Electrophilic substitution rate studies

From these results it appears that the 5-position of thiazole is two to three more reactive than the 4-position, that methylation in the 2-position enhances the rate of nitration by a factor of 15 in the 5-position and of 8 in the 4-position, that this last factor is 10 and 14 for 2-Et and 2-t-Bu groups, respectively. Asato (374) and Dou (375) arrived at the same figure for the orientation of the nitration of 2-methyl and 2-propylthiazole Asato used nitronium fluoroborate and the dinitrogen tetroxide-boron trifluoride complex at room temperature, and Dou used sulfonitric acid at 70°C (Table T54). About the same proportion of 4-and 5-isomers was obtained in the nitration of 2-methoxythiazole by Friedmann (376). Recently, Katritzky et al. (377) presented the first kinetic studies of electrophilic substitution in thiazoles the nitration of thiazoles and thiazolones (Table 1-55). The reaction was followed spec-trophotometrically and performed at different acidities by varying the... 

At this point, attention can be given to specific electrophilic substitution reactions. The kinds of data that have been especially useful for determining mechanistic details include linear ffee-energy relationships, kinetic studies, isotope effects, and selectivity patterns. In general, the basic questions that need to be asked about each mechanism are (1) What is the active electrophile (2) Which step in the general mechanism for electrophilic aromatic substitution is rate-determining (3) What are the orientation and selectivity patterns ... 

Equation (7-85) is a selectivity-reactivity relationship, with lower values of Sf denoting lower selectivity. Lower values ofpt correspond to greater reactivity, with the limit being a partial rate factor of unity for an infinitely reactive electrophile. This selectivity-reactivity relationship is followed for the electrophilic substitution reactions of many substituted benzenes, although toluene is the best studied of these. 

Kinetic studies are of little value in attempting to determine the extent of complex formation in the reaction path of electrophilic substitution. The reasons for this have been adequately presented elsewhere29 and the conclusions are that, unless the formation of the complex is rate-determining, the kinetic form is independent of complex formation. Further, the influence of complex formation on reaction rates only comes from the factors which lead in the first place to complex formation, and substituent effects are inadequate for showing the extent of complex formation though when they indicate similar effects on substitution and complex formation they provide evidence that the latter is a pathway of the former. 

A kinetic study of the electrophilic substitution of pyridine-N-oxides has also been carried out50b,c. Rate-acidity dependencies were unfortunately given in graphical form only and the rate parameters (determined mostly over a 30 °C range) are given in Table 4b. There is considerable confusion in Tables 3 and 5 of the original paper, where the rate coefficients are labelled as referring to the free base. In fact the rate coefficients for the first three substituted compounds in... 

Nitration by nitric acid in sulphuric acid has also been by Modro and Ridd52 in a kinetic study of the mechanism by which the substituent effects of positive poles are transmitted in electrophilic substitution. The rate coefficients for nitration of the compounds Pl CHi NMej (n = 0-3) given in Table 10 show that insertion of methylene groups causes a substantial decrease in deactivation by the NMej group as expected. Since analysis of this effect is complicated by the superimposed activation by the introduced alkyl group, the reactivities of the... 

The first quantitative study of the reaction was carried out with anthracene-9-carboxylic acid (which possesses the necessary steric requirement by virtue of the peri-hydrogen atoms, and is very reactive at the 9 position towards electrophilic substitution). Schenkel632 found that the decarboxylation rate was increased in the presence of acid, and the first-order rate coefficients (believed to be in sec-1) are given in Table 205. It was subsequently concluded that in the absence of acid,... 

Friedel-Crafts reactions involving electrophilic substitution of aromatic compounds have been reported on solid base catalysts such as thallium oxide and MgO. The rates of benzylation of toluene by benzyl chloride over MgO nanocrystals were found to be of the order CP-MgO > CM-MgO > AP-MgO.56 An important observation in the study was that x-ray diffraction of the spent catalyst... 

The apparently first kinetic study of a metal-assisted electrophilic substitution in a Co(III) complex is recent. The bromination of Co(NH3)5imidH is complicated by the presence of different bromine species in solution (Brj, HOBr and Brj"). In addition, successive brominations of the coordinated imidazole occur. Rate data can be interpreted in terms of reaction of the conjugate base of the Co(III) complex with Brj, and a suggested mechanism for the first steps is (Rq = Co(NH3)5 ")... 

Replacement of the proton by deuterium represents the simplest electrophilic substitution the process is effected by concentrated deuteriosulfuric acid. Deuteration studied over the ranges 45-96% acid and 150-250 °C showed that for both quinoline and quinoline AT-oxide reaction occurs in the positions 8>5,6>7>3 and rates increased both with increasing acid concentration and with temperature. The mechanism proceeds via the conjugate acid (Scheme 4) (75TL1395, 72IZV2092, 71JCS(B)4, 67CPB826). 

In the first example, we studied the competitive bromination of two disubsti-tuted trisacetylacetonates of chromium. The dichloro compound (X = C1) reacts with iV-bromosuccinimide much more rapidly than the dinitro compound (X =N02). The reaction is thought to involve electrophilic substitution. This substantial influence of substituents on the reaction rate is undoubtedly an electronic rather than a steric effect. 

