Litcius/Paper detail

ARC physics basis–magnetohydrodynamics

N. Leuthold, N.C. Logan, D.A. Burgess, A. O. Nelson, S. Benjamin, C. Hansen, A. Kumar, C. F. B. Zimmermann, F. Carpanese, A.J. Creely, J.C. Hillesheim, M. Muraca, C. Paz-Soldan

2026Journal of Plasma Physics8 citationsDOIOpen Access PDF

Abstract

ARC is designed to produce ${400}\,\textrm {MW}$ of net electricity and prove the commercial feasibility of a fusion power plant. In order to achieve this goal ARC has to operate with optimal core performance in a stationary scenario that minimises wear on the first wall and divertor. This requires avoiding or mitigating magnetohydrodynamic (MHD) instabilities which have the potential to not only degrade the plasma core but also lead to deleterious transient heat loads on plasma facing components. Therefore, this work aims at characterising the MHD stability of the high performance ARC scenario and inform the design of error field correction coils. Firstly, simulations of vertical displacement events show that an in-vessel coil is not needed and instead the poloidal shaping coils can be used to control vertical stability. These simulations also inform the demands on the corresponding coil power supplies. Stability analysis of the ideal kink mode with or without a conducting wall and kinetic effects suggests that the ARC baseline scenario operates deeply in the stable region. Using RDCON, tearing modes at the $m/n=2/1$ and $3/2$ surfaces (with poloidal mode number $m$ , and toroidal mode number $n$ ) are shown to be linearly stable, and including thermal transport effects in the rational surfaces lead to further stabilisation. However, other transient plasma instabilities can seed neoclassical tearing modes (NTMs). The marginally stable width of NTMs in ARC strongly depends on the internal inductance and can fall below ${0.1}{\,\,\%}$ of the normalised poloidal flux. Furthermore, an empirical cross-machine model of the $n=1$ error field leading to a disruption predicts a critical error field larger than SPARC but smaller than ITER. Three-dimensional coils can be designed with the Generalised Purturbed Equilbium Code based on a simple model that calculates the maximum correctable error field that is limited by the neoclassical toroidal viscosity torque. Broad scans of different coil geometries identify a set of 2 rows of off-midplane coils to be a suitable solution. It is also determined that such a set of three-dimensional coils is capable of correcting $n=2$ error fields to some degree and creating strong enough $n=2$ or $n=3$ edge resonant perturbation fields for the suppression of edge-localised modes at reasonable coil currents. The final design of the first ARC will be further informed by results from SPARC.

Topics & Concepts

PhysicsMagnetohydrodynamic driveMagnetohydrodynamicsPlasmaToroidMechanicsTransient (computer programming)Electromagnetic coilArc (geometry)TokamakLarge Helical DeviceCore (optical fiber)Magnetic fieldPower (physics)InstabilityTearingWork (physics)Vertical displacementToroidal and poloidalMode (computer interface)Resistive touchscreenDisplacement (psychology)Fusion powerStability (learning theory)Kink instabilityAerospace engineeringKinetic energyElectric arcArc suppressionField lineComputational physicsClassical mechanicsThermalField (mathematics)Magnetic reconnectionPlasma arc weldingMagnetic confinement fusion researchSuperconducting Materials and ApplicationsFusion materials and technologies