic compounds may still be found in the chemical literature and chemical supply catalogs, and so it is important to be somewhat familiar with these as well as with the IUPAC rules. Give the systematic name for (a) isobutane and (b) isopentane. (c) Formulate a rule for the usage of the prefix iso- and predict the structure of isohexane. Structures for these compounds can be found on the Web site for this book. 18.69 (a) What carbon–carbon bond angles are expected for cyclopropane? (b) What are the consequences of insisting on sp3 hybridization for the carbon atoms in cyclopropane? (c) Calculate the enthalpy of combustion of cyclopropane using Tables 7.7 and 7.8. (d) The experimental enthalpy of combustion of cyclopropane is –2.09 MJиmolϪ1 . Explain any difference. (Hint: consider how a restriction in bond angles might affect the energies of the bonds.) 18.70 Cubane is an unusual alkane in which eight carbon atoms at the corners of a cube are bonded to adjacent carbon atoms along the edges of the cube. (a) Write the chemical formula of cubane and draw its structure. (b) What carbon–carbon bond angles are expected for cubane? (c) What is the expected hybridization of the carbon atoms? (d) Some compounds based on cubane have been found to be good explosives. Write the chemical equation for the combustion of cubane and calculate its enthalpy of combustion from the bond enthalpies in Tables 7.7 and 7.8. (e) The experimental enthalpy of combustion of cubane is –4.2 MJиmolϪ1 . Account for any difference from the calculated value and explain what makes cubane a good explosive. (Hint: consider how a restriction in bond angles might affect the energies of the bonds.) 18.71 In a combustion analysis, 3.21 g of a hydrocarbon formed 4.48 g of water and 9.72 g of carbon dioxide. Deduce its empirical formula and state whether it is likely to be an alkane, an alkene, or an alkyne. Explain your reasoning. 18.72 In a combustion analysis, 5.535 g of a hydrocarbon formed 6.750 g of water and 17.550 g of carbon dioxide. Deduce the empirical formula of the hydrocarbon and state whether it is likely to be an alkane, an alkene, or an alkyne. Explain your reasoning. 18.73 The following names of organic molecules are incorrect. Draw line structures and determine the correct systematic name for (a) 4-methyl-3-propylheptane; (b) 4,6-dimethyloctane; (c) 2,2-dimethyl-4-propylhexane; (d) 2,2-dimethyl-3-ethylhexane. 18.74 Alkanes undergo substitution of hydrogen atoms when treated with halogens. Bromination of which of the following compounds could give rise to chiral monosubstituted products: (a) ethane; (b) propane; (c) butane; (d) pentane? Include in your answer the names of the chiral compounds that would be formed. 18.75 A hydrocarbon with the formula C3H6 does not react with bromine in the absence of light but does react in the presence of light, producing C3H5Br. What is the name of this hydrocarbon? 18.76 A hydrocarbon is 90% carbon by mass and 10% hydrogen by mass and has a molar mass of 40 gиmolϪ1 . It decolorizes bromine water, and 1.46 g of the hydrocarbon reacts with 1.60 L of hydrogen (measured at STP) in the presence of a nickel catalyst. Write the molecular formula of the hydrocarbon and the structural formulas of two possible isomers. 18.77 The compound 1-bromo-4-nitrobenzene (p-bromonitrobenzene) can be brominated. What do you expect to be the major product and why? Draw appropriate Lewis structures to support your answer. 18.78 Consider the nitration of the compound If the reaction can be controlled so that one NO2 group replaces one H atom of the molecule, where do you expect the nitro group to end up in the product? 18.79 (a) Draw the structure of the hydrocarbon 3,4,6-trimethyl-1heptene. (b) Identify the chiral carbon atoms in the structure with stars. (c) Are cis and trans isomers possible for this molecule? 18.80 Trinitrotoluene, TNT, is a well-known explosive. (a) Using the structure available on the Web site, determine the systematic name for TNT. (b) TNT is made by nitrating toluene (methylbenzene) with a mixture of concentrated nitric and sulfuric acids. Explain why this particular trisubstituted isomer is the one that is formed during the nitration. 18.81 A chemist obtains the mass spectrum of 1,2-dichloro-4ethylbenzene. Give at least four possible fragments and the masses O H CHO EXERCISES 757 at which you would expect them to occur. Chlorine has two naturally occurring isotopes: 35 Cl, 34.969mu, 75.53%, and 37 Cl, 36.966mu, 24.47%. The mass of 1 H is 1.0078mu. See Major Technique 6, Mass Spectrometry, which follows this set of exercises. 18.82 How will the mass spectrum of D2O differ from that described in the text for H2O? See Major Technique 6, Mass Spectrometry, which follows this set of exercises. 18.83 The occurrence of isotopes of some elements allows the presence of these elements to be readily identified in a mass spectrum of a compound. For example, Br has two naturally occurring isotopes with masses 79mu and 81mu, in abundances 50.5% and 49.5%, respectively. How will this information make the determination of the number of bromine atoms in an organic molecule relatively easy? For example, in the bromination of an alkane, it is possible that a number of products with more than one bromine atom might be produced. See Major Technique 6, Mass Spectrometry, which follows this set of exercises. 18.84 A chemist treats toluene (methylbenzene) with chlorine in the presence of a metal catalyst. A sample of the reaction mixture is injected into a GC-MS unit (gas chromatograph–mass spectrometer). One of the compounds that is separated by using gas chromatography gives a mass spectrum with peaks at 128mu, 126mu, 113mu, 111mu, and 91mu, among others. The peak at 128mu is approximately one-third the size of the peak at 126mu, and the peak at 113mu is approximately one-third the size of the peak at 111mu. What is the likely composition of this compound, and what fragments may be assigned to these peaks? See Major Technique 6, Mass Spectrometry, which follows this set of exercises. 18.85 Conjugated polyenes are hydrocarbons with alternating single and double bonds. They are commonly used as dyes because they absorb in the visible range. Two such molecules have the formulas C6H8 and C8H10. Of the two, which has its maximum absorption at the longer wavelength? Justify your answer. See Major Technique 2, following Chapter 3. 18.86 How many liters of hydrogen at 1.00 atm and 298 K are needed to hydrogenate (a) 1.00 mol C6H10, cyclohexene; (b) 1.00 mol C6H6, benzene, completely? (c) Estimate the reaction enthalpy of each hydrogenation from the average bond enthalpies in Tables 7.7 and 7.8. (d) The Lewis structures imply that the enthalpy of hydrogenation of benzene is three times that of cyclohexene. Do your calculations support this implication? Explain any differences. Chemistry Connections 18.87 A gaseous compound used to make both bubble gum and automobile tires was analyzed to determine its properties and toxicity. (a) When 0.108 g of the compound was analyzed by combustion analysis, 0.352 g of CO2 and 0.109 g of H2O were produced. What is the empirical formula of the compound? (b) The molar mass of the compound was found to be 54.09 gиmolϪ1 . What is the molecular formula of the compound? (c) Draw the structural formulas of at least six possible structural isomers of the compound. (d) When the compound is exposed to hydrogen gas over a catalyst, the molar mass of the hydrogenated product is 58.12 gиmolϪ1 . Which of the isomers in part (c) does this information help to eliminate? (e) A 2.45-L flask was filled with the compound at 25°C and 1.0 atm. Hydrogen bromide gas was pumped into the flask until the total pressure in the flask reached 5.0 atm. Reaction then proceeded to completion because the single product was removed as fast as it was formed. After completion of the reaction the pressure of the excess HBr in the flask was 2.0 atm. What is the molecular formula of the product? (f) The product in (e) has three structural isomers, two of which are optical isomers. Draw the structural formulas of the original compound and each of the product isomers. Place an asterisk on each chiral carbon atom. (g) Assign a hybridization scheme to each C atom in the original compound. (h) Write the name of the original compound. MASS SPECTROMETRYMAJOR TECHNIQUE 6XIn spectroscopy, a diffraction grating or prism is used to separate photons of light by their wavelengths. In mass spectrometry, a magnetic field is used to separate ions by their masses. This technique is one of our most powerful analytical methods because it provides both quantitative and qualitative information about the substance being analyzed, it requires only tiny samples, and it can be conducted in the field, by using lightweight, portable units. Mass spectrometry is used to determine isotopic abundance (Section B), to study the composition of bone and other body tissues, to analyze the blood of newborns for congenital diseases, to detect vanishingly small concentrations of drugs in urine, and to determine the structure of the human genome. The Technique We met a classic type of mass spectrometer in Section B. Another common type of mass spectrometer is the large magnet mass spectrometer (Fig. 1). In each case, the spectrometer uses the degree to which charged particles are deflected by a magnetic field to determine the relative masses of the particles. In a mass spectrometer, the sample is first vaporized and then ionized. The resulting ions are accelerated by an electric field into a narrow beam that, as it passes between a set of magnets, is deflected toward a detector. The heavier the particle, the less it is deflected, and the degree of deflection allows the relative masses of the particles to be determined. The results are displayed as a series of peaks, with the height of each peak being proportional to the relative number of particles with a given mass. The entire spectrometer must first be evacuated (have all the air pumped out) to ensure that no gas molecules can collide with the ions produced from the sample and deflect them in unpredictable ways. Then the sample is introduced in the form of a vapor into the sample inlet chamber and through a pinhole into the ionization chamber. In this chamber, rapidly moving electrons collide violently with the molecules of the vapor. When one of the accelerated electrons collides with a molecule, the colliding electron knocks another electron out of the molecule, leaving a molecular cation. The molecular ion may split apart into two or more charged fragments. The positive ions—the original (“parent”) molecular ions and their fragments—are accelerated out of the chamber by a strong electric field applied across a series of metal grids. The speeds reached by the ions depend on their masses: light ions reach higher speeds than heavier ones. The rapidly moving ions pass between the poles of an electromagnet. The magnetic field bends the paths of the ions to an extent that depends on their speeds and on the strength of the field. In the large magnet mass spectrometer, the magnetic field is kept constant but the strength of the electric field is varied, and so the molecular ions are accelerated to different speeds. At a given electric field strength, ions of only one particular mass reach the detector. Any ions with different masses collide with the walls of the chamber. The strength of the electric field is varied and the result is a mass spectrum—a plot of the detector signal against the strength of the electric field. The positions of the peaks in the mass spectrum give the mass-to-charge ratios of the ions. If all the ions have charges of ϩ1, then the peaks give the mass ratios and their relative heights give the proportions of ions of various masses. Analyzing a Mass Spectrum If the sample consists of atoms of one element, the mass spectrum gives the isotopic distribution of the sample, as in Fig. B.6. The relative molar masses of the isotopes can be determined by comparison with atoms of carbon-12. If the sample is a compound, the formula and structure of the compound can be determined by studying the fragments. For example, the ϩ1 ions that CH4 could produce are CH4 ϩ , CH3 ϩ , CH2 ϩ , CHϩ , Cϩ , and Hϩ . Some of the particles that strike the detector are those that result when the molecule simply loses an electron (for example, to produce CH4 + from methane): Molecule ϩ eϪ moleculeϩ ϩ 2 eϪ The mass of this molecular ion, the parent ion, is called the parent mass. The parent ion has essentially the same molar mass as the compound itself. However, if the electron beam is moving at a very high speed, only fragments of the molecule may survive. Some fragments are almost always produced, and other information must be used to help with the interpretation. For example, a sample of a known compound can be analyzed and its spectrum compared to that of an unknown sample to look for similar fragments. The sample can also be passed through a gas chromatograph first (see Major Technique 4). The chromatogram allows comparison with a large number of possible compounds, and the mass spectrum verifies the identification. The identification of a molecular structure from a mass spectrum requires good chemical detective work. Let’s see how that is done by trying to identify a simple compound, the one that produced the mass spectrum summarized in the table. The parent mass is 18, 19, or 20. If the parent mass is 20, the compound ¡ FIGURE 1 A schematic drawing of a large magnet mass spectrometer. Pinhole Electron beam Accelerating field To pump Magnet Detector Sample 758 could be HF. However, fluorine has only one stable isotope, fluorine-19; so we could not explain the large peaks at 17 and 18. Because of the very small abundances of the peaks at 19 and 20, we can also guess that they represent the less abundant isotopes of one or more of the elements in the compound. We can conclude that the parent mass is 18 and the compound is probably water. The peaks at 19 and 20 would be due to the mass of parent molecules containing naturally occurring isotopes such as oxygen-18 and deuterium. The peak at 17 represents the OH+ fragment, the peak at 16 would be Oϩ ions, and the peak at 1 the few Hϩ ions that form in the ionization process. More complex detective work is required to analyze large biomolecules and drugs. However, fragmentation generally follows predictable patterns, and one compound can be identified by comparing its mass spectrum with those of other known compounds with similar structures. In Fig. 2, we see the spectrum of a sample of blood from a newborn infant. The blood is being analyzed to determine whether the child has phenylketonuria. The presence of the compound phenylalanine is a positive indication of the condition. Some phenylalanine labeled with a radioactive isotope has been injected along with the sample to identify the parent mass. The radioactive compound, which contains an isotope making it 5mu heavier than the phenylalanine, appears in the spectrum 5mu above it, thereby allowing a positive identification of the presence of the chemical. Related Exercises: 18.81–18.84 FIGURE 2 The two phenylalanine peaks include the radioactive tracer (the right-hand peak) and the phenylalanine in the blood (the peak 5mu to the left). The presence of the latter peak shows that the baby from whom the blood was drawn has phenylketonuria. 140 180 220 260 Mass/charge Detectorsignal Glycine Serine Valine Leucine/isoleucine Methionine Phenylalanine Tyrosine Glutamate Proline Alanine Mass Spectrum of an Unknown Compound Peak intensity as a m/e* percentage of largest peak 1 Ͻ 0.1 16 1.0 17 21.0 18 100.0 19 0.08 20 0.22 *The quantity m/e is the conventional notation for the mass-to-charge ratio of molecular ions, with the mass a multiple of the atomic mass constant mu and the charge a multiple of the fundamental charge e. 759 This page intentionally left blank 761 What Are the Key Ideas? The properties and reactions of many organic compounds are due to the presence of characteristic groups of atoms known as functional groups. Why Do We Need to Know This Material? Organic chemistry is the foundation of the pharmaceutical industry and, consequently, of medicine. Organic chemistry is also the basis of biochemistry and molecular biology; through those disciplines, it provides an understanding of life. The great diversity of organic molecules found in living systems results from the presence of groups of atoms with characteristic functions. Once we understand the properties of these groups, we can predict the properties of other organic molecules, even those of the giant biomolecules of proteins, carbohydrates, and genetic material, and the synthetic polymeric materials that have revolutionized our lives. What Do We Need to Know Already? This chapter builds on Chapter 18 and requires the same preparation, as well as the concepts of acid–base and redox reactions (Sections J and K). It also makes use of the concepts of molecular polarity (Section 3.3) and solubility (Section 9.9). T o solve some of the most difficult problems related to materials, scientists must look to organic chemistry. For example, soldiers and law enforcement officers sometimes did not wear body armor because its bulk interfered with their movement, leading to tragic loss of life. Today body armor made from organic compounds is lightweight and flexible and so is saving lives. The whole of the life-saving pharmaceutical industry is an application of organic chemistry. Molecular biology, the understanding of the processes of life, is another. This broad array of applications shows the immense variety of organic compounds, a variety that can be intimidating at first sight. Fortunately, organic compounds can be understood in terms of a relatively small number of functional groups, which are small groups of atoms with characteristic properties. Whereas the hydrocarbons are built only from carbon and hydrogen, functional groups may include atoms of other elements. Because functional groups have characteristic chemical properties, we do not have to learn all the properties of each different compound—once we identify the functional groups that are present, we have gone a long way toward understanding and predicting the likely chemical properties of the compound. This chapter has three parts. In the first part, we look at the structures and properties of some of the common functional groups and describe some of the characteristic mechanisms by which the groups react. Then we examine how functional groups are used to create modern polymers. As in so many spheres, nature has preceded chemists’ explorations. In the final part of the chapter, we see some examples of how functional groups in nature sustain us, feed us, and reproduce us. COMMON FUNCTIONAL GROUPS Functional groups are either attached to the carbon backbone of a molecule or form part of that chain. Examples are the chlorine atom in chloroethane, CH3CH2Cl, and the ßOH group in ethanol, CH3CH2OH. Carbon–carbon multiple bonds, such as the double bond in 2-butene, CH3CH≈CHCH3, are also often considered functional groups. Table 19.1 lists the most common functional groups. Double and triple carbon–carbon COMMON FUNCTIONAL GROUPS 19.1 Haloalkanes 19.2 Alcohols 19.3 Ethers 19.4 Phenols 19.5 Aldehydes and Ketones 19.6 Carboxylic Acids 19.7 Esters 19.8 Amines, Amino Acids, and Amides THE IMPACT ON TECHNOLOGY 19.9 Addition Polymerization 19.10 Condensation Polymerization 19.11 Copolymers 19.12 Physical Properties of Polymers THE IMPACT ON BIOLOGY 19.13 Proteins 19.14 Carbohydrates 19.15 Nucleic Acids 761 Chapter 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS bonds were considered in Chapter 18. In the following eight sections, we examine some other important functional groups, look at their characteristic chemical properties, and examine some of the reaction mechanisms that account for these properties. 19.1 Haloalkanes The haloalkanes (also called alkyl halides) are alkanes in which at least one hydrogen atom has been replaced by a halogen atom. Although they have important uses, many haloalkanes are highly toxic and a threat to the environment. The haloalkane 1,2dichlorofluoroethane, CHClFCH2Cl, is an example of a chlorofluorocarbon (CFC), one of the compounds held responsible for the depletion of the ozone layer (see Box 14.3). Many pesticides are aromatic compounds with several halogen atoms. Carbon–halogen bonds are polar (1). The carbon atom to which the halogen atom is attached is partially positive, making it susceptible to nucleophilic substitution, in which a nucleophile replaces the halogen atom. A nucleophile is a reactant that seeks out centers of positive charge in a molecule. Two examples are the hydroxide ion, OH– , and the water molecule, H2O. In each case a lone pair on the oxygen atom is attracted to regions of partial positive charge; the hydroxide ion is the stronger nucleophile because of its negative charge. Water acts as a nucleophile in a hydrolysis reaction, a reaction with water in which a carbon–element bond is replaced by a carbon–oxygen bond. For example, bromomethane undergoes hydrolysis by hydroxide ions in aqueous ethanol to methanol and bromide ions: CH3Br ϩ OHϪ CH3OH ϩ BrϪ Haloalkanes are alkanes in which at least one hydrogen atom has been replaced by a halogen atom; they undergo nucleophilic substitution. 19.2 Alcohols The hydroxyl group is an ßOH group covalently bonded to a carbon atom. An alcohol is an organic compound that contains a hydroxyl group not connected directly to a benzene ring or to a ϾC≈O group. One of the best-known organic compounds is ethanol, CH3CH2OH, which is also called ethyl alcohol and grain alcohol. The ßOH group in an alcohol molecule is polar and alcohols can give up their hydroxyl protons in certain solvents (Fig. 19.1), but their conjugate bases are so strong that they are not acids in water. There are several ways of naming alcohols, and you need to be familiar with all three: • Add the suffix -ol to the stem of the parent hydrocarbon, as in methanol and ethanol. When the location of the ßOH group needs to be specified (to avoid ambiguity), the number of the carbon atom to which it is attached is given, as in 1-propanol for CH3CH2CH2OH and 2-propanol for CH3CH(OH)CH3. • Name the parent hydrocarbon as a group and attach the name alcohol, as in methyl alcohol, CH3OH, and ethyl alcohol, CH3CH2OH. • Name the ßOH group as a substituent, in which case the name hydroxy is used, as in 2-hydroxybutane for CH3CH(OH)CH2CH3. We shall normally use the first of these three procedures. ¡ 762 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS TABLE 19.1 Common Functional Groups Group Class of compound Group Class of compound ∫X halide (X≈F, Cl, Br, or I) ∫COOH carboxylic acid ∫OH alcohol, phenol ∫COOR ester ∫O∫ ether ∫NϽ amine ∫CHO aldehyde ∫CO∫NϽ amide ∫CO∫ ketone 1 Chloromethane, CH3Cl FIGURE 19.1 The charge distribution in an ethanol molecule. The red color denotes the region of net negative charge around the oxygen atom and the blue color denotes regions of net positive charge. Because the molecule is polar and can form hydrogen bonds, it is highly soluble in water. 2-Propanol is often known by its common name, isopropyl alcohol. Alcohols are divided into three classes according to the number of organic groups attached to the carbon atom connected to the ßOH group: Type of alcohol Structure Example primary RCH2ßOH ethanol, CH3CH2OH secondary R2CHßOH 2-butanol, CH3CH(OH)CH2CH3 tertiary R3CßOH 2-methyl-2-propanol, (CH3)3COH Each R represents an organic group, such as a methyl or ethyl group; they need not all be the same. Methanol is usually prepared industrially from synthesis gas, which is obtained from coal (Section 15.3): CO(g) ϩ 2 H2(g) catalyst, 250°C, 50–100 atm CH3OH(g) The catalyst is a mixture of copper, zinc oxide, and chromium(III) oxide. Ethanol is produced in large quantities throughout the world by the fermentation of carbohydrates. It is also prepared by the hydration of ethene in an addition reaction: CH2≈CH2(g) ϩ H2O(g) catalyst, 300°C CH3CH2OH(g) The catalyst is phosphoric acid. The laboratory synthesis of alcohols is by nucleophilic substitution of haloalkanes. Ethylene glycol, or 1,2-ethanediol, HOCH2CH2OH (2), is an example of a diol, which is a compound with two hydroxyl groups. Ethylene glycol is used as a component of antifreeze mixtures and in the manufacture of some synthetic fibers. Alcohols with low molar masses are liquids, and alcohols have much lower vapor pressures than do hydrocarbons with approximately the same molar mass. For example, ethanol is a liquid at room temperature, but butane, which has a higher molar mass than ethanol, is a gas. The relatively low volatility of alcohols is a sign of the strength of hydrogen bonds. The ability of alcohols to form hydrogen bonds also accounts for the solubility in water of alcohols with low molar mass. The formulas of alcohols are derived from that of water by replacing one of the hydrogen atoms with an organic group. Like water, they form intermolecular hydrogen bonds. 19.3 Ethers An ether is an organic compound of the form R∫O∫R, where R is an alkyl group (the two R groups need not be the same). We can think of an ether as an HOH molecule in which both H atoms have been replaced by alkyl groups: H∫O∫H CH3CH2∫O∫H CH3CH2∫O∫CH2CH3 Water Ethanol (an alcohol) Diethyl ether (an ether) Ethers are more volatile than alcohols of the same molar mass because their molecules do not form hydrogen bonds to one another (Fig. 19.2). They are also less soluble in 19.3 ETHERS 763 The common names of 2-methyl- 2-propanol are tertiary-butanol and tertiary-butyl alcohol (commonly shortened to tert-butanol and tert-butyl alcohol or even t-butanol and t-butyl alcohol). ∫∫∫∫∫∫∫∫∫∫∫∫B ∫∫∫∫∫∫B Alcohols 79 97 117 138 0 100 Boilingpoint(°C) Number of carbon atoms 157 −25 2 3 4 5 6 11 35 64 91 Ethers FIGURE 19.2 The boiling points of ethers are lower than those of isomeric alcohols because there is hydrogen bonding in alcohols but not in ethers. All the molecules represented here are unbranched. 2 Ethanediol, HOCH2CH2OH OH OH water because they can form fewer hydrogen bonds to water molecules. Because ethers are not very reactive and have low molecular polarity, they are useful solvents for other organic compounds. However, ethers are flammable; diethyl ether is easily ignited and must be used with great care. Cyclic ethers (ethers in the form of a ring) with alternating ∫CH2CH2∫O∫ units are called crown ethers, owing to the crownlike shape of the molecules (3). Crown ethers bind very strongly to some metal cations; for example, a crown ether effectively encases Kϩ in a shell with the O atoms pointing inward toward the Kϩ ion and the hydrocarbon chain wrapped around the outside. Thus, crown ether molecules act as a sort of “Trojan horse” for the Kϩ ions, which in this form are soluble in nonpolar solvents. Potassium permanganate, for example, dissolves readily in benzene when a crown ether with six O atoms is added to it. The resulting solution can be used to carry out oxidation reactions in organic solvents. Ethers are not very reactive. They are more volatile than alcohols with similar molar masses because their molecules cannot form hydrogen bonds with one another. Crown ethers adopt shapes that can enclose ions and carry them into nonpolar solvents. 19.4 Phenols In a phenol, a hydroxyl group is attached directly to an aromatic ring. The parent compound, phenol itself, C6H5OH (4), is a white, crystalline, molecular solid. It was once obtained from the distillation of coal tar, but now it is mainly synthesized from benzene. Many substituted phenols occur naturally, some being responsible for the fragrances of plants. They are often components of essential oils, the oils that can be distilled from flowers and leaves. Thymol (5), for instance, is the active ingredient of oil of thyme, and eugenol (6) provides most of the scent and flavor of oil of cloves. Phenols differ from alcohols in that they are weak acids. Similar to the resonance in phenol itself (Section 18.8), the resonance in the anion delocalizes the negative charge of the conjugate base of phenol and hence stabilizes the anion. As a result, C6H5O– is a weaker conjugate base than the corresponding conjugate base of an alcohol, such as CH3CH2OϪ , the ethoxide ion, which is formed from ethanol. Consequently, phenol, C6H5OH, is a stronger acid than ethanol, CH3CH2OH, and phenols that are otherwise insoluble in water are soluble in basic solutions. However, even a single ∫CH2∫ group can insulate the O atom from the benzene ring; and phenylmethanol, C6H5CH2OH (benzyl alcohol, 7), is an alcohol, not a phenol. Phenols are weak acids as a result of delocalization and stabilization of the conjugate base. 19.5 Aldehydes and Ketones The carbonyl group, ϾC≈O, occurs in two closely related families of compounds: Aldehydes are compounds of the form Ketones are compounds of the form ¬ C ƒ R O ¬ R ¬ C ƒ R O ¬ H O Ϫ Ϫ Ϫ Ϫ O O O I I I 764 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS OH 4 Phenol, C6H5OH OH 6 Eugenol CH3 O CH © CH2 CH2OH 7 Benzyl alcohol, phenylmethanol, C6H5CH2OH OH 5 Thymol CH(CH3)2 H3C 3 A crown ether In an aldehyde, the carbonyl group is found at the end of the carbon chain, whereas in a ketone, it is at an intermediate position. The R groups may be either aliphatic or aromatic and the two R groups of a ketone need not be the same. In condensed structural formulas, the carbonyl group of a ketone is written ∫CO∫, as in CH3COCH3, propanone (acetone), a common laboratory solvent. The carbonyl group in an aldehyde is normally written ∫CHO, as in HCHO (formaldehyde), the simplest aldehyde. Formalin, the liquid used to preserve biological specimens, is an aqueous solution of formaldehyde. Wood smoke contains formaldehyde, and formaldehyde’s destructive effect on bacteria is one reason why smoking food helps to preserve it. The systematic names of aldehydes are obtained by replacing the ending -e by -al, as in methanal for HCHO and ethanal for CH3CHO. Note that the carbon atom of the carbonyl group is included in the count of carbon atoms when determining the alkane from which the aldehyde is derived. Ketones are given the suffix -one, as in propanone, CH3COCH3. To avoid ambiguity, a number is used to denote the carbon atom that has become the carbonyl group; thus, CH3CH2CH2COCH3 is 2-pentanone and CH3CH2COCH2CH3 is 3-pentanone. Aldehydes occur naturally in essential oils and contribute to the flavors of fruits and the odors of plants. Benzaldehyde, C6H5CHO (8), contributes to the characteristic aroma of cherries and almonds. Cinnamaldehyde (9) is found in cinnamon, and vanilla extract contains vanillin (10), which is present in oil of vanilla. Ketones can also be fragrant. For example, carvone (Section 18.1) is the essential oil of spearmint. Formaldehyde is prepared industrially (for the manufacture of phenol-formaldehyde resins) by the catalytic oxidation of methanol: 600°C, Ag 2 CH3OH(g) ϩ O2(g) ∫∫∫∫∫B 2 HCHO(g) ϩ 2 H2O(g) Further oxidation of the product to a carboxylic acid (Section 19.6) can be avoided by using a mild oxidizing agent. There is less risk of further oxidation for ketones than for aldehydes, because a CßC bond would have to be broken for a carboxylic acid to form. Dichromate oxidation of secondary alcohols produces ketones in good yield, with little additional oxidation. For example, CH3CH2CH(OH)CH3 can be oxidized to CH3CH2COCH3. The difference between the ease of oxidation of aldehydes and that of ketones is used to distinguish them. Aldehydes can reduce silver ions to form a silver mirror—a coating of silver on test-tube walls—with Tollens reagent, a solution of Agϩ ions in aqueous ammonia (Fig. 19.3): Aldehydes: CH3CH2CHO ϩ Agϩ (in Tollens reagent) gives CH3CH2COOH and Ag(s) Ketones: CH3COCH3 ϩ Agϩ (in Tollens reagent) gives no reaction Aldehydes and ketones can be prepared by the oxidation of alcohols. Aldehydes can be more easily oxidized than ketones can. 19.6 Carboxylic Acids The carboxyl group, , normally abbreviated ßCOOH, is the functional group found in carboxylic acids, which are weak acids of the form RßCOOH. The strengths of carboxylic acids are related to their structures, as described in Section 11.10. The simplest carboxylic acid is formic acid, HCOOH, the acid in ant venom. Another common carboxylic acid is acetic acid, CH3COOH, the acid of vinegar. It forms when the ethanol in wine is oxidized by air: CCH3CH2OH ϩ H2O O⌯ ∫B ƒ O ¬ H3C ® O2 ¬ ƒ C O ¬ OH 19.6 CARBOXYLIC ACIDS 765 C 8 Benzaldehyde, C6H5CHO © ∫ OH OH 10 Vanillin OCH3 CHO 9 Cinnamaldehyde CHO FIGURE 19.3 An aldehyde (left) produces a silver mirror with Tollens reagent, but a ketone (right) does not. Lab Video 19.3 Carboxylic acids are named systematically by replacing the -e of the parent hydrocarbon by the suffix -oic acid; the carbon atom of the carboxyl group is included in the count of atoms to determine the parent hydrocarbon molecule. Thus, formic acid is formally methanoic acid, and acetic acid is ethanoic acid. Carboxylic acids can be prepared by oxidizing primary alcohols and aldehydes with a strong oxidizing agent, such as acidified aqueous potassium permanganate solution. In some cases, an alkyl group can be oxidized directly to a carboxyl group. This process is very important industrially. Carboxylic acids have an ßOH group attached to a carbonyl group to form the carboxyl group, ßCOOH. 19.7 Esters The product of the reaction between a carboxylic acid and an alcohol is called an ester (11). Acetic acid and ethanol, for example, react when heated to about 100°C in the presence of a strong acid. The products of this esterification are ethyl acetate and water: Many esters have fragrant odors and contribute to the flavors of fruits. For example, benzyl acetate, CH3COOCH2C6H5, is an active component of oil of jasmine. Other naturally occurring esters include fats and oils. For example, the animal fat tristearin (12), which is a component of beef fat, is an ester formed from glycerol and stearic acid. Ester formation is an example of a condensation reaction in which two molecules combine to form a larger one and a small molecule is eliminated (Fig. 19.4). The reaction is catalyzed by a small amount of strong acid, such as sulfuric acid. In an esterification of a carboxylic acid and an alcohol, the eliminated molecule is H2O. Condensation reactions provide a solution to a problem resulting from the hydrogenation of oils (Section 18.6). During the hydrogenation process the remaining double bonds are converted from their naturally occurring cis forms to the trans isomer. These fats, which are called “trans fats,” can contribute to health problems such as arteriosclerosis. Transesterification is a technique in which enzymes are used to promote switching of the long carboxylic acid chains from one alcohol location to another in a fatty acid (see Section 9.9). The resulting fat has the desired higher melting point yet is still unsaturated and has no trans fats. The new process also reduces the need for cooling water and does not use toxic or flammable solvents. Self-Test 19.1A (a) Write the condensed structural formula of the ester formed from the reaction between propanoic acid, CH3CH2COOH, and methanol, CH3OH. (b) Write the condensed structural formulas of the acid and alcohol that react to form pentyl ethanoate, CH3COOC5H11, a contributor to the flavor of bananas. [Answer: (a) CH3CH2COOCH3; (b) CH3COOH and CH3(CH2)3CH2OH] Self-Test 19.1B (a) Write the condensed structural formula of the ester formed from the reaction between formic acid, HCOOH, and ethanol, CH3CH2OH. (b) Write the condensed structural formulas of the acid and alcohol that react to form methyl butanoate, CH3(CH2)2COOCH3, a contributor to the flavor of apples. Alcohols condense with carboxylic acids to form esters. CH2O ƒ O å ƒ O å CH2O ƒ O CH2O 12 Tristearin, C57H110O6 ¬ C ƒ H3C O ¬ OH H∫O ¬ CH2CH3 ¬B ¬ ƒ H3C O ¬ O®CH2CH3 ϩ H2OC 766 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS C ∫ 11 Ethyl acetate, CH3COOC2H5 © ∫ O ∫ CH2CH3 H3C O FIGURE 19.4 In a condensation reaction, two molecules are linked as a result of removing two atoms or groups (the orange and yellow spheres) as a small molecule. Condensation 19.8 Amines, Amino Acids, and Amides An amine is a compound with a formula derived from NH3 in which various numbers of H atoms are replaced by organic groups, which may be either aliphatic or aromatic. Amines are classified as primary, secondary, or tertiary according to the number of R groups on the nitrogen atom: Type of amine Structure Example primary RNH2 methylamine, CH3NH2 secondary R2NH dimethylamine, (CH3)2NH tertiary R3N trimethylamine, (CH3)3N Each R represents an organic group, such as a methyl or ethyl group; they need not all be the same. In each case, the N atom is sp3 hybridized, with one lone pair of electrons and three ␴-bonds. A quaternary ammonium ion is a tetrahedral ion of the form R4Nϩ , where as many as three of the R groups (which may all be different) can be replaced by H atoms. For example, the tetramethylammonium ion, (CH3)4Nϩ , and the trimethylammonium ion, (CH3)3NHϩ , are quaternary ammonium ions. The amino group, the parent functional group of amines, is ßNH2. Amines are widespread in nature. Many of them have a pungent, often unpleasant odor. Because proteins are organic polymers containing nitrogen, amines are present in the decomposing remains of living matter and, together with sulfur compounds, are responsible for the stench of decaying flesh. The common names of two diamines— putrescine, NH2(CH2)4NH2, and cadaverine, NH2(CH2)5NH2—speak for themselves. Like ammonia, amines are weak bases (Section 11.7), but quaternary ammonium ions with at least one H atom attached to the N atom are generally acidic. An amino acid is a carboxylic acid that contains an amino group as well as a carboxyl group. The simplest example is glycine, NH2CH2COOH (13). Notice that an amino acid has both a basic group (ßNH2) and an acidic group (ßCOOH) in the same molecule. In aqueous solution with pH close to 7, amino acids are present as the zwitterion, such as ϩ H3NCH2CO2 Ϫ , in which the amino group is protonated and the carboxyl group is deprotonated. There are four possible forms of an amino acid, which differ in the extent of protonation of the two functional groups. In very acidic solution, alanine exists as ϩ H3NCH(CH3)COOH, but, as base is added, the proton on the N is removed first, leaving NH2CH(CH3)COOH (mainly in its zwitterion form), and then the proton from the carboxylic acid, to form NH2CH(CH3)CO2 Ϫ . The concentrations of the various species in a solution of an amino acid can be calculated by the same methods used for polyprotic acids in Section 11.16. Figure 19.5 shows how the concentrations of alanine species present in a solution vary with pH. Notice that the molecular form of alanine is almost nonexistent at any pH: its concentration had to be multiplied by a factor of 100 million for it to be visible on the plot. By far the most important amino acids are the ␣-amino acids, in which the ßNH2 group is attached to the carbon atom next to the carboxyl group, as in glycine. However, other types of amino acids are common and play an important biological role. For instance, the ␥-amino acid NH2CH2CH2CH2COOH is the neurotransmitter GABA. 19.8 AMINES, AMINO ACIDS, AND AMIDES 767 13 Glycine, NH2CH2COOH NH2 OH O Like alcohols, amines condense with carboxylic acids: The product is an amide. When the reactant is a primary amine, RNH2, the product is a molecule of the form Rß(CO)ßNHR. The mechanism of amide formation is a source of insight into the properties of carboxylic acids and amines. Initially, we might expect an amine to act as a base and simply accept a proton from the carboxylic acid. Indeed, that does happen, and a quaternary ammonium salt is formed when the reagents are mixed in the absence of a solvent. For example, CH3COOH ϩ CH3NH2 CH3CO2 – ϩ CH3NH3 ϩ However, on heating to about 200°C, a thermodynamically more favorable reaction takes place. The proton transfer is reversed, and the amine acts as a nucleophile as it attacks the carbon atom of the carboxyl group in a condensation reaction: One example of a familiar amide is the pain-relieving drug sold as Tylenol (14); we shall see another important example when we consider the polymer known as nylon in Section 19.10. Many amides have N–H bonds that can take part in hydrogen bonding, and so the intermolecular forces between their molecules are relatively strong. Self-Test 19.2A Predict whether an ester or a primary amine of the same molar mass is likely to have the higher boiling point and explain why. [Answer: The amine; it can form hydrogen bonds with the ßNH2 group, but the ester group cannot form hydrogen bonds in the pure state.] Self-Test 19.2B What are the hybridization schemes of the C and N atoms in formamide, HCONH2? ϩ ƒ ƒ C R HO R H2N ¬ Oa a a a a O NH3a R HO C ¬ NH3 ¬ Oa a a R ϩH2O C ¬ NH2 Oa a C ϩ H2O¬B ¬B ¬B ϪϪ ϩ ¡ ¬ C ƒ H3C O ¬ OH H∫NH ¬ CH2CH3 ¬B ¬ ƒ H3C O NH ¬ ¬CH2CH3 ϩ H2OC 768 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS FIGURE 19.5 The fractional composition of a solution of alanine, a typical amino acid, as a function of pH. Notice that the concentration of the molecular form is extremely low at all pH values; its concentration had to be multiplied by a factor of 108 for it to be visible on the graph. Amino acids are present almost entirely in ionic form in aqueous solution. Fraction,f 0 0.2 0.4 0.6 0.8 1.0 0 5 1.03 11.25 10 15 pH NH2CHRCO2 − +NH3CHRCO2 − + NH3CHRCOOH NH2CHRCOOH (ϫ 108 ) The red arrow on the second structure shows the migration of a proton. NH ∫ 14 Tylenol OH © å O CH3 SOLVE 19.8 AMINES, AMINO ACIDS, AND AMIDES 769 EXAMPLE 19.1 Naming compounds with functional groups Name the compounds (a) CH3CH(CH3)CH(OH)CH3; (b) CH3CHClCH2COCH3; and (c) (CH3CH2)2NCH2CH2CH3. PLAN Follow the procedures in Toolbox 19.1. TOOLBOX 19.1 HOW TO NAME SIMPLE COMPOUNDS WITH FUNCTIONAL GROUPS CONCEPTUAL BASIS In general, the names of compounds containing functional groups follow the same conventions and numbering system as those used in the names of hydrocarbons (Toolbox 18.1), with the ending of the name changed to indicate the functional group. The aim here, as there, is to be succinct but unambiguous. PROCEDURE The functional group has priority in numbering over hydrocarbon side chains. Alcohols To form the systematic name, identify the parent hydrocarbon and replace the ending -e by -ol. The location of the hydroxyl group is denoted by numbering the C atoms of the backbone, starting at the end of the chain that results in the lowest number for the ßOH group location. When ßOH is named as a substituent, it is called hydroxy. For example, CH3CH(OH)CH2CH2CH3 is 2-pentanol or 2-hydroxypentane. Aldehydes and ketones For aldehydes, identify the parent hydrocarbon: include the C of ßCHO in the count of carbon atoms. Then change the final -e of the hydrocarbon name to -al. The C in the ßCHO group is always carbon 1, at the end of a carbon chain, and is not explicitly numbered. For ketones, change the -e of the parent hydrocarbon to -one and number the chain in the order that gives the carbonyl group the lower number. Thus, CH3CH2CH2COCH3 is 2-pentanone. Carboxylic acids Change the -e of the parent hydrocarbon to -oic acid. To identify the parent acid, include the C atom of the ßCOOH group when counting carbon atoms. Thus, CH3CH2CH2COOH is butanoic acid. Esters Change the -anol of the alcohol to -yl and the -oic acid of the parent acid to -oate. Thus, CH3COOCH3 (from methanol and ethanoic acid) is methyl ethanoate. Amines Amines are named systematically by specifying the groups attached to the nitrogen atom in alphabetical order (disregarding prefixes), followed by the suffix -amine. Amines with two amino groups are called diamines. The ßNH2 group is called aminowhen it is a substituent. Thus, (CH3CH2)2CH3N is diethylmethylamine and CH3CH(NH2)CH3 is 2-aminopropane. Halides Name the halogen atom as a substituent by changing the -ine part of its name to -o, as in 2-chlorobutane, CH3CHClCH2CH3. These rules are illustrated in Example 19.1. ¬ ¬ CH3 ¬ OH CH¬CH3¬CHH3C 1234 (a) We determine the number of carbon atoms in the longest chain and replace the ending of the name of that chain with -ol: The alcohol is 3-methyl-2-butanol. ƒ ¬ ¬ ¬ Cl O CH2 C ¬CH3¬CHH3C 12345 (b) The compound is both a ketone and a haloalkane. Identify the hydrocarbon chain and number the chain in the direction that gives the ketone group the lower number. The chain has five carbon atoms; the ketone group is on the second carbon atom from one end, and the chlorine atom is on the fourth: The compound is 4-chloro-2-pentanone. ¬CH2H3C ¬CH2H3C ¬ ¬ N ¬CH2 CH2 CH3¬ ¬ (c) The compound (CH3CH2)2NCH2CH2CH3 has two ethyl groups and one propyl group attached to a nitrogen atom. Give the ethyl groups the prefix di- to indicate their number and list the groups in alphabetical order. The compound is diethylpropylamine. Self-Test 19.3A Name (a) CH3CH(CH2CH2OH)CH3; (b) CH3CH(CHO)CH2CH3; (c) (C6H5)3N. [Answer: (a) 3-methyl-1-butanol; (b) 2-methylbutanal; (c) triphenylamine] Self-Test 19.3B Name (a) CH3CH2CH(OH)CH2CH3; (b) CH3CH2COCH2CH3; (c) CH3CH2NHCH3. Amines are derived from ammonia by the replacement of hydrogen atoms with organic groups. Amides result from the condensation of amines with carboxylic acids. Amines and many amides take part in hydrogen bonding. THE IMPACT ON TECHNOLOGY The chains of carbon atoms in organic compounds can reach enormous lengths and give rise to macromolecules. Polymers are macromolecular compounds in which chains or networks of small repeating units form giant molecules, such as polypropylene and polytetrafluoroethylene (sold as Teflon). Polymers are made by two main types of reactions, addition reactions and condensation reactions. Which type of reaction is used depends on the functional groups present in the starting materials. Most of the raw material for polymers comes from petroleum, but some polymers are made from agricultural products such as corn and soybeans. 19.9 Addition Polymerization Alkenes can react with themselves to form long chains in a process called addition polymerization. For example, an ethene molecule may form a bond to another ethene molecule; another ethene molecule may add to that, and so on, forming a long hydrocarbon chain. The original alkene, such as ethene, is a small molecule called the monomer. Each monomer becomes one repeating unit, the structure that repeats over and over to produce the polymer chain. The product, the chain of covalently linked repeating units, is the polymer. The simplest addition polymer is polyethylene, ß(CH2CH2)nß, which is made by polymerizing ethene and so consists of long chains of thousands of repeating ßCH2CH2ß units. Many addition polymer molecules also have a number of branches, which are generated as new chains sprout from intermediate points along the “backbone” chain. The plastics industry has developed polymers from a number of monomers with the formula CHX≈CH2, where X is a single atom (such as the Cl in vinyl chloride, CHCl≈CH2) or a group of atoms (such as the CH3 in propene). These substituted ethenes are used to make polymers of formula ß(CHXCH2)nß, including polyvinyl chloride (PVC), ß(CHClCH2)nß, and polypropylene, ß(CH(CH3)CH2)nß (Table 19.2). They differ in appearance, rigidity, transparency, and resistance to weathering. 770 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS TABLE 19.2 Common Addition Polymers Monomer name Formula Polymer formula Common name ethene* CH2¢CH2 ∫(CH2∫CH2)n∫ polyethylene vinyl chloride CHCl¢CH2 ∫(CHCl∫CH2)n∫ polyvinyl chloride styrene CH(C6H5)¢CH2 ∫(CH(C6H5)∫CH2)n∫ polystyrene acrylonitrile CH(CN)¢CH2 ∫(CH(CN)∫CH2)n∫ Orlon, Acrilan propene* CH(CH3)¢CH2 ∫(CH(CH3)∫CH2)n∫ polypropylene methyl methacrylate CH3OOCC(CH3)C¢CH2 Plexiglas, Lucite tetrafluoroethene* CF2¢CF2 ∫(CF2∫CF2)n∫ Teflon, PTFE† *The suffix -ene is replaced by -ylene in the common names of these compounds, hence the names of the corresponding polymers. † PTFE, polytetrafluoroethylene. C C CH2 CH3 O OCH3 n A widely used synthetic procedure is radical polymerization, polymerization by a radical chain reaction (Section 14.9). In a typical procedure, a monomer (such as ethene) is compressed to about 1000 atm and heated to 100°C in the presence of a small amount of an organic peroxide (a compound of formula RßOßOßR, where R is an organic group). The reaction is initiated by dissociation of the OßO bond, giving two radicals: R∫O∫O∫R R∫Oи ϩ иO∫R Once it has been initiated, the chain reaction can propagate as the radicals attack the monomer molecules CHX≈CH2 (with X ϭ H for ethene itself) and form a new, highly reactive radical: This radical attacks another monomer molecule, and the chain grows longer: The reaction continues until all the monomer has been used up or until it terminates when pairs of chains have linked together into single nonradical species. The product consists of macromolecules with many repeating units. Polyethylene (with X ϭ H), for instance, consists of long chains of formula ß(CH2CH2)nß in which n can reach many thousands. Strong, tough polymers have chains that pack together well. One problem with early attempts to make polypropylene was that the orientations of the H and CH3 groups on each C atom were random, thereby preventing the chains from packing well. The resulting material was amorphous, sticky, and nearly useless. Now, however, the stereochemistry of the chains can be controlled by using a Ziegler–Natta catalyst, a catalyst consisting of the compounds titanium tetrachloride, TiCl4, and triethylaluminum, (CH3CH2)3Al. A polymer in which each unit or pair of repeating units has the same relative orientation is described as being stereoregular; the stereoregularity arises from the manner in which the chains grow on the catalyst (Fig. 19.6). The chains of stereoregular polymers produced by Ziegler–Natta catalysts pack together well to form highly crystalline, dense materials (Fig. 19.7). Rubber is a polymer of isoprene (15). Natural rubber is obtained from the bark of the rubber tree as a milky white liquid, which is called latex (Fig. 19.8) and consists of a suspension of rubber particles in water. The rubber itself is a soft white solid that becomes even softer when warm. It is used for pencil erasers and was once used as crepe rubber for the soles of shoes. Chemists were unable to synthesize rubber for a long time, even though they knew it was a polymer of isoprene. The enzymes in the rubber tree produce a stereoregular polymer in which all the links between monomers are in a cis arrangement (Fig. 19.9); straightforward radical polymerization, however, produces a random mixture of cis and trans links and a sticky, useless product. The stereoregular polymer was achieved with a Ziegler–Natta catalyst, and almost pure, rubbery cis-polyisoprene can now be produced. trans-Polyisoprene, in which all the links are trans, is the hard, naturally occurring material gutta-percha, once used inside golf balls and still used to fill root canals in teeth. ∫ CH2 ∫C !R ¬ O ¬¬ ∫B H X ϩ H2C ©C H X ∫ CH2 ∫C ∫CH2 ∫R ¬ O ¬¬ C ! ¬¬ H X ¬¬ H X ! ϩ H2C © CR ¬ O ¬¬ ∫B H X R ∫O ∫CH2 ∫C 1 ¬¬ H X ¡ 19.9 ADDITION POLYMERIZATION 771 FIGURE 19.6 (a) A polymer in which the substituents lie on random sides of the chain. (b) A stereoregular polymer produced by using a Ziegler–Natta catalyst. In this case, the substituents all lie on the same side of the chain.(a) (b) 15 Isoprene FIGURE 19.7 Polypropylene carpeting gets its strength from the regularity of the structure of its chains. Alkenes undergo addition polymerization. When a Ziegler–Natta catalyst is used, the polymer is stereoregular and has a high density. 19.10 Condensation Polymerization In condensation polymers, the monomers are linked together by condensation reactions, like those used to form ester or amide links. Polymers formed by linking together monomers that have carboxylic acid groups with those that have alcohol groups are called polyesters. Polymers of this type are widely used to make artificial fibers. A typical polyester is Dacron, or Terylene, a polymer produced from the esterification of terephthalic acid with ethylene glycol (see 2, 1,2-ethanediol): its technical name is polyethylene terephthalate, or PETE. The first condensation is FIGURE 19.8 Collecting latex from a rubber tree in Malaysia, a principal producer of latex. (a) (b) cis trans FIGURE 19.9 (a) In natural rubber, the isoprene units are polymerized to be all cis. (b) The harder material, gutta-percha, is the all-trans polymer. C O HO C O C O HO C O O OH ϩ H OH ϩ H2O O OH ∫B C O HO C O O O O C C O O OH n A new ethylene glycol molecule can condense with the carboxyl group on one end of the product, and another terephthalic acid molecule can condense with the hydroxyl group on the other end. As a result, the polymer grows at both ends and becomes In the radical addition polymerization of alkenes, side chains can grow out from the main chain. However, in condensation polymerization, growth can occur only at the functional groups, and so chain branching is much less likely. As a result, polyester molecules make good fibers, because the unbranched chains can be made to lie side by side when the heated product is stretched and forced through small holes (Fig. 19.10). The fibers produced can then be spun into yarn (Fig. 19.11). Polyesters can also be molded and used in surgical implants, such as artificial hearts, or made into thin films for cassette tapes. Condensation polymerization of amines with carboxylic acids leads to the polyamides, substances more commonly known as nylons. A common polyamide is nylon-66, which is a polymer of 1,6-diaminohexane, H2N(CH2)6NH2, and adipic acid, HOOC(CH2)4COOH. The 66 in the name indicates the numbers of carbon atoms in the two monomers. For condensation polymerization, it is necessary to have two functional groups on each monomer and to mix stoichiometric amounts of the reactants. In polyamide production, the starting materials first form “nylon salt” by proton transfer: HOOC(CH2)4COOH ϩ H2N(CH2)6NH2 Ϫ O2C(CH2)4CO2 Ϫ ϩ ϩ H3N(CH2)6NH3 ϩ At this point, the excess acid or amine can be removed. Then, when the nylon salt is heated, the condensation begins, just as in the preparation of simple amides. The first step is The amide grows at both ends by further condensations (Fig. 19.12), and the final product is The long polyamide (nylon) chains can be spun into fibers (like polyesters) or molded. The NßHиииO≈C hydrogen bonding that takes place between neighboring chains accounts for much of the strength of nylon fibers (Fig. 19.13). This ability to form hydrogen bonds also accounts for the tendency of nylon to absorb moisture, because H2O molecules can hydrogen bond to the polymer and worm their way in among the chains. ƒ O ¬ O ϪO C C(CH2)4 ¬¬¬ ¬ ƒ ¬ ƒ ƒ OO ¬ O C (CH2)4 ¬ ƒ n NH(CH2)6NH3 ϩNH(CH2)6NH ¬ C NH(CH2)6NH3 ϩ ϩ H2O ¬ C ƒ O ¬ ¬ ƒ O ϪO C (CH2)4 ¬ O ϪO C C(CH2)4 ϩ ϩ NH3(CH2)6NH3 ϩ OϪ ∫B¬¬ ƒ O ¬ ¬ ¬ ƒ ¡ FIGURE 19.10 Synthetic fibers are made by extruding liquid polymer from small holes in an industrial version of a spider’s spinneret. FIGURE 19.11 A scanning electron micrograph of Dacron polyester and cotton fibers in a blended shirt fabric. The cotton fibers have been colored green. Compare the smooth cylinders of polyester (orange) with the irregular surface of the cotton (green). The smooth polyester fibers resist wrinkles, and the irregular cotton fibers produce a more comfortable and absorbent texture. FIGURE 19.12 A rather crude nylon fiber can be made by dissolving the salt of an amine in water and dissolving the acid in a layer of hexane, which floats on the water. The polymer forms at the interface of the two layers, and a long string can be slowly pulled out. Lab Video 19.12 FIGURE 19.13 The strength of nylon fibers is an indication of the strength of the hydrogen bonds between neighboring polyamide chains. Animation 19.13 19.9 ADDITION POLYMERIZATION 773 774 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS (a) Amide groups are present in the backbone, and so the polymer is a polyamide. Because the amide groups face in opposite directions, there are two different monomers, one with two acid groups and the other with two amine groups. We split each amide group apart and add a molecule of water to each amide link. O O OHHO ϩϩ ϩN N H H H H ---- ---- O H2O H2O H2O O O NH NH (b) The monomer is an alkene, so it forms an addition polymer. Replace each ␲-bond by an additional ␴-bond to an adjacent monomer: H3C HO O OH CH C 16 Lactic acid, CH3CH(OH)COOH ∫ ƒ ∫∫ ∫ EXAMPLE 19.2 Determining the formulas of polymers and monomers Write the formulas of (a) the monomers of Kevlar, a strong fiber used to make bulletproof vests: (b) two repeating units of the polymer that is formed when peroxides are added to CH3CH2CH≈CH2 at a high temperature and pressure. PLAN (a) Look at the backbone of the polymer, the long chain to which the other groups are attached. If the atoms are all carbon atoms, then the compound is an addition polymer. If ester groups are present in the backbone, then the polymer is a polyester and the monomers will be an acid and an alcohol. If the backbone contains amide groups, then the polymer is a polyamide and the monomers will be an acid and an amine. (b) If the monomer is an alkene or alkyne, then the monomers will add to one another; a ␲-bond will be replaced by new ␴-bonds between the monomers. If the monomers are an acid and an alcohol or amine, then a condensation polymer forms with the loss of a molecule of water. SOLVE O C NH O C NH n HC CH3 ƒ CH2 ¬ ¬HC CH3 ƒ CH2 CH CH3 CH2 ¬¬ CH CH3 ¬ CH2 ¬ ¬ HC CH3 ƒ CH2 HC CH3 ƒ CH2 CH CH3 CH2 ¬ ¬ CH3 CH2CH Self-Test 19.4A (a) Write the formula for the monomer of the polymer sold as Teflon, ß(CF2CF2)nß. (b) The polymer of lactic acid (16) is a biodegradable polymer made from renewable resources. It is used in surgical sutures that dissolve in the body. Write the formula for a repeating unit of this polymer. [Answer: (a) CF2≈CF2; (b) (OCH(CH3)CO)n] Self-Test 19.4B Write the formula for (a) the monomer of poly(methyl methacrylate), used in contact lenses (17); (b) two repeating units of polyalanine, the polymer of the amino acid alanine, CH3CH(NH2)COOH. Most condensation polymers are formed by the reaction of a carboxylic acid with an alcohol to form a polyester or with an amine to form a polyamide. 19.11 Copolymers Copolymers are polymers made up of more than one type of repeating unit (Fig. 19.14). One example is nylon-66, in which the repeating units are formed from 1,6-diaminohexane, H2N(CH2)6NH2, and adipic acid, HOOC(CH2)4COOH. They form an alternating copolymer, in which acid and amine monomers alternate. In a block copolymer, a long segment made from one monomer is followed by a segment formed from the other monomer. One example is the block copolymer formed from styrene and butadiene. Pure polystyrene is a transparent, brittle material that is easily broken; polybutadiene is a synthetic rubber that is very resilient, but soft and opaque. A block copolymer of the two monomers produces high-impact polystyrene, a material that is a durable, strong, yet transparent plastic. A different formulation of the two polymers produces styrene–butadiene rubber (SBR), which is used mainly for automobile tires and running shoes, but also in chewing gum. In a random copolymer, different monomers are linked in no particular order. A graft copolymer consists of long chains of one monomer with shorter chains of the other monomer attached as side groups. For example, the polymer used to make hard contact lenses is a nonpolar hydrocarbon that repels water. The polymer used to make soft contact lenses is a graft copolymer that has a backbone of nonpolar monomers but side groups of a different water-absorbing monomer. So much water is absorbed by the side chains that 50% of the volume of the contact lens is water, which makes it pliable, soft, and more comfortable to wear than a hard contact lens. Composite materials (Section 6.21) differ from copolymers in that the two materials making up the composite retain their identities in the material and the separate regions can be large. Self-Test 19.5A Use Fig. 19.14 to identify the type of copolymer formed by monomers A and B: ßAAAABBBBBß. [Answer: Block copolymer] Self-Test 19.5B Identify the type of copolymer formed by monomers A and B: ßABABABABß. Copolymers combine the advantages of more than one component material. 19.12 Physical Properties of Polymers A polymer can be designed to have the desired properties for an application. The first consideration is chain length. Because synthetic polymers consist of molecules with different lengths, they do not have definite molar masses. We can speak only of the average molar mass and the average chain length of a polymer. Because of the variability in chain length, polymers do not have definite melting points; rather, they soften gradually as the temperature is raised. The viscosity of a polymer, its ability to flow when molten (Section 5.7), depends on its chain length. The longer the chains, the more tangled together they may be, and hence the slower their flow. The mechanical strength of a polymer increases as the strength of the interactions between chains increases. Therefore, the longer the chains, the greater the strength of the polymer. For chains of the same length, stronger intermolecular forces result in greater mechanical strength. The nature of the groups of atoms attached to a polymer affects the strength of intermolecular forces and contributes to the mechanical strength of the polymer. For example, nylon is a polyamide, and so has a series of repeating ßNHß and ß(CO)ß groups that are hydrophilic and can take part in hydrogen bonding. Consequently, nylon is a strong polymer. It is also hygroscopic (absorbs water), because the water molecules are attracted to these polar groups. In contrast, polyethylene is a hydrocarbon that contains only 19.12 PHYSICAL PROPERTIES OF POLYMERS 775 FIGURE 19.14 The classification of copolymers. (a) A simple polymer made from a single monomer represented by the green rectangles. (b) An alternating copolymer of two monomers, represented by the green and orange rectangles. (c) A block copolymer. (d) A graft copolymer. (a) Simple polymer (b) Alternating copolymer (c) Block copolymer (d) Graft copolymer CH2 CH3 C COOCH3 n 17 Poly(methyl methacrylate) CßC and C–H bonds, which are hydrophobic. As a result, whereas polyethylene repels water, water can penetrate through thin nylon fabrics because H2O molecules can migrate by forming and breaking hydrogen bonds to the polymer molecules. The chain-packing arrangements that maximize intermolecular contact result in greater strength as well as greater density. Long, unbranched chains can line up next to one another like uncooked spaghetti and form crystalline regions that result in strong, dense materials. Branched polymer chains cannot fit together as closely and form weaker, less dense materials (Fig. 19.15). A soft, lightweight body armor has been developed by creating arrays of long polyethylene chains that are closely aligned in the same direction, giving rise to very strong intermolecular forces. This body armor is reported to be 15 times stronger than steel, yet has such a low density that it floats on water. It is also soft and flexible, so it is comfortable to wear (Fig. 19.16). FIGURE 19.15 The two samples of polyethylene, a polymer of the hydrocarbon ethene, in the test tube were produced by different processes. The floating (low-density) one was produced by high-pressure polymerization and the chains contain many branches. The one at the bottom (high-density) was produced with a special catalyst that allowed it to pack together uniformly with a minimum of branching. As the insets show, the latter has a higher density because the polymer chains pack together better. FIGURE 19.16 Recruits at the New York Police Academy are issued bullet-proof vests. The high-density polyethylene body armor protects law enforcement personnel without restricting movement because it is soft and flexible. Low-density polyethylene High-density polyethylene Loosely packed polymer chains Tightly packed polymer chains Polyisoprene molecule Disulfide link FIGURE 19.17 The gray cylinders in the small inset represent the long chains of rubber molecules, and the beaded yellow strings represent disulfide (ßSßSß) links that are introduced when the rubber is vulcanized, or heated with sulfur. These cross-links increase the resilience of the rubber and make it more useful than natural rubber. Automobile tires are made of vulcanized rubber and a number of additives, including carbon. Animation 19.17 The elasticity of a polymer is its ability to return to its original shape after being stretched. Natural rubber has long hydrocarbon chains with low elasticity and is easily softened by heating. However, the “vulcanization” of rubber increases its elasticity. In vulcanization, rubber is heated with sulfur. The sulfur atoms form cross-links between the polyisoprene chains and produce a three-dimensional network of atoms (Fig. 19.17). Because the chains are covalently linked together, vulcanized rubber does not soften as much as natural rubber when the temperature is raised. Vulcanized rubber is also much more resistant to deformation when stretched, because the cross-links pull it back. Polymeric materials that return to their original shapes after stretching are called elastomers. However, extensive cross-linking can produce a rigid network that resists stretching. For example, high concentrations of sulfur result in very extensive crosslinking and the hard material called ebonite. Plastics can be distinguished by their reaction to heat. A thermoplastic polymer is one that can be softened again after it has been molded; a thermosetting polymer is one that takes on a permanent shape in a mold and does not soften when heated. Many thermoplastic materials are made of addition polymers and can be recycled by melting and reprocessing. Examples are polyethylene and polyethylene terephthalate (Table 19.3). Thermosetting plastics are used where heat resistance is important. For example, the vulcanized rubber in vehicle tires and the urea-formaledehyde foam used to make plywood are thermosetting plastics. Silicones are synthetic polymeric materials that are based on silicon instead of carbon. They consist of long ßOßSißOßSiß chains with the two remaining bonding positions on each Si atom occupied by organic groups, such as the methyl group, ßCH3 (Fig. 19.18). Silicones are used to waterproof fabrics because their oxygen atoms attach to the fabric, leaving the hydrophobic (water-repelling) methyl groups like tiny, inside-out umbrellas sticking up out of the fabric’s surface. Silicone-based soft materials have a wide variety of medical and personal care uses such as implants, drug delivery, and cosmetics. They are also used in the aerospace and electronics industries as adhesives, insulators, and heat-resistant rubber. Because they are molecular compounds, most polymers are electrical insulators. However, polymers that have alternating double bonds along the chain can be used to conduct electricity (Box 19.1). These conducting polymers tend to have long chains with few branches. Polymers melt over a range of temperatures, and polymers consisting of long chains tend to have high viscosities. Polymer strength increases with increasing chain length and the extent of crystallization. Thermoplastic polymers are recyclable. THE IMPACT ON BIOLOGY At one level, life can be regarded as a collection of hugely complex reactions taking place between organic compounds in oddly shaped containers. Many of these organic compounds are polymers, including the cellulose of wood, natural fibers such as cotton and silk, the proteins and carbohydrates in our food, and the nucleic acids of our genes. 19.13 Proteins Protein molecules are condensation copolymers of up to twenty different naturally occurring amino acids that differ in their side chains (Table 19.4). Our bodies can synthesize eleven amino acids in sufficient amounts for our needs. But we cannot produce the proteins necessary for life unless we ingest the other nine, which are known as the essential amino acids. 19.13 PROTEINS 777 TABLE 19.3 Recycling Codes Recycling code Polymer Recycling code Polymer 1 polyethylene terephthalate 5 polypropylene 2 high-density polyethylene 6 polystyrene 3 polyvinyl chloride 7 other 4 low-density polyethylene 4 LDPE 7 OTHER 3 PVC 6 PS 2 HDPE 5 PP 1 PETE Si O CH3 CH3 O FIGURE 19.18 A typical silicone structure. The hydrocarbon groups give the substance a water-repelling quality. Note the similarity of this structure to that of the purely inorganic pyroxenes in Fig. 6.14. One day, if you want to check your e-mail in a remote location, you might unroll a plastic sheet with a tiny microprocessor embedded in it. When you activate the microprocessor, your messages will appear and you might reply by writing on the screen with a special pen or by speaking to it. The remarkable material of this flat computer already exists: one form of it was discovered by accident in the early 1970s when a chemist who was polymerizing ethyne (acetylene) added a thousand times too much catalyst. Instead of a synthetic rubber, he made a thin, flexible film. It looked like metal foil tinted pink (see the photograph), and—very much like a metal—it conducted electricity. Metals conduct electricity because their valence electrons move easily from atom to atom. Most covalently bonded solids do not conduct electricity, because their valence electrons are locked into individual bonds and are not free to move. Exceptions FRONTIERS OF CHEMISTRY: CONDUCTING POLYMERS*BOX 19.1 This flexible polyacetylene sheet was peeled from the walls of the reaction flask in which it was made. such as graphite and carbon nanotubes have delocalized ␲-bonds in connected aromatic rings through which electrons can move freely because there are empty molecular orbitals close in energy to occupied orbitals (Sections 6.5 and 6.23). However, a disadvantage is that commercial graphite is fragile and brittle. Conducting polymers provide a new and exciting alternative. They are organic compounds that do not rust and they have low densities. They can be molded or drawn into shells, fibers, or thin plastic sheets, but they can still act like metallic conductors. They can be made to glow with almost any color and to change conductivity with conditions. Imagine cases of food labeled with polymer tags that change in conductivity when the cases are left unrefrigerated for too long. All conducting polymers have a common feature: a long chain of sp2 hybridized carbon atoms, often with nitrogen or sulfur atoms included in the chains. Polyacetylene, the first conducting polymer, is also the simplest, consisting of thousands of ßCH≈CHß units: The alternation of double and single bonds means that each C atom has an unhybridized p-orbital that can overlap with the p-orbital on either side. This arrangement allows electrons to be delocalized along the entire chain like a one-dimensional version of graphite. One conducting polymer, polypyrrole, NH NH NH NH TABLE 19.4 The Naturally Occurring Amino Acids, XßCH(NH2)COOH X Name Abbreviation X Name Abbreviation ∫H glycine Gly ∫CH2(CH2)3NH2 lysine* Lys ∫CH3 alanine Ala phenylalanine* Phe ∫CH2(CH2)2NH arginine Arg ∫CH(CH3)2 valine* Val ∫CH2CH(CH3)2 leucine* Leu ∫CH(CH3)CH2CH3 isoleucine* Ile ∫CH2OH serine Ser histidine* His ∫CH(OH)CH3 threonine* Thr tyrosine Tyr tryptophan* Trp ∫CH2COOH aspartic acid Asp ∫CH2CONH2 asparagine Asn ∫CH2CH2COOH glutamic acid Glu ∫CH2CH2CONH2 glutamine Gln ∫CH2SH cysteine Cys ∫CH2CH2SCH3 methionine* Met proline† Pro *Essential amino acids for humans. † The entire amino acid is shown. CH2 OH COOH NH NH CH2 NH CH2 N CH2 C NH2 NH A molecule formed by the condensation of two or more amino acids is called a peptide. An example is the combination of glycine and alanine, denoted Gly-Ala: The ßCOßNHß link shown in the red box is called a peptide bond, and each monomer used to form a peptide is called a residue. A typical protein is a polypeptide chain of more than a hundred residues joined through peptide bonds and arranged in a strict order. When only a few amino acid residues are present, we call the molecule an oligopeptide. The artificial sweetening agent aspartame is a type of oligopeptide called a dipeptide because it has two residues. The primary structure of a protein is the sequence of residues in the peptide chain. Aspartame consists of phenylalanine (Phe) and aspartic acid (Asp), and so its primary structure is Phe-Asp. Three fragments of the primary structure of human hemoglobin are Leu-Ser-Pro-Ala-Asp-Lys-Thr-Asn-Val-Lys- . . . . . . -Val-Lys-Gly-Trp-Ala-Ala- . . . . . . -Ser-Thr-Val-Leu-Thr-Ser-Lys-Ser-Lys-Tyr-Arg The determination of the primary structure of a protein is a very demanding analytical task, but, thanks to automated procedures, many of these structures are now known. Any modification of the primary structure of a protein—the replacement of one amino acid residue by another—may lead to a congenital disease. Even one wrong amino acid in the chain can disrupt the normal function of the molecule (Fig. 19.19). CH2 ¬ ¬ ¬ ¬ ƒ O NHH2N ¬ ®C CH CH3 COOH has been used in smart windows, which darken from a transparent yellow-green to a nearly opaque blue-black in bright sunlight. Fibers of polypyrrole are also woven into radar camouflage cloth that absorbs microwaves. Because it does not reflect microwaves back to their source, the cloth appears on radar as a patch of empty space. Polyaniline, which has the structure is being used in flexible coaxial cable; rechargeable, flat, buttonlike batteries; and laminated, rolled films that could be used as flexible computer or television displays. Thin films of poly-p-phenylenevinylene, PPV, give off light when exposed to an electric field, a process called electroluminescence. By varying the composition of the polymer, scientists have coaxed it to glow in a wide range of colors. Such multicolor light-emitting diode (LED) displays can be as bright as fluorescent ones. HOW MIGHT YOU CONTRIBUTE? Current PPV displays last only about 10% as long as fluorescent displays. If their longevity grows, however, they could replace the computer and television screens that we use today. Polyaniline could one day serve both as a nonmetallic solder for the printed circuit boards inside a computer and as electrical shielding for the case. All-plastic transistors and other electronic components can be miniaturized to an amazing degree, raising the possibility of nanoscale microprocessors and computers that could survive highly corrosive conditions, such as those in the body or at marine research sites. Because conducting polymers can also be designed to change shape with the level of electrical current, they could serve as artificial muscles or give flexibility of movement to robots. For these goals to be achieved, the characteristics of these polymers must be known and their responses to various conditions have to be studied. Related Exercises: 19.91, 19.92 For Further Reading:. S. Günes, H. Neugebauer, and N. S. Sariciftci, “Conjugated polymer-based organic solar cells,” Chemical Reviews, vol. 107, pp. 1324–1338, 2007. D. W. Hatchett and M. Josowicz, “Composites of intrinsically conducting polymers as sensing nanomaterials,” Chemical Reviews, vol. 108, pp. 746–769, 2008. T. A. Skotheim and J. R. Reynolds, Handbook of Conducting Polymers, 3rd edition, CRC Press, 2007. P. Yam, “Plastics get wired,” Scientific American, July 1995, pp. 83–89. Information (advanced) on the Nobel Prize 2000, at http://nobelprize.org/nobel_prizes/chemistry/laureates/2000/adv.html *The 2000 Nobel Prize in chemistry was awarded to A. J. Heeger, A. G. MacDiarmid, and H. Shirakawa for their discovery of conducting polymers. ? N N N FIGURE 19.19 Sickle-shaped red blood cells form when only one amino acid (glutamic acid) in a polypeptide chain is replaced by another amino acid (valine). These cells are less able to take up oxygen than normal cells. 780 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS FIGURE 19.20 A representation of part of an ␣ helix, one of the secondary structures adopted by polypeptide chains. The cylinder encloses the “backbone” of the polypeptide chain, and the side groups project outward from it. The thin lines represent the hydrogen bonds that maintain the helical shape. The secondary structure of a protein is the shape adopted by the polypeptide chain— in particular, how it coils or forms sheets. The order of the amino acids in the chain controls the secondary structure, because their intermolecular forces hold the chains together. The most common secondary structure in animal proteins is the ␣ helix, a helical conformation of a polypeptide chain held in place by hydrogen bonds between residues (Fig. 19.20). One alternative secondary structure is the ␤ sheet, which is characteristic of the protein that we know as silk. In silk, protein molecules lie side by side to form nearly flat sheets. The molecules of many other proteins consist of alternating ␣-helical and ␤-sheet regions (Fig. 19.21). The tertiary structure of a protein is the shape into which its secondary structure is folded as a result of interactions between residues. The globular form of each chain in hemoglobin is an example. One important type of link responsible for tertiary structure is the covalent disulfide link, ßSßSß, between residues containing sulfur. Other links are formed by the various types of intermolecular forces. In most cases, a given protein will fold into a precise three-dimensional conformation determined by the locations of the hydrophobic and hydrophilic groups on the chain (Fig. 19.22). Sometimes, however, the proteins do not fold properly. When this incorrect folding happens in the body, it can lead to illnesses such as Alzheimer’s disease. In Alzheimer’s disease, brain function is constricted by deposits of proteins that have misfolded and can no longer perform their functions. The so-called “prion diseases,” such as variant Creutzfeld– Jakob disease (“mad cow disease”), are also due to protein misfolding. If scientists can solve the puzzle of why proteins misfold and discover how to correct that, then diseases now considered untreatable can be cured. Proteins may also have a quaternary structure, in which neighboring polypeptide units stack together in a specific arrangement. The hemoglobin molecule, for example, has a quaternary structure of four polypeptide units, one of which is shown in Fig. 19.21. FIGURE 19.21 One of the four polypeptide chains that make up the human hemoglobin molecule. The chains consist of alternating regions of ␣ helix and ␤ sheet. The ␣-helix regions are represented by red helices. The oxygen molecules that we inhale attach to the iron atom (blue sphere) and are carried through the bloodstream. Animation 19.21 (a) (b) (c) (d) FIGURE 19.22 These structures show how a protein first forms ␣ helices and ␤ sheets and then how the coils and sheets fold together to form the shape of a protein. Finally, if the protein has a quaternary structure, the protein subunits stack together. (a) Newly formed polypeptide; (b) intermediate; (c) subunit; (d) mature (in this case, dimeric) protein. The structures of some natural protein-based materials, such as silk and wool, result in strong, tough fibers. Spiders and silkworms use proteins as a structural material of remarkable strength (Fig. 19.23). Chemists are duplicating nature by making artificial spider silk (Fig. 19.24), which is one of the strongest fibers known. Materials made of synthetic spider silk represent a great improvement over some conventional materials, because they are lightweight, thin, and flexible. For example, products as diverse as parachutes, artificial ligaments, automobile bumpers, and banknotes have been proposed for synthetic spider silk. The loss of structure by a protein is called denaturation. This structural change may be a loss of quaternary, tertiary, or secondary structure; it may also be degradation of the primary structure by cleavage of the peptide bonds. Even mild heating can cause irreversible denaturation. When we cook an egg, the protein called albumen denatures into a white mass. The “permanent waving” of hair, which consists primarily of long ␣ helices of the protein keratin, is a result of partial denaturation. Proteins are polymers made of amino acid units. The primary structure of a polypeptide is the sequence of amino acid residues; secondary structure is the formation of helices and sheets; tertiary structure is the folding into a compact unit; quaternary structure is the packing of individual protein units together. 19.14 Carbohydrates The carbohydrates are so called because many have the empirical formula CH2O, which suggests a hydrate of carbon. They include starches, cellulose, and sugars such as glucose, C6H12O6 (18), which contains an aldehyde group, and fructose (fruit sugar), a structural isomer of glucose that is a ketone (19). Carbohydrates have many ßOH groups, and so they may also be regarded as alcohols. The presence of these ßOH groups allows them to form numerous hydrogen bonds with one another and with water. The polysaccharides are polymers of glucose. They include starch, which we can digest, and cellulose, which we cannot. Starch is made up of two components: amylose and amylopectin. Amylose, which makes up about 20% to 25% of most starches, consists of chains made up of several thousand glucose units linked together (Fig. 19.25). 19.14 CARBOHYDRATES 781 FIGURE 19.23 The protein produced by spiders to make a web is a form of silk that can be exceptionally strong. H H H H H C C C C C OH OH OH HO CH2OH 18 Glucose, C6H12O6 O H H H C C C C OH OH O HO CH2OH CH2OH 19 Fructose, C6H12O6 FIGURE 19.24 Artificial spider silk can now be made in bulk. It can be spun into thin, tough thread, like that on the spools shown here, or wound into cables strong enough to support suspension bridges. FIGURE 19.25 The amylose molecule, one component of starch, is a polysaccharide, a polymer of glucose. It consists of glucose units linked together to give a structure like the one shown but with a moderate degree of branching. Animation 19.25 Amylopectin is also made up of glucose chains (Fig. 19.26), but its chains are linked into a branched structure and its molecules are much larger. Each molecule consists of about a million glucose units. Cellulose is the structural material of plants. It is a polymer with the same monomer (glucose) that starch has, but the units in cellulose are linked differently, forming flat, ribbonlike strands (Fig. 19.27). Hydrogen bonds between these strands lock them together into a rigid structure that for us (but not for termites) is indigestible. Cellulose is the most abundant organic chemical in the world, and billions of tons of it are produced annually by photosynthesis. In research on alternative fuels, enzymes are used to break down the cellulose in waste biomass into glucose, which is then fermented to make ethanol for use as a fuel (see Box 7.2). Carbohydrates include sugars, starches, and cellulose. Glucose is an alcohol and an aldehyde that polymerizes to form starch and cellulose. 19.15 Nucleic Acids The nucleus of every living cell contains at least one deoxyribonucleic acid (DNA) molecule to control the production of proteins and to carry genetic information from one generation of cells to the next. Human DNA molecules are immense: if a molecule of DNA could be extracted without damage from a cell nucleus and drawn out straight from its highly coiled natural shape, it would be about 2 m long (Fig. 19.28). The ribonucleic acid (RNA) molecule is closely related to DNA. One of its functions is to carry information stored by DNA to a region of the cell where that information can be used in protein synthesis. 