Enhanced crack propagation resistance after healing treatment by addition of boron in FeNi-base superalloy

The objective of the present study was to investigate whether the crack propagation resistance of boron-containing FeNi-based superalloy could be enhanced by healing treatment. The healing treatment was performed by pre-straining and subsequent heat treatment, resulting in a pronounced boron segrega...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2024-06, Vol.903, p.146664, Article 146664
Main Authors: Kim, Cham Il, Lee, Ji Yeong, Kim, Won Tae, Park, Eun Soo, Kim, Do Hyang
Format: Article
Language:English
Subjects:
Boron segregation
FeNi-Based superalloy
Healing treatment
Interface strengthening
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Summary:The objective of the present study was to investigate whether the crack propagation resistance of boron-containing FeNi-based superalloy could be enhanced by healing treatment. The healing treatment was performed by pre-straining and subsequent heat treatment, resulting in a pronounced boron segregation zone at the interface. Formation of boron segregation zone reinforced the crack propagation path, thereby effectively enhancing the mechanical properties of FeNi-based superalloy. The tested alloys were prepared by hot-rolling followed by aging treatment, resulting in precipitation of γ′-Ni3Ti and γ''-Ni3Nb embedded in the γ matrix. After pre-straining and healing heat treatment, η-Ni3Ti phase formed at the grain boundary, leading to the formation of a boron segregation zone at the interface between the η-Ni3Ti phase and γ matrix. Both strength and ductility were improved with increasing boron content from 0 at% to 0.2 at% after healing treatment. The spontaneous segregation of boron at the precipitate-matrix interface played a role in enhancing both strength and ductility by interface strengthening. Moreover, it was revealed that a critical amount of boron segregation is required for interface strengthening. Dislocation density analysis revealed that the recovery effect was weaker in alloys with boron than in those without it, leading to a more pronounced work-hardening effect. [Display omitted] •After healing treatment, the alloy with added boron exhibited improved mechanical properties.•The introduction of boron induced by stress enhances the properties of the alloy.•The behavior of boron due to the healing treatment was confirmed through APT analysis.•Using the Halder-Wagner method for dislocation density calculation, variations in recovery related to boron were observed.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2024.146664