Influence of varying metal-to-glass ratio on GMI effect in [formula omitted] amorphous glass-coated microwires

Abstract

The influence of a varying metal-to-glass ratio on the GMI effect in amorphous glass-coated Co 70.3Fe 3.7B 10Si 13Cr 3 microwires has been investigated. In the range of frequencies investigated (1–10 MHz), the magnitude of the GMI effect increases as the metal-to-glass ratio ( h ) increases from 4.11 to 9.29. The GMI curves for the h = 4.11 microwire exhibit a single-peak feature for f ≤ 1 MHz and a double-peak feature for f > 1 MHz, whereas a consistent double-peak feature is observed for microwires with h = 8.07 , 8.72 , and 9.29. The largest GMI effect is achieved for microwires with h = 9.29 . The anisotropy field ( H k ) , determined from GMI curves, increases with h = 4.11 to h = 8.07 and decreases when h > 8.07 . The calculated radial stress decreases as h increases from 4.11 to 9.29. These results provide further insights into the correlation between the GMI effect and microwire dimensions towards the GMI optimization of amorphous glass-coated magnetic microwires for sensor applications.