Benzene phenyl-palladium

Highly selective formation of phenyl acetate was observed in the oxidation of benzene with palladium promoted by heteropoly acids.694 Lead tatraacetate, in contrast, usually produces acetoxylated aromatics in low yields due to side reac-tions. Electrochemical acetoxylation of benzene and its derivatives and alkoxylation of polycyclic aromatics789 790 are also possible. Thermal or photochemical decomposition of diacyl peroxides, when carried out in the presence of polycyclic aromatic compounds, results in ring acyloxylation.688 The less reactive... 

Hydrogenation of 5-chloro-3-methy 1-6-phenyl-1,2,4-triazine (73) in benzene over palladium in the presence of triethylamine afforded the dechlorinated product (74) <85H(23)2807). The reduction of chloro-l,2,4-triazines, mainly by catalytic means, has been used for the synthesis of a variety of 1,2,4-triazines <76CB 1113 >. 

Dinuclear palladium complexes catalyze m-hydroarylation of alkynes with arenes.56 The reaction of 3-hexyne with benzene in the presence of a dinulear palladium complex Pd2R2(M-OH)(//-dpfam) [dpfam = j/V,Ar -bis[2-(diphenyl-phosphino)phenyl]formamidinate, R=/>-Tol] and tri(/z-butyl)borane at 100 °C for 4h affords ( )-3-phenyl-3-hexene quantitatively (Equation (53)). The hydroarylation of 3-hexyne with monosubstituted benzenes ( )-3-aryl-3-hexenes with a 2 1 ratio of the meta- and ra -isomers. This regioselectivity is different from that of the hydroarylation of diphenylacetylene catalyzed by Rh4(GO)12.57... 

Benzyne, which is generated in situ from 2-(trimethylsilyl)phenyl triflate and KF, acts as an alkyne congener in distannation in the presence of palladium-/ r/-alkyl isocyanide complex.157 A variety of substituted benzyne derivatives inserts into the Sn-Sn bond to give l,2-bis(stannyl)benzenes (Equation (59)). The reaction fails to occur in the presence of other palladium catalysts such as Pd(PPh3)4. 

DMA in 500 ml ether mix rapidly with 270 ml 0.9 M phenyl-Li, boil fifteen hours and extract as for (VI) or as described previously to get 8 g oily 4-methoxy-indoline (or its 1-methyl derivative) (VII). Alternatively, add 36 g naphthalene to 300 ml tetrahydrofuran and add 11 g Na metal cut in small pieces. Reflux and stir three hours and add 18 g (VI) and 8 g DEA in 200 ml tetrahydrofuran rapidly and boil twelve hours. Evaporate in vacuum, dissolve the oily residue in 2N HCI and extract with ether. Proceed as described to get (VII). 4 g (VII) in 200 ml dry pyridine add to 6 g Cu chloride in 400 ml pyridine and reflux 1 xh hours. Pour on water and extract with ether. Wash extract with 4N HCI and then water and dry and evaporate in vacuum the ether to get 2 g of the indole (VIII). Alternatively, dissolve 4 g (VII) and 9.5 g cinnamic acid in 700 ml mesitylene, add 1 g 5% palladium-carbon and reflux five hours. Filter, wash with HCI and NaHC03 and dry and evaporate in vacuum the mesitylene to get the red, oily (VIII) (can chromatograph on alumina and elute with benzene-petroleum ether). 

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. ... 

A few experiments have been tried with conjugated dienes in the substitution reaction. Preliminary results indicate that they too may react normally. Using palladium acetate in a stoichiometric reaction, benzene and butadiene were found to form 1-phenylbutadiene in about 25% yield (41). Iodobenzene and isoprene react with triethylamine and Pd(PPh3)2(OAc)2 as catalyst at 100° to form ( )-3-methyl-l-phenyl-1, 3-butadiene in 52% yield (42) ... 

Silver acetate has a small catalytic effect on the alkene substitution reaction but 5 equiv. of the salt only give 140% of stilbene in the styrene phenylation, based upon palladium.15 The same reaction carried out at 80 C under 300 lbf in-2 (1 lbf in-2 = 6.89 kPa) of oxygen gives stilbene in 248% yield, based upon palladium.16 The best reoxidation reagent is f-butyl perbenzoate, which yields 10-14 turnovers of the palladium in the vinyl substitution of cinnamaldehyde and similar alkenes with benzene.17... 

The benzene derivatives containing the fluorinated sulfone have been prepared either by nucleophilic substitution of the 4-fluorophenyl derivative (e.g. 1) or by starting with the appropriately substituted sodium thiophenoxide and reacting with perfluoroalkyl iodide follow by oxidation with either MCPBA or chromium oxide (12. li.) The biphenyl derivatives have been prepared by palladium catalyzed cross coupling chemistry of the 4-bromophenyl derivative (e.g. 2) with substituted phenyl boronic acid (yields 37-84%) (JLH, .). Compound 16 has been prepared by palladium catalyzed cross coupling of (4-bromophenyl)perfluorohexyl sulfone with vinyl anisole in 37 % yield (JJL). The vinyl sulfones, 7 and 9, have been prepared by condensation of CH3S02Rf (JJL) with the appropriate aldehyde (yields 70,and 73%) following a literature procedure (1 ). Yields were not optimized. 

Reaction of 2,3-dihydrofuran with aryl triflate in benzene in the presence of a base and a palladium catalyst, prepared in situ from Pd(OAc)2 and 2 equivalents of (R)-BINAP, gave (R)-2-aryl-2,3-dihydrofuran (2) and a small amount of the regioisomer (5)-2-aryl-2,3-dihydrofuran (3) (Scheme 1). Table I demonstrates that the arylation reaction proceeds in extremely high enantioselectivity with a variety of aryl triflates. Particularly, almost enantiomerically pure (R)-2 was obtained with 2-naphthyl triflate and phenyl triflates bearing an electron-withdrawing substituent at the para or meta position. 

