English

A relaxation scheme for a hyperbolic multiphase flow model. Part I: barotropic eos

Numerical Analysis 2019-07-10 v2 Numerical Analysis Analysis of PDEs Classical Physics

Abstract

This article is the first of two in which we develop a relaxation finite volume scheme for the convective part of the multiphase flow models introduced in the series of papers [10, 9, 4]. In the present article we focus on barotropic flows where in each phase the pressure is a given function of the density. The case of general equations of state will be the purpose of the second article. We show how it is possible to extend the relaxation scheme designed in [8] for the barotropic Baer-Nunziato two-phase flow model to the multiphase flow model with N-where N is arbitrarily large-phases. The obtained scheme inherits the main properties of the relaxation scheme designed for the Baer-Nunziato two phase flow model. The approximated phase fractions and phase densities are proven to remain positive and a discrete energy inequality is also proven under a classical CFL condition. For the same level of refinement, the relaxation scheme is shown to be much more accurate than Rusanov's scheme, and for a given level of approximation error, the relaxation scheme is shown to perform much better in terms of computational cost than Rusanov's scheme. Moreover, contrary to Rusanov's scheme which develops strong oscillations when approximating vanishing phase solutions, the numerical results show that the relaxation scheme remains stable in such regimes.

Keywords

Cite

@article{arxiv.1803.10600,
  title  = {A relaxation scheme for a hyperbolic multiphase flow model. Part I: barotropic eos},
  author = {Khaled Saleh},
  journal= {arXiv preprint arXiv:1803.10600},
  year   = {2019}
}

Comments

arXiv admin note: text overlap with arXiv:1601.07345

R2 v1 2026-06-23T01:07:43.565Z