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Full Length Article | Open Access

Enhancing the ductility of cast Mg-Li alloys via dispersed α-Mg phase mitigating the dimension and distribution of interspersed eutectics along grain boundaries

Yu WangaZiyang XiaaJingpeng XiongaGang ZengaPenghao WangaLan LuoaRuizhi Wub( )Jian Wangc( )Yong Liua( )
Key Laboratory of Light weight and high strength structural materials of Jiang xi Province, Advanced Manufacturing School of Nanchang University, Nanchang 330031, China
Key Laboratory of Superlight Materials & Surface Technology, Ministry of Education, Harbin Engineering University, Harbin 150001, China
Mechanical and Materials Engineering, University of Nebraska-Lincoln, Lincoln, NE 68588, USA
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Abstract

Mg-Li alloys with high lithium concentrations possess a lightweight body-centered cubic (BCC) matrix structure (β-Li). Interspersed eutectics (primarily the reticulated I-phase) often form along phase boundaries (PBs) and grain boundaries (GBs) which strengthen the alloy but cause the loss of ductility due to the brittle behavior of I-phase. By modifying the Li content, we fabricated the (β+α) biphase Mg-Li alloy in which the α-Mg phase with a hexagonal close-packed structure (HCP) is embedded in β-Li matrix, significantly increasing interface density. The high-density interfaces mitigate the distribution and dimension of the I-phase along GBs and PBs. The alloy exhibits enhanced ductility (elongation (EL) = 17.8 %) compared with the alloy without the α-Mg phase (EL = 5.1 %). Structural characterizations unveil the strengthening mechanism of the nanoscale B2 (Li, Mg)3Zn-type precipitates in conjunction with the microscale I-phase. The (Li, Mg)3Zn nanophases augment the yield and ultimate tensile strength of the alloy without a discernible compromise in ductility, predominantly due to gliding dislocations cutting through the precipitates. In contrast, the microscale I-phase presents a formidable barrier to dislocation motion, facilitating dislocation pileups at interfaces and culminating in diminished ductility across the interface. In-situ stretching techniques were employed to scrutinize the microstructural evolution of alloys during tensile deformation, elucidating that the deformation compatibility of alloys correlates with the average size of the I-phase and their distribution along GBs and PBs. Corresponding to the orientation relationship (OR) between the α-Mg and β-Li phases {110}Li//{0001}Mg and <111>Li //<1120>Mg, the slip continuity between α-Mg and β-Li on plane pairs of {123}Li-{1122}Mg and {112}Li-{1122}Mg assures the deformation compatibility through facilitating the deformation across interfaces. Simultaneously, during the stretching process, the dispersed I-phase instigates the emergence of sporadic microcracks, indicating gradual damage evolution. These discoveries offer novel insights into achieving exceptional strength-ductility amalgamations in Mg-Li alloys through microstructural adjustments.

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Journal of Magnesium and Alloys
Pages 4722-4739

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Cite this article:
Wang Y, Xia Z, Xiong J, et al. Enhancing the ductility of cast Mg-Li alloys via dispersed α-Mg phase mitigating the dimension and distribution of interspersed eutectics along grain boundaries. Journal of Magnesium and Alloys, 2024, 12(11): 4722-4739. https://doi.org/10.1016/j.jma.2024.01.035

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Received: 18 January 2024
Revised: 22 January 2024
Accepted: 29 January 2024
Published: 23 February 2024
© 2024 Chongqing University.

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/) Peer review under responsibility of Chongqing University