Introduction to Computational Quantum Chemistry Intermolecular interactions Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 1 / 10 Intermolecular interactions “Noncovalent” interactions Usually weaker than covanlent bonding (thus reversible) Hydrogen bonding, stacking, ion-ion, ion-dipole... Halogen/chalcogen/pnicogen bonds (σ-hole) Ion-π, π-hole ... Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 2 / 10 Stabilization energy Upon formation of stable complex, energy is released: ∆E = Ecomplex − Emonomers (1) Binding vs Interaction energy Basis Set Superposition Error (BSSE) Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 3 / 10 Nature of stabilization Mainly discussion of chemists To what degree are Quantum or Classical stabilizations responsible for the complex formation? Consequences: How the interactions with EM radiation differ? Can the interaction be modeled by MM? Can the electrostatic potential be used as guide to modeling? Difficulty of transferring the properties between various systems QM stabilization present for formally “noncovalent” interactions Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 4 / 10 Analysis of bonding EDA-NOCV NBO SAPT IQA NCI Electrostatic - Orbital(Polarisation, charge transfer) - Pauli - Dispersion Alternative decomposition: Coloumb - Kinetic - Exchange All include certain degree of arbitrariness Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 5 / 10 HOMEWORK: σ-hole interaction Analyze the σ-hole bonding between bromide and C6F5Br.Br− (structure available in IS) Calculate the interaction energy (M062X and B3LYP/def2tzvpp/BSSE in Gaussian). Explain different DFT values. Reoptimize the C6F5Br, calculate difference in single point energy of both free and bound form and estimate deformation energy (use Gaussian setup). What is the relation of interaction with bond deformation? Perform EDA analysis in ADF2019 using M062X/TZVP, compare the individual terms (Electrostatic, Pauli, Orbital) with C6F6.Br− . Input see bellow. Generate complex.wfn file from single-point calculation in Gaussian on C6F5Br.Br− (in *.com file keyword output=wfn and put name of wfn at the end of *.com file), run NCI-analysis of reduced gradient of electron density, prepare visualization of cube file in VMD (use session file vmd -e *vmd). Input see bellow.. Interpret the results. Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 6 / 10 ADF-EDA Input for adf_compl.inp Atoms C -3.0298060 0.6213630 -0.0000060 f=m ... Br -1.7821970 6.2717390 0.0000290 f=n End ZlmFit Quality good End charge -1 fragments m t21.frag1 n t21.frag2 end Basis Type TZ2P Core none End integration accint 7 end Symmetry Nosym XC MetaHybrid M062X End SAVE TAPE21 End Input Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 7 / 10 ADF-EDA run script Input for run.sh module add adf adf < adf1.inp > adf1.out mv TAPE21 t21.frag1 adf < adf2.inp > adf2.out mv TAPE21 t21.frag2 adf < adf_compl.inp > adf_compl.out Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 8 / 10 NonCovalent Interactions (NCI) Analysis of reduced density gradient: RDG(ρ) = 1 2(3π2)1/3 | ρ| ρ4/3 (2) vs electron density multiplied by the sign of second eigenvalue of Laplacian: sign(λ2)ρ(r) (3) Sign of λ2 is indicator of “attractive” (negative) vs “repulsive” (positive) density Manual of NCIplot: http://www.lct.jussieu.fr/pagesperso/contrera/ nciplot-manual.pdf Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 9 / 10 NCI plot Input for nci.sh module add nciplot nciplot < nci.inp > nci.out Input for nci.inp 1 complex.wfn CUTOFFS 1.0 1.0 Jan Novotny, Martin Novák (NCBR) Intermolecular interactions November 2, 2021 10 / 10