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Phenylation of aromatics

This is because of greater electronegativity of sp hybridised carbon to which carbojyl carbon is attached. The presence of electron withdrawing group on the phenyl of aromatic carbojylic acid increases their acidity whUe electron donating groups decrease their acidity. [Pg.104]

BINAP-derived 1,2-amino alcohols catalyse the enantioselective phenylalkynylation and phenylation of aromatic aldehydes by zinc reagents.243... [Pg.27]

Binsch and Riichardt (1966) have demonstrated the presence of the radical PliN=N—0 when A-nitrosoacetanilide is dissolved in benzene at room temperature, supporting the mechanism earlier proposed by Riichardt and Merz (1964) in which this radical is an intermediate in the free-radical phenylations of aromatic compounds which are brought about by. -nitrosoacetanilide. [Pg.66]

Barton, D. H. R., Yadav-Bhatnagar, N., Finet, J. P., Khamsi, J. Phenylation of aromatic and aliphatic amines by phenyllead triacetate using copper catalysis. Tetrahedron Lett. 1987, 28, 3111-3114. [Pg.698]

The second thoughtful description was given by Perkins.6 He explained the unusual product distributions of phenylations of aromatic compounds when phenylazotriphenylmethane is used as thermal phenyl radical generator. Scheme 5 provides an example. It had been found7 that benzene solutions yield 1,4-dihydro-4-triphenylmethylbiphenyls as major products besides biphenyl and triphenylmethane, and a particular feature of this scheme is the absence of dimerization and disproportionation of the interme-... [Pg.279]

The ethylation of aromatic and aliphatic aldehydes in toluene at O C in presence of an amount of 8 mol% of the supported-ligand 198 was performed. Except for a-susbituted aldehydes (around 50% conversion), both conversion and ee were high. The phenylation of aromatic aldehydes was also tested with polymeric ligand 198. Although conversions were excellent, the enantioselectivities were moderate (38-48% ee) and lower than those obtained with functionalized resin 191 and 195. [Pg.110]

The catalyst is inactive for the hydrogenation of the (isolated) benzene nucleus and so may bo used for the hydrogenation of aromatic compounds containing aldehyde, keto, carbalkoxy or amide groups to the corresponding alcohols, amines, etc., e.g., ethyl benzoate to benzyl alcohol methyl p-toluate to p-methylbenzyl alcohol ethyl cinnamate to 3 phenyl 1-propanol. [Pg.873]

Fig. 1-21. Partial rate factors for the phenylation and the thiazol-2-ylation of aromatic substrates (414). Fig. 1-21. Partial rate factors for the phenylation and the thiazol-2-ylation of aromatic substrates (414).
Amides result from the reaction of aromatic hydrocarbons with isocyanates, such as phenyl isocyanate [103-71-9], ia the presence of aluminum chloride. Phenyl isothiocyanate [103-72-0] similarly gives thioanilides (136). [Pg.560]

Electrolytic reductions generally caimot compete economically with chemical reductions of nitro compounds to amines, but they have been appHed in some specific reactions, such as the preparation of aminophenols (qv) from aromatic nitro compounds. For example, in the presence of sulfuric acid, cathodic reduction of aromatic nitro compounds with a free para-position leads to -aminophenol [123-30-8] hy rearrangement of the intermediate N-phenyl-hydroxylamine [100-65-2] (61). [Pg.263]

Benzisothiazoles can be prepared by the reaction of aromatic chloro compounds with sulfur and ammonia. Thus, 2,6-dichlorobenzylidene chloride gives 4-chloro-l,2-benzisothiazole (72AHC(14)43), and 2-chlorobenzophenone gives 3-phenyl-l,2-benziso-thiazole (79GEP27 34866). [Pg.169]

Phenyl radicals can be generated by the thermal decomposition of lead tctrabcnzoate, phenyl iodosobenzoate, and diphenyliodonium hydroxide,- - and by the electrolysis of benzoic acid.- These methods have been employed in the arylation of aromatic compounds, including heterocycles. A method of promise which has not been applied to the arylation of heterocycles is the formation of aryl radicals by the photolysis of aromatic iodides at 2537... [Pg.135]

It is understandable that dihydro adducts should be formed by polycyclic compounds and not by benzene or pyridine, because the loss of aromatic resonance energy is smaller in the former than in the latter process, (c) When dibenzoyl peroxide is decomposed in very dilute solution (0.01 Af) in benzene, 1,4-dihydro biphenyl is produced as well as biphenyl, consistent with addition of the phenyl... [Pg.137]

