Palladium complex compounds, anions

Monoanions derived from nitroalkanes are more prone to alkylate on oxygen rather than on carbon in reactions with alkyl halides, as discussed in Section 5.1. Methods to circumvent O-alkylation of nitro compounds are presented in Sections 5.1 and 5.4, in which alkylation of the a.a-dianions of primary nitro compounds and radial reactions are described. Palladium-catalyzed alkylation of nitro compounds offers another useful method for C-alkylation of nitro compounds. Tsuj i and Trost have developed the carbon-carbon bond forming reactions using 7t-allyl Pd complexes. Various nucleophiles such as the anions derived from diethyl malonate or ethyl acetoacetate are employed for this transformation, as shown in Scheme 5.7. This process is now one of the most important tools for synthesis of complex compounds.6811-1 Nitro compounds can participate in palladium-catalyzed alkylation, both as alkylating agents (see Section 7.1.2) and nucleophiles. This section summarizes the C-alkylation of nitro compounds using transition metals. 

In a slightly less convenient procedure, but one which has general versatility, carbonylation of aryl (or vinyl) palladium compounds produces aryl, heteroaryl, and vinyl carboxylic acids. As with the other procedures, immediate upon its formation, the carboxylate anion migrates to the aqueous phase. Consequently, haloaromatic acids can be obtained from dihaloarenes, without further reaction of the second halogen atom, e.g. 1,4-dibromobenzene has been carbonylated (90% conversion) to yield 4-bromobenzoic acid with a selectivity for the monocarbonylation product of 95%. Additionally, the process is economically attractive, as the organic phase containing the catalyst can be cycled with virtually no loss of activity and ca. 4000 moles of acid can be produced for each mole of the palladium complex used [4],... 

Often Lewis acids are added to the system as a cocatalyst. It could be envisaged that Lewis acids enhance the cationic nature of the nickel species and increase the rate of reductive elimination. Indeed, the Lewis acidity mainly determines the activity of the catalyst. It may influence the regioselectivity of the catalyst in such a way as to give more linear product, but this seems not to be the case. Lewis acids are particularly important in the addition of the second molecule of HCN to molecules 2 and 4. Stoichiometrically, Lewis acids (boron compounds, triethyl aluminium) accelerate reductive elimination of RCN (R=CH2Si(CH3)3) from palladium complexes P2Pd(R)(CN) (P2= e g. dppp) [7], This may involve complexation of the Lewis acid to the cyanide anion, thus decreasing the electron density at the metal and accelerating the reductive elimination. 

Recently, the oxidative addition of C2-S bond to Pd has been described. Methyl levamisolium triflate reacts with [Pd(dba)2] to give the cationic palladium complex 35 bearing a chiral bidentate imidazolidin-2-ylidene ligand [120]. The oxidative addition of the levamisolium cation to triruthenium or triosmium carbonyl compounds proceeds also readily to yield the carbene complexes [121], The oxidative addition of imidazolium salts is not limited to or d transition metals but has also been observed in main group chemistry. The reaction of a 1,3-dimesitylimidazolium salt with an anionic gallium(I) heterocycle proceeds under formation of the gaUium(III) hydrido complex 36 (Fig. 12) [122]. 

The most recent development concerns the heterocyclic (amino)(ylide)carbenes AYC. Such compounds have been known for some years [203] but so far had little impact compared to their diamino stabilized relatives. Both phosphorus ylide (86) and sulfur ylide (87) stabilized AYC ligands have been generated in situ and were stabilized at suitable metal centers (Fig. 27) [204, 205]. The palladium complex 88 with an anionic (amino) [bis(ylide)]carbene is also known [206]. 

The formation of compound 175 could be rationalized in terms of an unprecedented domino allene amidation/intramolecular Heck-type reaction. Compound 176 must be the nonisolable intermediate. A likely mechanism for 176 should involve a (ji-allyl)palladium intermediate. The allene-palladium complex 177 is formed initially and suffers a nucleophilic attack by the bromide to produce a cr-allylpalladium intermediate, which rapidly equilibrates to the corresponding (ji-allyl)palladium intermediate 178. Then, an intramolecular amidation reaction on the (ji-allyl)palladium complex must account for intermediate 176 formation. Compound 176 evolves to tricycle 175 via a Heck-type-coupling reaction. The alkenylpalladium intermediate 179, generated in the 7-exo-dig cyclization of bro-moenyne 176, was trapped by the bromide anion to yield the fused tricycle 175 (Scheme 62). Thus, the same catalytic system is able to promote two different, but sequential catalytic cycles. 

