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Simulation of the transport processes in confined conditions. / Rudyak, V. Ya; Belkin, A. A.; Lezhnev, E. V.

International Conference on the Methods of Aerophysical Research, ICMAR 2020. ред. / Vasily M. Fomin; Alexander Shiplyuk. American Institute of Physics Inc., 2021. 030043 (AIP Conference Proceedings; Том 2351).

Результаты исследований: Публикации в книгах, отчётах, сборниках, трудах конференцийстатья в сборнике материалов конференциинаучнаяРецензирование

Harvard

Rudyak, VY, Belkin, AA & Lezhnev, EV 2021, Simulation of the transport processes in confined conditions. в VM Fomin & A Shiplyuk (ред.), International Conference on the Methods of Aerophysical Research, ICMAR 2020., 030043, AIP Conference Proceedings, Том. 2351, American Institute of Physics Inc., 20th International Conference on the Methods of Aerophysical Research, ICMAR 2020, Akademgorodok, Novosibirsk, Российская Федерация, 01.11.2020. https://doi.org/10.1063/5.0052157

APA

Rudyak, V. Y., Belkin, A. A., & Lezhnev, E. V. (2021). Simulation of the transport processes in confined conditions. в V. M. Fomin, & A. Shiplyuk (Ред.), International Conference on the Methods of Aerophysical Research, ICMAR 2020 [030043] (AIP Conference Proceedings; Том 2351). American Institute of Physics Inc.. https://doi.org/10.1063/5.0052157

Vancouver

Rudyak VY, Belkin AA, Lezhnev EV. Simulation of the transport processes in confined conditions. в Fomin VM, Shiplyuk A, Редакторы, International Conference on the Methods of Aerophysical Research, ICMAR 2020. American Institute of Physics Inc. 2021. 030043. (AIP Conference Proceedings). doi: 10.1063/5.0052157

Author

Rudyak, V. Ya ; Belkin, A. A. ; Lezhnev, E. V. / Simulation of the transport processes in confined conditions. International Conference on the Methods of Aerophysical Research, ICMAR 2020. Редактор / Vasily M. Fomin ; Alexander Shiplyuk. American Institute of Physics Inc., 2021. (AIP Conference Proceedings).

BibTeX

@inproceedings{98380ee4992d41f6aee777c4ab567e90,
title = "Simulation of the transport processes in confined conditions",
abstract = "The goal of this paper was to study the viscosity of liquids and gases in nanochannels. The classical molecular dynamics method is used to simulate the viscosity of liquids in nanochannels. However, the transport coefficients are determined by the special fluctuation-dissipation theorems constructed by the authors on the basis of nonequilibrium statistical mechanics. These theorems generalize the well-known Green-Kubo formulas. The dependences of the viscosity coefficient of argon and benzene in channels made of copper and aluminum with square and circular cross-sections on the size of the channel are studied. The fluid viscosity in the channel can be either greater or less than its viscosity in the bulk. It is shown that the effective viscosity of the fluid can be controlled by changing the material of the channel walls. The decisive role in this effect played the depth of the well of the interaction potential of the wall atoms; with its increase, the effective viscosity of the liquid increases. To simulate the transport coefficients of rarefied gases in nanochannels, a method of stochastic molecular modeling has been developed. The walls are assumed to be solid, and the interaction of fluid molecules with them is described by specular, diffuse, or specular-diffuse reflection laws. A strong anisotropy of the viscosity of the gases in nanochannels, even with rather large sizes, has been established. The viscosity coefficients in different directions can differ by more than ten times. In this case the determining role plays the interaction of the gas molecules with the walls of the channel again.",
author = "Rudyak, {V. Ya} and Belkin, {A. A.} and Lezhnev, {E. V.}",
note = "Funding Information: This work was partially supported by the Russian Foundation for Basic Research (grants No. 19-01-00399 and 20-01-00041). Publisher Copyright: {\textcopyright} 2021 Author(s). Copyright: Copyright 2021 Elsevier B.V., All rights reserved.; 20th International Conference on the Methods of Aerophysical Research, ICMAR 2020 ; Conference date: 01-11-2020 Through 07-11-2020",
year = "2021",
month = may,
day = "24",
doi = "10.1063/5.0052157",
language = "English",
series = "AIP Conference Proceedings",
publisher = "American Institute of Physics Inc.",
editor = "Fomin, {Vasily M.} and Alexander Shiplyuk",
booktitle = "International Conference on the Methods of Aerophysical Research, ICMAR 2020",

}

RIS

TY - GEN

T1 - Simulation of the transport processes in confined conditions

AU - Rudyak, V. Ya

AU - Belkin, A. A.

