Formation of core–shell structure in immiscible CoCrCuFe1.5Ni0.5 high-entropy alloy

Kaixi Lin; Chen Wei; Yixuan He; Chao Li; Pingxiang Zhang; Jinshan Li; Jun Wang

doi:10.1016/j.matlet.2022.132452

Formation of core–shell structure in immiscible CoCrCuFe_1.5Ni_0.5 high-entropy alloy

Kaixi Lin, Chen Wei, Yixuan He, Chao Li, Pingxiang Zhang, Jinshan Li, Jun Wang

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

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

4 Scopus citations

Abstract

The microstructure evolution and properties of CoCrCuFe_1.5Ni_0.5 high-entropy alloy solidified at different undercoolings (ΔT) have been investigated by using cyclic superheating technique. Results show that this alloy exhibits typical liquid phase separation (LPS) behavior and the core–shell structure can be attained at tiny undercooling, e.g., ΔT = 43 K. Ulteriorly, the large variation distribution of Cu-rich phase in core area certified second LPS has taken place when undercooling is above 140 K. The hardness of alloy in Cu-lean core phase increases greatly from 165 HV to 219 HV owing to the refined grain with the increasing undercooling. The results provide a method to regulate the morphologic structures and mechanical properties of the immiscible CoCrCuFe_1.5Ni_0.5 HEA.

Original language	English
Article number	132452
Journal	Materials Letters
Volume	321
DOIs	https://doi.org/10.1016/j.matlet.2022.132452
State	Published - 15 Aug 2022

Keywords

Core-shell structure
High-entropy alloy
Metallurgy
Microstructure
Solidification

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10.1016/j.matlet.2022.132452

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title = "Formation of core–shell structure in immiscible CoCrCuFe1.5Ni0.5 high-entropy alloy",

abstract = "The microstructure evolution and properties of CoCrCuFe1.5Ni0.5 high-entropy alloy solidified at different undercoolings (ΔT) have been investigated by using cyclic superheating technique. Results show that this alloy exhibits typical liquid phase separation (LPS) behavior and the core–shell structure can be attained at tiny undercooling, e.g., ΔT = 43 K. Ulteriorly, the large variation distribution of Cu-rich phase in core area certified second LPS has taken place when undercooling is above 140 K. The hardness of alloy in Cu-lean core phase increases greatly from 165 HV to 219 HV owing to the refined grain with the increasing undercooling. The results provide a method to regulate the morphologic structures and mechanical properties of the immiscible CoCrCuFe1.5Ni0.5 HEA.",

keywords = "Core-shell structure, High-entropy alloy, Metallurgy, Microstructure, Solidification",

author = "Kaixi Lin and Chen Wei and Yixuan He and Chao Li and Pingxiang Zhang and Jinshan Li and Jun Wang",

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year = "2022",

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doi = "10.1016/j.matlet.2022.132452",

language = "英语",

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T1 - Formation of core–shell structure in immiscible CoCrCuFe1.5Ni0.5 high-entropy alloy

AU - Lin, Kaixi

AU - Wei, Chen

AU - He, Yixuan

AU - Li, Chao

AU - Zhang, Pingxiang

AU - Li, Jinshan

AU - Wang, Jun

PY - 2022/8/15

Y1 - 2022/8/15

N2 - The microstructure evolution and properties of CoCrCuFe1.5Ni0.5 high-entropy alloy solidified at different undercoolings (ΔT) have been investigated by using cyclic superheating technique. Results show that this alloy exhibits typical liquid phase separation (LPS) behavior and the core–shell structure can be attained at tiny undercooling, e.g., ΔT = 43 K. Ulteriorly, the large variation distribution of Cu-rich phase in core area certified second LPS has taken place when undercooling is above 140 K. The hardness of alloy in Cu-lean core phase increases greatly from 165 HV to 219 HV owing to the refined grain with the increasing undercooling. The results provide a method to regulate the morphologic structures and mechanical properties of the immiscible CoCrCuFe1.5Ni0.5 HEA.

AB - The microstructure evolution and properties of CoCrCuFe1.5Ni0.5 high-entropy alloy solidified at different undercoolings (ΔT) have been investigated by using cyclic superheating technique. Results show that this alloy exhibits typical liquid phase separation (LPS) behavior and the core–shell structure can be attained at tiny undercooling, e.g., ΔT = 43 K. Ulteriorly, the large variation distribution of Cu-rich phase in core area certified second LPS has taken place when undercooling is above 140 K. The hardness of alloy in Cu-lean core phase increases greatly from 165 HV to 219 HV owing to the refined grain with the increasing undercooling. The results provide a method to regulate the morphologic structures and mechanical properties of the immiscible CoCrCuFe1.5Ni0.5 HEA.

KW - Core-shell structure

KW - High-entropy alloy

KW - Metallurgy

KW - Microstructure

KW - Solidification

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U2 - 10.1016/j.matlet.2022.132452

DO - 10.1016/j.matlet.2022.132452

M3 - 文章

AN - SCOPUS:85130410514

SN - 0167-577X

VL - 321

JO - Materials Letters

JF - Materials Letters

M1 - 132452

ER -

Formation of core–shell structure in immiscible CoCrCuFe_1.5Ni_0.5 high-entropy alloy

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Keywords

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