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Neutral substrates

Fonnation of a complex with a copper cation only further stimulates this behaviour. As a result, S.lg is almost completely bound to the micelles, even at low concentrations of Cu(DS)2. By contrast, the reaction of 5.1 f still benefits from an increasing surfactant concentration at 10 mM of Cu(DS)2. In fact, it is surprising that the reaction of this anionic compound is catalysed at all by an anionic surfactant. Probably it is the copper complex of 5.If, being overall cationic, that binds to the micelle. Not surprisingly, the neutral substrate S.lc shows intermediate behaviour. [Pg.143]

The numerical values of F+ are found to be related to Y, the measure of solvent ionizing power for neutral substrates, by the equation... [Pg.256]

Thus, in contrast to an ionization process from a neutral substrate, which initially generates an intimate ion pair, deamination reactions generate a cation which does not have an anion closely associated with it. Furthermore, the leaving group, molecular nitrogen, is very stable so that little, if any, nutleophilic participation is needed for bond cleavage. The... [Pg.306]

VV -values for bromoform and pyrrole, acidic liquids, against poly(vinyl chloride), an acidic polymer, and dimethyl sulfoxide, a predominantly basic liquid, against polyfmethyl methacrylate), a basic polymer, but large values for the acidic liquids against PMMA and the basic liquid against PVC. 2-Iodoethanol, a bifunctional liquid, showed appreciable -values with both polymers. Despite these results in line with expectations, other results based on wettability measurements are not so clear-cut. For example, Vrbanac [94] found significant apparent acid-base interactions of various aromatic liquids against poly(ethylene), presumably a neutral substrate. [Pg.40]

Figure 14-12. Various types of OFETs. (a) Inverted coplanar on a highly doped Si wafer, (b) inverted coplanar on a neutral substrate, (c) inverted staggered oil a neutral substrate, (d) inverted staggered using the dielectric layer as the substrate. Figure 14-12. Various types of OFETs. (a) Inverted coplanar on a highly doped Si wafer, (b) inverted coplanar on a neutral substrate, (c) inverted staggered oil a neutral substrate, (d) inverted staggered using the dielectric layer as the substrate.
So far, many kinds of nucleophiles active for hydrolysis such as imidazolyl-, amino-, pyridino-, carboxyl- and thiol-groups, have been used for preparation of hydrolase models. Overberger et al.108,1091 prepared copolymers of vinylimidazole and acrylic acid 60 (PVIm AA), by which the cationic substrate, 61 (ANTI), was hydrolyzed. This kind of copolymer is considered to be a model of acetylcholinesterase. With ANTI, the rate of the copolymer catalysis was higher than that of imidazole itself in the higher values of pH, as is seen in Table 9. In this work, important contributions of the electrostatic interactions are clear. The activity of the copolymer was not as high with the negatively charged and neutral substrates. [Pg.162]

The formation of an ion will have a negative A F and hence electrode reactions which produce an anion or a cation from a neutral substrate wiU be favoured by an increase in pressure. That is, the reversible potential for the reaction... [Pg.205]

It is apparent that, as in chemical systems, the magnitude of these effects will become useful and interesting from a practical viewpoint only when the pressure is increased above one kilobar. Thus for a typical electron transfer reaction with JF"=—20 cm mole , AE will be 211 mV when the pressme is ten kilobars. This shift could be important in the not uncommon situation where, at atmospheric pressure, the oxidation of a neutral substrate occurs at around the same potential as the anion of the base electrolyte. An increase in the pressure to ten kilobars will result in a separation of the processes... [Pg.206]

Much of the interpretation of electroorganic reactions has assumed the model implied in the above discussion, i.e. conversion of the neutral substrate into a radical ion followed by distinct chemical and/or electrochemical steps. It follows therefore that specific structural effects should be found in the reactions of the intermediates. [Pg.210]

There is evidence, both experimental and theoretical, that there are intermediates in at least some Sn2 reactions in the gas phase, in charge type I reactions, where a negative ion nucleophile attacks a neutral substrate. Two energy minima, one before and one after the transition state, appear in the reaction coordinate (Fig. 10.1). The energy surface for the Sn2 Menshutkin reaction (p. 499) has been examined and it was shown that charge separation was promoted by the solvent.An ab initio study of the Sn2 reaction at primary and secondary carbon centers has looked at the energy barrier (at the transition state) to the reaction. These minima correspond to unsymmetrical ion-dipole complexes. Theoretical calculations also show such minima in certain solvents, (e.g., DMF), but not in water. "... [Pg.393]

The reaction between permangante ion and neutral formic acid follows similar bimolecular kinetics with k2 = 1.1 x 10 exp(—16.4x 10 /lt7 )l.mole . sec . No primary kinetic isotope effect was found for this path either in light or heavy water. However, Mocek and Stewart have reported that in very strong sulphuric acid the oxidations of neutral substrate by both HMnO and MnOj display substantial isotope effects. [Pg.317]

