Crowding induced clustering under confinement

We present Langevin dynamics simulations that study the collective behavior of driven particles embedded in a densely packed background consisting of passive particles. Depending on the driving force, the densities of driven and passive particles, and the temperature we observe a dynamical phase separation of the driven particles, which cluster together in tight bands. We explore the mechanisms that drive this cluster formation, and determine the critical conditions for such phase separation. A simple physical picture explains the formation and subsequent growth of a jammed zone developing in front of the driven cluster. The model correctly captures the observed scaling with time. We analyze the implications of this clustering transition for the driven transport in dense particulate flows, which due to a non-monotonic dependence on the applied driving force is not straightforwardly optimized. We provide proof-of-concept for a direct application of the clustering effect, and propose a 'colloidal chromatograph'; a setup that permits the separation of colloids by mass or size.