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Frequency tunable Ni–Ti‐substituted Ba–M hexaferrite for efficient electromagnetic wave absorption in 8.2–75 GHz range

Seong Jun Cheon, Jae Ryung Choi, Sang‐Bok Lee, J.-I. Lee, Horim Lee

2023Journal of Alloys and Compounds32 citationsDOIOpen Access PDF

Abstract

The development of 5 G telecommunication technology, has seen a high demand for effective electromagnetic (EM) wave absorbers in the millimeter wave (mmWave) band. Because hexagonal M‐type ferrite is known to have high ferromagnetic resonance (FMR) in the 5 G band frequency, it has attracted significant attention as a mmWave absorber. However, study of the relationship between magnetocrystalline anisotropy, FMR frequency, and EM wave absorption performance in the mmWave band remains insufficient. In this study, Ni–Ti‐substituted M‐type barium ferrite (Ba–M ferrite) was synthesized using the citrate sol–gel method, and the change in the magnetic properties caused by Ni–Ti substitution was analyzed. The complex permittivity, permeability, and reflection loss (RL) of the Ni–Ti‐substituted Ba–M ferrite composites in the 8.2–75 GHz broadband frequency range were also studied. The EM wave absorption frequency, which is governed by the FMR frequency, could be tuned by controlling the amount of substituted Ni–Ti ions in the Ba–M ferrite. The prepared EM wave absorber exhibited excellent EM wave absorption properties with an RL of −52 dB at 29.5 GHz and a matching thickness of 0.95 mm. This study provides insights into a frequency‐tunable EM wave absorber with enhanced absorption properties, attained by changing the magnetic properties of Ni–Ti‐substituted M‐type hexaferrites in the mmWave frequency band.

Topics & Concepts

Materials scienceFerrite (magnet)Barium ferritePermittivityMicrowaveExtremely high frequencyReflection lossFerromagnetic resonanceMagnetocrystalline anisotropyAbsorption bandElectromagnetic radiationX bandAbsorption (acoustics)OptoelectronicsOpticsMagnetic anisotropyDielectricComposite materialMagnetizationMagnetic fieldComposite numberTelecommunicationsPhysicsComputer scienceQuantum mechanicsElectromagnetic wave absorption materialsAdvanced Antenna and Metasurface TechnologiesMagnetic Properties and Synthesis of Ferrites