Mesoscopic Kinetic Basis of Macroscopic Chemical Thermodynamics: A Mathematical Theory

TL;DR

This paper develops a mathematical framework showing how macroscopic chemical thermodynamics emerges from mesoscopic kinetic models of complex reactions, applicable to both equilibrium and nonequilibrium systems, with explicit energy functions and laws.

Contribution

It introduces a mesoscopic kinetic model that derives macroscopic thermodynamic laws and energy functions for complex chemical systems, including nonlinear and driven systems.

Findings

Macroscopic laws emerge as system volume increases.

Generalized free energy functions relate to classical thermodynamics.

Applicable to equilibrium and nonequilibrium chemical systems.

Abstract

From a mathematical model that describes a complex chemical kinetic system of $N$ species and $M$ elementrary reactions in a rapidly stirred vessel of size $V$ as a Markov process, we show that a macroscopic chemical thermodynamics emerges as $V\rightarrow\infty$. The theory is applicable to linear and nonlinear reactions, closed systems reaching chemical equilibrium, or open, driven systems approaching to nonequilibrium steady states. A generalized mesoscopic free energy gives rise to a macroscopic chemical energy function $\varphi^{ss}(\vx)$ where $\vx=(x_1,\cdots,x_N)$ are the concentrations of the $N$ chemical species. The macroscopic chemical dynamics $\vx(t)$ satisfies two emergent laws: (1) $(\rd/\rd t)\varphi^{ss}[\vx(t)]\le 0$, and (2)$(\rd/\rd t)\varphi^{ss}[\vx(t)]=\text{cmf}(\vx)-\sigma(\vx)$ where entropy production rate $\sigma\ge 0$ represents the sink for the chemical energy, and chemical motive force $\text{cmf}\ge 0$ is non-zero if the system is driven under a sustained nonequilibrium chemostat. For systems with detailed balance $\text{cmf}=0$, and if one assumes the law of mass action,$\varphi^{ss}(\vx)$ is precisely the Gibbs' function $\sum_{i=1}^N x_i\big[\mu_i^o+\ln x_i\big]$ for ideal solutions. For a class of kinetic systems called complex balanced, which include many nonlinear systems as well as many simple open, driven chemical systems, the $\varphi^{ss}(\vx)$, with global minimum at $\vx^*$, has the generic form $\sum_{i=1}^N x_i\big[\ln(x_i/x_i^*)-x_i+x_i^*\big]$,which has been known in chemical kinetic literature.Macroscopic emergent "laws" are independent of the details of the underlying kinetics. This theory provides a concrete example from chemistry showing how a dynamic macroscopic law can emerge from the kinetics at a level below.