Acetylide anion alkynyl

The acetylide anion 3 is likely to form an alkynyl-copper complex by reaction with the cupric salt. By electron transfer the copper-II ion is reduced, while the acetylenic ligands dimerize to yield the -acetylene 2 ... 

Terminal alkynes contain an acidic proton, which can be deprotonated by sodium amide (NaNH2). The negative charge of the alkynyl (or acetylide) anion resides in an sp-orbital. This is more stable than a vinyl anion (produced on deprotonation of an alkene), because these are sp2 hybridised. The greater the s character, the more closely the anion is held to the positively charged nucleus (which stabilises it). 

Alkynyl complexes contain metal-carbon bonds in which the metal is bound to the sp-hybridized carbon at the terminus of a metal-carbon triple bond. The materials properties of these complexes have been investigated extensively. The properties of these complexes include luminescence, optical nonlinearity, electrical conductivity, and liquid crystallinity. These properties derive largely from the extensive overlap of the metal orbitals with the ir-orbitals on the alkynyl ligand. The M-C bonds in alkynyl complexes appear to be considerably stronger than those in methyl, phenyl, or vinyl complexes. Alkynyl complexes are sometimes prepared from acetylide anions generated from terminal alkynes and lithium bases (e.g., method A in Equation 3.42), but the acidity of alkynyl C-H bonds, particularly after coordination of the alkyne to the transition metal, makes it possible to form alkynyl complexes from alkynes and relatively weak bases (e.g., method B in Equation 3.42). Alkynyl copper complexes are easily prepared and often used to make alkynylnickel, -palladium, or -platinum complexes by transmetallation (Equation 3.43). This reaction is a step in the preparation of Ni, Pd, or Pt alkynyl complexes from an alkyne, base, and a catalytic amoimt of Cul (Equation 3.44). This protocol for... 

In the synthesis of propargylic alcohols, we saw the reaction of an alkynyl nucleophile (either the anion RC=CNa or the Grignard RC CMgBr, both prepared from the alkyne RC CH) with a carbonyl electrophile to give an alcohol product. Such acetylide-type nucleophiles will undergo Sn2 reactions with alkyl halides to give more substituted alkyne products. With this two-step sequence (deprotonation followed by alkylation), acetylene can be converted to a terminal alkyne, and a terminal alkyne can be converted to an internal alkyne. Because acetylide anions are strong bases, the alkyl halide used must be methyl or 1° otherwise, the E2 elimination is favored over the Sn2 substitution mechanism. 

We described the alkynylation of the carbonyl group with the acetylide anion in Sect. 2.2. Before the initial retrosynthetic step from TM 5.5, let us consider the mechanism of hydration of the triple bond activated by Hg(ll) ions (Scheme 5.13). 

ALkynylation of the cyclopentanone derivative by the acetylide anion leads to carbinol. Hg(II)-catalyzed hydration in the next step affords a-hydroxy ketone, which in the last step is methylated by the Grignard reagent, completing the short... 

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). 

The tantalum(V) calix[4]arene complex 44 provides an interesting scaffold for the construction of an j -PhC2C=CPh ligand upon reaction with an excess of phenylethynyllithium (Scheme 10). The coupling reaction is presumed to proceed via bis-alkynyl 45, which is subsequently attacked at the a-carbon of one of the acetylide ligands to give anion 46, isolated as its lithium salt. The addition of a further equivalent of LiC CPh is probably prohibited by orbital constraints. ... 

The alkyne insertion reaction is terminated by anion capture. As examples of the termination by the anion capture, the alkenylpalladium intermediate 189, formed by the intramolecular insertion of 188, is terminated by hydrogenolysis with formic acid to give the terminal alkene 192. Palladium formate 190 is formed, and decarboxylated to give the hydridopalladium 191, reductive elimination of which gives the alkene 192 [81]. Similarly the intramolecular insertion of 193 is terminated by transmetallation of 194 with the tin acetylide 195 (or alkynyl anion capture) to give the dienyne 196 [82], Various heterocyclic compounds are prepared by heteroannulation using aryl iodides 68 and 69, and internal alkynes. Although the mechanism is not clear, alkenylpalladiums, formed by insertion of alkynes, are trapped by nucleophiles... 

Direct bridgehead alkynylation of 1-iodoadamantane has been achieved by treatment with a variety of silver acetylides at reflux in IV-methylmorpholine.114 The methodology has been extended to the direct bridgehead substitution of methyl-bicyclo[2.2.2]octane and a carborate anion (Scheme 1.50).115... 

As with cyanide, Sn2 reactions of alkyne anions can be done with substrates other than halides or sulfonate esters. Epoxides are opened by acetylides at the less sterically hindered carbon to give an alkynyl alcohol. A synthetic example is the reaction of epoxide 38 with the indicated lithium alkyne anion gave an 85% yield of 39, an intermediate in the Sinha et al. synthesis of squamotacin.49... 

The other major synthetic use of alkyne anions is their reaction with ketones and aldehydes to give an alkynyl alcohol via nucleophilic acyl addition. The lithium salt of 1-propyne, for example, reacted with aldehyde 40 to give alcohol 41 as part of Smith s synthesis of (+)-acutiphycin.50 The reaction is selective for ketones and aldehydes in the presence of acid derivatives, if the acetylide is not present in large excess. l... 

Alkynyl(phenyl)iodonium salts have found synthetic application for the preparation of various substituted alkynes by the reaction with appropriate nucleophiles, such as enolate anions [980,981], selenide and telluride anions [982-984], dialkylphosphonate anions [985], benzotriazolate anion [986], imidazolate anion [987], N-functionalized amide anions [988-990] and transition metal complexes [991-993]. Scheme 3.291 shows several representative reactions the preparation of Ai-alkynyl carbamates 733 by alkynylation of carbamates 732 using alkynyliodonium triflates 731 [989], synthesis of ynamides 735 by the alkyny-lation/desilylation of tosylanilides 734 using trimethylsilylethynyl(phenyl)iodonium triflate [990] and the preparation of Ir(III) a-acetylide complex 737 by the alkynylation of Vaska s complex 736 [991]. 

Propargylic alcohols are available by methods which avoid the use of relatively basic acetyllde anions. Brown has used -1-alkynyl-9-BBN compounds as acetylide equivalents and found that... 

Electrophilic attack on the 3-carbon of alkynyl ligands (Equation 12.50) is common and is a route to vinylidene complexes introduced in Chapter 3. Examples of protonation and electrophilic alkylation of an anionic acetylide complex at the 3-carbon are shown in Equation 12.51. Attack of two protons on an anionic carbyne complex generates a new carbyne complex, as shown in Equation 12.52. ° This reaction, presumably, occurs by initial formation of a vinylidene complex. 

Differences between cyanide and acetylide complexes arise from the instability of the acetylide ligand to hydrolysis. The alkynyl anions are strong bases, and anhydrous solvents such as liquid ammonia must be used in the preparation of many of their complexes. Metal thiocyanates,... 

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