Simulations of edge localised mode instabilities in MAST-U Super-X tokamak plasmas

S. F. Smith, S. J.P. Pamela, A. Fil, M. Hölzl, G. T.A. Huijsmans, A. Kirk, D. Moulton, O. Myatra, A. J. Thornton, H. R. Wilson

Research output: Contribution to journalArticlepeer-review

9 Scopus citations

Abstract

The high heat fluxes to the divertor during edge localised mode (ELM) instabilities have to be reduced for a sustainable future tokamak reactor. A solution to reduce the heat fluxes could be the Super-X divertor, which will be tested on MAST-U. ELM simulations for MAST-U Super-X tokamak plasmas have been obtained, using JOREK. A factor 10 decrease in the peak heat flux to the outer target and almost a factor 8 decrease in the ELM energy fluence when comparing the Super-X to a conventional divertor configuration has been found. A detached MAST-U case, after the roll-over in the target parallel electron density flux, is used as a starting point for ELM burn-through simulations. The plasma burns through the neutrals front during the ELM causing the divertor plasma to re-attach. After the crash a transition back to detachment is indicated, where the recovery to pre-ELM divertor conditions occurs in a few milliseconds, when the neutral pressure is high in the divertor. Recovery times are shorter than the inter-ELM phase in previous MAST experiments. The peak ELM energy fluence obtained after the ELM burn-through is 0.82 kJ/m2, which is significantly lower than that predicted from the empirical scaling of the ELM energy fluence - indicating promising results for future MAST-U operations.

Original languageEnglish
Article number066021
JournalNuclear Fusion
Volume60
Issue number6
DOIs
StatePublished - Jun 2020
Externally publishedYes

Funding

FundersFunder number
Horizon 2020 Framework Programme633053

    Keywords

    • ELM
    • ELM burn-through
    • JOREK
    • MAST-U super-X
    • non-linear MHD
    • simulations

    Fingerprint

    Dive into the research topics of 'Simulations of edge localised mode instabilities in MAST-U Super-X tokamak plasmas'. Together they form a unique fingerprint.

    Cite this