Motility-Induced Microphase and Macrophase Separation in a Two-Dimensional Active Brownian Particle System

As a result of nonequilibrium forces, purely repulsive self-propelled particles undergo macrophase separation between a dense and a dilute phase. We present a thorough study of the ordering kinetics of such motility-induced phase separation (MIPS) in active Brownian particles in two dimensions, and we show that it is generically accompanied by microphase separation. The growth of the dense phase follows a law akin to the one of liquid-gas phase separation. However, it is made of a mosaic of hexatic microdomains whose size does not coarsen indefinitely, leaving behind a network of extended topological defects from which microscopic dilute bubbles arise. The characteristic length of these finite-size structures increases with activity, independently of the choice of initial conditions.

Motility-Induced Microphase and Macrophase Separation in a Two-Dimensional Active Brownian Particle System

Drops: Controlled crystallization of organic crystals and their use as matrix materials for encapsulation of volatiles

Skyrmion Control and Phase Transitions in Cu2OSeO3

Unified analysis of topological defects in 2D systems of active and passive disks

Drops: Controlled crystallization of organic crystals and their use as matrix materials for encapsulation of volatiles

Skyrmion Control and Phase Transitions in Cu2OSeO3

Unified analysis of topological defects in 2D systems of active and passive disks