Overview of ASDEX Upgrade results

Zohm, H.; Angioni, C.; Arslanbekov, Robert; Atanasiu, C. V.; Becker, G.; Becker, Werner; Behler, K.; Behringer, K.; Bergmann, Andreas; Bilato, R.; Bobkov, V.; Bolshukhin, D.; Bolzonella, T.; Borraß, K.; Brambilla, M.; Braun, F.; Buhler, A.; Carlson, A.; Conway, G. D.; Coster, D.; Drube, R.; Dux, R.; Egorov, S.M.; Eich, T.; Engelhardt, K.; Fahrbach, H.‐U.; Fantz, U.; Faugel, H.; Finken, K. H.; Foley, M.; Franzen, P.; Fuchs, Julien; Gafert, J.; Fournier, K. B.; Gantenbein, G.; Gehre, O.; Geier, A.; Gernhardt, J.; Goodman, T. P.; Gruber, O.; Gude, A.; Günter, S.; Haas, G.; Hartmann, D.; Heger, B.; Heinemann, B.; Herrmann, A.; Hobirk, J.; Hofmeister, F.; Hohenöcker, H.; Horton, L. D.; Igochine, V.; Jacchia, A.; Jakobi, Martin; Jenko, F.; Kallenbach, A.; Kardaun, O.; Kaufmann, Michael; Keller, Andrei; Kendl, A.; Kim, J.-W.; Kirov, K.; Kochergov, R.; Kollotzek, H.; Kraus, Werner; Krieger, K.; Kurki-Suonio, T.; Kurzan, B.; Lang, P. T.; Lasnier, C.; Lauber, P.; Laux, M.; Leonard, A. W.; Leuterer, F.; Lohs, A.; Lorenz, A.; Lorenzini, R.; Maggi, C. F.; Maier, H.; Mank, K.; Manso, M. E.; Mantica, P.; Maraschek, M.; Martines, E.; Mast, K. F.; McCarthy, Patrick J.; Meisel, D.; Meister, H.; Méo, F.; Merkel, P.; Merkel, R.; Merkl, D.; Mertens, V.; Monaco, F.; Mück, A.; Müller, Hans; Münich, M.; Mürmann, H.; Na, Y.-S.; Neu, G.; Neu, R.; Neuhäuser, J.; Nguyen, Frédéric; Nishijima, D.; Nishimura, Yasumasa; Noterdaeme, J.-M.; Nunes, I.; Pautasso, G.; Peeters, A. G.; Pereverzev, G.; Pinches, S. D.; Poli, E.; Proschek, M.; Pugno, R.; Quigley, E.; Raupp, G.; Reich, M.; Ribeiro, Tiago; Riedl, R.; Rohde, V.; Roth, J.; Ryter, F.; Saarelma, S.; Sandmann, W.; Savtchkov, A.; Sauter, O.; Schade, S.; Schilling, H.-B.; Schneider, W.; Schramm, G.; Schwarz, E. J.; Schweinzer, J.; Schweizer, Sabine; Scott, B.; Seidel, U.; Serra, F.; Šesnić, S.; Sihler, C.; Silva, Carlos; Sips, A. C. C.; Speth, E.; Stäbler, A.; Steuer, K.-H.; Stober, J.; Streibl, B.; Strumberger, E.; Suttrop, W.; Tabasso, A.; Tanga, A.; Tardini, G.; Tichmann, C.; Treutterer, W.; Troppmann, M.; Urano, H.; Varela, P.; Vollmer, O.; Wágner, D.; Wenzel, U.; Wesner, F.; Westerhof, E.; Wolf, R. C.; Wolfrum, E.; Würsching, E.; Yoon, S. W.; Yu, Q.; Zasche, D.; Zehetbauer, T.; Zehrfeld, H. P.

doi:10.1088/1741-4326/aa64f6

Cited by 59 publications

(35 citation statements)

References 38 publications

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“…In the discharges at hand, the optical thickness in the pedestal region is too low, therefore, measurements by the correlation electron cyclotron emission diagnostic are affected by density fluctuations. To put the present studies into context, it should be pointed out that N seeding into type-I ELMy H-mode plasmas generally can lead to a confinement improvement on AUG [31,77], which is due to a reduction of the high field side high density (HFSHD) pattern through increased SOL radiation and a resulting inward shift of the density profile [78]. Since the HFSHD is a consequence of the direction of E × B drifts in the divertor in favorable configuration, it is usually not present in unfavorable configuration with reversed divertor drift directions.…”

Section: Discussionmentioning

confidence: 99%

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Approaching detachment in I-mode—response of core confinement and the edge pedestal in the ASDEX Upgrade tokamak

et al. 2021

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Experiments on nitrogen assisted divertor detachment in the improved energy confinement mode (I-mode) are reported from the ASDEX Upgrade tokamak. When nitrogen is introduced into the divertor and radiation losses cool the divertor plasma down, a loss of core confinement is observed, concomitant with an increase in low frequency edge fluctuation levels. The loss in confinement can be compensated and the I-mode can be maintained by additional heating power input. Detachment of the inner divertor leg has been observed for the first time in an I-mode discharge. The outer divertor leg remains attached in these experiments. Good energy confinement properties (H 98(y, 2) = 0.9) during the detachment of the inner divertor leg are reported.

