Thiophene nitration

Imidazole is much less reactive to nitration than heterocycles like furan and thiophene. Nitration of l-methyl-2-(2 -furyl)imidazole (and the thienyl analogue) in acetic anhydride occurs at the 5 -position in polyphosphoric acid the imidazole ring is also 5-nitrated <89CHE1168, 91CHE1140>. Imidazole is, however, more reactive than thiazole imidazole substituted at C-2 by 2-methyl-4-thiazolyl nitrates at both 4- and 5-positions without affecting the thiazole moiety <89JHC1627>. 

Early attempts to nitrate thiophene and to reduce a nitro-product, in analogy with benzene chemistry, were unsuccessful until the conditions for nitration of thiophene were found. Eventually, rather special conditions were developed thiophene vapour mixed with air was passed for several hours through fuming nitric acid. After work-up, mononitrothiophene and a dinitrothiophene were isolated [125], Later it became clear that the failure in thiophene nitration with nitric acid is due to the presence of nitrous acid that led to the formation of nitrosothiophene, which is prone to decomposition [ 126]. A mixture of nitric acid with acetic anhydride in glacial acetic acid can mononitrate thiophene very effectively (Scheme 84) [127]. 

Other useful thiophene-nitrating reagents include copper(ll) nitrate in acetic anhydride and aluminium nitrate in acetic anhydride [128, 129]. Nitration of substituted thiophenes is subject to the usual mesomeric and inductive effects of the substituents [130]. Nitration can also take place at already substituted positions, replacing bromine or iodine (see, e.g. [131]). The nitration of... 

Thiophen-z-T acid, 25 °C (kinetic) Benzoyl nitrate—acetonitrile, 0-88 15... 

Nitration. It is difficult to control nitration of thiophene, which yields 2-nitrothiophene [609-40-9]. The strongly electropbilic nitronium ion leads to significant yields (12—15%) of 3-isomer. A preferred procedure is the slow addition of thiophene to an anhydrous mixture of nitric acid, acetic acid, and acetic anhydride. 

The range of preparatively useful electrophilic substitution reactions is often limited by the acid sensitivity of the substrates. Whereas thiophene can be successfully sulfonated in 95% sulfuric acid at room temperature, such strongly acidic conditions cannot be used for the sulfonation of furan or pyrrole. Attempts to nitrate thiophene, furan or pyrrole under conditions used to nitrate benzene and its derivatives invariably result in failure. In the... 

Thiophene is much more easily nitrated than benzene and it is therefore possible to use mild nitrating agents such as acetyl or benzoyl nitrate. Like pyrrole and furan the principal nitration product is the 2-derivative. The a selectivity decreases with increasing vigour of the reagent and up to 15% of the 3-isomer has been obtained. 

Nitration of benzo[6]thiophene (HNOs/AcOH) yields mainly the 3-nitro derivative. Under these conditions the /3 to a ratio of substitution is approximately 5 1, which is... 

Nitration of 4-(2-thienyl)- (301) and 4-(3-thienyl)-pyrazoles (302) mainly occurs on the thiophene ring, but when acetyl nitrate is used as the nitration agent small quantities of products nitrated on the pyrazole ring are isolated (position of the nitro group uncertain) (80CS( 15)102). Pyrazol-l -ylpyridines (303) undergo electrophilic reactions (bromination, chlorination and nitration) preferentially in the pyrazole ring. Thus, the nitration of (303 R = R = = H) either with a mixture of nitric acid and sulfuric acid at 10-15 °C or with... 

Benzo[6]thiophene, 1,2-dimethyl-cycloaddition reactions with dichloroethene, 4, 793 Benzo[6]thiophene, 2,3-dimethyl-nitration, 4, 763... 

