Flexible and flame-retarding phosphorylated MXene/polypropylene composites for efficient electromagnetic interference shielding

•MXene/PP composites are prepared by hot-pressing PP non-woven fabric coated with functionalized MXene.•The final composite exhibits an EMI shielding performance of ∼90 dB (8–12 GHz, thickness ∼400 μm).•The resultant MXene/PP composites are mechanically robust with a superior anti-fatigue capability...

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Bibliographic Details
Published in:Journal of materials science & technology 2022-06, Vol.111, p.66-75
Main Authors: Tang, Tingting, Wang, Shanchi, Jiang, Yue, Xu, Zhiguang, Chen, Yu, Peng, Tianshu, Khan, Fawad, Feng, Jiabing, Song, Pingan, Zhao, Yan
Format: Article
Language:English
Subjects:
EMI shielding
Flame retardancy
MXene
Polypropylene composite
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Summary:•MXene/PP composites are prepared by hot-pressing PP non-woven fabric coated with functionalized MXene.•The final composite exhibits an EMI shielding performance of ∼90 dB (8–12 GHz, thickness ∼400 μm).•The resultant MXene/PP composites are mechanically robust with a superior anti-fatigue capability.•The resultant MXene/PP composites exhibit a self-extinguishing capability. Flame-retardant composites with high electromagnetic interference (EMI) shielding performance are desirable for electronic device packaging. Despite great potential of MXene for high EMI, it still remains a great challenge to develop high-performance flame-retardant polymer/MXene composites with excellent EMI shielding effectiveness because of the poor oxidative stability of MXene. Herein, phosphorylated MXene/polypropylene (PP) composites are prepared by coating phosphorylated MXene on PP fabric followed by spraying polyethylenimine (PEI) and hot-pressing. The phosphorylated MXene proves to be more durable against oxidation than pure MXene due to the protection effect of polyphosphates. Upon hot-pressing, melted PP fibers are fused together at their contact points and thus as-prepared composites are bi-continuous with two interpenetrating phases. The composites show significantly improved thermal stability and flame retardancy relative to pure PP, with a low total heat release (THR) of 3.7 kJ/g and a heat release rate (HRR) of 50.0 W/g, which are reduced by 78% and 87%, respectively. In addition, the composites exhibit a high electrical conductivity of ∼36,700 S/m and an EMI shielding performance of ∼90 dB over the whole frequency range of 8–12 GHz with a thickness of ∼400 μm. The as-developed PP/MXene composites hold great promise for reliable protection of next-generation electronic devices working in complex environments.
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2021.08.091