7T-allyl complexes

A similar ring-opening metallation is observed with bicyclo[3.1.0]hex-2-ene and bieyclo[5.1.0]oct-2-ene. The olefin 49 undergoes ring enlargement with Fe2(CO)9 to form the corresponding rc-allyl and >/4-diene complexes [27]. trans-Palladation of 53 results in the formation of the 7t-allyl complexes 54 [28]. (Scheme 19 and 20)... 

In the presence of in, V -generated palladium(O) species, an electrophilic 7t-allyl complex 228 is formed, which is readily engaged in an intramolecular carbometallation (Scheme 57). The resulting vinylpalladium species then undergoes a Stille-type cross-coupling to provide a triene.232... 

Thus, after the formation of the 7t-allyl complex 397 from the corresponding allyl trifluoroacetate, an exchange of ligand with triphenylphosphine generates 398. The formation of the phosphine-Pd complex 398 appears to be the key to successful cyclization, because the complex 397 failed to cyclize. 

Feringa and coworkers [258] and O Doherty et al. [259] independently reported palladium-catalyzed glycosylations of 2-substituted 6-acyl-2H-pyran-3(6H)-one derivatives and alcohols (Scheme 5.98). This reaction presumably involves electrophilic Pd 7t-allyl complex intermediate, which was generated by the reaction of 2-substituted 6-acyl-2Ff-pyran-3(6H)-one and Pd(0)/PPh3. It is noteworthy that 2-substituted 6-acyl-2H-pyran-3(6H)-one derivatives were stereoselectively converted into 2-substituted 6 - a I k o x y - 2 H - p y r an - 3 (6 H) -o n e derivatives with complete retention of configuration by this reaction. A two-step reduction/oxidation manipulation after the glycosylation can install new stereocenters in the obtained glycosides. 

C5 is extremely acidic, and once deprotonated it is nucleophilic. C4, though, is not electrophilic, so we need to convert it to an electrophilic C. Looking at the product, one sees that the new C-C bond is allylic. This suggests attack of C5 on a 7t allyl complex. This complex could be made by insertion of the C1=C2 n bond into a Pd-H bond. This last could be made by protonation of Pd(0) by C5. 

Acetylation occurs at the 2-position of allene systems (Scheme 8.14). The intermediate 7t-allyl complex breaks down via the nucleophilic displacement of the cobalt carbonyl group by the hydroxide ion to produce the hydroxyketone (7) [ 11 ]. An alternative oxygen-initiated radical decomposition of the complex cannot, however, be totally precluded. The formation of a second major product, the divinyl ketone (8), probably arises from direct interaction of the dicobalt octacarbonyl with the allene and does not require the basic conditions. 

The dissociative mechanism can explain both facts in that the hydrogen removed in the first step may recombine with an isomeric form of the ally lie intermediate to yield the isomeric olefin. Apparently syn and anti 7T-allylic complexes [67, 68) retain their configurations unless each may be converted into a common a-bonded complex in which the nonterminal carbon atoms of the allyl group are connected by a single bond and the isomerization of the intermediate can be represented as in Fig. 11. However, the recombination of the hydrogen atom with the allylic intermediate must be faster than the rate at which it enters the surface pool of... 

Additional mechanistic insights were gained when Hartwig and coworkers isolated and characterized the first 7t-allyl complexes that are chemically and kinetically competent to be intermediates in iridium-catalyzed allylic substitution [46]. These complexes were prepared independently from allylic electrophiles that are more reactive than allylic carbonates. The isolation and structural characterization of these species provided a detailed view into the origins of enantioselectivity. 

Pair-of-dimer effects, chromium, 43 287-289 Palladium alkoxides, 26 316 7t-allylic complexes of, 4 114-118 [9JaneS, complexes, 35 27-30 112-16]aneS4 complexes, 35 53-54 [l5]aneS, complexes, 35 59 (l8)aneS4 complexes, 35 66-68 associative ligand substitutions, 34 248 bimetallic tetrazadiene complexes, 30 57 binary carbide not reported, 11 209 bridging triazenide complex, structure, 30 10 carbonyl clusters, 30 133 carboxylates... 

Stereoselectivity, or the formation of a cis-1,4 or tram-1,4 unit, is connected to the structure of the chain end 7t-allyl complex (Scheme 13.8). The syn-allyl (52) and the anri-allyl (53) form, which are in equilibrium,383 give rise to the formation of the trans-1,4 or cis-1,4 groups, respectively. ... 

Fe2(CO)9 also gives small amounts (1.5 3%) of the distal ring-opened dinuclear allylic complexes (equations 336 and 337)378. 

