期刊
CHEMICAL ENGINEERING JOURNAL
卷 405, 期 -, 页码 -出版社
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2020.126927
关键词
Biomass-derived carbon foam; Shaper-memory trans-1,4-polyisoprene; MXene; Adjustable EMI shielding; Self-fixable mechanical deformation
资金
- S&T Innovation 2025 Major Special Programme of Ningbo, China [2018B10054]
- Natural Science Foundation of Ningbo, China [2018A610004]
- National Natural Science Foundation of China, China [51603218]
The study proposes a novel electromagnetic shielding material that can conveniently adjust performance under self-fixable mechanical deformation, exhibiting excellent thermally/electrically stimulated shape memory behaviors. These composites not only can adjust the shielding effectiveness value, but also have smart functions, allowing for performance tuning or switching under different conditions, providing a promising platform for developing smart electromagnetic response applications.
The design and fabrication of novel electromagnetic interference (EMI) shielding materials with the capability of realizing convenient performance regulation under self-fixable mechanical deformation is becoming an urgent challenge due to the increasingly complex application conditions. To alleviate this problem, the composite construction that consisted of compressible carbon foam (CF) and shape-memory polymer coating was proposed, and the demo samples were fabricated by coating trans-1,4-polyisoprene (TPI)-MXene layer onto compressible wood-derived CF with multilayer microstructure. The resultant composites (thickness: similar to 2-10 mm, density: similar to 150 mg/cm(3)) with enhanced shielding effectiveness (SE) of similar to 25.3-44.7 dB could not only adjust their SE value by changing their compressive strains, but also possess excellent thermally/electrically stimulated shape memory behaviors that can be easily deformed and recovered as being heated and fix a temporary shape at low temperature, thereby realizing convenient SE regulation under self-fixable mechanical deformation. Moreover, based on different initial SE performance and compression conditions, the EMI SE of the composites can also be tuned within effective SE range of 20 dB, or switched between > 20 and < 20 dB, exhibiting smart function-tunable or function-switchable feature, which provides a promising platform for developing novel EMI shields for smart electromagnetic response applications.
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