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JOURNALS // Computer Research and Modeling // Archive

Computer Research and Modeling, 2022 Volume 14, Issue 4, Pages 781–794 (Mi crm998)

This article is cited in 3 papers

SPECIAL ISSUE

A study of nonlinear processes at the interface between gas flow and the metal wall of a microchannel

S. V. Polyakovab, V. O. Podrygaac

a Keldysh Institute of Applied Mathematics RAS, 4 Miusskaya square, Moscow 125047, Russia
b National Research Nuclear University MEPhI (Moscow Engineering Physics Institute), 31 Kashirskoe hwy, Moscow 115409, Russia
c Moscow Automobile and Road Construction State Technical University, 64 Leningradsky prospect, Moscow 125319, Russia

Abstract: The work is devoted to the study of the influence of nonlinear processes in the boundary layer on the general nature of gas flows in microchannels of technical systems. Such a study is actually concerned with nanotechnology problems. One of the important problems in this area is the analysis of gas flows in microchannels in the case of transient and supersonic flows. The results of this analysis are important for the gas-dynamic spraying techique and for the synthesis of new nanomaterials. Due to the complexity of the implementation of full-scale experiments on micro- and nanoscale, they are most often replaced by computer simulations. The efficiency of computer simulations is achieved by both the use of new multiscale models and the combination of mesh and particle methods. In this work, we use the molecular dynamics method. It is applied to study the establishment of a gas microflow in a metal channel. Nitrogen was chosen as the gaseous medium. The metal walls of the microchannels consisted of nickel atoms. In numerical experiments, the accommodation coefficients were calculated at the boundary between the gas flow and the metal wall. The study of the microsystem in the boundary layer made it possible to form a multicomponent macroscopic model of the boundary conditions. This model was integrated into the macroscopic description of the flow based on a system of quasi-gas-dynamic equations. On the basis of such a transformed gas-dynamic model, calculations of microflow in real microsystem were carried out. The results were compared with the classical calculation of the flow, which does not take into account nonlinear processes in the boundary layer. The comparison showed the need to use the developed model of boundary conditions and its integration with the classical gas-dynamic approach.

Keywords: gas-dynamic microflows in channels with real wall structure, multiscale mathematical modeling, boundary conditions problem, combination of microscopic and macroscopic approaches, parallel computing.

UDC: 519.6

Received: 18.12.2021
Revised: 28.02.2022
Accepted: 12.04.2022

Language: English

DOI: 10.20537/2076-7633-2022-14-4-781-794



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