782 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS CH2 O FIGURE 19.26 The amylopectin molecule is another component of starch. It has a more highly branched structure than amylose, as emphasized in the inset. (a) FIGURE 19.27 (a) Cellulose is yet another polysaccharide constructed from glucose units. The units in cellulose link together in such a way that they form long, flat ribbons that can produce a fibrous material through hydrogen bonding. (b) These long tubes of cellulose (shown in cross section) form the structural material of an aspen tree. Animation 19.27 (b) DNA is a polymer with a backbone built of repeating units derived from the sugar ribose (20). For DNA, the ribose molecule has been modified by removing the oxygen atom at carbon atom 2, the second carbon atom clockwise from the ether oxygen atom in the five-membered ring. Therefore, the repeating unit—the monomer—is called deoxyribose (21). Attached by a covalent bond to carbon atom 1 of the deoxyribose ring is an amine (and therefore a base), which may be adenine, A (22); guanine, G (23); cytosine, C (24); or thymine, T (25). In RNA, uracil, U (26), replaces thymine. The base bonds to carbon atom 1 of deoxyribose through the nitrogen of the ßNHß group (printed in red); and the compound so formed is called a nucleoside. All nucleosides have a similar structure, which we can summarize as the shape shown in (27); the lens-shaped object represents the attached amine. The DNA monomers are each completed by a phosphate group, ßOßPO3 2Ϫ , covalently bonded to carbon atom 5 of the ribose unit to give a compound called a nucleotide (28). Because there are four possible nucleoside monomers (one for each base), there are four possible nucleotides in each type of nucleic acid. Molecules of DNA and RNA are polynucleotides, polymeric species built from nucleotide units. Polymerization takes place when the phosphate group of one nucleotide (which is the conjugate base of an organic phosphoric acid) condenses with the ßOH group on carbon atom 3 of the ribose unit of another nucleotide, thereby forming an ester link and releasing a molecule of water. As this condensation continues, it results in a structure like that shown in Fig. 19.29, a compound known as a nucleic acid. The DNA molecule itself is a double helix in which two long nucleic acid strands are wound around each other. The ability of DNA to replicate lies in its double-helical structure. There is a precise correspondence between the bases in the two strands. Adenine in one strand always forms two hydrogen bonds to thymine in the other, and guanine always forms three hydrogen bonds to cytosine; so, across the helix, the base pairs are always AT and GC (Fig. 19.30). Any other combination would not be held together as well. During replication of the DNA, the hydrogen bonds, which are relatively weak compared with the H HH H H O OϪ O P O OH O CH2 28 A nucleotide N Base Ϫ H HH H H O OH HO CH2 27 A nucleoside N Base 26 Uracil N H O O HN 25 Thymine N H O O HN CH3 24 Cytosine N H O NH2 N 23 Guanine N N N H O H2N HN 22 Adenine N N N N H NH2 H H H H O OH HHO HOCH2 21 Deoxyribose, C5H10O4 H H H H O OH OHHO HOCH2 20 Ribose, C5H10O5 19.15 NUCLEIC ACIDS 783 FIGURE 19.28 A DNA molecule is very large, even in bacteria. In this micrograph, a DNA molecule has spilled out through the damaged cell wall of a bacterium. covalent bonds in the strands, can be broken by an enzyme while the strands themselves remain intact. Nucleotides in the cellular fluid then attach in the appropriate places on each strand to form the double helices of two new molecules of DNA. As well as replication—the production of copies of itself for reproduction and cell division—DNA governs the production of proteins by serving as the template during the synthesis of molecules of RNA. The RNA molecules, with U in place of T, are considered to be “messenger” molecules, because they carry information about segments of the genetic message out of the cell nucleus to the locations where protein synthesis takes place. In this way, the chemical reactions of functional groups, and in a broader sense, the principles of chemistry, bring matter to life. Nucleic acids are copolymers of four nucleotides joined by phosphate ester links. The nucleotide sequence stores all genetic information. 784 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS FIGURE 19.29 The condensation of nucleotides that leads to the formation of a nucleic acid, a polynucleotide. CH2 CH2O O O O O O− O− ϩ H2O −O HO CH2 O O O H ϩ HO P O−−O P O O−−O P CH2 O O O O HO P N N N N ∫B Base pairs C G T A FIGURE 19.30 The bases in the DNA double helix fit together by virtue of the hydrogen bonds that they can form, as shown on the left. Once formed, the AT and GC pairs are almost identical in size and shape. As a result, the turns of the helix shown on the right are regular and consistent. EXERCISES 785 ❑ 1 Recognize a simple haloalkane, alcohol, ether, phenol, aldehyde, ketone, carboxylic acid, amine, amide, or ester, given a molecular structure. ❑ 2 Predict the oxidation products of aldehydes and ketones (Section 19.5). ❑ 3 Write the structural formula of an ester or an amide formed from the condensation reaction of a given carboxylic acid with a given alcohol or amine (Sections 19.7 and 19.8). ❑ 4 Predict the influence of hydrogen bonding on the physical properties of organic compounds (Self-Test 19.2). ❑ 5 Name simple functional groups (Toolbox 19.1 and Example 19.1). ❑ 6 Predict the type of polymer that a given monomer can form and identify monomers, given the repeating unit of a polymer (Example 19.2). ❑ 7 Distinguish the various types of copolymers (Self-Test 19.5). ❑ 8 Explain the role of chain length, crystallinity, network formation, cross-linking, and intermolecular forces in determining the physical properties of polymers (Section 19.12). ❑ 9 Describe the composition of proteins and distinguish their primary, secondary, tertiary, and quaternary structures (Section 19.13). ❑ 10 Describe the composition of carbohydrates (Section 19.14). ❑ 11 Describe the structures and functions of nucleic acids (Section 19.15). SKILLS YOU SHOULD HAVE MASTERED Identifying Functional Groups and Naming Their Compounds 19.1 Write the general formula of each of the following types of compounds, using R to denote an organic group: (a) amine; (b) alcohol; (c) carboxylic acid; (d) aldehyde. 19.2 Write the general formula of each of the following types of compounds, using R to denote an organic group: (a) ether; (b) ketone; (c) ester; (d) amide. 19.3 Identify each type of compound: (a) RßOßR; (b) RßCOßR; (c) RßNH2; (d) RßCOOR. 19.4 Identify each type of compound: (a) RßCHO; (b) RßCOOH; (c) RßCONHR; (d) RßOH. 19.5 Name the following compounds: (a) CH3CHClCH3; (b) CH3CH2C(CH3)ClCH2CHClCH3; (c) CH3CI3; (d) CH2Cl2. 19.6 Name the following compounds: (a) CH3CH2CHO; (b) CH2CHCH2CH2OH; (c) CH3CCCH2CH2CH2Cl; (d) CH3CH2COCH2CH2CH3. 19.7 Write the formulas of the following compounds and state whether each one is a primary, secondary, or tertiary alcohol or a phenol: (a) 1-chloro-2-hydroxybenzene; (b) 2-methyl-3-pentanol; (c) 2,4-dimethyl-1-hexanol; (d) 2-methyl-2-butanol. 19.8 Write the formulas of the following compounds and state whether each one is a primary, secondary, or tertiary alcohol or a phenol: (a) 2-methyl-1-propanol; (b) 2-propanol; (c) p-hydroxytoluene; (d) 1-bromo-2-(hydroxymethyl)benzene. 19.9 Write the formula of (a) ethyl methyl ether, (b) ethyl propyl ether; (c) dimethyl ether. 19.10 Write the formula of (a) dipropyl ether; (b) dipentyl ether; (c) ethyl propyl ether. 19.11 Name each compound: (a) CH3CH2CH2OCH2CH2CH2CH3; (b) C6H5OCH3; (c) CH3CH2CH2OCH2CH2CH2CH2CH3. 19.12 Name each compound: (a) CH3CH2CH2OCH3; (b) CH3CH2OCH2CH2CH2CH2CH3; (c) CH3CH2CH2CH2OCH2CH2CH2CH3. 19.13 Identify each compound as an aldehyde or a ketone and give its systematic name: (a) CH3CHO; (b) CH3COCH3; (c) (CH3CH2)2CO. 19.14 Identify each compound as an aldehyde or a ketone and give its systematic name: (a) CH3CH2CHO; (b) (c) (CH3CH2)2CHCH2COCH3 19.15 Write the structural formula of (a) butanal; (b) 3-hexanone; (c) 2-heptanone. 19.16 Write the structural formula of (a) 2-ethyl-2-methylpentanal; (b) 3,5-dihydroxy-4-octanone; (c) 4,5-dimethyl-3-hexanone. 19.17 Give the systematic name of (a) CH3COOH; (b) CH3CH2CH2COOH; (c) CH2(NH2)COOH. 19.18 Give the systematic name of (a) CH3CH(CH3)CH2COOH; (b) CH2ClCH2COOH; (c) CH3(CH2)7COOH. 19.19 Draw the structure of (a) benzoic acid, C6H5COOH; (b) 2-chloro-3-methylpentanoic acid; (c) hexanoic acid; (d) propenoic acid. 19.20 Draw the structure of (a) 2-methylpropanoic acid; (b) 2,2-dichlorobutanoic acid; (c) 2,2,2-trifluoroethanoic acid; (d) 4,4-dimethylpentanoic acid. 19.21 Give the systematic name of each of the following amines: (a) CH3NH2; (b) (CH3CH2)2NH; (c) o-CH3C6H4NH2. 19.22 Give the systematic name of each of the following amines: (a) CH3CH2CH2NH2; (b) (CH3CH2)4Nϩ ; (c) p-ClC6H4NH2. 19.23 Write the structural formula of each of the following amines: (a) o-methylphenylamine; (b) triethylamine; (c) tetramethylammonium ion. 19.24 Write the structural formula of each of the following amines: (a) methylpropylamine; (b) dimethylamine; (c) m-methylphenylamine. Reactivity Patterns and Functional Groups 19.25 Which of the following molecules or ions may function as a nucleophile in a nucleophilic substitution reaction: (a) NH3; (b) CO2; (c) BrϪ ; (d) SiH4? 19.26 Which of the following molecules or ions may function as a nucleophile in a nucleophilic substitution reaction: (a) OHϪ ; (b) NH4 ϩ ; (c) NH2 Ϫ ; (d) H2O? ¬¬ CHOH3C EXERCISES 19.27 Suggest an alcohol that could be used for the preparation of each of the following compounds and indicate how the reaction would be carried out; (a) ethanal; (b) 2-octanone; (c) 5-methyloctanal. 19.28 Suggest an alcohol that could be used for the preparation of each of the following compounds and indicate how the reaction would be carried out: (a) propanal; (b) 2-pentanone; (c) 5-ethyl-3-nonanone. 19.29 Draw the structure of the principal product formed from each of the following condensation reactions: (a) butanoic acid with 2-propanol; (b) ethanoic acid with 1-pentanol; (c) hexanoic acid with methylethyl amine; (d) ethanoic acid with propylamine. 19.30 Draw the structure of the principal product formed from each of the following condensation reactions: (a) octanoic acid with methanol; (b) propanoic acid with ethanol; (c) propanoic acid with methylamine; (d) methanoic acid with diethylamine. 19.31 Classify each of the following reactions as (1) an addition reaction, (2) a nucleophilic substitution reaction, (3) an electrophilic substitution reaction, or (4) a condensation reaction: (a) the reaction of 1-butene with chlorine in the absence of light; (b) the polymerization of the amino acid glycine; (c) the hydrogenation of 1-butyne; (d) the polymerization of styrene, CH2CHC6H5; (e) the reaction of methylamine with butanoic acid. 19.32 Classify each of the following reactions as (1) an addition reaction, (2) a nucleophilic substitution reaction, (3) an electrophilic substitution reaction, or (4) a condensation reaction: (a) the reaction of terephthalic acid with 1,2-ethanediol; (b) the reaction of 3-chlorohexane with concentrated sodium hydroxide; (c) the reaction of water with 2-iodo-2-methylpropane; (d) the reaction of propanoic acid with ethanol; (e) the reaction of toluene with bromine in the presence of FeBr3. 19.33 You are given samples of propanal, 2-propanone, and ethanoic acid. Describe how you would use chemical tests, such as acid–base indicators and oxidizing agents, to distinguish among the three compounds. 19.34 You are given samples of 1-propanol, pentane, and ethanoic acid. Describe how you would use chemical tests, such as aqueous solubility and acid–base indicators, to distinguish among the three compounds. 19.35 Rank the following acids in order of increasing acid strength: ClCH2COOH, Cl3CCOOH, CH3COOH, and CH3CH2COOH. Justify your answer. 19.36 Rank methylamine, dimethylamine, and diethylamine in order of increasing base strength. Explain your rankings in relation to molecular structure. Polymers 19.37 Sketch three repeating units of the polymer formed from (a) CH2≈C(CH3)2; (b) CH2≈CHCN; (c) isoprene, . 19.38 Sketch three repeating units of the polymer formed from (a) tetrafluoroethene; (b) phenylethene; (c) CH3CHϭCHCH3. 19.39 A polyamide has the repeating unit ß(COC6H12CONHC6H4NH)nß. Identify the monomers of the polyamide. 19.40 A polyester has the repeating unit ß(OCH2C6H4CH2OOCC6H4CO)nß. Identify the monomers of the polyester. 19.41 Write the structural formulas of the monomers of each of the following polymers, for which one repeating unit is shown: (a) polyvinylchloride (PVC), ß(CHClCH2)nß; (b) Kel-F, ß(CFClCF2)nß. 19.42 Write the structural formulas of the monomers of each of the following polymers, for which one repeating unit is shown: (a) a polymer used to make carpets, ß(OC(CH3)2CO)nß; (b) ß(CH(CH3)CH2)nß; (c) a polypeptide, ß(NHCH2CO)nß. 19.43 Write the structural formula of two units of the polymer formed from (a) the reaction of oxalic acid (ethanedioic acid), HOOCCOOH, with 1,4-diaminobutane, H2NCH2CH2CH2CH2NH2; (b) the polymerization of the amino acid alanine (2-aminopropanoic acid). 19.44 Write the structural formula of two units of the polymer formed from (a) the reaction of terephthalic acid with 1,2-diaminoethane, H2NCH2CH2NH2; (b) the polymerization of 4-hydroxybenzoic acid. 19.45 Identify the type of copolymer formed by monomers A and B: ßBBBBAAß. 19.46 Identify the type of copolymer formed by monomers A and B: ßAABABBAAß. 19.47 Why do polymers not have definite molar masses? How does the fact that polymers have average molar masses affect their melting points? 19.48 Rank the following polymers according to increasing value as fibers: polyesters, polyamides, polyalkenes. Explain your reasoning. 19.49 How does average molar mass (which is proportional to the chain length) affect each of the following polymer characteristics: (a) softening point; (b) viscosity; (c) strength? 19.50 How does the polarity of the side chains in a polymer affect each of the following characteristics of the polymer: (a) softening point; (b) viscosity; (c) strength? 19.51 Describe how the linearity of the polymer chain affects polymer strength. 19.52 Describe how cross-linking affects the elasticity and rigidity of a polymer. Biological Compounds 19.53 (a) Draw the structure of the peptide bond that links the amino acids in proteins. (b) Identify the functional group formed. (c) Identify the type of polymer formed (addition or condensation). 19.54 (a) Draw the structure of the link between glucose units that creates amylose. (b) Identify the functional group formed. (c) Identify the type of polymer formed (addition or condensation). 19.55 Name the amino acids in Table 19.4 that contain side groups capable of forming hydrogen bonds. This interaction contributes to the tertiary structure of a protein. 4-Hydroxybenzoic acid HO O C OH Terephthalic acid HO OH O O C C CH3 CH2H2C H 786 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS 19.56 Name the amino acids in Table 19.4 that contain nonpolar side groups. These groups contribute to the tertiary structure of a protein by preventing contact with water. 19.57 Draw the structure of the peptide formed from the reaction of the acid group of tyrosine with the amine group of glycine. 19.58 Draw the structure of the peptide formed from the reaction of the acid group of glycine with the amine group of tyrosine. 19.59 Identify (a) the functional groups and (b) the chiral carbon atoms in the mannose molecule shown here. 19.60 Identify (a) the functional groups and (b) the chiral carbon atoms in the histidine molecule shown here. 19.61 Write the complementary nucleic acid sequence that would pair with each of the following DNA sequences: (a) CATGAGTTA; (b) TGAATTGCA. 19.62 Write the complementary nucleic acid sequence that would pair with each of the following DNA sequences: (a) ATTAGATCAT; (b) GACTAGGATCT. Integrated Exercises 19.63 Write the chemical formula of the compound represented by each of the following line structures: 19.64 Write the chemical formula of the compound represented by each of the following line structures: 19.65 Identify all the functional groups in each of the following compounds: (a) vanillin, the compound responsible for vanilla flavor, (b) carvone, the compound responsible for spearmint flavor, (c) caffeine, the stimulant in coffee, tea, and cola drinks, 19.66 Identify all the functional groups in each of the following compounds: (a) zingerone, the pungent, hot component of ginger, (b) Tylenol, an analgesic, (c) procaine, a local anesthetic, 19.67 Identify the chiral carbon atoms in each of the following compounds: (a) camphor, used in cooling salves, (b) testosterone, a male sex hormone, O OH O NH2 O O N NH O OH O O HO N N N O O N O O CHOHO HO O (c) Eugenol N N N NH2 NH (b) Adenine OHHS OH2N (a) Cysteine OH OH2N (c) Alanine CHO CH2OH (b) D-Glucose H HO H H OH H OH OH N N HN O H2N NH (a) Guanine HN N O OHH2N H O C C C C C CH2OH H OH H OH OH H OH H EXERCISES 787 19.68 Identify the chiral carbon atoms in each of the following compounds: (a) menthol, the flavor of peppermint, (b) estradiol, a female sex hormone, 19.69 The structures of the following molecules can be found on the Web site for this text. Draw the structure of each and identify its chiral carbon atoms: (a) cocaine; (b) aflatoxin B2, a toxin and carcinogen that occurs naturally in peanuts as a by-product of the growth of fungi. 19.70 The structures of the following molecules can be found on the Web site for this text. Draw the line structure of each and identify its chiral carbon atoms: (a) cephalosporin C, toxic to penicillin-resistant staphylococci; (b) thromboxane A2, a substance that promotes the clotting of blood. 19.71 Three compounds that could be produced biologically and used as fuels are methylamine, H2NCH3, a gas that occurs in herring brines and animal urine, dimethyl ether, CH3OCH3, a gas that can be produced from methanol, and acetic acid, H3CCOOH, a liquid (⌬Hvap ϭ 23.70 kJ·mol–1 ) obtained from the fermentation of sugars. (a) Draw the Lewis structures of each of these compounds. (b) Use bond enthalpies to calculate the specific enthalpy of combustion of each fuel (the enthalpy of combustion per gram of fuel), assuming that they burn to produce gaseous CO2, liquid H2O, and in the case of glycine, N2. (c) Look up these compounds and their toxicity in reference books such as The Merck Index or the Handbook of Chemistry and Physics. Would any make a useful fuel in their pure form? 19.72 A carbon tax has been proposed to limit emissions of carbon dioxide. If fuel were taxed at the rate of $100 per tonne (1 t ϭ 103 kg) of carbon, what would be the tax on 10.0 kg of (a) methane, (b) octane, a major component of gasoline, (c) ethanol, (d) peat (approximately 50% carbon), (e) anthracite coal (approximately 95% carbon). 19.73 (a) Write the structural formulas of diethyl ether and 1-butanol (note that they are isomers). (b) The boiling point of 1-butanol is 117°C, higher than that of diethyl ether (35°C), yet the solubility of both compounds in water is about 8 g per 100 mL. Account for these observations. 19.74 Consider the following organic molecules, which have approximately the same molar masses but contain different functional groups: CH3CH2CH2CH2CH2CH3, CH3CH2CH2CH2CHCH2, CH3CH2CH2CH2CH2OH, CH3CH2CH2CH2CHO, CH3CH2CH2COOH, CH3CH2COOCH3, CH3CH2COCH2CH3, CH3CH2CH2CH2OCH3. (a) Draw a Lewis structure for each molecule, name it, and classify it by functional group. (b) Which molecules are isomers of each other? Are any chiral? If so, which ones? (c) For each molecule, list the types of intermolecular forces that are present. (d) Use your answers to parts (a) and (b) to predict the relative boiling points, from lowest to highest. 19.75 Write the structural formula for the product of (a) the reaction of glycerol (1,2,3-trihydroxypropane) with stearic acid, CH3(CH2)16COOH, to produce a saturated fat; (b) the oxidation of 4-hydroxybenzyl alcohol by sodium dichromate in an acidic organic solvent. 19.76 Pheromones are commonly called sex attractants, although they have other signaling functions, too. A pheromone of the queen bee is trans-CH3CO(CH2)5CH≈CHCOOH. (a) Write the structural formula of the pheromone. (b) Identify and name the functional groups in the molecule. 19.77 Write the condensed structural formulas of the principal products of the reaction that takes place when (a) ethylene glycol, 1,2-ethanediol, is heated with stearic acid, CH3(CH2)16COOH; (b) ethanol is heated with oxalic acid, HOOCCOOH; (c) 1-butanol is heated with propanoic acid. 19.78 The pKa values for phenol, o-nitrophenol, m-nitrophenol, and p-nitrophenol are 9.89, 7.17, 8.28, and 7.15, respectively. Explain the origin of these differences in pKa. 19.79 Acrylic resins are polymeric materials used to make warm yet lightweight garments. The osmotic pressure of a solution prepared by dissolving 47.7 g of an acrylic resin in enough water to make 500. mL of solution is 0.325 atm at 25°C. (a) What is the average molar mass of the polymer? (b) How many monomers constitute the “average” molecule? The repeating unit of this acrylic resin has the formula ßCH2CH(CN)ß. (c) What would be the vapor pressure of the solution if the vapor pressure of pure water at 25°C is 0.0313 atm? (Assume that the density of the solution is 1.00 gиcmϪ3 .) (d) Which approach (osmometry or the lowering of vapor pressure) would you prefer for the determination of very high molar masses such as those of acrylic resins? Why? 19.80 The average molar mass of a sample of polypropylene was determined by measuring the osmotic pressure of 500. mL of a solution of 3.16 g of polypropylene in benzene. A pressure of 0.0112 atm was observed at 25°C. (a) What is the average molar mass of the polymer? (b) How many propene monomer units with formula ßCH(CH3)CH2ß were combined on average to create each chain? (c) If this sample consists only of linear chains and the carbon–carbon bond lengths in the polymer are close to their average value, what is the average chain length? 19.81 (a) Explain the differences among the primary, secondary, tertiary, and quaternary structures of a protein. (b) Identify the forces holding each structure together as covalent bonds or primarily intermolecular forces. 19.82 Haloalkanes may react with hydroxide ions, undergoing nucleophilic displacement of the halide ion to form an alcohol. A complication of such reactions is competition from elimination reactions rather than substitution (see Section 18.5). (a) Predict the possible products from the reaction of 2-bromopentane with sodium hydroxide. (b) What can be done to favor the substitution reaction over the elimination pathway or vice versa? 19.83 The protonated form of glycine (ϩ H3NCH2COOH) has Ka1 ϭ 4.47 ϫ 10Ϫ3 , and Ka2 ϭ 1.66 ϫ 10Ϫ10 . (a) Write the chemical equations for the proton transfer equilibria. (b) What is the dominant form of glycine in solution at pH ϭ 2, pH ϭ 5, and pH ϭ 12? HO OH OH 788 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS 19.84 In the amide group, rotation is restricted about the CßN bond, so that the C, N, and O atoms in that group are normally in the same plane. This rigidity helps to form the primary structure of proteins. The amino acid glycine can form a dipeptide, composed of two glycine monomers. (a) Draw the Lewis structure of the glycine dipeptide. (b) Explain how resonance structures can account for the restricted rotation and draw a second resonance structure for the dipeptide. 19.85 Explain the process of condensation polymerization. How might the polymer obtained from benzene-1,2-dicarboxylic acid and ethylene glycol differ from Dacron? 19.86 The average molar mass of a hydrogen-bonded pair of nucleotides in a DNA molecule is 625 g·mol–1 . Each successive pair is found at a distance of 340 pm along the chain. If the total length of one strand of a DNA molecule is 0.299 m, what is the molar mass of the molecule? 19.87 A segment of a protein is analyzed and found to contain the amino acid sequence Glu-Leu-Asp. Draw the Lewis structure of this segment, showing the peptide bonds. 19.88 Ferritin is a globular iron-storage protein that stores iron as Fe3ϩ . To leave the ferritin, Fe3ϩ must first be reduced to Fe2ϩ . Ferritin has two types of channels through which the Fe2ϩ could leave: a “three-fold channel” and a “four-fold channel.” The threefold channel is lined with the amino acids aspartate (Asp) and glutamate (Glu) and the four-fold channel is lined with the amino acid leucine (Leu). Through which channel is the Fe2ϩ more likely to leave the ferritin protein? Explain your answer. 19.89 A silicone oil being studied for use in artificial limbs has a structure in which each silicon atom in the ß(OßSißOßSiß)nß backbone is attached to two methyl groups (see Fig. 19.18). Draw the molecular structure of three repeating units of this oil. 19.90 The polyphosphazenes, which are being used as heatresistant polymers in the aerospace industry and as flexible scaffolds for bone regeneration, are inorganic polymers with the repeating unit (ßPR2≈Nß)n, in which R stands for side chains such as ßCH3 groups. How would you expect the properties of the polyphosphazene with methyl group side chains to differ from those of the corresponding silicone polymer (see Fig. 19.18)? Explain your reasoning. 19.91 The monomer of the conducting polymer polyaniline is the compound aniline (aminobenzene). (a) Draw the structural formula of the aniline monomer. What is the hybridization of the N atom in (b) aniline? (c) polyaniline? (d) Indicate the locations of lone pairs, if any, in polyaniline. (e) Do the N atoms help to carry the current? Explain your reasoning. See Box 19.1. 19.92 Fibers of the conducting polymer polypyrrole are woven into radar camouflage cloth. Because it absorbs microwaves, rather than reflecting them back to their source, the cloth appears to be a patch of empty space on radar.(a) What is the hybridization of the N atom in polypyrrole? (b) Explain why polypyrrole absorbs microwave radiation, but small organic molecules do not. See Box 19.1 for the structure of polypyrrole. For the following nine exercises, see Major Technique 7, Nuclear Magnetic Resonance, following this chapter. 19.93 Predict the features of the 1 H NMR spectrum of ethanal, CH3CHO. 19.94 Predict the features of the 1 H NMR spectrum of propane. 19.95 Explain the features of the following 1 H NMR spectrum of ethyl-3,3-dimethylbutanoate. 19.96 The 1 H NMR spectra of (a) 2-butanone and (b) ethyl acetate are shown here. The spectra are very similar yet have some important differences. Explain the observed similarities and differences. 19.97 When propane is treated with chlorine gas, a mixture of compounds results. The mixture is separated and analysis of one of the components gives the 1 H NMR spectrum shown here. What is this product? 19.98 Other nuclei besides the proton have a nuclear spin of and, in principle at least, may be suitable for nuclear magnetic resonance spectroscopy. From standard literature sources, find at 1 2 8.0 7.0 6.0 5.0 4.0 3.0 2.0 1.0 0 * Tetramethylsilane * δ 8.0 7.0 6.0 5.0 4.0 3.0 2.0 1.0 0 (b) * Tetramethylsilane * δ 8.0 7.0 (a) 6.0 5.0 4.0 3.0 2.0 1.0 0 * Tetramethylsilane * δ 8.0 7.0 6.0 * Tetramethylsilane * 5.0 4.0 δ 3.0 2.0 1.0 0 EXERCISES 789 least five other naturally occurring, nonradioactive elements that have spin of and that can be examined by NMR spectroscopy. 19.99 One naturally occurring isotope of carbon is suitable for NMR spectroscopy. (a) From literature sources, determine which isotope of carbon has a spin of . (b) What is the natural abundance of this isotope of carbon? (c) Given that only nuclei having a nuclear spin may interact to produce fine structure in an NMR spectrum, do you expect to see the splitting due to interactions between adjacent carbon atoms in an organic molecule such as propane in its carbon NMR spectrum? (d) Do you expect to see splitting of the proton signal in the 1 H NMR spectrum of propane due to the interactions between the carbon and the proton nuclei? (e) Do you expect to see splitting of the carbon signal in the carbon NMR spectrum of propane due to the interactions between the carbon and the proton nuclei? 19.100 Predict the features of the 1 H NMR spectra of benzene and the three isomeric dichlorobenzenes. Is it possible to distinguish the isomeric dichlorobenzenes on the basis of their NMR spectra alone? 19.101 The NMR spectrum of a compound can reveal whether the atoms within the molecule are equivalent or different. For example, the hydrogen atoms in CH2≈CH2 are equivalent: they all exist in an identical environment. However, in CH2≈CHCl, the two hydrogen atoms attached to the same carbon atom are equivalent, but different from the hydrogen atom on the other carbon atom. Predict how many different types of hydrogen atoms can be identified in the 1 H NMR spectrum of each of the following molecules: (a) C2H2; (b) cis-C2H2Cl2; (c) trans-C2H2Cl2; (d) CH3OH. (e) In the molecule C2H5Cl, the hydrogen atoms would all be different if the molecule existed in only one conformation. However, only two types of hydrogen atoms are detected. Propose an explanation. Chemistry Connections 19.102 Waste reduction is an important goal of the green chemistry movement. In many chemical syntheses in industry, not all the atoms required for the reaction appear in the product. Some end up in by-products and are wasted. “Atom economy” is the use of as few atoms as possible to reach an end product and is calculated as a percentage, using atom economy ϭ (mass of desired product obtained)/(mass of all reactants consumed) ϫ 100%. (a) Consider the following synthesis of CH3CH≈CHCH3: CH3CH2CHBrCH3 ϩ CH3CH2OϪ ∫∫ ethanol ∫∫B CH3CHϭCHCH3 ϩ CH3CH2OH ϩ BrϪ Identify the type of reaction (substitution, elimination, addition). (b) Name each organic reactant and product. (c) Does the CH3CH2O– ion function as a nucleophile, an electrophile, or neither? (d) Calculate the atom economy of the reaction, assuming 100% yield. (e) An alternative synthesis of CH3CH≈CHCH3 is CH3CH2CHBrCH3 ϩ CH3OϪ methanol ∫∫ ∫∫B CH3CHϭCHCH3 ϩ CH3OH ϩ BrϪ Calculate the atom economy for the reaction, assuming 100% yield. (f) Another alternative synthesis of CH3CH≈CHCH3 is CH3CH2CHBrCH3 ϩ CH3SϪ methanethiol CH3CHϭCHCH3 ϩ CH3SH ϩ BrϪ Calculate the atom economy for the reaction, assuming 100% yield. (g) Which of the three syntheses produces the lowest mass of waste? Which produces the highest? (h) Assume that you carry out each of the three syntheses, starting with 50.0 g of CH3CH2CHBrCH3 and with the second reagent in excess in each case. Your yields of CH3CH≈CHCH3 for the three reactions are as follows: (a) 16.2 g; (e) 15.4 g; (f) 13.1 g. Calculate the percentage yield and experimental atom economy for each reaction. (i) Which reaction would you recommend to a manufacturer? Explain your reasoning. 1 2 1 2 790 CHAPTER 19 ORGANIC CHEMISTRY II: POLYMERS AND BIOLOGICAL COMPOUNDS ∫∫∫∫∫∫B Nuclear magnetic resonance (NMR) is the principal technique for the identification of organic compounds and is among the leading techniques for the determination of their structures. The technique has also been developed, as magnetic resonance imaging (MRI), as a diagnostic procedure in medicine. The Technique Many atomic nuclei behave like small bar magnets, with energies that depend on their orientation in a magnetic field. An NMR spectrometer detects transitions between these energy levels. The nucleus most widely used for NMR is the proton, and we shall concentrate on it. Two other very common nuclei, those of carbon-12 and oxygen-16, are nonmagnetic, so they are invisible in NMR. Like an electron, a proton possesses the property of spin, which for elementary purposes can be thought of as an actual spinning motion. Because a proton has an electric charge and because a moving charge generates a magnetic field, a proton acts as a tiny bar magnet that can have either of two orientations, which are denoted ↑ (or ␣) and ↓ (or ␤). In the presence of a magnetic field these two orientations have different energies. If the sample is exposed to electromagnetic radiation, the nuclei are flipped from one orientation to another when the energy of the incoming photons (which is h␯, where ␯ is the frequency of the radiation) matches the energy separation of the two spin orientations. The strong coupling between nuclei and radiation that occurs when this condition is satisfied is called resonance. At resonance, the radiation is strongly absorbed and a sharp peak appears in the detector output. Superconducting magnets are used to generate very high magnetic fields, and resonance requires radio-frequency radiation at about 500 MHz. Each proton in a compound comes into resonance at a frequency related to its location in the molecule. Figure 1, for instance, shows the NMR spectrum of ethanol; and we see that there are three groups of peaks and a characteristic pattern of splitting within the groups. Because all compounds that contain hydrogen give a characteristic NMR fingerprint, or pattern of peaks, many can be recognized by comparing the observed pattern with a library of patterns from known substances or by calculating the expected pattern of lines. The Chemical Shift The separation of the absorption into groups of lines is due to the different proton environments within the molecule. Thus, in ethanol, CH3CH2OH, three protons are present in the methyl group (CH3), two are present in the methylene group (CH2), and one is present in the hydroxyl group (OH). The applied magnetic field acts on the electrons in these three groups and causes them to circulate throughout the nuclear framework. These circulating charged particles give rise to an additional magnetic field, and so NUCLEAR MAGNETIC RESONANCEMAJOR TECHNIQUE 7 the protons in each of the three groups experience a local magnetic field that is not the same as the applied magnetic field. Because the electronic structure in each of the groups is different, the protons in each group experience slightly different local magnetic fields. As a result, slightly different radio-frequency fields are needed to bring them into resonance, and three groups of peaks are observed in the NMR spectrum. We say that each group of protons has a characteristic chemical shift. The measurement of the chemical shift helps to identify the type of group responsible for the absorption and indicates what groups are present in the molecule. The chemical shift of a group of lines is expressed in terms of the ␦ scale (delta scale), which measures the difference in absorption frequency between the sample (␯) and a standard (␯°): The standard is typically tetramethylsilane, Si(CH3)4, which has a lot of protons and dissolves in many samples without reaction. Each group has a characteristic chemical shift, although the precise value depends on the other groups attached to the group of interest. For instance, if we observe a resonance at d ϭ 1, we can be reasonably confident that it arises from a methyl group in an alcohol.* The intensities (heights) of the peaks are proportional to the numbers of protons that they represent. The three peaks in the ethanol spectrum, for example, have overall intensities in the ratio 3 : 2 : 1, which is what we would expect for the three methyl, two methylene, and one hydroxyl protons. d = n - n° n° * 106 4 3 2 1 δ Fine structure CH3CH2OH CH3CH2OH CH3CH2OH FIGURE 1 The NMR spectrum of ethanol. The red letters denote the protons that give rise to the associated peaks. 791 (continued) The Fine Structure The fine structure of the spectrum is the splitting of the resonance into sharp peaks. Note that the methyl resonance in ethanol at d ϭ 1 consists of three peaks with intensities in the ratio 1 : 2 : 1. The fine structure arises from the presence of other magnetic nuclei close to the protons undergoing resonance. The fine structure of the methyl group in ethanol, for instance, arises from the presence of the protons in the neighboring methylene group. Let’s imagine that we are a proton in the methyl group in ethanol and can sense the spins of the two neighboring methylene (ßCH2ß) group protons. There are four possible orientations of these two spins: ␣␣, ␣␤, ␤␣, and ␤␤. Suppose our neighbors have ␣␣ spins. This arrangement gives rise to a magnetic field that we experience in addition to the applied magnetic field; so we (the methyl protons) come into resonance at the corresponding frequency. If we are in a molecule in which our neighbors are ␤␤, we experience a different local magnetic field, and we come into resonance at a different frequency. If our neighbors happen to be either ␣␤ or ␤␣, the magnetic field arising from the ␣ spin cancels the field arising from the ␤ spin; so the local field that we experience is the same as it would be in the absence of any neighbors, and we resonate at the characteristic frequency. Because there are two arrangements that give this resonance (␣␤ and ␤␣), the central line of the resonance will be twice as intense as the two outer lines (which arise when our neighbors are ␣␣ and ␤␤, respectively). Thus, we expect a 1 : 2 : 1 fine structure, just as observed. If there are three equivalent protons in a nearby group (as there are for ethanol’s methylene group resonance, because the methylene group has a methyl group as a neighbor), we expect four lines in the intensity ratio 1 : 3 : 3 : 1, just as observed. Four equivalent neighboring protons would yield lines in the intensity ratio 1 : 4 : 6 : 4 : 1, five would produce intensities in the ratios 1 : 5 : 10 : 10 : 5 : 1, and so on. The hydroxyl resonance is not split by the other protons in the molecule because its proton is very mobile: it can jump from one ethanol molecule to another ethanol molecule or to any water molecules present. As a result, the proton does not stay on one molecule long enough to show any characteristic splitting or to give rise to splitting in other groups. Magnetic Resonance Imaging Magnetic resonance imaging is a noninvasive structural technique for complex systems of molecules, such as people. In its simplest form, MRI portrays the concentration of protons in a sample. If the sample—which may be a living human body—is exposed to a uniform magnetic field in an NMR spectrometer and if we work at a resolution that does not show any chemical shifts or fine structure, then the protons give rise to a single resonance line. However, if the magnetic field varies linearly across the sample, the protons will resonate at different frequencies according to their location in the field. Moreover, the intensity of the resonance at a given field will be proportional to the number of protons at the spatial location corresponding to that particular field value. If the field gradient is rotated into different orientations, another portrayal of the concentration of protons through the sample is obtained. After several such measurements of the absorption intensity, the data can be analyzed on a computer, which constructs a two-dimensional image of any section, or “slice” through the sample. Figure 2 shows the distribution of protons—in large measure, the distribution of water in a brain— and the different regions can be identified. A major advantage of MRI over x-rays is that, if a series of slices are obtained, they can be assembled into a three-dimensional image that yields a much more accurate image of soft tissues than is possible with x-rays. Related Exercises: 19.93–19.101 FIGURE 2 An MRI image of a human brain. The patient must lie within the strong magnetic field. The detectors can be rotated around the patient’s head, thereby allowing many different views to be recorded. *Chemical shifts are sometimes expressed in parts per million, such as d ϭ 1 ppm for the methyl resonance; ignore the ppm in calculations. 792 NUCLEAR MAGNETIC RESONANCE (CONTINUED)MAJOR TECHNIQUE 7 A1 1A SYMBOLS Each physical quantity is represented by an Italic or Greek symbol (thus, m for mass, not m). Table 1 lists most of the symbols used in this textbook together with their units (see also Appendix 1B). The symbols may be modified by attaching subscripts, as set out in Table 2. Fundamental constants are not included in the lists but can be found inside the back cover of the book. APPENDIX 1: Symbols, Units, and Mathematical Techniques TABLE 1 Common Symbols and Units Symbol Physical quantity SI unit ␣ (alpha) polarizability C2 иm2 иJϪ1 ␥ (gamma) surface tension NиmϪ1 ␦ (delta) chemical shift — ␪ (theta) colatitude degree, rad ␭ (lambda) wavelength m ␮ (mu) dipole moment Cиm ␯ (nu) frequency Hz ⌸ (pi) osmotic pressure Pa ␴ (sigma) cross section m2 ␾ (phi) azimuth degree (°), rad ␹ (chi) electronegativity — ␺ (psi) wavefunction mϪn/2 (in n dimensions) a activity — van der Waals parameter L2 иatmиmolϪ2 unit-cell parameter m A area m2 mass number — Madelung constant — b molality molиkgϪ1 , “m” van der Waals parameter LиmolϪ1 B second virial coefficient LиmolϪ1 C heat capacity JиKϪ1 third virial coefficient L2 иmolϪ2 c molar concentration, molarity molиLϪ1 , “M” c2 second radiation constant Kиm d density kgиmϪ3 (gиcmϪ3 ) length of unit-cell diagonal m E energy J electrode potential V Ea activation energy JиmolϪ1 (kJиmolϪ1 ) Ebind nuclear binding energy J Ecell cell potential V Eea electron affinity JиmolϪ1 (kJиmolϪ1 ) Ek kinetic energy J Ep potential energy J e elementary charge C F force N G Gibbs free energy J (continued) A2 APPENDIX 1A2 APPENDIX 1 TABLE 1 Common Symbols and Units (continued) Symbol Physical quantity SI unit H enthalpy J h height m I ionization energy JиmolϪ1 (kJиmolϪ1 ) electric current A (CиsϪ1 ) i i factor — [J] molarity, molar concentration molиLϪ1 , “M” k rate constant (depends on order) decay constant sϪ1 kb boiling-point constant KиkgиmolϪ1 kf freezing-point constant KиkgиmolϪ1 kH Henry’s law constant molиLϪ1 иatmϪ1 K equilibrium constant — Ka acidity constant — Kb basicity constant — Kc equilibrium constant — Kf formation constant — KM Michaelis constant molиLϪ1 KP equilibrium constant — Ksp solubility product — Kw water autoprotolysis constant — l, L length m m mass kg M molar mass kgиmolϪ1 (gиmolϪ1 ) N number of entities — n amount of substance mol p linear momentum kgиmиsϪ1 P pressure Pa PA partial pressure Pa q heat J Q electric charge C reaction quotient — relative biological effectiveness — r radius m R radial wavefunction m–3/2 S entropy JиKϪ1 molar solubility molиLϪ1 s dimensionless molar solubility — t time s t1/2 half-life s T absolute temperature K U internal energy J v velocity mиsϪ1 V volume m3 , L w work J xA mole fraction — Y angular wavefunction — Z compression factor — atomic number — TABLE 2 Subscripts for Symbols Subscript Meaning Example (units) a acid acidity constant, Ka b base basicity constant, Kb boiling boiling temperature, Tb (K) B bond bond enthalpy, ⌬HB (kJиmol–1 ) bind binding binding energy, Ebind (eV) (continued) SYMBOLS, UNITS, AND MATHEMATICAL TECHNIQUES A3 1B UNITS AND UNIT CONVERSIONS Each physical quantity is reported as a multiple of a defined unit: Physical quantity ϭ numerical value ϫ unit For instance, a length may be expressed as a multiple of the unit of length, the meter, m; so we write l ϭ 2.0 m. All units are denoted by roman letters, such as m for meter and s for second. The Système International (SI) is the internationally accepted form of the metric system. It defines seven base units in terms of which all physical quantities can be expressed: meter, m The meter, the unit of length, is the length of the path traveled by light during a time interval of 1/299 792 458 of a second. kilogram, kg The kilogram, the unit of mass, is the mass of a standard cylinder maintained at a laboratory in France. second, s The second, the unit of time, is 9 192 631 770 periods of a certain spectroscopic transition in a cesium-133 atom. ampere, A The ampere, the unit of electric current, is defined in terms of the force exerted between two parallel wires carrying the current. kelvin, K The kelvin, the unit of temperature, is 1/273.16 of the absolute temperature of the triple point of water. mole, mol The mole, the unit of chemical amount, is the amount of substance that contains as many specified entities as there are atoms in exactly 12 g of carbon-12. candela, cd The candela, the unit of luminous intensity, is defined in terms of a carefully specified source. We do not use the candela in this book. Any unit may be modified by one of the prefixes given in Table 3, which denote multiplication or division by a power of 10 of the unit. Thus, 1 mm ϭ 10Ϫ3 m and 1 MK ϭ 106 K. Note that all the prefixes are upright (roman), not Italic. TABLE 2 Subscripts for Symbols (continued) Subscript Meaning Example (units) c concentration equilibrium constant, Kc combustion enthalpy of combustion, ⌬Hc (kJиmol–1 ) critical critical temperature, Tc (K) e nonexpansion (extra) work electrical work, we (J) f formation enthalpy of formation, ⌬Hf (kJиmol–1 ) formation constant, Kf freezing freezing temperature, Tf (K) fus fusion enthalpy of fusion, ⌬Hfus (kJиmol–1 ) H Henry Henry’s law constant, kH In indicator indicator constant, KIn k kinetic kinetic energy, Ek (J) L lattice lattice enthalpy, ⌬HL (kJиmol–1 ) m molar molar volume, Vm ϭ V/n (Lиmol–1 ) M Michaelis Michaelis constant, KM mix mixing enthalpy of mixing, ⌬Hmix (kJиmol–1 ) p potential potential energy, Ep (J) P constant pressure heat capacity at constant pressure, CP (JиK–1 ) r reaction reaction enthalpy, ⌬Hr (kJиmol–1 ) s specific specific heat capacity, Cs ϭ C/m (JиK–1 иg–1 ) sol solution enthalpy of solution, ⌬Hsol (kJиmol–1 ) sp solubility product solubility product, Ksp sub sublimation enthalpy of sublimation, ⌬Hsub (kJиmol–1 ) surr surroundings entropy of surroundings, Ssurr (JиK–1 ) tot total total entropy, Stot (JиK–1 ) V constant volume heat capacity at constant volume, CV (JиK–1 ) vap vaporization enthalpy of vaporization, ⌬Hvap (kJиmol–1 ) w water water autoprotolysis constant, Kw 0 initial initial concentration, [A]0 ground state wavefunction, ␺0 A4 APPENDIX 1 Derived units are combinations of the base units (Section A). Table 4 lists some derived units. Note that the names of units derived from the names of people all begin with a lowercase letter but the initial letter of their abbreviation is uppercase. TABLE 3 Typical SI Prefixes prefix: deca- kilo- mega- giga- tera- petaabbreviation: da k M G T P factor: 10 103 106 109 1012 1015 prefix: deci- centi- milli- micro- nano- pico- femto- atto- zeptoabbreviation: d c m ␮ (mu) n p f a z factor: 10Ϫ1 10Ϫ2 10Ϫ3 10Ϫ6 10Ϫ9 10Ϫ12 10Ϫ15 10Ϫ18 10Ϫ21 TABLE 4 Derived Units with Special Names Physical quantity Name of unit Abbreviation Definition absorbed dose gray Gy Jиkg–1 dose equivalent sievert Sv Jиkg–1 electric charge coulomb C Aиs electric potential volt V JиC–1 energy joule J Nиm, kgиm2 иs–2 force newton N kgиmиs–2 frequency hertz Hz s–1 power watt W Jиs–1 pressure pascal Pa Nиm–2 , kgиm–1 иs–2 volume liter L dm3 It is often necessary to convert one set of units (for instance, calories for energy and inches for length) into SI units. Table 5 lists some common conversions; the values in boldface type are exact. TABLE 5 Relations Between Units Physical quantity Common unit Abbreviation SI equivalent mass pound lb 0.453 592 37 kg tonne t 103 kg (1 Mg) ton (short, U.S.) ton 907.184 74 kg ton (long, U.K.) ton 1016.046 kg length inch in. 2.54 cm foot ft 30.48 cm volume U.S. quart qt 0.946 352 5 L U.S. gallon gal 3.785 41 L Imperial quart qt 1.136 522 5 L Imperial gallon gal 4.546 09 L time minute min 60 s hour h 3600 s energy calorie (thermochemical) cal 4.184 J electronvolt eV 1.602 177 ϫ 10–19 J kilowatt-hour kWh 3.6 ϫ 106 J liter-atmosphere Lиatm 101.325 J pressure torr Torr 133.322 Pa atmosphere atm 101 325 Pa (760 Torr) bar bar 105 Pa pounds/square inch psi 6894.76 Pa power horsepower hp 745.7 W dipole moment debye D 3.335 64 ϫ 10–30 Cиm SYMBOLS, UNITS, AND MATHEMATICAL TECHNIQUES A5 As explained in Section A, to convert between units, we use a conversion factor of the form Conversion factor ϭ When using a conversion factor, we treat the units just like algebraic quantities: they are multiplied or canceled in the normal way. Thus, the units in the denominator of the conversion factor cancel the units in the original data, leaving the units in the numerator of the conversion factor. The conversion of temperatures is carried out slightly differently. Because the Fahrenheit degree (°F) is smaller than a Celsius degree by a factor of (because there are 180 Fahrenheit degrees between the freezing point and boiling point of water but only 100 Celsius degrees between the same two points) and because 0°C coincides with 32°F, we use Temperature (°F) ϭ (The 32 is exact.) For example, to convert 37°C (blood temperature) into degrees Fahrenheit, we write Temperature (°F) ϭ and the temperature is reported as 99°F. A more sophisticated way of expressing the same relation is to write Temperature/°F ϭ In this expression, we treat temperature units like numbers and cancel them when it is appropriate. The same conversion then becomes Temperature/°F ϭ ϭ and multiplication through by °F gives Temperature ϭ 99°F The corresponding expression for conversion between the Celsius and Kelvin scales is Temperature/°C ϭ temperature/K ϩ 273.15 (The 273.15 is exact.) Note that the size of the degree Celsius is the same as that of the kelvin. 1C SCIENTIFIC NOTATION In scientific notation, a number is written as A ϫ 10a . Here A is a decimal number with one nonzero digit in front of the decimal point and a is a whole number. For example, 333 is written 3.33 ϫ 102 in scientific notation, because 102 ϭ 10 ϫ 10 ϭ 100: 333 ϭ 3.33 ϫ 100 ϭ 3.33 ϫ 102 E9 5 * 37F + 32 = 99 E9 5 * (37°C)/°CF + 32 E9 5 * temperature/°CF + 32 E9 5 * 37F + 32 = 99 E9 5 * temperature (°C)F + 32 5 9 units required units given We use 101 ϭ 10 102 ϭ 10 ϫ 10 ϭ 100 103 ϭ 10 ϫ 10 ϫ 10 ϭ 1000 104 ϭ 10 ϫ 10 ϫ 10 ϫ 10 ϭ 10 000 and so on. Note that the number of zeros following 1 is equal to the power of 10. Numbers between 0 and 1 are expressed in the same way, but with a negative power of 10; they have the form A ϫ 10Ϫa , with 10Ϫ1 ϭ 0.1, and so on. Thus, 0.0333 in decimal notation is 3.33 ϫ 10Ϫ2 because and therefore We use 10Ϫ2 ϭ 10Ϫ1 ϫ 10Ϫ1 ϭ 0.01 10Ϫ3 ϭ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϭ 0.001 10Ϫ4 ϭ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϭ 0.0001 When a negative power of 10 is written out as a decimal number, the number of zeros following the decimal point is one less than the number (disregarding the sign) to which 10 is raised. Thus, 10Ϫ5 is written as a decimal point followed by 5 Ϫ 1 ϭ 4 zeros and then a 1: 10Ϫ5 ϭ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϫ 10Ϫ1 ϭ 0.000 01 The digits in a reported measurement are called the significant figures. There are two significant figures (written 2 sf) in 1.2 cm3 and 3 sf in 1.78 g. Fundamentals Section A describes how to find the number of significant figures in a measurement. Some zeros are legitimately measured digits, but other zeros serve only to mark the place of the decimal point. Trailing zeros (the last ones after a decimal point), as in 22.0 mL, are significant, because they were measured. Thus, 22.0 mL has 3 sf. The “captive” zero in 80.1 kg is a measured digit, and so 80.1 kg has 3 sf. However, the leading digits in 0.0025 g are not significant; they are only placeholders used to indicate powers of 10, not measured numbers. We can see that they are only placeholders by reporting the mass as 2.5 ϫ 10Ϫ3 g, which has 2 sf. We distinguish between the results of measurements, which are always uncertain, and the results of counting, which are exact. For example, the report “12 eggs” means that there are exactly 12 eggs present, not a number somewhere between 11.5 and 12.5. Some ambiguity arises with whole numbers ending in zero. Does a length reported as 400 m have 3 sf (4.00 ϫ 102 ), 2 sf (4.0 ϫ 102 ), or only 1 sf (4 ϫ 102 )? In such cases, the use 0.033 = 3.33 * 1 100 = 3.33 * 10-2 10-2 = 1 10 * 1 10 = 1 100 A6 APPENDIX 1 of scientific notation removes any ambiguity. If it is not convenient to use scientific notation, a final decimal point can be used to indicate that every digit to the left of the decimal is significant. Thus, 400 m is ambiguous and cannot be taken to have more than 1 sf unless other information is given. However, 400. m unambiguously has 3 sf. Different rounding-off rules are needed for addition (and its reverse, subtraction) and multiplication (and its reverse, division). In both procedures, we round off the answers to the correct number of significant figures. Rounding off In calculations, round up if the last digit is above 5 and round down if it is below 5. For numbers ending in 5, always round to the nearest even number. For example, 2.35 rounds to 2.4 and 2.65 rounds to 2.6. In a calculation with multiple steps, round off only in the final step; if possible, carry all digits in the memory of the calculator until that stage. Addition and subtraction When adding or subtracting, make sure that the number of decimal places in the result is the same as the smallest number of decimal places in the data. For example, 0.10 g ϩ 0.024 g ϭ 0.12 g. Multiplication and division When multiplying or dividing, make sure that the number of significant figures in the result is the same as the smallest number of significant figures in the data. For example, (8.62 g)/(2.0 cm3 ) ϭ 4.3 g·cmϪ3 . Integers and exact numbers In multiplication or division of a measured value by an integer or an exact number, the uncertainty of the result is determined by the measured value. Some unit conversion factors are defined exactly, even though they are not whole numbers. For example, 1 in. is defined as exactly 2.54 cm and the 273.15 in the conversion between Celsius and Kelvin temperatures is exact; so 100.000°C converts into 373.150 K. Logarithms and exponentials The mantissa of a common logarithm (the digits following the decimal point, see Appendix 1D) has the same number of significant figures as the original number. Thus, log 2.45 ϭ 0.389. A common antilogarithm of a number has the same number of significant figures as the mantissa of the original number. Thus, 100.389 ϭ 2.45 and 1012.389 ϭ 2.45 ϫ 1012 . There is no simple rule for assessing the correct number of significant figures when natural logarithms are used: one way is to convert natural logarithms into common logarithms and then to use the rules just specified. 1D EXPONENTS AND LOGARITHMS To multiply numbers in scientific notation, multiply the decimal parts of the numbers and add the powers of 10: (A ϫ 10a ) ϫ (B ϫ 10b ) ϭ (A ϫ B) ϫ 10a ϩ b An example is (1.23 ϫ 102 ) ϫ (4.56 ϫ 103 ) ϭ 1.23 ϫ 4.56 ϫ 102 ϩ 3 ϭ 5.61 ϫ 105 This rule also applies if the powers of 10 are negative: (1.23 ϫ 10Ϫ2 ) ϫ (4.56 ϫ 10Ϫ3 ) ϭ 1.23 ϫ 4.56 ϫ 10Ϫ2 Ϫ 3 ϭ 5.61 ϫ 10Ϫ5 The results of such calculations are then adjusted so that one digit precedes the decimal point: (4.56 ϫ 10Ϫ3 ) ϫ (7.65 ϫ 106 ) ϭ 34.88 ϫ 103 ϭ 3.488 ϫ 104 When dividing two numbers in scientific notation, divide the decimal parts of the numbers and subtract the powers of 10: An example is ϭ 4.37 ϫ 1012 Before adding and subtracting numbers in scientific notation, we rewrite the numbers as decimal numbers multiplied by the same power of 10: 1.00 ϫ 103 ϩ 2.00 ϫ 102 ϭ 1.00 ϫ 103 ϩ 0.200 ϫ 103 ϭ 1.20 ϫ 103 When raising a number in scientific notation to a particular power, raise the decimal part of the number to the power and multiply the power of 10 by the power: (A ϫ 10a )b ϭ Ab ϫ 10a ϫ b For example, 2.88 ϫ 104 raised to the third power is (2.88 ϫ 104 )3 ϭ 2.883 ϫ (104 )3 ϭ 2.883 ϫ 103 ϫ 4 ϭ 23.9 ϫ 1012 ϭ 2.39 ϫ 1013 The rule follows from the fact that (104 )3 ϭ 104 ϫ 104 ϫ 104 ϭ 104 ϩ 4 ϩ 4 ϭ 103 ϫ 4 The common logarithm of a number x, denoted log x, is the power to which 10 must be raised to equal x. Thus, the logarithm of 100 is 2, written log 100 ϭ 2, because 102 ϭ 100. The logarithm of 1.5 ϫ 102 is 2.18 because 102.18 ϭ 100.18 ϩ 2 ϭ 100.18 ϫ 102 ϭ 1.5 ϫ 102 The number to the left of the decimal point in the logarithm (the 2 in log (1.5 ϫ 102 ) ϭ 2.18) is called the characteristic of the logarithm: it is the power of 10 in the original number (the power 2 in 1.5 ϫ 102 ). The decimal fraction (the numbers to the right of the decimal point; such as 0.18 in our example) is called the mantissa (from the Latin word for “makeweight”). It is the logarithm of the decimal number written with one nonzero digit to the left of the decimal point (the 1.5 in the example). The distinction between the characteristic and the mantissa is important when we have to decide how many significant figures to retain in a calculation that includes logarithms (as in the calculation of pH). Just as the power of 10 in a 4.31 * 105 9.87 * 10-8 = 4.31 9.87 * 105 - (-8) = 0.437 * 1013 A * 10a B * 10b = A B * 10a - b SYMBOLS, UNITS, AND MATHEMATICAL TECHNIQUES A7 decimal number indicates only the location of the decimal point and plays no role in the determination of significant figures, so the characteristic of a logarithm is not included in the count of significant figures in a logarithm (see Appendix 1C). The number of significant figures in the mantissa is equal to the number of significant figures in the decimal number. The common antilogarithm of a number x is the number that has x as its common logarithm. In practice, the common antilogarithm of x is simply another name for 10x , and so the common antilogarithm of 2 is 102 ϭ 100 and that of 2.18 is 102.18 ϭ 100.18 ϩ 2 ϭ 100.18 ϫ 102 ϭ 1.5 ϫ 102 The logarithm of a number greater than 1 is positive, and the logarithm of a number less than 1 (but greater than 0) is negative: If x Ͼ 1, log x Ͼ 0 If x ϭ 1, log x ϭ 0 If x Ͻ 1, log x Ͻ 0 Logarithms are not defined either for 0 or for negative numbers. The natural logarithm of a number x, denoted ln x, is the power to which the number e ϭ 2.718. . . must be raised to equal x. Thus, ln 10.0 ϭ 2.303, signifying that e2.303 ϭ 10.0. The value of e may seem a peculiar choice, but it occurs naturally in a number of mathematical expressions, and its use simplifies many formulas. Common and natural logarithms are related by the expression ln x ϭ ln 10 ϫ log x In practice, a convenient approximation is ln x Ϸ 2.303 ϫ log x The natural antilogarithm of x is normally called the exponential of e; it is the value of e raised to the power x. Thus, the natural antilogarithm of 2.303 is e2.303 ϭ 10.0. The following relations between logarithms are useful. Written here mainly for common logarithms, they also apply to natural logarithms. Relation Example log 10x ϭ x log 10Ϫ7 ϭ Ϫ7 ln ex ϭ x ln eϪkt ϭ Ϫkt log x ϩ log y ϭ log xy log [Agϩ ] ϩ log [ClϪ ] ϭ log [Agϩ ][ClϪ ] log x Ϫ log y ϭ log (x/y) log A0 Ϫ log A ϭ log (A0/A) x log y ϭ log yx 2 log [Hϩ ] ϭ log ([Hϩ ]2 ) log(1/x) ϭ Ϫlog x log (1/[Hϩ ]) ϭ Ϫlog [Hϩ ] Logarithms are useful for solving expressions of the form ax ϭ b for the unknown x. (This type of calculation can arise in the study of chemical kinetics to determine the order of a reaction.) We take logarithms of both sides log ax ϭ log b and, from a relation given in the preceding table, we write the expression as x log a ϭ log b Therefore, 1E EQUATIONS AND GRAPHS A quadratic equation is an equation of the form ax2 ϩ bx ϩ c ϭ 0 The two roots of the equation (the solutions) are given by the expression The roots can also be determined graphically (by using a graphing calculator, for instance) by noting where the graph of y(x) ϭ ax2 ϩ bx ϩ c against x passes through y ϭ 0 (Fig. 1). When a quadratic equation arises in connection with a chemical calculation, we accept only the root that leads to a physically plausible result. For example, if x is a concentration, then it must be a positive number, and a negative root can be ignored. A calculation may result in a cubic equation: ax3 ϩ bx2 ϩ cx ϩ d ϭ 0 Cubic equations are often very tedious to solve exactly, and so it is better to use mathematical software, a graphing calculator, or a plotter, such as the one on the Web site for this book, and to identify the locations where the graph of y(x) against x passes through y ϭ 0 (Fig. 2). Experimental data can often be analyzed most effectively from a graph. In many cases, the best procedure is to find a way of plotting the data as a straight line. It is easier to tell whether the data in fact fall on the line, whereas small deviations from a curve are harder to detect. Moreover, it is also easy to calculate the slope of a straight line, to extrapolate (extend) a straight line beyond the range of the data, and to interpolate between the data points (that is, find a value between two measured values). x = -b ; 2b2 - 4ac 2a x = log b log a FIGURE 1 A graph of a function of the form y(x) ϭ ax2 ϩ bx ϩ c passes through y ϭ 0 at two points, which are the two roots of the quadratic equation ax2 ϩ bx ϩ c ϭ 0. 0 y x y = 0 FIGURE 2 A graph of a function of the form y(x) ϭ ax3 ϩ bx2 ϩ cx ϩ d passes through y ϭ 0 at three points, which are the three roots of the cubic equation ax3 ϩ bx2 ϩ cx ϩ d ϭ 0. y x0 y = 0 A8 APPENDIX 1 The formula of a straightline graph of y (the vertical axis) plotted against x (the horizontal axis) is y ϭ mx ϩ b Here b is the intercept of the line with the y-axis (Fig. 3), the value of y when x ϭ 0. The slope of the graph, its gradient, is m. The slope can be calculated by choosing two points, x1 and x2, and their corresponding values on the y-axis, y1 and y2, and substituting the values into the formula Because b is the intercept and m is the slope, the equation of the straight line is equivalent to y ϭ (slope ϫ x) ϩ intercept Many of the equations that we meet in the text can be rearranged to give a straight-line graph when plotted as shown in the following table. Application y ϭ slope ؋ x ϩ intercept temperature scale temp./°C ϭ 1 ϫ T/K Ϫ273.15 conversions temp./°F ϭ ϫ temp./°C ϩ32 ideal gas law P ϭ nRT ϫ (1/V) first-order ln[A] ϭ Ϫk ϫ t ϩln [A]0 integrated rate law second-order 1/[A] ϭ k ϫ t ϩ1/[A]0 integrated rate law Arrhenius ln k ϭ (ϪEa/R) ϫ (1/T) ϩln A equation The slope of a straight line is the same at all points. On a curve, however, the slope changes from point to point. The slope at a specified point is given by the slope of the line tangent to the curve at that point. The tangent can be found by a series of approximations, as shown in Fig. 4. We might start (approximation 1) by drawing a point on the curve on each side of the point of interest (corresponding to equal distances along the x-axis) and joining them by a straight line. A better 9 5 m = y2 - y1 x2 - x1 approximation (approximation 2) is obtained by moving the points an equal distance closer to the point of interest and drawing a new line. The exact tangent is obtained when the two points virtually coincide with the point of interest. Its slope is then equal to the slope of the curve at the point of interest. This technique can be used to measure the rate of a chemical reaction at a specified time. 1F CALCULUS Differential calculus is the part of mathematics that deals with the slopes of curves and with infinitesimal quantities. Suppose we are studying a function y(x). As explained in Appendix 1E, the slope of its graph at a point can be calculated by considering the straight line joining two points x and x ϩ ␦x, where ␦x is small. The slope of this line is Slope ϭ In differential calculus, the slope of the curve is found by letting the separation of the points become infinitesimally small. The first derivative of the function y with respect to x is then defined as where “lim” means the limit of whatever follows—in this case, the value of the expression as ␦x is allowed to become zero. For example, if y(x) ϭ x2 , Therefore, the slope of the graph of the function y ϭ x2 at any point x is 2x. The same procedure can be applied to other functions. However, in practice, it is usually more convenient to consult tables of first derivatives that have already been worked out. A selection of common functions and their first derivatives is given here. Function, y(x) Derivative, dy/dx xn nxn Ϫ 1 ln x 1/x eax aeax sin ax a cos ax cos ax Ϫa sin ax The second derivative of a function, denoted d2 y/dx2 , is defined like the first derivative but is applied to the function that has been obtained by taking the first derivative. For example, the second derivative of the function x2 is the derivative of the function 2x, which is the constant 2. Likewise, = lim ␦x: 0 2xdx + (␦x)2 ␦x = lim ␦x: 0 (2x + ␦x) = 2x = lim ␦x: 0 x2 + 2x␦x + (␦x)2 - x2 ␦x dy dx = lim ␦x: 0 (x + ␦x)2 - x2 ␦x dy dx = lim ␦x: 0 y(x + ␦x) - y(x) ␦x y(x + ␦x) - y(x) ␦x FIGURE 4 Successive approximations to the true tangent are obtained as the two points defining the straight line come closer together and finally coincide. y x0 Approximation 1 Approximation 2 True tangent FIGURE 3 The straight line y(x) ϭ mx ϩ b; its intercept with the vertical axis at x ϭ 0 is b and its slope is m. y 0 x1 x2 x b x2 − x1 y2 − y1 x2 − x1 y2 − y1 m = y1 y2 y = mx + b SYMBOLS, UNITS, AND MATHEMATICAL TECHNIQUES A9 the second derivative of sin ax is Ϫa2 sin ax. The second derivative is an indication of the curvature of the function. Where d2 y/dx2 is positive, the graph has a ∪ shape; where it is negative, the graph has a ∩ shape. The greater the magnitude of d2 y/dx2 , the sharper the curvature of the graph. Integral calculus provides a way to determine the original function, given its first derivative. Thus, if we know that the first derivative is 2x, then the integral calculus allows us to deduce that the function itself is y ϭ x2 ϩ constant. The constant is included because when we differentiate x2 ϩ constant we get 2x regardless of the value of the constant. Formally, we write It follows that the functions in the left-hand column of the preceding table are the integrals (to within a constant) of the functions in the right-hand column. More formally, they are L (2x) dx = x2 + constant Area ϭ An integral with limits attached, as in this example, is called a definite integral (because the unknown constant has canceled). = 1 + 1 = 2 = a -cos p + constantb - a -cos 0 + constantb L p 0 sin x dx = (-cos x + constant) ` p 0 FIGURE 5 The definite integral of the function y(x) between x ϭ a and x ϭ b is equal to the area bounded by the curve, the x-axis, and the two vertical lines through a and b. y x0 a b Area = ∫a y(x) y(x)dx b b b Ϫ1 1 the indefinite integrals of the function (“indefinite” on account of the presence of the unknown constant), in contrast with the “definite” integrals described next. Tables of indefinite integrals may be consulted for more complex examples, and mathematical software or a graphing calculator can be used to evaluate them. An integral has a further important interpretation: the integral of a function evaluated between two points is the area beneath the graph of the function between the two points (Fig. 5). For example, the area beneath the curve y(x) ϭ sin x between x ϭ 0 and x ϭ ␲ is This page intentionally left blank LAST H1 HEAD A11 2A THERMODYNAMIC DATA AT 25°C Inorganic Substances APPENDIX 2: Experimental Data A11 Enthalpy Gibbs free energy Molar heat Molar mass, of formation, of formation, capacity, Molar entropy,* Substance M (gؒmolϪ1 ) ⌬Hf° (kJؒmolϪ1 ) ⌬Gf° (kJؒmolϪ1 ) CP,m (JؒKϪ1 ؒmolϪ1 ) Sm° (JؒKϪ1 ؒmolϪ1 ) Aluminum Al(s) 26.98 0 0 24.35 28.33 Al3ϩ (aq) 26.98 Ϫ524.7 Ϫ481.2 — Ϫ321.7 Al2O3(s) 101.96 Ϫ1675.7 Ϫ1582.35 79.04 50.92 Al(OH)3(s) 78.00 Ϫ1276 — — — AlCl3(s) 133.33 Ϫ704.2 Ϫ628.8 91.84 110.67 Antimony Sb(s) 121.76 0 0 25.23 45.69 SbH3(g) 124.78 ϩ145.11 ϩ147.75 41.05 232.78 SbCl3(g) 228.11 Ϫ313.8 Ϫ301.2 76.69 337.80 SbCl5(g) 299.01 Ϫ394.34 Ϫ334.29 121.13 401.94 Arsenic As(s), gray 74.92 0 0 24.64 35.1 As2S3(s) 246.05 Ϫ169.0 Ϫ168.6 116.3 163.6 AsO4 3Ϫ (aq) 138.92 Ϫ888.14 Ϫ648.41 — Ϫ162.8 Barium Ba(s) 137.33 0 0 28.07 62.8 Ba2ϩ (aq) 137.33 Ϫ537.64 Ϫ560.77 — ϩ9.6 BaO(s) 153.33 Ϫ553.5 Ϫ525.1 47.78 70.42 BaCO3(s) 197.34 Ϫ1216.3 Ϫ1137.6 85.35 112.1 BaCO3(aq) 197.34 Ϫ1214.78 Ϫ1088.59 — Ϫ47.3 Boron B(s) 10.81 0 0 11.09 5.86 B2O3(s) 69.62 Ϫ1272.8 Ϫ1193.7 62.93 53.97 BF3(g) 67.81 Ϫ1137.0 Ϫ1120.3 50.46 254.12 Bromine Br2(l) 159.80 0 0 75.69 152.23 Br2(g) 159.80 ϩ30.91 ϩ3.11 36.02 245.46 Br(g) 79.90 ϩ111.88 ϩ82.40 20.79 175.02 BrϪ (aq) 79.90 Ϫ121.55 Ϫ103.96 — ϩ82.4 HBr(g) 80.91 Ϫ36.40 Ϫ53.45 29.14 198.70 Calcium Ca(s) 40.08 0 0 25.31 41.42 Ca(g) 40.08 ϩ178.2 ϩ144.3 20.79 154.88 Ca2ϩ (aq) 40.08 Ϫ542.83 Ϫ553.58 — Ϫ53.1 (continued) A12 APPENDIX 2 Inorganic Substances (continued ) Enthalpy Gibbs free energy Molar heat Molar mass, of formation, of formation, capacity, Molar entropy,* Substance M (gؒmolϪ1 ) ⌬Hf° (kJؒmolϪ1 ) ⌬Gf° (kJؒmolϪ1 ) CP,m (JؒKϪ1 ؒmolϪ1 ) Sm° (JؒKϪ1 ؒmolϪ1 ) CaO(s) 56.08 Ϫ635.09 Ϫ604.03 42.80 39.75 Ca(OH)2(s) 74.10 Ϫ986.09 Ϫ898.49 87.49 83.39 Ca(OH)2(aq) 74.10 Ϫ1002.82 Ϫ868.07 — Ϫ74.5 CaCO3(s), calcite 100.09 Ϫ1206.9 Ϫ1128.8 81.88 92.9 CaCO3(s), aragonite 100.09 Ϫ1207.1 Ϫ1127.8 81.25 88.7 CaCO3(aq) 100.09 Ϫ1219.97 Ϫ1081.39 — Ϫ110.0 CaF2(s) 78.08 Ϫ1219.6 Ϫ1167.3 67.03 68.87 CaF2(aq) 78.08 Ϫ1208.09 Ϫ1111.15 — Ϫ80.8 CaCl2(s) 110.98 Ϫ795.8 Ϫ748.1 72.59 104.6 CaCl2(aq) 110.98 Ϫ877.1 Ϫ816.0 — 59.8 CaBr2(s) 199.88 Ϫ682.8 Ϫ663.6 72.59 130 CaC2(s) 64.10 Ϫ59.8 Ϫ64.9 62.72 69.96 CaSO4(s) 136.14 Ϫ1434.11 Ϫ1321.79 99.66 106.7 CaSO4(aq) 136.14 Ϫ1452.10 Ϫ1298.10 — Ϫ33.1 Carbon (for organic compounds, see the next table) C(s), graphite 12.01 0 0 8.53 5.740 C(s), diamond 12.01 ϩ1.895 ϩ2.900 6.11 2.377 C(g) 12.01 ϩ716.68 ϩ671.26 20.84 158.10 CO(g) 28.01 Ϫ110.53 Ϫ137.17 29.14 197.67 CO2(g) 44.01 Ϫ393.51 Ϫ394.36 37.11 213.74 CO3 2Ϫ (aq) 60.01 Ϫ677.14 Ϫ527.81 — Ϫ56.9 CCl4(l) 153.81 Ϫ135.44 Ϫ65.21 131.75 216.40 CS2(l) 76.15 ϩ89.70 ϩ65.27 75.7 151.34 HCN(g) 27.03 ϩ135.1 ϩ124.7 35.86 201.78 HCN(l) 27.03 ϩ108.87 ϩ124.97 70.63 112.84 HCN(aq) 27.03 ϩ107.1 ϩ119.7 — 124.7 Cerium Ce(s) 140.12 0 0 26.94 72.0 Ce3ϩ (aq) 140.12 Ϫ696.2 Ϫ672.0 — Ϫ205 Ce4ϩ (aq) 140.12 Ϫ537.2 Ϫ503.8 — Ϫ301 Chlorine Cl2(g) 70.90 0 0 33.91 223.07 Cl(g) 35.45 ϩ121.68 ϩ105.68 21.84 165.20 ClϪ (aq) 35.45 Ϫ167.16 Ϫ131.23 — ϩ56.5 HCl(g) 36.46 Ϫ92.31 Ϫ95.30 29.12 186.91 HCl(aq) 36.46 Ϫ167.16 Ϫ131.23 — 56.5 Copper Cu(s) 63.55 0 0 24.44 33.15 Cuϩ (aq) 63.55 ϩ71.67 ϩ49.98 — ϩ40.6 Cu2ϩ (aq) 63.55 ϩ64.77 ϩ65.49 — Ϫ99.6 Cu2O(s) 143.10 Ϫ168.6 Ϫ146.0 63.64 93.14 CuO(s) 79.55 Ϫ157.3 Ϫ129.7 42.30 42.63 CuSO4(s) 159.61 Ϫ771.36 Ϫ661.8 100.0 109 CuSO4и5H2O(s) 249.69 Ϫ2279.7 Ϫ1879.7 280 300.4 Deuterium D2(g) 4.028 0 0 29.20 144.96 D2O(g) 20.028 Ϫ249.20 Ϫ234.54 34.27 198.34 D2O(l) 20.028 Ϫ294.60 Ϫ243.44 34.27 75.94 EXPERIMENTAL DATA A13 Enthalpy Gibbs free energy Molar heat Molar mass, of formation, of formation, capacity, Molar entropy,* Substance M (gؒmolϪ1 ) ⌬Hf° (kJؒmolϪ1 ) ⌬Gf° (kJؒmolϪ1 ) CP,m (JؒKϪ1 ؒmolϪ1 ) Sm° (JؒKϪ1 ؒmolϪ1 ) Fluorine F2(g) 38.00 0 0 31.30 202.78 FϪ (aq) 19.00 Ϫ332.63 Ϫ278.79 — Ϫ13.8 HF(g) 20.01 Ϫ271.1 Ϫ273.2 29.13 173.78 HF(aq) 20.01 Ϫ330.08 Ϫ296.82 — 88.7 Hydrogen (see also Deuterium) H2(g) 2.0158 0 0 28.82 130.68 H(g) 1.0079 ϩ217.97 ϩ203.25 20.78 114.71 Hϩ (aq) 1.0079 0 0 0 0 H2O(l) 18.02 Ϫ285.83 Ϫ237.13 75.29 69.91 H2O(g) 18.02 Ϫ241.82 Ϫ228.57 33.58 188.83 H2O2(l) 34.02 Ϫ187.78 Ϫ120.35 89.1 109.6 H2O2(aq) 34.02 Ϫ191.17 Ϫ134.03 — 143.9 H3Oϩ (aq) 19.02 Ϫ285.83 Ϫ237.13 75.29 ϩ69.91 Iodine I2(s) 253.80 0 0 54.44 116.14 I2(g) 253.80 ϩ62.44 ϩ19.33 36.90 260.69 IϪ (aq) 126.90 Ϫ55.19 Ϫ51.57 — ϩ111.3 HI(g) 127.91 ϩ26.48 ϩ1.70 29.16 206.59 Iron Fe(s) 55.84 0 0 25.10 27.28 Fe2ϩ (aq) 55.84 Ϫ89.1 Ϫ78.90 — Ϫ137.7 Fe3ϩ (aq) 55.84 Ϫ48.5 Ϫ4.7 — Ϫ315.9 Fe3O4(s), magnetite 231.52 Ϫ1118.4 Ϫ1015.4 143.43 146.4 Fe2O3(s), hematite 159.68 Ϫ824.2 Ϫ742.2 103.85 87.40 FeS(s, ␣) 87.90 Ϫ100.0 Ϫ100.4 50.54 60.29 FeS(aq) 87.90 — ϩ6.9 — — FeS2(s) 119.96 Ϫ178.2 Ϫ166.9 62.17 52.93 Lead Pb(s) 207.2 0 0 26.44 64.81 Pb2ϩ (aq) 207.2 Ϫ1.7 Ϫ24.43 — ϩ10.5 PbO2(s) 239.2 Ϫ277.4 Ϫ217.33 64.64 68.6 PbSO4(s) 303.3 Ϫ919.94 Ϫ813.14 103.21 148.57 PbBr2(s) 367.0 Ϫ278.7 Ϫ261.92 80.12 161.5 PbBr2(aq) 367.0 Ϫ244.8 Ϫ232.34 — 175.3 Magnesium Mg(s) 24.31 0 0 24.89 32.68 Mg(g) 24.31 ϩ147.70 Ϫ113.10 20.79 148.65 Mg2ϩ (aq) 24.31 Ϫ466.85 Ϫ454.8 — Ϫ138.1 MgO(s) 40.31 Ϫ601.70 Ϫ569.43 37.15 26.94 MgCO3(s) 84.32 Ϫ1095.8 Ϫ1012.1 75.52 65.7 MgBr2(s) 184.11 Ϫ524.3 Ϫ503.8 — 117.2 Mercury Hg(l) 200.59 0 0 27.98 76.02 Hg(g) 200.59 ϩ61.32 ϩ31.82 20.79 174.96 HgO(s) 216.59 Ϫ90.83 Ϫ58.54 44.06 70.29 Hg2Cl2(s) 472.08 Ϫ265.22 Ϫ210.75 102 192.5 (continued) A14 APPENDIX 2 Inorganic Substances (continued ) Enthalpy Gibbs free energy Molar heat Molar mass, of formation, of formation, capacity, Molar entropy,* Substance M (gؒmolϪ1 ) ⌬Hf° (kJؒmolϪ1 ) ⌬Gf° (kJؒmolϪ1 ) CP,m (JؒKϪ1 ؒmolϪ1 ) Sm° (JؒKϪ1 ؒmolϪ1 ) Nitrogen N2(g) 28.02 0 0 29.12 191.61 NO(g) 30.01 ϩ90.25 ϩ86.55 29.84 210.76 N2O(g) 44.02 ϩ82.05 ϩ104.20 38.45 219.85 NO2(g) 46.01 ϩ33.18 ϩ51.31 37.20 240.06 N2O4(g) 92.02 ϩ9.16 ϩ97.89 77.28 304.29 HNO3(l) 63.02 Ϫ174.10 Ϫ80.71 109.87 155.60 HNO3(aq) 63.02 Ϫ207.36 Ϫ111.25 — 146.4 NO3 Ϫ (aq) 62.02 Ϫ205.0 Ϫ108.74 — ϩ146.4 NH3(g) 17.03 Ϫ46.11 Ϫ16.45 35.06 192.45 NH3(aq) 17.03 Ϫ80.29 Ϫ26.50 — 111.3 NH4 ϩ (aq) 18.04 Ϫ132.51 Ϫ79.31 — ϩ113.4 NH2OH(s) 33.03 Ϫ114.2 — — — HN3(g) 43.04 ϩ294.1 ϩ328.1 98.87 238.97 N2H4(l) 32.05 ϩ50.63 ϩ149.34 139.3 121.21 NH4NO3(s) 80.05 Ϫ365.56 Ϫ183.87 84.1 151.08 NH4Cl(s) 53.49 Ϫ314.43 Ϫ202.87 — 94.6 NH4ClO4(s) 117.49 Ϫ295.31 Ϫ88.75 — 186.2 Oxygen O2(g) 32.00 0 0 29.36 205.14 O3(g) 48.00 ϩ142.7 ϩ163.2 39.29 238.93 OHϪ (aq) 17.01 Ϫ229.99 Ϫ157.24 — Ϫ10.75 Phosphorus P(s), white 30.97 0 0 23.84 41.09 P4(g) 123.88 ϩ58.91 ϩ24.44 67.15 279.98 PH3(g) 33.99 ϩ5.4 ϩ13.4 37.11 210.23 P4O10(s) 283.88 Ϫ2984.0 Ϫ2697.0 — 228.86 H3PO3(aq) 81.99 Ϫ964.8 — — — H3PO4(l) 97.99 Ϫ1266.9 — — — H3PO4(aq) 97.99 Ϫ1288.34 Ϫ1142.54 — 158.2 PCl3(l) 137.32 Ϫ319.7 Ϫ272.3 — 217.18 PCl3(g) 137.32 Ϫ287.0 Ϫ267.8 71.84 311.78 PCl5(g) 208.22 Ϫ374.9 Ϫ305.0 112.8 364.6 PCl5(s) 208.22 Ϫ443.5 — — — Potassium K(s) 39.10 0 0 29.58 64.18 K(g) 39.10 ϩ89.24 ϩ60.59 20.79 160.34 Kϩ (aq) 39.10 Ϫ252.38 Ϫ283.27 — ϩ102.5 KOH(s) 56.11 Ϫ424.76 Ϫ379.08 64.9 78.9 KOH(aq) 56.11 Ϫ482.37 Ϫ440.50 — 91.6 KF(s) 58.10 Ϫ567.27 Ϫ537.75 49.04 66.57 KCl(s) 74.55 Ϫ436.75 Ϫ409.14 51.30 82.59 KBr(s) 119.00 Ϫ393.80 Ϫ380.66 52.30 95.90 KI(s) 166.00 Ϫ327.90 Ϫ324.89 52.93 106.32 KClO3(s) 122.55 Ϫ397.73 Ϫ296.25 100.25 143.1 KClO4(s) 138.55 Ϫ432.75 Ϫ303.09 112.38 151.0 K2S(s) 110.26 Ϫ380.7 Ϫ364.0 — 105 K2S(aq) 110.26 Ϫ471.5 Ϫ480.7 — 190.4 Silicon Si(s) 28.09 0 0 20.00 18.83 SiO2(s, ␣) 60.09 Ϫ910.94 Ϫ856.64 44.43 41.84 EXPERIMENTAL DATA A15 Enthalpy Gibbs free energy Molar heat Molar mass, of formation, of formation, capacity, Molar entropy,* Substance M (gؒmolϪ1 ) ⌬Hf° (kJؒmolϪ1 ) ⌬Gf° (kJؒmolϪ1 ) CP,m (JؒKϪ1 ؒmolϪ1 ) Sm° (JؒKϪ1 ؒmolϪ1 ) Silver Ag(s) 107.87 0 0 25.35 42.55 Agϩ (aq) 107.87 ϩ105.58 ϩ77.11 — ϩ72.68 Ag2O(s) 231.74 Ϫ31.05 Ϫ11.20 65.86 121.3 AgBr(s) 187.77 Ϫ100.37 Ϫ96.90 52.38 107.1 AgBr(aq) 187.77 Ϫ15.98 Ϫ26.86 — 155.2 AgCl(s) 143.32 Ϫ127.07 Ϫ109.79 50.79 96.2 AgCl(aq) 143.32 Ϫ61.58 Ϫ54.12 — 129.3 AgI(s) 234.77 Ϫ61.84 Ϫ66.19 56.82 115.5 AgI(aq) 234.77 ϩ50.38 ϩ25.52 — 184.1 AgNO3(s) 169.88 Ϫ124.39 Ϫ33.41 93.05 140.92 Sodium Na(s) 22.99 0 0 28.24 51.21 Na(g) 22.99 ϩ107.32 ϩ76.76 20.79 153.71 Naϩ (aq) 22.99 Ϫ240.12 Ϫ261.91 — ϩ59.0 NaOH(s) 40.00 Ϫ425.61 Ϫ379.49 59.54 64.46 NaOH(aq) 40.00 Ϫ470.11 Ϫ419.15 — 48.1 NaCl(s) 58.44 Ϫ411.15 Ϫ384.14 50.50 72.13 NaBr(s) 102.89 Ϫ361.06 Ϫ348.98 51.38 86.82 NaI(s) 149.89 Ϫ287.78 Ϫ286.06 52.09 98.53 Sulfur S(s), rhombic 32.06 0 0 22.64 31.80 S(s), monoclinic 32.06 ϩ0.33 ϩ0.1 23.6 32.6 S2Ϫ (aq) 32.06 ϩ33.1 ϩ85.8 — Ϫ14.6 SO2(g) 64.06 Ϫ296.83 Ϫ300.19 39.87 248.22 SO3(g) 80.06 Ϫ395.72 Ϫ371.06 50.67 256.76 H2SO4(l) 98.08 Ϫ813.99 Ϫ690.00 138.9 156.90 SO4 2Ϫ (aq) 96.06 Ϫ909.27 Ϫ744.53 — ϩ20.1 HSO4 Ϫ (aq) 97.07 Ϫ887.34 Ϫ755.91 — ϩ131.8 H2S(g) 34.08 Ϫ20.63 Ϫ33.56 34.23 205.79 H2S(aq) 34.08 Ϫ39.7 Ϫ27.83 — 121 SF6(g) 146.06 Ϫ1209 Ϫ1105.3 97.28 291.82 Tin Sn(s), white 118.71 0 0 26.99 51.55 Sn(s), gray 118.71 Ϫ2.09 ϩ0.13 25.77 44.14 SnO(s) 134.71 Ϫ285.8 Ϫ256.9 44.31 56.5 SnO2(s) 150.71 Ϫ580.7 Ϫ519.6 52.59 52.3 Zinc Zn(s) 65.41 0 0 25.40 41.63 Zn2ϩ (aq) 65.41 Ϫ153.89 Ϫ147.06 — Ϫ112.1 ZnO(s) 81.41 Ϫ348.28 Ϫ318.30 40.25 43.64 *The entropies of individual ions in solution are determined by setting the entropy of Hϩ in water equal to 0 and then defining the entropies of all other ions relative to this value; hence a negative entropy is one that is lower than the entropy of Hϩ in water. All absolute entropies are positive, and no sign need be given; all entropies of ions are relative to that of Hϩ and are listed here with a sign (either ϩ or Ϫ). A16 APPENDIX 2 Organic Compounds Enthalpy Enthalpy Gibbs free Molar of of energy of heat Molar Molar combustion, formation, formation, capacity, entropy, mass, ⌬Hc° ⌬Hf° ⌬Gf° CP,m Sm° Substance M (gиmolϪ1 ) (kJиmolϪ1 ) (kJиmolϪ1 ) (kJиmolϪ1 ) (JиKϪ1 иmolϪ1 ) (JиKϪ1 иmolϪ1 ) Hydrocarbons CH4(g), methane 16.04 Ϫ890 Ϫ74.81 Ϫ50.72 35.31 186.26 C2H2(g), ethyne 26.04 Ϫ1300 ϩ226.73 ϩ209.20 43.93 200.94 (acetylene) C2H4(g), ethene 28.05 Ϫ1411 ϩ52.26 ϩ68.15 43.56 219.56 (ethylene) C2H6(g), ethane 30.07 Ϫ1560 Ϫ84.68 Ϫ32.82 52.63 229.60 C3H6(g), propene 42.08 Ϫ2058 ϩ20.42 ϩ62.78 63.89 266.6 (propylene) C3H6(g), cyclopropane 42.08 Ϫ2091 ϩ53.30 ϩ104.45 55.94 237.4 C3H8(g), propane 44.09 Ϫ2220 Ϫ103.85 Ϫ23.49 73.5 270.2 C4H10(g), butane 58.12 Ϫ2878 Ϫ126.15 Ϫ17.03 97.45 310.1 C5H12(g), pentane 72.14 Ϫ3537 Ϫ146.44 Ϫ8.20 120.2 349 C6H6(l), benzene 78.11 Ϫ3268 ϩ49.0 ϩ124.3 136.1 173.3 C6H6(g) 78.11 Ϫ3302 ϩ82.9 ϩ129.72 81.67 269.31 C7H8(l), toluene 92.13 Ϫ3910 ϩ12.0 ϩ113.8 — 221.0 C7H8(g) 92.13 Ϫ3953 ϩ50.0 ϩ122.0 103.6 320.7 C6H12(l), cyclohexane 84.15 Ϫ3920 Ϫ156.4 ϩ26.7 156.5 204.4 C6H12(g) 84.15 Ϫ3953 — — — — C8H18(l), octane 114.22 Ϫ5471 Ϫ249.9 ϩ6.4 — 358 Alcohols and phenols CH3OH(l), methanol 32.04 Ϫ726 Ϫ238.86 Ϫ166.27 81.6 126.8 CH3OH(g) 32.04 Ϫ764 Ϫ200.66 Ϫ161.96 43.89 239.81 C2H5OH(l), ethanol 46.07 Ϫ1368 Ϫ277.69 Ϫ174.78 111.46 160.7 C2H5OH(g) 46.07 Ϫ1409 Ϫ235.10 Ϫ168.49 65.44 282.70 C6H5OH(s), phenol 94.11 Ϫ3054 Ϫ164.6 Ϫ50.42 — 144.0 Carboxylic acids HCOOH(l), 46.02 Ϫ255 Ϫ424.72 Ϫ361.35 99.04 128.95 formic acid CH3COOH(l), 60.05 Ϫ875 Ϫ484.5 Ϫ389.9 124.3 159.8 acetic acid CH3COOH(aq) 60.05 — Ϫ485.76 Ϫ396.46 — 86.6 (COOH)2(s), 90.04 Ϫ254 Ϫ827.2 Ϫ697.9 117 120 oxalic acid C6H5COOH(s), 122.12 Ϫ3227 Ϫ385.1 Ϫ245.3 146.8 167.6 benzoic acid Aldehydes and ketones HCHO(g), methanal 30.03 Ϫ571 Ϫ108.57 Ϫ102.53 35.40 218.77 (formaldehyde) CH3CHO(l), ethanal 44.05 Ϫ1166 Ϫ192.30 Ϫ128.12 — 160.2 (acetaldehyde) CH3CHO(g) 44.05 Ϫ1192 Ϫ166.19 Ϫ128.86 57.3 250.3 CH3COCH3(l), 58.08 Ϫ1790 Ϫ248.1 Ϫ155.4 124.7 200 propanone (acetone) EXPERIMENTAL DATA A17 Enthalpy Enthalpy Gibbs free Molar of of energy of heat Molar Molar combustion, formation, formation, capacity, entropy, mass, ⌬Hc° ⌬Hf° ⌬Gf° CP,m Sm° Substance M (gиmolϪ1 ) (kJиmolϪ1 ) (kJиmolϪ1 ) (kJиmolϪ1 ) (JиKϪ1 иmolϪ1 ) (JиKϪ1 иmolϪ1 ) Sugars C6H12O6(s), glucose 180.15 Ϫ2808 Ϫ1268 Ϫ910 — 212 C6H12O6(aq) 180.15 — — Ϫ917 — — C6H12O6(s), fructose 180.15 Ϫ2810 Ϫ1266 — — — C12H22O11(s), sucrose 342.29 Ϫ5645 Ϫ2222 Ϫ1545 — 360 Nitrogen compounds CO(NH2)2(s), urea 60.06 Ϫ632 Ϫ333.51 Ϫ197.33 93.14 104.60 C6H5NH2(l), aniline 93.13 Ϫ3393 ϩ31.6 ϩ149.1 — 191.3 NH2CH2COOH(s), glycine 75.07 Ϫ969 Ϫ532.9 Ϫ373.4 99.2 103.51 CH3NH2(g), methylamine 31.06 Ϫ1085 Ϫ22.97 ϩ32.16 53.1 243.41 A18 APPENDIX 2 2B STANDARD POTENTIALS AT 25°C Potentials in Electrochemical Order Reduction half-reaction E° (V) Reduction half-reaction E° (V) Strongly oxidizing NO3 Ϫ ϩ H2O ϩ 2 eϪ B NO2 Ϫ ϩ 2 OHϪ ϩ0.01 H4XeO6 ϩ 2 Hϩ ϩ 2 eϪ B XeO3 ϩ 3 H2O ϩ3.0 Ti4ϩ ϩ eϪ B Ti3ϩ 0.00 F2 ϩ 2 eϪ B 2 FϪ ϩ2.87 2 Hϩ ϩ 2 eϪ B H2 0, by definition O3 ϩ 2 Hϩ ϩ 2 eϪ B O2 ϩ H2O ϩ2.07 Fe3ϩ ϩ 3 eϪ B Fe Ϫ0.04 S2O8 2Ϫ ϩ 2 eϪ B 2 SO4 2Ϫ ϩ2.05 O2 ϩ H2O ϩ 2 eϪ B HO2 Ϫ ϩ OHϪ Ϫ0.08 Ag2ϩ ϩ eϪ B Agϩ ϩ1.98 Pb2ϩ ϩ 2 eϪ B Pb Ϫ0.13 Co3ϩ ϩ eϪ B Co2ϩ ϩ1.81 Inϩ ϩ eϪ B In Ϫ0.14 H2O2 ϩ 2 Hϩ ϩ 2 eϪ B 2 H2O ϩ1.78 Sn2ϩ ϩ 2 eϪ B Sn Ϫ0.14 Auϩ ϩ eϪ B Au ϩ1.69 AgI ϩ eϪ B Ag ϩ IϪ Ϫ0.15 Pb4ϩ ϩ 2 eϪ B Pb2ϩ ϩ1.67 Ni2ϩ ϩ 2 eϪ B Ni Ϫ0.23 2 HClO ϩ 2 Hϩ ϩ 2 eϪ B Cl2 ϩ 2 H2O ϩ1.63 V3ϩ ϩ eϪ B V2ϩ Ϫ0.26 Ce4ϩ ϩ eϪ B Ce3ϩ ϩ1.61 Co2ϩ ϩ 2 eϪ B Co Ϫ0.28 2 HBrO ϩ 2 Hϩ ϩ 2 eϪ B Br2 ϩ 2 H2O ϩ1.60 In3ϩ ϩ 3 eϪ B In Ϫ0.34 MnO4 Ϫ ϩ 8 Hϩ ϩ 5 eϪ B Mn2ϩ ϩ 4 H2O ϩ1.51 Tlϩ ϩ eϪ B Tl Ϫ0.34 Mn3ϩ ϩ eϪ B Mn2ϩ ϩ1.51 PbSO4 ϩ 2 eϪ B Pb ϩ SO4 2Ϫ Ϫ0.36 Au3ϩ ϩ 3 eϪ B Au ϩ1.40 Ti3ϩ ϩ eϪ B Ti2ϩ Ϫ0.37 Cl2 ϩ 2 eϪ B 2 ClϪ ϩ1.36 In2ϩ ϩ eϪ B Inϩ Ϫ0.40 Cr2O7 2Ϫ ϩ 14 Hϩ ϩ 6 eϪ B 2 Cr3ϩ ϩ 7 H2O ϩ1.33 Cd2ϩ ϩ 2 eϪ B Cd Ϫ0.40 O3 ϩ H2O ϩ 2 eϪ B O2 ϩ 2 OHϪ ϩ1.24 Cr3ϩ ϩ eϪ B Cr2ϩ Ϫ0.41 O2 ϩ 4 Hϩ ϩ 4 eϪ B 2 H2O ϩ1.23 Fe2ϩ ϩ 2 eϪ B Fe Ϫ0.44 MnO2 ϩ 4 Hϩ ϩ 2 eϪ B Mn2ϩ ϩ 2 H2O ϩ1.23 In3ϩ ϩ 2 eϪ B Inϩ Ϫ0.44 ClO4 Ϫ ϩ 2 Hϩ ϩ 2 eϪ B ClO3 Ϫ ϩ H2O ϩ1.23 S ϩ 2 eϪ B S2Ϫ Ϫ0.48 Pt2Ϫ ϩ 2 eϪ B Pt ϩ1.20 In3ϩ ϩ eϪ B In2ϩ Ϫ0.49 Br2 ϩ 2 eϪ B 2 BrϪ ϩ1.09 Gaϩ ϩ eϪ B Ga Ϫ0.53 Pu4ϩ ϩ eϪ B Pu3ϩ ϩ0.97 O2 ϩ eϪ B O2 Ϫ Ϫ0.56 NO3 Ϫ ϩ 4 Hϩ ϩ 3 eϪ B NO ϩ 2 H2O ϩ0.96 U4ϩ ϩ eϪ B U3ϩ Ϫ0.61 2 Hg2ϩ ϩ 2 eϪ B Hg2 2ϩ ϩ0.92 Se ϩ 2 eϪ B Se2Ϫ Ϫ0.67 ClOϪ ϩ H2O ϩ 2 eϪ B ClϪ ϩ 2 OHϪ ϩ0.89 Cr3ϩ ϩ 3 eϪ B Cr Ϫ0.74 Hg2ϩ ϩ 2 eϪ B Hg ϩ0.85 Zn2ϩ ϩ 2 eϪ B Zn Ϫ0.76 NO3 Ϫ ϩ 2 Hϩ ϩ eϪ B NO2 ϩ H2O ϩ0.80 Cd(OH)2 ϩ 2 eϪ B Cd ϩ 2 OHϪ Ϫ0.81 Agϩ ϩ eϪ B Ag ϩ0.80 2 H2O ϩ 2 eϪ B H2 ϩ 2 OHϪ Ϫ0.83 Hg2 2ϩ ϩ 2 eϪ B 2 Hg ϩ0.79 Te ϩ 2 eϪ B Te2Ϫ Ϫ0.84 AgF ϩ eϪ B Ag ϩ FϪ ϩ0.78 Cr2ϩ ϩ 2 eϪ B Cr Ϫ0.91 Fe3ϩ ϩ eϪ B Fe2ϩ ϩ0.77 Mn2ϩ ϩ 2 eϪ B Mn Ϫ1.18 BrOϪ ϩ H2O ϩ 2 eϪ B BrϪ ϩ 2 OHϪ ϩ0.76 V2ϩ ϩ 2 eϪ B V Ϫ1.19 MnO4 2Ϫ ϩ 2 H2O ϩ 2 eϪ B MnO2 ϩ 4 OHϪ ϩ0.60 Ti2ϩ ϩ 2 eϪ B Ti Ϫ1.63 MnO4 Ϫ ϩ eϪ B MnO4 2Ϫ ϩ0.56 Al3ϩ ϩ 3 eϪ B Al Ϫ1.66 I2 ϩ 2 eϪ B 2 IϪ ϩ0.54 U3ϩ ϩ 3 eϪ B U Ϫ1.79 I3 Ϫ ϩ 2 eϪ B 3 IϪ ϩ0.53 Be2ϩ ϩ 2 eϪ B Be Ϫ1.85 Cuϩ ϩ eϪ B Cu ϩ0.52 Mg2ϩ ϩ 2 eϪ B Mg Ϫ2.36 Ni(OH)3 ϩ eϪ B Ni(OH)2 ϩ OHϪ ϩ0.49 Ce3ϩ ϩ 3 eϪ B Ce Ϫ2.48 O2 ϩ 2 H2O ϩ 4 eϪ B 4 OHϪ ϩ0.40 La3ϩ ϩ 3 eϪ B La Ϫ2.52 ClO4 Ϫ ϩ H2O ϩ 2 eϪ B ClO3 Ϫ ϩ 2 OHϪ ϩ0.36 Naϩ ϩ eϪ B Na Ϫ2.71 Cu2ϩ ϩ 2 eϪ B Cu ϩ0.34 Ca2ϩ ϩ 2 eϪ B Ca Ϫ2.87 Hg2Cl2 ϩ 2 eϪ B 2 Hg ϩ 2 ClϪ ϩ0.27 Sr2ϩ ϩ 2 eϪ B Sr Ϫ2.89 AgCl ϩ eϪ B Ag ϩ ClϪ ϩ0.22 Ba2ϩ ϩ 2 eϪ B Ba Ϫ2.91 Bi3ϩ ϩ 3 eϪ B Bi ϩ0.20 Ra2ϩ ϩ 2 eϪ B Ra Ϫ2.92 SO4 2Ϫ ϩ 4 Hϩ ϩ 2 eϪ B H2SO3 ϩ H2O ϩ0.17 Csϩ ϩ eϪ B Cs Ϫ2.92 Cu2ϩ ϩ eϪ B CuϪ ϩ0.15 Rbϩ ϩ eϪ B Rb Ϫ2.93 Sn4ϩ ϩ 2eϪ B Sn2ϩ ϩ0.15 Kϩ ϩ eϪ B K Ϫ2.93 AgBr ϩ eϪ B Ag ϩ BrϪ ϩ0.07 Liϩ ϩ eϪ B Li Ϫ3.05 Strongly reducing EXPERIMENTAL DATA A19 Potentials in Alphabetical Order Reduction half-reaction E° (V) Reduction half-reaction E° (V) Agϩ ϩ eϪ B Ag ϩ0.80 In2ϩ ϩ eϪ B Inϩ Ϫ0.40 Ag2ϩ ϩ eϪ B Agϩ ϩ1.98 In3ϩ ϩ eϪ B In2ϩ Ϫ0.49 AgBr ϩ eϪ B Ag ϩ BrϪ ϩ0.07 In3ϩ ϩ 2 eϪ B Inϩ Ϫ0.44 AgCl ϩ eϪ B Ag ϩ ClϪ ϩ0.22 In3ϩ ϩ 3 eϪ B In Ϫ0.34 AgF ϩ eϪ B Ag ϩ FϪ ϩ0.78 Kϩ ϩ eϪ B K Ϫ2.93 AgI ϩ eϪ B Ag ϩ IϪ Ϫ0.15 La3ϩ ϩ 3 eϪ B La Ϫ2.52 Al3ϩ ϩ 3 eϪ B Al Ϫ1.66 Liϩ ϩ eϪ B Li Ϫ3.05 Auϩ ϩ eϪ B Au ϩ1.69 Mg2ϩ ϩ 2 eϪ B Mg Ϫ2.36 Au3ϩ ϩ 3 eϪ B Au ϩ1.40 Mn2ϩ ϩ 2 eϪ B Mn Ϫ1.18 Ba2ϩ ϩ 2 eϪ B Ba Ϫ2.91 Mn3ϩ ϩ eϪ B Mn2ϩ ϩ1.51 Be2ϩ ϩ 2 eϪ B Be Ϫ1.85 MnO2 ϩ 4 Hϩ ϩ 2 eϪ B Mn2ϩ ϩ 2 H2O ϩ1.23 Bi3ϩ ϩ 3 eϪ B Bi ϩ0.20 MnO4 Ϫ ϩ eϪ B MnO4 2Ϫ ϩ0.56 Br2 ϩ 2 eϪ B 2 BrϪ ϩ1.09 MnO4 Ϫ ϩ 8 Hϩ ϩ 5 eϪ B Mn2ϩ ϩ 4 H2O ϩ1.51 BrOϪ ϩ H2O ϩ 2 eϪ B BrϪ ϩ 2 OHϪ ϩ0.76 MnO4 2Ϫ ϩ 2 H2O ϩ 2 eϪ B MnO2 ϩ 4 OHϪ ϩ0.60 Ca2ϩ ϩ 2 eϪ B Ca Ϫ2.87 NO3 Ϫ ϩ 2 Hϩ ϩ eϪ B NO2 ϩ H2O ϩ0.80 Cd2ϩ ϩ 2 eϪ B Cd Ϫ0.40 NO3 Ϫ ϩ 4 Hϩ ϩ 3 eϪ B NO ϩ 2 H2O ϩ0.96 Cd(OH)2 ϩ 2 eϪ B Cd ϩ 2 OHϪ Ϫ0.81 NO3 Ϫ ϩ H2O ϩ 2 eϪ B NO2 Ϫ ϩ 2 OHϪ ϩ0.01 Ce3ϩ ϩ 3 eϪ B Ce Ϫ2.48 Naϩ ϩ eϪ B Na Ϫ2.71 Ce4ϩ ϩ eϪ B Ce3ϩ ϩ1.61 Ni2ϩ ϩ 2 eϪ B Ni Ϫ0.23 Cl2 ϩ 2 eϪ B 2 ClϪ ϩ1.36 Ni(OH)3 ϩ eϪ B Ni(OH)2 ϩ OHϪ ϩ0.49 ClOϪ ϩ H2O ϩ 2 eϪ B ClϪ ϩ 2 OHϪ ϩ0.89 O2 ϩ eϪ B O2 Ϫ Ϫ0.56 ClO4 Ϫ ϩ 2 Hϩ ϩ 2 eϪ B ClO3 Ϫ ϩ H2O ϩ1.23 O2 ϩ 4 Hϩ ϩ 4 eϪ B 2 H2O ϩ1.23 ClO4 Ϫ ϩ H2O ϩ 2 eϪ B ClO3 Ϫ ϩ 2 OHϪ ϩ0.36 O2 ϩ H2O ϩ 2 eϪ B HO2 Ϫ ϩ OHϪ Ϫ0.08 Co2ϩ ϩ 2 eϪ B Co Ϫ0.28 O2 ϩ 2 H2O ϩ 4 eϪ B 4 OHϪ ϩ0.40 Co3ϩ ϩ eϪ B Co2ϩ ϩ1.81 O3 ϩ 2 Hϩ ϩ 2 eϪ B O2 ϩ H2O ϩ2.07 Cr2ϩ ϩ 2 eϪ B Cr Ϫ0.91 O3 ϩ H2O ϩ 2 eϪ B O2 ϩ 2 OHϪ ϩ1.24 Cr2O7 2Ϫ ϩ 14 Hϩ ϩ 6 eϪ B 2 Cr3ϩ ϩ 7 H2O ϩ1.33 Pb2ϩ ϩ 2 eϪ B Pb Ϫ0.13 Cr3ϩ ϩ 3 eϪ B Cr Ϫ0.74 Pb4ϩ ϩ 2 eϪ B Pb2ϩ ϩ1.67 Cr3ϩ ϩ eϪ B Cr2ϩ Ϫ0.41 PbSO4 ϩ 2 eϪ B Pb ϩ SO4 2Ϫ Ϫ0.36 Csϩ ϩ eϪ B Cs Ϫ2.92 Pt2ϩ ϩ 2 eϪ B Pt ϩ1.20 Cuϩ ϩ eϪ B Cu ϩ0.52 Pu4ϩ ϩ eϪ B Pu3ϩ ϩ0.97 Cu2ϩ ϩ 2 eϪ B Cu ϩ0.34 Ra2ϩ ϩ 2 eϪ B Ra Ϫ2.92 Cu2ϩ ϩ eϪ B Cuϩ ϩ0.15 Rbϩ ϩ eϪ B Rb Ϫ2.93 F2 ϩ 2 eϪ B 2 FϪ ϩ2.87 S ϩ 2 eϪ B S2Ϫ Ϫ0.48 Fe2ϩ ϩ 2 eϪ B Fe Ϫ0.44 SO4 2Ϫ ϩ 4 Hϩ ϩ 2 eϪ B H2SO3 ϩ H2O ϩ0.17 Fe3ϩ ϩ 3 eϪ B Fe Ϫ0.04 S2O8 2Ϫ ϩ 2 eϪ B 2 SO4 2Ϫ ϩ2.05 Fe3ϩ ϩ eϪ B Fe2ϩ ϩ0.77 Se ϩ 2 eϪ B Se2Ϫ Ϫ0.67 Gaϩ ϩ eϪ B Ga Ϫ0.53 Sn2ϩ ϩ 2 eϪ B Sn Ϫ0.14 2 Hϩ ϩ 2 eϪ B H2 0, by definition Sn4ϩ ϩ 2 eϪ B Sn2ϩ ϩ0.15 2 HBrO ϩ 2 Hϩ ϩ 2 eϪ B Br2 ϩ 2 H2O ϩ1.60 Sr2ϩ ϩ 2 eϪ B Sr Ϫ2.89 2 HClO ϩ 2 Hϩ ϩ 2 eϪ B Cl2 ϩ 2 H2O ϩ1.63 Te ϩ 2 eϪ B Te2Ϫ Ϫ0.84 2 H2O ϩ 2 eϪ B H2 ϩ 2 OHϪ Ϫ0.83 Ti2ϩ ϩ 2 eϪ B Ti Ϫ1.63 H2O2 ϩ 2 Hϩ ϩ 2 eϪ B 2 H2O ϩ1.78 Ti3ϩ ϩ eϪ B Ti2ϩ Ϫ0.37 H4XeO6 ϩ 2 Hϩ ϩ 2 eϪ B XeO3 ϩ 3 H2O ϩ3.0 Ti4ϩ ϩ eϪ B Ti3ϩ 0.00 Hg2 2ϩ ϩ 2 eϪ B 2 Hg ϩ0.79 Tlϩ ϩ eϪ B Tl Ϫ0.34 Hg2ϩ ϩ 2 eϪ B Hg ϩ0.85 U3ϩ ϩ 3 eϪ B U Ϫ1.79 2 Hg2ϩ ϩ 2 eϪ B Hg2 2ϩ ϩ0.92 U4ϩ ϩ eϪ B U3ϩ Ϫ0.61 Hg2Cl2 ϩ 2 eϪ B 2 Hg ϩ 2 ClϪ ϩ0.27 V2ϩ ϩ 2 eϪ B V Ϫ1.19 I2 ϩ 2 eϪ B 2 IϪ ϩ0.54 V3ϩ ϩ eϪ B V2ϩ Ϫ0.26 I3 Ϫ ϩ 2 eϪ B 3 IϪ ϩ0.53 Zn2ϩ ϩ 2 eϪ B Zn Ϫ0.76 Inϩ ϩ eϪ B In Ϫ0.14 A20 APPENDIX 2 2C GROUND-STATE ELECTRON CONFIGURATIONS* Z Symbol Configuration Z Symbol Configuration 1 H 1s1 29 Cu [Ar]3d10 4s1 2 He 1s2 30 Zn [Ar]3d10 4s2 3 Li [He]2s1 31 Ga [Ar]3d10 4s2 4p1 4 Be [He]2s2 32 Ge [Ar]3d10 4s2 4p2 5 B [He]2s2 2p1 33 As [Ar]3d10 4s2 4p3 6 C [He]2s2 2p2 34 Se [Ar]3d10 4s2 4p4 7 N [He]2s2 2p3 35 Br [Ar]3d10 4s2 4p5 8 O [He]2s2 2p4 36 Kr [Ar]3d10 4s2 4p6 9 F [He]2s2 2p5 37 Rb [Kr]5s1 10 Ne [He]2s2 2p6 38 Sr [Kr]5s2 11 Na [Ne]3s1 39 Y [Kr]4d1 5s2 12 Mg [Ne]3s2 40 Zr [Kr]4d2 5s2 13 Al [Ne]3s2 3p1 41 Nb [Kr]4d4 5s1 14 Si [Ne]3s2 3p2 42 Mo [Kr]4d5 5s1 15 P [Ne]3s2 3p3 43 Tc [Kr]4d5 5s2 16 S [Ne]3s2 3p4 44 Ru [Kr]4d7 5s1 17 Cl [Ne]3s2 3p5 45 Rh [Kr]4d8 5s1 18 Ar [Ne]3s2 3p6 46 Pd [Kr]4d10 19 K [Ar]4s1 47 Ag [Kr]4d10 5s1 20 Ca [Ar]4s2 48 Cd [Kr]4d10 5s2 21 Sc [Ar]3d1 4s2 49 In [Kr]4d10 5s2 5p1 22 Ti [Ar]3d2 4s2 50 Sn [Kr]4d10 5s2 5p2 23 V [Ar]3d3 4s2 51 Sb [Kr]4d10 5s2 5p3 24 Cr [Ar]3d5 4s1 52 Te [Kr]4d10 5s2 5p4 25 Mn [Ar]3d5 4s2 53 I [Kr]4d10 5s2 5p5 26 Fe [Ar]3d6 4s2 54 Xe [Kr]4d10 5s2 5p6 27 Co [Ar]3d7 4s2 55 Cs [Xe]6s1 28 Ni [Ar]3d8 4s2 56 Ba [Xe]6s2 EXPERIMENTAL DATA A21 Z Symbol Configuration Z Symbol Configuration 57 La [Xe]5d1 6s2 85 At [Xe]4f14 5d10 6s2 6p5 58 Ce [Xe]4f1 5d1 6s2 86 Rn [Xe]4f14 5d10 6s2 6p6 59 Pr [Xe]4f3 6s2 87 Fr [Rn]7s1 60 Nd [Xe]4f4 6s2 88 Ra [Rn]7s2 61 Pm [Xe]4f5 6s2 89 Ac [Rn]6d1 7s2 62 Sm [Xe]4f6 6s2 90 Th [Rn]6d2 7s2 63 Eu [Xe]4f7 6s2 91 Pa [Rn]5f2 6d1 7s2 64 Gd [Xe]4f7 5d1 6s2 92 U [Rn]5f3 6d1 7s2 65 Tb [Xe]4f9 6s2 93 Np [Rn]5f4 6d1 7s2 66 Dy [Xe]4f10 6s2 94 Pu [Rn]5f6 7s2 67 Ho [Xe]4f11 6s2 95 Am [Rn]5f7 7s2 68 Er [Xe]4f12 6s2 96 Cm [Rn]5f7 6d1 7s2 69 Tm [Xe]4f13 6s2 97 Bk [Rn]5f9 7s2 70 Yb [Xe]4f14 6s2 98 Cf [Rn]5f10 7s2 71 Lu [Xe]4f14 5d1 6s2 99 Es [Rn]5f11 7s2 72 Hf [Xe]4f14 5d2 6s2 100 Fm [Rn]5f12 7s2 73 Ta [Xe]4f14 5d3 6s2 101 Md [Rn]5f13 7s2 74 W [Xe]4f14 5d4 6s2 102 No [Rn]5f14 7s2 75 Re [Xe]4f14 5d5 6s2 103 Lr [Rn]5f14 6d1 7s2 76 Os [Xe]4f14 5d6 6s2 104 Rf [Rn]5f14 6d2 7s2 (?) 