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Layered Compounds
Graphite and Graphene
Clay Minerals
Layered Double Hydroxides (LDHs)
Layered Zirconium Phosphates and Phosphonates
Layered Metal Oxides
Layered Metal Chalcogenides - TiS2, MPS3 (M = V, Mn, Fe, Co, Ni, Zn)
Alkali Silicates and Crystalline Silicic Acids
Two-dimensional layers
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Layered Compounds
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Host-Guest Structures
Host dimensionality
3D 2D 1D 0D
TOPOTACTIC SOLID-STATE REACTIONS = modifying existing solid
state structures while maintaining the integrity of the overall structure
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Intercalation
Intercalation Insertion of molecules between layers
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Intercalation
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Intercalation
Exfoliation
Host + Guest
Staging
Intercalate
APB = advancing phase boundary
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Exfoliation
APB = advancing phase boundary
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APB = advancing phase boundary
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Staging
Hendricks-Teller effect
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HT = galleries are filled randomly
Intercalation
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Dependence of the basal spacing of the
intercalates of the alkylamines (circles) and
alkanols (crosses) on the number of carbon
atoms nC in SrC6H5PO3·2H2O
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Graphite
ABABAB
Graphite sp2 sigma-bonding in-plane p-p-bonding out of plane
Hexagonal graphite = two-layer ABAB stacking sequence
SALCAOs of the p-p-type create the valence and conduction
bands of graphite, very small band gap, metallic conductivity
properties in-plane, 104 times that of out-of plane conductivity
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Graphite
GRAPHITE INTERCALATION
G (s) + K (melt or vapour)  C8K (bronze)
C8K (vacuum, heat)  C24K  C36K  C48K  C60K
C8K potassium graphite ordered structure
Ordered K guests between the sheets, K to G charge transfer
AAAA stacking sequence
reduction of graphite sheets, electrons enter CB
K nesting between parallel eclipsed hexagonal planar carbon six-rings
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Graphite
Intercalates
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Li-ion Cells
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Graphene
• Discovery – 2004
• Exotic properties:
– Firm structure
– Inert material
– Hydrofobic character
– Electric and thermal conductivity
– High mobility of electrons
– Specific surface area
(theoretically):
2630 m2g-1
K. Novoselov A. Geim
http://www.synchrotron.org.au/
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Sythesis of graphene
• Top down
– Mechanical exfoliation
– Chemical exfoliation
• Bottom up
– CVD, epitaxial growth, …
• Defects
• Application: diodes, sensors, solar cell, energy
storage, composites, …
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http://www.nanowerk.com/what_is_graphene.php
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Graphene
High electric conductivity (metallic)
Optically transparent – 1 layer absorbs 2.3% of photons
High mechanical strength
HRTEM
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Graphene
LCAO-band structure of graphene
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GraphenePreparation:
• Scotch tape – layer peeling, flaking
• SiC pyrolysis – epitaxial graphene layer on a SiC crystal
• Exfoliation of graphite (chemical, sonochemical)
• CVD from CH4, CH2CH2, or CH3CH3 on Ni (111), Cu, Pt surfaces
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Scotch tape – Layer peeling
Mechanical exfoliation
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SiC pyrolysis
• Annealing of the SiC crystal in a vacuum furnace (UHV 10-10 Torr)
• Sublimation of Si from the surface at 1250 1450 °C
• The formation of graphene layers by the remaining carbon atoms
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Exfoliation
Chemical exfoliation (surfactant)
Sonochemical exfoliation
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CVD from CH4 / H2 on Metal Surfaces
(A) SEM - graphene on a copper
foil
(B) High-resolution SEM - Cu grain
boundary and steps, two- and
three-layer graphene flakes, and
graphene wrinkles. Inset (B) TEM
images of folded graphene edges.
1L, one layer; 2L, two layers.
Graphene transferred onto
(C) a SiO2/Si substrate
(D) a glass plate
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Graphene on SiO2
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Pseudo-magnetism
Graphene on platinum grown from ethylene at high temperatures.
Cooled to low temperature to measure STM to a few degrees above
absolute zero.
