Origin of Spatiotemporal Fluctuations in Discontinuous Shear Thickening

Abstract

Rheological phase transitions open the door to the less explored realm of non-equilibrium phase transitions. The main mechanism driving these transitions is usually mechanical perturbation by shear--- an unjamming mechanism. Investigating discontinuous shear thickening (DST) is challenging because the shear counterintuitively acts as a jamming mechanism. Moreover, at the brink of this transition, a thickening material exhibits fluctuations that extend both spatially and temporally. Despite recent extensive research, the origins of such spatiotemporal fluctuations remain unidentified. Here, we investigate large fluctuations in DST by using versatile tools of stochastic thermodynamics. We discover a non-equilibrium dichotomy in the underlying mechanisms that give rise to large fluctuations and demonstrate that this dichotomy is a manifestation of novel collective behaviors across the transition. We then reveal the origin of spatiotemporal fluctuations in the shear thickening transition. Our study emphasizes the roles of stochastic thermodynamics tools in investigating non-equilibrium phase transitions, and demonstrates that these transitions are accompanied by simple dichotomies. We expect that our general approach will pave the way to unmasking the nature of non-equilibrium phase transitions.