This last result bears also on the mode of conversion of the adduct to the final substitution product. As written in Eq. (10), a hydrogen atom is eliminated from the adduct, but it is more likely that it is abstracted from the adduct by a second radical. In dilute solutions of the radical-producing species, this second radical may be the adduct itself, as in Eq. (12) but when more concentrated solutions of dibenzoyl peroxide are employed, the hydrogen atom is removed by a benzoyloxy radical, for in the arylation of deuterated aromatic compounds the deuterium lost from the aromatic nucleus appears as deuterated benzoic acid, Eq. (13).The over-all reaction for the phenylation of benzene by dibenzoyl peroxide may therefore be written as in Eq, (14). [Pg.138]

It is difficult to treat the effect of a heteroatom on the localization energies of aromatic systems, but Brown has derived molecular orbital parameters from which he has shown that the rates of attack of the phenyl radical at the three positions of pyridine relatively to benzene agree within 10% with the experimental results. He and his co-workers have shown that the formation of 1-bromoisoquinoline on free-radical bromination of isoquinoline is in agreement with predictions from localization energies for physically reasonable values of the Coulomb parameters, but the observed orientation of the phcnylation of quinoline cannot be correlated with localization ener-... [Pg.176]

In Section 3.4 we discussed the problem of reversibility of diazotization of aromatic and heteroaromatic amines. Simple stoichiometric considerations indicate that the reverse reaction (ArNJ -> ArNH2) may take place under strongly acidic conditions. Experimentally the reverse reaction was found only with heteroaromatic diazonium salts (Kavalek et al., 1989). Reaction conditions of hydroxy-de-diazonia-tion are comparable to those used for the reverse reactions of diazotization (e.g., 10 m H2S04, but at 0°C for the formation of 2-amino-5-phenyl-l,3,4-thiadiazol from the corresponding diazonium salt, Kavalek et al., 1979). So far as we know, however, amines have never been detected in aromatic hydroxy-de-diazoniations, not even in small amounts. [Pg.227]

Iodosobenzene diacetate is used as a reagent for the preparation of glycol diacetates from olefins,9 for the oxidation of aromatic amines to corresponding azo compounds,10 for the ring acetylation of N-arylacetamides,11 for oxidation of some phenols to phenyl ethers,12 and as a coupling agent in the preparation of iodonium salts.13 Its hydrolysis to iodosobenzene constitutes the best synthesis of that compound.14... [Pg.64]

The reaction with disubstituted formamides and phosphorus oxychloride, called the Vilsmeier or the Vilsmeier-Haack reaction,is the most common method for the formylation of aromatic rings. However, it is applicable only to active substrates, such as amines and phenols. An intramolecular version is also known.Aromatic hydrocarbons and heterocycles can also be formylated, but only if they are much more active than benzene (e.g., azulenes, ferrocenes). Though A-phenyl-A-methyl-formamide is a common reagent, other arylalkyl amides and dialkyl amides are also used. Phosgene (COCI2) has been used in place of POCI3. The reaction has also been carried out with other amides to give ketones (actually an example of 11-14),... [Pg.715]

Alkyl Side Chains of Aromatic Rings. The preferential position of attack on a side chain is usually the one a to the ring. Both for active radicals such as chlorine and phenyl and for more selective ones such as bromine such attack is faster than that at a primary carbon, but for the active radicals benzylic attack is slower than for tertiary positions, while for the selective ones it is faster. Two or three aryl groups on a carbon activate its hydrogens even more, as would be expected from the resonance involved. These statements can be illustrated by the following abstraction ratios ... [Pg.902]


See other pages where Phenylation of aromatics is mentioned: [Pg.98]    [Pg.280]    [Pg.98]    [Pg.194]    [Pg.89]    [Pg.98]    [Pg.280]    [Pg.98]    [Pg.194]    [Pg.89]    [Pg.163]    [Pg.327]    [Pg.438]    [Pg.54]    [Pg.136]    [Pg.241]    [Pg.280]    [Pg.657]    [Pg.172]    [Pg.9]    [Pg.25]    [Pg.127]    [Pg.444]    [Pg.254]    [Pg.256]    [Pg.58]    [Pg.252]    [Pg.264]    [Pg.701]    [Pg.267]    [Pg.861]    [Pg.17]   
See also in sourсe #XX -- [ Pg.329 ]




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