Abstract
We present our studies of the factors affecting soft magnetic properties and giant magnetoimpedance effect in thin amorphous and nanocrystalline microwires. We showed that the magnetoelastic anisotropy is one of the most important parameters that determine magnetic softness and GMI effect of glass-coated microwires and annealing can be very effective for manipulation the magnetic properties of amorphous ferromagnetic glass-coated microwires. Considerable magnetic softening and increasing of the GMI effect is observed in Fe-rich nanocrystalline FINEMET-type glass-coated microwires after the nanocrystallization.
Highlights
Studies of innovative design of electromagnetic materials continue to be an important issue in microwave technology
In soft magnetic amorphous wires subjected to an external magnetic field giant magnetoimpedance (GMI) is in the range of 100% even at frequencies of few GHz [4,5,6]
The annealing even for quite short time and at low temperature leads to significant changing of the magnetic properties of both studied Co-rich microwires (Figs 2a-c)
Summary
Studies of innovative design of electromagnetic materials continue to be an important issue in microwave technology. Composite structural materials containing periodic or random arrays of metallic wires often referred to as wire metamaterials have a strong dispersion of the dielectric function in the GHz frequency band. This behaviour could be of plasmonic or resonance type for long or short-cut wires, respectively [1,2]. Recent few years studies of glass-coated magnetic microwires exhibiting excellent sift magnetic properties and Giant magnetoimpedance effect gained considerable attention[5,6,7] These properties are related to cylindrical symmetry as well as to crystalline structure of magnetic wires. We present our recent studies of the factors affecting soft magnetic properties and giant magnetoimpedance (GMI) effect in thin amorphous wires
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