Effect of Cu Content on Properties of Friction Stir Processed Mg-8Zn-xCu Alloys

doi:10.11901/1005.3093.2025.199

Chinese Journal of Materials Research

2025, Vol. 39

Issue (11): 813-823 DOI: 10.11901/1005.3093.2025.199

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Effect of Cu Content on Properties of Friction Stir Processed Mg-8Zn-xCu Alloys

DAI Hengxia¹, DONG Xuguang¹(

), XUE Peng¹^,², NI Dingrui², Ma Zongyi¹^,²

^1.School of Materials Science and Engineering, Shenyang Ligong University, Shenyang 110159, China
^2.Shi -changxu Innovation Center for Advanced Materials, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

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DAI Hengxia, DONG Xuguang, XUE Peng, NI Dingrui, Ma Zongyi. Effect of Cu Content on Properties of Friction Stir Processed Mg-8Zn-xCu Alloys. Chinese Journal of Materials Research, 2025, 39(11): 813-823.

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Abstract

Three Mg-8Zn-xCu (x = 0, 0.5 and 1, mass fraction, %) alloys were prepared by friction stir processing (FSP). Meanwhile, the influence of Cu content on the formability and mechanical properties of FSP Mg-8Zn alloys at high rotation rate was investigated by differential thermal analysis (DTA) and backscattered electron (BSE) etc. It was found that with the increasing Cu content, the eutectic in the Mg-8Zn-xCu alloys was transformed from a low-melting-point binary eutectic (346 °C) to a high-melting-point ternary eutectic (434 °C) during solidification process. The predominant eutectic phase was evolved from the Mg₇Zn₃ to the MgZnCu phase. The elevated eutectic temperature effectively suppressed the liquation (i.e., liquid formation) and liquation-induced cracking during FSP. By a Cu content of 0.5%, most of the secondary phases were dissolved into the Mg matrix via the thermo-mechanical coupling effect of FSP. This resulted in a super high Zn solid solution content of 6.62% (mass fraction) in Mg matrix, approximately 4 times of the room-temperature equilibrium solubility. Compared with the FSP Mg-8Zn alloy, the FSP Mg-8Zn-0.5Cu alloy exhibits a 50 MPa increase in tensile strength, achieving 300 MPa, and the elongation to fracture significantly increases from 13.4% to 30.2%. It is the improvement of microstructural uniformity that leads to a simultaneous enhancement of strength and ductility, supplemented by the synergistic action of high-content Zn solid solution strengthening, grain refinement, and MgZn₂ dynamic precipitation strengthening. As the Cu content was increased to 1%, stripe-like particle clusters formed within the processing zone due to the undissolved secondary phases, leading to a significant degradation in tensile properties.

Key words: metallic materials high-zinc magnesium alloy friction stir processing liquation-induced cracking eutectic solid solution

Received: 10 June 2025

ZTFLH:

TG146.22

Fund: National Natural Science Foundation of China(52071317);Shenyang U40 Outstanding Youth Foundation(RC230864)

Corresponding Authors: DONG Xuguang, Tel: 13555804884, E-mail: xgdong@sylu.edu.cn

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	DAI Hengxia
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	NI Dingrui
	Ma Zongyi

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https://www.cjmr.org/EN/10.11901/1005.3093.2025.199 OR https://www.cjmr.org/EN/Y2025/V39/I11/813

Table 1 Eutectic properties and solid solubility parameters of binary Mg-based alloys

Fig.1 SEM images of the as-cast microstructure (a) Mg-8Zn, (b) Mg-8Zn-0.5Cu, (c) Mg-8Zn-1Cu, (d) region 1, (e) region 2, (f) region 3

Fig.2 Mg-Zn binary phase diagram^[17] (a) and enlarged diagram near the eutectic point [Mg-51.3Zn at 613 K (340 ^oC)] ^[19] (b)

Fig.3 DTA results of the as-cast alloys (a) Mg-8Zn, (b) Mg-8Zn-0.5Cu, (c) Mg-8Zn-1Cu

Fig.4 Surface morphologies of FSP samples

Fig.5 Cross-section morphologies of FSP Mg-8Zn alloy (a) macrostructures of processing zone, (b) enlarged SE image of region 1, (c) EDS map of intergranular eutectic film, (d) enlarged BSE image of region 2, (e) BSE image of upper processing zone, (f) BSE image of lower processing zone

Fig.6 Cross-section morphologies of FSP Mg-8Zn-xCu alloy (a) Mg-8Zn-0.5Cu, (b) Mg-8Zn-1Cu, (c) Mg-8Zn-0.5Cu, (d) EDS map of particles in Mg-8Zn-0.5Cu, (e) Mg-8Zn-1Cu, (f) magnification view of region 1

Fig.7 EBSD microstructures of Mg-8Zn-0.5Cu alloys (a) as-cast, (b) as-FSP

Fig.8 XRD patterns of Mg-8Zn alloys with Cu addition (a) XRD pattern of as-cast and FSP Mg-8Zn alloys, (b) enlarged image at 35°-45°

Fig.9 Morphology of nanoscale precipitates in the FSP Mg-8Zn-0.5Cu alloy (The electron beam was parallel to <11 $2 ¯$ 0> _α )

Fig.10 Microhardness profile of FSP Mg-8Zn-xCu alloys at the cross-section

Fig.11 Engineering stress-strain curves of FSP Mg-8Zn-xCu alloys (a) and comparison of fracture elongation and ultimate tensile strength values in different FSP Mg-Zn alloys^[23~30] (b)

Fig.12 Fracture morphologies of FSP Mg-8Zn-xCu alloys (a, b) Mg-8Zn, (c, d) Mg-8Zn-0.5Cu, (e, f) Mg-8Zn-1Cu, (a, c, e) SE, (b, d, f) BSE

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