Development of tungsten as plasma-facing materials by doping tantalum carbide nanoparticles

Tungsten and its alloys are primary plasma-facing materials in fusion reactors. In this study, pure W and W/TaC alloys and their powders were developed via a powder metallurgical method and a novel wet chemical process, respectively. W alloys with 1, 2, and 4wt.% TaC were sintered via spark plasma s...

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Bibliographic Details
Published in:Powder technology 2015-01, Vol.269, p.437-442
Main Authors: Tan, Xiao-Yue, Luo, Lai-Ma, Lu, Ze-Long, Luo, Guang-Nan, Zan, Xiang, Cheng, Ji-Gui, Wu, Yu-Cheng
Format: Article
Language:English
Subjects:
Spark plasma sintering
Thermal conductivity
W/TaC alloys
Wet chemical process
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Summary:Tungsten and its alloys are primary plasma-facing materials in fusion reactors. In this study, pure W and W/TaC alloys and their powders were developed via a powder metallurgical method and a novel wet chemical process, respectively. W alloys with 1, 2, and 4wt.% TaC were sintered via spark plasma sintering at 1800°C for 1min. The sintered samples were characterized using field-emission scanning electron and transmission electron microscopes. TaC particles were found in grain boundaries, which could be crack sources. TaC particles were also found in grain interiors, which changed the crack propagation path, thereby improving material toughness. The microhardness and thermal conductivity of the pure and doped W materials were investigated. The particle microhardnesss increased with the increase in TaC content. The W–1wt.% TaC alloy exhibited the highest thermal conductivity (up to 183.8W/mK). [Display omitted] •W/TaC composite powders were fabricated via a novel wet chemical process.•TaC nanoparticles exist in the grain interior and at the grain boundary.•The W–1wt.% TaC alloy exhibited the highest thermal conductivity (up to 183.8W/mK).
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2014.09.039