Extracting Dynamical Maps of Non-Markovian Open Quantum Systems

Abstract

The most general description of quantum evolution up to a time τ is a completely positive tracing preserving map known as a dynamical map (τ). Here we consider (τ) arising from suddenly coupling a system to one or more thermal baths with a strength that is neither weak nor strong. Given no clear separation of characteristic system/bath time scales (τ) is generically expected to be non-Markovian, however we do assume the ensuing dynamics has a unique steady state implying the baths possess a finite memory time τ m. By combining several techniques within a tensor network framework we directly and accurately extract (τ) for a small number of interacting fermionic modes coupled to infinite non-interacting Fermi baths. We employ the Choi-Jamiolkowski isomorphism so that (τ) can be fully reconstructed from a single pure state calculation of the unitary dynamics of the system, bath and their replica auxillary modes up to time τ. From (τ) we also compute the time local propagator L(τ). By examining the convergence with τ of the instantaneous fixed points of these objects we establish their respective memory times τ m and τL m. Beyond these times, the propagator L(τ) and dynamical map (τ) accurately describe all the subsequent long-time relaxation dynamics up to stationarity. Our numerical examples of interacting spinless Fermi chains and the single impurity Anderson model demonstrate regimes where our approach can offer a significant speedup in determining the stationary state compared to directly simulating the long-time limit.