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Section: Discussionmentioning

confidence: 99%

“…The N concentration in the plasma reached only roughly 1.5%, which implies good impurity screening. Due to mostly non-stationary conditions, no estimates of divertor enrichment [31] and compression [32] can be given. L-mode parameters comparable to those before the L-I transition are obtained.…”

Section: Nitrogen Seeding Experiments In I-modementioning

confidence: 99%

Approaching detachment in I-mode—response of core confinement and the edge pedestal in the ASDEX Upgrade tokamak

et al. 2021

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“…The AUG is a mid-size divertor tokamak (major radius R = 1.65 m, minor radius a 0 = 0.5 m) where the plasma-facing components are mainly tungsten 14 (W) and the walls are repeatedly conditioned by boronization. In its reactor-relevant all-metal-wall configuration equipped with a powerful auxiliary heating system, the versatile set of diagnostics needed for plasma analysis and characterization are well suited for the task.…”

Section: Short Description Of the Setupmentioning

confidence: 99%

Targeting a Versatile Actuator for EU-DEMO: Xenon Doping of Fueling Pellets

Lang

Ploeckl

Bernert

et al. 2021

Fusion Science and Technology

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Xenon is a potential candidate as a pedestal and edge radiator in DEMO, but it is considered troublesome in cases where larger amounts have to be handled in the fuel cycle. Hence, direct and efficient codeposition inside the confined plasma with the fuel injected by means of solid cryogenic pellets is regarded as more favorable than simple gas puffing. At ASDEX Upgrade, investigations are underway to develop a versatile reactor-relevant pellet actuator. Equipped with an accordingly set up pellet launching system and well diagnosed, this all-metal-wall tokamak is well suited for this task. Here, we report on efforts to produce and inject pellets made from deuterium with a reasonable amount of admixed xenon. Results indicate xenon supply via carrier fueling pellets is possible while showing advanced performance. Compared to xenon gas puffing where long latency is observed, presumably due to wall sticking, doped pellets provide much shorter response times. Hence, this first exploration suggests fueling pellets with admixed auxiliary gases can be a versatile, efficient, and fast actuator for additional control features such as, e.g., radiative plasma cooling.

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“…The AUG tokamak [5] is equipped with several reflectometry systems and was considered as experimental reference. An example of O-mode fixed frequency reflectometers in conventional set-up at AUG can be found in [6].…”

Section: Jinst 14 C10043mentioning

confidence: 99%

Synthetic conventional reflectometry probing of edge and scrape-off layer plasma turbulence

Vicente¹,

Silva²,

Ribeiro³

et al. 2019

J. Inst.

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A: Microwave reflectometry techniques have been successfully applied to measure electron density fluctuations in magnetic confined fusion devices with good spatial and time resolutions. However, quantitative interpretation of turbulence measurements has driven continuous development of both analytical theory and sophisticated numerical codes in support of reflectometry. Comparisons between experimental and synthetic reflectometry have been performed previously while only recently realistic gyro-fluid simulations have been employed together with a full-wave code to simulate measured turbulence properties with reflectometry. In this work, we report on recent efforts to employ the two-dimensional full-wave code REFMUL to implement a synthetic reflectometry diagnostic to model plasma turbulence measurements on the edge and scrape-off layer (SOL) peripheral regions of fusion devices. Numerical descriptions of microscopic turbulence were obtained from both an analytical model (following a Kolgomorov-like wavenumber spectrum) and from the GEMR turbulence code based on gyro-fluid theory. Simulations of fixed frequency conventional reflectometry with ordinary mode (O-mode) wave propagation were carried out for both turbulence cases separately. Preliminary comparisons between synthetic measurements, numerical plasma characteristics, and experimental data from ASDEX Upgrade tokamak are made. As previously described in literature, regimes of linear and non-linear response occurring at low and high turbulence levels, respectively, are observed and characterized. Synthetic spectra across moderate to high turbulence levels display qualitatively good agreement with experimental data across the edge region. K: Nuclear instruments and methods for hot plasma diagnostics; Simulation methods and programs 1Corresponding author.

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Overview of ASDEX Upgrade results

Cited by 59 publications

References 38 publications

Approaching detachment in I-mode—response of core confinement and the edge pedestal in the ASDEX Upgrade tokamak

Approaching detachment in I-mode—response of core confinement and the edge pedestal in the ASDEX Upgrade tokamak

Targeting a Versatile Actuator for EU-DEMO: Xenon Doping of Fueling Pellets

Synthetic conventional reflectometry probing of edge and scrape-off layer plasma turbulence

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