Litcius/Paper detail

Fine-regulating ultramicropores in porous carbon<i>via</i>a self-sacrificial template route for high-performance supercapacitors

Yunbo Zhao, Ye Yuan, Yanmei Xu, Guiyue Zheng, Qian Zhang, Yuqian Jiang, Zeyu Wang, Naishun Bu, Lixin Xia, Zhuojun Yan

2020Nanoscale21 citationsDOI

Abstract

Ultramicropores (size < 0.7 nm) are critically demanded to provide an efficient path for the penetration and transportation of electrolytes to achieve high-performance supercapacitors. Here, a self-sacrificial template approach is adopted, which introduces C8 alkyl chains with a kinetic diameter of 0.8-1 nm to occupy the cavity of a porous aromatic framework (PAF). During the heating process, the alkyl chains decompose from the dense architecture as the temperature increased from 500 to 600 °C, forming ∼1 nm micropores. The newly-obtained cavities provide sites for thermal-driven skeleton engineering (700-900 °C) to obtain ultramicropores. Based on the well-defined pore structure, the carbonized PAF solid revealed outstanding electrochemical performances, including high rate and long-term stability in a 6 M KOH electrolyte. Notably, the specific capacitance (294 F g-1) derived from the self-sacrificial template method exceeds the capability of all the other methods for the construction of ultramicropores including self-template strategy, carbonization of nanoparticles, and template-assisted strategy. The synthesis of ultramicroporous carbons via the self-sacrificial template route opens up a promising gate to adjust the porous structure for high-performance applications in supercapacitors.

Topics & Concepts

SupercapacitorElectrolyteMaterials sciencePorosityCarbon fibersNanotechnologyTemplatePenetration (warfare)Chemical engineeringCapacitanceComposite materialElectrodeChemistryEngineeringComposite numberPhysical chemistryOperations researchSupercapacitor Materials and FabricationAdvancements in Battery MaterialsElectrocatalysts for Energy Conversion