An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys

Fenghui Duan; Qian Li; Zhihao Jiang; Lin Zhou; Junhua Luan; Zheling Shen; Weihua Zhou; Shiyuan Zhang; Jie Pan; Xin Zhou; Tao Yang; Jian Lu

doi:10.1038/s41467-024-50984-9

An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys

Fenghui Duan, Qian Li, Zhihao Jiang, Lin Zhou, Junhua Luan, Zheling Shen, Weihua Zhou, Shiyuan Zhang, Jie Pan, Xin Zhou, Tao Yang^*, Jian Lu^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

8 Citations (Scopus)

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Abstract

Nanocrystalline metallic materials have the merit of high strength but usually suffer from poor ductility and rapid grain coarsening, limiting their practical application. Here, we introduce a core-shell nanostructure in a multicomponent alloy to address these challenges simultaneously, achieving a high tensile strength of 2.65 GPa, a large uniform elongation of 17%, and a high thermal stability of 1173 K. Our strategy relies on an ordered superlattice structure that excels in dislocation accumulation, encased by a ≈3 nm disordered face-centered-cubic nanolayer acting as dislocation sources. The ordered superlattice with high anti-phase boundary energy retards dislocation motions, promoting their interaction and storage within the nanograins. The disordered interfacial nanolayer promotes dislocation emission and effectively accommodates the plastic strain at grain boundaries, preventing intergranular cracking. Consequently, the order-disorder core-shell nanostructure exhibits enhanced work-hardening capability and large ductility. Moreover, such core-shell nanostructure exhibits high coarsening resistance at elevated temperatures, enabling it high thermal stability. Such a design strategy holds promise for developing high-performance materials. © The Author(s) 2024.

Original language	English
Article number	6832
Journal	Nature Communications
Volume	15
Online published	9 Aug 2024
DOIs	https://doi.org/10.1038/s41467-024-50984-9
Publication status	Published - 2024

Funding

We sincerely acknowledge discussions with C.T. Liu (City University of Hong Kong). We also sincerely thank Yantao Sun, Fanghai Xin, and Fengkai Yan at the Liaoning Academy of Science for the technique assistance of the in-situ micro-tensile test. J. Lu gratefully acknowledges the support of the National Natural Science Foundation of China/Hong Kong Research Grants Council Joint Research Scheme (Project No: N_CityU151/23), Hong Kong General Research Fund (GRF) Scheme (CityU 11216219), and Hong Kong Innovation and Technology Commission via the Hong Kong Branch of National Precious Metals Material Engineering Research Center. This work was supported by the National Natural Science Foundation of China (Nos. 52101162). T. Yang greatly acknowledges the financial support from the National Natural Science Foundation of China (Grant No. 52222112 and 52101151) and the Hong Kong Research Grant Council (RGC) (Grant No. CityU 11208823). Q. Li acknowledges the support from the National Natural Science Foundation of China (Nos. 52101162). APT research was conducted at the Inter-University 3D APT Unit of City University of Hong Kong (CityU), which is supported by the CityU grant 9360161.

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title = "An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys",

abstract = "Nanocrystalline metallic materials have the merit of high strength but usually suffer from poor ductility and rapid grain coarsening, limiting their practical application. Here, we introduce a core-shell nanostructure in a multicomponent alloy to address these challenges simultaneously, achieving a high tensile strength of 2.65 GPa, a large uniform elongation of 17%, and a high thermal stability of 1173 K. Our strategy relies on an ordered superlattice structure that excels in dislocation accumulation, encased by a ≈3 nm disordered face-centered-cubic nanolayer acting as dislocation sources. The ordered superlattice with high anti-phase boundary energy retards dislocation motions, promoting their interaction and storage within the nanograins. The disordered interfacial nanolayer promotes dislocation emission and effectively accommodates the plastic strain at grain boundaries, preventing intergranular cracking. Consequently, the order-disorder core-shell nanostructure exhibits enhanced work-hardening capability and large ductility. Moreover, such core-shell nanostructure exhibits high coarsening resistance at elevated temperatures, enabling it high thermal stability. Such a design strategy holds promise for developing high-performance materials. {\textcopyright} The Author(s) 2024.",

author = "Fenghui Duan and Qian Li and Zhihao Jiang and Lin Zhou and Junhua Luan and Zheling Shen and Weihua Zhou and Shiyuan Zhang and Jie Pan and Xin Zhou and Tao Yang and Jian Lu",

