The Resonating Valence Bond Model of Molecules and Reactions

Author: Voter, Arthur Ford

Year: 1983

Degree: Dissertation (Ph.D.)

Advisor: Gray, Harry B.

Committee Members: Gray, Harry B.; Goddard, William A., III; Beauchamp, Jesse L.; McKoy, Basil Vincent

Option: Chemistry

DOI: 10.7907/d754-h174

Abstract

This thesis presents an ab initio generalization of Pauling's theory of resonance, the generalized resonating valence bond (GRVB) method. In GRVB, we optimize a wavefunction of the form

Ψ_TOT = C_A Ψ_A + C_B Ψ_B

where Ψ_A and Ψ_B are multiconfigurational wavefunctions with arbitrary overlap. This type of wavefunction has been considered unfeasible for more than a few electrons due to the n! computational dependence of evaluating the matrix element < Ψ_A | H | Ψ_B >. We reduce this dependence to ~n⁵ by biorthogonalizing the orbitals in each determinant pair. GRVB is ideally suited to describing systems which require a resonance of more than one bonding structure, such as benzene, molecules with three-electron bonds, and reaction transition states. Besides yielding a conceptually simple avefunction, we find that GRVB yields quantitative results for processes in which the dominant differential correlation is a resonance effect. For example, the GRVB barrier heights for the HCl + H and HF + H exchange reactions are each within one kcal of the basis set limit, in contrast to the orthogonal configuration interaction (CI) approaches which require hundreds or thousands of configurations to achieve the same accuracy. We also present application to the three-electron bonding in noble gas dimer ions, and various other examples.

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