Effective Kinetics of Chemical Reaction Networks

Tomoharu Suda
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Abstract

Chemical reaction network theory is a powerful framework to describe and analyze chemical systems. While much about the concentration profile in an equilibrium state can be determined in terms of the graph structure, the overall reaction's time evolution depends on the network's kinetic rate function. In this article, we consider the problem of the effective kinetics of a chemical reaction network regarded as a conversion system from the feeding species to products. We define the notion of effective kinetics as a partial solution of a system of non-autonomous ordinary differential equations determined from a chemical reaction network. Examples of actual calculations include the Michaelis-Menten mechanism, for which it is confirmed that our notion of effective kinetics yields the classical formula. Further, we introduce the notion of straight-line solutions of non-autonomous ordinary differential equations to formalize the situation where a well-defined reaction rate exists and consider its relation with the quasi-stationary state approximation used in microkinetics. Our considerations here give a unified framework to formulate the reaction rate of chemical reaction networks.
化学反应网络的有效动力学
化学反应网络理论是描述和分析化学系统的强大框架。平衡状态下的浓度分布可以根据图结构确定,而整个反应的时间演化则取决于网络的动力学速率函数。在本文中,我们将化学反应网络视为一个从原料到产物的转化系统,考虑其有效动力学问题。我们将有效动力学的概念定义为由化学反应网络确定的非自治常微分方程系统的部分解。实际计算的例子包括 Michaelis-Menten 机理,对该机理的研究证实,我们的有效动力学运动可以得到经典公式。此外,我们还引入了非自治常微分方程直线解的概念,将存在定义明确的反应速率的情况正规化,并考虑了它与微动力学中使用的准稳态近似的关系。我们在这里的考虑为化学反应网络的反应速率提供了一个统一的表述框架。
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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