@article{Gai2025, 
author = {Lixue Gai and Yongzheng Chen and Yan Wang and Xijiang Han and Ping Xu and Yunchen Du},
title = {Engineering impedance-matched double-shells in hollow Co/carbon microspheres with gradient graphitization for high-efficiency electromagnetic wave absorption},
year = {2025},
journal = {Journal of Advanced Ceramics},
volume = {14},
number = {12},
pages = {9221212},
keywords = {impedance matching, hollow structure, electromagnetic (EM) wave absorption, gradient graphitization, Co/C microspheres},
url = {https://www.sciopen.com/article/10.26599/JAC.2025.9221212},
doi = {10.26599/JAC.2025.9221212},
abstract = {The inherent trade-off between impedance matching and electromagnetic (EM) attenuation capability has long been a fundamental limitation in carbon-based materials, hindering further advances in their EM absorption performance. To overcome this challenge, we innovatively designed hollow double-shell Co/carbon microspheres with a gradient graphitization structure, where Co3O4 nanoparticles preanchored on melamine formaldehyde (MF) microspheres can induce the formation of graphitic inner shells during high-temperature pyrolysis; nevertheless, the outer carbon shells remain amorphous due to the lack of corelated species, ultimately resulting in gradient graphitization from the inside. This unique double-shell architecture combines the advantages of both gradient graphitization and a hollow structure, which are favorable for powerful EM attenuation and impedance matching at the same time. EM analyses revealed that the outer amorphous carbon shells not only play a key role in optimizing impedance matching but also create heterogeneous interfaces with the inner graphitic shells to enhance interfacial polarization. As a result, the as-prepared sample achieves a superior reflection loss (RL) of −62.9 dB, and its maximum effective absorption bandwidth (EABmax) can be extended to 11.3 GHz through a rationally designed multilayer structure, significantly surpassing that of its nongradient counterparts. Computer simulation technology (CST) simulations further verify a remarkable radar cross-section (RCS) reduction of 22.3 dB·m2. This work provides an effective strategy for reconciling the conflict between impedance matching and attenuation in carbon-based materials and demonstrates their great potential as lightweight and broadband EM wave absorbing materials (EWAMs) in the future.}
}