Dynamical heterogeneity in a highly supercooled liquid: Consistent calculations of correlation length, intensity, and lifetime

Abstract

We have investigated dynamical heterogeneity in a highly supercooled liquid using molecular-dynamics simulations in three dimensions. Dynamical heterogeneity can be characterized by three quantities: correlation length 4, intensity 4, and lifetime τhetero. We evaluated all three quantities consistently from a single order parameter. In a previous study (H. Mizuno and R. Yamamoto, Phys. Rev. E 82, 030501(R) (2010)), we examined the lifetime τhetero(t) in two time intervals t=τα and τngp, where 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. In the present study, in addition to the lifetime τhetero(t), we evaluated the correlation length 4(t) and the intensity 4(t) from the same order parameter used for the lifetime τhetero(t). We found that as the temperature decreases, the lifetime τhetero(t) grows dramatically, whereas the correlation length 4(t) and the intensity 4(t) increase slowly compared to τhetero(t) or plateaus. Furthermore, we investigated the lifetime τhetero(t) in more detail. We examined the time-interval dependence of the lifetime τhetero(t) and found that as the time interval t increases, τhetero(t) monotonically becomes longer and plateaus at the relaxation time of the two-point density correlation function. At the large time intervals for which τhetero(t) plateaus, the heterogeneous dynamics migrate in space with a diffusion mechanism, such as the particle density.