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Ubiquitous quantum scarring does not prevent ergodicity

Saúl Pilatowsky-Cameo, David Villaseñor, Miguel A. Bastarrachea-Magnani, Sergio Lerma-Hernández, Lea F. Santos, Jorge G. Hirsch

2021Nature Communications57 citationsDOIOpen Access PDF

Abstract

In a classically chaotic system that is ergodic, any trajectory will be arbitrarily close to any point of the available phase space after a long time, filling it uniformly. Using Born's rules to connect quantum states with probabilities, one might then expect that all quantum states in the chaotic regime should be uniformly distributed in phase space. This simplified picture was shaken by the discovery of quantum scarring, where some eigenstates are concentrated along unstable periodic orbits. Despite that, it is widely accepted that most eigenstates of chaotic models are indeed ergodic. Our results show instead that all eigenstates of the chaotic Dicke model are actually scarred. They also show that even the most random states of this interacting atom-photon system never occupy more than half of the available phase space. Quantum ergodicity is achievable only as an ensemble property, after temporal averages are performed.

Topics & Concepts

ErgodicityQuantumChaoticPhase spacePhysicsEigenvalues and eigenvectorsStatistical physicsQuantum chaosQuantum systemPhase (matter)Point (geometry)Quantum mechanicsChaotic systemsQuantum stateTrajectorySpace (punctuation)Chaotic hysteresisSynchronization of chaosQuantum phase transitionParameter spaceQuantum dynamicsClassical mechanicsOpen quantum systemQuantum phasesRandom matrixChaotic scatteringQuantum chaos and dynamical systemsQuantum many-body systemsCold Atom Physics and Bose-Einstein Condensates
Ubiquitous quantum scarring does not prevent ergodicity | Litcius