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journal = "Nature Communications",

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T1 - An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys

AU - Duan, Fenghui

AU - Li, Qian

AU - Jiang, Zhihao

AU - Zhou, Lin

AU - Luan, Junhua

AU - Shen, Zheling

AU - Zhou, Weihua

AU - Zhang, Shiyuan

AU - Pan, Jie

AU - Zhou, Xin

AU - Yang, Tao

AU - Lu, Jian

PY - 2024

Y1 - 2024

N2 - Nanocrystalline metallic materials have the merit of high strength but usually suffer from poor ductility and rapid grain coarsening, limiting their practical application. Here, we introduce a core-shell nanostructure in a multicomponent alloy to address these challenges simultaneously, achieving a high tensile strength of 2.65 GPa, a large uniform elongation of 17%, and a high thermal stability of 1173 K. Our strategy relies on an ordered superlattice structure that excels in dislocation accumulation, encased by a ≈3 nm disordered face-centered-cubic nanolayer acting as dislocation sources. The ordered superlattice with high anti-phase boundary energy retards dislocation motions, promoting their interaction and storage within the nanograins. The disordered interfacial nanolayer promotes dislocation emission and effectively accommodates the plastic strain at grain boundaries, preventing intergranular cracking. Consequently, the order-disorder core-shell nanostructure exhibits enhanced work-hardening capability and large ductility. Moreover, such core-shell nanostructure exhibits high coarsening resistance at elevated temperatures, enabling it high thermal stability. Such a design strategy holds promise for developing high-performance materials. © The Author(s) 2024.

AB - Nanocrystalline metallic materials have the merit of high strength but usually suffer from poor ductility and rapid grain coarsening, limiting their practical application. Here, we introduce a core-shell nanostructure in a multicomponent alloy to address these challenges simultaneously, achieving a high tensile strength of 2.65 GPa, a large uniform elongation of 17%, and a high thermal stability of 1173 K. Our strategy relies on an ordered superlattice structure that excels in dislocation accumulation, encased by a ≈3 nm disordered face-centered-cubic nanolayer acting as dislocation sources. The ordered superlattice with high anti-phase boundary energy retards dislocation motions, promoting their interaction and storage within the nanograins. The disordered interfacial nanolayer promotes dislocation emission and effectively accommodates the plastic strain at grain boundaries, preventing intergranular cracking. Consequently, the order-disorder core-shell nanostructure exhibits enhanced work-hardening capability and large ductility. Moreover, such core-shell nanostructure exhibits high coarsening resistance at elevated temperatures, enabling it high thermal stability. Such a design strategy holds promise for developing high-performance materials. © The Author(s) 2024.

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An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys

Abstract

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NSFC: Bulk Complex Concentrated Alloys Based on Grain Boundary Complexion Engineering and Study of Their Toughening Mechanisms

GRF: Compositional Design and Microstructural Control of Ultrastrong-yet-ductile Chemically Complex Intermetallic Alloys for Advanced High-temperature Structural Applications

ResFac: Inter-University 3D Atom Probe Tomography Unit

Cite this

An order-disorder core-shell strategy for enhanced work-hardening capability and ductility in nanostructured alloys

Abstract

Funding

Publisher's Copyright Statement

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Projects

NSFC: Bulk Complex Concentrated Alloys Based on Grain Boundary Complexion Engineering and Study of Their Toughening Mechanisms

GRF: Compositional Design and Microstructural Control of Ultrastrong-yet-ductile Chemically Complex Intermetallic Alloys for Advanced High-temperature Structural Applications

ResFac: Inter-University 3D Atom Probe Tomography Unit

Cite this