Nonequilibrium Thermodynamic Formalism of Nonlinear Chemical Reaction Systems with Waage-Guldberg's Law of Mass Action

Abstract

Macroscopic entropy production σ(tot) in the general nonlinear isothermal chemical reaction system with mass action kinetics is decomposed into a free energy dissipation and a house-keeping heat: σ(tot)=σ(fd)+σ(hk); σ(fd)=- A/ t, where A is a generalized free energy function. This yields a novel nonequilibrium free energy balance equation A/ t=-σ(tot)+σ(hk), which is on a par with celebrated entropy balance equation S/ t=σ(tot)+η(ex) where η(ex) is the rate of entropy exchange with the environment.For kinetic systems with complex balance, σ(fd) and σ(hk) are the macroscopic limits of stochastic free energy dissipation and house-keeping heat, which are both nonnegative, in the Delbr\"uck-Gillespie description of the stochastic chemical kinetics.Therefore, we show that a full kinetic and thermodynamic theory of chemical reaction systems that transcends mesoscopic and macroscopic levels emerges.