SECTION 2 Analogies

We continue to assume that d = pn. As in Section 2 analogous results will hold for general d. To any allowed sequence 6 there is associated the function... 

When one refers to the in situ gas-volume fraction, Rq, the term void fraction is commonly used. The holdup ratio, Hb), is a related quantity, and is defined as the ratio of the gas-liquid volume ratio in the feed to the gas-liquid volume ratio in the flow section. Analogous to these... 

This review on the synthesis, properties, and chemistry of coordination complexes will concentrate on the literature since the end of 1985, referring to earlier literature only where relevant. It includes a general survey of recent publications, with more detailed discussions of interesting developments in the latter sections. Analogous Ru chemistry will also be included in particular sections, to show the similarities and differences in the chemistry of these elements. Appropriate literature dealing with organometallic chemistry will be referred to where relevant to the discussion of the coordination chemistry, because Os chemistry often transcends these traditional boundaries. However, no attempt has been made to review recent developments in Os organo-... 

In the present section, analogies and similarities will be noted between enzymes and heterogeneous catalysts in the concept of the active site and metal-protein/metal-support analogies the possession of size and shape selectivity the similarity or identity in kinetics between the two processes the use of electrochemical organization on a molecular or supramolecular level the possibility of... 

In Section 4.2.2.3 examples are given where the product is treated with bases and acids to enable the separation of the product. In this section analogous cases will... 

Note that the group cross section Si2 is in fact the slowing-down cross section (analogous to 2 ) from the fast group to the slow. With these definitions Eqs. (8.325) and (8.326) may be written... 

This chapter presents engineering characteristics of strong ground motion. In section Analog... 

There has been much activity in the study of monolayer phases via the new optical, microscopic, and diffraction techniques described in the previous section. These experimental methods have elucidated the unit cell structure, bond orientational order and tilt in monolayer phases. Many of the condensed phases have been classified as mesophases having long-range correlational order and short-range translational order. A useful analogy between monolayer mesophases and die smectic mesophases in bulk liquid crystals aids in their characterization (see [182]). 

Various functional forms for / have been proposed either as a result of empirical observation or in terms of specific models. A particularly important example of the latter is that known as the Langmuir adsorption equation [2]. By analogy with the derivation for gas adsorption (see Section XVII-3), the Langmuir model assumes the surface to consist of adsorption sites, each having an area a. All adsorbed species interact only with a site and not with each other, and adsorption is thus limited to a monolayer. Related lattice models reduce to the Langmuir model under these assumptions [3,4]. In the case of adsorption from solution, however, it seems more plausible to consider an alternative phrasing of the model. Adsorption is still limited to a monolayer, but this layer is now regarded as an ideal two-dimensional solution of equal-size solute and solvent molecules of area a. Thus lateral interactions, absent in the site picture, cancel out in the ideal solution however, in the first version is a properly of the solid lattice, while in the second it is a properly of the adsorbed species. Both models attribute differences in adsorption behavior entirely to differences in adsorbate-solid interactions. Both present adsorption as a competition between solute and solvent. 

The state of an adsorbate is often described as mobile or localized, usually in connection with adsorption models and analyses of adsorption entropies (see Section XVII-3C). A more direct criterion is, in analogy to that of the fluidity of a bulk phase, the degree of mobility as reflected by the surface diffusion coefficient. This may be estimated from the dielectric relaxation time Resing [115] gives values of the diffusion coefficient for adsorbed water ranging from near bulk liquids values (lO cm /sec) to as low as 10 cm /sec. 

The Langmuir-Hinshelwood picture is essentially that of Fig. XVIII-14. If the process is unimolecular, the species meanders around on the surface until it receives the activation energy to go over to product(s), which then desorb. If the process is bimolecular, two species diffuse around until a reactive encounter occurs. The reaction will be diffusion controlled if it occurs on every encounter (see Ref. 211) the theory of surface diffusional encounters has been treated (see Ref. 212) the subject may also be approached by means of Monte Carlo/molecular dynamics techniques [213]. In the case of activated bimolecular reactions, however, there will in general be many encounters before the reactive one, and the rate law for the surface reaction is generally written by analogy to the mass action law for solutions. That is, for a bimolecular process, the rate is taken to be proportional to the product of the two surface concentrations. It is interesting, however, that essentially the same rate law is obtained if the adsorption is strictly localized and species react only if they happen to adsorb on adjacent sites (note Ref. 214). (The apparent rate law, that is, the rate law in terms of gas pressures, depends on the form of the adsorption isotherm, as discussed in the next section.)... 

In this section, we concentrate on the relationship between diffraction pattern and surface lattice [5], In direct analogy with the tln-ee-dimensional bulk case, the surface lattice is defined by two vectors a and b parallel to the surface (defined already above), subtended by an angle y a and b together specify one unit cell, as illustrated in figure B1.21.4. Withm that unit cell atoms are arranged according to a basis, which is the list of atomic coordinates within drat unit cell we need not know these positions for the purposes of this discussion. Note that this unit cell can be viewed as being infinitely deep in the third dimension (perpendicular to the surface), so as to include all atoms below the surface to arbitrary depth. 

A further preliminary statement to this section would be that, somewhat analogously to classical physics or mechanics where positions and momenta (or velocities) are the two conjugate variables that determine the motion, moduli and phases play similar roles. But the analogy is not perfect. Indeed, early on it was questioned, apparently first by Pauli [104], whether a wave function can be constructed from the knowledge of a set of moduli alone. It was then argued by Lamb [105] that from a set of values of wave function moduli and of their rates... 

These terms are analogous to those on p. 265 of [7], It will be noted that the symbol c has been reinstated as in Section VI.F, so as to facilitate the order of magnitude estimation in the nearly nonrelativistic limit. We now proceed based on Eq. (168) as it stands, since the transformation of Eq. (168) to modulus and phase variables and functional derivation gives rather involved expressions and will not be set out here. 

In this section, notions used to describe nonrelativistic conical intersections are extended to the present case. For simplicity, unless otherwise specified we consider the ri = 3 case. The analogous treatment for T = 5 will be reported in [17]. 

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