Excellent mechanical, thermal and electrical properties of ultrafine W-Cu alloys via freeze-drying technology

In order to further refine W particles and improve properties of traditional W-Cu alloys, an innovative freeze-drying and subsequent solid phase sintering technology was employed to fabricate ultrafine W-10/20/30Cu alloys in our work. Compared with W-Cu powder precursors synthesized by traditional t...

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Bibliographic Details
Published in:Scripta materialia 2024-01, Vol.239, p.115805, Article 115805
Main Authors: Hu, Weiqiang, Li, Yanchao, Zhang, Wen, Ma, Zongqing, Feng, Yiyu, Liu, Chenxi, Li, Chong, Yu, Liming, Liu, Yongchang
Format: Article
Language:English
Subjects:
Freeze-drying
High electricity and thermal conductivity
High hardness
Solid phase sintering
Ultrafine particles
W-Cu
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Summary:In order to further refine W particles and improve properties of traditional W-Cu alloys, an innovative freeze-drying and subsequent solid phase sintering technology was employed to fabricate ultrafine W-10/20/30Cu alloys in our work. Compared with W-Cu powder precursors synthesized by traditional technologies, the freeze-dried powders (35 nm) are finer and better dispersed, which possess ultrahigh sintering activity. After solid phase sintering, the relative density of prepared W-Cu alloys is as high as above 98%. Meanwhile, the Cu network possesses complete continuity and the W particles keep ultrafine size (178 nm), which is much smaller than W particles in W-Cu literatures. Compared with other traditional technologies, freeze-dried W-Cu alloys in our work possess the highest hardness (499 HV0.2), taking into account high thermal conductivity (246.9 W/mk) and electrical conductivity (48.3% IACS), which provides a new insight for the further development of W-Cu alloy industries. [Display omitted]
ISSN:1359-6462
1872-8456
DOI:10.1016/j.scriptamat.2023.115805