Anomalous Diffusion of Symmetric and Asymmetric Active Colloids

Abstract

The stochastic dynamics of colloidal particles with surface activity--in the form of catalytic reaction or particle release--and self-phoretic effects is studied analytically. Three different time scales corresponding to inertial effects, solute redistribution, and rotational diffusion are identified and shown to lead to a plethora of different regimes involving inertial, propulsive, anomalous, and diffusive behaviors. For symmetric active colloids, a regime is found where the mean-squared displacement has a super-diffusive t3/2 behavior. At the longest time scales, an effective diffusion coefficient is found which has a non-monotonic dependence on the size of the colloid.