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Catalysts Noyori

Since the original report, about 12 other reagents have been reported to catalyze this reaction, but this reagent of Noyori (1) and that of Oguni (15,268) seem to be the most effective. In addition, both can effect chiral amplification, an increase of enan-tioselectivity over that of the catalyst. Noyori suggests that the alkyl transfer reaction involves a dinuclear Zn complex such as 3, whose structure has been established by... [Pg.141]

When the acetal and the silyl enol ether are mixed with the same Lewis acid catalyst, Noyori found that an efficient aldol-style condensation takes place with the acetal providing the electrophile. The reaction is successful at low temperatures and only a catalytic amount of the Lewis acid is needed. Under these conditions, with no acid or base, few side-reactions occur. Notice that the final desilylation is carried out by the triflate anion to regenerate the Lewis acid Me3Si-OTf. Triflate would be a very poor nucleophile for saturated carbon but is reasonable for silicon because oxygen is the nucleophilic atom. [Pg.1290]

Enantioselective use of aliphatic diazo compounds was reviewed by Doyle in three papers (1991, 1992, 1993), and by Ye and McKervey (1994). Potential industrial applications were summarized in a book edited by Collins et al. (1992). Scientific aspects of asymmetric catalysis in general were discussed in a monograph by the pioneer of the use of chiral catalysts, Noyori (1994). There is no doubt that further progress reports will be necessary in coming years ... [Pg.382]

Shvo s hydride catalyst 2 was the first reported example of a ligand-metal bifunctional catalyst. Noyori introduced this nomenclature for catalysts that transfer a hydride from a metal center and a proton from a ligand [21, 22]. In the case of catalyst 2, simultaneous transfer of hydride from the metal center... [Pg.86]

Asymmetric hydrogenation has been achieved with dissolved Wilkinson type catalysts (A. J. Birch, 1976 D. Valentine, Jr., 1978 H.B. Kagan, 1978). The (R)- and (S)-[l,l -binaph-thalene]-2,2 -diylblsCdiphenylphosphine] (= binap ) complexes of ruthenium (A. Miyashita, 1980) and rhodium (A. Miyashita, 1984 R. Noyori, 1987) have been prepared as pure atrop-isomers and used for the stereoselective Noyori hydrogenation of a-(acylamino) acrylic acids and, more significantly, -keto carboxylic esters. In the latter reaction enantiomeric excesses of more than 99% are often achieved (see also M. Nakatsuka, 1990, p. 5586). [Pg.102]

A different approach to making chiral drugs is asymmetric synthesis. An optically inactive precursor is converted to the drug by a reaction that uses a special catalyst, usually an enzyme (Chapter 11). If all goes well, the product is a single enantiomer with the desired physiological effect In 2001, William S. Knowles, Ryogi Noyori, and K. Barry Sharpless won the Nobel Prize in chemistry for work in this area. [Pg.601]

These transition-metal catalysts contain electronically coupled hydridic and acidic hydrogen atoms that are transferred to a polar unsaturated species under mild conditions. The first such catalyst was Shvo s diruthenium hydride complex reported in the mid 1980s [41 14], Noyori and Ikatiya developed chiral ruthenium catalysts showing excellent enantioselectivity in the hydrogenation of ketones [45,46]. [Pg.36]

Redox-type reactions show by far the worst performance in meeting the golden atom economical threshold. Three reductions meet this criterion with (AE)min values of 1 hydrogenation of olefins using the Lindlar catalyst (1952), Noyori stereoselective hydrogenation reaction (1985), and Zincke disulphide cleavage reaction (1911) whereas, oxidations... [Pg.99]

TaniaPhos active catalyst discussion As shown by Salzer (2) such complexes with half sandwich stracture result in the catalyst cycle into a hydride species where the pentadienyl moiety can be hydrogenolyticaUy liberated (2, 6). This was verified in the case of BINAP complexes (2, diss. Podewils, Geyser). In accordance to this fact and other mechanistic aspects from Noyori s work (3, 5) it is likely that the pre-catalyst species undergoes the same reaction pathway and that the reactive part of the pre-catalyst, the pentadienyl moiety, will be liberated under hydrogenolytic conditions as shown below in Scheme 23.9 ... [Pg.208]

The most important progress in the last decade has been in the design and synthesis of [RuCl2(diphosphine)(l,2-diamine)] catalysts exploiting the metal-ligand bifunctional concept developed by Noyori and co-workers.29-31 The Noyori catalysts seem to possess all of the desired properties, such as high turnover number (TON), high turnover frequency (TOF), and operationally simple, safe, and environmentally friendly reaction conditions. [Pg.76]

Asymmetric catalysis is four-dimensional chemistry as stated by Noyori,6 because high efficiency can only be achieved through the coordination of both an ideal three-dimensional structure x, y, z) and suitable kinetics (/). Recently developed metal-ligand difunctional catalysts really provide a new basis for developing efficient catalytic reactions. [Pg.91]

A monohydride mechanism is not operating in reactions catalyzed by these complexes. Noyori observed that the presence of an NH or NH2 in the auxiliary ligands was crucial for catalytic activity, the corresponding dialkylamino analogs being totally ineffective. These findings indicate a novel metal-ligand bifunctional cycle (Scheme 28) KOH reacts with the pre-catalyst (87)... [Pg.95]

The standard work of Evans [2] as well as a survey of the papers produced in the Journal of Labeled Compounds and Radiopharmaceuticals over the last 20 years shows that the main tritiation routes are as given in Tab. 13.1. One can immediately see that unlike most 14C-labeling routes they consist of one step and frequently involve a catalyst, which can be either homogeneous or heterogeneous. One should therefore be able to exploit the tremendous developments that have been made in catalysis in recent years to benefit tritiation procedures. Chirally catalyzed hydrogenation reactions (Knowles and Noyori were recently awarded the Nobel prize for chemistry for their work in this area, sharing it with Sharpless for his work on the equivalent oxidation reactions) immediately come to mind. Already optically active compounds such as tritiated 1-alanine, 1-tyrosine, 1-dopa, etc. have been prepared in this way. [Pg.436]

Liese el al. attached a transfer-hydrogenation catalyst to a soluble polymer and applied this system in a continuously operated membrane reactor.[60] A Gao-Noyori catalyst was bound to a soluble polysiloxane polymer via a hydrosilylation reaction (Figure 4.41). [Pg.100]

Figure 4.41. Goa-Noyori catalyst bound to a polysiloxane polymer.[60]... Figure 4.41. Goa-Noyori catalyst bound to a polysiloxane polymer.[60]...
See other pages where Catalysts Noyori is mentioned: [Pg.25]    [Pg.25]    [Pg.325]    [Pg.350]    [Pg.352]    [Pg.197]    [Pg.68]    [Pg.89]    [Pg.115]    [Pg.40]    [Pg.100]    [Pg.120]    [Pg.289]    [Pg.75]    [Pg.50]    [Pg.89]    [Pg.212]    [Pg.3]    [Pg.89]    [Pg.112]    [Pg.124]    [Pg.376]    [Pg.523]    [Pg.174]    [Pg.176]    [Pg.32]    [Pg.2]    [Pg.2]    [Pg.2]    [Pg.5]    [Pg.50]   
See also in sourсe #XX -- [ Pg.402 ]



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