Stereochemistry carbopalladation

Palladium-catalyzed cyclization of alkenes and alkynes were reported by Balme and co-workers.143 144 Intramolecular carbopalladation occurs to give polycyclic compounds. It has been shown that the nucleophile type has a large influence on the cyclization process. Both 5-exo- and 6-endo-cyclization are observed for substrates with nitrile (116 and 118) and ester (120, 122, and 124) substituents, respectively (Scheme 36). When a mixed nucleophile (CN and C02Me) is used, a mixture of 5-exo and 6-endo products is obtained. The chemoselectivity is controlled by the size of the nucleophile used. The stereochemistry of the initial double bond plays an important role on the stereoselectivity of the cyclization. (Z)-olefins (118 and 120) and (/. )-olefins (116 and 124) afford as- (119 and 121) and trans-cyclization products (117 and 123), respectively. 

Insertion of palladium into the Si-Sn bond generates intermediate 428 that undergoes m-addition on the triple bond (Scheme 108). The resulting vinylpalladium 429 ensures the carbopalladation of the second triple bond followed by reductive elimination with retention of stereochemistry.376... 

To probe the reaction mechanism of the silane-mediated reaction, EtjSiD was substituted for PMHS in the cyclization of 1,6-enyne 34a.5 The mono-deuterated reductive cyclization product 34b was obtained as a single diastereomer. This result is consistent with entry of palladium into the catalytic cycle as the hydride derived from its reaction with acetic acid. Alkyne hydrometallation provides intermediate A-7, which upon cw-carbopalladation gives rise to cyclic intermediate B-6. Delivery of deuterium to the palladium center provides C-2, which upon reductive elimination provides the mono-deuterated product 34b, along with palladium(O) to close the catalytic cycle. The relative stereochemistry of 34b was not determined but was inferred on the basis of the aforementioned mechanism (Scheme 24). 

By considering the H-migration origin/destination, one may distinguish I, II and III/IV. On this basis, experiments (i) and (ii) with a type A catalyst as shown in Scheme 12.9 eliminated mechanisms I and II from consideration this left III and IV which were both fully consistent with the results. The outcome for (i) is obvious the allylic hydrogens (see Hb in mechanism I, Scheme 12.8) are not involved in the reaction. The outcome for (ii) is more subtle and relates to the stereochemistry attending fceta-carbopalladation and beta-hydride elimination which are both known to proceed with syn stereochemistry. Thus, mechanism II which does not involve a beta-hydride elimination would not affect the alkene stereochemistry (see Hc in II, Scheme 12.8), as was revealed by D-labelling, Scheme 12.9. In contrast, mechanisms III and IV should reverse the stereochemistry (see Hc in III and IV, Scheme 12.8), as was observed. 

Oxypalladation of vinyl ether, followed by alkene insertion, is an interesting synthetic route to functionalized cyclic ethers. In prostaglandin synthesis, the oxypalladation of ethyl vinyl ether (40) with the protected cyclopentenediol 39 generates 41 and its intramolecular alkene insertion generates 42. The intermolecular insertion of the alkene 43, and /1-elimination of 44 occurred as one-pot reaction at room temperature, giving the final product 45 in 72% yield [46], The stereochemistry of the product shows that the alkene insertion (carbopalladation of 41) is syn. It should be noted that the elimination of /1-hydrogen from the intermediate 42 is not possible, because there is no /1-hydrogen syn coplanar to the Pd and, instead, the insertion of alkene 43 occurs. 

The stereochemistry of the insertion (carbopalladation) is syn addition. The syn addition of Ar-PdX to an alkene generates ff-(j6-aryl)alkylpalladiums 17. Then internal rotation around the former double bond occurs, making the syn j6-H elimination possible to give the /ram -alkenes 18. 

Stereochemistry. There are ample experimental indications that both hydropalladation (pattern 5) and carbopalladation (pattern 8) as well as their microscopic reversals (patterns 15 and 18) are, at least in the great majority of cases, strict syn addition processes, as predicted by the concerted mechanism shown in Scheme 8. In the hydropalladation and carobpalladation reactions of alkynes, the stereochemical course of the reactions is readily seen and unmistakable. However, clear-cut and explicit demonstration of the... 

Ikenaga et reported that trimethyl(styryl)germanes coupled with arenediazonium tetrafluoroborates in the presence of a palladium catalyst (Scheme 36). Although the reaction proceeds smoothly under mild conditions, stereochemistry of the alkenylgennanes is not retained as was observed with alkenylsilanes shown in Scheme 2. The mechanism is ascribed to a carbopalladation route as discussed with alkenylsilanes. 

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