Power exhaust in the snowflake divertor for L- and H-mode TCV tokamak plasmas

Vijvers, W.A.J.; Canal, G. P.; Labit, B.; Reimerdes, H.; Tál, B.; Coda, S.; Temmerman, G.C. De; Duval, B.P.; Morgan, T.W.; Zielinski, JJ Jakub

doi:10.1088/0029-5515/54/2/023009

Cited by 39 publications

(48 citation statements)

References 24 publications

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“…Previously, similar observations were made in TCV [5] and NSTX [8]. In the DIII-D H-mode discharges, the majority of ELMs were Type I ELMs with DW ELM =W ped $ 0:02 À 0:1, with a few larger ELMs.…”

Section: Elm Heat Flux Mitigationsupporting

confidence: 78%

“…standard divertor) and has a strong impact on edge plasma properties. Experiments performed in the TCV [3][4][5], NSTX [6][7][8] and DIII-D tokamaks [9] are providing data to support the physics basis for the SF divertor concept development for future high-power facilities. Initial experiments in DIII-D and NSTX at high divertor power density demonstrated significantly reduced divertor heat flux with the SF-minus divertor and compatibility with high performance operation (H98y2P1).…”

Section: Introductionmentioning

confidence: 99%

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Radiative snowflake divertor studies in DIII-D

Soukhanovskii

Allen

Fenstermacher

et al. 2015

Journal of Nuclear Materials

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a b s t r a c tRecent DIII-D experiments assessed the snowflake divertor (SF) configuration in a radiative regime in Hmode discharges with D 2 seeding. The SF configuration was maintained for many energy confinement times (2-3 s) in H-mode discharges (I p ¼ 1:2 MA, P NBI ¼ 4-5 MW, and B Â rB down (favorable direction toward the divertor)), and found to be compatible with high performance operation (H98y2 P 1). The two studied SF configurations, the SF-plus and the SF-minus, have a small finite distance between the primary X-point and the secondary B p null located in the private flux region or the common flux region, respectively. In H-mode discharges with the SF configurations (cf. H-mode discharges with the standard divertor with similar conditions) the stored energy lost per the edge localized mode (ELM) was reduced, and significant divertor heat flux reduction between and during ELMs was observed over a range of collisionalities, from lower density conditions toward a higher density H-modes with the radiative SF divertor.

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Section: Elm Heat Flux Mitigationsupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Radiative snowflake divertor studies in DIII-D

Soukhanovskii

Allen

Fenstermacher

et al. 2015

Journal of Nuclear Materials

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“…A new 32-chords divertor spectroscopy system (DSS) [23] has been installed for extracting information on recombination and electron temperature from Balmer series spectra. This information can be combined with radiation measurements estimated from Bolometry [24] and absolute extreme ultraviolet (AXUV) bolometric camera sightlines [25]. An array of wall-mounted Langmuir probes (LPs) [26] covers the inner and outer wall as well as the floor.…”

Section: Methodsmentioning

confidence: 99%

Modification of SOL profiles and fluctuations with line-average density and divertor flux expansion in TCV

et al. 2017

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Abstract. A set of Ohmic density ramp experiments addressing the role of parallel connection length in modifying Scrape Off Layer (SOL) properties has been performed on the TCV tokamak. The parallel connection length has been modified by varying the poloidal flux expansion f x . It will be shown that this modification does not influence neither the detachment density threshold, nor the development of a flat Scrape Off Layer (SOL) density profile which instead depends strongly on the increase of the core line average density. The modification of the SOL upstream profile, with the appearance of what is generally called a density shoulder, has been related to the properties of filamentary blobs. Blob size increases with density, without any dependence pn the parallel connection length both in the near and far SOL. The increase of the density decay length, corresponding to a profile flattening, has been related to the variation of the divertor normalized collisionality Λ div [1,2], showing that in TCV the increase of Λ div is not sufficient to guarantee the SOL upstream profile flattening.

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“…This unique snowflake divertor property was observed experimentally [18,[20][21][22] and is highly beneficial for inter-ELM and ELM peak heat flux mitigation. The associated transport mechanism in the divertor null region is not well understood.…”

Section: Heat and Particle Flux Sharing Among All Divertor Legsmentioning

confidence: 69%

Tokamak Power Exhaust with the Snowflake Divertor: Present Results and Outstanding Issues

Soukhanovskii

2015

J Fusion Energ

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A snowflake divertor magnetic configuration (Ryutov in Phys Plasmas 14(6):064502, 2007) with the second-order poloidal field null offers a number of possible advantages for tokamak plasma heat and particle exhaust in comparison with the standard poloidal divertor with the first-order null. Results from snowflake divertor experiments are briefly reviewed and future directions for research in this area are outlined.

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Power exhaust in the snowflake divertor for L- and H-mode TCV tokamak plasmas

Cited by 39 publications

References 24 publications

Radiative snowflake divertor studies in DIII-D

Radiative snowflake divertor studies in DIII-D

Modification of SOL profiles and fluctuations with line-average density and divertor flux expansion in TCV

Tokamak Power Exhaust with the Snowflake Divertor: Present Results and Outstanding Issues

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