First operation with the JET International Thermonuclear Experimental Reactor-like wall

Research output: Contribution to journalArticle

Researchers

  • R. Neu
  • G. Arnoux
  • M. Beurskens
  • V. Bobkov
  • S. Brezinsek
  • J. Bucalossi
  • G. Calabro
  • C. Challis
  • J. W. Coenen
  • E. De La Luna
  • P. C. De Vries
  • R. Dux
  • L. Frassinetti
  • C. Giroud
  • J. Hobirk
  • E. Joffrin
  • P. Lang
  • M. Lehnen
  • E. Lerche
  • T. Loarer
  • P. Lomas
  • G. Maddison
  • C. Maggi
  • G. Matthews
  • S. Marsen
  • M. L. Mayoral
  • A. Meigs
  • Ph Mertens
  • I. Nunes
  • V. Philipps
  • T. Pütterich
  • F. Rimini
  • M. Sertoli
  • B. Sieglin
  • A. C C Sips
  • D. Van Eester
  • G. Van Rooij
  • JET-EFDA Contributors

Research units

  • Culham Science Centre
  • EFDA-CSU
  • Max-Planck-Institut für Plasmaphysik
  • Jülich Research Centre
  • IRFM-CEA
  • Associazione Euratom/ENEA sulla Fusione
  • Associacion Euratom/Ciemat
  • Association EURATOM/DIFFER
  • Royal Institute of Technology
  • Association Euratom-Etat Belge/Belgische Staat
  • EURATOM/IST Fusion Association

Abstract

To consolidate International Thermonuclear Experimental Reactor (ITER) design choices and prepare for its operation, Joint European Torus (JET) has implemented ITER's plasma facing materials, namely, Be for the main wall and W in the divertor. In addition, protection systems, diagnostics, and the vertical stability control were upgraded and the heating capability of the neutral beams was increased to over 30 MW. First results confirm the expected benefits and the limitations of all metal plasma facing components (PFCs) but also yield understanding of operational issues directly relating to ITER. H-retention is lower by at least a factor of 10 in all operational scenarios compared to that with C PFCs. The lower C content (≈ factor 10) has led to much lower radiation during the plasma burn-through phase eliminating breakdown failures. Similarly, the intrinsic radiation observed during disruptions is very low, leading to high power loads and to a slow current quench. Massive gas injection using a D2/Ar mixture restores levels of radiation and vessel forces similar to those of mitigated disruptions with the C wall. Dedicated L-H transition experiments indicate a 30% power threshold reduction, a distinct minimum density, and a pronounced shape dependence. The L-mode density limit was found to be up to 30% higher than for C allowing stable detached divertor operation over a larger density range. Stable H-modes as well as the hybrid scenario could be re-established only when using gas puff levels of a few 1021 es-1. On average, the confinement is lower with the new PFCs, but nevertheless, H factors up to 1 (H-Mode) and 1.3 (at β N ≈ 3, hybrids) have been achieved with W concentrations well below the maximum acceptable level.

Details

Original languageEnglish
Article number056111
Pages (from-to)1-13
Number of pages13
JournalPhysics of Plasmas
Volume20
Publication statusPublished - May 2013
MoE publication typeA1 Journal article-refereed

ID: 4160295