Arrested phase separation and chiral symmetry breaking in active dumbbells under shear

Through molecular dynamics simulations, we investigate the phase separation and aggregation dynamics of active dumbbell particles in two-dimensions subjected to shear.

We find that the growth of the phase-separated region is arrested when shear is applied, with the average clusters size plateauing towards a value R_s that remains constant over time. As the shear rate increases, R_s decreases non-linearly, while increasing activity makes clusters more resilient to shear breaking. We find that clusters in the stationary state are progressively less polarized and increasingly elongated with increasing shear. At the same time, we find a spontaneous breaking in chiral symmetry of both rotation direction and internal organization of clusters: typically, dumbbells point towards the cluster center with a small non-zero angle, such that the active torque opposes the shear torque, with cluster's angular velocity well captured by a simplified analytical model. We argue this conformation makes clusters more stable against shear.