Phase separation and disorder

Phase separation and disorder

Interacting active particles (with or without attraction) can undergo Motility Induced Phase separation (MIPS):

What happens to this phase transition if active particles move on a random (short-range correlated, bounded) landscape?

Sunghan Ro, Y. Kafri, M. Kardar, J. Tailleur, Phys. Rev. Lett. 126, 048003 (2021)

For non-interacting active particles, density variations are similar to that expected for an equilibrium system

in response to a chemical potential (magnetic field) with long-range correlations:

We may inquire of the effects of a similar "random field" on phase transition of an equilibrium system:

Imry-Ma: Consider stability of an ordered domain of size R to flip to the oppositely ordered state;

Can the cost of surface tension be made up by a fortuitous gain in random field energy?

The ordered phase is unstable to random field induced flips of large enough domains for

The absence of MIPS with disorder is supported by simulations:

Quench with no disorder:

Quench with bulk disorder:

Turning on bulk disorder in a phase separated state:

Turning off bulk disorder:

Disorder on boundaries is surprisingly sufficient to destroy phase separation (order) in the bulk!

Local random asymmetries at the boundary acts as pumps that stir up the interior of the active fluid over long distances.

(a) Simulation setup (b) Density fluctuations (c) Current fluctuations (y-direction)

Imry-Ma argument can be generalized to include the effect long-range fields sourced at a boundary

The ordered phase in the bulk is unstable to boundary field induced flips of large enough domains for

Passive flat wall: Active flat wall:

Passive rough wall: Active rough wall:

Turning on boundary disorder in a phase separated state:

Ydan Ben Dor, S. Ro, Y. Kafri, M. Kardar, J. Tailleur, Phys. Rev. E 105, 044603 (2022)