Charging Dynamics of Aerosol OT Inverse Micelles

Karvar, Masoumeh; Strubbe, Filip; Beunis, Filip; Kemp, Roger; Smith, Nathan J.; Goulding, Mark; Neyts, Kristiaan

doi:10.1021/acs.langmuir.5b01677

Cited by 11 publications

(21 citation statements)

References 44 publications

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“…Two kinds of boundary conditions for the negative inverse micelles are compared by numerical simulation: the boundary condition of adsorption and release [12] (where the inverse micelles stick to the surface when they touch it and are released when the field is zero) and the blocking boundary condition [30] (where the inverse micelles form a diffuse double layer or Debye layer with thickness λ DL = (εε 0 k B T/2q 2 n − ) ≈ 100 nm near the interface when the electric field is directed from the liquid to the solid). There is a subtle but important difference in the location of the negative charges in steady state between the two kinds of boundary conditions.…”

Section: Boundary Condition For Counterchargesmentioning

confidence: 99%

Electrodynamics of Electronic Paper Based on Total Internal Reflection

et al. 2018

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We present a study of the fundamental electrodynamics of an electronic ink pixel based on frustrated total internal reflection, which is relevant for the ongoing development of video-speed-capable electronic ink displays. Devices are fabricated with plane-parallel electrodes covered with a dielectric coating of the poly(p-xylylene) polymer Parylene C and filled with ink proprietary fluorochemical fluid containing absorbing particles. Reflectivity measurements of frustrated total internal reflection and transient current measurements provide information on the concentration of particles near the electrodes, conductivity of the ink, and screening of the electric field. By comparing the measurements with an electro-optical model, it is found that the electrical properties of the ink are dominated by positively charged particles and negative countercharges. Screening of the electric field depends as expected on the dielectric coating thickness. The observation of an asymmetry in the steady-state gray level response to an applied voltage is explained by fixed positive charges adsorbed at the interface between the dielectric coating and the dispersion. The overall switching dynamics of the device for different voltage sequences is in good agreement with simulations.

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Section: Boundary Condition For Counterchargesmentioning

confidence: 99%

Electrodynamics of Electronic Paper Based on Total Internal Reflection

et al. 2018

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“…There are various experimental methodologies to study the charge formation and the EDL of dispersed and bulk solids in contact with nonpolar liquids; these include but are not limited to electrical conductivity measurements, ,,− electrophoretic mobility measurements, − transient current measurements, − or total internal reflection microscopy . Recently, Yezer et al , used electrical impedance spectroscopy (EIS) to study the EDL of mixtures of dodecane and the nonionic surfactants OLOA 11 000, Span 80, and Span 85.…”

Section: Introductionmentioning

confidence: 99%

Charge and Electrical Double Layer Formation in a Nonpolar Solvent Using a Nonionic Surfactant

2020

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In this work, we study the charge formation and the characteristics of the electrical double layer in a nonpolar medium using electrical impedance spectroscopy. To stabilize the free ionic species, a nonionic surfactant is added to the system. The conductivity and permittivity of the medium are obtained from high-to medium-frequency impedance data. Based on the correlation between (viscosity-adjusted) conductivity and surfactant concentration, we conclude that charge formation occurs due to a disproportionation mechanism. We accordingly estimate the concentration of the charge carriers in the sample and the Debye length of the diffuse double layer. The capacitance of the electrical double layer can be extracted from the low-frequency impedance data. We use this data to calculate the electrode distance of an equivalent parallel plate capacitor. It is found that this distance is on the order of magnitude of Angstroms, indicating that the measured electrical double layer capacitance is in fact the Stern layer capacitance.

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“…13−15 Based on the measured capacitance of the Stern layer, the monovalent "core" of an adsorbed micelle appears to be situated even closer to the indium tin oxide (ITO) than the steric hindrance of the inverse micelle would allow, suggesting a different arrangement of the surfactant such as a hemi-micelle-like geometrical configuration. For example, in the case of AOT/ dodecane, 13 adsorption of charged inverse micelles on ITO is fast and bulk field screening is directly governed by Stern capacitances. In the case of OLOA11k (and OLOA 1200), 1 the adsorption of charged inverse micelles on ITO is much slower, such that the bulk electric field screening is dominated by the formation of a diffuse double layer.…”

Section: ■ Introductionmentioning

confidence: 99%

“…To measure the properties of charged inverse micelles, there are two commonly used methods: transient current measurements − and impedance spectroscopy. , These methods allow the measurement of bulk properties such as the concentration of charged inverse micelles and the electrophoretic mobility (and related to this the hydrodynamic radius) and details on the charge generation mechanism ,, and on interface phenomena. ,− When a potential difference is applied across a mixture, the behavior of charged inverse micelles near the electrodes depends on the type of surfactant system and on the type of surface. ,− Bulk dynamics based on drift and diffusion predict the formation of a diffuse double layer, though, due to adsorption of inverse micelles onto the electrode, this can evolve into a Stern layer. − Based on the measured capacitance of the Stern layer, the monovalent “core” of an adsorbed micelle appears to be situated even closer to the indium tin oxide (ITO) than the steric hindrance of the inverse micelle would allow, suggesting a different arrangement of the surfactant such as a hemi-micelle-like geometrical configuration. For example, in the case of AOT/dodecane, adsorption of charged inverse micelles on ITO is fast and bulk field screening is directly governed by Stern capacitances. In the case of OLOA11k (and OLOA 1200), the adsorption of charged inverse micelles on ITO is much slower, such that the bulk electric field screening is dominated by the formation of a diffuse double layer.…”

Section: Introductionmentioning

confidence: 99%

Polarity-Dependent Adsorption of Inverse Micelles

et al. 2020

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The adsorption of charged inverse micelles at the electrode–liquid interface has an important effect on field screening and on the voltage drop over diffuse double layers. Recently, we analyzed the behavior of inverse micelles in a nonpolar liquid close to this electrode–liquid interface. For the fluorocarbon/surfactant system under study, we are in the limit of slow adsorption and negligible desorption of inverse micelles on the electrodes. Upon applying a voltage step, this results in a measurable Stern layer buildup in the time range of hours clearly distinguishable from the diffuse double layer buildup, which happens in less than 1 s. This Stern layer buildup manifests itself by a shift in the voltage drop from the diffuse double layer to the Stern layer until the voltage drop over the Stern layers reaches the applied voltage, leaving a zero bulk field without the diffuse double layer. New measurements of the transients of Stern layer buildup show that the buildup of charges in the Stern layer is more complex. We explain the observed transient behavior by introducing an asymmetry in the adsorption rate of charged inverse micelles. We provide an equivalent electrical network, an analytical solution to explain the behavior in more detail, and simulations within the diffuse double layer limit for a range of adsorption rates.

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Charging Dynamics of Aerosol OT Inverse Micelles

Cited by 11 publications

References 44 publications

Electrodynamics of Electronic Paper Based on Total Internal Reflection

Electrodynamics of Electronic Paper Based on Total Internal Reflection

Charge and Electrical Double Layer Formation in a Nonpolar Solvent Using a Nonionic Surfactant

Polarity-Dependent Adsorption of Inverse Micelles

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