A dynamic mesh adaptation method for magnetohydrodynamics problems

Dynamic mesh adaptation is a very useful technique for reducing the computational time and memory requirements when solving evolutionary partial differential equations. The reduction is greater when the solution exhibits localized behaviour as in the case of a moving front where the 'action' occurs

Several physical systems, such as nonrelativistic and relativistic magnetohydrodynamics (MHD), radiation MHD, electromagnetics, and incompressible hydrodynamics, satisfy Stoke's law type equations for the divergence-free evolution of vector fields. In this paper we present a full-fledged scheme for

A Cartesian adaptive mesh code for time-dependent, compressible hydrodynamics (HD) and idea1 magnetohydrodynamics (MHD) in three space dimensions has been developed. The strategy of multiple subgrid nesting is used for mesh refinement and is incorporated into an operator-split, mixed finite-differen

A numerical model is developed for the simulation of moving interfaces in viscous incompressible flows. The model is based on the finite element method with a pseudo-concentration technique to track the front. Since a Eulerian approach is chosen, the interface is advected by the flow through a fixed

A finite element discretization for two-dimensional MHD is described. The elements are triangles with piecewise linear basis functions. The main computational difficulty is the accurate calculation of the current. The most effective solution is to employ a current-vorticity advection formulation of