In chemorepulsive active colloids with quenched disorder and angular noise, noise-driven phase transitions depend on density unlike pinning transitions, and short-range interactions yield density bands and bimodal order near the transition.
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A multiscale perturbative coarse-graining method derives effective large-scale descriptions for dry scalar active matter with motility regulation, identifying conditions for equilibrium-like regimes and capturing emergent particle currents when those conditions fail.
Derives unifying hydrodynamics for motility-regulated active matter from particles to polymers, captured by orientation autocorrelation tensor, and identifies anti-MIPS in quorum-sensing polymers.
citing papers explorer
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Emergent flocking dynamics in chemorepulsive active colloids: interplay of disorder and noise
In chemorepulsive active colloids with quenched disorder and angular noise, noise-driven phase transitions depend on density unlike pinning transitions, and short-range interactions yield density bands and bimodal order near the transition.
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Multiscale perturbative approach to active matter with motility regulation
A multiscale perturbative coarse-graining method derives effective large-scale descriptions for dry scalar active matter with motility regulation, identifying conditions for equilibrium-like regimes and capturing emergent particle currents when those conditions fail.
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Unifying hydrodynamic theory for motility-regulated active matter: from single particles to interacting polymers
Derives unifying hydrodynamics for motility-regulated active matter from particles to polymers, captured by orientation autocorrelation tensor, and identifies anti-MIPS in quorum-sensing polymers.