Mesoscopic Kinetic Basis of Macroscopic Chemical Thermodynamics: A Mathematical Theory

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→∞. 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 ss() where =(x1,·s,xN) are the concentrations of the N chemical species. The macroscopic chemical dynamics (t) satisfies two emergent laws: (1) (/ t)ss[(t)] 0, and (2)(/ t)ss[(t)]=cmf()-σ() where entropy production rate σ 0 represents the sink for the chemical energy, and chemical motive force cmf 0 is non-zero if the system is driven under a sustained nonequilibrium chemostat. For systems with detailed balance cmf=0, and if one assumes the law of mass action,ss() is precisely the Gibbs' function Σi=1N xi[μio+ xi] 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 ss(), with global minimum at *, has the generic form Σi=1N xi[(xi/xi*)-xi+xi*],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.