Abstract
The recent mechanistic understanding of active sites, adsorbed intermediate products, and rate-determining steps (RDS) of nitrogen (N)-modified carbon catalysts in electrocatalytic oxygen reduction (ORR) and oxygen evolution reaction (OER) are still rife with controversy because of the inevitable coexistence of diverse N configurations and the technical limitations for the observation of formed intermediates. Herein, seven kinds of aromatic molecules with designated single N species are used as model structures to investigate the explicit role of each common N group in both ORR and OER. Specifically, dynamic evolution of active sites and key adsorbed intermediate products including O(2) (ads), superoxide anion O(2) (-) *, and OOH* are monitored with in situ spectroscopy. We propose that the formation of *OOH species from O(2) (-) * (O(2) (-) *+H(2) O→OOH*+OH(-) ) is a possible RDS during the ORR process, whereas the generation of O(2) from OOH* species is the most likely RDS during the OER process.