Finite-Size Effects in Aging can be Interpreted as Sub-Aging

Abstract

Systems brought out of equilibrium through a rapid quench from a disordered initial state into an ordered phase undergo physical aging in the form of phase-ordering kinetics, with characteristic dynamical scaling. In many systems, notably glasses, dynamical scaling is often described through sub-aging, where a phenomenological sub-aging exponent 0<μ< 1 is empirically chosen to achieve the best possible data collapse. Here it is shown that finite-size effects modify the dynamical scaling behavior, away from simple aging with μ=1 towards μ<1, such that phenomenologically it would appear as sub-aging. This is exemplified for the exactly solved dynamical spherical model in dimensions 2<d<4 and numerical simulations of the two-dimensional Ising model, with short-ranged and long-ranged interactions.