Critical scaling and supercritical coarsening in Active Model B+

Abstract

We study critical dynamics and phase-ordering kinetics in Active Model B (AMB) and its minimal extension, Active Model B+ (AMB+), using deterministic simulations in two dimensions. At criticality rc=0, both models display identical mean-field scaling despite nonequilibrium currents, with order-parameter decay with time as m(t) t-α, with α=14, and dynamical exponent being z=4. A generalized equal-area construction yields the binodal densities and phase diagram of AMB+. For supercritical quenches, domain size grows as L(t) t1/3(1+c/ t), revealing logarithmic corrections to the classic t1/3 growth-law; moreover it is consistent with the functional renormalization group predictions for marginal activity in d=2. While the logarithmic corrections are quite prominent in AMB, in AMB+ they are suppressed as the active current acts against the formation of macro-clusters; the growth is eventually arrested when a long-lived microphase-separated state appears.