77 Ir [Xe]4f14 5d7 6s2 105 Db [Rn]5f14 6d3 7s2 (?) 78 Pt [Xe]4f14 5d9 6s1 106 Sg [Rn]5f14 6d4 7s2 (?) 79 Au [Xe]4f14 5d10 6s1 107 Bh [Rn]5f14 6d5 7s2 (?) 80 Hg [Xe]4f14 5d10 6s2 108 Hs [Rn]5f14 6d6 7s2 (?) 81 Tl [Xe]4f14 5d10 6s2 6p1 109 Mt [Rn]5f14 6d7 7s2 (?) 82 Pb [Xe]4f14 5d10 6s2 6p2 110 Ds [Rn]5f14 6d8 7s2 (?) 83 Bi [Xe]4f14 5d10 6s2 6p3 111 Rg [Rn]5f14 6d10 7s1 (?) 84 Po [Xe]4f14 5d10 6s2 6p4 *The electron configurations followed by a question mark are speculative. A22 APPENDIX 2 2D THE ELEMENTS Melting Atomic Molar mass* Normal Density point Element Symbol number (gиmolϪ1 ) state† (gиcmϪ3 ) (°C) actinium Ac 89 (227) s, m 10.07 1230 (Greek aktis, ray) aluminum Al 13 26.98 s, m 2.70 660 (from alum, salts of the form KAl(SO4)2и12H2O) americium Am 95 (243) s, m 13.67 990 (the Americas) antimony Sb 51 121.76 s, md 6.69 631 (probably a corruption of an old Arabic word; Latin stibium) argon Ar 18 39.95 g, nm 1.66‡ Ϫ189 (Greek argos, inactive) arsenic As 33 74.92 s, md 5.78 613§ (Greek arsenikos, male) astatine At 85 (210) s, nm — 300 (Greek astatos, unstable) barium Ba 56 137.33 s, m 3.59 710 (Greek barys, heavy) berkelium Bk 97 (247) s, m 14.79 986 (Berkeley, California) beryllium Be 4 9.01 s, m 1.85 1285 (from the mineral beryl, Be3Al2SiO18) bismuth Bi 83 208.98 s, m 8.90 271 (German weisse Masse, white mass) bohrium Bh 107 (264) — — — (Niels Bohr) boron B 5 10.81 s, md 2.47 2300 (Arabic buraq, borax, Na2B4O7и10H2O; bor(ax) ϩ (carb)on bromine Br 35 79.90 l, nm 3.12 Ϫ7 (Greek bromos, stench) cadmium Cd 48 112.41 s, m 8.65 321 (Greek Cadmus, founder of Thebes) calcium Ca 20 40.08 s, m 1.53 840 (Latin calx, lime) californium Cf 98 (251) s, m — — (California) carbon C 6 12.01 s, nm 2.27 3700§ (Latin carbo, coal or charcoal) cerium Ce 58 140.12 s, m 6.71 800 (the asteroid Ceres, discovered 2 days earlier) cesium Cs 55 132.91 s, m 1.87 28 (Latin caesius, sky blue) chlorine Cl 17 35.45 g, nm 1.66‡ Ϫ101 (Greek chloros, yellowish green) chromium Cr 24 52.00 s, m 7.19 1860 (Greek chroma, color) cobalt Co 27 58.93 s, m 8.80 1494 (German Kobold, evil spirit; Greek kobalos, goblin) EXPERIMENTAL DATA A23 Boiling Ionization Electron Atomic Ionic point energies affinity Principal radius radius || (°C) (kJиmolϪ1 ) (kJиmolϪ1 ) Electronegativity oxidation states (pm) (pm) 3200 499, 1170, 1900 — 1.1 ϩ3 188 118(3ϩ) 2467 577, 1817, 2744 ϩ43 1.6 ϩ3 143 54(3ϩ) 2600 578 — 1.3 ϩ3 173 107(3ϩ) 1750 834, 1794, 2443 ϩ103 2.1 Ϫ3, ϩ3, ϩ5 141 89(3ϩ) Ϫ186 1520 Ͻ0 — 0 174 — — 947, 1798 ϩ78 2.2 Ϫ3, ϩ3, ϩ5 121 222(3Ϫ) 350 1037, 1600 ϩ270 2.0 Ϫ1 — 227(1Ϫ) 1640 502, 965 ϩ14 0.89 ϩ2 217 135(2ϩ) — 601 — 1.3 ϩ3 — 87(4ϩ) 2470 900, 1757 Ͻ0 1.6 ϩ2 113 34(2ϩ) 1650 703, 1610, 2466 ϩ91 2.0 ϩ3, ϩ5 155 96(3ϩ) — 660 — — ϩ5 128# 83(5ϩ)# 3931 799, 2427, 3660 ϩ27 2.0 ϩ3 88 23(3ϩ) 59 1140, 2104 ϩ325 3.0 Ϫ1, ϩ1, ϩ3, ϩ4, ϩ5, ϩ7 114 196(1Ϫ) 765 868, 1631 Ͻ0 1.7 ϩ2 149 103(2ϩ) 1490 590, 1145, 4910 ϩ2 1.3 ϩ2 197 100(2ϩ) — 608 — 1.3 ϩ3 169 117(2ϩ) — 1090, 2352, 4620 ϩ122 2.6 Ϫ4, Ϫ1, ϩ2, ϩ4 77 260(4Ϫ) 3000 527, 1047, 1949 Ͻ50 1.1 ϩ3, ϩ4 183 107(3ϩ) 678 376, 2420 146 0.79 ϩ1 265 167(1ϩ) 234 1255, 2297 ϩ349 3.2 Ϫ1, ϩ1, ϩ3, 99 181(1Ϫ) ϩ4, ϩ5, ϩ6, ϩ7 2600 653, 1592, 2987 ϩ64 1.7 ϩ2, ϩ3 125 84(2ϩ) 2900 760, 1646, 3232 ϩ64 1.9 ϩ3, ϩ6 125 64(3ϩ) (continued) A24 APPENDIX 2 Melting Atomic Molar mass* Normal Density point Element Symbol number (gиmolϪ1 ) state† (gиcmϪ3 ) (°C) copper Cu 29 63.55 s, m 8.93 1083 (Latin cuprum, from Cyprus) curium Cm 96 (247) s, m 13.30 1340 (Marie Curie) darmstadtium Ds 110 — — — — (town in Germany) dubnium Db 105 (262) s, m 29 — (Dubna) dysprosium Dy 66 162.50 s, m 8.53 1410 (Greek dysprositos, hard to get at) einsteinium Es 99 (252) s, m — — (Albert Einstein) erbium Er 68 167.26 s, m 9.04 1520 (Ytterby, a town in Sweden) europium Eu 63 151.96 s, m 5.25 820 (Europe) fermium Fm 100 (257) s, m — — (Enrico Fermi, an Italian physicist) fluorine F 9 19.00 g, nm 1.51‡ Ϫ220 (Latin fluere, to flow) francium Fr 87 (223) s, m — 27 (France) gadolinium Gd 64 157.25 s, m 7.87 1310 (Johann Gadolin, a Finnish chemist) gallium Ga 31 69.72 s, m 5.91 30 (Latin Gallia, France; also a pun on the discoverer’s forename, Le Coq) germanium Ge 32 72.64 s, md 5.32 937 (Latin Germania, Germany) gold Au 79 196.97 s, m 19.28 1064 (Anglo-Saxon gold; Latin aurum, gold) hafnium Hf 72 178.49 s, m 13.28 2230 (Latin Hafnia, Copenhagen) hassium Hs 108 (277) — — — (Hesse, the German state) helium He 2 4.00 g, nm 0.12‡ — (Greek helios, the sun) holmium Ho 67 164.93 s, m 8.80 1470 (Latin Holmia, Stockholm) hydrogen H 1 1.0079 g, nm 0.070‡ Ϫ259 (Greek hydro ϩ genes, Water-forming) indium In 49 114.82 s, m 7.29 156 (from the bright indigo line in its spectrum) iodine I 53 126.90 s, nm 4.95 114 (Greek ioeide¯s, violet) iridium Ir 77 192.22 s, m 22.56 2447 (Greek and Latin iris, rainbow) iron Fe 26 55.84 s, m 7.87 1540 (Anglo-Saxon iron; Latin ferrum) EXPERIMENTAL DATA A25 Boiling Ionization Electron Atomic Ionic point energies affinity Principal radius radius || (°C) (kJиmolϪ1 ) (kJиmolϪ1 ) Electronegativity oxidation states (pm) (pm) 2567 785, 1958, 3554 ϩ118 1.9 ϩ1, ϩ2 128 72(2ϩ) — 581 — 1.3 ϩ3 174 99(3ϩ) — — — — — — — — 640 — — ϩ5 139# 68(5ϩ)# 2600 572, 1126, 2200 — 1.2 ϩ3 177 91(3ϩ) — 619 Ͻ50 1.3 ϩ3 203 98(3ϩ) 2600 589, 1151, 2194 Ͻ50 1.2 ϩ3 176 89(3ϩ) 1450 547, 1085, 2404 Ͻ50 — ϩ3 204 98(3ϩ) — 627 — 1.3 ϩ3 — 91(3ϩ) Ϫ188 1680, 3374 ϩ328 4.0 Ϫ1 58 133(1Ϫ) 677 400 ϩ44 0.7 ϩ1 270 180(1ϩ) 3000 592, 1167, 1990 Ͻ50 1.2 ϩ2, ϩ3 180 97(3ϩ) 2403 577, 1979, 2963 ϩ29 1.6 ϩ1, ϩ3 122 62(3ϩ) 2830 784, 1557, 3302 ϩ116 2.0 ϩ2, ϩ4 122 90(2ϩ) 2807 890, 1980 ϩ223 2.5 ϩ1, ϩ3 144 91(3ϩ) 5300 642, 1440, 2250 0 1.3 ϩ4 156 84(3ϩ) — 750 — — ϩ3 126# 80(4ϩ)# Ϫ269 2370, 5250 Ͻ0 — 0 128 — 2300 581, 1139 Ͻ50 1.2 ϩ3 177 89(3ϩ) Ϫ253 1310 ϩ73 2.2 Ϫ1, ϩ1 30 154(1Ϫ) 2080 556, 1821 ϩ29 1.8 ϩ1, ϩ3 163 80(3ϩ) 184 1008, 1846 ϩ295 2.7 Ϫ1, ϩ1, ϩ3, ϩ5, ϩ7 133 220(1Ϫ) 4550 880 ϩ151 2.2 ϩ3, ϩ4 136 75(3ϩ) 2760 759, 1561, 2957 ϩ16 1.8 ϩ2, ϩ3 124 82(2ϩ) (continued) A26 APPENDIX 2 Melting Atomic Molar mass* Normal Density point Element Symbol number (gиmolϪ1 ) state† (gиcmϪ3 ) (°C) krypton Kr 36 83.80 g, nm 3.00‡ Ϫ157 (Greek kryptos, hidden) lanthanum La 57 138.91 s, m 6.17 920 (Greek lanthanein, to lie hidden) lawrencium Lr 103 (262) s, m — — (Ernest Lawrence, an American physicist) lead Pb 82 207.2 s, m 11.34 328 (Anglo-Saxon lead; Latin plumbum) lithium Li 3 6.94 s, m 0.53 181 (Greek lithos, stone) lutetium Lu 71 174.97 s, m 9.84 1700 (Lutetia, ancient name of Paris) magnesium Mg 12 24.31 s, m 1.74 650 (Magnesia, a district in Thessaly, Greece) manganese Mn 25 54.94 s, m 7.47 1250 (Greek and Latin magnes, magnet) meitnerium Mt 109 (268) — — — (Lise Meitner) mendelevium Md 101 (258) — — — (D. Mendeleev) mercury Hg 80 200.59 l, m 13.55 Ϫ39 (the planet Mercury; Latin hydrargyrum, liquid silver) molybdenum Mo 42 95.94 s, m 10.22 2620 (Greek molybdos, lead) neodymium Nd 60 144.24 s, m 7.00 1024 (Greek neos ϩ didymos, new twin) neon Ne 10 20.18 g, nm 1.44‡ Ϫ249 (Greek neos, new) neptunium Np 93 (237) s, m 20.45 640 (the planet Neptune) nickel Ni 28 58.69 s, m 8.91 1455 (German Nickel, Old Nick, Satan) niobium Nb 41 92.91 s, m 8.57 2425 (Niobe, daughter of Tantalus; see tantalum) nitrogen N 7 14.01 g, nm 1.04‡ Ϫ210 (Greek nitron ϩ genes, soda–forming) nobelium No 102 (259) s, m — — (Alfred Nobel, the founder of the Nobel prizes) osmium Os 76 190.23 s, m 22.58 3030 (Greek osme, a smell) oxygen O 8 16.00 g, nm 1.14‡ Ϫ218 (Greek oxys ϩ genes, acid forming) palladium Pd 46 106.42 s, m 12.00 1554 (the asteroid Pallas, discovered at about the same time) phosphorus P 15 30.97 s, nm 1.82 44 (Greek phosphoros, light bearing) EXPERIMENTAL DATA A27 Boiling Ionization Electron Atomic Ionic point energies affinity Principal radius radius || (°C) (kJиmolϪ1 ) (kJиmolϪ1 ) Electronegativity oxidation states (pm) (pm) Ϫ153 1350, 2350 Ͻ0 — ϩ2 189 169(1ϩ) 3450 538, 1067, 1850 ϩ50 1.1 ϩ3 188 122(3ϩ) — — — 1.3 ϩ3 — 88(3ϩ) 1760 716, 1450 ϩ35 2.3 ϩ2, ϩ4 175 132(2ϩ) 1347 519, 7298 ϩ60 1.0 ϩ1 152 76(1ϩ) 3400 524, 1340, 2022 Ͻ50 1.3 ϩ3 173 85(3ϩ) 1100 736, 1451 Ͻ0 1.3 ϩ2 160 72(2ϩ) 2120 717, 1509 Ͻ0 1.6 ϩ2, ϩ3, ϩ4, ϩ7 137 91(2ϩ) — 840 — — ϩ2 — 83(2ϩ) — 635 — 1.3 ϩ3 — 90(3ϩ) 357 1007, 1810 Ϫ18 2.0 ϩ1, ϩ2 160 112(2ϩ) 4830 685, 1558, 2621 ϩ72 2.2 ϩ4, ϩ5, ϩ6 136 92(2ϩ) 3100 530, 1035 Ͻ0 1.1 ϩ3 182 104(3ϩ) Ϫ246 2080, 3952 0 — 0 — — — 597 — 1.4 ϩ5 150 88(5ϩ) 2150 737, 1753 ϩ156 1.9 ϩ2, ϩ3 125 78(2ϩ) 5000 664, 1382 ϩ86 1.6 ϩ5 143 69(5ϩ) Ϫ196 1400, 2856 Ϫ7 3.0 Ϫ3, ϩ3, ϩ5 75 171(3Ϫ) — 642 — 1.3 ϩ2 — 113(2ϩ) 5000 840 ϩ106 2.2 ϩ3, ϩ4 135 81(3ϩ) Ϫ183 1310, 3388 ϩ141, Ϫ844 3.4 Ϫ2 66 140(2Ϫ) 3000 805, 1875 ϩ54 2.2 ϩ2, ϩ4 138 86(2ϩ) 280 1011, 1903, 2912 ϩ72 2.2 Ϫ3, ϩ3, ϩ5 110 212(3Ϫ) (continued) A28 APPENDIX 2 Melting Atomic Molar mass* Normal Density point Element Symbol number (gиmolϪ1 ) state† (gиcmϪ3 ) (°C) platinum Pt 78 195.08 s, m 21.45 1772 (Spanish plata, silver) plutonium Pu 94 (244) s, m 19.81 640 (the planetlike Pluto) polonium Po 84 (209) s, md 9.40 254 (Poland) potassium K 19 39.10 s, m 0.86 64 (from potash; Latin kalium and Arabic qali, alkali) praseodymium Pr 59 140.91 s, m 6.78 935 (Greek prasios ϩ didymos, green twin) promethium Pm 61 (145) s, m 7.22 1168 (Prometheus, the Greek god) protactinium Pa 91 231.04 s, m 15.37 1200 (Greek protos ϩ aktis, first ray) radium Ra 88 (226) s, m 5.00 700 (Latin radius, ray) radon Rn 86 (222) g, nm 4.40‡ Ϫ71 (from radium) rhenium Re 75 186.21 s, m 21.02 3180 (Latin Rhenus, Rhine) rhodium Rh 45 102.90 s, m 12.42 1963 (Greek rhodon, rose; its aqueous solutions are often rose-colored) roentgenium Rg 111 — — — — (W. Roentgen, discoverer of x-rays) rubidium Rb 37 85.47 s, m 1.53 39 (Latin rubidus, deep red, “flushed”) ruthenium Ru 44 101.07 s, m 12.36 2310 (Latin Ruthenia, Russia) rutherfordium Rf 104 (261) — — — (Ernest Rutherford) samarium Sm 62 150.36 s, m 7.54 1060 (from samarskite, a mineral) scandium Sc 21 44.96 s, m 2.99 1540 (Latin Scandia, Scandinavia) seaborgium Sg 106 (266) — — — (Glenn Seaborg) selenium Se 34 78.96 s, nm 4.79 220 (Greek se¯le¯ne¯, the moon) silicon Si 14 28.09 s, md 2.33 1410 (Latin silex, flint) silver Ag 47 107.87 s, m 10.50 962 (Anglo-Saxon seolfor; Latin argentum) sodium Na 11 22.99 s, m 0.97 98 (English soda; Latin natrium) strontium Sr 38 87.62 s, m 2.58 770 (Strontian, Scotland) sulfur S 16 32.06 s, nm 2.09 115 (Sanskrit sulvere) tantalum Ta 73 180.95 s, m 16.65 3000 (Tantalos, Greek mythological figure) EXPERIMENTAL DATA A29 Boiling Ionization Electron Atomic Ionic point energies affinity Principal radius radius || (°C) (kJиmolϪ1 ) (kJиmolϪ1 ) Electronegativity oxidation states (pm) (pm) 3720 870, 1791 ϩ205 2.3 ϩ2, ϩ4 138 85(2ϩ) 3200 585 — 1.3 ϩ3, ϩ4 151 108(3ϩ) 960 812 ϩ174 2.0 ϩ2, ϩ4 167 65(4ϩ) 774 418, 3051 ϩ48 0.82 ϩ1 227 138(1ϩ) 3000 523, 1018 Ͻ50 1.1 ϩ3 183 106(3ϩ) 3300 536, 1052 Ͻ50 — ϩ3 181 106(3ϩ) 4000 568 — 1.5 ϩ5 161 89(5ϩ) 1500 509, 979 — 0.9 ϩ2 223 152(2ϩ) Ϫ62 1036, 1930 Ͻ0 — ϩ2 — — 5600 760, 1260 ϩ14 1.9 ϩ4, ϩ7 137 72(4ϩ) 3700 720, 1744 ϩ110 2.3 ϩ3 134 75(3ϩ) — — — — — — — 688 402, 2632 ϩ47 0.82 ϩ1 248 152(1ϩ) 4100 711, 1617 ϩ101 2.2 ϩ2, ϩ3, ϩ4 134 77(3ϩ) — 490 — — ϩ4 150# 67(4ϩ)# 1600 543, 1068 Ͻ50 1.2 ϩ3 180 100(3ϩ) 2800 631, 1235 ϩ18 1.4 ϩ3 161 83(3ϩ) — 730 — — ϩ6 132# 86(5ϩ)# 685 941, 2044 ϩ195 2.6 Ϫ2, ϩ4, ϩ6 117 198(2Ϫ) 2620 786, 1577 ϩ134 1.9 ϩ4 117 26(4ϩ) 2212 731, 2073 ϩ126 1.9 ϩ1 144 113(1ϩ) 883 494, 4562 ϩ53 0.93 ϩ1 154 102(1ϩ) 1380 548, 1064 ϩ5 0.95 ϩ2 215 118(2ϩ) 445 1000, 2251 ϩ200, Ϫ532 2.6 Ϫ2, ϩ4, ϩ6 104 184(2Ϫ) 5400 761 ϩ14 1.5 ϩ5 143 72(3ϩ) (continued) A30 APPENDIX 2 Melting Atomic Molar mass* Normal Density point Element Symbol number (gиmolϪ1 ) state† (gиcmϪ3 ) (°C) technetium Tc 43 (98) s, m 11.50 2200 (Greek techne¯tos, artificial) tellurium Te 52 127.60 s, md 6.25 450 (Latin tellus, earth) terbium Tb 65 158.93 s, m 8.27 1360 (Ytterby, a town in Sweden) thallium Tl 81 204.38 s, m 11.87 304 (Greek thallos, a green shoot) thorium Th 90 232.04 s, m 11.73 1700 (Thor, Norse god of thunder, weather, and crops) thulium Tm 69 168.93 s, m 9.33 1550 (Thule, early name for Scandinavia) tin Sn 50 118.71 s, m 7.29 232 (Anglo-Saxon tin; Latin stannum) titanium Ti 22 47.87 s, m 4.55 1660 (Titans, Greek mythological figures, sons of the Earth) tungsten W 74 183.84 s, m 19.30 3387 (Swedish tung ϩ sten, heavy stone; from wolframite) uranium U 92 238.03 s, m 18.95 1135 (the planet Uranus) vanadium V 23 50.94 s, m 6.11 1920 (Vanadis, Scandinavian mythological figure) xenon Xe 54 131.29 g, nm 3.56‡ Ϫ112 (Greek xenos, stranger) ytterbium Yb 70 173.04 s, m 6.97 824 (Ytterby, a town in Sweden) yttrium Y 39 88.91 s, m 4.48 1510 (Ytterby, a town in Sweden) zinc Zn 30 65.41 s, m 7.14 420 (Anglo-Saxon zinc) zirconium Zr 40 91.22 s, m 6.51 1850 (Arabic zargun, gold color) EXPERIMENTAL DATA A31 Boiling Ionization Electron Atomic Ionic point energies affinity Principal radius radius || (°C) (kJиmolϪ1 ) (kJиmolϪ1 ) Electronegativity oxidation states (pm) (pm) 4600 702, 1472 ϩ96 1.9 ϩ4, ϩ7 136 72(4ϩ) 990 870, 1775 ϩ190 2.1 Ϫ2, ϩ4 137 221(2Ϫ) 2500 565, 1112 Ͻ50 — ϩ3 178 97(3ϩ) 1457 590, 1971 ϩ19 2.0 ϩ1, ϩ3 170 105(3ϩ) 4500 587, 1110 — 1.3 ϩ4 180 99(4ϩ) 2000 597, 1163 Ͻ50 1.2 ϩ3 175 94(3ϩ) 2720 707, 1412 ϩ116 2.0 ϩ2, ϩ4 141 93(2ϩ) 3300 658, 1310 ϩ7.6 1.5 ϩ4 145 69(4ϩ) 5420 770 ϩ79 2.4 ϩ5, ϩ6 137 62(6ϩ) 4000 584, 1420 — 1.4 ϩ6 154 80(6ϩ) 3400 650, 1414 ϩ51 1.6 ϩ4, ϩ5 132 61(4ϩ) Ϫ108 1170, 2046 Ͻ0 2.6 ϩ2, ϩ4, ϩ6 218 190(1ϩ) 1500 603, 1176 Ͻ50 — ϩ3 194 86(3ϩ) 3300 616, 1181 ϩ30 1.2 ϩ3 181 106(3ϩ) 907 906, 1733 ϩ9 1.6 ϩ2 133 83(2ϩ) 4400 660, 1267 ϩ41 1.3 ϩ4 160 87(4ϩ) *Parentheses around molar mass indicate the most stable isotope of a radioactive element. † The normal state is the state of the element at normal temperature and pressure (20°C and 1 atm). s denotes solid, l, liquid, and g, gas; m denotes metal, nm, nonmetal, and md, metalloid. ‡ The density quoted is for the liquid. § The solid sublimes. || Charge in parentheses. # Atomic and ionic radii are estimated. A32 APPENDIX 2 2E THE TOP 23 CHEMICALS BY INDUSTRIAL PRODUCTION IN THE UNITED STATES IN 2008 Production data are compiled annually by the American Chemical Society and published in Chemical and Engineering News. This table is based on the information about production in 2008 that was published in the July 6, 2009, issue. Water, sodium chloride, and steel traditionally are not included and would outrank the rest if they were. Hydrogen is heavily used but almost always “on site” as soon as it has been prepared. Rank Name Annual production (109 kg) Comment on source 1 sulfuric acid 32.4 contact process 2 ethene (ethylene) 22.6 thermal cracking of petroleum 3 polyethylene 16.0 polymerization of ethene 4 propene (propylene) 14.8 thermal cracking of petroleum 5 chlorine 9.6 electrolysis 6 ammonia 9.5 Haber process 7 phosphoric acid 9.2 from phosphate rocks 8 dichloroethane 9.0 chlorination of ethene (ethylene dichoride) 9 diammonium hydrogen 8.0 processing of phosphate rocks phosphate 10 polypropylene 7.6 polymerization of propylene 11 nitric acid 7.5 Ostwald process 12 sodium hydroxide 7.3 electrolysis of brine 13 ammonium nitrate 7.3 ammonia ϩ nitric acid 14 polyvinyl chloride and 5.8 polymerization of vinyl chloride copolymers 15 urea 5.3 ammonia ϩ carbon dioxide 16 ammonium dihydrogen 5.0 processing of phosphate rocks phosphate 17 ethylbenzene 4.1 Friedel–Crafts alkylation of benzene 18 styrene 4.1 dehydration of ethylbenzene 19 hydrogen chloride 3.8 by-product of hydrocarbon chlorination 20 cumene (isopropylbenzene) 3.4 alkylation of benzene 21 ethylene oxide 2.9 addition of O2 to ethene 22 ammonium sulfate 2.5 ammonia ϩ sulfuric acid 23 polystyrene 2.4 polymerization of styrene 3A THE NOMENCLATURE OF POLYATOMIC IONS APPENDIX 3: Nomenclature Charge Chemical Oxidation number Charge Chemical Oxidation number number formula Name of central element number formula Name of central element ϩ2 Hg2 2ϩ mercury(I) ϩ1 O3 Ϫ ozonide UO2 2ϩ uranyl ϩ6 OHϪ hydroxide Ϫ2(O) VO2ϩ vanadyl ϩ4 SCNϪ thiocyanate — ϩ1 NH4 ϩ ammonium Ϫ3 Ϫ2 C2 2Ϫ carbide Ϫ1 PH4 ϩ phosphonium Ϫ3 (acetylide) Ϫ1 CH3CO2 Ϫ acetate 0(C) CO3 2Ϫ carbonate ϩ4 (ethanoate) C2O4 2Ϫ oxalate ϩ3 HCO2 Ϫ formate ϩ2(C) CrO4 2Ϫ chromate ϩ6 (methanoate) Cr2O7 2Ϫ dichromate ϩ6 CNϪ cyanide ϩ2(C), Ϫ3(N) O2 2Ϫ peroxide Ϫ1 ClO4 Ϫ perchlorate* ϩ7 S2 2Ϫ disulfide Ϫ1 ClO3 Ϫ chlorate* ϩ5 SiO3 2Ϫ metasilicate ϩ4 ClO2 Ϫ chlorite* ϩ3 SO4 2Ϫ sulfate ϩ6 ClOϪ hypochlorite* ϩ1(Cl) SO3 2Ϫ sulfite ϩ4 MnO4 Ϫ permanganate ϩ7 S2O3 2Ϫ thiosulfate ϩ2 NO3 Ϫ nitrate ϩ5 Ϫ3 AsO4 3Ϫ arsenate ϩ5 NO2 Ϫ nitrite ϩ3 BO3 3Ϫ borate ϩ3 N3 Ϫ azide PO4 3Ϫ phosphate ϩ5 *These names are representative of the halogen oxoanions. -1 3 -1 3 When a hydrogen ion bonds to a Ϫ2 or Ϫ3 anion, add “hydrogen” before the name of the anion. For example, HSO3 Ϫ is hydrogen sulfite (or hydrogensulfite). If two hydrogen ions bond to a Ϫ3 anion, add “dihydrogen” before the name of the anion. For example, H2PO4 Ϫ is dihydrogen phosphate (or dihydrogenphosphate). Oxoacids and Oxoanions The names of oxoanions and their parent acids can be determined by noting the oxidation number of the central atom and then referring to the table on the right. For example, the nitrogen in N2O2 2Ϫ has an oxidation number of ϩ1; because nitrogen belongs to Group 15/V, the ion is a hyponitrite ion. Group number 14/IV 15/V 16/VI 17/VII Oxoanion Oxoacid — — Ϫ ϩ7 per . . . ate per . . . ic acid ϩ4 ϩ5 ϩ6 ϩ5 . . . ate . . . ic acid — ϩ3 ϩ4 ϩ3 . . . ite . . . ous acid — ϩ1 ϩ2 ϩ1 hypo . . . ite hypo . . . ous acid A33 A34 APPENDIX 3 3B COMMON NAMES OF CHEMICALS Many chemicals are often referred to by their common names, sometimes as a result of their use over hundreds of years and sometimes because they appear on the labels of consumer products, such as detergents, beverages, and antacids. The following names are just a few that have found their way into the language of everyday life. Common name Formula Chemical name baking soda NaHCO3 sodium hydrogen carbonate (sodium bicarbonate) bleach, laundry NaClO sodium hypochlorite borax Na2B4O7и10H2O sodium tetraborate decahydrate brimstone S8 sulfur calamine ZnCO3 zinc carbonate chalk CaCO3 calcium carbonate Epsom salts MgSO4и7H2O magnesium sulfate heptahydrate fool’s gold FeS2 iron(II) disulfide gypsum CaSO4и2H2O calcium sulfate dihydrate lime (quicklime) CaO calcium oxide lime (slaked lime) Ca(OH)2 calcium hydroxide limestone CaCO3 calcium carbonate lye, caustic soda NaOH sodium hydroxide marble CaCO3 calcium carbonate milk of magnesia Mg(OH)2 magnesium hydroxide plaster of Paris CaSO4и H2O calcium sulfate hemihydrate potash* K2CO3 potassium carbonate quartz SiO2 silcon dioxide table salt NaCl sodium chloride vinegar CH3COOH acetic acid (ethanoic acid) washing soda Na2CO3и10H2O sodium carbonate decahydrate *Potash also refers collectively to K2CO3, KOH, K2SO4, KCl, and KNO3. 1 2 3C NAMES OF SOME COMMON CATIONS WITH VARIABLE CHARGE NUMBERS Modern nomenclature includes the oxidation number of elements with variable oxidation states in the names of their compounds, as in cobalt(II) chloride. However, the traditional nomenclature, in which the suffixes -ous and -ic are used, is still encountered. The table on the right translates from one system into the other for some common elements. Element Cation Old-style name Modern name cobalt Co2ϩ cobaltous cobalt(II) Co3ϩ cobaltic cobalt(III) copper Cuϩ cuprous copper(I) Cu2ϩ cupric copper(II) iron Fe2ϩ ferrous iron(II) Fe3ϩ ferric iron(III) lead Pb2ϩ plumbous lead(II) Pb4ϩ plumbic lead(IV) manganese Mn2ϩ manganous manganese(II) Mn3ϩ manganic manganese(III) mercury Hg2 2ϩ mercurous mercury(I) Hg2ϩ mercuric mercury(II) tin Sn2ϩ stannous tin(II) Sn4ϩ stannic tin(IV) ab initio method The calculation of molecular structure by solving the Schrödinger equation numerically. Compare with semiempirical method. absolute zero (T ϭ 0; that is, 0 on the Kelvin scale) The lowest possible temperature (Ϫ273.15°C). absorb To accept one substance into and throughout the bulk of another substance. Compare with adsorb. absorbance (A) A measure of the extent of absorption of radiation by a sample: A ϭ log(I0/I). absorbed dose (of radiation) The energy deposited in a given mass of sample when it is exposed to radiation (particularly but not exclusively nuclear radiation). Absorbed dose is measured in rad or gray. absorption spectrum The wavelength dependence of the absorption of a sample, determined by measuring the extent to which the sample absorbs electromagnetic radiation as the wavelength is varied over a range. abundance (of an isotope) The percentage (in terms of the numbers of atoms) of the isotope present in a sample of the element. See also natural abundance. acceleration The rate of change of velocity (either its direction or its magnitude). acceleration of free fall (g) The acceleration experienced by a body owing to the gravitational field at the surface of the Earth. accuracy Freedom from systematic error. Compare with precision. accurate measurement A measurement that has small systematic error and gives a result close to the accepted value of the property. achiral Not chiral: identical with its mirror image. See also chiral. acid See Arrhenius acid; Brønsted acid; Lewis acid. Used alone, “acid” normally means a Brønsted acid. acid anhydride A compound that forms an oxoacid when it reacts with water. See also formal anhydride. Example: SO3, the anhydride of sulfuric acid. acid–base indicator See indicator. acid–base titration See titration. acid buffer See buffer. acidic hydrogen atom A hydrogen atom (more exactly, the proton of that hydrogen atom) that can be donated to a base. acidic ion An ion that acts as a Brønsted acid. Examples: NH4 ϩ ; [Al(H2O)6]3ϩ . acidic oxide An oxide that reacts with water to give an acid; the oxides of nonmetallic elements generally are acidic oxides. Examples: CO2; SO3. acidic solution A solution with pH Ͻ 7. acid ionization (dissociation) constant (Ka) See acidity constant. acidity The strength of the tendency to donate a proton. acidity constant (Ka) The equilibrium constant for proton transfer to water; for an acid HA, Ka ϭ [H3Oϩ ][A– ]/[HA] at equilibrium. actinide Former (and still very common) term for actinoid. actinoid A member of the second row of the f-block (thorium through nobelium). activated complex An unstable combination of reactant molecules that can either go on to form products or fall apart into the unchanged reactants. activated complex theory See transition state theory. activation energy (Ea) (1) The minimum energy needed for reaction. (2) The height of the activation barrier. (3) An empirical parameter that describes the temperature dependence of the rate constant of a reaction. activity (1) In thermodynamics, aJ, the effective concentration or pressure of a species J expressed as the partial pressure or concentration of the species relative to its standard value. (2) In radioactivity, the number of nuclear disintegrations per second. activity coefficient (␥J) The proportionality factor between the activity of a species and its molar concentration or partial pressure (divided by its standard value). Example: for a solute J, aJ ϭ ␥J[J]/c°. addition polymerization The polymerization, usually of alkenes, by an addition reaction propagated by radical or ionic intermediates. addition reaction A chemical reaction in which atoms or groups bond to two atoms joined by a multiple bond. The product of the reaction is a single molecule that contains all the reactant atoms. Example: CH3CH≈CH2 ϩ HBr → CH3CH2CH2Br. adhesion Binding to a surface. adhesive forces Forces that bind a substance to a surface. adiabatic Not permitting or accompanied by the passage of energy as heat. Example: adiabatic wall. adsorb To bind a substance to a surface; the surface adsorbs the substance. Distinguish from absorb. aerosol A fine mist of solid particles or droplets of liquid suspended in a gas. alcohol An organic molecule containing an ßOH group attached to a carbon atom that is not part of a carbonyl group or an aromatic ring. Alcohols are classified as primary, secondary, and tertiary according to the number of carbon atoms attached to the CßOH carbon atom. Examples: CH3CH2OH (primary); (CH3)2CHOH (secondary); (CH3)3COH (tertiary). aldehyde An organic compound containing the ßCHO group. Examples: CH3CHO, ethanal (acetaldehyde); C6H5CHO, benzaldehyde. aliphatic hydrocarbon A hydrocarbon that does not have benzene rings in its structure. GLOSSARY B1 B2 GLOSSARY alkali An aqueous solution of a strong base. Example: aqueous NaOH. alkali metal A member of Group 1 of the periodic table (the lithium family). alkaline earth metal Calcium, strontium, and barium; more informally, a member of Group 2 of the periodic table (the beryllium family). alkaline solution An aqueous solution with pH Ͼ 7. alkane (1) A hydrocarbon with no carbon–carbon multiple bonds. (2) A saturated hydrocarbon. (3) A member of a series of hydrocarbons derived from methane by the repetitive insertion of ßCH2ß groups; alkanes have the molecular formula CnH2nϩ2. Examples: CH4; CH3CH3; CH3(CH2)6CH3. alkene (1) A hydrocarbon with at least one carbon–carbon double bond. (2) A member of a series of hydrocarbons derived from ethene by the repetitive insertion of ßCH2ß groups; alkenes with one double bond have the molecular formula CnH2n. Examples: CH2≈CH2; CH3CH≈CH2; CH3CH≈CHCH2CH3. alkyne (1) A hydrocarbon with at least one carbon–carbon triple bond. (2) A member of a series of hydrocarbons derived from ethyne by the repetitive insertion of ßCH2ß groups; alkynes with one triple bond have the molecular formula CnH2n–2. Examples: CHΩCH; CH3CΩCCH3. allotropes Alternative forms of an element that differ in the way in which the atoms are linked. Examples: O2 and O3; white and gray tin. alloy A mixture of two or more metals formed by melting, mixing, and then cooling. A substitutional alloy is an alloy in which atoms of one metal are substituted for atoms of another metal. An interstitial alloy is an alloy in which atoms of one metal lie in the gaps in the lattice formed by atoms of another metal. A homogeneous alloy is an alloy in which the atoms of the elements are distributed uniformly. A heterogeneous alloy is an alloy that consists of (micro)crystalline phases with different compositions. alpha (␣) helix One type of secondary structure adopted by a polypeptide chain, in the form of a right-handed helix. alpha (␣) particle Positively charged, subatomic particle emitted from some radioactive nuclei; nucleus of a helium atom (4 2He2ϩ ). alternating copolymer See copolymer. ambidentate ligand A ligand that can coordinate to a metal atom by using atoms of different elements. Example: SCNϪ , which can coordinate through S or N. amide An organic compound formed by the reaction of an amine and a carboxylic acid in which the acidic ßOH group has been replaced by an amino group or a substituted amino group. An amide contains the group ßCONR2. Example: CH3CONH2, acetamide. amine A compound derived from ammonia by replacing various numbers of H atoms with organic groups; the number of hydrogen atoms replaced determines the classification as primary, secondary, or tertiary. Examples: CH3NH2 (primary); (CH3)2NH (secondary); (CH3)3N (tertiary). See also quaternary ammonium ion. amino acid A carboxylic acid that also contains an amino group. The essential amino acids are amino acids that must be ingested as a part of the diet. Example: NH2CH2COOH, glycine. See Table 19.4. amino group The functional group ßNH2 characteristic of amines. amorphous solid A solid in which the atoms, ions, or molecules lie in a random jumble with no long-range order. Examples: glass; butter. Compare with crystalline solid. amount of substance (n) The number of entities in a sample divided by Avogadro’s constant. Also referred to as chemical amount. See mole. ampere (A) The SI unit of electric current. See also Appendix 1B. amphiprotic Having the ability both to donate and to accept protons. See amphoteric. Examples: H2O; HCO3 Ϫ . amphoteric Having the ability to react with both acids and bases. See amphiprotic. Examples: Al; Al2O3. amplitude The height of a mathematical function above 0. On a graph depicting a wave, the height of the wave above the center line. analysis See chemical analysis. analyte The solution of unknown concentration in a titration. Normally, the analyte is in the flask, not the buret. analytical chemistry The study and application of techniques for identifying substances and measuring their amounts. angular wavefunction (Y(␪,␾)) The angular part of a wavefunction, particularly the angular component of the wavefunctions of the hydrogen atom; the probability amplitude of an electron as a function of orientation around the nucleus. anhydride See acid anhydride. anhydrous Lacking water. Example: CuSO4, the anhydrous form of copper(II) sulfate. Compare with hydrate. anion A negatively charged ion. Examples: F– ; SO4 2Ϫ . anisotropic Depending on orientation. anode The electrode at which oxidation takes place. antibonding orbital A molecular orbital that, when occupied, contributes to an overall raising of the energy of a molecule. antiferromagnetic material A substance in which electron spins on neighboring atoms are locked into an antiparallel arrangement over large regions. Example: manganese. antilogarithm If the logarithm to the base B is x, then the antilogarithm of x is Bx . The common antilogarithm of x is 10x . The natural antilogarithm of x is the exponential ex . antioxidant A substance that reacts with radicals and so prevents the oxidation of another substance. antiparticle A particle with the same mass as a subatomic particle but with opposite charge. Example: positron, the antiparticle of an electron. applied research Investigations directed toward the solution of real-world problems. See also basic research. aqueous solution A solution in which the solvent is water. arene An aromatic hydrocarbon. aromatic compound An organic compound that includes a benzene ring as part of its structure. Examples: C6H6 (benzene); C6H5Cl (chlorobenzene); C10H8 (naphthalene). GLOSSARY B3 aromatic hydrocarbon See aromatic compound (the more general term). Arrhenius acid A compound that contains hydrogen and releases hydrogen ions (Hϩ ) in water. Examples: HCl; CH3COOH; but not CH4. Arrhenius base A compound that produces hydroxide ions (OH– ) in water. Examples: NaOH; NH3; but not Na, because it is not a compound. Arrhenius behavior A reaction shows Arrhenius behavior if a plot of ln k against 1/T is a straight line. See Arrhenius equation. Arrhenius equation The equation ln k ϭ ln A Ϫ Ea/RT for the commonly observed temperature dependence of a rate constant k. An Arrhenius plot is a graph of ln k against 1/T. Arrhenius parameters The pre-exponential factor A (also called the frequency factor) and the activation energy Ea. See also Arrhenius equation. aryl group An aromatic group. Example: ßC6H5, phenyl. atmosphere (1) The layer of gases surrounding a planet (specifically, the air for planet Earth). (2) A unit of pressure (1 atm ϭ 1.013 25 ϫ 105 Pa exactly). atom (1) The smallest particle of an element that has the chemical properties of that element. (2) An electrically neutral species consisting of a nucleus and its surrounding electrons. atomic hypothesis The proposal advanced by John Dalton that matter is composed of atoms. atomic mass constant (mu, formerly amu) One-twelfth the mass of one atom of carbon-12. atomic nucleus See nucleus. atomic number (Z) The number of protons in the nucleus of an atom; this number determines the identity of the element and the number of electrons in the neutral atom. atomic orbital A region of space in which there is a high probability of finding an electron in an atom. An s-orbital is a spherical region; a p-orbital has two lobes, on opposite sides of the nucleus; a d-orbital typically has four lobes, with the nucleus at the center; an f-orbital has a more complicated arrangement of lobes. atomic radius Half the distance between the centers of neighboring atoms in a solid or a homonuclear molecule. atomic structure The arrangement of electrons around the nucleus of an atom. atomic weight The numerical value of the molar mass of an element. Aufbau principle See building-up principle. autoionization See autoprotolysis. autoprotolysis A reaction in which a proton is transferred between two molecules of the same substance. The products are the conjugate acid and conjugate base of the substance. Example: 2 H2O(l) T H3Oϩ (aq) ϩ OH– (aq). autoprotolysis constant The equilibrium constant for an autoprotolysis reaction. Example: for water, Kw, with Kw ϭ [H3Oϩ ][OHϪ ]. average bond enthalpy (ΔHB(AßB)) See mean bond enthalpy. average reaction rate The reaction rate calculated by measuring the change in concentration of a reactant or product over a finite time interval (and hence an average of the changing rate within that interval). See also unique average reaction rate. Avogadro’s constant The number of objects per mole of objects (NA ϭ 6.022 14 ϫ 1023 molϪ1 ). Avogadro’s number is the number of objects in 1 mol of objects (that is, the dimensionless number 6.022 14 ϫ 1023 ). Avogadro’s principle The volume of a sample of gas at a given temperature and pressure is proportional to the amount of gas molecules in the sample: V n. axial bond A bond that is perpendicular to the molecular plane in a bipyramidal molecule. axial lone pair A lone pair lying on the axis of a bipyramidal molecule. azeotrope A mixture of liquids that boils without change of composition. A minimum-boiling azeotrope has a boiling point lower than that of either component; a maximum-boiling azeotrope has a boiling point higher than that of either component. azimuthal quantum number (l) See orbital angular momentum quantum number. background radiation The average nuclear radiation to which the Earth’s inhabitants are exposed daily. balanced equation See chemical equation. ball-and-stick model A depiction of a molecule in which atoms are represented by balls and bonds are represented by sticks. Balmer series A family of spectral lines (some of which lie in the visible region) in the spectrum of atomic hydrogen. band gap A range of energies for which there are no orbitals in a solid. Unless stated otherwise, the band gap refers to the gap between the valence band and the conduction band. band of stability A region of a plot of mass number against atomicnumbercorrespondingtotheexistenceof stablenuclei. bar A unit of pressure: 1 bar ϭ 105 Pa. barometer An instrument for measuring the atmospheric pressure. base See Arrhenius base; Brønsted base; Lewis base. Used alone, “base” normally means a Brønsted base. base buffer See buffer. base ionization constant See basicity constant. base pair Two specific nucleotides that link one complementary strand of a DNA molecule to the other by means of hydrogen bonding: adenine pairs with thymine and guanine pairs with cytosine. base units The units of measurement in the International System (SI) in terms of which all other units are defined. Examples: kilogram for mass; meter for length; second for time; kelvin for temperature; ampere for electric current. basic ion An ion that acts as a Brønsted base. Example: CH3CO2 – . basicity constant (Kb) The equilibrium constant for proton transfer from water to a base; for a base B, Kb ϭ [BHϩ ][OHϪ ]/[B]. basic oxide An oxide that is a Brønsted base. The oxides of metallic elements are generally basic. Examples: Na2O; MgO. basic research Investigations aimed at discovering the reasons for phenomena and the fundamental principles of r B4 GLOSSARY chemistry, the synthesis of new materials, and the investigation of their properties. See also applied research. basic solution A solution with pH Ͼ 7. battery A collection of galvanic cells joined in series; the voltage that the battery produces is the sum of the voltages of each cell. becquerel(Bq) TheSIunitof radioactivity(onedisintegration per second). Beer’s law The absorbance of electromagnetic radiation by a sample is proportional to the molar concentration of the absorbing species and the length of the sample through which the radiation passes. beta (␤) decay Nuclear decay due to ␤-particle emission. beta (␤) particle A fast electron emitted from a nucleus in a radioactive decay. beta (␤) sheet One type of planar secondary structure adopted by a polypeptide, in the form of a pleated sheet. bimolecular reaction An elementary reaction in which two molecules, atoms, or ions come together and form a product. Example: O ϩ O3 → O2 ϩ O2. binary Consisting of two components, as in binary mixture and binary (ionic or molecular) compound. Examples: acetone and water (a binary mixture); HCl, CaCl2, C6H6 (binary compounds; CaCl2 is ionic, HCl and C6H6 are molecular). bio-based material A material taken from or made from natural materials in living things. biochemistry Thestudyof biologicallyimportantsubstances, processes, and reactions. bioenergetics The deployment and utilization of energy in living cells. biological chemistry The application of chemical principles to biological structures and processes. biomass The organic material of the planet produced annually by photosynthesis. biomimetic material A material modeled after a naturally occurring material. biradical A species with two unpaired electrons. Example: иCH2CH2CH2и. black body An object that absorbs and emits all frequencies of radiation without favor. black-body radiation The electromagnetic radiation emitted by a black body. block (s-block, p-block, d-block, f-block) The region of the periodic table containing elements for which, according to the building-up principle, the corresponding subshell is currently being filled. block copolymer See copolymer. body-centered cubic structure (bcc) A crystal structure with a unit cell in which a central atom lies at the center of a cube formed by eight others. Bohr frequency condition The relation between the change in energy of an atom or molecule and the frequency of radiation emitted or absorbed: ΔE ϭ h␯. Bohr radius (a0) In an early model of the hydrogen atom, the radiusof thelowestenergyorbit;nowaspecificcombination of fundamental constants (a0 ϭ 4␲␧0U2 /mee2 ϭ 52.9 pm) in the description of the wavefunctions of hydrogen. boiling Rapid vaporization taking place throughout a liquid. See boiling temperature. boiling point (b.p.) See boiling temperature; normal boiling point. boiling-point constant (kb) The constant of proportionality between the boiling-point elevation and the molality of a solute. boiling-point elevation The increase in normal boiling point of a solvent caused by the presence of a solute (a colligative property). boiling temperature (1) The temperature at which a liquid boils. (2) The temperature at which a liquid is in equilibrium with its vapor at the pressure of the surroundings; vaporization then occurs throughout the liquid, not only at the liquid’s surface. Boltzmann formula (for the entropy) The formula S ϭ k ln W, where k is Boltzmann’s constant and W is the number of atomic arrangements that correspond to the same energy. Boltzmann’s constant (k) A fundamental constant; k ϭ 1.380 66 ϭ 10Ϫ23 JиKϪ1 . Note that R ϭ NAk. bond A link between atoms. See also covalent bond; double bond; ionic bond; triple bond. bond angle In an AßBßC molecule or part of a molecule, the angle between the BßA and BßC bonds. bond enthalpy (ΔHB(XßY)) The enthalpy change accompanying the dissociation of a bond. Example: H2(g) → 2 H(g), ΔHB(HßH) ϭ ϩ436 kJиmolϪ1 . bonding orbital A molecular orbital that, when occupied, results in an overall lowering of the energy of a molecule. bond length The distance between the centers of two atoms joined by a bond. bond order The number of electron pair bonds that link a specific pair of atoms. Born–Haber cycle A closed series of reactions used to express the enthalpy of formation of an ionic solid in terms of contributions that include the lattice enthalpy. Born interpretation The interpretation of the square of the wavefunction, ␺, of a particle as the probability density for finding the particle in a region of space. Born–Mayer equation The formula for the minimum energy of an ionic solid. boundary condition A constraint on the value of the wavefunction of a particle. boundary surface The surface showing the region of space within which there is about 90% probability of finding an electron when it occupies a specific orbital in an atom or molecule. Boyle’s law At constant temperature, and for a given sample of gas, the volume is inversely proportional to the pressure: P ϰ 1/V. Bragg equation An equation relating the angle of diffraction of x-rays to the spacing of layers of atoms in a crystal (␭ ϭ 2d sin ␪). branched alkane An alkane with hydrocarbon side chains. branching Description of a step in a chain reaction in which more than one chain carrier is formed in a propagation step. Example: иOи ϩ H2 → иOH ϩ иH. See also propagation. Bravais lattices The 14 basic patterns of unit cells from which a crystal can be built. breeder reactor A reactor used to generate nuclear fuel by making use of neutrons that are not moderated. GLOSSARY B5 Brønsted acid A proton donor (a source of hydrogen ions, Hϩ ). Examples: HCl; CH3COOH; HCO3 Ϫ ; NH4 ϩ . Brønsted base A proton acceptor (a species to which hydrogen ions, Hϩ , can bond). Examples: OHϪ ; ClϪ ; CH3CO2 Ϫ ; HCO3 Ϫ ; NH3. Brønsted–Lowry definition A definition of acids and bases in terms of the ability of molecules and ions to participate in proton transfer. See Brønsted–Lowry theory. Brønsted–Lowry theory A theory of acids and bases involving proton transfer from one species to another. See also Brønsted acid and Brønsted base. Brownian motion The ceaseless jittering motion of colloidal particles caused by the impact of solvent molecules. buffer A solution that resists any change in pH when small amounts of acid or base are added. An acid buffer stabilizes solutions at pH Ͻ 7 and a base buffer stabilizes solutions at pH Ͼ 7. Examples: a solution containing CH3COOH and CH3CO2 Ϫ (acid buffer); a solution containing NH3 and NH4 ϩ (base buffer). buffer capacity An indication of the amount of acid or base that can be added before a buffer loses its ability to resist the change in pH. building-up principle The procedure for arriving at the groundstate electron configurations of atoms and molecules. bulk matter Matter composed of large numbers of atoms. See bulk property. bulk property A property that depends on the collective behavior of large numbers of atoms. Examples: melting point; vapor pressure; internal energy. buret A narrow, graduated tube fitted with a stopcock, used to measure the volume of liquid delivered into another vessel. calibration Interpretation of an observation by comparison with known information. calorie (cal) A unit of energy. The unit is now defined in terms of the joule by 1 cal ϭ 4.184 J exactly. The nutritional calorie is 1 kcal. calorimeter Anapparatususedtodeterminetheheatreleasedor absorbed in a process by measuring the temperature change. candela (cd) The SI unit of luminous intensity. See also Appendix 1B. capillary action The rise of liquids up narrow tubes. carbohydrate A compound of general formula Cm(H2O)n, although small deviations from this general formula are often encountered. Carbohydrates include cellulose, starches, and sugars. Examples: C6H12O6, glucose; C12H22O11, sucrose. carbonyl group A ϾCO group in an inorganic or organic compound. carboxyl group The functional group ßCOOH. See carboxylic acid. carboxylic acid An organic compound containing the carboxyl group, ßCOOH. Examples: CH3COOH, acetic acid; C6H5COOH, benzoic acid. carrier See chain carrier. catalyst A substance that increases the rate of a reaction without being consumed in the reaction. A catalyst is homogeneous if it is present in the same phase as the reactants and heterogeneous if it is in a different phase from the reactants. Examples: homogeneous, Br– (aq) for the decomposition of H2O2(aq); heterogeneous, Pt in the Ostwald process. catenate To form chains or rings of atoms. Examples: O3; S8. cathode The electrode at which reduction takes place. cathodic protection Protection of a metal object by connecting it to a more strongly reducing metal. cation A positively charged ion. Examples: Naϩ ; NH4 ϩ ; Al3ϩ . cell diagram A description of an electrochemical cell that corresponds to a given cell reaction. Example: Zn(s)⏐Zn2ϩ (aq)⏐⏐Cu2ϩ (aq)⏐Cu(s). cell potential (Ecell) (1) The potential difference between the electrodes of an electrochemical cell when it is producing no current. (2) An indication of the tendency of a reaction in an electrochemical cell to occur spontaneously. Celsius scale A temperature scale on which the freezing point of water is at 0 degrees and its normal boiling point is at 100 degrees. Units on this scale are degrees Celsius, °C. ceramic (1) A solid obtained by the action of heat on clay. (2) A noncrystalline inorganic solid usually containing oxides, borides, and carbides. cesium chloride structure A crystal structure the same as that of solid cesium chloride. chain branching A propagation step in a chain reaction when more than one chain carrier is formed. chain carrier An intermediate in a chain reaction. chain reaction A reaction that is propagated when an intermediate reacts to produce another intermediate in a seriesof elementaryreactions.Example:Br·ϩH2 →HBrϩ H· followed by Hи ϩ Br2 →HBr ϩ Brи. chalcogens Oxygen, sulfur, selenium, and tellurium in Group 16/VI of the periodic table. change of state The change of a substance from one of its physical states to another of its physical states. Example: melting, solid → liquid. characteristic (of a logarithm) The number preceding the decimal point. charge A measure of the strength with which a particle can interact electrostatically with another particle. charge balance The requirement that, because a solution is neutral overall, the concentration of positive charge due to cations must equal the concentration of negative charge due to anions. charge-transfer transition A transition in which an electron is excited from the ligands of a complex to the metal atom or vice versa. Charles’s law The volume of a given sample of gas at constant pressure is directly proportional to its absolute temperature: V ϰ T. chelate A complex containing at least one polydentate ligand that forms a ring of atoms including the central metal atom. Example: [Co(en)3]3ϩ . chemical analysis The determination of the chemical composition of a sample. See also qualitative, quantitative. chemical bond See bond. chemical change The conversion of one or more substances into different substances. chemical element See element. B6 GLOSSARY chemical energy The energy available from a chemical reaction. Example: the energy released in the combustion of a fuel. chemical engineering The study of industrial chemical processes. chemical equation A statement in terms of chemical formulas summarizing the qualitative information about the chemical changes taking place in a reaction and the quantitative information that atoms are neither created nor destroyed in a chemical reaction. In a balanced chemical equation (commonly called a “chemical equation”), the same number of atoms of each element appears on both sides of the equation. chemical equilibrium A dynamic equilibrium between reactants and products in a chemical reaction. chemical formula A collection of chemical symbols and subscripts that shows the composition of a substance. See also condensed structural formula; empirical formula; molecular formula; structural formula. chemical kinetics The study of the rates of chemical reactions and the steps by which they take place. chemical nomenclature The systematic naming of compounds. chemical plating The deposition of a metal surface on an object by making use of a chemical reduction reaction. chemical property The ability of a substance to participate in a chemical reaction. chemical reaction A chemical change in which one substance responds to the presence of another, to a change of temperature, or to some other influence. chemical symbol The abbreviation of the name of an element. chemiluminescence The emission of light by products formed in energetically excited states during a chemical reaction. chemistry The branch of science concerned with the study of matter and the changes that matter can undergo. chiral (molecule or complex) Not able to be superimposed on its own mirror image. Examples: CH3CH(NH2)COOH; CHBrClF; [Co(en)3]3ϩ . chloralkali process The production of chlorine and sodium hydroxide by the electrolysis of aqueous sodium chloride. cholesteric phase A liquid crystal phase in which layers of parallel molecules are twisted relative to one another in such a way that the orientations of the molecules form a helical structure. chromatogram A record of the signal from the detector (or the paper record) obtained in a chromatographic analysis of a mixture. chromatography A separation technique that relies on the ability of different phases to adsorb substances to different extents. cis–trans isomerization The conversion of a cis isomer into a trans isomer and vice versa. Example: cis-butene N trans-butene. classical mechanics The laws of motion proposed by Isaac Newton in which particles travel in definite paths in response to forces. clathrate A structure in which a molecule of one substance sits in a cage made up of molecules of another substance, typically water. Example: SO2 in water. Clausius–Clapeyron equation An equation that gives the quantitative dependence of the vapor pressure of a substance on the temperature. Clausius inequality The relation ΔS Ն q/T. Claus process A process for obtaining sulfur from the H2S in oil wells by the oxidation of H2S with SO2; the latter is formed by the oxidation of H2S with oxygen. closed shell (or subshell) A shell (or subshell) containing the maximum number of electrons allowed by the exclusion principle. Example: the neonlike core 1s2 2s2 2p6 . closed system See system. close-packed structure A crystal structure in which atoms occupy the smallest total volume with the least empty space. Examples: hexagonal close packing and cubic close packing of identical spheres. coagulation The formation of aggregates from colloidal particles. cohesion The act or state in which the particles of a substance stick to one another. cohesive forces The forces that bind the molecules of a substance together to form a bulk material and are responsible for condensation. coinage metals The elements copper, silver, and gold. colligative property A property that depends only on the relative number of solute and solvent particles present in a solution and not on the chemical identity of the solute. Examples: elevation of boiling point; depression of freezing point; osmosis. collision cross section The area that a molecule presents as a target during a collision. collision theory The theory of elementary gas-phase bimolecular reactions in which molecules are assumed to react only if they collide with a characteristic minimum kinetic energy. colloid (or colloidal suspension) A dispersion of tiny particles with diameters between 1 nm and 1 ␮m in a gas, liquid, or solid. Example: milk. combined gas law A combination of Boyle’s law and Charles’s law that allows the pressure, volume, or temperature of a sample of an ideal gas to be predicted after a change in state. P1V1/n1T1 ϭ P2V2/n2T2. combustion A reaction in which an element or compound burns in oxygen. Example: CH4(g) ϩ 2 O2(g) → CO2(g) ϩ 2 H2O(l). combustion analysis The determination of the composition of a sample by the measurement of the masses of the products of its combustion. common antilogarithm See antilogarithm. common-ion effect Reduction of the solubility of one salt by the presence of another salt with one ion in common. Example: the lower solubility of AgCl in NaCl(aq) than in pure water. common logarithm See logarithm. common name An informal name for a compound that may give little or no clue to the compound’s composition. Examples: water; aspirin; acetic acid. GLOSSARY B7 competing reaction A reaction taking place at the same time as the reaction of interest and using some of the same reactants, but forming different products. complementarity The impossibility of knowing the position of a particle with arbitrarily great precision if its linear momentum is known precisely. complementary color The color that white light becomes when one of the colors present in it is removed. complete ionic equation A balanced chemical equation expressed in terms of the cations and anions present in solution. Example: Agϩ (aq) ϩ NO3 Ϫ (aq) ϩ Naϩ (aq) ϩ Cl– (aq) : AgCl(s) ϩ NO3 Ϫ (aq) ϩ Naϩ (aq). complex (1) The combination of a Lewis acid and a Lewis base linked by a coordinate covalent bond. (2) A species consisting of several ligands (the Lewis bases) that have an independent existence bonded to a single central metal atom or ion (the Lewis acid). Examples: (1) H3NßBF3; (2) [Fe(H2O)6]3ϩ ; [PtCl4]Ϫ . composite material A synthetic material composed of a polymer and one or more other substances that have been solidified together. compound (1) A specific combination of elements that can be separated into its elements by chemical techniques but not physical techniques. (2) A substance consisting of atoms of two or more elements in a definite, unchangeable ratio. compress To reduce the volume of a sample. compressible Able to be compressed into a smaller volume. compression factor (Z) The ratio of the actual molar volume of a gas to the molar volume of an ideal gas under the same conditions. computational chemistry The application of computational techniques to the determination of the structures and properties of molecules and bulk matter. concentration The quantity of a substance in a given volume. See also molar concentration. concentration cell A galvanic cell in which the electrodes have the same composition but are at different concentrations. condensation The formation of a liquid or solid phase from the gas phase of the substance. condensation polymer A polymer formed by a chain of condensation reactions. Examples: polyesters; polyamides (nylon). condensation reaction A reaction in which two molecules combine to form a larger one and a small molecule is eliminated. Example: CH3COOH ϩ C2H5OH : CH3COOC2H5 ϩ H2O. condensed phase A solid or liquid phase; not a gas. condensed structural formula A compact version of the structural formula, showing how the atoms are grouped together. Example: CH3CH(CH3)CH3 for methylpropane. conduction band An incompletely occupied band of energy levels in a solid. configuration See electron configuration. conformations Molecular shapes that can be interchanged by rotation about bonds, without bond breakage and reformation. congeners Elements in the same group of the periodic table. conjugate acid The Brønsted acid formed when a Brønsted base has accepted a proton. Example: NH4 ϩ is the conjugate acid of NH3. conjugate acid–base pair A Brønsted acid and its conjugate base. Examples: HCl and ClϪ ; NH4 ϩ and NH3. conjugate base The Brønsted base formed when a Brønsted acid has donated a proton. Example: NH3 is the conjugate base of NH4 ϩ . conjugated double bonds A sequence of alternating single and double bonds, as in ßC≈CßC≈Cß. connectivity (of atoms in a molecule) The pattern in which the atoms in a molecule are bonded to one another. constructive interference Interference that results in an increased amplitude of a wave. Compare with destructive interference. contact process The production of sulfuric acid by the combustion of sulfur and the catalyzed oxidation of sulfur dioxide to sulfur trioxide. conversion factor A factor that is used to convert a measurement from one unit into another. cooling curve A graph of the variation of the temperature of a sample over time as it loses energy at a constant rate. Compare with heating curve. Cooper pair A pair of electrons that can travel together almost freely through a crystal lattice and give rise to superconductivity. coordinate Use of a lone pair to form a coordinate covalent bond. Examples: F3B ϩ :NH3 →F3BßNH3; Ni ϩ 4 CO → Ni(CO)4. coordinate covalent bond A bond formed between a Lewis base and a Lewis acid by sharing an electron pair originally belonging to the Lewis base. See coordinate. coordination complex The product of the reaction of a Lewis acid and a Lewis base to form a coordinate covalent bond. See also coordination compound. coordination compound A neutral complex or an ionic compound in which at least one of the ions is a complex. Examples: Ni(CO)4; K3[Fe(CN)6]. coordination isomers Isomers that differ by the exchange of one or more ligands between a cationic complex and an anionic complex. coordination number (1) The number of nearest neighbors of an atom in a solid. (2) For ionic solids, the coordination number of an ion is the number of nearest neighbors of opposite charge. (3) For complexes, the number of points at which ligands are attached to the central metal ion. coordination sphere The ligands directly attached to the central ion in a complex. copolymer A polymer formed from a mixture of different monomers. In random copolymers, the sequence of monomers has no particular order; in alternating copolymers, two monomers alternate; in block copolymers, regions of one monomer alternate with regions of another; in graft copolymers, chains of one monomer are attached to a backbone chain of a second monomer. core The inner closed shells of an atom. core electrons The electrons that belong to an atom’s core. B8 GLOSSARY corrosion The unwanted reaction of a material that results in the dissolution or consumption of the material. Example: the unwanted oxidation of a metal. corrosive (1) A reagent that can cause corrosion. (2) Having a high reactivity, such as the reactivity of a strong oxidizing agent or a concentrated acid or base. coulombic attraction The attraction between opposite electric charges. Coulomb potential energy The potential energy of an electric charge in the vicinity of another electric charge; the potential energy is inversely proportional to the separation of the charges. Coulomb’s law The potential energy of a pair of electric charges is inversely proportional to the distance between them and proportional to the product of the charges. couple See redox couple. covalent bond A pair of electrons shared between two atoms. covalent radius The contribution of an atom to the length of a covalent bond. cracking The process of converting petroleum fractions into smaller molecules with more double bonds. Example: CH3(CH2)6CH3 → CH3(CH2)3CH3 ϩ CH3CH≈CH2. critical mass The mass of fissionable material above which so few neutrons escape from a sample of nuclear fuel that the fission chain reaction is sustained; a greater mass is supercritical and a smaller mass is subcritical. critical point The point in a phase diagram at the critical pressure and critical temperature. critical pressure (Pc) The vapor pressure of a liquid at its critical temperature. critical temperature (Tc) The temperature at and above which a substance cannot exist as a liquid. crownether AcyclicetherwithalternatingßCH2CH2Oßunits. cryogenics The study of matter at very low temperatures. cryoscopy The measurement of molar mass by using the depression of freezing point. crystal face A flat plane forming a side of a crystal. crystal field The electrostatic influence of the ligands (modeled as point negative charges) on the central ion of a complex. Crystal field theory is a rationalization of the optical, magnetic, and thermodynamic properties of complexes in terms of the crystal field of their ligands. crystalline solid A solid in which the atoms, ions, or molecules lie in an orderly array. Examples: NaCl; diamond; graphite. Compare with amorphous solid. crystallization The process in which a solute comes out of solution as crystals. cubic close-packed structure (ccp) A close-packed structure with an ABCABC . . . pattern of layers. curie (Ci) A unit of activity (for radioactivity). current (I) The rate of supply of charge; current is measured in amperes (A), with 1 A ϭ 1 C·sϪ1 . cycle (1) In thermodynamics, a sequence of changes that begins and ends at the same state. (2) In spectroscopy, one complete reversal of the direction of the electromagnetic field and its return to the original direction. cycloalkane A saturated aliphatic hydrocarbon in which the carbon atoms form a ring. Example: C6H12, cyclohexane. Dalton’s law of partial pressures The total pressure of a mixture of gases is the sum of the partial pressures of its components. data The information provided or obtained from experiments. daughternucleus Anucleusthatistheproductof anucleardecay. d–d transition A transition in which an electron is excited from one d-orbital to another. de Broglie relation The proposal that every particle has wavelike properties and that its wavelength, ␭, is related to its mass by ␭ ϭ h/(mass ϫ velocity). debye (D) The unit used to report electric dipole moments: 1 D ϭ 3.336 ϫ 10Ϫ30 Cиm. decant To pour off a liquid from on top of another, denser liquid or from a solid. decay constant (k) The rate constant for radioactive decay. decomposition A reaction in which a substance is broken down into simpler substances; thermal decomposition is decomposition brought about by heat. Example: CaCO3(s) ⌬ B CaO(s) ϩ CO2(g). definite integral An integral with limits attached. See also Appendix 1F. degenerate Having the same energy. Example: atomic orbitals in the same subshell. dehydrating agent A reagent that removes water or the elements of water from a compound. Example: H2SO4. dehydrogenation The removal of a hydrogen atom from each of two neighboring carbon atoms, resulting in the formation of a carbon–carbon multiple bond. dehydrohalogenation The removal of a hydrogen atom and a halogen atom from neighboring carbon atoms in a haloalkane. delocalized Spread over a region. In particular, delocalized electrons are electrons that spread over several atoms in a molecule. delta (⌬, in a chemical equation) A symbol that signifies that the reaction takes place at elevated temperatures. delta X (⌬X) The difference between the final and initial values of a property, ⌬X ϭ Xfinal Ϫ Xinitial. Examples: ⌬T; ⌬E. denaturation The loss of structure of a large molecule, such as a protein. density (d) The mass of a sample of a substance divided by its volume: d ϭ m/V. density isosurface A graphic image that represents a molecular structure as a surface and shows the distribution of electrons in a molecule; the surface corresponds to locations with the same electron density. deposition The condensation of a vapor directly to a solid. Deposition is the reverse of sublimation. deprotonation Loss of a proton from a Brønsted acid. Example: NH4 ϩ (aq) ϩ H2O(l) → H3Oϩ (aq) ϩ NH3(aq). derived unit A combination of base units. Examples: centimeters cubed (cm3 ); joules (kg·m2 ·sϪ2 ). descriptive chemistry The description of the preparation, properties, and applications of the elements and their compounds. destructive interference Interference that results in a reduced amplitude of a wave. Compare with constructive interference. GLOSSARY B9 deuteron The nucleus of a deuterium atom, 2 Hϩ , consisting of a proton and a neutron. diagonal relationship A similarity in properties between diagonal neighbors in the periodic table, especially for main-group elements in Periods 2 and 3 at the left-hand side of the table. Examples: Li and Mg; Be and Al. diamagnetic (substance) A substance that tends to be pushed out of a magnetic field; consisting of atoms, ions, or molecules with no unpaired electrons. Examples: most common substances. diamine An organic compound that contains two –NH2 groups. diathermic Permitting the passage of energy as heat. Example: diathermic walls. diatomic ion An ion that consists of two atoms with a net charge. diatomic molecule A molecule that consists of two atoms. Examples: H2; CO. differential calculus The part of mathematics that deals with the slopes of curves and with infinitesimal quantities. See also Appendix 1F. diffraction The deflection of waves and the resulting interference caused by an object in their path. See also x-ray diffraction. diffraction pattern The pattern of bright spots against a dark background resulting from diffraction. diffusion The spreading of one substance through another substance. dilute (1) verb: To reduce the concentration of a solute by adding more solvent. (2) adjective: Describes a solution in which the solute has a low concentration. dimer The union of two identical molecules. Example: Al2Cl6 formed from two AlCl3 molecules. diol An organic compound with two –OH groups. dipeptide A peptide formed by the condensation of two amino acids. dipole See electric dipole; instantaneous dipole moment. dipole–dipole interaction The interaction between two electric dipoles: like partial charges repel and opposite partial charges attract. dipole–induced-dipole interaction The interaction between an electric dipole and the instantaneous dipole that it induces in a nonpolar molecule. dipole moment See electric dipole moment. diprotic An acid with two acidic hydrogen atoms. See also polyprotic acid or base. disaccharide A carbohydrate molecule that is composed of two saccharide units. Example: C12H22O11, sucrose. dispersion (1) The spatial separation of light into its component colors (as by a prism). (2) See suspension. dispersion force See London force. disproportionation A redox reaction in which a single element is simultaneously oxidized and reduced. Example: 2 Cuϩ (aq) → Cu(s) ϩ Cu2ϩ (aq). dissociation (1) The breaking of a bond. (2) The separation of ions that occurs when an ionic solid dissolves. dissociation constant See acidity constant. dissociation energy (D) The energy required to separate bonded atoms. distillate A liquid obtained by distillation. distillation The separation of the components of a mixture by making use of their different volatilities. distribution (of molecular speeds) The fraction of gas molecules moving at each speed at any instant. disulfide link An ∫S∫S∫ link that contributes to the secondary and tertiary structures of polypeptides. domain A region of a metal in which the electron spins of the atoms are aligned, resulting in ferromagnetism. doping The addition of a known, small amount of a second substance to an otherwise pure solid substance. d-orbital See atomic orbital. dose equivalent The actual dose of radiation experienced by a sample, modified to take into account the relative biological effectiveness of the radiation. The dose equivalent is measured in sievert (and formerly rem). double bond (1) Two electron pairs shared by neighboring atoms. (2) One ␴-bond and one ␲-bond between neighboring atoms. drying agent A substance that absorbs water and thus maintains a dry atmosphere. Example: phosphorus(V) oxide. ductility The ability to be drawn out into a wire (as for a metal). duplet The 1s2 electron pair of the heliumlike electron configuration. dynamic equilibrium The condition in which a forward process and its reverse are taking place simultaneously at equal rates. Examples: vaporizing and condensing; chemical reactions at equilibrium. effective nuclear charge (Zeff) The net nuclear charge after taking into account the shielding caused by other electrons in the atom. effervesce To bubble out of solution as a gas. effusion The escape of a substance (particularly a gas) through a small hole. elasticity The ability to return to the original shape after distortion. elastomer An elastic polymer. Example: rubber (polyisoprene). electricalconduction Theconductionof electricchargethrough matter. See also electronic conductor; ionic conduction. electric conductivity (␬) A measure of the ability of a substance to conduct electricity (in siemens per meter). electric current See current. electric dipole A positive charge next to an equal but opposite negative charge. electric dipole moment (␮) The magnitude of the electric dipole (in debye). electric field A region of influence that affects charged particles. electrochemical cell A system consisting of two electrodes in contact with an electrolyte. A galvanic cell (voltaic cell) is an electrochemical cell used to produce electricity, and an electrolytic cell is an electrochemical cell in which an electric current is used to cause chemical change. electrochemical series Redox couples arranged in order of oxidizing and reducing strengths; usually arranged with strong oxidizing agents at the top of the list and strong reducing agents at the bottom. B10 GLOSSARY electrochemistry The branch of chemistry that deals with the use of chemical reactions to produce electricity, the relative strengths of oxidizing and reducing agents, and the use of electricity to produce chemical change. electrode A metallic conductor that makes contact with an electrolyte in an electrochemical cell. A half-cell is sometimes also referred to as an electrode. electrolysis A process in which a chemical change is produced by passing an electric current through a liquid. electrolyte (1) An ionically conducting medium. (2) A substance that dissolves to give an electrically conducting solution. A strong electrolyte is a substance that is fully ionized in solution. A weak electrolyte is a molecular substance that is only partially ionized in solution. A nonelectrolyte does not ionize in solution. Examples: NaCl is a strong electrolyte; CH3COOH is a weak electrolyte; C6H12O6 is a nonelectrolyte. electrolyte solution A solution of an electrolyte. electrolytic cell See electrochemical cell. electromagnetic field The region of influence generated by accelerated charged particles. electromagnetic radiation A wave of oscillating electric and magnetic fields; includes light, x-rays, and ␥-rays. electromotive force (emf) See cell potential. electron (eϪ ) A negatively charged subatomic particle found outside the nucleus of an atom. electron affinity (Eea) The energy released when an electron is added to a gas-phase atom or monatomic ion. electron arrangement (VSEPR model) The threedimensional geometry of the arrangement of bonds and lone pairs about a central atom in a molecule or ion. electron capture The capture by a nucleus of one of its own atom’s s-electrons. electron configuration The occupancy of orbitals in an atom or molecule. Example: N, 1s2 2s2 2p3 . electron-deficient compound A compound with too few valence electrons for it to be assigned a valid Lewis structure. Example: B2H6. electronegative element An element with a high electronegativity. Examples: O; F. electronegativity (␹, chi) The ability of an atom to attract electrons to itself when it is part of a compound. electronic conductor A substance that conducts electricity by the transfer of electrons. electronic structure The details of the distribution of the electrons that surround the nuclei in atoms and molecules. electronvolt (eV) A unit of energy; the change in potential energy of an electron when it moves through a potential difference of 1 V; 1 eV ϭ 1.602 18 ϫ 10Ϫ19 J. electrophile A reactant that is attracted to a region of high electron density. Examples: Br2; NO2 ϩ . electrophilic substitution Substitution that takes place as a result of an attack by an electrophile. Example: nitration of benzene. electroplating The deposition of a thin film of metal on an object by electrolysis. electropositive element An element that has a low electronegativity and is likely to give up electrons to another element on compound formation. Examples: Cs; Mg. electrostatic potential surface A molecular structure in which the net charge is calculated at each point of the density isosurface and depicted by different colors; an “elpot” surface. element (1) A substance that cannot be separated into simpler components by chemical techniques. (2) A substance consisting of atoms of the same atomic number. Examples: hydrogen; gold; uranium. elementary reaction An individual step in a proposed reaction mechanism. elimination reaction A reaction in which two groups or atoms on neighboring carbon atoms are removed from a molecule, thereby leaving a multiple bond between the carbon atoms. Example: CH3CHBrCH3 ϩ OHϪ → CH3CH≈CH2 ϩ H2O ϩ BrϪ . empirical Determined by experiment. empirical formula A chemical formula that shows the relative numbers of atoms of each element in a compound by using the simplest whole-number subscripts. Examples: P2O5; CH for benzene. emulsion A suspension of droplets of one liquid dispersed throughout another liquid. enantiomers A pair of optical isomers that are mirror images of, but not superimposable on, each other. endothermic process A process that absorbs heat (ΔH Ͼ 0). Examples: vaporization; N2O4(g) → 2 NO2(g). end point The stage in a titration at which enough titrant has been added to bring the indicator to a color halfway between its initial and its final colors. energy (E) The capacity of a system to do work or supply heat. Kinetic energy is the energy of motion, and potential energy is the energy arising from position. The total energy is the sum of the kinetic and potential energies. energy level A permitted value of the energy in a quantized system such as an atom or a molecule. enrich In nuclear chemistry, to increase the abundance of a specific isotope. ensemble A collection of hypothetical replications of a system. enthalpy (H) A state property; H ϭ U ϩ PV. A change in enthalpy is equal to the heat transferred at constant pressure. enthalpy density (of a fuel) The enthalpy of combustion per liter (without the negative sign). enthalpy of freezing The enthalpy change per mole accompanyingfreezing;thenegativeof theenthalpyof fusion. enthalpy of fusion (ΔHfus) The enthalpy change per mole accompanying fusion (melting). enthalpy of hydration (ΔHhyd) The enthalpy change accompanying the hydration of gas-phase ions. enthalpy of melting (ΔHmelt) See enthalpy of fusion. enthalpy of mixing (ΔHmix) The change in enthalpy when two fluids (liquids or gases) mix. enthalpy of solution (ΔHsol) The change in enthalpy when a substance dissolves. The limiting enthalpy of solution is the enthalpy of solution for the formation of an infinitely dilute solution. enthalpy of sublimation (ΔHsub) The enthalpy change per mole accompanying sublimation (the direct conversion of a solid into a vapor). GLOSSARY B11 enthalpy of vaporization (ΔHvap) The enthalpy change per mole accompanying vaporization (the conversion of a substance from the liquid state into the vapor state). entropy (S) (1) A measure of the disorder of a system. (2) A change in entropy is equal to the heat supplied reversibly to a system divided by the temperature at which the transfer takes place. entropy of vaporization (ΔSvap) The entropy change per mole accompanying vaporization (the conversion of a substance from the liquid state into the vapor state). enzyme A biological catalyst. e-orbital One of the orbitals or in an octahedral or tetrahedral complex. In an octahedral complex, the orbitals are designated eg. equation of state A mathematical expression relating the pressure, volume, temperature, and amount of substance present in a sample. Example: ideal gas law, PV ϭ nRT. equatorial bond A bond perpendicular to the axis of a molecule (particularly trigonal bipyramidal and octahedral molecules). equatorial lone pair A lone pair in the plane perpendicular to the molecular axis. equilibrium See chemical equilibrium; dynamic equilibrium. equilibrium constant (K) An expression characteristic of the equilibrium composition of the reaction mixture, with a form given by the law of mass action. Example: N2(g) ϩ 3 H2(g) T 2 NH3(g), K ϭ ( )2 / ( )3 . equilibrium table A table used to calculate the composition of a reaction mixture at equilibrium, given the initial composition. The columns are headed by the species and the rows are, successively, the initial composition, the change to reach equilibrium, and the equilibrium composition. equimolar Having the same molar concentration or the same number of moles. equipartition theorem The average energy of each quadratic contribution to the energy of a molecule in a sample at a temperature T is equal to kT (where k is Boltzmann’s constant). equivalence point See stoichiometric point. essential amino acid An amino acid that is an essential component of the diet because it cannot be synthesized in the body. ester The product (other than water) of the reaction between a carboxylic acid and an alcohol and having the formula RCOORЈ. Example: CH3COOC2H5, ethyl acetate. esterification The formation of an ester. ether An organic compound of the form R∫O∫RЈ. Examples: CH3OC2H5, ethyl methyl ether; C2H5OC2H5, diethyl ether. evaporate To vaporize completely. excited state A state other than the state of lowest energy. exclusion principle No more than two electrons can occupy any given orbital; and, when two electrons do occupy one orbital, their spins must be paired. exothermic process A process that releases heat (ΔH Ͻ 0). Examples: freezing; N2(g) ϩ 3 H2(g) → 2 NH3(g). expanded valence shell A valence shell containing more than eight electrons. Also called an expanded octet. Examples: the valence shells of P and S in PCl5 and SF6. 1 2 PH2 PN2 PNH3 dx2 -y2dz2 expansion work See work. experiment A test carried out under carefully controlled conditions. exponential The exponential of x is the natural antilogarithm of x, namely, ex . exponential decay A variation with time of the form eϪkt . Example: [A] ϭ [A]0eϪkt . extensive property A physical property that depends on the size of the sample. Examples: volume; internal energy; enthalpy; entropy. extrapolate To extend a graph outside the region covered by the data. extrinsic semiconductor A material in which semiconduction arises from the presence of a low concentration of a dopant. Example: Arsenic added to very pure silicon. face See crystal face. face-centered cubic structure (fcc) A crystal structure built from a cubic unit cell in which there is an atom at the center of each face and one at each corner. Fahrenheit scale A temperature scale on which the freezing point of water is at 32 degrees and the normal boiling point is at 212 degrees. Units on this scale are degrees Fahrenheit, °F. fallout The fine dust that settles from clouds of airborne particles after a nuclear bomb test. Faraday’s constant (F) The magnitude of the charge per mole of electrons; F ϭ NAe ϭ 96.485 kC·molϪ1 . Faraday’s law of electrolysis The amount of product formed by an electric current is chemically equivalent to the amount of electrons supplied. fat An ester of glycerol and carboxylic acids with long hydrocarbon chains; fats act as long-term energy storage in living systems. fatty acid A carboxylic acid with a long hydrocarbon chain. Example: CH3(CH2)16COOH, stearic acid. ferrimagnetic material A material in which the electron spins on neighboring atoms are different and locked together in an antiferromagnetic arrangement. ferroalloy An alloy of a metal with iron and, often, carbon. Example: ferrovanadium. ferrofluid A magnetic liquid that is a suspension of a finely powdered magnetic material such as magnetite, Fe3O4, in a viscous, oily liquid (such as mineral oil) that contains a detergent. ferromagnetic material See ferromagnetism. ferromagnetism The ability of some substances to be permanently magnetized; the electron spins of neighboring atoms are aligned. Examples: iron; magnetite, Fe3O4. ferrous alloy An alloy based on iron and often including various other d-block metals. Examples: The varieties of steels. field An influence spreading over a region of space. Examples: an electric field from a charge; a magnetic field from a magnet or a moving charge. filtration The separation of a heterogeneous mixture of a solid and liquid by passing the mixture through a fine mesh. B12 GLOSSARY first derivative (dy/dx) A measure of the slope of a curve. See also Appendix 1F. first ionization energy (I1) See ionization energy. first law of thermodynamics The internal energy of an isolated system is constant. first-order reaction A reaction in which the rate is proportional to the first power of the concentration of a substance. fissile nucleus A nucleus having the ability to undergo fission induced by slow neutrons. Example: 235 U is fissile. fission (nuclear) The breakup of a nucleus into two smaller nuclei of similar mass; fission may be spontaneous or induced (particularly by the impact of neutrons). fissionable Havingtheabilitytoundergoinducednuclearfission. fix (nitrogen) Convert elemental nitrogen to its compounds, particularly ammonia. flammability The ability of a substance to burn in air. flocculation The reversible aggregation of colloidal particles into larger particles that can be filtered. fluorescence The emission of light from molecules excited by radiation of higher frequency. foam (1) A frothy collection of bubbles formed by a liquid. (2) A type of colloid formed by a gas of tiny bubbles in a liquid or solid. f-orbital See atomic orbital. force (F) An influence that changes the state of motion of an object. Examples: an electrostatic force from an electric charge; a mechanical force from an impact. formal anhydride An acid anhydride that does not necessarily react with water to form the corresponding acid. Example: CO, the formal anhydride of formic acid, HCOOH. formal charge (1) The electric charge of an atom in a molecule assigned on the assumption that the bonding is nonpolar covalent. (2) Formal charge (FC) ϭ number of valence electrons in the free atom – (number of lone-pair electrons ϩ ϫ number of shared electrons). formation constant (Kf) The equilibrium constant for complex formation. The overall formation constant is the product of step-by-step formation constants. The inverse of the formation constant (1/Kf) is called the stability constant. formula unit The group of ions that matches the formula of the smallest unit of an ionic compound. Example: NaCl, one Naϩ ion and one ClϪ ion. formula weight The numerical value of the molar mass of an ionic compound. fossil fuel The partly decomposed remains of vegetable and marine life (mainly coal, oil, and natural gas). fraction Samples of distillate obtained in different ranges of boiling temperatures. fractional distillation Separation of the components of a liquid mixture by repeated distillation, making use of their differing volatilities. Frasch process A process for mining sulfur that uses superheated water to melt the sulfur and compressed air to force it to the surface. free energy See Gibbs free energy. free expansion Expansion against zero opposing pressure. freezing-point constant (kf) The constant of proportionality between the freezing-point depression and the solute molality. 