Reaction kinetics of non-localised particle-trap complexes

A. V. Barashev; S. I. Golubov; Yu N. Osetsky; R. E. Stoller

doi:10.1080/14786430903190825

Reaction kinetics of non-localised particle-trap complexes

A. V. Barashev, S. I. Golubov, Yu N. Osetsky, R. E. Stoller

Multiscale Modeling & Materials by Desig

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

The classical transition state theory for calculating complex dissociation rates requires separation of time scales. It is shown here that this condition is satisfied for complexes with long-range interaction, such as an edge dislocation and a cluster of self-interstitial atoms in metallic materials. Hence, one can apply the equations for first-order reactions with a rescaled mean dissociation time and the cross-section of complex formation. The rescaling coefficient is the Eyring transmission coefficient. A general expression for this coefficient through the first two moments of the distribution function of dissociation times is derived. It is shown that it is equal to unity if the dividing surface between 'bound' and 'free' states is defined as that where the interaction energy is equal to the thermal energy.

Original language	English
Pages (from-to)	897-906
Number of pages	10
Journal	Philosophical Magazine
Volume	90
Issue number	7-8
DOIs	https://doi.org/10.1080/14786430903190825
State	Published - Mar 2010

Funding

AVB acknowledges a research grant from the UK Engineering and Physical Sciences Research Council. Research at ORNL was sponsored by the Division on Materials Sciences and Engineering (RES and YNO) and the Office of Fusion Energy Sciences (SIG), US Department of Energy, under contract no. DE-AC05-00OR22 725 with UT-Battelle, LLC.

Keywords

Complexes
Dissociation reactions
Edge dislocations
Metals
Transition state theory

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10.1080/14786430903190825

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AU - Barashev, A. V.

AU - Golubov, S. I.

AU - Osetsky, Yu N.

AU - Stoller, R. E.

PY - 2010/3

Y1 - 2010/3

N2 - The classical transition state theory for calculating complex dissociation rates requires separation of time scales. It is shown here that this condition is satisfied for complexes with long-range interaction, such as an edge dislocation and a cluster of self-interstitial atoms in metallic materials. Hence, one can apply the equations for first-order reactions with a rescaled mean dissociation time and the cross-section of complex formation. The rescaling coefficient is the Eyring transmission coefficient. A general expression for this coefficient through the first two moments of the distribution function of dissociation times is derived. It is shown that it is equal to unity if the dividing surface between 'bound' and 'free' states is defined as that where the interaction energy is equal to the thermal energy.

AB - The classical transition state theory for calculating complex dissociation rates requires separation of time scales. It is shown here that this condition is satisfied for complexes with long-range interaction, such as an edge dislocation and a cluster of self-interstitial atoms in metallic materials. Hence, one can apply the equations for first-order reactions with a rescaled mean dissociation time and the cross-section of complex formation. The rescaling coefficient is the Eyring transmission coefficient. A general expression for this coefficient through the first two moments of the distribution function of dissociation times is derived. It is shown that it is equal to unity if the dividing surface between 'bound' and 'free' states is defined as that where the interaction energy is equal to the thermal energy.

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KW - Edge dislocations

KW - Metals

KW - Transition state theory

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Reaction kinetics of non-localised particle-trap complexes

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