Enantioselective fluorination is commonly conducted with chiral agents such as quinine-based [N-F]+ compounds, and these have been successfully utilised in ionic liquids.115,161 Very good yields and selectivities have been obtained in the enantioselective fluorination of /Nkctoesters catalysed by the chiral palladium complex 57, see Scheme 9.2. l l Depending on the substrate employed, substantial acceleration of the reaction rate relative to that in ethanol was observed with yields and selectivities comparable to those obtained in water or ethanol. The reaction rate was found to depend on both the length of the alkyl substituent of the imidazolium cation as, well as on the type of anion present, whereas the selectivity was not affected by such variations. The products were extracted from the ionic liquid phase with diethyl ether, and in that manner catalytic activity was maintained for up to ten cycles. 

The neutral palladium(II) compound 43 is transformed by addition of AgOTf into the cationic complex 44. In the presence of water an exchange of the triflate anion to hydroxide occurs (44 — 45). Finally, the palladium enolate 46 is formed from the palladium complex and the silyl enol ether. 

Compounds containing the unusual difluorophosphonato-group, e.g. MC1(PF20)(PR3), have been obtained from a Michaelis-Arbuzov type of reaction of PFjOF with the platinum or palladium complexes MCl2(PR3)2. In addition, it is possible to prepare anionic difluorophosphonato-metallates, formulated as (RL)2 [M(PF20)4], from an alkoxy-difluorophosphine and a neutral complex MCI2L2. 

In recent years, a number of low-valent group 10 complexes with anionic pincer ligands have been isolated and characterized. Milstein investigated the chemical reduction of palladium [81] and platinum [82] complexes with PCP Hgands with sodium (Scheme 2.8). The Pd-pincer framework of complex 2 does not resist reduction and collapses, giving rise to the unusual binuclear complex 29. In this compound, both PCP ligands are covalently bound to one of the Pd atoms, which... 

Addition of anionic Fischer carbene complexes, of their CS2 adducts and of an anionic thiocarbyne complex to cationic organometallic Lewis acids and to coordinated, unsaturated hydrocarbons gives novel hydrocarbon bridged heterodimetallic compounds. Oxidative addition of halocarbyne complexes to zerovalent platinum and palladium complexes provides a synthesis of carbido bridged complexes. 

Fe4S4(SR)4] , are good catalysts for reduction of CO2. Recently it was found that other compounds also facilitate such reduction. Electrolytic reduction of CO2 in acetonitrile in the presence of [Rh(dppe)2]Cl leads to the formation of The rhenium(I) compound [ReCl(CO)3 (bipy)] catalyzes electrolytic reduction of CO2 to carbon monoxide. The electrolytic reduction of CO2 in some cases probably proceeds via the radical anion C02 its formation explains various reduction products see scheme (13.241). Palladium complexes, for instance, [Pd2Cl2(dppm)2], [Pd(dppm)2], and [PdCl2(dppm)], slowly catalyze reduction of CO2 to methane, ethyl formate, and traces of ethyl oxalate. 

Nickel(O) complexes are extremely effective for the dimerization and oligomerization of conjugated dienes [8,9]. Two molecules of 1,3-butadiene readily undergo oxidative cyclization with a Ni(0) metal to form bis-allylnickel species. Palladium(O) complexes also form bis-allylpalladium species of structural similarity (Scheme 2). The bis-allylpalladium complexes show amphiphilic reactivity and serve as an allyl cation equivalent in the presence of appropriate nucleophiles, and also serve as an allyl anion equivalent in the presence of appropriate electrophiles. Characteristically, the bis-allylnickel species is known to date only as a nucleophile toward carbonyl compounds (Eq. 1) [10,11],... 

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