Phenanthro[l,2-d][l,2,3]selenadiazole, 10,11 dihydro- H NMR, 6, 348 synthesis, 6, 353 Phenanthro[b]thiophenes synthesis, 4, 914 Phenanthro[4,5-bcd]thiophenes synthesis, 4, 883, 907, 914 Phenanthro[9,10-ej[l, 2,4]triazines synthesis, 3, 434 Phenarsazin synthesis, 1, 561 Phenazine dyes, 3, 196-197 nitration, 3, 177 UV Spectra, 2, 127 Phenazine, 3-amino-2-hydroxy-in colour photography, 1, 374 Phenazine, 1-chloro-nucleophilic substitution, 3, 164-165 5-oxide... 

H NMR, 4, 1042 ionization potentials, 4, 1046 synthesis, 4, 1066 UV spectra, 4, 1044 Selenolo[2,3 -cjthiophenes H NMR, 4, 1042 synthesis, 4, 1067 UV spectra, 4, 1044 Selenolo[3,2-6]thiophenes dipole moments, 4, 1049 H NMR, 4, 1042 ionization potentials, 4, 1046 synthesis, 4, 1066 UV spectra, 4, 1044 Selenolo[3,4-6]thiophenes synthesis, 4, 1067 Selenolo[3,4-c]thiophenes addition reactions, 4, 1062 synthesis, 4, 1076 Selenomethionine applications, 4, 970 Selenophene, 3-acetamido-reactions, 4, 953 Selenophene, 2-acetyl-mercuration, 4, 946 nitration, 4, 947 Selenophene, 2-alkyl-reactions, 4, 45 synthesis, 4, 135, 967 Selenophene, 3-alkyl-synthesis, 4, 135, 967 Selenophene, 3-aryl-synthesis, 4, 963 Selenophene, 2-benzyl-reactivity, 4, 946 Selenophene, 2-benzyl-5-ethyl-reduction, 4, 950... 

Thieno[3,2-h]thiinium perchlorates synthesis, 4, 1028 Thieno[3,2-c]thiinium perchlorates synthesis, 4, 1028 Thienothiinium salts, 4, 1027 synthesis, 4, 1028 UV spectra, 4, 1029 Thienothiins synthesis, 6, 1011 Thieno[2,3-h]thiophene, 2-acetyl-nitration, 4, 1054 Thieno[2,3-h]thiophene, 2-amino-synthesis, 4, 1070... 

Thiophene undergoes electrophilie substitution resulting in two possible isomers, e.g., for nitration. 

Aceording to Frontier Molecular Orbital (FMO) theory, thiophene s most reactive site can be identified by examining the shape of its highest-occupied molecular orbital (HOMO). Which atoms contribute to thiophene s HOMO Which atom(s) contributes the most Which nitration product should form preferentially ... 

Nitration of thiophene with cupric nitrate in acetic anhydride or acetic acid is considered to be milder than nitric acid in the same solvents and has been used successfully with thiophene derivatives which decomposed on conventional nitration/ ... 

Finally, certain 3-substituted compounds can be prepared by utilizing the - meta) directing powet (cf. Section IV,B) of some groups in the 2-position which afterward can be removed. 3-Nitrothiophene is prepared by nitration of 2-thiophenesulfonyl chloride and by removal of the sulfonic acid group of the 4-nitro-2-sulfonyl chloride formed with superheated steam. Another approach to 3-nitrothio-phene is to nitrate 2-cyanothiophene, separate the 4-nitro-2-cyano-thiophene from the 5-isomer, hydrolyze, and decarboxylate. A final method of preparation of 3-nitrothiophene is by simultaneous de-bromination and decarboxylation of 5-bromo-4-nitro-2-thiophene-carboxylic acid obtained through the nitration of methyl 5-bromo-2-thiophenecarboxylate. 

