Dispersion of inertial particles in cellular flows in the small-Stokes, large-P\'eclet regime

Abstract

We investigate the transport of inertial particles by cellular flows when advection dominates over inertia and diffusion, that is, for Stokes and P\'eclet numbers satisfying St 1 and Pe 1. Starting from the Maxey--Riley model, we consider the distinguished scaling St \, Pe = O(1) and derive an effective Brownian dynamics approximating the full Langevin dynamics. We then apply homogenisation and matched-asymptotics techniques to obtain an explicit expression for the effective diffusivity D characterising long-time dispersion. This expression quantifies how D, proportional to Pe-1/2 when inertia is neglected, increases for particles heavier than the fluid and decreases for lighter particles. In particular, when St Pe-1, we find that D is proportional to St1/2/( ( St \, Pe))1/2 for heavy particles and exponentially small in St \, Pe for light particles. We verify our asymptotic predictions against numerical simulations of the particle dynamics.