Fig. 14 Potential energy profile for stepwise and concerted mechanisms with (solid lines) and without (dotted lines) an attractive interaction between the caged fragments in the product cluster. The case of the reduction of a neutral substrate is represented. It can be transposed for reductions of a positively charged substrate or for oxidations of neutral or negatively charged substrates. Fig. 14 Potential energy profile for stepwise and concerted mechanisms with (solid lines) and without (dotted lines) an attractive interaction between the caged fragments in the product cluster. The case of the reduction of a neutral substrate is represented. It can be transposed for reductions of a positively charged substrate or for oxidations of neutral or negatively charged substrates.
Ionic reactions of neutral substrates can show large solvent dependence, due to the differential solvent stabilization of the ionic intermediates and their associated dipolar transition states (Reichardt, 1988). This is the case for the electrophilic addition of bromine to alkenes (Ruasse, 1990, 1992 Ruasse et al., 1991) and the bromination of phenol (Tee and Bennett, 1988a), both of which have Grunwald-Winstein m values approximately equal to 1 so that the reactions are very much slower in media less polar than water. Such processes, therefore, would be expected to be retarded or even inhibited by CDs for two reasons (a) the formation of complexes with the CD lowers the free concentrations of the reactants and (b) slower reaction within the microenvironment of the less polar CD cavity (if it were sterically possible). [Pg.17]

We have assumed that the values of as for formation weak encounter complexes between nucleophile and substrate, and between nucleophile and carbocation are similar. This is supported by the observation of similar values of [see above] for formation of encounter complexes between neutral substrate and anionic nucleophile (0.7 between cationic substrate and anionic nucleophile (0.2 and... [Pg.315]

The difference between A obsd and caic might be due to a specific salt effect on the rate constant for solvolysis. However, this is unlikely because perchlorate ion acts to stabilize carbocations relative to neutral substrates.At high concentrations of sodium bromide, the rate-limiting step for solvolysis of 1-Br is the capture of 1 by solvent (ks Scheme 5A). Substitution of Br for CIO4 should destabilize the carbocation-like transition state for this step relative to the starting neutral substrate, and this would lead to a negative, rather than positive deviation of obsd for equations (3A) and (3B). [Pg.317]

Fig. 3. A plot of the observed rate constant versus a for the hydrolysis of 3-nitro-4-acetoxy-benzene sulfonate in the presence of (1) 0.016 Af 4-methylpyridine (control) and (2) poly(4-vinyl-pyridine) with 0.01 M pyridine units. Line (3) is a calculated line projected from the pH dependence of the hydrolysis of a neutral substrate, dinitrophenyl acetate. From Letsinger and Savereide (55). Fig. 3. A plot of the observed rate constant versus a for the hydrolysis of 3-nitro-4-acetoxy-benzene sulfonate in the presence of (1) 0.016 Af 4-methylpyridine (control) and (2) poly(4-vinyl-pyridine) with 0.01 M pyridine units. Line (3) is a calculated line projected from the pH dependence of the hydrolysis of a neutral substrate, dinitrophenyl acetate. From Letsinger and Savereide (55).
On the basis of this equation, an index of nucleophilicity pt can be assigned to each nucleophile Y (see Table 4.13). It is found, moreover, that a plot against pt of logfcy, for reaction of Y with another Pt(II) neutral substrate, is also often linear. Thus, Eq. (2.168) applies, and 5 is termed the nucleophilic discrimination factor (Sec. 4.7.1). Some of the departures from linearity of plots of Ary vs p, which have been observed, disappear if the Pt reference substrate chosen is of the same charge as the Pt reactants. The value of p, for a bulky nucleophile has also to be modified to allow for steric hindrance features. [Pg.104]

The final stage of the reaction in Scheme 3.65 involves protonation, yielding the derivative of 1,4-dihydronaphthalene. The oxidation may produce a 4-substituted binaphthyl, which is not contaminated with the isomeric products. It is worth noting here that the described ion-radical method of introduction of the alkyl group into the aromatic nucleus has an advantage over the radical or heteroly tic alkylation. In these cases, the neutral substrate may produce a composite mixture of isomeric products. The binaphthyl anion-radical reaction proceeds regioselectively and nonstereospecifically. [Pg.184]

An attempt to combine electrochemical and micellar-catalytic methods is interesting from the point of view of the mechanism of anode nitration of 1,4-dimethoxybenzene with sodinm nitrite (Laurent et al. 1984). The reaction was performed in a mixture of water in the presence of 2% surface-active compounds of cationic, anionic, or neutral nature. It was established that 1,4-dimethoxy-2-nitrobenzene (the product) was formed only in the region of potentials corresponding to simultaneous electrooxidation of the substrate to the cation-radical and the nitrite ion to the nitrogen dioxide radical (1.5 V versus saturated calomel electrode). At potentials of oxidation of the sole nitrite ion (0.8 V), no nitration was observed. Consequently, radical substitution in the neutral substrate does not take place. Two feasible mechanisms remain for addition to the cation-radical form, as follows ... [Pg.255]

Scheme 7.26 reflects the final result of the reaction. The initial step of this reaction consists of one-electron oxidation of the substrate. The resulting cation-radical of o-diethynylbenzene transforms into a fulvenyl intermediate, which further reacts with the neutral substrate to yield fulvenyl... [Pg.367]

X 10 with acetylthiocholine. On the other hand, neutral substrates such as phenylacetate and isoamyla-cetate have bimolecular rate constants of 6 x 10 and... [Pg.198]

See other pages where Neutral substrates is mentioned: [Pg.108]    [Pg.264]    [Pg.264]    [Pg.266]    [Pg.433]    [Pg.161]    [Pg.450]    [Pg.380]    [Pg.211]    [Pg.209]    [Pg.196]    [Pg.211]    [Pg.300]    [Pg.85]    [Pg.165]    [Pg.739]    [Pg.271]    [Pg.273]    [Pg.170]    [Pg.214]    [Pg.314]    [Pg.315]    [Pg.332]    [Pg.153]    [Pg.300]    [Pg.66]    [Pg.243]    [Pg.328]    [Pg.88]    [Pg.88]   
See also in sourсe #XX -- [ Pg.227 , Pg.253 , Pg.390 , Pg.423 ]



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