Nucleophilic attack Subject

The mechanism of anionic polymerization of cyclosiloxanes has been the subject of several studies (96,97). The first kinetic analysis in this area was carried out in the early 1950s (98). In the general scheme of this process, the propagation/depropagation step involves the nucleophilic attack of the silanolate anion on the sUicon, which results in the cleavage of the siloxane bond and formation of the new silanolate active center (eq. 17). 

The chemistry of this cure system has been the subject of several studies (44—47). It is now generally accepted that the cure mechanism involves dehydrofluorination adjacent to hexafluoropropylene monomer units. The subsequent fluoroolefin is highly reactive toward nucleophilic attack by a variety of curatives (eg, diamines, diphenols). 

There are expressions of uncertainty concerning the mechanism of the first step of the Strecker amino acid synthesis13-17. The reaction can proceed via the formation of an imine and subsequent nucleophilic attack of cyanide (path ). Alternatively, it has been speculated that the reaction of the aldehyde with hydrogen cyanide furnishes a cyanohydrin (path ), which then is subjected to a nucleophilic displacement of the hydroxy group by the amino function. 

In a recent study, we showed that the more flexible pyrido[l,2-a]indole-based cyclopropyl quinone methide is not subject to the stereoelectronic effect.47 Scheme 7.17 shows an electrostatic potential map of the protonated cyclopropyl quinone methide with arrows indicating the two possible nucleophilic attack sites on the electron-deficient (blue-colored) cyclopropyl ring. The 13C label allows both nucleophile attack products, the pyrido[l,2-a]indole and azepino [l,2-a]indole, to be distinguished without isolation. The site of nucleophilic is under steric control with pyrido [1,2-a]indole ring formation favored by large nucleophiles. 

In reactions with azides, ketones are directly converted to 5-hydroxytriazolines. Ketone enolate 247, generated by treatment of norbornanone 246 with LDA at 0°C, adds readily to azides to provide hydroxytriazolines 248 in 67-93% yield. Interestingly, l-azido-3-iodopropane subjected to the reaction with enolate 247 gives tetracyclic triazoline derivative 251 in 94% yield. The reaction starts from an electrophilic attack of the azide on the ketone a-carbon atom. The following nucleophilic attack on the carbonyl group in intermediate 249 results in triazoline 250. The process is completed by nucleophilic substitution of the iodine atom to form the tetrahydrooxazine ring of product 251 (Scheme 35) <2004JOC1720>. 

Extracellular peroxidases are produced by Streptomyces chromofuscus, with the capability to decolorize azo dyes associated to ligninolytic activity in aerobiosis. Azo dyes are converted to cationic radicals, which are subjected to nucleophilic attack by water or hydrogen peroxide molecules, producing reactive compounds that undergo redox reactions that result in a more stable intermediate [37]. 

This system was described in one report and has been synthesized by a copper-assisted cycloisomerization of alkynyl imines. The authors proposed the following mechanism at first, 372 could undergo a base-induced propargyl-allenyl isomerization to form 373 next, coordination of copper to the terminal double bond of the allene (intermediate 374) would make it subjected to intramolecular nucleophilic attack to produce a zwitterion 375. The latter would isomerize into the more stable zwitterionic intermediate 376, which would be transformed to the thiazole 377 (Scheme 55) <2001JA2074>. 

The sulfur atom of a sulfenic acid is itself subject to nucleophilic attack under appropriate conditions. Thiols have been shown (Allan et al., 1973) to react with sulfenic acid [7] in the manner indicated in (15), a reaction that... 

In acid solution an equilibrium (116) similar to (111) also exists for a disulfide and sulfinic acid. The work of Smallcombe and Caserio (1971) discussed earlier has shown that the dico-ordinate sulfur atom in species of the type SR is subject to very rapid nucleophilic attack by sulfides or disulfides so it is hardly surprising that [28] can be readily attacked by a second molecule of disulfide in the fashion shown in (117) (Kice and Morkved, 1964). The dithiosulfonium ion so produced then reacts rapidly with sulfinic acid to form the thiolsulfonate ArSQ2SR (118), a reaction analogous to... 

The pH-rate profile for reaction of nitrosobenzene with A-methylhydroxylamine (to form only 1-methyl 2-phenyldiazene-2-oxide) has been found to exhibit a negative break between pH 0.5 and 3.0. This has been ascribed to a change in ratedetermining step from nucleophilic attack on nitrosobenzene at low pH to dehydration of the A,iV -dihydroxy intermediate at higher pH the dehydration is subject to general-acid catalysis a = 0.34) and specific and general-base catalysis (f) = 0.20). The pH-rate profile is similar to that for reaction of A-methylhydroxylamine with... 

Thus, ketone enolates easily substitute chlorine in position 2 of the electrophilic nucleus of pyrazine (1,4-diazabenzene), and even in the dark, the reaction proceeds via the Sj l mechanism (Carver et al. 1981). It is expected that the introduction of the second chlorine in the ortho position to 4-nitrogen in the electrophilic nucleus of pyrazine promotes the ion-radical pathway even more effectively. However, 2,6-dichloropyrazine in the dark or subjected to light reacts with the same nucleophiles by Sr.,2 and not S nI mechanism (Carver et al. 1983). The authors are of the opinion that two halogens in the pyrazine cycle facilitate the formation of a-complex to the extent that deha-logenation of anion-radicals in solution and a subsequent nucleophilic attack of free pyrazine radical become virtually impossible. Thus, the reaction may either involve or exclude the intermediate a-complex, and only special identification experiments can tell which is the true one. 

When 2,2-dichloro-3-phenylpropanal 203 is subjected to standard reaction conditions with chiral triazolium salt 75c, the desired amide is produced in 80% ee and 62% yield Eq. 20. This experiment suggests that the catalyst is involved in an enantioselec-tive protonation event. With this evidence in hand, the proposed mechanism begins with carbene addition to the a-reducible aldehyde followed by formation of activated car-boxylate XLII (Scheme 32). Acyl transfer occurs with HOAt, presumably due to its higher kinetic nucleophilicity under these conditions, thus regenerating the carbene. In turn, intermediate XLin then undergoes nucleophilic attack by the amine and releases the co-catalyst back into the catalytic cycle. 

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