Nitration allylic

Furo[3,4-d]pyridazine-1,4-diones synthesis, 4, 985 Furopyridazines, 4, 984 Furo[2,3-6]pyridine, 3-amino-synthesis, 4, 977 Furo[2,3-6]pyridine, 4-methyl-synthesis, 4, 976 Furo[2,3-6]pyridine, 6-methyl-synthesis, 4, 976 Furo[2,3-6]pyridine, 5-nitro-synthesis, 4, 977 Furo[3,2-c]pyridine, 4-allyl-synthesis, 4, 982 Furopyri dines H NMR, 4, 983 physical data, 4, 983 properties, 4, 982 synthesis, 4, 974-982 UV spectroscopy, 4, 983 Furo[6]pyri dines HMO data, 4, 975 Furo[2,3-6]pyri dines synthesis, 4, 974-977 7, 512 Furo[3,2-6]pyri dines C NMR, 4, 982 synthesis, 4, 648, 981 Furo[c]pyri dines HMO data, 4, 976 Furo[2,3-c]pyri dines synthesis, 4, 977 Furo[3,2-c]pyri dines nitration, 4, 983 synthesis, 4, 978-981 Furo[3,4-c]pyri dines synthesis, 4, 982 Furo[3,2-c]pyridin-3-ols synthesis, 4, 980 Furo[2,3-6]pyridin-6-ones synthesis, 4, 976 Furo[3,4-c]pyridin-4-ones synthesis, 4, 982... 

Vilsmeier-Haack formylation, 4, 222 Indole, dimethyl- C NMR, 4, 172 Indole, 1,2-dimethyl-bis-allylation, 4, 357 Indole, 1,3-dimethyl-nitration, 4, 211 reactions... 

Thiazole, 2-acetylamino-4-methyl-alkylation, 6, 256 Thiazole, 2-acylamino-4-hydroxy-synthesis, 6, 297 Thiazole, 5-alkoxy-cleavage, 6, 289 synthesis, 6, 302 Thiazole, 2-alkyl-A7-alkylation, 6, 253 hydrogen exchange, 6, 276 methylation, 6, 253 quatemization, 6, 253-254 reactions, S, 88 Thiazole, 4-alkyl-A7-alkylation, 6, 253 methylation, 6, 253 quatemization, 6, 253-254 Thiazole, 5-alkyl-A7-alkylation, 6, 253 methylation, 6, 253 Thiazole, 2-alkylamino-tautomerism, 6, 248 Thiazole, 4-alkyl-2,5-dimethyl-quatemization, 6, 253-254 Thiazole, 2-alkylthio-reactions, S, 103 rearrangement, 5, 103 6, 291 Thiazole, 3-allyl-4-hydroxy-2-imino-synthesis, 6, 297 Thiazole, 2-allyloxy-rearrangement, 6, 289 Thiazole, 2-amino-diazo coupling, 6, 257 nitration, 6, 255... 

A135-R to A136-L. A patented process (Ref) obtains polymers by heating allyl ale, or homologs, at 50—100° in the presence of oxygen and/or an oxygen-yielding catalyst such as a peroxide, perchlorate or persulfate. Nitration of these polymers has yielded some expls Ref Anon, DutchP 66784 (1950) CA 45,... 

Dihydropyrans [71] and 4-dihydropyranones [72] have been prepared by BF3 or Me2AlCl catalyzed Diels-Alder reactions of alkyl and aryl aldehydes with dienes 72 and 73 (Equations 3.20 and 3.21). Allylic bis-silanes are useful building blocks for synthesizing molecules of biological interest [73], 4-Pyra-nones have been obtained by cerium ammonium nitrate (CAN) oxidation of the cycloadducts. 

Allyl acetates are more commonly used as electrophiles for the palladium-catalyzed allylic alkylation than allylic nitro compounds.20 However, the reaction of allylic nitro compounds has found wider applications. Allylic nitro compounds are readily available by nitration of alkenes. The regio- and stereoselective introduction of electrophiles and nucleophiles into alkenes is possible as outlined in Eq. 7.19. In fact, this strategy is applied to the synthesis of terpenoids.21... 

Conversion of ketone 80 to the enol silane followed by addition of lithium aluminum hydride to the reaction mixture directly provides the allylic alcohol 81 [70]. Treatment of crude allylic alcohol 81 with tert-butyldimethylsilyl chloride followed by N-b ro m o s u cc i n i m i de furnishes the a-bromoketone 82 in 84 % yield over the two-step sequence from a.p-unsaturated ester 80. Finally, a one-pot Komblum oxidation [71] of a-bromoketone 82 is achieved by way of the nitrate ester to deliver the glyoxal 71. It is worth noting that the sequence to glyoxal 71 requires only a single chromatographic purification at the second to last step (Scheme 5.10). 

