(583e) Toward a Fundamental Understanding of Catalytically-Active Phases and Reaction Mechanism of Layered Double Hydroxides for the Oxygen Evolution Reaction

Generating green H₂ fuel through electrochemical water splitting is a key route toward Net-Zero Emissions by 2050. In this process, however, O₂ generation at the anode through the oxygen evolution reaction (OER) is inherently slower by over four orders of magnitude than H₂ generation at the cathode. Thus, improving OER efficiency has been a majority effort in electrolysis. Ni-based and Co-based layered double hydroxides (LDHs) are among the most active and studied catalysts for the oxygen evolution reaction (OER) in alkaline electrolytes. Because it happens under extremely oxidative aqueous conditions, however, in-situ crystal structures of the OER active phase are still largely unknown, significantly hindering the establishment of structure-property relationships.

In this talk, we provide the first direct atomic-scale evidence that, under applied anodic potentials, NiFe and CoFe LDHs oxidize from as-prepared α-phases to activated γ-phases. The OER-active γ-phases are characterized by about 8% contraction of the lattice spacing and switching of the intercalated ions from carbonate to potassium. The calculated surface phase diagrams indicate that surface sites are fully saturated under OER conditions. These structures, and the associated reaction free energies, suggest that the OER proceeds via a Mars van Krevelen mechanism, starting with the oxidation of bridge OH at the reaction centers with dual metal sites, i.e., M1-OH-M2. Our study further showed that, to approach the minimum overpotential dictated by a specific OH-OOH scaling relationship, the key is to break the OH-O scaling relationship. A possible route is to form binary metal oxyhydroxides with dual metal sites at the reaction centers or introduce a third element into NiFe LDH or CoFe LDH.

References:

Nature Communications 2020, 11, 2522.

Angew. Chem., Int. Ed. 2021, 60, 14446-14457.