Review—Goodenough-Kanamori-Anderson Rules-Based Design of Modern Radio-Frequency Magnetoceramics for 5G Advanced Functionality

Harris, Vincent G.; Andalib, Parisa

doi:10.1149/2162-8777/ac71c4

Cited by 8 publications

(4 citation statements)

References 128 publications

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“…This in turn also determines the magnetic characteristics of the material, whereby normal spinels exhibit antiferromagnetism, and the inverse exhibit ferromagnetism, as described by the Goodenough-Kanamori rules. , One can predict which type of structure should be adopted by a given spinel (and thus its magnetic properties) based on a calculation of the crystal field stabilization energy (CFSE) resulting from each possible ordering of spins across the octahedral and tetrahedral sites, e.g., for magnetite (Fe II Fe III 2 O 4 ): Fe oct 3 + → ( 3 × 0.4 Δ oct ) − ( 2 × 0.6 Δ oct ) → CFSE = 0 Fe tet 3 + → ( 2 × 0.6 Δ tet ) − ( 3 × 0.4 Δ tet ) → CFSE = 0 Fe oct 2 + → ( 4 × 0.4 Δ oct ) − ( 2 × 0.6 Δ oct ) → CFSE = 0.4 normalΔ oct − normalP …”

Section: Introductionmentioning

confidence: 99%

“…This in turn also determines the magnetic characteristics of the material, whereby normal spinels exhibit antiferromagnetism, and the inverse exhibit ferromagnetism, as described by the Goodenough-Kanamori rules. 13 , 14 One can predict which type of structure should be adopted by a given spinel (and thus its magnetic properties) based on a calculation of the crystal field stabilization energy (CFSE) resulting from each possible ordering of spins across the octahedral and tetrahedral sites, e.g., for magnetite (Fe II Fe III 2 O 4 ): where Δ oct is the octahedral field stabilization energy, Δ tet the tetrahedral field stabilization energy, and P the spin pairing energy. Note that Δ oct is ×2.25 Δ tet , and so while there is no preference for where the Fe 3+ ions reside, the CFSE is maximized when Fe 2+ ions solely occupy the octahedral sites in the lattice.…”

Section: Introductionmentioning

confidence: 99%

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Introducing Materials Science: Experimenting with Magnetic Nanomaterials in the Undergraduate Chemistry Laboratory

et al. 2023

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Materials science research has expanded significantly in recent years; a multidisciplinary field, home to an ever-growing number of chemists. However, our general chemistry degree courses have not changed to reflect the rise in interest in this topic. In this paper, we propose a laboratory experiment for the undergraduate chemistry practical course, which may serve as a hands-on introduction to this field. The experiment involves the synthesis and characterization of magnetic materials via commonly employed techniques in materials science. Students begin by producing three metal ferrite spinels using a sol–gel combustion synthesis. They must then characterize the differing magnetic properties across their three samples using a magnetic susceptibility balance. In the second part of the experiment, students must create a ferrofluid via coprecipitation, from which they may observe the phenomenon of “spiking” in response to an external magnet. Additional data such as X-ray diffraction (XRD) patterns and transmission electron microscopy (TEM) images corresponding to these materials are also provided, and students are tasked with the interpretation of these data in their writeup report. Upon completion, students should gain a new-found understanding of materials science and its fundamental overlap with chemistry.

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Section: Introductionmentioning

confidence: 99%

“…This in turn also determines the magnetic characteristics of the material, whereby normal spinels exhibit antiferromagnetism, and the inverse exhibit ferromagnetism, as described by the Goodenough-Kanamori rules. 13 , 14 One can predict which type of structure should be adopted by a given spinel (and thus its magnetic properties) based on a calculation of the crystal field stabilization energy (CFSE) resulting from each possible ordering of spins across the octahedral and tetrahedral sites, e.g., for magnetite (Fe II Fe III 2 O 4 ): where Δ oct is the octahedral field stabilization energy, Δ tet the tetrahedral field stabilization energy, and P the spin pairing energy. Note that Δ oct is ×2.25 Δ tet , and so while there is no preference for where the Fe 3+ ions reside, the CFSE is maximized when Fe 2+ ions solely occupy the octahedral sites in the lattice.…”

Section: Introductionmentioning

confidence: 99%

Introducing Materials Science: Experimenting with Magnetic Nanomaterials in the Undergraduate Chemistry Laboratory

et al. 2023

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“…Ferrite materials provide the necessary magnetic media to break time-reversal symmetry, allowing non-reciprocal behavior to passive control elements, such as circulators and isolators [1][2][3]. Despite progress over the past several decades, these devices remain comparatively large and heavy, mostly due to the external permanent magnets required to provide the necessary bias fields to saturate the ferrite.…”

Section: Introductionmentioning

confidence: 99%

“…Broadband, low-loss properties are prerequisites for high-performing, high-frequency, and self-biased MMW devices based on crystallographically textured Ba-hexaferrites [3]. Improved remanent magnetization, 4πM r , and narrow ferromagnetic resonance linewidths, ∆H FMR , allow for the reduction in resonance losses [8] and optimized anisotropy fields, H a .…”

Section: Introductionmentioning

confidence: 99%

Crystallographically Textured and Magnetic LaCu-Substituted Ba-Hexaferrite with Excellent Gyromagnetic Properties

Jiao

Wang

Wei³

et al. 2022

Materials

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Excellent gyromagnetic properties of textured, bulk Ba-hexaferrite samples are required for low-loss, self-biased applications for microwave and millimeter-wave (MMW) devices. However, conventionally processed bulk Ba-hexaferrite ceramics typically demonstrate low remanent magnetization values, 4πMr, of 2.0~3.0 kG, and relatively large ferromagnetic resonance (FMR) linewidths, ΔHFMR, of 0.8~2 kOe. These properties lead to the development of high-performance, practical devices. Herein, crystallographically textured Ba-hexaferrite samples, of the composition Ba0.8La0.2Fe11.8Cu0.2O19, having excellent functional properties, are proposed. These materials exhibit strong anisotropy fields, Ha, of ~14.6 kOe, high remanent magnetization, 4πMr, of 3.96 kGs, and a low ΔHFMR of 401 Oe at zero-bias field at the Q-band. Concomitantly, the broadband millimeter-wave transmittance was utilized to determine the complex permeability, μ*, and permittivity, ε*, of textured hexaferrites. Based on Schlöemann’s theory of complex permeability, μ*, the remanent magnetization, 4πMr, anisotropy field, Ha, and effective linewidth, ΔHeff, were estimated; these values agree well with measured values.

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Goodenough–Kanamori–Anderson Rules of Superexchange Applied to Ferrite Systems

Harris¹,

Andalib²

2022

Modern Ferrites

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Review—Goodenough-Kanamori-Anderson Rules-Based Design of Modern Radio-Frequency Magnetoceramics for 5G Advanced Functionality

Cited by 8 publications

References 128 publications

Introducing Materials Science: Experimenting with Magnetic Nanomaterials in the Undergraduate Chemistry Laboratory

Introducing Materials Science: Experimenting with Magnetic Nanomaterials in the Undergraduate Chemistry Laboratory

Crystallographically Textured and Magnetic LaCu-Substituted Ba-Hexaferrite with Excellent Gyromagnetic Properties

Goodenough–Kanamori–Anderson Rules of Superexchange Applied to Ferrite Systems

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