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NITRO COMPOUNDS , in organic See also:chemistry, compounds containing the monovalent See also:radical —NO2 directly combined with See also:carbon. Aiphatic Nitro Compounds.—The nitroparaffins may be obtained by the See also:action of the alkyl iodides on See also:silver nitrite (V. See also:Meyer, See also:Ann. 1874, 171, p. I et seq.). When methyl iodide is used, nitromethane is the See also:sole product, but the higher homologues give more or less of the isomeric nitrous See also:esters. Nitro-paraffins may also be obtained by the action of See also:sodium nitrite on the a-halogen fatty acids, the a-nitro fatty acids first formed readily eliminating carbon dioxide (H. See also:Kolbe, Jour. prak. Chem., . 1872 [2] 5, p. 427). See also:Tertiary nitro compounds may also be obtained by the oxidation of the corresponding amino-, hydroxyl-amino-, and nitroso-See also:hydrocarbons with monopersulphuric See also:acid (E. See also:Bamberger, Ber., 1903, 36, p. 385) : C•See also:NH2—> C•NHOH—j .> C•NO—> . C•NO2. The nitro compounds of the See also:lower members of the See also:paraffin See also:series cannot be prepared by the See also:direct action of nitric acid on the hydrocarbons themselves, but, in the See also:case of some of the higher members of the series direct nitration is possible (M. Konowalow, Comples rendus, 1892, 114, p. 26; Ber., 1895, 28, p. 1852; R. A. Worstall, Amer. Chem. Jour., 1898, 20, p. 202). The nitro compounds are colourless, somewhat pleasant smelling liquids, which distil without decomposition and possess boiling points much higher than those of the isomeric nitrous esters. Reduction with acid-reducing agents gives See also:amines. The See also:primary and secondary nitro compounds (i.e. those containing the groupings •CH2NO2 and >CH•NO2) See also:form metallic derivatives; for example, sodium salts, which according to A. Hantzsch (Ber., 1899, 32, pp. 577 et seq.) are probably derived from the isomeric iso-nitro compounds R : NO(OH), and thus the nitro derivatives are to be looked upon as pseudo-acids. These sodium salts are crystalline solids which are readily soluble in See also:water and are very explosive. Stannous chloride and hydrochloric acid reduce the nitroparaffins to 0-alkyl hydroxylamines, amines and some See also:ammonia being simultaneously produced (V. Meyer, Ber., 1891, 24, p. 3530), whilst the primary nitro compounds on See also:heating with hydrochloric acid yield See also:hydroxylamine and an acid: See also:CH3•See also:CH2•NO2+See also:H2O = CH 3.0O2H+NH2OH (V. Meyer, Ann., 1876, 18o, p. 163). When reduced by the See also:Sabatier and Senderens' method (Comptes rendus, 1902, 135, p. 225) they are converted into amines, provided the temperature be kept at 15o°-2oo° C., a higher temperature leading to the formation of paraffins and ammonia. The See also:hydrogen in the primary and secondary nitro compounds which is attached to the same carbon See also:atom as the nitro See also:group is readily replaced by See also:bromine in alkaline See also:solution. The reactions of the nitroparaffins with nitrous acid are very characteristic and have been used as a method for discriminating between the primary, secondary and tertiary See also:alcohols (q.v.) (V. Meyer, Ann., 1875, 175, p. 93). The primary compounds form nitrolic acids of the type R.C(:NOH)NO, the secondary yield pseudo-nitrols of the type RR': C(NO)(NO2), whilst the tertiary nitro compounds are not acted upon by nitrous acid. The primary nitroparaffins combine with nitric See also:oxide in the presence of sodium ethylate, to form nitroalkylisonitramines, R•CH(NO2)•N202H (W. Traube, Ann., 1898, 300, p• 95). Nitromethane, CH3NO2, is a colourless oil which boils at 101° C. Fuming sulphuric acid decomposes it into carbon monoxide and hydroxylamine. It combines with aromatic See also:aldehydes in the presence of alcoholic potash to form addition products which