Torsion Dependence of Domain Transition and MI Effect of Melt-Extracted Co68.15Fe4.35Si12.25B13.25Nb1Cu1 Microwires

Abstract EN

We present the torsional stress induced magnetoimpedance (MI) effect and surface domain structure evolution of magnetostrictive melt-extracted Co68.15Fe4.35Si12.25B13.25Nb1Cu1 microwires.

Experimental results indicate that the surface domain structures observed by magnetic force microscope (MFM) transform from the weak circumferential domain of as-cast state to the helical domain under large torsional strain of 81.6 (2π rad/m).

Domain wall movement distorts at torsional strain ξ = 20.4 (2π rad/m) and forms a helical anisotropy with an angle of around 30° versus axial direction of wire.

At 15 MHz, the maximum of GMI ratio Δ Z / Z (%) increases to 194.4% at ξ = 20.4 (2π rad/m) from 116.3% of the as-cast state and then decreases to 134.9% at ξ = 102.0 (2π rad/m).

The torsion magnetoimpedance (TMI) ratio Δ Z / Z ξ (%) is up to 290%.

Based on this large torsional strain and high MI ratio, the microwire can be as an referred candidate for high-performance TMI sensor application.