Quantum mechanical algebraic variational methods for inelastic and reactive molecular collisions

David W. Schwenke; Kenneth Haug; Meishan Zhao; Donald G. Truhlar; Yan Sun; John Z.H. Zhang; Donald J. Kouri

doi:10.1021/j100322a032

Quantum mechanical algebraic variational methods for inelastic and reactive molecular collisions

David W. Schwenke, Kenneth Haug, Meishan Zhao, Donald G. Truhlar, Yan Sun, John Z.H. Zhang, Donald J. Kouri

Chemistry (Twin Cities)

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101 Scopus citations

Abstract

The quantum mechanical problem of reactive or nonreactive scattering of atoms and molecules is formulated in terms of square-integrable (ℒ²) basis sets with variational expressions for the reactance matrix. We present and test several formulations, involving expansions of the wave function (the Schwinger variational principle) or amplitude density (a generalization of the Newton variational principle), single-channel or multichannel distortion potentials, and primitive or contracted basis functions. The test results, for inelastic and reactive atom-diatom collisions, are very encouraging, and we anticipate that the methods will be very useful for a variety of collision calculations and that they will allow the accurate quantal treatment of systems for which other available methods would be prohibitively expensive.

Original language	English (US)
Pages (from-to)	3202-3216
Number of pages	15
Journal	Journal of physical chemistry
Volume	92
Issue number	11
DOIs	https://doi.org/10.1021/j100322a032
State	Published - Jan 1 1988

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AU - Zhao, Meishan

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AU - Sun, Yan

AU - Zhang, John Z.H.

AU - Kouri, Donald J.

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Quantum mechanical algebraic variational methods for inelastic and reactive molecular collisions

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