Optimizing the high-frequency magnetic properties of soft magnetic composites via surface nanoengineering

Abstract

Owing to the presence of large residual internal stress during cold compaction, it is difficult to optimize the multiple high-frequency magnetic properties of amorphous soft magnetic composites (ASMCs) simultaneously. Here, a surface nanoengineering strategy was proposed to address the above dilemma by constructing a stress buffer layer composed of amorphous nano-particles, between amorphous powder and insulation coating. The amorphous FeSiBCCr@x wt.% FeB (x = 0.5, 1, 3) composite powders with core-shell structures were successfully prepared via an in-situ chemical reduction method. Especially, when the composite ratio of nano-particles is 1 wt.%, the comprehensive properties of the ASMC reach the best balance. Compared with the FeSiBCCr ASMC, the saturation magnetization of the modified ASMC enhances from 153 to 171 emu/g. Meanwhile, the core loss decreases by 28.25 %, while the effective permeability increases by 25 % and can stabilize to ∼20 MHz. Therefore, our work provides a strategy for achieving superior comprehensive soft magnetic properties of ASMCs via surface nanoengineering, which presents enormous application potential in high-frequency electric devices.