Carbopalladation 3-hydride elimination

Based on a /rarcr-acetoxypalladation of the triple bond, Lu has developed a highly enantioselective (up to 87% ee) synthesis of 7-butyrolactones with Pd(n) catalysis (Scheme 73).280 Following the initial /ra/w-acetoxy-palladation, a plausible mechanism for this sequence involves an intramolecular carbopalladation of the pendant olefin, and deacetoxypalladation instead of the common /3-hydride elimination in the final step. 

Cyclization of 2-(l-alkynyl)XV-alkylidene anilines is catalyzed by palladium to give indoles (Equation (114)).471 Two mechanisms are proposed the regioselective insersion of an H-Pd-OAc species to the alkyne moiety (formation of a vinylpalladium species) followed by (i) carbopalladation of the imine moiety and /3-hydride elimination or (ii) oxidative addition to the imino C-H bond and reductive coupling. 

A clean twofold Heck coupling of unsubstituted butadiene 46 (R = H) in the 1- and 4-positions has not been reported. However, the initial carbopalladation product from 46 (R = H) and an in situ formed arylpalladium halide, the cr-allylpalladium halide 47 equilibrating with the corresponding 7r-allylpalladium halide, can efficiently be trapped with the anion formed by arylation of malononitrile or cyanoacetate to give 48, a product of reductive 1,4-arylation-alkylation of 1,3-butadiene 46 (R = H)." /3-Hydride elimination from the intermediate 47 (R H) can be accomplished when the reaction is carried out in the presence of silver acetate or thallium acetate, leading to the... 

Five-membered ring closures have been observed when o-halostyrene derivatives such as 113 were coupled with alkenes under palladium catalysis. Apparently, an intramolecular carbopalladation with S-exo-trig ring closure to give 114-R can favorably compete with / -hydride elimination in the first-formed intermediate to yield 115-R This reaction mode for the halostyrene is observed especially under Jeffery conditions, when the alkene is ethene or propene (Scheme 31). Under the same conditions, however, < -dibromobenzene gives very high yields of o-dialkenylbenzene derivatives (see Scheme 2). ... 

When /J-hydride elimination in the carbopalladation relay is completely blocked as in norbornene 116 and norbornadiene 117, the coupling with 6 -bromostyrene 113 furnished the respective cyclopentannelation products 118 and 119 exclusively and in good yields. 

The transformations of 136 proceed cleanly upon treatment with a catalytic amount of Pd(PPh3)4, in the presence of triethylamine and molecular sieve (MS) 4 A it apparently is initiated by oxidative addition of the N(sp )-0 bond of 136 to the Pd(0) complex, and this is succeeded by two or even three intramolecular carbopalladations followed by / -hydride elimination. This Heck-type reaction is not affected by the configuration of the oxime derivatives probably due to a facile enough if/Z-isomerization of the alkylideneaminopalladium intermediate. 

Under palladium catalysis, the < -iodoallenylbenzene 146 first undergoes an intermolecular carbopalladation of the double bond in the added norbornene 116, and only then follows an intramolecular carbopalladation of the allene moiety in 146 ensuing /3-hydride elimination finally provides the tricyclic compound 147 (Scheme 37)7 ... 

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. 

In their pioneering work on the catalytic carbopalladation reaction of 1,2-heptadiene with phenyl iodide in the presence of a suitable base, Shimizu and Tsuji observed the formation of the corresponding substituted 1,3-dienes 62 via a / -hydride elimination from the 7z>allyl intermediate 61 [61]. Based on these observations, a three-component Heck-Diels-Alder cascade process has been developed by Grigg and co-workers [73]. A wide variety of aryl and heteroaryl iodides were used for the intermolecular reaction with dimethylallene to afford the corresponding 1,3-dienes. These subsequently react in situ with N-methylmaleimide to give the bicyclic adducts 63 (Scheme 8.30). 

Palladium-catalyzed vinylations of aryl halides are generally referred to as the Heck reaction (for reviews on the Heck reaction see [34-40]), a versatile process that can be performed inter- and intramolecularly [41]. In the Heck reaction the carbon-carbon single bond forming step is an insertion of an al-kene into the aryl-Pd bond, i.e., a carbopalladation, giving rise to an alkyl-Pd species. If this insertion is terminated by /1-hydride elimination the expected vinylation product is the outcome of the classical Heck reaction. Likewise, reversible insertion of a highly strained olefin where the /1-hydride elimination is suppressed leads to an entry to multiple Pd-catalyzed bond forming processes. 

However, studies on the scope of this sequence revealed that the substrate has to be an N-tosyl sulfonamide and that certain boronic acids are not trans-metallated but rather give rise to the formation of the pyrrole 21 or a pyridine derivative 22 (Scheme 7). The peculiar outcome as a carbopalladation-Suzuki sequence is rationalized by co or dinative stabilization of the insertion intermediate 18 by the sulfonyl oxygen atom, as represented in structure 19, now suppressing the usual /3-hydride elimination. If the transmetallation is rapid the Suzuki pathway is entered leading to product 17. However, if the transmetallation is slow, as for furyl or ferrocenyl boronic acid, either /i-hydride elimination or a subsequent cyclic carbopalladation occurs. The former leads to the formation of the diene 20 that is isomerized to the pyrrole 21. The latter furnishes the cyclopropylmethyl Pd species 23, which rearranges with concomitant ring expansion to furnish piperidyl-Pd intermediate 24 that suffers a -hydride elimination to give the methylene tetrahydro pyridine 22. 

