Copper complexes conductive

The treatment of LB films of copper behenate (10-50 layers) with H2S gas resulted in formation of the semiconductor CU2S [177]. In this case, the LB films of behenic acid alone were formed and then exposed to solutions of copper chloride. Conversion of the carboxyl groups to carboxylate groups upon copper complexation was confirmed by infrared spectroscopy. Resistivity measurements versus temperature confirmed the formation of semiconducting CU2S in one case, and showed a linear increase in log(R) versus IT K). All of the samples became insulators on exposure to air maintaining the conductivity required storage under vacuum. The formation of CuiS sheets in some of the sample was concluded from optical microscopy and resistivity data. 

Asymmetric synthesis of 2,5-dimethyl-2,4-hexadiene (28) and /-menthyl diazoacetate (29) with chiral copper complexes (30) was successfully conducted by Aratani et al. [13] to afford the (1 A)-chrysanthem ic acid /-menthyl ester (31) in high optical and chemical yield. Since this finding, a lot of chiral copper complexes have been reported and applied to the asymmetric synthesis of (IR)-chrysanthemate. However, these copper complexes required more than 1 mol% of the catalyst and the cis/trans ratio still remains unsatisfactory. Moreover, /-menthyl ester was crucial for the high enantioselectivity. Given an industrial production of... 

Related to copper-containing enzymes such as laccase and tyrosinase, recent studies have been conducted on the structural characterization of the reactive species generated from molecular oxygen and copper complexes. A continuous effort has also been directed toward the efficient utilization of such oxygen-copper complexes as oxidants, in industrial processes, which will hopefully replace metal compounds such as chromate, manganate and others. 

Ohmura, K. Kijima, M. Shirakawa, H. Synthesis of conducting polymers with conjugated carbon-carbon triple bonds by electrochemical condensation of acetylene derivatives catalyzed by copper complex. Synth. Metals 1997, 84, 417-418. 

The initial studies on Pd-catalyzed C—O bond formation were conducted as intramolecular reactions to form oxygen heterocycles (Eq. 1). It is known that copper complexes will catalyze these transformations, and copper acetylide is particularly valuable for these... 

Alkynyl complexes contain metal-carbon bonds in which the metal is bound to the sp-hybridized carbon at the terminus of a metal-carbon triple bond. The materials properties of these complexes have been investigated extensively. The properties of these complexes include luminescence, optical nonlinearity, electrical conductivity, and liquid crystallinity. These properties derive largely from the extensive overlap of the metal orbitals with the ir-orbitals on the alkynyl ligand. The M-C bonds in alkynyl complexes appear to be considerably stronger than those in methyl, phenyl, or vinyl complexes. Alkynyl complexes are sometimes prepared from acetylide anions generated from terminal alkynes and lithium bases (e.g., method A in Equation 3.42), but the acidity of alkynyl C-H bonds, particularly after coordination of the alkyne to the transition metal, makes it possible to form alkynyl complexes from alkynes and relatively weak bases (e.g., method B in Equation 3.42). Alkynyl copper complexes are easily prepared and often used to make alkynylnickel, -palladium, or -platinum complexes by transmetallation (Equation 3.43). This reaction is a step in the preparation of Ni, Pd, or Pt alkynyl complexes from an alkyne, base, and a catalytic amoimt of Cul (Equation 3.44). This protocol for... 

More detailed mechanistic studies have been conducted with isolated ligated copper complexes, along with kinetic studies on reactions catalyzed by complexes of diamine ligands. These studies have shown that copper(I) amidate and imidate complexes are competent to be intermediates in the catalytic coupling of aryl halide with amides and imi-des. These studies also implied that two-coordinate anionic cuprate complexes undergo oxidative addition of the aryl halide more slowly than do related three-coordinate, neutral copper complexes containing a bidentate dative ligand. This conclusion is shown clearly by the formation of coupled product from iodotoluene and the species that equilibrates between the ionic and three-coordinate neutral species (Equation 19.119) and the lack of... 

Copper complexes have been used as reagents and as catalysts for the formation of carbon-carbon bonds. The most utilized reactions mediated by copper have been couplings of alkyl halides and sulfonates because copper complexes were unique for many years as reagents that would mediate the nucleophilic substitution of alkyl and aryl nucleophiles with alkyl halides. In recent years, work has been conducted to develop copper-catalyzed versions of cross couplings with aryl halides to address the issues of the cost of palladium catalysts. Although few examples of these processes currently rival those catalyzed by palladium complexes, they do illustrate the potential of copper complexes to catalyst these types of cross-coupling processes. 

The conductivity changes of phthalocyaninatometal complexes most probably originate from the electronic influences of substituents as observed for phthalocyani-natozinc and -copper complexes. 

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