Tunable structure and dynamics of active liquid crystals

TL;DR

This paper investigates how the structure and dynamics of active nematic liquid crystals can be tuned by controlling activity levels, revealing transitions in defect interactions and elastic properties through combined theoretical and experimental approaches.

Contribution

It provides new insights into the non-equilibrium properties of active nematics, demonstrating how defect interactions and elastic moduli are affected by activity, enabling potential control of their dynamic behavior.

Findings

Defect interactions transition from attractive to repulsive with activity.

Elastic properties, especially bend elasticity, decrease with increased activity.

Defects exhibit liquid-like arrangements and orientation preferences at high activity.

Abstract

Active materials are capable of converting free energy into directional motion, giving rise to striking dynamical phenomena. Developing a general understanding of their structure in relation to the underlying non-equilibrium physics would provide a route towards control of their dynamic behavior and pave the way for potential applications. The active system considered here consists of a quasi-two-dimensional sheet of short ($\approx$ 1 $\mu$m) actin filaments driven by myosin-II motors. By adopting a concerted theoretical and experimental strategy, new insights are gained into the non-equilibrium properties of active nematics over a wide range of internal activity levels. In particular, it is shown that topological defect interactions can be led to transition from attractive to repulsive as a function of initial defect separation and relative orientation. Furthermore, by examining the +1/2 defect morphology as a function of activity, it is found that the apparent elastic properties of the system (the ratio of bend-to-splay elastic moduli) are altered considerably by increased activity, leading to an effectively lower bend elasticity. At high levels of activity, the topological defects that decorate the material exhibit a liquid-like structure, and adopt preferred orientations depending on their topological charge. Taken together, these results suggest that it should be possible to tune internal stresses in active nematic systems with the goal of designing out-of-equilibrium structures with engineered dynamic responses.