Oxidative Mizoroki-Heck-Type Arylations

Scheme 7.42 Electrophilic C—H bond activation or transmetallation as an entry into oxidative Mizoroki-Heck-type arylations.

Herein, a survey of the literature up to mid 2007 is provided, covering catalytic arylation and alkenylation reactions of alkenes with metals other than palladium. The review summarizes Mizoroki-Heck-type reactions employing organic (pseudo)halides as electrophiles (Scheme 10.1), while oxidative Mizoroki-Heck-type reactions [6] are beyond the scope of this review (Chapters 4 and 9). Valuable transition-metal-catalysed arylation reactions of alkenes employing stoichiometric amounts of organometallic compounds as... 

C-0 bond cleavage of aryl triflates or tosylates is also studied in relation to Mizoroki-Heck type reactions [101], Oxidative addition of PhOTf to Pd(PPh3)4 is 10 times slower than that of Phi. Since similar trend is observed for the catalytic Mizoroki-Heck reaction, the oxidative addition of aryl compound is considered to be the rate-determining step in the overall catalytic process. This feature suggests that the C-0 bond cleavage of aryl triflate proceeds by the concerted SNAr mechanism. However, since the triflate normally acts as a non-coordinating anion, thermally unstable cationic arylpalladium(II) complexes are formed in this reaction (Scheme 3.54). 

Based on a transformation described by Catellani and coworkers [80], Lautens s group [81] developed a series of syntheses of carbocycles and heterocycles from aryl iodide, alkyl halides and Mizoroki-Heck acceptors. In an early example, the authors described a three-component domino reaction catalysed by palladium for the synthesis of benzo-annulated oxacycles 144 (Scheme 8.37). To do so, they used an m-iodoaryl iodoalkyl ether 143, an alkene substimted with an electron-withdrawing group, such as t-butyl acrylate and an iodoalkane such as -BuI in the presence of norbomene. It is proposed that, after the oxidative addition of the aryliodide, a Mizoroki-Heck-type reaction with nor-bornene and a C—H activation first takes place to form a palladacycle PdCl, which is then alkylated with the iodoalkane (Scheme 8.37). A second C—H activation occurs and then, via the formation of the oxacycle OCl, norbomene is eliminated. Finally, the aryl-palladium species obtained reacts with the acrylate. The alkylation step of palladacycles of the type PdCl and PdCl was studied in more detail by Echavarren and coworkers [82] using computational methods. They concluded that, after a C—H activation, the formation of a C(sp )—C(sp ) bond between the palladacycle PdCl and an iodoalkane presumably proceeds by oxidative addition to form a palladium(IV) species to give PdC2. This stays, in contrast with the reaction between a C(sp )—X electrophile (vinyl or aromatic halide) and PdCl, to form a new C(sp )—C(sp ) bond which takes place through a transmetallation. 

The catalytic system proved not only applicable to alkyl hahdes, but also allowed for the intramolecular conversion of aryl halides. Interestingly, the corresponding Mizoroki-Heck-type cyclization products were formed selectively, without traces of reduced side-products (Scheme 10.27) [55]. Therefore, a radical reaction via a single electron-transfer process was generally disregarded for cobalt-catalysed Mizoroki-Heck-type reactions of aromatic hahdes. Instead, a mechanism based on oxidative addition to yield an aryl-cobalt complex was suggested [51]. 

In the Mizoroki-Heck reaction, the catalysis begins with the oxidative addihon of a C(sp )—X bond to a palladium(O) complex to give a C(sp )—Pd(II) complex common to almost all palladium(O)-catalyzed cross-coupling reachons (cf. Section 7.2.1). There are, however, alternative ways to generate the central o-aryl palladium(II) intermediate and to effect a Mizoroki-Heck-type process (Scheme 7.42). 

Oxidations. Cu(OAc)2 has been used as a reoxidant in Pd catalyzed reactions of aryl and alkenyl boronic acids with alkenes and alkynes, and aryltins, and aryl or alkenyl silanols with electron deficient olefins (eq 26). This Mizoroki-Heck type reaction supposedly proceeds through a Pd(II)-boron transmetallation step, followed by addition across the double (triple) bond and final... 

Carbon-carbon bond formation reactions and the CH activation of methane are another example where NHC complexes have been used successfully in catalytic applications. Palladium-catalysed reactions include Heck-type reactions, especially the Mizoroki-Heck reaction itself [171-175], and various cross-coupling reactions [176-182]. They have also been found useful for related reactions like the Sonogashira coupling [183-185] or the Buchwald-Hartwig amination [186-189]. The reactions are similar concerning the first step of the catalytic cycle, the oxidative addition of aryl halides to palladium(O) species. This is facilitated by electron-donating substituents and therefore the development of highly active catalysts has focussed on NHC complexes. 

Regioselectivity is one of the major problems of Mizoroki-Heck reactions. It is supposed to be affected by the type of mechanism ionic versus neutral, when the palladium is ligated by bidentate P P ligands. The ligand dppp has been taken as a model for the investigation of the regioselectivity. Cabri and Candiani [Ig] have reported that a mixture of branched and linear products is formed in Pd°(P P)-catalysed Mizoroki-Heck reactions performed from electron-rich alkenes and aryl halides (Scheme 1.26a) or aryl ttiflates in the presence of halide ions (Scheme 1.26b). This was rationalized by the so-called neutral mechanism (Scheme 1.27). The neutral complex ArPdX(P P) is formed in the oxidative addition of Pd°(pAp) yj Qj. Q aj.yj triflates in the presence of halides. The carbopalladation... 

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