Heat loads on JET plasma facing components from ICRF and LH wave absorption in the SOL

Jacquet, P.; Colas, L.; Mayoral, M.‐L.; Arnoux, G.; Bobkov, V.; Brix, M.; Coad, P.; Czarnecka, A.; Dodt, D.; Durodié, F.; Ekedahl, A.; Frigione, D.; Fursdon, M.; Gauthier, E.; Goniche, M.; Graham, M.; Joffrin, E.; Korotkov, A.; Lerche, E.; Mailloux, J.; Monakhov, I.; Noble, C.; Ongena, J.; Petržı́lka, V.; Portafaix, C.; Rimini, F.; Sirinelli, A.; Riccardo, V.; Vízváry, Z.; Widdowson, A.; Zastrow, K.‐D.; Contributors, Jet

doi:10.1088/0029-5515/51/10/103018

Cited by 67 publications

(73 citation statements)

References 34 publications

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“…This parametric dependence is valuable for design and experimental studies. In particular, the RFinduced heat loads in the RF antenna vicinity were inferred experimentally to scale as E //ap 1 , 29,30 consistent with the first order theory. The particular simulation showed in Ref.…”

Section: -13supporting

confidence: 71%

“…From a practical point of view, this is also a critical regime since experimentally the deleterious plasma-wall interaction related to the sheaths gets exacerbated at high RF power. 18,[28][29][30] Sections III and IV detail the asymptotic resolution for several configurations of the excitation and of the target plasma. The way to refine iteratively the solution from its asymptotic value is also outlined.…”

Section: Introductionmentioning

confidence: 99%

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Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

et al. 2012

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A minimal two-field fluid approach is followed to describe the radio-frequency (RF) wave propagation in the bounded scrape-off layer plasma of magnetic fusion devices self-consistently with direct current (DC) biasing of this plasma. The RF and DC parts are coupled by non-linear RF and DC sheath boundary conditions at both ends of open magnetic field lines. The physical model is studied within a simplified framework featuring slow wave (SW) only and lateral walls normal to the straight confinement magnetic field. The possibility is however kept to excite the system by any realistic 2D RF field map imposed at the outer boundary of the simulation domain. The self-consistent RF + DC system is solved explicitly in the asymptotic limit when the width of the sheaths gets very large, for several configurations of the RF excitation and of the target plasma. In the case of 3D parallelepipedic geometry, semi-analytical results are proposed in terms of asymptotic waveguide eigenmodes that can easily be implemented numerically. The validity of the asymptotic treatment is discussed and is illustrated by numerical tests against a quantitative criterion expressed from the simulation parameters. Iterative improvement of the solution from the asymptotic result is also outlined. Throughout the resolution, key physical properties of the solution are presented. The radial penetration of the RF sheath voltages along lateral walls at both ends of the open magnetic field lines can be far deeper than the skin depth characteristic of the SW evanescence. This is interpreted in terms of sheath-plasma wave excitation. Therefore, the proper choice of the inner boundary location is discussed as well as the appropriate boundary conditions to apply there. The asymptotic scaling of various quantities with the amplitude of the input RF excitation is established.

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Section: -13supporting

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

et al. 2012

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“…However, the understanding of the interaction between ICRF antennas and the scrape-off layer (SOL) plasma is crucial in order to improve the performance of ICRF in a tokamak. In fact, many ICRF heating experiments [2,3,4,5,6,7,8,9] have found regimes in which significant fractions of the coupled RF power does not appear in the core. Experimental studies on erosion and impurity generation in the presence of ICRF have been performed on different machines [4,7,10,8,9].…”

Section: Introductionmentioning

confidence: 99%

“…In fact, many ICRF heating experiments [2,3,4,5,6,7,8,9] have found regimes in which significant fractions of the coupled RF power does not appear in the core. Experimental studies on erosion and impurity generation in the presence of ICRF have been performed on different machines [4,7,10,8,9]. In the recent years, a large effort has been made to understand the main physical mechanisms behind the interaction between RF waves and the SOL, such as parametric decay [11,3,12,13], sheath effects [14,15], etc..…”

Section: Introductionmentioning

confidence: 99%

Full wave simulations of fast wave efficiency and power losses in the scrape-off layer of tokamak plasmas in mid/high harmonic and minority heating regimes^*

