Hierarchically porous Co/C nanocomposites for ultralight high-performance microwave absorption

Carbon-based composites have gained extensive attention as microwave absorbing materials due to the lighter weight compared with other materials. In this work, Co/C nanocomposites with Co nanoparticles uniformly distributed in amorphous carbon sheets are prepared by a freezing dry and carbothermic r...

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Bibliographic Details
Published in:Advanced composites and hybrid materials 2021-03, Vol.4 (1), p.173-185
Main Authors: Xie, Peitao, Liu, Yuan, Feng, Mei, Niu, Mang, Liu, Chunzhao, Wu, Nannan, Sui, Kunyan, Patil, Rahul Rangrao, Pan, Duo, Guo, Zhanhu, Fan, Runhua
Format: Article
Language:English
Subjects:
Ceramics
Chemistry and Materials Science
Composites
Glass
Materials Engineering
Materials Science
Natural Materials
Original Research
Polymer Sciences
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Summary:Carbon-based composites have gained extensive attention as microwave absorbing materials due to the lighter weight compared with other materials. In this work, Co/C nanocomposites with Co nanoparticles uniformly distributed in amorphous carbon sheets are prepared by a freezing dry and carbothermic reduction process. Hierarchical porous microstructures (micropores, mesopores, macropores) are achieved by ice template and huge amounts of gas during carbothermal reduction. Excellent absorption performance is achieved at a very low Co/C content (10% and 15%), which is a great success to design ultralight absorbers. At 10% content level, the effective absorption bandwidth is 5.0 GHz with a thin thickness of 1.8 mm, while the absorption bandwidth is 4.7 GHz with a thin thickness of 1.5 mm at 15% Co/C content level. The excellent absorption performance is attributed to excellent impedance matching resulting from synergy of cobalt and carbon and strong interfacial polarization induced by the hierarchical porous microstructures. This work provides a new pathway of designing ultralight absorbers with the advantage of thin thickness and wide bandwidth. Graphical Abstract Excellent absorption performance is achieved at only 10% Co/C content level, a success to design ultralight absorbers.
ISSN:2522-0128
2522-0136
DOI:10.1007/s42114-020-00202-z