Disorder-Induced Long-Ranged Correlations in Scalar Active Matter

Abstract

We study the impact of a random quenched 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 non-vanishing steady-state currents. Using a combination of phenomenological models and a field-theoretical treatment, we show the existence of a lower-critical dimension, dc=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/q2 which accounts for our numerics. In d=2 we predict that, at larger scales, the behaviour should cross over to a strong-disorder regime. In d>2, these two regimes exist separately, depending on the strength of the potential.