Origin of the age-hardening and age-softening response in Mg-Li-Zn based alloys

The origin of the age-hardening and age-softening response in the Mg-10Li(-Zn)(-Er) alloys is studied. The results show that the age-hardening of the Mg-10Li-5Zn (LZ105) alloy quickly after quenching is due to the precipitation of the semi-coherent (Mg, Li)(3)Zn phase. The Zn atom occupation of the precipitate is confirmed. Beside precipitate coarsening, Mg atoms in the (Mg, Li)(3)Zn precipitate are gradually replaced by Li/Zn atoms, primarily accounting for the origin of age-softening. The substitution of Li for Mg is dominant at low aging temperature, while the substitutions of both Li and Zn for Mg are prominent at high aging temperature. The reduced modulus strengthening leads to the strength reduction of the LZ105 alloy during low-temperature aging. High-temperature aging brings about significant coarsening of the precipitate and the strength decreases dramatically. Er addition retards the evolution of the (Mg, Li)(3)Zn precipitate, resulting in the deceleration of age-softening observed in the LZ105 alloy modified by 0.5 wt% Er addition during aging at 50 degrees C. The considerable Mg-Zn-Er phases along with trace Er atoms dissolved in the matrix lower the available Zn concentration for (Mg, Li)(3)Zn precipitation and retard the diffusion of Li and Zn atoms during aging. A novel aging mechanism based on the (Mg, Li)(3)Zn precipitate evolution in Mg-Li-Zn-based alloys is proposed in this study and provides a theoretical basis for deeply understanding the aging behaviors of Mg-Li-Al/Zn alloys. (C) 2022 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

The origin of the age-hardening and age-softening response in Mg-10Li(-Zn)(-Er) alloys is studied. The age-hardening is attributed to the precipitation of the semi-coherent (Mg, Li)(3)Zn phase, while the age-softening is primarily caused by the gradual substitution of Mg atoms by Li/Zn atoms in the precipitate. The addition of Er retards the evolution of the (Mg, Li)(3)Zn precipitate, leading to a deceleration of age-softening in the alloy.