Superb cryogenic strength of equiatomic CrCoNi derived from gradient hierarchical microstructure

Bin Gan; Jeffrey M. Wheeler; Zhongnan Bi; Lin Liu; Jun Zhang; Hengzhi Fu

doi:10.1016/j.jmst.2018.12.002

Superb cryogenic strength of equiatomic CrCoNi derived from gradient hierarchical microstructure

Bin Gan, Jeffrey M. Wheeler, Zhongnan Bi, Lin Liu, Jun Zhang, Hengzhi Fu

School of Materials Sience and Engineering

Research output: Contribution to journal › Article › peer-review

48 Scopus citations

Abstract

This work demonstrates the effectiveness of a cryogenic torsional pre-straining for significantly improving the cryogenic strength of an equiatomic CrCoNi alloy. The origin of this phenomenon is elucidated by various microstructural characterization tools, which shows that the sequential torsion and tension tests lead to the observed hierarchical microstructure through the activation of different twinning systems and stacking faults. This gives rise to the significant increase in the yield strength from 600 MPa to 1215 MPa, while the fracture strain changes from 68% to 48%. The current study reveals that the incorporation of nanotwins architecture by shear deformation may constitute a viable strategy to tune the mechanical performance and, in particular, to dramatically increase the strength while keeping a good ductility.

Original language	English
Pages (from-to)	957-961
Number of pages	5
Journal	Journal of Materials Science and Technology
Volume	35
Issue number	6
DOIs	https://doi.org/10.1016/j.jmst.2018.12.002
State	Published - Jun 2019

Keywords

CrCoNi
Hierarchical microstructure
Medium entropy alloy
Strengthening
Torsion

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10.1016/j.jmst.2018.12.002

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title = "Superb cryogenic strength of equiatomic CrCoNi derived from gradient hierarchical microstructure",

abstract = "This work demonstrates the effectiveness of a cryogenic torsional pre-straining for significantly improving the cryogenic strength of an equiatomic CrCoNi alloy. The origin of this phenomenon is elucidated by various microstructural characterization tools, which shows that the sequential torsion and tension tests lead to the observed hierarchical microstructure through the activation of different twinning systems and stacking faults. This gives rise to the significant increase in the yield strength from 600 MPa to 1215 MPa, while the fracture strain changes from 68% to 48%. The current study reveals that the incorporation of nanotwins architecture by shear deformation may constitute a viable strategy to tune the mechanical performance and, in particular, to dramatically increase the strength while keeping a good ductility.",

keywords = "CrCoNi, Hierarchical microstructure, Medium entropy alloy, Strengthening, Torsion",

author = "Bin Gan and Wheeler, {Jeffrey M.} and Zhongnan Bi and Lin Liu and Jun Zhang and Hengzhi Fu",

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T1 - Superb cryogenic strength of equiatomic CrCoNi derived from gradient hierarchical microstructure

AU - Gan, Bin

AU - Wheeler, Jeffrey M.

AU - Bi, Zhongnan

AU - Liu, Lin

AU - Zhang, Jun

AU - Fu, Hengzhi

PY - 2019/6

Y1 - 2019/6

N2 - This work demonstrates the effectiveness of a cryogenic torsional pre-straining for significantly improving the cryogenic strength of an equiatomic CrCoNi alloy. The origin of this phenomenon is elucidated by various microstructural characterization tools, which shows that the sequential torsion and tension tests lead to the observed hierarchical microstructure through the activation of different twinning systems and stacking faults. This gives rise to the significant increase in the yield strength from 600 MPa to 1215 MPa, while the fracture strain changes from 68% to 48%. The current study reveals that the incorporation of nanotwins architecture by shear deformation may constitute a viable strategy to tune the mechanical performance and, in particular, to dramatically increase the strength while keeping a good ductility.

AB - This work demonstrates the effectiveness of a cryogenic torsional pre-straining for significantly improving the cryogenic strength of an equiatomic CrCoNi alloy. The origin of this phenomenon is elucidated by various microstructural characterization tools, which shows that the sequential torsion and tension tests lead to the observed hierarchical microstructure through the activation of different twinning systems and stacking faults. This gives rise to the significant increase in the yield strength from 600 MPa to 1215 MPa, while the fracture strain changes from 68% to 48%. The current study reveals that the incorporation of nanotwins architecture by shear deformation may constitute a viable strategy to tune the mechanical performance and, in particular, to dramatically increase the strength while keeping a good ductility.

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KW - Hierarchical microstructure

KW - Medium entropy alloy

KW - Strengthening

KW - Torsion

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M3 - 文章

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JO - Journal of Materials Science and Technology

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Superb cryogenic strength of equiatomic CrCoNi derived from gradient hierarchical microstructure

Abstract

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