Palladium 2- phenyl groups

A more expected difference between platinum oxide and palladium-on-carbon was found in the hydrogenolysis of 5-phenyI-2-(3,4-dimethoxybenzyI)-2-oxazoline. Cleavage occurred at the benzyl-oxygen bond over both catalysts, but over platinum, the less substituted phenyl group was saturated as well (78). 

The palladium-catalyzed arylation of 2-phenylphenols and naphthols shows an interesting feature of arylation of C-H bonds, leading to the formation of an (aryl)(aryloxy)palladium(n) intermediate.65,65a,65b The phenolates are suitable as precoordinating groups. The reaction of 2-hydroxybiphenyl with an excess of iodobenzene occurs regioselectively at the two ortho-positions of phenyl group under palladium catalysis (Equation (57)). In the case of 1-naphthol, the peri-position is phenylated (Equation (58)). 

The use of cyclic alkenes as substrates or the preparation of cyclic structures in the Heck reaction allows an asymmetric variation of the Heck reaction. An example of an intermolecular process is the addition of arenes to 1,2-dihydro furan using BINAP as the ligand, reported by Hayashi [23], Since the addition of palladium-aryl occurs in a syn fashion to a cyclic compound, the 13-hydride elimination cannot take place at the carbon that carries the phenyl group just added (carbon 1), and therefore it takes place at the carbon atom at the other side of palladium (carbon 3). The normal Heck products would not be chiral because an alkene is formed at the position where the aryl group is added. A side-reaction that occurs is the isomerisation of the alkene. Figure 13.20 illustrates this, omitting catalyst details and isomerisation products. 

Phosphoric acids 3 bearing different aromatic substituents at the 3,3 -positions can be synthesized in a few steps starting from commercially available BINOL (6) (Scheme 3). The key step involves a palladium-catalyzed cross-coupling of boronic acid 7 and the respective aryl halide. Both the electronic and steric properties of potential catalyst 3 can be tuned by a proper choice of the substituents at the 3,3 -positions. Besides a simple phenyl group, Akiyama et al. introduced monosubsti-tuted phenyl derivatives as well as a mesityl group, whereas Terada and coworkers focused on substituents such as biphenyl or 4-(2-naphthyl)-phenyl. 

The intermolecular carbopalladation of a triple bond can be faster than that of an intramolecular double bond as, for example, in the (9-iodo(l-methylallyl)benzene 152. The arylpalladium iodide initially formed from 152 and a palladium(O) species intermolecularly carbopalladates diphenylacetylene 71, and only the thus formed alkenylpalla-dium intermediate 153 undergoes insertion into the internal double bond to furnish the neopentylpalladium species 154 which, by <9r/ (9-attack on the adjacent phenyl group, finally forms the tetracyclic system 155. ... 

The silyl group in 311, prepared by intramolecular silylformylation, is intermolecularly substituted by a phenyl group by a palladium-catalyzed reaction with Phi to give coupled product 312 (Equation (56)). ... 

A more recent synthesis for (14-9) takes quite a different course. The first step comprises the displacement of one of the halogens in 1,4-dibromobenzene by the alkoxide from A-2-hydroxyethylpyrrolidine (15-2) in the presence of 18-crown ether to afford (15-3). Condensation of the lithium salt from (15-3) with 6-methoxy-tetralone (15-4) followed by dehydration of the initially formed carbinol give the intermediate (15-5), which incorporates the important basic ether. Reaction of that compound with pridinium bromide perbromide leads to the displacement of the vinylic proton by halogen and the formation of bromide (15-6). Condensation of that product with phenylboronic acid in the presence of a tetrakistriphenyl-phosphine palladium catalyst leads to the coupling of the phenyl group by the formal displacement of bromine. The product (14-9) is then taken on to lasoxifene (14-11) as above [16]. 

By contrast, for iodide 18 having the triple bond activated by a phenyl group, conversion to the cyclic organozinc species 25 occurred effectively and the latter could be efficiently functionalized, provided that traces of moisture were excluded by pre-treatment of zinc powder with Mel. The substituted benzylidene cyclopentanes 26 and 27 were respectively obtained after iodinolysis and palladium-catalyzed cross-coupling reaction with benzoyl chloride (equation 10). However, it could not be assessed whether the formation of organozinc 25 was attributable to an anionic or a radical cyclization pathway (or both) as, had iodide 26 been produced by a radical iodine atom-transfer, it would have been converted to 25 by reaction with metallic zinc due to the presence of the activating phenyl group21. 

Although the phenyl group does not appear to provide sufficient activation when the nickel complex is used, it does activate the disilane in a system involving a palladium complex, as reported by Tsuji and co-workers in 1992.50 Under carbon monoxide pressure, which is required to maintain... 

The authors propose that the influence of the phenyl group is not an electronic effect, as no product formation is observed with palladium catalysts known to be highly active in disilane systems substituted with electronegative elements. Rather, the phenyl group may allow for precoordination via a w-arene complex, which would accelerate the oxidative addition of an Si-Si bond to platinum, a key step in the proposed catalytic cycle. 

Backwall and coworkers have extensively studied the stereochemistry of nucleophilic additions on 7r-alkenic and ir-allylic palladium(II) complexes. They concluded that nucleophiles which preferentially undergo a trans external attack are hard bases such as amines, water, alcohols, acetate and stabilized carbanions such as /3-diketonates. In contrast, soft bases are nonstabilized carbanions such as methyl or phenyl groups and undergo a cis internal nucleophilic attack at the coordinated substrate.398,399 The pseudocyclic alkylperoxypalladation procedure occurring in the ketonization of terminal alkenes by [RCC PdOOBu1], complexes (see Section 61.3.2.2.2)42 belongs to internal cis addition processes, as well as the oxidation of complexed alkenes by coordinated nitro ligands (vide in/ra).396,397... 

Benzyl chloride reacts easily with methyl acrylate in the presence of tri-n-butylamine and palladium acetate (1 mol %) as catalyst.51 The product is a mixture of (E)-methyl 4-phenyl-3-butenoate (67%) and (E)-methyl 4-phenyl-2-butenoate (9%), arising from elimination-addition reactions of the palladium hydride group which largely isomerize the initial elimination product. 

A sterically demanding group at one terminus of the allyl moiety blocks the incoming nucleophile in palladium-catalyzed allylic substitutions. The Mc Si group in 161 can fulfil such a purpose and prevails over the phenyl group as a controlling element in the... 

The benzyl and phenyl groups were removed by hydro-genolysis over palladium and platinum catalysts, respectively, and the acetyl groups by treatment with ammonia in methanol. In this case too, the monoammonium salt of the phosphorylated disaccharide 2 was isolated physical and chemical parameters of the compounds obtained by both methods were identical. 

Complex 49 catalyzes, among other reactions, the addition of morpholine to methylacrylonitrile giving the amination product with modest selectivity (37% ee) (Scheme 35). In order to obtain catalytically active species with palladium, complex 48 was converted into dicationic derivatives of the general type [Pd(NCCH3)(PCP)](PF6)2. Using this catalyst, the addition of morpholine to methylacrylonitrile could be achieved with 47% ee. Further improvement in selectivity was obtained by the introduction of methyl substituents at the 3- and 5-positions of the phenyl groups in diphenylphosphanyl derivative leading to ee s of over 70% [94]. 

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