Surprisingly, spiropentane was shown to be more resistant to the ring opening by transition metal compounds than cyclopropane. For example, while Rh(I) and Pd(II) destroy the skeleton of spiropentane, yielding 7t-allylic complex 65 (equation 44), in the presence... 

In a proton NMR experiment in which 1,4-pentadiene was added to a solution of HNi[P(OMe)3]4, it was possible to watch the isomerization of 1,4- to 1,3-pentadiene, followed by formation of l,3-dimethyl-7t-allyl complexes (53). The observation of 7t-allyl products in the reaction of the hydride with the conjugated diene, but not in the ff-alkyl intermediates involved in isomerization, illustrates the much greater stability of zr-allyl complexes of nickel compared to tr-alkyls, a feature which is also observed in the hydrocyanation reactions. 

The cationic Jt-allyl complex is often isolable and has been the subject of considerable study. X-ray structures of the 7t-allyl complexes with chiral ligands have been a primary source of structural information from which the design and predictive model of chiral catalysts derive. Chiral-metal-olefin complexes, which constitute another important class of intermediates have also been isolated, albeit few in number [31]. These static studies have been complemented by a growing number of NMR studies taking advantage of modem heteronuclear correlation and NOE techniques, which offer opportunities to monitor solution structures of the catalytic species [32-34],... 

Although metal-olefin complexation can be a source of enandoselection, reactions exploiting this mechanistic motif have not been developed much. Due to the facile enantioface interconversion process, the origin of the enantioselection often reverts back to Type C alkylation (Figure 8E, 1). To transfer chiral recognition of the coordination process to the ee of the product, kinetic trapping of the incipient 7t-allyl complex is required prior to any isomerization process. For this reason, few successful examples have come from the use of more reactive heteroatom nucleophiles (N, O and S) and/or intramolecular reactions. 

Mesylates are used for Ni-catalysed reactions. Arenediazodium salts 2 are very reactive pseudohalides undergoing facile oxidative addition to Pd(0). They are more easily available than aryl iodides or triflates. Also, acyl (aroyl) halides 4 and aroyl anhydrides 5 behave as pseudohalides after decarbonylation under certain conditions. Sulfonyl chlorides 6 react with evolution of SO2. Allylic halides are reactive, but their reactions via 7t-allyl complexes are treated in Chapter 4. Based on the reactions of those pseudohalides, several benzene derivatives such as aniline, phenol, benzoic acid and benzenesulfonic acid can be used for the reaction, in addition to phenyl halides. In Scheme 3.1, reactions of benzene as a parent ring compound are summarized. Needless to say, the reactions can be extended to various aromatic compounds including heteroaromatic compounds whenever their halides and pseudohalides are available. 

The coordination of the Pd(0)-catalyst to fhe double bond forms an r 2 n-allyl complex. An oxidative addition, during which the leaving group is expelled, gives an i)3 7t-allyl complex. This step is also called ionization ... 

The reaction of this allylic acetate with the sodium salt of Me Id r urn s acid (structure in margin) demonstrates the retention of configuration in the palladium(0)-catalysed process. The tetraacetate and the intermediate 7t-allyl complex are symmetrical, thus removing any ambiguity in the formation or reaction of the 7t-allyl complex and hence in the regiochemistry of the overall reaction. 

The presence of five-membered rings such as cyclopentanes, cyclopentenes, and dihydrofurans in a wide range of target molecules has led to a variety of methods for their preparation. One of the most successful of these is the use of trimethylenemethane [3 + 2] cycloaddition, catalysed by pal-ladium(O) complexes. The trimethylenemethane unit in these reactions is derived from 2-[ (trimethylsilyl)methyl]-2-propen- 1-yl acetate which is at the same time an allyl silane and an allylic acetate. This makes it a weak nucleophile and an electrophile in the presence of palladium(0). Formation of the palladium 7t-allyl complex is followed by removal of the trimethylsilyl group by nucleophilic attack of the resulting acetate ion, thus producing a zwitterionic palladium complex that can undergo cycloaddition reactions. 

The palladium-catalyzed decarboxylative coupling of allyl 2-(benzo[c(jthiazol-2-yl)acetates 118 provides a facile approach to 2-(but-3-enyl)benzo[c(jthiazoles 122 <07JA4138>. The reaction is initiated by nucleophilic attack of Pd(0) on the allyl ester to give Pd-7t-allyl complex 119, which undergoes nucleophilic attack at the less substituted allylic carbon from the benzothiazole nitrogen to produce 120. Decarboxylative dearomatization leads to intermediate 121, and a subsequent aza-Cope rearrangement driven by rearomatization affords the final product 122 and accounts for the unusual regioselectivity. This appears to be the first report of a tandem allylation/aza-Cope reaction driven by decarboxylative dearomatization/ rearomatization. 

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