Abstract
In this work we formulate an efficient method for the description of fully many-body localized systems in weak contact with thermal environments at temperature T. The key idea is to exploit the representation of the system in terms of quasi-local integrals of motion (l-bits) to efficiently derive the generator for the quantum master equation in Born–Markov approximation. We, moreover, show how to compute the steady state of this equation efficiently by using quantum-jump Monte-Carlo techniques as well as by deriving approximate kinetic equations of motion. As an example, we consider a one-dimensional disordered extended Hubbard model for spinless fermions, for which we derive the l-bit representation approximately by employing a recently proposed method valid in the limit of strong disorder and weak interactions. Coupling the system to a global thermal bath, we study the transport between two leads with different chemical potentials at both of its ends. We find that the temperature-dependent current is captured by an interaction-dependent version of Mott’s law for variable range hopping, where transport is enhanced/lowered depending on whether the interactions are attractive or repulsive, respectively. We interpret these results in terms of spatio-energetic correlations between the l-bits.
Highlights
Many-body localization (MBL) has emerged as a new paradigm for phase structures in interacting quantum matter protected by the underlying robust nonergodicity imposed by strong disorder [1,2,3,4,5,6]
We focus on the limit of weak interactions, where it is assumed that there exists a quasi-local transformation between the l-bits and the local annihilation operators ai for fermions on lattice sites i [4, 40]
All of our results are obtained in the limit of weak interactions and strong disorder in which the approximation [Eq (30)] is justified
Summary
Many-body localization (MBL) has emerged as a new paradigm for phase structures in interacting quantum matter protected by the underlying robust nonergodicity imposed by strong disorder [1,2,3,4,5,6]. In this work we develop an efficient formalism with which we can access the steady states of MBL systems weakly coupled to thermal environments We apply this method to a spinless fermionic Hubbard chain with strong onsite disorder and weak interactions, where we achieve to solve for mesoscopic system sizes of the order of 100 lattice sites. While deriving explicitly the lbit representation is in general a demanding task, here, we make use of a recently proposed efficient approximate method controlled in the limit of strong disorder and weak interactions [35] We show how this derived quantum master equation can be solved by means of quantum-jump Monte-Carlo simulations [36]. In order to push our description to even larger systems we use a further simplification of the quantum master equation in terms of a kinetic theory, which as we show provides an accurate description with the advantage that it allows us to reach system sizes of the order of 100 lattice sites
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