Understanding hydrogen electrocatalysis by probing the hydrogen-bond network of water at the electrified Pt-solution interface

Q Sun and NJ Oliveira and S Kwon and S Tyukhtenko and JJ Guo and N Myrthil and SA Lopez and I Kendrick and S Mukerjee and L Ma and SN Ehrlich and JK Li and WA Goddard and YS Yan and QY Jia, NATURE ENERGY, 8, 859-869 (2023).

DOI: 10.1038/s41560-023-01302-y

Hydrogen evolution and oxidation on platinum surfaces are central reactions in electrochemical devices. Sun et al. show that they can be promoted by introduction of the organic molecules, N-methylimidazoles, and explore the underlying phenomena at play through in situ spectroscopy and computation. Rational construction of the electrode- solution interface where electrochemical processes occur is of paramount importance in electrochemistry. Efforts to gain better control and understanding of the interface have been hindered by lack of probing methods. Here we show that the hydrogen evolution and oxidation reactions (HER/HOR) catalysed by platinum in base can be promoted by introduction of N-methylimidazoles at the platinum-water interface. In situ spectroscopic characterization together with simulations indicate that the N-methylimidazoles facilitate diffusion of hydroxides across the interface by holding the second layer of water close to platinum surfaces, thereby promoting the HER/HOR. We thus propose that the HER/HOR kinetics of platinum in acid and base is governed by diffusion of protons and hydroxides, respectively, through the hydrogen-bond network of interfacial water by the Grotthuss mechanism. Moreover, we demonstrate a 40% performance improvement of an anion exchange membrane electrolyser by adding 1,2-dimethylimidazole into the alkali fed into its platinum cathode.

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