Litcius/Paper detail

Precise stellarator quasi-symmetry can be achieved with electromagnetic coils

Florian Wechsung, Matt Landreman, Andrew Giuliani, Antoine Cerfon, Georg Stadler

2022Proceedings of the National Academy of Sciences38 citationsDOIOpen Access PDF

Abstract

128, 035001, 2022] reports the discovery of toroidal magnetic fields that are quasi-symmetric to orders-of-magnitude higher precision than previously known fields. We show that these fields can be accurately produced using electromagnetic coils of only moderate engineering complexity, that is, coils that have low curvature and that are sufficiently separated from each other. Our results demonstrate that these new quasi-symmetric fields are relevant for applications requiring the confinement of energetic charged particles for long time scales, such as nuclear fusion. The coils' length plays an important role for how well the quasi-symmetric fields can be approximated. For the longest coil set considered and a mean field strength of 1 T, the departure from quasi-symmetry is of the order of Earth's magnetic field. Additionally, we find that magnetic surfaces extend far outside the plasma boundary used by Landreman and Paul, providing confinement far from the core. Simulations confirm that the magnetic fields generated by the new coils confine particles with high kinetic energy substantially longer than previously known coil configurations. In particular, when scaled to a reactor, the best found configuration loses only 0.04% of energetic particles born at midradius when following guiding center trajectories for 200 ms.

Topics & Concepts

StellaratorPhysicsSymmetry (geometry)Magnetic fieldElectromagnetic coilToroidCurvatureCircular symmetryMagnetic confinement fusionPlasmaComputational physicsClassical mechanicsTokamakNuclear physicsGeometryQuantum mechanicsMathematicsMagnetic confinement fusion researchSolar and Space Plasma DynamicsAstro and Planetary Science