Multi-time density correlation functions in glass-forming liquids: Probing dynamical heterogeneity and its lifetime

TL;DR

This paper introduces a multi-time density correlation function to analyze dynamical heterogeneity in glass-forming liquids, revealing couplings of motions over various time scales and estimating heterogeneity lifetimes.

Contribution

It develops a multi-time correlation framework analogous to nonlinear spectroscopy, providing new insights into the temporal evolution and lifetime of dynamical heterogeneity.

Findings

Correlations are sensitive to dynamical heterogeneity in both time and frequency domains.

Mobile and immobile particle contributions are distinguishable in the three-time correlation.

Heterogeneity lifetime exceeds the alpha-relaxation time in highly supercooled states.

Abstract

A multi-time extension of a density correlation function is introduced to reveal temporal information about dynamical heterogeneity in glass-forming liquids. We utilize a multi-time correlation function that is analogous to the higher-order response function analyzed in multidimensional nonlinear spectroscopy. Here, we provide comprehensive numerical results of the four-point, three-time density correlation function from longtime trajectories generated by molecular dynamics simulations of glass-forming binary soft-sphere mixtures. We confirm that the two-dimensional representations in both time and frequency domains are sensitive to the dynamical heterogeneity and that it reveals the couplings of correlated motions, which exist over a wide range of time scales. The correlated motions detected by the three-time correlation function is divided into mobile and immobile contributions that are determined from the particle displacement during the first time interval. We show that the peak positions of the correlations are in accord with the information on the non-Gaussian parameters of the van-Hove self correlation function. Furthermore, it is demonstrated that the progressive changes in the second time interval in the three-time correlation function enable us to analyze how correlations in dynamics evolve in time. From this analysis, we evaluated the lifetime of the dynamical heterogeneity and its temperature dependence systematically. Our results show that the lifetime of the dynamical heterogeneity becomes much slower than the $\alpha$-relaxation time that is determined from the two-point density correlation function when the system is highly supercooled.