Hydrogenation of cinnamaldehyde to 3-phenylpropionaldehyde over palladium catalyst may be accompanied by the formation of 3-phenyl-1-propanol and propyl-benzene,218 although the formation of 3-phenylpropionaldehyde usually predominates.219,220 The composition of the products are widely affected by the nature of palladium catalysts, solvents, supports, and additives.216,221 The hydrogenation over Pd-Al203 in ethanol or over Pd-kieselguhr in acetic acid gave 3-phenylpropionalde-hyde quantitatively at room temperature and atmospheric pressure. The addition of a 1 1 ratio of ferrous chloride to palladium also resulted in quantitative formation of 3-phenylpropionaldehyde in the hydrogenation over 5% Pd-C in methanol.221 This result was contrasted with those obtained with platinum oxide where iron additives led... 

The palladium-catalyzed Sonogashira reaction between l-(2-propynyl)-l//-indole 1460 and l-iodo-2-(2-phenylethy-nyl)benzene 1461 was successful in producing 17/-indole 1462 in excellent yield (Scheme 279) <2005JOC6647>. Treatment of indole 1462 with a strong base produced 12-phenyl-7//-indeno[l, 2 4,5]pyrido[l,2- ]indole 1463 in... 

The more recent synthesis for lasoxifene (74) takes a very different course. The first step comprises displacement of one of the halogens in 1,4-dibromo-benzene by the alkoxide from A -2-hydroxyethylpyrrolidine 75 in the presence of 18-crown ether to afford 76. Condensation of the lithium salt from 76 with 6-methoxytetralone (77) followed by dehydration of the initially formed carbinol yields intermediate 78, which incorporates the important basic ether. Reaction of this compound with pridinium bromide perbromide leads to displacement of the vinylic proton by halogen and formation of the bromide 79. Condensation of this product with phenylboronic acid in the presence of a palladium catalyst leads to coupling of the phenyl group by formal displacement of bromine. The product (79), is then taken on to 74 as above. 

Just as aromatic rings are generally inert to oxidation, they re also inert to catalytic hydrogenation under conditions that reduce typical alkene double bonds. As a result, it s possible to reduce an alkene double bond selectively in the presence of an aromatic ring. I or example, 4-phenyl-3-buten-2-one is reduced to 4-phenyl-2-butanone at room temperature and atmospheric pressure using a palladium cataly st. Neither the benzene ring nor the ketone carbonyl group is affected. 

The reagent is prepared by heating the diazonium salt (1) in anhydrous benzene. It is an unstable off-white solid. The precursor (I) is prepared from 2-methoxy-2 -nitrodi-phenyl by reduction with hydrazine hydrate in the presence of palladium to give 2-amino-2 -methoxydiphenyl this product is then diazotized with sodium nitrite in... 

Several derivatives of phenols have been found to be especially suited for hydrogenolysis by catalytic hydrogenation. Phenol ethers prepared by the reaction of phenols with l-phenyl-5-chlorotetrazole or with 2-chlorobenzoxazole are hydrogenolyzed over 5% palladium on carbon or over platinum oxide, but not over Raney nickel. The hydrogenations are run at 35 °C in benzene, ethanol or tetrahydrofuran, and give 35-89% yields of the corresponding hydrocarbons. The reaction sequence is exemplified by conversion of phenylphenols to biphenyls (equation 77). 

Phenyl, vinyl or carbonyl substituted cyclopropanes are more easily hydrogenolyzed than are the alkyl substituted species. Such compounds are commonly cleaved over palladium catalysts at room temperature and atmospheric pressure. Hydrogenolyses run over platinum, rhodium or nickel catalysts frequently result in the saturation of the double bond, the benzene ring or the carbonyl group with the cyclopropane ring remaining intact or cleaved to only a slight extent. 20 As illustrated in Fig. 20.22 the bond broken in the... 

Aryl hydroxy groups have been removed by first converting them into an ether by reaction with a heterocycle such as l-phenyl-5-chlorotetrazole (61) and then hydrogenolyzing the ether with platinum or palladium (Eqn. 20.42).97-99 other aryl ether groups that are readily hydrogenolyzed to give the benzene are the benzoxazole, 62, > sulfonates, 63, and phosphates, 64. ... 

Direct arylations of arenes are, however, not restricted to palladium-catalyzed transformations, but were also accomplished with, inter alia, iridium complexes. Thus, the direct coupling of various aryl iodides with an excess of benzene in the presence of [Cp IrHCl]2 afforded the corresponding biaryl products, but usually in moderate yields only (Scheme 9.30) [69]. The reaction is believed to proceed via a radical-based mechanism with initial base-mediated reduction of iridium(III) followed by electron transfer from iridium(II) to the aryl iodide. Rather high catalyst loadings were required and the phenylation of toluene (90) under these reaction conditions provided a mixture of regioisomers 91, 92, and 93 in an overall low yield (Scheme 9.30) [69]. 

Preparation. - Fluorophosphines have been obtained from the reactions of the related chlorophosphines with trimethyl tin fluoride. Phenyl(isopropyl)-fluorophosphine has been resolved via a chiral amine-palladium(II) complex, providing the first example of the resolution of a free fluorophosphine chiral at phosphorus. This compound racemises at 20 °C in benzene solution over six hours. The neat compound rapidly decomposes by redox disproportionation. The same approach has been used for the resolution of the related chloro-phosphine, but the optically active compound could not be liberated unchanged from the crystallised diastereoisomeric palladium complex. The dihalo-genophosphines... 

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