Palladium complexes, isomers

The palladium complex isomer resulting from aryl migration to the norbornyl site was clearly the less reactive for ring closure to hexahydromethanotriphenylene and it could be trapped by norbornene itself, according to Scheme 5 [44]. The formation of the two isomers was interpreted as resulting from a common intermediate which forms by oxidative addition of the aryl halide to the palladacycle, according to Eq. 38. 

The nickel or cobalt catalyst causes isomerization of the double bond resulting in a mixture of C-19 isomers. The palladium complex catalyst produces only the 9-(10)-carboxystearic acid. The advantage of the hydrocarboxylation over the hydroformylation reaction is it produces the carboxyUc acids in a single step and obviates the oxidation of the aldehydes produced by hydroformylation. 

Palladium, polymethylenebis(diphenylphosphine)-bis(thiocyanato)-linkage isomers, 1, 185 Palladium, tetraammine-tetrachloropalladate history, 1, 2 Palladium, tetrachloro-crystal structure, 1, 16 Palladium, tris(dinitrogen)-synthesis, 1,28 Palladium complexes a,(5-dione dioximates electrical properties, 6, 143 acetylacetone hydrolysis, 2,379 alkylperoxo... 

Concerning enantioselective processes, Fujihara and Tamura have proved that palladium NPs containing (S)-BINAP (2,2 -bis(diphenylphosphino)-l,l -binaphthyl) as chiral stabiliser, catalyse the hydrosilylation of styrene with trichlorosilane, obtaining (S)-l-phenylethanol as the major isomer (ee = 75%) [42]. In contrast, the palladium complex [Pd(BINAP)(C3H5)]Cl is inactive for the same reaction [43]. 

In 2004, Molander et al. developed another type of chiral sulfur-containing ligands for the intermolecular Heck reaction. Thus, their corresponding novel cyclopropane-based phosphorus/sulfur palladium complexes proved to be active as catalysts for the reaction between phenyltriflate and dihydrofuran, providing at high temperature a mixture of the expected product and its iso-merised analogue (Scheme 7.7). The major isomer C was obtained with a maximum enantioseleetivity of 63% ee. 

In a stoichiometric reaction the 6jr-allyl)palladium complex 66 was isolated and characterized5815. In a subsequent reaction the jr-allyl complex was reacted with benzoquinone in acetic acid to give an allylic acetate, which was hydrolyzed and oxidized to theaspirone. Interestingly, a quite high diastereoselectivity for the turns methyl isomer was obtained in the palladium-mediated spirocyclization (equation 28). 

Dinuclear palladium complexes catalyze m-hydroarylation of alkynes with arenes.56 The reaction of 3-hexyne with benzene in the presence of a dinulear palladium complex Pd2R2(M-OH)(//-dpfam) [dpfam = j/V,Ar -bis[2-(diphenyl-phosphino)phenyl]formamidinate, R=/>-Tol] and tri(/z-butyl)borane at 100 °C for 4h affords ( )-3-phenyl-3-hexene quantitatively (Equation (53)). The hydroarylation of 3-hexyne with monosubstituted benzenes ( )-3-aryl-3-hexenes with a 2 1 ratio of the meta- and ra -isomers. This regioselectivity is different from that of the hydroarylation of diphenylacetylene catalyzed by Rh4(GO)12.57... 

Addition of diphenyl disulfide (PhS)2 to terminal alkynes is catalyzed by palladium complexes to give l,2-bis(phe-nylthio)alkenes (Table 3)168-172 The reaction is stereoselective, affording the (Z)-adducts as the major isomer. A rhodium(i) catalyst system works well for less reactive aliphatic disulfides.173 Bis(triisopropylsilyl) disulfide adds to alkynes to give (Z)-l,2-bis(silylsulfanyl)alkenes, which allows further transformations of the silyl group to occur with various electrophiles.174,175 Diphenyl diselenide also undergoes the 1,2-addition to terminal alkynes in the presence of palladium catalysts.176... 

