Palladium acetate alkylations

Dimethyl-1,2,4-triazolium iodide with palladium acetate yields the carbene adduct 182 (97JOM(530)259). Under water it undergoes cis-trans isomerization to 183. Some other derivatives were reported in 1981 (81BCSJ800). 1,1 -Methylenebis(4-alkyl-l,2,4-triazolium)diiodides (alkyl = /-Pr, n-Bu, octyl) with palladium(II) acetate give the mononuclear complexes [L Pdl ] (99EJIC1965), where L2= l,l -methylenebis(4-R-l,2,4-triazol-2-ylidene) (R = /-Pr, n-Bu, octyl). Thermolysis of the products in THF gives the rran -dinuclear complexes 184... 

Several palladium catalysts for formation of aryl sulfides from aryl halides have been investigated more recently. A combination of Pd2(dba)3 and DPEphos catalyzed the formation of a broad range of diaryl sulfides in the presence of 1 mol.% palladium and NaO-t-Bu base in toluene solvent.12,rThe highest yields of alkyl aryl sulfides were obtained from aryl triflates and n-butyl thiol catalyzed by a combination of palladium acetate and BINAP. However, these reactions contained 10 mol.% catalyst, were long, and required deactivated aryl triflates. A combination of Pd2(dba)3 and DPPF catalyzed the coupling of thiols with resin-bound aryl halides.121... 

TABLE 8.34. PALLADIUM-CATALYZED ALKYLATION OF DTPHFNYT AT.TYT. ACETATE WITH DIMETHYL MALONATE... 

TABLE 8.35 PALLADIUM-CATALYZED ALKYLATION OF DIMF.THYT AT T YT. ACETATE AND DIMETHYLALLYL l-BUTYLCARBONATE WITH DIMETHYL MALONATE, 490... 

By using an olefin embedded into the parent molecule Stoltz developed the oxidative annulation of indoles. The optimal catalyst consisted of palladium acetate and ethyl nicotinate, and molecular oxygen was used as the oxidant in the process. The reaction proceeded equally well irrespective of the attachment point of the alkyl chain bearing the pendant olefin bond on the five membered ring, and the formation of five and six membered rings were both effective (6.95.),127... 

The telomerization of sucrose with butadiene was catalyzed in aqueous solution by palladium acetate and tppts (102). The sucrose conversion was about 96%, but octadienyl ethers of different degrees of alkylation were also formed. 

In contrast, the closely related palladium acetate-promoted intramolecular alkylation of alkenes by tri-methylsilyl enol ethers (Scheme 4)6,7 has been used to synthesize a large number of bridged carbocyclic systems (Table 1). In principle, this process should be capable of being made catalytic in palladium(II), since silyl enol ethers are stable to a range of oxidants used to carry the Pd° -> Pd11 redox chemistry required for catalysis. In practice, catalytically efficient conditions have not yet been developed, and the reaction is usually carried out using a full equivalent of palladium(II) acetate. This chemistry has been used in the synthesis of quadrone (equation 2).8 With the more electrophilic palladium(II) trifluoroace-tate, methyl enol ethers underwent this cyclization process (equation 3).9... 

Experimental KTEs and theory were used to investigate the mechanism of the palladium-catalysed alkylation of 1,1-dimethylallyl acetate (2) by dimethyl malonate.6 The transition structure in THF is believed to have long Pd-C bonds and significant Sn 1 character, as described earlier. 

Palladium/silver-catalyzed Heck reactions have usually involved vinyl or aryl halides and alkenes, but these reaction conditions were also extended to allenes. Indeed, Zenner and Larock65 showed that simple alkyl allenes readily reacted with aryl and vinyl iodide derivatives in the presence of palladium acetate or chloride and silver phosphate. Moreover, the reaction could be rendered asymmetric using chiral ligands the best one was a bisoxazolidine derivative (Scheme 10.37). 

The details of the cupric salt reaction with the palladium adduct are not clear. Exchange to form a cupric alkyl is one possibility or complex formation,"probably with chloride bridges between the palladium adduct and cupric chloride, may occur with subsequent anion shift from palladium to carbon or perhaps an Sn2 displacement of the complex metal group by an anion may occur. Rearrangements producing 1,3 and 1,4 substituted products from linear olefins have also been observed. For example, 1-butene produced several percent of 1,3- and 1,4-chloro acetates and diacetates under the reaction conditions used 16>. "Hydrido-palladium acetate or chloride" -complexes would seem to be likely intermediates in these arrangements. 

