Measurements of the impurity flow velocity and temperature in deuterium and hydrogen plasmas in the divertor legs of the stochastic layer in LHD

the LHD Experiment Group

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Abstract

This paper presents carbon impurity flow velocity and temperature measurements in the divertor region for a wide density range ne = (1 - 14) ×1019 m-3, central electron temperature Te = 1.5 - 3.5 keV, and with total neutral beam injection power of 9 - 12MW. The isotope effect on the transport is studied in hydrogen (H) and deuterium (D) discharges. Flow velocities for D plasma are systematically slower, by the factor of 1.4 - 2, compared to H plasma. For all selected discharges, the carbon ions flow toward the divertor in both H and D plasmas. Different velocities are obtained depending on the charge states. For C+ and C2+ they are in the range of 10 - 30 km/s, and 5 - 20 km/s for C3+ ions. It is also found that there is no change of flow direction even in the lowest density, where the impurity transport model predicts flow toward upstream in the thermal force dominant regime. In H discharges velocities increase proportionally to the plasma density, while in D discharges this dependency is weaker. Possible mechanism to interpret these observations is discussed based on the parallel momentum balance of impurity transport.

Original languageEnglish
Article number3402058
JournalPlasma and Fusion Research
Volume13
DOIs
StatePublished - 2018
Externally publishedYes

Funding

This work has been financially supported by JSPS Grant No. 16H04622, and by the NIFS budget ULPP026 and KOAP031.

FundersFunder number
Japan Society for the Promotion of Science18K03576, 16H04622
National Institute for Fusion ScienceKOAP031, ULPP026

    Keywords

    • Carbon
    • Deuterium
    • Echelle spectroscopy
    • Hydrogen
    • Impurity
    • Isotope effect
    • Transport

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