Developing a lamellar-structured Mg-4Li-3Al-0.4Ca alloy with high strength-ductility synergy

doi:10.1016/j.jmst.2024.11.083

Abstract

Abstract: The low strength of Mg-Li alloys sets a limit to lightweight applications. Introducing crystal defects (twins, dislocations, and SFs) is a distinctive strategy for maintaining good mechanical properties of metallic materials. A lamellar-structured Mg-4Li-3Al-0.4Ca alloy with high performance was prepared by hot extrusion and rotary swaging. The as-swaged alloy exhibits excellent mechanical properties with ten-sile strength, yield strength, elongation to failure, and specific strength of 391 MPa, 312 MPa, 14.2 %, and 238.4 kN m kg^-1, respectively. The average grain size of the as-swaged alloy is 160± 23 nm, and the microstructure is mainly composed of lamellar structures, twins, ultrafine grains, and nano-grains. The abundant lamellar structures and twins promote the storage of dislocations and SFs, leading to the formation of twin-twin interactions and enhancing strain hardening. The formation of UFG and NG by dynamic recrystallization further improves the yield strength. Shearable second phases play a critical role in enhancing the yield strength and ductility. More importantly, extensive planar dislocation glide and<c + a>dislocations efficiently relax the local stress concentrations, and thus improve the ductility.

Key words: Mg-Li alloy, Rotary swaging, High strength, Lamellar structure, Planar dislocation glide

Xiaofei Cui, Yan Yang, Zihao Zhou, Zhonghua Hu, Yangyang Luo, Guobing Wei, Wen Gao, Bin Jiang, Xiaodong Peng, Fusheng Pan. Developing a lamellar-structured Mg-4Li-3Al-0.4Ca alloy with high strength-ductility synergy[J]. J. Mater. Sci. Technol., 2025, 229: 116-124.

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