Phase separation in a chiral active fluid of inertial self-spinning disks
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We show that systematic particle rotations in a fluid composed of disk-shaped spinners can spontaneously lead to phase separation. The phenomenon arises out of a homogeneous and hydrostatic stationary state, due to a pressure feedback mechanism that increases local density fluctuations. We show how this mechanism induces phase separation, coined as Rotation Induced Phase Separation (RIPS), when the active rotation is not properly counterbalanced by translational friction. A low density phase can coexist with a dense chiral liquid due to the imbalance between pressure and stress transmitted through chiral flows when a significant momentum transfer between rotational and translational motion can be sustained. As a consequence, RIPS is expected to appear generically in chiral fluids.
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Forward citations
Cited by 2 Pith papers
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Sparkling bubbles in chiral active fluids
Chiral active fluids form rotating bubbles that dynamically break up and reform in a sparkling instability at optimal packing fractions, as predicted by coarse-grained hydrodynamics.
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Equation of state for the edge flow of chiral colloidal fluids
Edge fluxes in chiral fluids equal the average odd stress in confined geometries or the jump in odd stress across interfaces in phase-separated systems.
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