Aniline isolation

Phenyl-3//-3-benzazepine-2,4-dicarboxylic acid on heating at 210-260 °C suffers loss of aniline (isolated in 39% yield) and ring contraction to uncharacterized products."... 

A second preparation to illustrate sulphonation is that of sulphanilic acid, NH2C4H4SO3H, a highly crystalline substance which, having a low solubility in cold water, can be readily isolated. If aniline is treated with an excess of concentrated sulphuric acid, aniline hydrogen sulphate is first formed, and... 

When the crude reaction product is made alkaline and steam-distilled, a mixture of quinoline and some unchanged aniline passes over. Pure quinoline can be isolated from this mixture by one of the following methods ... 

Secondary and tertiary amines are not generally prepared in the laboratory. On the technical scale methylaniline is prepared by heating a mixture of aniline hydrochloride (55 parts) and methyl alcohol (16 parts) at 120° in an autoclave. For dimethylaniline, aniline and methyl alcohol are mixed in the proportion of 80 78, 8 parts of concentrated sulphuric acid are added and the mixture heated in an autoclave at 230-235° and a pressure of 25-30 atmospheres. Ethyl- and diethyl-anihne are prepared similarly. One method of isolating pure methyl- or ethyl-aniline from the commercial product consists in converting it into the Y-nitroso derivative with nitrous acid, followed by reduction of the nitroso compound with tin and hydrochloric acid ... 

If the presence of unreduced nitrobenzene is suspected (odour and/or high b.p. residue), treat all the product with excess of dilute hydrochloric acid and remove the nitrobenzene either by steam distillation or by ether extraction render the residue alkaline with sodium hydroxide solution and isolate the aniline os before. 

Hydrolysis of benzanilide. Place 5 g. of benzanilide and 50 ml. of 70 per cent, sulphuric acid in a small flask fitted with a reflux condenser, and boU gently for 30 minutes. Some of the benzoio acid will vapourise in the steam and solidify in the condenser. Pour 60 ml. of hot water down the condenser this will dislodge and partially dissolve the benzoic acid. Cool the flask in ice water filter off the benzoic acid (anifine sulphate does not separate at this dilution), wash well with water, drain, dry upon filter paper, and identify by m.p. (121°) and other tests. Render the filtrate alkaline by cautiously adding 10 per cent, sodium hydroxide solution, cool and isolate the aniline by ether extraction. Recover the ether and test the residue for anifine (Section IV,100). 

An alternative method of removing the aniline is to add 30 ml. of concentrated sulphuric acid carefully to the steam distillate, cool the solution to 0-5°, and add a concentrated solution of sodium nitrite until a drop of the reaction mixture colours potassium iodide - starch paper a deep blue instantly. As the diazotisation approaches completion, the reaction becomes slow it will therefore be necessary to teat for excess of nitrous acid after an interval of 5 minutes, stirring all the whUe. About 12 g. of sodium nitrite are usually required. The diazotised solution is then heated on a boiling water bath for an hour (or until active evolution of nitrogen ceases), treated with a solution of 60 g. of sodium hydroxide in 200 ml. of water, the mixture steam-distilled, and the quinoline isolated from the distillate by extrsM-tion with ether as above. 

The diazonium salts precursors can be aniline, o- and p-toluidine, o-and p-anisidine, o- and p-phenetidine. or 3-naphthy]amine. The resulting formazans are crystalline and inlensel> colored. They are soluble in organic solvents, giving a red-violet coloration that darkens to blue. Dehydrogeneration gives the corresponding tetrazolium salts, which are isolated as perbromides (Scheme 51. Table X-13). 

Aniline was first isolated in 1826 as a degradation prod uct of indigo a dark blue dye obtained from the West Indian plant Indigofera anil from which the name aniline IS derived... 

