Thiophene oxides synthesis

Thiophene, 3-pentadeuterophenyl-chemical shifts, 4, 730 Thiophene, 2-phenyl-oxidation, 4, 800 phototranspositions, 4, 743 rearrangement, 4, 42 reduction, 4, 775 synthesis, 4, 865, 914 UV spectrum, 4, 735 Thiophene, 3-phenyl-photochemical rearrangements, 4, 735 phototranspositions, 4, 743 lsmeier formylation, 4, 759 Thiophene, 2-pivaloyl-Birch reduction, 4, 775 Thiophene, polybromo-reactivity, 4, 829 Thiophene, polylithio-synthesis, 4, 831 Thiophene, (propargylthio)-rearrangement, 4, 746 Thiophene, 2-(3-pyridinyl)-synthesis, 4, 781 Thiophene, 2-(5-pyrimidinyl)-synthesis, 4, 781 Thiophene, 3-pyrrolidinyl-cycloaddition reactions, 4, 68 with dimethyl acetylenedicarboxylate, 4, 788-789... 

Nitrile oxides of the thiophene series, synthesis and reactivity 91MI45. 

Several mechanisms have been proposed for both electrochemical and chemical oxidative synthesis of poly thiophenes. The proposed mechanisms are similar to those proposed for polypyrrole formation. The first step of the polymerization is the oxidation of the thiophene monomer to a cation radical. The subsequent steps are controversial. There are several possibilities. The cation radical can couple with another cation radical or with a neutral species. Alternatively, the cation radical can deprotonate to form a neutral radical. This radical can then couple with another radical or with a neutral species. Several of these possibilities are discussed below. 

An indirect method for the synthesis of aryl alkyl sulhdes involves treatment of an aryl halide with butyllithium and then elemental sulfur. The resulting thiophen-oxide anion reacts with an alkyl halide to give the targeted sulhde. °... 

Thiophene 1,1-dioxides, formation from diallenyl sulfones 85PS(23)297. Thiophene 1,1-dioxides, sesquioxides, and I-oxides, synthesis ... 

The oxidative ring-closure of (178) gave (179), and similarly (180) was obtained from 3,4-diamino-2,5-dithiocarbamino-thieno[2,3-6]thiophen. The synthesis of substituted (3//)-thieno[2,3-rf]imidazoles has been achieved by a Curtius rearrangement of (181). ... 

Substituted nitrothiophenes serve as precursors for a variety of condensed thiophenes. The synthesis of thienopyrroles has been reviewed <85S143>. Treatment of (2-nitro-3-thienyl)methyl phenyl sulfone (497) with diethyl maleate in the presence of K2CO3 and 18-crown-6 gave the thienopyridine A -oxide (498) in 38% yield <92acs689>. The reaction apparently proceeds by Michael addition, followed by elimination of phenylsulfinate and cyclization. The starting material can be prepared by vicarious nucleophilic substitution discussed earlier. 

Another interesting water-soluble polythiophene is 22, bearing a chiral amino acid side chain, which was prepared by Hjertberg, Inganas and co-workers by oxidative polymerization with FeClg. The chiroptical and sol-vatochromic properties of this optically active polymer are described in the later section entitled Chiroptical properties of optically active poly thiophenes. The synthesis of other, organic solvent-soluble chiral polythiophenes is discussed directly below. 

The synthesis involves the nickel-catalyzed coupling of the mono-Grignard reagent derived from 3-alkyl-2,5-diiodothiophene (82,83). Also in that year, transition-metal hahdes, ie, FeCl, MoCl, and RuCl, were used for the chemical oxidative polymerization of 3-substituted thiophenes (84). Substantial decreases in conductivity were noted when branched side chains were present in the polymer stmcture (85). 

