Generalized free energy and excess entropy production for active systems

Abstract: We propose a generalized free energy potential for active systems, including both stochastic master equations and deterministic nonlinear chemical reaction networks. Our generalized free energy is defined variationally as the "most irreversible" state observable. This variational principle is motivated from several perspectives, including large deviations theory, thermodynamic uncertainty relations, Onsager theory, and information-theoretic optimal transport. In passive systems, the most irreversible observable is the usual free energy potential and its irreversibility is the entropy production rate (EPR). In active systems, the most irreversible observable is the generalized free energy and its irreversibility gives the excess EPR, the nonstationary contribution to dissipation. The remaining "housekeeping" EPR is a genuine nonequilibrium contribution that quantifies the nonconservative nature of the forces. We derive far-from-equilibrium thermodynamic speed limits for excess EPR, applicable to both linear and nonlinear systems. Our approach overcomes several limitations of the steady-state potential and the Hatano-Sasa (adiabatic/nonadiabatic) decomposition, as we demonstrate in several examples.