Microscopic origin of excess wings in relaxation spectra of deeply supercooled liquids

We combine the giant equilibration speedup provided by the swap Monte Carlo algorithm to extensive multi-CPU molecular dynamics simulations to explore the first ten decades of the equilibrium dynamics of supercooled liquids near the experimental glass transition. We demonstrate in particular the emergence of a power law in relaxation spectra, in quantitative agreement with the excess wings observed experimentally. Detailed analysis of particle motion shows that this power law directly originates from broadly distributed processes experienced by rare, localised regions relaxing much before the bulk. We explain why these wings appear in "excess" by constructing an empirical model associating heterogeneous activated dynamics and dynamic facilitation, which appear to be the two minimal physical ingredients revealed by our simulations.