1 2 freezing-point depression The lowering of the freezing point of a solvent caused by the presence of a solute (a colligative property). freezing temperature The temperature at which a liquid freezes. The normal freezing point is the freezing temperature under a pressure of 1 atm. frequency (of radiation) (␯, nu) The number of cycles (repeats of the waveform) per second (unit: hertz, Hz). fuel cell A primary electrochemical cell in which the reactants are supplied continuously from outside while the cell is in use. functional group A group of atoms that brings a characteristic set of chemical properties to an organic molecule. Examples: ßOH ; ßBr ; ßCOOH. functionalization The introduction of functional groups into an alkane molecule. fundamental charge (e) The magnitude of the charge of an electron. fusion (1) Melting. (2) The merging of nuclei to form the nucleus of a heavier element. galvanic cell See electrochemical cell. galvanize Coat a metal with an unbroken film of zinc. gamma (␥) radiation Very high frequency, short-wavelength electromagnetic radiation emitted by nuclei. gas A fluid form of matter that fills the container that it occupies and can easily be compressed into a much smaller volume. (A gas differs from a vapor in that a gas is a substance at a higher temperature than its critical temperature; a vapor is a gaseous form of matter at a temperature below its critical temperature.) gas constant (R) (1) The constant that appears in the ideal gas law. See inside the back cover of the book for values. (2) R ϭ NAk, where k is Boltzmann’s constant. gas–liquid chromatography A version of chromatography in which a gas carries the sample over a stationary liquid phase. gauge pressure The pressure inside a container less that outside the container. Geiger counter A device that is used to detect and measure radioactivity by relying on ionization caused by incident radiation. gel A soft, solid colloid that typically consists of a liquid trapped within a solid network. geometrical isomers Stereoisomers that differ in the spatial arrangement of the atoms. Geometrical isomers exhibit cis–trans isomerism. Gibbs free energy (G ϭ H Ϫ TS) The energy of a system that is free to do work at constant temperature and pressure. The direction of spontaneous change at constant pressure and temperature is the direction of decreasing Gibbs free energy. Gibbs free energy of reaction The difference in molar Gibbs free energies of the products and reactants, weighted by the stoichiometric coefficients in the chemical equation. glass An ionic solid with an amorphous structure resembling that of a liquid. glass electrode A thin-walled glass bulb containing an electrolyte solution and a metallic contact; used for measuring pH. graft copolymer See copolymer. GLOSSARY B13 Graham’s law of effusion The rate of effusion of a gas is inversely proportional to the square root of its molar mass. gravimetric analysis An analytical method using measurements of mass. gray (Gy) The SI unit of absorbed dose; 1 Gy corresponds to an energy deposit of 1 JиkgϪ1 . See also rad. green chemistry The practice of chemistry that conserves resources and minimizes impact on the environment. greenhouse effect The blocking by some atmospheric gases (notably carbon dioxide) of the radiation of heat from the surface of the Earth back into space, leading to the possibility of a worldwide rise in temperature. greenhouse gas A gas that contributes to the greenhouse effect. ground state The state of lowest energy. group A vertical column in the periodic table. Haber process (Haber–Bosch process) The catalyzed synthesis of ammonia at high pressure. half-cell One compartment of an electrochemical cell consisting of an electrode and an electrolyte. half-life (t1/2) (1) In chemical kinetics, the time needed for the concentration of a substance to fall to half its initial value. (2) In radioactivity, the time needed for half the initial number of radioactive nuclei to disintegrate. half-reaction A hypothetical oxidation or reduction reaction showing either electron loss or electron gain. Examples: Na(s) → Naϩ (aq) ϩ eϪ ; Cl2(g) ϩ 2 eϪ → 2 ClϪ (aq). halide ion An anion formed from a halogen atom. Examples: FϪ ; IϪ . Hall process (Hall–Hérault process) The production of aluminum by the electrolysis of aluminum oxide dissolved in molten cryolite. haloalkane An alkane with a halogen substituent. Example: CH3Cl, chloromethane. halogen A member of Group 17/VII. halogenation The incorporation of a halogen into a compound (particularly, into an organic compound). hamiltonian The operator H in the Schrödinger equation; H␺ ϭ E␺. hard matter Solid matter that can withstand strong forces without deforming. hard water Water that contains dissolved calcium and magnesium salts. heat (q) The energy that is transferred as the result of a temperature difference between a system and its surroundings. heat capacity (C) The ratio of heat supplied to the temperature rise produced. The heat capacity at constant pressure, CP, and the heat capacity at constant volume, CV, are normally distinguished. See also molar heat capacity; specific heat capacity. heating The act of transferring energy as heat. heating curve A graph of the variation of the temperature of a sample as it is heated at a constant rate. Heisenberg uncertainty principle If the location of a particle is known to within an uncertainty Δx, then the linear momentum parallel to the x-axis can be known only to within an uncertainty Δp, where ΔpΔx Ն h/2. Henderson–Hasselbalch equation An approximate equation for estimating the pH of a solution containing a conjugate acid and base. See also Section 12.2. Henry’s constant The constant kH that appears in Henry’s law. Henry’s law The solubility of a gas in a liquid is proportional to its partial pressure above the liquid: solubility ϭ kH ϫ partial pressure. hertz (Hz) The SI unit of frequency: 1 Hz is one complete cycle per second; 1 Hz ϭ 1 sϪ1 . Hess’s law A reaction enthalpy is the sum of the enthalpies of any sequence of reactions (at the same temperature and pressure) into which the overall reaction can be divided. heterogeneous alloy See alloy. heterogeneous catalyst See catalyst. heterogeneous equilibrium An equilibrium in which at least one substance is in a different phase from the others. Example: AgCl(s) T Agϩ (aq) ϩ ClϪ (aq). heterogeneous mixture A mixture in which the individual components,althoughmixedtogether,lieindistinctregions that can be distinguished with an optical microscope. Example: a mixture of sand and sugar. heterolytic dissociation Dissociation into ions. Example: CH3I → CH3 ϩ ϩ IϪ . Compare with homolytic dissociation. heteronuclear diatomic molecule A molecule consisting of two atoms of different elements. Examples: HCl; CO. hexagonal close-packed structure (hcp) A close-packed structure with an ABABAB . . . pattern of layers. high-boiling azeotrope See azeotrope. highest occupied molecular orbital (HOMO) The highestenergy molecular orbital in the ground state of a molecule occupied by at least one electron. high-spin complex A dn complex with the maximum number of unpaired electron spins. high-temperature superconductor A material that becomes superconducting at temperatures well above the transition temperature for the first generation of superconductors, typically 100 K and above. homeostasis The maintenance of constant physiological conditions. homogeneous alloy See alloy. homogeneous catalyst See catalyst. homogeneous equilibrium A chemical equilibrium in which all the substances taking part are in the same phase. Example: H2(g) ϩ I2(g) T 2 HI(g). homogeneous mixture A mixture in which the individual components are uniformly mixed, even on a molecular scale. Examples: air; solutions. homolytic dissociation Dissociation into radicals. Example: CH3I → иCH3 ϩ иI. Compare with heterolytic dissociation. homonuclear diatomic molecule A molecule consisting of two atoms of the same element. Examples: H2; N2. Hund’s rule If more than one orbital in a subshell is available, add electrons with parallel spins to different orbitals of that subshell. hybridization The formation of hybrid orbitals. hybrid orbital A mixed orbital formed by blending together atomic orbitals on the same atom. Example: an sp3 hybrid orbital. hydrate A solid compound containing H2O molecules. Example: CuSO4·5H2O. hydrated Having water molecules attached. See hydration. B14 GLOSSARY hydrate isomers Isomers that differ by an exchange of an H2O molecule and a ligand in the coordination sphere. hydration (1) of ions: The attachment of water molecules to a central ion. (2) of organic compounds: The addition of water across a multiple bond (H to one carbon atom, OH to the other). Example: CH2≈CH2 ϩ H2O → CH3CH2OH. hydride A binary compound of a metal or metalloid with hydrogen; the term is often extended to include all binary compounds of hydrogen. A saline or saltlike hydride is a compound of hydrogen and a strongly electropositive metal; a molecular hydride is a compound of hydrogen and a nonmetal; a metallic hydride is a compound of certain d-block metals and hydrogen. hydrocarbon A binary compound of carbon and hydrogen. Examples: CH4; C6H6. hydrogenation The addition of hydrogen to multiple bonds. Example: CH3CH≈CH2 ϩ H2 → CH3CH2CH3. hydrogen bond A link formed by a hydrogen atom lying between two strongly electronegative atoms (O, N, or F). The electronegative atoms may be located on different molecules or in different regions of the same molecule. hydrohalogenation The addition of a hydrogen halide to an alkene to form a haloalkane. Example: CH3CH≈CH2 ϩ HCl → CH3CHClCH3. hydrolysis reaction The reaction of water with a substance, resulting in the formation of a new element–oxygen bond. Example: PCl5(s) ϩ 4 H2O(l) → H3PO4(aq) ϩ 5 HCl(aq). hydrolyze To undergo hydrolysis. See also hydrolysis reaction. hydrometallurgical process The extraction of metals by reduction of their ions in aqueous solution. Example: Cu2ϩ (aq) ϩ Fe(s) → Cu(s) ϩ Fe2ϩ (aq). hydronium ion The ion H3Oϩ . hydrophilic Water attracting. Example: hydroxyl groups are hydrophilic. hydrophobic Water repelling. Example: hydrocarbon chains are hydrophobic. hydrostatic pressure The pressure exerted by a column of fluid. hydroxyl group An ßOH group in an organic compound. hypervalent compound A compound that contains an atom with more atoms attached than allowed by the octet rule. Example: SF6. hypothesis A suggestion put forward to account for a series of observations. Example: Dalton’s atomic hypothesis. ideal gas A gas that satisfies the ideal gas law and is described by the kinetic model. ideal gas law (PV ϭ nRT) All gases obey the law more and more closely as the pressure is reduced to very low values. ideal solution A solution that obeys Raoult’s law at any concentration; all solutions behave ideally as the concentration approaches zero. Example: benzene and toluene form an almost ideal system. i factor A factor that takes into account the existence of ions in an electrolyte solution, particularly for the interpretation of colligative properties. It indicates the number of particles formed from one formula unit of the solute. Example: i ≈ 2 for very dilute NaCl(aq). incandescence Light emitted by a hot body. incomplete octet A valence shell of an atom that has fewer than eight electrons. Example: the valence shell of B in BF3. indefinite integral An integral without limits attached. See also Appendix 1F. indicator A substance that changes color when it goes from its acidic to its basic form (an acid–base indicator) or from its oxidized to its reduced form (a redox indicator). induced dipole moment An electric dipole moment produced in a polarizable molecule by a neighboring charge or partial charge. induced-fit mechanism A model of the action of an enzyme in which the enzyme molecule adjusts its shape to accommodate the incoming substrate molecule. A modification of the lockand-key mechanism of enzyme action. induced nuclear fission See fission. inert (1) Unreactive. (2) Thermodynamically unstable but survives for long periods (nonlabile). inert-pair effect The observation that an element displays a valence lower than expected from its group number. An inert pair is a pair of valence shell s-electrons that are tightly bound to the atom and might not participate in bond formation. infrared radiation Electromagnetic radiation with a lower frequency (longer wavelength) than that of red light but a higher frequency (shorter wavelength) than microwave radiation. initial concentration (of a weak acid or base) The concentration as prepared, as if no deprotonation or protonation had taken place. initial rate The rate at the start of the reaction when products are present in concentrations too low to affect the rate. initiation The formation of reactive intermediates that serve as chain carriers from a reactant at the start of a chain reaction. Example: Br2 → Brи ϩ Br·. inner transition metal A member of the f-block of the periodic table (the lanthanoids and actinoids). inorganic chemistry The study of the elements other than carbon and their compounds. inorganic compound A compound that is not organic. See also organic compound. insoluble substance A substance that does not dissolve in a specified solvent. When the solvent is not specified, water is generally meant. instantaneous dipole moment A dipole moment that arises from a transient redistribution of charge and is responsible for the London force. instantaneous rate The slope of the tangent of a graph of concentration against time. insulator (electrical) A substance that does not conduct electricity. Examples: nonmetallic elements; molecular solids. integral (1) The sum of infinitesimal quantities. (2) The inverse of a derivative in the sense that the integral of the first derivative of a function is the original function. See definite integral, indefinite integral. integral calculus The part of mathematics that deals with the combination of infinitesimal quantities and the areas under curves. See also Appendix 1F. GLOSSARY B15 integrated rate law An expression for the concentration of a reactant or product in terms of the time, obtained from the rate law of the reaction. Example: [A] ϭ [A]0eϪkt . intensity The brightness of electromagnetic radiation. The intensity of a wave of electromagnetic radiation is proportional to the square of its amplitude. intensive property A physical property of a substance that is independent of the size of the sample. Examples: density; molar volume; temperature. intercept (of a graph) The value at which the line cuts the specified (usually vertical) axis. See also Appendix 1E. interference Interaction between waves, leading to a greater amplitude (constructive interference) or to a smaller one (destructive interference). interhalogen A binary compound of two halogens. Example: IF3. intermediate See reaction intermediate. intermetallic compound An inorganic compound formed from two metals in specific proportions. Examples: NiTi, Ag3Sn, FeCo. intermolecular Between molecules. intermolecular forces The forces of attraction and repulsion between molecules. Examples: hydrogen bonding; dipole– dipoleforce;Londonforce.SeealsovanderWaalsinteractions. internal energy (U) In thermodynamics, the total energy of a system. International System See SI. internuclear axis The straight line between the nuclei of two bonded atoms. interpolate To find a value between two measured values. interstice A hole or gap in a crystal lattice. interstitial alloy See alloy. interstitial compound A compound in which one type of atom occupies the gaps in a lattice of other atoms. Example: an interstitial carbide. intramolecular Within a molecule. intrinsic semiconductor A pure substance in which an empty conduction band lies close in energy to a full valence band. ion An electrically charged atom or group of atoms. Examples: Al3ϩ ; SO4 2Ϫ . See also anion; cation. ion–dipole interaction The attraction between an ion and the opposite partial charge of the electric dipole of a polar molecule. ion exchange The exchange of one type of ion in solution for another. ionic bond The attraction between the opposite charges of cations and anions. ionic character The extent to which ionic structures contribute to the resonance of a molecule or ion. ionic compound A compound that consists of ions. Examples: NaCl; KNO3. ionic conduction Electrical conduction in which the charge is carried by ions. See also electrical conduction; electronic conductor. ionic equation See complete ionic equation. ionic liquid An ionic compound that is liquid at ordinary temperatures because one of its ions is a relatively large, organic ion. Ionic liquids are used as nontoxic, nonvolatile solvents. ionic model The description of bonding in terms of ions. ionic radius The contribution of an ion to the distance between neighboring ions in a solid ionic compound. In practice, the radius of an ion is defined as its contribution to the distance between the centers of neighboring ions, with the radius of the O2– ion set equal to 140. pm. ionic solid A solid built from cations and anions. Examples: NaCl; KNO3. ionization (1) of atoms and molecules: Conversion into ions by the transfer of electrons. Example: K(g) → Kϩ (g) ϩ eϪ (g). (2) of acids and bases: See protonation and deprotonation. ionization constant See acidity constant. ionization energy (I) The minimum energy required to remove an electron from the ground state of a gaseous atom, molecule, or ion. The first ionization energy is the ionization energy for the removal of the first electron from an atom. The second ionization energy is the ionization energy for removal of a second electron, and so on. ionization isomers Isomers that differ by the exchange of a ligand with an anion or neutral molecule outside the coordination sphere. ionizing radiation High-energy radiation (typically but not necessarily nuclear radiation) that can cause ionization. ion pair A cation and anion in close proximity. ion-selective electrode An electrode sensitive to the concentration of a particular ion. irreversible process A process that is not reversed by an infinitesimal change in a variable. isoelectronic species Species with the same number of atoms and the same number of valence electrons. Examples: F– and Ne; SO2 and O3; CNϪ and CO. isolated system See system. isomer One of two or more compounds that contain the same number of the same atoms in different arrangements. In structural isomers, the atoms have different partners or lie in a different order; in stereoisomers, the atoms have the same partners but are in different arrangements in space. Optical isomers are related like an object and its mirror image; they are types of stereoisomers. Examples: CH3OCH3 and CH3CH2OH (structural isomers); cis- and trans-2-butene (stereoisomers). isomerization A reaction in which a compound is converted into one of its isomers. Example: cis-butene →trans-butene. isotherm A line on a graph depicting the variation of a property at constant temperature. isothermal change A change that occurs at constant temperature. isotope One of two or more atoms that have the same atomic number but different mass number. Example: 1 H, 2 H, and 3 H are all isotopes of hydrogen. isotopic abundance See abundance. isotopic dating The determination of the age of objects by measuring the activity of the radioactive isotopes that they contain, particularly 14 C. isotopic label See tracer. isotopomers Molecules that differ in their isotopic composition. Examples: 12 CH4 and 13 CH4. isotropic Not depending on orientation. B16 GLOSSARY joule (J) The SI unit of energy (1 J ϭ 1 kgиm2 иsϪ2 ). Joule–Thomson effect The cooling of a gas as it expands. Kekulé structures Two Lewis structures of benzene, consisting of alternating single and double bonds. kelvin (K) The SI unit of temperature. See also Appendix 1B. Kelvin scale A fundamental scale of temperature on which the triple point of water lies at 273.16 K and the lowest attainable temperature is at 0. The unit on the Kelvin scale is the kelvin, K. ketone An organic compound containing a carbonyl group between two carbon atoms, having the form R∫CO∫RЈ. Example: CH3∫CO∫CH2CH3, butanone. kilogram (kg) The SI unit of mass. See also Appendix 1B. kinetic energy (Ek) The energy of a particle due to its motion. Kinetic energy may be translational (arising from motion through space), rotational (arising from rotation about a center of mass), or vibrational (arising from the oscillating motion of the atoms in a molecule). Example: the translational kinetic energy of a particle of mass m and speed v is mv2 . kinetic model A model of the properties of an ideal gas in which pointlike molecules are in continuous random motion in straight lines until collisions occur between them. kinetic molecular theory (KMT) The mathematical version of the kinetic model of gases. Kirchhoff’s law The relation between the standard reaction enthalpies at two temperatures in terms of the temperature difference and the difference in heat capacities (at constant pressure) of the products and reactants. labeled The replacement of an atom in a compound with a radioisotope of the same element in order to allow very small amounts of the compound to be detected. labile Refers to species that survive only for short periods. lanthanide Former (and still widely used) term for lanthanoid. lanthanide contraction The reduction of atomic radius of the elements following the lanthanides below the values that wouldbeexpectedbyextrapolationof thetrenddownagroup (and arising from the poor shielding ability of f-electrons). lanthanoid A member of the first row of the f-block (cerium through ytterbium). lattice An orderly array of atoms, molecules, or ions in a crystal. lattice energy The difference between the potential energy of ions in a crystal and that of the same widely separated ions in a gas. lattice enthalpy The standard enthalpy change for the conversion of an ionic solid into a gas of ions. law A summary of an extensive series of observations. law of conservation of energy Energy can be neither created nor destroyed. law of conservation of mass Matter (and specifically atoms) is neither created nor destroyed in a chemical reaction. law of constant composition A compound has the same composition whatever its source. law of mass action For an equilibrium of the form a A ϩ b B T c C ϩ d D, the ratio aC c aD d /aA a aB b evaluated at 1 2 equilibrium is equal to a constant K, which has a specific value for a given chemical equation and temperature. law of partial pressures See Dalton’s law of partial pressures. law of radioactive decay The rate of decay is proportional to the number of radioactive nuclides in the sample. LCAO and LCAO-MO See linear combination of atomic orbitals. Le Chatelier’s principle When a stress is applied to a system in dynamic equilibrium, the equilibrium adjusts to minimize the effect of the stress. Example: a reaction at equilibrium tends to proceed in the endothermic direction when the temperature is raised. leveling The observation that strong acids all have the same strength in water, and all behave as though they were solutions of H3Oϩ ions. Lewis acid An electron pair acceptor. Examples: Hϩ ; Fe3ϩ ; BF3. Lewis base An electron pair donor. Examples: OHϪ ; H2O; NH3. Lewis formula (for an ionic compound) A representation of the structure of an ionic compound showing the formula unit of ions in terms of their Lewis diagrams. Lewis structure A diagram showing how electron pairs are shared between atoms in a molecule. Examples: HßClA¥ a and O¥A ¢C¢O¥A . Lewis symbol (for atoms and ions) The chemical symbol of an element, with a dot for each valence electron. ligand A group attached to the central metal ion in a complex; a polydentate ligand occupies more than one binding site. See also ambidentate ligand. ligand field splitting (Δ) The energy separation of the e- and t-orbitals in a complex induced by the presence of ligands. ligand field theory The theory of bonding in d-metal complexes, a more complete version of crystal field theory. See also crystal field. light See visible radiation. limiting enthalpy of solution See enthalpy of solution. limiting law A law that is accurately obeyed only at the limit of a property, such as when a property (the pressure of a gas, for example) is made very small. limiting reactant The reactant that governs the theoretical yield of product in a given reaction. linear combination of atomic orbitals (LCAO) A sum of atomic orbitals to form a molecular orbital (an LCAO-MO). linear momentum (p) The product of mass and velocity. line structure A representation of the structure of an organic molecule in which lines represent bonds; carbon atoms and the hydrogen atoms attached to them are not usually shown explicitly. linkage isomers Isomers that differ in the identity of the atom that a ligand uses to attach to a metal ion. lipid A naturally occurring organic compound that dissolves in hydrocarbons but not in water. Examples: fats; steroids; terpenes; the molecules that form cell membranes. liquid Afluidformof matterthathasawell-definedsurfaceand takes the shape of the part of the container that it occupies. liquid crystal A substance that flows like a liquid but has molecules that lie in a moderately orderly array. Liquid GLOSSARY B17 crystals may be nematic, smectic, or cholesteric, depending on the arrangement of the molecules. lock-and-key mechanism A model of enzyme action in which the enzyme is thought of as a lock and its substrate as a matching key. logarithm If a number x is written as By , then y is the logarithm of x to the base B. For common logarithms (denoted log x), B ϭ 10. For natural logarithms (denoted ln x), B ϭ e. See also Appendix 1D. London force The force of attraction that arises from the interaction between instantaneous electric dipoles on neighboring molecules. lone pair A pair of valence electrons that is not taking part in bonding. long period A period of the periodic table with more than eight members. long-range order An orderly arrangement of atoms or molecules that is repeated over long distances. lowest unoccupied molecular orbital (LUMO) The lowest- energymolecularorbitalthatisunoccupiedinthegroundstate. low-spin complex A dn complex with the minimum number of unpaired electron spins. luminescence The emission of light from a process, other than incandescence, that results from the formation of an excited state. Lyman series A series of lines in the spectrum of atomic hydrogen in which the transitions are to orbitals with n ϭ 1. lyotropic liquid crystal A liquid crystal that results from the action of a solvent on a solute. macroscopic level The level at which visible objects can be observed directly. Madelung constant (A) A number that appears in the expression for the lattice energy and depends on the type of crystal lattice. Example: A ϭ 1.748 for the rock-salt structure. magic numbers The numbers of protons or neutrons that correlate with enhanced nuclear stability. Examples: 2, 8, 20, 50, 82, and 126. magnetic field A region of influence that affects the motion of moving charged particles. magnetic quantum number (ml) The quantum number that identifies the individual orbitals of a subshell of an atom and determines their orientation in space. main group Any one of the groups forming the s- and p-blocks of the periodic table (Groups 1, 2, and 13/III through 18/VIII). malleability The ability to be deformed by being struck by a hammer (as a metal). manometer An instrument used for measuring the pressure of a gas confined inside a container. mantissa (of a logarithm) The numbers to the right of the decimal point. many-electron atom An atom with more than one electron. mass (m) The quantity of matter in a sample. mass number (A) The total number of nucleons (protons plus neutrons) in the nucleus of an atom. Example: 14 C, with mass number 14, has 14 nucleons (6 protons and 8 neutrons). mass percentage composition The mass of a substance present in a sample, expressed as a percentage of the total mass of the sample. mass spectrometer An instrument used in mass spectrometry. mass spectrometry Technique for measuring the masses and abundances of atoms and molecules by passing a beam of ions through a magnetic field. mass spectrum The display of the relative number of particles with each specified mass; the output generated by the detector of a mass spectrometer. See also mass spectrometry. material balance The requirement that the sum of the concentrations of all forms of a solute in a solution be equal to the initial concentration of the solute. Example: the sum of the concentrations of HCN and CNϪ in an aqueous solution of HCN is equal to the initial concentration of HCN. materials science The study of the chemical structures, compositions, and properties of materials. matter Anything that has mass and takes up space. maximum-boiling azeotrope See azeotrope. Maxwell distribution of molecular speeds The formula for calculating the percentage of molecules that move at any given speed in a gas at a specified temperature. mean bond enthalpy (ΔHB) The mean of A∫B bond enthalpies for a number of different molecules containing the A∫B bond. See also bond enthalpy. mean free path The average distance that a molecule travels between collisions. mean relative speed The mean speed at which two molecules approach each other in a gas. mechanical equilibrium The state in which the pressure of a system is equal to that of its surroundings. mechanism See reaction mechanism. medicinal chemistry The application of chemical principles to the development of pharmaceuticals. melting temperature The temperature at which a substance melts. The normal melting point is the melting point under a pressure of 1 atm. meniscus The curved surface that a liquid forms in a narrow tube. mesophase A state of matter showing some of the properties of both a liquid and a solid (a liquid crystal). metal (1) A substance that conducts electricity, has a metallic luster, is malleable and ductile, forms cations, and has basic oxides. (2) A metal consists of cations held together by a sea of electrons. Examples: iron; copper; uranium. metallic bond The form of bonding characteristic of metals in which cations are held together by a sea of electrons. metallic conductor An electronic conductor with a resistance that increases as the temperature is raised. metallic hydride See hydride. metallic solid See metal. metallocene A compound in which a metal atom lies between two cyclic ligands, thus resembling a sandwich. Example: ferrocene (dicyclopentadienyliron(0), [Fe(C5H5)2]). metalloid An element that has the physical appearance and properties of a metal but behaves chemically like a nonmetal. Examples: arsenic; polonium. meter (m) The SI unit of length. See also Appendix 1B. micelle A compact, often nearly spherical cluster of oriented detergent (surfactant) molecules. B18 GLOSSARY Michaelis constant (KM) A constant in the rate law for the Michaelis–Menten mechanism. Michaelis–Menten mechanism A model of enzyme catalysis in which the enzyme and its substrate reach a rapid preequilibrium with the bound substrate–enzyme complex. microporous catalyst A catalyst with an open, porous structure. Example: a zeolite. microscopic level A level of description that refers to the very small, such as atoms. microstate A permissible instantaneous arrangement of molecules in a sample (in the context of statistical thermodynamics and the statistical definition of entropy). microwaves Electromagnetic radiation with wavelengths close to 1 cm. millimeter of mercury (mmHg) The pressure exerted by a column of mercury of height 1 mm (at 15°C and in a standard gravitational field). minerals Substances that are mined; more generally, inorganic substances. minimum-boiling azeotrope See azeotrope. mixture A type of matter that consists of more than one substance and can be separated into its components by making use of the different physical properties of the substances present. model A simplified description of nature. moderator A substance that slows neutrons. Examples: graphite; heavy water. molality The amount of solute (in moles) per kilogram of solvent. molar Refers to the quantity per mole. Examples: molar mass, the mass per mole; molar volume, the volume per mole. (Molar concentration and some related quantities are exceptions.) molar absorption coefficient The constant of proportionality between the absorbance of a sample and the product of its molar concentration and path length. See also Beer’s law. molar concentration ([J]) The amount (in moles) of solute per liter of solution. molar heat capacity (Cm) The heat capacity per mole of substance. molarity ([J]) Molar concentration. molar mass (1) The mass per mole of atoms of an element. (2) The mass per mole of molecules of a molecular compound. (3) The mass per mole of formula units of an ionic compound. molar solubility (s) The numerical value of the molar concentration of a saturated solution of a substance. molar volume The volume of a sample divided by the amount (in moles) of atoms or molecules that it contains. mole (mol) The SI unit of chemical amount. See also Appendix 1B. molecular biology The study of the functions of living organisms in terms of their molecular composition. molecular compound A compound that consists of molecules. Examples: water; sulfur hexafluoride; benzoic acid. molecular formula A combination of chemical symbols and subscripts showing the actual numbers of atoms of each element present in a molecule. Examples: H2O; SF6; C6H5COOH. molecular hydride See hydride. molecularity The number of reactant molecules (or free atoms) taking part in an elementary reaction. See also bimolecular reaction; termolecular reaction; unimolecular reaction. molecular magnet A group of several d-block metal atoms bonded to nonmetal atoms such as carbon, hydrogen, and oxygen and which can respond to a magnetic field. molecular orbital A wavefunction that spreads throughout a molecule and gives the probability (through its square) that an electron will be found at each location. molecular orbital energy-level diagram A portrayal of the relative energies of the molecular orbitals in a molecule. molecular orbital theory The description of molecular structure in which electrons occupy orbitals that spread throughout a molecule. molecular solid A solid consisting of a collection of individual molecules held together by intermolecular forces. Examples: glucose; aspirin; sulfur. molecular weight The numerical value of the molar mass of a molecular compound. molecule (1) The smallest particle of a compound that possesses the chemical properties of the compound. (2) A definite, distinct, electrically neutral group of bonded atoms. Examples: H2; NH3; CH3COOH. mole fraction (x) The amount of particles (molecules, atoms, or ions) of a substance in a mixture expressed as a fraction of the total amount of particles in the mixture. mole ratio The stoichiometric relation between two species in a chemical reaction written as a conversion factor. Example: (2 mol H2)/(1 mol O2) in the reaction 2 H2(g) ϩ O2(g) → 2 H2O(l). momentum (p) See linear momentum. monatomic ion An ion formed from a single atom. Examples: Naϩ ; ClϪ . Mond process The purification of nickel by the formation and decomposition of nickel carbonyl. monomer A small molecule from which a polymer is formed. Examples: CH2≈CH2 for polyethylene; NH2(CH2)6NH2 for nylon. monoprotic acid A Brønsted acid with one acidic hydrogen atom. Example: CH3COOH. monosaccharide An individual unit from which carbohydrates are considered to be composed. Example: C6H12O6, glucose. multiple bond A double or triple bond between two atoms. nanomaterials Materials composed of nanoparticles or regular arrays of molecules or atoms such as nanotubes. nanoparticles Particles that range in size from about 1 to 100 nm and can be manufactured and manipulated at the molecular level. nanoscience The study of materials at the nanometer scale. These materials are larger than single atoms, but too small to exhibit most bulk properties. nanotechnology The study and manipulation of matter at the atomic level (nanometer scale). natural abundance (of an isotope) The abundance of an isotope in a sample of a naturally occurring material. natural antilogarithm See exponential. natural logarithm See logarithm. GLOSSARY B19 naturally occurring Found in nature without needing to be synthesized. natural product An organic substance that occurs naturally in the environment. negative deviation (from Raoult’s law) The tendency of a nonideal solution to have a vapor pressure lower than predicted by Raoult’s law. nematic phase A liquid-crystal phase in which rodshaped molecules have axes arranged parallel to each other but staggered with respect to one another in other directions. Nernst equation The equation expressing the emf of an electrochemical cell in terms of the concentrations of the reagents taking part in the cell reaction; Ecell ϭ Ecell° – (RT/nF) ln Q. net ionic equation The equation showing the net change in a chemical reaction, obtained by canceling the spectator ions in a complete ionic equation. Example: Agϩ (aq) ϩ Cl– (aq) → AgCl(s). network solid A solid consisting of atoms linked together covalently throughout its extent. Examples: diamond; silica. neutralization reaction The reaction of an acid with a base to form a salt. Example: HCl(aq) ϩ NaOH(aq) → NaCl(aq) ϩ H2O(l). neutron (n) An electrically neutral subatomic particle found in the nucleus of an atom; it has approximately the same mass as a proton. neutron emission A nuclear decay process in which a neutron is emitted. In neutron emission, the mass number decreases by 1, but the charge number remains the same. neutron-induced transmutation The conversion of one nucleus into another by the impact of a neutron. Example: 58 26Fe ϩ 2 1 0n → 60 27Co ϩ 0 Ϫ1e. neutron-rich nucleus A nucleus with such a high proportion of neutrons that it lies above the band of stability. NOx An oxide, or mixture of oxides, of nitrogen, typically in atmospheric chemistry. noble gas A member of Group 18/VIII of the periodic table (the helium family). nodal plane A plane on which an electron in an atom or molecule will not be found. node A point or surface on which a wavefunction passes through zero. nomenclature See chemical nomenclature. nonaqueous solution A solution in which the solvent is not water. Example: sulfur in carbon disulfide. nonbonding orbital A valence-shell atomic orbital that has not been used to form a bond to another atom. nonelectrolyte A substance that dissolves to give a solution that does not conduct electricity. Example: sucrose. nonelectrolyte solution A solution of a nonelectrolyte. nonexpansion work (we) See work. nonferrous alloy An alloy based on metals other than iron. Examples: brass, bronze. nonideal solution A solution that does not obey Raoult’s law. Compare with ideal solution. nonlabile Refers to a species that survives for a long period, even if it is thermodynamically unstable. nonmetal A substance that does not conduct electricity and is neither malleable nor ductile. Examples: all gases; phosphorus; sodium chloride. nonpolar bond (1) A covalent bond between two atoms that have zero partial charges. (2) A covalent bond between two atoms with the same or nearly the same electronegativity. nonpolar molecule A molecule with zero electric dipole moment. normal boiling point (Tb) (1) The boiling temperature when the pressure is 1 atm. (2) The temperature at which the vapor pressure of a liquid is 1 atm. normal form The form of a substance under typical everyday conditions (for instance, close to 1 atm, 25°C). normal freezing point (Tf) The temperature at which a liquid freezes at 1 atm. normal melting point (Tf) The melting point of a substance at a pressure of 1 atm. ns-orbital An atomic orbital with principal quantum number n and l ϭ 0. n-type semiconductor See semiconductor. nuclear atom The structure of the atom proposed by Rutherford: a central, small, very dense, positively charged nucleus surrounded by electrons. nuclear binding energy (Ebind) The energy released when Z protons and A – Z neutrons come together to form a nucleus with atomic number Z and mass number A. The greater the bindingenergypernucleon,thelowertheenergyof thenucleus. nuclear chemistry The study of the chemical consequences of nuclear reactions. nuclear decay The spontaneous partial breakup of a nucleus (including its fission). Nuclear decay is also referred to as nuclear disintegration. Example: 226 88Ra → 222 86Rn ϩ 4 2␣. nuclear equation A summary of the changes in a nuclear reaction, written in a form resembling a chemical equation. nuclear fission See fission. nuclear fusion See fusion. nuclear model A model of the atom in which the electrons surround a minute central nucleus. nuclear reaction A change that a nucleus undergoes (such as a nuclear transmutation). nuclear reactor A device for achieving controlled selfsustaining nuclear fission. nuclear transmutation The conversion of one element into another. Example: 12 6C ϩ 4 2␣ → 16 8O ϩ ␥. nucleic acid (1) The product of a condensation of nucleotides. (2) A molecule containing an organism’s genetic information. nucleon A proton or a neutron; thus, either of the two principal components of a nucleus. nucleophile A reactant that seeks out centers of positive charge in a molecule. Examples: H2O, OH– . nucleophilic substitition Substitution that results from attack by a nucleophile. Examples: hydrolysis of haloalkanes, CH3Br ϩ H2O → CH3OH ϩ HBr. nucleoside A combination of an organic base and a ribose or deoxyribose molecule. nucleosynthesis The formation of an element. nucleotide A nucleoside with a phosphate group attached to the carbohydrate ring; one of the units from which nucleic acids are made. B20 GLOSSARY nucleus The small, positively charged particle at the center of an atom that is responsible for most of its mass. nuclide A specific nucleus. Examples: 1 1H; 16 8O nutritional calorie (Cal) A unit used in food science to measure the caloric value of food; 1 nutritional calorie ϭ 1 kilocalorie. occupy Have the characteristics of the wavefunction of a specified state; to be in a specified state. octahedral complex A complex in which six ligands are arranged at the corners of a regular octahedron, with a metal atom or ion at the center. Example: [Fe(CN)6]4Ϫ . octahedral hole A cavity in a (usually close packed) crystal lattice formed from six spheres at the corners of a regular octahedron. octet An ns2 np6 valence electron configuration. octet rule When atoms form bonds, they proceed as far as possible toward completing their octets by sharing electron pairs. oligopeptide A short chain of amino acids connected by amide (peptide) bonds. one-component phase diagram See phase diagram. open system See system. optical activity The ability of a substance to rotate the plane of polarized light passing through it. optical isomers Isomers that are related like an object and its mirror image. Optical isomerism is the existence of optical isomers. Optical isomerism is a type of stereoisomerism. orbital See atomic orbital and molecular orbital. orbital angular momentum A measure of the rate of rotation. orbital angular momentum quantum number (l) The quantum number that specifies the subshell of a given shell in an atom and determines the shapes of the orbitals in the subshell; l ϭ 0, 1, 2, . . . , n Ϫ 1. Examples: l ϭ 0 for the s-subshell; l ϭ 1 for the p-subshell. (The quantum number l also specifies the magnitude of the angular momentum of the electron around the nucleus.) order of reaction The power to which the concentration of a single substance is raised in a rate law. Example: if the rate ϭ k[SO2][SO3]Ϫ1/2 , then the reaction is first order in SO2, and of order in SO3. ore The natural mineral source of a metal. Example: Fe2O3, hematite, an iron ore. organic chemistry The branch of chemistry that deals with organic compounds. organic compound A compound containing the element carbon and usually hydrogen. (The carbonates are normally excluded.) organometallic compound A compound that contains a metal–carbon bond. Example: Ni(CO)4.(Complexes of CNϪ are normally excluded.) oscillating Varying in a periodic manner with time. osmometry The determination of the molar mass of a solute from osmotic pressure measurements. osmosis The tendency of a solvent to flow through a semipermeable membrane into a more concentrated solution (a colligative property). -1 2 osmotic pressure (⌸, pi) The pressure needed to stop the flow of solvent through a semipermeable membrane. See also osmosis. overall formation constant See formation constant. overall order The sum of the powers to which individual concentrationsareraisedintheratelawof areaction.Example: If rate ϭ k[SO2][SO3]Ϫ1/2 , then the overall order is . overall reaction The net outcome of a sequence of reactions. overlap The merging of orbitals belonging to different atoms of a molecule. overpotential The additional potential difference that must be applied beyond the cell potential to cause appreciable electrolysis. oxidation (1) Combination with oxygen. (2) A reaction in which an atom, ion, or molecule loses an electron. (3) A half-reaction in which the oxidation number of an element is increased. Examples: (1, 2) 2 Mg(s) ϩ O2(g) → 2 MgO(s); (2, 3) Mg(s) → Mg2ϩ (s) ϩ 2 eϪ . oxidation number The effective charge on an atom in a compound, calculated according to a set of rules (see Toolbox K.1). An increase in oxidation number corresponds to oxidation; a decrease corresponds to reduction. oxidation–reduction reaction See redox reaction. oxidation state The actual condition of a species with a specified oxidation number. oxidizing agent A species that removes electrons from a species being oxidized (and is itself reduced) in a redox reaction. Examples: O2; O3; MnO4 Ϫ ; Fe3ϩ . oxoacid An acid that contains oxygen. Examples: H2CO3; HNO3; HNO2; HClO. oxoanion An anion of an oxoacid. Examples: HCO3 Ϫ ; CO3 2– . paired electrons Two electrons with opposed spins (↑↓). parallel spins Electrons with spins aligned in the same direction (↑↑). paramagnetic substance See paramagnetism. paramagnetism The tendency to be pulled into a magnetic field; a paramagnetic substance is composed of atoms or molecules with unpaired electrons. Examples: O2; [Fe(CN)6]3Ϫ . parent nucleus In a nuclear reaction, the nucleus that undergoes disintegration or transmutation. partial charge A charge arising from small shifts in the distributions of electrons. A partial charge can be either positive (␦ϩ) or negative (␦–). partial pressure (PX) The pressure that a gas (X) in a mixture would exert if it alone occupied the container. particle in a box A particle confined between rigid walls. parts per million (ppm) (1) The ratio of the mass of a solute to the mass of the solution, multiplied by 106 . (2) The mass percentage composition multiplied by 104 . (Parts per billion, ppb, the mass ratio multiplied by 109 , also may be used.) pascal (Pa) The SI unit of pressure: 1 Pa ϭ 1 kg·mϪ1 ·sϪ2 . See also Appendix 1B. passivation Protection from further reaction by a surface film. Example: aluminum in air. Pauli exclusion principle See exclusion principle. p-electron An electron in a p-orbital. 1 2 GLOSSARY B21 penetration The possibility that an s-electron may be found inside the inner shells of an atom and hence close to the nucleus. peptide A molecule formed by a condensation reaction between amino acids; often described in terms of the number of units, for example, dipeptide, oligopeptide, polypeptide. peptide bond The ßCONHß group. percentage composition See mass percentage composition; volume percentage composition. percentage deprotonation The fraction of a weak acid, expressed as a percentage, that is present as its conjugate base in a solution. percentage ionization The fraction of molecules of a substance, expressed as a percentage, that is present as ions. percentage protonated The fraction of a base, expressed as a percentage, that is present as its conjugate acid in a solution. percentage yield The percentage of the theoretical yield of a product achieved in practice. period A horizontal row in the periodic table; the number of the period is equal to the principal quantum number of the valence shell of the atoms. periodic table A chart in which the elements are arranged in order of atomic number and divided into groups and periods in a manner that shows the relationships between the properties of the elements. pH The negative logarithm of the hydronium ion molarity in a solution: pH ϭ Ϫlog[H3Oϩ ]. A pH Ͻ 7 indicates an acidic solution; pH ϭ 7, a neutral solution; and pH Ͼ 7, a basic solution. phase A specific physical state of matter. A substance may exist in solid, liquid, and gaseous phases and, in certain cases, in more than one solid or liquid phase. Examples: white and gray tin are two solid phases of tin; ice, liquid, and vapor are three phases of water. phase boundary (1) A line separating two areas in a phase diagram; the points on a phase boundary represent the conditions at which the two adjoining phases are in dynamic equilibrium. (2) The surface between two phases. phase diagram A summary in graphical form of the conditions of temperature and pressure at which the various solid, liquid, and gaseous phases of a substance exist. A one-component phase diagram is a phase diagram for a single substance. phase transition The conversion of a substance from one phase into another phase. Examples: vaporization; white tin → gray tin. pH curve A graph of the pH of a reaction mixture against volume of titrant added in an acid–base titration. phenol An organic compound in which a hydroxyl group is attached directly to an aromatic ring (Ar∫OH). Example: C6H5OH, phenol. pH meter An electronic device used to measure the pH of a solution. phosphor A phosphorescent material that emits light after excitation to higher energy states. phosphorescence Long-lasting luminescence. photochemical reaction A reaction caused by light. Example: H2(g) ϩ Cl2(g) ßB h␯ 2 HCl(g). photoelectric effect The emission of electrons from the surface of a metal when electromagnetic radiation strikes it. photon A particle-like packet of electromagnetic radiation. The energy of a photon of frequency ␯ is E ϭ h␯. physical change A change in which the identity of the substance does not change and only its physical properties are different. Example: freezing. physical chemistry The study of the principles of chemistry. physical equilibrium A state in which two or more phases of a substance coexist without a tendency to change. Example: ice and water at 0°C and 1 atm. physical property A characteristic that we observe or measure without changing the identity of the substance. physical state The condition of being a solid, a liquid, or a gas at a particular temperature. pi (␲) bond A bond formed by the side-to-side overlap of two p-orbitals. piezoelectric Having the property of becoming electrically charged when mechanically distorted. Example: BaTiO3. pi (␲) orbital A molecular orbital that has one nodal plane cutting through the internuclear axis. pipet A narrow tube, sometimes with a central bulb, calibrated to deliver a specified volume. pKa and pKb The negative logarithms of the acidity and basicity constants: pK ϭ Ϫlog K. The larger the value of pKa or pKb, the weaker the acid or base, respectively. Planck’s constant (h) A fundamental constant of nature with the value 6.626 ϫ 10Ϫ34 Jиs. plasma (1) An ionized gas. (2) In biology, the colorless component of blood in which the red and white blood cells are dispersed. p–n junction An interface between a p-type and an n-type semiconductor. pOH The negative logarithm of the hydroxide ion molarity in a solution; pOH ϭ Ϫlog[OHϪ ]. poison Verb: To inactivate a catalyst. polar covalent bond A covalent bond between atoms that have partial electric charges. Examples: HßCl; OßS. polarizability (␣) The ease with which the electron cloud of a molecule can be distorted. polarizable An easily polarized species. polarize To distort the electron cloud of an atom or ion. polarized light Plane-polarized light is light in which the wave motion occurs in a single plane. polarizing power The ability of an ion to polarize a neighboring atom or ion. polar molecule A molecule with a nonzero electric dipole moment. Examples: HCl; NH3. polyamide A polymer in which the monomers are linked by amide bonds formed by condensation. polyatomic ion An ion in which more than two atoms are linked by covalent bonds. Examples: NH4 ϩ ; NO3 Ϫ ; SiF6 2Ϫ . polyatomic molecule A molecule that consists of more than two atoms. Examples: O3; C12H22O11. polycyclic compound An aromatic compound containing two or more benzene rings that share two neighboring carbon atoms. Example: naphthalene. polydentate ligand A ligand that can attach at several binding sites. B22 GLOSSARY polyester A polymer in which the monomers are linked by ester groups formed by condensation polymerization. polymer A substance with large molecules consisting of chains of covalently linked repeating units formed from small molecules known as monomers. Examples: polyethylene; nylon. See also copolymer. polymerization The formation of a polymer from its monomers. polynucleotide A polymer built from nucleotide units. Examples: DNA; RNA. polypeptide A polymer formed by the condensation of amino acids. polyprotic acid or base A Brønsted acid or base that can donate or accept more than one proton. (A polyprotic acid is sometimes called a polybasic acid.) Examples: H3PO4, triprotic acid; N2H4, diprotic base. polysaccharide A chain of many saccharide units, such as glucose, linked together. Examples: cellulose; amylose. p-orbital See atomic orbital. positional disorder Disorderly locations of molecules; a contribution to the entropy. positive ion An ion formed by loss of one or more electrons from an atom or molecule; a cation. positron A fundamental particle with the same mass as an electron but with opposite charge. positron emission A mode of radioactive decay in which a nucleus emits a positron. potential difference An electrical potential difference between two points is a measure of the work that must be done to move an electric charge from one point to the other. Potential difference is measured in volts, V, and is commonly called the voltage. potential energy (Ep) The energy arising from position. Example: the Coulomb potential energy of a charge is inversely proportional to its distance from another charge. potential energy surface A surface showing the variation of the potential energy with the relative location of the atoms in a polyatomic cluster of atoms (as in a collision between a diatomic molecule and an atom). power The rate of supply of energy. The SI unit of power is the watt, W (1 W ϭ 1 JиsϪ1 ). See also Appendix 1B. precipitate The solid formed in a precipitation reaction. precipitation The process in which a solute comes out of solution rapidly as a finely divided powder, called a precipitate. A precipitation reaction is a reaction in which a precipitate is formed when two solutions are mixed. Example: KBr(aq) ϩ AgNO3(aq) →KNO3(aq) ϩ AgBr(s). precise measurements (1) Measurements with a large number of significant figures. (2) A series of measurements with small random error and hence in close mutual agreement. precision Freedom from random error. Compare with accuracy. pre-equilibrium condition A pre-equilibrium arises (or is assumed) when an intermediate is formed in a rapid equilibrium reaction prior to a slow step in a reaction mechanism. pre-exponential factor (A) The constant obtained from the y intercept in an Arrhenius plot. pressure (P) Force divided by the area to which it is applied. primary alcohol See alcohol. primary cell A galvanic cell that produces electricity from chemicals sealed within it at the time of manufacture. It cannot be recharged. primary pollutant A pollutant directly introduced into the environment. Example: SO2. primary structure The sequence of amino acids in the polypeptide chain of a protein. primitive cubic structure A structure in which the unit cell consists of spheres (representing atoms or ions) at the corners of a cube. principal quantum number (n) The quantum number that specifies the energy of an electron in a hydrogen atom and labels the shells of the atom. probability density (of a particle) A function that, when multiplied by the volume of the region, gives the probability that the particle will be found in that region of space. See also Born interpretation. product A species formed in a chemical reaction. promotion (of an electron) The conceptual excitation of an electron to an orbital of higher energy in the description of bond formation. propagation A series of steps in a chain reaction in which one chain carrier reacts with a reactant molecule to produce another carrier. Examples: Brи ϩ H2 → HBr ϩ Hи; Hи ϩ Br2 → HBr ϩ Brи. See also chain reaction. property A characteristic of matter. Examples: vapor pressure; color; density; temperature. See also chemical property; physical property. protective oxide An oxide that protects a metal from further oxidation. Example: aluminum oxide. proton (p) A positively charged subatomic particle found in the nucleus of an atom. protonation Proton transfer to a Brønsted base. Example: H3Oϩ (aq) ϩ HSϪ (s) → H2S(g) ϩ H2O(l). proton emission A nuclear decay process in which a proton is emitted. In proton emission, the mass and charge numbers of the nucleus both decrease by 1. proton-rich nucleus A nucleus that has a low proportion of neutrons and lies below the band of stability. proton transfer equilibrium The equilibrium involving the transfer of a hydrogen ion between an acid and a base. proton transfer reaction See proton transfer equilibrium. pseudo-first-order reaction A reaction with a rate law that is effectively first order because all but one species have virtually constant concentrations. p-type semiconductor See semiconductor. pX The quantity Ϫlog X. Example: pOH ϭ Ϫlog [OHϪ ]. pyrometallurgical process The extraction of metals by using reactions at high temperatures. Example: Fe2O3(s) ϩ 3 CO(g) ⌬ B 2 Fe(l) ϩ 3 CO2(g). quadratic equation An equation of the form ax2 ϩ bx ϩ c ϭ 0. See also Appendix 1E. qualitative A nonnumerical description of the properties of a substance, system, or process. See qualitative analysis. qualitative analysis The identification of the substances present in a sample. quanta The plural of quantum. GLOSSARY B23 quantitative A numerical description of the properties of a substance, system, or process. See quantitative analysis. quantitative analysis The determination of the amount of each substance present in a sample. quantization The restriction of a property to certain values. Examples: the quantization of energy and angular momentum. quantum A packet of energy. quantum dot A small three-dimensional cluster of semiconducting materials. Example: 10 to 105 atoms of Cd and Se (as cadmium selenide, CdSe). quantum mechanics The description of matter that takes into account the wave–particle duality of matter and the fact that the energy of an object may be changed only in discrete steps. quantum number An integer (sometimes, a half-integer) that labels a wavefunction and specifies the value of a property. Example: principal quantum number, n. quaternary ammonium ion An ion of the form NR4 ϩ , where R denotes hydrogen or an alkyl group (the four groups may be different). quaternary structure The manner in which neighboring polypeptide units stack together to form a protein molecule. racemic mixture A mixture containing equal amounts of two enantiomers. rad A (non-SI) unit of absorbed dose of radiation; 1 rad corresponds to an energy deposit of 10Ϫ2 JиkgϪ1 . See also gray. radial distribution function The function that gives the probability that an electron in an atom will be found at a particular radius regardless of the direction. radial wavefunction (R(r)) The radial part of a wavefunction, particularly the radial component of the wavefunctions of the hydrogen atom; the probability amplitude of an electron as a function of distance from the nucleus. radiation absorbed dose (rad) The amount of radiation that deposits 10Ϫ2 J of energy per kilogram of tissue. radical An atom, molecule, or ion with at least one unpaired electron. Examples: иNO; иOи; иCH3. radical chain reaction A chain reaction propagated by radicals. radical polymerization A polymerization procedure that utilizes a radical chain reaction. radical scavenger A substance that reacts with radicals and inhibits a chain reaction. radioactive A nucleus is radioactive if it can change its structure spontaneously and emit radiation. radioactive series A step-by-step nuclear decay path in which ␣ and ␤ particles are successively ejected and which terminates at a stable nuclide (often a nuclide of lead). radioactivity The spontaneous emission of radiation by nuclei. Such nuclei are radioactive. radiocarbon dating Isotopic dating based specifically on the use of carbon-14. radioisotope A radioactive isotope. radius ratio The ratio of the radius of the smaller ion in an ionic solid to the radius of the larger ion. The radius ratio controls which crystal structure is adopted by a simple ionic solid. random copolymer See copolymer. random error An error that varies randomly from measurement to measurement, sometimes giving a high value and sometimes a low one. Raoult’s law The vapor pressure of a liquid solution of a nonvolatile solute is directly proportional to the mole fraction of the solvent in the solution: P ϭ xsolventPpure, where Ppure is the vapor pressure of the pure solvent. rate The change in a property divided by the time interval. rate constant (k) The constant of proportionality in a rate law. rate-determining step The elementary reaction that governs the rate of the overall reaction. Example: the step O ϩ O3 → O2 ϩ O2 in the decomposition of ozone. rate law An equation expressing the instantaneous reaction rate in terms of the concentrations, at any instant, of the substances taking part in the reaction. Example: rate ϭ k[NO2]2 . rate of reaction See instantaneous rate; reaction rate. reactant A species acting as a starting material in a chemical reaction; a reagent taking part in a specified reaction. reaction enthalpy (⌬H) The change of enthalpy for the reaction as expressed by the chemical equation, with stoichiometric coefficients interpreted as the amounts in moles. Example: CH4(g) ϩ 2 O2(g) → CO2(g) ϩ 2 H2O(l), ⌬H ϭ Ϫ890 kJ. reaction Gibbs free energy (⌬G) The change in Gibbs free energy for the reaction as expressed by the chemical equation with stoichiometric coefficients interpreted as amounts in moles. reaction intermediate A species that is produced and consumed during a reaction but does not appear in the overall chemical equation. reaction mechanism The pathway that is proposed for an overall reaction and accounts for the experimental rate law. reaction order See order of reaction. reaction profile The variation in potential energy as two reactants meet, form an activated complex, and separate as products. reaction quotient (Q) The ratio of the activities of the products to those of the reactants, each raised to a power equal to the stoichiometric coefficient (as in the definition of the equilibrium constant, but at an arbitrary stage of a reaction). Example: for N2(g) ϩ3 H2(g) → 2 NH3(g), Q ϭ ( )2 / ( )3 . reaction rate The unique rate of a chemical reaction calculated by dividing the change in concentration of a substance by the interval during which the change takes place and by taking into account the stoichiometric coefficient of the substance. See also unique average reaction rate. reaction sequence A series of reactions in which the products of one reaction take part as reactants in the next. Example: 2 C(s) ϩ O2(g) → 2 CO(g), followed by 2 CO(g) ϩ O2(g) → 2 CO2(g). reaction stoichiometry The quantitative relation between the amounts of reactants consumed and those of products formed in chemical reactions as expressed by the balanced chemical equation for the reaction. reagent A substance or a solution that reacts with other substances. PH2 PN2 PNH3 B24 GLOSSARY real gas An actual gas; a gas that differs from an ideal gas in its behavior. recrystallization Purification by repeated dissolving and crystallization. redox couple The oxidized and reduced forms of a substance taking part in a reduction or oxidation halfreaction. The notation is oxidized species/reduced species. Example: Hϩ /H2. redox indicator See indicator. redox reaction A reaction in which oxidation and reduction take place. Example: S(s) ϩ 3 F2(g) → SF6(g). redox titration See titration. reducing agent The species that supplies electrons to a substance being reduced (and is itself oxidized) in a redox reaction. Examples: H2; H2S; SO3 2Ϫ . reduction (1) The removal of oxygen from, or the addition of hydrogen to, a compound. (2) A reaction in which an atom, ion, or molecule gains an electron. (3) A halfreaction in which the oxidation number of an element is decreased. Example: Cl2(g) ϩ 2 eϪ → 2 ClϪ (aq). re-forming reaction A reaction in which a hydrocarbon is converted into carbon monoxide and hydrogen over a nickel catalyst. refractory Able to withstand high temperatures. relative biological effectiveness (Q) A factor used when assessing the damage caused by a given dose of radiation. rem See roentgen equivalent man. repeating unit The combination of atoms in a polymer that repeats over and over again in the polymer chain. residual entropy The nonzero entropy at T ϭ 0 in certain systems, which is due to a surviving disorder in the orientation of molecules. residue (biochemical) An amino acid in a polypeptide chain. resistance (electrical) A measure of the ability of matter to conduct electricity: the lower the resistance, the better it conducts. resonance A blending of Lewis structures into a single composite, hybrid structure. Example: O¥A ≈SAßO¥Aa · aO¥AßSA≈O¥A resonance hybrid The composite structure that results from resonance. reverse osmosis The passage of solvent out of a solution when a pressure greater than the osmotic pressure is applied on the solution side of a semipermeable membrane. reversible isothermal expansion Expansion at constant temperature against an external pressure matched to the pressure of the system. reversible process A process that can be reversed by an infinitesimal change in a variable. rock-salt structure A crystal structure the same as that of a mineral form of sodium chloride. roentgen equivalent man (rem) The (non-SI) unit for reporting dose equivalent. See also sievert. root mean square speed (vrms) The square root of the average valueof thesquaresof thespeedsof themoleculesinasample. roots (of an equation) The solutions of the equation f(x) ϭ 0. See also Appendix 1E. rotational kinetic energy See kinetic energy. rounding off The adjustment of a numerical result to the correct number of significant figures. Rydberg constant (R ) The constant in the formula for the frequencies of the lines in the spectrum of atomic hydrogen; R ϭ 3.290 ϫ 1015 Hz. sacrificial anode A metal electrode that is allowed to decay in order to protect a metallic artifact. See cathodic protection. saline hydride See hydride. salt (1) An ionic compound. (2) The ionic product of the reaction between an acid and a base. Examples: NaCl; K2SO4. salt bridge An inverted U-shaped tube containing a concentrated salt (potassium chloride or potassium nitrate) in a gel that acts as an electrolyte and provides a conducting path between two compartments of an electrochemical cell. sample A representative part of a whole. saturated Unable to take up further material. saturated hydrocarbon A hydrocarbon with no carbon–carbon multiple bonds. Example: CH3CH3. saturated solution A solution in which the dissolved and undissolved solute are in dynamic equilibrium. Schrödinger equation An equation for calculating the wavefunction of a particle, especially for an electron in an atom or molecule. See also wavefunction. science The systematically collected and organized body of knowledge based on experiment, observation, and careful reasoning. scientific method A set of procedures employed to develop a scientific understanding of nature. scientific notation The expression of numbers in the form n.nnn . . . ϫ 10a . scintillation counter A device for detecting and measuring radioactivity that makes use of the fact that certain substances give a flash of light when they are exposed to radiation. sea of instability A region in a graph of mass number against atomic number corresponding to unstable nuclei that decay spontaneously with the emission of radiation. See also band of stability. second (s) The SI unit of time. See also Appendix 1B. secondary alcohol See alcohol. secondary cell A galvanic cell that must be charged (or recharged) by using an externally supplied current before it can be used. secondary pollutant A pollutant formed by the chemical reaction of another species in the environment. Example: SO3 from the oxidation of SO2. secondary structure The manner in which a polypeptide chain is coiled. Examples: ␣ helix; ␤ sheet. second derivative (d2 y/dx2 ) A measure of the curvature of a function. See also Appendix 1F. second ionization energy (I2) The energy needed to remove an electron from a singly charged gas-phase cation. Example: Cuϩ (g) → Cu2ϩ (g) ϩ eϪ (g), I2 ϭ 1958 kJиmolϪ1 . second law of thermodynamics A spontaneous change is accompanied by an increase in the total entropy of the system and its surroundings. second-order reaction (1) A reaction with a rate that is proportional to the square of the molar concentration of a reactant. (2) A reaction with an overall order of 2. GLOSSARY B25 second virial coefficient (B) See virial equation. selective precipitation The precipitation of one compound in the presence of other, more soluble compounds. self-sustaining fission Induced nuclear fission that, once it is initiated, can continue even if the supply of neutrons from outside is discontinued. semiconductor An electronic conductor with a resistance that decreases as the temperature is raised. In an n-type semiconductor, the current is carried by electrons in a largely empty band; in a p-type semiconductor, the conduction is a result of electrons missing from otherwise filled bands. semi-empirical method The calculation of molecular structure that draws on experimental information to simplify the procedure. Compare with ab initio method. semipermeable membrane A membrane that allows only certain types of molecules or ions to pass. sequester Form a complex between a cation and a bulky molecule or ion that enwraps the central ion. Example: Ca2ϩ and O3POPO2OPO3 3Ϫ . series (in spectroscopy) A family of spectral lines arising from transitions that have one state in common. Example: the Balmer series in the spectrum of atomic hydrogen. shell All the orbitals of a given principal quantum number. Example: the single 2s- and three 2p-orbitals of the shell with n ϭ 2. shielding The repulsion experienced by an electron in an atom that arises from the other electrons present and opposes the attraction exerted by the nucleus. shift reaction A reaction between carbon monoxide and water: CO(g) ϩ H2O(g) → CO2(g) ϩ H2(g); the reaction is used in the manufacture of hydrogen. short-range order Atoms or molecules lying in a regular arrangement that does not extend very far past their nearest neighbors. SI (Système International) The International System of units; a collection of definitions of units and symbols and their deployment. It is an extension and rationalization of the metric system. See also Appendix 1B. side chain A hydrocarbon substituent on a hydrocarbon chain. sievert (Sv) The SI unit of dose equivalent: 1 Sv ϭ 1 JиkgϪ1 . sigma (␴) bond Two electrons in a cylindrically symmetrical cloud between two atoms. sigma (␴) orbital A molecular orbital that has no nodal plane containing the internuclear axis. significant figures (sf, in a measurement) The digits in the measurement, up to and including the first uncertain digit in scientific notation. Example: 0.0260 mL (that is, 2.60 ϫ 10Ϫ2 mL), a measurement with three significant figures (3 sf). single bond A shared electron pair. skeletal equation An unbalanced equation that summarizes the qualitative information about the reaction. Example: H2 ϩ O2 → H2O. slip plane A layer of atoms in a solid that may slide relatively easily across a neighboring layer. slope(of graph) Thegradientof agraph.SeealsoAppendix1E. smectic phase A liquid-crystal phase in which molecules lie parallel to one another and form layers. soft matter Matter that deforms readily when subjected to an applied force. sol A colloidal dispersion of solid particles in a liquid. solid A rigid form of matter that maintains the same shape whatever the shape of its container. solid electrolyte A solid ionic conductor. solid emulsion A colloidal dispersion of a liquid in a solid. Example: butter, an emulsion of water in butterfat. solid solution A solid homogeneous mixture of two or more substances. solubility The concentration of a saturated solution of a substance. solubility constant See solubility product. solubility product (Ksp) The product of ionic molar concentrations in a saturated solution; the dissolution equilibrium constant. Example: Hg2Cl2(s) T Hg2 2ϩ (aq) ϩ 2 ClϪ (aq), Ksp ϭ [Hg2 2ϩ ][ClϪ ]2 . solubility rules A summary of the solubility pattern of a range of common compounds in water. See also Table I.1. soluble substance A substance that dissolves to a significant extent in a specified solvent. When the solvent is not specified, water is generally meant. solute A dissolved substance. solution A homogeneous mixture. See also solute; solvent. solvated Surrounded by and linked to solvent molecules. Hydration is the special case in which the solvent is water. solvent (1) The most abundant component of a solution. (2) The component of a solution in which the other components are considered to be dissolved. solvent extraction A process for separating a mixture of substances that makes use of their differing solubilities in various solvents. s-orbital See atomic orbital. space-filling model A depiction of a molecule in which atoms are represented by spheres that indicate the space occupied by each atom. sp3 dn hybrid orbital A hybrid orbital formed from one s-orbital, three p-orbitals, and n d-orbitals. species An atom, ion, or molecule. specific enthalpy (of a fuel) The enthalpy of combustion per gram (without the negative sign). specific heat capacity The heat capacity of a sample divided by its mass. spectator ion An ion that is present but remains unchanged duringareaction.Examples:Naϩ andNO3 Ϫ inNaCl(aq)ϩ AgNO3(aq) → NaNO3(aq) ϩ AgCl(s). spectral line Radiation of a single wavelength emitted or absorbed by an atom or molecule. spectrochemical series Ligands ordered according to the strength of the ligand field splitting that they produce. spectrometer An instrument for recording the spectrum of a sample. spectrophotometer An instrument for measuring and recording electronically the intensity of radiation passing through a sample as the wavelength of the radiation is changed and hence recording the spectrum of the sample. spectroscopy The analysis of the electromagnetic radiation emitted, absorbed, or scattered by substances. spectrum The frequencies or wavelengths of the electromagnetic radiation emitted, absorbed, or scattered by substances. B26 GLOSSARY speed The magnitude of the velocity; the rate of change of position. sphalerite structure See zinc-blende structure. spherically symmetrical Independent of orientation about a central point. spherical polar coordinates The coordinates of a point expressed in terms of the radius r, the colatitude ␪, and the azimuth ␾. spn hybrid orbital A hybrid orbital constructed from an s-orbital and n p-orbitals. There are two sp hybrid orbitals, three sp2 hybrid orbitals, and four sp3 hybrid orbitals. spin The intrinsic angular momentum of an electron; the spin cannot be eliminated and can occur in only two senses, denoted ↑ and ↓ or ␣ and ␤. spin magnetic quantum number (ms) The quantum number that distinguishes the two spin states of an electron: ms ϭ (↑) and ms ϭ (↓). spontaneous change A natural change, one that has a tendency to occur without needing to be driven by an external influence. Examples: a gas expanding into a vacuum; a hot object cooling; methane burning. spontaneous neutron emission The decay of neutron-rich nuclei by the emission of neutrons without an external stimulus to do so. spontaneous nuclear fission See fission. square planar complex A complex in which four ligands lie at the corners of a square with the metal atom at the center. stability constant See formation constant. stable See thermodynamically stable compound. standard ambient temperature and pressure (SATP) 25°C (298.15 K) and 1 bar. standard cell potential (Ecell°) The cell potential when the concentration of each solute taking part in the cell reaction is 1 mol·L–1 (strictly, unit activity) and all the gases are at 1 bar. The standard cell potential of a galvanic cell is the difference between its two standard potentials: Ecell° ϭ E°(cathode) – E°(anode). standard emf See standard cell potential. standard enthalpy of combustion (⌬Hc°) The change of enthalpy per mole of substance when it burns (reacts with oxygen) completely under standard conditions. standard enthalpy of formation (⌬Hf°) The standard reaction enthalpy per mole of compound for the compound’s synthesis from its elements in their most stable form at 1 bar and the specified temperature. standard entropy of fusion (⌬Sfus°) The standard entropy change per mole accompanying fusion (the conversion of a substance from the solid state into the liquid state). standard entropy of vaporization (⌬Svap°) The standard entropy change per mole accompanying vaporization (the conversion of a substance from the liquid state into the vapor state). standard Gibbs free energy of formation (⌬Gf°) The standard reaction Gibbs free energy per mole for the formation of a compound from its elements in their most stable form. standard Gibbs free energy of fusion (⌬Gfus°) The standard Gibbs free energy change per mole accompanying fusion (the conversion of a substance from the solid state into the liquid state). -1 2+1 2 standard Gibbs free energy of reaction (⌬G°) The Gibbs free energy of reaction under standard conditions. standard Gibbs free energy of vaporization (⌬Gvap°) The standard Gibbs free energy change per mole accompanying vaporization (the conversion of a substance from the liquid state into the vapor state). standard hydrogen electrode (SHE) A hydrogen electrode that is in its standard state (hydrogen ions at concentration 1 mol·L–1 (strictly, unit activity) and hydrogen pressure 1 bar) and is defined as having E° ϭ 0 at all temperatures. standard molar entropy (Sm°) The entropy per mole of a pure substance at 1 bar. standard potential (E°) (1) The contribution of an electrode to the standard emf of a cell. (2) The standard emf of a cell when the left-hand electrode is a standard hydrogen electrode and the right-hand electrode is the electrode of interest. standard pressure (P°) A pressure of 1 bar exactly. standard reaction enthalpy (⌬H°) The reaction enthalpy under standard conditions. standard reaction entropy (⌬S°) The reaction entropy under standard conditions. standard state The pure form of a substance at 1 bar; for a solute, the concentration 1 molиLϪ1 . standard temperature and pressure (STP) 0°C (273.15 K) and 1 atm (101.325 kPa). standing wave A wave stable over time; a wave with peaks and troughs that do not migrate with time. state function A property of a substance that is independent of how the sample was prepared. Examples: pressure; enthalpy; entropy; color. state of matter The physical condition of a sample. The most common states of a pure substance are solid, liquid, or gas (vapor). state property See state function. state symbol A symbol (abbreviation) denoting the state of a species. Examples: s (solid); l (liquid); g (gas); aq (aqueous solution). statistical entropy The entropy calculated from statistical thermodynamics; S ϭ k ln W. statistical thermodynamics The interpretation of the laws of thermodynamics in terms of the behavior of large numbers of atoms and molecules. steady-state approximation The assumption that the net rate of formation of reaction intermediates is 0. Stefan–Boltzmann law The total intensity of radiation emitted by a heated black body is proportional to the fourth power of the absolute temperature. stereoisomers Isomers in which atoms have the same partners arranged differently in space. stereoregular polymer A polymer in which each unit or pair of repeating units has the same relative orientation. steric factor (P) An empirical factor that takes into account the steric requirement of a reaction. steric requirement A constraint on an elementary reaction in which the successful collision of two molecules depends on their relative orientation. Stern–Gerlach experiment The demonstration of the quantization of electron spin by passing a beam of atoms through a magnetic field. stick structure See line structure. GLOSSARY B27 stock solution A solution stored in concentrated form. stoichiometric coefficients The numbers multiplying chemical formulas in a chemical equation. Examples: 1, 1, and 2 in H2 ϩ Br2 → 2 HBr. stoichiometricpoint Thestageinatitrationwhenexactlythe right volume of solution needed to complete the reaction has been added. stoichiometric proportions Reactants in the same proportions as their coefficients in the chemical equation. Example: equal amounts of H2 and Br2 in the formation of HBr. stoichiometric relation An expression that equates the relative amounts of reactants and products that participate in a reaction. Example: 1 mol H2 ϴ 2 mol HBr for H2 ϩ Br2 → 2 HBr. stoichiometry See reaction stoichiometry. stopped-flow technique A procedure for observing fast reactions, involving the spectrometric analysis of a reaction mixture immediately after the rapid injection of reactants into a mixing chamber. STP See standard temperature and pressure. strong acids and bases Acids and bases that are fully deprotonated or protonated, respectively, in solution. Examples: HCl, HClO4 (strong acids); NaOH, Ca(OH)2 (strong bases). strong electrolyte See electrolyte. strong-field ligand A ligand that produces a large ligand field splitting and lies above H2O in the spectrochemical series. strong force A short-range but very strong force that acts between nucleons and binds them together to form a nucleus. structural formula A chemical formula that shows how atoms in a compound are attached to one another. See also condensed structural formula. structural isomers Isomers in which the atoms have different partners. subatomic particle A particle smaller than an atom. Examples: electron; proton; neutron. subcritical Having a mass less than the critical mass. sublimation The direct conversion of a solid into a vapor without first forming a liquid. sublimation vapor pressure The vapor pressure of a solid. subshell All the atomic orbitals of a given shell of an atom that have the same value of the quantum number l. Example: the five 3d-orbitals of an atom. substance A single, pure type of matter; either a compound or an element. substituent An atom or group that has replaced a hydrogen atom in an organic molecule. substitutional alloy See alloy. substitution reaction (1) A reaction in which an atom (or a group of atoms) replaces an atom in the original molecule. (2) In complexes, a reaction in which one Lewis base expels another and takes its place. Examples: (1) C6H5OH ϩ Br2 → BrC6H4OH ϩ HBr; (2) [Fe(OH2)6]3ϩ (aq) ϩ 6 CNϪ (aq) → [Fe(CN)6]3– (aq) ϩ 6 H2O(l). substrate The chemical species on which an enzyme acts. superconductor An electronic conductor that conducts electricity with zero resistance. See also high-temperature superconductor. supercooled Refers to a liquid cooled to below its freezing point but not yet frozen. supercritical Having a mass greater than the critical mass. supercritical fluid A fluid phase of a substance above its critical temperature and critical pressure. superfluidity The ability to flow without viscosity. superimpose The combination of atomic orbitals to form a molecular orbital. surface-active agent See surfactant. surface tension (␥) The tendency of molecules at the surface of a liquid to be pulled inward, resulting in a smooth surface. surfactant A substance that accumulates at the surface of a solution and affects the surface tension of the solvent; a component of detergents. Example: the stearate ion of soaps. surroundings The region outside a system, where observations are made. suspension A mist of small particles in a fluid medium. sustainable development The economical utilization and renewal of resources coupled with hazardous waste reduction and concern for the environment. symbolic level The discussion of chemical phenomena in terms of chemical symbols and mathematical equations. synthesis A reaction in which a substance is formed from simpler starting materials. Example: N2(g) ϩ 3 H2(g) → 2 NH3(g). synthesis gas A mixture of carbon monoxide and hydrogen produced by the catalyzed reaction of a hydrocarbon and water. system The object of study, usually a reaction vessel and its contents. An open system can exchange both matter and energy with the surroundings. A closed system has a fixed amount of matter but can exchange energy