Entropy production rate in thermodynamically consistent flocks
Abstract
We study the entropy production rate (EPR) of aligning self-propelled particles which undergo a flocking transition towards a polarized collective motion. In our thermodynamically consistent lattice model, individual self-propulsion is the exclusive source of irreversibility. We derive the fluctuating hydrodynamics for large system sizes using a controlled coarse-graining: our procedure entails an exact correspondence between the EPR evaluated at the hydrodynamic and particle-based levels. We reveal that EPR is maximal when the system adopts a homogeneous configuration, either apolar or polar, and reduced in the non-homogeneous state where a polar band travels in a apolar background due to strong spatial EPR modulations. By analyzing the latter we also show that asymmetric energetic exchanges occur at the trailing and leading edges, which we map into a thermodynamic cycle in density-polarization space. Finally, we demonstrate that the regime of weak self-propulsion features a singular scaling of EPR, and a non-analyticity of the travelling band profiles.
Cite
@article{arxiv.2505.13117,
title = {Entropy production rate in thermodynamically consistent flocks},
author = {Tal Agranov and Robert L. Jack and Michael E. Cates and Étienne Fodor},
journal= {arXiv preprint arXiv:2505.13117},
year = {2025}
}
Comments
33 pages, 9 figures