A MODEL FOR THE HYDROGEN BOND AND PROTON TRANSFER REACTIONS
Open Access
- 1 August 1964
- journal article
- Published by Canadian Science Publishing in Canadian Journal of Chemistry
- Vol. 42 (8) , 1822-1834
- https://doi.org/10.1139/v64-274
Abstract
A simple extension of Platt's model for determining the force constants in diatomic hydrides is used to investigate the properties of transition states for proton transfer reactions. The model is first tested by comparing the predicted and observed changes in bond lengths and stretching and bending frequencies for [Formula: see text] systems. The quantities predicted for the transition state are the geometry and the perpendicular bending frequencies. The implications of the results with regard to the interpretation of hydrogen–deuterium kinetic isotope effects are discussed. In particular, the variations in both the isotope effect and the geometry of the transition state with changing acid or base strength are considered in detail.Keywords
This publication has 9 references indexed in Scilit:
- Theoretical Interpretation of Force ConstantsThe Journal of Chemical Physics, 1963
- Evaluation of Molecular Integrals by Solid Spherical Harmonic ExpansionsThe Journal of Chemical Physics, 1962
- The forces between polyatomic molecules. II. Short-range repulsive forcesProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1961
- The Magnitude of the Primary Kinetic Isotope Effect for Compounds of Hydrogen and Deuterium.Chemical Reviews, 1961
- Use of Substituent Effects on Isotope Effects to Distinguish between Proton and Hydride Transfers. Part I. Mechanism of Oxidation of Alcohols by Bromine in Water1-3Journal of the American Chemical Society, 1961
- Transition states and isotope effects in proton-transfer reactionsTransactions of the Faraday Society, 1961
- Classical Partition Functions for Transition State Theory. Chlorine Atom ReactionsJournal of the American Chemical Society, 1957
- The dynamics of binary hydridesJournal of Inorganic and Nuclear Chemistry, 1955
- Prediction of Interatomic Distances and Force Constants in Diatomic HydridesThe Journal of Chemical Physics, 1950