with the surroundings. An isolated system has no contact with its surroundings. systematic error An error that persists in a series of measurements and does not average out. See also accuracy. systematic name The name of a compound that reveals which elements are present (and, in its most complete form, how the atoms are arranged). Example: methylbenzene is the systematic name for toluene. Système International d’Unités See SI. temperature (T) (1) How hot or cold a sample is. (2) The intensive property that determines the direction in which heat will flow between two objects in contact. temperature–composition diagram A phase diagram showing how the normal boiling point of a liquid mixture varies with composition. template synthesis A process in which nanostructures are formed by laying down atoms on a pre-existing substrate. termination A step in a chain reaction in which chain carriers combine to form products. Example: Brи ϩ Brи → Br2. termolecular reaction An elementary reaction in which three species collide simultaneously. tertiary alcohol See alcohol. tertiary structure The shape into which the ␣-helical and ␤-sheet sections of a polypeptide are twisted as a result of interactions between peptide groups lying in different parts of the primary structure. B28 GLOSSARY tetrahedral complex A complex in which four ligands lie at the corners of a regular tetrahedron with a metal atom at the center. Example: [Cu(NH3)4]2ϩ . tetrahedral hole A cavity in a (usually close-packed) crystal structure formed by one sphere lying in the dip formed by three others. theoretical chemistry The study of molecular structure and properties in terms of mathematical models. theoretical yield The maximum quantity of product that can be obtained, according to the reaction stoichiometry, from a given quantity of a specified reactant. theory A collection of ideas and concepts used to account for a scientific law. thermal decomposition See decomposition. thermal disorder The disorder arising from the thermal motion of molecules. thermal energy The sum of the potential and kinetic energies due to thermal motion. thermal equilibrium The state in which a system is at the same temperature as its surroundings. thermal motion The random, chaotic motion of atoms. thermal pollution The damage caused to the environment by the waste heat of an industrial process. thermite reaction (thermite process) The reduction of a metal oxide by aluminum. Example: 2 Al(s) ϩ Fe2O3(s) → Al2O3(s) ϩ 2 Fe(l). thermochemical equation An expression consisting of the balanced chemical equation and the corresponding reaction enthalpy. thermochemistry The study of the heat released or absorbed by chemical reactions; a branch of thermodynamics. thermodynamically stable compound (1) A compound with no thermodynamic tendency to decompose into its elements. (2) A compound with a negative Gibbs free energy of formation. thermodynamically unstable compound (1) A compound with a thermodynamic tendency to decompose into its elements. (2) A compound with a positive Gibbs free energy of formation. thermodynamics The study of the transformations of energy from one form to another. See also first law of thermodynamics; second law of thermodynamics, third law of thermodynamics. thermonuclear explosion An explosion resulting from uncontrolled nuclear fusion. thermoplastic polymer A polymer that can be softened by heating after it has been molded. thermosetting polymer A polymer that takes on a permanent shape in a mold and does not soften on heating. thermotropic liquid crystal A liquid crystal prepared by melting the solid phase. third law of thermodynamics The entropies of all perfect crystals are the same at the absolute zero of temperature. third virial coefficient See virial equation. three-center bond A chemical bond in which a hydrogen atom lies between two other atoms (typically boron atoms) and one electron pair binds all three atoms together. tie line (in a temperature–composition phase diagram) A line joining the point indicating the boiling point of a mixture of given composition with the corresponding composition of the vapor at that temperature. titrant The solution of known concentration added from a buret in a titration. titration The analysis of composition by measuring the volume of one solution needed to react with a given volume of another solution. In an acid–base titration, an acid is titrated with a base; in a redox titration, an oxidizing agent is titrated with a reducing agent. t-orbital One of the orbitals dxy, dyz, and dzx in an octahedral or tetrahedral complex. In an octahedral complex, these orbitals are designated t2g. torr (symbol: Torr) A unit of pressure: 760 Torr ϭ 1 atm exactly. total energy See energy. tracer An isotope that can be tracked from compound to compound in the course of a sequence of reactions. trajectory The path of a particle on which location and linear momentum are specified at each instant. transition A change of state. (1) In thermodynamics, a change of physical state. (2) In spectroscopy, a change of quantum state. transition metal An element that belongs to Groups 3 through 11. Examples: vanadium; iron; gold. transition state See activated complex. transition state theory A theory of reaction rates in which the reactants form an activated complex. translational kinetic energy See kinetic energy. transmeitnerium elements The elements beyond meitnerium; those with Z Ͼ 109. transmutation See nuclear transmutation. transuranium elements The elements beyond uranium; those with Z Ͼ 92. triboluminescence Luminescence that results from mechanical shock to a crystal. triple bond (1) Three electron pairs shared by two neighboring atoms. (2) One ␴-bond and two ␲-bonds between neighboring atoms. triple point The point where three phase boundaries meet in a phase diagram. Under the conditions represented by the triple point, all three adjoining phases coexist in dynamic equilibrium. triprotic See polyprotic acid or base. Trouton’s rule The empirical observation that the entropy of vaporization at the boiling point (the enthalpy of vaporization divided by the boiling temperature) is approximately 85 JиKϪ1 ·mol–1 for many liquids. tube structure A representation of molecular structure that uses tubes to indicate the lengths and distances of bonds. The ends of each tube are colored to indicate the identities of the elements forming the bond. ultraviolet catastrophe The classical prediction that any black body at any temperature should emit intense ultraviolet radiation. ultraviolet radiation Electromagnetic radiation with a higher frequency (shorter wavelength) than that of violet light. unbranched alkane An alkane with no side chains, in which all the carbon atoms lie in a linear chain. uncertainty principle See Heisenberg uncertainty principle. GLOSSARY B29 unimolecular reaction An elementary reaction in which a single reactant molecule changes into products. Example: O3 → O2 ϩ O. unique average reaction rate The rate of change in the concentration of a reactant or product divided by its stoichiometric coefficient in the balanced equation. All unique average rates are reported as positive quantities. See also average reaction rate. unit See base units. unit cell The smallest unit that, when stacked together repeatedly without any gaps, can reproduce an entire crystal. universe (in thermodynamics) The system and its surroundings. unsaturated hydrocarbon A hydrocarbon with at least one carbon–carbon multiple bond. Examples: CH2≈CH2; C6H6. valence The number of bonds that an atom can form. valence band In the theory of solids, a band of energy levels fully occupied by electrons. valence-bond theory The description of bond formation in terms of the pairing of spins in the atomic orbitals of neighboring atoms. valence electrons The electrons that belong to the valence shell. valence shell The outermost shell of an atom. Example: the n ϭ 2 shell of Period 2 atoms. valence-shell electron-pair repulsion model (VSEPR model) A model for predicting the shapes of molecules, using the fact that electron pairs repel one another. van der Waals equation An approximate equation of state for a real gas in which two parameters represent the effects of intermolecular forces. van der Waals interactions Intermolecular interactions that depend on the inverse sixth power of the separation. See intermolecular forces. van der Waals parameters The experimentally determined coefficients that appear in the van der Waals equation and are unique for each real gas. The parameter a is an indication of the strength of attractive intermolecular forces, and the parameter b is an indication of the strength of repulsive intermolecular forces. See also van der Waals equation. van der Waals radius Half the distance between the centers of nonbonded, touching atoms in a solid. van ’t Hoff equation (1) The equation for the osmotic pressure in terms of the molarity, ⌸ ϭ i[J]RT. (2) An equation that shows how the equilibrium constant varies with temperature. van ’t Hoff i factor See i factor. vapor The gaseous phase of a substance (specifically, of a substance that is a liquid or solid at the temperature in question). See also gas. vaporization The formation of a gas or a vapor from a liquid. vapor-phase synthesis A process in which a substance is vaporized and then condensed or mixed with a reactant and the condensed product forms tiny crystals. vapor pressure The pressure exerted by the vapor of a liquid (or a solid) when the vapor and the liquid (or solid) are in dynamic equilibrium. variable covalence The ability of an element to form different numbers of covalent bonds. Example: S in SO2 and SO3. variable valence The ability of an element to form ions with different charges. Example: Inϩ and In3ϩ . velocity The rate of change of position. vibrational kinetic energy See kinetic energy. virial equation An equation of state expressed in powers of 1/Vm: specifically, PV ϭ nRT(1 ϩ B/Vm ϩ C/Vm 2 ϩ . . .), where B is the second virial coefficient and C is the third virial coefficient. viscosity The resistance of a fluid (a gas or a liquid) to flow: the higher the viscosity, the slower the flow. visible light See visible radiation. visible radiation Electromagnetic radiation that can be detected by the human eye, with wavelengths in the range from 700 nm to 400 nm. Visible radiation is also called visible light or simply light. volatile Having a high vapor pressure at ordinary temperatures. A substance is typically regarded as volatile if its boiling point is below 100°C. volatility The readiness with which a substance vaporizes. See also volatile. volt (V) The SI unit of electrical potential. See also Appendix 1B. voltaic cell See electrochemical cell. volume (V) The amount of space that a sample occupies. volumetric analysis An analytical method using measurement of volume, as in a titration. volumetric flask A flask calibrated to contain a specified volume. water autoprotolysis constant (Kw) The equilibrium constant for the autoprotolysis (autoionization) of water, 2 H2O(l) T H3Oϩ (aq) ϩ OH– (aq), Kw ϭ [H3Oϩ ][OHϪ ]. water of hydration See hydration. water-splitting reaction The photochemical decomposition of water into hydrogen and oxygen. wavefunction (␺) A solution of the Schrödinger equation; the probability amplitude. wavelength (␭) The peak-to-peak distance of a wave. wave–particle duality The combined wavelike and particlelike character of both radiation and matter. weak acids and bases Acids and bases that are only incompletely deprotonated or protonated, respectively (commonly, in aqueous solution) at normal concentrations. Examples: HF, CH3COOH (weak acids); NH3, CH3NH2 (weak bases). weak electrolyte See electrolyte. weak-field ligand A ligand that produces a small ligand field splitting and that lies below NH3 in the spectrochemical series. Wien’s law The wavelength corresponding to the maximum in the radiation emitted by a heated black body is inversely proportional to the absolute temperature. work (w) The energy expended during the act of moving an object against an opposing force. In expansion work, the B30 GLOSSARY system expands against an opposing pressure; nonexpansion work is work that does not arise from a change in volume. work function (⌽) The energy required to remove an electron from a metal. x-ray Electromagnetic radiation with wavelengths from about 10 pm to about 1000 pm. x-ray diffraction The analysis of crystal structures by studying the interference pattern in a beam of x-rays. yield See percentage yield; theoretical yield. zeolite A microporous aluminosilicate. zero-order reaction A reaction with a rate that is independent of the concentration of the reactant. Example: the catalyzed decomposition of ammonia. zero-point energy The lowest possible energy of a system. Example: E ϭ h2 /8mL2 for a particle of mass m in a box of length L. Ziegler–Natta catalyst A stereospecific catalyst for polymerization reactions, consisting of titanium tetrachloride and triethylaluminum. zinc-blende structure A crystal structure in which the cations occupy half the tetrahedral holes in a nearly closepacked cubic lattice of anions; also known as sphalerite structure. zone refining A method for purifying a solid by repeatedly passing a molten zone along the length of a sample. zwitterion A form of an amino acid in which in which the amino group is protonated and the carboxyl group is deprotonated. Example: ϩ H3NCH2CO2 Ϫ . C1 Self-Tests B Fundamentals A.1B 250. g ϫ 1.000 lb/453.6 g ϫ 16 oz/1 lb ϭ 8.82 oz A.2B 9.81 m·s–2 ϫ 1 km/103 m ϫ (3600 s/1 h)2 ϭ 1.27 ϫ 105 kmиhϪ2 A.3B V ϭ m/d ϭ (10.0 g)/(0.17685 gиLϪ1 ) ϭ 56.5 L A.4B Ek ϭ mv2 /2 ϭ 1 ͞2 ϫ (1.5 kg) ϫ (3.0 mиsϪ1 )2 ϭ 6.8 J A.5B Ek ϭ mgh ϭ (0.350 kg) ϫ (9.81 mиsϪ2 ) ϫ (443 m) ϫ (10Ϫ3 kJ/J) ϭ 1.52 kJ B.1B number of Au atoms ϭ m(sample)/m(one atom) ϭ (0.0123 kg)/ (3.27 ϫ 10Ϫ25 kg) ϭ 3.76 ϫ 1022 Au atoms B.2B (a) 8, 8, 8; (b) 92, 144, 92 C.1B (a) Potassium is a Group 1 metal. Cation, ϩ1, so Kϩ . (b) Sulfur is a nonmetal in Group 16/VI. Anion, 16 Ϫ 18 ϭ Ϫ2, so S2Ϫ . C.2B (a) Li3N; (b) SrBr2 D.1B (a) dihydrogen arsenate; (b) ClO3 Ϫ D.2B (a) gold(III) chloride; (b) calcium sulfide; (c) manganese(III) oxide D.3B (a) phosphorus trichloride; (b) sulfur trioxide; (c) hydrobromic acid D.4B (a) Cs2Sи4H2O; (b) Mn2O7; (c) HCN; (d) S2Cl2 D.5B (a) pentane; (b) carboxylic acid E.1B atoms of H ϭ (3.14 mol H2O) ϫ (2 mol H )/(1 mol H2O) ϫ (6.022 ϫ 1023 atoms/mol) ϭ 3.78 ϫ 1024 H atoms E.2B (a) n ϭ m/M ϭ (5.4 ϫ 103 g)/(26.98 gиmolϪ1 ) ϭ 2.0 ϫ 102 mol; (b) N ϭ NA ϫ n ϭ (6.022 ϫ 1023 Al atoms/mol) ϫ (2.0 ϫ 102 mol) ϭ 1.2 ϫ 1026 Al atoms E.3B copper-63: (62.94 gиmolϪ1 ) ϫ 0.6917 ϭ 43.536 gиmolϪ1 ; copper-65: (64.93 gиmolϪ1 ) ϫ 0.3083 ϭ 20.018 gиmolϪ1 ; 43.536 gиmolϪ1 ϩ 20.018 gиmolϪ1 ϭ 63.55 gиmolϪ1 E.4B (a) phenol: 6 C, 6 H, 1 O; 6(12.01 gиmolϪ1 ) ϩ 6(1.008 gиmolϪ1 ) ϩ (16.00 gиmolϪ1 ) ϭ 94.11 gиmolϪ1 ;(b) Na2CO3и10H2O: 2 Na, 1 C, 13 O, 20 H; 2(22.99 gиmolϪ1 ) ϩ (12.01 gиmolϪ1 ) ϩ 13(16.00 gиmolϪ1 ) ϩ 20(1.008 gиmolϪ1 ) ϭ 286.15 gиmolϪ1 E.5B Ca(OH)2: 1 Ca, 2 O, 2 H; (40.08 gиmolϪ1 ) ϩ 2(16.00 gиmolϪ1 ) ϩ 2(1.008 gиmolϪ1 ) ϭ 74.10 gиmolϪ1 ; (1.00 ϫ 103 g lime)/(74.10 gиmolϪ1 ) ϭ 13.5 mol formula units of lime E.6B CH3COOH: 2 C, 4 H, 2 O; 2(12.01 gиmolϪ1 ) ϩ 4(1.008 gиmolϪ1 ) ϩ 2(16.00 gиmolϪ1 ) ϭ 60.05 gиmolϪ1 ; (60.05 gиmolϪ1 )(1.5 mol) ϭ 90. g F.1B % C ϭ (6.61 g/7.50 g) ϫ 100% ϭ 88.1%; % H ϭ (0.89 g/7.50 g) ϫ 100% ϭ 11.9% F.2B AgNO3: (107.87 gиmolϪ1 ) ϩ (14.01 gиmolϪ1 ) ϩ 3 (16.00 gиmolϪ1 ) ϭ 169.88 gиmolϪ1 ; % Ag ϭ (107.87 gиmolϪ1 )/ (169.88 gиmolϪ1 ) ϫ 100% ϭ 63.498% F.3B carbon: 0.778 ϫ (100 g eucalyptol) ϭ 77.8 g C; (77.8 g C)/ (12.01 gиmolϪ1 ) ϭ 6.48 mol C; hydrogen: (11.8 g H)/(1.0079 gиmolϪ1 ) ϭ 11.7 mol H; oxygen: (10.4 g O)/(16.00 gиmolϪ1 ) ϭ 0.650 mol O; 6.48 C:11.7 H:0.650 O F.4B n(O) ϭ (18.59 g)/(16.00 gиmolϪ1 ) ϭ 1.162 mol O; n(S) ϭ (37.25 g)/(32.07 gиmolϪ1 ) ϭ 1.162 mol; n(F) ϭ (44.16 g)/(19.00 gиmolϪ1 ) ϭ 2.324 mol. 1:1:2 ratio, formula is SOF2. F.5B M(CHO2) ϭ 45.012 gиmolϪ1 . (90.0 gиmolϪ1 )/(45.012 gиmolϪ1 ) ϭ 2.00; 2 ϫ (CHO2) ϭ C2H2O4 G.1B M(Na2SO4) ϭ 142.05 gиmolϪ1 . (15.5 g)/(142.05 gиmolϪ1 ) ϭ 0.109 mol; (0.109 mol)/(0.350 L) ϭ 0.312 M Na2SO4(aq) G.2B (0.125 molиLϪ1 ) ϫ (0.05000 L) ϭ 0.00625 mol oxalic acid. M(oxalic acid) ϭ 90.036 gиmolϪ1 . (0.00625 mol) ϫ (90.036 gиmolϪ1 ) ϭ 0.563 g oxalic acid G.3B (2.55 ϫ 10Ϫ3 mol HCl)/(0.358 mol HCl/L) ϭ 7.12 ϫ 10Ϫ3 L ϭ 7.12 mL G.4B Vinit ϭ (cfinal ϫ Vfinal)/cinit ϭ (1.59 ϫ 10Ϫ5 molиLϪ1 ) ϫ (0.02500 L)/(0.152 molиLϪ1 ) ϭ 2.62 ϫ 10Ϫ3 mL H.1B Mg3N2(s) ϩ 4 H2SO4(aq) : 3 MgSO4(aq) ϩ (NH4)2SO4(aq) I.1B (a) molecular compound and not an acid, so a nonelectrolyte, does not conduct electricity; (b) ionic compound, so a strong electrolyte, conducts electricity I.2B 3 Hg2 2ϩ (aq) ϩ 2 PO4 3Ϫ (aq) : (Hg2)3(PO4)2(s) I.3B SrCl2 and Na2SO4; Sr2ϩ (aq) ϩ SO4 2Ϫ (aq) : SrSO4(s) J.1B (a) is neither an acid nor a base; (b) and (c) are acids; (d) supplies the base OHϪ J.2B 3 Ca(OH)2(aq) ϩ 2 H3PO4(aq) : Ca3(PO4)2(s) ϩ 6 H2O K.1B Cuϩ (aq) is oxidized, I2(s) is reduced. K.2B (a) x ϩ 3(Ϫ2) ϭ Ϫ2; x ϭ ϩ4 for S; (b) x ϩ 2(Ϫ2) ϭ Ϫ1; x ϭ ϩ3 for N; (c) x ϩ 1 ϩ 3(Ϫ2) ϭ 0; x ϭ ϩ5 for Cl K.3B H2SO4 is the oxidizing agent (S is reduced from ϩ6 to ϩ4); NaI is the reducing agent (I is oxidized from Ϫ1 to ϩ5). K.4B 2 Ce4ϩ (aq) ϩ 2 IϪ (aq) : 2 Ce3ϩ (aq) ϩ I2(s) L.1B (2 mol Fe)/(1 mol Fe2O3) ϫ 25 mol Fe2O3 ϭ 50. mol Fe L.2B 2 mol CO2/1 mol CaSiO3; mol CO2 ϭ (3.00 ϫ 102 g)/ (44.01 gиmolϪ1 ) ϭ 6.82 mol; (1 mol CaSiO3/2 mol CO2) ϫ (6.82 mol CO2) ϭ 3.41 mol CaSiO3; (3.41 mol CaSiO3) ϫ (116.17 gиmolϪ1 CaSiO3) ϭ 396 g CaSiO3 L.3B 2 KOH ϩ H2SO4 : K2SO4 ϩ 2 H2O; 2 mol KOH 1 mol H2SO4; (0.255 mol KOHиLϪ1 ) ϫ (0.025 L) ϭ 6.375 ϫ 10Ϫ3 mol KOH. (6.375 ϫ 10Ϫ3 mol KOH) ϫ (1 mol H2SO4)/(2 mol KOH) ϭ 3.19 ϫ 10Ϫ3 mol H2SO4; (3.19 ϫ 10Ϫ3 mol H2SO4)/ (0.01645 L) ϭ 0.194 M H2SO4 L.4B (0.100 ϫ 0.02815) mol KMnO4 ϫ (5 mol As4O6)/ (8 mol KMnO4) ϫ 395.28 gиmolϪ1 ϭ 6.96 ϫ 10Ϫ2 g As4O6 M.1B 2 Fe2O3(s) : 4 Fe(s) ϩ 3 O2(g); (15 kg Fe2O3)/159.69 gиmolϪ1 ) ϫ (2 mol Fe)/(1 mol Fe2O3) ϫ (55.85 gиmolϪ1 ) ϭ 10.5 kg Fe; 8.8 kg/10.5 kg ϫ 100% ϭ 84% yield M.2B 2 NH3 ϩ CO2 : OC(NH2)2 ϩ H2O; n(NH3) ϭ (14.5 ϫ 103 g)/ (17.034 gиmolϪ1 ) ϭ 851 mol NH3; n(CO2) ϭ (22.1 ϫ 103 g)/ (44.01 gиmolϪ1 ) ϭ 502 mol CO2; 2 mol NH3 1 mol CO2; (a) NH3 is the limiting reactant. (851 mol NH3/2) Ͻ (502 mol CO2). (b) 2 mol NH3/1 mol urea. 426 mol, or 25.6 kg of urea can be produced. (c) (502 Ϫ 426) mol ϭ 76 mol CO2 excess ϭ 3.3 kg CO2 M.3B 3 NO2(g) ϩ H2O(l) : 2 HNO3(l) ϩ NO(g). There is 0.61 mol NO2 and 1.0 mol H2O. 1 mol H2O 3 mol NO2; therefore, there is not enough NO2, so NO2 is the limiting reactant. 22 g, or 0.35 mol HNO3, were produced. Theoretical yield is (0.61 mol NO2) ϫ (2 mol HNO3)/(3 mol NO2) ϭ 0.407 mol HNO3. Percentage yield ϭ (0.35 mol)/(0.407 mol) ϫ 100% ϭ 86%. M.4B The sample contains 0.0118 mol C (0.142 g C) and 0.0105 mol H (0.0106 g H). Mass of O ϭ 0.236 Ϫ (0.142 ϩ 0.0105)g ϭ 0.0834 g O (0.00521 mol O). The C:H:O mole ratios are 0.0118:0.0105:0.00521, or 2.26:2.02:1. Multiplying these numbers by 4 gives 9:8:4 and the empirical formula C9H8O4. Chapter 1 1.1B ␭ ϭ c/␯ ϭ (2.998 ϫ 108 mиsϪ1 )/(98.4 ϫ 106 Hz) ϭ 3.05 m 1.2B ␯ ϭ R(1/22 Ϫ 1/52 ) ϭ 21R/100; ␭ ϭ c/␯ ϭ 100c/21R ϭ (100 ϫ 2.998 ϫ 108 mиsϪ1 )/(21 ϫ 3.29 ϫ 1015 sϪ1 ) ϭ 434 nm; violet line 1.3B T ϭ constant/␭max ϭ (2.9 ϫ 10Ϫ3 mиK)/(700. ϫ 10Ϫ9 m) ϭ 4.1 ϫ 103 K 1.4B E ϭ h␯ ϭ (6.626 ϫ 10Ϫ34 Jиs) ϫ (4.8 ϫ 1014 Hz) ϭ 3.2 ϫ 10Ϫ19 J ϴ ϴ ϴ ANSWERS C2 ANSWERS 3.9B Carbon atom of CH3 group is sp3 hybridized and forms four ␴ bonds at 109.5°. The other two carbon atoms are both sp2 hybridized and each forms three ␴ bonds and one ␲ bond; bond angles are about 120°. 3.10B O2 ϩ : ␴2s 2 ␴2s *2 ␴2p 2 ␲2p 4 ␲2p *1 ; BO ϭ (8 Ϫ 3)/2 ϭ 2.5 3.11B CNϪ : 1␴2 2␴*2 1␲4 3␴2 Chapter 4 4.1B h ϭ P/dg ϭ (1.01 ϫ 105 kgиmϪ1 иsϪ2 )/[(998 kgиmϪ3 ) ϫ (9.80665 mиsϪ2 )] ϭ 10.3 m 4.2B P ϭ (10. cmHg) ϫ (10 mmHg)/(1 cmHg) ϫ (1.01325 ϫ 105 Pa)/ (760 mmHg) ϭ 1.3 ϫ 104 Pa 4.3B (630. Torr) ϫ (133.3 Pa/1 Torr) ϭ 8.40 ϫ 104 Pa or 84.0 kPa 4.4B V2 ϭ P1V1/P2 ϭ (1.00 bar) ϫ (750. L)/(5.00 bar) ϭ 150. L 4.5B P2 ϭ P1T2/T1 ϭ (760. mmHg) ϫ (573 K)/(293 K) ϭ 1.49 ϫ 103 mmHg 4.6B P2 ϭ P1n2/n1 ϭ (1.20 atm) ϫ (300. mol)/(200. mol) ϭ 1.80 atm 4.7B V/min ϭ (n/min) ϫ (RT)/P ϭ (1.00 mol/min) ϫ (8.206 ϫ 10Ϫ2 LиatmиKϪ1 иmolϪ1 ) ϫ (300. K)/(1.00 atm) ϭ 24.6 LиminϪ1 4.8B V2 ϭ P1V1/P2 ϭ (1.00 atm) ϫ (80. cm3 )/(3.20 atm) ϭ 25 cm3 4.9B P2 ϭ P1V1T2/V2T1 ϭ [(1.00 atm) ϫ (250. L) ϫ (243 K)]/ [(800. L) ϫ (293 K)] ϭ 0.259 atm 4.10B n ϭ (1 mol He/4.003 g He) ϫ (2.0 g He) ϭ 0.50 mol He; V ϭ nRT/P ϭ (0.50 mol) ϫ (24.47 L molϪ1 ) ϭ 12 L 4.11B M ϭ dRT/P ϭ (1.04 gиLϪ1 ) ϫ (62.364 LиTorrиKϪ1 иmolϪ1 ) ϫ (450. K)/(200. Torr) ϭ 146 gиmolϪ1 4.12B 2 H2(g) ϩ O2(g) : 2 H2O(l), and so 2 mol H2O ϴ 1 mol O2; n(O2) ϭ PV/RT ϭ [(1.00 atm) ϫ (100.0 L)]/ [(8.206 ϫ 10Ϫ2 LиatmиKϪ1 иmolϪ1 ) ϫ (298 K)] ϭ 4.09 mol O2. n(H2O) ϭ 2(4.09 mol O2) ϭ 8.18 mol H2O; m(H2O) ϭ (8.18 mol H2O) ϫ (18.02 gиmolϪ1 ) ϭ 147 g H2O 4.13B 2 H2O(l) :2 H2(g) ϩ O2(g); (2 mol H2/3 mol gas molecules) ϫ (720. Torr) ϭ 480. Torr H2; (1 mol O2/3 mol gas molecules) ϫ (720. Torr) ϭ 240. Torr H2 4.14B n(O2) ϭ (141.2 g O2)/(32.00 gиmolϪ1 ) ϭ 4.412 mol O2; n(Ne) ϭ (335.0 g Ne)/(20.18 gиmolϪ1 ) ϭ 16.60 mol Ne; ϭ (4.412 mol O2/21.01 mol total) ϫ (50.0 atm) ϭ 10.5 atm 4.15B (10. s) ϫ [(16.04 gиmolϪ1 )/(4.00 gиmolϪ1 )]1/2 ϭ 20. s 4.16B vrms ϭ (3RT/M)1/2 ϭ [3 ϫ (8.3145 JиKϪ1 иmolϪ1 ) ϫ (298 K)/ (16.04 ϫ 10Ϫ3 kgиmolϪ1 )]1/2 ϭ 681 mиsϪ1 4.17B P ϭ [nRT/(V Ϫ nb)] Ϫ an2 /V2 ϭ [{20. mol CO2 ϫ (8.206 ϫ 10Ϫ2 LиatmиKϪ1 иmolϪ1 )ϫ(293K)}/{100. Ϫ(20. ϫ4.29ϫ10Ϫ2 LиmolϪ1 )}] Ϫ {3.610 L2 иatmиmolϪ2 ϫ (20.)2 }/(100.)2 ϭ 4.7 atm Chapter 5 5.1B 1,1-dichloroethane, because it has a dipole moment 5.2B Unlike CF4, CHF3 has a net dipole moment. The resulting dipole–dipole interactions account for the higher boiling point of CHF3 even though one might expect the CF4 molecule (with more electrons) to exhibit stronger London interactions. 5.3B (a) CH3OH and (c) HClO 5.4B 8(1/8) ϩ 2(1/2) ϩ 2(1) ϭ 4 atoms 5.5B dfcc ϭ (4M)/(83/2 NAr 3 ) ϭ (4 ϫ 55.85 gиmolϪ1 )/{83/2 ϫ (6.022 ϫ 1023 molϪ1 ) ϫ (1.24 ϫ 10Ϫ8 cm)3 } ϭ 8.60 gиcmϪ3 ; dbcc ϭ (33/2 M)/(32NAr3 ) ϭ (33/2 ϫ 55.85 gиmolϪ1 )/{32 ϫ (6.022 ϫ 1023 molϪ1 ) ϫ (1.24 ϫ 10Ϫ8 cm)3 } ϭ 7.90 gиcmϪ3 . The observed density is closer to that predicted for a body-centered cubic structure. 5.6B ␳ ϭ (100 pm)/(184 pm) ϭ 0.54, rock-salt structure 5.7B ␳ ϭ (167 pm)/(220 pm) ϭ 0.76, cesium chloride structure; (132.91 + 126.90) gиmol-1 (6.022 * 1023 mol-1 )a 7.74 * 10-8 cm 31/2 b 3 = 4.83 gиcm-3 d = M NAa b 31/2 b 3 = PO2 1.5B (a) Ek ϭ 1/2 ϫ (9.109 ϫ 10Ϫ31 kg) ϫ (7.85 ϫ 105 mиsϪ1 )2 ϭ 2.81 ϫ 10Ϫ19 J; (b) 3.63 eV ϫ (1.602 ϫ 10Ϫ19 JиeVϪ1 ) ϭ 5.82 ϫ 10Ϫ19 J, ␭ ϭ [(3.00 ϫ 108 mиsϪ1 ) ϫ (6.626 ϫ 10Ϫ34 Jиs)]/(5.82 ϫ 10Ϫ19 J) ϭ 342 nm 1.6B ␭ ϭ h/m␯ ϭ (6.626 ϫ 10Ϫ34 Jиs)/(0.0050 kg ϫ 2 ϫ 331 mиsϪ1 ) ϭ 2.0 ϫ 10Ϫ34 m 1.7B ⌬␯ ϭ /2m⌬x ϭ (1.05457 ϫ 10Ϫ34 J)/(2 ϫ 2.0 t ϫ 103 kgиtϪ1 ϫ 1 m) ϭ 3 ϫ 10Ϫ38 mиsϪ1 1.8B E3 Ϫ E2 ϭ 5h2 /8meL2 ϭ h␯; ␯ ϭ 5h/8meL2 ; ␭ ϭ c/␯ ϭ 8mecL2 /5h ϭ [8 ϫ (9.10939 ϫ 10Ϫ31 kg) ϫ (2.998 ϫ 108 mиsϪ1 ) ϫ (1.50 ϫ 10Ϫ10 m)2 ]/(5 ϫ 6.626 ϫ 10Ϫ34 Jиs) ϭ 14.8 ϫ 10Ϫ9 m, or 14.8 nm 1.9B ratio ϭ (eϪ6a0/a0/␲a0 3 )/(1/␲a0 3 ) ϭ eϪ6 ϭ 0.0025 1.10B 3p 1.11B 1s2 2s2 2p6 3s2 3p1 or [Ne]3s2 3p1 1.12B [Ar]3d10 4s2 4p3 1.13B (a) r(Ca2ϩ ) Ͻ r(Kϩ ); (b) r(ClϪ ) Ͻ r(S2Ϫ ) 1.14B In the third ionization of Be, the electron is removed from the noble-gas core, but in the third ionization of B, the electron is removed from the valence shell. Core electrons are closer to the nucleus, so greater amounts of energy are required to remove them. 1.15B In fluorine (Group 17), an additional electron fills the single vacancy in the valence shell; the shell now has the noble-gas configuration of neon and is complete. In neon, an additional electron would have to enter a new shell, where it would be farther from the attraction of the nucleus. Chapter 2 2.1B (a) [Ar]3d5 ; (b) [Xe]4f14 5d10 2.2B IϪ , [Kr]4d10 5s2 5p6 2.3B KCl, because ClϪ has a smaller radius than BrϪ 2.4B ; H has no lone pairs, Br has 3 lone pairs. 2.5B 2.6B 2.7B 2.8B 2.9B 2.10B ; 10 electrons 2.11B 2.12B (a) CO2 2.13B CaS Chapter 3 3.1B trigonal planar 3.2B (a) trigonal planar; (b) angular 3.3B (a) AX2E2; (b) tetrahedral; (c) angular 3.4B square planar 3.5B (a) nonpolar; (b) polar 3.6B (a) 3 ␴, no ␲; (b) 2 ␴, 2 ␲ 3.7B Three ␴ bonds formed from two C2sp hybrids, one bond between the two C atoms and two connecting each C atom to an H atom in a linear arrangement; two ␲ bonds, one between the two C2px-orbitals and the other between the two C2py-orbitals. 3.8B (a) octahedral; (b) square planar; (c) sp3 d2 O O ® ¥ ¥ O ¥¥ ¥ ¥ £ 0 ϩ1 Ϫ1 I I® ® ¥ ¥ I ¥ ¥¥ ¥ ¥ 2 @ Ϫ O N£ß ¥ ¥ ¥ ¥ ¥ O Ϫ¥ F O® ® ¥ ¥ F ¥ ¥ ¥ ¥ ¥ ¥ 0 0 0 O N® ¥ ¥ O ¥¥ ¥ ¥ £ ƒ † © ¥ Ϫ O N ® ¥ ¥ O ¥¥ ¥ ¥ £ ƒ † © ¥ Ϫ MÍßßm H H HN® ® ® ¥ å H N ¥ å H H HN® ® ¥ å H® Br ¥ ¥ ¥ h SELF-TESTS B C3 Major Technique 3 MT3.1B d ϭ (152 pm)/(2 sin 12.1°) ϭ 363 pm Chapter 6 6.1B 4.7 ϫ 10Ϫ19 J 6.2B d(brass)͞d(Cu) ϭ 6.3B 6.4B xAg ϭ 0.63, xNi ϭ 0.37 (from Figure 6.8); m(Ag) ϭ 1.0 mol mixture ϫ m(Ni) ϭ 1.0 mol mixture ϫ mass% (Ag) ϭ 68 g͞(68 ϩ 22)g ϫ 100 ϭ 76%; mass% (Ni) ϭ 22 g͞(68 ϩ 22) g ϫ 100 ϭ 24% 6.5B (a) {(710 nm ϫ 1 cm/107 nm) ϫ (10 cm) ϫ (0.5 mm ϫ 1 cm/ 10 mm)} ϫ (2.27 gиcmϪ3 ) ϭ 8 ϫ 10Ϫ5 g; (8 ϫ 10Ϫ5 g)/(12.01 gиmolϪ1 ) ϭ 7 ϫ 10Ϫ6 mol; (b) (1.3 ϫ 10Ϫ6 mol) ϫ (6.022 ϫ 1023 atomsиmolϪ1 ) ϭ 4 ϫ 1018 atoms 6.6B 1.0 cm3 diamond ϫ 1.6 cm3 ; (1 ϩ x)3 ϭ 6.7B 1.0 kg hydrate ϫ 6.8B (a) sp2 ; (b) sp3 6.9B separation ϭ 2.25 m Ϫ 2.22 m ϭ 0.03 m, or 30. cm 6.10B SiO2(s) ϩ OHϪ (aq) : HSiO3 Ϫ (aq) 6.11B 10. kg SiO2 ϫ ϫ 9.10939 * 10-31 kg 1 e- * 103 g e- 1 kg e- = 0.27 g 103 g SiO2 1 kg SiO2 * 1 mol SiO2 60.09 g SiO2 * 30 mol e- 1 mol SiO2 * 6.022 * 1023 e- 1 mol e- 1 s 109 ns : 2.25 : 108 m 1 s = 2.25 m; 0.222 m; dred = 1.0 ns : dblue = 1.0 ns * 1 s 109 ns * 2.22 * 108 m 1 s = = 2.998 * 108 m # s-1 1.33 = 2.25 * 108 m # s-1 ;c¿ red = c nx c¿ blue = c nx = 2.998 * 108 mиs-1 1.35 = 2.22 * 108 mиs-1 ; 18.02 g water 1 mol water * 1 kg water 103 g water = 0.24 kg 103 g hydrate 1 kg hydrate * 1 mol hydrate 228.33 g hydrate * 18 mol water 6 mol hydrate * 1.6 cm3 , x = +0.170 cm 3.51 g diamond 1 cm3 diamond * 1 cm3 graphite 2.27 g graphite = 0.37 mol Ni 1.0 mol mixture * 58.69g Ni 1 mol Ni = 22 g Ni; 0.63 mol Ag 1.0 mol mixture * 107.87 g Ag 1 mol Ag = 68 g Ag; * 1 mol O2 1 mol C * 32.00 g O2 1 mol O2 * 1 kg 103 g = 93 kg 1 mol C 12.01 g C 1.0t * 106 g pig iron 1t * (4.5 - 1.0)g C removed 100 g pig iron * 0.5000 * 65.41 g # mol-1 + 0.5000 * 63.55 g # mol-1 63.55 g # mol-1 = 1.015 E = ch ␭ = (2.998 * 108 mиs-1 ) * (6.626 * 10-34 Jиs) 4.20 * 10-7 m = 6.12B 6.13B 6.14B p-type 6.15B In chemiluminescence, light is emitted as the result of molecules being excited during a chemical reaction. In phosphorescence, light is emitted when molecules remain excited after the stimulus has ceased. 6.16B (a) (b) 165 ϫ (207.2 ϩ 78.96) gиmolϪ1 ϫ (1 kg)/(1000 g) ϭ 47.2 kgиmolϪ1 (c) ϭ 1.48 mm Chapter 7 7.1B w ϭ ϪP⌬V ϭ Ϫ(9.60 atm) ϫ (2.2 L Ϫ 0.22 L) ϫ (101.325 JиLϪ1 иatmϪ1 ) ϭ Ϫ1926 J ϭ Ϫ1.9 kJ 7.2B w ϭ ϪP⌬V ϭ Ϫ(1.00 atm) ϫ (4.00 L Ϫ 2.00 L) ϫ 101.325 JиLϪ1 иatmϪ1 ϭ Ϫ202 J; w ϭ ϪnRT ln(Vfinal/Vinitial) ϭ Ϫ(1.00 mol) ϫ (8.3145 JиKϪ1 иmolϪ1 ) ϫ (303 K) ϫ ln(4.00 L/2.00 L) ϭ Ϫ1.75 kJ; isothermal reversible expansion does more work 7.3B q ϭ nCm⌬T ϭ (3.00 mol) ϫ (111 JиKϪ1 иmolϪ1 ) ϫ [15°C ϫ (1 K/1°C)] ϭ 5.0 kJ 7.4B 7.5B w ϭ ⌬U Ϫ q ϭ Ϫ150 J Ϫ (ϩ300 J) ϭ Ϫ450 J; w Ͻ 0 (the system did work) 7.6B q ϭ ϩ1.00 kJ; w ϭ Ϫ(2.00 atm) ϫ (3.00 L Ϫ 1.00 L) Ϫ (101.325 JиLϪ1 иatmϪ1 ) ϭ Ϫ405 J; ⌬U ϭ q ϩ w ϭ 1.00 kJ ϩ (Ϫ0.405 kJ) ϭ ϩ0.60 kJ 7.7B (a) ⌬H ϭ ϩ30 kJ; (b) ⌬U ϭ q ϩ w ϭ 30 kJ ϩ 40 kJ ϭ ϩ70 kJ 7.8B (a) 57.7 K, Tf ϭ 298 K ϩ 57.7 K ϭ 356 K; ⌬U ϭ q ϩ w ϭ 1.20 kJ ϩ 0 ϭ 1.20 kJ (b) (step 1) constant volume, find final temperature: 41.2 K; ¢T = q nCP = 1.20 kJ * 1000 J 1 kJ 1.00 mol * a 7 2 * 8.3145 Lиatmиmol-1 иK-1 b = ¢T = q nCV = 1.20 kJ * 1000 J 1 kJ 1.00 mol * a 5 2 * 8.3145 Lиatmиmol-1 иK-1 b = Ccal = qcal ¢T = 4.16 kJ 3.24°C = 1.28 kJ # (°C)-1 2 : a 3 : (6.626 : 10-34 Jиs) : (601 * 10-9 m) 8 : (9.109 * 10-31 kg) : (2.998 * 108 mиs-1 ) b 1/2 = d = 2r = 2 : a 3hl 8mec b 1/2 3.6 : 10-6 mol # L-11 2 * 6.0 mL : 103 mL 1 L = 1 q.d. 165 f.u. * 1 mol q.d. 6.022 * 1023 q.d. * 6.022 * 1023 f.u. 1 mol PbSe : 6.0 mL * 1 L 103 mL * 0.0012 mol Pb2+ 1 L * 1 mol PbSe 1 mol Pb2+ * 1 orbital 2 valence e- = 2.5 * 107 1.0 cm * 1012 pm 102 cm * 1 Ca atom (2 * 197 pm) * 2 valence e- 1 Ca atom * = 5 * 103 S-1 * 1Æ 1 S-1 = 5 * 103 Æ R = l A * k = 0.10 mm * 1 m 103 mm a1.0 cm2 * 1 m2 (100 cm)2 b a0.2 mSиm-1 * 1 S 103 mS b C4 ANSWERS Tf ϭ 298 K ϩ 41.2 K ϭ 339 K; ⌬U ϭ q ϩ w ϭ q ϩ 0, so ⌬U ϭ q ϭ nCV⌬T ϭ (1 mol) ϫ (5/2) ϫ (8.3145 JиmolϪ1 иKϪ1 ) ϫ (41.2 K) ϭ 856 J; (step 2) isothermal, ⌬T ϭ 0, so ⌬U ϭ 0; Therefore, after both steps, ⌬U ϭ ϩ856 J, Tf ϭ 339 K 7.9B 7.10B ⌬Hsub ϭ ⌬Hvap ϩ ⌬Hfus ϭ (38 ϩ 3) kJиmolϪ1 ϭ 41 kJиmolϪ1 7.11B qr ϭ Ϫqcal ϭ Ϫ(216 Jи°CϪ1 )(76.7 o C) ϭ Ϫ1.66 ϫ 103 J; Ϫ3.54 ϫ 103 kJ; C5H12(l) ϩ 8 O2(g) : 5 CO2(g) ϩ 6 H2O(l), ⌬H ϭ Ϫ3.54 ϫ 103 kJ 7.12B ⌬U ϭ ⌬H Ϫ ⌬ngasRT ϭ Ϫ3378 kJ Ϫ Ϫ3.37 ϫ 103 kJ 7.13B CH4(g) ϩ O2(g) : CH3OH(l), ⌬H° ϭ 206.10 kJ ϩ (Ϫ128.33 kJ) ϩ (Ϫ483.64 kJ) ϭ Ϫ164.05 kJ 7.14B 7.15B C(diamond) ϩ O2(g) : CO2(g); ⌬Hr° ϭ ⌬Hf°(CO2) Ϫ ⌬Hf° (C, diamond) Ϫ ⌬Hf° (O2,g) ϭ Ϫ393.51 kJиmolϪ1 Ϫ (ϩ1.895 kJиmolϪ1 ) Ϫ 0 kJиmolϪ1 ϭ Ϫ395.41 kJиmolϪ1 7.16B CO(NH2)2(s) ϩ O2(g) : CO2(g) ϩ 2 H2O(l) ϩ N2(g); ⌬Hr° ϭ ⌬Hf°(CO2) ϩ 2 ⌬Hf°(H2O) Ϫ ⌬Hf°(CO(NH2)2); Ϫ632 kJ ϭ Ϫ393.51 kJ ϩ 2(Ϫ285.83 kJ) Ϫ ⌬Hf°(CO(NH2)2); ⌬Hf°(CO(NH2)2) ϭ Ϫ333 kJиmolϪ1 7.17B [524.3 ϩ 147.70 ϩ 2(111.88) ϩ 736 ϩ 1451 Ϫ 2(325)] kJ Ϫ ⌬HL ϭ 0; ⌬HL ϭ ϩ2433 kJ 7.18B CH4(g) ϩ 2 F2(g) : CH2F2(g) ϩ 2 HF(g); bonds broken [2(CϪH), 2(FϪF)]: 2(412 kJиmolϪ1 ) ϩ 2(158 kJиmolϪ1 ) ϭ 1140 kJиmolϪ1 ; bonds formed [2(CϪF), 2(HϪF)]: 2(484 kJиmolϪ1 ) ϩ 2(565 kJиmolϪ1 ) ϭ 2098 kJиmolϪ1 ; ⌬H° ϭ 1140 kJиmolϪ1 Ϫ 2098 kJиmolϪ1 ϭ Ϫ958 kJиmolϪ1 7.19B ⌬Hr,523 K ϭ ⌬Hr,298 K ϩ ⌬Cp⌬T ϭ Ϫ365.56 kJиmolϪ1 ϩ (523 Ϫ 298) K ϭ Ϫ376 kJиmolϪ1 Chapter 8 8.1B ⌬S ϭ Ϫ50. J/1373 K ϭ Ϫ0.036 JиKϪ1 8.2B ⌬S ϭ (5.5 g)(0.51 JиKϪ1 иgϪ1 ) ln(373/293) ϭ ϩ0.68 JиKϪ1 8.3B ⌬S ϭ nR ln(V2/V1) ϭ (8.314 JиKϪ1 иmolϪ1 ) ln(10/1) ϭ ϩ19 JиKϪ1 иmolϪ1 8.4B ⌬S ϭ nR ln(P1/P2) ϭ 70.9 g ϫ (1 mol/70.9 g) ϫ (8.3145 JиmolϪ1 иKϪ1 ) ϫ ln(3.00 kPa/24.00 kPa) ϭ Ϫ17.3 JиKϪ1 8.5B (1) ⌬S ϭ (23.5 g)(1 mol/32.00 g)(8.3145 JиKϪ1 иmolϪ1 ) ϫ ln(2.00 kPa/8.00 kPa) ϭ Ϫ8.46 JиKϪ1 ; (2) ⌬S ϭ (23.5 g)(1 mol/32.00 g) (20.786 JиKϪ1 иmolϪ1 ) ϫ ln(360 K/240 K) ϭ ϩ6.19 JиKϪ1 ; ⌬S ϭ Ϫ8.46 ϩ 6.19 JиKϪ1 ϭ Ϫ2.27 JиKϪ1 8.6B 8.7B ⌬Hvap° ϭ (85 JиKϪ1 иmolϪ1 )(273.2 K ϩ 24.5 K) ϫ (1 kJ/103 J) ϭ 26.2 kJиmolϪ1 8.8B ⌬Sfus° ϭ ⌬Hfus°/Tf ϭ (10.59 ϫ 103 JиmolϪ1 )/(278.6 K) ϭ 38.01 JиKϪ1 иmolϪ1 ¢Svap° = ¢Hvap Tb = 40.7 kJ # mol-1 373.2 K * 103 J 1 kJ = 109 J # K-1 # mol-1 1 kJ 1000 J d JиK-1 иmol-1 *c a84.1 - 3 2 (29.36) - 2(28.82) - 29.12b 3 2 -350.kJ * 1 mol C2H5OH -1368 kJ * 46.07 g C2H5OH 1 mol C2H5OH = 11.8 g C2H5OH 1 2 1 2 a - 3 4 molb * a 8.3145 J molиK b : (1273 K) 1 * a 1 kJ 1000 J b = ¢Hr = -1.66 : 104 J 0.338 g * 72.15 g 1 mol * 1 kJ 1000 J = 22 kJ 23 g * 46.07 g 1 mol = 44 kJ # mol-1 8.9B ⌬S ϭ k lnW ϭ (1.38066 ϫ 10Ϫ23 JиKϪ1 )(1.0 mol)(6.022 ϫ 1023 molϪ1 ) ln(6) ϭ ϩ15 JиKϪ1 8.10B Nonzero entropy at T ϭ 0 indicates disorder. This disorder results when a molecule can orient itself more than one way in the crystal. In ice, each O atom is surrounded by four H atoms, of which there are two types. Two of the H atoms are covalently bonded to the O atom and the other two H atoms, which belong to neighboring water molecules, are interacting with the central O atom through hydrogen bonds. Thus, more than one orientation is possible in the crystal and entropy will not be zero at T ϭ 0. 8.11B (a) ⌬S ϭ Sgray Ϫ Swhite ϭ (44.14 Ϫ 51.55) JиKϪ1 иmolϪ1 ϭ Ϫ7.41 JиKϪ1 иmolϪ1 ; the gray form; (b) ⌬S ϭ Sgraphite Ϫ Sdiamond ϭ (5.7 Ϫ 2.4) JиKϪ1 иmolϪ1 ϭ ϩ3.3 JиKϪ1 иmolϪ1 ; diamond 8.12B positive, because a gas is produced from a solid 8.13B ⌬Sr o ϭ (229.60 Ϫ 219.56 Ϫ 130.68) JиKϪ1 ϭ Ϫ120.64 JиKϪ1 8.14B ⌬Ssurr ϭ Ϫ⌬H/T ϭ Ϫ(2.00 mol ϫ Ϫ46.11 kJиmolϪ1 )/298 K ϫ (103 J/1 kJ) ϭ ϩ309 JиKϪ1 8.15B ⌬Ssurr ϭ Ϫ⌬H/T ϭ Ϫ(49.0 kJ/298 K) ϫ (103 J/1 kJ) ϭ Ϫ164 JиKϪ1 ; ⌬Stot ϭ Ϫ164 JиKϪ1 ϩ (Ϫ253.18 JиKϪ1 ) ϭ Ϫ417 JиKϪ1 ; no 8.16B ⌬S ϭ nR ϫ ln(V2/V1) ϭ (2.00 mol) ϫ (8.3145 JиKϪ1 иmolϪ1 ) ϫ ln(0.200/4.00) ϭ Ϫ49.8 JиKϪ1 иmolϪ1 ; ⌬Ssurr ϭ ϩ49.8 JиKϪ1 иmolϪ1 ; ⌬Stot ϭ 0 8.17B ⌬Ssurr ϭ Ϫ⌬Hvap/T ϭ Ϫ(30.8 ϫ 103 JиmolϪ1 )/353.2 K ϭ Ϫ87.2 JиKϪ1 иmolϪ1 ; ⌬S ϭ ϩ87.2 JиKϪ1 ; ⌬Stot ϭ ⌬S ϩ ⌬Ssurr ϭ ϩ87.2 JиKϪ1 ϩ (Ϫ87.2 JиKϪ1 ) ϭ 0 at 353.2 K 8.18B Yes. ⌬G ϭ ⌬H Ϫ T⌬S. When ⌬S Ͼ 0, T⌬S Ͼ 0. Hence, as temperature increases, ϪT⌬S becomes more negative; eventually ⌬G Ͻ 0 and the process becomes spontaneous. 8.19B (a) ⌬Gm ϭ ⌬Hm Ϫ T⌬Sm ϭ 59.3 kJиmolϪ1 Ϫ (623 K) ϫ (0.0942 kJиKϪ1 иmolϪ1 ) ϭ ϩ0.6 kJиmolϪ1 ; vaporization is nonspontaneous; (b) ⌬Gm ϭ ⌬Hm Ϫ T⌬Sm ϭ 59.3 kJиmolϪ1 Ϫ (643 K) (0.0942 kJиKϪ1 иmolϪ1 ) ϭ Ϫ1.3 kJиmolϪ1 ; vaporization is spontaneous. 8.20B 3 H2 (g) ϩ 3 C (s, graphite) : C3H6 (g), ⌬Sr ϭ 237.4 JиKϪ1 иmolϪ1 Ϫ [3(130.68 JиKϪ1 иmolϪ1 ) ϩ 3(5.740 JиKϪ1 иmolϪ1 )] ϭ Ϫ171.86 JиKϪ1 иmolϪ1 , ⌬Gr ϭ ⌬Hr Ϫ T⌬Sr ϭ ϩ53.30 kJиmolϪ1 Ϫ (298 K)(Ϫ171.86 JиKϪ1 иmolϪ1 ) ϫ (1 kJ/103 J) ϭ ϩ104.5 kJиmolϪ1 8.21B From Appendix 2A, ⌬Gf°(CH3NH2, g) ϭ ϩ32.16 kJиmolϪ1 at 298 K. Because ⌬Gf° > 0, CH3NH2 is less stable than its elements at the stated conditions. 8.22B ⌬G ϭ [Ϫ910 ϩ (6 mol)(0)] ϫ [(6 mol)(Ϫ394.36) ϩ (6 mol)(Ϫ237.13)] ϭ ϩ2879 kJ 8.23B MgCO3(s) : MgO(s) ϩ CO2(g); ⌬H° ϭ Ϫ601.70 ϩ (Ϫ393.51) Ϫ (Ϫ1095.8) ϭ ϩ100.6 kJ; ⌬S° ϭ 26.94 ϩ 213.74 Ϫ 65.7 JиKϪ1 ϭ ϩ175.0 JиKϪ1 ; Chapter 9 9.1B CH3CH2CH3; molecules of the two substances have the same molar mass and thus the same number of electrons and comparable London forces. However, CH3CHO is polar and also experiences dipole–dipole forces. 9.2B P2 ϭ 142 Torr 9.3B T2 ϭ 339 K 9.4B The positive slope of the solidϪliquid boundary shows that monoclinic sulfur is more dense than liquid sulfur over the temperature range in which monoclinic sulfur is stable; the solid is more stable at high pressure. 9.5B Carbon dioxide is liquid at 60 atm and 25° C. When it is released into a room at 1 atm and 25° C, as the pressure decreases, the lna 760 Torr 400 Torr b = 35.3 * 103 J # mol-1 8.3145 J # mol-1 # K-1 a 1 323 K - 1 T2 b; lna P2 94.6 Torr b = 30.8 * 103 Jиmol-1 8.3145 Jиmol-1 иK-1 a 1 298 K - 1 308 K b; T = ¢H° ¢S° = 100.6 kJ 175.0 J # K-1 * 103 J 1 kJ = 574.9 K SELF-TESTS B C5 system reaches the liquidϪvapor boundary, at which pressure the liquid is changed to vapor. The vaporization absorbs sufficient heat to cool the CO2 to below its sublimation temperature at 1 atm. As a result, fine particles of solid CO2 “snow” are produced. 9.6B Critical temperature increases with the strength of intermolecular forces. For example, CH4 cannot form hydrogen bonds; so it has a lower critical temperature than either NH3 or H2O, which can form hydrogen bonds. 9.7B s ϭ (2.3 ϫ 10Ϫ2 molиLϪ1 иatmϪ1 )(1.00 atm) ϭ 2.3 ϫ 10Ϫ2 molиLϪ1 ; n(CO2) ϭ 0.900 L ϫ (2.3 ϫ 10Ϫ2 molиLϪ1 ) ϭ 0.021 mol 9.8B 0.300 molиkgϪ1 9.9B xH2O ϭ 1 Ϫ 0.250 ϭ 0.750; 0.750 mol H2O ϫ 18.02 gиmolϪ1 ϫ 1 kg/103 g ϭ 0.0135 kg; b(H2O) 9.10B Assume a 1 L solution; mNaCl ϭ 1 L ; mH2O ϭ 1070 g Ϫ 107 g ϭ 9.6 ϫ 103 g; 1.83 mol/0.96 kg ϭ 1.9 molиkgϪ1 9.11B P ϭ (0.986)(5.3 kPa) ϭ 5.2 kPa 9.12B ⌬Tf ϭ kfm ϭ (39.7 KиkgиmolϪ1 )(0.050 molиkgϪ1 ) ϭ 1.99 K ϭ 1.99°C; Tf ϭ 179.8°C Ϫ 1.99°C ϭ 177.8°C 9.13B i ϭ 1 since sucrose is a nonelectrolyte and does not dissociate; (1)(0.08206 LиatmиmolϪ1 иKϪ1 )(298 K) (0.120 molиLϪ1 ) ϭ 2.93 atm 9.14B b ϭ 0.51 K/39.7 kgиKиmolϪ1 ϭ 0.0128 molиkgϪ1 ; n(linalool) ϭ 0.100 kg ϫ (0.0128 mol/1 kg) ϭ 1.28 ϫ 10Ϫ3 mol; M ϭ 0.200 g/ (1.28 ϫ 10Ϫ3 mol) ϭ 156 gиmolϪ1 9.15B ϫ 0.175 L ϭ 1.52 ϫ 10Ϫ4 mol; 9.16B Equal masses; therefore, assume 50.00 g of each. Ptotal ϭ (0.5412) ϫ (94.6 Torr) ϩ (0.4588) ϫ (29.1 Torr) ϭ 64.5 Torr 9.17B (a) P ϭ (0.500)(94.6 Torr) ϩ (0.500)(29.1 Torr) ϭ 61.8 Torr; (b) 1 - 0.765 = 0.235 xC6H6,vap = (0.500) : (94.6 Torr) 61.8 Torr = 0.765; xC7H8,vap = xC7H8 = 0.5427 mol (0.6401 + 0.5427) mol = 0.4588; xC6H6 = 0.6401 mol (0.6401 + 0.5427) mol = 0.5412; nC7H8 = 50.00 g : 1 mol 92.13 g = 0.5427 mol; nC6H6 = 50.00 g * 1 mol 78.11 g = 0.6401 mol; M = a 1.50 g 1.52 : 10-4 mol b = 9.87 * 103 g # mol-1 = 9.87 kg # mol-1 n = cV = a 2.11 kPa (1) * (8.3145 LиkPaиK-1 иmol-1 ) : (293 K) b xC2H5OH = 1.09 mol (1.09 + 0.0151) mol = 0.986; nC2H5OH = 50.0 g * 1 mol 46.07 g = 1.09 mol; nC9H8O = 2.00 g * 1 mol 132.16 g = 0.0151 mol; 103 mL 1 L * 1.07 g 1 mL = 1.07 : 103 g msolution = 1 L soln :58.44 gиmol-1 = 106.9 g NaCl; : 1.83 mol NaCl 1 L soln : 0.250 mol CH3OH 0.0135 kg H2O = 18.5 mol # kg-1 = 0.0135 kg H2O; molality = molality = 7.36 g KClO3 0.200 kg H2O * 1 mol KClO3 122.55 g KClO3 = Major Technique 4 MT4.1B HCl is in the mobile phase; the order of elution of the compounds will be the same as the order of their solubilities in HCl: CuCl2 Ͼ CoCl2 Ͼ NiCl2. Chapter 10 10.1B K ϭ (PSO2 )2 (PH2O)2 /(PH2S)2 (PO2 )3 10.2B K ϭ [ZnCl2](PH2 )/[HCl]2 10.3B K ϭ 1/(PO2 )5 10.4B ⌬Gr ϭ 4.73 kJиmolϪ1 ϩ (8.3145 JиmolϪ1 иKϪ1 )(298 K) ϫ ln{(2.10)2 /0.80} ϫ (1 kJ/103 J) ϭ ϩ8.96 kJиmolϪ1 . Because ⌬G > 0, reaction proceeds toward reactants. 10.5B ⌬Gr° ϭ 2⌬Gf° (NO2(g)) Ϫ [⌬Gf° (O2(g)) ϩ 2⌬Gf° (NO(g))] ϭ [2(51.31 Ϫ (0 ϩ 2(86.55))] kJиmolϪ1 ϭ Ϫ70.48 kJиmolϪ1 ; ln K ϭ Ϫ(Ϫ70.48 ϫ 103 JиmolϪ1 )/(8.3145 kJиKϪ1 иmolϪ1 ϫ 298 K) ϭ 28.45; K ϭ 2.3 ϫ 1012 10.6B 52 kPa ϫ (1bar)/(102 kPa) ϭ 0.52 bar; PNO ϭ [K ϫ PN2 ϫ PO2 ]1/2 ϭ [(3.4 ϫ 10Ϫ21 ) ϫ (0.52 bar) ϫ (0.52 bar)]1/2 ϭ 3.0 ϫ 10Ϫ11 bar, or 3.0 ϫ 10Ϫ6 Pa 10.7B Q ϭ (1.2)2 /2.4 ϭ 0.60; K ϭ 0.15, and so Q > K and the partial pressure of N2O4 will increase. 10.8B Kc ϭ K(T/12.03 K)Ϫ⌬n , ⌬n ϭ 2 Ϫ 1 ϭ ϩ1; Kc ϭ (47.9) ϫ (12.03 K/400. K) ϭ 1.44 10.9B Kc ϭ (7.3 ϫ 10Ϫ13 )1/2 ϭ 8.5 ϫ 10Ϫ7 10.10B K ϭ (2x)2 (x)/(0.012 Ϫ 2x)2 Ϸ 4x3 /(0.012)2 ϭ 3.5 ϫ 10Ϫ32 ; x ϭ 1.1 ϫ 10Ϫ12 . At equilibrium: PHCl ϭ 0.012 bar; PHI ϭ 2.2 ϫ 10Ϫ12 bar; PCl2 ϭ 1.1 ϫ 10Ϫ12 bar; some solid I2 remains as well. 10.11B Q ϭ (0.100)2 /(0.200)(0.100) ϭ 0.5, so Q Ͻ K; K ϭ 20. ϭ (0.100 ϩ 2x)2 /[(0.200 Ϫ x)(0.100 Ϫ x)]; x ϭ 0.0750 bar; PClF ϭ 0.100 ϩ 2x ϭ 0.250 bar 10.12B The equilibrium tends to shift toward (a) products; (b) products; (c) reactants. 10.13B Q ϭ (1.30)2 /(0.080)(0.050)3 ϭ 1.7 ϫ 105 ; Q Ͻ K. K ϭ (1.30 ϩ 2x)2 /(0.080 Ϫ x)(0.050 Ϫ x)3 ϭ 6.8 ϫ 105 ; x ϭ 5.86 ϫ 10Ϫ3 bar; 0.074 bar N2; 1.31 bar NH3; 0.032 bar H2 10.14B Compression affects gaseous species only. In the forward reaction, 1 mol of CO2(g) reacts to form an aqueous species. Therefore, compression favors the formation of H2CO3(aq). 10.15B ⌬Hr° ϭ 2(Ϫ393.51 kJиmolϪ1 ) Ϫ 2 (Ϫ110.53 kJиmolϪ1 ) Ϫ 0 ϭ Ϫ565.96 kJиmolϪ1 . The reaction is exothermic; therefore, lowering the temperature shifts the reaction to the products. The pressure of CO2 will increase. 10.16B ⌬Hr° ϭ 0 ϩ (Ϫ287.0 kJиmolϪ1 ) Ϫ (Ϫ374.9 kJиmolϪ1 ) ϭ ϩ87.9 kJиmolϪ1 ; 7.0; K2 ϭ K1e7.0 ϭ (78.3)e7.0 ϭ 8.6 ϫ 104 Chapter 11 11.1B (a) H3Oϩ (it has one more Hϩ than H2O); (b) NH2 Ϫ (it has one less Hϩ than NH3) 11.2B (a) Brønsted acids: NH4 ϩ (aq), H2CO3(aq); Brønsted bases: HCO3 Ϫ (aq), NH3(aq); (b) Lewis acid: Hϩ (aq); Lewis bases: NH3(aq), HCO3 Ϫ (aq) 11.3B (a) [H3Oϩ ] ϭ (1.0 ϫ 10Ϫ14 )/(2.2 ϫ 10Ϫ3 ) ϭ 4.5 ϫ 10Ϫ12 molиLϪ1 ; (b) [OHϪ ] ϭ [NaOH]initial ϭ 2.2 ϫ 10Ϫ3 molиLϪ1 11.4B [OHϪ ] ϭ [NaOH]initial ϭ 0.077 molиLϪ1 ; [H3Oϩ ] ϭ (1.0 ϫ 10Ϫ14 )/(0.077) ϭ 1.30 ϫ 10Ϫ13 molиLϪ1 ; pH ϭ Ϫlog (1.3 ϫ 10Ϫ13 ) ϭ 12.89 11.5B [H3Oϩ ] ϭ 10Ϫ8.2 ϭ 6 ϫ 10Ϫ9 molиLϪ1 11.6B The conjugate base of HIO3 is IO3 Ϫ ; pKb ϭ pKw Ϫ pKa ϭ 14.00 Ϫ 0.77 ϭ 13.23 lna K2 K1 b = 87.9 * 103 J # mol-1 8.3145 J # mol-1 # K-1 c 1 523 K - 1 800 K d = C6 ANSWERS 11.7B (a) 1.8 ϫ 10Ϫ9 ϭ Kb(C5H5N) Ͻ Kb(NH2NH2) ϭ 1.7 ϫ 10Ϫ6 , so NH2NH2 is the stronger base. (b) From part a, C5H5N is the weaker base, so C5H5NHϩ is the stronger acid. (c) 1.7 ϫ 10Ϫ1 ϭ Ka(HIO3) Ͼ Ka(HClO2) ϭ 1.0 ϫ 10Ϫ2 , so HIO3 is the stronger acid. (d) Kb(HSO3 Ϫ ) ϭ (1.0 ϫ 10Ϫ14 )/(1.5 Ϫ10Ϫ2 ) ϭ 6.7 ϫ 10Ϫ13 ; Kb(ClO2 Ϫ ) ϭ (1.0 ϫ 10Ϫ14 )/(1.0 Ϫ10Ϫ2 ) ϭ 1.0 ϫ 10Ϫ12 ; Kb(HSO3 Ϫ ) Ͻ Kb(ClO2 Ϫ ); therefore, ClO2 Ϫ is the stronger base. 11.8B CH3COOH Ͻ CH2ClCOOH Ͻ CHCl2COOH (The electronegativity of Cl is greater than that of H. Therefore, the acidity increases as the number of attached chlorine atoms increases.) 11.9B Check approximation: Ka ϭ 1.4 ϫ 10Ϫ3 ϭ x2 /(0.22 Ϫ x), x ϭ 0.018, Ͼ 5% of 0.22, so the quadratic equation is required: x2 ϩ (1.4 ϫ 10Ϫ3 )x Ϫ 3.1 ϫ 10Ϫ4 ϭ 0; x ϭ 1.7 ϫ 10Ϫ2 molиLϪ1 ϭ [H3Oϩ ]; pH ϭ 1.77; percentage deprotonation ϭ [(1.7 ϫ 10Ϫ2 )/0.22] ϫ 100% ϭ 7.7% 11.10B [H3Oϩ ] ϭ 10Ϫ2.35 ϭ 4.5 ϫ 10Ϫ3 molиLϪ1 ; Ka ϭ (4.5 ϫ 10Ϫ3 )2 /{0.50 Ϫ (4.5 ϫ 10Ϫ3 )} ϭ 4.1 ϫ 10Ϫ5 11.11B Kb ϭ 1.0 ϫ 10Ϫ6 ϭ x2 /(0.012 Ϫ x) Ϸ x2 /.012; x ϭ 1.1 ϫ 10Ϫ4 ϭ [OHϪ ]; pOH ϭ 3.96; pH ϭ 14.00 Ϫ 3.96 ϭ 10.04; percentage protonated ϭ (1.1 ϫ 10Ϫ4 )/(0.012) ϫ 100 ϭ 0.92% 11.12B (a) CO3 2Ϫ is the conjugate base of HCO3 Ϫ , which is a weak acid; therefore, the solution is basic. (b) Ka(Al(H2O)6 3ϩ ) ϭ 1.4 ϫ 10Ϫ5 ; therefore, the solution is acidic. (c) Kϩ is a “neutral cation” and NO3 Ϫ is a conjugate base of a strong acid; therefore, the aqueous solution is neutral. 11.13B NH4 ϩ (aq) ϩ H2O(l) NH3(aq) ϩ H3Oϩ (aq); Kb(NH3) ϭ 1.8 ϫ 10Ϫ5 ; Ka(NH4 ϩ ) ϭ (1.0 ϫ 10Ϫ14 )/(1.8 ϫ 10Ϫ5 ) ϭ 5.6 ϫ 10Ϫ10 ; Ka ϭ 5.6 ϫ 10Ϫ10 ϭ x2 /(0.10 Ϫ x) ≈ x2 /0.10; x ϭ 7.5 ϫ 10Ϫ6 ; pH ϭ Ϫlog(7.5 ϫ 10Ϫ6 ) ϭ 5.12 11.14B FϪ (aq) ϩ H2O(l) HF(aq) ϩ OHϪ (aq); Ka(HF) ϭ 3.5 ϫ 10Ϫ4 ; Kb(FϪ ) ϭ (1.0 ϫ 10Ϫ14 )/(3.5 ϫ 10Ϫ4 ) ϭ 2.9 ϫ 10Ϫ11 ; Kb ϭ 2.9 ϫ 10Ϫ11 ϭ x2 /(0.020 Ϫ x) Ϸ x2 /0.020; x ϭ 7.56 ϫ 10Ϫ7 ; pOH ϭ 6.12; pH ϭ 14.00 Ϫ 6.12 ϭ 7.88 11.15B 0.012 ϭ (0.10 ϩ x)(x)/(0.10 Ϫ x); x2 ϩ 0.11x Ϫ 0.0012 ϭ 0; from the quadratic formula, x ϭ 0.0098; [H3Oϩ ] ϭ 0.10 ϩ 0.0098 ϭ 0.11; pH ϭ 0.96 11.16B pKa1(H3PO4) ϭ 2.12; pKa2(H3PO4) ϭ 7.21; pH ϭ (2.12 ϩ 7.21) ϭ 4.66 11.17B [ClϪ ] ϭ 0.50 molиLϪ1 ; ϩ NH3CH2COOH(aq) ϩ H2O(l) ϩ NH3CH2COOϪ (aq) ϩ H3Oϩ (aq), Ka1ϭ 4.5 ϫ 10Ϫ3 but Ͼ 5% ionization, so approximation not valid, x2 ϩ (4.5 ϫ 10Ϫ3 )x Ϫ 0.00225 ϭ 0; x ϭ 0.045 ϭ [H3Oϩ ] ϭ [ϩ NH3CH2COOϪ ]; [ϩ NH3CH2COOH] ϭ (0.50 Ϫ 0.045) molиLϪ1 ϭ 0.45 molиLϪ1 ; ϩ NH3CH2COOϪ (aq) ϩ H2O(l) NH2CH2COOϪ (aq) ϩ H3Oϩ (aq), Ka2 ϭ 1.7 ϫ 10Ϫ10 ϭ (x)(0.045)/ (0.045 Ϫ x), x ϭ 1.7 ϫ 10Ϫ10 molиLϪ1 ϭ [NH2CH2COOϪ ] (Ͻ 5% ionization, so approximation is valid); [OHϪ ] ϭ Kw/[H3Oϩ ] ϭ (1.0 ϫ 10Ϫ14 )/(0.045) ϭ 2.2 ϫ 10Ϫ13 molиLϪ1 11.18B Kw ϭ [H3Oϩ ]([H3Oϩ ] ϩ [NaOH]initial) ϭ x(x ϩ [NaOH]initial), x2 ϩ (2.0 ϫ 10Ϫ7 )x Ϫ (1.0 ϫ 10Ϫ14 ), x ϭ 4.1 ϫ 10Ϫ8 molиLϪ1 , pH ϭ Ϫlog (4.1 ϫ 10Ϫ8 ) ϭ 7.39 11.19B Ka(HIO) ϭ 2.3 ϫ 10Ϫ11 , x3 ϩ (2.3 ϫ 10Ϫ11 )x2 Ϫ [1.0 ϫ 10Ϫ14 ϩ (2.3 ϫ 10Ϫ11 )(1.0 ϫ 10Ϫ2 ]x Ϫ (2.3 ϫ 10Ϫ11 )(1.0 ϫ 10Ϫ14 ) ϭ 0, x3 ϩ (2.3 ϫ 10Ϫ11 )x2 Ϫ 2.4 ϫ 10Ϫ13 )x Ϫ (2.3 ϫ 10Ϫ25 ) ϭ 0, x ϭ 4.9 ϫ 10Ϫ7 ϭ [H3Oϩ ], pH ϭ Ϫlog(4.9 ϫ 10Ϫ7 ) ϭ 6.31 Chapter 12 12.1B Ka ϭ 5.6 ϫ 10Ϫ10 ; pH ϭ Ϫlog(5.6 ϫ 10Ϫ10 ) ϩ log(0.030/0.040) ϭ 9.13 12.2B n(CH3CO2 Ϫ )final ϭ [(0.500 L) ϫ (0.040 molиLϪ1 )] Ϫ 0.0100 mol ϭ 0.0100 mol, [CH3CO2 Ϫ ]final ϭ (0.0100 mol)/(0.500 L) ϭ 0.0200 molиLϪ1 ; n(CH3COOH)final ϭ [(0.500 L) ϫ (0.080 molиLϪ1 )] ϩ 0.0100 mol ϭ 0.0500 mol, [CH3COOH]final ϭ (0.0500 mol)/(0.500 L) ϭ 0.100 molиLϪ1 ; pH ϭ 4.75 ϩ log(0.0200/0.100) ϭ 4.05; pHfinal Ϫ pHinitial ϭ 4.05 Ϫ 4.45 ϭ Ϫ0.4 (a decrease of 0.4) 12.3B (CH3)3NHϩ /(CH3)3N, because the pKa ϭ 9.81, which is close to 10 Δ Δ 1 2 Δ Δ 12.4B pH Ϫ pKa ϭ 3.50 Ϫ 4.19 ϭ Ϫ0.69; ([C6H5CO2 Ϫ ]/ [ C6H5COOH]) ϭ 10Ϫ0.69 ϭ 0.20:1 12.5B Amount of H3Oϩ added ϭ 0.012 L ϫ (0.340 mol)/1 L ϭ 0.00408 mol; amount of OHϪ remaining ϭ 0.00625 Ϫ 0.00408 mol ϭ 0.00217 mol, [OHϪ ] ϭ (0.00217 mol)/(0.0370 L) ϭ 0.0586 molиLϪ1 ; pOH ϭ 1.232; pH ϭ 14.00 Ϫ1.232 ϭ 12.77 12.6B initial amount of NH3 ϭ 0.025 L ϫ (0.020 molиLϪ1 ) ϭ 5.0 ϫ 10Ϫ4 mol; volume of HCl added ϭ (5.0 ϫ 10Ϫ4 mol)/(0.015 molиLϪ1 ) ϭ 0.0333 L; [NH4 ϩ ] ϭ (5.0 ϫ 10Ϫ4 mol)/(0.0333 ϩ 0.02500)L ϭ 0.0086 molиLϪ1 ; Ka ϭ [H3Oϩ ][NH3]/[NH4 ϩ ] ϭ 5.6 ϫ 10Ϫ10 ϭ (x2 )/(0.0086 Ϫ x) Ϸ (x2 )/(0.0086); [H3Oϩ ] ϭ x ϭ 2.2 ϫ 10Ϫ6 ; pH ϭ 5.66 12.7B final volume of solution ϭ 25.00 ϩ 15.00 mL ϭ 40.00 mL; amount of HCO2 Ϫ formed ϭ amount of OHϪ added ϭ (0.150 molиLϪ1 ) ϫ (15.00 mL) ϭ 2.25 mmol; amount of HCOOH remaining ϭ 2.50 Ϫ 2.25 mmol ϭ 0.25 mmol; [HCOOH] ϭ (0.25 ϫ 10Ϫ3 mol)/(0.04000 L) ϭ 0.062 molиLϪ1 ; [HCO2 Ϫ ] ϭ (2.25 ϫ 10Ϫ3 mol)/(0.04000 L) ϭ 0.0562 molиLϪ1 ; pH ϭ 3.75 ϩ log(0.0562/0.0062) ϭ 4.71 12.8B (a) amount of H3PO4 ϭ (0.030 L)(0.010 molиLϪ1 ) ϭ 3.0 ϫ 10Ϫ4 mol; at first stoichiometric point, initial amount of H3PO4 ϭ amount of NaOH added; volume of NaOH ϭ 3.0 ϫ 10Ϫ4 mol/ 0.020 molиLϪ1 ϭ 0.015 L, or 15 mL. (b) 2 ϫ15 mL ϭ 30. mL 12.9B (0.020 L)(0.100 molиLϪ1 ) ϭ 0.0020 mol H2S; 0.0020 mol/ (0.300 molиLϪ1 ) ϭ 0.0067 L, or 6.7 mL NaOH for first stoichiometric point and 2 ϫ 6.7 mL ϭ 13.4 mL for second stoichiometric point; (a) before first stoichiometric point; primary species present are Naϩ , H2S, and HSϪ ; (b) at second stoichiometric point, primary species present are Naϩ and S2Ϫ (also HSϪ and OHϪ because S2Ϫ has a relatively large Kb) 12.10B Ksp ϭ [Agϩ ][BrϪ ] ϭ (8.8 ϫ 10Ϫ7 )2 ϭ 7.7 ϫ 10Ϫ13 12.11B Ksp ϭ [Pb2ϩ ][FϪ ]2 ϭ (s)(2s)2 ϭ 4s3 ; 3.7 ϫ 10Ϫ8 ϭ 4s3 ; s ϭ 2.1 ϫ 10Ϫ3 molиLϪ1 12.12B In 0.10 M CaBr2(aq), [BrϪ ] ϭ 2 ϫ (0.10 molиLϪ1 ) ϭ 0.20 molиLϪ1 ; s ϭ [Agϩ ] ϭ Ksp/[BrϪ ] ϭ (7.7 ϫ 10Ϫ13 )/(0.20) ϭ 3.8 ϫ 10Ϫ12 molиLϪ1 12.13B [Ba2ϩ ] ϭ {(1.0 ϫ 10Ϫ3 molиLϪ1 ) ϫ (100 mL)}/300 mL ϭ 3.3 ϫ 10Ϫ4 molиLϪ1 . [FϪ ] ϭ {(1.0 ϫ 10Ϫ3 molиLϪ1 ) ϫ (200 mL)}/300 mL ϭ 6.7 ϫ 10Ϫ4 molиLϪ1 . Qsp ϭ (3.3 ϫ 10Ϫ4 )(6.7 ϫ 10Ϫ4 )2 ϭ 1.5 ϫ 10Ϫ10 < Ksp ϭ 1.7 ϫ 10Ϫ6 ; therefore, no precipitate of BaF2 forms. 12.14B (a) For PbCl2 to precipitate, [ClϪ ] ϭ (Ksp/[Pb2ϩ ])1/2 ϭ (1.6 ϫ 10Ϫ5 /0.020)1/2 ϭ 2.8 ϫ 10Ϫ2 molиLϪ1 . For AgCl to precipitate, [ClϪ ] ϭ (Ksp/[Agϩ ]) ϭ (1.6 ϫ 10Ϫ10 /0.0010) ϭ 1.6 ϫ 10Ϫ7 molиLϪ1 . Therefore, AgCl precipitates first at [ClϪ ] ϭ 1.6 ϫ 10Ϫ7 molиLϪ1 , then PbCl2 precipitates at [ClϪ ] ϭ 2.8 ϫ 10Ϫ2 molиLϪ1 . (b) When the PbCl2 precipitates, [Agϩ ] ϭ (Ksp/[ClϪ ]) ϭ (1.6 ϫ 10Ϫ10 )/(2.8 ϫ 10Ϫ2 ) ϭ 5.7 ϫ 10Ϫ9 molиLϪ1 . 12.15B CuS(s) ϩ 4 NH3(aq) Δ Cu(NH3)4 2ϩ (aq) ϩ S2Ϫ (aq); K ϭ (1.3 ϫ 10Ϫ36 ) ϫ (1.2 ϫ 1013 ) ϭ 1.6 ϫ 10Ϫ23 ; K ϭ [Cu(NH3)4 2ϩ ][S2Ϫ ]/[NH3]4 ϭ 1.6 ϫ 10Ϫ23 ϭ x2 /(1.2 Ϫ 4x)4 Ϸ x2 /(1.2 )4 ; x/(1.2)2 ϭ 4.0 ϫ 10Ϫ12 ; x ϭ [S2Ϫ ] ϭ 5.8 ϫ 10Ϫ12 molиLϪ1 Chapter 13 13.1B reduction: (8 Hϩ ϩ MnO4 Ϫ ϩ 5 eϪ : Mn2ϩ ϩ 4 H2O) ϫ 2; oxidation: (H2O ϩ H2SO3 : HSO4 Ϫ ϩ 2 eϪ ϩ 3 Hϩ ) ϫ 5; net reaction: Hϩ (aq) ϩ 2 MnO4 Ϫ (aq) ϩ 5 H2SO3(aq) : 2 Mn2ϩ (aq) ϩ 5 HSO4 Ϫ (aq) ϩ 3 H2O(l) 13.2B oxidation: (3 IϪ : I3 Ϫ ϩ 2 eϪ ) ϫ 8; reduction: 9 H2O ϩ 16 eϪ ϩ 3 IO3 Ϫ : I3 Ϫ ϩ 18 OHϪ ; net reaction: 3 H2O(l) ϩ IO3 Ϫ (aq) ϩ 8 IϪ (aq) : 3 I3 Ϫ (aq) ϩ 6 OHϪ (aq) 13.3B Half reactions for the silver battery in Table 13.2 show that n ϭ 2; ⌬G ϭ Ϫ(2 mol)(9.6485 ϫ 104 CиmolϪ1 )(1.6 V) ϭ Ϫ3.09 ϫ 105 CиVиmolϪ1 ϭ Ϫ3.1 ϫ 102 kJ. 13.4B Mn(s)|Mn2ϩ (aq)||Cu2ϩ (aq),Cuϩ (aq)|Pt(s) 13.5B (a) left: 2 Hg(l) ϩ 2 HCl(aq) : Hg2Cl2(s) ϩ 2 eϪ ; right: 2 eϪ ϩ Hg2(NO3)2(aq) : 2 Hg(l) ϩ 2 NO3 Ϫ (aq); 2 HCl(aq) ϩ Hg2(NO3)2(aq) : Hg2Cl2(s) ϩ 2 HNO3(aq). (b) yes 13.6B E°(Pb2ϩ /Pb) ϭ E°cell ϩ E°(Fe2ϩ /Fe) ϭ 0.31 V ϩ (Ϫ0.44 V) ϭ Ϫ0.13 V SELF-TESTS B C7 13.7B Mn3ϩ ϩ eϪ : Mn2ϩ , E°1 ϭ ϩ1.51 V; Mn2ϩ ϩ 2eϪ : Mn(s), E°2 ϭ Ϫ1.18 V; net half-reaction: Mn3ϩ ϩ 3 eϪ : Mn(s), E°3 ϭ [(n1E1 ϩ n2E2)/(n3)] ϭ [(1 mol)(1.51 V) ϩ (2 mol)(Ϫ1.18 V)]/(3 mol) ϭ Ϫ0.28 V 13.8B O2 ϩ 2 H2O ϩ 4eϪ : 4 OHϪ , E° ϭ ϩ0.40 V; Cl2 ϩ 2 eϪ : 2 ClϪ , E° ϭ ϩ1.36 V. Yes, Cl2(g) can oxidize H2O to O2(g) in basic solution under standard conditions because the Cl2 reduction halfreaction has a more positive standard potential than the O2 reduction half-reaction. 13.9B oxidation half-reaction: Cu2ϩ ϩ 2 eϪ : Cu, E° ϭ ϩ0.34 V; reduction half-reaction: Agϩ ϩ eϪ : Ag, E° ϭ ϩ0.80 V; net reaction: Cu(s) ϩ 2 Ag2ϩ (aq) : Cu2ϩ (aq) ϩ 2 Ag(s), E° ϭ ϩ 0.46 V. Therefore, Agϩ is the stronger oxidizing agent. Cu(s)͉Cu2ϩ (aq)ʈAgϩ (aq)͉Ag(s) 13.10B Cd(OH)2 ϩ 2 eϪ : Cd ϩ 2 OHϪ , E° ϭ Ϫ0.81 V; Cd2ϩ ϩ 2 eϪ : Cd, E° ϭ Ϫ0.40 V; net: Cd(OH)2(s) : Cd2ϩ (aq) ϩ 2 OHϪ (aq), E° ϭ Ϫ0.41 V; ln Ksp ϭ (2)(Ϫ0.41 V)/0.025693 V ϭ Ϫ31.92; Ksp ϭ 1.4 ϫ 10Ϫ14 13.11B cell reaction: Agϩ (aq, 0.010 molиLϪ1 ) : Agϩ (aq, 0.0010 molиLϪ1 ), E° ϭ 0.0 V, n ϭ 1; E ϭ 0.0 V Ϫ (0.025693 V) ϫ ln(0.0010/0.010) ϭ ϩ0.059 V 13.12B At pH ϭ 12.5, pOH ϭ 1.5 and [OHϪ ] ϭ 10Ϫ1.5 ϭ 0.032 molиLϪ1 ; [Agϩ ] ϭ (Ksp/[OHϪ ]) ϭ (1.5 ϫ 10Ϫ8 /(0.032) ϭ 4.7 ϫ 10Ϫ7 molиLϪ1 . E ϭ Ϫ(0.025693 V/1) ln(4.7 ϫ 10Ϫ7 /1.0) ϭ 0.37 V 13.13B The reduction half-reactions are: Br2(l) ϩ 2 eϪ : 2 BrϪ (aq), E° ϭ ϩ1.09 V; O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ : 2H2O (l), E ϭ ϩ0.82 V at pH ϭ 7; 2 Hϩ (aq) ϩ 2 eϪ : H2(g), E° ϭ 0.00 V. Product at the cathode: H2; product at the anode: O2 and Br2. (We predict that H2O will be oxidized rather than BrϪ . However, because of the high overpotential for oxygen production, bromine may also be produced.) 13.14B 12.0 mol eϪ ϫ (1 mol Cr)/(6 mol eϪ ) ϭ 2 mol Cr 13.15B 13.16B 13.17B (b) Aluminum. It is the only one of the metals with a standard potential (Ϫ1.66 V) lower than that of iron (ϩ0.44 V), so it is the only one more easily oxidized than iron. Chapter 14 14.1B average rate of disappearance of Hb ϭ 4 ϫ 10Ϫ6 mmolиLϪ1 и␮sϪ1 14.2B (a) 1 ⁄2[5.0 ϫ 10Ϫ3 (mmol HI)иLϪ1 иsϪ1 ] ϭ 2.5 ϫ 10Ϫ3 (mmol H2)иLϪ1 иsϪ1 ; (b) unique average rate ϭ ⌬[H2]/⌬t ϭ ⌬[I2]/⌬t ϭ Ϫ1 ⁄2(⌬[HI]/⌬t) ϭ 2.5 ϫ 10Ϫ3 mmolиLϪ1 иsϪ1 14.3B (a) first order in C4H9Br; zero order in OHϪ ; (b) first order overall; (c) sϪ1 14.4B rate ϭ k [CO]m [Cl2]n Therefore, rate ϭ k [CO][Cl2]3/2 . From experiment 1, k ϭ 0.121 molиL-1 иs-1 (0.12 molиL-1 )(0.20 molиL-1 )3/2 = 11 L3/2 иmol-3/2 иs-1 log 2.8 log 2 = 1.5; rate (3) rate (2) = 0.682 0.241 = a 0.24 0.24 b m a 0.40 0.20 b n ; 2.8 = (2)n ; n = rate (2) rate (1) = 0.241 0.121 = a 0.24 0.12 b m a 0.20 0.20 b n ; 2 = (2)m ; m = 1; -[(8.0 : 10-7 ) - (1.2 : 10-6 )](mmol Hb)иL-1 0.10 ␮s = t = (1.385 mol e)(9.6485 : 104 C # mol-1 ) 6.20 C # s-1 : 1 h 3600 s = 5.99 h 12.00 g Cr : 1 mol Cr 52.00 g Cr : 6 mol e- 1 mol Cr = 1.385 mol e- ; 1 mol Cr 6 mol e- * 52.00 g Cr 1 mol Cr = 12.0 g Cr mCr = (6.20 C # s-1 )(6.00 h : 3600 s # h-1 ) 9.6485 : 104 C # mol-1 : 14.5B [C3H6]t ϭ [C3H6]0 eϪkt ϭ (0.100 molиLϪ1 )[eϪ(6.7 ϫ 10Ϫ4иsϪ1)(200 s) ] ϭ 0.087 molиLϪ1 14.6B A plot of ln(CH3N2CH3) against time is linear, showing that the reaction must be first order; k ϭ 3.60 ϫ 10Ϫ4 sϪ1 . 14.7B Reaction is first order with k ϭ 6.7 ϫ 10Ϫ4 sϪ1 at 500° C; ϭ 7.9 ϫ 103 s ϭ 2.2 h 14.8B ϭ 5.6 ϫ 104 y 14.9B (a) Four half-lives are required for the concentration to fall to one-sixteenth of its initial value: (1/2)4 ϭ 1/16; (b) The reaction is first order with k ϭ 5.5 ϫ 10Ϫ4 sϪ1 at 973 K. t1/2 ϭ (ln 2)/k ϭ (ln 2)/(5.5 ϫ 10Ϫ4 sϪ1 ) ϭ 1.3 ϫ 103 s ϭ 21 min. t ϭ 4t1/2 ϭ 4 ϫ 21 min ϭ 84 min. 14.10B (a) bimolecular (two reactants); (b) unimolecular (one reactant) 14.11B net ratedisappearance of B ϭ k1[H2A][B] ϩ k2[HAϪ ][B] Ϫ k1Ј[HAϪ ][BHϩ ]; net rateformation of HAϪ ϭ k1[H2A][B] Ϫ k1Ј[HAϪ ][BHϩ ] Ϫ k2[HAϪ ] [B] ϭ 0; [HAϪ ] ϭ (k1[H2A][B])/(k1Ј[BHϩ ] ϩ k2[B]); substitute for [HAϪ ]: net ratedisappearance of B ϭ assume k2[B] ϽϽ k1Ј[BHϩ ]; then net ratedisappearance of B ϭ k[H2A][B]2 [BHϩ ]Ϫ1 ; k ϭ (2k2k1)͞k1Ј; H2A ϩ 2 B : 2 BHϩ ϩ A2Ϫ 14.12B Ea ϭ 2.3 ϫ 104 JиmolϪ1 ϭ 23 kJиmolϪ1 14.13B Ϫ14.77 kЈ/k ϭ eϪ14.77 ; kЈ ϭ (6.7 ϫ 10Ϫ4 sϪ1 )(eϪ14.77 ) ϭ 2.6 ϫ 10Ϫ10 sϪ1 14.14B (a) The homogeneous catalyst changes the reaction pathway, and therefore changes the rate law. (b) Since a catalyst does not change the thermodynamics of the reaction, a homogeneous catalyst does not change the equilibrium constant. Chapter 15 15.1B Oxygen. It is above both gallium and tellurium in the periodic table and to the right of gallium. 15.2B Aluminum forms an amphoteric oxide in which it has the oxidation state ϩ3; therefore, aluminum is the element. 15.3B Hydrogen is a nonmetal and a diatomic gas at room temperature. It has an intermediate electronegativity (␹ ϭ 2.2), so it forms covalent bonds with nonmetals and forms anions in combination with metals. In contrast, Group 1 elements are solid metals that have low electronegativities and form cations in combination with nonmetals. 15.4B K(s) ϩ O2(g) : KO2(s) 15.5B The molar mass of potassium is smaller than that of cesium. Thus the same amount of O2 can be obtained from a smaller mass of KO2 than can be obtained from a larger mass of CsO2. 15.6B 2 Ba(s) ϩ O2(g) : 2 BaO(s) 15.7B Lewis acidϪbase reaction; CaO is the base and SiO2 is the acid. 15.8B Boric acid acts as a Lewis acid. The boron atom in B(OH)3 has an incomplete octet and forms a bond by accepting a lone pair of electrons from a water molecule, which is acting as a Lewis base. The complex formed is a weak Brønsted acid in which an acidic proton can be lost from an H2O molecule in the complex. 2.72 : 105 Jиmol-1 8.3145 Jиmol-1 иK-1 c 1 773 - 1 573 d = lna k¿ k b = Ea R c 1 T - 1 T¿ d; lna k¿ k b = Ea 8.3145 Jиmol-1 иK=1 c 1 291 K - 1 303 K d; ln a 4.35 3.00 b =ln a k¿ k b = Ea R c 1 T - 1 T¿ d; k1[H2A][B] + (k2k1[H2A][B]2 ) k1 ¿ [BH+ ] + k2[B] k ¿ 1 k1[H2A][B][BH+ ] k ¿ 1 [BH+ ] + k2[B] ; k = ln 2 2.4 * 104 y ; t = 2.4 : 104 y ln 2 clna 1.0 0.20 b d t = 1 k ln [C3H6]0 [C3H6]t = 1 6.7 : 10-4 s-1 ln a 1.0 mol # L-1 0.0050 mol # L-1 b C8 ANSWERS 15.9B (a) ϩ3, because the oxidation number of H in this hydride is taken to be Ϫ1; (b) ϩ3 15.10B Lewis acid–base reaction; CO is the Lewis acid and OHϪ is the Lewis base. 15.11B SiH4 is a Lewis acid that can react with the Lewis base OHϪ . CH4 is not a Lewis acid, because the C atom is much smaller than the Si atom and has no accessible d-orbitals to accommodate added electron pairs. 15.12B (a) ; (b) Other resonance structures violate the octet rule, so the one shown in (a) is the major resonance contributor. (c) The azide ion is linear and nonpolar. 15.13B Assume 1 L solution; 1 L soln ϫ (103 mL/1 L) ϫ (1.7 g soln/ 1 mL soln) ϫ (85 g H3PO4/100 g soln) ϫ (1 mol H3PO4/97.99 g H3PO4) ϭ 15 M H3PO4(aq) 15.14B Reduction: 2 (2 eϪ ϩ F2 : 2 FϪ ); oxidation: 2 H2O : O2 ϩ 4 Hϩ ϩ 4 eϪ ; overall: 2 H2O(l) ϩ 2 F2(g) : O2(g) ϩ 4 Hϩ (aq) ϩ 4 FϪ (aq); E° ϭ 2.87 Ϫ 1.23 V ϭ ϩ1.64 V; ⌬Gº ϭ Ϫ(4 mol) (96.485 kCиmolϪ1 )(1.64 V) ϭ Ϫ633 kJ 15.15B (a) ϩ1; (b) ϩ6 15.16B The melting and boiling points of the halogens increase down the group because the intermolecular attractions become stronger; London forces become stronger as the number of electrons present increase. 15.17B In the reduction of HClO3 an acid is a reactant. Therefore, increasing the pH reduces the oxidizing ability of HClO3. 15.18B square pyramidal Chapter 16 16.1B Each metal atom will lose one 4s-electron. Vϩ , Mnϩ , Coϩ , and Niϩ will have one electron in the 4s-orbital, but Crϩ and Cuϩ will have zero electrons in the 4s-orbital. Because their outermost valence electrons will be in 3d-orbitals and not the 4s-orbital, their radii should be smaller than the other cations. 16.2B Oxidation: 2 Hg(l) :Hg2 2ϩ (aq) ϩ 2 eϪ ; reduction: 4 Hϩ (aq) ϩ NO3 Ϫ (aq) ϩ 3 eϪ :NO(aq) ϩ 2 H2O(l); overall: 6 Hg(l) ϩ 8 Hϩ (aq) ϩ 2 NO3 Ϫ (aq) :3 Hg2 2ϩ (aq) ϩ 2 NO(aq) ϩ 4 H2O(l); E° ϭ 0.96 V Ϫ 0.79 V ϭ ϩ0.17 V 16.3B (a) pentaaminebromidocobalt(II) sulfate; (b) [Cr(NH3)4(OH2)2]Br3 16.4B The ratio of CrCl3и6H2O to Cl is 1:3; therefore, the isomer [Cr(OH2)6]Cl3 is present. 16.5B (a) NCSϪ is replaced by SCNϪ ; linkage isomers; (b) H2O is exchanged for ClϪ ; hydrate isomers. 16.6B (a) not chiral; (b) chiral; (c) not chiral; (d) chiral; no entantiomeric pairs 16.7B ⌬⌷ ϭ hc/␭ ϭ (6.022 ϫ 1023 molϪ1 )(6.626 ϫ 10Ϫ34 JиsϪ1 ) (2.998 ϫ 108 mиsϪ1 )/(305 ϫ 10Ϫ9 m) ϫ (1 kJ/103 J) ϭ 392 kJиmolϪ1 16.8B (a) Strong-field ligands have large ⌬O. The configuration is t2g 6 eg 1 and there is one unpaired electron. (b) Weak-field ligands have small ⌬O. The configuration is t2g 5 eg 2 and there are three unpaired electrons. 16.9B The ligand en is strong-field, and H2O is a weak-field ligand. However, because Ni2ϩ has eight d-electrons it is a d8 complex and there is no empty eg orbital. Therefore, both [Ni(en)3]2ϩ and [Ni(H2O)6]2ϩ have a t2g 6 eg 2 configuration, and are paramagnetic. Chapter 17 17.1B (a) : is produced. (b) : is produced. 17.2B (a) : is produced. (b) : is produced.A Z E + 0 +1 e; 11 5 B 11 6 CA Z E ; 55 25 Mn55 26 Fe + 0 -1 e A Z E + 0 -1 e; 228 89 Ac 228 88 RaA Z E + 4 2 ␣; 228 88 Ra232 90 Th N N A A A N A £ £ Ϫ1 ϩ1 Ϫ1 Ϫ 17.3B (c) Ce-148 is neutron rich (in the blue band) and therefore might undergo ␤ emission, which converts a neutron into a proton, to reach stability. 17.4B (a) mass number: 250 ϩ A ϭ 257 ϩ 4(1), A ϭ11; atomic number: 98 ϩ Z ϭ 103 ϩ 4(0), Z ϭ 5; the missing nuclide is (b) mass number: A ϩ 12 ϭ 254 ϩ 4(1), A ϭ 246; atomic number: Z ϩ 6 ϭ 102 ϩ 4(0), Z ϭ 96; the missing nuclide is 17.5B 17.6B 17.7B ⌬m ϭ {(235.0439mu) Ϫ 92(1.0078mu) Ϫ 143(1.0087mu)} ϫ (1.6605 ϫ 10Ϫ27 kg) ϭ Ϫ3.1845 ϫ 10Ϫ27 kg; Ebind ϭ ͉3.1845 ϫ 10Ϫ27 kg͉ ϫ (3.00 ϫ 108 mиsϪ1 )2 ϫ (1 eV)/(1.60218 ϫ 10Ϫ19 J) ϭ 1.79 ϫ 109 eV 17.8B ⌬m ϭ {137.91mu ϩ 85.91mu ϩ 12(1.0087mu) Ϫ (235.04mu ϩ 1.0087mu)} ϫ 1.6605 ϫ 10Ϫ27 kg ϭ Ϫ2.06 ϫ 10Ϫ28 kg per nucleus; ⌬E ϭ (1.0 ϫ 10Ϫ3 kg)/(235.0 ϫ 1.6605 ϫ 10Ϫ27 kg) ϫ (Ϫ2.06 ϫ 10Ϫ28 kg) ϫ (3.00 ϫ 108 mиsϪ1 )2 ϭ Ϫ4.8 ϫ 1010 J Chapter 18 18.1B (a) (b) (CH3)2CH(CH2)3CH(CH3)CH2CH3 18.2B (a) 4-ethyl-2-methylhexane; (b) 18.3B (a) 4-ethyl-2-hexene; (b) 18.4B CH3(CH2)2CH2Br; CH3CH2CHBrCH3; (CH3)2CHCH2Br; (CH3)3CBr C CC œ œ ç ç HH H H œ ç £ å å åC H H C H H C C C C C HH C H H ß ß ßß ß ß ß ß ß ß ß å å H å å H å H å H ßH H H ßH ßH C å å C å H å ßH ßH ßH ßH C å å H H å å C å H å H å C H å H å C H C C C OH H H H HH H H H H H H CC H C C C C t = - a 5.73 : 103 y ln 2 b : ln a 1.4 : 104 18400 b = 2.3 : 103 y m = m0e-kt = (5.0 ␮g)e-(3.3:10- 7 a- 1 )(1.0:106 a) = 3.6 ␮g 246 96 Cm. 11 5 B. SELF-TESTS B C9 18.5B 27a and 27b are both trans. 18.6B (c) is chiral, because the second C atom is attached to four different groups. 18.7B (a) has the higher boiling point because it has a longer chain than (b), and therefore has stronger London forces. 18.8B CH3CHClCH2CH3 18.9B 1-ethyl-3,5-dimethyl-2-propylbenzene Chapter 19 19.1 B (a) HCOOCH2CH3; (b) CH3OH and CH3(CH2)2COOH 19.2B C: sp2 hybridization ; N: sp3 hybridization 19.3B (a) 3-pentanol; (b) 3-pentanone; (c) ethylmethylamine 19.4B (a) CH2≈C(CH3)COOCH3; (b) ßNHCH(CH3)COßNHCH(CH3)COß 19.5B The A and B monomers alternate; therefore, ßABABABß copolymer is an alternating copolymer. C10 ANSWERS Odd-Numbered Exercises Fundamentals A.1 (a) chemical; (b) physical; (c) physical A.3 The temperature of the injured camper, the evaporation and condensation of water are physical properties. The ignition of propane is a chemical change. A.5. (a) physical; (b) chemical; (c) chemical A.7 (a) intensive; (b) intensive; (c) extensive; (d) extensive A.9 (a) 1 kilograin; (b) 1 centibatman; (c) 1 megamutchkin A.11 236 mL A.13 19.3 gиcmϪ3 A.15 0.0427 cm3 A.17 0.8589 gиcmϪ3 A.19 7.41 cm A.21 3 (0.989) A.23 (a) 4.82 ϫ 103 pm; (b) 30.5 mm3 иsϪ1 ; (c) 1.88 ϫ 10Ϫ12 kg; (d) 2.66 ϫ 103 kgиmϪ3 ; (e) 0.044 mgиcmϪ3 A.25 (a) 1.72 gиcmϪ3 (more precise); (b) 1.7 gиcmϪ3 A.27 (a) formula: X ϭ 50 ϩ 2°C; (b) 94°X A.29 32 J A.31 4.0 ϫ 103 kJ; 150 m A.33 6.0 J A.35 Since R ϭ RE ϩ h, If from the expansion in x. Then where B.1 1.40 ϫ 1022 atoms B.3 (a) 5p, 6n, 5e; (b) 5p, 5n, 5e; (c) 15p, 16n, 15e; (d) 92p, 146n, 92e B.5 (a) 194 Ir; (b) 22 Ne; (c) 51 V B.7 chlorine, 36 Cl, 17, 19, 17, 36; zinc, 65 Zn, 30, 35, 30, 65; calcium, 40 Ca, 20, 20, 20, 40; lanthanum, 137 La, 57, 80, 57, 137 B.9 (a) They all have the same mass. (b) They have differing numbers of protons, neutrons, and electrons. B.11 (a) 0.5519; (b) 0.4479; (c) 2.459 ϫ 10Ϫ4 ; (d) 551.9 kg B.13 (a) Scandium is a Group 3 metal. (b) Strontium is a Group 2 metal. (c) Sulfur is a Group 16/VI nonmetal. (d) Antimony is a Group 15/V metalloid. B.15 (a) Sr, metal; (b) Xe, nonmetal; (c) Si, metalloid B.17 fluorine, F, Z ϭ 9, gas; chlorine, Cl, Z ϭ 17, gas; bromine, Br, Z ϭ 35, liquid; iodine, I, Z ϭ 53, solid B.19 (a) d-block; (b) p-block; (c) d-block; (d) s-block; (e) p-block; (f) d-block B.21 The element is Pb. It is located in Group 14/IV and Period 6. It is a metal. C.1 (a) mixture, one compound and one element; (b) single element C.3 C40H56O2 C.5 (a) C3H7O2N; (b) C2H7N C.7 (a) cation, Csϩ ; (b) anion, IϪ ; (c) Se2Ϫ ; (d) Ca2ϩ C.9 (a) 4 p, 6 n, 2 e; (b) 8 p, 9 n, 10 e; (c) 35 p, 45 n, 36 e; (d) 33 p, 42 n, 36 e C.11 (a) 19 FϪ ; (b) 24 Mg2ϩ ; (c) 128 Te2Ϫ ; (d) 86 Rbϩ g = GmE R 2 E EP = GmEm RE a1 - a1 - h RE b b = GmEmh R 2 E = mgh 1 1 + h RE L 1 - h RE x = h RE , then = -GmEm RE P 1 1 + h RE - 1 Q = GmEm RE P 1 - 1 1 + h RE Q EP = ¢EP = -GmEm RE + h - a -GmEm RE b C.13 (a) Al2Te3; (b) MgO; (c) Na2S; (d) RbI C.15 (a) Group 13/III; (b) aluminum, Al C.17 (a) 0.542; (b) 0.458; (c) 2.49 ϫ 10Ϫ4 ; (d) 14 kg C.19 (a) Na2HPO3; (b) (NH4)2CO3; (c) ϩ2; (d) ϩ2 C.21 (a) molecular compound; (b) element; (c) ionic compound; (d) element; (e) molecular compound; (f) ionic compound D.1 (a) MnCl2; (b) Ca3(PO4)2; (c) Al2(SO3)3; (d) Mg3N2 D.3 (a) calcium phosphate; (b) tin(IV) sulfide, stannic sulfide; (c) vanadium(V) oxide; (d) copper(I) oxide, cuprous oxide D.5 (a) TiO2; (b) SiCl4; (c) CS2; (d) SF4; (e) Li2S; (f) SbF5; (g) N2O5; (h) IF7 D.7 (a) sulfur hexafluoride; (b) dinitrogen pentoxide; (c) nitrogen triiodide; (d) xenon tetrafluoride; (e) arsenic tribromide; (f) chlorine dioxide D.9 (a) hydrochloric acid; (b) sulfuric acid; (c) nitric acid; (d) acetic acid; (e) sulfurous acid; (f) phosphoric acid D.11 (a) ZnF2; (b) Ba(NO3)2; (c) AgI; (d) Li3N; (e) Cr2S3 D.13 (a) BaCl2; (b) ionic D.15 (a) sodium sulfite; (b) iron(III) oxide or ferric oxide; (c) iron(II) oxide or ferrous oxide; (d) magnesium hydroxide; (e) nickel(II) sulfate hexahydrate; (f) phosphorus pentachloride; (g) chromium(III) dihydrogen phosphate; (h) diarsenic trioxide; (i) ruthenium(II) chloride D.17 (a) CuCO3, copper (II) carbonate; (b) K2SO3, potassium sulfite; (c) LiCl, lithium chloride D.19 (a) heptane; (b) propane; (c) pentane; (d) butane D.21 (a) cobalt(III) oxide monohydrate, Co2O3иH2O; (b) cobalt(II) hydroxide, Co(OH)2 D.23 E ϭ Si; SiH4, silicon tetrahydride; Na4Si, sodium silicide D.25 (a) lithium aluminum hydride, ionic (with a molecular anion); (b) sodium hydride, ionic D.27 (a) selenic acid; (b) sodium arsenate; (c) calcium tellurite; (d) barium arsenate; (e) antimonic acid; (f) nickel(III) selenate D.29 (a) alcohol; (b) carboxylic acid; (c) haloalkane E.1 8.67 ϫ 1010 km E.3 18 Ca atoms E.5 (a) 1.0 ϫ 10Ϫ14 mol; (b) 3.2 ϫ 106 years E.7 (a) 1.38 ϫ 1023 O atoms; (b) 1.26 ϫ 1022 formula units; (c) 0.146 mol of H2O E.9 (a) 6.94 gиmolϪ1 ; (b) 6.96 gиmolϪ1 E.11 % 10 B ϭ 73.8%; % 10 B ϭ 26.2% E.13 (a) 75 g of indium. (b) 15.0 g of P. (c) Neither, they have the same number of moles. E.15 (a) 20.027 gиmolϪ1 . (b) 1.11 gиcmϪ3 . (c) volume of the spherical tank 905 m3 ; volume calculated from the density data 901 m3 . (d) no. (e) The assumption in part (b) is reasonable because the nuclei are so small and the volume difference between a D2O molecule and a H2O can be ignored. E.17 (a) 0.0981 mol, 5.91 ϫ 1022 molecules; (b) 1.30 ϫ 10Ϫ3 mol, 7.83 ϫ 1020 molecules; (c) 4.56 ϫ 10Ϫ5 mol, 2.79 ϫ 1019 molecules; (d) 6.94 mol, 4.18 ϫ 1024 molecules; (e) 0.312 mol N atoms, 1.88 ϫ 1023 N atoms; 0.156 mol N2, 9.39 ϫ 1022 N2 molecules E.19 (a) 0.0134 mol; (b) 8.74 ϫ 10Ϫ3 mol; (c) 430. mol; (d) 0.0699 mol E.21 (a) 4.52 ϫ 1023 formula units; (b) 124 mg; (c) 3.036 ϫ 1022 formula units E.23 (a) 2.992 ϫ 10Ϫ23 gиmoleculeϪ1 ; (b) 3.34 ϫ 1025 molecules E.25 (a) 0.0417 mol; (b) 0.0834 mol; (c) 1.00 ϫ 1023 molecules; (d) 0.3099 E.27 (a) $109.28 per L H2O; (b) $70.20 E.29 (a) 12.013 gиmolϪ1 ; (b) 197.18 gиmolϪ1 E.31 3.18 mol E.33 0.39% F.1 78.90% C, 10.59% H, 10.51% O F.3 52.15% C, 9.3787% H, 8.691% N, 29.78% O F.5 (a) 63.4 gиmolϪ1 ; (b) copper(I) oxide F.7 (a) Na3AlF6; (b) KClO3; (c) NH6PO4 or [NH4][H2PO4] F.9 (a) PCl5; (b) phosphorus pentachloride F.11 C16H13ClN2O F.13 (a) OsC4O4; (b) Os3C12O12 F.15 C8H10N4O2 ODD-NUMBERED EXERCISES C11 F.17 C49H78N6O12 F.19 ethene (85.63%) Ͼ heptane (83.91%) Ͼ propanol (59.96%) F.21 (a) empirical formula: C2H3Cl, molecular formula: C4H6Cl2; (b) empirical formula: CH4N, molecular formula: C2H8N2 F.23 45.1% G.1 (a) false. They can only be separated by chemical methods. (b) true. (c) false. The properties of a compound are unlike those of the elements that compose it. G.3 (a) heterogeneous, decanting; (b) heterogeneous, dissolving followed by filtration and distillation; (c) homogeneous, distillation G.5 Measure 482.2 g H2O on a balance and pour it into a beaker. Then weigh 27.8 g of K2NO3 and mix it with the water until it totally dissolves. G.7 15.2 g G.9 (a) 13.5 mL; (b) 62.5 mL; (c) 5.92 mL G.11 (a) Weigh 1.6 g (0.010 mol, molar mass of KMnO4 ϭ 158.04 gиmolϪ1 ) into a 1.0-L volumetric flask and add water to give a total volume of 1.0 L. Smaller (or larger) volumes could also be prepared by using a proportionally smaller (or larger) mass of KMnO4. (b) Starting with 0.050 molиLϪ1 KMnO4, add four volumes of water to one volume of starting solution, because the concentration desired is onefifth of that of the starting solution. This relation can be derived from the expression Vi ϫ molarityi ϭ Vf ϫ molarityf where i represents the initial solution and f the final solution. For example, to prepare 50 mL of solution, you would add 40 mL of water to 10 mL of 0.050 molиLϪ1 KMnO4. G.13 (a) 4.51 mL. (b) Add 48.0 mL of water to 12.0 mL of 2.5 molиLϪ1 NaOH. G.15 (a) 8.0 g; (b) 12. g G.17 (a) 4.58 ϫ 10Ϫ2 gиmolϪ1 ; (b) 9.07 ϫ 10Ϫ3 gиmolϪ1 G.19 (a) 21.8 g; (b) 0.24 g; (c) 60 g G.21 0.13 M ClϪ (aq) G.23 Less than one molecule will be left after 69 doublings; no health benefits. G.25 600. mL G.27 The level that the instrument can detect: 2.07 ppb Ͻ 10 ppb. The instrument can detect levels lower than 10 ppb. It is satisfactory. H.1 (a) You cannot add a different compound or element to the chemical equation which is not produced (or involved) in the chemical reaction. In this case, an O atom is not produced by the defined reaction. (b) 2 Cu ϩ SO2 : 2 CuO ϩ S H.3 2 SiH4 ϩ 4 H2O : 2 SiO2 ϩ 8 H2 H.5 (a) NaBH4(s) ϩ 2 H2O(l) : NaBO2(aq) ϩ 4 H2(g) (b) Mg(N3)2(s) ϩ 2 H2O(l) : Mg(OH)2(aq) ϩ 2 HN3(aq) (c) 2 NaCl(aq) ϩ SO3(g) ϩ H2O(l) : Na2SO4(aq) ϩ 2 HCl(aq) (d) 4 Fe2P(s) ϩ 18 S(s) : P4S10(s) ϩ 8 FeS(s) H.7 (a) Ca(s) ϩ 2 H2O(l) : H2(g) ϩ Ca(OH)2(aq) (b) Na2O(s) ϩ H2O(l) : 2 NaOH(aq) (c) 3 Mg(s) ϩ N2(g) : Mg3N2(s) (d) 4 NH3(g) ϩ 7 O2(g) : 6 H2O(g) ϩ 4 NO2(g) H.9 (I) 3 Fe2O3(s) ϩ CO(g) : 2 Fe3O4(s) ϩ CO2(g) (II) : H.11 (I) : (II) : H.13 : H.15 : H.17 : H.19 2 C10H15N(s) ϩ 26 O2(g) : 19 CO2(g) ϩ 13 H2O(l) ϩ CH4N2O(aq) H.21 (I) : (II) : (III) 2 Na2S5(alc) ϩ 9 O2(g) ϩ 10 H2O(l) : 2Na2S2O3и5H2O(s) ϩ 6 SO2(g) H.23 (a) P2O5, P2O3; (b) P4O10 (phosphorus(V) oxide); P4O6 (phosphorus(III) oxide); (c) P4(s) ϩ 3 O2(g) : P4O6(s); P4(s) ϩ 5 O2(g) : P4O10(s) Na2S 5(alc) + 4 H2(g)4 H2S(g) + Na2S(alc) Na2S(aq) + 2H2O(l)H2S(g) + 2NaOH(s) + 9 H2O(l) + N2 ( g )14 CO2(g) C14H18 N2O5(s) + 16 O2(g) + 8 H2O(g)7 CO2(g)C7H16(l) + 11 O2(g) SiF4(aq) + 2 H2O(l)4 HF(aq) + SiO2(s) 2 NO2(g)2 NO(g) + O2(g) 2 NO(g)N2(g) + O2(g) 3 Fe(s) + 4 CO2(g)Fe3O4(s) + 4 CO(g) I.1 The picture would show a precipitate, CaSO4(s), at the bottom of the flask composed of red and pink particles in a 1:1 ratio. Sodium (black) and chloride (blue) ions, NaCl(aq), would remain throughout the solution. I.3 (a) dilute H2SO4, Pb2ϩ (aq) ϩ SO4 2Ϫ (aq) : PbSO4(s) (b) H2S solution, Mg2ϩ (aq) ϩ S2Ϫ (aq) : MgS(s) I.5 (a) nonelectrolyte; (b) strong electrolyte; (c) strong electrolyte I.7 (a) soluble; (b) slightly soluble; (c) insoluble; (d) insoluble I.9 (a) (b) ; (c) ; (d) I.11 (a) , precipitate; (b) , precipitate forms; (c) no precipitate I.13 (a) : ; Naϩ , ClϪ (b) : ; (c) : ; (d) : ; (e) : ; I.15 (a) overall equation: : complete ionic equation: 2 NH4 ϩ (aq) ϩ CrO4 2Ϫ (aq) ϩ Ba2ϩ (aq) ϩ 2ClϪ (aq) : BaCrO4(s) ϩ2 NH4 ϩ (aq) ϩ 2 CIϪ (aq) : (b) : complete ionic equation: : : (c) : complete ionic equation: 3 Fe2ϩ (aq) ϩ 6 ClϪ (aq) ϩ 6 NH4 ϩ (aq) ϩ 2 PO4 3Ϫ (aq) : Fe3(PO4)2(s) ϩ 6 NH4 ϩ (aq) ϩ 6 ClϪ (aq) : (d) : complete ionic equation: 2 Kϩ (aq) ϩ C2O4 2Ϫ (aq) ϩ Ca2ϩ (aq) ϩ 2 NO3 Ϫ (aq) : CaC2O4(s) ϩ 2Kϩ (aq) ϩ 2 NO3 Ϫ (aq) : (e) : complete ionic equation: : : I.17 (a) : Ba(aq) ϩ 2 CH3CO2 Ϫ (aq) ϩ 2 Liϩ (aq) ϩ CO3 2Ϫ (aq) : (b) 2 NH4Cl(aq) ϩ Hg2(NO3)2(aq) : 2 NH4NO3(aq) ϩ Hg2Cl2(s) : : (c) Cu(NO3)2(aq) ϩ Ba(OH)2 (aq) : Cu(OH)2(s) ϩ Ba(NO3)2(aq) : net ionic equation: : Cu(OH)2(s)Cu2+ (aq) + 2 OH- (aq) Cu(OH)2(s) + Ba2+ (aq) + 2 NO3 - (aq) Cu2+ (aq) + 2 NO3 (aq) + Ba2+ (aq) + 2 OH- (aq) Hg2Cl2(s)net ionic equation: Hg2 2+ (aq) + 2 Cl- (aq) Hg2Cl2(s) + 2 NH4 + (aq) + 2 NO3 - (aq) 2 NH4 + (aq) + 2 Cl(aq) + Hg2 2+ (aq) + 2 NO3 - (aq) net ionic equation: Ba2+ (aq) + CO3 2(aq) : BaCO3(s) BaCO3(s) + 2 Li+ (aq) + 2 CH3CO2 - (aq) BaCO3(s) + 2 LiCH3CO2(aq) Ba(CH3CO2)2(aq) + Li2CO3(aq) spectator ions: Ni2+ , NO3 BaSO4(s)net ionic equation: Ba2+ (aq) + SO4 2- (aq) Ni2+ (aq) + 2 NO3 (aq) + BaSO4(s) Ni2+ (aq) + SO4 2(aq) + Ba2+ (aq) + 2 NO3 - (aq) Ni(NO3)2(aq) + BaSO4(s)NiSO4(aq) + Ba(NO3)2(aq) spectator ions: K+ , NO3 CaC2O4(s)net ionic equation: Ca2+ (aq) + C2O4 2- (aq) CaC2O4(s) + 2 KNO3(aq)K2C2O4(aq) + Ca(NO3)2(aq) spectator ions: Cl, NH4 + Fe3(PO4)2(s)net ionic equation: 3 Fe2+ (aq) + 2 PO4 3- (aq) Fe3(PO4)2(s) + 6 NH4Cl(aq)3 FeCl2(aq) + 2 (NH4)3PO4(aq) spectator ions: Na+ , SO4 2CuS(s)net ionic equation: Cu2+ (aq) + S2- (aq) CuS(s) + 2 Na+ (aq) + SO4 2- (aq) Cu2+ (aq) + SO4 2(aq) + 2 Na+ (aq) + S2- (aq) CuS(s) + Na2SO4(aq)CuSO4(aq) + Na2S(aq) spectator ions: NH4 + , ClBaCrO4(s)net ionic equation: Ba2+ (aq) + CrO4 2- (aq) BaCrO4(s) + 2 NH4Cl(aq) (NH4)2CrO4(aq) + BaCl2(aq) spectator ions: K+ , NO3 Hg2SO4(s)net ionic equation: Hg2 2+ (aq) + SO4 2- (aq) spectator ions: Na+ , NO3 PbCrO4(s)net ionic equation: Pb2+ (aq) + CrO4 2- (aq) spectator ions: NO3 , K+ CaSO4(s)net ionic equation: Ca2+ (aq) + SO4 2- (aq) spectator ions: K+ , NO3 PbI2(s)net ionic equation: Pb2+ (aq) + 2 I- (aq) FeS(s)Fe2+ (aq) + S2- (aq) Ag2CO3Fe(OH)3 Fe2+ (aq) and SO4 2- (aq)NH4 + (aq) and PO4 3- (aq) Ag+ (aq) and CO3 2(aq), Ag2CO3 is insoluble Na+ (aq) and I- (aq); C12 ANSWERS I.19 (a) ; (b) ; (c) I.21 (a) : (b) : (c) : (d) ; Hg(CH3CO2)2 and Li2S; Liϩ , CH3CO2 Ϫ ; I.23 white ppt ϭ AgCl(s), Agϩ ; no ppt with H2SO4, no Ca2ϩ ; black ppt ϭ ZnS, Zn2ϩ I.25 (a) : complete ionic equation: : net ionic equation: : (b) 0.0800 M I.27 (a) 0.357 M; (b) 2.09 g; (c) MgCrO4 J.1 (a) base; (b) acid; (c) base; (d) acid; (e) base J.3 (a) overall equation: : complete ionic equation: : net ionic equation: : (b) overall equation: : complete ionic equation: : net ionic equation: : (c) overall equation: : complete ionic equation: : net ionic equation: : J.5 (a) : (b) : (c) : (d) : J.7 (a) acid: base: ; (b) acid: base: ; (c) acid: ; base: CaO(s) J.9 (a) CHO2; (b) C2H2O4; (c) (COOH)2(aq) ϩ 2 NaOH(aq) : Na2C2O4(aq) ϩ 2 H2O(l) net ionic equation: (COOH)2(aq) ϩ 2 OHϪ : C2O4 2Ϫ (aq) ϩ 2 H2O(l) J.11 (a) C6H5OϪ (aq) ϩ H2O(l) : C6H5OH(aq) ϩ OHϪ (aq) (b) ClOϪ (aq) ϩ H2O(l) : HClO(aq) ϩ OHϪ (aq) (c) C5H5NHϩ (aq) ϩ H2O(l) : C5H5N(aq) ϩ H3Oϩ (aq) (d) NH4 ϩ (aq) ϩ H2O(l) : NH3(aq) ϩ H3Oϩ (aq) J.13 (a) AsO4 3Ϫ (aq) ϩ H2O(l) : HAsO4 2Ϫ (aq) ϩ OHϪ (aq) HAsO4 2Ϫ (aq) ϩ H2O(l) : H2AsO4 Ϫ (aq) ϩ OHϪ (aq) H2AsO4 Ϫ (aq) ϩ H2O(l) : H3AsO4(aq) ϩ OHϪ (aq) In each equation, H2O is the acid. (b) 0.505 mol J.15 (a) CO2(g) ϩ H2O(l) : H2CO3(aq) (carbonic acid) (b) SO3(g) ϩ H2O(l) : H2SO4(aq) (sulfuric acid) K.1 (a) : (b) : (c) : (d) : K.3 (a) : (b) : (c) : (d) : 2 Fe2O3(s)4 Fe(s) + 3 O2(g) 2 HCl(g)H2(g) + Cl2(g) Fe3+ (aq) + Ce3+ (aq)Fe2+ (aq) + Ce4+ (aq) Mg2+ (aq) + Cu(s)Mg(s) + Cu2+ (aq) 2 AsCl3(l)2 As(s) + 3 Cl2(g) 2 Cr3+ (aq) + Sn2+ (aq)2 Cr2+ (aq) + Sn4+ (aq) 8 Na2S(s)S8(s) + 16 Na(s) N2O5(g) + O2(g)2 NO2(g) + O3(g) HI(aq)C2H5NH2(aq) HCl(aq);CH3NH2(aq)H3O+ (aq); K3PO4(aq) + 3 H2O(l)3 KOH(aq) + H3PO4(aq) Ca(CN)2(aq) + 2 H2O(l)Ca(OH)2(aq) + 2 HCN(aq) Zn(NO2)2(aq) + 2 H2O(l)Zn(OH)2(aq) + 2 HNO2(aq) KBr(aq) + H2O(l)HBr(aq) + KOH(aq) 2 H2O(l)OH(aq) + H3O+ (aq) Li+ (aq) + I(aq) + 2 H2O(l) Li+ (aq) + OH(aq) + H3O+ (aq) + I- (aq) LiI(aq) + H2O(l)LiOH(aq) + HI(aq) (CH3)3NH+ (aq) + H2O(l) (CH3)3N(aq) + H3O+ (aq) (CH3)3NH+ (aq) + NO3 (aq) + H2O(l) (CH3)3N(aq) + H3O+ (aq) + NO3 - (aq) (CH3)3NHNO3(aq)(CH3)3N(aq) + HNO3(aq) F(aq) + H2O(l)HF(aq) + OH- (aq) Na+ (aq) + F(aq) + H2O(l) HF(aq) + Na+ (aq) + OH- (aq) NaF(aq) + H2O(l) HF(aq) + NaOH(aq) Cu(OH)2(s)Cu2+ (aq) + 2 OH- (aq) Cu(OH)2(s) + 2 Na+ (aq) + 2 NO - 3 (aq) 2 Na+ (aq) + 2 OH(aq) + Cu2+ (aq) + 2 NO - 3 (aq) Cu(OH)2(s) + 2 NaNO3(aq) 2 NaOH(aq) + Cu(NO3)2(aq) CaCl2 and K3PO4; K+ , ClAgNO3 and Na2SO4; Na+ , NO3 Ca3(PO4)2(s)3 Ca2+ (aq) + 2 PO4 3- (aq) HgS(s)Hg2+ (aq) + S2- (aq) Ag2SO4(s)2 Ag+ (aq) + SO4 2- (aq) Cd(ClO4)2 and (NH4)2S CaCl2 and Na2CO3AgNO3 and Na2CrO4 K.5 (a) ϩ4; (b) ϩ4; (c) Ϫ2; (d) ϩ5; (e) ϩ1; (f) 0 K.7 (a) ϩ2; (b) ϩ2; (c) ϩ6; (d) ϩ4; (e) ϩ1 K.9 (a) oxidized: (aq), reduced: . (b) oxidized: some sulfur; reduced: Mo. (c) is both oxidized and reduced. K.11 (a) will be reduced more easily and is therefore a stronger oxidizing agent than (b) will be a stronger oxidizing agent because it will be readily reduced. will accept more readily than will K.13 (a) oxidizing agent: in HCl(aq); reducing agent: Zn(s); (b) oxidizing agent: ; reducing agent: ; (c) oxidizing agent: reducing agent: Mg(s) K.15 (a) reducing agent, Cl goes from ϩ7 to ϩ4; (b) reducing agent, S goes from ϩ6 to ϩ4 K.17 CO2(g) ϩ 4 H2(g) : CH4(g) ϩ 2 H2O(l); oxidation–reduction reaction K.19 (a) oxidizing agent: ; reducing agent: (b) oxidizing agent: HCl; reducing agent: Mg(s) (c) oxidizing agent: reducing agent: C(s) (d) oxidizing agent: ; reducing agent: K.21 (a) 3 N2H4(l) : 4 NH3(g) ϩ N2(g). (b) Ϫ2 in N2H4; Ϫ3 in NH3, 0 in N2. (c) N2H4 is both oxidizing and reducing agent. (d) 2.5 ϫ 102 L K.23 (a) 2 Cr2ϩ ϩ Cu2ϩ : 2 Cr3ϩ ϩ Cu(s); (b) 2 e_ transferred; (c) 2.27 M NO3 Ϫ , 1.50 M SO4 2Ϫ K.25 (a) SiCl4(l) ϩ 2 H2(g) : Si(s) ϩ 4 HCl(g); silicon tetrachloride; Si4ϩ (b) SnO2(s) ϩ C(s) : Sn(l) ϩ CO2; tin(IV) oxide; Sn4ϩ (c) V2O5(s) ϩ 5 Ca(l) : 2 V(s) ϩ 5 CaO(s); vanadium(V) oxide; V5ϩ (d) B2O3(s) ϩ 3 Mg(s) : 2 B(s) ϩ 3 MgO(s); boron oxide; B3ϩ K.27 (a) Cl2(g) ϩ H2O(l) : HClO(aq) ϩ HCl(aq) oxidizing agent: Cl2(g); reducing agent: Cl2(g) (b) 2 NaClO3(aq) ϩ SO2(g) ϩ H2SO4(aq, dilute) : 2 NaHSO4(aq) ϩ 2 ClO2(g) oxidizing agent: NaClO3(aq); reducing agent: SO2(g) (c) 2 CuI(aq) : 2 Cu(s) ϩ I2(s) oxidizing agent: CuI(aq); reducing agent: CuI(aq) L.1 (a) 8.6 ϫ 10Ϫ5 mol H2; (b) 11.3 g Li3N L.3 (a) 507.1 g Al; (b) 6.613 ϫ 106 g Al2O3 L.5 (a) 505 g; (b) 1.33 ϫ 103 g L.7 4.2 kg L.9 0.482 g L.11 (a) 0.271 molиLϪ1 ; (b) 0.163 g L.13 (a) 0.209 molиLϪ1 ; (b) 0.329 g L.15 63.0 gиmolϪ1 L.17 0.150 M AgNO3(aq) L.19 (a) : ; (b) L.21 : L.23 (a) S2O3 2Ϫ is both oxidized and reduced. (b) 11.1 g L.25 Pt L.27 : L.29 509 kg Fe L.31 (a) Pipette 31 mL of 16 M HNO3 into a 1.00-L volumetric flask which contains about 800 mL of H2O. Dilute to the mark with H2O. Shake the flask to mix the solution thoroughly. (b) 2.5 ϫ 102 mL L.33 (a) SnO2; (b) tin(IV) oxide L.35 (a) no effect; (b) too high; (c) too high; (d) too high M.1 93.1% M.3 (a) B2O3(s) ϩ 3 Mg(s) : 3 MgO(s) ϩ2 B(s); (b) 3.71 ϫ 104 g M.5 6 Cl atoms M.7 (a) ; (b) 5.77 g; (c) 5.7 g M.9 (a) Cu2ϩ (aq) ϩ 2 OHϪ (aq) : Cu(OH)2(s); (b) 2.44 g M.11 : M.13 C8H16N4O3 M.15 (a) ; (b) 130 gCa3(PO4)2 16 CO2(g) + 10 H2O(l) + 4 N2(g) 2 C8H10N4O2(s) + 19 O2(g) O2 BaCl2 + Br2x = 2, BaBr2 + Cl2 3 I+ Sn4+ I - 3 + Sn2+ 12.6 molиL-1 . 2 NaCl(aq) + H2CO3(aq)Na2CO3(aq) + 2 HCl(aq) N2H4(g)N2O4(g) SnO2(s); H2(g)WO3(s) B2O3(s); H2S(g)SO2(g) H+ N+ . e- N5+ N2O5Cl- . Cl2 Tl+ O2(g)CH3OH ODD-NUMBERED EXERCISES C13 M.17 93.0% M.19 (a) C11H14O3; (b) C22H28O6. M.21 The empirical and molecular formulas are both CHOCl. M.23 81.2% M.25 (a) 2 Al(s) ϩ 3 Cl2(g) : 2 AlCl3(s); (b) 671. g; (c) 44.7% Chapter 1 1.1 (a) Radiation may pass through a metal foil. (b) All light (electromagnetic radiation) travels at the same speed; the slower speed supports the particle model. (c) This observation supports the radiation model. (d) This observation supports the particle model; electromagnetic radiation has no mass and no charge. 1.3 microwaves Ͻ visible light Ͻ ultraviolet light Ͻ x-rays Ͻ ␥-rays 1.5 8.7 ϫ 1014 Hz, 340 nm, 5.8 ϫ 10Ϫ19 J, suntan; 5.0 ϫ 1014 Hz, 600 nm, 3.3 ϫ 10Ϫ19 J, reading; 300 MHz 1 m, 2 ϫ 10Ϫ25 J, microwave popcorn; 1.2 ϫ 1017 Hz, 2.5 nm, 7.9 ϫ 10Ϫ17 J, dental x-ray 1.7 (a) 486 nm; (b) Balmer series; (c) visible, blue 1.9 For the Lyman series, the lower energy level is for the Balmer series, for the Paschen series, and for the Brackett series, 1.11 30.4 nm 1.13 (a) false; (b) true; (c) false 1.15 1590 nm 1.17 8.8237 pm 1.19 (a) 3.37 ϫ 10Ϫ19 J; (b) 44.1 J (c) 203 kJ 1.21 1.4 ϫ 1020 photons 1.23 (a) 2.0 ϫ 10Ϫ10 m; (b) 1.66 ϫ 10Ϫ17 J; (c) 8.8 nm; (d) x-ray/gamma ray 1.25 1.1 ϫ 10Ϫ34 m 1.27 3.96 ϫ 103 mиsϪ1 1.29 1.65 ϫ 105 mиsϪ1 1.31 Yes. The first three cases of degenerate levels are: ; ; . 1.33 (a) 1.48 ϫ 10Ϫ8 m; (b) 6.18 ϫ 10Ϫ9 m 1.35 (a) (b) one node at x ϭ 0.500 m. (c) two nodes, at x ϭ 0.333 and 0.667 m. (d) The number of nodes is equal to . (e) x ϭ 0.25 m and x ϭ 0.75 m. (f) x ϭ 0.17, 0.50, and 0.83 m. 1.37 (b) no 1.39 0.33 1.41 With one electron in each p-orbital, the electron distribution is not a function of ␪ or ␾ and is, therefore, spherically symmetric. 1.43 (a) 32.3%; (b) 76.1% 1.45 (a) n - 1 0.00 0.333 0.500 0.667 1.00 x (m) 1.42 0.00 Ϫ1.42 n ϭ 2 n ϭ 3 ␺(x)/mϪ1/2 n1 = 2, n2 = 3 is degenerate with n1 = 3, n2 = 2 n1 = 1, n2 = 3 is degenerate with n1 = 3, n2 = 1 n1 = 1, n2 = 2 is degenerate with n1 = 2, n2 = 1 n = 4. n = 3;n = 2; n = 1; (b) A node is a region in space where the wavefunction passes through 0. (c) The simplest s-orbital has 0 nodes, the simplest p-orbital has 1 nodal plane, and the simplest d-orbital has 2 nodal planes. (d) three nodal planes. 1.47 The px-orbital will have its lobes oriented along the x axis, the py-orbital will have its lobes oriented along the y axis, and the pz-orbital will have its lobes oriented along the z axis. 1.49 (a) 1; (b) 5; (c) 3; (d) 7 1.51 (a) 7; (b) 5; (c) 3; (d) 4 1.53 (a) (b) (c) (d) 1.55 (a) (b) (c) (d) 1.57 (a) 6; (b) 10; (c) 2; (d) 14 1.59 (a) 5d, 5; (b) 1s, 1; (c) 6f, 7; (d) 2p, 3 1.61 (a) 6; (b) 2; (c) 8; (d) 2 1.63 (a) cannot exist; (b) exists; (c) cannot exist; (d) exists 1.65 (a) (b) The first term represents the coulombic attractions between the nucleus and each electron, and the second term represents the coulombic repulsions between each pair of electrons. 1.67 (a) false. is considerably affected by the total number of electrons present in the atom because the electrons in the lower energy orbitals will “shield” the electrons in the higher energy orbitals from the nucleus. This effect arises because the e–e repulsions tend to offset the attraction of the electron to the nucleus. (b) true. (c) false. The electrons are increasingly less able to penetrate to the nucleus as increases. (d) true 1.69 (a) excited state; (b) excited state; (c) excited state; (d) ground state 1.71 (a) possible; (b) not possible; (c) not possible 1.73 (a) ; (b) ; (c) ; (d) ; (e) ; (f) 1.75 (a) tellurium; (b) vanadium; (c) carbon; (d) thorium 1.77 (a) 4p; (b) 4s; (c) 6s; (d) 6s 1.79 (a) 5; (b) 11; (c) 5; (d) 20 1.81 (a) 3; (b) 2; (c) 3; (d) 2 1.83 Ga: , 1; Ge: , 2; As: , 3; Se: , 2; Br: , 1 1.85 (a) ; (b) (c) (d) 1.87 (a) silicon Ͼ sulfur Ͼ chlorine; (b) titanium Ͼ chromium Ͼ cobalt; (c) mercury Ͼ cadmium Ͼ zinc; (d) bismuth Ͼ antimony Ͼ phosphorus 1.89 1.91 (a) Ca; (b) Na; (c) Na 1.93 (a) Oxygen Ͼ selenium Ͼ tellurium; ionization energies generally decrease as one goes down a group. (b) Gold Ͼ osmium Ͼ tantalum; ionization energies generally decrease as one goes from right to left in the periodic table. (c) Lead Ͼ barium Ͼ cesium; ionization energies generally decrease as one goes from right to left in the periodic table. 1.95 (a) fluorine; (b) carbon; (c) chlorine; (d) lithium 1.97 (a) The inert-pair effect is the term used to describe the fact that heavy (Period 5 and greater) p-block elements have a tendency to form ions that are two units lower in charge than that expected based on their group number. (b) The inert-pair effect is presumed to be observed only for heavy elements because of the poor shielding ability of the d-electrons in these elements, enhancing the ability of the s-electrons to penetrate to the nucleus and therefore be bound tighter than expected. 1.99 (a) A diagonal relationship is a similarity in chemical properties between an element in the periodic table and one lying one period lower and one group to the right. (b) It is caused by the similarity in size of the ions. The lower-right element in the pair would generally be larger because it lies in a higher period, but it also will have a higher oxidation P3- 7 S2- 7 Cl(n - 1)d10 ns1 (n - 1)d5 ns2 ;ns2 p3 ;ns1 3Ar] 3d10 4s2 4p5 3Ar] 3d10 4s2 4p4 3Ar] 3d10 4s2 4p3 3Ar] 3d10 4s2 4p2 3Ar] 3d10 4s2 4p1 3Kr]4d10 5s2 5p5 3Xe]4f14 5d4 6s2 3Ar43d10 4s2 4p1 3Kr44d10 5s2 5p3 3He]2s2 3Kr]4d10 5s1 l Zeff + e2 4␲E0 a 1 r12 + 1 r13 + 1 r23 b V(r) = a -3e2 4␲E0 b a 1 r2 + 1 r2 + 1 r3 b -3, -2, -1, 0, +1, +2, +3. -1, 0, +1; -2, -1, 0, +1, +2; -1, 0, +1; n = 5; l = 3 n = 2; l = 1;n = 3; l = 2;n = 6; l = 1; c 1s 3d2p C14 ANSWERS state, which will cause the ion to be smaller. (c) For example, and compounds show the diagonal relationship, as do 1.101 (b) Li and Mg 1.103 The ionization energies of the s-block metals are considerably lower, thus making it easier for them to lose electrons in chemical reactions. 1.105 (a) metal; (b) nonmetal; (c) metal; (d) metalloid; (e) metalloid; (f) metal 1.107 (a) The observed values correspond respectively to the second and first ionization energies of Li (1s2 2s1 ). (b) The PES values observed correspond respectively to the second and first ionization energies of Be (1s2 2s2 ). 1.109 (a) 1.1 ϫ 1014 sϪ1 ; (b) 7.2 ϫ 10Ϫ20 J; (c) 43 kJиmolϪ1 1.111 A ground-state oxygen atom has four electrons in the p-orbitals. This configuration means that as one goes across the periodic table in Period 2, oxygen is the first element encountered in which the p-electrons must be paired. This added electron–electron repulsion energy causes the ionization energy to be lower. 1.113 The molar volume roughly parallels atomic size (volume), which decreases as the s-subshell begins to fill and subsequently increases as the p-subshell fills (refer to the text discussion of periodic variation of atomic radii). In the above plot, this effect is most clearly seen in passing from Ne(10) to Na(11) and Mg(12), then to Al(13) and Si(14). Ne has a filled 2p-subshell; the 3s-subshell fills with Na and Mg; and the 3p-subshell begins to fill with Al. 1.115 In general, as the principal quantum number increases, the energy spacing between orbitals becomes smaller. This trend indicates that it does not take very much change in electronic structure to cause the normal orbital energy pattern to rearrange. 1.117 (a) (b) Below is a plot of the first two wavefunctions describing the onedimensional particle-in-a-box and the product of these two wavefunctions. Notice that the area above zero in the product exactly cancels the area below zero, making the integral of the product zero. This happens whenever a wavefunction that is unaltered by a reflection through the center of the box (wavefunctions with odd n) is multiplied by a wavefunction that changes sign everywhere when reflected through the center of the box (wavefunctions with even n). 1.119 (a) no; (b) increase 1.121 (a) 9.35 ϫ 10Ϫ18 J. (b) x-ray. (c) 9.35 ϫ 10Ϫ24 J. (d) The individual energy levels get closer as the chain gets longer. n ϭ 1 0 L x 0 L x ␺ n ϭ 2␺ n ϭ 1)((␺ n ϭ 2)␺ L 2␲ asin ␲иx L b - L 6␲ asin 3␲иx L b Η L 0 = 0 3 L 0 a sin ␲иx L b и a sin 2␲иx L b dx = 10 Atomic number 30 25 20 15 10 5 0 0 5 s sp p 15 20 Molarvolume(cm3 иmolϪ1 ) (900 kJиmol-1 )(1760 kJиmol-1 ) (1.6 MJиmol-1 and 0.90 MJиmol-1 ) (519 kJиmol-1 ) (7300 kJиmol-1 ) (7.30 MJиmol-1 and 0.52 MJиmol-1 ) Li+ and Mg2+ .Ge4+ Al3+ 1.123 (a) In copper, it is energetically favorable for an electron to be promoted from the 4s-orbital to a 3d-orbital, giving a completely filled 3d-subshell. In the case of Cr, it is energetically favorable for an electron to be promoted from the 4s-orbital to a 3d-orbital to exactly fill the 3d-subshell. (b) From Appendix 2C, the other elements for which anomalous electron configurations exist are Nb, Mo, Ru, Rh, Pd, Ag, Pt, and Au. Of these, the explanation used for chromium and copper is valid for Mo, Pd, Ag, and Au. (c) Because the np-orbitals are so much lower in energy than the (n ϩ 1)s-orbitals, no elements are known where the (n ϩ 1)s-orbitals fill in preference to the np-orbitals. 1.125 The element must be either tin or hafnium. 1.127 (a) 285 pm; (b) 194 pm; (c) 356 kJиmolϪ1 1.129 A ϭ Na; B ϭ Cl; C ϭ Naϩ ; D ϭ ClϪ . The assignments can be made by looking at neutral atom and ionic radii (Figures 1.46 and 1.48) 1.131 (a) ; ; argon; (b) ; (c) 52.0 nm; (d) 2.30 ϫ 103 kJиmolϪ1 or 23.8 eV; (e) 35.73 gиmolϪ1 ; (f)–(h) ClO2, ϩ4, chlorine dioxide; NaClO, ϩ1, sodium hypochlorite; KClO3, ϩ5, potassium chlorate; NaClO4, ϩ7, sodium perchlorate Chapter 2 2.1 (a) 5; (b) 4; (c) 7; (d) 3 2.3 (a) [Ar]; (b) (c) (d) 2.5 (a) (b) (c) (d) 2.7 (a) same. Inϩ and Sn2ϩ lose 5p valence electrons. (b) none. (c) Pd 2.9 (a) (b) (c) (d) 2.11 (a) (b) (c) (d) 2.13 (a) 4s; (b) 3p; (c) 3p; (d) 4s 2.15 (a) ; (b) ; (c) ϩ1; (d) ϩ3; (e) ϩ2 2.17 (a) 3; (b) 6; (c) 6; (d) 2 2.19 (a) no unpaired electrons; (b) no unpaired electrons; (c) four unpaired electrons; (d) [Kr]; no unpaired electrons; (e) two unpaired electrons 2.21 (a) [Ar]; no unpaired electrons; (b) no unpaired electrons; (c) [Xe]; no unpaired electrons; (d) no unpaired electrons. 