▎ 摘 要
We investigated the selectivity of N-doped graphene nanoclusters (N-GNCs) toward the oxygen reduction reaction (ORR) using first-principles calculations within the density functional theory. The results show that the maximum electrode potentials (U-Max) for the four-electron (4e(-)) pathway are higher than those for the two-electron (2e(-)) pathway at almost all of the reaction sites. Thus, the N-GNCs exhibit high selectivity for the 4e(-) pathway, that is, the 4e(-) reduction proceeds preferentially over the 2e(-) reduction. Such high selectivity results in high durability of the catalyst because H2O2, which corrodes the electrocatalyst, is not generated. For the doping sites near the edge of the cluster, the value of U-Max greatly depends on the reaction sites. However, for the doping sites around the center of the cluster, the reaction-site dependence is hardly observed. The GNC with a nitrogen atom around the center of the cluster exhibits higher ORR catalytic capability compared with the GNC with a nitrogen atom in the vicinity of the edge. The results also reveal that the water molecule generated by the ORR enhances the selectivity toward the 4e(-) pathway because the reaction intermediates are significantly stabilized by water.