Mechanisms ruthenium catalysis

M(CxC) matrix, 32 290-291, 311-313 Measurements, interpretation of, in experimental catalysis, 2 251 Mechanism see also specific types cobalt catalysis, 32 342-349 dehydrocyclization, 29 279-283 rhodium catalysis, 32 369-375 ruthenium catalysis, 32 381-387 space, 32 280... 

Ashby, M. T., Halpern, J. Kinetics and mechanism of catalysis of the asymmetric hydrogenation of a,P-unsaturated carboxylic acids by bis(carboxylato) 2,2 -bis(diphenylphosphino)-1,1 -binaphthyl ruthenium(ll), [Rull(BINAP) (02CR)2]. J. Am. Chem. Soc. 1991,113, 589-594. 

As carboxylic acid additives increased the efficiency of palladium catalysts in direct arylations through a cooperative deprotonation/metallation mechanism (see Chapter 11) [45], their application to ruthenium catalysis was tested. Thus, it was found that a ruthenium complex modified with carboxylic acid MesC02H (96) displayed a broad scope and allowed for the efficient directed arylation of triazoles, pyridines, pyrazoles or oxazolines [44, 46). With respect to the electrophile, aryl bromides, chlorides and tosylates, including ortho-substituted derivatives, were found to be viable substrates. It should be noted here that these direct arylations could be performed at a lower reaction temperatures of 80 °C (Scheme 9.34). 

Kejrwords Dynamic kinetic asymmetric transformation (DYKAT) Dynamic kinetic resolution (DKR) Hydrogenation Imine reduction Ketone reduction Mechanism of carbonyl reduction Mechanism of imine reduction Mechanism of dUiydrogen activation Ruthenium catalysis Shvo s catalyst Transfer hydrogenation... 

The same reaction can be carried out under catalysis of the ruthenium complex 53. The reaction mechanism is identical with the one depicted in Scheme 49. The advantage of ruthenium catalysis is that enynes with various degree of the substitution of the double bond can be used for the construction of both five- and six-membered rings, and strikingly mild reaction conditions (in many cases the reaction proceeds at room temperature). Also, a number of functional groups are tolerated. Some typical examples are given in Table 22 [63]. 

Cofacial ruthenium and osmium bisporphyrins proved to be moderate catalysts (6-9 turnover h 1) for the reduction of proton at mercury pool in THF.17,18 Two mechanisms of H2 evolution have been proposed involving a dihydride or a dihydrogen complex. A wide range of reduction potentials (from —0.63 V to —1.24 V vs. SCE) has been obtained by varying the central metal and the carbon-based axial ligand. However, those catalysts with less negative reduction potentials needed the use of strong acids to carry out the catalysis. These catalysts appeared handicapped by slow reaction kinetics. 

The concerted delivery of protons from OH and hydride from RuH found in these Shvo systems is related to the proposed mechanism of hydrogenation of ketones (Scheme 7.15) by a series of ruthenium systems that operate by metal-ligand bifunctional catalysis [86]. A series of Ru complexes reported by Noyori, Ohkuma and coworkers exhibit extraordinary reactivity in the enantioselective hydrogenation of ketones. These systems are described in detail in Chapters 20 and 31, and mechanistic issues of these hydrogenations by ruthenium complexes have been reviewed [87]. 

Noyori and colleagues investigated the ring opening of unsaturated mono- and bicyclic endoperoxides catalyzed by 5-10 mol% of Pd(PPh3)4 [226, 227]. Similarly to the cobalt-catalyzed reactions, (Z)-4-hydroxy enones resulted as the main products, which were accompanied by (Z)-2-ene-l, 4-diols and diepoxides. The latter are formed as the major products under either ruthenium or cobalt catalysis (see Part 2, Sects. 3.5 and 5.8). Both two-electron and radical mechanisms were considered for this transformation. Saturated bicyclic endoperoxides gave mixtures of cyclic 4-hydroxy ketones and 1,4-diols and their formation may be a result of a radical process [227, 228]. 

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