It is thus apparent that the selectivity of a reagent toward thiophene and benzene can differ appreciably, and this difference in selectivity is also strongly noticeable in the proportions of 2- and 3-isomers formed. Although in certain reactions no 3-isomer has been detected, appreciable amounts have been found in other reactions. Thus 0.3% of the 3-isomer has been found in the chlorination of thiophene.- Earlier results indicated that 5-10% 3-nitrothiophene is formed in the nitration of thiophene and a recent gas-chromatographic analysis by Ostman shows that the mononitrothiophene fraction contains as much as 16% of the 3-isomer. It appears that gas-chromatographic analysis should be very useful for the detection of small amounts of 3-isomers in other substitution reactions. However, from routine analyses of IR spectra, it appears to the present author that the amount of 3-isomers formed in acylation, formylation, and bromina-tion of thiophene are certainly less than a few per cent. 

It can be seen from resonance structures (2) to (4) that a — I — M-substituent deactivates the 3- and 5-position most strongly in electrophilic substitution. If this deactivation of the 5-position is strong enough to overcome the activating effects of the sulfur in the 5-position, substitution will be directed to the 4-position to an increasing extent. Tirouflet and Fournari studied the nitration of 2-substituted thiophenes of this type. The analysis was carried out polarographically, and the percentage of 4-isomer was as follows ... 

From resonance structure (12) it is obvious that a —I—M-substit-uent strongly deactivates the 2-position toward electrophilic substitution, and one would thus expect that monosubstitution occurs exclusively in the 5-position. This has also been found to be the case in the chlorination, bromination, and nitration of 3-thiophenecarboxylic acid. Upon chlorination and bromination a second halogen could be introduced in the 2-position, although further nitration of 5-nitro-3-thiopheneearboxylic acid could not be achieved. Similarly, 3-thiophene aldehyde has been nitrated to 5-nitro-3-thiophene aldehyde, and it is further claimed that 5-bromo-3-thiopheneboronic acid is obtained upon bromination of 3-thiopheneboronic acid. ... 

The position of substitution in disubstituted thiophenes can, in most cases, easily be deduced from the directing effect of each substituent. Thus with a - -M-substituent in the 2-position and a —M-substituent in the 5-position, both substituents direct the entering group to the 3-position as is exemplified by the nitration of methyl 2-bromo-5-thiophenecarboxylate to methyl 2-bromo-3-nitro-5-thio-phenecarboxylate (109) or in the chlororaethylation of methyl 2-methyl-5-thiophenecarboxylate to methyl 2-methyl-3-chloromethyl-5-thiophenecarboxylate (110). °... 

Further substitution of 2,4-disubstituted and most 2,3-disubstituted thiophenes occurs in the free a-position, except when a - -M-substituent in the 3-position strengthens the 4-directing power of a —1—M-sub-stituent in the 2-position. Thus methyl 3-methyl-2-thiophenecar-boxylate is brominated in the 4-position and 3-brorao-2-thiophene-aldehyde is nitrated in the 4-position. Recent investigations on the chloromethylation, sulfonation, mercuration, and nitration of 2,4-di-chlorothiophene, which without proof are assumed to occur in the 5-position serves as examples of the reactivity of a 2,4-disubstituted thiophene. Formylation with iV,A-dimethylformamide and... 

Friedel-Crafts acylation of fluorobenzene with thiophene-l-carboxylic acid gives the ketone 7. Nitration proceeds ortho to the fluoro group to give the intermediate Nucleophilic displacement by means of... 

FIGURE 2.2 Transformation of (a) 5-aminonaphthalene-2-sulfonate, (b) benzo[fc]thiophene, (c) 4-chloro-biphenyl, (d) 4-nitrotoluene, (e) 3,5-dichlor-4-methoxybenzyl alcohol, (f) 2,3-diaminonaphthalene in presence of nitrate, and (g) 3,4-dichloroaniline presence of nitrate. 

During nitration of several amino derivatives, diazotisation and oxidation occurred to produce internal diazonium phenoxide compounds. 5-Acetylamino-3-bromobenzo[h ]thiophene unexpectedly underwent hydrolysis, diazotisation and oxidation to the explosive compound below. 

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