Multifunctional nanolayered renewable carbon for electromagnetic interference and energy devices

Controlled carbonization of biomass leads to nanolayered graphitic structures with characteristic crystalline sp2 hybridization, conductive properties up to 600 S/m, and electromagnetic interference shielding effectiveness of 47.7 dB at 12 GHz. We investigate functional properties of nanolayered renewable carbon, including conductive and photoluminescent features, leading to a new understanding of structure-property correlation and their graphitic multilayered nanostructures. Some unique and novel behaviors, such as negative dielectric factors, hold promise in the areas of cofactor sensors and electromagnetic interference shielding due to their correlation with the absorption of microwave radiation. An electromagnetic interference device demonstrates an application of these nanographitic carbon materials. These conductive and photoluminescent carbon materials hold significant promise in applications such as power electronics, batteries, and sensors, where they may replace conventional metal and graphene. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Controlled carbonization of biomass yields nanolayered graphitic structures with unique crystalline properties and conductive characteristics, showing great potential for various applications, especially in electromagnetic interference shielding.