Selective two-electron and four-electron oxygen reduction reactions using Co-based electrocatalysts

Abstract

The oxygen reduction reaction (ORR) can take place via both four-electron (4e⁻) and two-electron (2e⁻) pathways. The 4e⁻ ORR, which produces water (H₂O) as the only product, is the key reaction at the cathode of fuel cells and metal–air batteries. On the other hand, the 2e⁻ ORR can be used to electrocatalytically synthesize hydrogen peroxide (H₂O₂). For the practical applications of the ORR, it is very important to precisely control the selectivity. Understanding structural effects on the ORR provides the basis to control the selectivity. Co-based electrocatalysts have been extensively studied for the ORR due to their high activity, low cost, and relative ease of synthesis. More importantly, by appropriately designing their structures, Co-based electrocatalysts can become highly selective for either the 2e⁻ or the 4e⁻ ORR. Therefore, Co-based electrocatalysts are ideal models for studying fundamental structure–selectivity relationships of the ORR. This review starts by introducing the reaction mechanism and selectivity evaluation of the ORR. Next, Co-based electrocatalysts, especially Co porphyrins, used for the ORR with both 2e⁻ and 4e⁻ selectivity are summarized and discussed, which leads to the conclusion of several key structural factors for ORR selectivity regulation. On the basis of this understanding, future works on the use of Co-based electrocatalysts for the ORR are suggested. This review is valuable for the rational design of molecular catalysts and material catalysts with high selectivity for 4e⁻ and 2e⁻ ORRs. The structural regulation of Co-based electrocatalysts also provides insights into the design and development of ORR electrocatalysts based on other metal elements.