Abstract
Facile solvent reorganization promoting ion transfer across the solid–liquid interface is considered a prerequisite for efficient electrocatalysis. We provide first-principles insight into this notion by examining water self-ion dynamics at a highly rigid NaCl(100)–water interface. Through extensive density functional theory molecular dynamics simulations, we demonstrate for both acidic and alkaline solutions that Grotthuss dynamics is not impeded by a rigid water structure. Conversely, decreased proton transfer barriers and a striking propensity of H3O+ and OH– for stationary interfacial water are found. Differences in the ideal hydration structure of the ions, however, distinguish their behavior at the water contact layer. While hydronium can maintain its optimal solvation, the preferentially hypercoordinated hydroxide is repelled from the immediate vicinity of the surface due to interfacial coordination reduction. This has implications for alkaline hydrogen electrosorption in which the formation of undercoordinated OH– at the surface is proposed to contribute to the observed sluggish kinetics.
Highlights
Facile solvent reorganization promoting ion transfer across the solid−liquid interface is considered a prerequisite for efficient electrocatalysis
Interfacial water reorganization as a descriptor of electrochemical rates is an intriguing model underscoring the importance of solvent dynamics in electrochemical kinetics unlike common adsorption energy (ΔG)-based heuristics.[4,5]
In this Letter, we provide theoretical insight into this hypothesis through extensive (>0.5 ns) density functional theory molecular dynamics (DFTMD) simulations of acidic and alkaline NaCl(100)−water interfaces
Summary
Facile solvent reorganization promoting ion transfer across the solid−liquid interface is considered a prerequisite for efficient electrocatalysis.
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