Acetylene terminal

The proton of terminal acetylenes is acidic (pKa= 25), thus they can be deprotonated to give acetylide anions which can undergo substitution reactions with alkyl halides, carbonyls, epoxides, etc. to give other acetylenes. 

Insertion reaction of a vinyl carbene (terminal acetylenes)... 

Deprotonation of terminal acetylenes by organolithiurn compounds in organic solvents or by alkali metal amides is an extremely fast reaction, even at very... 

Iodoallenes can also be prepared in reasonable yields by treatment of secondary acetylenic alcohols with triphenylphosphite-methyl iodide, using DMF as a solvent. One of the -OPh groups is probably first replaced by the propargyloxy group. This intermediate subsequently undergoes attack by iodide on the terminal acetylenic carbon atom, affording the iodoallene in a 1,3-substitution ... 

Alkynyl anions are more stable = 22) than the more saturated alkyl or alkenyl anions (p/Tj = 40-45). They may be obtained directly from terminal acetylenes by treatment with strong base, e.g. sodium amide (pA, of NH 35). Frequently magnesium acetylides are made in proton-metal exchange reactions with more reactive Grignard reagents. Copper and mercury acetylides are formed directly from the corresponding metal acetates and acetylenes under neutral conditions (G.E. Coates, 1977 R.P. Houghton, 1979). 

Primary dialkylboranes react readily with most alkenes at ambient temperatures and dihydroborate terminal acetylenes. However, these unhindered dialkylboranes exist in equiUbtium with mono- and ttialkylboranes and cannot be prepared in a state of high purity by the reaction of two equivalents of an alkene with borane (35—38). Nevertheless, such mixtures can be used for hydroboration if the products are acceptable for further transformations or can be separated (90). When pure primary dialkylboranes are required they are best prepared by the reduction of dialkylhalogenoboranes with metal hydrides (91—93). To avoid redistribution they must be used immediately or be stabilized as amine complexes or converted into dialkylborohydtides. 

Potassium 3-aniinopropylaniide [56038-00-7] (KAPA), KNHCH2CH2CH2-NH2, pX = 35, can be prepared by the reaction of 1,3-diaminopropane and potassium metal or potassium hydride [7693-26-7] (57—59). KAPA powder has been known to explode during storage under nitrogen in a drybox, and is therefore made in situ. KAPA is extremely effective in converting an internal acetylene or aHene group to a terminal acetylene (60) (see Acetylene-DERIVED chemicals). 

Thalllum(III) Compounds. Tb allium (ITT) derivatives have been used extensively as oxidants in organic synthesis. In particular, thaUic acetate and ttifluoroacetate are extremely effective as electrophiles in oxythaHation and thaHation reactions. For example, ketones can be prepared from terminal acetylenes by means of (OOCCH ) in acetic acid (oxythaHation) (30) ... 

The metallocycle [67719-69-1] (24) undergoes an apparent P-elimination to a carbene-like reagent, which adds regiospecrfically to terminal acetylenes... 

Methyl ketones are important intermediates for the synthesis of methyl alkyl carbinols, annulation reagents, and cyclic compounds. A common synthetic method for the preparation of methyl ketones is the alkylation of acetone derivatives, but the method suffers limitations such as low yields and lack of regioselectivity. Preparation of methyl ketones from olefins and acetylenes using mercury compounds is a better method. For example, hydration of terminal acetylenes using HgSO gives methyl ketones cleanly. Oxymercuration of 1-olefins and subsequent oxidation with chromic oxide is... 

The polar tellurium(II)-nitrogen bond is readily susceptible to protolysis by weakly acidic reagents. Eor example, the reaction of [Te(NMe2)2]oo with two equivalents of Ph3CSH produces the monomeric thiolato derivative Te(SCPh3)2. Alkynyl tellurides may be prepared by the reaction of terminal acetylenes with arenetellurenamides (Eq. 10.13). ... 

Nonactivated terminal acetylenes have been added to enamines derived from aldehydes. A long reaction time or catalysis by copper(I) chloride is necessary. Thus the enamine (16) formed the adduct (72) on heating with phenylacetylene (64). 

Dipolar additions of diazomethane to acetylenes under mild conditions are restricted to monosubstituted acetylenes thus the formation of pyrazole derivatives 1 (1,3-dipolar addition, C=C isomerization, then methylation) confirms the existence of a terminal acetylene in caryoynencins (87TL3981) (Scheme 5). 

C. Cross-Coupling of Halogenopyrazoles with Terminal Acetylenes and Their Copper(I) Salts (Tables X to XV)... 

It should be noted that these were the first examples of the Cu-catalyzed crosscoupling of arylhalides with terminal acetylenes. The authors (71IZV1764) carried out the acetylenic condensation with unreactive 4-iodo-l,3,5-trimethylpyrazole, a compound in which the halogen atom is not only found in a position more unfavorable for replacement, but is also further deactivated by the introduction of electron-donor methyl groups (Scheme 40). 

