Amines from aromatic

Aromatic aUazines and ketazines. Polyphosphoric acid is an excellent catalyst and solvent for production of amines from aromatic aldehydes and ketones in the presence of various carbonyl reagents, for example, hydrazine, its salts, semicarbazide hydrochloride, toluene/i-sulfonohydrazide, and acid hydrazides. The reaction is usually complete at 100° within 15 min. The reaction is not useful in the case of aliphatic carbonyl compounds. 

From aromatic ketones and amines From aromatic ketones and monamines From diphenyl ketones and aliphatic monamines CU2 2,5-0(C1)C6H3 C(C6H5)=N C4H9 2Cl2 T=314 Zm = 691 Pm=1.26 T =216 Zm=645 p =1.00 T=101 Zm=640 p =0.68 74G17... 

Takeuchi and coworkers developed a reaction of hydrazoic acid with aromatic compounds in the presence of both trifluoromethanesulphonic acid (TFSA) and trifluoroacetic acid (TFA) giving aromatic amine in good yield [99]. The strong acidity of TFSA and the high solubility of TFSA in TFA play an important role in the aromatic amination. In addition, the combine of trimethylsilyl azide/trific acid, NaN3/trillic acid/aromatics, or HN3/HOTf/TFA was found effective for one-step preparation of primary aromatic amines from aromatics [100-102]. Very recently, Surya Prakash and coworkers developed an electrophilic rritrogenation of aromatics with sodium azide in BF3-H2O [103]. 

Note. Useful information can often be obtained by adding (i) dilute H,SO or (ii) dilute NaOH solution to an aqueous solution of the substance under investigation. A precipitate with (i) usually indicates an aromatic carboxylic acid from a metallic or from an ammonium salt. A precipitate or oil with (ii) usually indicates an aromatic amine from an amine salt. 

The reaction is applicable to the preparation of amines from amides of aliphatic aromatic, aryl-aliphatic and heterocyclic acids. A further example is given in Section IV,170 in connexion with the preparation of anthranilic acid from phthal-imide. It may be mentioned that for aliphatic monoamides containing more than eight carbon atoms aqueous alkaline hypohalite gives poor yields of the amines. Good results are obtained by treatment of the amide (C > 8) in methanol with sodium methoxide and bromine, followed by hydrolysis of the resulting N-alkyl methyl carbamate ... 

V-Phenylsuccinimide [83-25-0] (succanil) is obtained in essentially quantitative yield by heating equivalent amounts of succinic acid and aniline at 140—150°C (25). The reaction of a primary aromatic amine with phosgene leads to formation of an arylcarbamoyl chloride, that when heated loses hydrogen chloride to form an isocyanate. Commercially important isocyanates are obtained from aromatic primary diamines. 

Although this reduction is more expensive than the Bnchamp reduction, it is used to manufacture aromatic amines which are too sensitive to be made by other methods. Such processes are used extensively where selectivity is required such as in the preparation of nitro amines from dinitro compounds, the reduction of nitrophenol and nitroanthraquinones, and the preparation of aminoazo compounds from the corresponding nitro derivatives. Amines are also formed under the conditions of the Zinin reduction from aromatic nitroso and azo compounds. 

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). 

Other Applications. Hydroxylamine-O-sulfonic acid [2950-43-8] h.2is many applications in the area of organic synthesis. The use of this material for organic transformations has been thoroughly reviewed (125,126). The preparation of the acid involves the reaction of hydroxjlamine [5470-11-1] with oleum in the presence of ammonium sulfate [7783-20-2] (127). The acid has found appHcation in the preparation of hydra2ines from amines, aUphatic amines from activated methylene compounds, aromatic amines from activated aromatic compounds, amides from esters, and oximes. It is also an important reagent in reductive deamination and specialty nitrile production. 

Sulfur The yellow, orange, and brown sulfur dyes belong to this group. The dyes are usually made from aromatic amines, diamines, and... 

The most versatile derivative from which the free base can be readily recovered is the picrate. This is very satisfactory for primary and secondary aliphatic amines and aromatic amines and is particularly so for heterocyclic bases. The amine, dissolv in water or alcohol, is treated with excess of a saturated solution of picric acid in water or alcohol, respectively, until separation of the picrate is complete. If separation does not occur, the solution is stirred vigorously and warmed for a few minutes, or diluted with a solvent in which the picrate is insoluble. Thus, a solution of the amine and picric acid in ethanol can be treated with petroleum ether to precipitate the picrate. Alternatively, the amine can be dissolved in alcohol and aqueous picric acid added. The picrate is filtered off, washed with water or ethanol and recrystallised from boiling water, ethanol, methanol, aqueous ethanol, methanol or chloroform. The solubility of picric acid in water and ethanol is 1.4 and 6.23 % respectively at 20°. 

Lukes studied the reaction of N-methyl lactams with Grignard reagents. With the five- (39-42) and six-membered (43-47) rings, 2,2-dialkylated bases (16, = 1,2) are formed as by-products in addition to the l-methyl-2-alkyl pyrrolines (15, = 1) or l-methyl-2-alkyl piperideines (15, =2). Aromatic Grignard reagents afford only the unsaturated bases, probably because of steric factors (48,49). Separation of enamines and 2,2-dialkylated amines from each other can be easily achieved since the perchlorates of the enamines and the picrates of 2,2-dialkylated bases crystallize readily. Therefore enamines can be isolated as crystalline perchlorates and the 2,2-dialkylated bases as crystalline picrates. Some authors who repeated the reactions isolated only pyrrolines (50,57) or, by contrast, 2,2-dialkylated bases (52). This can be explained by use of unsuitable isolation techniques by the authors. 

The portions of the methyl orange molecule set off by the dotted lines come from aromatic amines like aniline. Aniline is indeed the starting material from which methyl orange and related dyes ( azo dyes ) are made. 

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