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Electric properties formal charges

What is the Gibbs free energy of an electric double layer The energy of an electric double layer plays a central role in colloid science, for instance to describe the properties of charged polymers (polyelectrolytes) or the interaction between colloidal particles. Here, we only give results for diffuse layers because it is simpler and in most applications only the diffuse layer is relevant. The formalism is, however, applicable to other double layers as well. [Pg.54]

Fluctuations in the dielectric properties near the interface lead to scattering of the EW as well as changes in the intensity of the internally reflected wave. Changes in optical absorption can be detected in the internally reflected beam and lead to the well-known technique of attenuated total reflectance spectroscopy (ATR). Changes in the real part of the dielectric function lead to scattering, which is the main topic of this review. Polarization of the incident beam is important. For s polarization (electric field vector perpendicular to the plane defined by the incident and reflected beams or parallel to the interface), there is no electric held component normal to the interface, and the electric field is continuous across the interface. For p polarization (electric field vector parallel to the plane defined by the incident and reflected beams), there is a finite electric field component normal to the interface. In macroscopic electrodynamics this normal component is discontinuous across the interface, and the discontinuity is related to the induced surface charge at the interface. Such discontinuity is unphysical on the molecular scale [4], and the macroscopic formalism may have to be re-examined if it is applied to molecules within a few A of the interface. [Pg.175]

Apart from equifinality, another important property of these operator networks is the periodic character of the changes in the properties and nature of the clusters constituting them. This peculiarity is clearly revealed when such networks are transformed into periodic tables grouped, for instance, in accordance with the principle of similarity of formal electric charge for corresponding clusters, as shown in Fig. 4.10 for even (represented by carbon) and for odd (represented by phosphorus) elements. Such tables of... [Pg.171]

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See also in sourсe #XX -- [ Pg.18 , Pg.53 , Pg.66 ]

See also in sourсe #XX -- [ Pg.18 , Pg.53 , Pg.66 ]



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