Growth mechanism of subsurface hydrogen cavities in tungsten exposed to low-energy high-flux hydrogen plasma

TitleGrowth mechanism of subsurface hydrogen cavities in tungsten exposed to low-energy high-flux hydrogen plasma
Publication TypeJournal Article
Year of Publication2020
AuthorsW.Q Chen, X.Y Wang, Y.L Chiu, T.W Morgan, W.G Guo, K.L Li, Y. Yuan, B. Xu, W. Liu
JournalActa Materialia
Volume193
Pagination19-27
Date Published07/2020
Abstract

Due to a lack of direct experimental results, the detailed mechanisms that govern the blistering behavior of tungsten (W) exposed to ITER-relevant condition in nuclear fusion remain unclear. The growth mechanism of hydrogen (H) blisters is one example. In this work, recrystallized W was exposed to H plasma at 50 eV, 1.5×1026m−2, and 573 K. Transmission electron microscopy (TEM) samples were prepared using plasma-focused ion beam (FIB) followed by flash-polishing to effectively remove surface damages induced by FIB. The TEM images revealed that the general blisters observed on the exposed surface are associated with underlying cavities. A considerable amount of dislocations were found in the vicinity of the cavities. Prismatic dislocation loop arrays were observed, including small size 'coffee-bean' prismatic loops and large size prismatic loops. Near the tip of surfaces cavities, evidences for the emission of shear loops were also found. Based on the experimental findings, a multi-stage growth mechanism of H cavities was proposed. The loop-punching mechanism is operative for both very small cavities and cavities with sizes larger than several hundreds of nanometers. Whereas at intermediate sizes, cavities grow by emitting shear loops from the cavity tip.

DOI10.1016/j.actamat.2020.04.012
Division

PSI

Department

PMI

PID

b760020fa4e70c62088e3c91fe4d5f21

Alternate TitleActa Mater.

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