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Defining Stable Phases of Open Quantum Systems

Tibor Rakovszky, Sarang Gopalakrishnan, Curt von Keyserlingk

2024Physical Review X22 citationsDOIOpen Access PDF

Abstract

The steady states of dynamical processes can exhibit stable nontrivial phases, which can also serve as fault-tolerant classical or quantum memories. For Markovian quantum (classical) dynamics, these steady states are extremal eigenvectors of the non-Hermitian operators that generate the dynamics, i.e., quantum channels (Markov chains). However, since these operators are non-Hermitian, their spectra are an unreliable guide to dynamical relaxation timescales or to stability against perturbations. We propose an alternative dynamical criterion for a steady state to be in a stable phase, which we name uniformity: Informally, our criterion amounts to requiring that, under sufficiently small local perturbations of the dynamics, the unperturbed and perturbed steady states are related to one another by a finite-time dissipative evolution. We show that this criterion implies many of the properties one would want from any reasonable definition of a phase. We prove that uniformity is satisfied in a canonical classical cellular automaton, and we provide numerical evidence that the gap determines the relaxation rate between nearby steady states in the same phase, a situation we conjecture holds generically whenever uniformity is satisfied. We further conjecture some sufficient conditions for a channel to exhibit uniformity and therefore stability. Published by the American Physical Society 2024

Topics & Concepts

Dissipative systemQuantumStatistical physicsConjectureEigenvalues and eigenvectorsHermitian matrixSteady state (chemistry)Cellular automatonPhysicsStability (learning theory)Open quantum systemQuantum decoherenceMarkov chainMathematicsQuantum mechanicsComputer sciencePure mathematicsMachine learningAlgorithmPhysical chemistryStatisticsChemistryQuantum many-body systemsQuantum chaos and dynamical systemsQuantum Mechanics and Non-Hermitian Physics
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