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Insights into core-shell multi-structure and strengthening by multi-microalloying (Sc, Zr, Er and Ti) of a T6 treated Al–Li–Mg alloy

Dengfeng Yin, Shenchen Zhang, Xin Li, Jian-Gang Yao, Qi Yin, Andrej Atrens, Ming‐Chun Zhao

2024Journal of Materials Research and Technology18 citationsDOIOpen Access PDF

Abstract

The core-shell multi-structure and strengthening of a multi-microalloyed (Sc, Zr, Er and Ti) T6 treated Al-Li-Mg alloy were studied using transmission electron microscopy (TEM) and microhardness. The T6 treated microstructure contained core-shell multi-structured particles. The (Sc, Zr, Ti)-rich core was generated at the earlier stage at higher temperature rather than at the final aging stage at 160 o C and still remained during aging. The core edge was Al 3 Er. The shell layer was δ′-Al 3 Li. These were generated during aging. The coarsening kinetics and precipitate size distributions of Al 3 (Sc, Zr, Er, Ti, Li) particles aged at 160 o C indicated that the volume diffusion and surface reaction at the particle/matrix interfaces occurred simultaneously. The particle growth was controlled by a combination of these two mechanisms. Multi-microalloying (Sc, Zr, Er and Ti) into the Al-Li-Mg alloy did not accelerate the peak aging time but increased the strength during aging. The peak hardness of the new Al-Li-Mg-Sc-Zr-Er-Ti alloy was increased by ∼22 % compared to that of the contrasting Al-Li-Mg alloy. Orowan bypass strengthening was the operative mechanism for the core-shell multi-structure particles.

Topics & Concepts

Materials scienceAlloyMetallurgyCore (optical fiber)Shell (structure)Composite materialAluminum Alloy Microstructure PropertiesAluminum Alloys Composites PropertiesMetallurgy and Material Forming
Insights into core-shell multi-structure and strengthening by multi-microalloying (Sc, Zr, Er and Ti) of a T6 treated Al–Li–Mg alloy | Litcius