Sub-diffusion in the Anderson model on random regular graph

Abstract

We study the finite-time dynamics of an initially localized wave-packet in the Anderson model on the random regular graph (RRG). Considering the full probability distribution (x,t) of a particle to be at some distance x from the initial state at time t, we give evidence that (x,t) spreads sub-diffusively over a range of disorder strengths, wider than a putative non-ergodic phase. We provide a detailed analysis of the propagation of (x,t) in space-time (x,t) domain, identifying four different regimes. These regimes in (x,t) are determined by the position of a wave-front Xfront(t), which moves sub-diffusively to the most distant sites Xfront(t) tβ with an exponent β < 1. We support our numerical results by a self-consistent semiclassical picture of wavepacket propagation relating the exponent β with the relaxation rate of the return probability (0,t) e- tβ. Importantly, the Anderson model on the RRG can be considered as proxy of the many-body localization transition (MBL) on the Fock space of a generic interacting system. In the final discussion, we outline possible implications of our findings for MBL.