Mizoroki-Heck reaction catalytic cycle

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. 

The Mizoroki-Heck reaction is a metal catalysed transformation that involves the reaction of a non-functionalised olefin with an aryl or alkenyl group to yield a more substituted aUcene [11,12]. The reaction mechanism is described as a sequence of oxidative addition of the catalytic active species to an aryl halide, coordination of the alkene and migratory insertion, P-hydride elimination, and final reductive elimination of the hydride, facilitated by a base, to regenerate the active species and complete the catalytic cycle (Scheme 6.5). 

Scheme 6.5 Catalytic cycle for the Mizoroki-Heck reaction...

Combination of the oxidative addition of aryl halide with olefin insertion followed by -hydrogen elimination provides a useful olefin arylation process catalyzed by a palladium complex (Mizoroki-Heck reaction) [63-65]. The essential part of the catalytic cycle is shown in Scheme 1.23. 

The mechanisms of Mizoroki-Heck reactions performed from aryl derivatives are presented herein by highlighting how the catalytic precursors, the bases and the ligands may affect the structure and reactivity of intermediate palladium(O) or palladium(II) complexes in one or more steps of the catalytic cycle and, consequently, how they may affect the efficiency and regioselectivity of the catalytic reactions. 

A catalytic cycle is proposed for Mizoroki-Heck reactions involving a P,C-palladacycle precursor based on the fact that a monoligated Pd(0) complex is formed from P,C-palladacycle precursors (see above). The structure of the Pd(0) complex 10 is close to thatof Pd° P(o-Tol)3 generated from Pd° P(o-Tol)3 2 as the minor but active species in oxidative additions of aryl bromides, as reported by Hartwig and Paul [62a]. The oxidative addition gives the dimeric complex [ArPd(/u.-Br) P(c>-Tol)3 ]2 in equilibrium with the former T-shaped complex ArPdBr P(c -Tol)3 prone to react with a nucleophile [62b,c]. Such a mechanism must be vahd for the Pd(0) complexes 10 or 13 generated in situ from the... 

The efficiency of bulky and electron-rich phosphines in Mizoroki-Heck reactions seems to be due to their ability to generate monophosphine-Pd(O) or -Pd(II) complexes in each step of the catalytic cycle (Scheme 1.55). Steric factors are probably more important than electronic factors. One sees from Fu s studies that the last step of the catalytic cycle in which the Pd(0) complex is regenerated in the presence of a base may be rate determining. The role of this last step has been underestimated for a long time. Provided this step is favoured (e.g. with P-r-Bus as ligand and Cy2NMe as base), the oxidative addition of aryl chlorides would appear to be rate determining. However, Mizoroki-Heck reactions performed from the same aryl chloride with the same Pd(0) catalyst and same base but... 

Scheme 1.55 Mechanism of Mizoroki-Heck reactions performed from ArCI when L = P-t-Buj (only one orientation of the alkene is presented). (A) + (B) catalytic cycle when n = 2 ...

It is important to stress that, in most other transition-metal-catalysed reactions, the control of catalytic processes is achieved through the choice, refinement and adjustment of stable ancillary ligands remaining in the coordination shell throughout all steps of the catalytic cycle. In those areas, the design of ligands is the essence of the art. The Mizoroki-Heck reaction, on the other hand, is very reluctant towards the control of catalytic activity via ancillary ligands. 

A tentative catalytic cycle for ligand-accelerated Mizoroki-Heck reactions is shown in Scheme 2.14. A pivotal feature of this mechanism is the requirement to have neutral complex 4 with a single ancillary ligand, as related coordinatively saturated species 1 or... 

The first waste-free vinylation of arenes under C—H activation is as old as the Mizoroki-Heck reaction itself already in 1967, Moritani and Fujiwara [6] revealed a stoichiometric reaction of styrene-palladium(II) chloride dimers with benzene in the presence of acetic acid to give stilbenes in a modest 24% yield. During this process, the palladium(II) precursor is reduced to palladium(O), so that the key to closing the catalytic cycle was to add an efficient reoxidation step to regenerate an active palladium(II) species. One year later, the same group presented a first approach, substoichiometric in palladium. 

Many domino Mizoroki-Heck reactions start with the formation of vinyl palladium species, which are generally formed by an oxidative addition of vinylic halides or triflates to palladium(O). S uch an intermediate can also be obtained from an addition of a nucleophile to a divalent palladium-coordinated alkyne or allene. In most of these cases some oxidant must be added to regenerate palladium(II) from palladium(O) in order to achieve a catalytic cycle. However, Liu and Ln [155] have successfully applied a protonolysis reaction of the C—Pd bond formed in the presence of excess halide ions to quench the C—Pd bond with regeneration of a palladinm(II) species. In this way, reaction of 306 and acrolein in the presence of Pd(OAc)2 and LiBr gave predominantly 307 (Scheme 8.76). Depending on the snbstitution pattern and reaction conditions, 308 was formed as a side prodnct. 

