Construction of hierarchical porous carbon nanosheets from template-assisted assembly of coal-based graphene quantum dots for high performance supercapacitor electrodes

Abstract

Using coal-based graphene quantum dots (GQDs) as the building blocks, we develop a simple template-assisted assembly strategy to prepare hierarchical porous carbon nanosheets (HPCNs) for supercapacitor electrodes. The coal-based GQDs are prepared by a simple liquid phase oxidation of the bituminous coal. Benefiting from their small size, enriched edge structure, abundant functional groups, and good flexibility and chemical reactivity, these GQDs are suitable to construct complex nanoarchitectures for advanced energy storage materials. As a result, the HPCNs show an interconnected loose-stacking graphene-like structure with the specific surface area of 1332 m2 g−1, hierarchical pore distribution, excellent conductivity, abundant active sites, and sufficient ion migration channels. An in situ chemical activation is further applied to improve its energy storage performance. Under the optimized conditions, the activated HPCN with a specific surface area of 1450 m2 g−1 shows a greatly improved capacitive performance, with a high specific capacitance of 230 F g−1 (1 A g−1) and capacitance retention of 74% at 100 A g−1 (170 F g−1). No obvious capacity fade was found even after cycled at 10 A g−1 for 10,000 times, demonstrating their excellent endurability. Our work may provide new thought for the effective use of abundant coal resource to design and preparation advanced carbon nanoarchitectures for energy storage.