Metallurgical Abstracts on Light Metals and Alloys vol. 58

Separation of aluminum and silicon from crystallizing Al–12.6wt%Si eutectic melts by applying an electromagnetic force during directional solidification

Takuya Tamura* and Mingjun Li*
* National Institute of Advanced Industrial Science and Technology (AIST), Multi-Material Research Institute

[Published in Journal of Materials Processing Technology, Volume 342 (2025), 118916]

https://doi.org/10.1016/j.jmatprotec.2025.118916
E-mail: takuya-tamura[at]aist.go.jp
Key Words: Al–12.6 %Si eutectic alloy, Electromagnetic force, Continuous casting, EBSD, Fluid flow, Directional solidification

Fine eutectic phases grow in a coupled mode from a quiescent liquid pool with a eutectic composition under a usual casting condition. The Al–12.6wt%Si alloy belongs to such a typical eutectic system that consists of fine Si plates/rods embedding in the Al matrix after solidification. Conventionally, it seems impossible to separate Al and Si from the eutectic alloy in directional solidification. Herein, we developed a novel process to separate Al and Si from the eutectic liquid when a directional electromagnetic force (EMF) was applied upon the crystallizing solid/liquid interface. Solidification structures were observed, confirming that Al and Si could be effectively separated from the eutectic melt during continuous casting. Fluid flow simulation results were applied to elucidate the separation behavior and growth directions of Al dendrites and Si crystals. The formation mechanism of the Al dendrites as the leading phase was clarified when considering the turbulent fluid flow upon the application of EMF. The aggregated Si crystals were characterized by the electron backscatter diffraction (EBSD) technique, showing convincing evidence of Si growth. The successful separation of Al and Si from the eutectic alloy using the present technique can eventually amend the recycling chain of Al–Si based alloys.

Microstructure of the billet when the electromagnetic force was imposed during directional solidification for the Al-Si eutectic melts.