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Microelectrodes viscosity

What happens when the dimensions are furthermore reduced Initially, an enhanced diffusive mass transport would be expected. That is true, until the critical dimension is comparable to the thickness of the electrical double layer or the molecular size (a few nanometers) [7,8]. In this case, diffusive mass transport occurs mainly across the electrical double layer where the characteristics (electrical field, ion solvent interaction, viscosity, density, etc.) are different from those of the bulk solution. An important change is that the assumption of electroneutrality and lack of electromigration mass transport is not appropriate, regardless of the electrolyte concentration [9]. Therefore, there are subtle differences between the microelectrodic and nanoelectrodic behaviour. [Pg.772]

The diffusion studies described in the above sections pertain to water-continuous and bicontinuous microemulsions. Chen and Georges [34] were the first to study diffusion in oil-continuous microemulsions using steady-state microelectrode voltammetry. Ferrocene was used to probe diffusion in an SDS-dodecane-1-heptanol-water system. The diffusion coefficient of the hydrophobic probe indicated the microviscosity of the oil rather than the bulk viscosity of the microemulsion. Owlia et al. [36] reported diffusion coefficient measurements of water droplets in an Aerosol OT [AOT, bis(2-ethylhexyl)sulfosuccinate] microemulsion using a microelectrode. Water-soluble cobalt(II) corrin complex (vitamin Bi2r) was used in an oil-continuous microemulsion containing 0.2 M AOT, 4 M water buffered at pH 3, and isooctane. The apparent diffusion coefficient decreased with the probe concentration in accordance with Eq. (13) as shown in Fig. 6 [36]. The water droplet size was... [Pg.666]

Figure 8 shows the results on the diffusion coefficient of Fc in a water/acetone mixed solution obtained from the cyclic voltammogram using a microelectrode without the fixed gel and Eq. (3). This diffusion coefficient corresponds to the diffusion coefficient Dq of Fc in the external solution in Fig. 1. As the viscosity of acetone is less than that of water, Dq is larger in acetone. However, the Dq value does not change linearly with respect to the solvent composition and it shows a minimum at an acetone... Figure 8 shows the results on the diffusion coefficient of Fc in a water/acetone mixed solution obtained from the cyclic voltammogram using a microelectrode without the fixed gel and Eq. (3). This diffusion coefficient corresponds to the diffusion coefficient Dq of Fc in the external solution in Fig. 1. As the viscosity of acetone is less than that of water, Dq is larger in acetone. However, the Dq value does not change linearly with respect to the solvent composition and it shows a minimum at an acetone...
See other pages where Microelectrodes viscosity is mentioned: [Pg.587]    [Pg.371]    [Pg.475]    [Pg.37]    [Pg.38]    [Pg.537]    [Pg.203]    [Pg.353]    [Pg.179]    [Pg.1194]    [Pg.462]    [Pg.203]    [Pg.453]    [Pg.177]    [Pg.192]    [Pg.643]    [Pg.270]   
See also in sourсe #XX -- [ Pg.195 ]



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