Copper complexes olefin

Copper olefin complexes are usually generated by the direct reaction of a Cu(l) source, the ligand, and the corresponding olefin. Copper ethylene complexes are of interest in view of their biochemical importance,98,98a-98e their applications in organic chemistry,99,99a,99b and industrial applications.100 100 Because of this, many copper alkene complexes have been reported, with different nuclearity, in compounds with one, two, or even three C=C units coordinated to a given copper center. 

A review of the photochemical properties of copper complexes includes a survey of the photocatalysed reactions of copper-olefin complexes. The addition of acetonitrile to norbornene may be induced by irradiation in the presence of silver ions. The reaction appears to involve excitation of a LMCT excited state of the norbomene-silver complexes and the formation of norbornene radical cations. 

Class 1—Photoexcitation of a preformed copper-olefin complex. Complexation plays a key role by shifting the absorption spectrum of the system into a wavelength region accessible to the irradiating light and/or by providing a sterically or electronically favored pathway to the photoproduct. 

Although the number of applications of olefin metathesis to transition metal complexes is small compared to the number of applications in organic synthesis, this field is becoming increasingly important. Spectacular examples are the double RCM reactions of copper phenanthroline complexes as a synthetic route to catenanes [113] or a recently reported approach to steric shielding of rhenium complex terminated sp-carbon chains [114]. 

The proposed reaction mechanism involves intermolecular nucleophilic addition of the amido ligand to the olefin to produce a zwitterionic intermediate, followed by proton transfer to form a new copper amido complex. Reaction with additional amine (presnmably via coordination to Cn) yields the hydroamination prodnct and regenerates the original copper catalyst (Scheme 2.15). In addition to the NHC complexes 94 and 95, copper amido complexes with the chelating diphosphine l,2-bis-(di-tert-bntylphosphino)-ethane also catalyse the reaction [81, 82]. 

In order to rationalize the catalyst-dependent selectivity of cyclopropanation reaction with respect to the alkene, the ability of a transition metal for olefin coordination has been considered to be a key factor (see Sect. 2.2.1 and 2.2.2). It was proposed that palladium and certain copper catalysts promote cyclopropanation through intramolecular carbene transfer from a metal carbene to an alkene molecule coordinated to the same metal atom25,64. The preferential cyclopropanation of terminal olefins and the less hindered double bond in dienes spoke in favor of metal-olefin coordination. Furthermore, stable and metastable metal-carbene-olefin complexes are known, some of which undergo intramolecular cyclopropane formation, e.g. 426 - 427 415). 

In 1986, Pfaltz et al. introduced a new type of pseudo C2-symmetrical copper-semicorrin complex (68) as the catalyst (Scheme 60).227 228 The complexes (68) are reduced in situ by the diazo compound or by pretreatment with phenylhydrazine to give monomeric Cu1 species (69), which catalyze cyclopropanation. Of the semicorrin complexes, complex (68a) (R = CMe2OH) showed the best enantioselectivity in the cyclopropanation of terminal and 1,2-disubstituted olefins.227,228,17 It is noteworthy that complex (68a) catalyzes cyclopropanation, using diazomethane as a carbene source, with good enantioselectivity (70-75% ee).17... 

The seminal report of an asymmetric homogeneous metal-catalyzed reaction described the copper-catalyzed group-transfer reaction from a diazoester to an alkene, Eq. 3 (2). This article provided experimental verification of the intervention of copper carbenoid olefin complexes in the catalytic decomposition of diazo com-... 

This rate expression is consistent with the reaction scheme shown in Eq. 10.6, formulated on the basis of the Krauss-Smith paper. Thus, the initially formed cuprate dimer/enone complex with lithium/carbonyl and copper/olefin coordinations [71, 72] transforms into the product via an intermediate or intermediates. A lithium/ carbonyl complex also forms, but this is a dead-end intermediate. Though detailed... 

The central feature of the mechanism is the 3-cuprio(III) enolate Cpop, of an open, dimeric nature, as shown by comparison of theory with experimentation involving NMR and KIEs [80, 81]. This species serves as the direct precursor to the product (Scheme 10.5, top box). In this critical CPop complex, copper/olefin (soft/soft) and a lithium/carbonyl (hard/hard) interactions are present. The open complex may be formed directly, by way of an open cluster (bottom left of Scheme 10.5), or by complexation of a closed cluster with the enone (CPcl). Experiments have shown that the enone/lithium complex (top left of Scheme 10.11) is a deadend species [60, 74]. 

Kneen s conclusions that copper(I)-olefin complexes are more stable than silver (I)-olefin complexes, were in agreement with those of other workers (25, 29). 

Oxidation of olefin containing molecules at the allylic position is yet another important synthetic transformation. There are many examples of oxidation of cyclic olefins including those by Pfaltz s group. These reactions consisted of the oxidation of cyclic olefins 222a-c by tcrt-butyl perbenzoate in the presence of the copper(I) complexes of ligands lb, 3, 6, and 45. The corresponding benzoates 223a-c were obtained in yields up to 84% with selectivities up to 84% (ee) (Table 9.35, Fig. 6.64). 

For an X-ray crystal structure of a bissulfoximine-copper(I) olefin complex. 

Three chiral intermediates are observed directly by H and NMR spectroscopy one olefin-copper(I) complex 26 and two magnesium enolates 27 and 28 (equation 43). 

The two methyl groups in the olefin-copper(I) complex 26 are crucial for asymmetric induction. The 150° dihedral angle between the a- and /3-protons of the magnesium enolate 27 provides valuable information to determine the stereochemical effects on the a center. The two magnesium enolates 27 and 28 are reversibly temperature-dependent. Enolate 27 is the major component at 253 K, while enolate 28 becomes the major component at 293 K. Therefore, temperature lower than ca 256 K is required to obtain high stereoselectivity. 

The first metal-olefin complex was reported in 1827 by Zeise, but, until a few years ago, only palladium(II), platinum(Il), copper(I), silver(I), and mercury(II) were known to form such complexes (67, 188) and the nature of the bonding was not satisfactorily explained until 1951. However, recent work has shown that complexes of unsaturated hydrocarbons with metals of the vanadium, chromium, manganese, iron, and cobalt subgroups can be prepared when the metals are stabilized in a low-valent state by ligands such as carbon monoxide and the cyclopentadienyl anion. The wide variety of hydrocarbons which form complexes includes olefins, conjugated and nonconjugated polyolefins, cyclic polyolefins, and acetylenes. 

Such J-mctals as Cu(I) [but not Cu(II)], form a variety of compounds with ethenes, for example [Cu(C2H4)(H20)2]C104 (from Cu, Cu2+, and C2H4) or Cu(C2H4)(bipy)+. It is necessary to mention that, of all the metals involved in biological systems, only copper reacts with ethylene [74b]. Such homoleptic alkene complexes can be useful intermediates for the synthesis of other complexes. The olefin complexes of the metals in high formal oxidation states are electron deficient and therefore inert toward electrophilic reagents. By contrast, the olefin complexes of the metals in low formal oxidation states are attacked by electrophiles such as protons at the electron-rich metal-carbon a-bonds [74c]. 

Interestingly, more recent MO calculations on silver(I) and copper(I) complexes have indicated that there is much less back donation between these metals and the olefin than in the related platinum compounds, and that the interaction might be primarily electrostatic (see [32], p. 4). 

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