Reaction dynamics through kinetic transition states

The transformation of a system from one state to another is often mediated by a bottleneck in the system's phase space. In chemistry these bottlenecks are known as \emph{transition states} through which the system has to pass in order to evolve from reactants to products. The chemical reactions...

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Veröffentlicht in:	arXiv.org 2013-03
Hauptverfasser:	Çiftçi, Ünver, Waalkens, Holger
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemical reactions Isomers Mathematics - Mathematical Physics Organic chemistry Phase transitions Physics - Chaotic Dynamics Physics - Chemical Physics Physics - Mathematical Physics
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description	The transformation of a system from one state to another is often mediated by a bottleneck in the system's phase space. In chemistry these bottlenecks are known as \emph{transition states} through which the system has to pass in order to evolve from reactants to products. The chemical reactions are usually associated with configurational changes where the reactants and products states correspond, e.g., to two different isomers or the undissociated and dissociated state of a molecule or cluster. In this letter we report on a new type of bottleneck which mediates \emph{kinetic} rather than configurational changes. The phase space structures associated with such \emph{kinetic transition states} and their dynamical implications are discussed for the rotational vibrational motion of a triatomic molecule. An outline of more general related phase space structures with important dynamical implications is given.
doi_str_mv	10.48550/arxiv.1303.3864
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subjects	Chemical reactions Isomers Mathematics - Mathematical Physics Organic chemistry Phase transitions Physics - Chaotic Dynamics Physics - Chemical Physics Physics - Mathematical Physics
title	Reaction dynamics through kinetic transition states
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