Oxidation of thiophene with peracid under carefully controlled conditions gives a mixture of thiophene sulfoxide and 2-hydroxythiophene sulfoxide. These compounds are trapped by addition to benzoquinone to give ultimately naphthoquinone (225) and its 5-hydroxy derivative (226) (76ACS(B)353). The further oxidation of the sulfoxide yields the sulfone, which may function as a diene or dienophile in the Diels-Alder reaction (Scheme 88). An azulene synthesis involves the addition of 6-(A,A-dimethylamino)fulvene (227) to a thiophene sulfone (77TL639, 77JA4199). 

Benzo[6]thiophene, 4,7-dialkoxy-synthesis, 4, 930 Benzo[6]thiophene, 2,3-dialkyl-synthesis, 4, 877-878 Benzo[6]thiophene, 3 -(dialkylamino)-synthesis, 4, 925 Benzo[c]thiophene, 1,3-diaryl-oxidative ring opening, 4, 768 Benzo[6]thiophene, 2,3-dibromo-reactions, 4, 830... 

Benzo[b]thiophene, 3-mercapto-2-methyl-synthesis, 4, 931 Benzo[6]thiophene, 2-methoxy-lithiation, 4, 773 synthesis, 4, 929 Benzo[6]thiophene, 3-methoxy-alkylation, 4, 765 synthesis, 4, 929 Benzo[6]thiophene, 4-methoxy-anodic oxidation, 4, 798 Benzo[6]thiophene, 5-methoxy-synthesis, 4, 929 Benzo[6]thiophene, 6-methoxy-synthesis, 4, 929 Benzo[6]thiophene, 7-methoxy-synthesis, 4, 929-930... 

Benzo[6]thiophene, methoxynitro-Meisenheimer complexes, 4, 816 Benzo[6]thiophene, 2-methyl-cycloaddition reactions, 4, 793 protonation, 4, 47 sulfonation, 4, 764 synthesis, 4, 879, 915 Benzo[6]thiophene, 3-methyl-cycloaddition reactions, 4, 793 1-oxide... 

Benzo[c]thiophene, 1,3-diphenyl-oxidative ring opening, 4, 768 synthesis, 4, 141-142... 

Distannacyclodecanes synthesis, 1, 606 Disulfide, benzylpurinyl ribosylation, S, 560 Disulfide, bis(l-alkenyl) rearrangement thiophenes from, 4, 871 Disulfide, bis(4-phenyl-3-butenyl) cyclization, 4, 867-868 Disulfide, dibenzothiazolyl as vulcanization accelerator, 1, 402 Disulfide, di(2,6-dimethoxypyrimidin-4-yl) oxidation, 3, 96 Disulfide, dipyrimidinyl synthesis, 3, 137 Disulfide, di(tetrazol-5-yl)... 

Ethylene, /3-(dimethylamino)-nitro-in pyrrole synthesis, 4, 334 Ethylene, dithienyl-in photochromic processes, 1, 387 Ethylene, furyl-2-nitro-dipole moments, 4, 555 Ethylene, l-(3-indolyl)-2-(pyridyl)-photocyclization, 4, 285 Ethylene, l-(2-methyl-3-indolyl)-l,2-diphenyl-synthesis, 4, 232 Ethylene, (phenylthio)-photocyclization thiophenes from, 4, 880 Ethylene carbonate C NMR, 6, 754 microwave spectroscopy, 6, 751 photochemical chlorination, 6, 769 synthesis, 6, 780 Ethylene oxide as pharmaceutical, 1, 157 thiophene synthesis from, 4, 899 Ethylene sulfate — see 2,2-dioxide under 1,3,2-Dioxathiolane... 

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... 

Thiophene, 3,5-diethyl-2,4-diphenyl-synthesis, 4, 900 Thiophene, dihydroconformation, 4, 34 cycloaddition reactions, 4, 850 H NM 4, 10 methiodide, 4, 86 molecular structure, 4, 7 1-oxide... 

The mechanism for the redistribution in oxidation states begins similarly to that of the Paal thiophene synthesis. However, upon formation of dithione 38, nucleophilic addition of one thiocarbonyl into the other produces the intermediate zwitterion 39. A 1,3-tautomerization of hydrogen then gives... 

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