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Terminal alkynes general

Highly Lewis basic and nucleophilic functional groups are not compatible with zinc carbenoids. The methylation or ylide formation of heteroatoms is one of the most important side reactions of these reagents. For example, amines, thioethers and phosphines readily react with the zinc reagents to generate ammonium salts", sulfonium" and phosphonium ylides" ". Terminal alkynes generally lead to a large number of by-products". ... [Pg.256]

In contrast to the reaction of alkenes, the addition of H—SR reagents to alkynes generally requires higher temperatures and the presence of a base.534 Terminal alkynes generally react to give anti-Markov-nikov products. Substituted alkynes, however, will provide terminal alkenes if the reaction is carried out in sodium and liquid ammonia (equation 305).554 Polyynes react with H2S to produce thiophenes (equation 306).555... [Pg.317]

Ruthenium complexes are known to be generally less reactive in hydrosilylation reactions when compared with platinum and rhodium ones. However, very selective ruthenium-based catalytic systems have been recently developed. The hydrosilylation of terminal alkynes generally tends to proceed through cis addition, resulting in trans adducts as the main products. [Pg.203]

Silylformylation of terminal alkynes generally occurs under relatively mild conditions to afford a silylolefm. The major side product of this reaction is hydrosilylation. The use of more reactive organosilanes or an increase in the carbon monoxide pressure has been shown to enhance silylformylation. Furthermore, Doyle and Shankin demonstrated that a dirhodium complex can be used to overcome this synthetic problem. Dirhodium(II) perfluorobut3n ate has been shown to give exclusively silylcarbonylation when used with phenylacetylene 70 favoring the cis product with Z E ratios as high as 40 1 (71a and 71b). Additional success with... [Pg.160]

The Addition of CFy Toward Alkynes and Alkenes The radical addition of Cp3. toward terminal alkynes generally proceeds in a highly regioselective manner to give the corresponding vinyl radical 22- cis or 22-... [Pg.780]

Alkynes, like alkenes, can be cleaved by reaction with powerful oxidizing agents such as ozone or KMnC, although the reaction is of little value and we mention it only for completeness. A triple bond is generally less reactive than a double bond and yields of cleavage products are sometimes low. The products obtained from cleavage of an internal alkyne are carboxylic acids from a terminal alkyne, CO2 is formed as one product. [Pg.270]

Because of its generality, acetylide alkylation is an excellent method for preparing substituted alkynes from simpler precursors. A terminal alkyne can be prepared by alkylation of acet dene itself, and an internal alkyne can be prepared by further alkylation of a terminal alkyne. [Pg.273]

In general, strong bases such as NaNH2 convert internal alkynes to terminal alkynes [a particularly good base for this purpose is potassium 3-aminopropyIamide (NH2CH2CH2CH2NHK) ], because the equilibrium is shifted by formation of the... [Pg.771]

The hydration of triple bonds is generally carried out with mercuric ion salts (often the sulfate or acetate) as catalysts. Mercuric oxide in the presence of an acid is also a common reagent. Since the addition follows Markovnikov s rule, only acetylene gives an aldehyde. All other triple-bond compounds give ketones (for a method of reversing the orientation for terminal alkynes, see 15-16). With allqmes of the form RC=CH methyl ketones are formed almost exclusively, but with RC=CR both possible products are usually obtained. The reaction can be conveniently carried out with a catalyst prepared by impregnating mercuric oxide onto Nafion-H (a superacidic perfluorinated resinsulfonic acid). ... [Pg.995]

Because of the slightly acidic nature of the sp C-H bonds, the reaction of metal acetylides with various electrophiles is one of the most general strategies in organic transformations.1 Traditionally, such reactions are carried out by using alkali metal acetylides which are air and water sensitive. On the other hand, there is much interest in developing transition-metal catalyzed terminal alkyne reactions involving soft and more stable C-M bonds as reaction intermediates, because many such reactions can tolerate water. [Pg.96]

Generally, organocopper compounds can be prepared by transmetallation between copper salts and organometallic reagents such as RLi, RMgX, and RZnX.53,53a,53b Copper alkynides can be obtained by reaction of terminal alkynes... [Pg.551]

Cleavage of Zr—C a bonds occurs readily on treatment with H20 or dilute acids, while the Zr—Cp bond usually survives mild protonolysis conditions. The use of D20 or DC1/D20 permits the replacement of Zr with D. Deuterolysis provides a generally reliable method for establishing the presence of Zr—C bonds. Protonolysis or deuterolysis of Zr—Csp bonds proceeds with retention of configuration [97]. In the hydrozirconation of terminal alkynes, deuterium can be introduced at any of the three positions in the vinyl group in a completely regio- and stereoselective manner, as shown in Scheme 1.18. Although relatively little is known about the mechanistic details, the experimental results appear to be consistent with concerted c-bond metathesis (Pattern 13) between C—Zr and H— X bonds. [Pg.15]

As would be expected, catalytic hydroboration is effective for alkynes as well as al-kenes, and prior examples have been reviewed [6]. An interesting development has been the diversion of the normal syn- to the anti-addition pathway for a terminal alkyne, with 99% (catechoborane) and 91% (pinacolborane) respectively (Fig. 2.5) [20]. The new pathway arises when basic alkylphosphines are employed in combination with [Rh(COD)Cl]2 as the catalyst in the presence of Et3N. Current thinking implies that this is driven by the initial addition of the rhodium catalyst into the alkynyl C-H bond, followed by [1,3]-migration of hydride and formal 1,1-addition of B-H to the resulting alkylidene complex. The reaction is general for terminal alkynes. [Pg.37]

The formation of vinylcarbamates is restricted to secondary amines and also to terminal alkynes, which is in line with the formation of a metal vinylidene intermediate. It is noteworthy that even starting from secondary amines, the presence of a hydroxy group in propargylic alcohols drove the reaction towards the formation of fi-keto carbamates, resulting from initial Markovnikov addition of the carbamate anion to the triple bond followed by intramolecular transesterification [10]. The proposed general catalytic cycle which applies for the formation of vinylic carbamates is shown in Scheme 10.2. [Pg.314]

The content of this book gathers in the same volume all aspects of vinylidene- and allenylidene-metal complexes, including the preparation of these organometallic carbon-rich systems with a metal-carbon double bond, their stoichiometric reactivity and theoretical aspects, and their applications in catalysis for the production of fine chemicals, mainly in the field of selective transformations of functional terminal alkynes. It provides essential general information on catalytic transformations of alkynes and their use in synthesis. [Pg.355]

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See also in sourсe #XX -- [ Pg.44 ]



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Terminal alkynes

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