Generation and suppression of runaway electrons in disruption mitigation experiments in TEXTOR

S. A. Bozhenkov, M. Lehnen, K. H. Finken, M. W. Jakubowski, R. C. Wolf, R. Jaspers, M. Kantor, O. V. Marchuk, E. Uzgel, G. Van Wassenhove, O. Zimmermann, D. Reiter

Research output: Contribution to journalArticlepeer-review

Abstract

Runaway electrons represent a serious problem for the reliable operation of the future experimental tokamak ITER. Due to the multiplication factor of exp(50) in the avalanche even a few seed runaway electrons will result in a beam of high energetic electrons that is able to damage the machine. Thus suppression of runaway electrons is a task of great importance, for which we present here a systematic study of runaway electrons following massive gas injection in TEXTOR. Argon injection can cause the generation of runaways carrying up to 30% of the initial plasma current, while disruptions triggered by injection of helium or of mixtures of argon (5%, 10%, 20%) with deuterium are runaway free. Disruptions caused by argon injection finally become runaway free for very large numbers of injected atoms. The appearance/absence of runaway electrons is related to the fraction of atoms delivered to the plasma centre. This so-called mixing efficiency is deduced from a 0D model of the current quench. The estimated mixing efficiency is 3% for argon, 15% for an argon/deuterium mixture and about 40% for helium. A low mixing efficiency of high-Z impurities can have a strong implication for the design of the disruption mitigation system for ITER. However, a quantitative prediction requires a better understanding of the mixing mechanism.

Original languageEnglish
Article number105007
JournalPlasma Physics and Controlled Fusion
Volume50
Issue number10
DOIs
Publication statusPublished - 1 Oct 2008

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