Dielectric permittivity and microwave absorption properties of SiC nanowires with different lengths

SiC nanowires with different lengths were prepared, and the effect of nanowire length on their dielectric permittivity and microwave absorption properties were investigated. The results reveal that SiC nanowires with longer length can improve the electrical conductivity of microwave absorbing materi...

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Bibliographic Details
Published in:Solid state sciences 2019-05, Vol.91, p.73-76
Main Authors: Kuang, Jianlei, Jiang, Peng, Hou, Xianjie, Xiao, Ting, Zheng, Qianfang, Wang, Qi, Liu, Wenxiu, Cao, Wenbin
Format: Article
Language:English
Subjects:
Conduction loss
Electrical conductance network
Microwave absorption
Nanowire length
SiC nanowires
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Summary:SiC nanowires with different lengths were prepared, and the effect of nanowire length on their dielectric permittivity and microwave absorption properties were investigated. The results reveal that SiC nanowires with longer length can improve the electrical conductivity of microwave absorbing materials. This may be attributed to the fact that longer nanowires are more easily to interconnect with each other, which facilitates the construction of a more complete electrical conduction network in the matrix. Cole-Cole curves also indicate that with increasing nanowire length, the dominant loss mechanism of SiC nanowires is changed from polarization loss to conductance loss. Therefore, the conductivity-dependent dielectric permittivity and microwave absorbing ability of SiC nanowires were significantly improved with the increase in the nanowire lengths. [Display omitted] •SiC nanowires with different nanowire lengths were prepared.•Dielectric permittivity and microwave absorption properties were investigated.•Longer SiC nanowires exhibit higher permittivity and microwave absorption ability.•Longer SiC nanowires are much easier to form a complete conduction loss network.•With increasing nanowire length, the conduction loss dominates absorption ability.
ISSN:1293-2558
1873-3085
DOI:10.1016/j.solidstatesciences.2019.03.015