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Hydrido complexes iridium

First attempts to isolate monocarbene-hydrido complexes by oxidative addition of A -(2-pyridyl)imidazolium cations to Pd° with utilization of the chelate effect of the donor-functionalized carbene ligand failed and only the dicarbene complexes such as 29 were isolated [112]. The iridium hydrido complex 30 was obtained in the oxidative addition of an W-(2-pyridylmethyl)imidazolium cation to iridium(I) (Fig. 11) [113]. This reaction proceeds most likely via the initial coordination of the nitrogen donor which brings the imidazolium C2-H bond in close proximity to the metal center. No reaction was observed with Rh under these conditions. [Pg.107]

Table II. Some Iridium Hydrido Complexes and Their Reactions... Table II. Some Iridium Hydrido Complexes and Their Reactions...
The iridium hydrido-complexes Ic was obtained from the corresponding chloride by reaction with sodium cyanoborohydride (eq. 15). [Pg.231]

Very air-sensitive iridium diphosphine complexes carrying a peraryldiphosphine ligand, [IrCl(diphosphine)]2 (42a, 42b)(a diphosphine = BPBP b diphosphine = BINAP [47, 48]) can also activate MeOH in addition to HjO at room temperature very easily. Reaction of 42 with excess MeOH in toluene at room temperature gave ah-stable and thermally stable colorless hydrido (me thoxo) complexes, [ IrH(diphos-phine) 2( 4-OMe)2( i-Cl)]Cl (69) quantitatively (Eq. 6.21) [49]. The shucture of 69b,... [Pg.184]

Merola reported the preparation of hydrido(carboxylato)iridium(lll) complexes, mer-[lrCl(0C(0)R)(H)(PMe3)3] (90) (R = Ph, Me), by oxidative addition of acetic acid or benzoic acid to [Ir(cod)(PMe3)3]Cl (67) [46]. The structure of 90 (R = Ph) in which the carboxylato ligand coordinates as an T -ligand, was confirmed by X-ray analysis. The reaction of 67 with salicylic acid yielded the product 91, which resulted from activation of the O-H bond of the carboxylato but not of the hydroxo group (Scheme 6-13). [Pg.189]

The iridium phosphine complex [IrC PEt,),] 39b can also activate O-H bonds of carboxylic acids. The stoichiometric reaction with a,(o-alkynoic acids RC=C(CH2)2 CO2H (R = Me, Ph) gave cis-hydrido(carboxylato)iridium(III) complexes 92 (Eq. 6.26), and the molecular structure of 92a was determined crystallographically [59]. [Pg.189]

We also found that iridium hydrido(hydroxo) complexes like [ lrH(diphos-phine) 2( x-OH)2( x-Cl)]Cl (43) and the precursor diphosphine complexes 42 can also catalyze the hydration of nitriles. In the presence of catalyhc amounts of these complexes, heating acetonitrile and benzonitrile with excess water at 120°C gave the corresponding amides [47, 50]. [Pg.198]

The main species in solution has been identified to be the hydrido-alkynyl complex [IrH(C2Ph)(cod)(//2-iPrPCH2CH2OMe)]+BF4 (23). This is, however, only a sink that results from direct reaction of 22 with the 1-alkyne, draining the active catalyst from the system. The catalysis proceeds via the dihydrido-diene intermediate [IrH2(cod)(//2- PrPCH2CH2OMe)]+ BF4 (24), which reacts reversibly with the alkyne to yield the hydrido-iridium-styryl complex 25, followed by a rate-determining reaction of this hydrido-vinyl species with hydrogen to re-... [Pg.386]

Electron-rich iridium(l) complexes can perform C—H activation reactions under mild conditions [13]. In this line, acetone-dis solutions of the [(ri -l,3,5-C 5H3Me3)) lr(Ti -C2H4)(P Pr3)]BF4 complex, at room temperature, show deuterium incorporation to the ethane ligand, most likely due to the participation of hydrido vinyl iridium(lll) species, formed by the C—H activation of ethane, according to Scheme 2.25 [21]. [Pg.32]

