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Mass transport thermodynamics in nonisothermal molecular liquid mixtures

 a,  b
a Institute for Biochemical Physics, Russian Academy of Sciences, ul. Kosygina 4, Moscow, 119334, Russian Federation
b Department of Chemistry, Boise State University, Boise, Idaho, USA

Mass transport in a nonisothermal binary molecular mixture is systematically discussed in terms of nonequilibrium thermodynamics, which for the first time allows a consistent and unambiguous description of the process. The thermodynamic and hydrodynamic approaches are compared, revealing that nonequilibrium thermodynamics and physicochemical hydrodynamics yield essentially the same results for molecular systems. The applicability limits for the proposed version of the thermodynamic approach are determined for large particles.

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Fulltext is also available at DOI: 10.3367/UFNe.0179.200910d.1105
PACS: 05.70.Ln, 66.10.C− (all)
DOI: 10.3367/UFNe.0179.200910d.1105
URL: https://ufn.ru/en/articles/2009/10/d/
000274503800004
2-s2.0-76649084570
2009PhyU...52.1045S
Citation: Semenov S N, Schimpf M E "Mass transport thermodynamics in nonisothermal molecular liquid mixtures" Phys. Usp. 52 1045–1054 (2009)
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Оригинал: Семенов С Н, Шимпф М Е «О термодинамике массопереноса в неизотермических молекулярных жидких смесях» УФН 179 1105–1115 (2009); DOI: 10.3367/UFNr.0179.200910d.1105

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  1. S.L. Sobolev “Local non-equilibrium transport models40 1043–1053 (1997)
  2. G.A. Martynov “Nonequilibrium statistical mechanics, transport equations, and the second law of thermodynamics39 1045–1070 (1996)
  3. V.V. Brazhkin, R.N. Voloshin et alPhase equilibria in partially open systems under pressure: the decomposition of stoichiometric GeO2 oxide46 1283–1289 (2003)
  4. I.E. Mazets “Kinetic equation including wave function collapses41 505–507 (1998)
  5. V.A. Davydov, V.G. Morozov “Galilean transformations and evolution of autowave fronts in external fields39 305–311 (1996)
  6. R.P. Poplavskii “Maxwell demon and the correspondence between information and entropy22 371–380 (1979)
  7. G. Oppen “Objects and environment39 617–622 (1996)
  8. A.B. Brailovskii, V.L. Vaks, V.V. Mityugov “Quantum models of relaxation39 745–750 (1996)
  9. B.B. Kadomtsev “Classical and quantum irreversibility38 923–929 (1995)
  10. V.V. Mityugov “Thermodynamics of simple quantum systems43 631–637 (2000)
  11. V.S. Olkhovsky “On time as a quantum observable canonically conjugate to energy54 829–835 (2011)
  12. E.L. Nolle “Tunneling photoeffect mechanism in metallic nanoparticles activated by cesium and oxygen50 1079–1082 (2007)
  13. V.V. Brazhkin “Can glassforming liquids be 'simple'?62 623–629 (2019)
  14. V.S. Beskin, V.I. Par’ev “Axially symmetric steady-state flows in the vicinity of a Kerr black hole and the nature of the activity of galactic nuclei36 (6) 529–539 (1993)
  15. Yu.L. Klimontovich “Fluctuation-dissipation relations. Role of the finiteness of the correlation time. Quantum generalization of Nyquist’s formula30 154–167 (1987)
  16. V.L. Ginzburg, L.P. Pitaevskii “Quantum Nyquist formula and the applicability ranges of the Callen-Welton formula30 168–171 (1987)

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