Many-body localization and enhanced non-ergodic sub-diffusive regime in the presence of random long-range interactions

Abstract

We study many-body localization (MBL) in a one-dimensional system of spinless fermions with a deterministic aperiodic potential in the presence of long-range interactions decaying as power-law Vij/(ri-rj)α with distance and having random coefficients Vij. We demonstrate that MBL survives even for α <1 and is preceded by a broad non-ergodic sub-diffusive phase. Starting from parameters at which the short-range interacting system shows infinite temperature MBL phase, turning on random power-law interactions results in many-body mobility edges in the spectrum with a larger fraction of ergodic delocalized states for smaller values of α. Hence, the critical disorder hcr, at which ergodic to non-ergodic transition takes place increases with the range of interactions. Time evolution of the density imbalance I(t), which has power-law decay I(t) t-γ in the intermediate to large time regime, shows that the critical disorder hcI, above which the system becomes diffusion-less (with γ 0) and transits into the MBL phase is much larger than hcr. In between hcr and hcI there is a broad non-ergodic sub-diffusive phase, which is characterized by the Poissonian statistics for the level spacing ratio, multifractal eigenfunctions and a non zero dynamical exponent γ 1/2. The system continues to be sub-diffusive even on the ergodic side (h < hcr) of the MBL transition, where the eigenstates near the mobility edges are multifractal. For h < h0<hcr, the system is super-diffusive with γ >1/2. The rich phase diagram obtained here is unique to random nature of long-range interactions. We explain this in terms of the enhanced correlations among local energies of the effective Anderson model induced by random power-law interactions.