Navier–Stokes transport coefficients for a model of a confined quasi-two-dimensional granular binary mixture

The Navier–Stokes transport coefficients for a model of a confined quasi-two-dimensional granular binary mixture of inelastic hard spheres are determined from the Boltzmann kinetic equation. A normal or hydrodynamic solution to the Boltzmann equation is obtained via the Chapman–Enskog method for sta...

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Bibliographic Details
Published in:Physics of fluids (1994) 2021-02, Vol.33 (2)
Main Authors: Garzó, Vicente, Brito, Ricardo, Soto, Rodrigo
Format: Article
Language:English
Subjects:
Binary mixtures
Boltzmann transport equation
Computational fluid dynamics
Cooling rate
Diameters
Diffusion rate
Elasticity
Fluid dynamics
Fluid flow
Heat flux
Integral equations
Kinetic equations
Mathematical models
Navier-Stokes equations
Physics
Polynomials
Shear viscosity
Thermal expansion
Transport properties
Two dimensional models
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Summary:The Navier–Stokes transport coefficients for a model of a confined quasi-two-dimensional granular binary mixture of inelastic hard spheres are determined from the Boltzmann kinetic equation. A normal or hydrodynamic solution to the Boltzmann equation is obtained via the Chapman–Enskog method for states near the local version of the homogeneous time-dependent state. The mass, momentum, and heat fluxes are determined to first order in the spatial gradients of the hydrodynamic fields, and the associated transport coefficients are identified. They are given in terms of the solutions of a set of coupled linear integral equations. In addition, in contrast to the previous results obtained for low-density granular mixtures, there are also nonzero contributions to the first-order approximations to the partial temperatures T i ( 1 ) and the cooling rate ζ(1). Explicit forms for the diffusion transport coefficients, the shear viscosity coefficient, and the quantities T i ( 1 ) and ζ(1) are obtained by assuming steady state conditions and by considering the leading terms in a Sonine polynomial expansion. The above transport coefficients are given in terms of the coefficients of restitution, concentration, and the masses and diameters of the components of the mixture. The results apply, in principle, for arbitrary degree of inelasticity and are not limited to specific values of concentration, mass, and/or size ratios. As a simple application of these results, the violation of the Onsager reciprocal relations for a confined granular mixture is quantified in terms of the parameter space of the problem.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0032919