Amides, alkynic

Geminal dihalide Sodium amide Alkyne Ammonia... 

The electrophile for the cyclization reaction of an a-amino-organolithium compound is not restricted to a terminal (or phenylthio-substituted) ahcene and examples have been reported using carboxylic amides, alkynes and allyhc ethers." " For example, Fautens and Kumanovic reported that treatment of the bicyclic stannane shown in Scheme 24... 

Reduction of CO and ketones Hydro formylation Fischer-Tropsch synthesis Synthesis of methanol from CO Hydrogenation of amides Alkyne cyclization Hydroxymethylation... 

Covalent Poly(N-isoptopylacryl amide) [alkyne, azide], poly (glycidyl methacrylate) [ring-opening], polyallylamine [imine formation] Poly(L-glutamic acid) [alkyne, azide], poly (L-lysine) [carbodiimide chemistry] Dextran [alkyne, azide], alginate [imine formation]... 

CO. Alkynes will react with carbon monoxide in the presence of a metal carbonyl (e.g. Ni(CO)4) and water to give prop>enoic acids (R-CH = CH-C02H), with alcohols (R OH) to give propenoic esters, RCH CHC02R and with amines (R NH2) to give propenoic amides RCHrCHCONHR. Using alternative catalysts, e.g. Fe(CO)5, alkynes and carbon monoxide will produce cyclopentadienones or hydroquinols. A commercially important variation of this reaction is hydroformyiation (the 0x0 reaction ). 

Terminal alkynes are only reduced in the presence of proton donors, e.g. ammonium sulfate, because the acetylide anion does not take up further electrons. If, however, an internal C—C triple bond is to be hydrogenated without any reduction of terminal, it is advisable to add sodium amide to the alkyne solution Hrst. On catalytic hydrogenation the less hindered triple bonds are reduced first (N.A. Dobson, 1955, 1961). 

Solutions of sodium acetylide (HC=CNa) may be prepared by adding sodium amide (NaNH2) to acetylene m liquid ammonia as the solvent Terminal alkynes react similarly to give species of the type RC=CNa... 

The most frequent applications of these procedures he in the preparation of terminal alkynes Because the terminal alkyne product is acidic enough to transfer a proton to amide anion one equivalent of base m addition to the two equivalents required for dou ble dehydrohalogenation is needed Adding water or acid after the reaction is complete converts the sodium salt to the corresponding alkyne... 

Alkyne Sodium Ammonia Trans alkene Sodium amide ... 

Acetylene and terminal alkynes are more acidic than other hydrocarbons They have s of approximately 26 compared with about 45 for alkenes and about 60 for alkanes Sodium amide is a strong enough base to remove a proton from acetylene or a terminal alkyne but sodium hydroxide is not... 

The acidity of acetylene and terminal alkynes permits them to be converted to their conjugate bases on treatment with sodium amide These anions are good nucleophiles and react with methyl and primary alkyl halides to form carbon-carbon bonds Secondary and tertiary alkyl halides cannot be used because they yield only elimination products under these conditions... 

Double dehydrohalogenation of gemmal dihalides (Section 9 7) An E2 elimination reaction of a gemmal dihalide yields an alkenyl halide If a strong enough base IS used sodium amide for example a second elimination step follows the first and the alkenyl halide IS converted to an alkyne... 

The first organometallic compounds we encountered were compounds of the type RC=CNa obtained by treatment of terminal alkynes with sodium amide m liquid ammo nia (Section 9 6)... 

Double dehydrohalogenation (Section 9 7) Reaction in which a geminal dihahde or vicinal dihahde on being treated with a very strong base such as sodium amide is converted to an alkyne by loss of two protons and the two halogen substituents... 

Alkylarylisoxazoles can be obtained from the cycloaddition of nitrile Af-oxides to substituted alkynes or alkenes (Section 4.16.4.1.2(ii)), and from the condensation of the 1,4-dilithio oximes (358) with benzonitriles (72JHC183) or amides (78JOC3015). 

Generalized methods of preparation include the reaction of /3-keto esters (or amides) with hydroxylamine, a-alkynic and a,/3-unsaturated esters (or amides) with hydroxylamine (real or generated in situ), hydroxylamine and nitrile oxides, and /3-keto and a-alkynic nitriles with hydroxylamine (62HC(l7)l, pp. 3,7). 

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