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Quantum correlation entropy

Joseph Schindler, Dominik Šafránek, Anthony Aguirre

2020Physical review. A/Physical review, A21 citationsDOIOpen Access PDF

Abstract

We study quantum coarse-grained entropy and demonstrate that the gap in entropy between local and global coarse-grainings is a natural generalization of entanglement entropy to mixed states and multipartite systems. This ``quantum correlation entropy'' ${S}^{q}c$ is additive over independent systems, is invariant under local unitary operations, measures total nonclassical correlations (vanishing on states with strictly classical correlation), and reduces to the entanglement entropy for bipartite pure states. It quantifies how well a quantum system can be understood via local measurements and ties directly to nonequilibrium thermodynamics, including representing a lower bound on the quantum part of thermodynamic entropy production. We discuss two other measures of nonclassical correlation to which this entropy is equivalent and argue that together they provide a unique thermodynamically distinguished measure.

Topics & Concepts

Quantum discordJoint quantum entropyQuantum relative entropyQuantum entanglementGeneralized relative entropyStatistical physicsEntropy (arrow of time)Unitary statePhysicsQuantum mechanicsMathematicsQuantumLawPolitical scienceAdvanced Thermodynamics and Statistical MechanicsQuantum many-body systemsQuantum Information and Cryptography
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