A quantum Maxwell demon near a black hole horizon loses some work extraction ability for external observers due to information inaccessibility but obeys local thermodynamics and preserves the equivalence principle for internal observers.
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Three-level quantum refrigerator shows identical COP for any driving light but cooling power modulated by photon statistics, with sub-Poissonian light yielding higher power than coherent light of same intensity.
A second-order perturbative framework decomposes coherence terms in the quantum first law into coherent heat and work, linking them to Fermi's golden rule transition rates.
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Quantum Maxwell Demon at the Black Hole Horizon: Thermodynamics, Information, and the Equivalence Principle
A quantum Maxwell demon near a black hole horizon loses some work extraction ability for external observers due to information inaccessibility but obeys local thermodynamics and preserves the equivalence principle for internal observers.
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Quantum refrigerator driven by nonclassical light
Three-level quantum refrigerator shows identical COP for any driving light but cooling power modulated by photon statistics, with sub-Poissonian light yielding higher power than coherent light of same intensity.
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Perturbative approach to the first law of quantum thermodynamics
A second-order perturbative framework decomposes coherence terms in the quantum first law into coherent heat and work, linking them to Fermi's golden rule transition rates.