Solidification of Immiscible Alloys under High Magnetic Field: A Review

Immiscible alloy is a kind of functional metal material with broad application prospects in industry and electronic fields, which has aroused extensive attention in recent decades. In the solidification process of metallic material processing, various attractive phenomena can be realized by applying a high magnetic field (HMF), including the nucleation and growth of alloys and microstructure evolution, etc. The selectivity provided by Lorentz force, thermoelectric magnetic force, and magnetic force or a combination of magnetic field effects can effectively control the solidification process of the melt. Recent advances in the understanding of the development of immiscible alloys in the solidification microstructure induced by HMF are reviewed. In this review, the immiscible alloy systems are introduced and inspected, with the main focus on the relationship between the migration behavior of the phase and evolution of the solidification microstructure under HMF. Special attention is paid to the mechanism of microstructure evolution caused by the magnetic field and its influence on performance. The ability of HMF to overcome microstructural heterogeneity in the solidification process provides freedom to design and modify new functional immiscible materials with desired physical properties. This review aims to offer an overview of the latest progress in HMF processing of immiscible alloys.

Automated summary

Immiscible alloys are functional metal materials with broad application prospects in industry and electronics. The application of high magnetic fields in the solidification process can control the nucleation and growth of alloys, as well as the evolution of microstructure. Recent advances in understanding the development of immiscible alloys in solidification microstructure induced by HMF have been reviewed, focusing on the relationship between phase migration behavior and microstructure evolution under HMF.