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A High-Order Residual-Based Viscosity Finite Element Method for the Ideal MHD Equations

Tuan Anh Dao, Murtazo Nazarov

2022Journal of Scientific Computing13 citationsDOIOpen Access PDF

Abstract

Abstract We present a high order, robust, and stable shock-capturing technique for finite element approximations of ideal MHD. The method uses continuous Lagrange polynomials in space and explicit Runge-Kutta schemes in time. The shock-capturing term is based on the residual of MHD which tracks the shock and discontinuity positions, and adds sufficient amount of viscosity to stabilize them. The method is tested up to third order polynomial spaces and an expected fourth-order convergence rate is obtained for smooth problems. Several discontinuous benchmarks such as Orszag-Tang, MHD rotor, Brio-Wu problems are solved in one, two, and three spacial dimensions. Sharp shocks and discontinuity resolutions are obtained.

Topics & Concepts

Discontinuity (linguistics)MathematicsMagnetohydrodynamicsShock (circulatory)Ideal (ethics)Mathematical analysisFinite element methodResidualConvergence (economics)Rate of convergenceApplied mathematicsPhysicsLawAlgorithmMagnetic fieldComputer scienceComputer networkPolitical scienceMedicineQuantum mechanicsEconomicsThermodynamicsChannel (broadcasting)Economic growthInternal medicineComputational Fluid Dynamics and AerodynamicsGas Dynamics and Kinetic TheoryFluid Dynamics and Turbulent Flows
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