Magnetocapacitance on the transition fields in Ni2+doped Y-type hexaferrite Ba0.6Sr1.4Co2Fe11AlO22 obtained by high-energy ball milling

Y-type hexaferrites possess multiple magnetic phases that are temperature and magnetic-field dependent. Some of these phases are ferrimagnetic and also exhibit room temperature spin-driven ferroelectricity that corresponds to a type-II magnetoelectric. The temperature stability and the magnetic activation field of the multiferroic phases of Y-type hexaferrite can be tuned by substituting Co2+ sites with transition metal ions, such as Ni2+. The present work describes a simple method for obtaining Y-type hexaferrites using high-energy ball milling with heat treatment at relative low temperatures, compared with other methods, and evaluates the effect of nickel as dopant in Ba0.6Sr1.4Co2-xNixFe11AlO22, with x varying from 0 to 2.0 (& UDelta;x = 0.5), on the magnetic, dielectric, and magnetodielectric properties. The results show successful synthesis of pure hexagonal Y-type hexaferrite (R-3 m) by an easy and economical method. In addition, it is observed that nickel doping produces a diminution in the specific magnetization, a change in the magnetic thresholds of the magnetic phases, and an increase in space charge polarization. In addition, the magnetodielectric measurements also show different positive magnetocapacitance behaviors linked to the effect of doping on the magnetic and electronic structure.

Automated summary

This study presents a simple method for synthesizing pure hexagonal Y-type hexaferrite using high-energy ball milling and low-temperature heat treatment. The effect of nickel doping on the magnetic, dielectric, and magnetodielectric properties is investigated. The results show that nickel doping reduces the specific magnetization, changes the magnetic thresholds of the magnetic phases, and increases space charge polarization. The magnetodielectric measurements also reveal different positive magnetocapacitance behaviors related to the effect of doping on the magnetic and electronic structure.