Poorly-/well-dispersed Fe3O4: Abnormal influence on electromagnetic wave absorption behavior of high-mechanical performance polyurea

[Display omitted] •A novel well-dispersed Fe3O4 with multifunction was successfully prepared via self-assembly technology.•Modified Fe3O4 can endow PUA simultaneously with excellent quasi-static and dynamic mechanical properties.•The abnormal EMW absorbing behaviors of PUA composites with poorly-/we...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-08, Vol.493, p.152833, Article 152833
Main Authors: Sun, Yaru, Liu, Yan, Zou, Yanyan, Wang, Jun, Bai, Fan, Yan, Junbo, Huang, Fenglei
Format: Article
Language:English
Subjects:
Abnormal performance
Dynamic mechanics
Electromagnetic wave absorption
Polyurea nanocomposite
Static mechanics
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Summary:[Display omitted] •A novel well-dispersed Fe3O4 with multifunction was successfully prepared via self-assembly technology.•Modified Fe3O4 can endow PUA simultaneously with excellent quasi-static and dynamic mechanical properties.•The abnormal EMW absorbing behaviors of PUA composites with poorly-/well-dispersed Fe3O4 were found.•Mechanism and modes for this abnormal phenomenon were proposed. In this work, novel core–shell Fe3O4 nanoparticles were prepared by self- assembly technology using phytate-melamine aggregates (PM) or phytate-melamine-Fe3+ aggregates (PM-Fe) as building block. A polyurea (PUA) matrix was filled with magnetic nanoparticle. The influence of Fe3O4, Fe3O4@PM or Fe3O4@PM-Fe content and dispersion on the mechanical and electromagnetic wave (EMW) absorption properties of PUA composite were investigated. Good dispersion of modified Fe3O4 in PUA matrix was obtained. Loading well-dispersed Fe3O4 significantly enhanced the mechanical properties of their PUA nanocomposite under quasi-static tensile, nanoindentation, and dynamic compression tests. Excellent EMW absorption performance of PUA/Fe3O4@PM nanocomposite was desired. Although well-dispersed Fe3O4@PM could effectively enhance the mechanical properties, nonetheless it surprisingly plays a negative role in the EMW absorption performance. The Fe3O4@PM with high dispersion and interfacial compatibility in the PUA matrix was detrimental to EMW absorption performance, which contradicts the well accepted EMW absorption mechanisms. A novel mechanism and model were suggested, along with a fresh understanding of the role of Fe3O4 in the EMW absorption of PUA composite. Furthermore, the Fe3O4@PM-Fe, obtained by constructing a conductive network on the surface of Fe3O4@PM, was used to investigate this assumption. The radar cross section simulation also demonstrated the superior EMW attenuation capability of PUA nanocomposites in the service condition. This work is beneficial to the development of EMW absorber, not limited to Fe3O4 magnetic nanoparticles.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.152833