Communication: transition state theory for dissipative systems without a dividing surface

Revuelta, F.; Benito, Rosa María; Borondo, Florentino; Bartsch, Thomas

UAM_Biblioteca

Author

Revuelta, F.; Benito, Rosa María; Borondo, Florentino

; Bartsch, Thomas

Entity

UAM. Departamento de Química

Publisher

American Institute of Physics

Date

2012-03-02

Citation

Journal of Chemical Physics 136.9 (2012): 091102

ISSN

0021-9606 (print); 1089-7690 (online)

DOI

10.1063/1.3692182

Funded by

Support from MICINN–Spain under Contract Nos. MTM2009–14621 and i–MATH CSD2006–32 is gratefully acknowledged

Editor's Version

http://dx.doi.org/10.1063/1.3692182

Subjects

Química

URI

http://hdl.handle.net/10486/663798

Note

The following article appeared in Journal of Chemical Physics 136.9 (2012): 091102 and may be found at http://scitation.aip.org/content/aip/journal/jcp/136/9/10.1063/1.3692182

Rights

Abstract

Transition state theory is a central cornerstone in reaction dynamics. Its key step is the identification of a dividing surface that is crossed only once by all reactive trajectories. This assumption is often badly violated, especially when the reactive system is coupled to an environment. The calculations made in this way then overestimate the reaction rate and the results depend critically on the choice of the dividing surface. In this Communication, we study the phase space of a stochastically driven system close to an energetic barrier in order to identify the geometric structure unambiguously determining the reactive trajectories, which is then incorporated in a simple rate formula for reactions in condensed phase that is both independent of the dividing surface and exact

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