Structure-activity relationship in Co-N-C catalysts for multiple H2O2-related electrochemical reactions

Abstract

H2O2 -related electrochemical reactions, including two-electron oxygen reduction reaction (2e-ORR), H2O2 oxidation reaction (HPOR), and H2O2 reduction reaction (HPRR), have received significant attention for the electrosynthesis H2O2 and energy storage. Understanding the complex structure-activity relationships among 2e-ORR/ HPOR/HPRR and their connections is crucial for further developing highly efficient catalysts and working systems. Herein, we unveil these intricacies by employing model Co-N-C catalysts with well-defined active site configuration (Co-N4-pyrrolic and Co-N4- pyridinic ) in a combined experimental and computational approach. We report the higher 2e-ORR/HPOR but lower HPRR activity of CoN4-pyrrolic site than the CoN4-pyridinic site based on their reaction free energy landscapes remodeled considering the chemisorption steps of O2 and H2O2 . The results reveal that the binding free energy of *OOH (ΔG*OOH ) can only be utilized as a reliable descriptor for 2e-ORR/HPOR activity, but not indicative of HPRR activity, regardless of the scaling relationship of the common reaction intermediates ( *OOH or *OH). The HPRR activity of CoN 4 sites strongly depends on the H2O2 adsorption strength and configuration. These findings provide valuable insights into the design of catalysts for H2O2 -related electrochemical energy conversion and storage systems.