Litcius/Paper detail

Thermodynamics of Active Field Theories: Energetic Cost of Coupling to Reservoirs

Tomer Markovich, Étienne Fodor, Elsen Tjhung, Michael E. Cates

2021Physical Review X48 citationsDOIOpen Access PDF

Abstract

The hallmark of active matter is the autonomous directed motion of its microscopic constituents driven by consumption of energy resources. This motion leads to the emergence of large-scale dynamics and structures without any equilibrium equivalent. Though active field theories offer a useful hydrodynamic description, it is unclear how to properly quantify the energetic cost of the dynamics from such a coarsegrained description. We provide a thermodynamically consistent framework to identify the energy exchanges between active systems and their surrounding thermostat at the hydrodynamic level. Based on linear irreversible thermodynamics, we determine how active fields couple with the underlying reservoirs at the basis of nonequilibrium driving. This approach leads to evaluating the rate of heat dissipated in the thermostat, as a measure of the cost to sustain the system away from equilibrium, which is related to the irreversibility of the active field dynamics. We demonstrate the applicability of our approach in two popular active field theories: (i) the dynamics of a conserved density field reproducing active phase separation and (ii) the coupled dynamics of density and polarization describing motile deformable droplets. Combining numerical and analytical approaches, we provide spatial maps of dissipated heat, compare them with the irreversibility measure of the active field dynamics, and explore how the overall dissipated heat varies with the emerging order.

Topics & Concepts

Active matterThermostatNon-equilibrium thermodynamicsPhysicsField (mathematics)Statistical physicsMeasure (data warehouse)Coupling (piping)DissipationDynamics (music)Classical mechanicsWork (physics)Polarization (electrochemistry)MechanicsPotential energyEnergy (signal processing)Heat transferEquations of motionMicro and Nano RoboticsAdvanced Thermodynamics and Statistical MechanicsQuantum many-body systems