Fast-ion physics in SPARC
Journal article, 2020

Potential loss of energetic ions including alphas and radio-frequency tail ions due to classical orbit effects and magnetohydrodynamic instabilities (MHD) are central physics issues in the design and experimental physics programme of the SPARC tokamak. The expected loss of fusion alpha power due to ripple-induced transport is computed for the SPARC tokamak design by the ASCOT and SPIRAL orbit-simulation codes, to assess the expected surface heating of plasma-facing components. We find good agreement between the ASCOT and SPIRAL simulation results not only in integrated quantities (fraction of alpha power loss) but also in the spatial, temporal and pitch-angle dependence of the losses. If the toroidal field (TF) coils are well-aligned, the SPARC edge ripple is small (0.15-0.30 %), the computed ripple-induced alpha power loss is small (similar to 0.25%) and the corresponding peak surface power density is acceptable (244 kW m(-2)). However, the ripple and ripple-induced losses increase strongly if the TF coils are assumed to suffer increasing magnitudes of misalignment. Surface heat loads may become problematic if the TF coil misalignment approaches the centimetre level. Ripple-induced losses of the energetic ion tail driven by ion cyclotron range of frequency (ICRF) heating are not expected to generate significant wall or limiter heating in the nominal SPARC plasma scenario. Because the expected classical fast-ion losses are small, SPARC will be able to observe and study fast-ion redistribution due to MHD including sawteeth and Alfven eigenmodes (AEs). SPARC's parameter space for AE physics even at moderate Q is shown to reasonably overlap that of the demonstration power plant ARC (Sorbom et al., Fusion Engng Des., vol. 100, 2015, p. 378), and thus measurements of AE mode amplitude, spectrum and associated fast-ion transport in SPARC would provide relevant guidance about AE behaviour expected in ARC.

plasma simulation

plasma confinement

fusion plasma

Author

S. D. Scott

Commonwealth Fusion Systems

G. J. Kramer

Princeton University

E. A. Tolman

Massachusetts Institute of Technology (MIT)

A. Snicker

Aalto University

J. Varje

Aalto University

Konsta Särkimäki

Chalmers, Physics, Subatomic, High Energy and Plasma Physics

J. C. Wright

Massachusetts Institute of Technology (MIT)

P. Rodriguez-Fernandez

Massachusetts Institute of Technology (MIT)

Journal of Plasma Physics

0022-3778 (ISSN) 1469-7807 (eISSN)

Vol. 86 5 865860508

Subject Categories

Energy Engineering

Fusion, Plasma and Space Physics

Other Electrical Engineering, Electronic Engineering, Information Engineering

DOI

10.1017/S0022377820001087

More information

Latest update

3/9/2021 7