Nitriles acetylenes

Af-Unsubstituted pyrazoles and indazoles add to compounds containing activated double and triple bonds (67HC 22)1,B-76MI40402>. Amongst C—C double and triple bonds, maleic anhydride, acrylic acid esters and nitriles, acetylene-carboxylic and -dicarboxylic esters (78AHC(23)263), quinones, and some a,/3-unsaturated ketones have been used with success. Phenylacetylene reacts with pyrazole in the presence of Na/HMPT as catalyst to yield the Z isomer of 1-styrylpyrazole in a highly stereoselective reaction (78JHC1543). 

With a,j -acetylenic nitriles, acetylenic organomagnesium compounds produce only the ketones resulting from 1,2-addition [4], Recently, the 1,4-addition of RMgX (R = saturated, vinylic, or allylic groups) and other organometallics to the conjugated structure of a-ethylidene-(Z)-1//-indole-2-acetonitrile has been observed [38] ... 

We at NASA reopened the question of learning to chain extend these fluoroether systems In consort with scientists at PCR Inc. The objective was to prepare long-chain difunctional polyperfluoroethers and investigate chain extension mechanisms, as well as to convert these materials to stable cross-linked polymers for sealant applications. The nitrile, acetylene, and isocyanate groups were considered. Each of these is capable of both trimerization reactions and dipolar cycloadditions. From this base line, one could then evoke both chain extension and cross-linking with a variety of reaction schemes. 

In the first method a secondary acetylenic bromide is warmed in THF with an equivalent amount of copper(I) cyanide. We found that a small amount of anhydrous lithium bromide is necessary to effect solubilization of the copper cyanide. Primary acetylenic bromides, RCECCH Br, under these conditions afford mainly the acetylenic nitriles, RCsCCHjCsN (see Chapter VIII). The aqueous procedure for the allenic nitriles is more attractive, in our opinion, because only a catalytic amount of copper cyanide is required the reaction of the acetylenic bromide with the KClV.CuCN complex is faster than the reaction with KCN. Excellent yields of allenic nitriles can be obtained if the potassium cyanide is added at a moderate rate during the reaction. Excess of KCN has to be avoided, as it causes resinifi-cation of the allenic nitrile. In the case of propargyl bromide 1,1-substitution may also occur, but the propargyl cyanide immediately isomerizes under the influence of the potassium cyanide. 

Perhaps the most firmly based report for the formation of an azete involves flash pyrolysis of tris(dimethylamino)triazine (303). This gave a red pyrolysate believed to contain the highly stabilized azete (304) on the basis of spectroscopic data. The putative azete decomposed only slowly at room temperature, but all attempts to trap it failed (73AG(E)847). Flash pyrolysis of other 1,2,3-triazines gives only acetylenes and nitriles and it is not possible to tell whether these are formed by direct <,2-l-<,2-l-<,2 fragmentation of the triazine or by prior extrusion of nitrogen and collapse to an azete (81JCR(S)162). 

Hydrazoic acid Hydrides, volatile Hydrogen cyanide (unstabilized) Hydrogen (low pressure) Hydrogen peroxide (> 35% water) Magnesium peroxide Mercurous azide Methyl acetylene Methyl lactate Nickel hypophosphite Nitriles > ethyl Nitrogen bromide... 

Nickel peroxide is a solid, insoluble oxidant prepared by reaction of nickel (II) salts with hypochlorite or ozone in aqueous alkaline solution. This reagent when used in nonpolar medium is similar to, but more reactive than, activated manganese dioxide in selectively oxidizing allylic or acetylenic alcohols. It also reacts rapidly with amines, phenols, hydrazones and sulfides so that selective oxidation of allylic alcohols in the presence of these functionalities may not be possible. In basic media the oxidizing power of nickel peroxide is increased and saturated primary alcohols can be oxidized directly to carboxylic acids. In the presence of ammonia at —20°, primary allylic alcohols give amides while at elevated temperatures nitriles are formed. At elevated temperatures efficient cleavage of a-glycols, a-ketols... 