The most common Mizoroki-Heck reaction mechanism is called the neutral mechanism, because its intermediates are uncharged. The catalytic cycle for the neutral manifold of the intramolecular Mizoroki-Heck reaction of alkenyl and aryl halides is shown in Scheme... 

A catalytic cycle arising from the common precatalyst mixture of Pd(OAc)2 and PPhs, termed the anionic pathway, has recently been proposed [ 14]. This pathway involves anionic palladinm(O) and palladium(II) intermediates in which the acetate anion is coordinated with palladinm in the catalytically active species persisting after oxidative addition. The anionic pathway has not been invoked or thoroughly explored for enantioselective intramolecular Mizoroki-Heck reactions. However, it may become more significant based on recent studies with Pd(OAc)2 and bidentate phosphine ligands for which the palladium(n) species is only formed in the presence of added acetate ion [15]. 

A detailed discussion of the current understanding of the mechanism of the Mizoroki-Heck reaction can be found in earUer chapters of this book and in several excellent reviews [7]. Two mechanistic pathways, typically termed neutral and cationic, have been proposed to account for the differences in reactivity and enantioselectivity observed in asymmetric Mizoroki-Heck cycUzations of unsaturated trillates and halides. These pathways differ in the degree of positive charge and the number of available coordination sites assignable to the palladium(II) intermediates of the catalytic cycle. Because catalytic asymmetric Mizoroki-Heck cyclizations are typically carried out with bidentate Ugands, these pathways will be illustrated with a chelating diphosphine Ugand. 

A catalytic cycle of such an enantiospecific Mizoroki-Heck reaction is outlined in Scheme 7.25. The catalytic cycle starts with an oxidative addition of the C—I bond of (M)-113 to palladium(O), yielding intermediate 115 with retention of axial chirality due to the hindered bond rotation of the N—Ar bond (1 115). Even at this stage, 115 can stiU provide either enantiomer of 114 because the alkene moiety will have to rotate for the insertion into the C(sp )—Pd(II) bond to occur. However, in case of a si-face attack, alkene complexation cannot occur because the palladium... 

Another of the standard palladium-catalyzed C—C bond formations is the Mizoroki-Heck reaction. This reaction is based on the palladium-catalyzed coupling of olefins with aryl or vinyl halides under basic conditions [21]. The catalytic cycle that is typically proposed for this reaction is outlined in Scheme 7.7. The first step of the reaction postulated in the mechanism is an oxidative addition of R -X to a Pd(0) complex. The next step is the insertion of the alkene to the Pd complex II. In order for this to be possible, an uncharged ligand has to break away giving a neutral Pd(II) complex that will be coordinated by the olefin. The insertion of the alkene into the Pd— bond results in the C C bond-forming step to give BO. Rotation around the C—C bond and 3-hydride elimination yields the new substituted olefin and intermediate 131. Regeneration of the active catalytic species occurs by the addition of a base. 

A rhodium(l)-catalyzed system in THF is also effective in the Mizoroki-Heck-type reaction of arylsilanediols with acrylates (Scheme 4).53 Interestingly, the use of aqueous THF switches the reaction to 1,4-addition forming /3-arylated esters. The proposed catalytic cycles for these reactions involve 1,4-addition of an arylrhodium species to an acrylate. The change of the reaction pathway is probably because, in aqueous THF, the resultant Rh enolate 6 undergoes protonolysis rather than /3-elimination. Similar Rh-catalyzed 1,4-additions to a,/3-unsaturated carbonyl compounds have been achieved with arylsilicones,54 arylchlorosilanes,55 and aryltrialkoxysilanes.56,57 The use of a cationic Rh-binap complex leads to highly enantioselective 1,4-additions of alkenyl- and arylsilanes.58 583... 

Recently, the present authors have achieved a facile recycling method for both catalyst and reachon medium using F-626 in a Mizoroki-Heck arylation reaction of acrylic acids [11]. The procedure employed a fluorous carbene complex, prepared in situ from a fluorous imidazolium salt, palladium acetate as the catalyst and F-626 as a single reaction medium. When acrylic acid was used as a substrate, separation of the product from the reaction mixture was performed simply by filtration with a small amount of FC-72. The FC-72 solution containing the fluorous Pd-catalyst and F-626 was evaporated and the residue containing the catalyst and F-626 (96% recovery) can be recycled for the next run (Scheme 3.5-6). They tried to reuse the catalyst, and observed no loss of catalytic activity in five re-use cycles. 

The long reaction times required for the previously reported copper-catalysed Mizoroki-Heck-type reactions could be significantly reduced with microwave irradiation [21] in polyethylene glycol (PEG) as solvent [22]. An induction period [23] was noted, resulting, interestingly, in improved isolated yields for the reused catalytic system in the second cycle (Scheme 10.5) [22]. Various aryl iodides, including orr/io-substituted electrophiles, were efficiently converted within 30 min. On the contrary, Ijromo- and chlorobenzene could not be converted under these reaction conditions. 

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