2.23 (a) ϩ7. (b) . (c) [Ne] for ϩ7, [Ar] for . (d) Electrons are lost or added to give noble-gas configuration. 2.25 (a) (b) ; (c) (d) (e) 2.27 (a) (b) (c) 2.29 (b) 2.31 The ion is smaller than the ion (58 versus 149 pm). Because the lattice energy is related to the coulombic attraction between the ions, it will be inversely proportional to the distance between the ions. 2.33 (a) (b) (c) (d) 2.35 (a) (b) (c) 2.37 (a) (b) H C H H Oß ß Hß å å H C O Hß ß ƒ N ß H H Ϫ åBr ß O Ϫ H H H Hß ßB Ϫ å å F F Nß ®F å O N£ ®F Cl O C® ® Cl ™ Cl Cl Cl C® ® å å Cl Rb+ Li+ Ga3+ , O2- MnO2Al2S3;TlCl3; BiF3H2Te;AlH3;In2S3Mg3As2; -1-1 [Kr]4d10 ; [Kr]4d10 5s2 ; [Ar]3d8 ; [Xe]4f14 5d4 ; [Kr]4d10 ;[Kr]4d10 5s2 ; -2-2 Mo3+ Ru3+ ;Fe3+ ;Co3+ ; Nb2+ Mo2+ ;Fe2+ ;Co2+ ; [Kr]4d10 ; [Kr]4d10 5s2 ; [Xe]4f14 5d10 [Ar]3d10 ;[Xe]4f14 5d10 6s2 ;[Ar]3d10 ; [Ar]3d10 4s2 [Kr]4d5 ;[Ar]3d10 4s2 ; 3Ne]3s2 3p4 4s1 3Ne]3s2 3p6 3Ne]3s2 3p5 1 2 ODD-NUMBERED EXERCISES C15 (c) 2.39 (a) (b) (c) 2.41 P 2.43 (a) (b) (c) 2.45 2.47 2.49 (a) (b) (c) (d) (e) 2.51 (a) (b) (c) 2.53 (b) and (c) H Cß ¥ ¥ N£ 0 Ϫ1 ϩ1 H Cß ¥ N 00 0 lower energy £ß O Cß ¥ ¥ ¥ ¥ ¥ S 0Ϫ1 ϩ1 £ßO C£ ¥ ¥ ¥ S ¥ £ 00 0 lower energy O Clß O HO ß å å Ϫ1 Ϫ1 ϩ2 0O Cl£ O HO ß ™ å 0 0 00 lower energy C ¥ ¥ N Ϫ1 0 ΅ Ϫ £ßC ¥ ¥ C Ϫ1 Ϫ1 ΅ Ϫ2 £ß C ¥ ¥ O Ϫ1 ϩ1 £ßN ¥ ¥ N 0 0 £ßN ¥ ¥ O 0 ϩ1 ΅ ϩ £ß O Cl Nß £ ¥ ¥¥ ¥ ¥ ¥ ¥ ¥ å OO Cl N£ ® ¥ ¥¥ ¥ ¥ ¥ ¥ ¥ å O 1 2 3 4 5 6 7 8 9 10 11 12 13 14C C C H H H H C C C C C C H H C C H H H H C C C 1 2 3 4 5 6 7 8 9 10 11 12 13 14C C C H H H H C C C C C C H H C C H H H H C C C C C C H H H H C C C C C C H H C C H H H H C C C 1 2 3 4 5 6 7 8 9 10 11 12 13 14C C C H H H H C C C C C C H H C C H H H H C C C 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Cl OßNaϩƒ † ƒ † Ϫ P Kϩ Kϩ ƒ†ƒ† 3Ϫ Kϩ H H H N Hß ß å å Cl Ϫ ϩ Cl H H C® ® å å Cl S C S ™ ™ H C H H Sß ß Hß å å C H O Hß ßß ƒ å C H H ßH Nß ß å å AA A O A A 2.55 (a) (b) (c) 2.57 (a) (b) (c) (a) is a radical. 2.59 (a) 2 bonding, 2 lone pairs; (b) 4 bonding, 2 lone pairs; (c) 3 bonding, 2 lone pairs; (d) 5 bonding, 1 lone pair 2.61 (a) (b) F Xe ¥ ¥ F ¥ ¥ ¥ ¥ ¥ å å 2™ 10 electrons F F F F F F S ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ å åœ œ ç ç 12 electrons Clß ¥ ¥ O ß ¥ ¥ ¥ O N£ ¥ ¥ O ¥ ¥ ¥ å Cl ClOß ß ¥ ¥ ¥ ¥ ¥¥ O ß ¥ ¥ ¥ ¥ Cl Oß z ¥ ¥ ¥ ¥ ¥ O N£ß ¥ ¥ ¥ ¥ ¥ ¥ O Ϫ O Nߣ ¥ ¥ ¥ ¥ ¥ ¥ O Ϫ O Cl ߣ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ ™ ™ O Cl ££ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ O Ϫ å ™ O Cl £ß ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ ™ ™ O Cl ££ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ å ™ O Cl ßß ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ ¥ O Ϫ å å O S ß ß £ ¥ ¥ ¥ ¥ ¥ ¥ ¥ OH ¥ O Ϫ å O S £ ß ß ¥ ¥ ¥ ¥ ¥ ¥ ¥ OH ¥ O Ϫ å O S ß ß ß ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ OH ¥ O Ϫ å O S £ß ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O 2Ϫ å O S ßß ¥ ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O 2Ϫ ™ O S ߣ ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O 2Ϫ å O S ßß ¥ ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O 2Ϫ å C16 ANSWERS (c) (d) 2.63 (a) (b) (c) 2.65 (a) In BeCl2, there are 4 electrons around the central beryllium atom: . (b) In ClO2 there are an odd number of electrons around the central chlorine atom: . 2.67 (a) (b) 2.69 (a) In the first structure, the formal charges at Xe and F are 0, whereas in the second structure, Xe is , one F is 0, and the other F is ϩ1. The first structure is favored on the basis of formal charges. (b) In the first structure, all of the atoms have formal charges of 0, whereas in the second structure, one O atom has a formal charge of ϩ1 and the other O has a formal charge of . The first structure is thus preferred. 2.71 In (1.8) Ͻ Sn (2.0) Ͻ Sb (2.1) Ͻ Se (2.6) 2.73 Electronegativity decreases down a group, so the heavier alkali metals and alkaline earth metals are the most electropositive. 2.75 (a) HCl; (b) ; (c) CO2 2.77 (a) KCl; (b) BaO 2.79 Ͻ Ͻ ; smaller, more highly charged cations have greater polarizing power. 2.81 Ͻ Ͻ Ͻ ; the polarizability increases as the ion gets larger and less electronegative. 2.83 (a) Ͼ Ͼ CO; (b) Ͼ L ; (c) Ͼ CH2NH Ͼ HCN 2.85 (a) 150 pm; (b) 127 pm; (c) CO: 127 ppm, CN: 142 pm; (d) 120 pm 2.87 (a) 149 pm. (b) 183 pm. (c) 213 pm. Bond distance increases with size going down Group 14/IV. CH3NH2 SO3SO2SO3 2- CO2CO3 2- Br- Cl- N3- O2- Be2+ Sr2+ Rb+ CF4 -1 -1 O S ß å ß ¥ ¥ ¥ ¥ ¥ ¥ ¥ O O ¥ ¥ ¥ ¥ O H Ϫ å åϪ1 Ϫ1 ϩ2 Ϫ1 0 O S ß å ß ¥ ¥ ¥ ¥ ¥ ¥ O O ¥ ¥ ¥ ¥ O H Ϫ å ™Ϫ1 ϩ1 Ϫ1 0 0 lower energy O S ß å ß ¥ ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O H Ϫ ™ Ϫ1 Ϫ1 ϩ1 0 O S ß å ß ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O H Ϫ ™ Ϫ1 0 0 0 lower energy O Cl ®® ¥¥¥ ¥ ¥ ¥ ¥¥ O Cl Be®® ¥¥ ¥ ¥ ¥ ¥ Cl F F O F F Xe ¥ ¥ ¥ ¥ ¥ ¥ ¥¥ ¥ ¥ ¥ ¥ ¥¥ ¥ ¡ œ œ ç ç 1 lone pair F F Xe ¥ ¥ ¥ ¥ ¥ ¥ F¥ ¥ ¥ ¥ F ¥ ¥å å ß ß@ @ 2 lone pairs O Xe ¥ ¥ F ¥ ¥ ¥ ¥ F ¥ ¥™ ß ß @ 2 2 lone pairs Cl Cl Cl Cl Te ¥¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ å åœ ç 10 electrons F As ¥¥ ¥ å åœ œ ç ç 12 electrons Ϫ F F F F F ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥¥ 2.89 (a) (b) 2.91 2.93 Yes, the molecule obeys the octet rule. 2.95 2.97 (a) (b) N C C H H H HC C N A @ N C C H H H H C N C A A N C C H H H H H C C C A C C C H H H H H H C C C N N ¥ ¥ ß ™ ßH C N ¥ ß ™ ß ßH HSi Siß ™ ß ßH HC Siß ™ ß ßH HC Cß ™ N N N N£ß N£A ϩ1 ϩ1 Ϫ1 A A A ß ™ N N N£ N£ NßA ϩ1 ϩ1 A A A Ϫ1 ß ™ N N N Nß Nß ϩ1 ϩ1Ϫ1 ß ™ ß ™ P P P P ¥ ¥ ¥¥ C H2C CH2 ¥ ¥ CH2 å Ϫ2 C H2C CH2 ¥ CH2 ¥ å Ϫ2 C H2C CH2 ¥ CH2 ¥ å Ϫ2 © CC ¥ ¥ Ϫ2 Ϫ1 Ϫ1 ß© OBr ¥ ¥ ¥ ¥ ϩ1 0 ϩ O C ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ¥ C Ϫ2 O ¥ ¥ O C ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ¥ C Ϫ2 O ¥ ¥ O C ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ ¥ C Ϫ2 O ¥ ¥ O C ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ ¥ C Ϫ1 Ϫ1 Ϫ2 0 O ¥ ¥ 0 0 0 ODD-NUMBERED EXERCISES C17 ϩ suitable resonance forms 2.99 (a) (b) All the atoms have formal charge 0 except the two oxygen atoms, which are Ϫ1. The negative charge is most likely to be concentrated at the oxygen atoms.(c) The protons will bond to the oxygen atoms. Oxygen atoms are the most negative sites in the molecule and act as Lewis bases due to their lone pairs of electrons. The resulting compound is named hydroquinone. 2.101 Number of Energy Z Configuration unpaired eϪ Element Charge state 26 [Ar]3d6 4 Fe 2ϩ ground 52 [Kr]4d10 5s2 5p5 6s1 2 Te 2Ϫ excited 16 [Ne]3s2 3p6 0 S 2Ϫ ground 39 [Kr]4d1 1 Y 2ϩ ground 30 [Ar]3d8 4s2 2 Zn 2ϩ excited C C H H H H C C O Hß ¥ ¥ O Hß ¥ ¥ H H H H O ¥ ¥ ¥ O ¥ ¥ ¥ 2Ϫ N N N N N N A A @ @ 2 2 N N N N A @ @ 2 2 H C N N N C N A A @2 HH N C N N N N A @ @ 2 H HC C N C N H HN C N A A @ @ N C N H H HC C N A @ @ N C C H H H C N N A @ 2 N C N H H H C N C A @ @ N C C H H H H N C C A A 2.103 (a) (b) (c) (d) 2.105 Lattice energy d(KϪX) (kJ mol ) fluoride 271 pm 826 chloride 319 pm 717 iodide 358 pm 645 The data fit a straight line with a correlation coefficient of greater than 99%. (b) 693 . (c) 689 ; the agreement is very good. 2.107 ↔ 2.109 (a) I: Tl2O3; II: Tl2O. (b) ϩ3; ϩ1. (c) [Xe]4f14 5d10 ; [Xe]4f14 5d10 6s2 . (d) Because compound II has a lower melting point, it is probably more covalent, which is consistent with the fact that the ϩ3 ion is more polarizing. 2.111 (a) O Cl© © ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ O Ϫ ƒ å Ϫ1 O Cl© ß ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ O Ϫ ƒ ƒ Ϫ1 O Cl© © ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ O Ϫ å ƒ Ϫ1 O Cl© © ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ O Ϫ å å ϩ1 Ϫ1 Ϫ1 O Clß ß ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ¥ O Ϫ ƒ ƒ ϩ1 Ϫ1Ϫ1 O Cl ›ß ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ ƒ å ϩ1 Ϫ1 Ϫ1 O Cl Í© ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ O Ϫ ƒ å ϩ1 Ϫ1 Ϫ1 O Cl Í© ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ O Ϫ ƒ åϩ1 Ϫ1 Ϫ1 O Cl ‹ß ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ ƒ åϩ1 Ϫ1 Ϫ1 C C CH R ß C£ HßCߣ ß å H å H å H å å RЈ ç C C CH R ß Cß HßC£ß £ å H å H å H å å RЈ çC C CH R ß Cß HßC££ ß å H å H å H å å RЈ ç kJиmol-1 kJиmol-1 y ϭ Ϫ2.0877x ϩ 1389 d(KϪX), pm 850 600 280260 300 320 340 KCl KF KI 360 380 Latticeenergy,kJиmolϪ1 800 750 700 650 -1# N C N ¥ O ¥ ¥ ¥ ß ß£ £N C N ¥ ¥ O ¥ ¥ ££ £ ϩ1 Ϫ1 C H H N N ¥ ¥ £ £ œ ç ϩ1 Ϫ1 C H H S O ¥ ¥ ¥ ¥ £ ß œ ç ϩ1 Ϫ1 C H H S O ¥ ¥ ¥ £ £ œ ç H O CN ¥ ¥ ¥ O ¥ ¥ ß ß ££ ϩ1 Ϫ1 H O CN ¥ ¥ O ¥ ¥ ¥ ß ß ßßß ß ϩ1 Ϫ1 H O CN ¥ ¥ ¥ O ¥ ¥ ß £ £ß ↔ ↔ C18 ANSWERS The four structures with three double bonds and the one with four double bonds are the most plausible Lewis structures according to formal charge arguments because these five structures minimize the formal charges. (b) The structure with four double bonds fits these observations best since its bond lengths would all be 140 pm, or only 4 pm shorter than the observed length. However, the four structures with three double bonds also fit because, if the double bonds are delocalized by resonance, we can estimate the average bond length to be , or just 3.5 pm longer than observed. (c) ϩ7. The structure with all single bonds fits this criterion best. (d) Approaches (a) and (b) are consistent but approach (c) is not. This result is reasonable because oxidation numbers are assigned by assuming ionic bonding. 2.113 The alkyne group has the stiffer C—H bond because a large force constant, k, results in a higher-frequency absorption. 2.115 Look at the Lewis structures for the molecules: (a) (b) (c) (d) (e) (f) Of these, (a), (c), (d), and (e) can all function as greenhouse gases. 2.117 (a) one; (b) ozone 2.119 (a) They have some double bond character. (b) and (c) The Lewis structures for the two possible S2F2 are If resonance is occurring, then one would expect that the SßS bond length is indeed between a single and a double bond in length. 2.121 (a) The Lewis structures of NO and NO2 are (best possible structure) (equivalent resonance structures) O N© ¥ ¥ O ¥ ¥ ßO N © ¥ ¥ O ¥ ¥ ¥ ¥ ß MÍßßm z zϪ1 Ϫ1ϩ1 ϩ1 N ©O ¥ ¥¥ z S ß ¥ S ¥ ¥ ¥ ϩ1 Ϫ1 isomer 2I F F ¥ ¥ ¥ ¥ ¥ ¥ œ ç S © ¥ S ¥ ¥ favored F F ¥ ¥ ¥ ¥ ¥ ¥ œ ç F S S® ® ¥ ¥ ¥ ¥ ¥ ¥ F ¥ ¥ ¥ ¥ ß F S S© ® ¥ ¥ ¥ ¥ ¥ F ¥ ¥ ¥ ¥ ß favored ϩ1 Ϫ1 isomer 1I Ar ¥ ¥ ¥ ¥ N © ON© ¥ ¥ ¥ ¥ Ϫ1 ϩ1 S © OOß ¥ ¥ ¥ ¥ ¥ ¥ Ϫ1 ϩ1 O© OOß ¥ ¥ ¥ ¥ ¥ ¥ Ϫ1 ϩ1 O © O ¥ ¥ ¥ ¥C Ω ¥ ¥ O Ϫ1 ϩ1 1 4(170 pm) + 3 4(140 pm) = 147.5 pm O Clß ß ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ ¥ O Ϫ ƒ å Ϫ1 Ϫ1 Ϫ1 ϩ2 O Cl© ß ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ O Ϫ å å Ϫ1 Ϫ1 Ϫ1 ϩ2 O Clß ß ¥ ¥ ¥ ¥ ¥ O ¥ ¥ ¥ O ¥ ¥ ¥ O Ϫ å ƒ Ϫ1 Ϫ1 Ϫ1 ϩ2 O Clß © ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ O Ϫ å å Ϫ1 Ϫ1 Ϫ1 ϩ2 O Clß ß ¥ ¥ ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ¥ O Ϫ å å Ϫ1 Ϫ1 Ϫ1 Ϫ1 ϩ3 O Cl© © ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ O Ϫ ƒ ƒϪ1 O Clß © ¥ ¥ ¥ ¥ O ¥ ¥O ¥ ¥ ¥ O Ϫ ƒ ƒ Ϫ1 From Table 2.4, the average bond dissociation energy of a NϭO bond is 630 kJиmolϪ1 , which is right in line with the Lewis structure of NO. The bond dissociation energy of each NO bond in NO2 is 469 kJиmolϪ1 , which is about half-way between an NßO double and an NßO single bond, suggesting that the resonance picture of NO2 is a reasonable one. (b) An NßO single bond should have a bond length of 149 pm while an NO double bond should have a bond length of 120 pm (values are obtained by summing the respective covalent radii values from Figure 2.21). From Table 2.5 the length of a NßO triple bond can be estimated to be between 105 and 110 pm. Since NO itself has a bond length of 115 pm, this suggests that its actual bond order is somewhere between that of a double and a triple bond. (c) (d) (e) N2O5(g) ϩ H2O(l) : 2 HNO3(aq). Nitric acid is produced. (f) 7.50 ϫ 10Ϫ2 molиLϪ1 . (g) NO: ϩ2; NO2: ϩ4; N2O3: ϩ3; N2O5: ϩ5. Chapter 3 3.1 (a) must have lone pairs; (b) may have lone pairs 3.3 (a) angular; (b) slightly less than 3.5 (a) trigonal pyramidal; (b) all OßSßCl bond angles are equal; (c) slightly less than 3.7 (a) linear; (b) slightly less than 3.9 (a) (b) (c) (d) (a) seesaw ; (b) T-shaped ; (c) square planar ; (d) trigonal pyramidal 3.11 The Lewis structures are (a) (b) (c) (d) (a) linear, ; (b) tetrahedral, ; (c) trigonal pyramid, less than ; (d) linear, 180°, AX2109.5°, AX3E 109.5°, AX4180°, AX2E3 N £££ ¥ ¥ N ¥ ¥ O N ££ ¥ ¥ N ¥ ¥ O O I O A A A A O (resonance forms possible) A A A A A A ß å å Ϫ PCl O Cl Clßß ¥¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥¥ å åå I I AA A I A A A A å å @ @ Ϫ AX3E AX4E2AX3E2AX4E OXe£££ ¥ ¥ ¥ ¥ ¥ O ¥ ¥O F ¥ ¥ ¥ F ¥ ¥ ¥ F ¥ I ¥ ¥ ¥ F ¥ ¥ ¥ Ϫ Cl I Cl A A A Cl A A A A A A ß å å @ @ SCl Cl Cl Clßß ¥¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥¥å å 180° 109.5° 120° N Nß ß © © O ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ Ϫ1 Ϫ1 ϩ1 ϩ1 0 O ¥ ¥ 0 0 å ¥ O ¥ ¥ åO N N © © ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ß ¥ Ϫ1ϩ10 00 å ODD-NUMBERED EXERCISES C19 3.13 The Lewis structures are (a) (b) (c) (d) (a) tetrahedral; (b) seesaw; (c) trigonal planar, (d) trigonal pyramidal, 3.15 (a) The angles represented by a and b are expected to be about while c is expected to be about in 2, 4-pentanedione. All of the angles are expected to be about 120° in the acetylacetonate ion. (b) The major difference arises at the C of the original sp3 hybridized group, which becomes sp2 when it loses the hydrogen ion. 3.17 (a) slightly less than ; (b) ; (c) ; (d) slightly less than 3.19 The Lewis structures are (a) (b) (c) (d) Molecules (a) and (d) are polar; (b) and (c) are nonpolar. 3.21 (a) polar; (b) nonpolar; (c) polar 3.23 (a) 1 and 2; (b) 1 3.25 The first two carbons (CH2 and CH) are sp2 hybridized with HßCßH and CßCßH angles of The third carbon (bonded to N) is sp hybridized with a CßCßN angle of 3.27 (a) tetrahedral, ; (b) tetrahedral about the carbon atoms, ; CßBeßC angle of ; (c) angular, slightly less than ; (d) angular, slightly less than 3.29 (a) HßCßH and HßCßC angles of (b) linear, (c) tetrahedral, (d) The arrangement of atoms about each N is trigonal pyramidal H H H HN N A A ß ß ß å å 107° O P Cl Cl Clß ßß å å 109.5° O P Cl Cl Clßß å å 180° C C H H H H £ œ ç œ ç 120° 120° 120°180°109.5° 109.5° 180°. 120°. C C H H H C N£ £ß ß å A œ ç F F S ßß ¥¥ ¥ ¥ ¥ F ¥ ¥ F ¥ ¥ ¥ ¥ ¥ å å ™ CS S££ @ 2 @ 2 CCl Cl Cl Clßß ¥¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥¥ å å CH H Cl Clßß ¥ ¥ ¥ ¥ ¥ ¥ å å 109.5° 180°180°120° CH2 109.5°120°, 109.5°, AX3EAX3;120°, 90° and 120°, AX4E;109.5°, AX4; CH H Hßß ¥ å Ϫ CF ¥ ¥ ¥ F ¥ ¥ ¥ O 2 ™ £ß å Cl Cl Te ßßCl Cl å å F F C ¥ ¥ ¥ ¥ ¥ ¥ Cl¥ ¥ ¥ ¥ F ¥ ¥å å ß ß 3.31 (a) tetrahedral: (b) tetrahedral: (c) seesaw: 3.33 (a) toward corners of a tetrahedron; (b) apart; (c) toward the corners of an octahedron; (d) toward the corners of an equilateral triangle 3.35 (a) (b) (c) (d) 3.37 (a) (b) (c) (d) 3.39 (a) (b) (c) (d) 3.41 (a) sp3 ; (b) nonpolar 3.43 increase 3.45 In formaldehyde, both the C and the O are sp2 hybridized. The HßCßO bond angle is the molecule has three sigma bonds (one each connecting the two H’s and O to the C) and one pi bond (between the C and the O). 3.47 Atomic orbitals a and b are mutually orthogonal if where the integration is over all space. Furthermore, an orbital, a, is normalized if . In this problem, the two hybrid orbitals are: Therefore, to show these two orbitals are orthogonal we must show Of course, this integral of a sum may be written as a sum of integrals: Because the hydrogen wavefunctions are mutually orthogonal, the members of this sum which are integrals of a product of two different wavefunctions are zero. Therefore, this sum of integrals simplifies to 3.49 3.51 (a) diamagnetic; (b) paramagnetic, one; (c) paramagnetic, one 3.53 (a) (1) (2) (3) (b) (1) 0.5, (2) 1.5, (3) 0; (c) (1) and (2) are paramagnetic, with one unpaired electron each; (d) for (1) and (3), ␲ for (2).␴ (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)2 (␲2py *)2 (␴2p*)2 (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)2 (␲2py *)1 (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)2 (␲2py *)2 (␴2p*)1 sp0.67 l = 0.67 L s2 dt - L px 2 dt + L py 2 dt - L pz 2 dt = 1 - 1 + 1 - 1 = 0 L s2 dt - L spxdt + L spy dt - L spz dt + Á pxpy + p 2 y - pypz + spz - pzpx + pzpy - p 2 z )dtspy - = L (s2 - spx + spy - spz + spx - p 2 x + pxpy - pxpz + L h1h2 dt = L (s + px + py + pz)(s - px + py - pz)dt L h1h2 dt = 0. py - pz. h1 = s + px + py + pz and h2 = s - px +L a2 dt = 1 L aиb dt = 0 (assuming a Z b) 120°; sp3 sp3 d;sp3 d2 ;sp3 ; sp3 sp3 d;sp3 ;sp2 ; sp3 sp3 ;sp2 ;sp; 180° O I F A A A O A A F A A A A A A A ß ß å ™ @ Ϫ O S Cl A A A O A A Cl A A A A A A A ßß å ™ O Sb Cl A A Cl A A Cl A A A A A A A A ß ß å å ClßCΩN: C20 ANSWERS 3.55 Ϫ2, 3 3.57 (a) The energy level diagram for is (b) The oxygen atom is more electronegative, which will make its orbitals lower in energy than those of N. The revised energy-level diagram is shown below. This will make all of the bonding orbitals closer to O than to N in energy and will make all the antibonding orbitals closer to N than to O in energy. Energy level diagram for (c) The electrons in the bonding orbitals will have a higher probability of being at O because O is more electronegative and its orbitals are lower in energy. 3.59 (a) , 1; (b) 0; (c) , 1 3.61 ; bond order ϭ 3 ; bond order ϭ 2.5 Due to the higher bond order for CO, it should form a stronger bond and therefore have the higher bond enthalpy. 3.63 All are paramagnetic. have one unpaired electron whereas has two. 3.65 (a) has a bond order of 1; F2 Ϫ has a bond order of . (b) has a bond order of 1; has a bond order of . will have the stronger bond. 3.67 3.69 Given the overlap integral , the bonding orbital , and the fact that the individual atomic orbitals are normalized, we are asked to find the normalization constant N which will normalize the bonding orbital ␺ such that: Given the definition of the overlap integral above and the fact that the = N2 a L c2 A1s dt + 2 L cA1scB1sdt + L c2 B1s dtb N2 L (cA1s + cB1s)2 dt = N2 L (c2 A1s + 2cA1scB1s + c2 B1s)dt L N2 c2 dt = N2 L (cA1s + cB1s)2 dt = 1 c = cA1s + cB1s S = L cA1s cB1sdt C2 - B2 1 2B2 + B2 1 2F2 B2 B2 and B2 + (␴2s)2 (␴2s*)2 (␲2px )2 (␲2py )2 (␴2p)1 CO+ (␴2s)2 (␴2s*)2 (␲2px )2 (␲2py )2 (␴2p)2 CO (␴2s)2 (␴2s*)2 (␴2p)2 (␴2px )2 (␲2py )2 (␲2px *)2 (␲2py *)2 (␴2s)2 (␴2s*)2 ,(␴2s)2 (␴2s*)2 (␲2px )1 (␲2py )1 a a a a a Ó ÓÓ Ó Ó Ó Ó a 2s 2s Orbitals on N Orbitals on O 2p 2p␴2p ␴2p* ␲2p* ␲2p ␴2s* ␴2s NO+ a a a aa Ó ÓÓ Ó Ó Ó Ó a 2s 2s Orbitals on N Orbitals on O 2p 2p ␴2p ␴2p* ␲2p* ␲2p ␴2s* ␴2s N2 individual orbitals are normalized, this expression simplifies to Therefore, 3.71 (a) Shape: tetrahedral Hybridization: Bond angles: 109.5° Nonpolar (b) Shape: seesaw Hybridization: Bond angles: Ͼ 90° and Ͼ120° Polar (c) Shape: seesaw Hybridization: Bond angles: Ͼ 90° and Ͼ120° Polar (d) Shape: tetrahedral Hybridization: Bond angles: 109.5° Nonpolar 3.73 (a) The Lewis structures are (b) None are radicals. (c) 3.75 (a) The elemental composition gives an empirical formula of which agrees with the molar mass. There is only one reasonable Lewis structure; this corresponds to the compound methanol. All of the bond angles about carbon should be . The bond angles about oxygen should be close to but will be somewhat less, due to the repulsions by the lone pairs. (b) Both carbon and oxygen are sp3 hybridized. (c) The molecule is polar. 3.77 (a) (b) Bonding Antibonding 109.5° 109.5° CH4O, CH2 2+ CH2 2- 6 CH3 - 6 CH4 6 CH2 6 CH3 + 6 C H H å å 2Ϫ A A C H H å å 2ϩ C H H å å A H C H H ß å å A Ϫ H HC H H ß ß å å H C H H ß å å ϩ sp3Cl Cl Si ¥ ¥ ¥ ¥ ¥ ¥ Cl ¥ ¥ ¥ ¥ Cl ¥ ¥å å ß ß dsp3Cl Cl Sb ¥ ¥¥ ¥ ¥ ¥ Cl ¥ ¥ ¥ ¥ Cl ¥ ¥å å å ß Ϫ dsp3F F Te ¥ ¥¥ ¥ ¥ ¥ F ¥ ¥ ¥ ¥ F ¥ ¥å å å ß sp3Cl Cl Ga ¥ ¥ ¥ ¥ ¥ ¥ Cl ¥ ¥ ¥ ¥ Cl ¥ ¥å å ß ß Ϫ N = A 1 2 + 2S N2 (1 + 2S + 1) = 1. ODD-NUMBERED EXERCISES C21 (c) The bonding and antibonding orbitals for HF appear different due to the fact that a p-orbital from the F atom is used to construct bonding and antibonding orbitals whereas in the H2 molecule s-orbitals on each atom are used to construct bonding and antibonding orbitals. 3.79 (a) Ͻ Ͻ . (b) has no unpaired electrons; CF has one unpaired electron and has two. 3.81 Orbitals at each B and N atom will be sp2 hybridized. 3.83 The antibonding molecular orbital is obtained by taking the difference between two atomic orbitals that are proportional to Halfway between the two nuclei, the distance from the first nucleus, , is equal to the distance to the second nucleus, , and the antibonding orbital is proportional to 3.85 VSEPR Formula: AX6 Shape: octahedral Bond angles: all 90° 3.87 To shift the wavelength of the absorption to longer wavelengths (lower energies) the length of the carbon chain, N, must increase. 3.89 (a) (b) ␴ Ͼ ␲ Ͼ ␦ 3.91 (a) Net ␲-bond order will drop from three to two. (b) Net ␲-bond order will drop from three to two. Both are paramagnetic. σ π δ = h2 (N + 1) 8 mN2 R2 = h2 8mN2 R2 c a N 2 + 1b 2 - a N 2 b 2 d ¢E = ELU - EHO = nLUh2 8mN2 R2 - nHOh2 8mN2 R2 F I ¥ ¥ ¥ F ¥ ¥ F ¥ ¥ F ¥ ¥ ¥ ¥ ¥ F ¥ ¥ ¥F ¥ ¥ ¥ c r e-r>ao - e-r>ao = 0 r2 r1 e-r>ao . B N B H H H H N B N B N B H H H H N B N H H H H CF- CF+ CF- CFCF+ 3.93 (a) (b) Benzyne would be highly reactive because the two carbon atoms that are sp hybridized are constrained to have a very strained structure compared with the linear structure associated with their hybridization. 3.95 (a) The carbon atoms are all sp3 hybridized. (b) The CßCßC, HßCßH, and HßCßC bond angles should be . (c) Because of the ring structure, however, the CßCßC bond angles must be . (d) The ␣-bond will have the electron density of the bond located on a line between the two atoms that it joins. (e) If the C atoms are truly sp3 hybridized, then the bonding orbitals will not necessarily point directly between the C atoms. (f) The sp3 hybridized orbitals can still overlap, even if they do not point directly between the atoms. 3.97 (a) and (d) have the possibility of n-to-␲* transitions because these molecules possess both an atom with a lone pair of electrons and a ␲-bond to that atom. 3.99 (a–b) : All atoms in this molecule have a formal charge of zero. 3.101 (a) (b) sp3 d 3.103 3.105 Ib and Id are sp3 d hybridized with the attached atoms occupying axial positions, which results in a bond angle of 180° around each axial atom. Ic is sp3 hybridized. 3.107 is nonpolar; all dipoles in the molecule (due to the bonds) will cancel: Al Cl AlAl ClCl Cl Cl Cl œç œç These cancel These cancel Al Al—Cl Al2Cl6 ¥¥ 2 ™ ™2 ™ ™ ç ∂ I I 2 ™ ™ ∂I I 2 ™ ™ çI Ϫa b c d e Bi Cl ClBi ¥ ¥ ¥ Cl ¥ ¥ ¥ ¥ ¥ ¥ Cl ¥ ¥ ¥ ¥ ¥ œ ßß ç œç 2Ϫ ϩ1 ϩ1 Ϫ2 Ϫ2 ¥ F F Sb Sb¥ ¥ å å¥ F ¥ å F F ¥ ¥ ¥ å ™ F F2™ ™ ß ¥ ¥ ¥ å ¥ ¥ ¥ å ™ 2™ ™ ßϩ1 Ϫ1 Ϫ1 Ϫ ¥ ¥ H C H H H O C Cß £ £ ß ß å å p(C2p, C2p) s(C2sp2 , C2sp2 ), s(C2sp2 , C2sp2 ) s(H1s, C2sp2 ) p(C2p, O2p) s(C2sp2 , O2sp2 ), s(H1s, C2sp2 ) s(H1s, C2sp2 ) Osp2 60° 109.5° H H H H C C sp2 sp2 sp2 sp sp sp2 C22 ANSWERS 3.109 (a) ; (b) ; (c) 3.111 (a) The Lewis structure of hydrogen peroxide is . No atoms have formal charges and the oxidation number of each O is . Oxidation number is more useful than formal charge in predicting the oxidizing ability of a compound as this will give us a clearer idea of whether a given atom wants to gain or lose an electron. (b) The bond angles should be about the same as those for water, about . All atoms in this molecule are in the same plane, but because of unrestricted rotation around the bond, it is expected that the hydrogens (and therefore the lone pairs of electrons on the oxygens) can rotate in and out of the plane; one of these rotations will lead to a polar structure (the different forms, arising from rotations around a single ␴-bond, are called rotomers). Because of this, the molecule is expected to be polar, but slightly less so than water. (c) (1) ; bond order ϭ 2; paramagnetic. (2) ; bond order ϭ 1.5; paramagnetic. (3) ; bond order ϭ 2.5; paramagnetic. (4) bond order ϭ 1; diamagnetic. (d) Bond length should inversely follow bond order; therefore, the longest bond should belong to the molecule with the lowest bond order and the shortest bond should belong to the species with the largest bond order , which is borne out in the data given. (e) : , 1.21 g (f) : , 0.795 g (g) two; (h) 761 nm Chapter 4 4.1 (a) (b) 80 kbar; (c) (d) 4.3 (a) 86 mmHg. (b) The side attached to the bulb will be higher. (c) 848 Torr 4.5 909 cm 4.7 2.9 ϫ 103 lb 4.9 (a) 22.4 in.; (b) in tube (1): 41.85 inHg; in tube (2): 59.85 inHg 4.11 (a) 20 L (b) (c) 0.32 K 4.13 (a) 1.06 ϫ 103 kPa; (b) 4.06 ϫ 102 mL; (c) 0.20 g; (d) 3.24 ϫ 105 mol; (e) 9.2 ϫ 1014 atoms y ϭ 0.0082x Ϫ 0.0026 R2 ϭ 0.9994 y ϭ 0.0041x Ϫ 0.0013 R2 ϭ 0.9994 T (K) 270 290 310 350330250 370 P(atm) 3.0 2.5 2.0 1.5 1.0 1 * 106 lbиin.-2 6 * 107 Torr;8 * 109 Pa; 2 Fe2+ + 2 H2O + 2 O22 Fe3+ + H2O2 + 2 OH- 2 Fe3+ + 2 H2O2 Fe2+ + H2O2 + 2 H+ (O2 + ) (O2 2- ) O2 2: (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)2 (␲2py *)2 ; O2 + : (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)1 O2 : (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)2 (␲2py *)1 O2: (␴2s)2 (␴2s*)2 (␴2p)2 (␲2px )2 (␲2py )2 (␲2px *)1 (␲2py *)1 Nonplanar, polar rotomer (one of many) O Oœ œ ç H H ¥ ¥ ¥ ¥ Planar, polar rotomer O Oœ œ ç H H ¥ ¥ ¥ ¥ Planar, nonpolar rotomer O Oœ œç H H ¥ ¥ ¥ ¥ O¬O 104° -1 sp2 dsp3 d3 fsp3 d3 4.15 (a) Volume (L) nR͞V atmؒ(K؊1 ) 0.01 8.21 0.02 4.10 0.03 2.74 0.04 2.05 0.05 1.64 (b) nR͞V; (c) 0.00 4.17 (a) 1.5 ϫ 103 kPa; (b) 4.5 ϫ 103 Torr 4.19 3.64 atm 4.21 10.7 L 4.23 The volume must be increased by 10.% to keep P and T constant. 4.25 0.050 g 4.27 (a) 11.8 mL; (b) 0.969 atm; (c) 199 K 4.29 (a) 63.4 L; (b) 6.3 L 4.31 18.1 L 4.33 4.18 atm 4.35 621 g 4.37 2.52 ϫ 10Ϫ3 mol 4.39 (a) 3.6 m3 ; (b) 1.8 ϫ 102 m3 4.41 4.43 342°C 4.45 (a) 1.28 gиLϪ1 ; (b) 3.90 gиLϪ1 4.47 (a) 70 gиmolϪ1 ; (b) CHF3; (c) 2.9 gиLϪ1 4.49 4.51 44.0 gиLϪ1 4.53 (a) 3.0 ϫ 105 L; (b) 1.0 ϫ 104 L 4.55 2.00 g CH4 4.57 2.4 ϫ 104 L 4.59 (a) 4.25 ϫ 10Ϫ3 g; (b) 0.0757 atm 4.61 (a) xHCl ϭ 0.9, Xbenzene ϭ 0.1; (b) PHCl ϭ 0.72 atm, Pbenzene ϭ 0.08 atm 4.63 (a) partial pressure of ϭ 1.0 atm, partial pressure ofN2(g) C2H2Cl2 CO 6 H2S 6 CO2 H2 (g) ϭ 2.0 atm; (b) 3.0 atm 4.65 1.9 atm 4.67 (a) 739.2 Torr; (b) : (c) 0.142 g 4.69 No; the reason is that not all the molecules are traveling at the same velocity. Force ϭ (NmAvx 2 ͞V), if vx varies, force will be different. 4.71 4.73 (a) 154 s; (b) 123 s; (c) 33.0 s; (d) 186 s 4.75 110 gиmolϪ1 ; 4.77 (a) (b) (c) 12.5 JиmolϪ1 4.79 (a) 627 mиsϪ1 ; (b) 458 mиsϪ1 ; (c) 378 mиsϪ1 4.81 241 m. sϪ1 4.83 0.316 4.85 (a) The most probable speed is the one that corresponds to the maximum on the distribution curve. (b) The percentage decreases. 4.87 At low temperatures, this hydrogen bonding causes the molecules of HF to be attracted to each other more strongly, thus lowering the pressure. As the temperature is increased, the hydrogen bonds are broken and the pressure rises more quickly than for an ideal gas. Dimers (two HF molecules bonded to each other) and chaiins of HF molecules are known to form. 4.89 (a) Root mean square speed vrms ϭ ; the smaller the molecular mass, the larger the vrms. Therefore, H2 molecules have greater root mean square speed. (b) NH3 will have stronger attraction between molecules because the H atom on one NH3 molecule tends to interact with the lone-pair electrons on the N of another NH3 molecule (H-bonding). 4.91 (a) 1.62; (b) 38.9; (c) At low pressures, the ideal gas law gives essentially the same values as the van der Waals equation, but at high pressures there is a very significant difference. 4.93 17.58, CH3CN; 3.392, CO2; 2.253, CH4; 0.2107, Ne 4.95 Clearly, the greater deviation from the ideal gas law values occurs at low volumes or higher pressures. Ammonia deviates more strongly and its van der Waals constants are larger than those for oxygen. This may likely arise because ammonia is polar and will have stronger intermolecular interactions. 1.88 * 103 atm. A 3RT M 4090.7 Jиmol-1 ;4103.2 Jиmol-1 ; C8H12 C10H10 H2(g) + 1 2 O2(g);H2O(l) ODD-NUMBERED EXERCISES C23 4.97 (a) 280. Torr; (b) 700. Torr 4.99 (a) 97.8 L; (b) 32.5 L; (c) 19.6 L 4.101 (a) (b) 0.020 ppm 4.103 0.481 M 4.105 (a) (b) 2.33 atm; (c) 4.65 atm; (d) ϭ 0.426; ϭ 0.574 4.107 (a) (b) (c) 4.2 ϫ 10Ϫ4 mol 4.109 No, the distribution changes with temperature. 4.111 Ͼ 2.35 m 4.113 254 gиmolϪ1 ; 4.115 23.1 g 4.117 (a) V ϭ 3.95 ϫ 107 pm3 иatomϪ1 , r ϭ 211 pm. (b) r ϭ 128 pm; V ϭ 8.78 ϫ 106 pm3 . (c) The difference in these values illustrates that there is no easy definition for the boundaries of an atom. The van der Waals value obtained from the correction for molar volume is considerably larger than the atomic radius, owing perhaps to longer range and weak interactions between atoms. One should also bear in mind that the value for the van der Waals b is a parameter used to obtain a good fit to a curve, and its interpretation is more complicated than a simple molar volume. 4.119 (a) ClNO2; (b) ClNO2; (c) (d) trigonal planar 4.121 (a) 0.0979 L; (b) Videal ϭ 0.130 L Ͼ VvdW ϭ 0.0979 L, attractive forces dominate Chapter 5 5.1 (a) London forces, dipole–dipole, hydrogen bonding; (b) London forces; (c) London forces, dipole–dipole, hydrogen bonding; (d) London forces, dipole–dipole. 5.3 (b), (c), and (d) 5.5 (a) NaCl; (b) butanol; (c) triiodomethane; (d) methanol 5.7 (a) trigonal pyramidal, ; (b) is bent, is linear; ; (c) trigonal planar, 5.9 (b) (c) Ͻ (e) < (a) < (d) 5.11 (d) 5.13 ⌸ because the dipoles are aligned with oppositely charged ends closest to each other thereby maximizing dipole–dipole attractions. 5.15 Ratio ϭ 1.03, Al3ϩ L BCl3SO2 CO2SO2PBr3 ¥ ¥ ¥ O ONß £ ¥ ¥ ¥ ¥ ¥ Cl å O ONߣ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ Cl å x = 3.99 = 100e-99Mv2 rms>2RT = 100v2 rmse-M100vrms 2>2RT v2 rmse-Mvrms 2>2RT = 100e(-M100vrms 2>2RT+ Mvrms 2>2RT ) = 4␲Na M 2RT b 3 2 (10vrms)2 e-M(10vrms)2>2RT 4␲Na M 2RT b 3 2 (vrms)2 e-M(vrms)2>2RT f(10vrms) f(vrms) H H HN® ® ® ¥ å H N ¥ å N2H4 xN2O4 xNO2 N2O4(g) : 2NO2(g); 5.17 (a) Xenon is larger, with more electrons, giving rise to larger London forces that increase the melting point. (b) Hydrogen bonding in water causes the molecules to be held together more tightly than in diethyl ether. (c) Both molecules have the same molar mass, but pentane is a linear molecule compared to dimethylpropane, which is a compact, spherical molecule. The compactness of the dimethylpropane gives it a lower surface area. That means that the intermolecular attractive forces, which are of the same type (London forces) for both molecules, will have a larger effect for pentane. 5.19 5.21 (a) As intermolecular forces increase, boiling point will increase because more thermal energy is required to separate the molecules; (b) viscosity will increase with the increase of intermolecular forces because stronger intermolecular forces will make molecules less mobile (or will not let molecules move past one another easily); (c) surface tension also increases with the increase of intermolecular forces because stronger intermolecular forces tend to pull molecules together and inward. 5.23 (a) cis-dichloroethene; (b) benzene at 20°C 5.25 Ͻ Ͻ 5.27 CH4, Ϫ162°C; CH3CH3, Ϫ88.5°C; (CH3)2CHCH2CH3, 28°C; CH3(CH2)3CH3, 36°C; CH3OH, 64.5°C; CH3CH2OH, 78.3°C; CH3CHOHCH3, 82.5°C; C5H9OH, 140°C; C6H5CH3OH, 205°C; OHCH2CHOHCH2OH, 290°C 5.29 (a) hydrogen bonding; (b) London dispersion forces increase 5.31 water 5.33 (a) glucose, London forces, dipole–dipole interactions, hydrogen bonds; benzophenone, dipole–dipole interactions, London forces; methane, London forces only; (b) 5.35 (a) network; (b) ionic; (c) molecular; (d) molecular; (e) network 5.37 substance A: ionic; substance B: metallic; substance C: molecular solid 5.39 (a) 2; (b) 8; (c) 286 pm 5.41 (a) 2.72 gиcmϪ3 ; (b) 0.813 gиcmϪ3 5.43 (a) 139 pm; (b) 143 pm 5.45 close-packed 5.47 (a) 3.73 ϫ 10Ϫ22 g; (b) 8 5.49 90.7% 5.51 (a) indium, 4; arsenide, 4; (b) InAs 5.53 (a) 1 ClϪ , 1 Csϩ , CsCl; (b) 4 O2Ϫ , 2 Ti4ϩ , ; (c) Ti atoms, 6-coordinate; O atoms, 3-coordinate. 5.55 (a) Rhenium oxide has a (6,2)-coordination. (b) ReO3 5.57 (a) 8; (b) 6; (c) 6 5.59 (a) 3.36 gиcmϪ3 ; (b) 4.67 gиcmϪ3 5.61 (a) the smallest possible rectangular unit cell is (b) 4 carbon atoms; (c) 3 5.63 3.897 cm 5.65 There are too many ways that these molecules can rotate and twist so that they do not remain rodlike. The molecular backbone when the molecule is stretched out is rodlike, but the molecules tend to curl up TiO2 (m.p. = 148 - 155°C) (m.p. = 48°C) 6 glucose6 benzophenoneCH4 (m.p. = -182°C) C6H5OHC6H5SHC6H6 F = -dEP dr = -d dr a 1 r6 b = - a -6 r7 b r 1 r7 : : C24 ANSWERS on themselves, destroying any possibility of long-range order with neighboring molecules. This is partly due to the fact that the molecules have only single bonds that allow rotation about the bonds, so that each molecule can adopt many configurations. If multiple bonds are present, the bonding is more rigid. 5.67 Use of a nonpolar solvent such as hexane or benzene in place of water should give rise to the formation of inverse micelles. 5.69 Because benzene is an isotropic solvent, its viscosity is the same in every direction. However, a liquid-crystal solvent is an anisotropic solvent and its viscosity is smaller in the direction parallel to the long axis of the molecule than in the “sideways” direction. Since methylbenzene is a small spherical molecule, its diffusion movement is not affected greatly whether the solvent is isotropic or anisotropic. 5.71 (a) trigonal pyramidal, polar, it can participate in dipole–dipole interactions (b) trigonal planar, nonpolar, it cannot participate in dipole–dipole interactions 5.73 (a) 2,2-dimethylpropane, 8.11 ϫ 105 pm2 ; pentane, 9.91 ϫ 105 pm2 ; (b) pentane; (c) pentane 5.75 ; Ne, 170 pm; Ar, 203 pm; Kr, 225 pm; Xe, 239 pm; Rn 246 pm 5.77 21.3 gиcmϪ3 5.79 (a) ; (b) Ti2ϩ ϭ 64%; Ti3ϩ ϭ 36 5.81 (a) true; (b) false; (c) true; (d) false 5.83 5.85 (a) 50.2 pm; (b) octahedral, 75% 5.87 Fused silica, also known as fused quartz, is predominantly with very few impurities. This glass is the most refractory, which means that it can be used at the highest temperatures. Quartz vessels are routinely used for reactions that must be carried out at temperatures up to Vycor, which is 96% , can be used at up to about , and normal borosilicate glasses at up to approximately . This is due to the fact that the glasses melt at lower temperatures as the amount of materials other than increases. The borosilicate glasses (Pyrex or Kimax) are commonly used because the lower softening points allow them to be more easily molded and shaped into different types of glass objects, such as reaction flasks, beakers, and other types of laboratory and technical glassware. 5.89 38.1 g 5.91 MA2 SiO2 550°C 900°CSiO2 1000°C. SiO2 +2.36 r = A (2.936 * 105 )M3 d I B ¥ ¥ ¥ I ¥ ¥ I ¥ ¥ ¥ ¥ I ¥ N ¥ ¥ ¥ I ¥ ¥ I ¥ ¥ ¥ ¥ 5.93 35% 5.95 (a) 48%. (b) The percentage of empty space in an fcc unit cell is 26%. 5.97 ; the bond angle is about 180° 5.99 (a) Increase the electrical conductivity of graphite. (b) The angle of the x-ray beam will decrease. 5.101 The lattice layers from which constructive x-ray diffraction occurs are parallel. First draw perpendicular lines from the point of intersection of the top x-ray with the lattice plane to the lower x-ray for both the incident and diffracted rays. The x-rays are in phase and parallel at point A. If we want them to be still in phase and parallel when they exit the crystal, then they must still be in phase when they reach point C. In order for this to be true, the extra distance that the second beam travels with respect to the first must be equal to some integral number of wavelengths. The total extra distance traveled, is equal to 2x. From the diagram, we can see that the angle A–D–B must also be equal to . The angles and sum to , as do the angles and A–D–B. We can then write and . The total distance traveled is So, for the two x-rays to be in phase as they exit the crystal, must be equal to an integral number of wavelengths. 5.103 5.074 5.105 633 K 5.107 (a)–(b) (c) The anion (NO3 Ϫ ). N5ϩ can be reduced to a lower oxidation state by a reducing agent. (d) CH3CH2NH2 ϩ HNO3 : CH3CH2NH3 ϩ NO3 Ϫ (acid–base). (e) Theoretical yield ϭ 0.0600 mol HNO3; percentage yield ϭ 63.2%. The forces holding EAN together in the solid contain ion–ion, hydrogen-bonding, and London forces. NaCl and NaBr have only ion–ion and London forces to hold them together (no hydrogen bonding involved). However, the ion–ion forces in NaCl and NaBr are much stronger that those in EAN because of the smaller ion sizes of NaCl and NaBr. As the ion size increases, the distance between ions will increase and the ion–ion forces will decrease, and the melting point will decrease. O N ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ å Ϫ Ϫ1 ϩ1 Ϫ1 sp2 0C H H C NßH ß ß å å Hß ϩ 0 0 H H å å 0 0 H H å å 0 00 0ϩ10 0 sp3 sp3 sp3 2d sin u 2x = 2d sin u. x = d sin usin u = x d a90°auu A : B : C, H ßF ¥ ¥ ¥p H HßF ¥ ¥ ¥ ßF ¥ ¥ ¥ p Chapter 6 6.1 4.47 ϫ 10Ϫ19 J 6.3 0.9703 6.5 The major impurity is carbon; it is removed by oxidation of carbon to CO2, followed by capture of the CO2 by base to form a slag. 6.7 Alloys are usually (1) harder and more brittle, and (2) poorer conductors of electricity than the metals from which they are made. 6.9 (a) The alloy is undoubtedly interstitial because the atomic radius of nitrogen is much smaller (74 pm versus 124 pm) than that of iron. The rule of thumb is that the solute atom be less than 60% the solvent atom in radius in order for an interstitial alloy to form. That criterion is met here. (b) We expect that nitriding will make iron harder and stronger, with a lower electrical conductivity. 6.11 (a) 2.8 Cu per Ni; (b) 15 Sn:1.2 Sb:1 Cu 6.13 In diamond, carbon is sp3 hybridized and forms a tetrahedral, three-dimensional network structure, which is extremely rigid. Graphite carbon is sp2 hybridized and planar. Its application as a lubricant results from the fact that the two-dimensional sheets can “slide” across one another, thereby reducing friction. In graphite, the unhybridized p-electrons are free to move from one carbon atom to another, which results in its high electrical conductivity. In diamond, all electrons are localized in sp3 hybridized C–C ␴-bonds, so diamond is a poor conductor of electricity. ODD-NUMBERED EXERCISES C25 6.15 (a) 1.1 ϫ 1016 C atoms; (b) 18 nmol 6.17 Due to the greater polarizing ability of the smaller Mg2ϩ ion on the carbonate ion, we expect MgCO3 to be less stable than CaCO3. Therefore, we expect that the oxide formed is MgO and that the carbonate is CaCO3. Furthermore, for MgCO3(s) : MgO(s) + CO2(g), ⌬Gr° is roughly +50 kJ, and for CaCO3(s) : CaO(s) + CO2(g), ⌬Gr° is roughly +130 kJ (as calculated from the data in Appendix 2A). Thus, the formation of MgO versus that of CaO is thermodynamically favored. 6.19 (a) The top layer of a unit cell of moissanite is (b) Although a Si atom is heavier than a C atom, a Si atom is larger than a C atom. This will result in more empty spaces between C and Si atoms during the packing process, which makes moissanite less dense than diamond. 6.21 (a) hexagonal; (b) carbonate ions, 6; CaCO3, 4 6.23 15.4 cm3 6.25 Formal charge: Si ϭ 0, O ϭ Ϫ1; oxidation number: Si ϭ ϩ4, O ϭ Ϫ2; this is an AX4 VSEPR structure; therefore, the shape is tetrahedral. 6.27 (a) The Si2O7 6Ϫ ion is built from two SiO4 4Ϫ tetrahedral ions in which the silicate tetrahedra share one O atom. This is the only case in which one O is shared. (b) The pyroxenes, for example, jade, NaAl(SiO3)2, consist of chains of SiO4 units in which two O atoms are shared by neighboring units. The repeating unit has the formula SiO3 2Ϫ . 6.29 ϩ4 6.31 930 g 6.33 Ionic fluorides react with water to liberate HF, which then reacts with the glass. Glass bottles used to store metal fluorides become brittle and may disintegrate upon standing on the shelf. 6.35 The iron ions impart a deep red color to the clay, which is not desirable for the manufacture of fine china; a white base is aesthetically more pleasing. 6.37 (a) ϩ5; (b) ϩ4 6.39 The conductivity of a semiconductor increases with temperature as increasing numbers of electrons are promoted into the conduction band, whereas the conductivity of a metal will decrease as the motion of atoms will slow down the migration of electrons. 6.41 0.27 ⍀ 6.43 n ϭ 1.8 ϫ 106 6.45 (a) In and Ga; (b) P and Sb 6.47 YBa2Cu3O7 6.49 In fluorescence, light absorbed by molecules is immediately emitted, whereas in phosphorescence, molecules remain in an excited state for a period of time before emitting the absorbed light. In both phenomena, the energy of the emitted photon is lower than that of the absorbed photon (emitted photons have a longer wavelength). 6.51 Fluorescent dyes allow much smaller concentrations of biomolecules to be detected than is normally possible. O Siß ß ßß ¥ ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ ¥ ¥ ¥ ¥ O Ϫ4 Si C 6.53 Sc, V, Fe, Ni, Zr, Mo, Ru, Lu, Ta, Re, Ir, Au, Ti, Mn, Co, Y, Nb, Tc, Rh, Hf, W, Os, Pt 6.55 The compound is ferromagnetic below Tc because the magnetization is higher. Above the Curie temperature, the compound is a simple paramagnet with randomly oriented spins, but below that temperature, the spins align and the magnetization increases. 6.57 The “top down” approach to manufacturing nanomaterials refers to physically assembling the nanoparticles into the form factor desired; on the other hand, the “bottom up” approach utilizes specific intermolecular interactions to cause the nanomaterials to self-assemble. 6.59 yellow, 726.9 pm 6.61 290 mиsϪ1 6.63 E111 ϭ ; E211 ϭ ; E221 ϭ . The 211, 121, and 112 levels are degenerate; that is E211 ϭ E121 ϭ E112. The 221, 122, and 212 levels are degenerate; that is E221 ϭ E121 ϭ E212. 6.65 SiC(s) ϩ 2NaOH(l) ϩ 2O2(g) : Na2SiO3(s) ϩ H2O(g) ϩ CO2(g) 6.67 (a) 3.75 g; (b) 6.89 Kg 6.69 When semiconductors are at very low temperatures, the valence band is fully occupied and the conduction band is empty, so the conductivity is low. As temperature increases in a vacuum, some electrons are promoted from the valence band to the conduction band and cause an increase in conductivity. However, when semiconductors are heated in oxygen, chemisorptions will occur and adsorbed oxygen on the surface will trap electrons, forming negative oxygen ions, which will decrease the electron conductivity. 6.71 Plot (a) was obtained from an organic dye and plot (b) was obtained from a quantum dot suspension. For an organic dye solution, since the sizes of organic dye molecules are the same and the quantum levels (n) are well fixed, a distinct absorption spectrum will be obtained. For a quantum dot suspension, due to the diameter variation of quantum dots and variable quantum transition levels, the separation of energy levels will vary (as 1͞r2 ). Therefore, the wavelength of light that can cause excitation will also vary. In addition, since the sizes of quantum dots vary only slightly, a continuous absorption spectrum is normally observed. 6.73 (a) C: sp2 ; B: sp2 ; N: sp2 . (b) 10. (c) In C60 the carbon atoms are sp2 hybridized and are nearly planar. However, the curvature of the molecule introduces some strain at the carbon atoms so that there is some tendency for some of the carbon atoms to undergo conversion to sp3 hybridization. However, to make every carbon sp3 hybridized would introduce much more strain on the carbon cage and, after a certain point, further addition of hydrogen becomes unfavorable. (d) The spherical structures require the formation of five-member rings. Boron nitride cannot form these rings because they would require high-energy boron–boron or nitrogen–nitrogen bonds.(e) 3.491 gиcmϪ3 . (f) cubic Chapter 7 7.1 (a) isolated; (b) closed; (c) isolated; (d) open; (e) closed; (f) open 7.3 (a) 28 J; (b) positive 7.5 864 kJ 7.7 (a) on; (b) 4.90 ϫ 102 J 7.9 5500 kJ 7.11 –1626 kJ 7.13 (a) true if no work is done; (b) always true; (c) always false; (d) true only if w ϭ 0 (in which case ⌬U ϭ q ϭ 0); (e) always true 7.15 (a) absorbed, on the system, q is positive, w is positive; (b) released, on the system, q is negative, w is positive 7.17 (a) 1.4 ϫ 102 kJ; (b) 90% 7.19 25°C 7.21 14.8 kJи(°C)Ϫ1 7.23 (a) Ϫ226 J; (b) Ϫ326 J 7.25 NO2. The heat capacity increases with molecular complexity—as more atoms are present in the molecule, there are more possible bond vibrations that can absorb added energy. 9h2 8meL2 3h2 4meL2 3h2 8meL2 C26 ANSWERS 7.27 (a) Ϫ90.6 J; (b) Ϫ54.4 J 7.29 (a) R; (b) 3R; (c) R; (d) R 7.31 2.49 ϫ 1027 photons 7.33 (a) Cu; (b) 8.90 gиcmϪ3 7.35 (a) 8.22 kJиmolϪ1 ; (b) 43.5 kJиmolϪ1 7.37 33.4 kJ 7.39 31°C 7.41 (c) 7.43 (a) 448 kJ; (b) 1.47 ϫ 103 kJ; (c) 352 g 7.45 (a) 2.2 ϫ 101 g; (b) Ϫ1.3 ϫ 105 kJ 7.47 (a) 1.9 ϫ 105 kJиyearϪ1 ; (b) 7.6 ϫ 106 kJ/year 7.49 7 kJ 7.51 Ϫ320 kJ 7.53 31°C 7.55 23.9 ϫ 103 kJиLϪ1 7.57 (a) CO(g) + H2O(g) : CO2(g) + H2(g); (b) Ϫ41.2 kJиmolϪ1 7.59 1.90 kJ 7.61 Ϫ16 kJ 7.63 Ϫ312 kJиmolϪ1 7.65 Ϫ2986.71 kJиmolϪ1 7.67 Ϫ184.6 kJ 7.69 Ϫ72.80 kJ 7.71 11.3 kJ 7.73 Ϫ444 kJиmolϪ1 7.75 (a) 286 kJиmolϪ1 ; (b) Ϫ257 kJиmolϪ1 ; (c) 227 kJиmolϪ1 ; (d) Ϫ1 kJиmolϪ1 7.77 2564 kJиmolϪ1 7.79 (a) Ϫ412 kJиmolϪ1 ; (b) 673 kJиmolϪ1 ; (c) 63 kJиmolϪ1 7.81 (a) Ϫ597 kJиmolϪ1 ; (b) Ϫ460 kJиmolϪ1 ; (c) 0 kJиmolϪ1 7.83 (a) ϩ248 kJиmolϪ1 ; (b) Ϫ45 kJиmolϪ1 ; (c) Ϫ115 kJиmolϪ1 7.85 approximately 228 kJ 7.87 (a) 33.93 kJиmolϪ1 . (b) 30.94 kJиmolϪ1 . (c) The value in the table is 30.8 kJиmolϪ1 for the enthalpy of vaporization of benzene. Heat capacities are not strictly constant with temperature. 7.89 For the reaction: A + 2B : 3C + D the molar enthalpy of reaction at temperature 2 is given by: Finally, , which is Kirchhoff’s law. 7.91 132.0 kJ 7.93 (a) 2H2S(g) + O2(g) : 2S(s) + 2H2O(l), ⌬H ϭ Ϫ530. kJ; (b) Ϫ4.96 ϫ 105 kJ; (c) cooled 7.95 12.71 kJиmolϪ1 7.97 7.53 kJиmolϪ1 7.99 (a) : (b) ϭ 0.4873, ϭ 0.1188, ϭ 0.02639; (c) 0.999 atm 7.101 (a) 131.29 kJиmolϪ1 , endothermic; (b) 623 kJ 7.103 (a) 14.7 mol; (b) Ϫ4.20 ϫ 103 kJ 7.105 (a) 3.72 kJ; (b) Ϫ3267.5 kJ; (c) Ϫ3263.8 kJ 7.107 (a) (1) (2) C C C H H HH H H H H H C C C H C C C H H H H H H H C C C H mN2 mH2OmCO2 6 CO2(g) + 7 2 H2O(l) + 1 2 N2(g)C6H5 NH2(l) + 31 4 O2(g) ¢Hr,2° = ¢Hr,1° + ¢Cp(T2 - T1) = ¢Hr,1° + [3Cp,m(C) + Cp,m(D) - Cp,m(A) - 2Cp,m(B)](T2 - T1) + [3Cp,m(C) + Cp,m(D) - Cp,m(A) - 2Cp,m(B)](T2 - T1) = 3Hm,1°(C) + Hm,1°(D) - Hm,1°(A) - 2Hm,1°(B) -[Hm,1°(A) + Cp,m(A)(T2 - T1)] - 2[Hm,1°(B) + Cp,m(B)(T2 - T1)] = 3[Hm,1°(C) + Cp,m(C)(T2 - T1)] + [Hm,1°(D) + Cp,m(D)(T2 - T1)] = 3Hm,2°(C) + Hm,2°(D) - Hm,2°(A) - 2Hm,2°(B) ¢Hr,2° = Hm,2°(products) - Hm,2°(reactants) 5 2 3 2 5 2 (3) (b) Ϫ372 kJ. (c) Ϫ205.4 kJиmolϪ1 . (d) The hydrogenation of benzene is much less exothermic than predicted by bond enthalpy estimations. Part of this difference can be due to the inherent inaccuracy of using average values, but the difference is so large that this cannot be the complete explanation. As may be expected, the resonance energy of benzene makes it more stable than would be expected by treating it as a set of three isolated double and three isolated single bonds. The difference in these two values is a measure of how much more stable benzene is than the Kekulé structure would predict. 7.109 (a) 2326 kJиmolϪ1 . (b) 3547 kJ. (c) more stable. (d) 20 kJ per carbon atom. (e) 25 kJ per carbon atom. (f) There is slightly less stabilization per carbon atom in C60 than in benzene. This fits with expectations, as the C60 molecule is forced by its geometry to be curved. 7.111 From the combustion equations we can see that the differences are (1) the consumption of more moles of O2(g) and (2) the production of three more moles of H2O(l) for the combustion of aniline. Because the of O2(g) is 0, the net difference will be the production of 3 more moles of . 7.113 (a) 1.5 L; (b) SO2(g); (c) 1.1 L; (d) 40 J, on the system; (e) Ϫ3.0 kJ, heat leaves the system; (f) Ϫ2960 J 7.115 (a) (b) CH4: Ϫ698 kJиmolϪ1 ; CH3OCH3: Ϫ1070 kJиmolϪ1 ; CH3CH2OH: Ϫ988 kJиmolϪ1 . The burning of 1 mole of dimethyl ether releases the most heat. (c) Methane as it releases the most heat per gram. (d) 1.1 ϫ 103 L. (e) methane gas, Ϫ890 kJиmolϪ1 CO2 (less CO2); ethanol liquid, Ϫ684 kJиmolϪ1 CO2 (more CO2); octane liquid, Ϫ684 kJиmolϪ1 CO2 (more CO2) Chapter 8 8.1 (a) 0.341 JиKϪ1 иsϪ1 . (b) 29.5 kJиKϪ1 иdayϪ1 . (c) Less, because in the equation ; if T is larger ⌬S is smaller. 8.3 (a) 0.22 JиKϪ1 . (b) 0.17 JиKϪ1 . (c) The entropy change is smaller at higher temperatures. The same amount of heat has a greater effect on entropy changes when transferred at lower temperatures. 8.5 (a) 6.80 JиKϪ1 ; (b) 4.08 JиKϪ1 8.7 14.8 JиKϪ1 8.9 42.4 JиKϪ1 8.11 Ϫ14.6 JиKϪ1 8.13 Assume the transfer of energy as heat is reversible. The change in entropy for each block (block 1 and block 2) is . If energy is transferred, then the change in entropy for the system is . If 1 J of energy is transferred from block 2 to block 1, . For the transfer of heat from block 2 to block 1 to be spontaneous, ⌬S must be positive and, therefore, T2 would have to be greater than T1. 8.15 (a) Heat enters the house interior and the entropy of the house interior increases. Heat leaves the house exterior and the entropy of the house exterior decreases. (b) ⌬Sinterior Ͻ ⌬Sexterior q1 = +1 J, q2 = -1 J, and ¢S = 1 T1 - 1 T2 ¢S = ¢S1 + ¢S2 = q1 T1 + q2 T2 ¢S1 = q1 T1 and ¢S2 = q2 T2 ¢S = -¢H T H® C O® C å å H H H ® ® å å H H ™ ™ H HC C å å å å å å å H H H å H O ™ ™ H® C ®H å å H H H2O(l) or 3 * (-285.83 kJиmol-1 ) = -857.49 kJ ¢Hf° 18 4 [-205 kJ - (-372 kJ) = 167 kJ] C C C H H HH H H H H H H H C C C H ODD-NUMBERED EXERCISES C27 8.17 (a) Ϫ22.0 JиKϪ1 ; (b) 134 JиKϪ1 8.19 (a) 290 K. (b) 293.9 K. (c) good agreement. (d) Because the enthalpy and entropy of vaporization are slightly different from the values calculated at 298 K, but the boiling point of ethanal is not 298 K. 8.21 (a) 253 K. (b) 248 K, which is in reasonably close agreement. The value 85 J KϪ1 molϪ1 is an average value for the entropy of vaporization of organic liquids and therefore deviations are expected when using this average value for individual organic liquids. 8.23 (a) 30 kJиmolϪ1 ; (b) Ϫ11 JиKϪ1 8.25 COF2; COF2, and BF3 are both trigonal planar molecules, but it would be possible for the molecule to be disordered with the fluorine and oxygen atoms occupying the same locations. Because all the groups attached to boron are identical, such disorder is not possible. 8.27 14.9 JиKϪ1 8.29 (a) HBr(g); (b) NH3(g); (c) I2 (l); (d) 1.0 mol Ar(g) at 1.00 atm 8.31 C(s, diamond) Ͻ H2O(s) Ͻ H2O(l) Ͻ H2O(g). It is easy to order H2O in its various phases because entropy will increase when going from a solid to a liquid to a gas. The main question concerns where to place C(s, diamond) in this order, and that will essentially become a question of whether C(s, diamond) should have more or less entropy than H2O(s), because we would automatically expect C(s, diamond) to have less entropy than any liquid. Water is a molecular substance held together in the solid phase by weak hydrogen bonds, and in C(s, diamond) the carbon is more rigidly held in place and will have less entropy. 8.33 (a) Iodine is expected to have higher entropy due to its larger mass and consequently a larger number of fundamental particles. (b) When we consider the two structures, it is clear that 1-pentene will have more flexibility in its framework than cyclopentane, which will be comparatively rigid. Therefore, we predict 1-pentene to have a higher entropy. (c) Ethene (or ethylene) is a gas and polyethylene is a solid, so we automatically expect ethene to have a higher entropy. Also, for the same mass, a sample of ethene will be composed of many small molecules, whereas polyethylene will be made up of fewer but larger molecules. 8.35 (a) decrease; (b) increase; (c) decrease 8.37 ⌬SB Ͻ ⌬SC Ͻ ⌬SA. The change in entropy for container A is greater than that for container B or C due to the greater number of particles. The change in entropy in container C is greater than that of container B because of the disorder due to the vibrational motion of the molecules in container C. 8.39 (a) Ϫ163.34 JиKϪ1 иmolϪ1 ; the entropy change is negative because 1 mol of a liquid is formed from 1.5 mol of gas. (b) Ϫ86.5 JиKϪ1 иmolϪ1 ; the entropy change is negative because the number of moles of gas has decreased by 0.5. (c) 160.6 JиKϪ1 иmolϪ1 ; the entropy change is positive because the number of moles of gas has increased by 1. (d) Ϫ36.8 JиKϪ1 иmolϪ1 ; the four moles of solid products are more ordered than the four moles of solid reactants. 8.41 If ⌬S(true) for heating graphite from 298 K to 400 K is = 3.31 JиK-1 иmol-1 (-8.54 * 105 JиKиmol-1 ) 2 a 1 (400 K)2 - 1 (298 K)2 b + (0.00477 JиK-2 иmol-1 )(400 K - 298 K) = (16.86 JиK-1 иmol-1 )lna 400 K 298 K b + = a lna T2 T1 b + b(T2 - T1) - c 2 a 1 T2 2 - 1 T1 2 b = L T2 T1 a a T + b + c T3 b dT = aa ln(T) + bT - c 2T2 b ` T2 T1 ¢S = L T2 T1 a + bT + c>T2 T dT CP,m = a + bT + c>T2 , then dS = dqrev T = CP,mdT T and, therefore, ¢S = L T2 T1 CP,m T dT. If we assume a constant heat capacity at the mean temperature of 350 K, and Not integrating the heat capacity leads to roughly a 3.0% error in ⌬S. 8.43 111 JиKϪ1 иmolϪ1 8.45 ⌬Sc ϭ 11.9 JиKϪ1 , ⌬Sh ϭ 11.1 JиKϪ1 , ⌬Stot ϭ 0.8 JиKϪ1 8.47 (a) ⌬Ssurr ϭ Ϫ73 JиKϪ1 , ⌬Ssystem ϭ 73 JиKϪ1 ; (b) ⌬Ssurr ϭ Ϫ29.0 JиKϪ1 , ⌬Ssystem ϭ 29.0 JиKϪ1 ; (c) ⌬Ssurr ϭ Ϫ29.0 JиKϪ1 , ⌬Ssystem ϭ 29.0 JиKϪ1 8.49 (a) ; (b) , 8.51 Spontaneous change means ⌬Stot Ͼ 0. A vapor to liquid change is condensation and it releases heat. However, as shown in the diagram, the temperature of the system does not change. Therefore the released heat must have left the system to the surroundings. Since heat flows from hot to cold, the temperature of the surroundings (Tsurr) must be lower than the temperature of the system (Tsys), and since , then ⌬Stot Ͼ 0. 8.53 Exothermic reactions tend to be spontaneous because the result is an increase in the entropy of the surroundings. Using the mathematical relationship , it is clear that if ⌬Hr is large and negative compared to ⌬Sr, then the reaction will generally be spontaneous. 8.55 (a) ⌬Hr° ϭ Ϫ235.8 kJиmolϪ1 , ⌬Sr° ϭ Ϫ133.17 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ195.8 kJиmolϪ1 ; (b) ⌬Hr° ϭ 11.5 kJиmolϪ1 , ⌬Sr° ϭ Ϫ149.7 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ 56.2 kJиmolϪ1 ; (c) ⌬Hr° ϭ Ϫ57.20 kJиmolϪ1 , ⌬Sr° ϭ Ϫ175.83 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ4.73 kJиmolϪ1 8.57 (a) : ⌬Hr° ϭ Ϫ46.11 kJиmolϪ1 , ⌬Sr° ϭ Ϫ99.38 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ16.49 kJиmolϪ1 (b) : ; ⌬Hr° ϭ Ϫ241.82 kJиmolϪ1 , ⌬Sr° ϭ Ϫ44.42 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ228.58 kJиmolϪ1 (c) : ; ⌬Hr° ϭ Ϫ110.53 kJиmolϪ1 , ⌬Sr° ϭ 89.36 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ137.2 kJиmolϪ1 (d) : ; ⌬Hr° ϭ 33.18 kJиmolϪ1 , ⌬Sr° ϭ Ϫ60.89 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ 51.33 kJиmolϪ1 8.59 (a) Ϫ141.74 kJиmolϪ1 , spontaneous; (b) 130.4 kJиmolϪ1 , not spontaneous; (c) Ϫ10590.9 kJиmolϪ1 , spontaneous 8.61 (a) and (d) are stable. 8.63 (a) PCl5(g) 8.65 (a) ⌬Hr° ϭ Ϫ196.10 kJиmolϪ1 , ⌬Sr° ϭ 125.8 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ233.56 kJиmolϪ1 ; (b) ⌬Hr° ϭ Ϫ748.66 kJиmolϪ1 , ⌬Sr° ϭ 14.6 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ713.02 kJиmolϪ1 8.67 (a) ⌬Gr° ϭ Ϫ98.42 kJиmolϪ1 , spontaneous below 612.9 K; (b) ⌬Gr° ϭ Ϫ283.7 kJиmolϪ1 , spontaneous at all temperatures; (c) ⌬Gr° ϭ 3.082 kJиmolϪ1 , nonspontaneous at all temperatures 8.69 Reaction A is spontaneous, but reaction B is not spontaneous at any temperature. 8.71 21.6 mol 8.73 (a) 1 ϭ 1-propanol; (b) no 8.75 (a) ⌬Go Ͻ 0; (b) ⌬Ho , unable to tell; (c) ⌬So , unable to tell; (d) ⌬Stotalr Ͼ 0 8.77 Higher; the cis compound will have 12 different orientations and the trans compound will have only 3 different orientations. 8.79 (a) W ϭ 3. (b) W ϭ 12. (c) Initially, one of the three-atom systems had two atoms in higher energy states. In part (b), the system NO2(g)1 2 N2(g) + O2(g) CO(g)C(s, graphite) + 1 2 O2(g) H2O(g)H2(g) + 1 2 O2(g) NH3(g);1 2 N2(g) + 3 2 H2(g) ¢Gr = ¢Hr - T¢Sr ¢Ssys = qrev Tsys and ¢Ssurr = qrev Tsurr ¢Ssurr = 0, ¢Stot = +3.84 JиK-1 .¢S = +3.84 JиK-1 ¢Stot = 0, so ¢Ssurr = -¢S = -3.84 JиK-1 3.41 JиK-1 иmol-1 ¢S(mean) = CP,m ln T2 T1 = (11.6 JиK-1 иmol-1 )lna 400 K 298 K b = = 11.6 JиK-1 иmol-1 (-8.54 * 105 JиKиmol-1 ) (350 K)2 CP,m = (16.86 JиK-1 иmol-1 ) + (0.00477 JиK-2 иmol-1 )(350 K) + C28 ANSWERS will be at equilibrium when each three-atom system has one quantum of energy. Therefore, energy will flow from the system with two quanta to the system with none. 8.81 According to Trouton’s rule, the entropy of vaporization of an organic liquid is a constant of approximately 85 JиmolϪ1 и KϪ1 . The relationship between entropy of fusion, enthalpy of fusion, and melting point is given by . . . . These numbers are reasonably close but clearly much smaller than the value associated with Trouton’s rule. 8.83 Fe2O3 is thermodynamically more stable because ⌬Gr° for the interconversion reaction is negative. 8.85 (a) Ϫ110.0 kJиmolϪ1 ; (b) 7.14 ϫ 10Ϫ2 molиLϪ1 8.87 (a) no; (b) positive; (c) positional disorder; (d) thermal disorder; (e) dispersal of matter 8.89 (a) method (i); (b) method (i); (c) no 8.91 The entries all correspond to aqueous ions. The fact that they are negative is due to the reference point that has been established. Because ions cannot actually be separated and measured independently, a reference point that defines has been established. This definition is then used to calculate the standard entropies for the other ions. The fact that they are negative will arise in part because the solvated ion will be more ordered than the isolated ion and solvent molecules 8.93 (a) 8.57 kJ at 298 K, Ϫ0.35 kJ at 373 K, Ϫ6.29 kJ at 423 K. (b) 0 kJ. (c) The discrepancy arises because the enthalpy and entropy values calculated from the tables are not rigorously constant with temperature. Better values would be obtained by using the actual enthalpy and entropy of vaporization measured at the boiling point. 8.95 8.97 eϪ⌬E/kT will tend toward 1 as : 8.99 (a) Since standard molar entropies increase with temperature (more translational, vibrational, and rotational motion), the term becomes more negative at higher temperatures. (b) For gases with translational motion, their increase in standard molar entropy on heating, is much larger than for solids and liquids. Therefore, their term is more negative. 8.101 The dehydrogenation of cyclohexane to benzene follows the equation : . The reaction of ethyne with hydrogen can be examined similarly: : We can now combine these two reactions: : : : ¢Gr° = -205.13 kJиmol-1 C6H6(l) + 3 C2H6(g)C6H12(l) + 3 C2H2(g) ¢Gr° = 3(-100.97 kJиmol-1 )C2H6(g)]+ 3[C2H2(g) + H2(g) ¢Gr° = + 97.6 kJиmol-1 C6H6(l) + 3 H2(g)C6H12 (l) = -100.97 kJиmol-1 = (-32.82 kJиmol-1 ) - 68.15 kJиmol-1 ¢Gr° = ¢Gf°(C2H6, g) - ¢Gf°(C2H2, g) C2H6(g)C2H2(g) + H2(g) C6H6(l) + 3 H2(g)C6H12(l) -T¢Sm° -T¢Sm° q.T B ϭ 0.1 T B ϭ 1 T B ϭ 10 T B ϭ 100 T Entropy(JиKϪ1 ) 8 6 4 2 0 Temperature (K) 6000 500100 200 300 400 (Mn+ + xH2O) M(H2O)x n+ Sm°(H+ , aq) = 0 7.12 JиK-1 For Na : ¢Sfus° = 2640 J 371 K =9.79 JиK-1 For Hg : ¢Sfus° = 2290 J 234 K =For Pb : ¢Sfus° = 5100 J 600 K = 8.50 JиK-1 ¢Sfus° = ¢Hfus° Tfus We can see that by combining these two reactions, the overall process becomes spontaneous. Essentially, we are using the energy of the favorable reaction to drive the nonfavorable process. 8.103 (a) (1) (2) (3) (b) (1 : 2) ⌬Hr° ϭ Ϫ4.18 kJиmolϪ1 , ⌬Sr° ϭ Ϫ4.33 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ2.89 kJиmolϪ1 ; (1 : 3) ⌬Hr° ϭ Ϫ9.91 kJиmolϪ1 , ⌬Sr° ϭ Ϫ7.11 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ7.79 kJиmolϪ1 ; (2 : 3) ⌬Hr° ϭ Ϫ5.73 kJиmolϪ1 , ⌬Sr° ϭ Ϫ2.78 JиKϪ1 иmolϪ1 , ⌬Gr° ϭ Ϫ4.90 kJиmolϪ1 ; (c) The most stable of the three compounds is 2-methylpropene. (d) 8.105 (a) 2 NaN3(s) : 3 N2(g) ϩ 2 Na(g). (b) is positive because a gas is produced (from a solid). (c) Azide ion, ; nitrogen is oxidized. (d) 688.4 JиKϪ1 иmolϪ1 ; (e) Ϫ3.39 ϫ 104 JиmolϪ1 ; (f) yes. (g) yes, lowered Chapter 9 9.1 0.017 g 9.3 (a) 87°C; (b) 113°C 9.5 289 K 9.7 (a) 28.3 kJиmolϪ1 ; (b) 91.3 JиKϪ1 иmolϪ1 ; (c) 1.1 kJиmolϪ1 ; (d) 309 K 9.9 (a) 28.6 kJиmolϪ1 ; (b) 90.6 JиKϪ1 иmolϪ1 ; (c) 0.53 atm 9.11 0.19 atm 9.13 (a) vapor; (b) liquid; (c) vapor 9.15 (a) 2.4 K; (b) about 10 atm; (c) 5.5 K; (d) no 9.17 (a) At the lower pressure triple point, liquid helium-I and -II are in equilibrium with helium gas; at the higher pressure triple point, liquid helium-I and -II are in equilibrium with solid helium. (b) helium-I 9.19 It would become a solid. 9.21 (a) water; (b) benzene; (c) water 9.23 (a) hydrophilic; (b) hydrophobic; (c) hydrophobic; (d) hydrophilic 9.25 (a) 6.4 ϫ 10Ϫ4 molиLϪ1 ; (b) 1.5 ϫ 10Ϫ2 molиLϪ1 ; (c) 2.3 ϫ 10Ϫ3 molиLϪ1 9.27 (a) 4 mgиLϪ1 or 4 ppm; (b) 0.1 atm; (c) 0.5 atm 9.29 (a) By Henry’s law, the concentration of CO2 in solution will double. (b) No change in the equilibrium will occur; the partial pressure of CO2 is unchanged and the concentration is unchanged. 9.31 1.5 g 9.33 (a) negative; (b) Li2SO4(s) : 2 Liϩ (aq) ϩ SO4 2Ϫ (aq) ϩ heat; (c) enthalpy of hydration 9.35 (a) 6.7 ϫ 102 J; (b) Ϫ5.0 ϫ 102 J; (c) Ϫ24.7 kJ; (d) 8.2 ϫ 102 J 9.37 (a) 0.856 m; (b) 0.18 m; (c) 0.0571 m 9.39 (a) 0.248 m; (b) 0.246 M 9.41 (a) 1.35 m; (b) 0.519 m; (c) 28.43 m 9.43 (a) 13.9 g; (b) 29 g 9.45 The free energy of the solvent in the NaCl solution will always be lower than the free energy of pure water; if given enough time, all of the water from the “pure water” beaker will become part of the NaCl solution, leaving an empty beaker. An equilibrium will be established between the solvent and the water vapor. 9.47 (a) 684 Torr; (b) 758 Torr 9.49 7.80 ϫ 10Ϫ2 mol 9.51 (a) 0.052; (b) 115 gиmolϪ1 9.53 (a) 100.34°C; (b) 81.0°C 9.55 1.6 ϫ 102 gиmolϪ1 9.57 (a) 1.84; (b) 0.318 molиkgϪ1 ; (c) 83.8% 9.59 The compound that freezes at the lower temperature will have the largest (assuming that i ϭ 1, since we are told they are both|¢Tf | - 1 3 ; nitrogen, 0 ¢Sr° Sm°(1) 7 Sm°(2) 7 Sm°(3). H3C H3C C C H H 2-Methylpropene H3C C C H H CH3 trans-2-Butene H3C C C H H CH3 cis-2-Butene ODD-NUMBERED EXERCISES C29 molecular compounds). Since the same mass of each compound is present in the same amount of solvent for each solution, the compound with the lower molar mass will have the larger number of moles and therefore the larger (since the compound with the largest molar amount present will have the largest amount of solute particles present). Since compound A caused the water to freeze at a lower T than compound B, compound A must have the lower molar mass. Compound B must therefore have the greater molar mass. 9.61 Ϫ0.20°C 9.63 (a) 0.24 atm; (b) 48 atm; (c) 0.72 atm 9.65 (a) 1.0 molиLϪ1 ; (b) 24 atm 9.67 2.0 ϫ 103 gиmolϪ1 9.69 5.8 ϫ 103 gиmolϪ1 9.71 (a) 1.2 atm; (b) 0.048 atm; (c) 8.3 ϫ 10Ϫ5 atm 9.73 2.5 ϫ 105 gиmolϪ1 9.75 (a) P ϭ 78.2 Torr, xbenzene ϭ 0.91, xtoluene ϭ 0.09; (b) P ϭ 43.0 Torr, xbenzene ϭ 0.469, xtoluene ϭ 0.531 9.77 63 g 9.79 Raoult’s law applies to the vapor pressure of the mixture, so positive deviation means that the vapor pressure is higher than expected for an ideal solution. Negative deviation means that the vapor pressure is lower than expected for an ideal solution. Negative deviation will occur when the interactions between the different molecules are somewhat stronger than the interactions between molecules of the same kind. (a) For methanol and ethanol, we expect the types of intermolecular attractions in the mixture to be similar to those in the component liquids, so that an ideal solution is predicted. (b) For HF and H2O, the possibility of intermolecular hydrogen bonding between water and HF would suggest that negative deviation would be observed, which is the case. HF and H2O form an azeotrope that boils at 111°C, a temperature higher than the boiling point of either HF (19.4°C) or water. (c) Because hexane is nonpolar and water is polar with hydrogen bonding, we would expect a mixture of these two to exhibit positive deviation (the interactions between the different molecules would be weaker than the intermolecular forces between like molecules). Hexane and water do form an azeotrope that boils at 61.6°C, a temperature below the boiling point of either hexane or water. 9.81 A foam is a colloid formed by suspending a gas in a liquid or a solid matrix, while a sol is a suspension of a solid in a liquid. Some examples of foams are styrofoam and soapsuds; examples of sols are muddy water and mayonnaise. 9.83 Colloids will reflect or scatter light while true solutions do not (this is known as the Tyndall effect). 9.85 Water is a polar molecule and as a result will orient itself differently around cations and anions, aligning its dipole in such a way as to present the most favorable interaction possible. 9.87 (a) stronger; (b) low; (c) high; (d) weaker; (e) weak, low; (f) low; (g) strong, high 9.89 (a, b) Viscosity and surface tension decrease with increasing temperature; at high temperatures the molecules readily move away from their neighbors because of increased kinetic energy. (c, d) Evaporation rate and vapor pressure increase with increasing temperature because the kinetic energy of the molecules increase with temperature, and the molecules are more likely to escape into the gas phase. 9.91 (a) Butane will dissolve in tetrachloromethane. |¢Tf | (b) Calcium chloride will dissolve water. 9.93 (a) 78.5%; (b) Some of the water vapor in the air would condense as dew or fog. 9.95 (a) If masssolute appears greater, Msolute appears greater than the actual molar mass, as masssolute occurs in the numerator above. Also, the ⌬T measured will be smaller because less solute will actually be dissolved. This has the same effect as increasing the apparent Msolute. (b) Because the true masssolvent ϭ d ϫ V, if dsolvent is less than 1.00 gиcmϪ3 , then the true masssolvent will be less than the assumed mass. Msolute is inversely proportional to masssolvent, so an artificially high masssolvent will lead to an artificially low Msolute. (c) If the true freezing point is higher than the recorded freezing point, the true ⌬T Ͻ assumed ⌬T, or the assumed ⌬T Ͼ true ⌬T, and Msolute appears less than the actual Msolute, as ⌬T occurs in the denominator. (d) If not all the solute dissolved, the true masssolute Ͻ assumed masssolute or the assumed masssolute Ͼ true masssolute, and Msolute appears greater than the actual Msolute, as masssolute occurs in the numerator. 9.97 The water Coleridge referred to was seawater. The boards shrank due to osmosis (a net movement of water from the cells of the wood to the saline water). You can’t drink seawater: osmosis would cause a net flow of water from the cells of the body to the saline-enriched surround solution and the cells would die. 9.99 (a) 4.8 ϫ 103 gиmolϪ1 . (b) Ϫ3.9 ϫ 10Ϫ4 °C. (c) The freezing point change is so small that it cannot be measured accurately, so osmotic pressure would be the preferred method for measuring the molecular weight. 9.101 76 gиmolϪ1 9.103 (a) (b) The relationship to plot is ln P versus This should result in a straight line whose slope is and whose intercept is . The pressure must be given in atm for this relationship, because atm is the standard state condition. (c) 30. Torr; (d) 338.1 K 9.105 (a) 56.9 gиmolϪ1 . This experimental molar mass of acetic acid is less than the known molecular mass of the acid (60.6 gиmolϪ1 ), indicating that the acid is dissociating in solution, giving an i Ͼ 1. (b) 116 gиmolϪ1 ; this experimental molar mass of acetic acid is significantly higher than the known molar mass of the acid (60.0 gиmolϪ1 ), indicating that the acid is forming diniers in solution, giving an i Ͻ 1. A van’t Hoff factor less than 1 indicates that acetic acid is not completely dissolved in the benzene, or that acetic acid molecules are aggregating together in solution. 9.107 (a) y ϭ Ϫ3358.714x ϩ 12.247; (b) 28 kJиmolϪ1 ; (c) 1.0 ϫ 102 JиKϪ1 иmolϪ1 ; (d) 2.7 ϫ 102 K; (e) 2.1 ϫ 102 K 9.109 The critical temperatures are CH4, Ϫ82.1°C; C2H6, 32.2°C; C3H8, 96.8°C; C4H10, 152°C. The critical temperatures increase with increasing mass, showing the influence of the stronger London forces. 9.111 (a) 195 Torr in flask A, 222 Torr in flask B. (b) xacetone, gas ϭ 0.70, xchloroform, gas ϭ 0.30, xacetone ϭ 0.67, xchloroform ϭ 0.33. (c) The solution shows negative deviation from Raoult’s law. This means that the molecules of acetone and chloroform attract each other slightly more than molecules of the same kind. Under such circumstances, the vapor pressure is lower than expected from the ideal calculation. This will give rise to a ¢S°vap R - ¢H°vap R 1 T . = - 4595 K T + 13.59 ln P = - 38 200 Jиmol-1 8.314 JиK-1 иmol-1 и 1 T + 113.0 JиK-1 иmol-1 8.314 JиK-1 иmol-1 ClϪ Ca2ϩ C30 ANSWERS high-boiling azeotrope. The gas phase composition will also be slightly different from that calculated from the ideal state, but whether acetone or chloroform would be richer in the gas phase depends on which side of the azeotrope the composition lies. Because we are not given the composition of the azeotrope, we cannot state which way the values will vary. 9.113 The vapor pressure is more sensitive if ⌬Hvap is large. The fact that ⌬Hvap is large indicates that it takes a lot of energy to volatilize the sample, which means that the intermolecular forces are weaker. Hence, we expect the ratio P1͞P2 in the Clausius–Clapeyron equation to be larger. 9.115 0.32 mg A 9.117 27.3 g 9.119 18.5 L 9.121 The nonpolar chains of both the surfactant and pentanol will interact to form a hydrophobic region with the heads of the two molecules pointing away from this region toward the aqueous solution. To prevent the heads of the shorter pentanol molecules from winding up in the hydrophobic region, the layered structure might be comprised of a water region, a surfactant layer (heads pointing toward the water), a pentanol layer (with tails pointing toward the hydrophobic tails of the surfactant), and then another aqueous region. 9.123 (a) The hybridization of the carbon atoms in citric acid is (b) yes; (c) solid, soluble; (d) 0.3 M; (e) 2 ϫ 101 g; (f) 1 g Chapter 10 10.1 (a) False, equilibrium is dynamic. At equilibrium, the concentrations of reactants and products will not change, but the reaction will continue to proceed in both directions. (b) False, equilibrium reactions are affected by the presence of both products and reactants. (c) False, the value of the equilibrium constant is not affected by the amounts of reactants or products added as long as the temperature is constant. (d) true 10.3 10.5 (a) flask 3; (b) 54.5%; (c) 0.16 10.7 (a) CH4(g) ϩ 2 O2(g) CO2(g) ϩ 2 H2O(g); KC ϭ (b) I2(g) ϩ 5 F2(g) 2 IF5(g); KC ϭ (c) 2 NO2(g) ϩ F2(g) 2 FNO2(g); KC ϭ [FNO2]2 [F2][NO2]2 Δ [IF5]2 [I2][F2]5 Δ [CO2][H2O]2 [CH4][O2]2 Δ 0.30 0.20 0.10 0.00 Time Concentration(mol·L−1 ) [PCl3] = [Cl2] [PCl5] 3 4210 O O O C C C C CH2 CH2HO HO OH OH ß ßß ß ‰ ‰ ç ∂ ƒ ƒ å ƒ sp2 sp2 sp2 sp3 sp3sp3 10.9 (a) Because the volume is the same, the number of moles of O2 is larger in the second experiment. (b) Because Kc is a constant and the denominator is larger in the second case, the numerator must also be larger, so the concentration of O2 is larger in the second case. (c) Although [O2]3 /[O3]2 is the same, [O2]/[O3] will be different, a result seen by solving for Kc in each case. (d) Because Kc is a constant, [O2]3 /[O3]2 is the same. (e) Because [O2]3 /[O3]2 is the same, its reciprocal must be the same. 10.11 48.8 for condition 1, 48.9 for conditions 2 and 3 10.13 (a) (b) [H3PO4]4 [H2S]10 ; (c) 10.15 (a) 8.3 ϫ 10Ϫ1 kJиmolϪ1 . (b) Because ⌬Gr is positive, the reaction will be spontaneous to produce I2. 10.17 (a) Ϫ27 kJ·molϪ1 ; (b) form products 10.19 (a) 1 ϫ 1080 ; (b) 1 ϫ 1090 ; (c) 1 ϫ 10Ϫ23 10.21 (a) Ϫ19 kJиmolϪ1 ; (b) 68 kJиmolϪ1 10.23 form reactants 10.25 1.5 ϫ 1034 10.27 2.1 ϫ 10Ϫ5 molиLϪ1 10.29 5.4 bar 10.31 (a) 0.50; (b) no; (c) form products 10.33 (a) 6.9; (b) yes 10.35 (a) 4.3 ϫ 10Ϫ4 ; (b) 1.87 10.37 (a) 0.024; (b) 6.4; (c) 1.7 ϫ 103 10.39 6.6 ϫ 10Ϫ3 10.41 1.58 ϫ 10Ϫ8 10.43 (c) K ϭ x2 /(1.0 Ϫ 2x)2 10.45 (a) [Cl] ϭ 1.1 ϫ 10Ϫ5 molиLϪ1 , [Cl2] ϭ 0.0010 molиLϪ1 ; (b) [F] ϭ 3.2 ϫ 10Ϫ4 molиLϪ1 , [F2] ϭ 8 ϫ 10Ϫ4 molиLϪ1 ; (c) chlorine 10.47 (a) [PCl3] ϭ [Cl2] ϭ 0.010 molиLϪ1 ; [PCl5] ϭ 0.009 molиLϪ1 ; (b) 53% 10.49 [NH3] ϭ 0.200 molиLϪ1 , [H2S] ϭ 8 ϫ 10Ϫ4 molиLϪ1 10.51 [NO] ϭ 3.6 ϫ 10Ϫ4 molиLϪ1 ; the concentrations of N2 and O2 remain essentially unchanged at 0.114 molиLϪ1 . 10.53 1.1 10.55 [CO2] ϭ 8.6 ϫ 10Ϫ5 molиLϪ1 ; [CO] ϭ 4.9 ϫ 10Ϫ3 molиLϪ1 ; [O2] ϭ 4.6 ϫ 10Ϫ4 molиLϪ1 10.57 1.4 molиLϪ1 10.59 3.88 10.61 [SO2] ϭ 0.0011 molиLϪ1 ; [NO2] ϭ 0.0211 molиLϪ1 ; [NO] ϭ 0.0389 molиLϪ1 ; [SO3] ϭ 0.0489 molиLϪ1 10.63 (a) no; (b) form products; (c) [PCl5] ϭ 3.7 molиLϪ1 ; [PCl3] ϭ 5.93 molиLϪ1 ; [Cl2] ϭ 0.93 molиLϪ1 10.65 PHCl ϭ 0.22 bar; PH2 ϭ PCl2 ϭ 3.9 ϫ 10Ϫ18 bar 10.67 (a) decrease; (b) [CO] ϭ 0.156 molиLϪ1 ; [H2] ϭ 0.155 molиLϪ1 ; [CH3OH] ϭ 2.6 ϫ 10Ϫ4 molиLϪ1 10.69 9.7 ϫ 1033 L 10.71 (a) decreases; (b) decreases; (c) increases; (d) no change 10.73 (a) decreases; (b) increases; (c) increases; (d) increases; (e) no change; (f) decreases; (g) decreases 10.75 (a) reactants; (b) reactants; (c) reactants; (d) no change; (e) reactants 10.77 (a) increases; (b) no 10.79 (a) products; (b) products; (c) reactants; (d) reactants 10.81 PN2 ϭ 4.61 bar, PH2 ϭ 1.44 bar, PNH3 ϭ 23.85 bar 10.83 (a) KC ϭ 0.403; (b) [CO] ϭ [H2] ϭ 0.364 molиLϪ1 ; [H2O] ϭ 0.330 molиLϪ1 10.85 No, less ammonia will be formed at 700. K. 10.87 No, the reaction will proceed to produce more products. 10.89 (a) At 298 K: K ϭ 1 ϫ 10Ϫ7 ; (b) At 298 K: 10.91 ln a Kc2 Kc1 b = ¢Hr° R a 1 T1 - 1 T2 b - ¢n ln a T2 T1 b ¢n ln a T2 T1 b + ln a Kc2 Kc1 b = ¢Hr° R a 1 T1 - 1 T2 b K = 7.8 * 10-2 ; at 423 K: K = 0.22 K = 1 * 10-16 ; at 423 K: PBrF3 2 PBr2 PF2 3 1 PBCl3 2 ; ODD-NUMBERED EXERCISES C31 10.93 Increasing the temperature (a) would increase the formation of X (g) because the reaction is endothermic (bond breaking). 10.95 (a) reactants; (b) no effect; (c) products; (d) products; (e) products; (f) no effect for a dilute glucose solution; (g) reactants 10.97 (a) 2A(g) : B(g) ϩ 2C(g); (b) 1.54 ϫ 10Ϫ2 ; (c) 6.21 ϫ 10Ϫ4 10.99 (a) 2.9; (b) ⌬G°r(3) ϭ Ϫ10 kJиmolϪ1 , K ϭ 2 10.101 (a) [N2O4] ϭ 0.0065 molиLϪ1 , [NO2] ϭ 7.0 ϫ 10Ϫ3 molиLϪ1 ; (b) [N2O4] ϭ 0.015 molиLϪ1 , [NO2] ϭ 0.010 molиLϪ1 10.103 ␣ ϭ ;(a) 0.953; (b) 0.912 10.105 (a) 0; (b) 978 K; (c) 7.50 bar; (d) PCO(g) ϭ 7.04 bar; PH2O(g) ϭ 5.04 bar; PCO2(g) ϭ 8.96 bar; PH2(g) ϭ 3.96 bar 10.107 (a) Bond dissociation ⌬G° Halogen energy (kJ и molϪ1 ) (kJ и molϪ1 ) fluorine 146 19.1 chlorine 230 47.9 bromine 181 42.8 iodine 139 5.6 (b) There is a correlation between the bond dissociation energy and the free energy of formation of the atomic species, but the relationship is clearly not linear. For the three heavier halogens, there is a trend to decreasing free energy of formation of the atoms as the element becomes heavier, but fluorine is anomalous. The F—F bond energy is lower than expected, owing to repulsions of the lone pairs of electrons on the adjacent F atoms because the F—F bond distance is so short. 10.109 (a) 4.5 ϫ 10Ϫ29 ; (b) 0.285 bar or 0.289 atm; (c) 3.6 ϫ 10Ϫ15 bar or 3.6 ϫ 10Ϫ15 atm; (d) 846 mL 10.111 (a) 5.6 ϫ 1015 ; (b) (a) no change, (b) decrease, (c) decrease, (d) decrease, (e) no change, (f) decrease, (g) increase 10.113 6.8 kJ 10.115 (a) 11.2. (b) If NO2 is added, the equilibrium will shift to produce more N2O4. The amount of NO2 will be greater than initially present, but less than the 3.13 molиLϪ1 present immediately upon making the addition. Kc will not be affected. (c) [N2O4] ϭ 0.64 molиLϪ1 , [NO2] ϭ 2.67 molиLϪ1 10.117 H2O: 24 Torr; D2O: 21 Torr. The answer is that D has a lower zero-point energy than H. This makes the D2O—D2O “hydrogen bond” stronger than the H2O—H2O hydrogen bond. Because the hydrogen bond is stronger, the intermolecular forces are stronger, the vapor pressure is lower, and the boiling point is higher. Potential energy curves for the O—H and O—D bonds as a function of distance: ⌬E ϭ energy required to break O—H or O—D bond. 10.119 (a) 1.70 kJиmolϪ1 ; (b) Ϫ137.15 kJиmolϪ1 ; (c) 124.7 kJиmolϪ1 ; (d) Ϫ22.2 kJиmolϪ1 10.121 10.123 (a) (i) increases, (ii) increases, (iii) no change; (b) 0.242 mol Chapter 11 11.1 (a) CH3NH3 ϩ ; (b) NH2NH3 ϩ ; (c) H2CO3; (d) CO3 2Ϫ ; (e) C6H5OϪ ; (f) CH3CO2 Ϫ 1250 650 50 Temperature (K) K 350300250 1(K/(P + K)) 11.3 For all parts (a) to (e), H2O and H3Oϩ form a conjugate acid–base pair in which H2O is the base and H3Oϩ is the acid. (a) H2SO4(aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ HSO4 Ϫ (aq) H2SO4 and HSO4 Ϫ (aq) form a conjugate acid–base pair in which H2SO4 is the acid and HSO4 Ϫ (aq) is the base. (b) C6H5NH3 ϩ (aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ C6H5NH2 (aq) C6H5NH3 ϩ and C6H5NH2(aq) form a conjugate acid–base pair in which C6H5NH3 ϩ is the acid and C6H5NH2(aq) is the base. (c) H2PO4 Ϫ (aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ HPO4 2Ϫ (aq) H2PO4 Ϫ (aq) and HPO4 2Ϫ (aq) form a conjugate acid–base pair in which H2PO4 Ϫ (aq) is the acid and HPO4 2Ϫ (aq) is the base. (d) HCOOH(aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ HCO2 Ϫ (aq) HCOOH(aq) and HCO2 Ϫ (aq) form a conjugate acid–base pair in which HCOOH(aq) is the acid and HCO2 Ϫ (aq) is the base. (e) NH2NH3 ϩ (aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ NH2NH2(aq) NH2NH3 ϩ (aq) and NH2NH2(aq) form a conjugate acid–base pair in which NH2NH3 ϩ (aq) is the acid and NH2NH2(aq) is the base. 11.5 (a) Brønsted acid: , Brønsted base: ; (b) conjugate base to , conjugate acid to 11.7 (a) HClO3 (chloric acid); conjugate base: ClO3 Ϫ (b) HNO2 (nitrous acid); conjugate base: NO2 Ϫ 11.9 (a) yes, NH4 ϩ (acid), H2O (base); (b) yes, NH4 ϩ (acid), IϪ (base); (c) no; (d) yes, NH4 ϩ (acid), NH2 Ϫ (base) 11.11 (a) HCO3 – as an acid: Δ HCO3 – (acid) and CO3 2Ϫ (base), H2O (base) and H3Oϩ (acid); HCO3 Ϫ as a base: Δ HCO3 – (base) and H2CO3 (acid), H2O (acid) and OHϪ (base) (b) HPO4 2– as an acid: Δ HPO4 2Ϫ (acid) and PO4 3Ϫ (base), H2O (base) and H3Oϩ (acid); HPO4 2Ϫ as a base: Δ HPO4 2– (base) and H2PO4 – (acid), H2O (acid) and OH– (base) 11.13 (a) Two protons can be accepted (one on each N); or (b) (c) Each of the two nitro groups will show amphiprotic behavior in aqueous solution (can either accept a proton or donate a proton). O O NH N H ∗ ∗ O O NH N H2 ϩO O NH2 ϩ N H H2PO4 (aq) + OH- (aq), HPO4 2(aq) + H2O(l) H3O+ (aq) + PO4 3- (aq), HPO4 2(aq) + H2O(l) H2CO3(aq) + OH- (aq), H2O(l) + HCO3 - (aq) H3O+ (aq) + CO3 2_ (aq), HCO3 (aq) + H2O(l) HPO4 2: H2PO4 HNO3: NO3 - HPO4 2- HNO3 C32 ANSWERS 11.15 The Lewis structures of (a) to (e) are 11.17 (a) (b) 11.19 (a) basic; (b) acidic; (c) amphoteric; (d) basic 11.21 0.92 11.23 (a) 5.0 ϫ 10Ϫ13 molиLϪ1 ; (b) 1.0 ϫ 10Ϫ9 molиLϪ1 ; (c) 3.2 ϫ 10Ϫ12 molиLϪ1 11.25 (a) 1.4 ϫ 10Ϫ7 molиLϪ1 , pH ϭ 6.80; (b) 1.4 ϫ 10Ϫ7 molиLϪ1 11.27 [Ba2ϩ ] ϭ 2.5 ϫ 10Ϫ2 molиLϪ1 , [OHϪ ] ϭ 5.0 ϫ 10Ϫ2 molиLϪ1 , [H3Oϩ ] ϭ 2.0 ϫ 10Ϫ13 molиLϪ1 11.29 (a) 1.6; (b) 1.7 11.31 (a) (b) (c) (d) 11.33 (a) pH ϭ 1.84, pOH ϭ 12.16; (b) pH ϭ 0.96, pOH ϭ 13.04; (c) pH ϭ 12.26, pOH ϭ 1.74; (d) pH ϭ 10.85, pOH ϭ 3.15; (e) pH ϭ 10.99, pOH ϭ 3.01; (f) pH ϭ 4.28, pOH ϭ 9.72 11.35 (a) 0.18 molиLϪ1 ; (b) 18 molиLϪ1 ; (c) 110 g 11.37 (a) (b) (c) (d) (e) 11.39 (a) Δ Δ (b) Δ Δ (c) Δ Δ Kb = 3C6H5OH43OH- 4 3C6H5O- 4 C6H5OH(aq) + OH- (aq)C6H5O(aq) + H2O(l) Ka = 3H3O+ 43C6H5O- 4 3C6H5OH4 ; H3O+ (aq) + C6H5O(aq)C6H5OH(aq) + H2O(l) Kb = 3HCN43OH- 4 3CN- 4 HCN(aq) + OH- (aq)CN(aq) + H2O(l) Ka = 3H3O+ 43CN- 4 [HCN] ; H3O+ (aq) + CN(aq)HCN(aq) + H2O(l) Kb = 3HClO243OH- 4 3ClO2 - 4 HClO2(aq) + OH- (aq)ClO2 (aq) + H2O(l) Ka = 3H3O+ 43ClO2 - 4 3HClO24 ; H3O+ (aq) + ClO2 (aq)HClO2(aq) + H2O(l) H2SeO3 6 H3PO4 6 H3PO3 6 HSeO4 - . 1.2 * 10-2 ;3.5 * 10-3 ;1.0 * 10-2 ;7.6 * 10-3 ; 3H3O+ 4 = 10-5.3 molиL-1 = 5 * 10-6 molиL-1 3H3O+ 4 = 10-4.4 molиL-1 = 4 * 10-5 molиL-1 ; 3H3O+ 4 = 10-6.7 molиL-1 = 2 * 10-7 molиL-1 ; 3H3O+ 4 = 10-3.3 = 5 * 10-4 molиL-1 ; ¥ Cl ¥ ¥ ¥ ¥ å O S ¥ ¥ O ¥ Ϫ ¥ Cl ¥ Ϫ © ™ ¥ ¥ ¥ ¥ ¥ å O S ¥ ¥ O ¥ © å Lewis acid Lewis base Product F F F P¥¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ F ¥ ¥ ¥ F ¥ ¥¥ F ¥ ¥ ¥ F ¥ ¥ ¥ å åœ œ ç çF F P ¥ ¥ ¥ ¥ ¥ ¥ F ¥ ¥ ¥ F ¥ ¥ ¥ F ¥ ¥ ¥ åœ œ ç ç Ϫ Ϫ Lewis acid Lewis base Product A Ϫ H (e) Lewis base A A A A Ϫ F (d) Lewis base Ag+ (c) Lewis acid B F F F çç å ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ (b) Lewis acid NH H Hßß ¥ å (a) Lewis base 11.41 11.43 11.45 (a) strong; (b) weak; (c) weak; (d) weak; (e) weak; (f) strong; (g) weak 11.47 The larger the the stronger the corresponding acid. 2,4,6Trichlorophenol is the stronger acid because the chlorine atoms have a greater electron-withdrawing power than the hydrogen atoms present in the unsubstituted phenol. 11.49 The larger the of an acid, the stronger the corresponding conjugate base; hence, the order is aniline Ͻ ammonia Ͻ methylamine Ͻ ethylamine. 11.51 For oxoacids, the greater the number of highly electronegative O atoms attached to the central atom, the stronger the acid. This effect is related to the increased oxidation number of the central atom as the number of O atoms increases. Therefore, is the stronger acid, with the lower 11.53 (a) HCl is the stronger acid, because its bond strength is much weaker than the bond in HF, and bond strength is the dominant factor in determining the strength of binary acids. (b) is stronger; there is one more O atom attached to the Cl atom in than in HClO. The additional O in helps to pull the electron of the H atom out of the H— O bond. The oxidation state of Cl is higher in than in HClO. (c) is stronger; Cl has a greater electronegativity than Br, making the H—O bond in more polar than in (d) is stronger; Cl has a greater electronegativity than P. (e) is stronger. The explanation is the same as that for part (b). has one more O atom. (f) is stronger; C has greater electronegativity than Ge. See part (c). 11.55 (a) The — group that is bonded to the carboxyl group, —COOH, in trichloroacetic acid is more electron withdrawing than the — group in acetic acid. Thus, trichloroacetic acid is the stronger acid. (b) The — group in acetic acid has electron-donating properties, which means that it is less electron withdrawing than the —H attached to the carboxyl group in formic acid, HCOOH. Thus, formic acid is a slightly stronger acid than acetic acid. However, it is not nearly as strong as trichloroacetic acid. The order is 11.57 (a) pH ϭ 2.72, pOH ϭ 11.28, 0.95%. (b) pH ϭ 0.85, pOH ϭ 13.15, 70%. (c) pH ϭ 2.22, pOH ϭ 11.78, 3.0%. (d) Acidity increases when the hydrogen atoms in the methyl group of acetic acid are replaced by atoms that have a higher electronegativity, such as chlorine. 11.59 (a) Ka ϭ 0.09, pKa ϭ 1.0; (b) Kb ϭ 5.6 ϫ 10Ϫ4 , pKb ϭ 3.25 11.61 (a) pOH ϭ 3.00, pH ϭ 11.00, 1.8%; (b) pOH ϭ 4.38, pH ϭ 9.62, 0.026%; (c) pOH ϭ 2.32, pH ϭ 11.68, 1.4%; (d) pOH ϭ 3.96, pH ϭ 10.04, 2.5% 11.63 (a) 0.021 molиLϪ1 ; (b) 1.5 ϫ 10Ϫ2 molиLϪ1 11.65 pH ϭ 2.58, Ka ϭ 6.5 ϫ 10Ϫ5 11.67 pH ϭ 11.83, Kb ϭ 4.8 ϫ 10Ϫ5 11.69 7.7 ϫ 10Ϫ9 11.71 (a) Δ (b) Δ (c) Δ (d) neutral (e) Δ (f) Δ 11.73 (c) Ͻ (a) Ͻ (b) Ͻ (d). (d) is a weak base, pH will be the highest. (c) is a weak acid but the concentration high which gives this solution the lowest pH. (a) is a strong acid, but the concentration is low. (b) is a conjugate acid of CH3NH2 (Kb ϭ 3.6 ϫ 10Ϫ4 ) with a Ka ϭ 2.8 ϫ 10Ϫ11 , which is a very weak acid. 11.75 (a) 9.28; (b) 5.00; (c) 3.06; (d) 11.04 11.77 5.42 H3O+ (aq) + Cu(H2O)5OH+ (aq) Cu(H2O)6 2+ (aq) + H2O(l)less than 7, H3O+ (aq) + Al(H2O)5OH2+ (aq) Al(H2O)6 3+ (aq) + H2O(l)less than 7, HF(aq) + OH(aq)greater than 7, H2O(l) + F- (aq) HCO3 (aq) + OH(aq)greater than 7, H2O(l) + CO3 2- (aq) H3O+ (aq) + NH3(aq)less than 7, NH4 + (aq) + H2O(l) CH3COOH. CCl3COOH W HCOOH 7 CH3 CH3 CCl3 H2CO3 HNO3 HNO3 HClO4HBrO2.HClO2 HClO2 HClO2 HClO2 HClO2 HClO2 pKa. HIO3 pKa Ka, C5H5N(8.75) V NH3(4.75) E(14.00 - 3.45 = 10.55) 6 CH3CO2 (14.00 - 4.75 = 9.25) 6 HNO2(3.37) 6 HClO2(2.00) (CH3)2NH2 + (14.00 - 3.27 = 10.73) 6 + NH3OH(14.00 - 7.97 = 6.03) 6 ODD-NUMBERED EXERCISES C33 11.79 HBrO 11.81 (a) 1.8 ϫ 10Ϫ6 molиLϪ1 ; (b) 5.26 11.83 6.113 11.85 0.80 11.87 (a) 4.18; (b) 1.28; (c) 3.80 11.89 (a) 4.37; (b) 4.37 11.91 (a) 4.55; (b) 6.17 11.93 [H2CO3] ϭ 0.0455 molиLϪ1 ; [H3Oϩ ] ϭ [HCO3 Ϫ ] ϭ 1.4 ϫ 10Ϫ4 molиLϪ1 ; [CO3 2Ϫ ] ϭ 5.6 ϫ 10Ϫ11 molиLϪ1 ; [OHϪ ] ϭ 7.1 ϫ 10Ϫ11 molиLϪ1 11.95 0.0028 molиLϪ1 , [CO3 2Ϫ ] ϭ 0.0428 molиLϪ1 , [H3Oϩ ] ϭ 3.6 ϫ 10Ϫ12 molиLϪ1 11.97 (a) (b) (c) 11.99 [ ] ϭ 0.14 molиLϪ1 ; [H2SO3] ϭ 3.2 ϫ 10Ϫ5 molиLϪ1 ; [ ] ϭ 0.0054 molиLϪ1 11.101 (a) 6.54; (b) 2.12; (c) 1.49 11.103 [H3PO4] ϭ 6.4 ϫ 10Ϫ3 molиLϪ1 ; [H2PO4 Ϫ ] ϭ 8.6 ϫ 10Ϫ3 molиLϪ1 ; [HPO4 2Ϫ ] ϭ 9.5 ϫ 10Ϫ8 molиLϪ1 ; [PO4 3Ϫ ] ϭ 3.5 ϫ 10Ϫ18 molиLϪ1 11.105 6.174 11.107 7.205 11.109 1.0 ϫ 10Ϫ6 molиLϪ1 11.111 (a) 6.35, 7.35; (b) 6.34, 6.96 11.113 (a) 6.69, 7.22; (b) 6.64, 6.92 11.115 (a) Acid (1) is a strong acid because it totally dissociates. (b) Acid (3) has the strongest base because it is the weakest acid. (c) Acid (3) has the largest pKa. Since pKa ϭ ϪlogKa, the smallest Ka value will result in the largest pKa. 11.117 The apparent motion of hydronium and hydroxide ions is not as dependent on the diffusion of individual ions as other ions; they are formed and reformed as protons are transferred from and to water molecules in solution. Autoprotolysis allows rapid proton transfer between water molecules. 