Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications

Min Ji Jang; Hyunjeong Kwak; Ye Won Lee; Youjin Jeong; Jahong Choi; Yong Hee Jo; Won Mi Choi; Hyun Je Sung; Eun Yoo Yoon; S. Praveen; Sunghak Lee; Byeong Joo Lee; Mohamed Ibrahim Abd El Aal; Hyoung Seop Kim

doi:10.1007/s12540-018-0184-6

Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications

Min Ji Jang, Hyunjeong Kwak, Ye Won Lee, Youjin Jeong, Jahong Choi, Yong Hee Jo, Won Mi Choi, Hyun Je Sung, Eun Yoo Yoon, S. Praveen, Sunghak Lee, Byeong Joo Lee, Mohamed Ibrahim Abd El Aal, Hyoung Seop Kim

Mechanical Engineering

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

57 Scopus citations

Abstract

A single FCC phase 40Fe–25Ni–15Cr–10Co–10V high-entropy alloy was designed, fabricated, and evaluated for potential cryogenic applications. The alloy forms a single FCC phase and exhibits higher yield strength, tensile strength, and elongation at cryogenic temperature (77 K) than at room temperature (298 K). The superior tensile properties at cryogenic temperature are discussed based on the formation of deformation twins during the tensile test at cryogenic temperature. In addition, a constitutive model reflecting the cryogenic deformation mechanism (i.e., twinning-induced plasticity) was implemented into the finite element method to analyze this behavior. Experimental results and the finite element analysis suggest that the increase in plastic deformation capacity at cryogenic temperature contributes to the formation of deformation twins.

Original language	English
Pages (from-to)	277-284
Number of pages	8
Journal	Metals and Materials International
Volume	25
Issue number	2
DOIs	https://doi.org/10.1007/s12540-018-0184-6
State	Published - 8 Mar 2019

Keywords

Cryogenic deformation
Deformation twinning
Finite element analysis
High-entropy alloy
Plastic deformation behavior

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10.1007/s12540-018-0184-6

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Jang, M. J., Kwak, H., Lee, Y. W., Jeong, Y., Choi, J., Jo, Y. H., Choi, W. M., Sung, H. J., Yoon, E. Y., Praveen, S., Lee, S., Lee, B. J., Abd El Aal, M. I., & Kim, H. S. (2019). Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications. Metals and Materials International, 25(2), 277-284. https://doi.org/10.1007/s12540-018-0184-6

@article{969fc72800a5407a9d770addfd4840c5,

title = "Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications",

abstract = "A single FCC phase 40Fe–25Ni–15Cr–10Co–10V high-entropy alloy was designed, fabricated, and evaluated for potential cryogenic applications. The alloy forms a single FCC phase and exhibits higher yield strength, tensile strength, and elongation at cryogenic temperature (77 K) than at room temperature (298 K). The superior tensile properties at cryogenic temperature are discussed based on the formation of deformation twins during the tensile test at cryogenic temperature. In addition, a constitutive model reflecting the cryogenic deformation mechanism (i.e., twinning-induced plasticity) was implemented into the finite element method to analyze this behavior. Experimental results and the finite element analysis suggest that the increase in plastic deformation capacity at cryogenic temperature contributes to the formation of deformation twins.",

keywords = "Cryogenic deformation, Deformation twinning, Finite element analysis, High-entropy alloy, Plastic deformation behavior",

author = "Jang, \{Min Ji\} and Hyunjeong Kwak and Lee, \{Ye Won\} and Youjin Jeong and Jahong Choi and Jo, \{Yong Hee\} and Choi, \{Won Mi\} and Sung, \{Hyun Je\} and Yoon, \{Eun Yoo\} and S. Praveen and Sunghak Lee and Lee, \{Byeong Joo\} and \{Abd El Aal\}, \{Mohamed Ibrahim\} and Kim, \{Hyoung Seop\}",

note = "Publisher Copyright: {\textcopyright} 2018, The Korean Institute of Metals and Materials.",

year = "2019",

month = mar,

day = "8",

doi = "10.1007/s12540-018-0184-6",

language = "English",

volume = "25",

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journal = "Metals and Materials International",

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T1 - Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications

AU - Jang, Min Ji

AU - Kwak, Hyunjeong

AU - Lee, Ye Won

AU - Jeong, Youjin

AU - Choi, Jahong

AU - Jo, Yong Hee

AU - Choi, Won Mi

AU - Sung, Hyun Je

AU - Yoon, Eun Yoo

AU - Praveen, S.

AU - Lee, Sunghak

AU - Lee, Byeong Joo

AU - Abd El Aal, Mohamed Ibrahim

AU - Kim, Hyoung Seop

PY - 2019/3/8

Y1 - 2019/3/8

N2 - A single FCC phase 40Fe–25Ni–15Cr–10Co–10V high-entropy alloy was designed, fabricated, and evaluated for potential cryogenic applications. The alloy forms a single FCC phase and exhibits higher yield strength, tensile strength, and elongation at cryogenic temperature (77 K) than at room temperature (298 K). The superior tensile properties at cryogenic temperature are discussed based on the formation of deformation twins during the tensile test at cryogenic temperature. In addition, a constitutive model reflecting the cryogenic deformation mechanism (i.e., twinning-induced plasticity) was implemented into the finite element method to analyze this behavior. Experimental results and the finite element analysis suggest that the increase in plastic deformation capacity at cryogenic temperature contributes to the formation of deformation twins.

AB - A single FCC phase 40Fe–25Ni–15Cr–10Co–10V high-entropy alloy was designed, fabricated, and evaluated for potential cryogenic applications. The alloy forms a single FCC phase and exhibits higher yield strength, tensile strength, and elongation at cryogenic temperature (77 K) than at room temperature (298 K). The superior tensile properties at cryogenic temperature are discussed based on the formation of deformation twins during the tensile test at cryogenic temperature. In addition, a constitutive model reflecting the cryogenic deformation mechanism (i.e., twinning-induced plasticity) was implemented into the finite element method to analyze this behavior. Experimental results and the finite element analysis suggest that the increase in plastic deformation capacity at cryogenic temperature contributes to the formation of deformation twins.

KW - Cryogenic deformation

KW - Deformation twinning

KW - Finite element analysis

KW - High-entropy alloy

KW - Plastic deformation behavior

UR - https://www.scopus.com/pages/publications/85052843917

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DO - 10.1007/s12540-018-0184-6

M3 - Article

AN - SCOPUS:85052843917

SN - 1598-9623

VL - 25

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EP - 284

JO - Metals and Materials International

JF - Metals and Materials International

IS - 2

ER -

Plastic Deformation Behavior of 40Fe–25Ni–15Cr–10Co–10V High-Entropy Alloy for Cryogenic Applications

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