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Autores principales: Nesterova, Irina, Khlyupin, Aleksey, Evstigneev, Nikolay, Ryabkov, Oleg, Gerke, Kirill M.
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2401.13458
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author Nesterova, Irina
Khlyupin, Aleksey
Evstigneev, Nikolay
Ryabkov, Oleg
Gerke, Kirill M.
author_facet Nesterova, Irina
Khlyupin, Aleksey
Evstigneev, Nikolay
Ryabkov, Oleg
Gerke, Kirill M.
contents The interfacial nature of the electric double layer (EDL) assumes that electrode surface morphology significantly impacts the EDL properties. Since molecular-scale roughness modifies the structure of EDL, it is expected to disturb the overscreening effect and alter differential capacitance (DC). In this Letter, we present a model that describes EDL near atomically rough electrodes with account for short-range electrostatic correlations. We provide numerical and analytical solutions for the analysis of conditions for the overscreening breakdown and DC shift estimation. Our findings reveal that electrode surface structure leads to DC decrease and can both brake or enhance overscreening depending on the relation of surface roughness to electrostatic correlation length and ion size asymmetry.
format Preprint
id arxiv_https___arxiv_org_abs_2401_13458
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Mechanism of overscreening breakdown by electrode surface morphology in asymmetric ionic liquids
Nesterova, Irina
Khlyupin, Aleksey
Evstigneev, Nikolay
Ryabkov, Oleg
Gerke, Kirill M.
Chemical Physics
The interfacial nature of the electric double layer (EDL) assumes that electrode surface morphology significantly impacts the EDL properties. Since molecular-scale roughness modifies the structure of EDL, it is expected to disturb the overscreening effect and alter differential capacitance (DC). In this Letter, we present a model that describes EDL near atomically rough electrodes with account for short-range electrostatic correlations. We provide numerical and analytical solutions for the analysis of conditions for the overscreening breakdown and DC shift estimation. Our findings reveal that electrode surface structure leads to DC decrease and can both brake or enhance overscreening depending on the relation of surface roughness to electrostatic correlation length and ion size asymmetry.
title Mechanism of overscreening breakdown by electrode surface morphology in asymmetric ionic liquids
topic Chemical Physics
url https://arxiv.org/abs/2401.13458