Palladacycles reaction mechanisms

Since the first X-ray crystal structure of a palladium(IV) complex was published by Canty [29, 30], a number of groups have undertaken the study of these relatively uncommon intermediates. In an effort to elucidate the role of palladium(IV) and palladium(II) intermediates in the reaction mechanism, Catellani prepared a number of isolable palladacycle complexes in both the (II) and (IV) oxidation states using 1,10-phenanthroline as the ligand (Scheme 8) [31]. Catellani successfully isolated palladium(IV) palladacycle 22, which was subsequently characterized by... 

However further studying of reaction mechanism by and C-labeling experiments [47] have shown that two kinds of metathesis dienes are obtained. Treatment of labeled enyne 38 with palladacycle complex 39 led to a mixture of 1,3-dienes 40 and 41, which were designated as single cleavage and double cleavage products, respectively (Scheme 7.22). 

The use of well-defined complexes has been widespread in this reaction, despite intriguing studies by Beller and others that have shown that in situ catalytic systems often give better yields in comparison to isolated carbene-Pd(O) complexes [147-149]. Since the mechanism consists of an oxidative addition on a Pd(0)-monocarbene species, efforts in catalyst synthesis have been directed towards Pd(ll)-monocarbene complexes with other labile groups that can be easily released leading to the formation of Pd(0). This is the case for dimers of the type [Pd( j,-C1)C1(NHC)]2, a family of pre-catalysts effective under aerobic conditions [150], the [Pd(acac)Cl(NHC)] complexes [151] and related palladacycles [152-154],... 

Herrmann WA, Brossmer C, Reisinger CP, Riermaier T, Ofele K, Beller M (1997) Coordination chemistry and mechanisms of metal-catalyzed C-C coupling reactions. Part 10. Palladacycles efficient new catalysts for the Heck vinylation of aryl halides. Chem Eur J 3 1357-1364 Iyer S, Jayanthi A (2001) Acetylferrocenyloxime palladacycle-catalyzed Heck reactions. Tetrahedron Lett 42 7877-7878 Iyer S, Ramesh C (2000) Aryl-Pd covalently bonded palladacycles, novel amino and oxime catalysts di- x-chlorobis(benzaldehydeoxime-6-C,AT)dipalla-dium(II), di- x-chlorobis(dimethylbenzylamine-6-C,A)dipalladium(II) for the Heck reaction. Tetrahedron Lett 41 8981-8984 Jeffery T (1984) Palladium-catalysed vinylation of organic halides under solid-liquid phase transfer conditions. J Chem Soc Chem Commun 1287-1289 (b) idem,... 

Rawal s group developed an intramolecular aryl Heck cyclization method to synthesize benzofurans, indoles, and benzopyrans [83], The rate of cyclization was significantly accelerated in the presence of bases, presumably because the phenolate anion formed under the reaction conditions was much more reactive as a soft nucleophile than phenol. In the presence of a catalytic amount of Herrmann s dimeric palladacyclic catalyst (101) [84], and 3 equivalents of CS2CO3 in DMA, vinyl iodide 100 was transformed into ortho and para benzofuran 102 and 103. In the mechanism proposed by Rawal, oxidative addition of phenolate 104 to Pd(0) is followed by nucleophilic attack of the ambident phenolate anion on o-palladium intermediate 105 to afford aryl-vinyl palladium species 106 after rearomatization of the presumed cyclohexadienone intermediate. Reductive elimination of palladium followed by isomerization of the exocyclic double bond furnishes 102. 

The palladium catalyzed reactions of substituted vinylallenes with unactivated 1,3-butadienes proceeded with high selectivity133. A multistep mechanism, involving several palladacycles, was proposed to explain the high selectivities observed. 

