Suppression of discontinuous precipitation and strength improvement by Sc doping in Cu-6 wt%Ag alloys

Bailing An; Rongmei Niu; Yan Xin; William L. Starch; Zhaolong Xiang; Yifeng Su; Robert E. Goddard; Jun Lu; Theo M. Siegrist; Engang Wang; Ke Han

doi:10.1016/j.jmst.2022.06.043

Suppression of discontinuous precipitation and strength improvement by Sc doping in Cu-6 wt%Ag alloys

Bailing An, Rongmei Niu, Yan Xin, William L. Starch, Zhaolong Xiang, Yifeng Su, Robert E. Goddard, Jun Lu, Theo M. Siegrist, Engang Wang, Ke Han

Corrosion Science & Technology

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

24 Scopus citations

Abstract

In low-Ag Cu matrix alloys, the presence of coarse discontinuous precipitates may limit strength. We demonstrated that discontinuous precipitation was suppressed, and continuous precipitation was enhanced by the doping of Cu-6 wt%Ag with Sc. A high-volume fraction of continuous precipitates, which nucleated on {111} planes, led to a 55 MPa increase in strength, with only a slight decrease in electrical conductivity. The addition of Sc inhibited the nucleation of discontinuous precipitates by causing the Sc and the Ag to co-segregate onto grain boundaries, thus forming a thin intermetallic compound layer between grains. After deformation, both discontinuous and continuous precipitates were drawn into Ag fibers. The combination of deformation strain and doping caused an increase in density and a decrease in the diameter of Ag fibers, resulting in about 205 MPa increase in doped samples when the deformation strain reached 4.9. The thinner, denser Ag fibers in the doped samples also caused higher electron scattering at interfaces, leading to electrical conductivity that was 11% IACS lower than in non-doped samples. For reference, 100% IACS (International Annealed Copper Standard) is equivalent to 1.7241 μΩ cm.

Original language	English
Pages (from-to)	80-96
Number of pages	17
Journal	Journal of Materials Science and Technology
Volume	135
DOIs	https://doi.org/10.1016/j.jmst.2022.06.043
State	Published - Feb 1 2023

Funding

This work was supported by the National Key R&D Program of China (No. 2017YFE0107900 ) and the 111 Project (2.0) of China (No. BP0719037 ). Some work was performed at the National High Magnetic Field Laboratory, USA , which is supported by the National Science Foundation Cooperative Agreement (Nos. DMR- 1157490 and NSF DMR- 1644779 ) and the State of Florida, USA. The authors are grateful to Mary Tyler for editing. The authors are grateful to China Scholarship Council (CSC) for financial support.

Keywords

Electrical conductivity
Grain boundary segregation
Plastic deformation
Precipitation
Sc doping
Strength

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title = "Suppression of discontinuous precipitation and strength improvement by Sc doping in Cu-6 wt\%Ag alloys",

abstract = "In low-Ag Cu matrix alloys, the presence of coarse discontinuous precipitates may limit strength. We demonstrated that discontinuous precipitation was suppressed, and continuous precipitation was enhanced by the doping of Cu-6 wt\%Ag with Sc. A high-volume fraction of continuous precipitates, which nucleated on \{111\} planes, led to a 55 MPa increase in strength, with only a slight decrease in electrical conductivity. The addition of Sc inhibited the nucleation of discontinuous precipitates by causing the Sc and the Ag to co-segregate onto grain boundaries, thus forming a thin intermetallic compound layer between grains. After deformation, both discontinuous and continuous precipitates were drawn into Ag fibers. The combination of deformation strain and doping caused an increase in density and a decrease in the diameter of Ag fibers, resulting in about 205 MPa increase in doped samples when the deformation strain reached 4.9. The thinner, denser Ag fibers in the doped samples also caused higher electron scattering at interfaces, leading to electrical conductivity that was 11\% IACS lower than in non-doped samples. For reference, 100\% IACS (International Annealed Copper Standard) is equivalent to 1.7241 μΩ cm.",

keywords = "Electrical conductivity, Grain boundary segregation, Plastic deformation, Precipitation, Sc doping, Strength",

author = "Bailing An and Rongmei Niu and Yan Xin and Starch, \{William L.\} and Zhaolong Xiang and Yifeng Su and Goddard, \{Robert E.\} and Jun Lu and Siegrist, \{Theo M.\} and Engang Wang and Ke Han",

