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

Bozhenkov, S.; Lehnen, M.; Finken, K. H.; Jakubowski, M.; Wolf, R. C.; Jaspers, R.; Kantor, M. Yu.; Marchuk, O.; Uzgel, E.; Wassenhove, G. Van; Zimmermann, O.; Reiter, D.; Team, Textor

doi:10.1088/0741-3335/50/10/105007

Cited by 87 publications

(132 citation statements)

References 46 publications

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“…To achieve temperatures below this limit, the impurity density and thus the electron density has to be too high to allow for detectable runaway generation (see also discussion in [15]). The limit '2' is an empirical limit taken from figure 3 for high magnetic fields.…”

Section: Electric Fieldmentioning

confidence: 99%

“…Thus, a mitigation technique has to provide a reliable suppression of this avalanche mechanism. Presently, massive gas injection is discussed as a technique to mitigate forces and heat loads and also to suppress runaway generation [20][21][22][23][24][25][26]15]. However, the latter aim might have severe implications which are not easily overcome.…”

Section: Runaway Dynamics and Wall Interactionmentioning

confidence: 99%

“…The mixing efficiency is defined as the ratio between impurity density in the current quench plasma and the mean density of atoms injected before the energy quench (amount of atoms divided by the vessel volume). The impurity density has been determined by modelling the current quench in TEXTOR disruptions [15]. The mixing efficiency is a function of the gas species (figure 8): 3-6% for pure Argon injection, 15-30% for the Argon/Deuterium mixture and above 35-70% for Helium injection.…”

Section: Massive Gas Injectionmentioning

confidence: 99%

“…The runaway generation rate is calculated according to the standard equations, which are given for example in [5,15]. For a maximum electric field of E = 50V/m a minimum diffusion coefficient of D pt = 2 × 10 −6 m 2 /m follows from the above considerations.…”

Section: Resonant Magnetic Perturbationsmentioning

confidence: 99%

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Runaway generation during disruptions in JET and TEXTOR

Lehnen¹,

Abdullaev²,

Arnoux

et al. 2009

Journal of Nuclear Materials

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Runaway electrons generated during ITER disruptions are of concern for the integrity of the plasma facing components. It is expected that a power of up to 8 GW is exposed to ITER PFCs. We present in this article observations from JET and TEXTOR on the generation of runaways and the heat load deposition. Suppression techniques like massive gas injection and resonant magnetic perturbations are discussed.

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Section: Electric Fieldmentioning

confidence: 99%

Section: Runaway Dynamics and Wall Interactionmentioning

confidence: 99%

Section: Massive Gas Injectionmentioning

confidence: 99%

Section: Resonant Magnetic Perturbationsmentioning

confidence: 99%

See 2 more Smart Citations

Runaway generation during disruptions in JET and TEXTOR

Lehnen¹,

Abdullaev²,

Arnoux

et al. 2009

Journal of Nuclear Materials

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“…[20][21][22] In order to mitigate the generation of REs, several techniques are studied. Massive gas injection [23][24][25][26] and pellet injection 27,28 aim at the suppression of the RE generation due to a steep increase of the electron density. In the case of gas, typically more than 10 22 atoms must be injected.…”

mentioning

confidence: 99%

Measurements of the runaway electron energy during disruptions in the tokamak TEXTOR

et al. 2012

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Calorimetric measurements of the total runaway electron energy are carried out using a reciprocating probe during induced TEXTOR disruptions. A comparison with the energy inferred from runaway energy spectra, which are measured with a scintillator probe, is used as an independent check of the results. A typical runaway current of 100 kA at TEXTOR contains 30 to 35 kJ of runaway energy. The dependencies of the runaway energy on the runaway current, the radial probe position, the toroidal magnetic field and the predisruptive plasma current are studied. The conversion efficiency of the magnetic plasma energy into runaway energy is calculated to be up to 26%. V C 2012 American Institute of Physics. [http://dx

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Wendelstein 7‐X: An Alternative Route to a Fusion Reactor

Wolf

Team

2009

Contrib. Plasma Phys.

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With the ITER tokamak magnetic confinement fusion is making the decisive step to realize a burning fusion plasma and prepare the basis for a demonstration power plant (DEMO). Despite the advantages of an intrinsically steady state magnetic field and better stability properties, the development of stellarators lags behind by about 1 1/2 device generations, because of the difficulties to realize the desired magnetic field configuration. The goal of the optimized stellarator Wendelstein 7-X is to overcome the principal deficiencies of the stellarator concept and demonstrate its reactor capability, combining sufficiently good thermal and fast ion confinement with reactor relevant β and collisionality under steady state conditions.

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

Cited by 87 publications

References 46 publications

Runaway generation during disruptions in JET and TEXTOR

Runaway generation during disruptions in JET and TEXTOR

Measurements of the runaway electron energy during disruptions in the tokamak TEXTOR

Wendelstein 7‐X: An Alternative Route to a Fusion Reactor

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