Scaling of Fock-space propagator and multifractality across the many-body localization transition

Abstract

We implement a recursive Green function method to extract the Fock space (FS) propagator and associated self-energy across the many-body localization (MBL) transition, for one-dimensional interacting fermions in a random onsite potential. We show that the typical value of the imaginary part of the local FS self-energy, t, related to the decay rate of an initially localized state, acts as a probabilistic order parameter for the thermal to MBL phase transition; and can be used to characterize critical properties of the transition as well as the multifractal nature of MBL states as a function of disorder strength W. In particular, we show that a fractal dimension Ds extracted from t jumps discontinuously across the transition, from Ds<1 in the MBL phase to Ds= 1 in the thermal phase. Moreover, t follows an asymmetrical finite-size scaling form across the thermal-MBL transition, where a non-ergodic volume in the thermal phase diverges with a Kosterlitz-Thouless like essential singularity at the critical point Wc, and controls the continuous vanishing of t as Wc is approached. In contrast, a correlation length () extracted from t exhibits a power-law divergence on approaching Wc from the MBL phase.