Electrophoretic mobility does not always reflect the charge on an oil droplet

Knecht, Volker; Risselada, Herre Jelger; Mark, Alan E.; Marrink, Siewert J.

doi:10.1016/j.jcis.2007.10.035

Cited by 50 publications

(69 citation statements)

References 41 publications

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“…For ͑"indifferent"͒ electrolytes whose cations and anions interact nearly equally with the surface, IEPϷ PZC. The exact meaning of ZP is, however, more ambiguous and highly model dependent ͑Hunter, 1989; Knecht et al, 2008͒. In recent years, new experimental approaches have been developed to determine zeta potential, surface charge density, and PZC's for a number of oxides at temperatures above 100°C ͑Wesolowski et al, 2000; Machesky et al, 2001;Zhou et al, 2003͒. The surface charge density at pH's other than the PZC is governed by the site densities of the surface species and the screening of surface charge buildup by water dipoles and charged, polar, and/or polarizable species in the solution.…”

Section: Structure and Dynamics At Oxide/electrolyte Interfacesmentioning

confidence: 99%

Long range interactions in nanoscale science

et al. 2010

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Our understanding of the "long range" electrodynamic, electrostatic, and polar interactions that dominate the organization of small objects at separations beyond an interatomic bond length is reviewed. From this basic-forces perspective, a large number of systems are described from which one can learn about these organizing forces and how to modulate them. The many practical systems that harness these nanoscale forces are then surveyed. The survey reveals not only the promise of new devices and materials, but also the possibility of designing them more effectively.

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Section: Structure and Dynamics At Oxide/electrolyte Interfacesmentioning

confidence: 99%

Long range interactions in nanoscale science

et al. 2010

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“…9,10 However, in Necturus, the filtration-dependent potential exhibited a polarity opposite to that observed in simple in vitro channels with a negatively charged surface. The physical phenomenon called "charged reversal" or "overcharging" [11][12][13][14][15][16][17][18] could be one of several possible physical mechanisms to explain why the negatively charged glomerular filter shows the electrokinetic characteristics of a positively charged filter. "Charge reversal" may occur if additional soluble counter ions (e.g., cations) are bound to the negatively charged filter walls by forces other than electrical interactions (e.g., chemical interactions) and thus change the apparent (i.e., the elec- D).…”

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confidence: 99%

Electrical Forces Determine Glomerular Permeability

Hausmann

Kuppe

Egger

et al. 2010

Journal of the American Society of Nephrology

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“…The mobility was initially related to the interfacial water structure, involving static properties such as the water dipolar ordering and the density profile as well as dynamic properties such as the viscosity and the slip length [21]. The mechanism was later disputed by Bonthuis et al [19], who showed that in an electroneutral dipolar fluid the static electric fields do not give rise to interfacial flow, even in the presence of dipolar ordering at the surface.…”

Section: Introductionmentioning

confidence: 99%

Establishing conditions for simulating hydrophobic solutes in electric fields by molecular dynamics

et al. 2014

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Despite considerable effort over the last decade, the interactions between solutes and solvents in the presence of electric fields have not yet been fully understood. A very useful manner in which to study these systems is through the application of molecular dynamics (MD) simulations. However, a number of MD studies have shown a tremendous sensitivity of the migration rate of a hydrophobic solute to the treatment of the long range part of the van der Waals interactions. While the origin of this sensitivity was never explained, the mobility is currently regarded as an artifact of an improper simulation setup. We explain the spread in observed mobilites by performing extensive molecular dynamics simulations using the GROMACS software package on a system consisting of a model hydrophobic object (Lennard-Jones particle) immersed in water both in the presence and absence of a static electric field. We retrieve a unidirectional field-induced mobility of the hydrophobic object when the forces are simply truncated. Careful analysis of the data shows that, only in the specific case of truncated forces, a non-zero van der Waals force acts, on average, on the Lennard-Jones particle. Using the Stokes law we demonstrate that this force yields quantitative agreement with the field-induced mobility found within this setup. In contrast, when the treatment of forces is continuous, no net force is observed. In this manner, we provide a simple explanation for the previously controversial reports.

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Electrophoretic mobility does not always reflect the charge on an oil droplet

Cited by 50 publications

References 41 publications

Long range interactions in nanoscale science

Long range interactions in nanoscale science

Electrical Forces Determine Glomerular Permeability

Establishing conditions for simulating hydrophobic solutes in electric fields by molecular dynamics

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