Molecular Orbital Theory

Molecular Orbital Theory
Hand-Outs: 19 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Molecular Orbital Theory (“Chemists”) Tight-Binding Theory (“Physicists”) Atomic Orbital Basis; Construct Symmetry-Adapted Linear Combinations of AO’s; Hamiltonian (Energy Operator) has total symmetry of point group of the molecule; Diagonalize Hamiltonian matrix for each IR to obtain eigenvalues (energies) and eigenvectors (orbital coefficients); Outcomes: MO energy diagram (HOMO, LUMO); orbital coefficients (population analysis) Construct Symmetry-Adapted Linear Combinations of AO’s with respect to translational symmetry (wavevector k); Hamiltonian (Energy Operator) has total symmetry of space group of the solid; Diagonalize Hamiltonian matrix at each k for each IR to obtain eigenvalues (energies) and eigenvectors (orbital coefficients); Outcomes: density of states (Fermi level, valence and conduction bands), energy dispersion, En(k), and COOP/COHP curves (population analysis)

IV. Electronic Structure and Chemical Bonding
Hand-Outs: 20 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Atomic Orbital Basis: 1s AO at each H atom (1 AO/atom) OR + 

Hand-Outs: 20 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Atomic Orbital Basis: 1s AO at each H atom (1 AO/atom) OR +  Symmetry Adapted Linear Combination of Basis Functions (SALCs): (Bloch)

Hand-Outs: 20 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Atomic Orbital Basis: 1s AO at each H atom (1 AO/atom) OR +  Symmetry Adapted Linear Combination of Basis Functions (SALCs): k = 0: eikma = e0 = 1

Hand-Outs: 20 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Atomic Orbital Basis: 1s AO at each H atom (1 AO/atom) OR +  Symmetry Adapted Linear Combination of Basis Functions (SALCs): k = /2a: eikma = emi/2 = (i)m (Real part)

Hand-Outs: 20 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Atomic Orbital Basis: 1s AO at each H atom (1 AO/atom) OR +  Symmetry Adapted Linear Combination of Basis Functions (SALCs): k = /a: eikma = emi = (1)m

Hand-Outs: 21 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Hamiltonian (Energy) Matrix: 1 H atom/unit cell = 1 1s AO/unit cell… 11 matrix

Hand-Outs: 20 Hand-Outs: 21 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Hamiltonian (Energy) Matrix: 1 H atom/unit cell = 1 1s AO/unit cell… 11 matrix Hückel Approximation: Ignore interactions beyond first nearest neighbors “Coulomb” integral = AO Energy “Resonance” integral

Hand-Outs: 21 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Chain of H atoms; lattice constant a; 1 H atom per unit cell… N (large) = Periodic Boundary Conditions. Hamiltonian (Energy) Matrix: 1 H atom/unit cell = 1 1s AO/unit cell… 11 matrix Hückel Approximation: Ignore interactions beyond first nearest neighbors “Coulomb” integral = AO Energy “Resonance” integral (NOTE: E(k) = E(k), so we limit k to 0  k  /a)

Hand-Outs: 21 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Outcomes: Band Structure Density of States Crystal Orbital Overlap Population Bandwidth Antibonding Orbitals Fermi Level for H Chain Bonding Orbitals

Hand-Outs: 21 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Outcomes: Comparison of Band Structure and DOS Curve Band Structure Density of States Crystal Orbital Overlap Population Bandwidth Antibonding Orbitals Fermi Level for H Chain Bonding Orbitals k

Hand-Outs: 22 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Bandwidth Band Center /a

Hand-Outs: 22 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 -Bandwidth -Bandwidth Band Center /a

Hand-Outs: 22 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3

Hand-Outs: 23 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Band Crossings: Band centers vs. Bandwidths p  s > |  |’s p-Band

Hand-Outs: 23 IV. Electronic Structure and Chemical Bonding Tight-Binding Model J.K. Burdett, Chemical Bonding in Solids, Ch. 1-3 Band Crossings: Band centers vs. Bandwidths p  s > |  |’s p  s < |  |’s

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 1 H atom / unit cell 1 1s AO / unit cell 2 a 2 H atoms / unit cell 2 1s AOs / unit cell 2 H atoms / unit cell 2 1s AOs / unit cell

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 1 H atom / unit cell 1 1s AO / unit cell 2 a 2 H atoms / unit cell 2 1s AOs / unit cell   2 H atoms / unit cell 2 1s AOs / unit cell 2 1 2 Energy Matrix (Hamiltonian Matrix):

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 2 a 1 = 2   No Distortion 2 1 2 Half-filled Band is unstable with respect to a Peierls Distortion: Electronically-driven

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 2 a 1 = 2   2 1 2 “Band Folding”

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 Polyacetylene Metallic

Hand-Outs: 24 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 Polyacetylene Metallic Semiconducting

Hand-Outs: 25 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 -Bands 11 valence e 10 valence e

Hand-Outs: 25 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 4 orbitals (BC *) -Bands 11 valence e 10 valence e 10 orbitals (BC , ) 2 orbitals (C 2s)

Hand-Outs: 25 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 YBC -Bands 11 valence e 10 valence e

Hand-Outs: 25 IV. Electronic Structure and Chemical Bonding Peierls Distortion J.K. Burdett, Chemical Bonding in Solids, Ch. 2 ThBC -Bands 11 valence e 10 valence e

Molecular Orbital Theory

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