are converted by acids into styrol derivatives (J. Thiele, Ber., 1899, 32, p. 1293). Nitroethane, C2HsNO2, is a colourless liquid which boils at 114° C. Nitroform (trinitromethane), CH(NO3)3, is obtained in the form of its ammonium See also:salt by the decomposition of trinitroacetonitrile with water (L. Schischkoff, Ann., 1857, 103, p. 364). It is a colourless crystalline solid which melts at 15° C. and has the properties of a strong acid. The See also:potassium salt is formed by the action of potassium ethylate on tetranitromethane (A. Hantzsch, Ber., 1899, 32, p. 631). It is a deep yellow coloured solid, whichis readily soluble in water. It explodes when heated. The silver salt, obtained by shaking an See also:ether solution of nitroform with freshly prepared, slightly moist silver oxide, reacts with methyl iodide to form trinitroethane, a crystalline solid which melts at 56° C. Concentrated See also:caustic potash decomposes the latter See also:compound, forming the potassium salt of dinitroethane, CHs•C(NO2)2K. Tetranitromethane, C(NO2)s, obtained by adding nitroform to a hot mixture of nitric and sulphuric acids, is a crystalline solid which melts at 13° C. See also:Chlorpicrin, CC13NO2, is a liquid of suffocating odour obtained by the action of nitric acid and chloride of See also:lime on many organic compounds. It boils at 112°. Aromatic Nitro Compounds.—The aromatic nitro compounds are generally obtained by the direct action of nitric acid. Substitution takes See also:place usually in the See also:nucleus and only rarely in the See also:side See also:chain, and according to the conditions of the experiment and the nature of the compound acted upon, one or more nitro See also:groups enter the See also:molecule. The reaction is generally carried out in the presence of sulphuric acid, which is used to absorb the water formed during the See also:process of nitration. Nitro compounds have also been prepared by the action of cuprous oxide on diazonium salts (T. Sandmeyer, Ber., 1887, 20, p. 1494); by the action of See also:copper See also:powder on the See also:double salt formed by the addition of potassium mercuric nitrite to diazonium nitrites; and by the oxidation of primary aromatic amines (E. Bamberger, Ber., 1893, 26, p. 496). The mono-nitro compounds are See also:stable and distil without decomposition; they have a See also:pale yellow See also:colour and possess an agreeable odour. Most of the poly-nitro compounds are not volatile, but undergo decomposition on heating. The nitro group in the aromatic series is See also:bound very firmly in the molecule and is not readily exchanged for othez groups. Several different products may be obtained by the reduction of the aromatic nitro compounds, the substances formed in any particular case depending on the conditions of experiment. In acid solution, amines are obtained, in alkaline solution, azoxy, See also:azo and hydrazo compounds, and in neutral solution hydroxylamino compounds. The electrolytic reduction of the aromatic nitro compounds gives rise to substituted hydroxylamines which are immediately transformed into aminophenols or amines. For the nitrobenzenes see See also:NITROBENZENE. Nitrotoluenes, CeH9(CH)s(NO)2. Three isomers exist, the ortho- and See also:para-compounds being the See also:chief products of the direct nitration of See also:toluene. They may be separated by fractional See also:distillation. The orthocompound melts at 10.5° C. and boils at 218° C., the para-compound melts at 54° C. and boils at 230° C. See also:Meta-nitrotoluene (melting at 16° C.) is obtained by nitrating acetparatoluidide and then replacing the amino group by hydrogen. Phenylnitromethane, C6Hs•CH2•NO2, isomeric with the nitro-toluenes, is prepared by the action of benzyl chloride on silver nitrite. It is a colourless oily liquid which boils at 225°-227° C., is somewhat soluble in water, and does not give a coloration with ferric chloride. It readily forms