Issue 25, 2013

Modeling of high-order terms in potential energy surface expansions using the reference-geometry Harris–Foulkes method

Abstract

The reference-geometry Harris–Foulkes (RGHF) approach has been used to model high-order terms within the expansion of multi-dimensional potential energy surfaces (PES) as needed within the calculation of accurate vibrational frequencies beyond the harmonic approximation. The key step of this method is a localization of the electron density to the atoms of the molecule at a given reference structure and a subsequent transfer of these atom-centered partial densities to the atom positions of distorted structures. This concept has been used to evaluate the 3-mode coupling terms of a multi-mode expansion of the PES as arising in the Watson Hamiltonian. Systematic benchmark calculations for vibrational frequencies obtained from vibrational configuration interaction (VCI) theory have been performed in order to study the effects of this approximation on the fundamental modes of a test suite of 28 molecules.

Graphical abstract: Modeling of high-order terms in potential energy surface expansions using the reference-geometry Harris–Foulkes method

Article information

Article type
Paper
Submitted
14 Jan 2013
Accepted
20 Feb 2013
First published
21 Feb 2013

Phys. Chem. Chem. Phys., 2013,15, 10233-10240

Modeling of high-order terms in potential energy surface expansions using the reference-geometry Harris–Foulkes method

P. Meier, G. Bellchambers, J. Klepp, F. R. Manby and G. Rauhut, Phys. Chem. Chem. Phys., 2013, 15, 10233 DOI: 10.1039/C3CP50172H

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