Fluctuating Phases and Fluctuating Relaxation Times in Glass Forming Liquids

The presence of fluctuating local relaxation times, $\tau_r(t)$ has been used for some time as a conceptual tool to describe dynamical heterogeneities in glass-forming systems. However, until now no general method is known to extract the full space and time dependent $\tau_r(t)$ from experimental or numerical data. Here we report on a new method for determining the local phase field, $\phi_r(t) = \int^{t} dt'/\tau_r(t')$ from snapshots $\{r(t_i)\}_{i=1...M}$ of the positions of the particles in a system, and we apply it to extract $\phi_r(t)$ and $\tau_r(t)$ from numerical simulations. By studying how the phase field depends on the number of snapshots, we find that it is a well defined quantity. By studying fluctuations of the phase field, we find that they describe heterogeneities well at long distance scales.