Predicting nonlinear physical aging of glasses from equilibrium relaxation via the material time

The noncrystalline glassy state of matter plays a role in virtually all fields of material science and offers complementary properties to those of the crystalline counterpart. The caveat of the glassy state is that it is out of equilibrium and therefore exhibits physical aging, i.e. the material properties change over time. For half a century the physical aging of glasses has been known to be described well by the material-time concept, though the existence of a material time has never been directly validated. We do this here by successfully predicting the nonlinear aging of the molecular glass 4-vinyl-1,3-dioxolan-2-one from its linear relaxation behavior. This establishes the defining property of the material time. Via the fluctuation-dissipation theorem our result imply that physical aging can be predicted from thermal-equilibrium fluctuation data and we confirm this by computer simulations of abinary model liquid.