Palladium silyl complexes

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]. 

The mechanism for the reaction catalyzed by cationic palladium complexes (Scheme 24) differs from that proposed for early transition metal complexes, as well as from that suggested for the reaction shown in Eq. 17. For this catalyst system, the alkene substrate inserts into a Pd - Si bond a rather than a Pd-H bond [63]. Hydrosilylation of methylpalladium complex 100 then provides methane and palladium silyl species 112 (Scheme 24). Complex 112 coordinates to and inserts into the least substituted olefin regioselectively and irreversibly to provide 113 after coordination of the second alkene. Insertion into the second alkene through a boat-like transition state leads to trans cyclopentane 114, and o-bond metathesis (or oxidative addition/reductive elimination) leads to the observed trans stereochemistry of product 101a with regeneration of 112 [69]. 

Palladium dimethylsilanedithiolato complex is a precursor for Ti—Pd and Ti—Pd2 heterometal-lic complexes.311 The bis-silyl sulfides (R3Si)2S have been widely used to prepare a variety of metal sulfide clusters, because these reagents exploit the strength of the Si—O and Si—Cl bond to... 

The palladium-isocyanide complex is effective for silastannation of ethoxyethyne, a labile alkyne, to produce (Z)-1-ethoxy-l-silyl-2-stannylethene with high regioselectivity (Equation (106)).253 The regioselectivity observed has also been studied by computation.263... 

A thermodynamically stable (silyl)(stannyl)palladium(n) complex is synthesized by an oxidative addition of the Si-Sn linkage to palladium(O) (Scheme 63).267 The complex has the square-planar geometry with a m-arrangement of the silicon and tin atoms. An alkyne reacts with the complex to afford a silastannated product as a mixture of cisjtrans stereoisomers (10 1). 

Hydrosilylation of o-allylstyrene (82) with trichlorosilane in the presence of 0.3mol% of a palladium catalyst bearing triphenylphosphine has been found to produce a mixture of indane (83) and the open-chain products (84) and (85) (Scheme 11). The reaction of styrene with trichlorosilane gave a quantitative yield of 1-phenyl-l-(trichlorosilyl)ethane whereas allylbenzene did not give silylation products under the same reaction conditions. These results show that the hydropalladation process is operative in the hydrosilylation of styrene derivatives with trichlorosilane catalysed by palladium-phosphine complexes." ... 

Metal chemical shifts have not found extensive use in relation to structural problems in catalysis. This is partially due to the relatively poor sensitivity of many (but not all) spin 1=1/2 metals. The most interesting exception concerns Pt, which is 33.7% abundant and possesses a relatively large magnetic moment. Platinum chemistry often serves as a model for the catalytically more useful palladium. Additionally, Pt NMR, has been used in connection with the hydrosilyla-tion and hydroformylation reactions. In the former area, Roy and Taylor [82] have prepared the catalysts Pt(SiCl2Me)2(l,5-COD) and [Pt()i-Cl)(SiCl2Me)(q -l,5-COD)]2 and used Pt methods (plus Si and NMR) to characterize these and related compounds. These represent the first stable alkene platinum silyl complexes and their reactions are thought to support the often-cited Chalk-Harrod hydrosilylation mechanism. 

Palladium(0)-catalyzed a-allylation of silyl ethers is a reaction which can be carried out with ketones as well as with aldehydes91. It is highly regiospecific when applied to ketones. a-Allylations can also be performed with enol acetates using allyl carbonates in the presence of catalytic amounts of palladium(O) complexes and (tributyl)methoxytin92,93. The steric course of the reaction has not been studied systematically but a high level of diastereoselectivity is expected and possibilities for asymmetric induction by the use of chiral auxiliaries are envisaged. 

Yamamoto has proposed a mechanism for the palladium-catalyzed cyclization/hydrosilylation of enynes that accounts for the selective delivery of the silane to the more substituted C=C bond. Initial conversion of [(77 -C3H5)Pd(GOD)] [PF6] to a cationic palladium hydride species followed by complexation of the diyne could form the cationic diynylpalladium hydride intermediate Ib (Scheme 2). Hydrometallation of the less-substituted alkyne would form the palladium alkenyl alkyne complex Ilb that could undergo intramolecular carbometallation to form the palladium dienyl complex Illb. Silylative cleavage of the Pd-G bond, perhaps via cr-bond metathesis, would then release the silylated diene with regeneration of a palladium hydride species (Scheme 2). 

