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Energetic footprints of irreversibility in the quantum regime

M. H. Mohammady, A. Auffèves, J. Anders

2020Communications Physics29 citationsDOIOpen Access PDF

Abstract

Abstract In classical thermodynamic processes the unavoidable presence of irreversibility, quantified by the entropy production, carries two energetic footprints: the reduction of extractable work from the optimal, reversible case, and the generation of a surplus of heat that is irreversibly dissipated to the environment. Recently it has been shown that in the quantum regime an additional quantum irreversibility occurs that is linked to decoherence into the energy basis. Here we employ quantum trajectories to construct distributions for classical heat and quantum heat exchanges, and show that the heat footprint of quantum irreversibility differs markedly from the classical case. We also quantify how quantum irreversibility reduces the amount of work that can be extracted from a state with coherences. Our results show that decoherence leads to both entropic and energetic footprints which both play an important role in the optimization of controlled quantum operations at low temperature.

Topics & Concepts

Quantum decoherenceQuantum thermodynamicsQuantumPhysicsQuantum dissipationQuantum discordWork (physics)Quantum mechanicsStatistical physicsEntropy (arrow of time)Quantum fluctuationEntropy productionDissipationQuantum processOpen quantum systemQuantum stateQuantum systemQuantum operationNon-equilibrium thermodynamicsQuantum entanglementQuantum dynamicsThermal management of electronic devices and systemsQuantum phasesExcess heatClassical mechanicsQuantum relative entropyQuantum algorithmQuantum technologyQuantum computerQuantum error correctionHeat engineAmplitude damping channelAdvanced Thermodynamics and Statistical MechanicsQuantum many-body systemsStatistical Mechanics and Entropy
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