Three-dimensional conductive network constructed by in-situ preparation of sea urchin-like NiFe2O4 in expanded graphite for efficient microwave absorption

• Published in: Journal of colloid and interface science Vol. 650; no. Pt A; pp. 710 - 718
• Main Authors: Deng, Shuanglin, Jiang, Jie, Wu, Dan, He, Qinchuan, Wang, Yiqun
• Format: Journal Article
• Language: English
• Published: Elsevier Inc 15.11.2023
• Subjects: absorption; computer simulation; electrical conductivity; electromagnetic radiation; Electromagnetic wave absorption; energy; Expanded graphite; graphene; magnetism; microwave treatment; RCS simulation; Sea urchin-like NiFe2O4; surface area; synergism; wavelengths; RCS simulation; Expanded graphite; Electromagnetic wave absorption; Sea urchin-like NiFe2O4
• ISSN: 0021-9797; 1095-7103; 1095-7103
• DOI: 10.1016/j.jcis.2023.07.003

[Display omitted] Expanded graphite (EG) is a modified conductive lamellar carbon that has been widely studied in the field of electromagnetic wave absorption due to its low density, good electrical conductivity, and unique structure. However, its application is limited because the interlayer gap cannot match microwave wavelength, and its single composition has less microwave loss. In this study, sea urchin-like NiFe2O4/EG composites are prepared in situ between expanded graphite layers by microwave treatment. The sea urchin-like NiFe2O4 grows between the expanded graphite to form a three-dimensional conductive network structure, which enhances conductive loss of composites and further increases the interlayer distance of EG. The extended interlayer distance promotes multiple reflections and scattering of electromagnetic waves in composites and improves dielectric properties. In addition, EG with a large specific surface area provides many active sites, further promoting interface and dipole polarization. Benefiting from synergistic effect of NiFe2O4 and EG, magnetic loss and dielectric loss of NiFe2O4/EG composites have been improved and impedance matching is further enhanced. The results indicate that the minimal reflection loss of NiFe2O4/EG-4 reaches −53.47 dB at 2.69 mm, and the effective absorption bandwidth reaches 2.97 GHz. In addition, based on the computer simulation technology results, NiFe2O4/EG can attenuate microwave energy under experimental conditions. This work provides a strategy for synthesizing carbon matrix composites with adjustable dielectric parameters and electromagnetic wave properties.