Bertelli

Jaeger²,

Hosea

et al. 2015

Nucl. Fusion

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Abstract. Several experiments on different machines and in different fast wave (FW) heating regimes, such as hydrogen minority heating and high harmonic fast waves, have found strong interaction between radio-frequency (RF) waves and the scrape-off layer (SOL) region. This paper examines the propagation and the power loss in the SOL by using the full wave code AORSA, in which the edge plasma beyond the last closed flux surface (LCFS) is included in the solution domain and a collisional damping parameter is used as a proxy to represent the real, and most likely nonlinear, damping processes. 3D AORSA results for National Spherical Torus eXperiment (NSTX), where a full antenna spectrum is reconstructed, are shown confirming the same behavior found for a single toroidal mode results in Bertelli et al Nucl. Fusion, 54 083004, 2014, namely, a strong transition to higher SOL power losses (driven by the RF field) has been found when the FW cut-off is removed from in front of the antenna by increasing the edge density. Additionally, full wave simulations have been extended for "conventional" tokamaks with higher aspect ratios, such as the DIII-D, Alcator C-Mod, and EAST devices. DIII-D results show similar behavior found in NSTX and NSTX-U, consistent with previous DIII-D experimental observations. In contrast, a different behavior has been found for C-Mod and EAST, which operate in the minority heating regime unlike NSTX/NSTX-U and DIII-D, which operate in the mid/high harmonic regime.

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“…It is known that ICRF operation can lead to deposition of additional heat loads due to RF sheath effects, as has been observed with carbon wall in JET [1]. ICRF operation can also lead to release of Be and high-Z impurities such as W [2] and nickel Ni.…”

Section: Introductionmentioning

confidence: 99%

ICRF specific plasma wall interactions in JET with the ITER-like wall

Bobkov

Arnoux

Brezinsek³

et al. 2013

Journal of Nuclear Materials

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Abstract.A variety of plasma wall interactions (PWIs) during operation of the so-called A2 ICRF antennas is observed in JET with the ITER-like wall. Amongst effects of the PWIs, the W content increase is the most significant, especially at low plasma densities. No increase of W source from the main divertor and entrance of the outer divertor during ICRF compared to NBI phases was found by means of spectroscopic and W I (400.9 nm) imaging diagnostics. In contrary, the W flux there is higher during NBI. Charge exchange neutrals could be excluded as considerable contributors to the W source. The high W content in ICRF heated limiter discharges suggests the possibility of other W sources than the divertor alone. Dependencies of PWIs to individual ICRF antennas during q 95 -scans, and intensification of those for the -90 o phasing, indicate a link between the PWIs and the antenna near-fields. The PWIs include heat loads and Be sputtering pattern on antenna limiters. Indications of some PWIs at the outer divertor entrance are observed which do not result in higher W flux compared to the NBI phases, but are characterized by small antenna-specific (up to 25% with respect to ohmic phases) bipolar variations of W I emission. The first TOPICA calculations show a particularity of the A2 antennas compared to the ITER antenna, due to the presence of long antenna limiters in the RF image current loop and thus high near-fields across the most part of the JET outer wall.

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Heat loads on JET plasma facing components from ICRF and LH wave absorption in the SOL

Cited by 67 publications

References 34 publications

Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

Full wave simulations of fast wave efficiency and power losses in the scrape-off layer of tokamak plasmas in mid/high harmonic and minority heating regimes^*

ICRF specific plasma wall interactions in JET with the ITER-like wall

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Heat loads on JET plasma facing components from ICRF and LH wave absorption in the SOL

Cited by 67 publications

References 34 publications

Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

Self consistent radio-frequency wave propagation and peripheral direct current plasma biasing: Simplified three dimensional non-linear treatment in the “wide sheath” asymptotic regime

Full wave simulations of fast wave efficiency and power losses in the scrape-off layer of tokamak plasmas in mid/high harmonic and minority heating regimes*

ICRF specific plasma wall interactions in JET with the ITER-like wall

Contact Info

Product

Resources

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Full wave simulations of fast wave efficiency and power losses in the scrape-off layer of tokamak plasmas in mid/high harmonic and minority heating regimes^*