Active Model H: Scalar Active Matter in a Momentum-Conserving Fluid

Abstract

We present a continuum theory of self-propelled particles, without alignment interactions, in a momentum-conserving solvent. To address phase separation we introduce a scalar concentration field φ with advective-diffusive dynamics. Activity creates a contribution ij=-ζ((∂iφ)(∂jφ)-(∇φ)2δij/d) to the deviatoric stress, where ζ is odd under time reversal and d is the number of spatial dimensions; this causes an effective interfacial tension contribution that is negative for contractile swimmers. We predict that domain growth then ceases at a length scale where diffusive coarsening is balanced by active stretching of interfaces, and confirm this numerically. Thus the interplay of activity and hydrodynamics is highly nontrivial, even without alignment interactions.