Aniline Oxidation. Even though this is quite an old process, it still has limited use to produce hydroquinone on a commercial scale. In the first step, aniline is oxidized by manganese dioxide in aqueous sulfuric acid. The resulting benzoquinone, isolated by vapor stripping, is reduced in a second step by either an aqueous acidic suspension of iron metal or by catalytic hydrogenation. 

The industrial source of indole has been isolation from coal-tar distillate (7). Several patents for the manufacture of indole have been issued with aniline and ethylene glycol (8), aniline and ethylene oxide (9), 2-ethy1ani1ine (10), and /V-ethy1ani1ine (11) as the starting materials. 

Sulfonation. Aniline reacts with sulfuric acid at high temperatures to form -aminoben2enesulfonic acid (sulfanilic acid [121 -57-3]). The initial product, aniline sulfate, rearranges to the ring-substituted sulfonic acid (40). If the para position is blocked, the (9-aminoben2enesulfonic acid derivative is isolated. Aminosulfonic acids of high purity have been prepared by sulfonating a mixture of the aromatic amine and sulfolane with sulfuric acid at 180-190°C (41). 

Most derivatives of aniline are not obtained from aniline itself, but ate prepared by hydrogenation of their nitroaromatic precursors. The exceptions, for example, /V-a1ky1ani1ines, /V-ary1ani1ines, sulfonated anilines, or the A/-acyl derivatives, can be prepared from aniline and have been discussed. Nitroanilines are usually prepared by ammonolysis of the corresponding chloronitroben2ene. Special isolation methods may be requited for some derivatives if the boiling points are close and separation by distillation is not feasible. Table 6 Hsts some of the derivatives of aniline that are produced commercially. 

Commercially, a small amount of the 4,4 -MDA is isolated by distillation from PMDA. Depending on the process employed, the removal of MDA can be partial (as is done with the isocyanates) or total. Partial removal of MDA gives some processiag latitude but yields of 4,4 -MDA are reduced. Distillation residues from PMDA manufacture that contain less than 1% MDA pose a disposal problem. Processes for the regeneration of MDA by heating these residues ia the presence of aniline and an acid catalyst have been patented (33—35). Waste disposal of PMDA is expensive and reclamation processes could become commercially viable. The versatility of the isocyanate process, however, can be used to avoid the formation of low MDA content distillation residues. 

In the reduction of nitro compounds to amines, several of the iatermediate species are stable and under the right conditions, it is possible to stop the reduction at these iatermediate stages and isolate the products (see Figure 1, where R = CgH ). Nitrosoben2ene [586-96-9] C H NO, can be obtained by electrochemical reduction of nitrobenzene [98-95-3]. Phenylhydroxylamine, C H NHOH, is obtained when nitrobenzene reacts with ziac dust and calcium chloride ia an alcohoHc solution. When a similar reaction is carried out with iron or ziac ia an acidic solution, aniline is the reduction product. Hydrazobenzene [122-66-7] formed when nitrobenzene reacts with ziac dust ia an alkaline solution. Azoxybenzene [495-48-7], C22H2QN2O, is... 

The central carbon atom is derived from an aromatic aldehyde or a substance capable of generating an aldehyde during the course of the condensation. Malachite green is prepared by heating benzaldehyde under reflux with a slight excess of dimethyl aniline in aqueous acid (Fig. 2). The reaction mass is made alkaline and the excess dimethylaniline is removed by steam distillation. The resulting leuco base is oxidized with freshly prepared lead dioxide to the carbinol base, and the lead is removed by precipitation as the sulfate. Subsequent treatment of the carbinol base with acid produces the dye, which can be isolated as the chloride, the oxalate [2437-29-8] or the zinc chloride double salt [79118-82-4]. 

The manufacture of crystal violet (1), however, is a special case which does not involve the isolation of the intermediate Michler s ketone (Fig. 3). Thus, phosgene is treated with excess dimethyl aniline in the presence of zinc chloride. Under these conditions, the highly reactive intermediate "ketone dichloride" is formed in good yield this intermediate further condenses with another mole of dimethyl aniline to give the dye. 

