Journal
SURFACES AND INTERFACES
Volume 40, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.surfin.2023.103069
Keywords
HoFeO3; Poly(EDOT-co-CNIn); Free-space measurement; Electromagnetic wave absorption
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This study presents the development of a new microwave absorbent material with low thickness, minimum reflection loss and effective absorption bandwidth utilizing a nanocomposite architecture. The synthesized composite material, consisting of polygonal HoFeO3 powder encapsulated with Poly(EDOT-co-CNIn), demonstrates improved impedance matching abilities and a high absorption capacity compared to other samples. The design strategy and measurement techniques presented in this work offer practical solutions for creating effective microwave absorbents.
New microwave absorbents with low thickness, minimum reflection loss and effective absorption bandwidth microwave absorption capabilities are urgently needed, but their realization remains still challenging. For this study, we used an innovative nanocomposite architecture comprised of polygonal HoFeO3 powder encapsulated with Poly(EDOT-co-CNIn) to create an electromagnetic wave absorption material optimized for the X-band fre-quency. Structural, morphological, magnetic, and microwave absorption characteristics of synthesized nano-composite materials were evaluated utilizing XRD, FTIR, FESEM, VSM, and VNA techniques. With 35 wt.% filler loading, HoFeO3@Poly(EDOT-co-CNIn) composite absorber achieves a minimum reflection loss (RLmini) of-40 dB having 1.6 mm thickness, as measured by the waveguide method. Compared to other absorber samples optimal sample featured improved impedance matching abilities, better attenuation coefficient and a high absorption capacity. The optimal sample is also tested using the free-space measurement technique having dimensions of 200 mm x 200 mm and thus the findings show that they accord well with those of the waveguide approach. This work presents a design strategy for an effective microwave absorbent with practical measuring strategies for both waveguide and free-space setups.
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