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A Two Transition State Model for Radical−Molecule Reactions:  A Case Study of the Addition of OH to C2H4

A two transition state model is applied to the study of the addition of hydroxyl radical to ethylene. This reaction serves as a prototypical example of a radical−molecule reaction with a negative activation energy in the high-pressure limit. The model incorporates variational treatments of both inne...

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Bibliographic Details
Published in:The journal of physical chemistry. A, Molecules, spectroscopy, kinetics, environment, & general theory Molecules, spectroscopy, kinetics, environment, & general theory, 2005-07, Vol.109 (27), p.6031-6044
Main Authors: Greenwald, Erin E, North, Simon W, Georgievskii, Yuri, Klippenstein, Stephen J
Format: Article
Language:English
Online Access:Get full text
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Summary:A two transition state model is applied to the study of the addition of hydroxyl radical to ethylene. This reaction serves as a prototypical example of a radical−molecule reaction with a negative activation energy in the high-pressure limit. The model incorporates variational treatments of both inner and outer transition states. The outer transition state is treated with a recently derived long-range transition state theory approach focusing on the longest-ranged term in the potential. High-level quantum chemical estimates are incorporated in a variational transition state theory treatment of the inner transition state. Anharmonic effects in the inner transition state region are explored with direct phase space integration. A two-dimensional master equation is employed in treating the pressure dependence of the addition process. An accurate treatment of the two separate transition state regions at the energy and angular momentum resolved level is essential to the prediction of the temperature dependence of the addition rate. The transition from a dominant outer transition state to a dominant inner transition state is predicted to occur at about 130 K, with significant effects from both transition states over the 10 to 400 K temperature range. Modest adjustment in the ab initio predicted inner saddle point energy yields theoretical predictions which are in quantitative agreement with the available experimental observations. The theoretically predicted capture rate is reproduced to within 10% by the expression [4.93 × 10-12 (T/298)-2.488 exp(−107.9/RT) + 3.33 × 10-12 (T/298)0.451 exp(117.6/RT); with R = 1.987 and T in K] cm3 molecules-1 s-1 over the 10−600 K range.
ISSN:1089-5639
1520-5215
DOI:10.1021/jp058041a