Power capacity enhancement and loss reduction induced by limited solid solubility of Ho <sup>3+</sup> rare-earth substitution in NiCuZn spinel ferrites
Hanyu Zhang, Qifan Li, Xiaona Jiang, Chuanjian Wu, Ke Sun, Zhongwen Lan, Zhong Yu
Abstract
The application of NiCuZn ferrites (NCZFs) in high-power communication systems is constrained by their nonlinear excitation. To reduce nonlinear effects, it is essential for ferrite materials to possess a relatively high spin-wave linewidth (Δ<i>H</i><sub>k</sub>). Doping with ions such as cobalt and rare-earth (RE) ions with fast relaxation has proven effective in increasing Δ<i>H</i><sub>k</sub> of ferrites. However, the regulatory mechanism of doping NCZFs with RE ions with larger ionic radii remains unclear. In this study, Ho<sup>3+</sup>-substituted NCZFs were synthesized via a solid-state reaction route. The spatial distribution and substitution amount of the Ho<sup>3+</sup> ions were carefully investigated via elemental and phase composition analysis, revealing the limited solid solubility of the Ho<sup>3+</sup> ions in NCZFs. Some of the Ho<sup>3+</sup> ions enter the lattice and occupy the octahedral sites, accelerating relaxation and increasing Δ<i>H</i><sub>k</sub> to a maximum value of 2.63 kA·m<sup>−1</sup>. Insoluble Ho<sup>3+</sup> ions combine with Fe<sup>3+</sup> ions to form a HoFeO<sub>3</sub> heterogeneous phase with Fe<sup>3+</sup> ions at the grain boundaries, leading to iron deficiency within NCZF crystals and significantly reducing the dielectric loss tangent at microwave frequencies. These results reveal the great potential of Ho<sup>3+</sup>-substituted NCZFs for high-power, low-loss microwave applications.