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1.3- Dioxane reactions

No data are available regarding the products of the OH-initiated oxidation of this species. Unlike the symmetric 1,4-dioxane species, there are three unique sites for OH attack on 1,3-dioxane. Reaction at the 2-position will, by analogy to the chemistry of 1,3-dioxolane (figure III-E-8), likely lead to the formation of l,3-dioxan-2-one. Decomposition of the alkoxy radical formed following OH attack at the identical 4- or 6-positions in 1,3-dioxane will lead to the HC(0)0CH20CH2CH20 radical, which may decompose and/or isomerize as outlined below ... [Pg.403]

The lone set of dimers in Table II, [M(C5Me5)2]2(M Pyraz ne) (Fig. 20 M = Ba), were synthesized from the base-free metallocenes by addition of pyrazine to MCp (1 2), analogous to the dioxane reaction for the amide compounds (Fig. 8).103 The pyrazine compounds are intensely colored owing to both charge transfer and intraligand electronic transitions. The pyrazine ligand has been shown to be labile by uv-vis spectroscopy. [Pg.247]

Polymorphic mp 170 and 194 [a] f +125 (dioxane). Reaction with zinc in toluene yields 17 -isodesoxycoitico-sterone acetate. [Pg.1226]

Pyrolysis at 500 -C with P2O5 to form alkenes, acetaldehyde, and 1,4-dioxane Reaction with anhydrides of HOAc and p-toluenesulfonic acid to form alkyl acetates and ethylene glycol diacetate... [Pg.301]

The sulphonic acids are usually prepared by the action of sulphuric acid upon a compound. The concentration of the acid and the temperature of reaction are varied according to the reactivity of the compound. Often oleum is used or even chiorosulphonic acid. Alternatively sulphur trioxide complexed to pyridine or dioxan can be used with reactive substrates. Aminosulphonic acids such as sulphanilic and naphthionic acids are most conveniently prepared by heating the sulphate of the amine at ISO C. [Pg.378]

Dissolve 10 g. of chloro- 2,4-dinitrobenzenet in 50 ml. of dioxan in a 250 ml. conical flask. Dilute 8 ml. of hydrazine hydrate with an equal volume of water and add this slowly with shaking to the dioxan solution, keeping the temperature between zo " and 25°. Heat under reflux for 10 minutes to complete the reaction and then add 5 ml. of ethanol and heat again for 5 minutes. Cool and filter oflF the orange 2,4-dinitrophenylhydra-zine. Recrystallise the dry product from ethyl acetate m.p. 200° (decomp.). Yield, 7 g. [Pg.263]

Hydrogenations with coppcr-chromium oxide catalyst are usually carried out in the liquid phase in stainless steel autoclaves at pressures up to 5000-6000 lb. per square inch. A solvent is not usually necessary for hydrogenation of an ester at 250° since the original ester and the alcohol or glycol produced serve as the reaction medium. However, when dealing with small quantities and also at temperatures below 200° a solvent is desirable this may be methyl alcohol, ethyi alcohol, dioxan or methylcyc/ohexane. [Pg.872]

Another method for the hydroxylation of the etliylenic linkage consists in treatment of the alkene with osmium tetroxide in an inert solvent (ether or dioxan) at room temperature for several days an osmic ester is formed which either precipitates from the reaction mixture or may be isolated by evaporation of the solvent. Hydrolysis of the osmic ester in a reducing medium (in the presence of alkaline formaldehyde or of aqueous-alcoholic sodium sulphite) gives the 1 2-glycol and osmium. The glycol has the cis structure it is probably derived from the cyclic osmic ester ... [Pg.894]

Introduce a solution of 15 g. of the diazo ketone in 100 ml. of dioxan dropwise and with stirring into a mixture of 2 g. of silver oxide (1), 3 g. of sodium thiosulphate and 5 g. of anhydrous sodium carbonate in 200 ml. of water at 50-60°. When the addition is complete, continue the stirring for 1 hour and raise the temperature of the mixture gradually to 90-100°. Cool the reaction mixture, dilute with water and acidify with dilute nitric acid. Filter off the a-naphthylacetic acid which separates and recrys-talhse it from water. The yield is 12 g., m.p. 130°. [Pg.904]

Alternatively, treat a solution of 3 9 g. of the 6is-diazo ketone in 50 ml. of warm dioxan with 15 ml. of 20 per cent, aqueous ammonia and 3 ml. of 10 per cent, aqueous silver nitrate under reflux in a 250 or 500 ml. flask on a water bath. Nitrogen is gently evolved for a few minutes, followed by a violent reaction and the production of a dark brown and opaque mixture. Continue the heating for 30 minutes on the water bath and filter hot the diamide of decane-1 lO dicarboxyhc acid is deposited on cooling. Filter this off and dry the yield is 3 -1 g., m.p. 182-184°, raised to 184-185° after recrystallisation from 25 per cent, aqueous acetic add. Hydrolyse the diamide (1 mol) by refluxing for 2-5 hours with 3N potassium hydroxide (4 mols) acidify and recrystaUise the acid from 20 per cent, acetic acid. The yield of decane-1 10-dicarboxyhc acid, m.p. 127-128°, is almost quantitative. [Pg.905]

The conversion of a carbonyl compound by ammonium polysulphide solution into an amide with the same number of carbon atoms is known as the Willgerodt reaction. The procedure has been improved by the addition of about 40 per cent, of dioxan or of pyridine to increase the mutual solubility of the ketone and aqueous ammonium polysulphide the requisite temperature is lowered to about and the yield is generally better. [Pg.923]

