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Naoko ASHIKAWA, Robert LUNSFORD, Federico NESPOLI, Erik GILSON, Yaowei YU, Jiansheng HU, Shinichiro KADO. Coated boron layers by boronization and a real-time boron coating using an impurity powder dropper in the LHD[J]. Plasma Science and Technology, 2024, 26(8): 085103. DOI: 10.1088/2058-6272/ad495f
Citation: Naoko ASHIKAWA, Robert LUNSFORD, Federico NESPOLI, Erik GILSON, Yaowei YU, Jiansheng HU, Shinichiro KADO. Coated boron layers by boronization and a real-time boron coating using an impurity powder dropper in the LHD[J]. Plasma Science and Technology, 2024, 26(8): 085103. DOI: 10.1088/2058-6272/ad495f

Coated boron layers by boronization and a real-time boron coating using an impurity powder dropper in the LHD

  • In the Large Helical Device (LHD), diborane (B2H6) is used as a standard boron source for boronization, which is assisted by helium glow discharges. In 2019, a new Impurity Powder Dropper (IPD) system was installed and is under evaluation as a real-time wall conditioning technique. In the LHD, which is a large-sized heliotron device, an additional helium (He) glow discharge cleaning (GDC) after boronization was operated for a reduction in hydrogen recycling from the coated boron layers. This operational time of 3 h was determined by spectroscopic data during glow discharges. A flat hydrogen profile is obtained on the top surface of the coated boron on the specimen exposed to boronization. The results suggest a reduction in hydrogen at the top surface by He-GDC. Trapped oxygen in coated boron was obtained by boronization, and the coated boron, which has boron-oxide, on the first wall by B-IPD was also shown. Considering the difference in coating areas between B2H6 boronization and B-IPD operation, it would be most effective to use the IPD and B2H6 boronization coating together for optimized wall conditioning.
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