1 electron counting rules and simple bonding descriptions for electron-poor materials -sib 3
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Electron counting rules and simple bonding descriptions for electron-poor materials
-SiB3
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Boron – the master of clusters
B4Cl4 B8Cl8B9Br9
Icosahedral clusters in elemental B
-rhombohedral boron
-rhombohedral boron
Bn Clusters in halides and hydrides (boranes)
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Boranes
Hoffmann, R.; Lipscomb, W. N. J. Chem. Phys. 1962, 37, 2872.Wade K. J. Chem. Soc. Chem. Comm. 1971, 792.Wade, K. Inorg. Nucl. Chem. Lett. 1972, 8, 559.
Bonding in boranes
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Constructing MOs:B atoms: The two sets of skeleton bonding combinations (12 basis functions) transform as:T1g, T2g, T1u, T2u
Those combinations correspond already to (triply degenerated) MOs.The two sets of combinations transform as:A1g, Eg, T1u
A1g, Eg, T1u
of which one is skeleton bonding (the set of inward pointing sp hybrid orbitals) and thus already represent MOs.H atoms: One set of type SALCs A1g, Eg, T1u
py
px5
2
3
4
x
y
1
2 345
6
H HB
H
ligand bonding
skeleton bonding
Number of electrons: 26Number of basis functions: 30
Point group: Oh
Local coordinate system
Dividing the orbitals:B atoms: two type functions (px and py)
two type orbitals (s, pz or better: two sp hybrid orbitals, one inward and one outward pointing)
H ligand atoms: one type orbital (s)
B6H62-
Use of 12 basis functions and 12 electrons for terminal ligand bonding, six bonding MOs (a1g, eg, t2u). For skeleton bonding 18 basis functions and 14 electrons remain.
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T1g
T2u
T1u
T2g
B- MO diagram B- MO diagram
- and type skeleton MOs with the same symmetry (T1u) interact which leads to a net stabilisation of the borane skeleton.
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Wade’s rules
A closo deltahedral cluster cage (parent poyhedron) with n vertices requires (n+1) pairs of electrons for skeleton bonding.
From a parent closo page with n vertices, a set of more open cages (nido, arachno, hypho) can be derived with a formally unchangedskeleton bonding picture
Thus, for a parent closo deltahedron with n vertices, the related nido-cluster has (n-1) vertices, but still (n+1) skeleton bonding MOs.
Thus, for a parent closo deltahedron with n vertices, the related arachno-cluster has (n-2) vertices, but still (n+1) skeleton bonding MOs.
Thus, for a parent closo deltahedron with n vertices, the related hypho-cluster has (n-3) vertices, but still (n+1) skeleton bonding MOs.
A entity BH in boranes may be replaced by a entity CH (carboranes) or P.
Wade’s rules link cluster geometries to certain electron counts
Alternatively:
Closo deltahedral clusters with n entities (vertices) (BH, CH, P) are stable with (4n+2) electrons.
Nido clusters with n entities are stable with (4n+4) electrons.
Arachno clusters with n entities are stable with (4n+6) electrons.
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-B12Electron counting for -B12
36 electrons per icosahedron
26 for skeleton bonding6 for 2c2e terminal bonding6x2/3 = 4 for 3c2e bonding within layers
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-B12
G. Will et al. (2001)
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-B28Electron counting for -B28
structure unit linkage
B12 4 × 2c2e 8 × 3c2e
26 4 × 2/2 8 × 2/3
B2 2 × 2c2e 4 × 3c2e
2 2 × 2/2 4 × 2/3
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From III-V to II-V semiconductors
Sb
GaSb and ZnSbII III IV V
EN: Sb = 1.7, Ga = 1.7, Zn = 1.6
GaSb ZnSb
EN 0 0.1
Eg [eV] 0.81
direct
0.50
indirect
vec 4 3.5
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Electronic structure of ZnSb
The ZnSb framework has a modest polarity
The optimum electron count is 3.5 e/atom
Non-classical 4c4e bonding within rhomboid rings Zn2Sb2 (localized multicentre bonding)
A. Mikhaylushkin, J. Nylén, U. Häussermann, Chem. Eur. J, 11 (2005), 4912
ZnSb – An electron poor framework semiconductor
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3 [Zn2Sb12/2]
2 [Sb2]
Electronic structure of -Zn4Sb3 (Zn6Sb5 )
Zn6Sb5 =
3 (4 + 4 + 4/2) = 30
2 (4 x 2) = 8
38 e for electron precise conditions (3.454 e/atom);37 e available
electron count
R-3c 36 Zn 18 Sb1 12 Sb2 = Zn36Sb30 (Zn6Sb5 = Zn3.6Sb3)
H. W. Mayer, I. Mikhail, K. Schubert, J. Less-Common Met. 59 (1978), 43.
Less electrons than ZnSb: rhomboid rings condense into chains
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-SiB3
Si42+
B122-
a
b
c
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-boron?