Efficient microwave absorption induced by hierarchical pores of reed-derived ultralight carbon materials

Manipulation on pore structure is an effective approach to reinforce electromagnetic wave absorption function of carbon-based materials. Herein, ultralight carbon materials with hierarchical pores are facilely synthesized from the waste reed through one-step calcination process. Through regulating the porous structure and complex permittivity of pure carbon, it can be found that the strongest microwave absorption peaks appear in different frequency range and shift from a high frequency of 17.2 GHz to a low frequency of 5.1 GHz. The unique cellular structure with hollow microchannels contributes to the conduction loss and multiple scattering, while the formation of abundant nanopores enhances the polarization loss, resulting in excellent microwave absorption performance. Under a low filler loading of 10 wt.%, the remarkable reflection loss reaches -63.9 dB at 10.8 GHz, and the effective absorption bandwidth as wide as 7.6 GHz. Moreover, by controlling the thickness (1.8-5.5 mm), the absorption bandwidth less than -20 dB ranges from 4.6 GHz to 18 GHz. This work offers the relevance of porous structure and wave absorption properties of pure carbon materials and provides a feasible strategy to design absorbers with efficient microwave absorption performance.

Automated summary

Manipulating the pore structure of carbon-based materials is an effective way to enhance their electromagnetic wave absorption function. In this study, ultralight carbon materials with hierarchical pores were synthesized from waste reed through a one-step calcination process. By adjusting the porous structure and complex permittivity of pure carbon, the researchers observed the strongest microwave absorption peaks occurring in different frequency ranges, ranging from a high frequency of 17.2 GHz to a low frequency of 5.1 GHz.