Similarly, vinylstannanes can also yield products of cine-substitution (Scheme 8.17), specially if tin and an electron-withdrawing or aryl group are bound to the same carbon atom [40, 137-141]. It has been suggested that formation of these products proceeds via intermediate formation of a palladium carbene complex [138, 140] or via reversible /3-hydride elimination [141], and can be avoided by addition of Cu(I) salts [142], which increase the rate of Stille coupling, or by protecting vinylic C-H groups by transient silylation [143]. 

The imines 12 (X = 4-CH3-QH4-SO2 (Ts), Ar, C02R, COR, etc.) preformed or generated in situ from N,0- or N,N-acetals or hemiacetals are another important class of Mannich reagents frequently used for diastereo- and/or enantioselective aminoalkylation reactions catalyzed by chiral Lewis acids (usually copper or palladium BINAP complexes such as 13). Among other things excellent results were obtained in the aminoalkylation of silyl enol ethers or ketene acetals [24], A typical example is the synthesis of Mannich bases 14 depicted in Scheme 5 [24b], Because of their comparatively high electrophilicity imines 12 could even be used successfully for the asymmetric aminoalkylation of unactivated alkenes 15 (ene reactions, see Scheme 5) [24h, 25], and the diastereo- and/or enantioselective aminoalkyla-... 

Lewis acid catalysts activate the aldehyde by coordination to the carbonyl oxygen. Shibasaki et al. [13] were able to demon,strate that the activation of the enol ether is possible too. The reaction of the aldehyde 37 with the silyl enol ether 38 in the presence of the catalyst 39 proceeds with good, but still not excellent enantioselectivity to yield the aldol adduct 40. Only 5 mol % of the chiral palladium(II) complex 39 was used (Scheme 6a). Activation of the Pd(lI)-BINAP complex 39 by AgOTf is necessary. Therefore, addition of a small amount of water is important. 

Organometallic complexes of PdIV were almost unknown until a few years ago. They are however accessible by the oxidative addition of Mel or PhCH2Br to palladium dialkyl complexes stabilized by nitrogen ligands such as bipy. Most are thermally sensitive and reductively eliminate R—Me at room temperature.49 The first PdIV silyl complex was obtained in a clean methyl exchange reaction between (dmpe)PdMe2 and l -QH SiFI the compound is thermally remarkably stable.50... 

Figure 22-4 Mechanism for the hydrosilylation and dehydrogenative silylation of 1-alkenes catalyzed by cationic palladium complexes Pd represents [(phen)Pd]+. The palladium alkene complex A is the resting state of the cycle. Cycle I denotes the hydrosilylation cycle, Cycle II describes the dehydrogenative silylation reaction.

The cross-coupling reaction of alkenyl(fluoro)silanes with aryl halides sometimes produces, in addition to the desired ipso-cowpled products, small amounts of cmc-coupled products [14]. The czne-coupling is often striking in the reaction with organotin compounds. The isomer ratio of products produced by the reaction of l-fluoro(dimethyl)silyl-l-phenylethene with aryl iodides is found to depend on the electronic nature of a substituent on aryl iodides (Eq. 11) an electron-withdrawing group like trifluoromethyl and acetyl favors the formation of the ipso-coupled product. To explain the substituent effect, the mechanism depicted in Scheme 3 is proposed for the transmetalation of alkenylsilanes with palladium(ll) complexes. It is considered that an electron-donating substituent on Ar enhances... 

Cationic Pd complexes can be applied to the asymmetric aldol reaction. Shibasaki and coworkers reported that (/ )-BINAP PdCP, generated from a 1 1 mixture of (i )-BINAP PdCl2 and AgOTf in wet DMF, is an effective chiral catalyst for asymmetric aldol addition of silyl enol ethers to aldehydes [63]. For instance, treatment of trimethylsi-lyl enol ether of acetophenone 49 with benzaldehyde under the influence of 5 mol % of this catalyst affords the trimethylsilyl ether of aldol adduct 113 (87 % yield, 71 % ee) and desilylated product 114 (9 % yield, 73 % ee) as shown in Sch. 31. They later prepared chiral palladium diaquo complexes 115 and 116 from (7 )-BINAP PdCl2 and (i )-p-Tol-BINAP PdCl2, respectively, by reaction with 2 equiv. AgBF4 in wet acetone [64]. These complexes are tolerant of air and moisture, and afford similar reactivity and enantioselec-tivity in the aldol condensation of 49 and benzaldehyde. Sodeoka and coworkers have recently developed enantioselective Mannich-type reactions of silyl enol ethers with imi-nes catalyzed by binuclear -hydroxo palladium(II) complexes 117 and 118 derived from the diaquo complexes 115 and 116 [65]. These reactions are believed to proceed via a chiral palladium(fl) enolate. 

