Palladium complexes alkyl

A similar involvement of palladium hydride, palladium alkyl, and palladium acyl complexes as intermediates in the catalytic cycle of the Pd-catalyzed hydroxycarbonylation of alkenes was reported for the aqueous-phase analogs. The cationic hydride PdH(TPPTS)3]+ was formed via the reduction of the Pd11 complex with CO and H20 to [Pd(TPPTS)3] and subsequent protonation in the acidic medium. The reaction of the hydride complex with ethene produced two new compounds, [Pd(Et)(TPPTS)3]+ and Pd(Et)(solvent)(TPPTS)2]+. The sample containing the mixture of palladium alkyl complexes reacted readily with CO to afford trans-[Pd(C(Q)Et)(TPPTS)2]+.665... 

Similarly to the hydroformylation, under certain reaction conditions the formation of the intermediate palladium-alkyl complex can be practically irreversible as shown by the different prevailing chirality of the 2-methylbutanoic acid ester obtained from 1-butene and (Z)-2-butene, as well as from ( )- and (Z)-2-butene. Therefore, re-gioselection and enantioface selection must occur, as in hydroformylation, during or before the formation of the postulated palladium-alkyl intermediate (see Scheme IV). 

P-hydride elimination, which is the Ayn-elimination of a hydrogen atom and Pd(II) from a palladium alkyl complex with no change in oxidation state ... 

Palladium alkyl complexes are inherently unstable because of p-elimination. We saw this in action in the discussion on hydrogenation in chapter 8. The palladium atom leaves with a hydrogen... 

In 2012, Yu, Houk, and eo-workers showed a detailed DFT calculation to understand reactivity and stereoselectivity in the Pd-catalyzed diastereoselec-tive C(sp )—H bond activation process. Characterization of the trinuclear palladium-alkyl complexes discloses a clear picture of the chiral induction model (Scheme 5.2). Computational investigation has revealed that the reactions with Pr- and Pu-substituted oxazolines involve different catalyst resting states before C—H bond activation and that the lower reactivity of an Pr-substituted oxazoline results from greater stability of its catalyst resting state. DFT calculation indicated that C—H bond activation most likely occurs at the monomeric Pd center and the most preferred transition state for C—H bond aetivation contains two sterically bulky Pu groups on the carboxylic acid, and the oxazoline moieties are oriented in anti-positions which leads to the major diastereomer. 

Few direct comparisons between the rates for insertions of alkenes and alkynes have been made. However, one comparison indicates that the insertions of alkenes are slower than die insertions of alkynes. The insertion of acetylene into the cationic palladium-alkyl complex in Equation 9.7H° is directly analogous to the insertions of ethylene into cationic palladium alkyl complexes. This insertion of acetylene is faster than the insertion of ettiylene into ttie same palladium-methyl complex. The insertion of 1-hexyne ismuch slower than the insertion of acetylene and gives a mixture of the two vinyl complexes that result from 1,2- and 2,1-insertion. 

Simpler p-halide eliminations occur from late transition metal catalysts for olefin polymerization (Equations 10.25 and 10.26). Reactions of the cationic palladium-alkyl complexes occur in a similar fashion to the reactions of the cationic group 4 complexes, despite the softer nature of these species. In this case, propylene and the metal chloride are formed. Even a neutral nickel-hydrocarbyl complex (the salicaldimine complex in Equation 10.26) undergoes reactions with vinyl chloride that involve insertion followed by P-chloride elimination. 

The reactions of some optically active benzyl halides have provided further evidence for the nucleophilicities of the [Pd(PR3)j] species (Lau et al., 1974, 1976 Wong et al., 1974 Stille and Lau, 1976). The salient features of these studies are summarised in Scheme 6. The stereochemistry of the addition is established by reaction of the palladium-alkyl complex with carbon monoxide (this insertion is known to take place by an intramolecular migration process, with retention of configuration in the migrating alkyl group), and subsequent formation of an ester from this acyl complex. 

