Heteroaromatic ring substitution

Reactions of aromatic and heteroaromatic rings are usually only found with highly reactive compounds containing strongly electron donating substituents or hetero atoms (e.g. phenols, anilines, pyrroles, indoles). Such molecules can be substituted by weak electrophiles, and the reagent of choice in nature as well as in the laboratory is usually a Mannich reagent or... 

Heteroaromatic ring stmctures can also be incorporated into poly(arylene vinylene) stmctures using the same precursor polymer method shown for PPV. Poly(thienylene vinylene) (13) (113—118) and poly(furylene vinylene) (14) (119,120) have been prepared in this manner. In addition, alkoxy-substituted poly(thienylene vinylenes) (15) (119,121) have been synthesized. Various copolymers containing phenjiene, thienylene, and furylene moieties have also been studied (120,122,123). 

In general, five-membered heteroaromatic ring systems with one heteroatom all undergo preferential a rather than /3 electrophilic substitution. This is rationalized in terms of the more effective delocalization of charge in the intermediate (36) leading to a substitution than in the intermediate (37) leading to /3 substitution. 

The reversed polarity of the double bond is induced by a n electron-accepting substituent A (A = C=0, C=N, NO2) the carbon and proton in the p-position are deshielded (-A/effect, larger shifts). These substituents have analogous effects on the C atoms of aromatic and heteroaromatic rings. An electron donor D (see above) attached to the benzene ring deshields the (substituted) a-C atom (-/ effect). In contrast, in the ortho and para positions (or comparable positions in heteroaromatic rings) it causes a shielding +M effect, smaller H and C shifts), whereas the meta positions remain almost unaffected. 

The position selectivity for electrophilic substitution in the simple five-membered heteroaromatic rings is usually 2 > 3. This reflects the more favorable conjugation in intermediate A than in intermediate B. In structure A the remaining C=C bond can delocalize the positive charge more effectively than in B. Substituents on the ring can easily override this directive influence, however. 

The most characteristic feature of the infrared spectra of all 5-mono- and -di-substituted-amino-l,2,3,4-thiatriazoles is a strong band in the 1540-1590 cm range, which without doubt is due to the C=N and N=N stretching vibrations of the heteroaromatic ring system. Various infrared bands between 889 and 1122 cm have been assigned to skeletal vibrations of the thiatriazole ring and a band... 

Elimination of nitrogen from D-A adducts of certain heteroaromatic rings has been useful in syntheses of substituted aromatic compounds.315 Pyrazines, triazines, and tetrazines react with electron-rich dienophiles in inverse electron demand cycloadditions. The adducts then aromatize with loss of nitrogen and a dienophile substituent.316... 

Tricyclic antihistamines as a rule carry aliphatic nitrogen as a substituent on a side chain attached to the central ring the side chain nitrogen may be part of a heteroaromatic ring. Conjugate addition of p-chloroaniline (49) to the substituted vinylpyridine 50 gives the alkylated aniline 51. Treatment of that intermediate with nitrous acid leads to N-nitroso intermediate 52 which is then reduced to the hydrazine (53). Reaction of 53 with N-methyl-4-piperidone... 

The same group [38] also developed a double Heck reaction which was then terminated by a Friedel-Crafts alkylation to give 6/1-54 from 6/1-53 (Scheme 6/1.12) this involved an attack of an alkylpalladium(II) intermediate on an aryl or heteroaryl moiety. Noteworthy is the finding that the formal Friedel-Crafts alkylation occurs on both electron-rich and electron-poor heteroaromatic rings, as well as on substituted phenyl rings. Single Heck/Friedel-Crafts alkylation combinations have also been performed. 

Scheme 6.119 Nucleophilic aromatic substitution reactions involving halo-substituted N-heteroaromatic ring systems.