If the compound to be tested is insoluble in water, it should be brought into solution by the addition of a little dioxan. Alcohols and some methyl ketones frequently react slowly in such cases it is advisable to employ a large excess (4-5 fold) of the relatively unstable reagent (3NaOI -> NaI03 -f- 2NaI). Quinones and hydroquinones also give the iodoform reaction. [Pg.1068]

Although no chemical reaction occurs, measurements of the freezing point and infra-red spectra show that nitric acid forms i i molecular complexes with acetic acid , ether and dioxan. In contrast, the infrared spectrum of nitric acid in chloroform and carbon tetrachloride - is very similar to that of nitric acid vapour, showing that in these cases a close association with the solvent does not occur. [Pg.32]

In the flask were placed 60 g of powdered paraformaldehyde, 100 ml of dioxane and 3 g of copper(II) acetate and 0.3 mol of liquid dimethylamine was added at -20 C. The temperature was allowed to rise gradually to 40-45°C with occasional cooling and when the reaction had subsided, the mixture was cooled to 20°C and a second portion of 0.3 mol of the amine was added. When this had reacted, the remainder of the 2.0 mol of dimethylamine was added in the same way. The mixture... [Pg.132]

Chlorination of the azobenzene complex 463 with chlorine produces mono-chloroazobenzene with regeneration of PdCN. Then complex formation takes place again with the chlorinated azobenzene. By this sequence, finally tetra-chloroazobenzene (503) is obtained using a catalytic amount of PdCT. The reaction, carried out by passing chlorine gas into an aqueous dioxane solution of azobenzene and PdCf for 16 h, gives a mixture of polychlorinated azoben-zenes[455]. [Pg.93]

The same regioselective and stereospecific reactions are observed in decalin systems. The 3/3-formate 605 is converted into the a-oriented (j-allylpalladium complex 606, and the hydride transfer generates the fra .s-decalin 607, while the cis junction in 610 is generated from the 3tt-formate 608 by attack of the hydride from the /3-side (609). An active catalyst for the reaction is prepared by mixing Pd(OAc)2 and BU3P in a 1 I ratio with this catalyst the reaction proceeds at room temperature. The reaction proceeded in boiling dioxane when a catalyst prepared from Pd(OAc)2 and BujP in a 1 4 ratio was used[390]. [Pg.373]

PdCb-CuCb catalyzes the condensation of branched-chain alkenes with formaldehyde to give the l,3-dioxanes 96a and 96b (Prins reaction)[73]. The yields are much higher than in the conventional acid-catalyzed Prins reaction. [Pg.524]

A mixture of l-(r-Boc)indol-2-yl-tri- -butylstannanc (1.2 mmol) and 4-bromo-benzonitrile (1.0 mmol) and Pd(PPh3)2C , (0.02 mmol) in dry dioxane (5 ml) was heated at I00°C overnight under nitrogen. The reaction mixture was cooled, diluted with EtOAc and stirred for 15 min with 15% aq. KF. The precipitate was removed by filtration and washed with EtOAc. The EtOAc layer was separated, washed with brine, dried (Na2S04) and concentrated. The residue was purified by chromatography on silica. The yield was 66%. [Pg.100]

This reaction is explosive and proceeds in low yield (—21%) because of the instability of the thioformamide that is destroyed as soon as it is cyclized with 1 (113,491). The thioformamide is better prepared directly in the reaction mixture by condensing phosphorus pentasulfide and for-mamide at room temperature, in dioxane solution, according to reaction 1 (491,492),... [Pg.171]

The reaction can be carried out in two steps (641). First, equimolar amounts of amide and phosphorus pentasulfide are mixed under stirring in dioxane, the temperature being kept below 45°C. After 20 minutes, the a-halocarbonyl compounds (in dioxane solution) are added in small portions. At the end of the addition the temperature reaches 80 to 100°C, and the reaction mixture is kept at this temperature for another hour. [Pg.191]

Iminothiobutyramide (30), containing four nucleophilic centers (only two of which might react with two electrophilic sites in phenacylbromide), undergoes the Hantzsch reaction preferentially, yielding the enamine (31) in dry dioxane or (4-phenylthiazol-2-yl)acetone (32) in isopropanol. Other enamines are obtainable from the ketone (32) by standard methods (626) (Scheme 15). [Pg.191]

A reaction carried out by Haruki et al. is the energic oxidation of 5-(l-hydroxyethyl)2-phenylthiazole (5) in dioxane by aqueous Kl-iodine to give 2-phenyl-5-thiazolecarboxylic acid (6) (Scheme 2) (28). [Pg.521]


See other pages where 1.3- Dioxane reactions is mentioned: [Pg.212]    [Pg.317]    [Pg.191]    [Pg.801]    [Pg.212]    [Pg.336]    [Pg.107]    [Pg.95]    [Pg.213]    [Pg.177]    [Pg.248]    [Pg.442]    [Pg.510]    [Pg.639]    [Pg.810]    [Pg.872]    [Pg.222]    [Pg.227]    [Pg.337]    [Pg.81]    [Pg.78]    [Pg.174]    [Pg.180]    [Pg.184]    [Pg.535]   
See also in sourсe #XX -- [ Pg.384 ]




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1.3- Dioxan-5-ones, aldol reactions

1.3- Dioxanes Lewis acid promoted reactions

1.3- Dioxanes Prins reaction

1.3- Dioxanes reactions, review

Chiral dioxane acetals reaction

Dichlorogermylene-dioxane complex reactions

Dioxane Grignard reactions in the

Dioxane forming reaction

Dioxanes Diels-Alder reactions

Prins reaction yields 1,3-dioxanes

Reaction with dihydro-1,4-dioxane

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