Ethylene cross metathesis with alkynes

Both catalysts 1 and 2 are effective in promoting cross-metathesis leading to various conjugated dienes from alkenes and alkynes. Chiral 2-(a-acetoxybenzyl)-1,3-butadiene is obtained from (/f)-3-acetoxy-3-phenylpropyne via cross-metathesis with ethylene. - Furthermore, the reaction of 1,6-diynes with alkenes is even more intriguing ... 

Metathesis is a versatile reaction applicable to almost any olefinic substrate internal, terminal or cyclic alkenes, as well as dienes or polyenes. (Alkyne metathesis is a growing area, but will not be dealt with here.) The reaction is also known as olefin disproportionation or olefin transmutation, and involves the exchange of fragments between two double bonds. Cross metathesis (CM, Figure 1) is defined as the reaction of two discrete alkene molecules to form two new alkenes. Where the two starting alkene molecules are the same it is called self-metathesis. Ethenolysis is a specific type of cross metathesis where ethylene... 

Treatment of an alkyne/alkene mixture with ruthenium carbene complexes results in the formation of diene derivatives without the evolution of byproducts this process is known as enyne cross-metathesis (Scheme 22). An intramolecular version of this reaction has also been demonstrated, sometimes referred to as enyne RCM. The yield of this reaction is frequently higher when ethylene is added to the reaction mixture. The preferred regiochemistry is opposite for enyne cross-metathesis and enyne RCM. The complex mechanistic pathways of Scheme 22 have been employed to account for the observed products of the enyne RCM reaction. Several experiments have shown that initial reaction is at the alkene and not the alkyne. The regiochemistry of enyne RCM can be attributed to the inability to form highly strained intermediate B from intermediate carbene complex A in the alkene-first mechanism. Enyne metathesis is a thermodynamically favorable process, and thus is not a subject to the equilibrium constraints facing alkene cross-metathesis and RCM. In a simple bond energy analysis, the 7r-bond of an alkyne is... 

Olefin metathesis is a reaction that is over fifty years old and has been developed over this time period from a process nm at high temperatures with ill-defined catalysts by unknown mechanisms to a process that can be conducted imder nuld conditions with designed catalysts by mechanisms that occur by established steps. Olefin metathesis, and the related alk3me metathesis, fully cleaves carbon-carbon double and triple bonds and reforms these bonds to generate new alkenes and alkynes. The reaction is often under equilibrium control, but certain classes of reactions can be conducted in a selective fashion that is controlled by relative rates or thermod)mamic preferences. This reaction can open strained rings to form polymers or small dienes. It can close small rings and macrocycles by a reaction that is driven by the expulsion of ethylene that makes the reaction favored entropically or by running in an open system under non-equilibrium conditions. It can also be run as a "cross metathesis" to form imsymmetrical alkenes when the steric or electronic properties of the two alkenes properly match. 

Cross-Enyne Metathesis/Diels-Alder MCRs Ruthenium-based complexes are known to catalyze the metathesis between alkynes and alkenes to afford 1,3-dienes. Fnstero, del Pozo et al. further exploited this cross-enyne metathesis (CEYM) by trapping the 1,3-diene with a dieno-phile via an intermolecnlar Diels-Alder reaction [198]. Thns, the Ru-catalyzed MCR between alkynes 220-221 and 1,7-octadiene as an in situ sonrce of ethylene by RCM generates a 1,3-diene that can snbseqnently nndergo a Diels-Alder reaction with a wide variety of dienophiles 222... 

Cross-Metathesis (CM) of Alkyne with Olefine Ethylene-mediated intermolecular enyne metathesis of various alkynes, pioneered by Mori et al., is a convenient procedure for the formation of 2-substituted or 2,3-disubstituted 1,3-dienes 248 (Scheme 24.60). The low... 

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