Abstract
Electromagnetic radiation can cause serious harm to the human body, such as the rise in body temperature and the decrease in immune function. In this study, the carbon nanotubes (CNTs)/Fe3O4 nonwovens were used to prepare wearable flexible absorbing materials. First, the single-layer absorbing structures were prepared by hot rolling, dipping, and film fabrication, respectively. Then, the single-layer structures were combined to form the multi-layer absorbing structures. By testing and analyzing the absorbing performance of various structures in the X-band frequency range, the optimum combination scheme was found, together with a good reflection loss value of CNTs/Fe3O4 nonwoven material. The experiment results displayed that the single-layer hot-rolled nonwovens modified by CNTs have the best wave absorbing performance. Its minimum reflection loss of −18.59 dB occurred at 10.55 GHz, and the efficient frequency occurred at 8.86–12.40 GHz. The modified film can significantly improve the absorbing performance of multi-layer structures. In addition, the absorbing performance was closely related to both the place where the absorbing film was introduced and the type of absorbing fillers. When the film-forming CNTs (FC) film was located at the bottom layer of the multi-layer structure, the hot rolled CNTs hot rolled mixed reagent film forming CNTs (HC-HM-FC) structure constructed exhibited the best absorbing effects. Its minimum reflection loss can reach −33 dB, and the effective absorbing frequency range covered half of the X-band.
Highlights
The electronics industry is booming with the rapid development of technology
Their difference lies in the different fillers, which are carbon nanotubes (CNTs), Fe3O4 powder and hybrid fillers, respectively
After the PET needle-punched cloth is impregnated and knife-coated, the tubular CNTs dispersed in the aqueous solution are dispersed into the pores of the PET needle-punched cloth along with the flow [22]
Summary
The electronics industry is booming with the rapid development of technology. 0.66 wt.% CNTs sponge/ 99.34 wt.% epoxy composite showed an EMI shielding effectiveness of around 33 dB in the X-band [6], which is higher than that of 20 wt.% conventional CNTs / 80 wt.% epoxy nanocomposites Another 3D 2.76 wt.% Fe3O4-CNTs/ 0.24 wt.% rGO Foam/ 97% EP nanocomposites displayed high electromagnetic interference SE value of 36 dB within the X-band, an almost 482% enhancement compared to Fe3O4-CNTs/ EP nanocomposites without three-dimensional structure (approximately 6 dB) [7]. The research on the absorbing function of textile materials is mainly focused on the absorbing agents [15,16,17,18], and there is limited research on enhancing the absorbing function by constructing new textile material structures These studies either have poor electromagnetic absorbing performance or require complex processing technology. The absorbing performances of all absorbing structures were tested, and the relationship between the multi-layer structures and electromagnetic absorbing performances were analyzed to find the optimal combination scheme, together with a good reflection loss value of CNTs/Fe3O4 nonwoven material
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