Benzene nitro-derivatives

The interaction of alkyl halides with mercaptans or alkaline mercaptides prodnces thioalkyl derivatives. This is a typical nncleophilic substitution reaction, and one cannot tell by the nature of products whether or not it proceeds through the ion-radical stage. However, the version of the reaction between 5-bromo-5-nitro-l,3-dioxan and sodium ethylmercaptide can be explained only by the intermediate stage involving electron transfer. As found (Zorin et al. 1983), this reaction in DMSO leads to diethyldisulfide (yield 95%), sodium bromide (quantitative yield), and 5,5 -bis(5-nitro-l,3-dioxanyl) (yield 90%). UV irradiation markedly accelerates this reaction, whereas benzene nitro derivatives decelerate it. The result obtained shows that the process begins with the formation of ethylthiyl radicals and anion-radical of the substrate. Ethylthiyl radicals dimerize (diethyldisulfide is obtained), and anion-radicals of the substrate decompose monomolecularly to give 5-nitro-l,3-dioxa-5-cyclohexyl radicals. The latter radicals recombine and form the final dioxanyl (Scheme 4.4). 

Ultraviolet irradiation markedly accelerates the reaction, while benzene nitro derivatives decelerate it. The result obtained shows that the process begins with the formation of ethylthiyl radicals and anion radicals of the substrate. Ethylthiyl radicals dimerize (diethyldisulfide is obtained), and anion radicals of the substrate decompose monomolecu-larly to give 5-nitro-l,3-dioxa-5-cyclohexyl radicals. The latter radicals recombine and form the final dioxanyl (Scheme 4-4). 

HEATS of combustion ANI) heats of formation of benzene nitro derivatives according... 

Nitro derivatives of benzene Nitro derivatives of diphenyl... 

Oxidation of side chains. Aromatic nitro compounds that contain a side chain (e.g., nitro derivatives of alkyl benzenes) may be oxidised to the corresponding acids either by alkahne potassium permanganate (Section IV,9, 6) or, preferably, with a sodium dichromate - sulphuric acid mixture in which medium the nitro compound is more soluble. 

In the section dealing with electrophilic attack at carbon some results on indazole homocyclic reactivity were presented nitration at position 5 (Section 4.04.2.1.4(ii)), sulfon-ation at position 7 (Section 4.04.2.1.4(iii)) and bromination at positions 5 and 7 (Section 4.04.2.1.4(v)). The orientation depends on the nature (cationic, neutral or anionic) of the indazole. Protonation, for instance, deactivates the heterocycle and directs the attack towards the fused benzene ring. A careful study of the nitration of indazoles at positions 2, 3, 5 or 7 has been published by Habraken (7UOC3084) who described the synthesis of several dinitroindazoles (5,7 5,6 3,5 3,6 3,4 3,7). The kinetics of the nitration of indazole to form the 5-nitro derivative have been determined (72JCS(P2)632). The rate profile at acidities below 90% sulfuric acid shows that the reaction involves the conjugate acid of indazole. 

However, other studies on the nitration of a series of 3-methyl- and 3-ethyl-1,2-benzisoxazoles have shown that a mixture of the 5-nitro and 5,7-dinitro derivatives is formed (77IJC(B)1058, 77IJC(B)1061). The effect of substituents in the benzene ring is also of interest. If the 5-position is blocked, e.g. by a chloro group or by alkyl groups, nitration then occurs at the 4-position. 3-Alkyl-7-chloro and 3,7-dialkyl derivatives result in the formation of the appropriate 5-nitro derivative. The isomeric 3-alkyl-6-chloro- and 3,6-dialkyl-1,2-benzisoxazoles yield a mixture of the 5-nitro and 5,7-dinitro compounds. Both H NMR measurements and alternate syntheses were used in establishing the structures of these substitution products. 

Toxicity. Picric Acid is more toxic than the nitro derivatives of toluene, xylene or naphthalene. It is, however, much less toxic than nitro derivatives of benzene... 

If an aromatic compound contains saturated aliphatic side chains nitration carried out under the above conditions takes place always in the benzene nucleus and not in the side chain. Since the carbon atoms of benzene are each united directly to only one hydrogen atom, the nitro-derivatives obtained are tertiary and therefore incapable of forming salts, nitrolic acids, or pseudonitroles, as do the primary and secondary nitro-compounds. 

A fractional order in the nitrite anion was found. This differs from the observed behavior in a benzene series where it is second order. The explanation, according to the Scheme 69, is based on the presence of a prototropic equilibrium between the diazonitrite form 241 and the conjugate base 242. The nitro derivatives 243 were mainly formed from the diazonitrite 241 because the equilibrium 241 242 is shifted towards the undissociated form, as shown by the calculated value of the quantity... 

We now turn to the two aryl hydroxylamines, Af-phenylhydroxylamine and its o-nitro derivative. As liquids, the former compound has an enthalpy of formation that is ca 20 kJmoH more positive than that of the latter. For comparison, we find the enthalpies of the corresponding hquid species without the NHOH group, Le. benzene and nitrobenzene, differ by 36.5 kJmol . Alternatively said, equation 4 is endothermic by 16.1 kJmol . 

More recently, Kim and coworkers have developed a novel radical alkylation reaction of organic nitro derivatives 16a-d via bis(silyloxy)enamines 17a-d (Scheme 16). This method enables not only P -alkylation to the nitro gronp, bnt also the conversion of the nitro group (16a-d) into an oxime ether fnnctionahty (18a-d). The irradiation of a solntion of 16a-d with iodomethyl phenyl snlfone (or ethyl iodoacetate) and hexamethylditin in benzene at 300 nm give the oxime ethers 18a-d in good yields. 

Nitryl chloride reacts with many organics forming their nitro derivatives. Such Friedel-Crafts nitration is catalyzed by a Lewis acid, such as AICI3. An example is nitration of benzene to nitrobenzene ... 

Nitration of pyridines in other than nitric or sulfuric acids is of little interest here because either no reaction or N-nitration takes place (see Section 2.05.2.10). However, pyridine 1-oxide is considerably more reactive and treatment with benzoyl nitrate ultimately leads to the 3-nitro derivative (Scheme 25) (60CPB28). Annelation of a benzene ring bestows greater reactivity on the 3-position in quinoline, compared with pyridine, and reaction with nitric acid in acetic anhydride furnishes the 3-nitro derivative (ca. 6%) (Scheme 26). This isomer has also been obtained, again at low yield (6-10%), by treatment of quinoline with tetranitratotitanium(IV) in carbon tetrachloride (74JCS(P1)1751>. Nitration of benzo analogues of pyridine occurs much more readily in the benzene ring, and Chapter 2.06 should be consulted for these reactions. 

That it is not necessary to employ substituted aryl compounds in order to obtain a substituted product was demonstrated by Gerecs and Windholz,41 who nitrated tetra-0-acetyl-/3-D-glucopyranosyl-benzene with cuprous nitrate in acetic anhydride to give a mixture ( 4 1) of the corresponding o- and p-nitro derivatives. 

Complete exclusion of moisture, short contact time of the reactants, and distillation of the reaction product in vacuo arc required for successful fluorination of (dichloromethyl)ben-zene and its 3- and 4-substituted fluoro and nitro derivatives. The hydrogen fluoride formed in side reactions is immediately removed to prevent polymerization of the (difluorometh-yl)benzenes.14... 

---