Dissipation and the relaxation to equilibrium

Denis J. Evans; Debra J. Searles; Stephen R. Williams

doi:10.1088/1742-5468/2009/07/P07029

Dissipation and the relaxation to equilibrium

Denis J. Evans, Debra J. Searles, Stephen R. Williams

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35 Citations (SciVal)

Abstract

Using the recently derived dissipation theorem and a corollary of the transient fluctuation theorem (TFT), namely the second-law inequality, we derive the unique time independent, equilibrium phase space distribution function for an ergodic Hamiltonian system in contact with a remote heat bath. We prove under very general conditions that any deviation from this equilibrium distribution breaks the time independence of the distribution. Provided temporal correlations decay, we show that any nonequilibrium distribution that is an even function of the momenta eventually relaxes (not necessarily monotonically) to the equilibrium distribution. Finally we prove that the negative logarithm of the microscopic partition function is equal to the thermodynamic Helmholtz free energy divided by the thermodynamic temperature and Boltzmann's constant. Our results complement and extend the findings of modern ergodic theory and show the importance of dissipation in the process of relaxation towards equilibrium.

Original language	English
Article number	P07029
Journal	Journal of Statistical Mechanics: Theory and Experiment
Volume	2009
Issue number	7
DOIs	https://doi.org/10.1088/1742-5468/2009/07/P07029
Publication status	Published - 2009

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AU - Searles, Debra J.

AU - Williams, Stephen R.

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AB - Using the recently derived dissipation theorem and a corollary of the transient fluctuation theorem (TFT), namely the second-law inequality, we derive the unique time independent, equilibrium phase space distribution function for an ergodic Hamiltonian system in contact with a remote heat bath. We prove under very general conditions that any deviation from this equilibrium distribution breaks the time independence of the distribution. Provided temporal correlations decay, we show that any nonequilibrium distribution that is an even function of the momenta eventually relaxes (not necessarily monotonically) to the equilibrium distribution. Finally we prove that the negative logarithm of the microscopic partition function is equal to the thermodynamic Helmholtz free energy divided by the thermodynamic temperature and Boltzmann's constant. Our results complement and extend the findings of modern ergodic theory and show the importance of dissipation in the process of relaxation towards equilibrium.

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DO - 10.1088/1742-5468/2009/07/P07029

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VL - 2009

JO - Journal of Statistical Mechanics: Theory and Experiment

JF - Journal of Statistical Mechanics: Theory and Experiment

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Dissipation and the relaxation to equilibrium

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