N-doped layered porous carbon electrodes with high mass loadings for high-performance supercapacitors

We report a porous carbon material (NPCM) with a high N content as a high-performance supercapacitor electrode material which was prepared by a simple activation-doping process using Metaplexis Japonica shell as the carbon precursor, ammonium chloride as the nitrogen source and zinc chloride as the activation agent. Its high electrical conductivity, large ion-accessible surface area and fast ion transport ability make it possible to achieve a high mass loading of NPCM per area of the electrode and a high energy and high power density supercapacitor. An electrode with a low NPCM mass loading of 1 mg cm(-2) has a gravimetric specific capacitance of 457 F g(-1) and an areal specific capacitance of 47.8 mu F cm(-2). At a much high NPCM loading of 17.7 mg cm(-2) it has a high gravimetric capacitance of 161 F g(-1). Furthermore, an assembled NPCM//NPCM symmetric supercapacitor with an optimal NPCM loading of 12.3 mg cm-2 delivered a high specific energy of 12.5 Wh kg(-1) at an ultrahigh power of 80 kW kg(-1) in 1 mol L-1 Na2SO4. The achievement of such high-energy and high-power densities using NPCM will open exciting opportunities for carbon-based supercapacitors in many different applications.