Evolution of Coagulation-Fragmentation Stochastic Processes Using Accurate Chemical Master Equation Approach.

IF 0.6 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS
Farid Manuchehrfar, Wei Tian, Tom Chou, Jie Liang
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引用次数: 0

Abstract

Coagulation and fragmentation (CF) is a fundamental process in which smaller particles attach to each other to form larger clusters while existing clusters break up into smaller particles . It is a ubiquitous process that plays important roles in many physical and biological phenomena. CF is typically a stochastic process that often occurs in confined spaces with a limited number of available particles . Here, we study the CF process formulated with the discrete Chemical Master Equation (dCME). Using the newly developed Accurate Chemical Master Equation (ACME) method, we examine the time-dependent behavior of the CF system. We investigate the effects of a number of important factors that influence the overall behavior of the system, including the dimensionality, the ratio of attachment to detachment rates among clusters, and the initial conditions. By comparing CF in one and three dimensions, we conclude that systems in three dimensions are more likely to form large clusters. We also demonstrate how the ratio of the attachment to detachment rates affects the dynamics and the steady-state of the system. Finally, we demonstrate the relationship between the formation of large clusters and the initial condition.

Abstract Image

Abstract Image

Abstract Image

基于精确化学主方程方法的凝固-破碎随机过程演化。
凝聚和破碎(CF)是一个基本的过程,在这个过程中,较小的颗粒相互附着形成较大的团簇,而现有的团簇则分解成较小的颗粒。它是一个无处不在的过程,在许多物理和生物现象中起着重要作用。CF通常是一个随机过程,通常发生在有限数量的可用粒子的密闭空间中。在这里,我们研究了用离散化学主方程(dCME)表示的CF过程。使用新开发的精确化学主方程(ACME)方法,我们研究了CF系统的时间依赖行为。我们研究了影响系统整体行为的一些重要因素的影响,包括维数、簇间的附着率和分离率的比率以及初始条件。通过比较一维和三维的CF,我们得出结论,三维的系统更有可能形成大的集群。我们还演示了附着率与分离率的比值如何影响系统的动力学和稳态。最后,我们证明了大簇的形成与初始条件之间的关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Communications in Information and Systems
Communications in Information and Systems COMPUTER SCIENCE, INFORMATION SYSTEMS-
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