Minimal mechanism for fluidic flocks in interacting active colloids

Abstract: Collective motion as a flock is a widely observed phenomenon in active matter systems. Finding possible mechanisms of attaining a global polar order via dynamical mechanisms - without any explicit alignment interaction - is an area of active current research. Here, we report a flocking transition sustained purely by chemo-repulsive torques at low to medium densities in a system of chemically interacting colloidal particles. The basic requirements to sustain the flock are excluded volume repulsions and deterministic long-ranged net repulsive torques, with the time scale individual colloids move a unit length being dominant with respect to the time they deterministically sense chemicals. Switching on the translational repulsive forces renders the flock a crystalline structure. The generality of this phenomenon is displayed for a range of attractive translational forces to which the flock is robust. We rationalize these results with a phenomenological hydrodynamical model.