Practically all pyridazine-carboxylic and -polycarboxylic acids undergo decarboxylation when heated above 200 °C. As the corresponding products are usually isolated in high yields, decarboxylation is frequently used as the best synthetic route for many pyridazine and pyridazinone derivatives. For example, pyridazine-3-carboxylic acid eliminates carbon dioxide when heated at reduced pressure to give pyridazine in almost quantitative yield, but pyridazine is obtained in poor yield from pyridazine-4-carboxylic acid. Decarboxylation is usually carried out in acid solution, or by heating dry silver salts, while organic bases such as aniline, dimethylaniline and quinoline are used as catalysts for monodecarboxylation of pyridazine-4,5-dicarboxylic acids. 

Combined Erythrina Alkaloids. The sources of the liberated alkaloids (see above) are now known to be, at least in two cases, the sulphur-containing alkaloids erysothiopine and erysothiovine, which are esters of sulphoacetic acid, HOOC. CHj. SOj. OH, identified as the aniline salt, m.p. 187-9° with erj sopine and erysovine respectively. The sources of erysodine and erysonine have not yet been isolated. These combined alkaloids arc believed to be sulphonic esters, of the type HO. OC. CHj. SOj. 0. R, where R is the alkaloidal residue. ... 

Aniline, PI1NH2, reacts with sodium nitrite, NaN02, and aqueous acid to give phenyl diazonium ion, PhN2. This ion can be isolated, but it also reacts readily with certain nucleophiles to give substitution products, e.g. 

In the first step of what is considered to be a fairly straightforward mechanism, the anilinic nitrogen reacts with the ester group of the 3-ketoester 5 to provide the anilide 3. The latter can either be isolated or carried on directly. Upon warming in the presence of acid, the acetanilide cyclizes with subsequent loss of water to yield the quinolone product 9. ... 

One of the drawbacks of the Skraup/Doebner-von Miller reaction is the isolation of the desired product from the starting aniline and co-formed alkyl anilines and 1,2,3,4-tetrahydroquinaldine. Isolation can be simplified greatly by addition of one equivalent of zinc chloride at the end of the reaction all of the basic products were precipitated. Washing the brown solids with 2-propanol removed all impurities and left the desired quinoline as a 2 1 complex with zinc chloride in yields of 42-55%. 

Studies on the Bischler-Napieralski cyclization of A -acetyltryptamine in the presence of indole have led to the isolation of numerous products, among which the indolocarbazole 186 could be found in 3.5% yield. This outcome was rationalized as a result of the intermediacy of a spiroindolenine species formed under these conditions [89H(28)175]. During detailed studies on the polymerization of indole, formation of a low yield of the related indolo[3,2-h]carbazole 187 was discovered in the product mixture originating from the treatment of indole with p-toluenesulfonic acid at elevated temperature [88JCS(P1)2387]. In an investigation of the condensation of p-benzoquinone with 4-substituted anilines, an indolo[3,2-h]carbazole derivative has been reported to be formed in 2% yield (80JOC1493). 

Good yields of 10-aryl-3,6-dinitroacridones were obtained merely by heating 2,2, 4,4 -tetranitrobenzophenone (419) with an excess of the corresponding aryl amines at 125°C. For example, aniline provided 420 in 80% yield (Eq. 38). The reaction is fairly general for meta- and para-substituted anilines, though it proceeds less readily with orf/io-substituted compounds (79JCS(P1)1364). A method of isolation of the intermediate diarylamine in the synthesis of certain 10-aryl-3,6-dinitroacridones from 2,2, 4,4 -tetranitrobenzophenone has also been described (93JCR(M)2779). 

A 1-2-phenyI shift occurs especially easily. In the acid fission of 2-(a-phenylethyl)-3-isopropyloxazirane (20) aniline was isolated as the sole basic fission component. Of the two available groups,... 

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