Optimizing active work: Dynamical phase transitions, collective motion, and jamming
Statistical Mechanics
2019-02-12 v3 Soft Condensed Matter
Abstract
Active work measures how far the local self-forcing of active particles translates into real motion. Using Population Monte Carlo methods, we investigate large deviations in the active work for repulsive active Brownian disks. Minimizing the active work generically results in dynamical arrest; in contrast, despite the lack of aligning interactions, trajectories of high active work correspond to a collectively moving, aligned state. We use heuristic and analytic arguments to explain the origin of dynamical phase transitions separating the arrested, typical, and aligned regimes.
Cite
@article{arxiv.1805.02887,
title = {Optimizing active work: Dynamical phase transitions, collective motion, and jamming},
author = {Takahiro Nemoto and Étienne Fodor and Michael E. Cates and Robert L. Jack and Julien Tailleur},
journal= {arXiv preprint arXiv:1805.02887},
year = {2019}
}
Comments
14 pages, 9 figures