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Direct Route to Thermodynamic Uncertainty Relations and Their Saturation

Cai Dieball, Aljaž Godec

2023Physical Review Letters54 citationsDOIOpen Access PDF

Abstract

Thermodynamic uncertainty relations (TURs) bound the dissipation in nonequilibrium systems from below by fluctuations of an observed current. Contrasting the elaborate techniques employed in existing proofs, we here prove TURs directly from the Langevin equation. This establishes the TUR as an inherent property of overdamped stochastic equations of motion. In addition, we extend the transient TUR to currents and densities with explicit time dependence. By including current-density correlations we, moreover, derive a new sharpened TUR for transient dynamics. Our arguably simplest and most direct proof, together with the new generalizations, allows us to systematically determine conditions under which the different TURs saturate and thus allows for a more accurate thermodynamic inference. Finally, we outline the direct proof also for Markov jump dynamics.

Topics & Concepts

Statistical physicsMathematical proofNon-equilibrium thermodynamicsJumpMarkov processLangevin equationLangevin dynamicsInferencePhysicsMarkov chainDissipationTransient (computer programming)Computer scienceCurrent (fluid)Applied mathematicsThermodynamicsMathematicsQuantum mechanicsArtificial intelligenceStatisticsGeometryOperating systemMachine learningAdvanced Thermodynamics and Statistical MechanicsNeural dynamics and brain functionQuantum Mechanics and Applications
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