The domino carbonylation and Diels-Alder reaction proceed only as an intramolecular version. Attempted carbonylation and intermolecular Diels-Alder reaction of conjugated 2-yne-4-enyl carbonates 101 in the presence of various alkenes as dienophiles give entirely different carbocyclization products without undergoing the intermolecular Diels-Alder reaction. The 5-alkylidene-2-cyclopenten-4-onecarboxy-lates 102 were obtained unexpectedly by the incorporation of two molecules of CO in 82% yield from 101 at 50 °C under 1 atm [25], The use of bidentate ligands such as DPPP or DPPE is important. The following mechanism of the carbocyclization of 103 has been proposed. The formation of palladacyclopentene 105 from 104 (oxidative cyclization) is proposed as an intermediate of 108. Then CO insertion to the palladacycle 105 generates acylpalladium 106. Subsequent reductive elimination affords the cyclopentenone 107, which isomerizes to the cyclopentenone 108 as the final product. 

A plausible mechanism for the one-pot synthesis ofcarbazoles is shown in Scheme 5. It consists of two interlinked catalytic cycles. In the first cycle a classical Buchwald-Hartwig amination reaction occurs to generate an intermediate 5 which then enters the second cycle by oxidative addition to Pd(0). The resulting Pd(II) complex then undergoes intramolecular C-H activation to give a six-membered palladacycle which subsequently yields the carbazole by reductive elimination. 

More recently, cationic intermediates have been observed in the Heck reactions of arene diazonium salts catalyzed by triolefinic macrocycle Pd(0) complexes [17,59], o-iodophenols and enoates to form new lactones [60], and o-iodophenols with olefins (the oxa-Heck reaction) [61 ]. In the first case ions were formed by oxidation of the analyte at the capillary, or by association of [NH4] or Na". In the two other cases ionization occurred through the more typical loss of a halide ligand. The oxa-Heck reaction provides a good example of how these experiments are typically performed and the type of information that can be obtained. The oxyarylations of olefins were performed in acetone, catalyzed by palladium, and required the presence of sodium carbonate as base. Samples from the reaction mixtures were diluted with acetonitrile and analyzed by ESI(+)-MS. Loss of iodide after oxidative addition of o-iodophenol to palladium afforded positively-charged intermediates. Species consistent with oxidative addition, such as [Pd(PPh3)2(C6H50)], and the formation of palladacycles of the type seen in Scheme 8 were observed. Based on this, a mechanism for the reaction was proposed (Scheme 8). 

These reactions are considered to involve insertion of the unsaturated compounds to arylpalladium species followed by the formation of palladacycle intermediates. Oxidative addition of another halide molecule to them leads to the products. In the reaction with norbornene [105 -108] and diphenylacety-lene [109],the corresponding 3 1 and4 1 products and 3 1 product,respectively, are also formed under somewhat different conditions. The mechanisms to account for the formation of these unusual products involving multiple C-H cleavage steps have been proposed. It is noted that, in contrast to Eq. (49), treatment of aryl bromides with aliphatic internal alkynes gives allene derivatives (Eq.50) [110]. 

The stereochemistry of oxidative addition to the palladium(II) palladacycle was studied by Lautens using an enantioenriched secondary alkyl halide (Scheme 9) [32], From alkyl halide 23, product 24 was obtained, showing a net inversion of stereochemistry [33-35], Previous work by Stille showed that reductive elimination from palladium(IV) occurs with retention of stereochemistry [36], suggesting that oxidative addition occurs with an inversion of stereochemistry. This corresponds with the generally accepted SN2 mechanism for the reaction of palladium(O) with alkyl halides [37, 38],... 

Internal alkynes will also readily undergo palladium-catalyzed annulation by functionally substituted aromatic or vinylic halides to afford a wide range of heterocycles and carbocycles. However, the mechanism here appears to be quite different from the mechanism for the annulation of terminal alkynes. In this case, it appears that the reaction usually involves (1) oxidative addition of the organic halide to Pd(0) to produce an organopalladium(II) intermediate, (2) subsequent insertion of the alkyne to produce a vinylic palladium intermediate, (3) cyclization to afford a palladacycle, and (4) reductive elimination to produce the cyclic product and regenerate the Pd(0) catalyst (Eq. 28). 

