Elimination of defects in a welded joint in a niobium superconducting resonator-Reference-Cited by-同舟云学术

Elimination of defects in a welded joint in a niobium superconducting resonator

Published:2023-04-01 Issue:1 Volume:68 Page:18-23
ISSN:2524-244X
Container-title:Proceedings of the National Academy of Sciences of Belarus, Physical-Technical Series
language:
Short-container-title:Vescì Akademìì navuk Belarusì. Seryâ fizika-tehničnyh navuk

Author:

Burin A. A.¹^ORCID,Zaleski V. G.¹,Pobol I. L.¹^ORCID

Affiliation:

1. Physical-Technical Institute of the National Academy of Sciences

Abstract

The possible reasons for the appearance of defects during welding of a niobium superconducting coaxial halfwave resonator (HWR) are investigated, which consist in the deviation of the shape of the welded surface from the given one, in the deviation of the angle of incidence of the beam from the perpendicular to the welded surface, in fluctuations in the thickness of the welded edges, and also the presence of some instability (pulsation) accelerating voltage, beam currents and focusing of the electron beam gun. The possibilities of preventing the appearance of defects during welding are determined, which consist in regulating the operating parameters of the electron beam gun depending on possible errors in the manufacture and preparation of the welded edges. Methods for elimination of defects in welding of niobium superconducting coaxial HWR are studied. A method has been developed for repairing defects in welded joints such as burn-throughs on the type of resonator under study using electron-beam deposition. The results of measuring the resonant frequency of the HWR before the onset and after the recovery of burn-through are presented, which showed that the melting of the hole did not lead to a change in the electrical characteristics. Vacuum and cryogenic tests at liquid nitrogen temperature confirmed the tightness of the welded joints. The results obtained can be used in the development of basic technologies for the restoration and repair of expensive and difficult-to-manufacture elements of accelerator technology – superconducting high-frequency resonators made of high-purity niobium sheet.

Publisher

Publishing House Belorusskaya Nauka

Subject

Pharmacology (medical)

Reference10 articles.

1. Pobol I. L., Yurevich S. V. Developing of superconducting niobium cavities for accelerators. Journal of Physics: Conference Series, 2015, vol. 653, no. 1, art. ID 012008. http://doi.org/10.1088/1742-6596/653/1/012008

2. Butenko A. V., Emelianov N. E., Sidorin A. O., Syresin E. M., Trubnikov G. V., Gusarova M. A., Kulevoy T. V., et al. Status of R&D on new superconducting injector linac for Nuclotron-NICA. 61st ICFA Advanced Beam Dynamics Workshop on HighIntensity and High-Brightness Hadron Beams, Daejeon, Korea, 17–22 June 2018: Proceedings. Daejeon, 2018, рp. 83–87. http://doi.org/10.18429/JACoW-HB2018-TUA2WC02

3. Gusarova M. A., Lalayan M. V., Nemchenko R. E., Polozov S. M., Butenko A. V., Syresin E. M., Bychenok D. S., et al. Current state of work on the creation of superconducting accelerating cavities for the Nuclotron-Nica project. VII Mezhdunarodnaya konferentsiya “Lazernye, plazmennye issledovaniya i tekhnologii” (Laplaz-2021), Moskva, NIYaU MIFI, 24–26 marta 2021 g. [7th International Conference “Laser, Plasma Research and Technologies” (Laplaz-2021), Moscow, MEPhI Research Institute, March 24–26, 2021]. Moscow, 2021, pp. 112–114 (in Russian).

4. Gao J., Zhai J. Y., Li Z. Q., Zhao T. X., Dai J. P., Wang Q. Y., Guo Z. D., et al. IHEP low-loss large grain 9-cell cavity fabrication and processing. 1st International Particle Accelerator Conference (IPAC’10), Kyoto, Japan, May 23–28, 2010: Proceedings. Geneva, 2010, pp. 2974–2976.

5. Navitski A., Elsen E., Foster B., Iversen J., Laasch R., Matheisen A., Reschke D., et al. ILC-higrade cavities as a tool of quality control for European XFEL. 16th International Conference on RF Superconductivity, SRF 2013, Paris, France, 23–27 September 2013: Proceedings. 2013, pp. 209–212.