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从复杂动力学中识别简单反应坐标。

Identification of simple reaction coordinates from complex dynamics.

作者信息

McGibbon Robert T, Husic Brooke E, Pande Vijay S

机构信息

Department of Chemistry, Stanford University, Stanford, California 94305, USA.

出版信息

J Chem Phys. 2017 Jan 28;146(4):044109. doi: 10.1063/1.4974306.

DOI:10.1063/1.4974306
PMID:28147508
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5272828/
Abstract

Reaction coordinates are widely used throughout chemical physics to model and understand complex chemical transformations. We introduce a definition of the natural reaction coordinate, suitable for condensed phase and biomolecular systems, as a maximally predictive one-dimensional projection. We then show that this criterion is uniquely satisfied by a dominant eigenfunction of an integral operator associated with the ensemble dynamics. We present a new sparse estimator for these eigenfunctions which can search through a large candidate pool of structural order parameters and build simple, interpretable approximations that employ only a small number of these order parameters. Example applications with a small molecule's rotational dynamics and simulations of protein conformational change and folding show that this approach can filter through statistical noise to identify simple reaction coordinates from complex dynamics.

摘要

反应坐标在整个化学物理领域被广泛用于对复杂化学转化进行建模和理解。我们引入了一种适用于凝聚相和生物分子系统的自然反应坐标的定义,将其作为一种具有最大预测性的一维投影。然后我们表明,这一标准由与系综动力学相关的积分算子的一个主导本征函数唯一满足。我们为这些本征函数提出了一种新的稀疏估计器,它可以在大量结构序参的候选池中进行搜索,并构建仅使用少量这些序参的简单、可解释的近似。对小分子旋转动力学以及蛋白质构象变化和折叠模拟的示例应用表明,这种方法可以滤除统计噪声,从复杂动力学中识别出简单的反应坐标。

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