Magnetoimpedance effect at the high frequency range for the thin film geometry: Numerical calculation and experiment

TL;DR

This paper combines theoretical modeling and experimental measurements to analyze the magnetoimpedance effect in ferromagnetic thin films across a broad frequency spectrum, validating the approach with experimental data.

Contribution

It introduces a comprehensive theoretical and experimental framework for analyzing magnetoimpedance in various thin film structures, confirming its validity through experimental comparison.

Findings

Good agreement between numerical calculations and experiments

The approach effectively describes magnetoimpedance in multilayered films

Analysis highlights advantages of different thin film structures

Abstract

The magnetoimpedance effect is a versatile tool to investigate ferromagnetic materials, revealing aspects on the fundamental physics associated to magnetization dynamics, broadband magnetic properties, important issues for current and emerging technological applications for magnetic sensors, as well as insights on ferromagnetic resonance effect at non-saturated magnetic states. Here, we perform a theoretical and experimental investigation of the magnetoimpedance effect for the thin film geometry in a wide frequency range. We calculate the longitudinal magnetoimpedance for single layered, multilayered or exchange biased systems from an approach that considers a magnetic permeability model for planar geometry and the appropriate magnetic free energy density for each structure. From numerical calculations and experimental results found in literature, we analyze the magnetoimpedance behavior, and discuss the main features and advantages of each structure. To test the robustness of the approach, we directly compare theoretical results with experimental magnetoimpedance measurements obtained in a wide range of frequencies for an exchange biased multilayered film. Thus, we provide experimental evidence to confirm the validity of the theoretical approach employed to describe the magnetoimpedance in ferromagnetic films, revealed by the good agreement between numerical calculations and experimental results.