Linear gyrokinetic stability of a high β non-inductive spherical tokamak
Abstract
Spherical tokamaks (STs) have been shown to possess properties desirable for a fusion power plant such as achieving high plasma β and having increased vertical stability. To understand the confinement properties that might be expected in the conceptual design for a high β ST fusion reactor, a 1 GW ST plasma equilibrium was analysed using local linear gyrokinetics to determine the type of micro-instabilities that arise. Kinetic ballooning modes and micro-tearing modes are found to be the dominant instabilities. The parametric dependence of these linear modes was determined and, from the insights gained, the equilibrium was tuned to find a regime marginally stable to all micro-instabilities at θ 0 = 0.0. This work identifies the most important micro-instabilities expected to generate turbulent transport in high β STs. The impact of such modes must be faithfully captured in first-principles-based reduced models of anomalous transport that are needed for predictive simulations.
- Publication:
-
Nuclear Fusion
- Pub Date:
- January 2022
- DOI:
- arXiv:
- arXiv:2108.11169
- Bibcode:
- 2022NucFu..62a6009P
- Keywords:
-
- gyrokinetics;
- spherical tokamak;
- electromagnetic;
- turbulence;
- kinetic ballooning mode;
- micro tearing mode;
- high β;
- Physics - Plasma Physics
- E-Print:
- 43 pages, 67 figures, 4 tables