Georgios G. Vogiatzis, Lambèrt C. A. van Breemen, Markus Hütter and Doros N. Theodorou
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引用次数: 1
摘要
提出了一种非平衡模拟方法,用于跟踪玻璃系统(或任何其他可以通过离散状态网络上的跳变动力学来描述的系统)的时间演化。利用图论和复杂性概念,以及马尔可夫网络的动态集成方法(G. C. Boulougouris和D. N. Theodorou, J. Chem)。理论物理。, 2007, 127, 084903),以便为处理非遍历系统的长时间尺度提供一个统一的框架。在发达的形式主义中,系统可访问的状态网络被认为是整个宇宙的有限部分,通过定义良好的边界状态与之通信。概率平衡方程的解析解无需假设网络状态之间存在平衡分布,并定义了相应的生存概率和逃逸概率(作为时间的函数)。更重要的是,通过分离系统及其环境的划分面对概率通量的研究揭示了系统的松弛机制。我们将我们的方法应用于通过探索无规聚苯乙烯的原子细节玻璃样品的能量景观而获得的状态网络。利用多维过渡状态理论计算了景观不同流域之间的速率常数。我们能够精确地探测δ-和γ-玻璃下弛豫机制的外观及其相关的时间尺度,而不是原子模拟。所提出的方法可以填补理性分子设计工具箱中的空白,为玻璃和/或其他涉及非常遥远时间尺度的缓慢分子过程(例如吸附或解吸)提供分子动力学的替代方案。
Network dynamics: a computational framework for the simulation of the glassy state
An out-of-equilibrium simulation method for tracking the time evolution of glassy systems (or any other systems that can be described by hopping dynamics over a network of discrete states) is presented. Graph theory and complexity concepts are utilised, alongside the method of the dynamical integration of a Markovian web (G. C. Boulougouris and D. N. Theodorou, J. Chem. Phys., 2007, 127, 084903) in order to provide a unified framework for dealing with the long time-scales of non-ergodic systems. Within the developed formalism, the network of states accessible to the system is considered a finite part of the overall universe, communicating with it through well-defined boundary states. The analytical solution of the probability balance equation proceeds without the need for assuming the existence of an equilibrium distribution among the states of the network and the corresponding survival and escape probabilities (as functions of time) are defined. More importantly, the study of the probability flux through the dividing surface separating the system and its environment reveals the relaxation mechanisms of the system. We apply our approach to the network of states obtained by exploring the energy landscape of an atomistically detailed glassy specimen of atactic polystyrene. The rate constants connecting different basins of the landscape are evaluated by multi-dimensional transition-state-theory. We are able to accurately probe the appearance of the δ- and γ-subglass relaxation mechanisms and their relevant time-scales, out of atomistic simulations. The proposed approach can fill a gap in the rational molecular design toolbox, by providing an alternative to molecular dynamics for structural relaxation in glasses and/or other slow molecular processes (e.g., adsorption or desorption) that involve very distant time-scales.
期刊介绍:
Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.