In aromatic systems, the Lewis acids which activate via coordination are also capable of activating the aromatic system by the formation of a and ir complexes. There are a sufficient number of examples available to indicate that the activation via the latter processes is the more important of these, where all are present. Olivier (52) showed in 1913 that the kinetic behavior of such reactions consists of two portions. When the catalyst, say aluminum chloride, is present in less than the amount required to complex all the functional groups, the reaction is relatively slow and the catalytic activity is due to the small amount of Lewis acid resulting from the dissociation of the complex. As soon as all the functional groups are coordinated, any additional Lewis acid is found to accelerate the rate enormously. In these electrophilic substitutions it seems highly probable that the the activation involves the pi electron system of the benzene ring. Olivier studied the reaction sequence ... 

The relative reactivity of different positions toward electrophilic substitution is conveniently studied by acid-catalyzed deuterium exchange reaction rates can be followed by NMR and introduction of deuterium hardly affects the reactivity of the remaining positions. In D2S04 both quinoline and quinoline 1-oxide react as the conjugate acid at positions 8 > 5, 6 > 7 > 3. 

Two excellent reviews <71AHC(13)235, 72IJS(C)(7)6l) have dealt with quantitative aspects of electrophilic substitution on thiophenes. Electrophilic substitution in the thiophene ring appears to proceed in most cases by a mechanism similar to that for the homocyclic benzene substrates. The first step involves the formation of a cr-complex, which is rate determining in most reactions in a few cases the decomposition of this intermediate may be rate determining. Evidence for the similarity of mechanism in the thiophene and benzene series stems from detailed kinetic studies. Thus in protodetritiation of thiophene derivatives in aqueous sulfuric and perchloric acids, a linear correlation between log k and —Ho has been established the slopes are very close to those reported for hydrogen exchanges in benzene derivatives. Likewise, the kinetic profile of the reaction of thiophene derivatives with bromine in acetic acid in the dark is the same as for bromination of benzene derivatives. The activation enthalpies and entropies for bromination of thiophene and mesitylene are very similar. 

The activated halogenothiophene is more reactive than a similarly activated halogeno-benzene. A quantitative study of the rate of piperidino-debromination of six isomeric bromonitrothiophenes reveals that these substrates react considerably faster than the corresponding bromonitrobenzenes. As in electrophilic substitution, the 2,3-, 2,4- and 2,5-relationships have been equated to ortho, meta and para substitution in benzene derivatives. Although there is some validity in this, a few inexplicable results have been encountered in the above study thus 2-bromo-4-nitrothiophene reacts much faster than either 2-bromo-3-nitro- or 2-bromo-5-nitro-thiophene (64AHC(3)285>. 

By the same token that aza substituents retard electrophilic substitution, so they accelerate nucleophilic substitution,19,20 40 41 particularly when positively charged. In an interesting study based on this type of reactivity, the equilibrium 16 = 17 has been investigated,85 and this and the rate of subsequent ring opening leading to substituted anils of glutaconic aldehyde found to correlate with o. ... 

From the Fischer rate study, it appears that primaiy ester-substituted radicals are not electrophilic but ambiphilic and the borderline between ambiphilic and electrophilic radicals is not at all clear. Consider our results68 (Scheme 16) on the atom transfer additions of ester-substituted radicals to alkynes (with the caution that it may be dangerous to compare yields in place of rate constants). The primary ester-substituted radical adds more efficiently to 1-heptyne but the tertiary ester-substituted radical prefers ethyl propiolate. 

Although there are several studies of the reactions of quinolines, there is a paucity of data on electrophilic substitutions. In the case of quinoline, with the exception of the 5-position, all of the others are deactivated relative to benzene, but only by a slight amount [71JCS(B)4, 71JCS(B)2382], The partial rate factors for quinoline have also been determined [71JCS(B)1254],... 

A far more serious consideration is the adequacy of the solvolysis of phenyldimethylcarbinyl chlorides as a model reaction for electrophilic substitution. As will be shown, the cr -parameters derived from the phenyldimethylcarbinyl chloride studies are in good agreement with the a+-values deduced from the data for electrophilic substitution. Not all model reactions would have proved as satisfactory. As this research developed, it became clear that the influences of substituents on aromatic substitution reactions are quite accurately described by the other hand, the relative rates for electrophilic side-chain reactions of which the phenyldimethylcarbinyl chloride solvolysis is characteristic are not as adequately correlated by these constants. 

This pattern of reactivity is reflected in most reactions of electrophiles with complexes containing aromatic ligands the rates of reaction are modified but the position of substitution is unchanged with respect to the free ligand. The reactivity of a range of quinoline complexes with electrophiles has been studied in some detail and the products have been shown to be substituted in exactly the same sites as the free ligands. For example, di(8-oxyquinolinato)copper(n) reacts with molecular bromine to yield di(5,7-dibromo-8-oxyquinolinato)copper(n) (Fig. 8-3). 

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