Campus Units

Physics and Astronomy, Mathematics, Ames Laboratory

Document Type

Article

Publication Version

Published Version

Publication Date

1986

Journal or Book Title

The Journal of Chemical Physics

Volume

85

First Page

5991

Last Page

6003

DOI

10.1063/1.451513

Abstract

A two‐Hilbert space formalism is first used to develop a general class of representations for the quantum mechanics of N‐particle reactive systems. Here the N‐particle Hilbert space HN is supplemented by a larger arrangement channel space CN of vectors with Hilbert space valued components for each N‐particle clustering, and an injection mapping of HN vectors into ‘‘physical’’ CNvectors. Such representations, for which components of the latter vectors carry an appropriate physical clustering interpretation, provide a rigorous and flexible basis for describing the statistical mechanics of reactive fluids, where atoms and molecules are treated on an equal footing (the molecular picture). Corresponding equilibrium multispecies fugacity or virial expansions follow immediately. Here we focus on analysis of the (previously derived) arrangement channel BBGKY hierarchy for a system where recombination and dissociation,as well as exchange reactions, occur. This formulation (coupled with a corresponding scattering theory) automatically suggests a reactive Boltzmannansatz which incorporates (standard) noninteracting asymptotic dynamics onlyfor two‐molecule nonreactive and reactive exchange collisions. In contrast, e.g., with three molecule recombination, two‐molecule dynamics for all three pairs is included (as required for a description of recombination via gradual stabilization of metastables). Finally we compare the resulting reduced form of appropriate channel space hierarchy equations, for a process involving dimer formation and decay, with the corresponding kinetic equations of Lowry and Snider.

Comments

This article is published as Evans, J. W. "Two‐Hilbert space formulations of the quantum statistical mechanics of reactive fluids: Dimer formation and decay." The Journal of chemical physics 85, no. 10 (1986): 5991-6003, doi:10.1063/1.451513. Posted with permission.

Copyright Owner

American Institute of Physics

Language

en

File Format

application/pdf

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