Magnetic Fields with General Omnigenity
Abstract
Omnigenity is a desirable property of toroidal magnetic fields that ensures confinement of trapped particles. Confining charged particles is a basic requirement for any fusion power plant design, but it can be difficult to satisfy with the non-axisymmetric magnetic fields used by the stellarator approach. Every ideal magnetohydrodynamic equilibrium previously found to approximate omnigenity has been either axisymmetric, quasi-symmetric or has poloidally closed contours of magnetic field strength . However, general omnigenous equilibria are a much larger design space than these subsets. A new model is presented and employed in the DESC stellarator optimization suite to represent and discover the full parameter space of omnigenous equilibria. Although exact omnigenity aside from quasi-symmetry is impossible, these results reveal that excellent particle confinement can be achieved in practice. Examples far from quasi-symmetry with poloidally, helically and toroidally closed contours are attained with DESC and shown to have low neoclassical collisional transport and fast particle losses.
Cite
@article{arxiv.2305.08026,
title = {Magnetic Fields with General Omnigenity},
author = {Daniel W. Dudt and Alan G. Goodman and Rory Conlin and Dario Panici and Egemen Kolemen},
journal= {arXiv preprint arXiv:2305.08026},
year = {2024}
}
Comments
14 pages, 4 figures