Considerably less is known about the chemistry of palladium and platinum 1,1-dithio complexes. Of late, there has been only one report that dealt with the synthesis of a large number of palladium dithiocar-bamates 392). Twenty-five yellow palladium dithiocarbamate complexes were obtained by reaction of PdCla with NaR2dtc in methanol solution. Several other reports have appeared in which a few dithiocarbamate complexes of palladium were synthesized. Thus, the novel [Pd (OH)2dtc 2], which is soluble in water, was isolated 393). The synthesis of optically active palladium(II) complexes of AT-alkyl-a-phen-ethyldithiocarbamates, similar to (XXIV), via the reaction between the optically active amine, CS2, and PdCl2, has been described. From ORD and CD spectra, it has been established that the vicinal contribution of a remote, asymmetric carbon center could give rise to optical activity of the d—d transitions of palladium 394). Carbon disulfide has been shown to insert into the Pt-F bond of [PtF(PPh3)3]HF2, and X-ray studies indicated the structure (XXIX). 

A plausible mechanism proposed for this reaction involves migratory insertion of an olefin into the Pd-Si bond of a paUadium-silyl intermediate I followed by migratory insertion of the pendant olefin into the resulting Pd-C bond of II forming palladium-alkyl intermediate III. Reaction of Iff with hydrosilane releases the carbocy-cle to regenerate the palladium-silyl complex I (Scheme 3-21) [61]. 

Phosphine ligands based on the ferrocene backbone are very efficient in many palladium-catalyzed reactions, e.g., cross-coupling reactions,248 Heck reaction,249 amination reaction,250 and enantioselective synthesis.251 A particularly interesting example of an unusual coordination mode of the l,l -bis(diphenylphosphino)ferrocene (dppf) ligand has been reported. Dicationic palladium(II) complexes, such as [(dppf)Pd(PPh3)]2+[BF4 ]2, were shown to contain a palladium-iron bond.252,253 Palladium-iron bonds occur also in monocationic methyl and acylpalladium(II) complexes.254 A palladium-iron interaction is favored by bulky alkyl substituents on phosphorus and a lower electron density at palladium. 

Cationic palladium(II) complexes are homogeneous catalysts for both intramolecular and inter-molecular hydroamination reactions.267 Palladium species immobilized on silica can be prepared by the simple addition of alkyl- or hydroxopalladium(II) complexes to partially dehydroxylated silica. The silica-bound species are more stable than their molecular precursors and are efficient catalysts for the cyclization of aminoalkynes.268... 

Palladium(II) complexes possessing bidentate ligands are known to efficiently catalyze the copolymerization of olefins with carbon monoxide to form polyketones.594-596 Sulfur dioxide is an attractive monomer for catalytic copolymerizations with olefins since S02, like CO, is known to undergo facile insertion reactions into a variety of transition metal-alkyl bonds. Indeed, Drent has patented alternating copolymerization of ethylene with S02 using various palladium(II) complexes.597 In 1998, Sen and coworkers also reported that [(dppp)PdMe(NCMe)]BF4 was an effective catalyst for the copolymerization of S02 with ethylene, propylene, and cyclopentene.598 There is a report of the insertion reactions of S02 into PdII-methyl bonds and the attempted spectroscopic detection of the copolymerization of ethylene and S02.599... 

As reported in Scheme 1 the process involves a series of steps. The alkylpalladium species 1 forms through oxidative addition of the aromatic iodide to palladium(O) followed by noibomene insertion (4-7). The ready generation of complex 2 (8-11) from 1 is due to the unfavourable stereochemistry preventing P-hydrogen elimination from 1 (12). Complex 2 further reacts with alkyl halides RX to form palladium(IV) complex 3 (13-15). Migration of the R group to the... 

When Knochel and his co-workers attempted to use [PdC CF CN ] and related palladium(n) complexes as catalysts in the reactions of dialkylzincs with alkyl iodides, they observed the formation of the halogen-zinc exchange405 or cyclization406 products only. A recent paper of Zhou and Fu demonstrated that palladium complexes can also be used in the coupling reactions of alkylzinc bromides with alkyl iodides, bromides, chlorides, and... 

Insertion of ethylene into the Ni-C bond in 3a leads to the alkyl complex 4a via the transition state TS[3a-4a] with a barrier [13a] of 17.5 kcal/mol relative to 3a It is worth to note that in TS[3a-4a both ethylene and the a-carbon of the growing (propyl) chain are situated in the N-Ni-N plane. For the corresponding palladium complex the insertion barrier [13c] is somewhat higher at 19.9 kcal/mol. 

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