Tracking discontinuities in shallow water equations and ideal magnetohydrodynamics equations via Ghost Fluid Method

Li Cai; Jian Hu Feng; Wen Xian Xie; Jun Zhou

doi:10.1016/j.apnum.2005.11.006

Tracking discontinuities in shallow water equations and ideal magnetohydrodynamics equations via Ghost Fluid Method

Li Cai, Jian Hu Feng, Wen Xian Xie, Jun Zhou

School of Astronautics

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Existing Ghost Fluid Method (GFM) works well for most gas flows but still leaves much room for further improvement in other applications. In the spirit of GFM, we propose a new GFM to track discontinuities in shallow water equations and ideal magnetohydrodynamics (MHD) equations: a new GFM is designed for tracking shock wave in shallow water equations; then the GFM is extended to treat contact discontinuity in ideal MHD equations where the interface moves with the entropy wave speed. In this paper, the zero contour of a level set function is used to specify the location of discontinuities, and the GFM implicitly captures the boundary conditions at the interface by the construction of a ghost fluid. The numerical results show the desired accuracy and robustness of our new GFM.

Original language	English
Pages (from-to)	1555-1569
Number of pages	15
Journal	Applied Numerical Mathematics
Volume	56
Issue number	12
DOIs	https://doi.org/10.1016/j.apnum.2005.11.006
State	Published - Dec 2006

Keywords

CWENO-type central-upwind schemes
Ghost Fluid Method
Ideal magnetohydrodynamics equations
Shallow water equations

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10.1016/j.apnum.2005.11.006

Cite this

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title = "Tracking discontinuities in shallow water equations and ideal magnetohydrodynamics equations via Ghost Fluid Method",

abstract = "Existing Ghost Fluid Method (GFM) works well for most gas flows but still leaves much room for further improvement in other applications. In the spirit of GFM, we propose a new GFM to track discontinuities in shallow water equations and ideal magnetohydrodynamics (MHD) equations: a new GFM is designed for tracking shock wave in shallow water equations; then the GFM is extended to treat contact discontinuity in ideal MHD equations where the interface moves with the entropy wave speed. In this paper, the zero contour of a level set function is used to specify the location of discontinuities, and the GFM implicitly captures the boundary conditions at the interface by the construction of a ghost fluid. The numerical results show the desired accuracy and robustness of our new GFM.",

keywords = "CWENO-type central-upwind schemes, Ghost Fluid Method, Ideal magnetohydrodynamics equations, Shallow water equations",

author = "Li Cai and Feng, {Jian Hu} and Xie, {Wen Xian} and Jun Zhou",

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T1 - Tracking discontinuities in shallow water equations and ideal magnetohydrodynamics equations via Ghost Fluid Method

AU - Cai, Li

AU - Feng, Jian Hu

AU - Xie, Wen Xian

AU - Zhou, Jun

PY - 2006/12

Y1 - 2006/12

N2 - Existing Ghost Fluid Method (GFM) works well for most gas flows but still leaves much room for further improvement in other applications. In the spirit of GFM, we propose a new GFM to track discontinuities in shallow water equations and ideal magnetohydrodynamics (MHD) equations: a new GFM is designed for tracking shock wave in shallow water equations; then the GFM is extended to treat contact discontinuity in ideal MHD equations where the interface moves with the entropy wave speed. In this paper, the zero contour of a level set function is used to specify the location of discontinuities, and the GFM implicitly captures the boundary conditions at the interface by the construction of a ghost fluid. The numerical results show the desired accuracy and robustness of our new GFM.

AB - Existing Ghost Fluid Method (GFM) works well for most gas flows but still leaves much room for further improvement in other applications. In the spirit of GFM, we propose a new GFM to track discontinuities in shallow water equations and ideal magnetohydrodynamics (MHD) equations: a new GFM is designed for tracking shock wave in shallow water equations; then the GFM is extended to treat contact discontinuity in ideal MHD equations where the interface moves with the entropy wave speed. In this paper, the zero contour of a level set function is used to specify the location of discontinuities, and the GFM implicitly captures the boundary conditions at the interface by the construction of a ghost fluid. The numerical results show the desired accuracy and robustness of our new GFM.

KW - CWENO-type central-upwind schemes

KW - Ghost Fluid Method

KW - Ideal magnetohydrodynamics equations

KW - Shallow water equations

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U2 - 10.1016/j.apnum.2005.11.006

DO - 10.1016/j.apnum.2005.11.006

M3 - 文章

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JO - Applied Numerical Mathematics

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ER -

Tracking discontinuities in shallow water equations and ideal magnetohydrodynamics equations via Ghost Fluid Method

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Keywords

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