Computational boundary specification in 3D fixed-boundary magnetohydrodynamic equilibrium modeling

Abstract

Outside the core of the plasma, the plasma current and pressure rapidly transition to zero in a scrape-off or edge region or plasma-vacuum interface. However, existing tools for fixed-boundary magnetohydrodynamic equilibria in 2D and 3D domains typically prescribe the computational boundary ∂ interior to this transition layer. We (1) argue that a more realistic and robust assumption is to define the computational boundary exterior to this transition layer, in a vacuum-like region where J|∂ p|∂ 0, (2) show that, without this boundary change, existing coil optimization routines for 3D toroidal equilibria (stellarators) should be changed to match free-boundary equilibrium requirements, and (3) derive an algorithm for a fixed-boundary 3D equilibrium solver compatible with a very general computational boundary, with conditions B · n|∂ ≠ 0 (not necessarily a flux surface), p|∂ ≠ const. (not necessarily an isobar), and J × n|∂ ≠ 0.