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JOURNALS // Regular and Chaotic Dynamics // Archive

Regul. Chaotic Dyn., 2020 Volume 25, Issue 5, Pages 453–475 (Mi rcd1077)

This article is cited in 4 papers

The Role of Depth and Flatness of a Potential Energy Surface in Chemical Reaction Dynamics

Wenyang Lyu, Shibabrat Naik, Stephen Wiggins

School of Mathematics, University of Bristol, Fry Building, Woodland Road, BS8 1UG Bristol, United Kingdom

Abstract: In this study, we analyze how changes in the geometry of a potential energy surface in terms of depth and flatness can affect the reaction dynamics.We formulate depth and flatness in the context of one and two degree-of-freedom (DOF) Hamiltonian normal form for the saddlenode bifurcation and quantify their influence on chemical reaction dynamics [1, 2]. In a recent work, García-Garrido et al. [2] illustrated how changing the well-depth of a potential energy surface (PES) can lead to a saddle-node bifurcation. They have shown how the geometry of cylindrical manifolds associated with the rank-1 saddle changes en route to the saddle-node bifurcation. Using the formulation presented here, we show how changes in the parameters of the potential energy control the depth and flatness and show their role in the quantitative measures of a chemical reaction. We quantify this role of the depth and flatness by calculating the ratio of the bottleneck width and well width, reaction probability (also known as transition fraction or population fraction), gap time (or first passage time) distribution, and directional flux through the dividing surface (DS) for small to high values of total energy. The results obtained for these quantitative measures are in agreement with the qualitative understanding of the reaction dynamics.

Keywords: Hamiltonian dynamics, bifurcation theory, phase space methods.

MSC: 37J05,37J15,37J20,34C23,70H05,37G05

Received: 26.04.2020
Accepted: 09.09.2020

Language: English

DOI: 10.1134/S1560354720050044



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