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- Title
Electromagnetic Properties and Microwave Absorption of Electrospun Fe<sub>2</sub>O<sub>3</sub>-Carbon Composite Nanofibers with Particle–Nanorod Structure.
- Authors
Xie, Guixu; Cheng, Guoting; Lv, Tianyang; Ma, Junqing; Zhang, Tingting; Zhang, Yurui; Yu, Yang; Jiang, Longlong; Wang, Xiao-Xiong; Long, Yun-Ze
- Abstract
Multifunctional composite nanostructure prepared via electrospinning has attracted wide attention. In this study, Fe2O3-carbon composite nanofiber with particle–nanorod structure was successfully prepared via electrospinning and followed calcination. Then, the electromagnetic properties of this material have been fully characterized, and the influence of different preparation conditions on these properties has been studied. In addition, compared to pure γ -Fe2O3 nanoparticles and hollow Fe2O3 nanofibers, the composite nanofibers with a thickness of 2.64 mm exhibited an additional absorption peak at a frequency of 13.92 GHz and an enhancement in absorption at a frequency of 15.45 GHz, which may be attributed to the increase in electrical loss introduced by amorphous carbon and the enhanced magnetic loss resulting from the multi-stage reflection introduced by the particle–nanorod structure. This study shows that the composite of Fe2O3 and carbon, and the introduction of the particle–nanorod structure can improve the microwave absorption efficiency of materials, and more nanocomposites can be designed like this to further improve their electromagnetic properties and absorption efficiency in the future. Fe2O3-carbon composite nanofibers with particle–nanorod structure are obtained via electrospinning. The size of nanoparticle will increase with the increase of calcination temperature and time, and further electromagnetic and microwave test indicates that the microwave absorption efficiency of materials could be improved by the introduction of the particle–nanorod structure.
- Subjects
CARBON nanofibers; NANOFIBERS; ABSORPTION; MICROWAVES; ELECTROMAGNETIC testing; MAGNETIC flux leakage
- Publication
NANO, 2021, Vol 16, Issue 12, p1
- ISSN
1793-2920
- Publication type
Article
- DOI
10.1142/S1793292021501435