Characterization of Dielectric Properties of Graphene and Graphite Using the Resonant Cavity in 5G Test Band

Abstract This paper presents a study about the dielectric constant εr, dielectric loss tangent tan g(δ) and effective electrical conductivity σe of graphene, graphite and graphene-bakelite combination using the resonant cavity method. For this purpose, cylindrical samples with diameter of 30 mm and...

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Bibliographic Details
Published in:Journal of Microwaves, Optoelectronics and Electromagnetic Applications Optoelectronics and Electromagnetic Applications, 2023-03, Vol.22 (1), p.63-76
Main Authors: Pereira, Vinicius M., Hardt, Luis G., Fantineli, Dieison G., Heckler, Marcos V. T., Armas, Luis E. G.
Format: Article
Language:English
Subjects:
Dielectric constant
dielectric loss constant
ENGINEERING, ELECTRICAL & ELECTRONIC
graphene
graphite
OPTICS
resonant cavity
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Summary:Abstract This paper presents a study about the dielectric constant εr, dielectric loss tangent tan g(δ) and effective electrical conductivity σe of graphene, graphite and graphene-bakelite combination using the resonant cavity method. For this purpose, cylindrical samples with diameter of 30 mm and thickness of 4.5 mm were analyzed taking into account the central frequency f0 = 3.5 GHz, according to 5G technology standards. The constants εr and tan g(δ) were obtained from the resonance frequency fa of measured scattering parameters (S-parameters), when the cavity was loaded with the samples. An empirical equation was developed to model the relation between fa and εr. With this empirical equation it was found εr = 9.3203 and tan g(δ) = 0.7000 for graphene and εr = 17.1508 and tan g(δ) = 0.2700 for graphite. The addition of bakelite in combination with graphene allowed controlling the dielectric properties of these composites. The results, obtained in this macroscale characterization, are interesting for Telecommunications Engineering, especially in the development of radiation-absorbent material, which is suitable for mitigation of interference between different wireless communication systems.
ISSN:2179-1074
2179-1074
DOI:10.1590/2179-10742021v20i3264599