Both the graphene and the platinum contracted – but Pt shrank more,
excess graphene pushed up into bubbles, size 4-10 nm x 2-3 nm
The stress causes electrons to behave as if they were subject to huge
magnetic fields around 300 T
(record high in a lab, max 85 T for a few ms)
twisted bilayer graphene
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Graphene family
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Graphene
hBN
BCN
Fluorographene
graphene oxide
C3N4
Graphene oxide
• More reactive than graphene
• Presence of oxygen groups: -OH, -COOH, =O, -Ohydrophilic
character
• Electric insulator
• Specific SA (theoretically): 1700-1800 m2g-1
• Hummers method
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Graphane – hydrogenated graphene
• 2009 (graphene + cold hydrogen plasma)
• Two conformations: chair x boat
• Calculated binding energy = most stable compound with
stoichiometric formula CH
• Chair type graphane insulating nanotubes
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Fluorographene
• Monolayer of graphite fluoride
• Chair type x boat type-strong repulsion
• Sythesis:
– Graphene + XeF2/CF4 (room temperature)
– Mechanical or chemical exfoliation of graphite fluoride
– By heating graphene in XeF2 gas at 250 °C
• Graphene + XeF2 at 70 °C – high-quality insulator, stable
up to 400 °C (resemblence with teflon)
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Graphyn, graphydiyn
• Predicted
• ‘‘Non-derivatives‘‘ of graphene
• Semiconductors
• Movement of electrons as in graphene but
only in one direction
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Graphitic carbon nitride
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Temperature-
induced
condensation
dicyandiamide
NH2C(=NH)NHCN
In a LiCl/KCl melt
1834 Berzelius, Liebig
Graphitic carbon nitride
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(a) triazine and (b) tri-s-triazine (heptazine)
Graphitic carbon nitride
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(‘‘g-C3N4’’)
band gap 1.6 - 2.0 eV
small band gap semiconductors
Si (1.11 eV), GaAs (1.43 eV), and GaP (2.26 eV)
Phosphorene
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Semiconductor - direct band gap
bulk BP 0.3 eV
monolayer phosphorene 1.5 eV
N -methyl-2-pyrrolidone
Black phosphorus
Orthorhombic
a = 3.31 Å, b = 4.38 Å, c = 10.50 Å
= 90
Space group Bmab
Exfoliation
Phosphorene
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Height-mode AFM images
single-layer phosphorene
ca. 0.9 nm
Phosphorene
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Black phosphorus
12 lattice vibrational modes
6 Raman active modes
3 vibrational modes A1
g , B2g , and A2
g can
be detected when the incident laser is
perpendicular to the layered phosphorene
plane: 361 cm1, 438 cm1, 465 cm1
As the number of phosphorene layers
increases, the three Raman peaks red-shift
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Layered Compounds - Zirconium
Phosphates
(a) α-zirconium phosphate = Zr(HPO4)2.H2O
interlayer spacing 7.6 Å
(b) γ-zirconium phosphate = Zr(PO4)(H2PO4)2H2O
interlayer spacing 12.2 Å
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Layered Compounds - Zirconium
Phosphates
α-zirconium phosphate
Zr(HPO4)2.H2O
interlayer spacing 7.6 Å
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Layered Compounds - Zirconium
Phosphates
(a) α-zirconium phosphate = Zr(HPO4)2.H2O
interlayer spacing 7.6 Å
(b) γ-zirconium phosphate = Zr(PO4)(H2PO4)2H2O
interlayer spacing 12.2 Å
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Clay Minerals
2:1 1:1
kaolinitemontmorillonite
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Montmorillonite
(Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2·10H2O
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Clay Minerals
A clay [Si4O10]4- tetrahedral (T) sheet in
(a) top view and (b) side view
A clay octahedral (O) sheet
(c) top view and (d) side view
The [Al4O12]12- dioctahedral
top view is shown in (c)
[Mg6O12]12- trioctahedral
top view would show
a continuous sheet of octahedral units
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Clay Minerals
N2 sorption isotherms
(a) TMA- and Ca-
montmorillonite
(b) An Italian sepiolite
(c) Natural
SHCa-1 Na-hectorite
(d) synthetic laponite
and Li-(silane)-hectorites
Closed symbols = adsorption
Open symbols = desorption
H3
H4 H4
H2
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Surface Area
nonpolar guest molecules N2 do not penetrate the interlayer regions
Na+ forms of smectites and vermiculites – no penetration
larger ions (Cs+ and NH4
+ keep the basal planes far enough) - limited penetration
the most important parameters of clays with respect to catalytic applications
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Layered Double Hydroxides
LDH = layered double hydroxides
HT = hydrotalcites
Natural mineral hydrotalcite Mg6Al2(OH)16CO3.4H2O
Brucite layers, Mg2+ substituted partially by Al3+
Layers have positive charge
Interlayer
spacing
d(003) = 0.760 nm
Hydrotalcite Mg6Al2(OH)16CO3.4H2O
the brucite-like layer = 0.480 nm