AU - Lezhnev, E. V.

N1 - Funding Information: This work was partially supported by the Russian Foundation for Basic Research (grants No. 19-01-00399 and 20-01-00041). Publisher Copyright: © 2021 Author(s). Copyright: Copyright 2021 Elsevier B.V., All rights reserved.

PY - 2021/5/24

Y1 - 2021/5/24

N2 - The goal of this paper was to study the viscosity of liquids and gases in nanochannels. The classical molecular dynamics method is used to simulate the viscosity of liquids in nanochannels. However, the transport coefficients are determined by the special fluctuation-dissipation theorems constructed by the authors on the basis of nonequilibrium statistical mechanics. These theorems generalize the well-known Green-Kubo formulas. The dependences of the viscosity coefficient of argon and benzene in channels made of copper and aluminum with square and circular cross-sections on the size of the channel are studied. The fluid viscosity in the channel can be either greater or less than its viscosity in the bulk. It is shown that the effective viscosity of the fluid can be controlled by changing the material of the channel walls. The decisive role in this effect played the depth of the well of the interaction potential of the wall atoms; with its increase, the effective viscosity of the liquid increases. To simulate the transport coefficients of rarefied gases in nanochannels, a method of stochastic molecular modeling has been developed. The walls are assumed to be solid, and the interaction of fluid molecules with them is described by specular, diffuse, or specular-diffuse reflection laws. A strong anisotropy of the viscosity of the gases in nanochannels, even with rather large sizes, has been established. The viscosity coefficients in different directions can differ by more than ten times. In this case the determining role plays the interaction of the gas molecules with the walls of the channel again.

AB - The goal of this paper was to study the viscosity of liquids and gases in nanochannels. The classical molecular dynamics method is used to simulate the viscosity of liquids in nanochannels. However, the transport coefficients are determined by the special fluctuation-dissipation theorems constructed by the authors on the basis of nonequilibrium statistical mechanics. These theorems generalize the well-known Green-Kubo formulas. The dependences of the viscosity coefficient of argon and benzene in channels made of copper and aluminum with square and circular cross-sections on the size of the channel are studied. The fluid viscosity in the channel can be either greater or less than its viscosity in the bulk. It is shown that the effective viscosity of the fluid can be controlled by changing the material of the channel walls. The decisive role in this effect played the depth of the well of the interaction potential of the wall atoms; with its increase, the effective viscosity of the liquid increases. To simulate the transport coefficients of rarefied gases in nanochannels, a method of stochastic molecular modeling has been developed. The walls are assumed to be solid, and the interaction of fluid molecules with them is described by specular, diffuse, or specular-diffuse reflection laws. A strong anisotropy of the viscosity of the gases in nanochannels, even with rather large sizes, has been established. The viscosity coefficients in different directions can differ by more than ten times. In this case the determining role plays the interaction of the gas molecules with the walls of the channel again.

UR - http://www.scopus.com/inward/record.url?scp=85107189805&partnerID=8YFLogxK

U2 - 10.1063/5.0052157

DO - 10.1063/5.0052157

M3 - Conference contribution

AN - SCOPUS:85107189805

T3 - AIP Conference Proceedings

BT - International Conference on the Methods of Aerophysical Research, ICMAR 2020

A2 - Fomin, Vasily M.

A2 - Shiplyuk, Alexander

PB - American Institute of Physics Inc.

T2 - 20th International Conference on the Methods of Aerophysical Research, ICMAR 2020

Y2 - 1 November 2020 through 7 November 2020

ER -

ID: 28866243