In situ phase engineering during additive manufacturing enables high-performance soft-magnetic medium-entropy alloys
Zu-Rui Cao, Pengcheng Zhang, Bailing An, Dawei Li, Yao Yu, Jie Pan, Cheng Zhang, Lin Liu
Abstract
Additive manufacturing (AM) shows promise as a method for producing soft-magnetic multicomponent alloys for use in electric motors and sustainable electromobility applications. However, the simultaneous achievement of a high saturation magnetic flux density (Bs) and a low coercivity (Hc) in AM soft-magnetic materials remains challenging. Herein, we present an approach that integrates an elemental powder mixture of Fe45Co30Ni25 with Fe2O3 nano-oxides, which is then subjected to laser powder bed fusion (LPBF) followed by high-temperature annealing to achieve an FCC-structured Fe45Co30Ni25 MEA/FeO composite. The FeO nanoparticles, a byproduct of the reaction between Fe powders and Fe2O3 nano-oxides, serve as nucleation sites for the formation of a single FCC phase in the MEA matrix. The resulting LPBF MEA/FeO composite has a Bs of 2.05 T and an exceedingly low Hc of 115 A m−1, compared to those of the BCC/FCC dual phase MEA and other state-of-the-art additively manufactured soft-magnetic alloys. In situ Lorentz transmission electron microscope (TEM) revealed that the low Hc of the FCC-structured MEA/FeO composite originates from the reduced pinning effect of grain boundaries in the FCC phase on domain wall movement compared with those in the FCC/BCC dual phase. Soft magnetic materials are critical components in the electric transport and energy sectors, such that even minor improvements in their properties can yield vast savings in energy. Here, Cao, Zhang and coauthors demonstrate via an additive manufacturing based approach, a medium entropy alloy with superior magnetic properties.