Hollow microspheres of polypyrrole/magnetite/carbon nanotubes by spray-dry as an electromagnetic synergistic microwave absorber

Combining dielectric and magnetic components has been regarded as a promising way to develop functional materials with outstanding microwave absorption (MA) performance. However, it remains a tremendous challenge to assemble multi components into an integrated composite with suitable impedance matching via conventional wet chemical methods. Herein, ternary polypyrrole@Fe3O4/carbon nanotubes (PPy@Fe3O4/CNTs) microspheres with special hollow structure were successfully fabricated via a facile spray-dry method, which can realize rational assembly of magnetic and dielectric components. Hollow PPy@Fe3O4/CNTs spheres simultaneously avoid the agglomeration of magnetic particles while achieve the synergistic absorption. The maximum reflection loss of PPy@Fe3O4/CNTs absorber reached -51.8 dB at 8.8 GHz at the thickness of 2.38 mm. The relationship among components, structure and MA performance was also studied. As MA units, multi-component PPy@Fe3O4/CNTs microspheres effectively combine conductive polymer (PPy), strong magnetic Fe3O4 and high-conductivity CNTs. Thus, the composite gains the advantage of complementation of dielectric, magnetic and conductive loss. Meanwhile, reasonable assembling of different components constructs abundant interfaces which can enhance dielectric polarization and hence improve absorption capacity. The special structure optimizes the distribution of CNTs, helping the composites to achieve better impedance matching. Overall, this work introduces an excellent microwave absorber and gives a new thought of material design. (C) 2021 Published by Elsevier Ltd.

Automated summary

Combining dielectric and magnetic components to develop functional materials with outstanding microwave absorption is a promising approach, though assembling multi components with suitable impedance matching remains challenging. Here, ternary PPy@Fe3O4/CNTs microspheres with hollow structure were successfully fabricated via a spray-dry method, enabling rational assembly of magnetic and dielectric components. The composite achieved excellent microwave absorption performance at 8.8 GHz, with a maximum reflection loss of -51.8 dB.