Effects of NiAl precipitate microstructure, loading axis and temperature on deformation behavior of Fe–Al–Ni single crystals

Effects of NiAl precipitate microstructure, loading axis and temperature on deformation behavior of Fe–Al–Ni single crystals

Effects of size and volume fraction of the B2-type NiAl precipitates on the deformation behavior of Fe–Al–Ni single crystals were investigated. In the crystals with different Ni contents, the fine NiAl phase was precipitated in the bcc matrix with small misfit strain. Strong precipitation hardening...

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Bibliographic Details
Published in:Intermetallics Vol. 115; p. 106627
Main Authors: Yasuda, Hiroyuki Y., Edahiro, Taisuke, Takeoka, Naoki, Yoshimoto, Takashi, Mizuno, Masataka, Cho, Ken
Format: Journal Article
Language:English
Published: Barking Elsevier Ltd 01-12-2019
Elsevier BV
Subjects:
Age-hardening
Aluminum
Antiphase boundaries
Deformation effects
Dislocation geometry and arrangement
Dislocation structure
First principles
Intermetallic compounds
Intermetallics (aluminides)
Iron
Mechanical properties, theory
Morphology
Nickel aluminides
Nickel base alloys
Nickel compounds
Precipitates
Precipitation hardening
Shear stress
Single crystals
Slip
Slip system
Temperature dependence
Yield stress
Dislocation structure
Slip system
Mechanical properties, theory
Age-hardening
Intermetallics (aluminides)
Dislocation geometry and arrangement
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Summary:Effects of size and volume fraction of the B2-type NiAl precipitates on the deformation behavior of Fe–Al–Ni single crystals were investigated. In the crystals with different Ni contents, the fine NiAl phase was precipitated in the bcc matrix with small misfit strain. Strong precipitation hardening occurred due to the difference in primary slip system between the bcc matrix and the NiAl precipitates. Moreover, not only slip but also slip occurred depending on the loading axis, the precipitate morphology and the deformation temperature, though the occurrence of slip is generally impossible in bcc metals. The dependence of the critical resolved shear stress for slip on the precipitate size was consistent with the modified precipitation hardening theory. To understand the precipitation hardening, an antiphase boundary energy of the NiAl precipitates was evaluated by first-principles calculations. Moreover, higher volume fraction of the NiAl precipitates was favorable for the activation of slip. Furthermore, the activated slip system varied with deformation temperature, and therefore, the temperature dependence of the yield stress was closely related to the slip system. •The size and volume fraction of the NiAl precipitates influence the strength.•CRSS for slip is closely related to the APB energy of the precipitates.•APB energy of NiAl with Fe was calculated to understand the hardening mechanism.•Higher volume fraction of the NiAl precipitates is favorable for slip.•The activate slip system depends on the loading axis and deformation temperature.
ISSN:0966-9795
1879-0216
DOI:10.1016/j.intermet.2019.106627