Deprotonation and cation adsorption on the NiOOH/water interface: A grand-canonical first-principles investigation

[Display omitted] Nickel-based oxides are highly active, cost-effective materials for the oxygen evolution reaction in alkaline conditions. Recent experimental studies have revealed the importance of surface deprotonation and alkali metal cation adsorption on the activity of Ni oxide surfaces, in co...

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Published in:Electrochimica acta 2021-12, Vol.398, p.139253, Article 139253
Main Authors: Eslamibidgoli, Mohammad J., Huang, Jun, Kowalski, Piotr M., Eikerling, Michael H., Groß, Axel
Format: Article
Language:English
Subjects:
Adsorbates
Adsorption
Cations
Computational hydrogen electrode
Density functional theory
Deprotonation
Dipole moments
Double layer effects
Electronic structure
First principles
Metal ions
Nickel (oxy)hydroxides
Oxygen evolution reactions
Pourbaix diagram
Pourbaix diagrams
Strong interactions (field theory)
Surface chemistry
Water chemistry
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Summary:[Display omitted] Nickel-based oxides are highly active, cost-effective materials for the oxygen evolution reaction in alkaline conditions. Recent experimental studies have revealed the importance of surface deprotonation and alkali metal cation adsorption on the activity of Ni oxide surfaces, in contact with aqueous alkaline electrolyte. As a first step to elucidate the role of the alkali adsorption for the activity, we performed first-principles electronic structure calculations to address the stable surface structures of β-NiOOH(0001) as a function of the operating conditions in an electrochemical environment. We present a grand-canonical approach to compute the surface Pourbaix diagram of the β-NiOOH/water interface for the processes of deprotonation and alkali metal cation adsorption. The results of this study emphasize the importance of double-layer effects, including the adsorbate-induced change of surface dipole moments and the rearrangement of water molecules due to their strong interaction with the adsorbed species, for the most stable interface structure.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2021.139253