Activation substitution, electrophilic

The model adopted by Ri and Eyring is not now acceptable, but some of the more recent treatments of electrostatic effects are quite close to their method in principle. In dealing with polar substituents some authors have concentrated on the interaction of the substituent with the electrophile whilst others have considered the interaction of the substituent with the charge on the ring in the transition state. An example of the latter method was mentioned above ( 7.2.1), and both will be encountered later ( 9.1.2). They are really attempts to explain the nature of the inductive effect, and an important question which they raise is that of the relative importance of localisation and electrostatic phenomena in determining orientation and state of activation in electrophilic substitutions. 

The reaction involves an electrophilic attack into the 5-position of the pyrimidine ring and thus only those pyrimidines that are activated toward electrophilic substitution by the presence of electron-donating substituents at the 2- and 4-positions undergo cyclization. 2,4,6-Triaminopyrimidine, 6-aminouracil, 6-amino-2-thiouracil, 4-amino-2,4 dimercaptopyrimidine, 2,4-diaminopyrimidin-6(l/I)-one, and various 4-amino-vV-alkyl and aryl pyriinidones have all been converted into pyrido[2,3-[Pg.160]

Electron-transfer activation of electrophilic aromatic substitution 274 Electron-transfer activation in nitrogen dioxide reactivity toward organic donors 292... 

ELECTRON-TRANSFER ACTIVATION OF ELECTROPHILIC AROMATIC SUBSTITUTION... 

Many unsaturated organosilicon compounds undergo facile electrophilic substitution reactions. The arylsilanes also appear to be activated towards electrophilic substitution. Substitution normally takes place exclusively at the site of silicon atom. 

Additional acylation studies were also reported (24), (26). In the first case it is claimed that acylation of thiophene is achieved by means of HC104 and acetic anhydride affording a 65 % yield of 2-acetylthiophene. In the second paper Levine and coworkers reported that while 2,5-dimethylthiophene could be readily acetylated, 2,5-dichlorothiophene acetylated sluggishly. This is, however, readily explained, since the presence of chlorine atoms on the thiophene ring decreased its reactivity in electrophilic substitution reactions. In the case of methyl substitution, however, the 3 and 4 positions of the ring are activated toward electrophilic substitution by the inductive and hyperconjugative effects. Thus 2,5-dimethylthiophene was successfully acylated by the boron fluoride etherate method in high yield with three aliphatic anhydrides. 

The formation of six-membered or larger rings by intramolecular C-H bond insertion normally requires the attacked position to be especially activated towards electrophilic attack [1157,1158]. Electron-rich arenes or heteroarenes [1159-1162] and donor-substituted methylene groups can react intramolecularly with electrophilic carbene complexes to yield six- or seven-membered rings. Representative examples are given in Table 4.8. 

A striking demonstration of the reduced activity towards electrophiles for the pyridine ring compared with the benzene ring will be seen later when we consider the fused heterocycles quinoline and isoquinoline (see Section 11.8.1). These contain a benzene ring fused to a pyridine ring electrophilic substitution occurs exclusively in the benzene ring. 

As Beak and coworkers have established several years ago, A-rert-butoxycarbonyla-mines are sufficiently acidic to be deprotonated adjacent to the nitrogen atom . When applying 5-BuLi/(—(-sparteine (11) to A-Boc-pyrrolidine, asymmetric deprotonation (149), onepro-S-H is removed with high selectivity, furnishing the configurationally stable 2-lithio derivative 150 which was trapped with several electrophiles to form the optically active substitution products 151 (equation 33) A prescription in Organic Syntheses is... 

With this purpose, several different types of solid acid catalysts have been investigated for the acylation of aromatics, but the best performances have been obtained with medium-pore and large-pore zeolites (3-9). In general, however, the use of acylating agents other then halides, e.g., anhydrides or acids, is limited to the transformation of aromatic substrates highly activated towards electrophilic substitution. In a previous work (10), we investigated the benzoylation of resorcinol (1,3-dihydroxybenzene), catalyzed by acid clays. It was found that the reaction mechanism consists of the direct 0-benzoylation with formation of resorcinol monobenzoate, while no primary formation of the product of C-benzoylation (2,4-dihydroxybenzophenone) occurred. The latter product formed exclusively by... 

The X-substituted benzene (aniline, Figure 11.2) is activated toward electrophilic attack since the HOMO is raised significantly. The electrophile would be directed to the ortho, para, and ipso positions of the ring and to the X substituent itself. The ipso channel is usually nonproductive since the common heteroatom-based X substituents are not easily displaced as Lewis acids. Loss of substituent is frequently observed with tertiary alkyl-substituted benzenes. Attachment of the electrophile to the X substituent is most likely if... 

The Z-substituted benzene (benzaldehyde, Figure 11.2) is not activated toward electrophilic attack since the HOMO of benzene is scarcely affected. No preferred site for attack of the electrophile can be deduced from inspection of the HOMOs. The interaction diagram for a Z-substituted pentadienyl cation, substituted in the 1-, 2-, and 3-positions, as models of the transition states for the ortho, meta, and para channels are too complex to draw simple conclusions. The HOMO and LUMO of the three pentadienyl cations with a formyl substituent are shown in Figure 11.4. The stabilities of the transition states should be in the order of the Hiickel n energies. These are 6a — 9.204 / , 6a — 9.2031/ , and 6a -9.1291/ , respectively. Thus, by SHMO, the ortho and meta channels are favored over the para channel, with no distinction between the ortho and meta pathways. Experimentally, meta substitution products are usually the major ones, contrary to the SHMO predictions. Either the SHMO method fails in this case or the predominance of meta products may be attributed to steric effects. 

Protecting the amino group of an arylamine in this way moderates its reactivity and permits nitration of the ring to be achieved. The acetamido group is activating toward electrophilic aromatic substitution and is ortho, para-directing. 

The effect of monofluorination on alkene or aromatic reactivity toward electrophiles is more difficult to predict Although a-fluonne stabilizes a carbocation relative to hydrogen, its opposing inductive effect makes olefins and aromatics more electron deficient. Fluorine therefore is activating only for electrophilic reactions with very late transition states where its resonance stabilization is maximized The faster rate of addition of trifluoroacetic acid and sulfuric acid to 2-fluoropropene vs propene is an example [775,116], but cases of such enhanced fluoroalkene reactivity in solution are quite rare [127] By contrast, there are many examples where the ortho-para-dueeting fluorine substituent is also activating in electrophilic aromatic substitutions [128]... 

Michael addition of substituted electrophilic olefins to the activated 2-substituent yields pyrrolooxazines on cyclization.244-248... 

Hyperconjugation also predicts that the R3SiCH2 group will be electron releasing at the ortho and para positions of an aromatic ring, and activating to electrophilic aromatic substitution, as shown in equation 4. 

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