A highly efficient, metal-free carbon nanocatalyst is presented that possesses abundant active, oxygenated graphitic edge sites. The edge site-rich nanocarbon catalyst exhibits about 28 times higher activity for H2 O2 production than a basal plane-rich carbon nanotube with a H2 O2 selectivity over 90 %. The oxidative treatment further promotes the H2 O2 generation activity to reach close to the thermodynamic limit. The optimized nanocarbon catalyst shows a very high H2 O2 production activity, surpassing previously reported catalysts in alkaline media. Moreover, it can stably produce H2 O2 for 16 h with Faradaic efficiency reaching 99 % and accumulated H2 O2 concentration of 24±2 mm. Importantly, we find that the heterogeneous electron transfer kinetics of the carbon-based catalyst is closely related to the electrocatalytic activity, suggesting that first outer-sphere electron transfer to O2 is an important step governing the H2 O2 production rate.
Keywords: carbon nanomaterials; electrocatalysts; electron transfer; hydrogen peroxide; oxygen reduction.
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