Laser repair of tungsten damaged by fusion-relevant plasmas

Li，Yu1,2; Guo，Chuan1,2,3; Sun，Yuhan4; Cheng，Long4; Peng，Jia Guan4; Yuan，Yue4; Lu，Guang Hong4; Zhu，Qiang1,2

2023-07-01

10.1016/j.jnucmat.2023.154426

Journal of Nuclear Materials   影响因子和分区

0022-3115

1873-4820

As a hotspot, the ITER tungsten divertor receives both extreme plasmas and considerable research attention. The projection is that certain plasma-induced defects in tungsten are inevitable under the scheduled ITER operation. Although the exact consequences of such defects on the divertor lifetime are unclear currently, approaches to combat them are desirable but remain limited. Here, we develop the idea of healing such defects through laser remelting. With a suitable combination of processing parameters—such as laser power, scan speed, and preheating temperature—the remelted (pristine) tungsten surface was nearly crack-free. Revealed by electron backscatter diffraction (EBSD) analysis, the remelted microstructure resembled that of fully recrystallized tungsten. Furthermore, the linear relationship between the normalized melt pool depth and the normalized enthalpy of the surface was established, the former of which indicates the healing depth. Lastly, proof-of-principle experiments were performed on damaged tungsten specimens containing respectively blisters, nanostructure fuzz, and fatigue cracks, yielding promising healing effects. Based on additional considerations of the plasma exposure behavior of laser remelted tungsten and deployment of the laser repair system, we conclude that the laser repair approach is compatible with the ITER operation plan.

Blister Fatigue cracking Laser repair Nanostructure fuzz Tungsten

SCI ; EI

英语

第一 ; 通讯

National Key Re-search and Development Program of China[2021YFF0700900] ; China Postdoc-toral Science Foundation[2022M711468] ; GuangDong Ba-sic and Applied Basic Research Foundation[2022A1515110023] ; Shenzhen Science and Technology Innovation Commission["JCYJ20210324104610029","KQTD20170328154443162","JCYJ20220818100613028"]

Materials Science ; Nuclear Science & Technology

Materials Science, Multidisciplinary ; Nuclear Science & Technology

WOS:000981406400001

ELSEVIER

20231513864253

Fatigue crack propagation ; Laser heating ; Repair ; Tungsten

Tungsten and Alloys:543.5 ; Laser Applications:744.9 ; Nanotechnology:761 ; Maintenance:913.5 ; Solid State Physics:933

ENGINEERING

2-s2.0-85151661492

Scopus

1.Department of Mechanical and Energy Engineering,Southern University of Science and Technology,Shenzhen,518055,China
2.Shenzhen Key Laboratory for Additive Manufacturing of High-Performance Materials,Shenzhen,518055,China
3.CityU-Shenzhen Futian Research Institute,Shenzhen,518045,China
4.School of Physics,Beihang University,Beijing,100191,China

Li，Yu,Guo，Chuan,Sun，Yuhan,et al. Laser repair of tungsten damaged by fusion-relevant plasmas[J]. Journal of Nuclear Materials,2023,580.

Li，Yu.,Guo，Chuan.,Sun，Yuhan.,Cheng，Long.,Peng，Jia Guan.,...&Zhu，Qiang.(2023).Laser repair of tungsten damaged by fusion-relevant plasmas.Journal of Nuclear Materials,580.

Li，Yu,et al."Laser repair of tungsten damaged by fusion-relevant plasmas".Journal of Nuclear Materials 580(2023).