Re-localization due to finite response times in a nonlinear Anderson chain

Abstract

We study a disordered nonlinear Schr\"odinger equation with an additional relaxation process having a finite response time τ. Without the relaxation term, τ=0, this model has been widely studied in the past and numerical simulations showed subdiffusive spreading of initially localized excitations. However, recently Caetano et al.\ (EPJ. B 80, 2011) found that by introducing a response time τ > 0, spreading is suppressed and any initially localized excitation will remain localized. Here, we explain the lack of subdiffusive spreading for τ>0 by numerically analyzing the energy evolution. We find that in the presence of a relaxation process the energy drifts towards the band edge, which enforces the population of fewer and fewer localized modes and hence leads to re-localization. The explanation presented here is based on previous findings by the authors et al.\ (PRE 80, 2009) on the energy dependence of thermalized states.