Synergistic strengthening of Al–SiC composites by nano-spaced SiC-nanowires and the induced high-density stacking faults

Yiming Wu; Chang Zhou; Rui Wu; Lixin Sun; Chenyang Lu; Yunzhen Xiao; Zhengxiong Su; Mingyu Gong; Kaisheng Ming; Kai liu; Chao Gu; Wenshu Yang; Jian Wang; Gaohui Wu

doi:10.1016/j.compositesb.2022.110458

Synergistic strengthening of Al–SiC composites by nano-spaced SiC-nanowires and the induced high-density stacking faults

Yiming Wu
, Chang Zhou
, Rui Wu
, Lixin Sun
, Chenyang Lu
, Yunzhen Xiao
, Zhengxiong Su
, Mingyu Gong
, Kaisheng Ming
, Kai liu
, Chao Gu
, Wenshu Yang^*
, Jian Wang^*
, Gaohui Wu^*

^*Corresponding author for this work

Faculty of Computing

Harbin Institute of Technology
University of Science and Technology Beijing
Harbin Engineering University
Xi'an Jiaotong University
Shanghai Jiao Tong University
Hebei University of Technology
Southern University of Science and Technology
University of Nebraska-Lincoln

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

37 Scopus citations

Abstract

Aluminum alloys are widely used in engineering structures due to light weight and corrosion resistance but aluminum has low yielding and flow strengths. Here we reported super-strong Al-30 vol%SiC composites with a flow strength of about 1.18 GPa up to a uniform strain of 16.0%. Micromechanical tests revealed a flow strength of 0.73 GPa associated with the nano-spaced SiC nanowires strengthening, and additional flow strength of 0.45 GPa associated with high-density stacking faults (SFs) that are rarely formed and stabilized in Al due to high stacking fault energy (SFE). More surprisingly, SFs possess excellent thermal stability up to 320 °C and can be regained by thermal cooling even after they are eliminated during annealing at 600 °C. Microscopy characterizations and theoretical analysis revealed that thermal mismatch induced high stress during cooling promotes the formation of SFs, and the segregation of Si into SFs and dislocation cores enables the thermal stability of wide SFs. This work demonstrated an approach to creating high-density and thermo stable SFs in high SFE metals via microstructure-enabled thermal stress.

Original language	English
Article number	110458
Journal	Composites Part B: Engineering
Volume	250
DOIs	https://doi.org/10.1016/j.compositesb.2022.110458
State	Published - 1 Feb 2023

Keywords

Aluminum
In situ micropillar compression tests
Metal matrix composites
Stacking faults
Thermal stability

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10.1016/j.compositesb.2022.110458

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title = "Synergistic strengthening of Al–SiC composites by nano-spaced SiC-nanowires and the induced high-density stacking faults",

abstract = "Aluminum alloys are widely used in engineering structures due to light weight and corrosion resistance but aluminum has low yielding and flow strengths. Here we reported super-strong Al-30 vol\%SiC composites with a flow strength of about 1.18 GPa up to a uniform strain of 16.0\%. Micromechanical tests revealed a flow strength of 0.73 GPa associated with the nano-spaced SiC nanowires strengthening, and additional flow strength of 0.45 GPa associated with high-density stacking faults (SFs) that are rarely formed and stabilized in Al due to high stacking fault energy (SFE). More surprisingly, SFs possess excellent thermal stability up to 320 °C and can be regained by thermal cooling even after they are eliminated during annealing at 600 °C. Microscopy characterizations and theoretical analysis revealed that thermal mismatch induced high stress during cooling promotes the formation of SFs, and the segregation of Si into SFs and dislocation cores enables the thermal stability of wide SFs. This work demonstrated an approach to creating high-density and thermo stable SFs in high SFE metals via microstructure-enabled thermal stress.",

keywords = "Aluminum, In situ micropillar compression tests, Metal matrix composites, Stacking faults, Thermal stability",

author = "Yiming Wu and Chang Zhou and Rui Wu and Lixin Sun and Chenyang Lu and Yunzhen Xiao and Zhengxiong Su and Mingyu Gong and Kaisheng Ming and Kai liu and Chao Gu and Wenshu Yang and Jian Wang and Gaohui Wu",

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year = "2023",

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day = "1",

doi = "10.1016/j.compositesb.2022.110458",

language = "英语",

volume = "250",

journal = "Composites Part B: Engineering",

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TY - JOUR

T1 - Synergistic strengthening of Al–SiC composites by nano-spaced SiC-nanowires and the induced high-density stacking faults

AU - Wu, Yiming

AU - Zhou, Chang

AU - Wu, Rui

AU - Sun, Lixin

AU - Lu, Chenyang

AU - Xiao, Yunzhen

AU - Su, Zhengxiong

AU - Gong, Mingyu

AU - Ming, Kaisheng

AU - liu, Kai

AU - Gu, Chao

AU - Yang, Wenshu

AU - Wang, Jian

AU - Wu, Gaohui

PY - 2023/2/1

Y1 - 2023/2/1

N2 - Aluminum alloys are widely used in engineering structures due to light weight and corrosion resistance but aluminum has low yielding and flow strengths. Here we reported super-strong Al-30 vol%SiC composites with a flow strength of about 1.18 GPa up to a uniform strain of 16.0%. Micromechanical tests revealed a flow strength of 0.73 GPa associated with the nano-spaced SiC nanowires strengthening, and additional flow strength of 0.45 GPa associated with high-density stacking faults (SFs) that are rarely formed and stabilized in Al due to high stacking fault energy (SFE). More surprisingly, SFs possess excellent thermal stability up to 320 °C and can be regained by thermal cooling even after they are eliminated during annealing at 600 °C. Microscopy characterizations and theoretical analysis revealed that thermal mismatch induced high stress during cooling promotes the formation of SFs, and the segregation of Si into SFs and dislocation cores enables the thermal stability of wide SFs. This work demonstrated an approach to creating high-density and thermo stable SFs in high SFE metals via microstructure-enabled thermal stress.

AB - Aluminum alloys are widely used in engineering structures due to light weight and corrosion resistance but aluminum has low yielding and flow strengths. Here we reported super-strong Al-30 vol%SiC composites with a flow strength of about 1.18 GPa up to a uniform strain of 16.0%. Micromechanical tests revealed a flow strength of 0.73 GPa associated with the nano-spaced SiC nanowires strengthening, and additional flow strength of 0.45 GPa associated with high-density stacking faults (SFs) that are rarely formed and stabilized in Al due to high stacking fault energy (SFE). More surprisingly, SFs possess excellent thermal stability up to 320 °C and can be regained by thermal cooling even after they are eliminated during annealing at 600 °C. Microscopy characterizations and theoretical analysis revealed that thermal mismatch induced high stress during cooling promotes the formation of SFs, and the segregation of Si into SFs and dislocation cores enables the thermal stability of wide SFs. This work demonstrated an approach to creating high-density and thermo stable SFs in high SFE metals via microstructure-enabled thermal stress.

KW - Aluminum

KW - In situ micropillar compression tests

KW - Metal matrix composites

KW - Stacking faults

KW - Thermal stability

UR - https://www.scopus.com/pages/publications/85143722871

U2 - 10.1016/j.compositesb.2022.110458

DO - 10.1016/j.compositesb.2022.110458

M3 - 文章

AN - SCOPUS:85143722871

SN - 1359-8368

VL - 250

JO - Composites Part B: Engineering

JF - Composites Part B: Engineering

M1 - 110458

ER -

Synergistic strengthening of Al–SiC composites by nano-spaced SiC-nanowires and the induced high-density stacking faults

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Keywords

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