Pyridines, phenyl-, nitration

Imidazo[4,5-c]pyridin-4(5H)-ones chlorination, 5, 621 Imidazo[ 1,2-a]pyrimidine, 2-phenyl-nitration, 5, 627... 

Imidazo[4,5-6]pyridine, 3-methyl-alkylation, 5, 616 bromination, 5, 617 nitration, 5, 617 radical methylation, 5, 618 Imidazo[4,5-6]pyridine, 2-methyl-3-phenyl-synthesis, 5, 637... 

Pyridine, l-lithio-2-phenyl-l,2-dihydro-, 2, 266 Pyridine, 2-methoxy-IR spectroscopy, 2, 129 photoelectron spectroscopy, 2, 140 pulsed ion gas-phase cyclotron resonance spectroscopy, 2, 157 Pyridine, 3-methoxy-nitration, 2, 191 Pyridine, 4-methoxy-pKa,, 2. 150... 

Oxidation of 5-arylazo-6-aminoquinoline 146 with copper sulfate in pyridine gave the corresponding 2-aryltriazolo[4,5-/]quinolines 147. Condensation of halo-genated nitrobenzenes with triazolo[4,5-/]quinoline 145 yielded the appropriate 2H- and 3//-aryl derivatives. The nitration of 3-phenyl-3//-triazolo[4,5-/]quino-line 147 occurred at position 4 of the phenyl ring (Scheme 46) (73T221). 

The presently known electrophilic substitution reactions all occur at the 4-position of the isoxazole nucleus, corresponding to the j3-position in pyridine. Thus the influence of the nitrogen atom is predominant. The introduction of alkyl and, particularly, aryl substituents into the isoxazole nucleus markedly increases its reactivity (on the other hand, during nitration and sulfonation the isoxazole nucleus also activates the phenyl nucleus). 

Carboxylic acids, a-bromination of 55, 31 CARBOXYLIC ACID CHLORIDES, ketones from, 55, 122 CARBYLAMINE REACTION, 55, 96 Ceric ammonium nitrate [Ammonium hexa mtrocerate(IV)[, 55, 43 Chlorine, 55, 33, 35, 63 CHROMIUM TRIOXIDE-PYRIDINE COMPLEX, preparation in situ, 55, 84 Cinnamomtnle, a-phenyl- [2-Propeneni-tnle 2,3-diphenyl-], 55, 92 Copper(l) iodide, 55, 105, 123, 124 Copper thiophenoxide [Benzenethiol, copper(I) salt], 55, 123 CYCLIZATION, free radical, 55, 57 CYCLOBUTADIENE, 55, 43 Cyclobutadieneiron tricarbonyl [Iron, tn-carbonyl(r)4-l,3-cyclo-butadiene)-], 55,43... 

Schrader prepared the ester (38) in 60% yield by reaction of sodium p-nitrophenate with diethyl chlorophosphate, using xylene as solvent for the reaction. He made it, but in lower yields, from p-nitrophenol and diethyl chlorophosphate, using, respectively, pyridine and sodium cyanide as acceptors for hydrogen chloride. Schrader also prepared it in 96% yield by nitrating diethyl phenyl phosphate at 0° C. or below. Under the conditions he used, Schrader claims that the nitro group is directed to the para position. No yield is given for the diethyl phenyl phosphate, which he presumably made from sodium phenate and diethyl chlorophosphate. Diethyl chlorophosphate may be prepared in high yield (30) from diethyl phosphite and chlorine. 

Pentanone Petroleum distillates Phenyl ether vapor Phenyl glycidyl ether n-Propyl acetate Propyl alcohol n-Propyl nitrate Propylene dichloride Propylene oxide Pyridine... 

Compounds 4 and 5 would be expected to be inert toward electrophilic substitution, and, in fact, sulfonation of the 2-phenyl derivative 201234 and nitration of the 1-phenyl derivative 202l69b lead to substitution on the phenyl rings. A series of electrophilic substitutions on the product (203) from 1 -(n-butyl)[l,2,3]triazolo[4,5-c]pyridine and dimethyl sulphate give 7-bromo-, 7-nitro-, and 7-chlorotriazolopyridin-4-ones the electrophilic attack may, in each case, be on the triazolopyridinone.169... 

The phase-stabilized AN is prepd by mixing 90 parts AN, 10 ps K nitrate some water, heating the mixt to 140°F, drying and grinding to 40 micron size particles. The proplnt is compressed into grains. Example of compn AN 82.95, K nitrate 9.22, petroleum pitch 4.11 90/10 copolymer of l,3-butadiene/2-methyl-5 -vinyl pyridine 1.76 Amm dichromate 1.96%] EE)R.MacDonald A.M.Bedard, "Methods of Chemical Analysis of Cardeplex Propellant No 4760/A5 and Its Ingredients", CARDE TR426/63 (1963) (Cardeplex No 4760/A5 is a composite ammonium perchlorate-polyurethane proplnt. Analysis of fully cured product includes detns of Amm perchlorate, Al, ferric acetylacetonate, phenyl-/3 -naphthylamine, lithium fluoride total iron) FF)Anon,... 

In contrast to the ease of N-functionalization, shown in Scheme 1, the triazolopyridine nucleus is resistant to direct nuclear oxidation or electrophilic additions. Electrophilic additions will occur on aryl substituents for example, nitration of l-phenyltriazolo[4,5-c]pyridine (26) and sulfonation of 2-phenyl-2i/-triazolo[4,5-6]pyridine (28) occur exclusively in the para position of the phenyl ring <34LA(514)279, 38MI 710-01). Nuclear functionalization was observed when l-( -butyl)-5-methyl-tri-azolo[4,5-c]pyridinium iodide (30) was treated with potassium ferricyanide to afford triazolopyridin-4-one (31), as shown in Scheme 2. Similarly, the iodide (30) is converted by either phosphorus oxychloride-phosphorus pentachloride, or bromine or nitric acid to 7-substituted triazolopyridin-4-ones (32) <37LA(529)288>. 

In an approach to direct C-functionalization of triazolo[4,5-c]pyridines, shown in Scheme 3, 1-methyl (or phenyl)[l,2,3]triazolo[4,5-c]pyridines (26,33) are alkylated exclusively at C-4 by radicals generated by decarboxylation of carboxylic acids (ammonium persulfate-sulfuric acid-silver nitrate) <90ZOB683>. However, with /-butanol various products are obtained depending on the catalyst employed. For example, with ammonium persulfate-sulfuric acid-silver nitrate, exclusive C(4)-methylation (34) was observed, while ammonium persulfate-sulfuric acid gave exclusively C(4)-/ -hydroxy-/ ,/ -dimethylethylation (cf. (36)). The /-butyl analogue (35) was obtained by decarboxylation of pivalic acid. 

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