Oxazoline formation from 5-vinyloxazolidinones promoted by palladium (0) is also known. Oxidative insertion of palladium with loss of CO2 results in a pair of equihbrating 71-allyl palladium complexes. The stereochemistry of the vinyl group is therefore not important. Ring closure from the thermodynamically more stable transition state accounts for the trans-isomer as the major product. Depending on the exact substitution, diastereoselectivities ranging from 2.5 1 to 16 1 can be obtained (Scheme 8.68). 

Palladium complexes exhibit even higher catalytic activity and produce branched acids preferentially.132 133 The selectivity, however, can be shifted to the formation of linear acids by increasing the phosphine concentration.134 Temperature, catalyst concentration, and solvent may also affect the isomer ratio.135 Marked increase in selectivity was achieved by the addition of Group IVB metal halides to palladium136 and platinum complexes.137 Linear acids may be prepared with selectivities up to 99% in this way. The formic acid-Pd(OAc)2-l,4-bis(diphe-nylphosphino)butane system has been found to exhibit similar regioselectivities.138 Significant enhancements of catalytic activity of palladium complexes in car-bomethoxylation by use of perfluoroalkanesulfonic acid resin cocatalysts was reported.139,140... 

A new efficient route for the synthesis of bis(diboranes) catalyzed by palladium complexes is diboration of allenes (Scheme 22).75 The stereochemistry of these bisboronic products was studied and the Z-isomer was also identified as the major product (93-95%). 

The presence of chelating groups in those complexes is necessary to stabilize the intermediate aryl-palladium complex for isolation but it does not seem necessary to cause palladation. The chelating group does, however, tremendously accelerate the palladation. Aromatic compounds reactive to electrophilic substitution apparently undergo palladation with palladium acetate in acetic acid solution fairly readily at 100 °C or above. Of course, the arylpalladium acetates presumably formed, are not stable under these conditions, and they decompose very rapidly into biaryls and palladium metal 34,35,36) ag do aryl palladium salts prepared by the exchange route 24>. If the direct palladation is carried out in the presence of suitable olefins, arylation can be achieved, so far, however, only in poor yields, arid with concurrent loss of stereospecificity and formation of isomers and other side products 37.38). 

On the other hand, Wacker-type oxidative cyclization is a versatile approach for the construction of oxygenated stereocenters [213,214]. The synthesis of a number of dihydrobenzofurans catalyzed by an in situ-formed carbene-palladium complex has been reported by Muniz [215]. When Pd(TFA)2 in combination with IMes were employed, high yields in pure cyclized products were obtained after simple work-up (Table 9). However, palladium salts containing chlorine or acetate groups led to the formation of mixtures containing the desired product and its six-membered ring isomer. 

Fig. 47. Polycatenar palladium complexes with lateral alkanoates. The parentheses around the alkoxy groups on the stilbazole indicate that a variety of isomers were studied.

Their original option was to use isomer i, because less sterical hindrance for the complexation of the double bond with the palladium was expected (Scheme 30). When no reaction occurred with several ligands, 275 was chosen, which produces the same (allyl)palladium complex. Trost assumed that preliminary complexation of the palladium to the alkyne and intramolecular transposition to the double bond as the reason for this surprising result. Indeed, when ii, where the alkyne is absent, was treated under identical conditions as 275, no reaction occurred (Scheme 30). 

Application of various chiral palladium complexes to the stereoselective hydrosilylation of dienes results in the formation of 3-silylcvcloalkenes irrespective of the isomer of the diene used (in the case of cyclohexadienes). When complexes containing menthyldiphenylphosphine (MDPP) and neomenthyldiphenylphosphine (NMDPP) are used, the chiral products with an excess of the (S)-enantiomer are always formed1011. 

Dipolar cycloaddition of nitrones to olefins is also catalyzed by chiral cationic palladium complexes [66]. When nitrone 119 is treated with 3-(( )-2-butenoyl)-l,3-oxazoli-din-2-one (120) under the influence of (5)-BINAP PdCla (10 mol %) and AgBF4 (20 mol %), isoxazolidine 121 is obtained in 61 % yield as a 45 55 mixture of endo and exo forms. The endo isomer is obtained in 91 % ee (Sch. 32). The chemical yield and endo selectivity are improved by employing (5 )-p-Tol-BINAP as chiral ligand. 

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