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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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
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cited_by cdi_FETCH-LOGICAL-c299t-86ae7204df7e2d0e7b75e788593cd4773865bdc24def22ac85534249d4fece093
cites cdi_FETCH-LOGICAL-c299t-86ae7204df7e2d0e7b75e788593cd4773865bdc24def22ac85534249d4fece093
container_end_page
container_issue 22
container_start_page 225703
container_title Nanotechnology
container_volume 32
creator Ye, Fengchao
He, Xinsheng
Zheng, Jiajia
Li, Yancheng
Li, Mengjia
Hu, Zhonglue
Wang, Sisi
Tong, Guoxiu
Li, Xiping
description 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.
doi_str_mv 10.1088/1361-6528/abe9e7
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title Highly stretchable and self-foaming polyurethane composite skeleton with thermally tunable microwave absorption properties
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