Aromatic compounds copper-catalyzed

Most of the work on the C-N bond-forming crosscoupling reactions has concentrated on the formation of aromatic C-N bonds. Recent studies show that the application of cross-coupling reactions to alkenyl halides or triflates furnished enamines (Scheme 19) (for palladium-catalyzed reaction, see 28,28a-28d, and for copper-catalyzed reaction, see 28e-28g). Brookhart et al. studied the palladium-catalyzed amination of 2-triflatotropone 109 for the synthesis of 2-anilinotropone 110.28 It was found that the reaction of 109 proceeded effectively in the presence of racemic BINAP and a base. As a simple method for the synthesis of enamines, the palladium-catalyzed reactions of alkenyl bromide 111 with secondary amine were achieved under similar conditions.2841 The water-sensitive enamine 112 was isolated as pure compound after dilution with hexane and filtration through Celite. The intramolecular cyclization of /3-lactam 113, having a vinyl bromide moiety, was investigated by Mori s... 

The cyclopropanation of alkenes, alkynes, and aromatic compounds by carbenoids generated in the metal-catalyzed decomposition of diazo ketones has found widespread use as a method for carbon-carbon bond construction for many years, and intramolecular applications of these reactions have provided a useful cyclization strategy. Historically, copper metal, cuprous chloride, cupric sulfate, and other copper salts were used most commonly as catalysts for such reactions however, the superior catalytic activity of rhodium(ll) acetate dimer has recently become well-established.3 This commercially available rhodium salt exhibits high catalytic activity for the decomposition of diazo ketones even at very low catalyst substrate ratios (< 1%) and is less capricious than the old copper catalysts. We recommend the use of rhodium(ll) acetate dimer in preference to copper catalysts in all diazo ketone decomposition reactions. The present synthesis describes a typical cyclization procedure. 

Fig. 16.30. Pd(0)-catalyzed arytation of a copper acetytide at the beginning of a three-step synthesis of an ethynyt aromatic compound. Mechanistic details of the C,C coupling Step 1 formation of a complex between the catalytically active Pd(0) complex and the arylating agent. Step 2 oxidative addition of the arylating agent and formation of a Pd(II) complex with a cr-bonded aryl moiety. Step 3 formation of a Cu-acetylide. Step 4 trans-metalation the alkynyl-Pd compound is formed from the alkynyl-Cu compound via ligand exchange. Step 5 reductive elimination to form the -complex of the arylated alkyne. Step 6 decomposition of the complex into the coupling product and the unsaturated Pd(0) species, which reenters the catalytic cycle anew with step 1.

Hagenmaier H, Brunner H, Haag R, Kraft M (1987b), Environ. Sci. Technol. 21 1085-1088. Copper-catalyzed dechlorination/hydrogenation of polychlorinated dibenzo-p-dioxins, polychlorinated dibenzofurans, and chlorinated aromatic compounds"... 

Since then, experiments have been reported which indicate that (1) organocopper compounds will couple with aryl halides (2) arylcopper compounds can be oxidatively and thermally dimerized (3) arylcopper compounds are intermediates in the Ullmann reaction (4) organocopper compounds are intermediates in copper-catalyzed decarboxylations and (5) copper-promoted coupling reactions are not restricted to aromatic halides. The copper(I) oxide-promoted coupling reactions, however, have still to yield firm evidence of a copper intermediate. 

An elegant method for linking terminal alkynes with aromatic compounds and olefins is the Sonogashira reaction [15]. The palladium-catalyzed reaction enables the simultaneous introduction of two or even more alkyne units and thereby makes it possible to synthesize acetylene derivatives, for example hexaalkynyl-benzenes [16], (eq. (7)), which can be obtained only with difficulty by other methods. It has been shown by Herrmann, Beller, and co-workers that the copper reagent is not necessary as a co-catalyst for the coupling of terminal alkynes with sp -carbon halides. By using phosphapalladacyclic catalysts 1 the... 

A new method, recently developed at DuPont [81], is based on the copper-catalyzed oxidative fluorination of aromatic compounds with hydrofluoric acid in the presence of oxygen (Scheme 2.31). 

Laccases (benzenediohoxygen oxidoreductases, EC 1.10.3.2) are a diverse group of multi-copper enzymes, which catalyze oxidation of a variety of aromatic compounds. Laccases oxidize their substrates by a one-electron transfer mechanism. They use molecular oxygen as the electron acceptor. The substrate loses a single electron and usually forms a firee radical. The unstable radical may undergo further laccase-catalysed oxidation or non-enzymatic reactions including hydration, disproportionation, and polymerisation. ... 

One group of nucleophilic aromatic substitution processes does not fit mechanistically into the previous categories. This group is a series of copper-catalyzed displacements of aromatic halogen compounds. 

Poly(phenylene oxides) are produced by the oxidative coupling of 2,6-disubstituted phenols. The polymers are also known as poly(oxyphenylenes) or poly(phenyl ethers), and, in the case of dimethyl compounds, also as poly(xylenols). Copper (I) salts in the form of their complexes with amines catalyze the reaction. Primary and secondary aliphatic amines must be used at low temperatures, since otherwise they are oxidized. Primary aromatic amines are oxidized to azo compounds, and secondary aromatic compounds probably to hydrazo compounds. Pyridine is very suitable. 

The Fukuyama synthesis commenced with the copper-catalyzed asymmetric reduction of butenolide 26 to give lactone 27 in 98% enantiomeric excess (Scheme 9). Sequential alkylation with CbzCl followed by methyl acrylate provided lactone 28 and installed both of the required contiguous stereocenters. The key Curtius rearrangement was performed by conversion of the benzyl ester to the acyl azide followed by heating. Subsequent treatment with aqueous HCI provided cyclized lactam 8. This compound was then dibromi-nated to lactam 29 using bromine, ZnCl2, and formic acid, which were the only conditions that were able to introduce the orf/to-bromine. The fully elaborated aromatic compound 29 was treated with methylamine followed by PDC to obtain cyclic A -methylimide 23. 

The following discussion focuses on the synthesis of aromatic heterocycles where a key palladium- or copper-catalyzed aryl halide (or equivalent) amination, etherification or thioetherification process is employed. Annulative routes utilizing anilines and related compounds with alkynes (Larock type) are also considered. Routes that do not lead to aromatic products or that rely on the functionalization of preexisting heterocycles have been discounted. Similarly, the synthesis of heterocycles via TT-allylpalladium chemistry or intramolecular cyclization of palladium Tr-olefin and TT-alkyne complexes is not featured. The discussion is structured predominantly around the type of bond being formed (C—N, C—O, or C—S) and is classified further by heterocycle type. Intramolecular and intermolecular C—X bond formations as well as tandem catalytic processes leading to aromatic heterocycle products are all discussed. 

In 2005, Saito et al. described the nitration of aryl halides catalyzed by 5% of copper bronze, using tetra-n-butylammonium nitrite as a nitrating agent and the DMEDA L26 as ligand [264]. This efficient system, which offers the aromatic nitro compounds in fair to excellent yields, constitutes an interesting alternative to the traditional more drastic industrial method involving the electrophilic nitration of aromatic compounds (Scheme 22). 

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