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Generalization of the Krook kinetic relaxation equation
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In this article, the Krook model relaxation equation was used to construct a sequence of model equations which provided the correct Prandtl number for a rarefied gas, which is based on an approximation of the Boltzmann equation for pseudo-Maxwellian molecules using the method suggested by the author previously.Abstract:
One of the most significant achievements in rarefied gas theory in the last 20 years is the Krook model for the Boltzmann equation [1]. The Krook model relaxation equation retains all the features of the Boltzmann equation which are associated with free molecular motion and describes approximately, in a mean-statistical fashion, the molecular collisions. The structure of the collisional term in the Krook formula is the simplest of all possible structures which reflect the nature of the phenomenon. Careful and thorough study of the model relaxation equation [2–4], and also solution of several problems for this equation, have aided in providing a deeper understanding of the processes in a rarefied gas. However, the quantitative results obtained from the Krook model equation, with the exception of certain rare cases, differ from the corresponding results based on the exact solution of the Boltzmann equation. At least one of the sources of error is obvious. It is that, in going over to a continuum, the relaxation equation yields a Prandtl number equal to unity, while the exact value for a monatomic gas is 2/3. In a comparatively recent study [5] Holway proposed the use of the maximal probability principle to obtain a model kinetic equation which would yield in going over to a continuum the expressions for the stress tensor and the thermal flux vector with the proper viscosity and thermal conductivity. In the following we propose a technique for constructing a sequence of model equations which provide the correct Prandtl number. The technique is based on an approximation of the Boltzmann equation for pseudo-Maxwellian molecules using the method suggested by the author previously in [6], For arbitrary molecules each approximating equation may be considered a model equation. A comparison is made of our results with those of [5].read more
Citations
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A unified gas-kinetic scheme for continuum and rarefied flows IV
TL;DR: The UGKS as discussed by the authors is a direct modeling method in the mesh size scale, and its underlying flow physics depends on the resolution of the cell size relative to the particle mean free path.
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Data on the Velocity Slip and Temperature Jump on a Gas-Solid Interface
TL;DR: In this article, the velocity slip and temperature jump coefficients have been applied to modeling of gas flows and a critical analysis of theoretical and experimental data available in the open literature is presented in an accessible form so that it can be easily understandable for nonspecialists in rarefied gas dynamics.
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Application of the Cercignani–Lampis scattering kernel to calculations of rarefied gas flows. II. Slip and jump coefficients
TL;DR: In this article, the Cercignani-Lampis scattering kernel of the gas surface interaction is applied to numerical calculations of the viscous slip coefficient, the thermal slip coefficient and the temperature jump coefficient.
Journal ArticleDOI
A Unified Gas-Kinetic Scheme for Continuum and Rarefied Flows II: Multi-Dimensional Cases
Juan-Chen Huang,Kun Xu,Pubing Yu +2 more
TL;DR: In this paper, a unified gas-kinetic scheme based on the Shakhov model in two-dimensional space is presented, which can capture non-equilibrium flow physics in the transition and rarefied flow regimes.
Journal ArticleDOI
Microchannel flow in the slip regime: gas-kinetic BGK-Burnett solutions
Kun Xu,Zhi-Hui Li +1 more
TL;DR: In this article, a gas-kinetic scheme based on the Bhatnagar-Gross-Krook (BGK) model for the microflow simulations in the near continuum flow regime is presented.
References
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Journal ArticleDOI
A Model for Collision Processes in Gases. I. Small Amplitude Processes in Charged and Neutral One-Component Systems
TL;DR: In this paper, a kinetic theory approach to collision processes in ionized and neutral gases is presented, which is adequate for the unified treatment of the dynamic properties of gases over a continuous range of pressures from the Knudsen limit to the high pressure limit where the aerodynamic equations are valid.
Small amplitude processes in charged and neutral one-component systems
TL;DR: In this article, a kinetic theory approach to collision processes in ionized and neutral gases is presented, which is adequate for the unified treatment of the dynamic properties of gases over a continuous range of pressures from the Knudsen limit to the high pressure limit where the aerodynamic equations are valid.
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New Statistical Models for Kinetic Theory: Methods of Construction
TL;DR: In this paper, a statistical model of the collision term in the Boltzmann equation is introduced which is similar in concept to the well-known Krook model but yields the correct Prandtl number of ⅔ for a monatomic gas.
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Note on N-dimensional hermite polynomials
TL;DR: In this article, it is shown that a complete set of orthonormal polynomials in N variables can be obtained by using products of such polynomial in a single variahle.