Hydrodynamic theory of wetting by active particles (2506.14559v1)

Abstract: The accumulation of self-propelled particles on repulsive barriers is a widely observed feature in active matter. Despite being implicated in a broad range of biological processes, from biofilm formation to cytoskeletal movement, wetting of surfaces by active particles remains poorly understood. In this work, we study this active wetting by considering a model comprising an active lattice gas, interacting with a permeable barrier under periodic boundary conditions, for which an exact hydrodynamic description is possible. Our model eliminates dynamical noise while retaining microscopic fidelity, enabling a precise characterisation of steady-states and their transitions. We demonstrate that the accumulation of active particles is remarkably similar to equilibrium wetting, and that active wetting transitions retain all the salient characteristics of equilibrium critical wetting - despite fundamental differences in underlying microscopic dynamics. Additionally, we uncover a ratchet mechanism on permeable barriers in active systems, and demonstrate that this gives rise to steady-state currents and a novel transition pathway in active wetting. Our results provide an intrinsically nonequilibrium framework in which to study active wetting, and precisely demonstrate the connection to equilibrium wetting - while clarifying how differences in microscopic dynamics give rise to novel macroscopic behaviour.