1965
DOI: 10.1063/1.1695749
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Transport Properties of Polyatomic Fluids, a Dilute Gas of Perfectly Rough Spheres

Abstract: A detailed account is given of the kinetic theory for a fluid composed of perfectly rough spheres. When one applies the method of Chapman and Enskog to a dilute gas of these spheres he finds that the nonequilibrium distribution function satisfies a nonself-adjoint integral equation. The solution of this equation is not an isotropic function of the molecular spin velocity. A study has been made of the bearing of this spin anisotropy upon the calculated values for the gas transport coefficients.

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Cited by 95 publications
(19 citation statements)
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“…where g5 < 1 and is the local equilibrium distribution function. The presentf'O) differs slightly from the equilibrium distribution functions used for the case of perfectly elastic and perfectly rough spheres by Chapman & Cowling (1970), Condiff et al (1965 and Theodosopulu & Dahler (1974a, b). In those cases, energy is conserved and there is equipartition of the mean translational and rotational fluctuation kinetic energies.…”
Section: Moment Methodsmentioning
confidence: 68%
See 1 more Smart Citation
“…where g5 < 1 and is the local equilibrium distribution function. The presentf'O) differs slightly from the equilibrium distribution functions used for the case of perfectly elastic and perfectly rough spheres by Chapman & Cowling (1970), Condiff et al (1965 and Theodosopulu & Dahler (1974a, b). In those cases, energy is conserved and there is equipartition of the mean translational and rotational fluctuation kinetic energies.…”
Section: Moment Methodsmentioning
confidence: 68%
“…For the case of uniform solid sphere treated here, K = Q. where n is the local number density of the particles and f ( l ) ( r , c, w ; t) is the usual single-particle velocity distribution function. The rate of change of ( y i ) can be expressed as (Condiff, Lu & Dahler 1965;Lun et al 1984;Lun & Savage 1987)…”
mentioning
confidence: 99%
“…2,[26][27][28][29] The most complete solution, at the level of the Chapman-Enskog approximation, was given by Condiff, Lu, and Dahler 2 who compared the contributions to transport coefficients from different terms in a basis of Sonine polynomials. At the lowest order of approximation, Pidduck's formulae for the transport coefficients are obtained, namely…”
Section: Transport Coefficientsmentioning
confidence: 99%
“…[1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17] Given such importance, it is valuable to have a set of well-converged benchmark calculations against which comparisons with theory can be made. In fact, Condiff, Lu, and Dahler 2 examined in some detail the effect of different basis sets on the values of transport coefficients using the Chapman-Enskog approximation to the Boltzmann equation.…”
Section: Introductionmentioning
confidence: 99%
“…Since A is a vector, it can be expressed as a sum of projections along the three polar vectors V, (V · ω)ω, and V × ω [57], namely…”
Section: Navier-stokes-fourier Transport Coefficients a Exact Formentioning
confidence: 99%