Unimolecular Rates Due to Multiple Critical Oscillators

1 December 1961

journal article
research article
Published by AIP Publishing in The Journal of Chemical Physics

Vol. 35 (6) , 2117-2122
https://doi.org/10.1063/1.1732217

Abstract

In the first part it is shown that Kassel's quantum model differs appreciably from the classical model in the description of the unimolecular pressure falloff behavior. In the second part the quantum model is extended to encompass dissociation by the accumulation of energy in several critical oscillators. The specific rate constant for molecules with energy E is developed along with the limiting high and low pressure rate constants, as well as the concomitant activation energy expressions. The approximations of the classical theory are indicated by comparisons of the relevant quantum and classical formulations.

Keywords

This publication has 13 references indexed in Scilit:

The Kinetics of the Homogeneous Gas Phase Thermal Decomposition of Ozone¹
Journal of the American Chemical Society, 1960
SIMULTANEOUS REACTION COÖRDINATES IN TRANSITION STATE THEORY
The Journal of Physical Chemistry, 1960
AN EXTENSION OF SLATER'S HIGH PRESSURE UNIMOLECULAR RATE EXPRESSION TO SIMULTANEOUS REACTION COÖRDINATES¹
The Journal of Physical Chemistry, 1960
Arrhenius factors (frequency factors) in unimolecular reactions
Quarterly Reviews, Chemical Society, 1960
High Frequency Factors in Unimolecular Reactions
The Journal of Chemical Physics, 1959
Some aspects of the theory of unimolecular gas reactions
Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1959
Kinetics of Reactions in Gases
Annual Review of Physical Chemistry, 1957
The Kinetics of the Recombination of Methyl Radicals and Iodine Atoms.
The Journal of Physical Chemistry, 1951
Kinetics of the Thermal Isomerization of Cyclopropane
Journal of the American Chemical Society, 1934
Studies in Homogeneous Gas Reactions. II. Introduction of Quantum Theory
The Journal of Physical Chemistry, 1928