Stochastic Dynamical Structure (SDS) of Nonequilibrium Processes in the Absence of Detailed Balance. III: potential function in local stochastic dynamics and in steady state of Boltzmann-Gibbs type distribution function

TL;DR

This paper rigorously establishes the existence of a potential function in general nonequilibrium stochastic processes without detailed balance, linking local dynamics and steady-state distributions, and introduces a formula for noise-induced drift shifts.

Contribution

It provides a rigorous proof of the potential function's existence in nonequilibrium systems and a method to derive stochastic differential equations from Fokker-Planck equations without requiring detailed balance.

Findings

Existence of a potential function in general nonequilibrium processes is proven.

A formula for noise-induced drift shift is derived.

Comparison with Ito and Stratonovich interpretations is discussed.

Abstract

From a logic point of view this is the third in the series to solve the problem of absence of detailed balance. This paper will be denoted as SDS III. The existence of a dynamical potential with both local and global meanings in general nonequilibrium processes has been controversial. Following an earlier explicit construction by one of us (Ao, J. Phys. {\bf A37}, L25 '04, arXiv:0803.4356, referred to as SDS II), in the present paper we show rigorously its existence for a generic class of situations in physical and biological sciences. The local dynamical meaning of this potential function is demonstrated via a special stochastic differential equation and its global steady-state meaning via a novel and explicit form of Fokker-Planck equation, the zero mass limit. We also give a procedure to obtain the special stochastic differential equation for any given Fokker-Planck equation. No detailed balance condition is required in our demonstration. For the first time we obtain here a formula to describe the noise induced shift in drift force comparing to the steady state distribution, a phenomenon extensively observed in numerical studies. The comparison to two well known stochastic integration methods, Ito and Stratonovich, are made ready. Such comparison was made elsewhere (Ao, Phys. Life Rev. {\bf 2} (2005) 117. q-bio/0605020).