Related papers: Simulating and investigating various dynamic aspects of $\rm{H}

Simulating and investigating various dynamic aspects of $\rm{H}_2\rm{O}$-related hydrogen bond model

URL: http://arxiv.org/abs/2410.15121v1
Date: Sat, 19 Oct 2024 14:29:01 GMT
Title: Simulating and investigating various dynamic aspects of $\rm{H}_2\rm{O}$-related hydrogen bond model
Authors: Jiangchuan You, Ran Chen, Wanshun Li, Hui-hui Miao, Yuri Igorevich Ozhigov,
Abstract summary: The formation and breaking processes of hydrogen bond are accompanied by the creation and annihilation of the thermal phonon of the medium. The magnitude changes of the interactions and dissipations have slight effect on the formation of hydrogen bond, but the variation of the reverse processes of dissipations significantly affect the formation of hydrogen bond.
Score: 2.067188682696963
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Abstract: A simple $\rm{H}_2\rm{O}$-related hydrogen bond model, modified from the Jaynes-Cummings model, is proposed and its various dynamic aspects are investigated theoretically. In this model, the formation and breaking processes of hydrogen bond are accompanied by the creation and annihilation of the thermal phonon of the medium. A number of simplifying assumptions about the dynamics of the molecules involved are used. Rotating wave approximation is applied under consideration of the strong-coupling condition. Dissipative dynamics under the Markovian approximation is obtained through solving the quantum master equation - Lindbladian. The probabilities of reaction channels involving hydrogen bond depending on the parameters of the external environment, are obtained. Differences between unitary and dissipative evolutions are disciussed. Consideration is given to the effect of all kinds of potential interactions and dissipations on evolution. Consideration is also given to the reverse processes (inflows) of dissipations. The results show that the magnitude changes of the interactions and dissipations have slight effect on the formation of hydrogen bond, but the variation of the reverse processes of dissipations significantly affect the formation of hydrogen bond. According to the findings, the dynamics of $\rm{H}_2\rm{O}$-related hydrogen bond model can be controlled by selectively choosing system parameters. The results will be used as a basis to extend the research to more complex chemical and biological model in the future.

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