Biomass-derived CaO in situ catalyzing approach towards hierarchical porous graphene nanosheets for high-rate performance supercapacitors

Hierarchical porous graphene is first fabricated from lotus leaves by naturally CaO in situ self-catalyzing strategy without the utilization of any chemical or physical agent. The intrinsic Ca-containing species in biomass first converses into CaCO3 and then decomposes into CaO during the pyrolysis process, and the imbedded CaO serves as in situ template and catalyst to generate hierarchical structure and graphitic structure. The resultant graphene exhibits 3D structural hierarchy with micro-sized in-plane vacancies, meso-sized channels and macro-sized cavities, contributing to rapid charge transfer, short ion diffusion pathway and robust framework. It has been demonstrated as a high-rate performance supercapacitor electrode (without the addition of any conductive agent) with outstanding rate capability (85.3% retention rate from 1 to 20 A/g) and high scan rate of 3000 mV/s. No obvious deterioration (98.2% capacitance retention) was observed after 10,000 charge-discharge cycles at 20 A/g. The first synthesis of nanoarchitecture graphene via one-step pyrolysis method by taking advantage of the unique natural features of biomass opened up new angle for the green and facile preparation of 3D graphene for energy storage. (c) 2021 Elsevier B.V. All rights reserved.

Automated summary

The hierarchical porous graphene fabricated from lotus leaves using naturally occurring CaO as a catalyst demonstrates excellent performance as a high-rate supercapacitor electrode, showcasing rapid charge transfer, short ion diffusion pathway, and structural robustness. This environmentally friendly synthesis method takes advantage of the unique natural features of biomass, providing a new approach for the green and facile preparation of 3D graphene for energy storage applications.