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Phenomenology of the Prethermal Many-Body Localized Regime

David M. Long, Philip J. D. Crowley, Vedika Khemani, Anushya Chandran

2023Physical Review Letters56 citationsDOIOpen Access PDF

Abstract

The dynamical phase diagram of interacting disordered systems has seen substantial revision over the past few years. Theory must now account for a large prethermal many-body localized regime in which thermalization is extremely slow, but not completely arrested. We derive a quantitative description of these dynamics in short-ranged one-dimensional systems using a model of successive many-body resonances. The model explains the decay timescale of mean autocorrelators, the functional form of the decay-a stretched exponential-and relates the value of the stretch exponent to the broad distribution of resonance timescales. The Jacobi method of matrix diagonalization provides numerical access to this distribution, as well as a conceptual framework for our analysis. The resonance model correctly predicts the stretch exponents for several models in the literature. Successive resonances may also underlie slow thermalization in strongly disordered systems in higher dimensions, or with long-range interactions.

Topics & Concepts

PhysicsThermalisationPhenomenology (philosophy)Statistical physicsExponentMany-body theoryResonance (particle physics)Phase diagramExponential functionMany-body problemRandom matrixExponential decayQuantum mechanicsPhase (matter)Mathematical analysisMathematicsPhilosophyEpistemologyLinguisticsEigenvalues and eigenvectorsQuantum many-body systemsPhysics of Superconductivity and MagnetismOpinion Dynamics and Social Influence
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