Boundary curvature induces wall accumulation in non-motile chiral active particles confined in circular geometries via tangential wall forces, as shown by simulations and hydrodynamics.
arXiv preprint arXiv:2509.05053 , year=
5 Pith papers cite this work. Polarity classification is still indexing.
fields
cond-mat.soft 5years
2026 5representative citing papers
A chirality-switching model of 2D active particles produces robust topological edge currents in confinement and at phase-separation interfaces, distinct from standard motility-induced phase separation.
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.
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.
citing papers explorer
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Curvature-driven wall accumulation in chiral active particles
Boundary curvature induces wall accumulation in non-motile chiral active particles confined in circular geometries via tangential wall forces, as shown by simulations and hydrodynamics.
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Designing topological edge currents in chiral active matter
A chirality-switching model of 2D active particles produces robust topological edge currents in confinement and at phase-separation interfaces, distinct from standard motility-induced phase separation.
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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.