Abstract
Indium-substituted strontium hexaferrites were prepared by the conventional solid-phase reaction method. Neutron diffraction patterns were obtained at room temperature and analyzed using the Rietveld methods. A linear dependence of the unit cell parameters is found. In3+ cations are located mainly in octahedral positions of 4fVI and 12 k. The average crystallite size varies within 0.84–0.65 μm. With increasing substitution, the TC Curie temperature decreases monotonically down to ~ 520 K. ZFC and FC measurements showed a frustrated state. Upon substitution, the average and maximum sizes of ferrimagnetic clusters change in the opposite direction. The Mr remanent magnetization decreases down to ~ 20.2 emu/g at room temperature. The Ms spontaneous magnetization and the keff effective magnetocrystalline anisotropy constant are determined. With increasing substitution, the maximum of the ε/ real part of permittivity decreases in magnitude from ~ 3.3 to ~ 1.9 and shifts towards low frequencies from ~ 45.5 GHz to ~ 37.4 GHz. The maximum of the tg(α) dielectric loss tangent decreases from ~ 1.0 to ~ 0.7 and shifts towards low frequencies from ~ 40.6 GHz to ~ 37.3 GHz. The low-frequency maximum of the μ/ real part of permeability decreases from ~ 1.8 to ~ 0.9 and slightly shifts towards high frequencies up to ~ 34.7 GHz. The maximum of the tg(δ) magnetic loss tangent decreases from ~ 0.7 to ~ 0.5 and shifts slightly towards low frequencies from ~ 40.5 GHz to ~ 37.7 GHz. The discussion of microwave properties is based on the saturation magnetization, natural ferromagnetic resonance and dielectric polarization types.
Highlights
Indium-substituted strontium hexaferrites were prepared by the conventional solid-phase reaction method
The O2− anions are closed packed with the Sr2+ and Fe3+ cations in the interstitial positons
The linear increasing behavior of the unit cell parameters in accordance with the Vegard’s low was established which was explained by the radii of the substituted and substituting cations
Summary
Indium-substituted strontium hexaferrites were prepared by the conventional solid-phase reaction method. The development of new information technologies and wireless data transmission systems[5] is based on materials with high microwave characteristics Such materials are mainly composites of complex oxides of transition m etals[6]. For hexaferrites with the M-type magnetoplumbite structure, high values of dielectric and magnetic permeability in the microwave region are especially distinguished[14]. One of the representatives of hard magnetic materials with a ferrimagnetic structure is M-type strontium hexaferrite S rFe12O1915. There are short Fe–Fe lengths in the structure, and at 4 fVI positions these Fe–Fe lengths are ~ 2.7 Å Such a complex unit cell is characterized by significant crystalline anisotropy, which is reflected in the ratio of lattice parameters c/a ≈ 3.96. The samples presented coercive field in the range of 3–5 kOe and remanence magnetization in the range of 33–36 emu/g18
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