B/N-Codoped Carbon Nanosheets Derived from the Self-Assembly of Chitosan-Amino Acid Gels for Greatly Improved Supercapacitor Performances.

Abstract

This work presents an efficient strategy for preparing chitosan (CS)-derived boron (B), nitrogen (N)-codoped porous carbon (C) nanosheets by using three amino acids with different acidities and the help of boric acid. Amino acids act not only as a N sources but also as the structure-directing agents through the interaction with CS to induce the formation of special morphology and structure. Boric acid serves both as the B source and as the reactive template, improving activition efficiency to creat more pores. When amino acids with different acidities are added, the morphology of the prepared samples changes from large bulks to thin nanosheets. In particular, the as-prepared carbon formed by a CS-aspartic acid gel precursor shows thin curved nanosheets. After adding KOH and boric acid, the samples possess loose and cross-linked morphologies with porous structure, which is favorable for ion transport and has benefit for the supercapacitor (SC) performance. As a result, the obtained B/N-codoped porous carbons show enhanced electrochemical performance. The sample CS/His-B prepared with basic amino acid shows the superior capacitance of 478 F g-1. Meanwhile, the assembled symmetric SC achieves a maximum energy density of 30.1 Wh kg-1 when the power density is 225.1 W kg-1 and demonstrates an ultralong cycling life for which the retention of capacitance is approximately 100% after 100 000 cycles. The maximum area capacitance is up to 12.7 F cm-1 with 50 mg of active material loaded. For an all-solid-state SC using KOH-polyvinyl alchydroohol (PVA) electrolyte, the device owns a wide potential range of 1.4 V, which shows an excellent maximum energy density of 14.4 Wh kg-1 and still remains 4.4 Wh kg-1 at the power density of 1049.5 W kg-1. B/N-codoped carbon nanosheets derived from the self-assembly of chitosan-amino acid gels represent a promising route for preparing carbon materials for high-performance SCs.