Dynamical Heterogeneity in a Highly Supercooled Liquid under a Sheared Situation

Abstract

In the present study, we performed molecular-dynamics simulations and investigated dynamical heterogeneity in a supercooled liquid under a steady shear flow. Dynamical heterogeneity can be characterized by three quantities: the correlation length 4(t), the intensity 4(t), and the lifetime τhetero(t). We quantified all three quantities by means of the correlation functions of the particle dynamics, i.e., the four-point correlation functions, which are extended to the sheared condition. Here, to define the local dynamics, we used two time intervals t=τα and τngp; τα is the α-relaxation time, and τngp is the time at which the non-Gaussian parameter of the Van Hove self-correlation function is maximized. We discovered that all three quantities (4(t), 4(t), and τhetero(t)) decrease as the shear rate γ of the steady shear flow increases. For the time interval t=τα, the scalings 4(τα) γ-0.08, 4(τα) γ-0.26, and τhetero(τα) γ-0.88 were obtained. The steady shear flow suppresses the heterogeneous structure as well as the lifetime of the dynamical heterogeneity. In addition, our results demonstrated that the α-relaxation time τα dependences of three quantities coincide with those at equilibrium. This means that all three quantities of the dynamical heterogeneity can be mapped onto those in the equilibrium state through τα.