A unified geometric formalism shows that mean dissipated availability and its fluctuations in microscopic heat engines are governed by metric tensors from equilibrium correlation functions in the linear-response regime.
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Derives duality between dissipation-coherence trade-off and thermodynamic speed limit for general stochastic limit cycles via dual observables substituted into the thermodynamic uncertainty relation in the weak-noise limit.
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Unified geometric formalism for dissipation and its fluctuations in finite-time microscopic heat engines
A unified geometric formalism shows that mean dissipated availability and its fluctuations in microscopic heat engines are governed by metric tensors from equilibrium correlation functions in the linear-response regime.
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Duality between dissipation-coherence trade-off and thermodynamic speed limit based on thermodynamic uncertainty relation for stochastic limit cycles
Derives duality between dissipation-coherence trade-off and thermodynamic speed limit for general stochastic limit cycles via dual observables substituted into the thermodynamic uncertainty relation in the weak-noise limit.