Interfacial coherence regulation and stabilization of molybdenum/Kovar alloy welded joint by CoCrCuFeNi high entropy alloy

•The real underlying reason for strength deterioration of Mo/Kovar alloy welded joint is revealed.•Coherence regulation and stabilization are achieved for phase interface via high entropy alloy.•σ(FeCr) nanoparticle precipitates at α-Mo/fcc interface to stabilize phase interface.•The tensile strengt...

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Bibliographic Details
Published in:Journal of materials science & technology 2024-09, Vol.194, p.43-50
Main Authors: Yin, Qianxing, Chen, Guoqing, Teng, Xinyan, Xiang, Yang, Leng, Xuesong
Format: Article
Language:English
Subjects:
Electron beam welding
High entropy alloy
Interfacial stabilization
Molybdenum
Nano-scale particle
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Summary:•The real underlying reason for strength deterioration of Mo/Kovar alloy welded joint is revealed.•Coherence regulation and stabilization are achieved for phase interface via high entropy alloy.•σ(FeCr) nanoparticle precipitates at α-Mo/fcc interface to stabilize phase interface.•The tensile strength of joint is increased from 262 MPa to 366 MPa after adding high entropy alloy. The crux of molybdenum/Fe-base alloy welded joint is embrittlement and consequently deteriorated strength. The current researches just attribute it to brittle intermetallic compound inside the weld. However, no brittle phase continuously precipitates at the fracture location of the molybdenum/Kovar alloy electron beam welded joint, meaning that the unstable phase interface is the real fundamental reason for the brittleness of joint, instead of the phases themselves. Noncoherent interfaces are formed between α-Mo and eutectoid α-Fe + μ(Fe3Mo2) deriving from solid-state phase transition. To optimize interfacial coherence and stabilize the interface, CoCrCuFeNi high entropy alloy is added into the weld. The new interfaces between α-Mo and eutectic face-centered cubic (fcc) + laves are transformed into coherent interfaces. σ(FeCr) nanoparticles precipitate at α-Mo/fcc interface, indicating the decreased interfacial energy and more stable interface. The tensile strength of the joint is increased from 262 to 366 MPa. The present work provides guidance for optimizing welding quality between molybdenum and Fe-base alloy. [Display omitted]
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2024.02.001