 Irreversibility and entropy production in transport phenomena IMasuo Suzuki Physica A: Statistical Mechanics and its Applications, 2011, vol. 390, issue 11, 1904-1916 Abstract: The linear response framework was established a half-century ago, but no persuasive direct derivation of entropy production has been given in this scheme. This long-term puzzle has now been solved in the present paper. The irreversible part of the entropy production in the present theory is given by (dS/dt)irr=(dU/dt)/T with the internal energy U(t) of the relevant system. Here, U(t)=〈H0〉t=TrH0ρ(t) for the Hamiltonian H0 in the absence of an external force and for the density matrix ρ(t). As is well known, we have (dS/dt)irr=0 if we use the linear-order density matrix ρlr(t)=ρ0+ρ1(t). Surprisingly, the correct entropy production is given by the second-order symmetric term ρ2(t) as (dS/dt)irr=(1/T)TrH0ρ2′(t). This is shown to agree with the ordinary expression J⋅E/T=σE2/T in the case of electric conduction for a static electric field E, using the relations TrH0ρ2′(t)=−TrḢ1(t)ρ1(t)=TrȦ⋅Eρ1(t)=J⋅E (Joule heat), which are derived from the second-order von Neumann equation iħdρ2(t)/dt=[H0,ρ2(t)]+[H1(t),ρ1(t)]. Here H1(t) denotes the partial Hamiltonian due to the external force such as H1(t)=−e∑jri⋅E≡−A⋅E in electric conduction. Thus, the linear response scheme is not closed within the first order of an external force, in order to manifest the irreversibility of transport phenomena. New schemes of steady states are also presented by introducing relaxation-type (symmetry-separated) von Neumann equations. The concept of stationary temperature Tst is introduced, which is a function of the relaxation time τr characterizing the rate of extracting heat outside from the system. The entropy production in this steady state depends on the relaxation time. A dynamical-derivative representation method to reveal the irreversibility of steady states is also proposed. The present derivation of entropy production is directly based on the first principles of using the projected density matrix ρ2(t) or more generally symmetric density matrix ρsym(t), while the previous standard argument is due to the thermodynamic energy balance. This new derivation clarifies conceptually the physics of irreversibility in transport phenomena, using the symmetry of non-equilibrium states, and this manifests the duality of current and entropy production. Keywords: Irreversibility; Symmetry; First-principles; Linear response; Electric conduction; Entropy production; Transport phenomena; Projected von Neumann equation; Steady states; Stationary temperature (search for similar items in EconPapers) Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:eee:phsmap:v:390:y:2011:i:11:p:1904-1916 DOI: 10.1016/j.physa.2011.01.008 Access Statistics for this article Physica A: Statistical Mechanics and its Applications is currently edited by K. A. Dawson, J. O. Indekeu, H.E. Stanley and C. Tsallis More articles in Physica A: Statistical Mechanics and its Applications from Elsevier |
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