Viscoelastic and elastomeric active matter: Linear instability and nonlinear dynamics
Abstract
We consider a continuum model of active viscoelastic matter, whereby an active nematic liquid-crystal is coupled to a minimal model of polymer dynamics with a viscoelastic relaxation time . To explore the resulting interplay between active and polymeric dynamics, we first generalise a linear stability analysis (from earlier studies without polymer) to derive criteria for the onset of spontaneous heterogeneous flows (strain rate) and/or deformations (strain). We find two modes of instability. The first is a viscous mode, associated with strain rate perturbations. It dominates for relatively small values of and is a simple generalisation of the instability known previously without polymer. The second is an elastomeric mode, associated with strain perturbations, which dominates at large and persists even as . We explore the novel dynamical states to which these instabilities lead by means of direct numerical simulations. These reveal oscillatory shear-banded states in 1D, and activity-driven turbulence in 2D even in the elastomeric limit . Adding polymer can also have calming effects, increasing the net throughput of spontaneous flow along a channel in a new type of "drag-reduction". Finally the effect of including strong, antagonistic coupling between nematic and polymer is examined numerically, revealing a rich array of spontaneously flowing states.
Cite
@article{arxiv.1512.04440,
title = {Viscoelastic and elastomeric active matter: Linear instability and nonlinear dynamics},
author = {E. J. Hemingway and M. E. Cates and S. M. Fielding},
journal= {arXiv preprint arXiv:1512.04440},
year = {2016}
}
Comments
25 pages, 21 figures; v2 fixed rendering issue with fig 4, updated to published version