Substitution of halogens on heteroaromatic rings is a common way to introduce new functionalities. The product from reaction 6 (Scheme 6) was required on a 100-g scale as an intermediate. In the literature, this exchange was done on a 5-g scale using ammonia in ethanol in a sealed tube under pressure for 6 h at 125-130°C with a yield of 76% (Bendich et al. 1954). Because of the lack of a suitable autoclave for high-pressure reactions, we choose the microwave reactor for scale-up trials. Using our Synthos 3000 equipment, we found suitable conditions with only minimal optimization at 170°C for 180 min and obtained the desired product on a 60-g scale in 83% yield. 

The generation of HO by pulse radiolysis provides a way for investigating the kinetics of hydroxyl spin adduct formation. For PBN and some of its 4-substituted derivatives (ranging from 4-MeO to 4-N02), rate constants in the range of (5-9) X 109 dm3 mol 1 s 1 were determined (Greenstock and Wiebe, 1982). A study of the reaction of the water-soluble 2-, 3- and 4-PyBN[23] and HO showed that most of the hydroxyl radicals became attached to the heteroaromatic ring (Neta et al., 1980 Sridhar et al., 1986). Similar findings... 

Since additional activity was not to be found in the less lipophilic heteroaromatic rings our study turned to the effect of substitution on the biphenyl aromatic rings(12). 

The first class of amine-based nucleophilic catalysts to give acceptable levels of selectivity in the KR of aryl alkyl. yec-alcohols was a series of planar chiral pyrrole derivatives 13 and 14, initially disclosed by Fu in 1996 [25, 26]. Fu and co-workers had set out to develop a class of robust and tuneable catalysts that could be used for the acylative KR of various classes of. yec-alcohols. Planar-chiral azaferrocenes 13 and 14 seemed to meet their criteria. These catalysts feature of a reasonably nucleophilic nitrogen and constitute 18-electron metal complexes which are highly stable [54-58]. Moreover, by modifying the substitution pattern on the heteroaromatic ring, the steric demand and hence potentially the selectivity of these catalysts could be modulated. 

Substantially fewer studies have been published for the reactions of alkyl-substituted heteroaromatics, although these compounds also have implications for coal combustion. Several references discussed in the previous section contain information on methylated heteroaromatic rings. Mackie and coworkers completed experimental and theoretical studies of the pyrolytic decomposition of 2-picoline (2-methylpyridine). They concluded that decomposition proceeded mainly through o-pyridinyl and 2-picolinyl radicals. The former tended to decompose predominantly to yield cyanoacetylene, while the latter favored decomposition to a cyano-functionalized cyclopentadiene (Fig. 16). 

Table 1 Thermodynamic and spin density information for methyl hydrogen atom loss reactions of methyl-substituted heteroaromatic rings. Enthalpies and energies in kcal/mol, obtained at the B3LYP/6-31 l+G //B3LYP/6-31G (designated as B3LYP) and CBS-QB3 (designated as CBS) levels...

IG ) for alkyl group loss reactions of methyl- and ethyl-substituted heteroaromatic rings... 

Fig. 17 Variation of reaction free energy (kcal/mol) with temperature (K) for alkyl C—H hydrogen atom loss in (a) five-membered ring methyl-substituted heteroaromatic rings and (b) six-membered ring methyl-substituted heteroaromatic rings.

Reactivity dealt with in the following sections is limited only to that of the heteroaromatic ring of pyrazines, quinoxalines, and phenazines, but exceptionally the reactivity on the benzo moiety of quinoxaline and phenazine is described in the Section 8.03.5.3. In general, any type of substitution reaction on quinoxaline and phenazine should be more facile than with pyrazine because of the resonance stabilization effect of the additional benzenoid ring on the transition states leading to the products. 

The preparation of norbomadiene-fused thiophene (17) involved a double-Wittig reaction of 1,2-dione 15 with the bis-ylide derived from phosphonium salt 16 <99BCSJ1597>. The effect of the fused heteroaromatic ring of 17 (neighboring group participation) on electrophilic substitution of the norbomadiene ring was examined. 

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