Alkene intermolecular arylations

As described above, the intermolecular a-arylation of simple aliphatic aldehydes is not successful. However, the authors have found that their aldol products, 2-substituted ( )-2-alkenals, are arylated efficiently and selectively at their y-position (Eq. 26) [64]. 

Early investigations dealing with intermolecular arylations of uiisymmetrically donor-substituted alkenes often revealed only poor regioselectivities, especially with acyclic enol ethers. However, suitable conditions have since been developed for both the selective a-... 

Scheme 3-36 Intramolecular tiryl-aryl as well as intra-intermolecular aryl-aryl and aryl-alkene coupling cascades [189].

Since the pioneering work by Beletskaya and co-workers [8] the intra- and (more commonly) intermolecular arylation of alkenes has been shown to proceed very smoothly in aqueous medium in the presence of palladium acetate. At the beginning, the methodology seemed to be limited to aryl iodides under a strong influence of the base it was shown that the presence of potassium acetate instead of carbonate yielded lower reaction temperatures and higher rates (Eq. 4). 

An organometallic reaction which shows a close similarity to the Mizoroki-Heck reaction is the cobalt-catalysed [46] reaction between alkenes and organic halides. The use of [CoCKPPhsls] (59) as catalyst for intermolecular arylations of methyl acrylate (1) and styrene (2) was reported by Iyer [47] (Scheme 10.20). The para-substituted aryl iodides could be employed with this homogeneous catalyst, but the more sterically hindered ortho-substituted iodoarenes failed to undergo the desired substitution reaction. Aryl bromides and chlorides, as well as alkyl-substituted halides, proved unreactive under these reaction conditions. 

Oxoesters are oxidized with Mn(OAc)3 to the corresponding radicals that can add intermolecularly or intramolecularly (eq Ib)" to generate alkyl radicals. In the presence of Cu(OAc)2 the latter are rapidly quenched and oxidized to give alkenes. Radical arylation with alkyl iodides can be induced with dibenzoyl peroxide the yield of the reaction can be improved using a catalytic amount of Cu(0Ac)2-H20, which minimizes hydrogen abstraction by the intermediate radical but introduces a competitive electron-transfer oxidation of the intermediate radical. The oxidative addition of disulfides to alkenes (Trost hydroxysulfenylation ) can be promoted by catalytic amounts ofCu(OAc)2. ... 

Using a similar concept, Wolfe and Rossi developed a novel palladium-catalyzed stereoselective synthesis of tetrahydrofurans from y-hydroxy alkenes and aryl bromides [27] (Scheme 6.17). After a series of deuterium labeling experiments, the authors suggested that the predominant mechanistic pathway for tetrahydrofiiran formation probably involves a rare syn insertion of an alkene into the Pd-O bond of an intermediate palladium aryl alkoxide [28]. Later, the same group reported similar intramolecular [29] and intermolecular [30] cyclizations to synthesize a series of tetrahydrofurans. 

Scheme 2.14 Copper-catalysed intermolecular hydroamination of electron-deficient aryl alkenes...

Recently, addition of organorhodium species to nitriles has been reported.420 4203 4201 Intermolecular reaction of benzonitrile with phenylborate (accompanied with r//w-aryiation) (Equation (65)), arylative cyclization of acetylenic nitriles (Equation (66)), and cyclization of 2-cyanophenylboronic acid with alkynes or strained alkenes (Equation (67)) are proposed to proceed via this process. 

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. 

The intermolecular alkylation of metallo nitronates with various alkyl halides is limited. The addition of methyl iodide to the silver salt of an aryl nitro-methane provides the corresponding methyl nitronate in moderate yield (Eq. 2.13) (150), which has also been extended to the silver salt of trinitromethane (Scheme 2.16) (151-153). However, in the case of primary halides, both O- and C-alkylation are observed. For secondary and tertiary halides, only O-alkylation is observed, but in low yields. Unfortunately, under the reaction conditions, the starting alkyl halide can undergo dehydrohalogenation to provide the corresponding alkene, which then undergoes [3+2] cycloaddition with the alkyl nitronate. 