Only a few examples exist for the intermolecular trapping of allyl radicals with alkenes68,69. The reaction of a-carbonyl allyl radical 28 with silyl enol ether 29 occurs exclusively at the less substituted allylic terminus to form, after oxidation with ceric ammonium nitrate (CAN) and desilylation of the adduct radical, product 30 (equation 14). Formation of terminal addition products with /ram-con figuration has been observed for reaction of 28 with other enol ethers as well. 

However, styrene and cyclohexene gave complex product mixtures, and 1-octene did not react under the same reaction conditions. Thus, the activity of this catalyst is intrinsically low. Jacobs and co-workers [159,160] applied Veturello s catalyst [PO WCKOj ]3- (tethered on a commercial nitrate-form resin with alkylammonium cations) to the epoxidation of allylic alcohols and terpenes. The regio- and diastereoselectivity of the parent homogeneous catalysts were preserved in the supported catalyst. For bulky alkenes, the reactivity of the POM catalyst was superior to that of Ti-based catalysts with large pore sizes such as Ti-p and Ti-MCM-48. The catalytic activity of the recycled catalyst was completely maintained after several cycles and the filtrate was catalytically inactive, indicating that the observed catalysis is truly heterogeneous in nature. 

Other polymerisation incidents are f Acrylaldehyde, 1145 Acrylamide, 1180 Acrylic acid, 1148 Acrylic acid, Initiator, Water, 1148 f Acrylonitrile, 1107 f Acrylonitrile, Initiators, 1107 f Acrylonitrile, Silver nitrate, 1107 f Acryloyl chloride, 1093 Allyl 4-toluenesulfonate, 3315 Aluminium chloride, Alkenes, 0062 3 - Aminopropiononitrile f Aziridine, Acids, 0863... 

Ceric ammonium nitrate promoted oxidative addition of silyl enol ethers to 1,3-butadiene affords 1 1 mixtures of 4-(/J-oxoalkyl)-substituted 3-nitroxy-l-butene and l-nitroxy-2-butene27. Palladium(0)-catalyzed alkylation of the nitroxy isomeric mixture takes place through a common ij3 palladium complex which undergoes nucleophilic attack almost exclusively at the less substituted allylic carbon. Thus, oxidative addition of the silyl enol ether of 1-indanone to 1,3-butadiene followed by palladium-catalyzed substitution with sodium dimethyl malonate afforded 42% of a 19 1 mixture of methyl ( )-2-(methoxycarbonyl)-6-(l-oxo-2-indanyl)-4-hexenoate (5) and methyl 2-(methoxycarbonyl)-4-(l-oxo-2-indanyl)-3-vinylbutanoate (6), respectively (equation 12). 

N-acetyl-phenethylamine. Place 100 ml of acetonitrile and 64.8 g (.2 mole) of mercuric nitrate in a flask with stirring and cool to 25°. To this externally cooled and stirred mixture add 0.2 mole of allyl benzene at such a slow rate as to keep the temp under 30°. After the addition, stir at room temp for 1 hour, cool again, and achieve the reduction by adding 200 ml of 3 M sodium hydroxide, followed by 200 ml of. 5 M sodium borohydrate in 3 M sodium hydroxide. After 1 hour the water layer is saturated with sodium chloride and the product taken up with (extracted with) ether. Distillation, collect the fraction coming over at 101-105°. Yields 20 g of product. 

Allylic and homoallylic alcohols are particularly susceptible to oxidation and dehydration. Hiskey and Oxley successfully nitrated both allyl alcohol and l-buten-4-ol with nitronium tetrafluoroborate in diethyl ether at -71 °C. 

Solutions of acetyl nitrate at subambient temperature can react with alkenes to yield a mixture of nitro and nitrate ester products. Cyclohexene forms a mixture of 2-nitrocyclohexanol nitrate, 2-nitrocyclohexanol acetate, 2-nitrocyclohexene and 3-nitrocyclohexene. This illustrates one of the problems of allylic and homoallylic alcohol 0-nitration with this reagent. 

The dihydroxylation of alkenes is a useful sttategy for the synthesis of polyols and these can be nitrated to the corresponding nitrate esters. Evans and Gallaghan " synthesized both the mono- (74) and di- (70) allyl ethers of pentaerythritol and used these for the synthesis of some novel nitrate ester explosives. 

Dihydroxylation of the allyl groups of (70) with hydrogen peroxide and catalytic osmium tetroxide, followed by 0-nitration of the product (72), yields the hexanitrate ester (73). Similar treatment of the mono-allyl ether (74) affords the pentanitrate ester (76). Evans and Callaghan also 0-nitrated the hydroxy groups of (70) and (74) to yield the dinitrate and trinitrate esters, (71) and (75), respectively. The dinitrate ester (71) may find use as a monomer for the synthesis of energetic binders. 

In 2000, Tanino and his co-workers developed the novel [5- -2]-cycloaddition reaction of a propargyiic cation equivalent bearing allylic silane 17 with enol silane 18 to give the corresponding cycloheptyne complexes 19 in good yields with an excellent diastereoselectivity (Scheme 3). While ceric ammonium nitrate (CAN) is generally used to... 

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