Fabrication and enhanced electromagnetic wave absorption properties of sandwich-like graphene@NiO@PANI decorated with Ag particles

The fabrication of sandwich graphene@NiO@PANI decorated with Ag particles was successfully carried out using multi-step method. A facile hydrothermal route (graphene@Ni(OH)2) was used in the first step, and calcination of precursor by tube furnace (graphene@NiO) in second step, followed using a situ...

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Bibliographic Details
Published in:Synthetic metals 2017-07, Vol.229, p.82-88
Main Authors: Wang, Yan, Wu, Xinming, Zhang, Wenzhi, Li, Jinhua, Luo, Chunyan, Wang, Qiguan
Format: Article
Language:English
Subjects:
Absorption
Graphene
Impedance matching
Microwave absorption properties
Nanocomposites
Nickel oxides
Particulate composites
Polyaniline
Polymerization
Studies
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Summary:The fabrication of sandwich graphene@NiO@PANI decorated with Ag particles was successfully carried out using multi-step method. A facile hydrothermal route (graphene@Ni(OH)2) was used in the first step, and calcination of precursor by tube furnace (graphene@NiO) in second step, followed using a situ polymerization (graphene@NiO@PANI), and finally formation of the quaternary composite (graphene@NiO@PANI@Ag) via reduction of AgNO3. The obtained samples were analyzed by kinds of instruments and the electromagnetic parameters demonstrated that the improving EM absorption property (−37.5dB) of graphene@NiO@PANI@Ag was ascribed to the better attenuation constant, impedance matching and enhanced interfacial effects. For graphene@NiO@PANI@Ag, the maximum reflection loss was up to −37.5dB at 13.4GHz, and bandwidth exceeding −10dB was 4.9GHz for a thickness of 3.5mm. Thus, the graphene@ NiO@PANI@Ag composite, with a high EM absorption performance and wide absorbing bandwidth, is a promising microwave absorbent.
ISSN:0379-6779
1879-3290
DOI:10.1016/j.synthmet.2017.05.007