How far from equilibrium is active matter?
Abstract
Active matter systems are driven out of thermal equilibrium by a lack of generalized Stokes-Einstein relation between injection and dissipation of energy at the microscopic scale. We consider such a system of interacting particles, propelled by persistent noises, and show that, at small but finite persistence time, their dynamics still satisfy a time-reversal symmetry. To do so, we compute perturbatively their steady-state measure and show that, for short persistent times, the entropy production rate vanishes. This endows such systems with an effective Fluctuation-Dissipation theorem akin to that of thermal equilibrium systems. Last we show how interacting particle systems with viscous drags and correlated noises can be seen as in equilibrium with a visco-elastic bath but driven out of equilibrium by non-conservative forces, hence providing an energetic insight on the departure of active systems from equilibrium.
Keywords
Cite
@article{arxiv.1604.00953,
title = {How far from equilibrium is active matter?},
author = {Étienne Fodor and Cesare Nardini and Mike E. Cates and Julien Tailleur and Paolo Visco and Frédéric van Wijland},
journal= {arXiv preprint arXiv:1604.00953},
year = {2016}
}
Comments
5 pages, 2 figures