Counterions nature

Interestingly, analogous platinum complexes decomposed under these acidic conditions. Even if the optimized yield is still below industrial expectations, tuning of the carbene, counterion nature and reaction conditions should lead to major improvement [170]. 

The catalytic activity of macroporous anionite and Amberlite gel in the reaction of acrylic acid esterification by epichlorohydrin was studied at 50- 90 C as a function of the catalyst concentration, molar ratio of reaction mixture components, counterion nature, reaction medium and catalyst particle size [36]. It was found that the reaction proceeds with an appreciable rate even in the presence of a very slight amount of catalyst. Furthermore, the product yield increased with an increment in the catalyst concentration and reaction temperature. The OH-form of ion-exchange resins was most active, and polar solvents promoted the process. 

Relaxation phenomena associated to redox switching of ECPs have been extensively studied [161-164], notably because of their implication in some important application fields like electrochro-mism [165]. In particular, the influence of various parameters like the counterion nature [166], the polymer thickness [167], the solvent properties [168], or the waiting potential [169] has been investigated. 

Because of the charged nature of many Langmuir films, fairly marked effects of changing the pH of the substrate phase are often observed. An obvious case is that of the fatty-acid monolayers these will be ionized on alkaline substrates, and as a result of the repulsion between the charged polar groups, the film reverts to a gaseous or liquid expanded state at a much lower temperature than does the acid form [121]. Also, the surface potential drops since, as illustrated in Fig. XV-13, the presence of nearby counterions introduces a dipole opposite in orientation to that previously present. A similar situation is found with long-chain amines on acid substrates [122]. 

The effect is more than just a matter of pH. As shown in Fig. XV-14, phospholipid monolayers can be expanded at low pH values by the presence of phosphotungstate ions [123], which disrupt the stmctival order in the lipid film [124]. Uranyl ions, by contrast, contract the low-pH expanded phase presumably because of a type of counterion condensation [123]. These effects caution against using these ions as stains in electron microscopy. Clearly the nature of the counterion is very important. It is dramatically so with fatty acids that form an insoluble salt with the ion here quite low concentrations (10 M) of divalent ions lead to the formation of the metal salt unless the pH is quite low. Such films are much more condensed than the fatty-acid monolayers themselves [125-127]. 

The reaction medium plays a very important role in all ionic polymerizations. Likewise, the nature of the ionic partner to the active center-called the counterion or gegenion-has a large effect also. This is true because the nature of the counterion, the polarity of the solvent, and the possibility of specific solvent-ion interactions determines the average distance of separation between the ions in solution. It is not difficult to visualize a whole spectrum of possibilities, from completely separated ions to an ion pair of partially solvated ions to an ion pair of unsolvated ions. The distance between the centers of the ions is different in... 

The nature of the sulfonium stmcture affects the yield and quaUty of the resulting PPV, and it has been found that use of cycHc sulfonium stmctures (12) is preferable (106). With cycHc sulfonium polyelectrolytes, more efficient elimination of sulfur and the counterion occurs during thermal conversion, so fewer sp defects are present in the final PPV. 

Pyrazole and its C-methyl derivatives acting as 2-monohaptopyrazoles in a neutral or slightly acidic medium give M(HPz) X, complexes where M is a transition metal, X is the counterion and m is the valence of the transition metal, usually 2. The number of pyrazole molecules, n, for a given metal depends on the nature of X and on the steric effects of the pyrazole substituents, especially those at position 3. Complexes of 3(5)-methylpyrazole with salts of a number of divalent metals involve the less hindered tautomer, the 5-methylpyrazole (209). With pyrazole and 4- or 5-monosubstituted pyrazoles M(HPz)6X2... 

Here AX is the acetyl compound (acetyl chloride or acetic anhydride), N is N-methylimidazole, I is the intermediate (presumably A -acetyl-A -methylimidazo-lium ion), X is the counterion (chloride or acetate), and ROH is the acetyl acceptor (alcohol or water). A general treatment of Scheme XXIII requires specification of the detailed nature of and k[ and is probably too complicated to be of practical use. However, several important special cases may arise from the operation of the ratio kxlk x, the behavior of apparent rate constants k /. and k, the relative magnitudes of k / and k, the relative concentrations of the reactants, the method of observation, and the nature of ROH. These cases are outlined in Scheme XXIV. 

