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The Equivalence of Dissipation from Gibbs’ Entropy Production with Phase-Volume Loss in Ergodic Heat-Conducting Oscillators

Advanced Technology Development Center, Department of Civil Engineering, Indian Institute of Technology, Kharagpur, West Bengal 721302, India

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William Graham Hoover

Ruby Valley Research Institute, Highway Contract 60, Box 601, Ruby Valley, Nevada 89833, USA

E-mail Address: hooverwilliam@yahoo.com

Corresponding author

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Carol Griswold Hoover

Ruby Valley Research Institute, Highway Contract 60, Box 601, Ruby Valley, Nevada 89833, USA

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, and

Julien Clinton Sprott

Department of Physics, University of Wisconsin – Madison, Wisconsin 53706, USA

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https://doi.org/10.1142/S0218127416500899Cited by:15 (Source: Crossref)

Abstract

Gibbs’ thermodynamic entropy is given by the logarithm of the phase volume, which itself responds to heat transfer to and from thermal reservoirs. We compare the thermodynamic dissipation described by (i) phase-volume loss with (ii) heat-transfer entropy production. Their equivalence is documented for computer simulations of the response of an ergodic harmonic oscillator to thermostated temperature gradients. In the simulations one or two thermostat variables control the kinetic energy or the kinetic energy and its fluctuation. All of the motion equations are time-reversible. We consider both strong and weak control variables. In every case, the time-averaged dissipative loss of phase-space volume coincides with the entropy produced by heat transfer. Linear-response theory nicely reproduces the small-gradient results obtained by computer simulation. The thermostats considered here are ergodic and provide simple dynamical models, some of them with as few as three ordinary differential equations, while remaining capable of reproducing Gibbs’ canonical phase-space distribution and are precisely consistent with irreversible thermodynamics.

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