Recent RHIC in-situ coating technology developments
A. Hershcovitch, M. Blaskiewicz, J.M. Brennan, Ashish Chawla, W. Fischer, C-J Liaw, W. Meng, R. Todd, Art Custer, Mark Erickson, Nader Jamshidi, P. H. Kobrin, R. Laping, H. J. Poole, J. M. Jimenez, H. Neupert, M. Taborelli, C. Yin-Vallgren, Н. С. Сочугов
- Year
- 2013
- Citations
- 2
- Access
- Open access
Abstract
To rectify the problems of electron clouds observed in RHIC and unacceptable ohmic heating for superconducting magnets that can limit future machine upgrades, we started developing a robotic plasma deposition technique for $in-situ$ coating of the RHIC 316LN stainless steel cold bore tubes based on staged magnetrons mounted on a mobile mole for deposition of Cu followed by amorphous carbon (a-C) coating. The Cu coating reduces wall resistivity, while a-C has low SEY that suppresses electron cloud formation. Recent RF resistivity computations indicate that 10 μm of Cu coating thickness is needed. But, Cu coatings thicker than 2 μm can have grain structures that might have lower SEY like gold black. A 15-cm Cu cathode magnetron was designed and fabricated, after which, 30 cm long samples of RHIC cold bore tubes were coated with various OFHC copper thicknesses; room temperature RF resistivity measured. Rectangular stainless steel and SS discs were Cu coated. SEY of rectangular samples were measured at room; and, SEY of a disc sample was measured at cryogenic temperatures.
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