Heterogeneous lattice strain strengthening in severely distorted crystalline solids

Jia Li; Yang Chen; Quanfeng He; Xiandong Xu; Hang Wang; Chao Jiang; Bin Liu; Qihong Fang; Yong Liu; Yong Yang; Peter K. Liaw; Chain T. Liu

doi:10.1073/pnas.2200607119

Heterogeneous lattice strain strengthening in severely distorted crystalline solids

Jia Li (Co-first Author), Yang Chen (Co-first Author), Quanfeng He (Co-first Author), Xiandong Xu, Hang Wang, Chao Jiang, Bin Liu, Qihong Fang^*, Yong Liu, Yong Yang^*, Peter K. Liaw, Chain T. Liu

^*Corresponding author for this work

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

114 Citations (Scopus)

98 Downloads (CityUHK Scholars)

Abstract

Multi–principal element alloys (MPEAs) exhibit outstanding mechanical properties because the core effect of severe atomic lattice distortion is distinctly different from that of traditional alloys. However, at the mesoscopic scale the underlying physics for the abundant dislocation activities responsible for strength-ductility synergy has not been uncovered. While the Eshelby mean-field approaches become insufficient to tackle yielding and plasticity in severely distorted crystalline solids, here we develop a three-dimensional discrete dislocation dynamics simulation approach by taking into account the experimentally measured lattice strain field from a model FeCoCrNiMn MPEA to explore the heterogeneous strain-induced strengthening mechanisms. Our results reveal that the heterogeneous lattice strain causes unusual dislocation behaviors (i.e., multiple kinks/jogs and bidirectional cross slips), resulting in the strengthening mechanisms that underpin the strength-ductility synergy. The outcome of our research sheds important insights into the design of strong yet ductile distorted crystalline solids, such as high-entropy alloys and high-entropy ceramics. © 2022 the Author(s). Published by PNAS.

Original language	English
Article number	e2200607119
Number of pages	7
Journal	PNAS: Proceedings of the National Academy of Sciences of the United States of America
Volume	119
Issue number	25
Online published	13 Jun 2022
DOIs	https://doi.org/10.1073/pnas.2200607119
Publication status	Published - 21 Jun 2022

Research Keywords

discrete dislocation dynamics
dislocation kink/jog
heterogeneous lattice strain
Multi–principal element alloys
strengthening mechanism

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This full text is made available under CC-BY-NC-ND 4.0. https://creativecommons.org/licenses/by-nc-nd/4.0/

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title = "Heterogeneous lattice strain strengthening in severely distorted crystalline solids",

abstract = "Multi–principal element alloys (MPEAs) exhibit outstanding mechanical properties because the core effect of severe atomic lattice distortion is distinctly different from that of traditional alloys. However, at the mesoscopic scale the underlying physics for the abundant dislocation activities responsible for strength-ductility synergy has not been uncovered. While the Eshelby mean-field approaches become insufficient to tackle yielding and plasticity in severely distorted crystalline solids, here we develop a three-dimensional discrete dislocation dynamics simulation approach by taking into account the experimentally measured lattice strain field from a model FeCoCrNiMn MPEA to explore the heterogeneous strain-induced strengthening mechanisms. Our results reveal that the heterogeneous lattice strain causes unusual dislocation behaviors (i.e., multiple kinks/jogs and bidirectional cross slips), resulting in the strengthening mechanisms that underpin the strength-ductility synergy. The outcome of our research sheds important insights into the design of strong yet ductile distorted crystalline solids, such as high-entropy alloys and high-entropy ceramics. {\textcopyright} 2022 the Author(s). Published by PNAS. ",

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author = "Jia Li and Yang Chen and Quanfeng He and Xiandong Xu and Hang Wang and Chao Jiang and Bin Liu and Qihong Fang and Yong Liu and Yong Yang and Liaw, {Peter K.} and Liu, {Chain T.}",

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Heterogeneous lattice strain strengthening in severely distorted crystalline solids. / Li, Jia (Co-first Author); Chen, Yang (Co-first Author); He, Quanfeng (Co-first Author) et al.
In: PNAS: Proceedings of the National Academy of Sciences of the United States of America, Vol. 119, No. 25, e2200607119, 21.06.2022.

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

TY - JOUR

T1 - Heterogeneous lattice strain strengthening in severely distorted crystalline solids

AU - Li, Jia

AU - Chen, Yang

AU - He, Quanfeng

AU - Xu, Xiandong

AU - Wang, Hang

AU - Jiang, Chao

AU - Liu, Bin

AU - Fang, Qihong

AU - Liu, Yong

AU - Yang, Yong

AU - Liaw, Peter K.

AU - Liu, Chain T.

PY - 2022/6/21

Y1 - 2022/6/21

N2 - Multi–principal element alloys (MPEAs) exhibit outstanding mechanical properties because the core effect of severe atomic lattice distortion is distinctly different from that of traditional alloys. However, at the mesoscopic scale the underlying physics for the abundant dislocation activities responsible for strength-ductility synergy has not been uncovered. While the Eshelby mean-field approaches become insufficient to tackle yielding and plasticity in severely distorted crystalline solids, here we develop a three-dimensional discrete dislocation dynamics simulation approach by taking into account the experimentally measured lattice strain field from a model FeCoCrNiMn MPEA to explore the heterogeneous strain-induced strengthening mechanisms. Our results reveal that the heterogeneous lattice strain causes unusual dislocation behaviors (i.e., multiple kinks/jogs and bidirectional cross slips), resulting in the strengthening mechanisms that underpin the strength-ductility synergy. The outcome of our research sheds important insights into the design of strong yet ductile distorted crystalline solids, such as high-entropy alloys and high-entropy ceramics. © 2022 the Author(s). Published by PNAS.

AB - Multi–principal element alloys (MPEAs) exhibit outstanding mechanical properties because the core effect of severe atomic lattice distortion is distinctly different from that of traditional alloys. However, at the mesoscopic scale the underlying physics for the abundant dislocation activities responsible for strength-ductility synergy has not been uncovered. While the Eshelby mean-field approaches become insufficient to tackle yielding and plasticity in severely distorted crystalline solids, here we develop a three-dimensional discrete dislocation dynamics simulation approach by taking into account the experimentally measured lattice strain field from a model FeCoCrNiMn MPEA to explore the heterogeneous strain-induced strengthening mechanisms. Our results reveal that the heterogeneous lattice strain causes unusual dislocation behaviors (i.e., multiple kinks/jogs and bidirectional cross slips), resulting in the strengthening mechanisms that underpin the strength-ductility synergy. The outcome of our research sheds important insights into the design of strong yet ductile distorted crystalline solids, such as high-entropy alloys and high-entropy ceramics. © 2022 the Author(s). Published by PNAS.

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Heterogeneous lattice strain strengthening in severely distorted crystalline solids

Abstract

Research Keywords

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GRF: Development of Strong-yet-Ductile Nanograined Alloys with Intergranular Amorphous Films Based on Metallic-Glass Templates

GRF: The Development of Dual-Phase Fe-Based Metallic Glasses and Composites with Optimized Mechanical and Magnetic Properties

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Heterogeneous lattice strain strengthening in severely distorted crystalline solids

Abstract

Research Keywords

Publisher's Copyright Statement

Access Output

Other Access Options

Permanent Link

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GRF: Development of Strong-yet-Ductile Nanograined Alloys with Intergranular Amorphous Films Based on Metallic-Glass Templates

GRF: The Development of Dual-Phase Fe-Based Metallic Glasses and Composites with Optimized Mechanical and Magnetic Properties

Cite this