English

Magnetohydrodynamic activity inside a sphere

Fluid Dynamics 2009-11-11 v2 Geophysics Plasma Physics

Abstract

We present a computational method to solve the magnetohydrodynamic equations in spherical geometry. The technique is fully nonlinear and wholly spectral, and uses an expansion basis that is adapted to the geometry: Chandrasekhar-Kendall vector eigenfunctions of the curl. The resulting lower spatial resolution is somewhat offset by being able to build all the boundary conditions into each of the orthogonal expansion functions and by the disappearance of any difficulties caused by singularities at the center of the sphere. The results reported here are for mechanically and magnetically isolated spheres, although different boundary conditions could be studied by adapting the same method. The intent is to be able to study the nonlinear dynamical evolution of those aspects that are peculiar to the spherical geometry at only moderate Reynolds numbers. The code is parallelized, and will preserve to high accuracy the ideal magnetohydrodynamic (MHD) invariants of the system (global energy, magnetic helicity, cross helicity). Examples of results for selective decay and mechanically-driven dynamo simulations are discussed. In the dynamo cases, spontaneous flips of the dipole orientation are observed.

Keywords

Cite

@article{arxiv.physics/0602147,
  title  = {Magnetohydrodynamic activity inside a sphere},
  author = {P. D. Mininni and D. C. Montgomery},
  journal= {arXiv preprint arXiv:physics/0602147},
  year   = {2009}
}

Comments

15 pages, 19 figures. Improved figures, in press in Physics of Fluids