Highly stretchable and self-foaming polyurethane composite skeleton with thermally tunable microwave absorption properties

Stretchable and lightweight polymer composite material possessing tunable microwave absorption (MA) properties under thermal radiations remain a significant challenge. Here, we proposed a facile strategy to fabricate stretchable, magnetic composite skeletons by incorporating the tadpole-like CNTs@Fe...

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Bibliographic Details
Published in:Nanotechnology 2021-05, Vol.32 (22), p.225703
Main Authors: Ye, Fengchao, He, Xinsheng, Zheng, Jiajia, Li, Yancheng, Li, Mengjia, Hu, Zhonglue, Wang, Sisi, Tong, Guoxiu, Li, Xiping
Format: Article
Language:English
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Summary:Stretchable and lightweight polymer composite material possessing tunable microwave absorption (MA) properties under thermal radiations remain a significant challenge. Here, we proposed a facile strategy to fabricate stretchable, magnetic composite skeletons by incorporating the tadpole-like CNTs@Fe O nanoparticles into self-foaming polyurethane (PU) matrix and the electromagnetic responsive of CNTs@Fe O /PU composite foams with different CNTs contents under heating-cooling cycle in a temperature range of 253 -333 K were carefully investigated. Enhanced complex permittivity and shifting peak frequency were observed at elevated temperatures. For instance, the 70-CNTs@Fe O /PU sample with 15 wt% loading content at 333 K exhibits excellent MA properties including a minimum reflection loss (RL ) of -66.9 dB and ultrabroad effective frequency bandwidth (RL ≤ -20 dB) of 9.98 GHz at the thickness of 1.58-3.37 mm. Meanwhile, great recoverability in terms of RL- profile was achieved in the process of thermal cooling back to 253 K. Such adjustable MA property was attributed to the well-matched impedance and dramatic attenuation ability, benefiting from the temperature-dependant electrical conductivity, abundant interfacial polarization and interior microcellular structures. Besides, the rising temperature increased the sample elongation and electrical conductivity with a slight sacrifice of maximum tensile strength. This stretchable PU skeleton with a unique assembly of CNTs and Fe O nanoparticles are expected to be promising candidates as smart absorbers for application in the harsh environments.
ISSN:0957-4484
1361-6528
DOI:10.1088/1361-6528/abe9e7