In this work, we propose a new stabilized finite element formulation for the approximation of the resistive magnetohydrodynamics equations. The novelty of this formulation with respect to existing ones is the fact that it always converges to the physical solution, even for singular ones. We have performed a detailed stability and convergence analysis of the formulation in a simplified setting. From the convergence analysis, we infer that a particular type of meshes with a macro-element structure is needed, which can be easily obtained after a straight modification of any original mesh. A detailed set of numerical experiments have been performed in order to validate our approach.Peer Reviewe
This paper studies a numerical scheme for approximating solutions of incompressible magnetohydrodyna...
This paper presents an initial study that is intended to explore the development of a scalable fully...
A numerical formulation to solve the MHD problem with thermal coupling is presented in full detail. ...
In this work, we propose a new stabilized finite element formulation for the approximation of the re...
In this work, we propose a new stabilized finite element formulation for the approximation of t...
In this work, we analyze a recently proposed stabilized finite element formulation for the approxima...
Magnetohydrodynamics (MHD) is the physics branch that studies electrically conducting fluids under e...
No es frecuente encontrar un campo donde dos ramas principales de la Física estén involucradas. La M...
In this work we present a stabilized finite element method for the stationary magneto-hydrodynamic e...
This thesis deals with the usage of nodal-based finite element methods in electromagnetism and incom...
A sufficient stability condition with respect to purely growing modes is derived for resistive magne...
In this work, a stabilized formulation to solve the inductionless magnetohydrodynamic (MHD) problem...
This paper is devoted to the design and analysis of some structure-preserving finite element schemes...
This thesis presents a finite element method for the solution of three-dimensional magnetohydrodynam...
In this article we propose different splitting procedures for the transient incompressible MHD syste...
This paper studies a numerical scheme for approximating solutions of incompressible magnetohydrodyna...
This paper presents an initial study that is intended to explore the development of a scalable fully...
A numerical formulation to solve the MHD problem with thermal coupling is presented in full detail. ...
In this work, we propose a new stabilized finite element formulation for the approximation of the re...
In this work, we propose a new stabilized finite element formulation for the approximation of t...
In this work, we analyze a recently proposed stabilized finite element formulation for the approxima...
Magnetohydrodynamics (MHD) is the physics branch that studies electrically conducting fluids under e...
No es frecuente encontrar un campo donde dos ramas principales de la Física estén involucradas. La M...
In this work we present a stabilized finite element method for the stationary magneto-hydrodynamic e...
This thesis deals with the usage of nodal-based finite element methods in electromagnetism and incom...
A sufficient stability condition with respect to purely growing modes is derived for resistive magne...
In this work, a stabilized formulation to solve the inductionless magnetohydrodynamic (MHD) problem...
This paper is devoted to the design and analysis of some structure-preserving finite element schemes...
This thesis presents a finite element method for the solution of three-dimensional magnetohydrodynam...
In this article we propose different splitting procedures for the transient incompressible MHD syste...
This paper studies a numerical scheme for approximating solutions of incompressible magnetohydrodyna...
This paper presents an initial study that is intended to explore the development of a scalable fully...
A numerical formulation to solve the MHD problem with thermal coupling is presented in full detail. ...