Nonmonotonic diffusion in sheared active suspensions of squirmers

Abstract: We investigate how shear influences the dynamics of active particles in dilute to concentrated suspensions. Specifically, we focus on apolar active suspensions of squirmers, which are individually immotile but display activity-induced hydrodynamic diffusion. Under shear, the instantaneous particle velocities fluctuate more rapidly, similar to passive suspensions; however, surprisingly, the long-time diffusive dynamics can slow down and exhibit a nonmonotonic dependence on the shear rate. We show that this behavior arises from an interplay between the activity-induced persistent motion and shear-induced negative velocity autocorrelation, both of which are more pronounced at lower volume fractions. Simulations of self-propelled particles with tunable persistence support this explanation and further offer a simple mechanism to understand the observed coupling. Our results reveal a generic effect of shear on diffusion in active suspensions, elucidate how internal and external forcing interact, and provide new possibilities to modulate transport in active fluids.