G. Röpke, “Electrical conductivity of charged particle systems and Zubarev's nonequilibrium statistical operator method”, TMF, 194:1 (2018), 90–126; Theoret. and Math. Phys., 194:1 (2018), 74

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Teoreticheskaya i Matematicheskaya Fizika, 2018, Volume 194, Number 1, Pages 90–126
DOI: https://doi.org/10.4213/tmf9402 (Mi tmf9402)

This article is cited in 12 scientific papers (total in 12 papers)

Electrical conductivity of charged particle systems and Zubarev's nonequilibrium statistical operator method

G. Röpke

Institute of Physics, University of Rostock, Rostock, Germany

Full-text PDF (682 kB) Citations (12)

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DOI: https://doi.org/10.4213/tmf9402

Abstract: One of the fundamental problems in physics that are not yet rigorously solved is the statistical mechanics of nonequilibrium processes. An important contribution to describing irreversible behavior starting from reversible Hamiltonian dynamics was given by D. N. Zubarev, who invented the method of the nonequilibrium statistical operator. We discuss this approach, in particular, the extended von Neumann equation, and as an example consider the electrical conductivity of a system of charged particles. We consider the selection of the set of relevant observables. We show the relation between kinetic theory and linear response theory. Using thermodynamic Green's functions, we present a systematic treatment of correlation functions, but the convergence needs investigation. We compare different expressions for the conductivity and list open questions.

Keywords: nonequilibrium statistical operator, electrical conductivity, linear response theory, kinetic theory, Kubo–Greenwood approach.

Received: 23.05.2017
Revised: 13.07.2017

English version:
Theoretical and Mathematical Physics, 2018, Volume 194, Issue 1, Pages 74–104
DOI: https://doi.org/10.1134/S0040577918010063

Bibliographic databases:

Document Type: Article

Language: Russian

Citation: G. Röpke, “Electrical conductivity of charged particle systems and Zubarev's nonequilibrium statistical operator method”, TMF, 194:1 (2018), 90–126; Theoret. and Math. Phys., 194:1 (2018), 74–104

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This publication is cited in the following 12 articles:

G. Röpke, “Electrical conductivity of hydrogen plasmas: Low-density benchmarks and virial expansion including e–e collisions”, Physics of Plasmas, 31:4 (2024)
V. S. Karakhtanov, “Dynamical screening in the description of plasma transport properties with arbitrary degeneracy”, Contrib. Plasma Phys., 62:3 (2022)
Yu. Bokhan, “Thermoelectric elements with negative temperature factor of resistance”, Thermoelectricity - Recent Advances, New Perspectives and Applications, 2022
M. French, G. Röpke, M. Schörner, M. Bethkenhagen, M. P. Desjarlais, R. Redmer, “Electronic transport coefficients from density functional theory across the plasma plane”, Phys. Rev. E, 105:6 (2022)
M. Veysman, G. Roepke, H. Reinholz, “Dynamical conductivity of warm dense matter from correlation functions with account for interband transitions”, Phys. Plasmas, 28:10 (2021), 103303
Rodrigues C.G., “Electron Mobility in Bulk N-Doped Sic-Polytypes 3C-Sic, 4H-Sic, and 6H-Sic: a Comparison”, Semiconductors, 55:7 (2021), 625–632
C. G. Rodrigues, R. Luzzi, “Nonlinear charge transport in highly polar semiconductors: gan, aln, inn and gaas”, Pramana-J. Phys., 95:1 (2021), 44
B. B. L. Witte, G. Roepke, P. Neumayer, M. French, P. Sperling, V. Recoules, S. H. Glenzer, R. Redmer, “Comment on “isochoric, isobaric, and ultrafast conductivities of aluminum, lithium, and carbon in the warm dense matter regime””, Phys. Rev. E, 99:4 (2019), 047201
A. M. D. Correa, C. G. Rodrigues, R. Luzzi, “Electron transport in bulk n-doped 3c-sic by using a non-equilibrium quantum kinetic theory”, Eur. Phys. J. B, 92:11 (2019), 261
Mikhail Veysman, Gerd Röpke, Heidi Reinholz, “Application of the Non-Equilibrium Statistical Operator Method to the Dynamical Conductivity of Metallic and Classical Plasmas”, Particles, 2:2 (2019), 242
Gerd Röpke, Non-Equilibrium Particle Dynamics, 2019
Gerd Röpke, “The Source Term of the Non-Equilibrium Statistical Operator”, Particles, 2:2 (2019), 309

Citing articles in Google Scholar: Russian citations, English citations
Related articles in Google Scholar: Russian articles, English articles

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