A combined finite volume - finite element scheme for a low-Mach system involving a Joule term

A combined finite volume - finite element scheme for a low-Mach system involving a Joule term

In this paper, we propose a combined finite volume - finite element scheme, for the resolution of a specific low-Mach model expressed in the velocity, pressure and temperature variables. The dynamic viscosity of the fluid is given by an explicit function of the temperature, leading to the presence o...

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Bibliographic Details
Main Authors: Caterina Calgaro, Claire Colin, Emmanuel Creusé
Format: Article
Language:English
Published: AIMS Press 2020-01-01
Series:AIMS Mathematics
Subjects:
low mach model
finite volume scheme
finite element scheme
joule term
maximum principle
Online Access:https://www.aimspress.com/article/10.3934/math.2020021/fulltext.html
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spelling doaj-fcb3c65b38474cc7b78794802eadaf9d2020-11-25T01:20:12ZengAIMS PressAIMS Mathematics2473-69882020-01-015131133110.3934/math.2020021A combined finite volume - finite element scheme for a low-Mach system involving a Joule termCaterina Calgaro0Claire Colin1Emmanuel Creusé21 University Lille, CNRS, UMR 8524, Inria - Laboratoire Paul Painlevé, F-59000 Lille, France1 University Lille, CNRS, UMR 8524, Inria - Laboratoire Paul Painlevé, F-59000 Lille, France2 University Polytechnique Hauts-de-France, EA 4015, LAMAV - FR CNRS 2956, F-59313 Valenciennes, FranceIn this paper, we propose a combined finite volume - finite element scheme, for the resolution of a specific low-Mach model expressed in the velocity, pressure and temperature variables. The dynamic viscosity of the fluid is given by an explicit function of the temperature, leading to the presence of a so-called Joule term in the mass conservation equation. First, we prove a discrete maximum principle for the temperature. Second, the numerical fluxes defined for the finite volume computation of the temperature are efficiently derived from the discrete finite element velocity field obtained by the resolution of the momentum equation. Several numerical tests are presented to illustrate our theoretical results and to underline the efficiency of the scheme in term of convergence rates.https://www.aimspress.com/article/10.3934/math.2020021/fulltext.htmllow mach modelfinite volume schemefinite element schemejoule termmaximum principle
collection DOAJ
language English
format Article
sources DOAJ
author Caterina Calgaro
Claire Colin
Emmanuel Creusé
spellingShingle Caterina Calgaro
Claire Colin
Emmanuel Creusé
A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
AIMS Mathematics
low mach model
finite volume scheme
finite element scheme
joule term
maximum principle
author_facet Caterina Calgaro
Claire Colin
Emmanuel Creusé
author_sort Caterina Calgaro
title A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
title_short A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
title_full A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
title_fullStr A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
title_full_unstemmed A combined finite volume - finite element scheme for a low-Mach system involving a Joule term
title_sort combined finite volume - finite element scheme for a low-mach system involving a joule term
publisher AIMS Press
series AIMS Mathematics
issn 2473-6988
publishDate 2020-01-01
description In this paper, we propose a combined finite volume - finite element scheme, for the resolution of a specific low-Mach model expressed in the velocity, pressure and temperature variables. The dynamic viscosity of the fluid is given by an explicit function of the temperature, leading to the presence of a so-called Joule term in the mass conservation equation. First, we prove a discrete maximum principle for the temperature. Second, the numerical fluxes defined for the finite volume computation of the temperature are efficiently derived from the discrete finite element velocity field obtained by the resolution of the momentum equation. Several numerical tests are presented to illustrate our theoretical results and to underline the efficiency of the scheme in term of convergence rates.
topic low mach model
finite volume scheme
finite element scheme
joule term
maximum principle
url https://www.aimspress.com/article/10.3934/math.2020021/fulltext.html
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