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Disorder-Induced Long-Ranged Correlations in Scalar Active Matter

Sunghan Ro, Yariv Kafri, Mehran Kardar, Julien Tailleur

2021Physical Review Letters43 citationsDOIOpen Access PDF

Abstract

We study the impact of quenched random potentials and torques on scalar active matter. Microscopic simulations reveal that motility-induced phase separation is replaced in two dimensions by an asymptotically homogeneous phase with anomalous long-ranged correlations and nonvanishing steady-state currents. Using a combination of phenomenological models and a field-theoretical treatment, we show the existence of a lower-critical dimension d_{c}=4, below which phase separation is only observed for systems smaller than an Imry-Ma length scale. We identify a weak-disorder regime in which the structure factor scales as S(q)∼1/q^{2}, which accounts for our numerics. In d=2, we predict that, at larger scales, the behavior should cross over to a strong-disorder regime. In d>2, these two regimes exist separately, depending on the strength of the potential.

Topics & Concepts

PhysicsScalar (mathematics)Active matterMathematicsBiologyCell biologyGeometryMicro and Nano RoboticsAdvanced Thermodynamics and Statistical MechanicsMolecular Communication and Nanonetworks
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