When the reactions were carried out in acetonitrile with palladium acetate or in methanol with palladium chloride/triethylamine with other phenyl alkyl telluriums, the yields of alkanecarboxylic acids never exceeded 8%l. 

The new binaphthyl ligands 49 [22] and 50 [23] have led to a breakthrough in the copper catalyzed 1,4-addition of organozinc reagents to a,jff-unsatu-rated ketones, a reaction which has proved to be difficult if carried out enantioselectively. Selectivities up to 96 % ee have been reached with cyclic substrates, while acyclic substrates still leave room for further improvement. 50 has also been successfully employed in palladium-catalyzed alkylations of allyl acetates [24]. 

The isomerization of allylic acetates can be a problem during palladium-catalyzed alkylation of these substrates, but can be circumvented by use of the lactone of the corresponding hydroxy acid (equation 11),... 

In a finding of greater practical significance. Overman and coworicers showed that the reactions could be carried out with catalytic amounts of the palladium(II) complex, and that the catalytic effect was broadly applicable to acyclic 1,5-dienes as well7 In a typical example (equation 32), 2-methyl-3-phe-nyl-l,5-hexadiene rearranges in 1 h at room temperature in 87% yield in the presence of 0.06 equiv. of bis(benzonitrile)palladium dichloride, in contrast to the thermal rearrangement which has t n = 13 h at 177 °C. The cat yst thus provides an estimated rate acceleration of about 10 °. The product is a 93 7 mixture of ( )- and (Z)-isomers, corresponding to the equilibrium ratio. Palladium acetate and tetra-kis(triphenylphosphine) were ineffective as catalysts. One serious limitation is that the catalyzed reaction occurs only with those 1,5-dienes which possess an alkyl or aryl substituent at C-2 or C-5 (but not both). 

Alkenyl, Alkynyl, Aryl and Heteroaryl Acids. Treatment of readily accessible (E)- and (Z)-alkyl and aryl substituted vinyl boronates (196) with triethyl phosphite in the presence of lead diacetate results in their stereospecific transformation into (E)- and (Z)-vinylphosphonates (197) (Scheme 53). ° Palladium acetate catalysed Mizoroki-Heck reaction of arylboronic acids (198) with diethyl vinylphosphonates (199) is an effective synthetic approach to... 

Cu(N03)2. Alkyl- and aryllithium compounds can be dimerized by transition-metal halides in a reaction similar to 14-24. Triarylbismuth compounds ArsBi react with palladium(O) complexes to give biaryls ArAr. Diethylzinc reacted with Ph2l BF4 in the presence of palladium acetate, to give biphenyl. ... 

Alkylation of sodium 1-(alkoxycarbonyl)methyIphosphonates proceeds equally with acetates in THF from low to room temperature or in DME at reflux. The asymmetric allylic alkylation of the sodium diethyl l-(ethoxycarbonyl)methylphosphonate with 3-acetoxy-l,3-diphenyl-l-propene and cyclic allylic acetates in the presence of a chiral palladium catalyst, prepared from chiral phosphine and palladium acetate, in THF at room temperature proceeds in good yields (44-88%) and high ec s. ... 

Although there are numerous methods for the protection and deprotection of diacetyl acetals, these are rarely used in synthesis as protective groups, but have been used as starting materials for palladium-catalyzed alkylations. ... 

The intermediate 591a was also used in a synthesis of tabersonine. Alkylation of 591a by Z-l,3-di-iodopropene followed by elimination of the phenylselenyl group gave a ring C diene 594, which was cyclized by a reductive Heck reaction with palladium acetate, sodium formate, triphenyl-phosphine, and base, with formation of tabersonine (78) in 43% yield (Scheme 77) (346). 

In 1984, Tremont described a procedure for palladium acetate-promoted anilide alkylation by alkyl iodides [45, 46], He suggested that the reaction proceeds by either a Pd(II)-Pd(IV) catalytic cycle or a sigma-bond metathesis mechanism. A possible Pd(II)-Pd(IV) catalytic cycle is presented in Scheme 8. 

DIYL)BIS[(4S)-4-PHENYL-2-OXAZOLINE] AS A LIGAND FOR ASYMMETRIC PALLADIUM-CATALYSED ALKYLATION OF ALLYLIC ACETATES IN FLUOROUS MEDIA... 

Table 5. Chemoselectivity with Palladium-Promoted Alkylation of Functionalized Cyclic Allyl Acetates with Soft Carbanions...

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