11.119 (a) C2HNaO4 (b) (c) sodium oxalate, amphiprotic, 2.71 11.121 The Lewis structure of boric acid is (a) no. (b) Boric acid acts as a Lewis acid because it accepts electron pairs (OHϪ ) from water, but its acidity is not due to its dissociation. 11.123 (a) Nitrous acid will act like a strong acid because its conjugate base, the nitrite ion, is a weaker base than the acetate ion. The presence of acetate ions will shift the proton transfer equilibrium of nitrous acid toward the products (NO2 – and H3Oϩ ) by consuming H3Oϩ , which will increase the apparent Ka of nitrous acid. Carbonic acid is a weaker acid than acetic acid, so no shift in equilibrium occurs. (b) Ammonia will act like a strong base because its conjugate acid, the ammonium ion, is a weaker acid than acetic acid. The presence of acetic acid will shift the proton transfer equilibrium of ammonia with water toward the products (NH4 ϩ and OH– ) by consuming OH– , which will increase the apparent Kb of ammonia. 11.125 6.9 ϫ 10Ϫ4 11.127 (a) D2O ϩ D2O D3Oϩ ϩ ODϪ ; (b) 14.870; (c) 3.67 ϫ 10Ϫ8 molиLϪ1 ; (d) pD ϭ pOD ϭ 7.435; (e) pD ϩ pOD ϭ pKhw ϭ 14.870 11.129 2.9% deprotonated; 271 K Δ B H H H H ßß ¥ ¥ O ¥ ¥ ¥ ¥ O ¥ OO ¥ å åå å ç ç Conjugate base B H ß H Hß ß ¥ O ¥ ¥ ¥ O ¥ O ¥ å å å Boric acid C C H O ™ ™ O™ ™ Ϫ O ¥ ¥ ¥ O ¥ ¥ SO3 2- HSO3 - H2AA2- ;HA- ; [H2CO3] = 2.3 * 10-8 molиL-1 , [OH] = [HCO3 ] = 11.131 1.3 ϫ 102 JиmolϪ1 11.133 The greater difference in the acidity constants, Ka1 and Ka2, of adipic acid and those of oxalic acid is due to the structural differences of these two acids. Adipic acid has four CH2 groups between the two carboxylic groups and this will cause a greater electron delocalization, which stabilizes the carboxylic anions. As a result, the two protons on the adipic acid can be easily removed almost simultaneously. This is why the two pKa values are so close. However, oxalic acid lacks the CH2 groups between the two carboxylic groups and a weaker electron delocalization ability of the anions results a large separation of the two pKa values. 11.135 (a) HbO2 Ϫ concentration will be lower in the tissues. (b) HbO2 Ϫ concentration will increase. 11.137 (a) CO2 will react with water to form carbonic acid, H2CO3. Determine the concentration of H3Oϩ . Under the specified conditions, pH ϭ 5.75. (b) [H2CO3] ϭ 4.4 ϫ 10Ϫ3 molиLϪ1 ; [HCO3 Ϫ ] ϭ 1.2 ϫ 10Ϫ4 molиLϪ1 ; [CO3 2Ϫ ] ϭ 4.2 ϫ 10Ϫ10 molиLϪ1 . (c) 50 kg. (d) 4.82. (e) 4.52. (f) 86.9 kg Chapter 12 12.1 (a) When solid sodium acetate is added to an acetic acid solution, the concentration of decreases because the equilibrium HC2H3O2(aq) ϩ H2O(l) Δ H3Oϩ (aq) ϩ C2H3O2 Ϫ (aq) shifts to the left to relieve the stress imposed by the increase of (Le Chatelier’s principle). (b) When HCl is added to a benzoic acid solution, the percentage of benzoic acid that is deprotonated decreases because the equilibrium Δ shifts to the left to relieve the stress imposed by the increased (Le Chatelier’s principle). (c) When solid is added to an ammonia solution, the concentration of decreases because the equilibrium Δ shifts to the left to relieve the stress imposed by the increased (Le Chatelier’s principle). Because decreases, increases and pH decreases. 12.3 (a) (b) 2.77 12.5 (a) 6.1 ϫ 10Ϫ10 mol. LϪ1 ; (b) 1.7 ϫ 10Ϫ11 molиLϪ1 ; (c) 2.5 ϫ 10Ϫ10 molиLϪ1 ; (d) 5.9 ϫ 10Ϫ9 molиLϪ1 12.7 (a) pH ϭ 1.62, pOH ϭ 12.38; (b) pH ϭ 1.22, pOH ϭ 12.78; (c) pH ϭ 1.92, pOH ϭ 12.08 12.9 (a) 9.46; (b) 9.71; (c) 9.31 12.11 (a) pH ϭ 6.3, change of 1.5; (b) pH ϭ 4.58, change of Ϫ0.17 12.13 increases by 1.16 12.15 12.17 (a) 2–4; (b) 3–5; (c) 11.5–13.5; (d) 6–8; (e) 5–7 12.19 (a) (b) (c) (d) 12.21 (a) (b) 77 g; (c) 1.8 g; (d) 2.8 ϫ 102 mL 12.23 (a) (b) 10 mL. (c) 5 mL. pH 12 10 8 6 4 2 0 Volume HCI (mL) 30 355 20 2515100 (b) pH at Stoichiometric point = 7.0 [CO3 2- ] [HCO3 - ] = 5.6; Na2HPO4 and Na3PO4, pKa = 12.68 CH2ClCOOH and NaCH2ClCO2, pKa = 2.85; NaH2PO4 and Na2 HPO4, pKa2 = 7.21; HClO2 and NaClO2, pKa = 2.00; [ClO- ] [HClO] = 9.3 * 10-2 pH = pKa = 3.08, Ka = 8.3 * 10-4 ; 3H3O+ 4 3OH- 43NH4 + 4 NH4 + (aq) + OH- (aq) NH3(aq) + H2O(l)OH- NH4Cl 3H3O+ 4 H3O+ (aq) + C6H5CO2 (aq)C6H5COOH(aq) + H2O(l) 3C2H3O2 - 4 H3O+ C34 ANSWERS 12.25 (a) 9.17 ϫ 10Ϫ3 L; (b) 0.0183 L; (c) 0.0635 molиLϪ1 ; (d) 2.25 12.27 (a) 234 gиmolϪ1 ; (b) 3.82 12.29 (a) 13.04; (b) 12.82; (c) 12.55; (d) 7.00; (e)1.80; (f) 1.55 12.31 79.4% 12.33 (a) 2.89; (b) 4.56; (c) 12.5 mL; (d) 4.75; (e) 25.0 mL; (f) 8.72 12.35 (a) 11.20; (b) 8.99; (c) 11 mL; (d) 9.25; (e) 22 mL; (f) 5.24; (g) methyl red 12.37 (a) Weak acid, because the initial pH of the acid ϭ 5.0 and the stoichiometric point occurs at pH ϭ10 (the anion is a base). (b) 1 ϫ 10Ϫ5 molиLϪ1 ; (c) Ka ϭ 10Ϫ7.5 ϭ 3 ϫ 10Ϫ8 ; (d) 3 ϫ 10Ϫ3 molиLϪ1 ; (e) 8 ϫ 10Ϫ3 M (f) phenolphthalien 12.39 The pH at the stoichiometric point is 8.8, which lies within the range of (c) thymol blue and (d) phenolphthalein. 12.41 Exercise 12.33: thymol blue or phenolphthalein; Exercise 12.35: methyl red or bromocresol green 12.43 (a) 37.4 mL; (b) (c) 12.45 (a) 22.0 mL; (b) 12.47 (a) a: initial point, b: first halfway point, c: first stoichiometric point, d: second halfway point, e: second stoichiometric point. Note: (i) The initial pH is higher than points b and c because we assume that the initial [Hϩ ] is from the first dissociation only (actually, the second dissociation contributes also); (ii) due to the close pKa values of thiosulfuric acid, only one obvious titration curve can be observed. In an actual aqueous titration, two protons will be titrated at the same time for this acid. (b) (C) ϭ 5.0 mL; (E) ϭ 10. mL. (c) First stoichiometric point: 1.2, second stoichiometric point: 7.0. 12.49 (a) 1.89; (b) 1.96; (c) 11.6 12.51 (a) 4.66; (b) 2.80; (c) 7.21 12.53 (a) 7.7 ϫ 10Ϫ13 ; (b) 1.7 ϫ 10Ϫ14 ; (c) 5.3 ϫ 10Ϫ3 ; (d) 6.9 ϫ 10Ϫ9 12.55 1.0 ϫ 10Ϫ12 12.57 (a) 1.30 ϫ 10Ϫ5 molиLϪ1 ; (b) 1.0 ϫ 10Ϫ3 molиLϪ1 ; (c) 9.3 ϫ 10Ϫ5 molиLϪ1 12.59 (a) 8.0 ϫ 10Ϫ10 molиLϪ1 ; (b) 1.2 ϫ 10Ϫ16 molиLϪ1 ; (c) 4.6 ϫ 10Ϫ3 molиLϪ1 ; (d) 1.3 ϫ 10Ϫ6 molиLϪ1 12.61 (a) 1.0 ϫ 10Ϫ12 molиLϪ1 ; (b) 3.1 ϫ 10Ϫ5 molиLϪ1 ; (c) 2.0 ϫ 10Ϫ3 molиLϪ1 ; (d) 0.20 molиLϪ1 12.63 (a) 1.6 ϫ 10Ϫ5 molиLϪ1 ; (b) 2.7 ϫ 102 ␮g 12.65 (a) 6.00; (b) 6.18 12.67 (a) yes; (b) no 12.69 (a) first to last: (b) Ni(OH)2 at pH Ϸ 7, Mg(OH)2 at pH Ϸ 10, Ca(OH)2 at pH Ϸ 13 12.71 The solubility difference is greatest between the two carbonates, and is the better choice of anion. 12.73 1.8 ϫ 10Ϫ9 molиLϪ1 12.75 (a) Δ (b) ; (c) 4 ϫ 10Ϫ4 molиLϪ1 2.0 * 10-4 molиL-1 K = KwиKb 2 = (4.0 * 10-11 )(2.9 * 10-11 )2 = 3.4 * 10-32 Ca2+ (aq) + 2HF(aq) + 2OH- (aq) CaF2(s) + 2H2O(l) CO3 2Ni(OH)2, Mg(OH)2, Ca(OH)2; 12 10 8 6 4 2 0 0 2 4 6 8 10 12 14 16 Volume KOH(aq)(mL) pH a b c d e 44.0 mL 112 mL74.8 mL; 12.77 2.0 ϫ 10Ϫ3 molиLϪ1 12.79 The two salts can be distinguished by their solubility in 1.0 molиLϪ1 The AgCl will dissolve, but most of the AgI will not. 12.81 In order to use qualitative analyses, the sample must first be dissolved. This can be accomplished by digesting the sample with concentrated and then diluting the resulting solution. HCl or could not be used because some of the metal compounds formed would be insoluble, whereas all of the nitrates would dissolve. Once the sample is dissolved and diluted, an aqueous solution containing chloride ions can be introduced. This should precipitate the as AgCl but would leave the bismuth and nickel in solution, as long as the solution is acidic. The remaining solution can then be treated with In acidic solution, will precipitate but NiS will not. Once the has been precipitated, the pH of the solution can be raised by the addition of base. Once this is done, NiS should precipitate. 12.83 0.260 molиLϪ1 in both acetic acid and sodium acetate 12.85 (a) 2.8; (b) 5.7; (c) HOOCCH2CO2 Ϫ 12.87 2.8 ϫ 10Ϫ2 12.89 2.2 ϫ 10Ϫ3 M 12.91 If the two pKa values of a diprotic acid are far apart (Ն1000), there will be two stoichiometric points observed. If the two pKa values of a diprotic acid are close (Ͻ500) (due to the electron delocalization of anions), like those of tartaric acid, there will be one stoichiometric point observed (i.e., two protons are titrated at about the same time). The titration curve in this case is not very steep due to the overlap titration of the first proton and the second proton. 12.93 The values from Table 12.4 are All the salts have the same expression for so the compound with the smallest will precipitate first, in this case CuS. 12.95 (a) 0.0796 molиLϪ1 . (b) At the stoichiometric point, pAgϩ ϭ 3.94. 12.97 (a) SO2(g) ϩ H2O(l) Δ H2SO3(aq); (b) 5 ϫ 10Ϫ7 mol; (c) 1.8 ppm 12.99 Ϫ345.65 kJиmolϪ1 12.101 (a) 3 ϫ 10Ϫ18 mol; (b) pH ϭ 5.8, change ϭ 0.3 12.103 (a) 4.93; (b) 2.08 g 12.105 (a) 9.3 ϫ 10Ϫ11 mol. LϪ1 . (b) [OHϪ ] ϭ 2.8 ϫ 10Ϫ10 M; pH ϭ 4.45. (c) Result in (b) is not reasonable because the OHϪ from water is ignored. [OHϪ ]water ϭ 1.0 ϫ 10Ϫ7 M. Actually, [OHϪ ] ϭ 1.0 ϫ 10Ϫ7 M in a saturated solution of Fe(OH)3 because the [OHϪ ] from Fe(OH)3 is much smaller than the [OHϪ ] from water; pH ϭ 7.0. (d) 5.0 ϫ 10Ϫ4 . (e) 5.3 g. (f) 60.1% pAg 5.5 5.0 4.5 4.0 3.5 3.0 2.5 2.0 1.5 Volume of AgNO3 (mL) 6010 40 5030200 Ksp Ksp, Ksp = [M2+ ][S2- 4, Cd2+ , 4 * 10-29 .Cu2+ , 1.3 * 10-36 ; Co2+ , 5 * 10-22 ; Ksp Bi2S3 Bi2S3H2S. Ag+ H2SO4 HNO3 NH3. ODD-NUMBERED EXERCISES C35 Chapter 13 13.1 (a) Cr reduced from 6ϩ to 3ϩ; C oxidized from 2Ϫ to 1Ϫ; (b) C2H5OH(aq) : C2H4O(aq) ϩ 2 Hϩ (aq) ϩ 2 eϪ ; (c) Cr2O7 2Ϫ (aq) ϩ 14 Hϩ (aq) ϩ 6 eϪ : 2 Cr3ϩ (aq) ϩ 7 H2O(l); (d) 8 Hϩ (aq) ϩ Cr2O7 2Ϫ (aq) ϩ 3 C2H5OH(aq) : 2 Cr3ϩ (aq) ϩ 3 C2H4O(aq) ϩ 7 H2O(l) 13.3 (a) 4 Cl2(g) ϩ S2O3 2Ϫ (aq) ϩ 5 H2O(l) : 8 ClϪ (aq) ϩ 2 SO4 2Ϫ (aq) ϩ 10 Hϩ (aq); Cl2 is the oxidizing agent and S2O3 2Ϫ is the reducing agent. (b) 2 MnO4 Ϫ (aq) ϩ Hϩ (aq) ϩ 5 H2SO3(aq) : 2 Mn2ϩ (aq) ϩ 3 H2O(l) ϩ 5 HSO4 Ϫ (aq); MnO4 Ϫ is the oxidizing agent and H2SO3 is the reducing agent. (c) Cl2(g) ϩ H2S(aq) : 2 ClϪ (aq) ϩ S(s) ϩ 2 Hϩ (aq); Cl2 is the oxidizing agent and H2S is the reducing agent. (d) H2O(l) ϩ Cl2(g) : HOCl(aq) ϩ Hϩ (aq) ϩ ClϪ (aq); Cl2 is both the oxidizing and the reducing agent. 13.5 (a) 3 O3(g) ϩ BrϪ (aq) : 3 O2(g) ϩ BrO3 Ϫ (aq); O3 is the oxidizing agent and BrϪ is the reducing agent. (b) 3 Br2(l) ϩ 6 OHϪ (aq) : 5 BrϪ (aq) ϩ BrO3 Ϫ (aq) ϩ 3 H2O(l); Br2 is both the oxidizing agent and the reducing agent. (c) 2 Cr3ϩ (aq) ϩ 4 OHϪ (aq) ϩ 3 MnO2(s) :2 CrO4 2Ϫ (aq) ϩ 2 H2O(l) ϩ 3 Mn2ϩ (aq); Cr3ϩ is the reducing agent and MnO2 is the oxidizing agent. (d) P4(s) ϩ 3 H2O(l) ϩ 3 OHϪ (aq) : 3 H2PO2 Ϫ (aq) ϩ PH3(g); P4(s) is both the oxidizing and the reducing agent. 13.7 half-reactions: P4S3(aq) ϩ 28 H2O(l) : 4 H3PO4(aq) ϩ 3 SO4 2Ϫ (aq) ϩ 44 Hϩ (aq) ϩ 38 eϪ ; NO3 Ϫ (aq) ϩ 4 Hϩ (aq) ϩ 3 eϪ : NO(aq) ϩ 2 H2O(l) overall reaction: 3 P4S3(aq) ϩ 38 NO3 Ϫ (aq) ϩ 20 Hϩ (aq) ϩ 8 H2O(l) : 12 H3PO4(aq) ϩ 9 SO4 2Ϫ (aq) ϩ 38 NO(g) 13.9 (a) Ϫ2.08 ϫ 105 J·molϪ1 ; (b) 7.47 ϫ 105 J·molϪ1 13.11 (a) cathode: Agϩ (aq) ϩ eϪ : Ag(s), anode: Ni2ϩ (aq) ϩ 2 eϪ : Ni(s), overall: 2 Agϩ (aq) ϩ Ni(s) : 2 Ag(s) ϩ Ni2ϩ (aq); (b) anode: 2 Hϩ (aq) ϩ 2eϪ : H2(g), cathode: Cl2(g) ϩ 2eϪ : 2 ClϪ (aq), overall: Cl2(g) ϩ H2(g) : 2 Hϩ (aq) ϩ 2 ClϪ (aq); (c) anode: Cu2ϩ (aq) ϩ 2 eϪ : Cu(s), cathode: Ce4ϩ (aq) ϩ eϪ : Ce3ϩ (aq), overall: 2 Ce4ϩ (aq) ϩ Cu(s) : Cu2ϩ (aq) ϩ 2 Ce3ϩ (aq); (d) cathode: O2(g) ϩ 2 H2O(l) ϩ 4 eϪ : 4 OHϪ (aq), anode: O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ : 2 H2O(l), overall: H2O(l) : Hϩ (aq) ϩ OHϪ (aq) (e) anode: Sn4ϩ (aq) ϩ 2 eϪ : Sn2ϩ (aq), cathode: Hg2Cl2(s) ϩ 2 eϪ : 2 Hg(l) ϩ 2 ClϪ (aq), overall: Sn2ϩ (aq) ϩ Hg2Cl2(s) : 2 Hg(l) ϩ 2 ClϪ (aq) ϩ Sn4ϩ (aq) 13.13 (a) cathode: Ni2ϩ (aq) ϩ 2 eϪ : Ni(s), anode: Zn2ϩ (aq) ϩ 2 eϪ : Zn(s), Zn(s)&Zn2ϩ (aq)&&Ni2ϩ (aq)&Ni(s) (b) cathode: 2[Ce4ϩ (aq) ϩ eϪ : Ce3ϩ (aq)], anode: I2(s) ϩ 2 eϪ : 2 IϪ (aq), Pt(s)&IϪ (aq)&I2(s)&&Ce4ϩ (aq), Ce3ϩ (aq)&Pt(s) (c) cathode: Cl2(g) ϩ 2 eϪ : 2 ClϪ (aq) E°(cathode) ϭ ϩ1.36 V, anode: 2 Hϩ (aq) ϩ 2 eϪ : H2(g) E°(anode) ϭ 0.00 V, Pt(s)&H2(g)&Hϩ (aq)&&ClϪ (aq)&Cl2(g)&Pt(s) (d) cathode: 3[Auϩ (aq) ϩ eϪ : Au(s)] E°(cathode) ϭ ϩ1.69 V, anode: Au3ϩ (aq) ϩ 3 eϪ : Au(s) E°(anode) ϭ ϩ1.40 V, Au(s)&Au3ϩ (aq)&&Auϩ (aq)&Au(s) 13.15 (a) cathode: Agϩ (aq) ϩ eϪ : Ag(s) E°(cathode) ϭ ϩ0.80 V, anode: AgBr(s) ϩ eϪ : Ag(s) ϩ BrϪ (aq) E°(anode) ϭ ϩ0.07 V, Ag(s)&AgBr(s)&BrϪ (aq)&&Agϩ (aq)&Ag(s) (b) cathode: O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ : 2 H2O(l) E°(cathode) ϭ ϩ1.23 V, anode: O2(g) ϩ 2 H2O(l) ϩ 4 eϪ : 4 OHϪ (aq) E°(anode) ϭ ϩ0.40 V, Pt(s)&O2(g)&OHϪ (aq)&&Hϩ (aq)&O2(g)&Pt(s) (c) anode: Cd(OH)2(s) ϩ 2 eϪ : Cd(s) ϩ 2 OHϪ (aq), cathode: Ni(OH)3(s) ϩ eϪ : Ni(OH)2(s) ϩ OHϪ (aq) E°(cathode) ϭ ϩ0.49 V, Cd(s)&Cd(OH)2(s)&KOH(aq)&&Ni(OH)3(s)&Ni(OH)2(s)&Ni(s) 13.17 (a) MnO4 Ϫ (aq) ϩ 8 Hϩ (aq) ϩ 5 eϪ : Mn2ϩ (aq) ϩ 4 H2O(l) (cathode half-reaction), 5[Fe2ϩ (aq) : Fe3ϩ (aq) ϩ eϪ ] (anode half-reaction) (b) MnO4 Ϫ (aq) ϩ 5 Fe2ϩ (aq) ϩ 8 Hϩ (aq) : Mn2ϩ (aq) ϩ 5 Fe3ϩ (aq) ϩ 4 H2O(l), Pt(s)&Fe3ϩ (aq), Fe2ϩ (aq)&&Hϩ (aq), MnO4 Ϫ (aq), Mn2ϩ (aq) &Pt(s) 13.19 (a) ϩ0.75 V; (b) ϩ0.37 V; (c) ϩ0.52 V; (d) ϩ1.52 V 13.21 (a) Ecell° ϭ E°(cathode) Ϫ E°(anode) ϭ ϩ0.96 V Ϫ (ϩ0.79 V) ϭ ϩ0.17 V. Hg(l)&Hg2 2ϩ (aq)&&NO3 Ϫ (aq), Hϩ (aq)&NO(g)&Pt(s) ⌬Gr° ϭ ϪnFE° ϭ Ϫ(6)(9.65 ϫ 104 CиmolϪ1 )(ϩ0.17 JиCϪ1 ) ϭ Ϫ98 kJиmolϪ1 (b) not spontaneous; (c) Ecell° ϭ E°(cathode) Ϫ E°(anode) ϭ ϩ1.33 V Ϫ (ϩ0.97 V) ϭ ϩ0.36 V Pt(s)&Pu3ϩ (aq), Pu4ϩ (aq)&&Cr2O7 2Ϫ (aq), Cr3ϩ (aq), Hϩ (aq)&Pt(s) ⌬Gr° ϭ ϪnFE° ϭ Ϫ(6)(9.65 ϫ 104 CиmolϪ1 )(0.36 JиCϪ1 ) ϭ Ϫ208 kJиmolϪ1 13.23 Ϫ0.349 V 13.25 (a) Cu Ͻ Fe Ͻ Zn Ͻ Cr; (b) Mg Ͻ Na Ͻ K Ͻ Li; (c) V Ͻ Ti Ͻ Al Ͻ U; (d) Au Ͻ Ag Ͻ Sn Ͻ Ni 13.27 Ϫ1.50 V 13.29 (a) oxidizing agent: Co2ϩ ; reducing agent: Ti3ϩ ; Pt(s) | Ti2ϩ (aq), Ti3ϩ (aq) || Co2ϩ (aq) | Co(s); ϩ0.09 V; (b) oxidizing agent: U3ϩ ; reducing agent: La3ϩ ; La(s) | La3ϩ (aq) || U3ϩ (aq) | U(s); ϩ0.73 V; (c) oxidizing agent: Fe3ϩ ; reducing agent: Hϩ ; Pt(s) | H2(g) | Hϩ (aq) || Fe2ϩ (aq), Fe3ϩ (aq) | Pt(s); ϩ0.77 V; (d) oxidizing agent: O3; reducing agent: Agϩ ; Ag(s) | Agϩ (aq) || OHϪ (aq) | O3(g), O2(g) | Pt(s); ϩ0.44 V; 13.31 (a) Cl2(g), ϩ0.27 V. (b) and (c) do not favor products. (d) NO3 Ϫ , ϩ1.56 V 13.33 (a) 0.743 V; (b) no 13.35 (a) 6 ϫ 10Ϫ16 ; (b) 1 ϫ 104 13.37 (a) Pb4ϩ (aq) ϩ Sn2ϩ (aq) : Pb2ϩ (aq) ϩ Sn4ϩ (aq), Q ϭ 106 ; (b) 2 Cr2O7 2Ϫ (aq) ϩ 16 Hϩ (aq) : 4 Cr3ϩ (aq) ϩ 8 H2O(l) ϩ 3 O2(g), Q ϭ 1.0 13.39 (a) ϩ0.030 V; (b) ϩ6 ϫ 10Ϫ2 V 13.41 (a) ϩ0.067 V; (b) 0.51 V; (c) Ϫ1.33 V; (d) 0.31 V 13.43 (a) 1.0; (b) 10Ϫ1 mol·LϪ1 13.45 2.25 13.47 (a) 1.2 ϫ 10Ϫ17 . (b) This value is a factor of 10 greater than the value in Table 12.4 (1.3 ϫ 10Ϫ18 ). 13.49 yes, 8.4 kJ per mole of Ag 13.51 (a) Ϫ0.27 V; (b) ϩ0.07 V 13.53 (a) cathode: Ni2ϩ (aq) + 2 eϪ : Ni(s); (b) anode: 2 H2O(I) : O2(g) ϩ 4 Hϩ (aq) ϩ 4 eϪ ; (c) ϩ1.46 V 13.55 (a) water; (b) water; (c) Ni2ϩ ; (d) Au3ϩ 13.57 (a) 3.3 g; (b) 0.59 L; (c) 0.94 g 13.59 (a) 27 h; (b) 0.44 g 13.61 (a) 0.64 A; (b) 0.24 A 13.63 ϩ2 13.65 ϩ4 13.67 (a) anode; (b) 0.134 mol; (c) 0.17 13.69 (a) oxidation/anode: 6 OHϪ (aq) ϩ 2 Al(s) : 2 Al(OH)3(aq) ϩ 6 eϪ reduction/cathode: 3 H2O(l) + 1 O2(g) ϩ 6 eϪ : 6 OHϪ (aq) overall: 3 H2O(l) ϩ 2 Al(s) ϩ 1 O2(g) : 2 Al(OH)3(aq) (b) ϩ2.06 V 13.71 100 A 13.73 (a) KOH(aq)/HgO(s); (b) HgO(s); (c) HgO(s) ϩ Zn(s) :Hg(l) ϩ ZnO(s) 13.75 (a) Pb(s) ϩ PbO2(s) ϩ 2 HSO4 Ϫ (aq) ϩ 2 Hϩ (aq) : 2 PbSO4(s) ϩ H2O(l). (b) pH increases. Amount of PbO2(s) decreases. Total amount of lead in the battery stays the same. 13.77 (a) KOH(aq); (b) 2 Ni(OH)2(s) ϩ 2 OHϪ (aq) : 2 Ni(OH)3 ϩ 2 eϪ 13.79 Comparison of the reduction potentials shows that Cr is more easily oxidized than Fe, so the presence of Cr retards the rusting of Fe. At the position of the scratch, the gap is filled with oxidation products of Cr, thereby preventing contact of air and water with the iron. 13.81 (a) 57.4%; (b) AgBr 13.83 (a) Fe2O3иH2O. (b) H2O and O2 jointly oxidize iron. (c) Water is more highly conducting if it contains dissolved ions, so the rate of rusting is increased. 1 2 1 2 C36 ANSWERS 13.85 (a) Aluminum or magnesium; both are below titanium in the electrochemical series. (b) Cost, availability, and toxicity of products in the environment; (c) Fe could act as the anode of an electrochemical cell if Cu2ϩ or Cuϩ were present; therefore, it could be oxidized at the point of contact. Water with dissolved ions would act as the electrolyte. 13.87 (a) E; (b) both; (c) neither; (d) E°; (e) E 13.89 Al, Zn, Fe, Co, Ni, Cu, Ag, Au 13.91 Ϫ0.92 V 13.93 ϩ0.14 V 13.95 A negatively charged ion flows from the cathode to the anode. 13.97 (a) yes, O2(g) ϩ 4 Hϩ (aq) ϩ 4 Ag(s) : 4 Agϩ (aq) ϩ 2 H2O(l), ϩ0.42 V; (b) yes, O2(g) ϩ 2 H2O(l) ϩ 4 Ag(s) : 4 Agϩ (aq) ϩ 4 OHϪ (aq), ϩ0.05 V 13.99 (a) Reduction takes place at the electrode with the higher concentration, which would be the chromium electrode in contact with the 1.0 M CrCl3. (b) yes; (c) yes; (d) no 13.101 (a) 1.0 ϫ 10Ϫ2 M; (b) 8.5 ϫ 10Ϫ17 13.103 10Ϫ3 13.105 (a) ⌬Gr1 o ϭ ϪnFE1 o ϭ ⌬Hr1 o Ϫ T1⌬Sr1 o , where r1 represents the reaction at T1. ⌬Gr2 o ϭ ϪnFE2 o ϭ ⌬Hr2 o Ϫ T2⌬Sr2 o , where r2 represents the reaction at T2. On subtracting the first reaction from the second, we obtain ϪnFE2 o ϩ nFE1 o ϭ ⌬Hr2 o Ϫ T2⌬Sr2 o Ϫ [⌬Hr1 o Ϫ T1⌬Sr1 o ]. Since ⌬Hr1 o ϭ ⌬Hr2 o , we obtain nFE1 o Ϫ nFE2 o ϭ ϪT2⌬Sr2 o ϩ T1⌬Sr1 o , which can be rewritten as ϪnFE1 o ϩ nFE2 o ϭ ϩT2⌬Sr2 o Ϫ T1⌬Sr1 o . Since ⌬Sr1 o ϭ ⌬Sr2 o ϭ ⌬Sr o , we obtain ϪnFE1 o ϩ nFE2 o ϭ ⌬Sr o (T2 Ϫ T1); nFE2 o ϭ nFE1 o ϩ ⌬Sr o (T2 Ϫ T1); E2 o ϭ E1 o ϩ ⌬Sr o (T2 Ϫ T1)/nF; (b) ϩ1.18 V 13.107 0.08 V to 0.09 V. 13.109 (a) ϩ0.26 V, spontaneous. (b) The formation of AgI precipitate means that the concentration of Agϩ ions is never high enough to achieve the conditions necessary for the redox reaction to take place. The solubility product Ksp limits the concentrations in solution, so that the actual redox potential is not the value calculated, which represents the values when [Agϩ ] ϭ 1 M and [IϪ ] ϭ 1 M. If we use the concentrations established by the solubility equilibrium and the Nernst equation, we can calculate the actual redox potential to be Ϫ0.68 V. 13.111 12 13.113 Ϫ0.828 V to ϩ0.828 V 13.115 (a) A plot of cell voltage, E, versus ln [Agϩ ]anode would be a linear increase with positive slope. (b) Slope ϭ 0.025693, corresponds to consistent. (c) E° 13.117 4 ϫ 10Ϫ9 13.119 0.205 A 13.121 (a) (i) Ϫ0.41 V; (ii) ϩ0.41 V; (b) Ϫ0.31 V; (c) (d) (e) NADH(aq) ϩ pyruvate ϩHϩ (aq) : NADϩ (aq) ϩ lactate, E* ϭ ϩ0.12 V, E° ϭ ϩ0.33 V; (f) Ϫ64 kJиmolϪ1 ; (g) ϩ1.43 ϫ 1011 H C O H H ¥ ¥ ¥ OH CH ¥ O ¥ ¥ sp3 sp2sp3 ᮎ H C O H H ¥ ¥ ¥ O ¥ ¥ O ¥ ¥ sp2 sp2sp3 ᮎ RT nF , Chapter 14 14.1 (a) one-third; (b) two-thirds; (c) two 14.3 (a) 0.28 mol·L·sϪ1 ; (b) 0.14 mol·LϪ1 ·sϪ1 14.5 (a) 3.3 ϫ 10Ϫ3 (mol O2)·LϪ1 ·sϪ1 ; (b) 3.3 ϫ 10Ϫ3 mol·LϪ1 ·sϪ1 14.7 (a) and (c) Note that the curves for the [I2] and [H2] are identical and only the [I2] curve is shown. (b) Time (s) Rate (mmol·LϪ1 ·sϪ1 ) 0 0.0060 1000 0.003 2000 0.000 98 3000 0.000 61 4000 0.000 40 5000 0.000 31 14.9 (a) molиLϪ1 иsϪ1 ; (b) sϪ1 ; (c) molиLиsϪ1 14.11 2.2 ϫ 10Ϫ4 (mol N2O5)иLϪ1 иsϪ1 14.13 (a) 2.2 ϫ 10Ϫ5 mol·LϪ1 иsϪ1 ; (b) factor of 2 14.15 rate ϭ k[CH3Br][OHϪ ] 14.17 (a) A ϭ 1, B ϭ 2, C ϭ 0, overall order ϭ 3; (b) rate ϭ k[A][B]2 ; (c) 2.0 ϫ 10Ϫ5 иL2 иmmolϪ2 иsϪ1 ; (d) 2.9 ϫ 10Ϫ6 mmolиLϪ1 иsϪ1 14.19 (a) rate ϭ k[A][B]2 [C]2 ; (b) 5; (c) 2.85 ϫ 1012 L4 иmolϪ4 ·sϪ1 ; (d) 1.13 ϫ 10Ϫ2 molиLϪ1 иsϪ1 14.21 2.0 mg 14.23 (a) 6.93 ϫ 10Ϫ4 иsϪ1 ; (b) 9.4 ϫ 10Ϫ3 иsϪ1 ; (c) 5.1 ϫ 10Ϫ3 иsϪ1 14.25 (a) 5.2 h; (b) 3.5 ϫ 10Ϫ2 molиLϪ1 ; (c) 6.5 ϫ 102 min 14.27 (a) 1065 s; (b) 710 s; (c) 9.7 ϫ 102 s; (d) 1.1 ϫ 103 s 14.29 (a) 0.17 minϪ1 ; (b) an additional 3.5 min 14.31 (a) (b) (i) 7.8 ϫ 10Ϫ3 LиmolϪ1 иsϪ1 ; (ii) 3.9 ϫ 10Ϫ3 LиmolϪ1 иsϪ1 14.33 (a) 7.4 ϫ 102 s; (b) 1.5 ϫ 102 s; (c) 2.0 ϫ 102 s 14.35 (a) 247 min; (b) 819 min; (c) 10.9 g 14.37 (a) 1.7 ϫ 102 min; (b) 3.3 ϫ 103 min 14.39 [A]t ϭ [A]0eϪakt , t1/2 ϭ ln 2/ak 14.41 t1/2 ϭ 3/(2k[A]0 2 ) 14.43 2AC ϩ B : A2B ϩ 2C. Intermediate is AB. 14.45 CH2≈CHCOOH ϩ HCl : ClCH2CH2COOH; intermediates: ClϪ , CH2≈CHC(OH)2 ϩ and ClCH2CHC(OH)2 14.47 (a) O3 ϩ O : 2 O2; (b) Step 1: rate ϭ k[O3][NO], bimolecular; Step 2: rate ϭ k[NO2][O], bimolecular; (c) NO2; (d) NO 14.49 rate ϭ k[NO][Br2] 35.00 30.00 25.00 20.00 15.00 10.00 5.00 0.00 0 1000 2000 3000 4000 5000 Time (s) 1/[HI](LиmolϪ1 ) 1/[HI] ϭ (0.0078 и t) ϩ 1.0 0 2 4 6 8 10 12 6000 Time (s) [HI], mmolиLϪ1 [I2], mmolиLϪ1 0 1000 2000 3000 4000 5000 Concentration (mmolиLϪ1) ODD-NUMBERED EXERCISES C37 14.51 If mechanism (a) were correct, the rate law would be rate ϭ k[NO2][CO]. But this expression does not agree with the experimental result and can be eliminated as a possibility. Mechanism (b) has rate ϭ k[NO2]2 from the slow step. Step 2 does not influence the overall rate, but it is necessary to achieve the correct overall reaction; thus this mechanism agrees with the experimental data. Mechanism (c) is not correct, which can be seen from the rate expression for the slow step, rate ϭ k[NO3] [CO]. [CO] cannot be eliminated from this expression to yield the experimental result, which does not contain [CO]. 14.53 (a) true. (b) false. At equilibrium, the rates of the forward and reverse reactions are equal, not the rate constants. (c) false. Increasing the concentration of a reactant causes the rate to increase by providing more reacting molecules. It does not affect the rate constant of the reaction. 14.55 The overall rate of formation of A is rate ϭ Ϫk[A] ϩ kЈ[B]. The first term accounts for the forward reaction and is negative as this reaction reduces [A]. The second term, which is positive, accounts for the back reaction which increases [A]. Given the 1:1 stoichiometry of the reaction, if no B was present at the beginning of the reaction, [A] and [B] at any time are related by the equation [A] ϩ [B] ϭ [A]0 where [A]0 is the initial concentration of A. Therefore, the rate law may be written The solution of this first-order differential equation is As t : the exponential term in the numerator goes to zero and the concentrations reach their equilibrium values given by and [B]eq ϭ [A]0 Ϫ [A]ϱ ϭ Taking the ratio of products over reactants we see that: where K is the equilibrium constant for the reaction. 14.57 (a) 2.72 ϫ 102 kJиmolϪ1 ; (b) 0.088 sϪ1 14.59 39 kJиmolϪ1 14.61 2.5 ϫ 109 LиmolϪ1 иsϪ1 14.63 9.2 ϫ 10Ϫ4 иsϪ1 14.65 (a) 0.676. (b) endothermic. (c) Raising the temperature will increase the rate constant of the reaction with the higher activation barrier more than it will the rate constant of the reaction with the lower energy barrier. We expect the rate of the forward reaction to go up substantially more than for the reverse reaction in this case. k will increase more than kЈ and consequently the equilibrium constant K will increase. This is consistent with Le Chatelier’s principle. 14.67 (a) 6 ϫ 108 ; (b) 3 ϫ 107 14.69 81 kJиmolϪ1 14.71 The overall reaction is RCN ϩ H2O : RC(≈O)NH2. RC(≈NϪ )OH and RC(≈NH)OH are intermediates. The hydroxide ion serves as a catalyst for the reaction. 14.73 (a) false. A catalyst increases the rate of both the forward and reverse reactions by providing a completely different pathway. (b) true, although a catalyst may be poisoned and lose activity. (c) false. There is a completely different pathway provided for the reaction in the presence of a catalyst. (d) false. The position of the equilibrium is unaffected by the presence of a catalyst. −10 −8 −6 −4 −2 0 1/T (KϪ1 ) 0.0011 0.00115 0.0012 y = −32700x + 35.0 0.00125 0.0013 0.00135 lnk [B]eq [A]eq = k k¿ = K k[A]0 k + k¿ [A]eq = k¿[A]0 k¿ + k q [A] = k¿ + ke -(k¿+k)t k¿ + k [A]0 d[A] dt = -k[A] + k¿([A]0 - [A]) = -(k + k¿)[A] + k¿[A]0 14.75 (a) To obtain the Michaelis–Menten rate equation, we will begin by employing the steady-state approximation, setting the rate of change in the concentration of the ES intermediate equal to zero: Rearranging gives [E][S] ϭ The total bound and unbound enzyme concentration, [E]0, is given by [E]0 ϭ [E] ϩ [ES], and therefore, [E] ϭ [ES] – [E]0. Substituting this expression for [E] into the preceding equation, we obtain ([ES] – [E]0)[S] ϭ KM [ES]. Rearranging to obtain [ES] gives: [ES] ϭ From the mechanism, the rate of appearance of the product is given by rate ϭ k2[ES]. Substituting the preceding equation for [ES], we obtain the Michaelis–Menten rate equation, which can be rearranged to obtain If one plots versus the slope will be and the y-intercept will be (b) 14.77 (a) rate ϭ k[NO]2 , bimolecular; (b) rate ϭ k[Cl2], unimolecular; (c) rate ϭ k[NO2]2 , bimolecular; (d) b and c 14.79 (a) CH3CH≈CHCH2Br because the positive charge on the reactive intermediate is on a primary carbon atom. This also agrees with the result that at high temperatures this is the predominant product as there is sufficient energy to overcome the larger activation energy. (b) Kinetic control predominates at low temperatures. The reaction pathway with the lower activation energy will predominate at low temperatures because the lower activation energy barrier results in a larger rate constant and therefore a faster reaction. 14.81 2.3 ϫ 105 LиmolϪ1 иsϪ1 14.83 (a) 5s (b) There should be four molecules at t ϭ 8 s 14.85 (a) CH3CHO : CH3 ϩ CHO, unimolecular [CH3 ......CHO]‡ (b) 2I : I2, termolecular [I.......I......Ar]‡ (c) O2 ϩ NO : NO2 ϩ O, bimolecular [O......O......NO]‡ 14.87 13.5 mg 14.89 The anticipated rate for mechanism (i) is rate ϭ k[C12H22O11], while the expected rate for mechanism (ii) is rate ϭ k[C12H22O11][H2O]. The rate for mechanism (ii) will be pseudo-first-order in dilute solutions of sucrose because the concentration of water will not change. Therefore, in dilute solutions kinetic data cannot be used to distinguish between the two mechanisms. However, in a highly concentrated solution of sucrose, the concentration of water will change during the course of the reaction. As a result, if mechanism (ii) is correct the kinetics will display a firstorder dependence on the concentration of H2O while mechanism (i) predicts that the rate of the reaction is independent of [H2O]. 0 0 1/[S] 1/rate KM k2[E]0 Slope = 1 k2[E]0 y-intercept = 1 k2[E]0 . KM k2[E]0 1 [S] , 1 rate 1 rate = KM k2[E]0[S] + 1 k2[E]0 . Rate = k2[E]0[S] KM + [S] , [E]0[S] KM + [S] . a k2 + k1¿ k1 b [ES] = KM[ES]. d[ES] dt = k1[E][S] - k1¿[ES] - k2[ES] = 0. C38 ANSWERS 14.91 (a) If step 2 is the slow step, if step 1 is a rapid equilibrium, and if step 3 is fast also, then our proposed rate law will be rate ϭ k2[N2O2][H2]. Consider the equilibrium of step 1: k1[NO]2 ϭ k1Ј[N2O2]; [N2O2] ϭ Substituting in our proposed rate law, we have rate ϭ k2 where k ϭ k2 The assumptions made above reproduce the observed rate law; therefore, step 2 is the slow step. (b) 14.93 75 kJ·molϪ1 14.95 1.5 ϫ 10Ϫ3 molиLϪ1 иsϪ1 14.97 (a) three steps; (b) first step; (c) third step; (d) two; (e) none 14.99 (a) ClO is the reaction intermediate; Cl is the catalyst. (b) Cl, ClO, O, O2. (c) Step 1 and step 2 are propagating. (d) Cl ϩ Cl : Cl2 14.101 For a third-order reaction, (a) first half-life ϭ t1 ϭ t1/2 ϭ (b) second half-life ϭ t2 ϭ total time ϭ t1 ϩ t2 ϭ t1 ϩ 4t1 ϭ 5t1 ϭ t1/4 (c) third half-life ϭ t3 ϭ half-life ϭ t4 ϭ ϭ t1 ϩ t2 ϩ t3 ϩ t4 ϭ t1 ϩ 4t1 ϩ 16t1 ϩ 64t1 ϭ 85t1 ϭ t1/16 14.103 The following plots are linear: (b), (c), (d), (f), (g). 14.105 (a) The overall reaction is OClϪ ϩ IϪ : OIϪ ϩ ClϪ . (b) rate ϭ (c) The rate will decrease as pH increases. (d) If the reaction is carried out in an organic solvent, then H2O is no longer the solvent and its concentration must be included in calculating the equilibrium concentration of HOCl: rate ϭ 14.107 To get an expression for t1/2 in terms of n, we need to evaluate an integral such as An expression for t1/2 is then 1 n - 1 a 1 [A]n-1 - 1 [A]0 n-1 b = kt 3 [A] [A]0 d[A] [A]n = -k 3 t 0 dt = -kt k2k1 k1¿ [OCl- ][I- ][H2O] [OH- ] k2k1 k1¿ [OCl- ][I- ] [OH- ] . constant (1 8[A0])2 = 64(constant) [A0]2 = 64t1; total time constant (1 4[A0])2 = 16(constant) [A0]2 = 16t1; fourth constant (1 2[A0])2 = 4(constant) [A0]2 = 4t1; constant [A0]2 t1/2 r 1 [A0]2 or t1/2 = constant [A0]2 Potentialenergy Ea,3 Ea,1 Ea,2 ΔH Progress of reaction Reactants Products a k1 k1¿ b k k1¿ [NO]2 [H2] = k[NO]2 [H2] k k1¿ [NO]2 An expression for t3/4 could be found by setting up [A] ϭ [A]0 The ratio t1/2/t3/4 is then 14.109 (a) methyl isonitrile Cyanomethane (b) Ϫ43 kJиmolϪ1 , cyanomethane. (c) kЈ ϭ 4.04 ϫ 10Ϫ15 sϪ1 , t ϭ 7.12 ϫ 1013 s. (d) Since ⌬H° for this isomerization reaction is exothermic (Ϫ43 kJиmolϪ1 ), the reaction profile has the product lower than the reactant. (e) 474 K. (f) Argon serves as a collision partner. Collisions between the CH3NC(g) and argon atoms provide the energy needed to overcome the activation energy and allow the isomerization reaction to proceed toward products. The argon atoms also serve as an energy sink, accepting the energy released during the isomerization reaction. (g) At high argon concentrations, collisions resulting in reaction are between the CH3NC(g) and argon atoms: CH3NC(g) ϩ Ar(g) : CH3CN(g) ϩ Ar(g). Given this elementary reaction, one would predict that the reaction was first order with respect to CH3NC(g) concentration and would appear first order overall if the concentration of Ar(g) was large and unchanging. If, however, the concentration of Ar(g) was greatly reduced, the isomerization reaction would also proceed through collisions between CH3NC(g) molecules, making the reaction second order with respect to CH3NC(g). Chapter 15 15.1 (a) nitrogen; (b) potassium; (c) gallium; (d) iodine 15.3 (a) sulfur; (b) selenium; (c) sodium; (d) oxygen 15.5 tellurium Ͻ selenium Ͻ oxygen 15.7 (a) antimony. (b) Antimony has a higher effective nuclear charge. 15.9 (a) bromide ion. (b) Bromide has the larger size. 15.11 : 15.13 (a) saline; (b) molecular; (c) molecular; (d) metallic 15.15 (a) acidic; (b) amphoteric; (c) acidic; (d) basic 15.17 (a) (b) B2O3 15.19 (a) : . Oxidation number of C in of C in carbon has been reduced. (b) : (c) : 15.21 (a) ; (b) ; (c) : ; (d) : 2 CuH(s)2 Cu(s) + H2(g)4 PH3(g)P4(s) + 6 H2(g) H2(g) + 2 Na(l) ¡ ¢ NaH(s) H2(g) + Cl2(g) ¡ light 2 HCl(g) Ba(OH)2 + 2 H2(g)BaH2(s) + 2 H2O(l) CO2(g) + H2(g)CO(g) + H2O(g) H2CRCH2 = -2,C2H2 = -1; H2C“CH2(g)C2H2(g) + H2(g) CO2; 2 KH(s)2 K(s) + H2(g) ¥ sp3 sp H H H Cß C Nß å å Polar ßßß ¥ sp3 sp H H H Cß N Cß ßßß å å Polar ϩ Ϫ t1/2/t3/4 = a 2n-1 - 1 (4/3)n-1 - 1 b 1 n - 1 a (4/3)n-1 - 1 [A]0 n-1 b = kt3/4 1 n - 1 a 4n-1 3n-1 [A]0 n-1 - 1 [A]0 n-1 b = kt3/4 3 4 1 n - 1 a 2n-1 - 1 [A]0 n-1 b = kt1/2 1 n - 1 a 2n-1 [A]0 n-1 - 1 [A]0 n-1 b = kt1/2 ODD-NUMBERED EXERCISES C39 15.23 The reason for this trend is mainly due to the trend of the electronegativity of the central atom (N Ͻ O Ͻ F), which makes F more partially negative, to attract H from another HF atom. 15.25 Lithium is the only Group 1 element that reacts directly with nitrogen to form lithium nitride; it reacts with oxygen to form mainly the oxide, whereas the other members of the group form mainly the peroxide or superoxide. Lithium exhibits the diagonal relationship that is common to many first members of a group. Li is similar in many of its compounds to the compounds of Mg. This behavior is related to the small ionic radius of 58 pm, which is closer to the ionic radius of 72 pm, but substantially less than that of 102 pm. 15.27 (a) 4 Na(s) ϩ O2(g) : 2 Na2O(s); (b) ; (c) : ; (d) : 15.29 : 15.31 (a) : ; (b) Ϫ57.33 kJ·molϪ1 15.33 (a) : ; (b) : ; (c) 15.35 (a) is ionic; is a molecular compound. (b) (c) sp 15.37 : 15.39 (a) ; (b) : ; (c) : 15.41 Bridging H atoms and four-coordinate B atoms have formal charge of Ϫ1; terminal H atoms and three-coordinate B atoms have formal charge of 0. 15.43 The shape of is tetrahedral. 15.45 Silicon occurs widely in the Earth’s crust in the form of silicates in rocks and as silicon dioxide in sand. It is obtained from quartzite, a form of quartz by the following processes: (1) reduction in an electric arc furnace, : . (2) Purification of the crude product in two steps, : , followed by reduction with hydrogen to the pure element, : . 15.47 (a) ϩ4; (b) ϩ4; (c) ϩ4 15.49 (a) MgC2(s) ϩ 2 H2O(l) : C2H2(g) ϩ Mg(OH)2(s) (acid–base); (b) 2 Pb(NO3)2(s) : 2 PbO(s) ϩ 4 NO2(g) ϩ O2(g) (redox) 15.51 ⌬Hr° ϭ 689.88 kJ·molϪ1 ; ⌬Sr° ϭ 360.85 J·KϪ1 ·molϪ1 ; ⌬Gr° ϭ 582.29 kJ·molϪ1 ; 1912 K 15.53 Ϫ3: NH2 Ϫ ; Ϫ2: ; Ϫ1: ; 0: ; ϩ1: ; ϩ2: NO; ϩ3: NO2 Ϫ ; ; ϩ4: ; ϩ5: NO3 Ϫ ; NO2FHNO3,N2O4NO2, NO+ NF3,N2F2N2O,N2NH2OH N2H2,H2NNH2LiNH2,Li3N,NH3, Si(s, pure) + 4 HCl(g)SiCl4(l) + 2 H2(g) SiCl4(l)2 Cl2(g) Si(s, crude) + Si(s, crude) + 2 CO(g)SiO2(s) + 2 C(s) (SiO2), Br Ga Br A A Br A A A A Br A A A A A A ß ß å å Ϫ GaBr4 - B H H H H HBß ß HB ß H H H H ß œ ç œ çå å B å å å å 2 Al2O3(s)4 Al(s) + 3 O2(g)2 AlCl3(s)2 Al(s) + 3 Cl2(g) B2O3(s) + 3 Mg(l) ¡¢ 2 B(s) + 3 MgO(s) 4 Al(s) + 3 CO2(g) 4 Al3+ (melt) + 6 O2(melt) + 3 C(s, gr) 180°BeCl2MgCl2 Cl Be ;Cl 2Mg2ϩ ß ß Cl ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ Ϫ BaCO3(s) ¡ ¢ BaO(s) + CO2(g) Ca(OH)2(aq) + H2(g)Ca(s) + 2H2O(l) MgCl2(aq) + 2H2O(l)Mg(OH)2(s) + 2 HCl(aq) Ca(OH)2(s)CaO(s) + H2O(l) Mg(OH)2 + H2(g)Mg(s) + 2 H2O(l) 4 KOH(s) + 3 O2(g)4 KO2(s) + 2 H2O(g) 2 NaOH(aq) + H2(g)2 Na(s) + 2 H2O(l) 6 Li(s) + N2(g) ¡ ¢ 2 Li3N(s) Na+ , Mg2+ ,Li+ , 15.55 : ; 6.4 kg 15.57 (a) 0.35 L. (b) larger volume. (c) Metal azides are good explosives because the azide ion is thermodynamically unstable with respect to the production of . This is because the NΩN triple bond is so strong and also because the production of a gas is favored entropically. 15.59 : : : 15.61 Ammonia (NH3) can undergo hydrogen bonding with itself while NF3 cannot. 15.63 (a) ; (b) 2 Na(s) ϩ 2 H2O(l) : 2 NaOH(aq) ϩ H2(g); (c) 2 F2(g) ϩ 2 H2O(l) : ; (d) : 15.65 (a) ; (b) : ; (c) 15.67 Both water and ammonia have four groups attached to their central atom and therefore both possess a tetrahedral electronic (or VSEPR) geometry. However, H2O has two unshared electron pairs while NH3 only has one, producing a larger dipole moment for H2O. 15.69 (a) The bond angle is predicted to be In actuality, it is (b) Cuϩ and (c) Mn2ϩ will be oxidized. 15.71 13.11 (13.12 if Ka2 is not ignored) 15.73 The weaker the H—X bond, the stronger the acid. Te has the weakest bond; the strongest. Therefore, the acid strengths are 15.75 (a) ϩ1; (b) ϩ4; (c) ϩ7; (d) ϩ5 15.77 (a) . (b) : . (c) : . (d) (a) and (b) are redox reactions; (c) is a Brønsted acid–base reaction. 15.79 (a) . (b) The oxidation number of Cl increases from HClO to . In , chlorine has its highest oxidation number of ϩ7, so will be the strongest oxidizing agent. 15.81 , angular, about . The actual bond angle is 110.9°. 15.83 (a) ICl5 has too many highly electronegative chlorine atoms present on the central iodine. (b) IF2 has an odd number of electrons and as a result is a radical and highly reactive. (c) ClBr3 is sterically too crowded (too many large atoms on a small central atom). 15.85 (a) IF3; (b) : 15.87 Because is negative, will not oxidize to form the permanganate ion in an acidic solution. 15.89 0.117 mol·LϪ1 15.91 of heat is released. 15.93 Helium occurs as a component of natural gases found under rock formations in certain locations, especially some in Texas. Argon is obtained by distillation of liquid air. 15.95 (a) ϩ2; (b) ϩ6; (c) ϩ4; (d) ϩ6 15.97 : Xe(g) + 4 HF(aq)XeF4(aq) + 4 H+ (aq) + 4 e- 7.59 * 103 kJ Mn2+ Cl2(g)Ecell ° 2 IF3(s) + 3 Xe(g)3 XeF2(g) + I2(g) 109°AX2E2,Cl Oß Clß HClO4HClO4 HClO4 HClO 6 HClO2 6 HClO3 6 HClO4 NaHSO4(aq) + HCl(g)NaCl(s) + H2SO4(aq HBrO(aq) + HBr(aq)Br2(l) + H2O(l) 4 KClO3(l) ¡ ¢ 3 KClO4(s) + KCl(s) H2Te 7 H2Se 7 H2S 7 H2O. H2O, H2 97°.6 109.5°. O H H O A A A A ß å å 2 H2S(g) + SO2(g) ----¡ 300°C,Al2O3 3 S(s) + 2H2O(l) Ca(OH)2(aq)CaO(s) + H2O(l) 2 H2S(g) + 3 O2(g) ¡ ¢ 2 SO2(g) + 2 H2O(g) O2(g) + 4 H+ (aq) + 4 e- 2 H2O(l) 4 HF(aq) + O2(g) 4 Li(s) + O2(g) ¡ ¢ 2 Li2O(s) 2 HNO3(aq)N2O5: HNO3; N2O5(g) + H2O(l) 2 HNO2(aq)N2O3: HNO2; N2O3(g) + H2O(l) H2N2O2(aq)N2O: H2N2O2; N2O(g) + H2O(l) N2(g) (NH4)2CO3(aq)CO(NH2)2(aq) + 2 H2O(l) C40 ANSWERS 15.99 Because has more highly electronegative O atoms bonded to Xe, we predict that is more acidic than 15.101 (a) (b) For both groups, the trend in standard potentials with increasing atomic number is overall downward (they become more negative), but lithium is anomalous. This overall downward trend makes sense because we expect that it is easier to remove electrons that are farther away from the nuclei. However, because there are several factors that influence ease of removal, the trend is not smooth. The potentials are a net composite of the free energies of sublimation of solids, dissociation of gaseous molecules, ionization enthalpies, and enthalpies of hydration of gaseous ions. The origin of the anomalously strong reducing power of Li is the strongly exothermic energy of hydration of the very small ion, which favors the ionization of the element in aqueous solution. 15.103 In the majority of its reactions, hydrogen acts as a reducing agent; that is, : In these reactions, hydrogen resembles Group 1 elements, such as Na and K. However, as described in the text, it may also act as an oxidizing agent; that is, : In these reactions, hydrogen resembles Group 17 elements, such as Cl and Br. Consequently, will oxidize elements with standard reduction potentials more negative than –2.25 V, such as the alkali and alkaline earth metals (except Be). The compounds formed are hydrides and contain the HϪ ion; the singly charged negative ion is reminiscent of the halide ions. Hydrogen also forms diatomic molecules and covalent bonds like the halogens. The atomic radius of H is 78 pm, which compares rather well to that of F (64 pm) but not as well to that of Li (157 pm). The ionization energy of H is 1310 kJиmolϪ1 , which is similar to that of F (1680 kJиmolϪ1 ) but not similar to that of Li (519 kJиmolϪ1 ). The electron affinity of H is ϩ73 kJиmolϪ1 , that of F is ϩ328 kJиmolϪ1 , and that of Li is 60 kJиmolϪ1 . So in its atomic radius and ionization energy, H more closely resembles the Period 2 halogen, fluorine, in Group 17, than the Period 2 alkali metal, lithium, in Group 1; whereas in electron affinity, it more closely resembles lithium, Group 1. In electronegativity, H does not resemble elements in either Group 1 or Group 17, although its electronegativity is somewhat closer to those of Group 1. Consequently, hydrogen could be placed in either Group 1 or Group 17. But it is best to think of hydrogen as a unique element that has properties in common with both metals and nonmetals; therefore, it should probably be centered in the periodic table, as it is shown in the table in the text. 15.105 0.0538 mol·LϪ1 15.107 Gases (a), (b), (c), and (d) can all function as greenhouse gases, while (e) cannot; argon is monoatomic. 15.109 Octane contributes more CO2 per liter burned. We also need to consider how much energy is produced per liter of fuel burned. 15.111 (a) Diborane, and have the same basic structure in the way in which the atoms are arranged in space. (b) The bonding Al2Cl6(g)B2H6, H2 2H(aq), E° = -2.25 V.H2(g) + 2 e- 2 H+ (aq) + 2 e, E° = 0 V.H2(g) Li+ −3.0 −2.8 −2.6 −2.4 −2.2 −2.0 −1.8 Group 2 Be Mg Ca Sr Ba Ra E°(v) −3.1 −3.0 −2.9 −2.8 −2.7 Group 1 Li Na K Rb Cs E°(v) H2XeO4.H4XeO6 H4XeO6 between the boron atoms and the bridging hydrogen atoms is electron deficient. There are three atoms and only two electrons to hold them together in a 3-center-2-electron bond. The bonding in is conventional in that all the bonds involve two atoms and two electrons. Here, the lone pair of a Cl atom is donated to an adjacent Al. (c) The hybridization is sp3 at the B and Al atoms. (d) The molecules are not planar. The Group 13 element and the terminal atoms to which it is bound lie in a plane that is perpendicular to the plane that contains the main group element and the bridging atoms. 15.113 (a) Molecule (g) : Moleculeϩ (g) ϩ eϪ (g). (b) has more electrons than ; I is also less electronegative and much bigger (and therefore more polarizable) than Cl. As a result it should be easier to remove an electron from , meaning that should have the higher ionization energy. 15.115 (a) 10-electron species: . 15-electron species: . 22-electron species: . (b) . (c) 15.117 Due to reduced hydrogen bonding, thiosulfuric acid should be less acidic and have a lower boiling point. 15.119 337.9 g 15.121 strongest: (a), ion–ion; weakest: (d) dipole–dipole 15.123 (a) , linear ; (b) FϪ , 133 pm; N3 Ϫ , 148 pm; ClϪ , 181 pm; therefore, between fluorine and chlorine. (c) HCl, HBr, and HI are all strong acids. For HF, Ka ϭ 3.5 ϫ 10Ϫ4 , so HF is slightly more acidic than The small size of the azide ion suggests that the H—N bond in is similar in strength to that of the H—F bond, so it is expected to be a weak acid. (d) ionic: etc.; covalent: etc. 15.125 The solubility of the ionic halides is determined by a variety of factors, especially the lattice enthalpy and enthalpy of hydration. There is a delicate balance between the two factors, with the lattice enthalpy usually being the determining one. Lattice enthalpies decrease from chloride to iodide, so water molecules can more readily separate the ions in the latter. Less ionic halides, such as the silver halides, generally have a much lower solubility, and the trend in solubility is the reverse of the more ionic halides. For the less ionic halides, the covalent character of the bond allows the ion pairs to persist in water. The ions are not easily hydrated, making them less soluble. The polarizability of the halide ions, and thus the covalency of their bonding, increases down the group. 15.127 (a) The molecular orbital diagram for should have the oxygen orbitals slightly lower in energy than the nitrogen orbitals, because oxygen is more electronegative. This will cause the bonding to be more ionic than in either There is an ambiguity, however, in that the MO diagram could be similar to either that of . Refer to Figures 3.31 and 3.32, where you will see that the ␴2p and ␲2p have different relative energies. There are consequently two possibilities for the orbital energy diagram: (b) The two orbital diagrams predict the same bond order (3) and same magnetic properties (diamagnetic), and so these properties cannot be used to determine which diagram is the correct one. That must be determined by more complex spectroscopic measurements. ␴ *2p ␴2p ␲2p ␲ *2p 2p 2p ␴ *2p ␴ *2s ␴2p ␴2s ␲2p ␲ *2p 2p 2s N O 2s ␴ *2s ␴2s 2s N O 2s 2p NOϩ (using N MO diagram) NOϩ (using O MO diagram) N2 orthatofO2 N2 or O2. NO+ HN3, B(N3)3, FN3, NaN3, Pb(N3)2, AgN3, HN3 HN3. 180°AX2, Ϫ1 NH3, NO, and N2O+ and NO + 2 H3O+ , NO,N2O+ and NO + 2NO and O + 2 NH3 and H3O+ SiCl4SiI4 SiCl4 SiI4 Al2Cl6 ODD-NUMBERED EXERCISES C41 15.129 (a) cloud: [NO] ϭ 860 ppt and [NO2] ϭ 250 ppt; clear air: [NO] ϭ 480 ppt and [NO2] ϭ 260 ppt. (b) clouds. (c) In addition to jet engines and automobile emissions, NO is also formed when NO2 dissolves in water. As a result one would expect to find more NO and less NO2 in clouds, which also contain water vapor. (d) nitrous acid: . (e) Nitrous acid would be expected to be more stable than either NO or the hydroxyl radical since both of these species have unpaired electrons while nitrous acid does not. (f) A possible mechanism that fits the observed rate law would be Step 1: NO ϩ O3 : NO2 ϩ O2 (slow) Step 2: NO2 ϩ O : NO ϩ O2 (fast) (g) 7.56 ϫ 10Ϫ29 molecules·cmϪ3 ·secϪ1 Chapter 16 16.1 Elements at the left of the d-block tend to have strongly negative standard potentials. 16.3 (a) Ti. (b) Because of the lanthanide contraction, they are about the same size. (c) Ta. (d) Ir 16.5 (a) Fe; (b) Cu; (c) Pt; (d) Pd; (e) Ta 16.7 Hg is much more dense than Cd, because the shrinkage in atomic radius that occurs between Z ϭ 58 and Z ϭ 71 (the lanthanide contraction) causes the atoms following the rare earths to be smaller than might have been expected for their atomic masses and atomic numbers. Zn and Cd have densities that are not too dissimilar, because the radius of Cd is subject only to a smaller d-block contraction. 16.9 (a) Proceeding down a group in the d-block (for example, from Cr to Mo to W), there is an increasing probability of finding the elements in higher oxidation states. That is, higher oxidation states become more stable on going down a group. (b) The trend for the p-block elements is reversed. Because of the inert-pair effect, the higher oxidation states tend to be less stable as one descends a group. 16.11 The ϩ6 oxidation state is most stable for Cr. 16.13 (a) ; (b) : ; (c) 16.15 (a) titanium(IV) oxide, TiO2; (b) iron(III) oxide, Fe2O3; (c) managanese(IV) oxide, MnO2; (d) iron(II) chromite, FeCr2O4 16.17 (a) CO (b) In Zones D & C, : , Fe3O4(s) ϩ CO(g) : 3 FeO(s) ϩ CO2(g). These reactions combine to give : . In Zone B, : , : . (c) carbon 16.19 (a) yes; (b) no 16.21 (a) : ; (b) : 16.23 As the value of n increases, d- and f-electrons become less effective at shielding the outermost, highest energy electron(s) from the attractive charge of the nucleus. This higher effective nuclear charge makes it more difficult to oxidize the metal atom or ion. 16.25 (a) behaves as a Brønsted acid: : . (b) The gelatinous precipitate is the hydroxide The precipitate dissolves as the complex ion is formed: : , : . 16.27 (a) hexacyanoferrate(II) ion, ϩ2; (b) hexaamminecobalt(III) ion, ϩ3; (c) aquapentacyanocobaltate(III) ion, ϩ3; (d) pentaamminesulfatocobalt(III) ion, ϩ3 16.29 (a) ; (b) ; (c) ; (d) Na3Fe(OH2)2 (C2O4)243Co(NH3)4(OH2)24Br3 3Co(NH3)5(SO4)4ClK33Cr(CN)64 Cr(OH)4 (aq)Cr(OH)3(s) + OH(aq)Cr(OH)3(s)3 OH- (aq) Cr3+ (aq) +Cr(OH)4 - Cr(OH)3. [Cr(OH2)5OH]2+ (aq) + H3O+ (aq)3Cr(OH2)643+ (aq) + H2O(l) 3Cr(OH2)6]3+ (aq), 2 VO 3- 4 (aq) + 3 H2O(l)V2O5(s) + 6 OH- (aq) 2 VO2 + (aq) + 3H2O(l)V2O5(s) + 2 H3O+ (aq) Fe(s) + CO2(g)FeO(s) + CO(g)2 Fe(s) + 3 CO2(g) Fe2O3(s) + 3 CO(g)2 FeO(s) + CO2(g) Fe2O3(s) + CO(g) 2 Fe3O4(s) + CO2(g) 3 Fe2O3(s) + CO(g) V2O5(s) + 5 Ca(l) ¡ ¢ 2 V(s) + 5 CaO(s) Co2+ (aq) + HCO3 (aq) + NO3 (aq)CoCO3(s) + HNO3(aq) TiCl4(g) + 2Mg(l) ¡ ¢ Ti(s) + 2 MgCl2(s) O ON Hß ß£ ¥ ¥ ¥ ¥ ¥ 16.31 (a) 3; (b) 1 or 2; (c) monodenate, 1; (d) 2 16.33 Only (b); in (a) and (c), the amine groups are too far apart to coordinate to the same metal atom. 16.35 (a) 4; (b) 2; (c) 6 (en is bidentate); (d) 6 (EDTA is hexadentate) 16.37 (a) structural isomers, linkage isomers; (b) structural isomers, ionization isomers; (c) structural isomers, linkage isomers; (d) structural isomers, ionization isomers 16.39 (a) yes and (b) no; (c) yes and 16.41 two linkage isomers, one ionization isomer: 16.43 (a) chiral; (b) not chiral Cr ClϪ NO2 Ϫ Cl NH3 NH3 NH3H3N H3N ϩ2 Cr 2ClϪ ONO NH3 NH3 NH3H3N H3N ϩ2 Cr 2ClϪ NO2 NH3 NH3 NH3H3N H3N ϩ2 Pt NH3 Cl Cl H3N trans-Diamminedichloridoplatinum(II) Pt NH3 NH3 Cl Cl cis-Diamminedichloridoplatinum(II) Co ClϪ иH2O å å Cl NH3 Cl NH3 H3N H3N ϩ cis-Tetraamminedichloridocobalt(III) chloride monohydrate Co ClϪ иH2O å å Cl Cl NH3 NH3 H3N H3N ϩ trans-Tetraamminedichloridocobalt(III) chloride monohydrate C42 ANSWERS 16.45 (a) 2; (b) 5; (c) 8; (d) 10; (e) 0 (or 8); (f) 10 16.47 (a) octahedral; strong-field ligand, 6 eϪ , no unpaired electrons (b) tetrahedral: weak-field ligand, 8 eϪ , two unpaired electrons (c) octahedral: weak-field ligand, 5 eϪ , five unpaired electrons (d) octahedral: strong-field ligand, 5 eϪ , one unpaired electron 16.49 (a) 0; (b) 2 16.51 Weak-field ligands do not interact strongly with the d-electrons in the metal ion, so they produce only a small crystal field splitting of the d-electron energy states. The opposite is true of strong-field ligands. With weak-field ligands, unpaired electrons remain unpaired if there are unfilled orbitals; hence, a weak-field ligand is likely to lead to a high-spin complex. Strong-field ligands cause electrons to pair up with electrons in lower energy orbitals. A strong-field ligand is likely to lead to a low-spin complex. Ligands arranged in the spectrochemical series help to distinguish strong-field and weak-field ligands. Measurement of magnetic susceptibility (paramagnetism) can be used to determine the number of unpaired electrons, which, in turn, establishes whether the associated ligand is weak-field or strong-field in nature. 16.53 In both cases we are looking at the difference between an Fe3ϩ (d5 ) and an Fe2ϩ (d6 ). Since CNϪ is a strong-field ligand, we expect that all the d-electrons in the [Fe(CN)6]3Ϫ complex are in the lower energy t2g orbitals. Upon reduction, one more electron is added, resulting in all electrons being paired, giving a diamagnetic complex: t2gt2g eg eg t 2– 5 ΔO 3– 5ΔO e ΔO t e 2– 5 ΔO 3– 5ΔO ΔO t e ΔT 3– 5 ΔT 2– 5ΔT t 3– 5 ΔO 2– 5ΔO e ΔO On the other hand, ClϪ is a weak-field ligand; here we expect the d-electrons to be distributed in both the t2g and the eg orbitals. Upon reduction, one more electron is added, resulting in only one electron being paired, leading to a complex that is still paramagnetic: 16.55 (a) [CoF6]3Ϫ is blue because Fis a weak-field ligand. (b) [Co(en)3]3ϩ is yellow because the en ligand is a strong-field ligand. 16.57 573 nm, yellow 16.59 (a) 0; (b) longer 16.61 In Zn2ϩ , the 3d-orbitals are filled (d10 ). Therefore, there can be no electronic transitions between the t- and e-levels; hence, no visible light is absorbed and the aqueous ion is colorless. The d10 configuration has no unpaired electrons, so Zn compounds would be diamagnetic, not paramagnetic. 16.63 (a) 162 kJ·molϪ1 ; (b) 260 kJ·molϪ1 ; (c) 208 kJ·molϪ1 ; (d) ClϪ Ͻ H2O Ͻ NH3 16.65 The eg set, which comprises the and orbitals. 16.67 (a) The CNϪ ion is a ␲-acid ligand accepting electrons into the empty ␲* orbital created by the C—N multiple bond. (b) The ClϪ ion has extra lone pairs in addition to the one that is used to form the ␴-bond to the metal, and so it can act as a ␲-base, donating electrons in a p-orbital to an empty d-orbital on the metal. (c) H2O, like ClϪ , dz2dx2 -y2 t2gt2g eg eg also has an “extra” lone pair of electrons that can be donated to a metal center, making it a weak ␲-base; (d) en is neither a ␲-acid nor a ␲-base, because it does not have any empty ␲-type antibonding orbitals nor does it have any extra lone pairs of electrons to donate. (e) Note that the spectrochemical series orders the ligands as ␲-bases Ͻ ␴-bond only ligands Ͻ ␲-acceptors. 16.69 nonbonding or slightly antibonding. In a complex that forms only ␴-bonds, the t2g set of orbitals is nonbonding. If the ligands can function as weak ␲-donors (those close to the middle of the spectrochemical series, such as H2O), the t2g set becomes slightly antibonding by interacting with the filled p-orbitals on the ligands. 16.71 Antibonding. The eg set of orbitals on an octahedral metal ion are always antibonding because of interactions with ligand orbitals that form the ␴-bonds. This is true regardless of whether the ligands are ␲-acceptors, ␲-donors, or neither. 16.73 Water has two lone pairs of electrons. Once one of these is used to form the ␴-bond to the metal ion, the second may be used to form a ␲-bond. This causes the t2g set of orbitals to move up in energy, making ⌬O smaller; therefore, water is a weak-field ligand. Ammonia does not have this extra lone pair of electrons and consequently cannot function as a ␲-donor ligand. 16.75 The green color suggests chromium or copper but the blue solution formed when the mineral is dissolved in sulfuric acid points to copper as the metal (CuSO4 is blue). The colorless gas that forms either upon heating or on treatment with acid is carbon dioxide; this is proven when the gas is bubbled into limewater (the cloudiness in the solution is due to calcium carbonate formation). CO2 is formed when carbonates are either heated or treated with acid. The mineral is most likely basic copper carbonate (Cu2CO3(OH)2). 16.77 (a) ϩ3; (b) : 16.79 3.6 ϫ 10Ϫ31 16.81 (a) Pt NH3 NH3 Br Br cis-Diamminedichloridoplatinum(II) 3PtBrCl(NH3)24 V4C3(s) + 5 CO2(g)2 V2O5(s) + 8 C(s) Cl- 6 H2O 6 en 6 CN- . ODD-NUMBERED EXERCISES C43 (b) If the compound were tetrahedral, there would be only one compound, not two. 16.83 (a) The first, will give a precipitate of AgCl when is added; the second will not. (b) The second, will show free when mildly oxidized with, for example, but the first will not. 16.85 (a) [MnCl6]4Ϫ a å a å a å a å a å Br2, I23NiCl2(en)2]I2, AgNO3 3Ni(SO4)(en)2]Cl2, Pt NH3 Br Br H3N trans-Diamminedichloridoplatinum(II) 16.93 The electron configuration expected for is For this complex to have no unpaired electrons, it would have to be square planar in its electronic geometry, as both the octahedral and tetrahedral geometries require a species to have two unpaired electrons. Square planar does not: 16.95 Since NH3 is a strong-field ligand (large ) and water is a weakfield ligand (small ), of the octahedral cobalt(II) complexes, and it is expected that the hexaammine complex will absorb at a shorter wavelength and therefore transmit light of a higher wavelength than the hexaaquo complex. is a tetrahedral complex, and since the magnitude of is much smaller than it is expected this complex will absorb at the longest wavelength of the three and therefore transmit light of the shortest wavelength. Based on this, is yellow, is pink, and is blue. 16.97 (a) , pentaammineaquacobalt(III) chloride, (b) , pentaamminechloridocobalt (III) chloride 16.99 (a) trigonal bipyramidal. (b) ϩ1. (c) There are six possible isomers [CoCl(NH3)5]Cl2 [Co(NH3)5OH24Cl3 [CoCl4]2- [Co(OH2)6]2+ [Co(NH3)6]2+ ¢O ¢t 3CoCl442- [Co(OH2)6]2+ ,[Co(NH3)6]2+ ¢O ¢O Ó ÓÓ Ó a ÓÓ Ó aa ÓÓÓ a d8 3Ar43d8 .Ni2+ octahedral d8 complex tetrahedral d8 complex square planar d8 complex 16.101 2 ϫ 106 16.103 15.12 mL Ir å åå å å Cl OC OC PPh3 PPh3 Ir å ååå å CO CO Ph3P Cl PPh3 Ir å åå å å PPh3 Cl OC CO PPh3 Ir å åå å å CO OC Cl PPh3 PPh3 Ir å åå å å Cl OC OC PPh3 PPh3 Ir å åå å å CO Cl Ph3P CO PPh3 Nonsuperimpossible mirror images (b) [MnCl6]4Ϫ : five; [Mn(CN)6]4Ϫ : one. (c) Complexes with weak-field ligands absorb longer wavelength light; therefore, [MnCl6]4Ϫ absorbs longer wavelengths. 16.87 If the prismatic structure were the true structural form of , one would expect to get four possible isomers, not the two seen (X ϭ NH3): 16.89 The correct structure for consists of four ions, and in aqueous solution. The chloride ions can be easily precipitated as AgCl. This would not be possible if they were bonded to the other ligands. If the structure were VSEPR theory would predict that the ion would have a trigonal planar ligand arrangement. The splitting of the d-orbital energies would not be the same as the octahedral arrangement and would lead to different spectroscopic and magnetic properties inconsistent with the experimental evidence. In addition, neither optical nor geometrical isomers would be observed. 16.91 See Figure 16.26. Remove (mentally) the ligands along the z axes. From the shape of the atomic orbitals and their orientation with respect to the x, y, and z axes, it is clear that the -orbital will have the greatest overlap, therefore repulsion, from the ligands in the xy plane. The -orbital will have the next strongest repulsion from these ligands, next, and finally, the weakest repulsion will be with and . Therefore, the energy-level diagram will be (schematically): The building-up principle is illustrated in the diagram with a d8 ion (Pd2ϩ ). The separation in energy between the and orbitals determines whether or not there will be unpaired electrons. dxydx2 -y2 dxz E dyz dxy dz2 dx2 Ϫ y2 dyzdxzdz2 dxy dx2 -y2 ; Co3+ Co(NH3—NH3—Cl)3, (NH3) 3 Cl- Co(NH3)6 3+ , 3Co(NH3)6]Cl3 X X Co X Cl Cl X Cl X Co Cl X X X Cl X Co X X X Cl Cl Cl Co X X X X 3CoCl2(NH3)44 Chapter 17 17.1 (a) 3.22 ϫ 1020 Hz, 9.32 ϫ 10Ϫ13 m; (b) 3.97 ϫ 1020 Hz, 7.56 ϫ 10Ϫ13 m; (c) 2.66 ϫ 1020 Hz, 1.13 ϫ 10Ϫ12 m 17.3 17.5 (a) : ; (b) : ; (c) : ; (d) : 17.7 (a) : ; (b) : ; (c) : ; (d) : 17.9 (a) : (b) : 128 51Sb + -1 0 e; a ␤ particle is emitted.128 50Sn 24 12Mg + -1 0 e; a ␤ particle is emitted.24 11Na 7 3Li7 4Be + -1 0 e4 2␣ + 181 77Ir185 79 Au -1 0 e + 63 29Cu63 28Ni0 1e + 8 4Be8 5B 4 2a + 221 89 Ac225 91 Pa-1 0 e + 87 37Rb87 36Kr 0 1e + 83 38Sr83 39Y-1 0 e + 3 2He3 1T 39 18Ar and 41 20Ca [Mn(CN)6]4Ϫ C44 ANSWERS (c) : (d) : 17.11 (a) : ; (b) : ; (c) : ; (d) : 17.13 (a) ␤ decay, : ; (b) ␤+ decay, : ; (c) ␣ decay, : ; (d) ␣ decay, : 17.15 ␣, : ; ␤, : ; ␣, : ; ␤, : ; ␣, : ; ␣, : ; ␣, : ; ␤, : ; ␣, : : ; ␣, : 17.17 (a) : ; (b) : ; (c) : ; (d) : 17.19 (a) : ; (b) : ; (c) : ; (d) : 17.21 : : 17.23 (a) : ; (b) : 17.25 (a) unbihexium, Ubh; (b) untrihexium, Uth; (c) binilnilium, Bnn 17.27 1.4 ϫ 10Ϫ5 Ci 17.29 (a) 9.2 ϫ 104 Bq; (b) 5.3 ϫ 1012 Bq; (c) 2.7 ϫ 108 Bq 17.31 75 rad, 75 rem, 0.75 Sv 17.33 100 days 17.35 (a) 5.64 ϫ 10Ϫ2 aϪ1 ; (b) 0.83 sϪ1 ; (c) 0.0693 minϪ1 17.37 8.8 h 17.39 (a) 69.6%; (b) 50.9% 17.41 9.29 ϫ 108 a 17.43 3.54 ϫ 103 a 17.45 (a) 9.9 ϫ 10Ϫ4 Ci; (b) 0.28 Ci; (c) 0.40 Ci 17.47 400 min 17.49 26.4% 17.51 , , , k1 0.0253 dϪ1 , k2 0.0371 dϪ1 . The plot assumes [X]0 ϭ 2.00 g. 17.53 If is used in the reaction, the label can be followed. Once the products are separated, a suitable technique, such as vibrational spectroscopy or mass spectrometry, can be used to determine whether the product has incorporated the For example, if the methanol ends up with the O atom from the water molecules, then its molar mass would be rather than the found for methanol with elements present at their natural isotopic abundance. 17.55 The vibrational frequency will decrease. 17.57 44.4 d 32 gиmol-1 34 gиmol-1 , 18 O. H2 18 O 0.0 150125100755025 t (days) m(grams) 0 2.0 1.5 1.0 0.5 X (g) Y (g) Z (g) === [X]0a1 + k1e-k2t - k2e-k1t k2 - k1 b [Z] = [X]0 - a[X]0e-k1t + k1 k2 - k1 (e-k1t - e-k2t )[X]0b 3Y4 = k1 k2 - k1 (e-k1t - e-k2t )[X]0[X] = [X]0e-k1t 240 95 Am + 0 -1e239 94 Pu + 1 0n17 8O + 1 1p14 7 N + 4 2 ␣ 62 32Ge + 6 0 -1e62 26Fe56 26Fe + 6 1 0n 1 1p + 28 13Al27 13Al + 2 1H␥ + 48 22Ti44 20Ca + 4 2␣16 8O + 24 12Mg 20 10Ne + 20 10Ne8 4Be + 16 8O20 10Ne + 4 2␣ 14 6C + ␥13 6C + 1 0n244 96 Cm + 0 -1e + ␥243 95Am + 1 0n 249 97Bk + 0 -1e248 96Cm + 1 0n17 8O + 1 1p14 7N + 4 2␣ 4 2␣ + 207 82 Pb211 84Po211 84Po-1 0 e +211 83Bi; ␤, 211 83Bi 4 2␣ +215 85At-1 0 e + 215 85At215 84Po4 2␣ + 215 84Po219 86Rn 4 2␣ + 219 86Rn223 88 Ra4 2␣ + 223 88Ra227 90Th -1 0 e + 227 90Th227 89Ac4 2␣ + 227 89Ac231 91 Pa -1 0 e + 231 91Pa231 90Th4 2␣ + 231 90Th235 92U 4 2␣ + 256 103Lr260 105Db 4 2␣ + 239 95 Am243 97 Bk0 1e + 103 47 Ag103 48Cd -1 0 e + 68 30 Zn68 29Cu 4 2␣ + 42 19K45 21Sc + 1 0n1 0n + 97 43Tc96 42Mo + 2 1D 1 0n + 36 18Ar35 17Cl + 2 1D21 0n + 13 7 N11 5 B + 4 2a 224 88Ra + 4 2␣; an ␣ particle is emitted.228 90Th 140 56Ba + 0 1e; a positron (␤+ )is emitted.140 57La 17.59 (a) 9.0 ϫ 1013 J; (b) 8.20 ϫ 10Ϫ14 J; (c) 90. J; (d) 1.51 ϫ 10Ϫ10 J 17.61 Ϫ4.3 ϫ 109 kgиsϪ1 17.63 (a) 1.41 ϫ 10Ϫ12 JиnucleonϪ1 ; (b) 1.21 ϫ 10Ϫ12 JиnucleonϪ1 ; (c) 1.8 ϫ 10Ϫ13 JиnucleonϪ1 ; (d) 4.3 ϫ 10Ϫ13 JиnucleonϪ1 ; (e) 17.65 (a) Ϫ7.8 ϫ 1010 JиgϪ1 ; (b) Ϫ3.52 ϫ 1011 JиgϪ1 ; (c) Ϫ2.09 ϫ 1011 JиgϪ1 ; (d) Ϫ3.36 ϫ 1011 JиgϪ1 17.67 (a) : ; (b) Ϫ8.85 ϫ 10Ϫ13 J; (c) Ϫ3.69 ϫ 10Ϫ14 JиnucleonϪ1 17.69 (a) : ; (b) : ; (c) : 17.71 (a) False; the dose equivalent is either equal to or larger than the actual dose, due to the Q factor. (b) False; , which is much smaller than 10 Ci. (c) true. (d) true 17.73 (a) 9 dpm; (b) 7 ϫ 105 decays 17.75 (a) 3.4 ϫ 108 pCiиLϪ1 ; (b) 1.1 ϫ 1019 atoms; (c) 1 ϫ 102 days 17.77 (a) 4.5 Ga; (b) 3.8 Ga 17.79 (a) 1.3 ϫ 10Ϫ5 sϪ1 ; 0.63 d; (b) 0.22 mg 17.81 (a) Radioactive substances that emit ␥ radiation are most effective for diagnosis because they are the least destructive of the types of radiation listed. Additionally, ␥-rays pass easily through body tissues and can be counted, whereas ␣ and ␤ particles are stopped by the body tissues. (b) ␣ particles tend to be best for this application because they cause the most destruction. (c) and (d) 8 d (used to image the thyroid); (used most often as the citrate complex); 6 h (used for various body tissues by varying the ligands attached to the Tc atom) 17.83 (a) : : ; (b) Tc-99m (N/Z ϭ 1.30 versus 1.36 for Mo-99) 17.85 To make a small nuclear bomb you need what is called a “critical mass” of radioactive material; this is the minimum amount of material needed to achieve spontaneous fission, which is the process that causes the bomb to explode. For plutonium, the amount of material needed is about 17 kg (or 33 lb), the weight of an average three-year-old child. Plutonium, however, is very dense (a large amount of it can fit in a very small space), so the actual size of this amount of plutonium would only be the size of a grapefruit, or just a little bigger than a softball. 17.87 0.26 L 17.89 1.63742 ϫ 10Ϫ13 J 17.91 (a) 262 dpm; (b) 1.18 ϫ 10Ϫ4 ␮Ci 17.93 (a) 9%, 13%; (b) 0.47 ␮Ci; (c) 51.4 d; (d) 0.17; (e) approximately 0% Chapter 18 18.1 (a) (b) (c) H H® ®C £ C ßC å H å H å H ® å H C å å H H Alkene H® C ® C ßC å å å H H å H å H H ® å H C ® å å H H H Alkane H® C C å å H H ® C ®®®® ®C å å H H H Alkyne 99m 43Tc + 0 -1␤99 42Mo98 42Mo + 1 0n 99m Tc,67 Ga,78h 131 I, 1.8 * 108 Bq = 0.003 Ci 101 42 Mo + 132 50 Sn + 31 0n235 92 U + 1 0n 96 40Zr + 138 52Te + 21 0n235 92 U + 1 0n 134 53 I + 107 42Mo + 3 1 0n244 95Am 24 12Mg + 0 -1e24 11Na 62 Ni ODD-NUMBERED EXERCISES C45 (d) (e) 18.3 (a) (CH3)3CH or C4H10, alkane; (b) C6H7CH3 or C7H10, alkene; (c) C6H12, alkane; (d) C6H12, alkane 18.5 (a) C12H26, alkane; (b) C13H20, alkene; (c) C7H14, alkane; (d) C14H8, aromatic hydrocarbon 18.7 (a) propane; (b) butane; (c) heptane; (d) decane 18.9 (a) methyl; (b) pentyl; (c) propyl; (d) hexyl 18.11 (a) propane; (b) ethane; (c) pentane; (d) 2,3-dimethylbutane 18.13 (a) 4-methyl-2-pentene; (b) 2,3-dimethyl-2-phenylpentane 18.15 (a) CH2≈CHCH(CH3)CH2CH3; (b) CH3CH2C(CH3)2CH(CH2CH3)(CH2)2CH3; (c) HCΩC(CH2)2C(CH3)3; (d) CH3CH(CH3)CH(CH2CH3)CH(CH3)2 18.17 (a) (b) (c) (d) 18.19 (a) (b) (c) 18.21 (a) hexenes H3C CH2 CH2 CH CH CH3 cis-2-Hexene H3C CH2 CH2 CH2 CH2 CH 1-Hexene C H H £ C œç œç CH2H3C ß CH3CH2 ß H® ßßC C å H C å CH3 CH3 å å H å HßC ßC® å H å åå å H CH3 H HH H® ßC C ßC C® å C å å CH2 CH3 å H HßßC ßC ßC® å H C å H å å å å å å å å HH CH2 CH3 å å CH2 CH2 CH3 å H å H H H H ßC å å H HH ®®® H® ßC ß C ßC C® å H C å CH3 å H åå H å H HßßC ßC ßC® å H C å H å å å ååå å å å å HH H CH3 HH H H H HH H H £C £ C ßC C å H ® å H C å H H H å H Alkene ç ∂ ç ∂ H ®®® £ CCCC ® C C å å H å H H å H å H å H ® ®C å å H H H Alkene and alkyne ®®® pentenes: butanes (b) cyclic molecules The following structures are drawn to emphasize the stereochemistry: H H H H H H CH3 CH3 cis-1,2-Dimethylcyclobutane 1,1-Dimethylcyclobutane CH3 CH3 Ethylcyclobutane CH2 CH3 Methylcyclopentane CH3 Cyclohexane H3C H3C 2,3-Dimethyl-2-butene œ CC œ œ œ £ CH3 CH3 H3C H3C 2,3-Dimethyl-1-butene œ C œ œœ œ CHß CH2 CH3 H3C H3C 3,3-Dimethyl-1-butene œ C œ œ œ CH CH3 CH2 H3C CH CH3 cis-4-Methyl-2-pentene (ϩ trans isomer) CH3 CH HC H3C H3C CH CH3 cis-3-Methyl-2-pentene (ϩ trans isomer) C CH2 H3C CH CH3 2-Methyl-2-pentene C CH3 CH2 H3C CH2 CH2 CH3 CCH2 2-Methyl-1-pentene H3C CH CH2 CH3 CHCH2 3-Methyl-1-pentene H3C CH2 CH2 CH3 CHCH 4-Methyl-1-pentene H3C CH2 CH2 CH3 CH CH trans-3-Hexene H3C CH2 CH2 CH CH CH3 cis-3-Hexene H3C CH2 CH2 CH CH CH3 trans-2-Hexene C46 ANSWERS 1,1,2-Trimethylcyclopropane (nonsuperimposable mirror images) H H CH3 CH3 H H H HH3C H3C CH3 CH3 trans-1-Ethyl-2-methylcyclopropane (nonsuperimposable mirror images) H2C H2C H H H CH3H H H H HH3C CH3ß CH3ß H H H 1-Ethyl-1-methylcyclopropane CH3 CH2 CH3 H ® H H HCH CH3 CH3 Isopropylcyclopropane or 2-cyclopropylpropane ß ß HH H H CH2H CH2 CH3 Propylcyclopropane ß ß HH H H3C H H H CH3 H H cis-1,3-Dimethylcyclobutane H H3C H H CH3 H H H trans-1,3-Dimethylcyclobutane H CH3 CH3 H H H H H H H3C H3C H H H H H trans-1,2-Dimethylcyclobutane (nonsuperimposable mirror images) 18.23 (a) not isomers; (b) structural isomers; (c) geometrical isomers; (d) not isomers, just different views of the same molecule 18.25 (a) (b) 18.27 An asterisk (*) designates a chiral carbon. (a) optically active, (b) not optically active, (c) optically active, (d) optically active, H H Cl Cl CH3C CH2 CH2 CH3C*ß ß ß ß ß å å å å H H Br Cl CH CH3C*ß ß ß å å å å Cl C CH3 HH Cl H C H3C CH2 CH3C* H Br ® H2C CH3C H CH3 Cl H3C CH3C Cl CH3 H3C CH3C CH3 H CH3 H H 1,2,3-Trimethylcyclopropane (cis–trans isomer) CH3 H H3C H CH3 H 1,2,3-Trimethylcyclopropane (all cis isomer) CH3 H H3C cis-1-Ethyl-2-methylcyclopropane (nonsuperimposable mirror images) H CH2 CH3 H H CH3H H H H HH3C CH2 CH3 ODD-NUMBERED EXERCISES C47 18.29 The difference can be traced to the weaker London forces that exist in branched molecules. Atoms in neighboring branched molecules cannot lie as close together as they can in unbranched isomers. 18.31 The balanced equations are C3Hg(g) ϩ 5 O2(g) : 3 CO2(g) ϩ 4 H2O(l), C4H10(g) ϩ O2(g) : 4 CO2(g) ϩ 5 H2O(l), C5H12(g) ϩ 8 O2(g) : 5 CO2(g) ϩ 6 H2O(l). The enthalpies of combustion that correspond to these reactions are listed in Appendix 2: (a) Enthalpy of (b) Heat released Compound combustion (kJؒmol؊1 ) per g (kJؒg؊1 ) propane Ϫ2220 50.3 butane Ϫ2878 49.5 pentane Ϫ3537 49.0 The molar enthalpy of combustion increases with molar mass as might be expected, because the number of moles of CO2 and H2O formed will increase as the number of carbon and hydrogen atoms in the compounds increases. The heat released per gram of these hydrocarbons is essentially the same because the H to C ratio is similar in the three hydrocarbons. 18.33 nine, none 18.35 (a) 4 ␴-type single bonds; (b) 2 ␴-type single bonds and 1 double bond with a ␴-bond and a ␲-bond; (c) 1 ␴-type single bond and 1 triple bond with a ␴-bond and 2 ␲-bonds 18.37 cis-1,2-Dichloropropene is polar, although trans-1,2-dichloropropene is slightly polar also. 18.39 (a) (b) addition reaction 18.41 (a) C6H11Br ϩ NaOCH2CH3 : C6H10 ϩ NaBr ϩ HOCH2CH3 (b) (c) elimination reaction 18.43 The reaction is less exothermic as the halogen becomes heavier. In general, the reactivity, and also the danger associated with use of the halogens in reactions, decreases as one descends the periodic table. C C C C C C œ œ ç ç ç H ç H H œ H Hß H H H H œ H ß ϩ NaBr ϩ HOCH2CH3 C C C C C C œ œ ç ç ç H ç H H œ H Hß H H H H œ H Hß ß Hß ϩ ıßBNaOCH2CH3 CH H H Cßß C Cß C Hß ßß å å H Br å å H H å å H H å å H H å å 2-Bromopentane CH H H Cßß C Cß C Hß ßß å å H H å å H Br å å H H å å H H å å 3-Bromopentane C H Cl Cl CH3 C£ œ ç œ ç trans-1,2-Dichloropropene C Cl Cl H CH3 C£ œ ç œ ç cis-1,2-Dichloropropene 13 2 18.45 (a) 1-ethyl-3-methylbenzene; (b) pentamethylbenzene (1,2,3,4, 5-pentamethylbenzene is also correct, but, because there is only one possible pentamethylbenzene, the use of the numbers is not necessary) 18.47 (a) (b) (c) (d) 18.49 (a) CH3 Cl Cl 1,3-Dichloro-5-methylbenzene CH3 Cl Cl 1,5-Dichloro-2-methylbenzene CH3 Cl Cl 1,4-Dichloro-2-methylbenzene CH3 Cl Cl 1,3-Dichloro-2-methylbenzene CH3 Cl CH3 CH3 CH3 Cl CH3 C48 ANSWERS (b) All of these molecules are at least slightly polar. 18.51 18.53 Two compounds can be produced. Resonance makes positions 1, 4, 6, and 9 equivalent. It also makes positions 2, 3, 7, and 8 equivalent. Positions 5 and 10 are equivalent but have no H atom. 18.55 These hydrocarbons are too volatile (they are all gases at room temperature) and would not remain in the liquid state. 18.57 CH2CHCH3 ϩ CH3CH2CH2CH3 : CH3(CH2)5CH3 18.59 (a) substitution, CH4 ϩ Cl2 : CH3Cl ϩ HCl; (b) addition CH2≈CH2 ϩ Br2 : CH2BrßCH2Br 18.61 Water is not used, as the nonpolar reactants will not readily dissolve in a highly polar solvent like water. Also, the ethoxide ion reacts with water. 18.63 (a) CH3CH2CH3(g) ϩ 5 O2(g) : 3 CO2(g) ϩ 4 H2O(g); CHCH ϩ 2 O2(g) : 2 CO2(g) + H2O(g). (b) propane: Ϫ46.35 kJиgϪ1 ; ethyne: Ϫ48.22 kJиgϪ1 . (c) More heat is released per gram of ethyne, resulting in a hotter flame. 18.65 (a) 2-methyl-1-propene, no geometrical isomers; (b) cis-3methyl-2-pentene, trans-3-methyl-2-pentene; (c) 1-hexyne, no geometrical isomers; (d) 3-hexyne, no geometrical isomers; (e) 2-hexyne, no geometrical isomers 18.67 (a) C10H18. (b) naphthalene, . C10H8. (c) yes. Cis and trans forms (relative to the CßC bond common to the two sixmembered rings) are possible. 1 2 1 2 3 46 57 9 10 8 E E C C C C N N N N ϩ ϩ ϩ ϪϪϪ CH3 Cl Cl 1,2-Dichloro-4-methylbenzene CH3 Cl Cl 1,2-Dichloro-3-methylbenzene 18.69 (a) 60°. (b) severe bond angle strain. (c) Ϫ1488 kJ·molϪ1 . (d) Cyclopropane releases more heat on combustion because it is not a stable molecule due to severe bond angle strain. The CßC and CßH bonds in cyclopropane are not as stable as regular CßC and C–H bonds and their true bond enthalpies are lower values. 18.71 The empirical formula is C4H9; the molecular formula might be C8H18, which matches the formula for alkanes (CnH2nϩ2). It is not likely an alkene or alkyne, because there is no reasonable Lewis structure for a compound having the empirical formula C4H9 and multiple bonds. 18.73 (a) (b) (c) (d) 3-Ethyl-2,2-dimethylhexane 2,2-Dimethyl-4-ethylheptane 3,5-Dimethyloctane 4-Ethyl-5-methyloctane H H H H H H H H H H H H H H H H cis-Decalin H H H H H H H H H H H H H H H H H trans-Decalin ODD-NUMBERED EXERCISES C49 18.75 cyclopropane 18.77 The NO2 group is a meta-directing group and the Br atom is an ortho, para-directing group. Because the position para to Br is already substituted with the NO2 group, further bromination will not occur there. The resonance forms show that the bromine atom will activate the position ortho to it as expected. The NO2 group will deactivate the group ortho to itself, thus in essence enhancing the reactivity of the position meta to the NO2 group. This position is ortho to the Br atom, so the effects of the Br and NO2 groups reinforce each other. Bromination is thus expected to occur as shown: 18.79 (a) and (b) (c) no 18.81 For a molecule such as 1,2-dichloro-4-diethylbenzene, C6H3Cl2(CH2CH3), 175.04 mu, it is relatively easy to lose heavy atoms such as chlorine and groups of atoms such as methyl and ethyl fragments. Molecules can also lose hydrogen atoms. In mass spectrometry, P is used to represent the parent ion, which is the ion formed from the molecule without fragmentation. Fragments are then represented as P – x, where x is the particular fragment lost from the parent ion to give the observed mass. Because the mass spectrum will measure the masses of individual molecules, the mass of carbon used will be 12.00 mu (by definition) because the large majority of the molecules will have all 12 C. The mass of H is 1.0078 mu. Some representative peaks that may be present are listed below. Relation to Fragment formula parent ion Mass (mu) C6H3 35 Cl2(CH2CH3) P 174.00 C6H3 35 Cl37 Cl(CH2CH3) P 176.00 C6H3 37 Cl2(CH2CH3) P 177.99 C6H3 35 Cl(CH2CH3) P – Cl 139.03 C6H3 37 Cl(CH2CH3) P – Cl 141.03 C6H3 35 Cl2(CH2) P – CH3 158.98 C6H3 35 Cl37 Cl(CH2) P – CH3 160.97 C6H3 37 Cl2(CH2) P – CH3 162.97 C6H3 35 Cl2 P – CH2CH3 144.96 C6H3 35 Cl37 Cl P – CH2CH3 146.96 C6H3 37 Cl2 P – CH2CH3 148.96 C6H3 35 Cl P – CH2CH3ßCl 109.99 C6H3 37 Cl P – CH2CH3ßCl 111.99 Etc. 18.83 The presence of one bromine atom will produce in the ions that contain Br companion peaks that are separated by 2 mu. Any fragment that contains Br will show this “doublet” in which the peaks are nearly but not exactly equal in intensity. Thus, seeing a mass spectrum of a compound that is known to have Br or that was involved in a reaction in which Br could have been added or substituted with such doublets, is almost a sure sign that Br is present in the compound. It is also fairly easy to detect Br atoms in the mass spectrum at 79 and 81 mu, confirming their presence. If more than one Br atom is present, then a more complicated pattern is observed for the presence of the two isotopes. The possible combinations for a molecule of unknown formula with two Br atoms is 79 Br 79 Br, 79 Br 81 Br, 81 Br 79 Br, and 81 Br 81 Br. Thus, a set of three peaks (the two possibilities 79 Br 81 Br and 81 Br 79 Br have identical masses) will be generated that differ in mass by two units. The center peak, which is produced by the 79 Br 81 Br and 81 Br 79 Br combinations, will have twice the intensity of the outer two peaks, because statistically there are twice as many combinations that produce this mass. All modern mass spectrometers have spectral simulation programs that can readily calculate and H H H H CH3 H CH3 CH3 H H H C C C C C C CH3 * * BrN O O Br Br N O O print out the relative isotopic distribution pattern expected for any compound formulation, so that it is possible to easily match the expected pattern for a particular ion with the experimental result. 18.85 C8H10 will have an absorption maximum at a longer wavelength. Molecular orbital theory predicts that in conjugated hydrocarbons (molecules which contain a chain of carbon atoms with alternating single and double bonds) electrons become delocalized and are free to move up and down the chain of carbon atoms. Such electrons may be described using the one-dimensional “particle-in-a-box” model introduced in Chapter 1. According to this model, as the box to which electrons are confined lengthens, the quantized energy states available to the electrons get closer together. As a result, the energy needed to excite an electron from the ground state to the next higher state is lower for electrons confined to longer boxes. Therefore, lower energy photons, i.e., photons with longer wavelengths, will be absorbed by the C8H10 molecule because it provides a longer “box” than C6H8. 18.87 (a) C2H3; (b) C4H6 (c) (d) the sixth compound (cyclobutene); (e) C4H8Br2 (f) (g) All the carbons are sp2 hybridized. (h) trans- and cis-1,3-butadiene. Chapter 19 19.1 (a) RNH2, R2NH, R3N; (b) ROH; (c) RCOOH; (d) RCHO 19.3 (a) ether; (b) ketone; (c) amine; (d) ester 19.5 (a) 2-iodo-2-butene; (b) 2,4-dichloro-4-methylhexane; (c) 1,1,1,-triiodoethane; (d) dichloromethane 19.7 (a) (b) CH3CH(CH3)CH(OH)CH2CH3, secondary alcohol; (c) CH3CH2CH(CH3)CH2CH(CH3)CH2OH, primary alcohol; (d) CH3C(CH3)(OH)CH2CH3, tertiary alcohol 19.9 (a) CH3CH2OCH3; (b) CH3CH2OCH2CH2CH3; (c) CH3OCH3 19.11 (a) butyl propyl ether; (b) methyl phenyl ether; (c) pentyl propyl ether 19.13 (a) aldehyde, ethanal; (b) ketone, propanone; (c) ketone, 3-pentanone 19.15 (a) O Butanal Cl, C6H4Cl(OH) OH Br Br * * 2,3-Dibromobutane BrBr * 1,3-Dibromobutane Br Br 1,4-Dibromobutane phenol; C50 ANSWERS (b) (c) 19.17 (a) ethanoic acid; (b) butanoic acid; (c) 2-aminoethanoic acid 19.19 (a) (b) (c) (d) 19.21 (a) methylamine; (b) diethylamine; (c) o-methylaniline, 2-methylaniline, o-methylphenylamine, or 1-amino-2-methylbenzene 19.23 (a) (b) (c) 19.25 (a) and (c) 19.27 (a) ethanol. (b) 2-octanol. (c) 5-methyl-1-octanol. These reactions can be accomplished with an oxidizing agent such as acidified sodium dichromate, Na2Cr2O7. 19.29 (a) (b) ™ ç O O CH2CH2CH2CH2CH3ß CH3C ™ œç ç O O CH CH3 CH3 ß CH3CH2CH2C H3C CH3 CH3 CH3ß ßN å å ϩ N CH3CH2 CH3CH2 CH2CH3ß œ ç NH2 CH3 C H2C CH£ O£ œ ç ç O H H3C H2 C C H2 H2 C C C H2 H O O ™ H3C H2 C CH CH3 O CH H O C Cl C OH O O 2-Heptanone O 3-Hexanone (c) (d) 19.31 (a) addition; (b) condensation; (c) addition; (d) addition; (e) condensation 19.33 The following procedures can be used: (1) Dissolve the compounds in water and use an acid–base indicator to look for a color change. (2) CH3CH2CHO +++++→ CH3CH2COOH ϩ Ag(s) (3) CH3COCH3 +++++→ no reaction Procedure (1) will distinguish ethanoic acid; (2) and (3) will distinguish propanal from 2-propanone. 19.35 CH3CH2COOHϽCH3COOHϽClCH2COOHϽCl3CCOOH. The greater the electronegativities of the groups attached to the carboxyl group, the stronger the acid. 19.37 (a) –CH2–C(CH3)2–CH2–C(CH3)2–CH2–C(CH3)2– (b) (c) 19.39 HOOCC6H12COOH; NH2C6H4NH2 19.41 (a) CHCl≈CH2; (b) CFCl≈CF2 19.43 (a) –OCCONH(CH2)4NHCOCONH(CH2)4NH–; (b) –OC–CH(CH3)–NH–OC–CH(CH3)–NH– 19.45 block copolymer 19.47 Polymers generally do not have definite molecular masses because there is no fixed point at which the chain-lengthening process will cease. The chain stops growing due to lack of nearby monomer units of the appropriate kind or a lack of properly oriented smaller polymeric aggregates. A polymer is, in a sense, not a pure compound, bur rather a mixture of similar compounds of different chain lengths. There is no fixed molar mass, only an average molar mass. Because there is no one unique compound, there is no one unique melting point, rather a range of melting points. 19.49 All increase with increasing molar mass. CC CC C C C C C C C C H H H H H H H HHH HHH H H H3C H3C H3C trans version H H H H H H H H H H H H H C C C C C CC CC CC C CH3 CH3 CH3 HH cis version CH CH CH CNCNCN CH2 CH2 CH2 ™ ç O NHCH2CH2CH3 CH3C ™ å ç O NCH2CH3 CH3 CH3CH2CH2CH2CH2C Tollens reagent Tollens reagent ODD-NUMBERED EXERCISES C51 19.51 Highly linear, unbranched chains allow for maximum interaction between chains. The greater the intermolecular contact between chains, the stronger the forces between them, and the greater the strength of the material. 19.53 (a) (b) amide; (c) condensation 19.55 Serine, threonine, tyrosine, aspartic acid, glutamic acid, lysine, arginine, histidine, asparagine, and glutamine satisfy the criteria. Proline and tryptophan generally do not contribute through hydrogen bonding, because they are typically found in hydrophobic regions of proteins. 19.57 19.59 (a) alcohols and aldehydes. (b) The chiral carbon atoms are marked with asterisks (*). 19.61 (a) GTACTCAAT; (b) ACTTAACGT 19.63 (a) C5H5N5O; (b) C6H12O6; (c) C3H7NO2 19.65 (a) alcohol, ether, aldehyde; (b) ketone, alkene; (c) amine, amide 19.67 (a) (b) 19.69 (a) CH2 CH3 H2 CHCH CH H3C CH2 CH2 H C C C N O O O * * * * CH3 OH O * * * * * * CH3 O CH3 * * HH HH OH CH2OHOHC C C OH OHOH CC* * * * OH CH2 H C C NH2 CH2NH COOH O C NH O (b) 19.71 (a) (b) methylamine: Ϫ27.94 kJиgϪ1 ; dimethyl ether: Ϫ17.84 kJиgϪ1 ; acetic acid: Ϫ11.36 kJиgϪ1 ; (c) dimethyl ether 19.73 (a) (b) 1-Butanol can hydrogen bond with itself but diethyl ether cannot, so 1-butanol molecules are held together more strongly in the liquid and therefore 1-butanol has the higher boiling point. Both compounds can form hydrogen bonds with water and therefore have similar solubilities. 19.75 (a) (b) 19.77 (a) HOCH2CH2OH ϩ 2 CH3(CH2)16COOH : CH3(CH2)16COOCH2CH2OOC(CH2)16CH3 ϩ 2 H2O; (b) 2CH3CH2OH ϩ HOOCCOOH : CH3CH2OOCCOOCH2 CH3 ϩ 2 H2O; HO CHO O (CH2)16CH3CH2 O C O (CH2)16CH3CH2 O C O (CH2)16CH3HC O C H H Cß Cß Cß Cß Oß Hß å H å H å H H H H H å å å å å 1-Butanol H H Cß Cß Oß Cß Cß Hß å H å H å H H H H H å å å å å Diethyl ether C H3C H O O ™ H3C CH3 O Dimethyl ether Acetic acid H H H H Cß ß å H å å å Methylamine N O O CH3 O O O CH CH2 C H2 CH H2 CH2C * * C52 ANSWERS (c) CH3CH2CH2CH2OH ϩ CH3CH2COOH CH3CH2COOCH2CH2CH2CH3 ϩ H2O 19.79 (a) 7180 g·molϪ1 . (b) 135. (c) 23.75 Torr. (d) The osmotic pressure developed by the resulting polymer solution is readily measured, while the change in partial pressure of H2O(g) changes by less than 0.1% upon addition of the polymer. 19.81 (a) Primary structure is the sequence of amino acids along a protein chain. Secondary structure is the conformation of the protein, or the manner in which the chain is coiled or layered, as a result of interactions between amide and carboxyl groups. Tertiary structure is the shape into which sections of the proteins twist and intertwine, as a result of interactions between side groups of the amino acids in the protein. If the protein consists of several polypeptide units, then the manner in which the units stick together is the quaternary structure. (b) The primary structure is held together by covalent bonds. Intermolecular forces provide the major stabilizing force of the secondary structure. The tertiary structure is maintained by a combination of London forces, hydrogen bonding, and sometimes ion–ion interactions. The same forces are responsible for the quaternary structure. 19.83 (a) ϩ H3NCH2COOH(aq) ϩ H2O(l) : ϩ H3NCH2CO2 Ϫ (aq) ϩ H3Oϩ (aq) ϩ H3NCH2COOϪ (aq) ϩ H2O(l) : H2NCH2COOϪ (aq) ϩ H3Oϩ (aq) (b)pKa1 ϭ 2.35, pKa2 ϭ 9.78; pH ϭ 2, ϩ H3NCH2COOH; pH ϭ 5, ϩ H3NCH2COOϪ ; pH ϭ 12, H2NCH2COOϪ 19.85 Condensation polymerization involves the loss of a small molecule, often water or HCl, when monomers are combined. Dacron is more linear than the polymer obtained from benzene-1,2-dicarboxylic acid and ethylene glycol, so Dacron can be more readily spun into yarn. 19.87 19.89 19.91 (a) NH2 O O O CH3 CH3 CH3 CH3 CH3 CH3 Si Si Si HN O H2N CHϪC CH2 ¥ ¥ ¥ ¥ ¥ ¥ ¥ ¥ CH2 C O OH HN O CHϪC CH2 ¥ ¥ ¥ CH3 CH3 CHϪ OH O CHϪC CH2 ¥ ¥ ¥ ¥ ¥ ¥ ¥ C O OH ¥ ¡ ¢ (b) sp3 . (c) sp2 . (d) Each N atom carries one lone pair of electrons. (e) Yes, the N atoms help to carry the current because the unhybridized p-orbital on each N atom is part of the extended ␲ conjugation (delocalized ␲-bonds) that allows electrons to move freely along the polymer. 19.93 Two peaks are observed with relative overall intensities 3:1. The larger peak is due to the three methyl protons and is split into two lines with equal intensities. The smaller peak is due to the proton on the carbonyl carbon atom and is split into four lines with relative intensities 1:3:3:1. 19.95 The peaks in the spectrum can be assigned on the basis of the intensities and the coupling to other peaks. The hydrogen atoms of the CH3 unit of the ethyl group will have an intensity of 3 and will be split into a triplet by the two protons on the CH2 unit. This peak is found at ␦ Ϸ 1.2. The CH2 unit will have an intensity of 2 and will be split into a quartet by the three protons on the methyl group. This peak is found at ␦ ϭ 4.1. The CH2 group that is part of the butyl function will have an intensity of 2 but will appear as a singlet because there are no protons on adjacent carbon atoms. This is the signal found at ␦ ϭ 2.1. The remaining CH3 groups are equivalent and also will not show coupling. They can be attributed to the signal at ␦ ϭ 1.0. Notice that the peak that is most downfield is the one for the CH2 group attached directly to the electronegative oxygen atom, and that the second most downfield peak is the one attached to the carbonyl group. 19.97 2-chloropropane 19.99 (a) 13 C . (b) 1.11% . (c) No; the reason is that the probability of finding two 13 C nuclei next to each other is very low. A 12 C nucleus next to a 13 C nucleus will not interact with the 13 C nucleus because the 12 C nucleus has no spin. Because the natural abundance of 13 C is 1.11%, the probability of finding two 13 C nuclei next to each other in an organic molecule will be 0.0111 ϫ 0.0111 or 1.23 ϫ 10Ϫ4 . Although such coupling is possible, it is generally not observed because the signal is so much weaker than the signal due to the molecules with a single 13 C nucleus. (d) Maybe; because most of the carbon to which the protons are attached is 12 C, the bulk of the signal will not be split. The protons that are attached to the 13 C atoms will be split, but this amounts to only 1.11% of the sample, so the peaks are very small. Peaks that result from coupling to a small percentage of a magnetically active isotope are referred to as satellites and may be observed if one has a very good spectrum. (e) Yes; although the splitting of protons by 13 C may not be observed because the amount of 13 C present is low, the opposite situation is not true. If a 13 C is attached to H atoms, the large majority of those H atoms will have a spin and so the 13 C will show fine structure due to splitting by the H atoms. 