BENZOYLATION OF AROMATIC AMINES

The benzoyl compounds frequently occlude traces of unchanged benzoyl chloride, which thus escape hydrolysis by the caustic alkali it is therefore advisable, wherever possible, to recrystallise the benzoyl derivatives from methyl, or ethyl alcohol or methylated spirit, since these solvents will esterify the unchanged chloride and so remove the latter from the recrystalKsed material. Sometimes the benzoyl compound does not crystallise well this difficulty may frequently be overcome by the use of p-nitrobenzoyl chloride or 3 5-dinitro-benzoyl chloride, which usually give highly crystalline derivatives of high melting point (see Section IV, 114j. 

Examples of benzoylation under Schotten-Baumann conditions are — 

Benzanilide is more conveniently prepared, particularly on a larger scale, by heating together aniline and benzoic acid  

Benzoyl compounds are readily hydrolysed by heating with about 70 per cent, sulphuric acid (alkaline hydrolysis is very slow for anilides)  

This procedure is of importance in connexion with the identification of substituted amines. 

In general, benzoylation of aromatic amines finds less application than acetylation in preparative work, but the process is often employed for the identification and characterisation of aromatic amines (and also of hydroxy compounds). Benzoyl chloride (Section IV, 185) is the reagent commonly used. This reagent is so slowly hydrolysed by water that benzoylation can be carried out in an aqueous medium. In the Schotten-Baumann method of benzoylation the amino compound or its salt is dissolved or suspended in a slight excess of 8-15 per cent, sodium hydroxide solution, a small excess (about 10-15 per cent, more than the theoretical quantity) of benzoyl chloride is then added and the mixture vigorously shaken in a stoppered vessel (or else the mixture is stirred mechanically). Benzoylation proceeds smoothly and the sparingly soluble benzoyl derivative usually separates as a solid. The sodium hydroxide hydrolyses the excess of benzoyl chloride, yielding sodium benzoate and sodium chloride, which remain in solution  

Examples of benzoylation under Schotten-Baumann conditions are — C6H6NH2 + C4HsCOC1 + NaOH — C HtNHCOC H6 + NaCl + H,0 

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In general, benzoylation of aromatic amines finds less application than acetylation in preparative work, but the process is often employed for the... 

Benzoic acids ionization (aq), equilibrium Phenols ionization (aq), equilibrium Benzoylation of aromatic amines in benezene, rate... 

Up to the present time, use has been made almost entirely of dimethacrylates which are polymerized by free radical mechanisms to yield crosslinked products (81. Polymerization is initiated by redox systems, such as benzoyl peroxlde/aromatic amine, and by... 

Several reactive chloro compounds have been used to attempt to effect the controlled monochlorination of aromatic amines. One such reagent is N-chlorosuccinimide, with which the chlorination of aniline, for example, can be largely restricted to monosubstitution, although a mixture of isomers (orthopara, 1.9 1) is obtained.24 One approach to the achievement of specific ortho chlorination is illustrated by the synthesis of o-chlorobenzanilide (Expt 6.61), readily hydrolysable to o-chloroaniline. The anilide is formed, by a type of Swi mechanism indicated below, when AT-phenylhydroxylamine is benzoylated and the product is treated with thionyl chloride.25 The reaction has been successfully applied to several substituted JV-phenylhydroxylamines, prepared by the controlled reduction of the corresponding substituted nitro compounds (cf. Expt 6.87). 

A resin with mixed carbonic-carboxylic anhydride function has been prepared and used as acylating reagent [144], Thus, the supported chloroformate 140 was obtained by reaction of hydroxymethylated polystyrene with phosgene in benzene (Scheme 7.43). Further treatment with benzoic acid in the presence of triethyl-amine in benzene gave rise to the supported mixed anhydride 141. This polymer has been used in the benzoylation of several amines, although variable amounts of benzoic acid from attack to the internal carbonyl were obtained when using aromatic amines. 

The other major catalyst system is the benzoyl peroxide/aromatic amine redox couple. The chemistry of this system has been well studied and the formation of benzoyl radicals has been established. 

The experimental technique is similar to that given under Aromatic Amines, Section IV,100,2. The following alternative method may also be used. Mix together 0 -5-0 - 8 ml. of the polyhydroxy compound, 5 ml. of pyridine and 2 -5 ml. of redistilled benzoyl chloride in a 50 ml. flask. 

The cure reaction of structural acrylic adhesives can be started by any of a great number of redox reactions. One commonly used redox couple is the reaction of benzoyl peroxide (BPO) with tertiary aromatic amines. Pure BPO is hazardous when dry [39]. It is susceptible to explosion from shock, friction or heat, and has an autoignition temperature of 79°C. Water is a very effective stabilizer for BPO, and so the initiator is often available as a paste or a moist solid [40], The... 

Benzoyl Chloride.—The formation of esters by ibe action of benzoyl chloride or othei acid chloride on an alcohol or ]ohcnol in presence of caustic soda is known as the Schotten- 13riumann reaction. The reaction may also be employed in the preparation of deri ati es of the aromatic amines containing i.n acid radical, like benzanilide, CjjH NH.CO... 

A wide array of aliphatic and aromatic amines has been converted to amides in very high yields by the particularly reactive tetrazolides. The reaction temperature was 10 °C to 20 °C. Higher temperatures (refluxing THF) should be avoided because of instability of the tetrazolide, which in this case was prepared from benzoyl chloride and phenyltetrazole in 68% yield.[99],[100]... 

Reduction of amides to aldehydes was accomplished mainly by complex hydrides. Not every amide is suitable for reduction to aldehyde. Good yields were obtained only with some tertiary amides and lithium aluminum hydride, lithium triethoxyaluminohydride or sodium bis 2-methoxyethoxy)aluminum hydride. The nature of the substituents on nitrogen plays a key role. Amides derived from aromatic amines such as JV-methylaniline [1103] and especially pyrrole, indole and carbazole were found most suitable for the preparation of aldehydes. By adding 0.25 mol of lithium aluminum hydride in ether to 1 mol of the amide in ethereal solution cooled to —10° to —15°, 37-60% yields of benzaldehyde were obtained from the benzoyl derivatives of the above heterocycles [1104] and 68% yield from N-methylbenzanilide [1103]. Similarly 4,4,4-trifluorobutanol was prepared in 83% yield by reduction of N-(4,4,4-trifluorobutanoyl)carbazole in ether at —10° [1105]. 

Bismuth(lll) chloride catalyzes the intramolecular hetero-Diels-Alder reaction of aldimines, generated in situ from aromatic amines and the A -allyl derivative of o-aminobenzaldehyde, in acetonitrile at reflux to generate [l,6]naphthyridine derivatives <2002TL1573>. The hetero-Diels-Alder reaction of 3-aryl-2-benzoyl-2-propeneni-triles and enol ethers yields 2-alkoxy, 6-diaryl-3,4-dihydro-2//-pyran-5-carbonitriles (Scheme 29) <1997M1157>. 

The Schotten-Baumann reaction can also be applied to primary and secondary aromatic amines (see p. 303) it is much used in the identification of compounds to which it can be applied, by the preparation of their benzoyl, phenylacetyl, or benzene sulphonyl derivatives. 

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