Design of Core-Shell Structured Magnetic Microwires with Desirable Properties for Multifunctional Applications

TL;DR

This paper introduces a multi-step Joule current annealing method to create core-shell structured magnetic microwires, enhancing their magnetic and mechanical properties for multifunctional applications.

Contribution

A novel annealing technique for designing core-shell structures directly from amorphous microwires, improving magnetic softness and mechanical strength simultaneously.

Findings

Optimized nanocrystal density improves magnetic properties.

Shell preserves mechanical strength of microwires.

Method enables multifunctional magnetic device applications.

Abstract

Amorphous Co-rich microwires with excellent soft magnetic and mechanical properties produced by melt-extraction technique are emerging as a multifunctional material for a variety of applications ranging from ultrasensitive magnetic field sensors to structural health self-monitoring composites. There is a pressing need for enhancing these properties to make the microwires practical for integration into new technologies. Conventional heat treatments at temperature below crystallization may improve the magnetic softness of an as-quenched amorphous wire, but usually deteriorate the good mechanical characteristic of the wire due to crystallization. To overcome this, we propose a new approach that utilizes the advantages of a multi-step Joule current annealing method to design novel (nanocrystal, amorphous)/amorphous core/shell structures directly from as-quenched amorphous microwires. These results show that the density and size of nanocrystals in the core can be optimized by controlling the Joule current intensity, resulting in the large enhancement of soft magnetic and giant magneto-impedance properties, while the amorphous shell preserves the excellent mechanical strength of the microwire. This study also provides a new pathway for the design of novel core/shell structures directly from rapidly quenched amorphous magnetic materials that are currently exploited in high frequency transformers, sensing and cooling devices.