Kinetic isotope effects in the reaction between atomic chlorine and molecular hydrogen. Tunnel coefficients of the hydrogen atom through an asymmetric potential barrier

Avigdor Persky, Fritz S. Klein

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Abstract

Kinetic isotope effects for the reactions between atomic chlorine and molecular hydrogen have been measured in the range of -30° to +70°C. The following expressions were obtained: chemical equation presented has been redetermined and found to agree with previous measurements. Theoretical calculations of these isotope effects, using (1) a Sato model, (2) a generalized Sato model, and (3) the Johnston-Parr method, were made to compare the calculated effects with experimental results. Tunnel corrections were applied using (1) an asymmetric Eckart barrier, or (2) the Johnston-Rapp method with an asymmetric barrier. Best agreement (within 15%) of calculated values with experiment was obtained for a generalized Sato model including Johnston-Rapp tunnel corrections. Empirical sets of four force constants describing the transition state H-H-Cl are also given. These are used to calculate isotope effects which are in excellent agreement with experimental values.

Original languageEnglish
Pages (from-to)3617-3626
Number of pages10
JournalJournal of Chemical Physics
Volume44
Issue number9
DOIs
StatePublished - 1966
Externally publishedYes

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