Long-Range Coherence and Multiple Steady States in a Lossy Qubit Array
Shovan Dutta, Nigel R. Cooper
Abstract
We show that a simple experimental setting of a locally pumped and lossy array of two-level quantum systems can stabilize states with strong long-range coherence. Indeed, by explicit analytic construction, we show there is an extensive set of steady-state density operators, from minimally to maximally entangled, despite this being an interacting open many-body problem. Such nonequilibrium steady states arise from a hidden symmetry that stabilizes Bell pairs over arbitrarily long distances, with unique experimental signatures. We demonstrate a protocol by which one can selectively prepare these states using dissipation. Our findings are accessible in present-day experiments.
Topics & Concepts
Coherence (philosophical gambling strategy)QubitLossy compressionPhysicsDissipationQuantumNon-equilibrium thermodynamicsStatistical physicsRange (aeronautics)Simple (philosophy)Steady state (chemistry)Set (abstract data type)Quantum mechanicsTopology (electrical circuits)Computer scienceMathematicsEngineeringArtificial intelligencePhilosophyCombinatoricsEpistemologyAerospace engineeringChemistryPhysical chemistryProgramming languageQuantum Information and CryptographyQuantum and electron transport phenomenaCold Atom Physics and Bose-Einstein Condensates