Influence of pre-compression and pre-aging on precipitation behavior in casting Mg-9.8Sn-3.0Zn alloy

Yun Liu , Chao-qiang Liu , Song Ni , Min Song

Journal of Central South University ›› 2025, Vol. 32 ›› Issue (8) : 2783 -2794.

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Journal of Central South University ›› 2025, Vol. 32 ›› Issue (8) : 2783 -2794. DOI: 10.1007/s11771-025-6041-0
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Influence of pre-compression and pre-aging on precipitation behavior in casting Mg-9.8Sn-3.0Zn alloy

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Abstract

The effects of pre-compression and pre-aging on the age-hardening response and microstructure of Mg-9.8Sn-3.0Zn (wt.%) alloy have been investigated via hardness test and advanced electron microscopy. The alloy subjected to both pre-compression and pre-aging exhibits the most refined and densest distribution of precipitates upon aging at 200 °C, leading to the superior age-hardening performance observed in the alloy. Comparatively, the alloy that underwent only pre-aging displayed a greater number density of precipitates than its counterpart that was neither pre-compressed nor pre-aged when both were aged to their peak conditions at 200 °C, indicating an enhanced age-hardening response in the pre-aged alloy. The precipitates in these three peak-aged alloys consist of Mg2Sn and MgZn2 phases. The reason why the pre-aged alloy has a higher number density of precipitates than the directly aged alloy is that MgZn2 phase formed during pre-aging can serve as heterogeneous nucleation site for the formation of Mg2Sn. The reason why the pre-compression and pre-aged alloy has the highest number density of precipitates is that Mg3Sn and MgZn2 phases formed during pre-aging, alongside lattice defects introduced during pre-compression, collectively act as effective heterogeneous nucleation sites for the formation of Mg2Sn during the subsequent aging at 200 °C.

Keywords

Mg-Sn-Zn alloy / pre-compression / pre-aging / age-hardening response / precipitation behavior

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Yun Liu, Chao-qiang Liu, Song Ni, Min Song. Influence of pre-compression and pre-aging on precipitation behavior in casting Mg-9.8Sn-3.0Zn alloy. Journal of Central South University, 2025, 32(8): 2783-2794 DOI:10.1007/s11771-025-6041-0

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