Palladium(0)-catalyzed cross-coupling of aryl halides and alkenes (i.e., the Heck reaction) is widely used in organic chemistry. Oxidative Heck reactions can be achieved by forming the Pd -aryl intermediate via direct palladation of an arene C - H bond. Intramolecular reactions of this type were described in Sect. 4.1.2, but considerable effort has also been directed toward the development of intermolecular reactions. Early examples by Fu-jiwara and others used organic peroxides and related oxidants to promote catalytic turnover [182-184]. This section will highlight several recent examples that use BQ or dioxygen as the stoichiometric oxidant. 

Electrophilic ring closure of aryl-substituted compounds such as alkenes, halides, alcohols, and carbonyl compounds called cyclialkylation can be induced by conventional Friedel-Crafts catalysts309 and by superacids. Examples are also known in which an intermolecular alkylation step is followed by intramolecular alkylation of the intermediate to furnish a cyclic product. 

In intermolecular cyclopropanations [100], it was found better to use a-bromoesters and amides as ylide precursors and a,/ -unsaturated ketones and esters as electron-deficient alkenes - rather than using a-haloketones as the ylide precursor. (For experimental details see Chapter 14.11.4). The reaction gives access to a range of 1,2-dicarbonyl-substituted cyclopropanes (see Fig. 10.5). The al-kene could have an aryl-, alkyl- or indole-substituted ketone, and a-substitution was also tolerated. Notably, Weinreb amides could be used as the ylide precursor and the product subsequently transformed into a diketocyclopropane. Both enan-... 

Although the Heck reaction may be efficiently employed for synthesis, it has its limits that should not go unmentioned the Heck reaction can not—at least not intermolecularly—couple alkenyl triflates (-bromides, -iodides) or aryl triflates (-bromides, -iodides) with metal-free aromatic compounds in the same way as it is possible with the same substrates and metal-free alkenes. The reason is step 4 of the mechanism in Figure 16.35 (part II). If an aromatic compound instead of an alkene was the coupling partner the aromaticity with this carbopallada-tion of a C=C double bond would have to be sacrificed in step 4. Typically, Heck reactions can only be run at a temperature of 100 °C even if they proceed without any such energetic effort. This is why this additional energetically demanding loss of aromaticity is not feasible. 

In comparison to the cyclization reactions shown above, intermolecular Meerwein arylations are often more difficult to conduct. Since the aryl radical addition to the alkene is no longer favored by the close proximity of the reacting centers, the probability for a direct recombination of the aryl radical with scavengers Y is significantly increased (Scheme 17). To maintain the desired reaction course from 44 to 45 including steps (1) and (2) [89, 90], Meerwein arylations have for a long time mostly been conducted with activated alkenes, such as acrylates (R = COOR ), vinylketones (R = COR ), styrenes (R = Ph), or conjugated dienes [91,92]. These types of alkenes are known for fast addition of aryl radicals. 

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 n-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. f>- Iydride elimination from 134 followed by isomerization gave 9-methylphenanthrene 131. 

The protic acid and Lewis acid-catalyzed [4 + 2] cycloaddition reactions of electron-rich alkenes with imines derived from anilines and aryl aldehydes constitute an extensively explored class of 2-azadienes capable of providing the products of a formaJ Diels-Alder reaction (equation 9).i5.27.i77 a useful extension of these studies and in efforts to increase the rate of the Att participation of simple 2-aza-1,3-buta-dienes in [4 + 2] cycloaddition reactions, Mariano and coworkers have examined the Lewis acid-catalyzed intermolecular reactions of (l ,3 )-l-phenyl-2-aza-l,3-pentadiene with electron-rich dienophiles, including enol ethers. Reductive work-up of the cycloaddition reactions provided the pro-... 

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