a sodium salt, from the aqueous solution of which on the addition of a See also:mineral acid an isomeric'solid form of the nitro compound (melting at 84° C.) is precipitated. This solid form gradually passes, on See also:standing, into the oily variety. It is probably a hydroxy-compound, since it gives a red-See also: Ponzio, Gazz., 1903, 33 (I), p. 5o8). They are colourless solids which are readily soluble in water and possess the See also:character of weak acids. They are characterized by the deep red colour of their solutions in alkalis. When strongly heated they decompose, forming fatty acids, nitrogen peroxide and nitrogen. By passing hydrochloric acid See also:gas into an ethereal solution of the acids, the nitro group is eliminated and the hydrochloride of an oximido-acid is obtained (A. See also:Werner and H. See also:Buss, Ber., 1895, 28, p.1282): CHs•C(: NOH ) NO2+ 2HC1=HNO2 + CH3.0 (: NOH)CI.HCI. When heated with water and miner?l acids, the nitrolic acids are completely decomposed, yielding fatty acids and nitrous oxide. A. Hantzsch and O. Graul (Ber. 1898, 31, p. 2854) described several series of salts of the nitrolic acids, with particular reference to ethylnitrolic acid. They discriminate between the red or erythro-salts, which are well crystallized, very explosive and unstable compounds, and which regenerate the colourless nitrolic acid on the addition of dilute mineral acids, and the leuco-salts, which are colourless salts obtained by warming the erythro-salts or by exposing them to direct sunlight. These salts cannot be converted either into the red salts or into the See also:free acid. An intensely yellow acid salt is described, as is also a very unstable colourless salt which could not be examined further owing to its very labile nature. The following structural formulae are assigned to these compounds: R CAN •OH R.0 N(OK) 0 R.0 iNO2K -'.NO2 ~N(:0) ~NO nitrolic acid; erythro-salt; leuco-salt. The acid salts are obtained by the addition of one molecule of See also:alkali to two molecules of the acid in concentrated alcoholic solution at a See also:low temperature. They are unstable compounds which readily split into the red salt and the free acid on standing. The pseudo-nitrols, RR':C(NO) (NO2), may be obtained by the action of nitrous acid on the secondary nitroparaffins; by the action of silver nitrite on such bromnitrosoparaffins as contain the bromine and the nitroso group See also:united to the same carbon atom (O. See also:Piloty, Ber., 1902, 35, p. 3093); and by the action of nitrogen peroxide on ethereal solutions of ketoximes (R. See also:Scholl, Ber., 1888, 21, p. 5o8; G. See also:Born, Ber. 1896, 29, p. 93). They exhibit an intense See also:blue colour when in the liquid See also:condition or dissolved in alkali and possess a very See also:sharp See also:smell. On oxidation with chromic acid they yield dinitrohydrocarbons, and on reduction with hydroxylamine (in alkaline solution) or with potassium sulphydrate give ketoximes, RR':C:NOH (R. Scholl and K. Landsteiner, Ber., 1896, 29, p. 87). RR': C(NO) .NO'--> RR': C(NH •OH)2—>RR': C:N•OH+NH2OH. Nitrosohydrocarbons have been prepared in the aliphatic series by the oxidation of the corresponding hydroxylamino compounds. Nitroso-tertiary butane, (CH3)3C•NO, is formed when the corresponding hydroxylamine is oxidized by sulphuric monoper acid (E. Bamberger, Ber., 1903, 36, p. 686). A nitrosooctane (CH2)2C(NO)•[CH2]2•CH(CH3)2, has been obtained by O. Piloty and O. See also:Ruff (Ber., 1898, 31, p. 457) from nitro-di-isobutyl by reducing it to the corresponding hydroxylamino compound with See also:aluminium See also:amalgam and oxidizing this with chromic acid mixture. It is a colourless solid which melts at 54° C. to a deep blue liquid. Numerous nitroso compounds are met with in the aromatic series. Additional information and CommentsThere are no comments yet for this article.
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