Significant lattice-distortion effect on compressive deformation in Mo-added CoCrFeNi-based high-entropy alloys

Large lattice distortion is an essential feature of high-entropy alloys (HEAs). Herein, the deformation behaviors of three types of as-cast CoCrFeNi-based HEAs, which contained 0, 7.9, and 17.1 wt% Mo, were comparatively studied through compressive tests and microstructural observations. The intrins...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 830; p. 142295
Main Authors Li, Jiaxiang, Yamanaka, Kenta, Chiba, Akihiko
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 07.01.2022
Elsevier BV
Subjects
Back-stress hardening
Deformation effects
Deformation twinning
Dislocation mobility
Distortion
Domain rotation
Domains
Edge dislocations
Hardening rate
High entropy alloys
High-entropy alloy
Incompatibility
Lattice-distortion effect
Microstructure
Simple shear
Strain hardening
Stress concentration
Deformation twinning
Simple shear
Lattice-distortion effect
Domain rotation
High-entropy alloy
Back-stress hardening
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Abstract Large lattice distortion is an essential feature of high-entropy alloys (HEAs). Herein, the deformation behaviors of three types of as-cast CoCrFeNi-based HEAs, which contained 0, 7.9, and 17.1 wt% Mo, were comparatively studied through compressive tests and microstructural observations. The intrinsic lattice distortion increased mainly as a function of the Mo content. By virtue of both the local strain incompatibility inside the coarse columnar grains of the as-cast microstructures and low dislocation mobility in HEAs, domain rotations were induced at low strains. Meanwhile, simple shear occurred between domains and produced a new boundary network in the microstructure. The large lattice distortion of the high-Mo HEA (17.1 wt%) gave rise to intense planar slip bands, on which a large number of dislocations slipped and impinged on strain-induced boundaries. As a result of the high back-stress hardening, the high-Mo HEA exhibited enhanced strain-hardening. At high strains, the stress concentration events increased as the lattice distortion of the HEAs increased; this promoted twin growth in the high-Mo HEA. The high-Mo HEA was highlighted with a high strain-hardening rate over a wide strain range. In this study, high-strength as-cast HEAs were developed based on the utilization of the lattice-distortion effect.
AbstractList Large lattice distortion is an essential feature of high-entropy alloys (HEAs). Herein, the deformation behaviors of three types of as-cast CoCrFeNi-based HEAs, which contained 0, 7.9, and 17.1 wt% Mo, were comparatively studied through compressive tests and microstructural observations. The intrinsic lattice distortion increased mainly as a function of the Mo content. By virtue of both the local strain incompatibility inside the coarse columnar grains of the as-cast microstructures and low dislocation mobility in HEAs, domain rotations were induced at low strains. Meanwhile, simple shear occurred between domains and produced a new boundary network in the microstructure. The large lattice distortion of the high-Mo HEA (17.1 wt%) gave rise to intense planar slip bands, on which a large number of dislocations slipped and impinged on strain-induced boundaries. As a result of the high back-stress hardening, the high-Mo HEA exhibited enhanced strain-hardening. At high strains, the stress concentration events increased as the lattice distortion of the HEAs increased; this promoted twin growth in the high-Mo HEA. The high-Mo HEA was highlighted with a high strain-hardening rate over a wide strain range. In this study, high-strength as-cast HEAs were developed based on the utilization of the lattice-distortion effect.
Large lattice distortion is an essential feature of high-entropy alloys (HEAs). Herein, the deformation behaviors of three types of as-cast CoCrFeNi-based HEAs, which contained 0, 7.9, and 17.1 wt% Mo, were comparatively studied through compressive tests and microstructural observations. The intrinsic lattice distortion increased mainly as a function of the Mo content. By virtue of both the local strain incompatibility inside the coarse columnar grains of the as-cast microstructures and low dislocation mobility in HEAs, domain rotations were induced at low strains. Meanwhile, simple shear occurred between domains and produced a new boundary network in the microstructure. The large lattice distortion of the high-Mo HEA (17.1 wt%) gave rise to intense planar slip bands, on which a large number of dislocations slipped and impinged on strain-induced boundaries. As a result of the high back-stress hardening, the high-Mo HEA exhibited enhanced strain-hardening. At high strains, the stress concentration events increased as the lattice distortion of the HEAs increased; this promoted twin growth in the high-Mo HEA. The high-Mo HEA was highlighted with a high strain-hardening rate over a wide strain range. In this study, high-strength as-cast HEAs were developed based on the utilization of the lattice-distortion effect.
ArticleNumber 142295
Author Yamanaka, Kenta
Chiba, Akihiko
Li, Jiaxiang
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  surname: Chiba
  fullname: Chiba, Akihiko
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Keywords Deformation twinning
Simple shear
Lattice-distortion effect
Domain rotation
High-entropy alloy
Back-stress hardening
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Snippet Large lattice distortion is an essential feature of high-entropy alloys (HEAs). Herein, the deformation behaviors of three types of as-cast CoCrFeNi-based...
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SubjectTerms Back-stress hardening
Deformation effects
Deformation twinning
Dislocation mobility
Distortion
Domain rotation
Domains
Edge dislocations
Hardening rate
High entropy alloys
High-entropy alloy
Incompatibility
Lattice-distortion effect
Microstructure
Simple shear
Strain hardening
Stress concentration
Title Significant lattice-distortion effect on compressive deformation in Mo-added CoCrFeNi-based high-entropy alloys
URI https://dx.doi.org/10.1016/j.msea.2021.142295
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