Conservative forces are the unique minimizers of renormalized entropy production in jump processes, restoring their optimality for optimal transport.
Thermodynamic interpretation of wasserstein distance
5 Pith papers cite this work. Polarity classification is still indexing.
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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.
Generalized free energy from large deviations enables excess/housekeeping decomposition of fluxes and dissipation plus thermodynamic speed limits in driven nonequilibrium systems.
A geometric decomposition of entropy production rate in reaction-diffusion systems isolates excess dissipation driving patterns and yields speed limits, uncertainty relations, and an optimal-transport extension for efficient pattern formation.
Stochastic thermodynamics is expanding to memory effects, active matter, geometric methods, and non-physical domains while the link between irreversibility and dissipation weakens at larger scales.
citing papers explorer
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Renormalized entropy production for optimal transport in jump processes: Make conservative forces optimal again
Conservative forces are the unique minimizers of renormalized entropy production in jump processes, restoring their optimality for optimal transport.
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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.
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Generalized free energy and excess/housekeeping decomposition in nonequilibrium systems: from large deviations to thermodynamic speed limits
Generalized free energy from large deviations enables excess/housekeeping decomposition of fluxes and dissipation plus thermodynamic speed limits in driven nonequilibrium systems.
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Geometric thermodynamics of reaction-diffusion systems: Thermodynamic trade-off relations and optimal transport for pattern formation
A geometric decomposition of entropy production rate in reaction-diffusion systems isolates excess dissipation driving patterns and yields speed limits, uncertainty relations, and an optimal-transport extension for efficient pattern formation.
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Quo vadis, stochastic thermodynamics?
Stochastic thermodynamics is expanding to memory effects, active matter, geometric methods, and non-physical domains while the link between irreversibility and dissipation weakens at larger scales.