Electro-osmosis over inhomogeneously charged surfaces in presence of non-electrostatic ion-ion interactions

In this study, we attempt to bring out a generalized formulation for electro-osmotic flows over inhomogeneously charged surfaces in presence of non-electrostatic ion-ion interactions. To this end, we start with modified electro-chemical potential of the individual species and subsequently use it to...

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Bibliographic Details
Published inPhysics of fluids (1994) Vol. 28; no. 6
Main Authors Ghosh, Uddipta, Chakraborty, Suman
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.06.2016
Subjects
Chemical potential
Computational fluid dynamics
Electrokinetics
Electrostatics
Fluid dynamics
Fluxes
Mathematical analysis
Organic chemistry
Osmosis
Physics
Singular perturbation
Slip
Slip velocity
Transport processes
Zeta potential
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Summary:In this study, we attempt to bring out a generalized formulation for electro-osmotic flows over inhomogeneously charged surfaces in presence of non-electrostatic ion-ion interactions. To this end, we start with modified electro-chemical potential of the individual species and subsequently use it to derive modified Nernst-Planck equation accounting for the ionic fluxes generated because of the presence of non-electrostatic potential. We establish what we refer to as the Poisson-Helmholtz-Nernst-Planck equations, coupled with the Navier-Stokes equations, to describe the complete transport process. Our analysis shows that the presence of non-electrostatic interactions between the ions results in an excess body force on the fluid, and modifies the osmotic pressure as well, which has hitherto remained unexplored. We further apply our analysis to a simple geometry, in an effort to work out the Smoluchowski slip velocity for thin electrical double layer limits. To this end, we employ singular perturbation and develop a general framework for the asymptotic analysis. Our calculations reveal that the final expression for slip velocity remains the same as that without accounting for non-electrostatic interactions. However, the presence of non-electrostatic interactions along with ion specificity can significantly change the quantitative behavior of Smoluchowski slip velocity. We subsequently demonstrate that the presence of non-electrostatic interactions may significantly alter the effective interfacial potential, also termed as the “Zeta potential.” Our analysis can potentially act as a guide towards the prediction and possibly quantitative determination of the implications associated with the existence of non-electrostatic potential, in an electrokinetic transport process.
ISSN:1070-6631
1089-7666
DOI:10.1063/1.4953999