Testing of magnetic and dielectric traits of microwave plasma treated NiCuZn spinel ferrites for efficient energy storage and high-frequency applications

In this study, the dielectric, microstructural, and magnetic characteristics of NiCuZnFe2O4 ferrites, produced by an auto-ignition method, were tuned through microwave non-thermal plasma treatment. XRD analysis confirmed the cubic spinel structure with an average crystallite size of 47.7 nm. It was also witnessed that plasma treatment slightly increased the porosity of prepared samples. FTIR analysis confirmed the appearance of absorption bands in the range of 450-700 cm(-1), which are assigned to spinel ferrites. The pristine spinel ferrite microstructures demonstrated sharp grain boundaries and agglomeration appeared in all specimens due to magnetic interactions. A slight decline in particle size in the plasma-treated sample was noticed in these investigations. VSM analysis revealed saturation magnetization of 31.70 emu/g and 53.20 emu/g for pristine ferrite and after 45 min of plasma treatment, respectively. Dielectric measurements demonstrated that plasma exposure significantly reduced the dielectric loss and improved the dielectric constant.

Automated summary

The dielectric, microstructural, and magnetic characteristics of NiCuZnFe2O4 ferrites were tuned through microwave non-thermal plasma treatment. XRD analysis confirmed the cubic spinel structure with an average crystallite size of 47.7 nm. Plasma treatment slightly increased the porosity of the samples, and FTIR analysis confirmed the appearance of absorption bands assigned to spinel ferrites. Pristine ferrite microstructures showed sharp grain boundaries and agglomeration due to magnetic interactions, but a slight decline in particle size was observed in the plasma-treated sample. VSM analysis revealed an increase in saturation magnetization after plasma treatment. Dielectric measurements demonstrated a significant reduction in dielectric loss and an improvement in dielectric constant after plasma exposure.