Disruption runaway electron generation and mitigation in the Spherical Tokamak for Energy Production (STEP)
Journal article, 2024

Generation of Runaway Electrons (REs) during plasma disruptions is of great concern for ITER and future reactors based on the tokamak concept. Unmitigated RE generation in the current STEP (Spherical Tokamak for Energy Production) concept design is modelled using the code DREAM, with hot-tail generation found to be the dominant primary generation mechanism and avalanche multiplication of REs found to be extremely high. Varying assumptions for the prescribed thermal quench (TQ) phase (duration, final electron temperature) as well as the wall time, the plasma-wall distance, and shaping effects, all STEP full-power and full-current unmitigated disruptions generate large RE beams (from 10 MA up to full conversion). RE mitigation is first studied by modelling idealised mixed impurity injections, with ad-hoc particle transport arising from the stochasticity of the magnetic field during the TQ, but no combination of argon and deuterium quantities allows runaways to be avoided while respecting the other constraints of disruption mitigation. Initial concept of STEP disruption mitigation system is then tested with DREAM, assuming two-stage shattered pellet injections (SPI) of pure D 2 followed by Ar+ D 2 . Such a scheme is found to reduce the generation of REs by the hot-tail mechanism, but still generates a RE beam of about 13 MA. Options for further optimising the SPI scheme, for mitigating a large RE beam in STEP (benign termination scheme), as well as estimations of required RE losses during the current quench (from a potential passive RE mitigation coil) will also be discussed.

disruption avoidance

fusion

runaway electrons

plasma disruption

spherical tokamak

disruption mitigation

STEP

Author

A. Fil

The French Alternative Energies and Atomic Energy Commission (CEA)

United Kingdom Atomic Energy Authority

L. Henden

United Kingdom Atomic Energy Authority

Sarah Newton

United Kingdom Atomic Energy Authority

M. Hoppe

Royal Institute of Technology (KTH)

Oskar Vallhagen

Chalmers, Physics, Subatomic, High Energy and Plasma Physics

Nuclear Fusion

00295515 (ISSN) 17414326 (eISSN)

Vol. 64 10 106049

Subject Categories

Other Physics Topics

Fusion, Plasma and Space Physics

DOI

10.1088/1741-4326/ad73e9

More information

Latest update

9/23/2024