Minimum Action Principle for Entropy Production Rate of Far-From-Equilibrium Systems

TL;DR

This paper develops a variational principle for the entropy production rate in far-from-equilibrium systems, unifying various thermodynamic relations and revealing optimal control protocols that minimize entropy production.

Contribution

It introduces a new variational principle for entropy production in non-equilibrium systems, linking it to transition probabilities and optimal control strategies.

Findings

Derives a non-quadratic dissipation function

Identifies optimal protocols with discontinuous jumps

Provides analytical solutions for finite-time driving

Abstract

The Boltzmann distribution connects the energetics of an equilibrium system with its statistical properties, and it is desirable to have a similar principle for non-equilibrium systems. Here, we derive a variational principle for the entropy production rate (EPR) of far-from-equilibrium discrete state systems, relating it to the action for the transition probability measure of discrete state processes. This principle leads to a tighter, non-quadratic formulation of the dissipation function, speed limits, the thermodynamic-kinetic uncertainty relation, the large deviation rate functional, and the fluctuation relation, all within a unified framework of the thermodynamic length. Additionally, the optimal control of non-conservative transition affinities using the underlying geodesic structure is explored, and the corresponding slow-driving and finite-time optimal driving exact protocols are analytically computed. We demonstrate that discontinuous endpoint jumps in optimal protocols are a generic, model-independent physical mechanism that reduces entropy production during finite-time driving of far-from-equilibrium systems.