The Physical Origins of Entropy Production, Free Energy Dissipation and their Mathematical Representations

Abstract

A complete mathematical theory of nonequilibrium thermodynamics of stochastic systems in terms of master equations is presented. As generalizations of isothermal entropy and free energy, two functions of states play central roles: the Gibbs entropy S and the relative entropy F, which are related via the stationary distribution of the stochastic dynamics. S satisfies the fundamental entropy balance equation dS/dt=ep-hd/T with entropy production rate ep 0 and heat dissipation rate hd, while dF/dt=-fd 0. For closed systems that satisfy detailed balance: Tep(t)=fd(t). For open system one has Tep(t)=fd(t)+Qhk(t) where the housekeeping heat Qhk 0 was first introduced in the phenomenological nonequilibrium steady state thermodynamics. Entropy production ep consists of free energy dissipation associated with spontaneous relaxation, fd, and active energy pumping that sustains the open system Qhk. The amount of excess heat involved in the relaxation Qex=hd-Qhk = fd-T(dS/dt).