Enhancement of Electromagnetic Wave Attenuation through Polarization Loss Induced by Hybridization of Rare‐Earth 4f and Mo‐4d Orbitals in Liquid Plasma

Wen, Jiaming; Hui, Shengchong; Chang, Qing; Chen, Geng; Zhang, Limin; Fan, Xiaomeng; Tao, Kai; Wu, Hongjing

doi:10.1002/adfm.202410447

Adv Funct Materials

2024

DOI: 10.1002/adfm.202410447

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Enhancement of Electromagnetic Wave Attenuation through Polarization Loss Induced by Hybridization of Rare‐Earth 4f and Mo‐4d Orbitals in Liquid Plasma

Jiaming Wen,

Shengchong Hui,

Qing Chang

et al.

Abstract: The incorporation of large‐sized rare earth (RE) elements with high coordination characteristics into transition metal dichalcogenide (TMD) absorbers while preserving a high 1T phase content during post‐processing poses a significant challenge. To address this, a novel strategy involving the confinement of RE elements within the 1T‐MoS2 lattice via liquid plasma assistance, is proposed. This approach effectively mitigates the environmental impact on the 1T phase of MoS2, yielding a remarkable 1T phase content … Show more

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Cited by 8 publications

References 64 publications

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Dual‐coupling networks engineering of self‐assembled ferromagnetic microspheres with enhanced interfacial polarization and magnetic interaction for microwave absorption

Xu,

Xiong,

et al. 2024

InfoMat

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The simultaneous enhancement of magnetic and dielectric properties in nanomaterials is becoming increasingly important for achieving exceptional microwave absorption performance. However, the engineering strategies for modulating electromagnetic responses remain challenging, and the underlying magnetic‐dielectric loss mechanisms are not yet fully understood. In this study, we constructed novel dual‐coupling networks through the tightly packed Fe3O4@C spindles, which exhibit both dielectric and magnetic dissipation effects. During the spray‐drying process, vigorous self‐assembly facilitated the formation of hierarchical microspheres composed of nanoscale core‐shell ferromagnetic units. Numerous heterogeneous interfaces and abundant magnetic domains were produced in these microspheres. The integrated dielectric/magnetic coupling networks, formed by discontinuous carbon layers and closely arranged Fe3O4 spindles, contribute to strong absorption through intense interfacial polarization and magnetic interactions. The mechanisms behind both magnetic and dielectric losses are elucidated through Lorentz electron holography and micromagnetic simulations. Consequently, the hierarchical microspheres demonstrate excellent low‐frequency absorption performance, achieving an effective absorption bandwidth of 3.52 GHz, covering the entire C‐band from 4 to 8 GHz. This study reveals that dual‐coupling networks engineering is an effective strategy for synergistically enhancing electromagnetic responses and improving the absorption performance of magnetic nanomaterials.image

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Dual‐coupling networks engineering of self‐assembled ferromagnetic microspheres with enhanced interfacial polarization and magnetic interaction for microwave absorption

Xu,

Xiong,

et al. 2024

InfoMat

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Research progress of NiCo2O4-based composites in microwave absorption: a review

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Han,

Liu

et al. 2024

J Mater Sci

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Sun,

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et al. 2025

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Enhancement of Electromagnetic Wave Attenuation through Polarization Loss Induced by Hybridization of Rare‐Earth 4f and Mo‐4d Orbitals in Liquid Plasma

Cited by 8 publications

References 64 publications

Dual‐coupling networks engineering of self‐assembled ferromagnetic microspheres with enhanced interfacial polarization and magnetic interaction for microwave absorption

Dual‐coupling networks engineering of self‐assembled ferromagnetic microspheres with enhanced interfacial polarization and magnetic interaction for microwave absorption

Research progress of NiCo2O4-based composites in microwave absorption: a review

CO2 plasma inducing steel-slag with active sites for efficient growth of carbon nanotubes for the high-performance microwave absorption

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