Similarly, the limitations and peculiarities of the cross-coupling of pyrazolyl-halides with terminal acetylenes have been fully and systematically studied by Russian chemists (86TH1 97TH1). 

A similar phenomenon was observed for 3-amino- and5-amino-4-iodopyrazoles. The anomalous reaction in which the products of oxidative coupling of terminal acetylenes (up to 90%) are present along with the products of deiodination (up to 90%) has been described for the first time [99JCS(P1 )3713] and will be considered below in the part related to cross-coupling of 4-iodopyrazoles. 

The reaction time between 4-iodopyrazoles and 1-alkynes varies from 5 to 25 h and the yield of products is 55-95%. It is noteworthy that the nature of the terminal acetylene has a greater effect on the rate of halogen atom substitution for low-reactive 4-iodopyrazoles. Thus, the reaction time for ethynylarenes is 5-6 h, and for less acidic aliphatic 1-alkynes is 10-25 h (Table XTT). 

The same type of reactions includes the Chodkiewicz-Cadiot reaction, i.e., a coupling of terminal acetylenes with bromoacetylenes, which is performed in... 

By the chlorination of 3-ethynyl-, 4-ethynyl-, and 5-ethynyl-l-methylpyrazole with KOCl the corresponding compounds were synthesized in 98%, 100%, and 94% yields. The typical procedure is as follows To an aqueous solution of KOX (0.64 N) in 12.5% KOH, prepared from the corresponding halogen and potassium hydroxide in water at 5-10°C, was added the terminal acetylene, followed by stirring at room temperature until the complete disappearance of the starting material. 

The comparatively high acidity of terminal acetylenes allows the alkylation (without isolation of an intermediate acetylide) of even the less active ethynyl... 

Terminal acetylenes can be obtained from the corresponding propylcarboxylic acids by thermal decomposition. Thus, l-methyl-3-ethynyl- and 2-methyl-3-ethynylindazole were obtained by thermolysis of indazolylpropiolic acids at 150-160°C. Yields of ethynyl derivatives were 65 and 60%, respectively (75KGS1678) (Scheme 100 Table XXIII). 

The thermodynamic CH acidity of terminal acetylenes in the series of A-alkylpyrazoles was studied (83IZV466). These equilibrium CH acidity measurements were performed in DMSO by the method of remetallation (75ZOB1529). It reveals some regularities concerning the influence of the ring structure, the nature of other substituents, and the position of the ethynyl group on the acidity of ethynyl pyr azoles. 

Unsaturated substituents of dioxolanes 36-38 and dioxanes 39-41 are prone to prototropic isomerization under the reaction conditions. According to IR spectroscopy, the isomer ratio in the reaction mixture depends on the temperature and duration of the experiment. However, in all cases, isomers with terminal acetylenic (36, 39) or allenic (37, 40) groups prevail. An attempt to displace the equilibrium toward the formation of disubstituted acetylene 41 by carrying out the reaction at a higher temperature (140°C) was unsuccessful From the reaction mixture, the diacetal of acetoacetaldehyde 42, formed via addition of propane-1,3-diol to unsaturated substituents of 1,3-dioxanes 39-41, was isolated (74ZOR953). 

Diacetylene homologs are involved in this reaction by terminal acetylene bond to form monoadducts 5-alkynylpyrazoles 82 (65ZOR610). 

The addition of benzyl azide to monosubstituted diacetylenes initially proceeds at the terminal acetylene bond to form two regioisomeric 4- and 5-ethynyl-1,2,3-triazoles 98 and 99 along with minor amounts of the corresponding diadducts (81ZOR741 82ZOR1619). 

Since l-heterobut-l-en-3-ynes are readily alkylated and functionalized at the terminal acetylenic carbon atom, their reaction with hydrazines makes it possible to introduce diverse (including functional) substituents into the pyrazole ring. For instance, from benzylated methoxybutenyne 112, isomeric 2-phenylethylpyrazoles 113 were obtained in 74% yield (81H146). 

The palladium-catalyzed reaction of o-iodoanilides with terminal acetylenic carbinols provides a facile route to the synthesis of quinolines using readily available starting materials (93TL1625). When o-iodoanilide 126 was stirred with acetylenic carbinol 127 in the presence of bis-triphenyl phosphine palladium(ll) chloride in triethylamine at room temperature for 24 h, the substituted alkynol 128 was obtained in 65% yield. On cyclization of 128 with sodium ethoxide in ethanol, 2-substituted quinoline 129 was obtained in excellent yield. 

Although a number of reagents can be used to reduce an isoxazole ring, molybdenum hexacarbonyl31 was selected for use in this synthesis. The action of this reagent on 24 reduces the weak N-0 bond of the isoxazole ring and produces a //-amino-a,//-unsaturated aldehyde (i.e. a vinylogous formamide) (see Scheme 19). Intermediate 87 forms smoothly upon deprotection of the terminal acetylene carbon with basic methanol-THF. 

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