Heterogeneity-Induced Oscillations in Active Nematics

TL;DR

This paper demonstrates how spatial variations in activity induce oscillations and alter instability modes in active nematics, providing a theoretical framework and numerical verification for these phenomena.

Contribution

It introduces a dynamical system model linking activity heterogeneity to oscillatory behavior in active nematics, revealing new spatio-temporal structures.

Findings

Spatial activity variations cause spontaneous oscillations.

Phase diagram shows how activity gradients influence oscillation nature.

Numerical results confirm analytical predictions.

Abstract

One of the defining features of active nematics is that above a critical activity the quiescent state becomes unstable to a distorted, flowing one. We show that spatial variations in activity can fundamentally change the nature of this instability, affecting the symmetry of the unstable mode and producing spontaneous oscillations. We analytically identify a dynamical system for the evolution of the odd and even director modes, with the leading-order coefficients dependent on the activity profile, allowing a quantitative connection between the spatially-heterogeneous activity and dynamics, which we verify numerically. In the context of constant gradients in activity, we determine a phase diagram for the active response and highlight how variation of the activity profile causes the oscillations to vary from almost harmonic to relaxational. Our results indicate a novel route to spatio-temporal structure in active nematics and suggest experiments on controllable light-activated systems.