Camellia Pollen‐Derived Carbon with Controllable N Content for High‐Performance Supercapacitors by Ammonium Chloride Activation and Dual N‐Doping
Lihua Cao, Huiling Li, Zhaoxiu Xu, Ruirui Gao, Suqing Wang, Guoying Zhang, Shaohua Jiang, Wenhui Xu, Haoqing Hou
Abstract
Abstract Biomass‐derived carbon materials are an amazing electrode material for supercapacitor, owing to their abundant, porous structure and composition. Herein, a controllable N content carbon material with hierarchical porous structure was fabricated via an integrated carbonization, activation and nitrogen‐doping process. N‐rich camellia pollen is used as carbon precursor, while NH 4 Cl is employed as both activation agent and dopant. The optimal N‐doped carbon with higher N content (3.82 at%), suitable pore size distribution and larger specific surface area (810 m 2 g −1 ), provides abundant ion transport channels and exposes more accessible active sites. Thus, a high specific capacitance of 280 F g −1 (1 A g −1 ) in 6 M KOH (three‐electrode system) can be obtained with making full use of N−HPC‐1. Moreover, the assembled symmetrical supercapacitor delivers high energy densities both in 6 M KOH (13.3 Wh kg −1 ) and 1 M Na 2 SO 4 (20 Wh kg −1 ) that can be used for LED lighting. More than that, it is also demonstrates excellent cycle stability in 6 M KOH (85.4% after 20000 cycles at 20 A g −1 ). In view of the above‐mentioned merits, this N‐doped hierarchical porous carbon is anticipated to be a promising material for application in supercapacitors and other fields.