Anomalous Heat Diffusion

Abstract

Consider anomalous energy spread in solid phases, i.e., MSD= ∫ (x -< x >E)2 E(x,t)dx tβ, as induced by a small initial excess energy perturbation distribution E(x,t=0) away from equilibrium. The associated total thermal equilibrium heat flux autocorrelation function CJJ(t) is shown to obey rigorously the intriguing relation, d2 MSD/dt2 = 2CJJ(t)/(kBT2c), where c is the specific volumetric heat capacity. Its integral assumes a time-local Helfand-moment relation; i.e. dMSD/dt|t=ts = 2/(kBT2c)∫0ts CJJ(s)ds, where the chosen cut-off time ts is determined by the maximal signal velocity for heat transfer. Given the premise that the averaged nonequilibrium heat flux is governed by an anomalous heat conductivity, energy diffusion scaling necessarily determines a corresponding anomalous thermal conductivity scaling behavior.