The mechanical properties of ionomers can be appreciably altered by the manner in which the ionomer is prepared and treated prior to testing. Some of the factors that are influential are the degree of conversion (neutralization) from the acid form to the salt form, the nature of the thermal treatment or aging, the type of counterion that is introduced, the solvent that is used for preparation of thin films, and the presence and nature of any plasticizers or additives that may be present. In the scope of this chapter, it is not possible to provide a complete description of the influence of each of these variables on the wide variety of ionomers that are now commercially available or produced in the laboratory. Instead, one or more examples of the changes in properties that may be induced by each of the processing variables is presented and discussed. 

The parameter n reflects the measure of deviation of the system from the behavior of the monomeric acid where n = 1, i.e., it characterizes the degree of interaction between the neighboring functional groups of the macroion. The value of n depends on the structure of the polyelectrolyte and the nature of the counterion pK = pK0 — log (1 — a)/a is the negative decadic logarithm of the effective dissociation constant of the carboxylic CP depending on a. 

Either diastereomer 2 or 3 may be preferentially produced with high selectivity depending on the nature of the enolate counterion present2642-44. Mechanistic details of the diastercofacial differentiation process are not clear in many cases the diastereomeric ratio of the products exhibits a complex dependence on stoichiometry, enolate counterion and reaction conditions26. The dependence of the d.r. on the nature of the enolate counterion is roughly outlined (vide supra) while examples of conditions employed for the reaction of the enolates 1 with prochiral aldehydes arc listed (Table 4). 

For amide enolates (X = NR2), with Z geometry, model transition state D is intrinsically favored, but, again, large X substituents favor the formation of nt/-adducts via C. Factors that influence the diastereoselectivity include the solvent, the enolate counterion and the substituent pattern of enolate and enonc. In some cases either syn- or unh-products are obtained preferentially by varying the nature of the solvent, donor atom (enolate versus thioeno-late), or counterion. Most Michael additions listed in this section have not been examined systematically in terms of diastereoselectivity and coherent transition stale models are currently not available. Similar models to those shown in A-D can be used, however all the previously mentioned factors (among others) may be critical to the stereochemical outcome of the reaction. 

A fundament of the quantum chemical standpoint is that structure and reactivity are correlated. When using quantum chemical reactivity parameters for quantifying relationships between structure and reactivity one has the advantage of being able to describe the nature of the structural influences in a direct manner, without empirical assumptions. This is especially valid for the so-called Salem-Klopman equation. It allows the differentiation between the charge and the orbital controlled portions of the interaction between reactants. This was shown by the investigation of the interaction between the Lewis acid with complex counterions 18> (see part 4.4). 

The solids were used as catalysts in the benchmark cyclopropanation reaction between styrene and ethyl diazoacetate (Scheme 7). As far as the nature of the clay is concerned, laponite was foimd to be the best support for the catalytic complexes. The best enantioselectivity results (Table 7) were obtained with ligand 6b (69% ee in trans cyclopropanes and 64% ee in cis cyclopropanes) but the recovered solid showed a lower activity and enantioselectivity, which was attributed to partial loss of the chiral ligand from the support. In general, the use of the three chiral ligands led to enantioselectivity results that were intermediate between those obtained in homogeneous phase with CuCl2 and Cu(OTf)2 as catalyst precursors. This seemed to indicate that the sohd behaved as a counterion with an intermediate coordinating abihty to the copper centers. 

The polyelectrolyte properties of pectins are breefly exposed specially the role of the carboxylic groups distribution along the chain is demonstrated to controll the electrostatic properties. The viscometric behaviour depends on the ionic concentration and on the nature of the counterions in relation with electrostatic repulsions. 

One of the main characteristic of polyelectrolyte is the pK of the - COOH function as usually with polyelectrolyte only the intrinsic pK (pKo) extrapolated to zero charge characterizes the polymer [41] one gets 3.30 which is in same range as other carboxylic polymers the apparent values of pK (pKa) depends on the charge distribution, on the polymer concentration, on the ionic strength of the solution and on the nature of the counterions. 

The purpose of this study is to consider in more detail the influence of the size and nature of the counterion on the degree and extent of dissociation of poly(a-D)galacturonic acid already discussed in a previous paper [2], particularly to check the effect of screening the charges on the polyacid in the presence of different counterions. 

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