L–H power threshold studies in JET with Be/W and C wall

Maggi, C. F.; Delabie, E.; Biewer, T. M.; Groth, M.; Hawkes, N.; Lehnen, M.; Luna, E. de la; McCormick, K.; Reux, C.; Rimini, F.; Solano, E.R.; Andrew, Y.; Bourdelle, C.; Bobkov, V.; Brix, M.; Calabrò, G.; Czarnecka, A.; Flanagan, J.; Lerche, E.; Marsen, S.; Nunes, I.; Eester, D. Van; Stamp, M.; Contributors, Jet

doi:10.1088/0029-5515/54/2/023007

Cited by 97 publications

(186 citation statements)

References 36 publications

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“…We also underline that, for ASDEX Upgrade, the difference between the carbon and tungsten walls is small. It is worth noticing that the B 4/5 T of n e,min reported for JET in [22] is in good agreement with equation 3, explained by the fact that in these JET experiments I p was varied almost proportionally to B T . Our formula also explains that Ohmic H-modes could be achieved in ASDEX Upgrade with B T = 1.1 T at densities as low as n e,min ≈ 2.2 × 10 19 m −3 : the low B T value does not only yield a low P L−H through B 0.…”

Section: Determination Of N Eminsupporting

confidence: 77%

“…It is worth noticing that the I p dependence is in agreement with the variation of n e,min yielded by our data. This formula can be applied to data from various devices: the recent results from Alcator C-Mod in [21] and JET with the ITER-Like Wall in [22], as well as those deduced from the ITPA threshold database and reported in [18] for DIII-D, JFT-2M and JT-60U. The comparison between the experimental and predicted values of n e,min is illustrated in figure 10.…”

Section: Determination Of N Eminmentioning

confidence: 99%

“…the upwards deviation from then e 0.72 dependence of the scaling, is observed in most of the tokamaks, but with variable strength [24,25,26,19,21,20,22]. The effect is particularly strong in plasmas heated with electron cyclotron resonant heating (ECRH), [24,19], suggesting that this might be due to the decoupling between the electron and ion heat channels, but this has, so far, not been demonstrated experimentally.…”

Section: Introductionmentioning

confidence: 99%

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Experimental evidence for the key role of the ion heat channel in the physics of the L–H transition

et al. 2014

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Abstract.Experimental investigations carried out in the ASDEX Upgrade tokamak under various conditions demonstrate that the ion heat flux at the plasma edge plays a key role in the L-H transition physics, while the electron heat flux does not seem to play any role. This is due to the fact that the ion heat flux governs the radial electric field well induced by the main ions which is responsible for the turbulence stabilization causing the L-H transition. The experiments have been carried out in the low density branch of the power threshold where the electron and ion heat channels can be well separated. In plasmas heated by electron heating, the edge ion heat flux has been increased to reach the L-H transition by using separately three actuators: heating power, density and plasma current. In addition, the key role of the edge ion heating has been confirmed in experiments taking advantage of the direct ion heating provided by neutral beam injection. The role of the ion heat flux explains the non-monotonic density dependence of the L-H threshold power. Based on these results, a formula for the density of the threshold minimum has been developed, which also describes well the values found in tokamaks of various size. For ITER it predicts a value which is close to the density presently foreseen to enter the H-mode and indicates that operation at half field and current would benefit from a very significantly lower density minimum and correspondingly low threshold power.

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Section: Determination Of N Eminsupporting

confidence: 77%

Section: Determination Of N Eminmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Experimental evidence for the key role of the ion heat channel in the physics of the L–H transition

et al. 2014

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“…The physics mechanisms underlying the low density dependence of the power threshold remain largely unknown. Recent results from JET with a Be/W and C wall show a correlation of the density roll-over to divertor geometry and divertor/wall materials [8]. On the other hand, experiments from ASDEX Upgrade demonstrate the key role played by the edge ion heat flux as an explanation for the strong increase in the L-H power threshold at low density with electron cyclotron resonant heating (ECRH) as the auxiliary heating power [33].…”

Section: H-mode Accessmentioning

confidence: 99%

Study on the L–H transition power threshold with RF heating and lithium-wall coating on EAST

Chen

Nielsen

et al. 2016

Nucl. Fusion

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The power threshold for low (L) to high (H) confinement mode transition achieved by radio-frequency (RF) heating and lithium-wall coating is investigated experimentally on EAST for two sets of walls: an all carbon wall (C) and molybdenum chamber and a carbon divertor (Mo/C). For both sets of walls, a minimum power threshold P thr of ~0.6 MW was found when the EAST operates in a double null (DN) divertor configuration with intensive lithium-wall coating. When operating in upper single null (USN) or lower single null (LSN), the power threshold depends on the ion ∇B drift direction. The low density dependence of the L-H power threshold, namely an increase below a minimum density, was identified in the Mo/C wall for the first time. For the C wall only the single-step L-H transition with limited injection power is observed whereas also the so-called dithering L-H transition is observed in the Mo/C wall. The dithering behaves distinctively in a USN, DN and LSN configuration, suggesting the divertor pumping capability is an important ingredient in this transition since the internal cryopump is located underneath the lower divertor. Depending on the chosen divertor configuration, the power across the separatrix P loss increases with neutral density near the lower X-point in EAST with the Mo/C wall, consistent with previous results in the C wall (Xu et al 2011 Nucl. Fusion 51 072001). These findings suggest that the edge neutral density, the ion ∇B drift as well as the divertor pumping capability play important roles in the L-H power threshold and transition behaviour.

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“…Although no ultimate way has been ever established for clarifying the nonlinear system, parameter scan experiments have succeeded to describe the nonlinear nature of the confined plasma. For example, the H-mode power threshold study is often performed by scanning the line averaged density and the input heating power [1][2][3].…”

Section: Introductionmentioning

confidence: 99%

Phenomenological Classification of Turbulence States in Linear Magnetized Plasma PANTA

Kobayashi

Inagaki

Sasaki

et al. 2017

Plasma and Fusion Research

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Changing the experimental conditions such as the neutral pressure and the magnetic field strength provides a drastic change in the turbulence states in linear magnetized helicon plasmas. In order to define the turbulence states and their occurrence region a throughout parameter scan in the two-dimensional parameter space was performed. The classification of the turbulence states is carried out phenomenologically based on the turbulence spectrum and the waveform.

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L–H power threshold studies in JET with Be/W and C wall

Cited by 97 publications

References 36 publications

Experimental evidence for the key role of the ion heat channel in the physics of the L–H transition

Experimental evidence for the key role of the ion heat channel in the physics of the L–H transition

Study on the L–H transition power threshold with RF heating and lithium-wall coating on EAST

Phenomenological Classification of Turbulence States in Linear Magnetized Plasma PANTA

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