High-performance electrocatalyst based on polyazine derived mesoporous nitrogen-doped carbon for oxygen reduction reaction

Nitrogen-doped porous carbon materials have high potential in metal-free electrocatalysts, which is essential for several renewable energy conversion systems. Herein, we report a convenient and environment-friendly method to fabricate a nitrogen doped mesoporous carbon (NMC) using a nonionic surfactant of Pluronic F127 micelles as the template and a Schiff-base polymer (polyazine) as the precursor. The synthesized NMCs were of spheric morphology and mesoporous structures with surface area up to 1174 m(2) g(-1) and high level of nitrogen (2.9-19 at%) and oxygen (4.9-7.4 at%) simultaneously doped. The electrochemical data of NMCs were analyzed in the context of the BET and XPS information. A correlation between ORR activity and the pyridinic-N was found. The NMC-700 demonstrate the highest electrocatalytic activity for ORR among the studied materials, which can be ascribed to the reasonable surface area and mesoporous structure, as well as the most abundant touchable pyridinic-N, thus providing more effective active sites for the oxygen reduction. In comparsion to the control sample, the NMC-700 provides the ORR electrocatalytic activity approximate to that of commercial Pt/C catalyst with a highly long-term stability.

Automated summary

Nitrogen-doped porous carbon materials have high potential in metal-free electrocatalysts for renewable energy conversion systems. A convenient and environmentally friendly method was reported to fabricate nitrogen-doped mesoporous carbon with high surface area and nitrogen-oxygen doping levels. The NMC-700 exhibited the highest electrocatalytic activity for oxygen reduction reaction, comparable to that of a commercial Pt/C catalyst with long-term stability.