Palladium-catalyzed reductive silylation has also been reported. The cathodic reduction of allylic acetates in the presence of silylating agents and a catalytic amount of (Ph3P)4Pd [53] gives the corresponding allylsilanes. The initially formed rr-allyl-palladium(II) complex seems to be reduced at the cathode to generate the allyl anion intermediate, which reacts with chlorosilane to give the final product. 

Oxidative addition of Si-Si bonds onto palladium(O) has long been presumed to be involved in a number of palladium-catalyzed bis-silylation reactions of unsaturated carbon compounds. The oxidative addition and its reverse reaction, i.e., reductive elimination, may be in rapid equilibrium, whose direction is influenced by the structure of disilanes and ligands on the palladium atom. In spite of early reports on the formation of bis(organosilyl)palladium(II) complexes [14,15], a well-characterized complex was first synthesized in 1992 by reaction of hydro disilanes with hydridepalladium complex, probably through initial activation of Si-H bond followed by silylene migration (see Sect. 2.3) [16]. Since... 

Reaction of bis(disilanyl)dithiane 32 with the corresponding palladium(O)-isonitrile complex affords a four-membered cyclic bis(silyl)palladium(II) complex 34 quantitatively together with the formation of a disilane (Eq. 15) [30]. The formal intramolecular metathesis of the two Si-Si bonds of 32 may proceed through initial formation of tetrakis(silyl)Pd(IV) complex, corresponding to the platinum complex 33. The double oxidative addition of the two Si-Si bonds may be followed by reductive elimination of the disilane with accompanying formation of four-membered bis(silyl)palladium complex 34, due to difficulty in reductive elimination leading to formation of a three-membered cyclic disilane. 

Palladium-phosphine complexes catalyze the similar 1,4-bis-silylation with the activated disilanes. In the presence of palladium-PPh3 complexes, fluoro-[55] and chloro-disilanes [56] provide 1,4-products 59 in good yields with high stereoselectivity giving Z-alkenes (Eq. 27). In the reaction of fluorinated disilane with isoprene, a minor amount of 1 2 adduct 60, which arises from regioselective... 

If the electrophile is a vinyl triflate, it is essential to add LiCl to the reaction so that the chloride may displace triflate from the palladium o-complex. Transmetallation takes place with chloride on palladium but not with triflate. This famous example illustrates the similar regioselectivity of enol triflate formation from ketones to that of silyl enol ether formation discussed in chapter 3. Kinetic conditions give the less 198 and thermodynamic conditions the more highly substituted 195 triflate. 

The success of this carboxylative trimethylenemethane cycloaddition extends to the addition to cyclohexenone. In contrast to the poorly yielding process involving the unsubstituted TMM -Pd complex, a respectable yield of 49 % is obtained here. This is explained by the reduced basicity of the silylated complex, thus leading to fewer side reactions. The reaction is also considered to have a greater degree of concertedness and this becomes apparent in the discussion of chiral Z- and f-olefins in Section 1.6.1.2.3.2. The failure of in situ derived palladium complexes to yield the desired product is attributed to the basic conditions employed which result in double-bond migrations to the endocyclic, conjugated system. 

Certain transition-metal salts were also found to catalyze the apparent 1,6-ECRC. For example, thermolysis of silyl ether 74 (R1 = R2 = H) in toluene solution at 110°C (7 d) affords only a modest yield of enone 76. Attempts to cyclize the potassium enolate corresponding to 74 were also unsuccessful. However, treatment of 74 with substoichiometric amounts of a palladium(II) complex, bis(trifurany]phosphane)palladium dichloride [Pd(PFu3)2Cl ], in toluene (110 °C, 72 h) affords enone 76 in 84% yield. Substitution at R1 is detrimental, but butyl and phenyl substituents at R2 afford -substituted 76 in comparable yields. (Triphenylphos-phane)ruthenium dichloride [Ru(PPh3)Cl2] can be used in place of the palladium salt. 

In a useful extension of the chemistry of the palladium (0) complexed trimethylenemethane moiety, Trost has described the formation of (24) from the bis-silyl compound (23). Even in the presence of an enone this complex is alkylated with the carbonate (25) produced in the first step, and then a second zwitterion is formed for reaction with an enone in a [3+2] cycloaddition (Scheme 5). The same research group has described an approach to brefeldin-A which uses the above [3+2] cycloaddition strategy to generate three contiguous stereocentres of correct absolute and... 

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