19.101 (a) 1. (b) 1. (c) 1. (d) 2. (e) Free rotation around the CßC and CßCl bonds averages out the environments so that both CH2 hydrogens are equivalent and all three CH3 hydrogens are equivalent, resulting in just two different hydrogen signals. D1 Front Matter pp. i, iii, v, xv, (and all chapter opening pages), Wise Research Group/http://people.ccmr.cornell.edu/~fwise/; p. xv (middle), P. Motta, Department of Anatomy, University “La Sapienza”/Science Photo Library/Photo Researchers; p. xvii (top), Mario Tama/Getty Images; p. xvii (middle), Courtesy of R. L. Kugler & J. C. Pashin; p. xviii, Chip Clark Fundamentals Fig. 1, Erich Lessing/Art Resource; Fig. 2, David Cavagnaro/Peter Arnold; Figs. 3 and 4, Richard Megna/Fundamental Photographs; Fig. 7, Warren Gretz/NREL (National Renewable Energy Laboratory); Figs. A.2, A.5, and B.1, W. H. Freeman photos by Ken Karp; Fig. B.2, Burndy Library; Fig. B.3, Dr. John D. Cunningham/Visuals Unlimited; Fig. B.4, Walter Schmid/Tony Stone/Getty Images; Fig. B.9, Alexander Boden; Figs. B.10, B.11, and C.1, Chip Clark; Fig. C.3, Andrew Syred/Science Photo Library/Photo Researchers; Fig. D.1, W. H. Freeman photo by Ken Karp; Fig. E.2, Chip Clark; Fig. E.3, Burndy Library; Fig. E.5, Chip Clark; Fig. F.1, Kenneth L. Rinehart, University of Illinois at Urbana-Champaign; Fig. G.1, Peter Kresan; Figs. G.2a–b, W. H. Freeman photos by Ken Karp; Fig. G.2c, Kristen Brochmann/Fundamental Photographs; Fig. G.3, Richard Megna/Fundamental Photographs; Fig. G.4, Chip Clark; Fig. G.6, W. H. Freeman photo by Ken Karp; Figs. G.8 and G.9, Richard Menga/Fundamental Photographs; Fig. H.1, Chip Clark; Fig. H.3, Pacific Gas and Electric; Fig. I.1, Richard Megna/Fundamental Photographs; Fig. I.4, Fundamental Photographs; Figs. I.5 and I.6, Richard Megna/Fundamental Photographs; Figs. J.1, Andrew Lambert Photography/Photo Researchers; K.1, W. H. Freeman photo by Ken Karp; Fig. K.2, Chip Clark; Fig. K.5, W. H. Freeman photo by Ken Karp; Fig. K.6, Peticolas/Megna/Fundamental Photographs; Fig. L.1, Pasquale Sorrentino/Photo Researchers; Figs. L.2 and L.3, W. H. Freeman photos by Ken Karp. Chapter 1 Fig. 1.1, Cavendish Laboratory; Fig. 1.4, Prof. Peter Fowler/Photo Researchers; Fig. 1.21, Science Museum, London; Fig. 1.23, Bettman/Corbis; Fig. 1.56, W. H. Freeman photo by Ken Karp; Figs. 1.59, 1.60, 1.61, 1.62, and 1.63, Chip Clark; Box 1.2, INTERFOTO Pressebildagenture/Alamy. Chapter 2 Figs. 2.5d–e, Paul Silverman/Fundamental Photographs; Fig. 2.8, Motta, Department of Anatomy, University “La Sapienza”/Science Photo Library/Photo Researchers; Fig. 2.9, W. H. Freeman photo by Ken Karp; Box 2.1, Breck P. Kent; Fig. 2.10, W. H. Freeman photo by Ken Karp. Chapter 3 Box 3.1, Gary Retherford/Science Source/Photo Researchers; Fig. 3.24, Donald Clegg, Champaign, IL. Chapter 4 Fig. 4.1, Dr. Jeremy Burgess/Science Photo Library/Photo Researchers; Fig. 4.6, NOAA; Figs. 4.15 and 4.16, W. H. Freeman photos by Ken Karp; Fig. 4.17, U.S. Department of the Interior, Bureau of Mines; Fig. 4.18, TRW; Fig. 4.30, W. H. Freeman photo by Ken Karp. Chapter 5 Fig. 5.7, W. H. Freeman photo by Ken Karp; Fig. 5.10, Brenda Tharp/Photo Researchers; Fig. 5.15, Peter Pfletschinger/Peter Arnold; Figs. 5.16 and 5.17, Chip Clark; Fig. 5.17, Chip Clark; Fig. 5.18a, Steven Smale; Fig. 5.18b, W. H. Freeman photo by Ken Karp; Fig. 5.20, Chip Clark; Fig. 5.24, Michael Heron/Woodfin Camp; Fig. 5.42, Andrew Syred/Science Photo Library/Photo Researchers; Box 5.1a, courtesy of Don Eigler, IBM Research Division, Almaden Research Center, San Jose, CA; Box 5.1b, Dr. Ben Oostra/Visuals Unlimited. Major Techniques 3 Fig. 3, adapted from J. P. Glusker and K. N. Trueblood, Crystal Structure Analysis A Primer, Oxford University Press, New York, 1972. Chapter 6 Fig. 6.1b, Sandia National Laboratories/NREL; Fig. 6.2b, Chip Clark; Fig. 6.6, U.S. Steel; Fig. 6.12, Field Museum of Natural History, Chicago; Figs. 6.15 and 6.16, Chip Clark; Fig. 6.17, Philip Hayson/Photo Researchers; Fig. 6.18, Aalborg Portland Betonforskningslaboratorium, Karlslunde; Fig. 6.19, Chip Clark; Fig. 6.21, courtesy of Corning Glass; Fig. 6.22, courtesy of Corning Museum of Glass, Corning, NY; Fig. 6.23, courtesy of R. L. Kugler and J. C. Pashin; Fig. 6.24, courtesy of NASA/JPL/Caltech; Fig. 6.31, Railway Technical Research Institute, Tokyo; Fig. 6.34, courtesy of American Superconductor, Westerborough, MA; Fig. 6.36, W. H. Freeman photo by Ken Karp; Fig. 6.38, S. Odenbach, ZARM, University of Bremen, Germany; Fig. 6.40, courtesy of Professor Mehmet Sarikaya, University of Washington, Seattle, WA; Fig. 6.41, courtesy of MM Industries; Fig. 6.42, courtesy of Evident Technologies, www.evidenttech.com; Fig. 6.43, Richard E. Smalley, Rice University, Center for Nanoscale Science and Technology; Fig. 6.45, courtesy of Anand Nilckar; Fig. 6.46, from M. F. Crommie, C. P. Lutz, and D. M. Eigler, Science 262, 218–220 (1993); Fig. 6.47, Science VU/NASA/ARC/Visuals Unlimited. Chapter 7 Figs. 7.1 and 7.2, Bettmann/Corbis; Figs. 7.8 and 7.9, W. H. Freeman photos by Ken Karp; Fig. 7.24, USGS, Flagstaff, AR; Fig. 7.27, Thiokol Propulsion; Box 7.2a, Warren Gretz/NREL; Box 7.2b, AP Photo/Andy Newman. Chapter 8 Figs. 8.1a–b, 8.2a–b, W. H. Freeman photos by Ken Karp; Fig. 8.6, Dieter Flamm; Box 8.1, courtesy of NIST; Fig. 8.23, New York Public Library; Fig. 8.29, EyeWire Images. Chapter 9 Fig. 9.13, from H. Eugene Stanley, Introduction to Phase Transitions and Critical Phenomena, Oxford University Press, New York, 1971; Fig. 9.16, W. H. Freeman photo by Ken Karp; Fig. 9.19, Chip Clark; Figs. 9.26 and 9.28, W. H. Freeman photos by Ken Karp; Fig. 9.31, Chip Clark; Figs. 9.32a–c, Dennis Kunkel Microscopy; Fig. 9.40, Eyewire; Fig. 9.44, Roger Ressmeyer/Corbis; Fig. 9.46, Tony Hisgett; Fig. 9.47, courtesy of the Royal Institute of Great Britain; Fig. 9.48, European Communities, 1995–2006; Box 9.1, left page (clockwise from left: (1) Patrick Aebischer, (2–4) Sam Ogden), ILLUSTRATION CREDITS D2 ILLUSTRATION CREDITS right page: (top) Patrick Aebischer (bottom) David McCarthy, Electron Microscopy Unit, School of Pharmacy, London. Chapter 10 Fig. 10.2a, Pacific Gas and Electric; Fig. 10.2b, W. H. Freeman photo by Ken Karp; Fig. 10.2c, Richard Megna/Fundamental Photographs; Fig. 10.9, Smithsonian Institution; Fig. 10.14, M. W. Kellogg Company; Fig. 10.15, JPL/NASA; Fig. 10.16, American Institute for Physics, Niels Bohr Library/Stein Collection. Chapter 11 Fig. 11.2, R-R/S/Grant Heilman Photography; Fig. 11.5, Andrew Lambert Photography/Photo Reserachers; Figs. 11.11, 11.14, and 11.19 W. H. Freeman photos by Ken Karp; Box 11.1a, D. Cavagnaro/Visuals Unlimited; Box 11.1b, National Atmospheric Deposition Program/National Trends Network. Chapter 12 Fig. 12.9, Brinkmann Instruments; Fig. 12.10, Chip Clark; Fig. 12.11, Darrell Gulin/Corbis; Fig. 12.16, W. H. Freeman photo by Ken Karp; Fig. 12.18, Chip Clark; Figs. 12.19a–b, Mitchell Bleier/Peter Arnold; Figs. 12.21a–c and 12.22, W. H. Freeman photos by Ken Karp; Box 12.1, Ben Edwards/Tony Stone/Getty Images. Chapter 13 Fig. 13.1, Bettmann/Corbis; Figs. 13.5 and 13.11, W. H. Freeman photos by Ken Karp; Fig. 13.13, Sir R. Hadfield and Messrs. Chapman and Hall, courtesy AIP Emilio Segrè Visual Archives, E. Scott Barr Collection; Fig. 13.16, Comstock; Fig. 13.17, W. H. Freeman photo by Ken Karp; Fig. 13.19, St. Joe Zinc Company/American Hot Dip Galvanizers Association; Fig. 13.23, Takeshi Takahara/Photo Researchers; Box 13.1, Michael Klinec/Alamy. Chapter 14 Fig. 14.1, Betsy R. Strasser/Visuals Unlimited; Fig. 14.2, Woods Hole Oceanographic Institute; Figs. 14.20, 14.22, 14.32, and 14.33, W. H. Freeman photos by Ken Karp; Box 14.3, NASA. Chapter 15 Fig. 15.10 and 15.11a–d, W. H. Freeman photos by Ken Karp; Fig. 15.13a–b, Richard Megna/Fundamental Photographs; Fig. 15.13c, Charles D. Winters/Photo Researchers; Fig. 15.14, Richard Megna/Fundamental Photographs; Fig. 15.15, W. H. Freeman photo by Ken Karp; Fig. 15.16, Texasgulf; Fig. 15.19a–e, W. H. Freeman photos by Ken Karp; Fig. 15.20, Houston Museum of Natural Science; Fig. 15.21, Alexander Boden; Fig. 15.23, L. Linkhart/Visuals Unlimited; Fig. 15.25, Houston Museum of Natural Science; Fig. 15.25b, Lee Boltin; Fig. 15.25c, Houston Museum of Natural Science; Figs. 15.26 and 15.27, Chip Clark; Fig. 15.28, Max Planck/Institute for Kenphysik; Fig. 15.31, W. H. Freeman photo by Ken Karp; Fig. 15.32, Chip Clark; Fig. 15.33, Photo Researchers; Fig. 15.34, Chip Clark; Fig. 15.35, W. H. Freeman photo by Ken Karp; Figs. 15.36, 15.37, and 15.38, Chip Clark; Fig. 15.39, Ross Chapple; Figs. 15.42 and 15.43a, Chip Clark; Fig. 15.43b, National Park Services; Figs. 15.44, Chip Clark; Fig. 15.46, Lee Boltin; Fig. 15.47, W. H. Freeman photo by Ken Karp; Fig, 15.48, Figs. 15.51 and 15.52, Chip Clark; Fig. 15.53, W. H. Freeman photos by Ken Karp; Fig. 15.54, Johnson Space Center/NASA; Fig. 15.56, Greater Pittsburgh Neon/Tom Anthony; Fig. 15.58, Argonne National Laboratory; Box 15.2, F. W. Goro. Chapter 16 Figs. 16.7 and 16.8, W. H. Freeman photos by Ken Karp; Fig. 16.9, Institute of Oceanographic Sciences/NERC/SPL/Photo Researchers; Fig. 16.11, Chip Clark; Fig. 16.13, Paul Chesley/Tony Stone/Getty Images; Fig. 16.14, Lee Boltin Picture Library; Fig. 16.15, Field Museum of Natural History, Chicago; Figs. 16.17 and 16.18, W. H. Freeman photos by Ken Karp; Figs. 16.32 and 16.33, Charles D. Winters; Fig. 16.34, Richard Megna/Fundamental Photographs. Chapter 17 Figs. 17.2 and 17.3, The Granger Collection; Box 17.1 (a) Marcus E. Raichle and Washington University School of Medicine, (b) adapted from “Positron Emission Tomographic Studies of the Cortical Anatomy of Single Word Processing,” by S. E. Peterson, P. T. Fox, M. I. Posner, M. A. Mintum, M. E. Raichle, 1988, Nature, 331:585–589; Box 17.2a, Chip Clark; Box 17.2, Chip Clark; Fig. 17.19, University of Arizona; Fig. 17.26, Tom Carroll/Phototake NYC; Fig. 17.27, Princeton Plasma Physics Laboratory; Fig. 17.28, Chip Clark; Fig. 17.29, Phil Schofield; Fig. 17.30, U.S. Department of Energy. Chapter 18 Fig. 18.12, W. H. Freeman photo by Ken Karp; Fig. 18.15, David Menuez/Photodisc. Chapter 19 Figs. 19.3, W. H. Freeman photos by Ken Karp; Fig. 19.7, Dena Digilio Betz; Fig. 19.8, W. H. Freeman photo by Ken Karp; Fig. 19.10, Fibers Division, Monsanto Chemical Company; Fig. 19.11, Andrew Syred/Science Photo Library/Photo Researchers; Fig. 19.12, Chip Clark; Fig. 19.15, W. H. Freeman photo by Ken Karp; Fig. 19.16, Mario Tama/Getty Images; Fig. 19.17, Steven Gottlieb/FPG International/Getty Images; Box 19.1, James Kilkelly; Fig. 19.19, A. Marmont and E. Damasio, Division of Hematology, S. Martin’s Hospital, Genoa, Italy; Fig. 19.23, Tom Bean/Tony Stone/Getty Images; Fig. 19.24, John P. O’Brien, DuPont; Fig. 19.27b, Institute of Paper Chemistry; Fig. 19.28, Photo Researchers. Major Technique 7 Fig. 2, Owen Franken/Tony Stone/Getty Images. ab initio methods, 610 absolute temperature, 139, 140 absolute zero, 304 absorbed dose, 716 absorption spectrum, 7 acceleration, F10 acceleration of free fall, F11 accuracy, F9 acetate ion, 443 acetic acid, 436, 443, F35 acetic acid dimer, 179 acetone, F66 acetylene, 111 acetylide, 639 acetylsalicylic acid, 509, 736 achiral, 688, 742 acid, 423, F2, F72 Brønsted, 424, F73 conjugate, 425 Lewis, 426, 681 polyprotic, 454, 455, 458 strong, 424 weak, 424 acid anhydride, 614, 615 acid-base indicator, 492 acid-base titration, F89 acid buffer, 477 acid dissociation constant, 436 acid ionization constant, 436 acid rain, 212, 462 acid strength, 440 bond strength and, 440 electronegativity and, 441, 442 molecular structure and, 444 oxidation state and, 671 oxygen atoms and, 442 acidic hydrogen atom, 424, F73 acidic oxide, 428 acidity constant, 436 acidosis, 484 Acrilan, 770 acrylonitrile, 770 actinide, 668, F19 actinoid, 48, 668, F19 activated carbon, 635 activated charcoal, 635 activated complex, 594 activated complex theory, 594 activation energy, 588 activity, 387 of radioactive sample, 717 activity (radioactive), 716 addition polymerization, 770 addition reaction, 746 adenine, 783 adenosine diphosphate (ADP), 81, 325 adenosine triphosphate (ATP), 81, 325, 647 adhesion, 181 ADP, 325. See Adenosine diphosphate (ADP) adsorb, F53 aerogel, 218 aerosol, 370 AFM (atomic force microscopy), 183 agate, 638 aging, 72 air composition of, 146 density, 145 air bag, 148, 169 air pollution, 462 alanine, 778 albumin, 179, 781 alcohol, F35 nomenclature, 769 aldehyde, 764 nomenclature, 769 aliphatic hydrocarbon, 735 alkali metal, 47, 619, F19 alkaline cell, 550, 551 alkaline earth metal, 623, F19 alkalosis, 484 alkane, 737, F35 nomenclature, 739, F35 properties, 743 substitution reaction, 744 alkene, 738, F35 properties, 745 alkylation, 751 alkyne, 112, 738 allotrope, 185 alloy, 48, 205 coinage, 207, 210 heterogeneous, 207 homogeneous, 207 interstitial, 208 nonferrous, 209 substitutional, 208 alnico, 210, 676 alpha helix, 780 alpha particle, 3, 706 alternating copolymer, 775 alternative fuels, 268 alum, 631, 650 alumina, 630 aluminosilicate, 213 aluminosilicate ceramics, 217 aluminum chloride, 76, 632 aluminum oxide, 218, 630 Alzheimer’s disease, 780 ambidentate ligand, 687 amethyst, 638 amide, 768 amine, 767 nomenclature, 769 amino acid, 767 essential, 777 amino group, 767 ammonia, 99, 108, 384, 642 autoprotolysis, 642 decomposition, 568 formation, 413 production, 597 Ammonians, 642 ammoniate, 643 amorphous silicon, 637 amorphous solid, 182 amount of substance, F38 concentration and, F54 ampere, A3 amphiprotic, 429 amphiprotic salt, 456 pH, 456 amphoteric, 429 amplitude, 4, 13 amylopectin, 782 amylose, 781 anaerobic, 269, 752 analysis, F22 analyte, 483, F89 analytical chemistry, F4 analytical concentration, 445 Anderson, J., 599 androgenic chemical, 598 anemia, 681, 734, 779 angular shape, 95 angular wavefunction, 24 anhydride, 615 anhydrous, 173, F31 aniline, 470 anion, F22 acid/base characteristics, 451 common, F30 nomenclature, F29 anisotropic, 194 anode, 523 sacrificial, 549 anodized aluminum, 629 anoxia, 414 anthracene, 748 antibonding orbital, 115 anticyclone, 137 antiferromagnetic material, 224 antimony, 640 antioxidant, 72 antiparticle, 707 apatite, 641 approximation method, 401 aqua regia, 679 aqueous solution, F32, F53 aragonite, 212 arene, 748 arginine, 778 argon, 659 argon configuration, 35 aromatic compound, F35 aromatic hydrocarbon, 735, 748 aromatization, 752 Arrhenius, S., 587, F73 Arrhenius acid and base, F73 Arrhenius behavior, 589 Arrhenius equation, 587 Arrhenius parameters, 588 arsenic, 601, 640 arthropod blood, 678 artificial bone, 225 aryl group, 748 asbestos, 213 asparagine, 778 aspartame, 779, F65 aspartic acid, 778 asphalt, 751 aspirin, 509, 736 astatine, 655 -ate suffix, F30 atmosphere (Earth), 133 atmosphere (unit), 137 atom, F15 electronic structure, 1 nuclear model of, 2, 3 atom economy, 790 atomic force microscopy (AFM), 183 atomic hypothesis, F16 atomic mass constant, 722 atomic nucleus, 705 atomic number, F16 atomic number (Z), 3 atomic orbital, 23 atomic radius, 39 periodicity, 612 atomic spectroscopy, 3 atomic spectrum, 6 atomic weight, F42 ATP (adenosine triphosphate), 81, 325, 647 Auger electron spectrometer, F4 autoionization constant, 430 automobile battery, 550, 551 autoprotolysis, 429 effect on pH, 464 autoprotolysis constant, 430 average bond dissociation energy, 80 average reaction rate, 562 average speed, 561 of gas molecules, 153 temperature and, 140 INDEX E1 Note: A and F preceding page numbers indicate Appendices and the Fundamentals section, respectively. E2 INDEX Avogadro, A., 138, F38 Avogadro’s constant, F38 Avogadro’s number, F37, F38 Avogadro’s principle, 38, 140 axial lone pair, 100 azeotrope, 369 azide, 643 azimuth, 24 azote, 641 azoxyanisole, 194, 195 background radiation, 716 Bacon, F., 552 baking powder, 623 baking soda, 623 balanced equation, F61 ball-and-stick model, F24 Balmer, J., 6 Balmer series, 7 band gap, 220 band of stability, 711 bar, 136 barium, 624, 625 barium titanate, 672 barometer, 135 base, 423, F72 Brønsted, 424, F73 conjugate, 425 Lewis, 426, 680 polyprotic, 454 as a proton acceptor, F73 base ionization constant, 437 base pairing, 783 basic buffer, 477 basic oxide, 428 basic oxygen process, 209 basicity constant, 437 battery, 522, 550 bauxite, 629 Bayer process, 629 bcc (body-centered cubic) structure, 188 becquerel, 717 Becquerel, H., 706 beef fat, 766 Belousov-Zhabotinskii reaction, 636 benzaldehyde, 765 benzene, 69, 111, 185, 336, 748, F35 molecular orbitals, 122 vapor pressure, 336 benzeneberg, 185 benzyl alcohol, 764 beryl, 624 beryllate ion, 626 beryllium, 624, 625 beryllium chloride, 95, 626 beryllium configuration, 34 beryllium hydride, 626 beta particle, 706 beta sheet, 780 bi- prefix, F30 bicarbonate of soda, 623 bidentate ligand, 684 bimolecular reaction, 580 binary acid, 440 binary compound, F22 binary ionic compound, F26, F27 binary liquid mixture, 365 binding energy, 722 bio-based material, 371 biochemistry, F4 biodiesel, 269 biodiversity, 462 bioenergetics, 235, 325 biofuel cell, 553 biological chemistry, F4 bioluminescence, 223 biomass, 268 biomimetic material, 371 bipolar disorder, 622 bipyramidal, 95, 96 bipyridine, 701 biradical, 72 bismuth, 640 bismuth-cadmium alloy, 210 black body, 8 black-body radiation, 8 blast furnace, 209, 675 bleach, hair, 651 blister copper, 677 block, 37, F19 block copolymer, 775 blood, buffer, 484 body armor, 774, 776 body-centered cubic (bcc) structure, 188 Bohr, N., 24 Bohr atom, 24 Bohr frequency condition, 13, 130 Bohr radius, 24 boiling, 338 boiling point, 338 alkanes, 743 anomalous, 178 boiling point elevation, 358 boiling point prediction, 174 boiling point trends, 177 boiling temperature, 295 Boltzmann, L., 298 Boltzmann distribution, 592 Boltzmann formula, 298 bomb calorimeter, 245 bond, 55 hydrogen, 178 pi, 106 sigma, 105 stiffness, 90 three-center, 633 bond angle, 95 and hybridization, 126 bond enthalpy, 276 bond length, 81 determination of, 83 bond order, 64, 118 bond strength, 79 acid strength and, 440 bonding in hydrocarbons, 111 periodic trends, 613 in solid state, 218 bonding orbital, 115 bone, 63 artificial, 225 borane, 632 borax, 628 borazine, 127 Borazon, 215 boric acid, 630 boride, 215 Born, M., 17 Born-Haber cycle, 274 Born interpretation, 18 Born-Meyer equation, 62 borohydride, 632 boron, 47, 628, 630 boron configuration, 34 boron neutron capture therapy, 714 boron nitride, 215 boron trifluoride, 76, 95, 102 borosilicate glass, 216 Bosch, C., 383, 413 bottom-up approach, in nanotechnology, 228 boundary condition, 20 boundary surface, 28, 29 box diagram, 33 Boyle, R., 138 Boyle’s law, 138 Bragg equation, 201 branches of chemistry, F4 branching, 585 Bravais lattice, 188 breathing, 414 breeder reactor, 726 brittleness, 59 bromination, 747 bromine, 655, F15 Brønsted, J., 424, F73 Brønsted acid, 424, F73 Brønsted base, 424, F73 Brønsted definition, 424 Brønsted-Lowry definition, F73 Brønsted-Lowry theory, 42 bronze, 210 Bronze Age, 210, 671 Brownian motion, 371 Buckminster Fuller, R., 635 buckminsterfullerene, 201, 227, 635 buffer, 476 acid, 477 basic, 477 physiological, 484 buffer capacity, 482 buffer system, 480 building-up principle, 34 bulk matter, 134 bullet-proof vest, 774, 776 buret, F56 butane, 737 cadmium, 679, F15 cadmium-bismuth alloy, 210 caffeine, 128, 787 calchocite, 677 calcite, 212, 624 calcium, 35, 624 calcium carbonate, 211, 627 calcium hypochlorite, 658 calcium phosphate, 63 calculus, A8 calibration, 245 calomel, 541 calomel electrode, 541 calorie, 243, A4 calorimeter, 245 camphor, 787 candela, A3 capillary action, 181 caramel, 184 carat, 679 carbide, 215, 639 carbohydrate, 781 carbon, 48, 633 phase diagram, 374 tetravalent, 64 carbon-14 dating, 719 carbon black, 634 carbon-carbon multiple bonds, 80, 111 carbon configuration, 34 carbon dioxide, 96, 102, 637 dissolved in water, 351 phase diagram, 340 supercritical, 343, 381 vibrations, 91 carbon monoxide, 107, 638 residual entropy, 300 carbon nanotube, 227, 635 carbon tetrachloride, 639 carbonate ion, 96, F26 carbonic acid, 637 carbonyl, 687 carbonyl group, 765 carborundum, 215 carboxyl group, 765, F35, F73 carboxylic acid, 765, F35 strength, 443 carnallite, 623 Carnot, S., 235, 236 carotene, 124 carrier, 725 carvone, 737 cassiterite, 637 cast iron, 208 catalyst, 48, 413, 595, F61 heterogeneous, 597 homogeneous, 596 industrial, 597 microporous, 598 poisoned, 599 catalytic converter, 462, 597 catenation, 649 cathode, 523 cathode ray, 2 cathodic protection, 549 cation, F22 nomenclature, A34 cation acidity, 450 cation hydration, 450 cationic electrodeposition, 549 ccp (cubic close-packed) structure, 186 cell diagram, 526 cell reaction and, 528 cell liquor, 623 INDEX E3 cell potential, 524 cellulose, 782 cement, 214 ceramics, 186, 217 in composite, 225 cesium, 620 cesium chloride density, 193 structure, 192 CFCs (chlorofluorocarbons), 598 chain branching, 585 chain carrier, 585 chain reaction, 585 chalcogen, 648 chalcopyrite, 677 chalk, 212, 624 characteristic (of logarithm), A6 charge balance, 464 charge number, 60 charge supplied, 545 charge-transfer transition, 131, 697 Charles, J., 138, 139 Charles’s law, 139 chelate, 686 chemical bond, 55 chemical change, F60 chemical energy, F13 chemical engineering, F4 chemical equation, F61 chemical equilibrium, 314, 383 chemical formula, F23 chemical kinetics, 531 chemical nomenclature, F29 chemical property, F6 chemical reaction, F60 chemical shift, 791 chemically equivalent, F85 chemiluminescence, 223, 641 chemistry branches of, F4 green, F4 china clay, 217 chiral complex, 688 chiral molecule, 742 chloralkali process, 547, 622 chlorate, 658 chlorination, 745 chlorine, 655 chlorine dioxide, 658 chloroaniline, 470 chlorobutane, F23 chlorofluorocarbons (CFCs), 598 chloromethane, 762, F36 chlorophyll, 626 cholesteric phase, 194 CHP system, 552 chromate ion, 673 chromatogram, 382, F55 chromatography, 381, F53 chrome recording tape, 673 chromic acid, 671 chromite, 673 chromium, 48, 673 chromophore, 130 cinnabar, 649 cinnamaldehyde, 765 cis-platin, 704 citral, F50 citric acid, 380 classical mechanics, 1 clathrate, 652 Claus process, 650 Clausius-Clapeyron equation, 337 Clausius inequality, 311 clay, 214 ceramic, 217 Cleopatra’s needle, 504 clinker, 214 close-packed structure, 186 closed shell, 33 closed system, 236 coagulation, 650 coal, 752 coal gas, 753 coal tar, 753 coalification, 753 cobalamin, 681 cobalt, 48, 676, 681 Codex Ebers, 146 coenzyme Q, 73 cohesion, 181 coinage alloy, 207, 210 coinage metal, 676 coke, 634 colatitude, 24 collagen, 225, 681 colligative properties, 352 collision cross section, 591 collision theory, 591 colloid, 370, 650 color, 4, 5 color wheel, 696 column chromatography, 381 combined gas law, 141 combustion, 267 combustion analysis, F100 commercial batteries, 550, 551 common antilogarithm, A7 common-ion effect, 500 common logarithm, A6 common name, A34, F29, F32 competing reaction, F95 complementarity, 15 complementary color, 696 complete ionic equation, F67 complex, 679 complex formation, and solubility, 505 complex ion formation, 505 complex nomenclature, 683 composite material, 225 compound, F22 compressible gas, 134 compression, 134 effect on equilibrium, 408 compression factor, 159 computational chemistry, 610, F4 concentration analytical, 445 formal, 445 initial, 445 concentration cell, 540 concrete, 215 condensation polymer, 772 condensation reaction, 647, 766 condensed phase, 172 condensed structural formula, 736 condenser, F54 conducting polymer, 778 conduction electronic, 218 ionic, 218 conduction band, 220 configuration complex, 680 congener, 611 conjugate acid, 425 conjugate acid-base pairs, 439 conjugate base, 425 conjugate seesaw, 438 conjugated double bonds, 122 conservation of energy, 247 conservation of mass, F61 constant acid dissociation, 436 acid ionization, 436 acidity, 436 atomic mass, 722 autoionization, 430 autoprotolysis, 430 base ionization, 437 basicity, 437 decay, 718 equilibrium, 386, 389, 536 Faraday’s, 524 force, 90 formation, 505 freezing-point, 359 gas, 141 ion product, 430 Madelung, 61 Michaelis, 600 Planck’s, 10 rate, 566 Rydberg, 7, 23 solubility, 497 solubility product, 497 constant composition, law of, F3, F22 constructive interference, 13, 115, 203 controlled-release drug delivery, 371, 372 conversion factor, A5, F7 Cooper pair, 221 coordinate, 682 coordinate-covalent bond, 76, 679 coordination complex, 505 coordination compound, 680 nomenclature, 673 coordination number (complex), 682 coordination number (ionic), 192 coordination number (metal), 186 coordination sphere, 682 copolymer, 775 copper, 48, 677, F15 displacement by zinc, F81 refining, 544, 678 copper-zinc alloy, 207 core, 34 core electrons, 43 Cornell, E., 305 corrosion, 548 corrosive, 434 corundum, 218 coulomb, 524, A4 Coulomb interaction, 172 Coulomb potential energy, 22, F12 covalent bond, 55, 63 covalent carbide, 215, 639 covalent radius, 39, 82 cracking, 751 Creutzfeld-Jakob disease, 780 cristobalite, 212, 213 critical mass, 726 critical point, 343 critical pressure, 343 critical temperature, 343 crown ether, 764 Crutzen, P., 598 cryogenics, 659 cryolite, 629, 654 cryoscopy, 360 crystal, 182 crystal face, 182 crystal field theory, 691, 698 crystalline solid, 55, 182 crystallization, F52 cubic close-packed (ccp) structure, 186 cubic equation, A7 cupronickel, 676 curie, 717 Curie, M., 624, 706 Curie, P., 624, 706 current, electric, 218 cyanide ion, 639 cycles, 4 cycloalkane, 737 nomenclature, 739 cyclohexane, 737 cyclone, 137 cyclopropane, 574, 737 cysteine, 778 cytosine, 469, 783 d block, F19 d-d transition, 697 d-metal, 668 d-metal complex, nomenclature, 673 d-orbital, 25, 29, 47 d-to-d transition, 131 Dacron, 772 Dalton, J., 149, F3, F15, F16 Dalton’s law of partial pressures, 149 Daniell, J., 523 Daniell cell, 523 data, F2 daughter nucleus, 708 Davisson, C., 14 E4 INDEX Davy, H., 624 de Broglie, L., 14 de Broglie relation, 14 debye, 77 Debye, P., 77 decane, 737 decanting, F53 decay constant, 718 definite integral, A9 degenerate, 26 dehydrohalogenation, 745 delocalization, 68 delocalized electron, 115 delta scale, 791 denaturation, 781 density, F7, F8 air, 145 ionic solid, 193 structure and, 190 density functional theory, 610 density isosurface, F24 deoxyribonucleic acid (DNA), 783 deoxyribose, 783 deprotonation, 424, F74 percentage, 445 derived unit, A4, F7 destructive distillation, 753 destructive interference, 13, 115, 203 detergent, 346 detonator, 148 deuterium, 727, F18 diagonal relationship, 46 diamagnetic, 113, 697 diamond, 185, 211, 635 diaphragm cell, 623 diatomic, F26 diatomic molecule, F23 electron configurations, 116 diborane, 632 dichlorobenzene, 69, 174, 175 dichloroethene, 102, 175 dichromate ion, 673 diethyl ether, 763 differential calculus, A8 differential equation, 19 differential thermal analysis (DTA), 260 diffraction, 13, 203 diffusion, 152 digestion, 269 dilution, F57 dimer, 76, 179 dimethyl ether, 335 dimethylamine, 767 dimethylpropane, 176 dinitrogen oxide, 644 dinitrogen pentoxide, 566 dinitrogen tetroxide, 645 dinitrogen trioxide, 641, 645 dipeptide, 777 dipole-dipole interaction, 174 dipole moment, 77, 101 instantaneous, 175 dipole–induced-dipole interaction, 176 direction of reaction, 396 disorder, 288, 301 dispersion interaction, 176 dissociated acid, F74 dissociation, 79 dissociation energy, 77, 79 dissolving precipitate, 504 distillate, 367 distillation, 367, F54 disulfide link, 780 DNA, 783 x-ray pattern, 204 Dobson unit (DU), 599 dodecahedral complex, 685 dolomite, 624 domain, 224 doping, 220 dose equivalent, 716 dosimeter, 717 double bond, 64, 106 characteristics of, 111 conjugated, 122 Dow process, 543 Downs process, 547, 620 drinking water purification, 650 driven reactions, 325 drug delivery, 372 drug design, 94 drug discovery, 94 dry cell, 550, 551 dry cleaning, 337 DTA (differential thermal analysis), 260 DU (Dobson unit), 599 duality, 14 ductility, 206, F20 duplet, 56 dynamic equilibrium, 314, 333, 384 dynamic self-assembly, 636 dynamite, 643 earths, 623 ebonite, 777 edta, 686 effect common-ion, 500 greenhouse, 637 inert-pair, 46 Joule-Thomson, 160 photoelectric, 10 effective mass, 90 effective nuclear charge, 32, 39 effusion, 152, 728 eg-orbital, 691 egg, cooking, 179 Einstein, A., 10, 722 eka-silicon, 38 elastomer, 777 electric conductivity, 219 electric current, 218 electric dipole, 77 electric dipole moment, 77 electric field, F12 electrical work, 525 electro-osmotic drag, 552 electrochemical cell, 522 electrochemical series, 534 electrochemistry, 515 electrode, 523 calomel, 541 glass, 542 ion-selective, 541 standard hydrogen, 530 electrode compartment, 524 electroluminescence, 779 electrolysis, 542 Faraday’s law of, 544 predicting result of, 545 electrolyte, 523, F65 solid, 219 electrolyte solution, F66 electrolytic cell, 542 electromagnetic field, F12 electromagnetic radiation, 3 electromagnetic spectrum, 6 electromotive force (emf), 525 electron, 2, F16 delocalized, 115 wavelike character, 14 electron affinity, 44, 77 periodicity, 613 electron arrangement, 95 electron capture, 709 electron cloud, 26 electron configuration, 33, 118 diatomic molecule, 116 electron-deficient compound, 113 electron density, 610 electron diffraction, 14 electron-gain enthalpy, 44 electron pair, shared, 63 electron paramagnetic resonance, 31 electron promotion, 107 electron sea, 44 electron spin, 30 electron transport, 48 electronegativity, 77 acid strength, 441, 442 periodicity, 613 electronic conduction, 218 electronic structure, 1, 35 electronvolt, A4 electrophile, 747 electrophilic substitution, 749 electroplating, 547 electrostatic forces of attraction, F10 electrostatic potential surface, 610, F24 electrostatic units, 53 element, F16 properties, A22 radioactive, 708 relative abundance, 612 elementary charge, 2 elementary reaction, 580 elimination reaction, 745 elpot diagram, 97, 102 elpot surface, 610, F24 elution, 381 emerald, 624, 625 emery, 218 emf (electromotive force), 525 empirical formula, F45, F47 emulsion, 370 enamel, tooth, 627 enantiomer, 688, 742 end point, 493 endothermic process, 243 energy, 237, F10 energy dispersion, 288 energy level, 20 energy quantization, 20 enrichment, 728 ensemble, 298 enthalpy, 252 internal energy and, 263 proton transfer, 440 reaction, 261 specific, 267 standard combustion, 267 temperature and, 323 enthalpy density, 269 enthalpy of formation, 271 enthalpy of freezing, 258 enthalpy of fusion, 258 enthalpy of hydration, 349 enthalpy of mixing, 368 enthalpy of solution, 349 enthalpy of sublimation, 259 enthalpy of vaporization, 257 entropy, 288 Gibb free energy and, 315 heat capacity and, 303 measurement, 303 molecular interpretation, 301 overall change, 310 residual, 300 system heating and, 291 temperature and, 323 entropy change compression, 294 irreversible expansion, 293 isothermal expansion, 293 of surroundings, 308 temperature/volume variation, 294 entropy of fusion, 297 entropy of phase change, 297 entropy of vaporization, 296 Environmental Protection Agency (EPA), 434 enzyme, 94, 600 EPR (electronic paramagnetic resonance), 31 Epsom salts, 626, F44 equation Boltzmann, 298 Born-Meyer, 62 Bragg, 203 chemical, F61 Clausius-Clapeyron, 337 differential, 19 Henderson-Hasselbalch, 481 Nernst, 538 nuclear, 708 Schrödinger, 17 thermochemical, 261 van der Waals, 161, 169 van ’t Hoff, 362, 411 virial, 161 INDEX E5 equation of state, 141 real gas, 161 equatorial lone pair, 100 equilibrium, 314, 333 chemical, 383 dynamic, 384 effect of compression, 408 effect of temperature, 410 Gibbs free energy, 390 heterogeneous, 388 homogeneous, 388 response to conditions, 405 equilibrium composition, 395 equilibrium constant, 384, 386, 389 from electrochemical data, 536 relation between, 400 standard Gibbs free energy of reaction, 394 standard potential, 536 in terms of concentration, 398 in terms of rate constants, 586 equilibrium table, 401, 402 equipartition theorem, 251, 255 equivalence point, F89 essential amino acid, 777, 778 essential oil, 764 ester, 766 esterification, 766 estradiol, 788 etched glass, 216, 657 ethane, 108, F35 ethanediol, 763 ethanol, 443, 762, 763, F24, F35 as fuel, 268 vapor pressure, 336 ethene, 97, 111, 738 ether, 763 ethoxide ion, 764 ethyl acetate, 766 ethyl alcohol, 762 ethylene, 111 ethylene glycol, 763 ethylenediamine, 686 ethylenediaminetetraacetic acid, 686 ethyne, 97, 111, 738 eugenol, 764 eutectic mixture, 210 evaporation pool, 622 excited state, 35 exclusion principle, 33, 36, 37, 185 exothermic process, 243 expanded octet, 72 expanded valence shell, 72 expansion against constant pressure, 239 expansion work, 237 experiment, F3 Geiger-Marsden, 3 oil-drop, 2 Stern-Gerlach, 31 Young’s slit, 203 experimental data, A11 explosion, 148 exponent, A6 exponential, A6, A7 exponential decay, 573 extensive property, F8 extent of reaction, 395 extrapolate, A7 extrinsic semiconductor, 220 f-block, 37, 39 f-orbital, 25, 29 face-centered cubic (fcc) structure, 188 fallout, 719 Faraday, M., 544 Faraday’s constant, 524 Faraday’s law of electrolysis, 544 fcc (face-centered cubic) structure, 188 feldspar, 213 femtochemistry, 564 fermentation, 268 ferrimagnetic material, 224 ferroalloy, 209, 672 ferrocene, 685 ferrofluid, 224 ferromagnetism, 114, 224 ferrous alloy, 205 Feynman, R., 229 field, 4 filtration, F53 fine structure, 792 fingerprint region, 91 fireflies, 589 first derivative, A8 first ionization energy, 42 first law of thermodynamics, 247 first-order integrated rate law, 573 first-order reaction, 568 fissile nucleus, 725 fission, 705, 724 fissionable nucleus, 725 flame front, 586 flint, 638 flocculation, 650 fluorapatite, 627, 654 fluorescein, 223 fluorescence, 223 fluorine, 119, 654 configuration, 35 fluorochlorocarbon, 657 fluorspar, 654 flux, 630 foam, 370 foot, A4 force, F9 force constant, 90 formal anhydride, 615 formal charge, 70 formal concentration, 445 formaldehyde, 765, F46 formalin, 765 formate ion, 487 formation constant, 505 formic acid, 112, 486, F35 formula unit, F27 formula weight, F42 fossil fuel, 615, 752 four-circle diffractometer, 204 Fourier synthesis, 204 fraction, 368 fractional composition, 461, 767 fractional distillation, 367 fractional occupation, 187 fragmentation, 758 Franklin, R., 204 Frasch process, 649 free energy, 315. See also Gibbs free energy free expansion, 239 free radical, 72 freezing, 258 freezing-point constant, 359 freezing-point depression, 358 freezing temperature, 339 freon, F96 frequency, 4, 5 froth flotation, 677 fructose, 781 fuel, 268 fuel cell, 550, F86 fullerene, 635 fullerite, 635 functional group, 759 functionalization, 744 fundamental charge, 2, F12 fusion, 258, 705, 726 GABA, 767 galena, 637, 649 Galileo, 135 gallium, 630 gallon, A4 Galvani, L., 515 galvanic cell, 522 galvanize, 549 gama grass, 462 gamma radiation, 707 gangue, 677 gas, F5 compressible, 134 kinetic model of, 153 real, 159 gas chromatograph–mass spectrometer (GC-MS), 382 gas constant, 141 gas density, 145 gas expansion, 239 gas laws, 138 gas liquefaction, 160 gas-liquid partition chromatography (GLPC), 382 gas-solid adsorption chromatography, 382 gas solubility, 347 gasoline, 268, 368, 751 gauge pressure, 134 Gay-Lussac, J.-L., 138, 139 GC-MS (gas chromatograph–mass spectrometer), 382 Geiger, H., 3 Geiger counter, 717 Geiger-Marsden experiment, 3 gel, 370 silica, 638 smart, 636 gelatin, 370 gene pool, 462 geometrical isomer, 688, 740 Gerlach, W., 31 germanium, 38, 48, 633, 637 Germer, L., 14 germide, 129 Gibbs, J. W., 315 Gibbs free energy, 315 criterion for equilibrium and, 316 equilibrium and, 390 ideal gas, 336 and nonexpansion work, 321 pressure dependence, 335, 336 of reaction, 318, 390 cell potential and, 524 variation with composition, 391 of solution, 351 variation with concentration, 391 variation with pressure, 390 variation with temperature, 358 Gillespie, R., 95 gingko biloba, 73 glass, 182, 216 etched, 216, 657 stained, 370 glass electrode, 542 GLPC (gas-liquid partition chromatography), 382 glucose, 781, F46 glutamic acid, 778 glutamine, 778 glycine, 767, 778 gold, 679 gold colloid, 370 gold leaf, F20 Goudsmit, S., 30 Gouy balance, 114 graft copolymer, 775 Graham, T., 152 Graham’s law, 152, 728 grain alcohol, 762 granite, 213, F52 graphene, 211 graphite, 185, 210, 635 graphite bisulfate, 201 gravimetric analysis, F69 gray, 716, A4 green chemistry, F4 ground state, 23 ground-state electron configuration, 35, A20 group, 35, F19 group number, 38 Grove, W., Sir, 552 guanine, 783 Guldberg, C., 385 E6 INDEX gutta-percha, 771, 772 gypsum, 214 Haber, F., 383, 413 Haber process, 597 Hahn, O., 724 hair bleach, 651 half-cell, 524 half-life (chemical), 576 half-life (radioactive), 719 half-reaction, 516 halide, nomenclature, 763 Hall, C., 629 Hall process, 629 haloalkane, 745, 762, F35 nomenclature, 763 halogen, 654, F19 physical property trends, 176 halogenation, 746 hamiltonian, 18 hard matter, 205 hard water, 351 harpoon mechanism, 593 Hazard! road sign, F63 hcp (hexagonal close-packed) structure, 186 head group, 346 heat, 243 heat capacity, 244 constant pressure, 252 constant volume, 252 constant volume/ pressure, 254 entropy and, 303 molecular origin, 255 variation with temperature, 255 heat transfer at constant pressure, 252 at constant volume, 252 heating curve, 259 Heisenberg, W., 15 Heisenberg uncertainty principle, 15 Heitler, H., 105 helium, 659 phase diagram, 374, 659 helium-II, 659 hematite, 674 hemoglobin, 414, 681, 778 Henderson-Hasselbalch equation, 481 Henry, W., 347 Henry’s constant, 347 Henry’s law, 347 hertz, 4, A4 Hess’s law, 265 heterogeneous alloy, 207 heterogeneous catalyst, 597 heterogeneous equilibria, 388 heterogeneous mixture, F52 heteronuclear diatomic molecule, 120 hexacyanoferrate ion, 682 hexadentate ligand, 684 hexagonal close-packed (hcp) structure, 186 hierarchy of materials, F53 high-impact polystyrene, 775 high-performance liquid chromatography (HPLC), 381 high-spin complex, 696 high-temperature superconductor, 222 highest occupied molecular orbital (HOMO), 123 highly radioactive fission products, 728 Hiroshima, 726 histidine, 778 hole, 187 homeostasis, 413 HOMO (highest occupied molecular orbital), 123 homogeneous alloy, 207 homogeneous catalyst, 596 homogeneous equilibria, 388 homogeneous mixture, F52 homolytic dissociation, 79 homonuclear diatomic molecule, 101 Hooke’s law, 90 hormone, 681 horsepower, A4 hour, A4 HPLC (high-performance liquid chromatography), 381 HRF products, 728 Humphreys series, 50 Hund, F., 35 Hund’s rule, 35, 36, 37 Hurricane Katrina, 137 hyaluronic acid, 370, 371 hybrid orbital, 107 hybridization bond angle, 126 molecular shape and, 109 hydrangea color, 494 hydrate, F31 hydrate isomer, 687 hydration, 173 hydrazine, 643 hydride, 613 hydride ion, 618 hydrocarbon, 735, F35 bonding in, 111 hydrogen, 615 hydrogen atom allowed energy levels, 22 spectrum, 6 structure, 21, 30 wavefunctions, 24 hydrogen bond, 178, 619 hydrogen bromide, 585 hydrogen chloride, 657 hydrogen electrode, 524 hydrogen fluoride, 105, 120, 179, 657 hydrogen halide, 656 hydrogen-oxygen cell, 552, F86 hydrogen peroxide, 651 decomposition, 596 hydrogen sulfide, 652 hydrogenperoxyl radical, 72 hydrolysis reaction, 644, 762 hydrometallurgy, 677 hydronium ion, 424, F73 hydrophilic, 346 hydrophobic, 346 hydrostatic pressure, 135 hydrosulfuric acid, 652 hydroxy group, 762 hydroxyaniline, 470 hydroxyapatite, 627 hygroscopic, 775 hypervalent compound, 72 hyperventilation, 484 hypo, photographer’s, F65 hypo- prefix, F30 hypochloric acid, 657 hypochlorous acid, 657 hypohalite, 657 hypohalous acid, 657 hypothesis, F3 -ic suffix, F33 ice residual entropy, 300 structure, 184, 185, 339 -ide suffix, F29 ideal gas, 141 Gibbs free energy, 336 molar volume, 144 ideal gas law, 141 ideal solution, 357 ilmenite, 672 iminodisuccinate ion, 686 implant, 372 incandescence, 8, 223 inch, A4 incomplete octet, 75 indefinite integral, A9 indicator color changes, 493 induced-fit mechanism, 600 induced nuclear fission, 725 industrial catalyst, 597 industrial chemical, A32 inert compound, 320 inert-pair effect, 46 infrared radiation, 4, 6, 90 infrared spectroscopy, 90 initial concentration, 445 initial rate, 566 initiation, 585 inner transition metal, 668, F19 inorganic chemistry, F4 inorganic compound, F22 inorganic molecular compounds, nomenclature, F33 inorganic substance, thermodynamic data, A11 insoluble substance, F65 instantaneous dipole moment, 175 instantaneous rate, 565 instantaneous speed, 561 insulator, 219 integral, A9 integral calculus, A9 integrated rate law, 572 first-order, 573 second-order, 578 intensity, 4 transition, 53 intensive property, F8 intercept, A8 interference, 13, 115, 203 interhalogen, 656 intermediate, 580 intermolecular forces, 159, 171 origin of, 172 internal energy, 237 heat transfer at constant volume, 252 molecular origin, 251 state function, 247 interpolate, A7 interstice, 208 interstitial alloy, 208 interstitial carbide, 638 intrinsic semiconductor, 220 iodine, 655, F16 ion, F22, F24 ion-dipole interaction, 173 ion formation, 56 pattern of, F25 ion hydration, 173 ion-ion interaction, 59 ion pair, F27 ion product constant, 430 ion-selective electrode, 541 ionic bond, 55, 120 ionic character, 78 ionic compound, F22 nomenclature, F31 ionic conduction, 218 ionic conductor, 523 ionic liquid, 195 ionic model, 55 ionic radius, 40 ionic solid, 55, 182 ionic structure, 191 ionization, 23 ionization energy, 42, 77, 117 periodicity, 612 ionization isomer, 687 ionized acid, F74 ionizing radiation, 715 iron, 48, 674 rusting, 548 steel production, 674 Iron Age, 671 iron pentacarbonyl, 676 irreversible process, 240 isochore, 411 isodensity surface, 610 isoelectronic, 41 isolated system, 236 isoleucine, 778 isomer, 686, 737, 740 isoprene, 736, 771 isopropyl alcohol, 762 isotherm, 138 isothermal magnetization, 304 isotope, F18 isotopic dating, 719 INDEX E7 isotropic material, 194 -ite suffix, F30 jade, 213 joule, 237, A4, F10 Joule, J., 160, 235, 236, F10 Joule-Thomson effect, 160 Ka, 438 kaolinate, 217 Kb, 438 Kc, relation to K, 398 Kekulé, F., 69 Kekulé structure, 69, 111 kelvin, A3 Kelvin, Lord, 160 Kelvin scale, 140 kernite, 628 kerosene, 751 ketone, 764 nomenclature, 763 Kevlar, 774 kilogram, A3, F6 kilowatt-hour, 550, A4 kimberlite, 211 kinetic energy, 11, 20, 251, F11 kinetic model of gases, 153 Kirchhoff’s law, 278 krypton, 660 krypton fluoride, 660 label, radioisotope, 721 labile compound, 320 lactated Ringer’s solution, 484 lactic acid, 774 lanthanide, 668, F19 lanthanide contraction, 669 lanthanoid, 48, 667, F19 lapis lazuli, 652 large magnet mass spectrometer, 758 latex, 772 lattice, 188 lattice energy, 59 lattice enthalpy, 274, 275 lattice parameter, 62 law, F2 Boyle’s, 138 Charles’s, 139 combined gas, 141 conservation of energy, 247, F13 constant composition, F3, F22 Dalton’s partial pressure, 149 electrolysis, 544 Faraday’s, 544 first, 247 gas, 138 Graham’s, 152, 728 Henry’s, 347 Hess’s, 265 Hooke’s, 90 ideal gas, 141 integrated rate, 572 Kirchhoff’s, 278 limiting, 141 of mass action, 386 Newton’s second, 10 periodic, 38 of radioactive decay, 718 Raoult’s, 356, 368 rate, 561, 567, 569, 572 second thermodynamic, 289 Stefan-Boltzmann, 9 third thermodynamic, 298 Wien’s, 9 LCAO-MO, 115 LCD screen, 195 Le Chatelier, H., 405 Le Chatelier’s principle, 405, 499 lead, 48, 633, 637 lead-acid cell, 550, 551 lead azide, 148 lead battery, 550, 551 Leclanché, G., 551 Leclanché cell, 551 LED (light-emitting diode), 224 Lewis, G. N., 58, 63, 426 Lewis acid, 426, 505, 682 Lewis base, 426, 505, 680 Lewis structure, 64 writing, 65 Lewis symbol, 58 Lewis theory, limitations of, 113 Libby, W., 719 ligand, 680, 684 ligand field splitting, 692 ligand field theory, 698 ligand-to-metal transition, 697 light, 4, 6 light-emitting diode (LED), 224 light-water reactor, 727 lightning, 598 like-dissolve-like rule, 345 lim (limit), A8 lime, 627 lime water, 627 limestone, 212, 624 limiting enthalpy of solution, 349 limiting law, 141 limiting reactant, F96, F97 Linde refrigerator, 161 line structure, F23 linear combination of atomic orbitals, 115 linear momentum, 14 linear shape, 95, 96 linkage isomer, 687 lipid, 73 liposome, 370, 371, 372 liquid, F5 volatile, 334 liquid crystal, 194, 370 liquid-crystal display (LCD), 195 liquid structure, 185 liter, A4 lithium, 620 lithium configuration, 33 lithium ion, 622 lithium-ion cell, 550, 551 lithium oxide, 621 lithium soap, 622 lithium treatment, 622 litmus, F72 localized electron model, 104 lock-and-key mechanism, 600 London, F., 105 London interaction, 176 lone pair, 63, 99 long period, 36 long-range order, 180 low-spin complex, 696 lowest unoccupied molecular orbital (LUMO), 123 Lowry, T., 424, F73 luciferase, 223 luciferin, 223 lucine, 778 Lucite, 770 luminescence, 223 LUMO (lowest unocuppied molecular orbital), 123 lycopene, 124 Lyman series, 7 lyotropic liquid crystal, 195 lysine, 778 macroscopic level, F2 mad cow disease, 780 Madelung constant, 61 magic number, 711 magnesium, 624 burning, F2 magnesium diboride, 222 magnetic field, F12 magnetic materials, 224 magnetic properties, predicting, 697 magnetic quantum number, 26 magnetic resonance imaging (MRI), 791, 792 magnetite, 674 main group, 38, F19 malachite, 677 malleability, 206 malleable, F20 manganese, 48, 674 manganese bronze, 674 manganese dioxide, 674 manganese nodules, 674 manometer, 136 mantissa, A6 many-electron atom, 32 marble, 212 Mars polar ice cap, 259 Marsden, E., 3 Mary the Jewess, F54 mass action law, 386 mass-energy relation, 722 mass number, F18 mass percentage composition, F46 mass spectrometry, 758, F16 mass spectrum, F17 mass-to-mass calculation, F86 mass versus weight, F42 master hormone, 681 material balance, 464 materials science, F4 matter, F5, F53 matter dispersion, 288 matter wave, 14 maximum-boiling azeotrope, 369 maximum work, 525 Maxwell, J. C., 157 Maxwell distribution of speeds, 157, 591 mean bond enthalpy, 276 mean relative speed, 591 mechanical equilibrium, 314 mechanics, 1 mechanism of reaction, 580 medicinal chemistry, F4 Meitner, L., 724 melting, thermodynamic origin, 317 melting temperature, 339 Mendeleev, D. I., 38 meniscus, 181 Menten, M., 600 menthol, 788 mercury, 679, F16 mercury cell, 557 mercury poisoning, 680 mesophase, 194 meta-, 748 metabolic acidosis, 484 metabolic alkalosis, 484 metal, 182, 184, F20 alkali, 619 coinage, 207, 210, 676 properties, 205 vs. nonmetal, 46, 47 metal-ammonia solution, 621 metallic bond, 55 metallic character, 44 metallic conductor, 219 metallic hydride, 614 metallic material, 205 metallic solid, 182, 184, 186 metallocene, 685 metalloid, 46, F20 metalloprotein, 681 metasilicic acid, 638 meter, A3, F6 methamphetamine, F65 methane, 64, 95, 96, F35 combustion, 261 as fuel, 268 methanol, F23, F35 methide, 639 methionine, 778 methyl group, F23, F75 methyl methacrylate, 770 methylamine, 767, F75 methylpropane, 737, F23 Meyer, L., 38 mica, 213 micelle, 199, 224, 346 Michaelis, L., 600 Michaelis constant, 600 Michaelis-Menten mechanism, 600 microporous catalyst, 598 microscope, scanning tunneling, 183, F16 microscopic level, F2 microstate, 298 E8 INDEX microwave, 4 microwave spectroscopy, 83 milk of magnesia, 626 Millikan, R., 2 millimeter of mercury (mmHG), 137 mineral, F1 minimum-boiling azeotrope, 369 minute, A4 mixed solution, 475 mixture, F51 eutectic, 210 gas, 148 mmHg, 137 MO theory, 114 mobile phase, 381 model, F4 moderator, 726 Moissan, H., 542 molal, 352 molality, 352 vs.molarity, 353 molar concentration, F54 molar convention, 390, 391 molar heat capacity, 244 molar mass, F39 colligative properties, 362 molar solubility, 345 molar volume, 140 ideal gas, 144 molarity, F54 vs. molality, 353 mole, A3, F37 mole fraction, 150, 352 mole ratio, F86 mole-to-mole calculation, F85 molecular beam, 593 molecular beam apparatus, 158 molecular biology, F4 molecular compound, F22 molecular formula, F23, F46 molecular hydride, 614 molecular magnet, 225 molecular orbital, 115 molecular orbital energy-level diagram, 115 molecular orbital theory, 114 molecular solid, 182, 184 molecular weight, F42 molecularity, 580 molecule, F22 Molina, M., 598 mollusk shell, 225 momentum angular, 25 linear, 14 orbital angular, 25 monatomic ion, F24 Mond process, 676 monoclinic sulfur, 341, 650 monomer, 770 monoprotic acid, F73 mortar, 215 Moseley, H., F16 most probable speed, 169 mother-of-pearl, 225 MRI (magnetic resonance imaging), 791, 792 Mulliken, R., 77 multiple bond, 64, 106 carbon-carbon, 111 muscone, F50 myoglobin, 414 n to pi star transition, 130 n-type semiconductor, 220 Nagasaki, 726 nanomaterial, 226 nanoparticle, 218 nanoscience, 226 nanosphere, 228 nanotechnology, 183, 226, F4 nanotube, 215, 227, 635 naphthalene, 748 natural antilogarithm, A7 natural logarithm, A7 natural product, 94 nematic phase, 194 neon, 659 neon configuration, 35 Nernst equation, 538 net ionic equation, F67 network solid, 185, 1828 neutralization reaction, F75 neutron, 3, 705, F17 neutron-induced transmutation, 715 neutron rich, 712 newton, A4 Newton’s second law, 9 nickel, 48, 676 nickel-metal hydride cell, 550, 551 nickel surface, 183 nickel tetracarbonyl, 676 NiMH cell, 550, 551 nitrate ion, 67, 97 nitration, 750 nitric acid, 646 nitric oxide, 72, 645 oxidation, 582 nitride, 215, 643 nitrite, 645 nitrite ion, 100 nitrogen, 117, 641 bonding in, 105 configuration, 35 photoelectron spectrum, 117 nitrogen dioxide, 98, 645 nitrogen fixation, 383, 641 nitrogen monoxide, 645 nitrogen oxides, 462, 644 nitrogen trifluoride, 98 nitrogen trihalides, 643 nitrophenol, 750 nitrous oxide, 644 NMR (nuclear magnetic resonance), 791 nobility, 669 noble gas, 659, F19 nodal plane, 29, 116 node, 17 nomenclature, A33 alcohol, 769 aldehyde, 763 alkane, 744 amine, 763 complex, 683 elements, 715 halide, 763 ketone, 763 nonaqueous solution, F53 nonbonding orbital, 122 nonelectrolyte, F66 nonelectrolyte solution, F66 nonexpansion work, 237, 321, 525 nonferrous alloy, 205, 209 nonideal solution, 357 nonlabile compound, 320 nonmetal, F20 nonpolar covalent bond, 120 nonpolar molecules, 101, 105 nonstoichiometric compound, 200 normal boiling point, 296, 338 normal freezing point, 339 normal melting point, 295, 339 normal mode, 90 normalized wavefunction, 53 NOx, 644 ns-orbital, 26 nuclear adiabatic demagnetization, 305 nuclear atom, 2 nuclear binding energy, 722 nuclear chemistry, 705 nuclear decay, 707 nuclear equation, 708 nuclear fallout, 719 nuclear fission, 705, 724 nuclear fusion, 705, 726 nuclear magnetic resonance, 791 nuclear medicine, 714 nuclear model, 3, F16 nuclear power, 728 nuclear reactor, 726 nuclear spin, 791 nuclear stability, 710 nuclear transmutation, 708 nuclear waste, 729 nuclear weapon, 720 nuclei, systematic nomenclature, 715 nucleic acid, 783 nucleon, 707, F17 nucleon number, F18 nucleophile, 762 nucleophilic substitution, 762 nucleoside, 783 nucleosynthesis, 712 nucleotide, 783 nucleus, 3, 705, F16 nuclide, 707 nutritional calorie, 243 nylon, 772 nylon salt, 773 occupying an orbital, 30 octahedral, 95, 96 octahedral complex, 685 octahedral hole, 187 octane rating, 752 octet, 56 octet rule, 63 exceptions to, 71 oil, essential, 764 oil-drop experiment, 2 OLED (organic light-emitting diode), 224 oleum, 653 oligopeptide, 779 one-component phase diagram, 340 onyx, 638 open system, 236 optical activity, 688 optical isomer, 688, 740, 742 orbital, 23 in many-electron atoms, 32 orbital angular momentum, 25 orbital angular momentum quantum number, 25 orbital energies, 117 order, 568 organic chemistry, F4 organic compound, 35, F22 thermodynamic data, A16 organic light-emitting diode (OLED), 224 Orlon, 770 orpiment, 642 ortho-, 748 orthosilicate, 213 orthosilicic acid, 638 osmometry, 362 osmosis, 360 reverse, 364 osmotic pressure, 361 Ostwald process, 646, F65 -ous suffix, F33 overall order, 569 overlap, 105 overpotential, 543 oxalic acid, F90 oxidant, F81 oxidation, 516, F78 oxidation number, F29, F79, F80 oxidation state, F79 oxidative stress, 73 oxide ion, 424 oxidizing agent, F81 oxoacid, F33, F34 nomenclature, A33 oxoacid strength, 442 oxoanion, F26, F30 nomenclature, A33 oxygen, 648 configuration, 35 paramagnetism, 113 oxygen storage, 414 oxygen transport, 414 ozone, 100, 102, 648 decomposition, 570, 580 ozone hole, 598 ozone layer, 598 p-n junction, 221 p-orbital, 25, 29 p-type semiconductor, 220 paired spins, 33 paper chromatography, F54 papermaker’s alum, 631 para-, 748 INDEX E9 paraffin, 744 paraffin wax, 751 parallel spins, 34 paramagnetism, 114 oxygen, 113 parent ion, 758 partial charge, 77 partial pressure, 149 particle in a box, 18 entropy and, 301 particle model, 13 partition, 381 pascal, 134, A4 passivate, 549 patina, 678 Pauli, W., 33 Pauli exclusion principle, 33, 36, 37, 185 Pauling, L., 77, 105 pencil lead, 185 penetration, 33 penicillin decay, 565 pentagonal bipyramidal, 95, 96 pentane, 176 peptide, 779 peptide bond, 779 per- prefix, F30 percentage deprotonation, 445 percentage protonation, 448 percentage yield, F95 perchlorate, 658 perchloric acid, 658 perfect crystal, 299 period, 35, F19 periodic law, 38 periodic table, 36, 37, F19 periodic variation atomic radius, 39 electron affinity, 44 ionization energy, 42, 44 periodicity, 39, 612 permanent wave, 781 permanganate, 671 permanganate ion, 697 permittivity, F12 pernicious anemia, 681, 734 persulfate reaction, 569 perxenate, 660 PES (photoelectron spectroscopy), 117 PET (positron emission tomography), 714 PETE (polyethylene terephthalate), 772 petroleum, 368 petroleum constituents, 751 petroleum refining, 745, 751 pH, 431, F72 amphiprotic salt, 456 autoprotolysis effect on, 464 of blood, 484 buffer solution, 477 calculation for titrations, 487 electrochemical determination, 541 polyprotic acid, 455 salt solution, 450 at stoichiometric point, 487 water, 431 weak acid, 445 weak acids, 466 weak base, 448 pH curve, 483 pH meter, 433, 492 phase, 172, 333 phase boundary, 340 phase diagram, 340 carbon, 374 helium, 374, 659 sulfur, 341 water, 340 phase transition, 333 phenanthroline, 701 phenol, 470, 750, 764 phenolphthalein, 493, F89 phenyl group, 748 phenylketonurea, 759 pheromone, 787 phosgene, 71 phosphate ion, 75, F26 phosphate rock, 647 phosphine, 643 phospholipid, 371 phosphor, 223 phosphorescence, 223 phosphoric acid, 646 phosphoric acid fuel cell, 552 phosphorous acid, 442, 646 phosphorus, 640, 641, F15 phosphorus pentachloride, 72, 74, 95, 96, 110, 644 phosphorus trichloride, 72, 644 phosphorus(III) oxide, 641 phosphorus(V) oxide, 646 photochemical smog, 168 photodissociation, 598 photoelectric effect, 10, 11 photoelectron spectrometer, 117 photoelectron spectrum, 117 photographer’s hypo, F65 photographic emulsion, 370 photon, 10 photosynthesis, 721 physical chemistry, F4 physical property, F5 physical quantity, A3 physiological buffer, 484 phytochemical, 73 pi-bond, 106 pi-orbital, 116 pi to pi star transition, 130 piezoelectric, 672 pitchblende, 728 Planck, M., 10 Planck’s constant, 10 plane-polarized light, 689 plasma, 727 plastic, 770 plastic sulfur, 649 plausible structure, 70 Plexiglas, 770 plumbane, 81 plutonium, 716 pOH, 434 poison, enzyme, 601 poisoned catalyst, 598 polar covalent bond, 77, 120 polar molecules, 101, 105 polarimetry, 689 polarizability, 176 periodicity, 613 polarizable, 78 polarization, 79 polarizing power, 79 pollution, 462 polonium, 650 poly-p-phenylenevinylene (PPV), 779 polyacetylene, 778 polyamide, 772, 779 polyatomic molecule, F26 molecular orbitals, 121 polydentate ligand, 684 polyelectron atom, 32 polyethylene, 184, 770 polyethylene terephthalate (PETE), 772 polyisoprene, 771 polymer, 770 polymerization, 770 poly(methyl methacrylate), 775 polynucleotide, 783 polypropylene, 770 polyprotic acid, 454 pH, 455 species in solution, 458 titration, 494 polyprotic base, 454 polypyrrole, 778 polysaccharide, 781 polystyrene, 770, 775 polysulfane, 652 polytetrafluorethylene, 657 polyvinyl chloride, 770 Portland cement, 214 positional disorder, 290 positron, 707 positron emission, 709 positron emission tomography (PET), 714 potassium, 620 potassium configuration, 35 potassium superoxide, 147, 622 potential difference, 522 potential energy, 32, F11 potential energy surface, 595 potentiometer, 527 pound, A4 powder diffraction, 203 Powell, H., 95 PPV (poly-pphenylenevinylene), 779 pre-equilibrium condition, 583 pre-exponential factor, 588 precipitate, F67 dissolving, 504 precipitation, F52 prediction of, 501 selective, 502 precipitation reaction, F67, F70 precision, F9 prefix, SI, A4 pressure, 134 critical, 343 pressure units, 136 pressurized water reactor, 721 primary alcohol, 763 primary amine, 767 primary cell, 550 primary structure, 779 primitive cubic structure, 188 principal quantum number, 23 principle Avogadro’s, 38, 140 Heisenberg uncertainty, 15 Le Chatelier’s, 405, 499 Pauli exclusion, 33, 36, 37, 185 prion disease, 780 probability density, 17 procaine, 787 process Bayer, 629 chloralkali, 547, 622 Claus, 650 Dow, 543 Downs, 547, 620 Frasch, 649 Haber, 597 Hall, 629 Mond, 676 Ostwald, 646, F65 product, F60 proline, 778 promotion, electron, 107 propagation, 585 propene, 574 property (of matter), F5 proportional to, 10 propyne, 736 proton, 3, 705, F16 proton exchange membrane, 552 proton rich, 712 proton sink, 476 proton source, 476 proton transfer, 424 protonation, 425, F74 percentage, 448 psi, 17 PTFE, 770 PVC, 770 pX meter, 542 pyramidal, 95 Pyrex, 216 pyrimidine, 701 pyrite, 649, 674 pyrolusite, 674 pyrometallurgy, 677 pyrophosphoric acid, 647 pyroxene, 213 quadratic equation, 404, A7 qualitative analysis, 475, 507, F69 qualitative concept, F3 quanta, 10 quantitative analysis, F69 quantitative formulation, F3 quantized, 20 quantum dot, 226, 229 quantum mechanics, 1 quantum number, 18 magnetic, 26 orbital angular momentum, 25 principal, 23 spin magnetic, 30 E10 INDEX quantum theory, 8 quart, A4 quartz, 182, 212, 213, 635 quartzite, 212, 635 quaternary ammonium ion, 767 quaternary structure, 780 quicklime, 627 racemic mixture, 689, 742 rad, 716 radial distribution function, 27 radial wavefunction, 24 radiation black-body, 8 electromagnetic, 3 infrared, 4, 6, 90 ultraviolet, 6 radiation absorbed dose (rad), 716, 718 radiation units, 718 radical, 723 radical chain reaction, 585, 745 radical polymerization, 771 radio waves, 4 radioactive decay law, 718 radioactive element, 708 radioactive series, 712 radioactivity, 706 radiocarbon dating, 719 radioisotope, 721 radioisotope label, 721 radius ratio, 192 radon, 660 random copolymer, 775 random error, F9 Raoult, F-M., 356 Raoult’s law, 356 deviations from, 368 rare earth, 667 rate constant, 566 rate-determining step, 583 rate law, 561, 568, 569 integrated, 572 rate of reaction, 561 rational drug design, 94 reactant, F60 limiting, F96, F97 reaction addition, 746 Belousov-Zhabotinskii, 636 competing, F95 condensation, 647 elimination, 745 hydrolysis, 762 neutralization, F75 radical chain, 745 redox, F79 substitution, 682, 744 reaction enthalpy, 261 combining, 265 standard, 264 variation with temperature, 278 reaction Gibbs free energy, 318, 390 reaction intermediate, 580 reaction mechanism, 580 reaction order, 568 reaction profile, 592 reaction quotient, 392 reaction rate, 561 effect of temperature, 587 reaction sequence, 265 reaction stoichiometry, F85 reactive scattering, 593 reagent, F60 real gas, 159 realgar, 642 recycling codes, 777 red blood cells, 361 red phosphorus, 641, F15 redox couple, 516 redox reaction, F79 balancing, 516 balancing equation, F83 redox titration, F89 reducing agent, F81 reductant, F81 reduction, 516, F78 refining, petroleum, 745 reforming reaction, 616 refractory, 626 relative abundance, of principal elements, 612 relative biological effectiveness, 716 rem, 716, 718 repeating unit, 770 repulsion, 185 residual entropy, 300 residue, 779 resistance, 219 resonance, 67, 111, 750, 791 resonance hybrid, 67 respiration, 681 respiratory alkalosis, 484 retinal, 112 reverse osmosis, 364 reversibility, 525 reversible isothermal expansion, 241 reversible process, 240 rhombic sulfur, 341, 650 ribonucleic acid (RNA), 782 ribose, 783 RNA, 782 roast, 676 roasting, F64 rock-salt structure, 191 rocket fuel, 658 roentgen equivalent man (rem), 716 root mean square speed, 156 roots of equation, A7 rotational energy, 251 rotational energy levels, 83 rounding rules, A6 Rowland, S., 598 rubber, 771 rubidium, 620 ruby, 631 rule Hund’s, 35, 36, 37 like-dissolve-like, 345 octet, 63 Trouton’s, 297 Rutherford, E., 2, 3, 706 rutile, 672 Rydberg constant, 7, 23 s-block element, 46, 47 s-electron, 26 s-orbital, 25, 28 sacrificial anode, 549 saddle point, 595 salicylic acid, 509 saline carbide, 639 saline hydride, 614 salt, F75 amphiprotic, 456 salt bridge, 526 salt solution, pH, 450 sample, F2 sand, 212, 216, 635 sandwich compound, 685 sapphire, 631 SATP (standard ambient temperature and pressure), 144 saturated hydrocarbon, 736 saturated solution, 345 SBR (styrene-butadiene rubber), 775 scale, 351 scandium, 35, 48, 672 scanning tunneling microscope (STM), 183, F16 Schilling test, 734 Schrödinger, E., 17 Schrödinger equation, 17 scientific method, F2 scientific notation, A5 scintillation counter, 717 screen, LCD, 195 sea of instability, 711 seashell, 212, 225 second, A3, F6 second derivative, A9 second ionization energy, 42 second law of thermodynamics, 289 second-order integrated rate law, 578 second-order reaction, 568 second virial coefficient, 161 secondary alcohol, 763 secondary cell, 550, 551 secondary structure, 779 seesaw, 95 selective precipitation, 502 selenium, 48, 650 self-assembling materials, 636 semi-empirical methods, 610 semiconductor, 219, 220 extrinsic, 220 intrinsic, 220 semipermeable membrane, 360 separation between neighbors, 20 separation techniques, F53 sequester, 686 series (spectral), 7 serine, 778 sewage plants, 269 shapes of simple molecules, 95 shell (electron), 25, 26, 33, 212 shell (seashell), 212, 225 shielding, 32 shift reaction, 617 short-range order, 180 SI (Système International), F6 prefixes, A4 sickle-cell anemia, 779 Sidgwick, N., 95 sievert, 716, 718, A4 sigma bond, 105 sigma orbital, 116 significant figures, A5, F9 silane, 639 silica, 182, 216, 635, 638 silica gel, 638 silicate, 212, 635 silicon, 47, 633, 639 silicon carbide, 639 silicon tetrachloride, 639 silk, 781 silver, 678 silver cell, 550, 551 single bond, 64, 106 single-crystal diffraction, 204 sintering, 209 skeletal equation, F61 slag, 627, 675 slaked lime, 627 Slater, J., 105 slip plane, 206 slope of graph, A8 smart gel, 373, 636 smectic phase, 194 smelling salt, 643 smelt, 677 smog, 168 sneeze analogy, 309 soap, 346 soda, 623 soda ash, 623 soda-lime glass, 216 sodium, 620 production, 547 sodium aluminate, 631 sodium azide, 148 sodium carbonate, 623 sodium chromate, 673 sodium hydroxide, 622 sodium peroxide, 622 sodium stearate, 346 sodium-sulfur cell, 550, 551 soft matter, 205 sol, 370 sol-gel process, 218 solid, F5 characteristics, 184 structure, 182, 184 solid dispersion, 370 solid electrolyte, 219 solid emulsion, 370 solid foam, 370 solid solution, F53 Solomon, S., 599 solubility, 344 complex formation, 505 variation with temperature, 348 solubility equilibria, 496 INDEX E11 solubility product, 497 constant, 497 from electrochemical data, 537 solubility rules, F69 soluble substance, F65 solute, F52 solution, F52 ideal vs. nonideal, 357 saturated, 345 solvent, F52 solvent-accessible surface, 610 solvent extraction, 381 soot, 634 Sorensen, S., 431 SOx, 652 sp hybrid orbital, 107 sp2 hybrid orbital, 108, 109 sp3 hybrid orbital, 107, 109 space-filling model, F24 space shuttle fuel, 264 sp3 d hybrid orbital, 109 sp3 d2 hybrid orbital, 109 spearmint, 765 speciation, 458, 767 specific energy, 550 specific enthalpy, 267 specific heat capacity, 244 spectator ion, F67 spectral lines, 6 spectrochemical series, 693 spectrometer, total ozone mapping, 599 spectroscopy, 1, 3 ultraviolet, 130 visible, 130 spectrum atomic, 6 hydrogen atom, 6 speed, 561, F10 mean relative, 591 temperature and, 140 speed of light, 3, 4 sphalerite, 649 sphalerite structure, 193 spherical polar coordinates, 24 spherical symmetry, 26 spider silk, 781 spin, 30 spin magnetic quantum number, 30 spin-spin coupling, 792 splitting atom, 724 spontaneous change, 287 spontaneous nuclear fission, 725 spontaneous reaction, 396 Gibb free energy and, 315 temperature and, 323 square antiprism, 674 square planar, 95 square-planar complex, 685 square pyramidal, 95 SQUID (superconducting quantum interference device), 114 stable compound, 320 stained glass, 370 stainless steel, 209 stalactite, 424 stalagmite, 424 standard ambient temperature and pressure (SATP), 144 standard cell potential, 526 standard electrode potential, 529 standard enthalpy of combustion, 267 standard enthalpy of formation, 309 standard entropy of vaporization, 296 standard Gibbs free energy of formation, 319 standard Gibbs free energy of reaction, 318, 390 equilibrium constant and, 394 standard hydrogen electrode, 530 standard molar entropy, 306 standard potential, 529, A18 combining, 533 and equilibrium constant, 536 significance, 534 standard pressure, 136 standard reaction enthalpy, 264 from standard enthalpy of formation, 272 standard reaction entropy, 306 standard reduction potential, 529 standard state, 264 standard temperature and pressure (STP), 144 stannane, 81 starch, 782 state function, 247 state of matter, F5 state symbol, F61 static self-assembly, 636 stationary phase, 381 statistical entropy, 298 thermodynamic entropy and, 301 statistical thermodynamics, 235 steady-state approximation, 582 steel, 208, 674 alnico, 210, 676 stainless, 209 Stefan-Boltzmann law, 9 stereoisomer, 686, 742 stereoregular, 771 steric factor, 593, 594 steric requirement, 593 Stern, O., 31 Stern-Gerlach experiment, 31 stibnite, 642 stiffness, bond, 90 STM (scanning tunneling microscope), 183, F16 Stock number, F29 stock solution, F57 stoichiometric coefficient, F61 stoichiometric point, 486, 493, F89 detection with indicator, 492 pH, 487 stoichiometric relation, F86 stoichiometry, gas, 147 stopped flow technique, 564 STP (standard temperature and pressure), 144 Strassmann, F., 724 strong acid, 424, F74 strong base, 425, F74 strong electrolyte, F66 strong-field ligand, 694 strong force, 712 strontium, 624 structural formula, F23 structural isomer, 686, 740 styrene, 770 styrene-butadiene rubber (SBR), 775 subatomic particle, 1, F18 subcritical mass, 726 sublimation, 259, 334 subshell, 25, 26 substance, F5 substitution reaction, 682 alkane, 744 substitutional alloy, 208 substrate, 600 successive ionization energies, 43 sucrose, 184 sulfate ion, 75 sulfite ion, 98, 99 sulfur, 48, 649 phase diagram, 341 plastic, 649 sulfur dioxide, 100, 652 oxidation, 570 sulfur hexafluoride, 95, 96 sulfur oxides, 462 sulfur phases, 341 sulfur tetrafluoride, 74, 101 sulfur trioxide, 653 sulfuric acid, 653 pH, 455 sulfurous acid, 652 superconducting quantum interference device (SQUID), 114 superconductor, 219, 221 supercooled, 339 supercritical carbon dioxide, 343, 381 supercritical fluid, 343 supercritical mass, 726 superfluidity, 659 superimposition, 115 superoxide ion, 622 surface tension, 181 surfactant, 346 surroundings, 236 sustainable development, F4 sylvite, 623 symbolic level, F2 Synroc, 729 synthesis, F22 synthesis gas, 282, 616, 763 synthetic fiber, 772 system, 236 systematic error, F9 systematic name, F29 Système International, F6 T-shaped molecule, 95 talc, 213 technetium, 714 Teflon, 657, 770 television, LCD, 195 tellurium, 48, 650 temperature absolute, 139, 140 absolute zero, 304 average speed and, 140 boiling, 295 critical, 343 effect on equilibrium, 410 enthalpy and, 323 freezing, 339 melting, 339 reaction rate, 587 spontaneous reaction and, 323 temperature-composition diagram, 367 temperature conversion, A5 template synthesis, 228 terephthalic acid, 791 termination, 585 termolecular reaction, 581 tertiary structure, 780 Terylene, 772 testosterone, 787, F24 tetrachloromethane, 102, 337 tetraethyl lead, 637 tetrafluoroborate ion, 76 tetrahedral, 95 tetrahedral complex, 685, 696 tetrahedral hole, 187 tetramethylsilane, 791 tetravalent carbon, 64 tg-orbital, 691 thallium, 630 theoretical chemistry, F4 theoretical yield, F95 theory, F3 activated complex, 594 Brønsted-Lowry, 424 collision, 591 crystal field, 691, 698 density functional, 610 ligand field, 698 molecular orbital, 114 transition state, 594 thermal disorder, 290 thermal equilibrium, 314 thermal motion, F13 thermochemical equation, 261 thermodynamic data, A11 thermodynamic entropy, statistical entropy and, 301 thermodynamically stable compound, 320 thermodynamically unstable compound, 320 thermodynamics, 235 first law, 247 second law, 289 third law, 298 thermogram, 260 thermonuclear explosion, 727 thermotropic liquid crystal, 195 E12 INDEX third law of thermodynamics, 298 third virial coefficient, 161 Thomson, G. P., 15 Thomson, J. J., 2 Thomson, W. (Lord Kelvin), 160 three-center bond, 633 threonine, 778 thymine, 469, 783 thymol, 764 tie line, 367 tin, 47, 633, 637 allotropes, 306 titanate, 672 titanium, 48, 672 titrant, 483, F89 titration, 483 acid-base, F89 polyprotic acid, 494 redox, F89 strong acid–strong base, 483 strong acid–weak base, 486, 490 weak acid–strong base, 486, 490 TNT, 748 Tollens reagent, 765 tomography, 714 TOMS (Total Ozone Mapping Spectrometer), 599 ton, A4 tonne, A4 tooth enamel, 627 top-down approach, in nanotechnology, 228 topaz, 631 Torr, 137 Torricelli, E., 135 total energy, F12 Total Ozone Mapping Spectrometer (TOMS), 599 tracer, 721 trajectory, 17 trans fat, 766 transdermal patch, 372 transesterification, 766 transition, 8 atomic spectra and, 13 chromophores and, 130 transition intensity, 53 transition metal, 47, 667, F19 transition state, 594 transition state theory, 594 translational energy, 251 transmeitnerium element, 715 transmutation, 708, 713 neutron-induced, 715 transuranium element, 715 trauma, 484 tremolite, 213 triboluminescence, 223 trichloromethane, 102, F36 trichlorophenol, 470 tridentate ligand, 684 trigonal bipyramidal, 95, 96 trigonal planar, 95, 96 trigonal prismatic, 703 trigonal pyramidal, 95 trimethylamine, 767, F75 trinitrophenol, 748 trinitrotoluene, 646 triple bond, 64, 106 triple point, 340 tristearin, 766 tritium, 727, F18 tropical fireflies, 589 Trouton’s rule, 297 tryptophan, 778 Tsvet, M. S., 381 tube structure, F24 tunneling, 183 turgidity, 361 Tylenol, 768, 787 tyrosine, 778 Uhlenbeck, G., 30 ultra-high density polyethylene, 184 ultraviolet catastrophe, 9 ultraviolet radiation, 6 ultraviolet spectroscopy, 130 uncertainty principle, 15 unimolecular reaction, 580 unique average rate, 563 unit, A3, F6 unit cell, 188 unit conversion, A4 universal indicator paper, 433 universe, 236 unsaturated hydrocarbon, 736 unstable compound, 320 uracil, 783 uranite, 728 uranium, 728 uranium enrichment, 728 uranium hexafluoride, 728 urea, 67 vacuum permittivity, F12 valence, 63 valence band, 220 valence-bond theory, 105 valence electron, 34, 55 valence electron configuration, 35 valence shell, 35 valence-shell electron-pair repulsion (VSEPR) model, 95 valine, 778 van der Waals, J., 39, 177 van der Waals equation, 161, 169 van der Waals interaction, 177 van der Waals parameters, 161 van der Waals radius, 39 van ’t Hoff equation, 362, 411 van ’t Hoff i factor, 360 van ’t Hoff isochore, 411 vanadium, 48, 672 vanadium pentoxide, 673 vanillin, 765 vapor, F5 vapor composition, 366 vapor-phase synthesis, 228 vapor pressure, 149, 334 binary liquid mixture, 365 temperature dependence, 336 vapor-pressure lowering, 356 vaporization, thermodynamic origin, 317 variable covalence, 73 variable valence, 56 VB theory, 105 velocity, F10 velocity selector, 158 vermiculite, 215 vibrational energy, 251 Viking Lander, 382 vinyl chloride, 770 virial coefficient, 161 virial equation, 161 viscosity, 180 visible light, 4, 6 visible spectroscopy, 130 vision, 112 vitamin, 73 vitamin C, F47 volatile liquids, 334 volt, 524, A4 Volta, A., 516 voltage, 522 voltaic cell, 522 voltaic pile, 516 volume, F7 volumetric analysis, F89 volumetric flask, F55 Voyager 2, 721 VSEPR formula, 98 VSEPR model, 95 vulcanization, 776 Waage, P., 385 washing soda, 623 water, 102 autoprotolysis, 429 corrosion and, 548 density and temperature, 185 electrolysis, 543 hard, 351 heating curve, 259 molecular orbitals, 122 pH, 431 phase diagram, 340, 341, 342 polarity, 173 purification, 650 vapor pressure, 336 water-splitting reaction, 615 watt, A4 wave model, 14 wave-particle duality, 14 wavefunction, 17 angular, 24 hydrogen, 24 radial, 24 wavelength, 4, 5, 20 wax, 751 weak acid, 424, F74 calculation of pH, 445 pH, 466 very dilute solutions, 466 weak base, 425, F74 calculation of pH, 448 weak electrolyte, F66 weak-field ligand, 693 weather map, 137 weight versus mass, F42 wetting, 181 white phosphorus, 641 Wieman, C., 305 Wien’s law, 9 Winkler, C., 38 Wöhler, F., 624 wool, 781 work, 236, F11 electrical, 238 expansion, 238 extension, 238 sign convention, 237 surface expansion, 238 table of varieties, 238 work function, 11 wrought iron, 208 x-ray, 4 x-ray diffraction, 203 xenic acid, 661 xenon tetrafluoride, 74, 660 xenon tetroxide, 660 xenon trioxide, 660 yield, F95 Young’s slit experiment, 203 Z (atomic number), 3 zeolite, 370, 598 zero-order reaction, 568 zero-point energy, 21 Ziegler-Natta catalyst, 771 zinc, 48, 679 zinc-blende structure, 192 zinc-copper alloy, 207 zinc enzymes, 681 zingerone, 787 zircon, 213 zone refining, 635 zwitterion, 767 This page intentionally left blank 3 4 5 6 7 8 9 2 3 4 5 6 7 IIIB IVB VB VIB VIIB VIIIB I II IA IIA 1 2 1 H hydrogen 1.0079 11 Na 12 Mg 21 Sc sodium magnesium scandium 22.99 24.31 44.96 22 Ti 23 V 24 Cr 25 Mn titanium vanadium chromium manganese 50.9447.87 52.00 54.94 26 Fe 27 Co iron cobalt 55.84 58.93 37 Rb 38 Sr 87 Fr 39 Y 40 Zr 41 Nb 42 Mo 72 Hf 73 Ta 74 W 104 Rf 105 Db 106 Sg rubidium strontium yttrium zirconium niobium molybdenum hafnium tantalum tungsten francium rutherfordium dubnium seaborgium 85.47 87.62 88.91 91.22 92.91 95.94 178.49 180.95 183.84 (223) (261) (262) (266) 43 Tc 44 Ru 45 Rh 75 Re 76 Os 77 Ir 107 Bh 108 Hs 109 Mt technetium ruthenium rhodium rhenium osmium iridium bohrium hassium meitnerium (98) 101.07 102.90 186.21 190.23 192.22 (264) (267) (268) 57 La 89 Ac lanthanum actinium 138.91 (227) (actinides) Lanthanoids Group Period PERIODIC TABLE OF THE ELEMENTS Period 1 Molar masses (atomic weights) quoted to the number of significant figures given here can be regarded as typical of most naturally occurring samples. 1s1 4 Be beryllium 9.01 2s2 3 Li lithium 6.94 2s1 3s2 3s1 20 Ca calcium 40.08 4s2 19 K potassium 39.10 4s1 5s2 5s1 56 Ba barium 137.33 6s2 55 Cs cesium 132.91 6s1 88 Ra radium (226) 7s2 7s1 3d1 4s2 3d2 4s2 3d3 4s2 3d5 4s1 3d5 4s2 3d6 4s2 3d7 4s2 4d1 5s2 4d2 5s2 4d4 5s1 4d5 5s1 4d5 5s2 4d7 5s1 4d8 5s1 5d1 6s2 5d2 6s2 5d3 6s2 5d4 6s2 5d5 6s2 5d6 6s2 5d7 6s2 6d1 7s2 6d2 7s2 6d3 7s2 6d4 7s2 6d5 7s2 6d6 7s2 6d7 7s2 58 Ce 59 Pr 60 Nd 61 Pm 62 Sm 90 Th 91 Pa 92 U 93 Np 94 Pu cerium praseodymium neodymium promethium samarium thorium protactinium uranium neptunium plutonium 140.12 140.91 144.24 (145) 150.36 232.04 231.04 238.03 (237) (244) 6 7 Actinoids (lanthanides) 4f1 5d1 6s2 5f2 6d1 7s2 5f3 6d1 7s2 5f4 6d1 7s2 4f3 6s2 4f4 6s2 4f5 6s2 4f6 6s2 6d2 7s2 5f6 7s2 *The names of the elements 112 and higher have not yet been determined; both 112 and 114 have been confirmed. 10 11 12 13 14 15 16 17 18 111 Rg 112* 113 114 115 116 117 118 IB IIB III IV V VI VII VIII IIIA IVA VA VIA VIIA VIIA helium 4.00 5 B 6 C 7 N 8 O boron carbon nitrogen oxygen 10.81 12.01 14.01 16.00 9 F 10 Ne fluorine neon 19.00 20.18 28 Ni 29 Cu nickel copper 58.69 63.55 13 Al 14 Si 15 P 16 S aluminum silicon phosphorus sulfur 17 Cl 18 Ar chlorine argon 26.98 28.09 30.97 32.06 35.45 39.95 30 Zn 31 Ga 32 Ge 33 As 34 Se 35 Br 36 Kr zinc gallium germanium arsenic selenium bromine 65.41 69.72 72.64 74.92 78.96 79.90 krypton 83.80 46 Pd 47 Ag 48 Cd 78 Pt 79 Au 80 Hg palladium silver cadmium platinum gold mercury 106.42 107.87 112.41 195.08 196.97 200.59 49 In 50 Sn 51 Sb 52 Te 53 I 54 Xe 81 Tl 82 Pb 83 Bi 84 Po 85 At 86 Rn indium tin antimony tellurium iodine xenon thallium lead bismuth polonium astatine radon 204.38 207.2 208.98 (209) (210) (222) 114.82 118.71 121.76 127.60 126.90 131.29 110 Ds darmstadtium (271) roentgenium (272) 2 He 1s2 2s2 2p6 2s2 2p5 2s2 2p4 2s2 2p3 2s2 2p2 2s2 2p1 3s2 3p6 3s2 3p5 3s2 3p4 3s2 3p3 3s2 3p2 3s2 3p1 4s2 4p6 4s2 4p5 4s2 4p4 4s2 4p3 4s2 4p2 4s2 4p1 5s2 5p6 5s2 5p5 5s2 5p4 5s2 5p3 5s2 5p2 5s2 5p1 6s2 6p6 6s2 6p5 6s2 6p4 6s2 6p3 6s2 6p2 6s2 6p1 3d8 4s2 3d10 4s1 3d10 4s2 4d10 4d10 5s1 4d10 5s2 5d9 6s1 5d10 6s1 6d8 7s2 6d10 7s1 5d10 6s2 71 Lu 103 Lr lutetium lawrencium 174.97 (262) 63 Eu 64 Gd 95 Am 96 Cm 65 Tb 66 Dy 67 Ho 68 Er 69 Tm 70 Yb 97 Bk 98 Cf 99 Es 102 No europium gadolinium americium terbium dysprosium holmium berkelium californium einsteinium erbium thulium ytterbium nobelium 151.96 157.25 158.93 (243) (247) (247) 162.50 164.93 167.26 168.93 173.04 curium (251) (252) (259) 4f7 5d1 6s2 5d1 6s2 4f7 6s2 4f9 6s2 4f10 6s2 4f11 6s2 4f12 6s2 4f13 6s2 4f14 6s2 5f7 6d1 7s2 6d1 7s2 5f7 7s2 5f9 7s2 5f10 7s2 5f11 7s2 100 Fm fermium (257) 5f12 7s2 101 Md mendelevium (258) 5f13 7s2 5f14 7s2 4 ANSWERS FREQUENTLY USED TABLES AND FIGURES Page Atomic and molecular properties Atomic radii Fig. 1.46 40 First Ionization Energies Fig. 1.50 43 Electron Affinity Fig. 1.54 45 Electronegativity Fig. 2.12 78 Ground-State Electron Configurations Appendix 2C A20 The Elements (Physical Properties) Appendix 2D A22 Thermodynamic properties Standard Enthalpies of Physical Change Table 7.3 258 Lattice Enthalpies Table 7.6 275 Mean Bond Enthalpies Table 7.8 277 Vapor Pressure of Water Table 9.3 335 Thermodynamic Data Appendix 2A A11 Solutions Acidity Constants Table 11.1 436 Basicity Constants Table 11.2 437 Acidity Constants of Polyprotic Acids Table 11.9 451 Solubility Products Table 12.4 497 Electrochemistry Standard Potentials Table 13.1, 532 Appendix 2B A18 1. General Roots of the equation ax2 ϩ bx ϩ c ϭ 0: Kinetic energy of a particle: Gravitational potential energy: Ep ϭ mgh Coulomb potential energy of two charges Q1 and Q2 at a separation r: Ep ϭ Q1Q2͞4␲␧0r 2. Structure and spectroscopy Relation between the wavelength, ␭, and frequency, ␯, of electromagnetic radiation: ␭␯ ϭ c Energy of a photon of electromagnetic radiation of frequency ␯: E ϭ h␯ de Broglie relation: ␭ ϭ h/p Heisenberg uncertainty principle: Energy of a particle of mass m in a one-dimensional box of length L: En ϭ n2 h2 /8mL2 n ϭ 1, 2, . . . Bohr frequency condition: h␯ ϭ Eupper – Elower Energy levels of a hydrogenlike atom of atomic number Z: En ϭ –Z2 hR ͞n2 , n ϭ 1, 2, . . . Formal charge FC ϭ V Ϫ L ϩ S 3. Thermodynamics Ideal gas law: PV ϭ nRT Expansion work against constant external pressure: w ϭ ϪPex⌬V Work of reversible, isothermal expansion of an ideal gas: w ϭ ϪnRT ln (Vfinal͞Vinitial) First law of thermodynamics: ⌬U ϭ q ϩ w Definition of entropy change: ⌬S ϭ qrev͞T Definition of enthalpy H ϭ U ϩ PV Definition of Gibbs free energy G ϭ H Ϫ TS Change in Gibbs free energy at constant temperature: ⌬G ϭ ⌬H Ϫ T⌬S Relation between the constant-pressure and constant-volume molar heat capacities of an ideal gas: CP,m ϭ CV,m ϩ R Standard reaction enthalpy (X ϭ H) and Gibbs free energy (X ϭ G) from standard enthalpies and Gibbs free energies of formation: ⌬X° ϭ ⌺ n⌬Xf°(products) – ⌺ n⌬Xf°(reactants), n in moles ⌬Xr° ϭ ⌺ n⌬Xf°(products) Ϫ ⌺ n⌬Xf°(reactants), n dimensionless Standard reaction entropy: ⌬S° ϭ ⌺ nSm°(products) Ϫ ⌺ nSm°(reactants), n in moles ⌬Sr° ϭ ⌺ nSm°(products) Ϫ ⌺ nSm°(reactants), n dimensionless Kirchhoff’s law: ⌬H2° ϭ ⌬H1° ϩ ⌬CP(T2 Ϫ T1) Change in entropy when a substance of constant heat capacity, C, is heated from T1 to T2: ⌬S ϭ C ln (T2͞T1) Change in entropy when an ideal gas expands isothermally from V1 to V2: ⌬S ϭ nR ln (V2͞V1) Boltzmann’s formula for the statistical entropy: S ϭ k ln W Entropy change of the surroundings for a process in a system with enthalpy change ⌬H: ⌬Ssurr ϭ Ϫ⌬H͞T b 1 2 a U¢p¢x Ú 1 2 Ek = 1 2 mv2 x = -b ; (b2 - 4ac)1/2 2a 4. Equilibrium and electrochemistry Definition of activity (for ideal systems): For an ideal gas: aJ ϭ PJ/P°, P° ϭ 1 bar For a solute in an ideal solution: aJ ϭ [J]/c°, c° ϭ 1 molиL–1 For a pure liquid or solid: aJ ϭ 1 Reaction quotient and equilibrium constant: For the reaction a A ϩ b B : c C ϩ d D, Q ϭ aC c aD d /aA a aB b For the equilibrium a A ϩ b B Δ c C ϩ d D, K ϭ (aC c aD d /aA a aB b )equilibrium Variation of Gibbs free energy of reaction with composition: ⌬Gr ϭ ⌬Gr° ϩ RT ln Q Relation between standard reaction Gibbs free energy and equilibrium constant: ⌬Gr° ϭ ϪRT ln K van ’t Hoff equation: Relation between K and Kc: P°/Rc° ϭ 12.03 K Clausius–Clapeyron equation: Relation between Gibbs free energy and maximum nonexpansion work: ⌬G ϭ we,max at constant temperature and pressure Relation between pH and pOH: pH ϩ pOH ϩ pKw Relation between acidity and basicity constants of a conjugate acid–base pair: pKa ϩ pKb ϭ pKw Henderson–Hasselbalch equation: pH ϭ pKa ϩ log ([base]initial/[acid]initial) Relation between the Gibbs free energy of reaction and the cell potential: ⌬G ϭ ϪnFEcell Relation between the equilibrium constant for a cell reaction and the standard cell potential: ln K ϭ nFEcell°/RT Nernst equation: Ecell ϭ Ecell° – (RT/nF) ln Q 5. Kinetics Average reaction rate: Rate of consumption of R ϭ Ϫ Rate of formation of P ϭ Unique average rate for a A ϩ b B : c C ϩ d D Unique average reaction rate ϭ Ϫ Integrated rate laws: For Rate of disappearance of A ϭ k[A], ln For Rate of disappearance of A ϭ k[A]2 , Half-life of a reactant in a first-order reaction: t1/2 ϭ (ln 2)/k Arrhenius equation: ln ϭ ln A Ϫ Ea/RT The rate constant at one temperature in terms of its value at another temperature: The equilibrium constant in terms of the rate constants: K ϭ kforward/kreverse ln k2 k1 = Ea R a 1 T1 - 1 T2 b 1 [A]t - 1 [A]0 = kt, [A]t = [A]0 1 + [A]0kt , 1 [A]t = kt + 1 [A]0 [A]t [A]0 = -kt, [A]t = [A]0e-kt 1 a ¢[A] ¢t = - 1 b ¢[B] ¢t = 1 c ¢[C] ¢t = 1 d ¢[D] ¢t ¢[P] ¢t ¢[R] ¢t ln P2 P1 = ¢Hvap° R a 1 T1 - 1 T2 b K = (RTc°/P°)¢ngas Kc ln K2 K1 = ¢Hr° R a 1 T1 - 1 T2 b KEY EQUATIONS THE ELEMENTS Molar Atomic mass* Element Symbol Number (gиmolϪ1) Actinium Ac 89 (227) Aluminum Al 13 26.98 Americium Am 95 (243) Antimony Sb 51 121.76 Argon Ar 18 39.95 Arsenic As 33 74.92 Astatine At 85 (210) Barium Ba 56 137.33 Berkelium Bk 97 (247) Beryllium Be 4 9.01 Bismuth Bi 83 208.98 Bohrium Bh 107 (264) Boron B 5 10.81 Bromine Br 35 79.90 Cadmium Cd 48 112.41 Calcium Ca 20 40.08 Californium Cf 98 (251) Carbon C 6 12.01 Cerium Ce 58 140.12 Cesium Cs 55 132.91 Chlorine Cl 17 35.45 Chromium Cr 24 52.00 Cobalt Co 27 58.93 Copper Cu 29 63.55 Curium Cm 96 (247) Darmstadtium Ds 110 — Dubnium Db 105 (262) Dysprosium Dy 66 162.50 Einsteinium Es 99 (252) Erbium Er 68 167.26 Europium Eu 63 151.96 Fermium Fm 100 (257) Fluorine F 9 19.00 Francium Fr 87 (223) Gadolinium Gd 64 157.25 Gallium Ga 31 69.72 Germanium Ge 32 72.64 Gold Au 79 196.97 Hafnium Hf 72 178.49 Hassium Hs 108 (277) Helium He 2 4.00 Holmium Ho 67 164.93 Hydrogen H 1 1.0079 Indium In 49 114.82 Iodine I 53 126.90 Iridium Ir 77 192.22 Iron Fe 26 55.84 Krypton Kr 36 83.80 Lanthanum La 57 138.91 Lawrencium Lr 103 (262) Lead Pb 82 207.2 Lithium Li 3 6.94 Lutetium Lu 71 174.97 Magnesium Mg 12 24.31 Manganese Mn 25 54.94 Meitnerium Mt 109 (268) Molar Atomic mass* Element Symbol Number (gиmolϪ1) Mendelevium Md 101 (258) Mercury Hg 80 200.59 Molybdenum Mo 42 95.94 Neodymium Nd 60 144.24 Neon Ne 10 20.18 Neptunium Np 93 (237) Nickel Ni 28 58.69 Niobium Nb 41 92.91 Nitrogen N 7 14.01 Nobelium No 102 (259) Osmium Os 76 190.23 Oxygen O 8 16.00 Palladium Pd 46 106.42 Phosphorus P 15 30.97 Platinum Pt 78 195.08 Plutonium Pu 94 (244) Polonium Po 84 (209) Potassium K 19 39.10 Praseodymium Pr 59 140.91 Promethium Pm 61 (145) Protactinium Pa 91 231.04 Radium Ra 88 (226) Radon Rn 86 (222) Rhenium Re 75 186.21 Rhodium Rh 45 102.90 Roentgenium Rg 111 — Rubidium Rb 37 85.47 Ruthenium Ru 44 101.07 Rutherfordium Rf 104 (261) Samarium Sm 62 150.36 Scandium Sc 21 44.96 Seaborgium Sg 106 (266) Selenium Se 34 78.96 Silicon Si 14 28.09 Silver Ag 47 107.87 Sodium Na 11 22.99 Strontium Sr 38 87.62 Sulfur S 16 32.06 Tantalum Ta 73 180.95 Technetium Tc 43 (98) Tellurium Te 52 127.60 Terbium Tb 65 158.93 Thallium Tl 81 204.38 Thorium Th 90 232.04 Thulium Tm 69 168.93 Tin Sn 50 118.71 Titanium Ti 22 47.87 Tungsten W 74 183.84 Uranium U 92 238.03 Vanadium V 23 50.94 Xenon Xe 54 131.29 Ytterbium Yb 70 173.04 Yttrium Y 39 88.91 Zinc Zn 30 65.41 Zirconium Zr 40 91.22 *Parentheses around molar mass indicate the most stable isotope of a radioactive element. SI PREFIXES z zepto- 10Ϫ21 a atto- 10Ϫ18 f femto 10Ϫ15 p pico- 10Ϫ12 n nano- 10Ϫ9 ␮ micro- 10Ϫ6 m milli- 10Ϫ3 c centi- 10Ϫ2 d deci- 10Ϫ1 da deka- 10 h hecto- 102 k kilo- 103 M mega- 106 G giga- 109 T tera- 1012 P peta- 1015 FUNDAMENTAL CONSTANTS Name Symbol Value Atomic mass constant mu 1.660 54 ϫ 10Ϫ27 kg Avogadro’s constant NA 6.022 14 ϫ 1023 molϪ1 Boltzmann’s constant k 1.380 65 ϫ 10Ϫ23 JиKϪ1 Fundamental charge e 1.602 18 ϫ 10Ϫ19 C Faraday’s constant F ϭ NAe 9.648 53 ϫ 104 CиmolϪ1 Gas constant R ϭ NAk 8.314 47 JиKϪ1 иmolϪ1 8.314 47 LиkPaиKϪ1 иmolϪ1 8.205 74 ϫ 10Ϫ2 LиatmиKϪ1 иmolϪ1 62.36 37 LиTorrиKϪ1 иmolϪ1 8.314 47 ϫ 10Ϫ2 LиbarиKϪ1 иmolϪ1 Mass of electron me 9.109 38 ϫ 10Ϫ31 kg Mass of neutron mn 1.674 93 ϫ 10Ϫ27 kg Mass of proton mp 1.672 62 ϫ 10Ϫ27 kg Planck’s constant h 6.626 08 ϫ 10Ϫ34 Jиs ϭ h/2␲ 1.054 57 ϫ 10Ϫ34 Jиs Rydberg constant R 3.289 84 ϫ 1015 Hz Speed of light c 2.997 92 ϫ 108 mиsϪ1 Standard acceleration of free fall g 9.806 65 mиsϪ2 Vacuum permittivity ␧0 8.854 19 ϫ 10Ϫ12 JϪ1 иC2 иmϪ1 U RELATIONS BETWEEN UNITS* Property Common unit SI unit Mass 2.205 lb (lb ϭ pound) 1.000 kg 1.000 lb 453.6 g 1.000 oz (oz ϭ ounce) 28.35 g 1.000 ton (ϭ 2000 lb) 907.2 kg 1 t (t ϭ tonne, metric ton) 103 kg Length 1.094 yd (yd ϭ yard) 1.000 m 0.3937 in. (in. ϭ inch) 1.000 cm 0.6214 mi (mi ϭ mile) 1.000 km 1 in. 2.54 cm 1 ft (ft ϭ foot) 30.48 cm 1.000 yd 0.9144 m 1 Å (Å ϭ ångström) 10Ϫ10 m Volume 1 L (L ϭ liter) 103 cm3 , 1 dm3 1.000 gal (gal ϭ gallon)† 3.785 dm3 (3.785 L) 1.00 ft3 (ft3 ϭ cubic foot) 2.83 ϫ 10Ϫ2 m3 (28.3 L) 1.00 qt (qt ϭ quart)† 9.46 ϫ 102 cm3 (0.946 L) Time 1 min (min ϭ minute) 60 s 1 h (h ϭ hour) 3600 s 1 day 86 400 s Pressure 1 atm (atm ϭ atmosphere) 1.013 25 ϫ 105 Pa 1.000 Torr or 1.000 mmHg 133.3 Pa 1.000 psi (psi ϭ pounds per square inch) 6.895 kPa 1 bar 105 Pa Energy 1 cal 4.184 J 1 eV 1.60218 ϫ 10Ϫ19 J; 96.485 kJиmolϪ1 1 CиV 1 J 1 kWh (kWh ϭ kilowatt hour) 3.600ϫ 103 kJ 1 Lиatm 101.325 J Temperature (Fahrenheit temperature)/°F ϭ ϫ (Celsius temperature)/°C ϩ 32 conversions (Celsius temperature)/°C ϭ ϩ{(Fahrenheit temperature)/°F Ϫ 32} (Kelvin temperature)/K ϭ (Celsius temperature)/°C ϩ 273.15 *Entries in boldface type are exact. † The European and Canadian Imperial quart and gallon are 1.201 times as large. 5 9 9 5