It seems highly likely that all palladium-catalysed reactions that commence with an oxidative addition as the first step of the catalytic cycle proceed though a Pd(0) / Pd(ll) mechanism. Thus one needs to conclude that all palladacycles and pincers are converted to some form of Pd(0) in these reactions. In many cases this was shown to be in the form of palladium nanoparticles. However, with the more reactive iodoarenes it is possible that most of the catalyst is in the form of an anionic or neutral monomeric or dimeric palladium species. 

At this point, there are still some gaps in our understanding, particularly concerning the reaction on chloroarenes where palladacycles seem to perform better than Pd(OAc)2, with or without added TBAB. This is unexpected if one assumes that both mechanisms proceed though a Pd(0)/Pd(ll) mechanism in which the Pd(0) is in the form of palladium nanoparticles. 

Larock found that the reaetion of 2-iodo -methylbiphenyl (34) with acrylate provided two products 35 and 36 in equal amounts using cesium pivalate as a base. Of course, 35 is an expected produet [27]. Also the reaction of 37 afforded the mixture of 35 and 36. Gallagher also diseovered a similar migration using 3-bromo-4-phenylpyridine (38) and acrylate to afford 39 and 40 [28]. Although the mechanism of the migration process to form the crossover produets is not clear, certainly a reversible 1,4-Pd shift of arylpalladium intermediates 41 and 43 via the palladacycle 42 is occurring. 

Larock and Reddy obtained the 2-alkylidenecyclopentanone 72 by the reaction of l-(l-alkynyl)cyclobutanol 71 with iodobenzene. The bicyclononanone 74 was obtained from 73. Selective formation of 74 demonstrates that the more substituted bond a in the eyelobutanol 73 undergoes exclusive cleavage (or migration) [8,13]. Larock proposed the mechanism of the reaction of 75 involving ring expansion of 76 to form palladacycle 77 and reductive elimination to give 78. 

Although a mechanism has been proposed to rationalize the reaction that contains a several steps for the catalytic cycle, a different mechanism is proposed here. The original mechanism includes the following steps in the catalytic cycle (a) reduction of Pd(OAc)2 to Pd(0) to initiate the catalytic cycle, b) coordination of chloride to palladium, (c) oxidative addition of aryl iodide to Pd(0), d) coordination of alkyne to palladium atom and subsequent regioselective. yyn-insertion into the arylpalladium bond, (e) nitrogen displacement of the halide in the resulting vinylic palldium intermediate to form a palladacycle, and (/) reductive elimination to form indole and the regenerated Pd(0) reenters the catalytic cycle. 

Hemnann et have indicated that the standard palladacycle trans-di(fju-acetato)-bis[o-(di-o-tolylphosphino)benzyl]-dipaUadium(II) (A) might be a catalyst precursor to active palladium(O) complexes (Scheme 41). In other words, the palladacycle may act as a thermally stable reservoir for the real catalytic species, which is released by heterolytic Pd—C bond cleavage and is activated by subsequent reduction. If this is the acmal case a tfaditional catalytic cycle via Pd(0)/Pd(II) has to be postulated also with palladacycles. In addition, for cross-coupling and amination reactions there is strong evidence for the reduction mechanism of phosphapaUadacycle A into a Pd(0) species.f ... 

Mechanistically, this reaction can be understood on the basis of the Jolly mechanism. As before, oxidative coupling affords the palladacycle 12, and protonation (adding Ha+ in an Se fashion) leads to the chelated 7r-allyl intermediate 13. In the absence of a good nucleophile, 13 loses proton Hb to afford a palladium(O) complex of the observed triene product (Scheme 4). It should be noted that the initially formed triene may subsequently undergo Pd-catalyzed double bond isomerization and thus in some cases product mixtures will be observed. 

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