Dielectric Dispersion of Water in the Frequency Range from 10 mHz to 30 MHz

Batalioto, F.; Duarte, A. R.; Barbero, Giovanni; Neto, Antônio Martins Figueiredo

doi:10.1021/jp910114y

Cited by 28 publications

(16 citation statements)

References 25 publications

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“…The diffusion impedance analysis could be complicated in case of anomalous behavior [20][21][22][23]. But in the present case, the hypothesis of diffusion impedance could be disregarded due to the fact that the microelectrodes were not in contact with electrolyte and the current was not faradaic.…”

Section: Eis Measurements In Microchannel Filled With Nacl Solutionmentioning

confidence: 88%

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Kechadi

Gamby

Chaal

et al. 2013

Electrochimica Acta

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a b s t r a c tThe present work describes a new methodology for contact free impedance of a solution in a polymer microchip taking into account the role played by the surrounding polymer on the impedance accuracy. Measurements were carried out using a photoablated polyethylene terephthalate (PET) microchannel above two embedded microband electrodes. The impedance diagrams exhibit a loop from high frequencies to medium frequencies (1 MHz-100 Hz) and a capacitive behavior at low frequencies (100-1 Hz). The impedance diagrams were corrected by eliminating from the global microchip response the contribution of the impedance of the PET layer between the two microband electrodes. This operation enables a clear observation of the impedance in the microchannel solution, including the bulk solution contribution and the interfacial capacitance related to the surface roughness of the photoablated microchannel. Models for the impedance of solutions of varying conductivity showed that the capacitance of the polymer-solution interface can be modeled by a constant phase element (CPE) with an exponent of 0.5. The loop diameter was found to be proportional to the microchannel resistivity, allowing a cell constant around 4.93 × 10 5 m −1 in contactless microelectrodes configuration.

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Section: Eis Measurements In Microchannel Filled With Nacl Solutionmentioning

confidence: 88%

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Kechadi

Gamby

Chaal

et al. 2013

Electrochimica Acta

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“…We analyzed our NaCl solution measurements based on the model of Debye [1929]. Similar to the work of Batalioto et al [2010] on dielectric dispersion of water, we fitted our experimental data to Debye's model to validate our NaCl solution measurements. We limited our validation to the case that one relaxation time is enough for a reasonably good description of our NaCl solution measurements.…”

Section: Methodsmentioning

confidence: 99%

Hysteresis in the nonmonotonic electric response of homogeneous and layered unconsolidated sands under continuous flow conditions with water of various salinities, 100 kHz to 2 MHz

Kavian¹,

Slob²,

Mulder³

2011

J. Geophys. Res.

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[1] We measured the electric parameters for four different configurations of unconsolidated homogeneous and layered sands as a function of frequency, water saturation, and salinity under fluid flow conditions. Our objective is to determine if the effect of heterogeneities at scales much smaller than the skin depth can be captured by introducing effective frequency-dependent electrical values whose behavior can be described by simple functions. We employed the parallel plate capacitor technique to measure the complex impedance over a broad frequency range, from 100 kHz up to 3 MHz. We conducted main drainage and secondary imbibition cycles at atmospheric pressure and temperatures between 21°C and 22°C. The hysteretic effect in the real part of the effective complex permittivity at higher concentrations of NaCl is more pronounced for the homogeneous configurations than for the heterogeneous samples. Effective medium theory works well for dry and saturated layered sand, when the NaCl solution concentration is 1 mmol/l. It fails for fully saturated layered sands at salinities of 10 mmol/l or more. It also does not work for partially saturated sands, independent of salinity. A description of the electric properties of a layered sand at all saturation levels by means of an effective homogeneous medium will therefore require a dependence on frequency, saturation level, and salinity of the pore fluid. An extended version of the Cole-Cole model fits the nonmonotonic behavior of the real part of permittivity versus saturation.Citation: Kavian, M., E. C. Slob, and W. A. Mulder (2011), Hysteresis in the nonmonotonic electric response of homogeneous and layered unconsolidated sands under continuous flow conditions with water of various salinities, 100 kHz to 2 MHz,

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“…[38-12 40] Thus our data is indicative that the DND seeding causes differences in conduction behavior of the dissociated ions. [38] The values for the components of the equivalent circuit shown in Fig. 2 as obtained from LEVMW are summarized in Fig.…”

Section: Resultsmentioning

confidence: 99%

Characterization of Nanodiamond Seeded Interdigitated Electrodes using Impedance Spectroscopy of Pure Water

Hasan

Zhang

Radadia

2016

Electrochimica Acta

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We have recently demonstrated enhancement in sensitivity of an impedance biosensor by seeding detonation nanodiamonds (DNDs) at the interdigitated electrodes (IDEs). Here, impedance spectroscopy of pure water is carried out at such IDEs to reveal the role of the DNDs. The impedance data is fit to an equivalent circuit model consisting of a geometrical resistance in series with a distributed element for Havriliak-Negami (HN) relaxation, and in parallel with a geometrical capacitance. Concurrently, the motion of charges across the IDEs is modeled as Plank-Nerst-Poisson anomalous diffusion across two partially blocking conductive electrodes. Results show that the DNDs (having a positive zeta potential) at the IDEs reduce the geometrical resistance

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Dielectric Dispersion of Water in the Frequency Range from 10 mHz to 30 MHz

Cited by 28 publications

References 25 publications

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Hysteresis in the nonmonotonic electric response of homogeneous and layered unconsolidated sands under continuous flow conditions with water of various salinities, 100 kHz to 2 MHz

Characterization of Nanodiamond Seeded Interdigitated Electrodes using Impedance Spectroscopy of Pure Water

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