Complex Fluid Models of Mixed Quantum–Classical Dynamics

IF 2.6 2区 数学 Q1 MATHEMATICS, APPLIED Journal of Nonlinear Science Pub Date : 2024-07-02 DOI:10.1007/s00332-024-10044-4
François Gay-Balmaz, Cesare Tronci
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Abstract

Several methods in nonadiabatic molecular dynamics are based on Madelung’s hydrodynamic description of nuclear motion, while the electronic component is treated as a finite-dimensional quantum system. In this context, the quantum potential leads to severe computational challenges and one often seeks to neglect its contribution, thereby approximating nuclear motion as classical. The resulting model couples classical hydrodynamics for the nuclei to the quantum motion of the electronic component, leading to the structure of a complex fluid system. This type of mixed quantum–classical fluid models has also appeared in solvation dynamics to describe the coupling between liquid solvents and the quantum solute molecule. While these approaches represent a promising direction, their mathematical structure requires a certain care. In some cases, challenging higher-order gradients make these equations hardly tractable. In other cases, these models are based on phase-space formulations that suffer from well-known consistency issues. Here, we present a new complex fluid system that resolves these difficulties. Unlike common approaches, the current system is obtained by applying the fluid closure at the level of the action principle of the original phase-space model. As a result, the system inherits a Hamiltonian structure and retains energy/momentum balance. After discussing some of its structural properties and dynamical invariants, we illustrate the model in the case of pure-dephasing dynamics. We conclude by presenting some invariant planar models.

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量子-经典混合动力学的复杂流体模型
非绝热分子动力学中的几种方法都是基于马德隆对核运动的流体力学描述,而电子元件则被视为有限维量子系统。在这种情况下,量子势将带来严峻的计算挑战,人们往往试图忽略量子势的贡献,从而将核运动近似为经典运动。由此产生的模型将原子核的经典流体力学与电子元件的量子运动结合起来,从而形成复杂的流体系统结构。这种量子-经典混合流体模型也出现在溶解动力学中,用于描述液体溶剂与量子溶质分子之间的耦合。虽然这些方法代表了一个有前途的方向,但其数学结构需要一定的谨慎。在某些情况下,具有挑战性的高阶梯度使这些方程难以理解。在其他情况下,这些模型基于相空间公式,存在众所周知的一致性问题。在这里,我们提出了一个新的复杂流体系统,解决了这些难题。与常见的方法不同,当前的系统是通过在原始相空间模型的作用原理层面上应用流体封闭而获得的。因此,该系统继承了哈密顿结构,并保持了能量/动量平衡。在讨论了模型的一些结构特性和动力学不变式之后,我们以纯消隐动力学为例对模型进行了说明。最后,我们将介绍一些不变的平面模型。
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来源期刊
CiteScore
5.00
自引率
3.30%
发文量
87
审稿时长
4.5 months
期刊介绍: The mission of the Journal of Nonlinear Science is to publish papers that augment the fundamental ways we describe, model, and predict nonlinear phenomena. Papers should make an original contribution to at least one technical area and should in addition illuminate issues beyond that area''s boundaries. Even excellent papers in a narrow field of interest are not appropriate for the journal. Papers can be oriented toward theory, experimentation, algorithms, numerical simulations, or applications as long as the work is creative and sound. Excessively theoretical work in which the application to natural phenomena is not apparent (at least through similar techniques) or in which the development of fundamental methodologies is not present is probably not appropriate. In turn, papers oriented toward experimentation, numerical simulations, or applications must not simply report results without an indication of what a theoretical explanation might be. All papers should be submitted in English and must meet common standards of usage and grammar. In addition, because ours is a multidisciplinary subject, at minimum the introduction to the paper should be readable to a broad range of scientists and not only to specialists in the subject area. The scientific importance of the paper and its conclusions should be made clear in the introduction-this means that not only should the problem you study be presented, but its historical background, its relevance to science and technology, the specific phenomena it can be used to describe or investigate, and the outstanding open issues related to it should be explained. Failure to achieve this could disqualify the paper.
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