Co0.2Fe2.8O4/C composite nanofibers with designable 3D hierarchical architecture for high-performance electromagnetic wave absorption

High-performance electromagnetic (EM) wave absorption property could be achieved by architecture design of nanomaterials. Herein, two layer hybrid Co0.2Fe2.8O4/carbon nanofibers with porous three-dimensional (3D) hierarchical structure were synthesized successfully through facile electrospinning, carbonization and mild chemical treatment. The Co0.2Fe2.8O4 particles grew along the carbon nanofibers, forming the enhanced heterogeneous interfaces and high specific areas. As expected, the EM wave absorbent showed an excellent absorbing capability. The composites achieved a maximum reflection loss (RL) of -43.45 dB at 11.1 GHz with thickness of 3.0 mm. More importantly, the effective bandwidth (RL <= -10dB) was 5.85 GHz, covering 30% of the entire measured bandwidth. The absorption intensity and bandwidth were superior to other typical CoFebased composites. The intrinsic mechanism of the absorption revealed that the polarization losses, magnetic losses, magnetic natural resonance and exchanged resonance losses contributed to the high-performance microwave absorption. Moreover, good impedance matching and complex transmission paths that generated from unique porous network also played an important role. This study is expected to guide future exploration on designing and synthesizing high performance EM wave absorbents.

Automated summary

High-performance electromagnetic wave absorption can be achieved through architecture design of nanomaterials. The synthesized two layer hybrid Co0.2Fe2.8O4/carbon nanofibers with porous three-dimensional hierarchical structure showed excellent absorbing capability, with a maximum reflection loss of -43.45 dB at 11.1 GHz and an effective bandwidth of 5.85 GHz.