Active Inhomogeneous Mode-Coupling Theory (aIMCT) for Dense Systems of Self-Propelled Particles
Abstract
Glassy dynamics in a dense system of active particles with self-propulsion force f0 and persistence time τp are crucial for many biological processes. Recent studies have shown that, unlike relaxation dynamics, dynamic heterogeneity (DH) in active glasses exhibits nontrivial behavior. However, the mechanism by which activity affects DH remains unknown. We have developed an active inhomogeneous mode-coupling theory (aIMCT) for DH in active glasses. We show that the nontrivial behavior of DH comes from a novel nonequilibrium effect of activity that leads to distinct behaviors of DH and relaxation dynamics in active glasses. When activity is small, DH exhibits equilibrium-like behavior with a power-law divergence of the peak height of the four-point correlation function, Cpeak, and the aIMCT value of the exponent, μ 1.0, is consistent with the existing and our new simulations of active glasses. However, Cpeak deviates from the scaling relations at higher f0 values because of the novel effect on DH, although the deviation with varying τp is relatively weak.
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