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year = "2023",

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day = "1",

doi = "10.1016/j.jmst.2022.06.043",

language = "English",

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TY - JOUR

T1 - Suppression of discontinuous precipitation and strength improvement by Sc doping in Cu-6 wt%Ag alloys

AU - An, Bailing

AU - Niu, Rongmei

AU - Xin, Yan

AU - Starch, William L.

AU - Xiang, Zhaolong

AU - Su, Yifeng

AU - Goddard, Robert E.

AU - Lu, Jun

AU - Siegrist, Theo M.

AU - Wang, Engang

AU - Han, Ke

PY - 2023/2/1

Y1 - 2023/2/1

N2 - In low-Ag Cu matrix alloys, the presence of coarse discontinuous precipitates may limit strength. We demonstrated that discontinuous precipitation was suppressed, and continuous precipitation was enhanced by the doping of Cu-6 wt%Ag with Sc. A high-volume fraction of continuous precipitates, which nucleated on {111} planes, led to a 55 MPa increase in strength, with only a slight decrease in electrical conductivity. The addition of Sc inhibited the nucleation of discontinuous precipitates by causing the Sc and the Ag to co-segregate onto grain boundaries, thus forming a thin intermetallic compound layer between grains. After deformation, both discontinuous and continuous precipitates were drawn into Ag fibers. The combination of deformation strain and doping caused an increase in density and a decrease in the diameter of Ag fibers, resulting in about 205 MPa increase in doped samples when the deformation strain reached 4.9. The thinner, denser Ag fibers in the doped samples also caused higher electron scattering at interfaces, leading to electrical conductivity that was 11% IACS lower than in non-doped samples. For reference, 100% IACS (International Annealed Copper Standard) is equivalent to 1.7241 μΩ cm.

AB - In low-Ag Cu matrix alloys, the presence of coarse discontinuous precipitates may limit strength. We demonstrated that discontinuous precipitation was suppressed, and continuous precipitation was enhanced by the doping of Cu-6 wt%Ag with Sc. A high-volume fraction of continuous precipitates, which nucleated on {111} planes, led to a 55 MPa increase in strength, with only a slight decrease in electrical conductivity. The addition of Sc inhibited the nucleation of discontinuous precipitates by causing the Sc and the Ag to co-segregate onto grain boundaries, thus forming a thin intermetallic compound layer between grains. After deformation, both discontinuous and continuous precipitates were drawn into Ag fibers. The combination of deformation strain and doping caused an increase in density and a decrease in the diameter of Ag fibers, resulting in about 205 MPa increase in doped samples when the deformation strain reached 4.9. The thinner, denser Ag fibers in the doped samples also caused higher electron scattering at interfaces, leading to electrical conductivity that was 11% IACS lower than in non-doped samples. For reference, 100% IACS (International Annealed Copper Standard) is equivalent to 1.7241 μΩ cm.

KW - Electrical conductivity

KW - Grain boundary segregation

KW - Plastic deformation

KW - Precipitation

KW - Sc doping

KW - Strength

UR - https://www.scopus.com/pages/publications/85136150788

U2 - 10.1016/j.jmst.2022.06.043

DO - 10.1016/j.jmst.2022.06.043

M3 - Article

AN - SCOPUS:85136150788

SN - 1005-0302

VL - 135

SP - 80

EP - 96

JO - Journal of Materials Science and Technology

JF - Journal of Materials Science and Technology

ER -

Suppression of discontinuous precipitation and strength improvement by Sc doping in Cu-6 wt%Ag alloys

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