Enviar artigo por via de e-mail Compatibility of Molybdenum, Tungsten, and 304 Stainless Steel in Static Liquid Lithium Under High Vacuum
- Autores: Meng X.1,2, Zuo G.2, Sun Z.2, Xu W.2, Huang M.2, Xu C.3, Qian Y.2, Hu W.3, Hu J.2,4, Deng H.1,3
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Afiliações:
- Department of Applied Physics, School of Physics and Electronics
- Institute of Plasma Physics
- College of Materials Science and Engineering
- CAS Key Laboratory of Photovoltaic and Energy Conservation Materials
- Edição: Volume 44, Nº 7 (2018)
- Páginas: 671-677
- Seção: Tokamaks
- URL: https://journals.rcsi.science/1063-780X/article/view/186841
- DOI: https://doi.org/10.1134/S1063780X18070036
- ID: 186841
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Resumo
Molybdenum (Mo), tungsten (W), and stainless steel (SS) are widely used as important structure materials and first wall materials in fusion devices, while liquid lithium (Li) limiter/divertor can provide an attractive option for withstanding high heat load and solving life-time problem of first wall. Studying the compatibility of these materials exposed to liquid Li is significant for the application in Mo, W, and SS in fusion reactors. The corrosion behaviors of Mo, W, and 304SS exposed to static liquid Li at 600 K up to 1320 h under high vacuum with pressure 10−4 Pa were investigated. After exposure to liquid Li, it was found that the weight loss of Mo, W, and 304SS increases with corrosion time, but the total amount is moderate. 304SS specimens produce a non-uniform corrosion behavior because of Cr, Ni, and carbon (C) elements selectivity depletion and formation of carbides compound near surface. Mo and W surface microstructures are unchanged. 304SS surface hardness increases with corrosion products because these particles include C element, which increases by 49 HV after exposed to liquid Li for 1320 h, while Mo and W surface hardness are unchanged by the reason of their excellent corrosion resistance.
Sobre autores
Xiancai Meng
Department of Applied Physics, School of Physics and Electronics; Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Changsha, 410082; Hefei, 230031
Guizhong Zuo
Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031
Zhen Sun
Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031
Wei Xu
Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031
Ming Huang
Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031
Chao Xu
College of Materials Science and Engineering
Email: hujs@ipp.ac.cn
República Popular da China, Changsha, 410082
Yuzhong Qian
Institute of Plasma Physics
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031
Wangyu Hu
College of Materials Science and Engineering
Email: hujs@ipp.ac.cn
República Popular da China, Changsha, 410082
Jiansheng Hu
Institute of Plasma Physics; CAS Key Laboratory of Photovoltaic and Energy Conservation Materials
Autor responsável pela correspondência
Email: hujs@ipp.ac.cn
República Popular da China, Hefei, 230031; Hefei, 230031
Huiqiu Deng
Department of Applied Physics, School of Physics and Electronics; College of Materials Science and Engineering
Email: hujs@ipp.ac.cn
República Popular da China, Changsha, 410082; Changsha, 410082
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