Velocity alignment promotes motility-induced phase separation

We study the phase behavior of polar active Brownian particles moving in two-spatial dimensions and interacting through volume exclusion and velocity alignment. We combine particle-based simulations of the microscopic model with a simple mean-field kinetic model to understand the impact of velocity alignment on the motility-induced phase separation of self-propelled disks. We show that, as the alignment strength is increased, approaching the onset of collective motion from below, orientational correlations grow, rendering the diffusive reorientation dynamics slower. As a consequence, the tendency of particles to aggregate into isotropic clusters is enhanced, favoring the complete de-mixing of the system into a low and high-density phase. Copyright (C) EPLA, 2018

Velocity alignment promotes motility-induced phase separation

Microscopic field theory for structure formation in systems of self-propelled particles with generic torques

Atomistic modeling of the solid-liquid interface of metals and alloys

Thermal origin of quasilocalized excitations in glasses

Atomistic modeling of the solid-liquid interface of metals and alloys

Microscopic field theory for structure formation in systems of self-propelled particles with generic torques

Thermal origin of quasilocalized excitations in glasses