Phenyl azide with aluminum chloride

Decomposition of aryl azides in the presence of Lewis acids does not involve arylnitrenes arylnitrenium-Lewis acid complexes are much more likely intermediates. The reaction of phenyl azide with aluminum chloride and aromatic substrates gives fair yields of diarylamines. This reaction is not undergone by phenyl azide alone on thermolysis or photolysis in aromatic solvents (Section II.l.A) ... 

On decomposition of the 1 1 adduct of phenyl azide with both alkyl aluminum chlorides, the main reaction is A-ethylation with the formation of IV-ethylanilides 100). 

In 1956, Hattori and co-workers estabUshed that aluminum azide adds to alkyl isocyanates or acid chlorides in tetrahydrofuran to afford l-aUcyl-A -tetrazoline-5-ones in excellent yields [ 101 ]. Three years later, Horwitz and coworkers reported on the synthesis of l-aryl-A -tetrazoline-5-ones by reaction of aryl isocyanates with a mixture of sodium azide and aluminum chloride in tetrahydrofiuan at reflux temperature [102]. The in situ produced aluminum azide adds to the N=C-bond of the corresponding isocyanate 122 and yields the 1-substituted A -tetrazoHne-5-one 124. According to this method, different 1-substituted A -tetrazoUne-5-ones 124 were synthesized by reaction of phenyl isocyanate and further 1-p-substituted phenyl isocyanates with aluminum azide. In addition, acyl halides 123, like acetyl chloride and benzoyl chloride, were converted to 1-methyl and 1-phenyl-A -tetrazoline-5-one with aluminum azide under the same conditions (Scheme 28A). It is assumed that in the initial step of the reaction, aluminum azide is able to coordinate to the aryl isocyanate by foiu pathways, forming an aluminum salt 129. The first two possibilities (Scheme 28B 125 and 126) require the separation of an azide ion from the complex, recombination at the electrophihc carbon atom followed... 

Butyl alcohol in synthesis of phenyl 1-butyl ether, 46, 89 1-Butyl azidoacetate, 46, 47 hydrogenation of, 46, 47 1-Butyl chloroacetate, reaction with sodium azide, 46, 47 lre l-4-i-BUTYLCYCLOHEXANOL, 47,16 4-(-Butylcyclohexanonc, reduction with lithium aluminum hydride and aluminum chloride, 47, 17 1-Butyl hypochlorite, reaction with cy-clohexylamine, 46,17 l-Butylthiourea, 46, 72... 

In the presence of gallium chloride, aluminum bromide, aluminum chloride, and ferric chloride, benzoyl azide is decomposed according to eq 2. Here complex formation is very fast, and the decomposition of the complex is the ratedetermining step. The halides do not complex with the phenyl isocyanate formed and, as a consequence, they are not consumed in the reaction. As long as benzoyl azide is in excess, the concentration of the complex is equal to the halide concentration and remains constant. The experimentally determined pseudo-zero-order rate constant depends therefore upon the first power of the initial halide concentration. When, however, the reaction is at a stage where the azide is no longer in excess, the rate of the reaction becomes first order with respect to benzoyl azide and zero order with respect to halide. PhCONj + AlBr, -r - PhCONrAlBr, r+-... 

ALUMINUM CHLORIDE (7446-70-0) Contact with moist air or water produces hydrogen chloride and heat. Contact with water, alcohol, alkenes. bases, epichlorohydrin, ethylene oxide can result in violent polymerization. Incompatible with butyl nitrate, glycidol, methyl chloride, organic material, oxygen difluoride, phenyl azide. Forms shock-sensitive or explosive compounds with ammonium nitrate, nitrobenzene. Attacks metals including 316 stainless steel in the presence of moisture. 

---