Induced charge electroosmotic flow with finite ion size and solvation effects

Fuhrmann, Jürgen; Guhlke, Clemens; Linke, Alexander; Merdon, Christian; Müller, Rüdiger

doi:10.1016/j.electacta.2019.05.051

Cited by 7 publications

(2 citation statements)

References 41 publications

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“…Taking into account steric effects leads to reduced charge accumulation near the charged surfaces, mitigating the highly nonlinear effects arising when high ζ-potentials are involved [100,101]. This overestimation of the charge density may significantly affect the EOF [102].…”

Section: Some Limitations Of the Pnp-ns Modelmentioning

confidence: 99%

Electroosmosis in nanopores: Computational methods and technological applications

Gubbiotti¹,

Baldelli²,

Muccio³

et al. 2021

Preprint

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Electroosmosis is a fascinating effect where liquid motion is induced by an applied electric field. Counter ions accumulate in the vicinity of charged surfaces, triggering a coupling between liquid mass transport and external electric field. In nanofluidic technologies, where surfaces play an exacerbated role, electroosmosis is thus of primary importance. Its consequences on the transport properties in biological and synthetic nanopores are subtle and intricate. Thorough understanding is therefore challenging yet crucial to fully assess the mechanisms at play. Here, we review recent progress on computational techniques for the analysis of electroosmosis and discuss technological applications, in particular for sensing devices.

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Section: Some Limitations Of the Pnp-ns Modelmentioning

confidence: 99%

Electroosmosis in nanopores: Computational methods and technological applications

Gubbiotti¹,

Baldelli²,

Muccio³

et al. 2021

Preprint

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“…The Maxwell electrostatic potential can be thus considered constant within the electrolyte (assuming no net fluxes and perfect mixing). Consequently, we assume that the electrochemical potential of species in the electrolyte is the same near the membrane and near the electrode, which greatly simplifies the modeling (since the Poisson equation would have to be solved otherwise [15,16]).…”

Section: Transportmentioning

confidence: 99%

Open-Circuit Voltage Comes from Non-Equilibrium Thermodynamics

Olmo

Pavelka

Košek

2020

Journal of Non-Equilibrium Thermodynamics

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Originally derived by Walther Nernst more than a century ago, the Nernst equation for the open-circuit voltage is a cornerstone in the analysis of electrochemical systems. Unfortunately, the assumptions behind its derivation are often overlooked in the literature, leading to incorrect forms of the equation when applied to complex systems (for example, those with ion-exchange membranes or involving mixed potentials). Such flaws can be avoided by applying a correct thermodynamic derivation independently of the form in which the electrochemical reactions are written. The proper derivation of the Nernst equation becomes important, for instance, in modeling of vanadium redox flow batteries or zinc-air batteries. The rigorous path towards the Nernst equation derivation starts in non-equilibrium thermodynamics.

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