Memories of initial states and density imbalance in dynamics of interacting disordered systems

Abstract

We study the dynamics of one and two dimensional disordered lattice bosons/fermions initialized to a Fock state with a pattern of 1 and 0 particles on A and A sites. For non-interacting systems we establish a universal relation between the long time density imbalance between A and A site, I(∞), the localization length l, and the geometry of the initial pattern. For alternating initial pattern of 1 and 0 particles in 1 dimension, I(∞)=[a/l], where a is the lattice spacing. For systems with mobility edge, we find analytic relations between I(∞), the effective localization length l and the fraction of localized states fl. The imbalance as a function of disorder shows non-analytic behaviour when the mobility edge passes through a band edge. For interacting bosonic systems, we show that dissipative processes lead to a decay of the memory of initial conditions. However, the excitations created in the process act as a bath, whose noise correlators retain information of the initial pattern. This sustains a finite imbalance at long times in strongly disordered interacting systems.