Active Model B+ exhibits mean-field critical scaling identical to AMB and supercritical coarsening with logarithmic corrections to t^{1/3} growth that are suppressed by active currents, leading to arrested microphase separation.
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UNVERDICTED 3representative citing papers
Active nematics show activity-independent linearized temperature correlations in homogeneous states but develop inhomogeneous temperature profiles under confinement during spontaneous flow transitions.
An agent-based model with orientation-weighted velocity-dependent alignment generates disordered, flocking, jammed, and active-crystal-like collective phases by varying alignment strength.
citing papers explorer
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Critical scaling and supercritical coarsening in Active Model B+
Active Model B+ exhibits mean-field critical scaling identical to AMB and supercritical coarsening with logarithmic corrections to t^{1/3} growth that are suppressed by active currents, leading to arrested microphase separation.
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On the temperature of an active nematic
Active nematics show activity-independent linearized temperature correlations in homogeneous states but develop inhomogeneous temperature profiles under confinement during spontaneous flow transitions.
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Collective dynamics of active matter with orientation-weighted alignment
An agent-based model with orientation-weighted velocity-dependent alignment generates disordered, flocking, jammed, and active-crystal-like collective phases by varying alignment strength.