Unraveling the pH-Dependent Oxygen Reduction Performance on Single-Atom Catalysts: From Single- to Dual-Sabatier Optima

Metal–nitrogen–carbon (M–N–C) single-atom catalysts (SACs) have emerged as a potential substitute for the costly platinum-group catalysts in oxygen reduction reaction (ORR). However, several critical aspects of M–N–C SACs in ORR remain poorly understood, including their pH-dependent activity, selectivity for 2- or 4-electron transfer pathways, and the identification of the rate-determining steps. Herein, by analyzing >100 M–N–C structures and >2000 sets of energetics, we unveil a pH-dependent evolution in ORR activity volcanosfrom a single peak in alkaline media to a double peak in acid... Mehr ...

Verfasser: Di Zhang
Zhuyu Wang
Fangzhou Liu
Peiyun Yi
Linfa Peng
Yuan Chen
Li Wei
Hao Li
Dokumenttyp: Dataset
Erscheinungsdatum: 1753
Schlagwörter: Biophysics / Biochemistry / Biotechnology / Evolutionary Biology / Infectious Diseases / Space Science / Chemical Sciences not elsewhere classified / several critical aspects / oxygen reduction reaction / moderate dipole moments / electron transfer pathways / dependent electrochemical applications / dependent evolution / dependent behavior / dependent activity / turnover frequency / theoretical predictions / theoretical discovery / tafel slope / sabatier </ / potential substitute / kinetic current / group catalysts / experiments matched / double peak / determining steps / costly platinum / atom catalysts / alkaline media / alkaline environments / 2000 sets
Sprache: unknown
Permalink: https://search.fid-benelux.de/Record/base-29672622
Datenquelle: BASE; Originalkatalog
Powered By: BASE
Link(s) : https://doi.org/10.1021/jacs.3c11246.s002

Metal–nitrogen–carbon (M–N–C) single-atom catalysts (SACs) have emerged as a potential substitute for the costly platinum-group catalysts in oxygen reduction reaction (ORR). However, several critical aspects of M–N–C SACs in ORR remain poorly understood, including their pH-dependent activity, selectivity for 2- or 4-electron transfer pathways, and the identification of the rate-determining steps. Herein, by analyzing >100 M–N–C structures and >2000 sets of energetics, we unveil a pH-dependent evolution in ORR activity volcanosfrom a single peak in alkaline media to a double peak in acids. We found that this pH-dependent behavior in M–N–C catalysts fundamentally stems from their moderate dipole moments and polarizability for O* and HOO* adsorbates, as well as unique scaling relations among ORR adsorbates. To validate our theoretical discovery, we synthesized a series of molecular M–N–C catalysts, each characterized by well-defined atomic coordination environments. Impressively, the experiments matched our theoretical predictions on kinetic current, Tafel slope, and turnover frequency in both acidic and alkaline environments. These new insights also refine the famous Sabatier principle by emphasizing the need to avoid an “acid trap” while designing M–N–C catalysts for ORR or any other pH-dependent electrochemical applications.