Snowflake divertor configuration studies in National Spherical Torus Experiment

Soukhanovskii, V A; McLean, A G; Rognlien, T D; Ryutov, D D; Umansky, M V; Bell, R E; Diallo, A; Gerhardt, S; Kaye, S; Kolemen, E; LeBlanc, B P; Menard, J E; Paul, S F; Podesta, M; Roquemore, A L; Scotti, F; Battaglia, D; Bell, M G; Gates, D A; Kaita, R; others, and

doi:10.1063/1.4737117

Title: Snowflake divertor configuration studies in National Spherical Torus Experiment

Journal Article · Wed Aug 15 00:00:00 EDT 2012 · Physics of Plasmas

DOI:https://doi.org/10.1063/1.4737117· OSTI ID:22086032

Soukhanovskii, V A; McLean, A G; Rognlien, T D; Ryutov, D D; Umansky, M V ^[1]; Bell, R E; Diallo, A; Gerhardt, S; Kaye, S; Kolemen, E; LeBlanc, B P; Menard, J E; Paul, S F; Podesta, M; Roquemore, A L; Scotti, F; Battaglia, D; Bell, M G; Gates, D A; Kaita, R ^[2] more »

Lawrence Livermore National Laboratory, Livermore, California 94551 (United States)
Princeton Plasma Physics Laboratory, Princeton, New Jersey 08543 (United States)

Experimental results from NSTX indicate that the snowflake divertor (D. Ryutov, Phys. Plasmas 14, 064502 (2007)) may be a viable solution for outstanding tokamak plasma-material interface issues. Steady-state handling of divertor heat flux and divertor plate erosion remains to be critical issues for ITER and future concept devices based on conventional and spherical tokamak geometry with high power density divertors. Experiments conducted in 4-6 MW NBI-heated H-mode plasmas in NSTX demonstrated that the snowflake divertor is compatible with high-confinement core plasma operation, while being very effective in steady-state divertor heat flux mitigation and impurity reduction. A steady-state snowflake divertor was obtained in recent NSTX experiments for up to 600 ms using three divertor magnetic coils. The high magnetic flux expansion region of the scrape-off layer (SOL) spanning up to 50% of the SOL width {lambda}{sub q} was partially detached in the snowflake divertor. In the detached zone, the heat flux profile flattened and decreased to 0.5-1 MW/m{sup 2} (from 4-7 MW/m{sup 2} in the standard divertor) indicative of radiative heating. An up to 50% increase in divertor, P{sub rad} in the snowflake divertor was accompanied by broadening of the intrinsic C III and C IV radiation zones, and a nearly order of magnitude increase in divertor high-n Balmer line emission indicative of volumetric recombination onset. Magnetic reconstructions showed that the x-point connection length, divertor plasma-wetted area and divertor volume, all critical parameters for geometric reduction of deposited heat flux, and increased volumetric divertor losses were significantly increased in the snowflake divertor, as expected from theory.

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OSTI ID:: 22086032

Journal Information:: Physics of Plasmas, Vol. 19, Issue 8; Other Information: (c) 2012 American Institute of Physics; Country of input: International Atomic Energy Agency (IAEA); ISSN 1070-664X

Country of Publication:: United States

Language:: English

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Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
BALMER LINES
DIVERTORS
EROSION
HEAT FLUX
H-MODE PLASMA CONFINEMENT
ITER TOKAMAK
MAGNET COILS
MAGNETIC FLUX
MAGNETIC RECONNECTION
MATHEMATICAL SOLUTIONS
NSTX DEVICE
PLASMA IMPURITIES
PLASMA SCRAPE-OFF LAYER
POWER DENSITY
RECOMBINATION
STEADY-STATE CONDITIONS

Title: Snowflake divertor configuration studies in National Spherical Torus Experiment

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