Impact of Temperature and Non-Gaussian Statistics on Electron Transfer in Donor–Bridge–Acceptor Molecules

A combination of experimental data and theoretical analysis provides evidence of a bell-shaped kinetics of electron transfer in the Arrhenius coordinates ln k vs 1/T. This kinetic law is a temperature analogue of the familiar Marcus bell-shaped dependence based on ln k vs the reaction free energy. T...

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Bibliographic Details
Published in:The journal of physical chemistry. B 2017-03, Vol.121 (12), p.2665-2676
Main Authors: Waskasi, Morteza M, Newton, Marshall D, Matyushov, Dmitry V
Format: Article
Language:English
Subjects:
Arrhenius coordinates
BASIC BIOLOGICAL SCIENCES
bell-shaped kinetic law
electron transfer
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
polar solvation
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Summary:A combination of experimental data and theoretical analysis provides evidence of a bell-shaped kinetics of electron transfer in the Arrhenius coordinates ln k vs 1/T. This kinetic law is a temperature analogue of the familiar Marcus bell-shaped dependence based on ln k vs the reaction free energy. These results were obtained for reactions of intramolecular charge shift between the donor and acceptor separated by a rigid spacer studied experimentally by Miller and co-workers. The non-Arrhenius kinetic law is a direct consequence of the solvent reorganization energy and reaction driving force changing approximately as hyperbolic functions with temperature. The reorganization energy decreases and the driving force increases when temperature is increased. The point of equality between them marks the maximum of the activationless reaction rate. Reaching the consistency between the kinetic and thermodynamic experimental data requires the non-Gaussian statistics of the donor–acceptor energy gap described by the Q-model of electron transfer. The theoretical formalism combines the vibrational envelope of quantum vibronic transitions with the Q-model describing the classical component of the Franck–Condon factor and a microscopic solvation model of the solvent reorganization energy and the reaction free energy.
ISSN:1520-6106
1520-5207
DOI:10.1021/acs.jpcb.7b00140