In an earlier report, Maitlis et al. showed that 1 could be easily converted into a hydrido complex [Cp lrHCl]2 (2) under ambient conditions by treatment with alcohol and a weak base (Scheme 5.1) [19], probably accompanied by the formation of carbonyl compounds. This fact means that the hydrogen atom in an alcohol can be rapidly transferred to the iridium center in the form of a hydride but then, if the hydride on the iridium could be re-transferred to another hydrogen acceptor, a new catalytic system using alcohols as substrates might be realized. In fact, a wide variety of Cp Ir complex-catalyzed hydrogen transfer systems using alcohols as substrates, and based on the above hypothesis, have been reported to date [20]. [Pg.107]

Many transition metal complexes catalyze homogeneous activation of molecular hydrogen in solution, forming hydrido complexes. Such complexes include pentacyanocobaltate(II) anion, [Co(CN)5], many metal carbonyls, and several complexes of rhodium, iridium, and palladium. [Pg.355]

Vaska, L. and DiLuzio, J.W. (1961) Carbonyl and hydrido-carbonyl complexes of iridium by reaction with alcohols-hydrido complexes by reaction with acid. J. Am. Chem. Soc., 83, 2784. [Pg.118]

Okazaki, M., Kawano, Y., Tobita, H., Inomata, S., and Ogino, H. (1995) Light-and heat-induced isomerization of chloro (hydrido)iridium(III) complex containing a (2-phosphinoethyl)silyl chelate ligand. Chemistry Letters, 1005—1006. [Pg.92]

The feverish interest in hydrido complexes has, as its main cause, the tremendous potential of these reactions in catalytic systems. In a relatively short span of time, hydrido complexes have been found to play a role in a significant number of catalytic processes (6, 9)—e.g., oligomerization of olefins (rhodium), decarboxylation reactions (rhodium), and hydrogenation reactions (ruthenium, osmium, rhodium, iridium, and platinum). Discussion of these applications would go beyond the scope of the present treatment. [Pg.70]

The remainder of this review is devoted to giving a closer look at the hydrido complexes of iridium and their reactions. Iridium gives the most extensive and versatile range of hydrido complexes of any platinum metal (29). The main types of compounds known and some of their reactions are shown in Table II. To this, one must add the hydrogen abstraction reaction mentioned earlier. [Pg.70]

Scheme 9.9 Preparation of the cycloalkyl(hydrido) and alkyl(hydrido) iridium(III) complexes 24a,b and 25a,b by intermolecular C—H bond activation from the dihydrido iridium(III) and the dicarbonyl iridium(I) compounds 21 and 22 as the precursors (a L = PMe3 b L = CO)... Scheme 9.9 Preparation of the cycloalkyl(hydrido) and alkyl(hydrido) iridium(III) complexes 24a,b and 25a,b by intermolecular C—H bond activation from the dihydrido iridium(III) and the dicarbonyl iridium(I) compounds 21 and 22 as the precursors (a L = PMe3 b L = CO)...
The dimeric hydrido complex [Ir(H)(X)2(CO)(PR3)]2 (X = Cl, Br PR3 = PEt3, PPh3) has been synthesized by carbonylation of iridium halides followed by phosphine addition the complex... [Pg.1150]

See other pages where Hydrido complexes iridium is mentioned: [Pg.107]    [Pg.149]    [Pg.107]    [Pg.1735]    [Pg.107]    [Pg.149]    [Pg.107]    [Pg.1735]    [Pg.1121]    [Pg.177]    [Pg.178]    [Pg.179]    [Pg.188]    [Pg.150]    [Pg.219]    [Pg.24]    [Pg.36]    [Pg.62]    [Pg.373]    [Pg.169]    [Pg.118]    [Pg.200]    [Pg.149]    [Pg.20]    [Pg.47]    [Pg.66]    [Pg.70]    [Pg.70]    [Pg.317]    [Pg.1162]    [Pg.1163]    [Pg.1051]    [Pg.1844]    [Pg.1846]   
See also in sourсe #XX -- [ Pg.1052 ]

See also in sourсe #XX -- [ Pg.280 , Pg.784 ]



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