From the two possible intermediates (a vinylacetylene, or a -chlorovinyl ketone as in Section II,C, 2,c) the latter would appear more probable the addition of benzojd chloride to phenylacetylene yielding 3-ehloro-3-phenylacrylophenone (/S-chlorochalcone) is not reported in the literature, however. Replacing the acetylene by Schiff bases or nitriles, azapyrylium or diazapyrylium can be obtained. 

Tile following photochemical conversions also involve 1,2-dithietes as intermediates whose chemical trapping was reported in most cases. Tlie formation of the dithiin 249 from 250 may best be explained by the formation of the dithiete dimer 251 and the loss of S2 (73ZC424).Tlie formation of 252 and 253 from 254 (78NJC331) should be compared with the sulfuration of the acetylene 182 with elemental sulfur (93BCJ623).Tlie photolysis of 255 provides a rare example when the ejection of a nitrile was employed for the generation of a 1,2-dithiete (73ZC431). 

As shown by the Italian school, the formation of isoxazole derivatives by the action of nitric acid or nitrogen oxides on acetylene derivatives and related reactions proceeds through intermediate nitrile oxides and must, therefore, be included with this type of synthesis. 

The experimental conditions for the syntheses starting from acid chlorides of hydroxamic acids and from nitrile oxides are somewhat different. In the former case the other component of the reaction is organometallic, usually an organomagnesium derivative of an acetylene or, less frequently, a sodium enolate of a /8-diketone. Nitrile oxides condense directly with unsaturated compounds. 

The general synthetic scheme starting from nitrile oxides, which condense with acetylenes to yield isoxazoles and with olefins to yield A -isoxazoIines may be represented by Eqs. (1) and (2). The forma-... 

This procedure, which involves the addition of an anion derived from a nitrile to an unactivated acetylenic bond under rather mild conditions, is a convenient general method for the synthesis of a-vinyl-nitriles (see Table I). The reaction proceeds smoothly in either dimethyl sulfoxide or hexamethylphosphoric triamide (see p. 103 for warning) as solvent with a tetraalkylam monium salt as catalyst. The products thus prepared are obtained in yields higher2 than those obtained under conventional conditions, which generally require higher temperatures and elevated pressures.3-4... 

There is generally little or no competition from 1,2 addition (to the C=0). However, when R is allylic,l,4 addition is observed with some substrates and 1,2 addition with others. The compound R2CuLi also add to a,P-unsaturated sulfones but not to simple aP-unsaturated nitriles. Organocopper reagents RCu (as well as certain R2CuLi) add to ocP-unsaturated and acetylenic sulfoxides. ... 

In a related reaction, heating ketones in the presence of TlClsOTf leads to 1,3,5-trisubstituted arenes. " Nitriles react with 2 mol of acetylene, in the presence of a cobalt catalyst, to give 2-substituted pyridines. " Triketones fix nitrogen gas in the presence of TiCU and lithium metal to form bicyclic pyrrole derivatives. " ... 

Dipole moments of substituted nitriles were correlated with the a constants by Taft and with the Op constants by Charton (18). In addition to dipole moment data, some information is available on the C=N stretching frequencies of substituted nitriles. The sets studied are reported in Table XXXVI. Results of the correlations with eq. (2) are given in Table XXXVII, and values of Pr are set forth in Table XXXVIII. The correlation of the dipole moments of substituted nitriles with eq. (2) gave significant results, which were very much improved by the exclusion of the value for X=I (set 36-1-2). In contrast to the results obtained for substituted ethylenes, acetylenes, and benzenes, the value of /3 obtained for dipole moments of substituted nitriles is not significant. The value of a obtained for the substituted nitriles is comparable to the value of a observed for the substituted acetylenes. 

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