As indicated in the previous example, carbopalladation does not necessarily culminate in /i-hydride elimination as the expected outcome of reactions under Heck conditions. In those cases where the initial carbopalladation can be reversed at a later stage in the sequence fascinating options for catalytic processes may evolve. In particular, Catellani (for an overview see [67]) has established that norbornene, a strained olefin, which is reversibly introduced and eliminated, might efficiently serve as a relay to open new pathways for Pd-mediated processes. Indeed, most of the processes were explored and conducted both in a stoichiometric and in a catalytic fashion. 

Of the two mechanistic pathways, i.e., via palladacyclization or via hydropalladation-cyclic carbopalladation, the latter seems to be more suitable for the development of sequentially catalyzed processes. Considering cycloisomerizations via the hydropalladation-cyclic carbopalladation route the catalytic reaction can terminate by /1-hydride elimination giving rise to the formation of dienes and derivatives thereof (Scheme 79). Alternatively, the alkyl-Pd species formed in the cyclic carbopalladation can be susceptible to subsequent transmetallation with organometallic substrates. Then, a reductive elimination could conclude this second Pd-mediated step releasing the Pd(0) species for a new catalytic cycle. 

The palladium-catalyzed reaction of allyl chloride 11 with the benzyne precursor 104 to produces phenanthrene derivatives 131 is also known [83]. A plausible mechanism for this inter molecular benzyne-benzyne-alkene insertion reaction is shown in Scheme 38. Initially tt-allyl palladium chloride la is formed from Pd(0) and 11. Benzyne 106, which is generated from the reaction of CsF and 104, inserted into la to afford the aryl palladium intermediate 132. A second benzyne insertion into 132 produce 133 and subsequent carbopalladation to the alkene afford the cyclized intermediate 134. -Hydride elimination from 134 followed by isomerization gave 9-methylphenanthrene 131. 

Presumably, the oxidative cyclization of 1 commences with direct palladation at the orfAo-position, forming o-arylpalladium(II) complex 3 in a fashion analogous to a typical electrophilic aromatic substitution (this notion is useful in predicting the regiochemistry of oxidative cyclizations). The mechanism of the second formal C—H bond functionalization step is not fully elucidated, but may occur either via (a) an intramolecular carbopalladation reaction (migratory insertion) followed by czHft-P-hydride elimination from 4 (Path A) (b) by o-bond metathesis (through a four-centered transition state) followed by reductive elimination (Path B) (c) by electrophilic aromatic substitution followed by C—C bond-forming reductive elimination (PathC) [9]. 

The reaction is thought to proceed by co-ordination of the alkene with the organopalladium(II) species, followed by carbopalladation. Subsequent p-hydride elimination regenerates an alkene and releases palladium(II). This is reduced (reductive elimination) to palladium(O) in the presence of a base, to allow further oxidative addition and continuation of the cycle (1.211). The carbopalladation and p-hydride elimination steps occur syn selectively. Excellent regioselectivity, even for intermolecular reactions, is often observed, with the palladium normally adding to the internal position of terminal alkenes (except when the alkene substituent is electron-rich as in enamines or enol derivatives), thereby leading to linear substitution products. 

Cascade reactions arising from sequential carbopalladations are especially valuable for the construction of various carbo- and heterooligocyclic systans with three, four, or even more annelated rings. The Heck reaction has successfully been employed in various inter-inter-, intra-inter-, as well as all-intramolecular reaction cascades (Sect. IV.3). In the carbopalladation step of the Heck reaction (Scheme 6) a new metal-carbon bond is formed, which, in principle, can undergo any of the typical reactions of a hydride elimination is not too fast. When the /S-hydride elimination is totally suppressed, the palladium species can undergo a number of reactions with the formation... 

When the /3-hydride elimination in the intermediate is retarded or even impossible, as in the carbopalladation products of alkynes or norbomene, the respective cyclopentan-nelation products are formed in higher yields (Scheme 5),[i9].[20]... 

When the carbopalladated relay is less prone to undergo /S-hydride elimination (as, e.g., a corbopalladated methylenecyclopropane moiety) or the /S-hydride elimination is even completely blocked [as, e.g., an alkyne, norbomene (Scheme 2) ", or acenaphthylene (Scheme 3)] and the respective cyclopentannelation products can be isolated in... 

Norbomene can serve as an excellent external relay, for example, for the alkenylpalla-dium species first formed by intramolecular carbopalladation of an ort/to-alkynyl-substituted arylpalladium halide. The 2-alkenylnorbonylpalladium halide formed by intermolecular carbopalladation then undergoes another intramolecular carbopalladation, this one in a 3-exo-trig mode, and subsequent /3-hydride elimination terminates the cascade process to yield a cyclopropanated norbomene derivative (Scheme... 

An analogous reaction mode is followed in the 1 2 cross-coupling of 2-bromostyrene with acenaphthylene, which yields a bisannelated tetrahydrofulvene (Scheme 48)J Norbomene can favorably serve as a relay for cascade carbopalladations as the /S-hydride elimination is virtually impossible. The reaction always starts with an alkenyl-or arylpaUadium starter, generated either by oxidative addition of an alkenyl or aryl halide to a paUadium(O) species or by hydro- or carbopalladation of an alkyne, adding to the double bond. With /3-bromostyrene, norbomene can yield the same type of bisannelated tetrahydrofulvene derivative " as with acenaphthylene, but under different reaction conditions can also react with a 2 1 stoichiometry to give a cyclohexadiene-annelated norbomane derivative (Scheme 49). ... 

Under yet different conditions, the carbopalladation product from an alkenylpalladium intermediate undergoes a 3-exo-trig cyclization and subsequent /3-hydride elimination leading to a 2,3-methanobicyclo[2.2.1]heptane derivative (Scheme 50). "... 

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