Title :
A finite volume implementation of an approximate Riemann solver for MHD
Author :
Shumlak, U. ; Udrea, B.
Author_Institution :
Washington Univ., Seattle, WA, USA
Abstract :
Summary form only given. The magnetohydrodynamic (MHD) equations model the time evolution of plasmas and other conducting magnetofluids. Applications include electric plasma propulsion, magnetic confinement devices, and pulsed power generators. The MHD model is a set of mixed hyperbolic and parabolic equations. The hyperbolic component of the equations can be expressed in conservative form and suggests the use of an approximate Riemann solver to accurately track the wave behavior. The algorithm that will be described uses Roe-type approximate Riemann solver with a finite volume implementation. Finite volume grids are ideally suited for modeling complicated 3D geometries. The finite volume implementation defines a coordinate system that is locally aligned with the cell interface. Working in the coordinate system simplifies the calculation of the flux vector.
Keywords :
electric propulsion; finite element analysis; hyperbolic equations; magnetohydrodynamics; parabolic equations; plasma magnetohydrodynamics; MHD; Roe-type approximate Riemann solver; approximate Riemann solver; cell interface; conducting magnetofluids; coordinate system; electric plasma propulsion; finite volume grids; finite volume implementation; flux vector; hyperbolic equations; magnetic confinement devices; magnetohydrodynamic equations model; parabolic equations; plasma time evolution; pulsed power generators; wave behavior; Equations; Magnetic confinement; Magnetic flux; Magnetohydrodynamic power generation; Plasma applications; Plasma confinement; Plasma devices; Plasma waves; Power generation; Propulsion;
Conference_Titel :
Plasma Science, 1998. 25th Anniversary. IEEE Conference Record - Abstracts. 1998 IEEE International on
Conference_Location :
Raleigh, NC, USA
Print_ISBN :
0-7803-4792-7
DOI :
10.1109/PLASMA.1998.677517
