Effect of Yb Content on Microstructure and Mechanical Property of Mg-Gd-Y-Zn-Zr Alloy
WANG Sheng1, ZHU Yancheng1, PAN Hucheng1(), LI Jingren1, ZENG Zhihao1, QIN Gaowu1,2()
1 Key Laboratory for Anisotropy and Texture of Materials (Ministry of Education), College of Materials Science and Engineering, Northeastern University, Shenyang 110819, China 2 Research Center for Strategic Materials and Components, Shenyang University of Chemical Technology, Shenyang 110142, China
Cite this article:
WANG Sheng, ZHU Yancheng, PAN Hucheng, LI Jingren, ZENG Zhihao, QIN Gaowu. Effect of Yb Content on Microstructure and Mechanical Property of Mg-Gd-Y-Zn-Zr Alloy. Acta Metall Sin, 2025, 61(3): 499-508.
To examine the effects of Yb addition on wrought Mg alloys, this study evaluates the influence of Yb content (0%-1.0%, mass fraction) on the microstructure, room-temperature, and high-temperature mechanical properties of the Mg-9Gd-4Y-1.2Zn-0.3Zr (mass fraction, %) alloy (GWZK). Mechanical performance tests and microstructural characterizations were conducted on alloy samples after solid solution treatment, extrusion, and aging. The results reveal that the GWZK-0.2Yb alloy exhibits superior mechanical properties, achieving tensile yield strength (TYS) of 456 MPa, which is an increase of approximately 45 MPa compared to the Yb-free GWZK-0Yb sample, and an ultimate tensile strength of 509 MPa. Furthermore, at 250 oC, the GWZK-0.2Yb alloy demonstrates a high yield strength of 326 MPa and ductility of 10.6%, indicating a synergistic improvement in strength and plasticity relative to the Yb-free sample. Microstructural analysis shows that the addition of 0.2%Yb suppresses the formation of long-period stacking ordered (LPSO) phases in the GWZK alloy while promoting the precipitation of β′ and γ′ phases during aging. The enhancement in strength is primarily attributed to the lamellar LPSO within the α-Mg matrix post-aging, as well as the dense precipitation of β′ and γ′ phases. However, increasing the Yb content to 0.5% reduces ductility at both room and high temperatures, primarily due to the high volume fraction of brittle β phases. Further increasing the Yb content to 1.0% leads to simultaneous decrease in strength and ductility at both temperature ranges. This degradation is attributed to the increased presence of the β phase, which reduces the number density of β′ and γ′ phases precipitated during the aging of the GWZK-1.0Yb alloy.
Fund: National Key Research and Development Program of China(2023YFB3710900);National Natural Science Foundation of China(U2167213);Fundamental Research Funds for the Central Universities(N2202020);XingLiao Talent Plan(XLYC2203202)
Corresponding Authors:
PAN Hucheng, professor, Tel: 13166643462, E-mail: panhc@atm.neu.edu.cn; QIN Gaowu, professor, Tel: (024)83691565, E-mail: qingw@smm.neu.edu.cn
Fig.1 Engineering stress-strain curves of peak-aged GWZK-xYb alloys (a, b) and extruded GWZK-xYb alloys (c) at different temperatures and comparison of high-strength/peak-aged Mg-Gd series alloys prepared by similar extrusion process[20~26] (d) (Black and red curves are the fitting curves of tensile yield strength (TYS) and untimate tensile strength (UTS) of high strength Mg-Gd series alloys, respectively) (a, c) at room temperature (25 oC) (b) at 250 oC
Alloy
PA RT
PA ET
ES RT
TYS
MPa
UTS
MPa
EL
%
TYS
MPa
UTS
MPa
EL
%
TYS
MPa
UTS
MPa
EL
%
GWZK-0Yb
411
471
6.6
310
357
7.7
349
414
11.1
GWZK-0.2Yb
456
509
4.3
326
373
10.6
324
394
9.6
GWZK-0.5Yb
451
496
1.9
327
379
9.0
353
409
5.0
GWZK-1.0Yb
418
443
1.7
312
344
5.8
363
408
3.5
Table 1 Tensile properties of peak-aged GWZK-xYb alloy tested at room temperature and 250 oC and extruded GWZK-xYb alloy tested at room temperature
Fig.2 Low (a, c, e, g) and high magnified (b, d, f, h) SEM images of GWZK-0Yb (a, b), GWZK-0.2Yb (c, d), GWZK-0.5Yb (e, f), and GWZK-1.0Yb (g, h) alloys in the solid solution state (Insets in Figs.2d, f, and h are the corresponding EDS mappings of Yb element; LPSO represent long-period stacking ordered)
Point
Mg
Gd
Y
Zn
Yb
A
88.73
3.49
2.95
4.82
0
B
89.90
3.07
2.54
4.36
0.14
C
89.11
3.65
2.67
4.36
0.22
D
83.35
7.22
3.09
5.53
0.81
E
81.72
6.80
3.54
7.00
0.94
F
78.51
6.31
4.07
6.14
4.98
Table 2 EDS results corresponding to each point in Figs.2b, d, f, and h
Fig.3 OM images of as-extruded GWZK-0Yb (a), GWZK-0.2Yb (b), GWZK-0.5Yb (c), and GWZK-1.0Yb (d) alloys (ED—extrusion direction, DRX—dynamic recrystallization)
Fig.4 SEM images of GWZK-0Yb (a), GWZK-0.2Yb (b), GWZK-0.5Yb (c, e), and GWZK-1.0Yb (d) alloys in as-extruded state; and volume fraction of blocky phases in different samples (f)
Point
Mg
Gd
Y
Zn
Yb
G
87.80
3.50
3.55
4.95
0.20
H
83.95
6.71
3.56
5.13
0.65
Table 3 EDS results corresponding to each point in Fig.4e
Fig.5 TEM characterizations of the peak-aged GWZK-0Yb (a-c), GWZK-0.2Yb (d-f), and GWZK-0.5Yb (g-i) alloys (White lines Figs.5b, e, and h represent bending and twisting)
Fig.6 Low (a, b) and high (c) magnified HAADF-STEM images and corresponding EDS mappings of the peak-aged GWZK-0.2Yb alloy (Inset in Fig.3c is SAED pattern of the layered region (under B = <210>); B —the incident direction of the electron beam)
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