Decoupling between Shockley partials and stacking faults strengthens multiprincipal element alloys

Zongrui Pei; Siyuan Zhang; Yinkai Lei; Fan Zhang; Mingwei Chen

doi:10.1073/pnas.2114167118

Decoupling between Shockley partials and stacking faults strengthens multiprincipal element alloys

Zongrui Pei^*, Siyuan Zhang, Yinkai Lei, Fan Zhang, Mingwei Chen

^*Corresponding author for this work

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

17 Citations (Scopus)

Abstract

Mechanical properties are fundamental to structural materials, where dislocations play a decisive role in describing their mechanical behavior. Although the high-yield stresses ofmultiprincipal element alloys (MPEAs) have received extensive attention in the last decade, the relation between their mechanistic origins remains elusive. Our multiscale study of density functional theory, atomistic simulations, and high-resolution microscopy shows that the excellent mechanical properties of MPEAs have diverse origins. The strengthening effects through Shockley partials and stacking faults can be decoupled in MPEAs, breaking the conventional wisdom that low stacking fault energies are coupled with wide partial dislocations. This study clarifies the mechanistic origins for the strengthening effects, laying the foundation for physicsinformed predictive models for materials design.

Original language	English
Article number	e2114167118
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	118
Issue number	51
DOIs	https://doi.org/10.1073/pnas.2114167118
Publication status	Published - 21 Dec 2021
Externally published	Yes

Keywords

Dislocation
Multiprincipal element alloys
Stacking fault energy
Strengthening mechanism

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10.1073/pnas.2114167118

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title = "Decoupling between Shockley partials and stacking faults strengthens multiprincipal element alloys",

abstract = "Mechanical properties are fundamental to structural materials, where dislocations play a decisive role in describing their mechanical behavior. Although the high-yield stresses ofmultiprincipal element alloys (MPEAs) have received extensive attention in the last decade, the relation between their mechanistic origins remains elusive. Our multiscale study of density functional theory, atomistic simulations, and high-resolution microscopy shows that the excellent mechanical properties of MPEAs have diverse origins. The strengthening effects through Shockley partials and stacking faults can be decoupled in MPEAs, breaking the conventional wisdom that low stacking fault energies are coupled with wide partial dislocations. This study clarifies the mechanistic origins for the strengthening effects, laying the foundation for physicsinformed predictive models for materials design.",

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author = "Zongrui Pei and Siyuan Zhang and Yinkai Lei and Fan Zhang and Mingwei Chen",

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T1 - Decoupling between Shockley partials and stacking faults strengthens multiprincipal element alloys

AU - Pei, Zongrui

AU - Zhang, Siyuan

AU - Lei, Yinkai

AU - Zhang, Fan

AU - Chen, Mingwei

PY - 2021/12/21

Y1 - 2021/12/21

N2 - Mechanical properties are fundamental to structural materials, where dislocations play a decisive role in describing their mechanical behavior. Although the high-yield stresses ofmultiprincipal element alloys (MPEAs) have received extensive attention in the last decade, the relation between their mechanistic origins remains elusive. Our multiscale study of density functional theory, atomistic simulations, and high-resolution microscopy shows that the excellent mechanical properties of MPEAs have diverse origins. The strengthening effects through Shockley partials and stacking faults can be decoupled in MPEAs, breaking the conventional wisdom that low stacking fault energies are coupled with wide partial dislocations. This study clarifies the mechanistic origins for the strengthening effects, laying the foundation for physicsinformed predictive models for materials design.

AB - Mechanical properties are fundamental to structural materials, where dislocations play a decisive role in describing their mechanical behavior. Although the high-yield stresses ofmultiprincipal element alloys (MPEAs) have received extensive attention in the last decade, the relation between their mechanistic origins remains elusive. Our multiscale study of density functional theory, atomistic simulations, and high-resolution microscopy shows that the excellent mechanical properties of MPEAs have diverse origins. The strengthening effects through Shockley partials and stacking faults can be decoupled in MPEAs, breaking the conventional wisdom that low stacking fault energies are coupled with wide partial dislocations. This study clarifies the mechanistic origins for the strengthening effects, laying the foundation for physicsinformed predictive models for materials design.

KW - Dislocation

KW - Multiprincipal element alloys

KW - Stacking fault energy

KW - Strengthening mechanism

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DO - 10.1073/pnas.2114167118

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AN - SCOPUS:85122568622

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JO - Proceedings of the National Academy of Sciences of the United States of America

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Decoupling between Shockley partials and stacking faults strengthens multiprincipal element alloys

Abstract

Keywords

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