English

Extreme active matter at high densities

Soft Condensed Matter 2020-06-24 v1

Abstract

Extreme active matter, an assembly of self-propelled particles with large persistence time τp\tau_p and high P\'eclet number, exhibits remarkable behaviour at high densities. As τp0\tau_p\to 0, the assembly undergoes a gradual slowing down of density relaxations, as one reduces the active propulsion force ff, until at the glass transition, the relaxation times diverge. In the other limit, τp\tau_p \to \infty, the fluid jams on lowering ff, at a critical threshold f()f^*(\infty), with stresses concentrated along force-chains. As one moves away from this jamming threshold, the force-chains dynamically remodel, and the lifetime of the force-balanced configurations diverges as one approaches f()f^*(\infty), by tuning τp\tau_p. In between these limits, the approach to dynamical arrest at low ff, goes through a phase characterised by intermittency in the kinetic energy. This intermittency is a consequence of long periods of jamming followed by bursts of plastic yielding associated with Eshelby deformations, akin to the response of dense amorphous solids to an externally imposed shear. The frequency of these plastic bursts increases as one moves towards the intermittent phase-fluid boundary, where the correlated plastic events result in large scale vorticity and turbulence. Dense extreme active matter brings together the physics of glass, jamming, plasticity and turbulence, in a new state of driven classical matter.

Keywords

Cite

@article{arxiv.1902.05484,
  title  = {Extreme active matter at high densities},
  author = {Rituparno Mandal and Pranab Jyoti Bhuyan and Pinaki Chaudhuri and Chandan Dasgupta and Madan Rao},
  journal= {arXiv preprint arXiv:1902.05484},
  year   = {2020}
}

Comments

17 pages; movies available on request

R2 v1 2026-06-23T07:41:15.023Z