Hierarchically assembled carbon microtube@SiC nanowire/Ni nanoparticle aerogel for highly efficient electromagnetic wave absorption and multifunction

Efficient electromagnetic wave (EMW) absorption is of great significance to enjoy the service of electromagnetic wave technologies safely. Compared with powder-based EMW absorption materials, aerogels with 3D continous and highly porous network structure have demonstrated to have coordinate impedance matching and attenuation characteristics. Further introducing multicomponent to fabricate aerogels with synergetic conductive/dielectric/magnetic properties are expected to achieve efficient EMW absorption property but still remain challenging. Herein, we report the preparation and properties of a carbon microtube (as conductive network), SiC nanowires (as dielectric network), and Ni nanoparticles (as magnetic network) assembled aerogel with hierarchically network structure that is assembled by. The carbon microtube@SiC nanowire/Ni nanoparticle aerogel displays low density (similar to 5 mg/cm(3)), broad absorption bandwidth (10.1 GHz) and strong reflection loss (-51.3 dB). The unique synergistic magnetic/dielectric/conductive coupling attenuation mechanisms contribute to the good EMW absorption performance. This study opens a pathway for using 3D hierarchically network structure with conductive/dielectric/magnetic components to achieve excellent EMW absorption for promising applications. (C) 2022 Elsevier Ltd. All rights reserved.

Automated summary

Efficient electromagnetic wave absorption is important for safe utilization of electromagnetic wave technologies. Aerogels with 3D continuous and highly porous network structure, compared to powder-based materials, have demonstrated coordinate impedance matching and attenuation characteristics. This study reports the preparation and properties of an assembled aerogel with hierarchically network structure composed of carbon microtube, SiC nanowires, and Ni nanoparticles. The aerogel exhibits low density, broad absorption bandwidth, strong reflection loss, and good electromagnetic wave absorption performance.