In a minimal non-reciprocal graphene model, quantum capacitance scales as (1 - β²)^{-1} near the exceptional point, offering an equilibrium thermodynamic signature of non-Hermiticity.
Kosloff, Quantum thermodynamics: A dynamical viewpoint, Entropy15, 2100 (2013)
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The paper demonstrates a quantum Mpemba-like effect during Unruh thermalization of a UDW detector and identifies maximum fidelity difference as a diagnostic distinguishing quantum Unruh thermalization from classical thermal bath effects.
Multilayer graphene quantum Stirling engines reach Carnot efficiency at low magnetic fields and moderate temperatures, with AB-stacked bilayer showing the broadest viable parameter range.
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Thermodynamic signatures of non-Hermiticity in Dirac materials via quantum capacitance
In a minimal non-reciprocal graphene model, quantum capacitance scales as (1 - β²)^{-1} near the exceptional point, offering an equilibrium thermodynamic signature of non-Hermiticity.
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Quantum Mpemba-like effect in Unruh thermalization
The paper demonstrates a quantum Mpemba-like effect during Unruh thermalization of a UDW detector and identifies maximum fidelity difference as a diagnostic distinguishing quantum Unruh thermalization from classical thermal bath effects.
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Reaching maximum efficiency in quantum Stirling engines using multilayer graphene
Multilayer graphene quantum Stirling engines reach Carnot efficiency at low magnetic fields and moderate temperatures, with AB-stacked bilayer showing the broadest viable parameter range.