Saved in:
Bibliographic Details
Main Authors: de Kam, Lucas B. T., Maier, Thomas L., Krischer, Katharina
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.18418
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913374999150592
author de Kam, Lucas B. T.
Maier, Thomas L.
Krischer, Katharina
author_facet de Kam, Lucas B. T.
Maier, Thomas L.
Krischer, Katharina
contents This paper introduces the combination of an advanced double-layer model with electrochemical kinetics to explain electrolyte effects on the alkaline hydrogen evolution reaction. It is known from experimental studies that the alkaline hydrogen evolution current shows a strong dependence on the concentration and identity of cations in the electrolyte, but is independent of pH. To explain these effects, we formulate the faradaic current in terms of the electric potential in the double layer, which is calculated using a mean-field model that takes into account the cation and anion sizes as well as the electric dipole moment of water molecules. We propose that the Volmer step consists of two activated processes: a water reduction sub-step, and a sub-step in which a hydroxide ion is transferred away from the reaction plane through the double layer. Either of these sub-steps may limit the rate. The proposed models for these sub-steps qualitatively explain experimental observations, including cation effects, pH-independence, and the trend reversal between gold and platinum electrodes. We also assess the quantitative accuracy of the water-reduction-limited current model; we suggest that the predicted functional relationship is valid as long as the hydrogen bonding structure of water near the electrode is sufficiently maintained.
format Preprint
id arxiv_https___arxiv_org_abs_2403_18418
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Electrolyte effects on the alkaline hydrogen evolution reaction: a mean-field approach
de Kam, Lucas B. T.
Maier, Thomas L.
Krischer, Katharina
Chemical Physics
This paper introduces the combination of an advanced double-layer model with electrochemical kinetics to explain electrolyte effects on the alkaline hydrogen evolution reaction. It is known from experimental studies that the alkaline hydrogen evolution current shows a strong dependence on the concentration and identity of cations in the electrolyte, but is independent of pH. To explain these effects, we formulate the faradaic current in terms of the electric potential in the double layer, which is calculated using a mean-field model that takes into account the cation and anion sizes as well as the electric dipole moment of water molecules. We propose that the Volmer step consists of two activated processes: a water reduction sub-step, and a sub-step in which a hydroxide ion is transferred away from the reaction plane through the double layer. Either of these sub-steps may limit the rate. The proposed models for these sub-steps qualitatively explain experimental observations, including cation effects, pH-independence, and the trend reversal between gold and platinum electrodes. We also assess the quantitative accuracy of the water-reduction-limited current model; we suggest that the predicted functional relationship is valid as long as the hydrogen bonding structure of water near the electrode is sufficiently maintained.
title Electrolyte effects on the alkaline hydrogen evolution reaction: a mean-field approach
topic Chemical Physics
url https://arxiv.org/abs/2403.18418