Document Type

Article

Publication Date

7-2011

Journal or Book Title

Communication in Computational Physics

Volume

10

Issue

1

First Page

216

Last Page

252

DOI

10.4208/cicp.020210.160910a

Abstract

A moment method with closures based on Gaussian quadrature formulas is proposed to solve the Boltzmann kinetic equation with a hard-sphere collision kernel for mono-dispersed particles. Different orders of accuracy in terms of the moments of the velocity distribution function are considered, accounting for moments up to seventh order. Quadrature-based closures for four different models for inelastic collisionthe Bhatnagar-Gross-Krook, ES-BGK, the Maxwell model for hard-sphere collisions, and the full Boltzmann hard-sphere collision integral-are derived and compared. The approach is validated studying a dilute non-isothermal granular flow of inelastic particles between two stationary Maxwellian walls. Results obtained from the kinetic models are compared with the predictions of molecular dynamics (MD) simulations of a nearly equivalent system with finite-size particles. The influence of the number of quadrature nodes used to approximate the velocity distribution function on the accuracy of the predictions is assessed. Results for constitutive quantities such as the stress tensor and the heat flux are provided, and show the capability of the quadrature-based approach to predict them in agreement with the MD simulations under dilute conditions.

Comments

This article is from Communication in Computational Physics 10 (2011): 216-252, doi: 10.4208/cicp.020210.160910a. Posted with permission.

Copyright Owner

Global-Science Press

Language

en

File Format

application/pdf

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