Structure, magnetoelectric properties and microwave absorption properties of Dy-doped Z-type hexaferrite Ba3Co2Fe24-xDyxO41

Rare earth dysprosium-doped Z-type hexaferrite were synthesized by the sol-gel method. The synthesized material has a uniform particle size and a typical hexagonal flake shape. The research results show that the samples have excellent soft magnetic properties, and the saturation magnetization of the samples increases gradually with the increase of the doping amount of Dy. In addition, it is also found that the doping of trace dysprosium has a significant effect on the improvement of microwave absorption properties of Z-type hexaferrite. Specifically, when the doping amount is x = 0.05, the sample not only exhibits an excellent reflection loss value of -52.6dB at 5.25 GHz, but also has a maximum effective absorption bandwidth (RL<-10dB) of 6.6 GHz, encompassing both C-band and X-band. When the amount of doping is excessive, an impurity phase will be generated, and the magnetic properties and microwave absorption properties of the material will be reduced, indicating that doping an appropriate amount of Dy3+ will improve the microwave absorption property of Z-type hexaferrite.

Automated summary

Rare earth dysprosium-doped Z-type hexaferrite with uniform particle size and hexagonal flake shape were synthesized by the sol-gel method. The samples exhibit excellent soft magnetic properties, with saturation magnetization increasing gradually with the amount of Dy doping. Trace doping of dysprosium significantly improves the microwave absorption properties of Z-type hexaferrite, with a sample doped at x = 0.05 showing an exceptional reflection loss value of -52.6dB at 5.25 GHz and a maximum effective absorption bandwidth of 6.6 GHz, covering both C-band and X-band. Excessive doping leads to impurity phase generation and reduction in magnetic properties and microwave absorption, highlighting the importance of appropriate Dy3+ doping for enhancing the microwave absorption property of Z-type hexaferrite.