Hyperuniformity in phase ordering: the roles of activity, noise, and non-constant mobility
Abstract
Hyperuniformity emerges generically in the coarsening regime of phase-separating fluids. Numerical studies of active and passive systems have shown that the structure factor S(q) behaves as q for q 0, with hyperuniformity exponent = 4. For passive systems, this result was explained in 1991 by a qualitative scaling analysis of Tomita, exploiting isotropy at scales much larger than the coarsening length . Here we reconsider and extend Tomita's argument to address cases of active phase separation and of non-constant mobility, again finding =4. We further show that dynamical noise of variance D creates a transient = 2 regime for q q D t[1-(d+2)]/2, crossing over to = 4 at larger q. Here, is the coarsening exponent, with t, and q q is the rescaled wavenumber. In diffusive coarsening, =1/3, so the rescaled crossover wavevector q vanishes at large times when d≥ 2. The slowness of this decay suggests a natural explanation for experiments that observe a long-lived = 2 scaling in phase-separating active fluids (where noise is typically large). Conversely, in d=1, we demonstrate that with noise the = 2 regime survives as t∞, with q D5/6. (The structure factor is not then determined by the zero-temperature fixed point.) We confirm our analytical predictions by numerical simulations of active and passive continuum theories in the deterministic case and of Model B for the stochastic case. We also compare them with related findings for a system near an absorbing-state transition rather than undergoing phase separation. A central role is played throughout by the presence or absence of a conservation law for the centre of mass position of the order parameter field.
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