From sub-aging to hyper-aging in structural glasses

Abstract

We demonstrate non-equilibrium scaling laws for the aging dynamics in glass formers that emerge from combining a recent application of Onsager's theory of irreversible processes with the equilibrium scaling laws of glassy dynamics. Different scaling regimes are predicted for the evolution of the system's structural relaxation time τ with age (waiting time tw), depending on the depth of the quench from the liquid into the glass: simple aging (τ tw) applies for quenches close to the critical point of mode-coupling theory (MCT) and implies sub-aging (τ≈\ twδ with δ<1) as a broad cross-over for quenches to nearly-arrested equilibrium states; hyper-aging (or super-aging, τ twδ' with δ'>1) emerges for quenches deep into the glass. The latter is cut off by non-mean-field fluctuations that we account for within a recent extension of MCT, the stochastic β-relaxation theory (SBR). We exemplify the scaling laws by a schematic model that allows to quantitatively fit recent simulation results for density-quenched hard-sphere-like particles.