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Self-alignment and anti-self-alignment suppress motility-induced phase separation in active systems

Marco Musacchio, Alexander P. Antonov, Hartmut Löwen, Lorenzo Caprini

2025The Journal of Chemical Physics12 citationsDOI

Abstract

In this article, we investigate the impact of self-alignment and anti-self-alignment on collective phenomena in dense active matter. These mechanisms correspond to effective torques that align or anti-align a particle's orientation with its velocity, as observed in active granular systems. In the context of motility-induced phase separation (MIPS)-a non-equilibrium coexistence between a dense clustered phase and a dilute homogeneous phase-both self- and anti-self-alignment are found to suppress clustering. In particular, increasing self-alignment strength first leads to flocking within the dense cluster and eventually to the emergence of a homogeneous flocking phase. In contrast, anti-self-alignment induces a freezing phenomenon, progressively reducing particle speed until MIPS is suppressed and a homogeneous phase is recovered. These results are supported by scaling arguments and are amenable to experimental verification in high-density active granular systems exhibiting self- or anti-self-alignment.

Topics & Concepts

Separation (statistics)Phase (matter)MotilityMaterials scienceBiological systemChemistryControl theory (sociology)Computer scienceBiologyArtificial intelligenceCell biologyMachine learningOrganic chemistryControl (management)Micro and Nano RoboticsModular Robots and Swarm IntelligenceNeural dynamics and brain function
Self-alignment and anti-self-alignment suppress motility-induced phase separation in active systems | Litcius