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Self-doped porous carbon derived from traditional Chinese medicine residues for high performance supercapacitors

Heng Chen, Tingting Lv, Jiao Guo, Liujie Wang, Li Li, Laiping Zhang, Pengfa Li, Chengye Wang, Li Zhu

2025Industrial Crops and Products6 citationsDOIOpen Access PDF

Abstract

To achieve high-value utilization of herbal residues, this study employed rhubarb residue - representative of mixed herbal residues' composition - to prepare porous carbon for supercapacitor applications. By controlling the preparation process, the inherent heteroatoms from the raw material were effectively retained, achieving self-doping of nitrogen and oxygen. As-synthesized porous carbon exhibits an ultrahigh specific surface area of 2817 m 2 /g with well-defined hierarchical porosity. This structural architecture provides abundant active sites for charge storage while facilitating rapid ion diffusion. Furthermore, the presence of self-doped nitrogen (2.07 at%) and oxygen (9.76 at%) enhances the specific capacitance through pseudocapacitive contributions. When employed as supercapacitor electrodes, the materials deliver a remarkable electrochemical capacitance of 356 F/g at 1 A/g and maintain superior rate capability, retaining 274 F/g at 10 A/g. The electrodes also exhibit exceptional cycling stability, with 93.5 % capacitance retention after 10,000 cycles at 10 A/g. These findings innovatively demonstrate that employing lower temperatures and shorter activation times can effectively retain heteroatoms in Chinese herbal residues. This not only confirms the suitability of herbal residues as premium raw material for capacitor carbon production but also provides a viable strategy for high-value utilization of biomass waste in supercapacitor applications. • Heteroatom self-doping was realized via short-term activation. • (2) KOH-activated material: SSA = 2817 m²/g with hierarchical pores. • (3) Remarkable electrochemical performance is achieved with 356 F/g electrochemical capacitance and 12 Wh/kg energy density. • (4) 93.5 % capacitance retention after 10,000 cycles (10 A/g).

Topics & Concepts

SupercapacitorHeteroatomCapacitanceMaterials scienceRaw materialCarbon fibersElectrochemistryPorosityCapacitorNitrogenChemical engineeringSpecific surface areaBiomass (ecology)Energy storageNanotechnologyElectrodePseudocapacitancePyrolysisSupercapacitor Materials and FabricationConducting polymers and applicationsAdvanced Battery Materials and Technologies