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Review
. 2024 Dec 20;63(52):e202413910.
doi: 10.1002/anie.202413910. Epub 2024 Nov 18.

Proton Relays in Molecular Catalysis for Hydrogen Evolution and Oxidation: Lessons From the Mimicry of Hydrogenases and Electrochemical Kinetic Analyses

Matthieu Haake  1 Bertrand Reuillard  1 Murielle Chavarot-Kerlidou  1 Cyrille Costentin  2 Vincent Artero  1
Affiliations
Review

Proton Relays in Molecular Catalysis for Hydrogen Evolution and Oxidation: Lessons From the Mimicry of Hydrogenases and Electrochemical Kinetic Analyses

Matthieu Haake et al. Angew Chem Int Ed Engl. .

Abstract

The active sites of metalloenzymes involved in small molecules activation often contain pendant bases that act as proton relay promoting proton-coupled electron-transfer processes. Here we focus on hydrogenases and on the reactions they catalyze, i. e. the hydrogen evolution and oxidation reactions. After a short description of these enzymes, we review some of the various biomimetic and bioinspired molecular systems that contain proton relays. We then provide the formal electrochemical framework required to decipher the key role of such proton relay to enhance catalysis in a single direction and discuss the few systems active for H2 evolution for which quantitative kinetic data are available. We finally highlight key parameters required to reach bidirectional catalysis (both hydrogen evolution and hydrogen oxidation catalyzed) and then transition to reversible catalysis (both reactions catalyzed in a narrow potential range) as well as illustrate these features on few systems from the literature.

Keywords: bioinspiration; electrocatalysis; hydrogen; hydrogenases; proton-coupled electron transfer processes.

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