Dichloroethane aromatics acylation

The greater steric hindrance to acetylation was also shown by a comparison of the rate of (103At2) of acetylation of toluene (0.763), ethylbenzene (0.660), i-propylbenzene (0.606) and f-butylbenzene (0.462) with those (determined by the competition method) for benzoylation both sets of data (Table 112) were obtained with dichloroethane as solvent at 25 °C, all reagent concentrations being 0.1 A/421. Relative rates of acylation other aromatics under the same conditions have also been obtained and are given in Table 113422. The different steric requirements for acetylation and benzoylation are further shown by the following respective relative rates for acylation of naphthalene derivatives in chloroform at 0 °C naphthalene (1 position) 1.00,1.00, (2 position) 0.31,0.04 2,3-dimethylnaphthalene (1 position) 1.59, 172, (5 position) 7.14, 38.2, (6 position) 3.68, 7.7422a. 

Selection of an appropriate solvent for Friedel-Crafts acylation is an important question since solvents are known to affect regioselectivities.8,9 In many cases acylation is carried out in an excess of the reacting aromatic compound. Aromatics, however, are poor solvents for most Lewis acids and therefore, they merely serve as diluent in biphase systems. Carbon disulfide is a reasonably good solvent just as dichloromethane and dichloroethane. Although AICI3 is insoluble in chlorinated hydrocarbons, they dissolve many of the complexes formed between acyl halides and AICI3. Nitrobenzene and nitromethane are also suitable solvents. Moreover, the 1 1 addition complexes they form with AICI3 allow acylations to be performed under mild conditions often without side reactions. 

BTI is a useful reagent for Pummerer-type reactions of a-acyl sulphides. Instead of being separately oxidized to their sulphoxides, the sulphides were converted in situ into sulphonium salts these subsequently reacted with added aromatics or intramolecularly to afford various products. These reactions were performed in boiling 1,2-dichloroethane and some results are illustrated in Table 4.6. 

Acylations. Catalyzed by graphite the Friedel-Crafts acylation as well as the transformation of ethers to esters by acyl halides in refluxing 1,2-dichloroethane are realized. Although aliphatic chlorides are inferior to aromatic halides this method is quite general as shown by the synthesis of benzoates (e.g., allyl benzoate from allyl benzyl ether and methyl benzoates from methyl f-butyl ether). 

Catalytic acylation of electron-rich aromatics is achieved with a combination of InCls and silver perchlorate (Scheme 8.114) [157]. Acetic anhydride, acetyl chloride and isopropenyl acetate serve as satisfactory acyl donors. By using an InCl3-impreg-nated Si-MCM-41 catalyst at low concentration, acylation of aromatic compounds (benzene, toluene, p-xylene, mesitylene, anisole, naphthalene, methylnaphfhalene, and methoxynaphfhalene) by acyl chlorides (benzoyl chloride, phenylacetyl chloride, propionyl chloride, or butyryl chloride) can be accomplished rapidly (3 h) at 80 °C in high yield, even in the presence of moisture in the aromatic substrate or solvent (dichloroethane) (Scheme 8.115) [158], In(OTf) j is an efficient catalyst in the sulfonylation of both activated and deactivated aromatic compounds (Scheme 8.116) [159]. 

Table 2.3 Aluminum chloride-lithium chloride catalyzed acylation of aromatics with acyl chlorides in 1,2-dichloroethane...

Aromatic compounds (eqs 16 and 17) are acylated by PhCOCI in the presence of a Lewis acid such as AICI3, TiCU, BF3, SnCU, ZnClz, or FeClz, or of a strong acid such as polyphos-phoric acid or CF3SO3H. Metallic A1 or Fe and iodine (in situ formation of a Lewis acid) can also act as a catalyst. Various solvents that have been used to perform this reaction are CSz, CH2CI2, 1,2-dichloroethane, nitrobenzene, and nitromethane. PhCOCI is less reactive than aliphatic carboxylic acid chlorides (with benzene in nitromethane the relative reaction rates are Ph-COCl MeCOCl = 6 100). As for all electrophilic substitutions, the rate and the regioselectivity of the acylation closely depend on the nature and on the position of the substituents on the aromatic system (eqs 16 and 18 ). The nature of the solvent can also exert a strong influence. ... 

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