Primitive model electrolytes in the near and far field: Decay lengths from DFT and simulations

Cats, Peter; Evans, Robert; Härtel, Andreas; Roij, René van

doi:10.1063/5.0039619

Cited by 58 publications

(114 citation statements)

References 75 publications

(151 reference statements)

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“…The RPM and, in particular, its structural properties are well described in the theoretical framework of classical density functional theory (DFT) [22], because the framework remarkably well handles hard-sphere interactions within fundamental measure theory [23][24][25][26]. In consequence, DFT is able to describe the structure of the first layers of ions in the vicinity of an electrode [27][28][29], a property that recently has been discussed to be key for properties like the heat production during charging [10] and the differential capacitance in EDLs [30].…”

Section: Introductionmentioning

confidence: 99%

Extension of the primitive model by hydration shells and its impact on the reversible heat production during the buildup of the electric double layer

Pelagejcev,

Glatzel,

Härtel

2021

Preprint

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Recently the reversible heat production during electric double layer (EDL) buildup in a sodium chloride solution was measured experimentally [Phys. Rev. Lett. 119, 166002 (2017)] and matched with theoretical predictions from density functional theory and molecular dynamics simulations [J. Chem. Phys. 154, 064901 (2021)]. In the latter, it was found that the steric interactions of the ions with the electrode's walls, which result in the so called Stern layer, are sufficient to explain the experimental results. As only symmetric ion sizes in a restricted primitive model were examined, it is instructive to investigate systems of unequal ion sizes that lead to modified Stern layers. In this work, we explore the impact of ion asymmetry on the reversible heat production for each electrode separately. In this context, we further study an extension of the primitive model where hydration shells of ions can evade in the vicinity of electrode's walls. We find a strong dependence on system parameters like the particle sizes and the total volume taken by particles. Here, we even found situations where one electrode was heated and the other electrode was cooled at the same time during charging, while, in sum, both electrodes together behaved very similarly to the already mentioned experimental results. Thus, heat production should be measured also in experiments for each electrode separately. By this, the importance of certain ingredients that we proposed to model electrolytes could be confirmed or ruled out experimentally, finally leading to a deeper understanding of the physics of electric double layers.

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Section: Introductionmentioning

confidence: 99%

Extension of the primitive model by hydration shells and its impact on the reversible heat production during the buildup of the electric double layer

Pelagejcev,

Glatzel,

Härtel

2021

Preprint

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“…of which the first c (1) and second direct correlation c (2) function are the most important ones (within this thesis)…”

Section: By Writing ρmentioning

confidence: 99%

“…For the case that this medium polarizes linearly with the electric field and the medium is homogeneous, 1 , the effective pair potential u between two ions of species i and j with charge ez i and ez j , respectively, separated by a distance r, is given by the Coulomb (C) pair potential…”

Section: The Primitive Model For the Electrolytementioning

confidence: 99%

“…(1) b = c (1) (ρ b ). We choose the external potential V ext (r) to correspond to a planar wall or to a big (spherical) solute, such that V ext (r) → 0 as r → ∞, and ρ(r) → ρ b , the bulk reservoir value.…”

Section: C Decay Of the Density Profile Versus That Of The Bulk Corre...mentioning

confidence: 99%

“…Noting that c (1) (r; [ρ]) is both a functional of ρ and a function of r, we can expand this term around the bulk density to lowest order:…”

Section: C Decay Of the Density Profile Versus That Of The Bulk Corre...mentioning

confidence: 99%

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The Electrode-Electrolyte Interface from the perspective of Density Functional Theory

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Odin, the chief of the Aesir (Norse gods), has many names and is often portrayed as an old man, dressed in grey, with a wide-brimmed hat, and one eye. Odin is constantly in pursuit of gaining knowledge and wisdom, often in exchange of a sacrifice; he gave his eye to drink from the well of Mimir, which contains much wisdom, and even hung himself at Yggdrasil (the world tree) pierced by his own spear Gungnir for nine days and nights in order to understand the runes, which also contained wisdom and knowledge. He does not seek knowledge and wisdom only for himself, but he wants to learn anything that might prevent catastrophe at Ragnarok. Moreover in the poem Hávamál (part of the Edda), meaning "words of the high one" (a reference to Odin), he gives wisdom and advice on how to live a good life, e.g. never stop learning, and do not drink too much alcohol.

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Competitive adsorption of alkali ions on aqueous mica surface: A force field comparison molecular dynamics study

Xiao

Chen

Zhou

et al. 2022

Applied Clay Science

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Primitive model electrolytes in the near and far field: Decay lengths from DFT and simulations

Cited by 58 publications

References 75 publications

Extension of the primitive model by hydration shells and its impact on the reversible heat production during the buildup of the electric double layer

Extension of the primitive model by hydration shells and its impact on the reversible heat production during the buildup of the electric double layer

The Electrode-Electrolyte Interface from the perspective of Density Functional Theory

Competitive adsorption of alkali ions on aqueous mica surface: A force field comparison molecular dynamics study

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