Intermolecular reactions 3-hydride elimination

The proposed catalytic cycle of the ruthenium-catalyzed intermolecular Alder-ene reaction is shown in Scheme 21 (cycle A) and proceeds via ruthenacyclopentane 100. Support for this mechanism is derived from the observation that the intermediate can be trapped intramolecularly by an alcohol or amine nucleophile to form the corresponding five-or six-membered heterocycle (Scheme 21, cycle B and Equation (66)).74,75 Four- and seven-membered rings cannot be formed via this methodology, presumably because the competing /3-hydride elimination is faster than interception of the transition state for these substrates, 101 and 102, only the formal Alder-ene product is observed (Equations (67) and (68)). 

The use of cyclic alkenes as substrates or the preparation of cyclic structures in the Heck reaction allows an asymmetric variation of the Heck reaction. An example of an intermolecular process is the addition of arenes to 1,2-dihydro furan using BINAP as the ligand, reported by Hayashi [23], Since the addition of palladium-aryl occurs in a syn fashion to a cyclic compound, the 13-hydride elimination cannot take place at the carbon that carries the phenyl group just added (carbon 1), and therefore it takes place at the carbon atom at the other side of palladium (carbon 3). The normal Heck products would not be chiral because an alkene is formed at the position where the aryl group is added. A side-reaction that occurs is the isomerisation of the alkene. Figure 13.20 illustrates this, omitting catalyst details and isomerisation products. 

Examples of catalytic formation of C-C bonds from sp C-H bonds are even more scarce than from sp C-H bonds and, in general, are limited to C-H bonds adjacent to heteroatoms. A remarkable iridium-catalyzed example was reported by the group of Lin [116] the intermolecular oxidative coupling of methyl ethers with TBE to form olefin complexes in the presence of (P Pr3)2lrH5 (29). In their proposed mechanism, the reactive 14e species 38 undergoes oxidative addition of the methyl C-H bond in methyl ethers followed by olefin insertion to generate the intermediate 39. p-hydride elimination affords 35, which can isomerize to products 36 and 37 (Scheme 10). The reaction proceeds under mild condition (50°C) but suffers from poor selectivity as well as low yield (TON of 12 after 24 h). 

The main steps in the currently accepted catalytic cycle of the Heck reaction are oxidative addition, carbopalla-dation (G=G insertion), and / -hydride elimination. It is well established that both, the insertion as well as the elimination step, are m-stereospecific. Only in some cases has formal /r/ / i--elimination been observed. For example, exposure of the l,3-dibromo-4-(dihydronaphthyloxy)benzene derivative 16 and an alkene 1-R to a palladium source in the presence of a base led to a sequential intra-intermolecular twofold Heck reaction furnishing the alkenylated tetracyclic products 17 in good to excellent yields (Scheme 9). " In the rate-determining step, the base removes a proton in an antiperiplanar orientation from the benzylic palladium intermediate. The best amine base was found to be l,4-diazabicyclo[2.2.2]octane, which apparently has an optimal shape for this proton abstraction. 

Scheme 9 Sequential intra-intermolecular twofold Heck reaction involving a trans-/ -hydride elimination. ...

As mentioned previously, the partially reduced forms of five membered heteroaromatic systems might act as olefins in insertion reactions. This behaviour is characteristic particularly of dihydrofuranes. The olefin insertion and the following / hydride elimination should in principle lead to a trisubstituted olefin, which is rarely observed, however. Typical products of this reaction are 2-aryl-2,3-dihydrofuranes. A characteristic example of such a reaction is presented in 6.54. The coupling of 4-iodoanisole and dihydrofurane led to the formation of the chiral 2-anisyl-2,3-dihydrofurane in excellent yield.83 The shift of the double bond, which leads to the creation of a new centre of chirality in the molecule, opens up the way for enantioselective transformations. Both intermolecular and intramolecular variants of the asymmetric Heck reaction have been studied extensively.84... 

The mechanisms proposed for these reactions are all quite analogous, and only the intramolecular cases will be considered in detail (Scheme 5). Oxidative addition by Pd° into the allylic C—O bond of the allyl 0-ketocaiboxylate produces an allylpalladium caxboxylate. This species then undergoes decarboxylation to yield an allylpalladium enolate (oxa-ir-allyl), which subsequently eliminates a 0-H to form the enone and provide an allyl-Pd-H. Reductive elimination from the allyl-Pd-H yields propene and returns Pd to its zero oxidation state. A similar mechanism can be imagined for the alkenyl allylcarbonate. Oxidative addition by the Pd° forms an allylpalladium carbonate, which decarboxylates again to give an allylpalladium enolate (oxa-ir-allyl). 0-Hydride elimination and reductive elimination complete the process. The intermolecular cases derive the same allylpalladium enolate intermediates, only now as the result of bimolecular processes. 

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). 

