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Probing quantum correlations in many-body systems: a review of scalable methods

Irénée Frérot, Matteo Fadel, Maciej Lewenstein

2023Reports on Progress in Physics48 citationsDOIOpen Access PDF

Abstract

We review methods that allow one to detect and characterize quantum correlations in many-body systems, with a special focus on approaches which are scalable. Namely, those applicable to systems with many degrees of freedom, without requiring a number of measurements or computational resources to analyze the data that scale exponentially with the system size. We begin with introducing the concepts of quantum entanglement, Einstein-Podolsky-Rosen steering, and Bell nonlocality in the bipartite scenario, to then present their multipartite generalization. We review recent progress on characterizing these quantum correlations from partial information on the system state, such as through data-driven methods or witnesses based on low-order moments of collective observables. We then review state-of-the-art experiments that demonstrate the preparation, manipulation and detection of highly-entangled many-body systems. For each platform (e.g. atoms, ions, photons, superconducting circuits) we illustrate the available toolbox for state preparation and measurement, emphasizing the challenges that each system poses. To conclude, we present a list of timely open problems in the field.

Topics & Concepts

Quantum entanglementComputer scienceQuantum nonlocalityScalabilityMultipartiteObservableQuantumTheoretical computer scienceQuantum stateStatistical physicsQuantum informationField (mathematics)PhysicsTheoretical physicsQuantum mechanicsMathematicsPure mathematicsDatabaseCold Atom Physics and Bose-Einstein CondensatesQuantum Mechanics and ApplicationsQuantum many-body systems
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