gallery height = 0.280 nm
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Hydrotalcites
Brucite layers, Mg2+ substituted partially by Al3+
Layers have positive charge
(a) [Ca2Al(OH)6]2SO4.6H2O (b) [LiAl2(OH)6]Cl (c) [Mg2.25Al0.75( OH)6]OH
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Hydrotalcite
The layered structure of LDH is closely related to brucite Mg(OH)2
a brucite layer, Mg2+ ions octahedrally surrounded by six OHthe
octahedra share edges and form an infinite two-dimensional
layer
the brucite-like layers stack on top of one another
either rhombohedral (3R) or hexagonal (2H) sequence
Hydrotalcite Mg6Al2(OH)16CO3.4H2O - 3R stacking
[MII
1-xMIII
x (OH)2]x+(Am-)x/m]·nH2O
x = 0.25 Mg6Al2(OH)16CO3
x = 0 Mg(OH)2
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Hydrotalcite
The interlayer spacing c′ is equal to d003, 2d006, 3d009, etc.;
c′ = (d003 + 2d006 + … + nd00(3n)) / n
The cell parameterc is a multiple of the interlayer spacing c′
c = 3c′ for rhombohedral (3R)
c = 2c′ for hexagonal (2H) sequences
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Hydrotalcite
Hydrotalcite Mg6Al2(OH)16CO3.4H2O - 3R stacking
unit cell parameters
a = 0.305 nm c = 3d(003) = 2.281 nm
the interlayer spacing: d(003) = 0.760 nm
the spacing occupied by the anion (gallery height) = 0.280 nm
a thickness of the brucite-like layer = 0.480 nm
the average M—O bond = 0.203 nm
the distance between two nearest OH- ions in the two opposite side layers =
0.267 nm shorter than a (0.305 nm) and indicative of some contraction
along the c-axis.
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XRD Patterns of LDH
XRD patterns of layered double hydroxides synthesized by
coprecipitation method with various cations composition:
A – Mg/Al; B- Mg/Co/Al; C- Mg/Ni/Al
* = Reflections from Si crystal used as a reference
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XRD Patterns of LDH
rhombohedral structure
the cell parameters c and a
The lattice parameter a = 2d(110) corresponds to an average cation–cation
distance
The c parameter corresponds to three times the thickness of d003
c = 3/2 [d003+2d006]
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Layered Compounds
LDH = layered double hydroxides
hydrotalcites
mineral Mg6Al2(OH)16CO3.4H2O
Brucite layers, Mg2+ substituted partially by Al3+
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Intercalation to LDH
the intercalation of methylphosphonic acid into Li/Al LDH
(a) [LiAl2(OH)6]Cl.H2O
(b) second-stage intermediate, alternate layers occupied by Cl and MPA
anions
(c) first-stage product with all interlayer regions occupied by MPA.
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Intercalation to LDH
LDH = layered double
hydroxides
hydrotalcites
mineral Mg6Al2(OH)16CO3.4H2O
Brucite layers, Mg2+ substituted
partially by Al3+
Layers have positive charge
Intercalate anions [Cr(C2O4)3]3-
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The anionic exchange capacity (AEC)
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Types of the composite structures
Li Intercalation Compounds
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Li Intercalation
x Li + TiS2  LixTiS2
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Li Intercalation
Li/C  e + Li+ + C
Li+ + e + FePO4  LiFePO4
Molybdenum Disulfide (MoS2)
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Molybdenum Disulfide (MoS2)
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Molybdenum Disulfide (MoS2)
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(b,c) infraredand (d−f) Raman-active
Frequency of A1g band is increasing
while that of E1
2g is decreasing with
increase in number of layers
Molybdenum Disulfide (MoS2)
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Fermi level
An indirect band gap A direct band gap
Conduction band
Valence band
photoluminescence
Molybdenum Disulfide (MoS2)
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Nature Reviews Materials volume 2, Article number: 17033 (2017)
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3D Intercalation Compounds
Cu3N and Mn3N crystallize in the (anti-) ReO3-type structure
the large cuboctahedral void in the structure can be filled
By Pd to yield (anti-) perovskite-type PdCu3N
By M = Ga, Ag, Cu leading to MMn3N
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3D Intercalation Compounds
Tungsten trioxide structure
= WO6 octahedra joined at their corners
= the perovskite structure of CaTiO3 with all the calcium sites vacant
The color and conductivity changes are due to the intercalation of protons into the
cavities in the WO3 structure, and the donation of their electrons to the conduction
band of the WO3 matrix. The material behaves like a metal, with both its
conductivity and color being derived from free electron behavior.
The coloration reaction used in electrochromic displays for sun glasses, rear view
mirrors in cars
Zn + 2 HCl  2 H + ZnCl2
WO3 + x H  HxWO3
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0D Intercalation Compounds
C60 = FCC
K3 C60