Hydrodynamic Theory of Multicomponent Diffusion and Thermal Diffusion in Multitemperature Gas Mixtures

Ramshaw, John D.

doi:10.1515/jnet.1993.18.2.121

Cited by 76 publications

(70 citation statements)

References 9 publications

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“…Ghorui 116 and Colombo 117 compared the two theories and concluded that Devoto's approach (without coupling) was adequate to determine the electrical conductivity, the viscosity and the thermal conductivity of a nonequilibrium plasma even if the diffusion coefficients used in the expressions were obtained by the Ramshaw's approach. 123 Today, most of the works published seem to agree on the expressions to be used to calculate the viscosity, the electrical conductivity, the internal and translational thermal conductivities. The question especially concerns the calculation of one or two reactional thermal conductivities (and consequently the existence of a unique total thermal conductivity).…”

Section: Discussionmentioning

confidence: 99%

Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Cressault

2015

AIP Advances

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This paper has for objectives to present the radiative and the transport properties for people beginning in thermal plasmas. The first section will briefly recall the equations defined in numerical models applied to thermal plasmas; the second section will particularly deal with the estimation of radiative losses; the third part will quickly present the thermodynamics properties; and the last part will concern the transport coefficients (thermal conductivity, viscosity and electrical conductivity of the gas or mixtures of gases). We shall conclude the paper with a discussion about the validity of these results the lack of data for some specific applications, and some perspectives concerning these properties for non-equilibrium thermal plasmas. C 2015 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution 3.0 Unported License. [http://dx

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Section: Discussionmentioning

confidence: 99%

Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Cressault

2015

AIP Advances

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“…Constitutive equations are needed for all fields which are relevant to single components of a species, in particular P i and q i , and for the collision contributions on the right sides, (14) and (16), that involve the specific distribution functions f i , and bear trace of their kinetic origin via the collision kernels affecting all integrals.…”

Section: Slmentioning

confidence: 99%

“…On the other hand, a multi-temperature approach naturally arises also in plasmas at high temperature [3], in the flow field around hypersonic vehicles at high altitude [15], as well as in several problems of aerothermodynamics [16,21]. In fact, a one-temperature gas flow description is not reliable in thermal non-equilibrium conditions when vibrational relaxations and possible chemical reactions proceed at the gas dynamic time scale, as widely investigated, especially by the Russian school [12].…”

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confidence: 99%

Multi-temperature Hydrodynamic Limit from Kinetic Theory in a Mixture of Rarefied Gases

2012

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Starting from the Boltzmann kinetic equations for a mixture of gas molecules whose internal structure is described by a discrete set of internal energy levels, hydrodynamic equations at Euler level are deduced by a consistent hydrodynamic limit in the presence of a two-scale collision process. The fast process driving evolution is constituted by mechanical encounters between particles of the same species, whereas inter-species scattering proceeds at the macroscopic scale. The resulting multi-temperature and multi-velocity fluid-dynamic equations are briefly commented on, and some results in closed analytical form are given for special simplified situations like Maxwellian collision kernels, or monoatomic hard sphere gases.

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“…There is a shortage of experimental data, and the traditional theory is so complex as to hinder its application by the nonspecialist, ttowevcr, Ramshaw has developed an approximate simplified theory [24] that has been incorporated into COYOTE. The first step is to estimate the collision cross section between molecules of types a and ~ as…”

Section: Pu = E (14)mentioning

confidence: 99%

A Selected Library of Transport Coefficients for Combustion and Plasma Physics Applications

Cloutman¹

2000

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COYOTE and similar combustion programs based on the multicomponent NavierStokes equations require the mixture viscosity, thermal conductivity, and species transport coefficients as input. This report documents a model of these molecular transport coefficients that is simpler than the general theory, but which provides adequate accuracy for many purposes. This model leads to a computationally convenient, selfcontained, and easy-to-use source of such data in a format suitable for use by such programs. We present the data for various neutral species in two forms. The first form is a simple functional fit to the transport coefficients. The second form is the use of tabulated Lennard-Jones parameters in simple theoretical expressions for the gas-phase transport coefficients. The model then is extended to the case of a twotemperature plasma. Lennard-Jones parameters are given for a number of chemical species of interest in combustion research.

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Hydrodynamic Theory of Multicomponent Diffusion and Thermal Diffusion in Multitemperature Gas Mixtures

Cited by 76 publications

References 9 publications

Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Multi-temperature Hydrodynamic Limit from Kinetic Theory in a Mixture of Rarefied Gases

A Selected Library of Transport Coefficients for Combustion and Plasma Physics Applications

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