Density propagator for many-body localization: finite size effects, transient subdiffusion, and exponential decay

Abstract

We investigate charge relaxation in quantum-wires of spin-less disordered fermions (t-V-model). Our observable is the time-dependent density propagator, (x,t), calculated in windows of different energy density, , of the many-body Hamiltonian and at different disorder strengths, W, not exceeding the critical value Wc. The width x(t) of (x,t) exhibits a behavior d x(t) / d t = β(t), where the exponent function β(t)1/2 is seen to depend strongly on L at all investigated parameter combinations. (i) We confirm the existence of a region in phase space that exhibits subdiffusive dynamics in the sense that β<1/2 in large window of times. However, subdiffusion might possibly be transient, only, finally giving way to a conventional diffusive behavior with β=1/2. (ii) We cannot confirm the existence of many-body mobility edges even in regions of the phase-diagram that have been reported to be deep in the delocalized phase. (iii) (Transient) subdiffusion 0<β(t) 1/2, coexists with an enhanced probability for returning to the origin, (0,t), decaying much slower than 1/ x (t). Correspondingly, the spatial decay of (x,t) is far from Gaussian being exponential or even slower. On a phenomenological level, our findings are broadly consistent with effects of strong disorder and (fractal) Griffiths regions.