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Quantum and Classical Ergotropy from Relative Entropies

Akira Sone, Sebastian Deffner

2021Entropy28 citationsDOIOpen Access PDF

Abstract

The quantum ergotropy quantifies the maximal amount of work that can be extracted from a quantum state without changing its entropy. Given that the ergotropy can be expressed as the difference of quantum and classical relative entropies of the quantum state with respect to the thermal state, we define the classical ergotropy, which quantifies how much work can be extracted from distributions that are inhomogeneous on the energy surfaces. A unified approach to treat both quantum as well as classical scenarios is provided by geometric quantum mechanics, for which we define the geometric relative entropy. The analysis is concluded with an application of the conceptual insight to conditional thermal states, and the correspondingly tightened maximum work theorem.

Topics & Concepts

QuantumWork (physics)Quantum discordQuantum thermodynamicsPhysicsStatistical physicsQuantum relative entropyState (computer science)ThermalQuantum stateQuantum mechanicsQuantum algorithmKullback–Leibler divergenceMathematicsQuantum operationQuantum processClassical capacityQuantum systemOpen quantum systemQuantum dissipationQuantum informationEntropy (arrow of time)Energy (signal processing)Theoretical physicsClassical mechanicsGeneralized relative entropyQuantum mutual informationAdvanced Thermodynamics and Statistical MechanicsStatistical Mechanics and EntropyQuantum many-body systems
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