Litcius/Paper detail

Fluctuation-Induced Phase Separation in Metric and Topological Models of Collective Motion

D.G. Martin, Hugues Chaté, Cesare Nardini, Alexandre Solon, Julien Tailleur, Frédéric van Wijland

2021Physical Review Letters47 citationsDOIOpen Access PDF

Abstract

We study the role of noise on the nature of the transition to collective motion in dry active matter. Starting from field theories that predict a continuous transition at the deterministic level, we show that fluctuations induce a density-dependent shift of the onset of order, which in turn changes the nature of the transition into a phase-separation scenario. Our results apply to a range of systems, including models in which particles interact with their "topological" neighbors that have been believed so far to exhibit a continuous onset of order. Our analytical predictions are confirmed by numerical simulations of fluctuating hydrodynamics and microscopic models.

Topics & Concepts

Collective motionPhysicsPhase transitionStatistical physicsActive matterMetric (unit)Noise (video)Topological defectMotion (physics)Range (aeronautics)Phase (matter)Field (mathematics)Order (exchange)Mean field theoryTopology (electrical circuits)Classical mechanicsCondensed matter physicsQuantum mechanicsComputer scienceMathematicsMaterials scienceArtificial intelligenceOperations managementCombinatoricsComposite materialCell biologyImage (mathematics)BiologyEconomicsPure mathematicsFinanceMicro and Nano RoboticsDiffusion and Search DynamicsAdvanced Thermodynamics and Statistical Mechanics
Fluctuation-Induced Phase Separation in Metric and Topological Models of Collective Motion | Litcius