Metal mediated coupling with alkynes

Cp Rh(MeCN)(/r-CH2)]2 +, both methylene units couple with two alkyne molecules see Organic Synthesis Using Metal-mediated Coupling Reactions) to form (146). ... 

A considerable number of reactions of CpRh(/x-CO)(/x- ) ) -F3CC=CCF3)RhCp have been reported which illustrates the diversity of products that can be obtained in transition metal alkyne chemistry see Organic Synthesis Using Metal-mediated Coupling Reactions). Reaction of this complex with dimethyldiazomethane forms a mixtme of (147) and (148), and on recrystallization (148) converts to (149) by... 

The inter- and intramolecular catalytic reductive couplings of alkynes and aldehydes recently have experienced rapid growth and are the topic of several recent reviews.5 h-8k 107 With respect to early transition metal catalysts, there exists a single example of the catalytic reductive cyclization of an acetylenic aldehyde, which involves the titanocene-catalyzed conversion of 77a to ethylidene cyclopentane 77b mediated by (EtO)3SiH.80 This process is restricted to terminally substituted alkyne partners (Scheme 53). 

Transition metal mediated or catalyzed benzene formation reactions have been reported using various metals. However, the use of three different alkynes is difficult [38], In many cases, a mixture of several benzene derivatives is obtained. In 1974, Wakatsuki and Yamazaki used three different alkynes with Co complexes [27b], but isomers were formed and a tedious chromatographic separation was necessary. The first selective coupling of three different alkynes in high yields was reported in 1995 using a combination of unsymmetrical zirconacydopentadienes and CuCl, as shown in Eq. 2.52 [7k]. 

The method enables conversion of substituted alkynes to (fc)-2-methyl-1 -alkenylalumi-num species, and, by subsequent iodinolysis, to the corresponding iodoalkenes with retention of the double-bond configuration. Depending on the substitution pattern of the starting alkyne, many useful products emerge from this reaction, which themselves can serve as building blocks for transition metal-mediated or -catalyzed coupling reactions [59—62]. 

The final stages of the synthesis illustrate both the power and the current limitations of transition-metal mediated C-C bond formation. Coupling of 2 and 3 led to the ene-yne 7. Pd-mediated hydrostannylation of the alkyne proceeded with high geometric control, but tended to... 

Reactions of alkynyliodonium salts 119 with nucleophiles proceed via an addition-elimination mechanism involving alkylidenecarbenes 120 as key intermediates. Depending on the structure of the alkynyliodonium salt, specific reaction conditions, and the nucleophile employed, this process can lead to a substituted alkyne 121 due to the carbene rearrangement, or to a cyclic product 122 via intramolecular 1,5-carbene insertion (Scheme 50). Both of these reaction pathways have been widely utilized as a synthetic tool for the formation of new C-C bonds. In addition, the transition metal mediated cross-coupling reactions of alkynyliodonium salts are increasingly used in organic synthesis. 

Metal mediated and catalyzed reactions have made significant contributions to organic synthesis over the past two decades [1]. One of the earliest and most useful of these is the Pauson-Khand carbon-carbon coupling reaction [2] first reported in 1971. In this reaction, a cyclopente-none is formed from an alkyne and an alkene in the presence of [Co2(CO) ] with insertion of carbon monoxide in a formal 12-h2+1 ]-cycloaddi-tion. The exceptional potential of this reaction has been demonstrated in many (mostly intramolecular) syntheses (Scheme 1) [3]. 

Metallacycles have been claimed to play pivotal roles in many transition metal-mediated multi-component coupling reactions [1]. For example, [2 -i- 2 -i- 2] alkyne cyclo-trimerization leading to benzenes - the Reppe reaction - has been considered to proceed via metallacyclopentadiene and elusive metallacycloheptatriene intermediates ("common mechanism ), while metallacyclopentenes have been proposed as intermediates for the [2 -i- 2 -i- 1] cyclo-coupling reactions of an alkyne, an alkene, and CO leading to a cyclopentenone (the Pauson-Khand reaction). A metallacyclic compound - which is defined here as a carbocyclic system with one atom replaced by a transition metal element - can be generally formed by oxidative cyclization of two unsaturated molecules with a low-valent transition metal fragment [2-4]. Alter-... 

The Pauson-Khand reaction gives the same product as the group 4 metal-mediated reductive coupling and carbonylation, and both reactions proceed by essentially the same mechanism formation of an alkyne-metal tt complex, insertion of an alkene, insertion of CO, and reductive elimination. Some details differ, however. When an alkyne is added to Co2(CO)g, CO evolves, and an isolable, chromatographable alkyne-Co2(CO)6 complex is obtained. This butterfly complex contains four Co(II)-C bonds, and the Co-Co bond is retained. The formation of the alky n e-C o2 (C O) 6 complex involves the formation of an ordinary tt complex of the alkyne with one Co(0) center, with displacement of CO. The tt complex can be written in its Co(II) cobaltacyclopropene resonance structure. The tt bond of the cobaltacyclopropene is then used to form a tt complex to the other Co center with displacement of another equivalent of CO. This second tt complex can also be written in its cobaltacyclopropene resonance structure. The alkyne-Co2(CO)6 complex has two 18-electron Co(II) centers. 

Zirconium Reagents. Ethenylation can be effected via hydrozirconated terminal alkynes (Scheme 83). The alkenylzirconocene gives the -aUcenyl product. The reaction is carried out in the presence of zinc chloride. Presumably metal metathesis occurs before the palladium-mediated coupling takes place. The coupling is regiospecific with initial... 

Transition-metal-mediated C—X bond formation by intramolecular reactions with alkynes is a powerful strategy for the construction of heteroarene rings such as pyridines, pyrroles, and furans. Because of the wide availability of Sonogashira coupling of various haloarenes with terminal alkynes, these transformations provide efficient routes to synthesize fused heteroarenes, including isoquinolines, indoles, and benzofurans. In this chapter the construction of aromatic rings by transition-metal-catalyzed or transition-metal-mediated intramolecular C—X bond formation between C—X or X—H and alkynes is described. As shown in Scheme 19.1, Section... 

The Lee group originated rhodium alkenylidene-mediated catalysis by combining acetylide/alkenylidene interconversion with known metal vinylidene functionalization reactions [31], Thus, the first all-intramolecular three-component coupling between alkyl iodides, alkynes, and olefins was realized (Scheme 9.17). Prior to their work, such tandem reaction sequences required several distinct chemical operations. The optimized reaction conditions are identical to those of their original two-component cycloisomerization of enynes (see Section 9.2.2, Equation 9.1) except for the addition of an external base (Et3N). Various substituted [4.3.0]-bicyclononene derivatives were synthesized under mild conditions. Oxacycles and azacycles were also formed. The use of DMF as a solvent proved essential reactions in THF afforded only enyne cycloisomerization products, leaving the alkyl iodide moiety intact. 

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