Sentence examples for capacitance of the interface from inspiring English sources

The effect of capillary waves on the double layer capacitance of the interface between two immiscible electrolytes has been studied.

The solid part of the RGO paper exhibits at 50 Hz in-plane conductivity 31 S/m, through-thickness conductivity 1.17 S/m, through-thickness relative permittivity (imaginary part) −4.2 × 108, through-thickness dielectric loss angle 90.0°, specific capacitance of the interface with an electrical contact 0.31 μF/m2, and areal resistivity of this interface 0.18 Ω cm2.

At 50 Hz and 2 MHz respectively, the in-plane conductivity is 0.07 and 2.5 S/m, the through-thickness conductivity is 6.7 × 10−6 and 4.8 × 10−3 S/m, the through-thickness relative dielectric constant is 915 and 91, the specific capacitance of the interface with an electrical contact is 18.3 and 1.1 μF/m2, and the areal resistivity of this interface is 1.5 × 105 and 1.0 × 102 Ω cm2.

The electrical capacitance of the interface, C T, is expressed as the sum of two capacitors in series: Eq. (1).

CPE1 is the capacitance of the interface of substrate coating, and CPE2 is the coating capacitance observed for coatings that the solution penetrates in their structures due to presence of different defects or porosity.

In this context resistance and capacitance of the AgAgCl interface were measured and analysed in the light of ionic space charge effects.

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.

We have studied the capacitance of the solid/electrolyte interface on Ag(11n) and Au(11n) surfaces in KClO4 and HClO4 as function of the electrolyte concentration and the step density.

Besides, the analysis of the electrochemical impedance measurements showed that at an open-circuit potential (OCP), the polarization resistance and double-layer capacitance of the film/electrolyte interface of the laser-treated specimen were one order of magnitude higher and six times lower than that of the untreated specimen, respectively.

For potential values in the double layer region, the impedance behavior observed at low frequency was attributed to the double layer capacitance of the oxide/electrolyte interface, while at high frequency it was attributed to a mass transport limited process occurring in difficult-to-access oxide regions.

The electrode modified with GO/PPy-DEX film exhibited an impedance drop across all measured frequencies compared to both the bare electrode and the electrode modified with PPy-DEX, indicating that the nanocomposite film improves the capacitance of the electrode/electrolyte interface.