Entropy Scaling Laws in Self Propelled Glass Formers

Abstract

Predicting transport from equilibrium structure is a challenging problem in liquid state physics. Here we probe a glass forming liquid composed of self-propelled "active" particles and show that increasing the duration of self-propulsion τp makes the pair excess entropy S2 more negative, thereby reducing the number of accessible configurations per particle. At moderate values of effective temperature T, the self-diffusivity is Arrhenius and in a reduced form obeys a Dzugutov like scaling law D* eα S2, directly yielding us the scaling formula S2 -1/T. In the strongly super-cooled regime, Dzugutov law does not apply and the entropy follows a power law S2 -1/Tβ all the way up to the glass transition Tg. To demonstrate generality, we set the particle interactions to be purely repulsive (PR) in one case and Lennard-Jones (LJ) in the other, and find that in both the cases, the reported scaling laws are robust over three decades of variation in τp. Our results may apply to transport in active colloidal suspensions, passive tracers in bacterial baths, and self-propelled granular media, to mention a few.