High-performance double-null plasmas under radiating mantle scenarios on DIII-D

Actively enhancing plasma radiated power has been used to reduce divertor heat flux in high power, high-performance double null divertor (DND) and near-DND plasmas in DIII-D, while at the same time maintaining acceptable energy confinement. One form of this approach that we focus on here is the radi...

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Bibliographic Details
Published in:Nuclear materials and energy 2019-05, Vol.19 (C)
Main Authors: Petrie, T. W., Grierson, B., Osborne, T. H., Turco, F., Allen, S. L., Fenstermacher, M. E., Ferron, J. R., Guo, H. Y., Hinson, E., La Haye, R., Lasnier, C. J., Leonard, A. W., Luce, T. C., Petty, C., Thomas, D., Victor, B., Wang, H., Watkins, J. G.
Format: Article
Language:English
Subjects:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
DIII-D
edge pedestal
energy confinement
gas injection and fueling impurity
power deposition
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Summary:Actively enhancing plasma radiated power has been used to reduce divertor heat flux in high power, high-performance double null divertor (DND) and near-DND plasmas in DIII-D, while at the same time maintaining acceptable energy confinement. One form of this approach that we focus on here is the radiating mantle. The effectiveness of the radiating mantle was found to depend strongly on the location of electron cyclotron (EC) heating deposition and on the effect that seed impurities have on triggering inimical MHD activity inside the plasma. In addition, we present experimental support for the predictions made by the ELITE boundary stability code (Snyder et al., 2002, [1]) for ways to improve confinement and fueling in these high-performance plasmas. Representative AT operating conditions were H98 ≈ 1.4–1.7, βN ≈ 3–4, and q95 ≈ 4.7–6.5.
ISSN:2352-1791
2352-1791
DOI:10.1016/j.nme.2019.01.028