A ruthenium based catalytic system was developed by Trost and coworkers and used for the intermolecular Alder-ene reaction of unactivated alkynes and alkenes [30]. In initial attempts to develop an intramolecular version it was found that CpRu(COD)Cl catalyzed 1,6-enyne cycloisomerizations only if the olefins were monosubstituted. They recently discovered that if the cationic ruthenium catalyst CpRu(CH3CN)3+PF6 is used the reaction can tolerate 1,2-di- or tri-substituted alkenes and enables the cycloisomerization of 1,6- and 1,7-enynes [31]. The formation of metallacyclopentene and a /3-hydride elimination mechanism was proposed and the cycloisomerization product was formed in favor of the 1,4-diene. A... 

Fig.l Cross-coupling reaction of unactivated alkyl electrophiles showing intramolecular p-hydride elimination (undesired) and intermolecular transmetalation (desired). 

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. 

The development of the intermolecular cyclic version of the Heck reaction began in the late 1970s. It was immediately evident that the problem with reversible hydride eliminations complicated the use of endocyclic aUcenesf t " t ° and long chain acyclic... 

Another potentially powerfnl sequence arises by combining one or two intramolecular Heck-type couplings with an intra- or intermolecular Diels-Alder addition (for early examples of inter-intermolecular one-pot domino Heck-Diels-Alder reactions see Refs. [49] and [50]). An all-intramolecular version of such a sequence has been shown to proceed reasonably smoothly for terminally alkoxycarbonyl-substituted 2-bromotrideca-l,ll-dien-6-ynes under palladium catalysis at 130 °C. At 80 °C, the sequential reaction stops after the two consecutive Heck-type cyclizations and subsequent /3-hydride elimination to give a 1,3,6-triene apparently only the ( )-isomer undergoes the intramolecular Diels-Alder reaction, as the (Z)-l,3,6-triene is observed accompanying the tetracyclic system obtained at 130 °C (Scheme 36). 

The prototypic substrate for intermolecular cascade reactions is norbomene or one of its analogs. Starting from an aryl halide, addition of the formed palladium species to the strained double bond of norbomene yields a norbomylpalladium derivative, which cannot undergo /3-hydride elimination but can accept hydride, for example, from piperidinium formate (Scheme 1) or potassium formate, the latter reaction occurring even at room temperature. 

B. INTERMOLECULAR CARBOPALLADATION OF ALLENES FOLLOWED BY /8-HYDRIDE ELIMINATION REACTION... 

As outlined in Sect. B and C, catalytic intermolecular carbopalladations of allenes followed by either /3-hydride elimination or intermolecular nucleophilic trapping provide 1,3-dienes or allyl derivatives bearing the nucleophile moiety, respectively, while an intermolecular carbopalladation followed by intramolecular trapping sequential reaction provides cyclic skeletons (Scheme 27). In Type I, the nucleophilic moiety is connected with the C—X bond, and in lype II it is attached to the allene moiety. 

The investigation of the intermolecular version of the Mizoroki-Heck reaction with endo-cyclic alkenes began in the late 1970s [50-52], It was directly evident that the problem with reversible and repeating -hydride eliminations/migratory insertions complicated the use of cyclic alkenes in a manner similar to long-chain acyclic 1-alkenes [53], Mixtures of isomers were obtained. An example of a C—C bond formation-isomerization [54] process is shown in Figure 3.5. 

In addition to the several reports of intermolecular Fujiwara-Moritani reactions, there have been a nnmber of examples of intramolecular reactions, both stoichiometric and catalytic in palladinm. In considering an intramolecular oxidative Heck reaction, one can again draw a direct analogy to the classical Heck reaction (Figure 9.3). In the standard Heck reaction, a halogenated arene nndergoes an oxidative addition by palladium(0), followed by alkene insertion and jS-hydride elimination. In an oxidative version, a C—H bond of... 

Two recent reports have described Pd"-catalyzed carboamination reactions involving two alkenes that afford pyrrolidine products. Building on early work by Oshima that employed stoichiometric amounts of palladium [44], Stahl has developed an inter-molecular Pd-catalyzed coupling of N-allylsulfonamide derivatives with enol ethers or styrene derivatives that affords substituted pyrrolidines in high yields with moderate diastereoselectivity [45]. For example, treatment of 44 with styrene in the presence of Pd" and Cu" co-catalysts, with methyl acrylate added for catalyst stability, provided 45 in 97% yield with 1.9 1 dr (Eq. (1.21)). This reaction proceeds through intermolecular aminopalladation of styrene to afford 46. Intramolecular carbopalla-dation then provides intermediate 47, and subsequent P-hydride elimination yields product 45. 

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 intermolecular benzyne-benzyne-alkene insertion reaction is shown in Scheme 38. Initially 7r-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 cycUzed intermediate 134. /i-Hydride elimination from 134 followed by isomerization gave 9-methylphenanthrene 131. 

The intermolecular version of the reaction can also be effective, and, under the right conditions, can give good yields even when the substrate, such as iodide 4.90, is capable of p-hydride elimination (Scheme 4.37). Curiously, the intramolecular carbonylative Heck reaction of styrene 4.03 proeeeded with net reduction of... 

---