Functionalized ketones, hydrogenation

Hydrogenation of a and functionalized ketones Hydrogenation / reduction of other... 

The results clearly show that these novel ligands are able to form a suitable asymmetric enviromnent around the metal resulting in high asymmetric induction. Their catalytic potential has been demonstrated in the highly enantioselective Rh-catalyzed hydrogenation of itaconates and a-enamides and Ru-catalyzed hydrogenation of p-functionalized ketone. 

BPPM Scheme 1.17) was used as catalyst [60]. The enantioselective hydrogenation of functionalized ketones was also efficiently achieved by a series of rhodium(I) aminophosphine- and amidophosphine-phosphinite complexes [61]. 

Complexes containing one binap ligand per ruthenium (Fig. 3.5) turned out to be remarkably effective for a wide range of chemical processes of industrial importance. During the 1980s, such complexes were shown to be very effective, not only for the asymmetric hydrogenation of dehydroamino adds [42] - which previously was rhodium s domain - but also of allylic alcohols [77], unsaturated acids [78], cyclic enamides [79], and functionalized ketones [80, 81] - domains where rhodium complexes were not as effective. Table 3.2 (entries 3-5) lists impressive TOF values and excellent ee-values for the products of such reactions. The catalysts were rapidly put to use in industry to prepare, for example, the perfume additive citronellol from geraniol (Table 3.2, entry 5) and alkaloids from cyclic enamides. These developments have been reviewed by Noyori and Takaya [82, 83]. 

Bppfoh and bppfa derivatives have been applied most successfully for the Rh-catalyzed hydrogenation of dehydro amino acid derivatives such as MAC (ee 97%) and of functionalized ketones [7]. The nature of the amino group has a significant effect on enantioselectivity and often also on activity, and is used to tailor the ligand for a particular substrate. Rh-bppfa complexes were among the first catalysts able to hydrogenate tetrasubstituted C=C bonds, albeit with relatively low activity (Table 25.2, entries 2.1-2.3). Ferrophos, one of the very few li-... 

Ferrocene-based complexes have some potential for the enantioselective reduction of ketones, but compared to other ligand classes this is relatively limited [3]. Rh complexes of bppfa, bophoz and josiphos are among the most selective catalysts for the hydrogenation of a-functionalized ketones (Table 25.9 Fig. 25.18, 30-32). Ru complexes of walphos and ferrotane are quite effective for... 

Rhodium-Catalyzed Enantioselective Hydrogenation of Functionalized Ketones... 

In this chapter, we will focus on the rhodium-catalyzed hydrogenation of functionalized ketones and the development of chiral phosphorous ligands for this process. Although there are other chiral phosphorous ligands which are effective for ruthenium-, iridium-, platinum-, titanium-, zirconium-, and palladium-catalyzed hydrogenation, they will not be discussed here. For details of these chemistries, the reader should refer to other chapters of this book. 

Rhodium-Catalyzed Enantioselective Hydrogenation of Functionalized Ketones 33.3.2.2 a,y-Diketoesters... 

Hydrogen will not reduce ketones or imines using CATHy or related catalysts. Inorganic hydrogen donors that have been used include dithionite and di-hydrogenphosphite salts, metal hydrides such as sodium borohydride, and sodium cyanoborohydride. Recently, amines have been shown to function as hydrogen donors with some catalysts. The enzymic cofactor NADH can be used stoichiometrically, and the potential exists to use this catalytically [56]. 

Asymmetric hydrogenation of ketones is one of the most efficient methods for making chiral alcohols. Ru-BINAP catalysts are highly effective in the asymmetric hydrogenation of functionalized ketones,54,55 and this may be used in the industrial production of synthetic intermediates for some important antibiotics. The preparation of statine 65 (from 63b R = i-Bu) and its analog is one example (Scheme 6-28).56 Table 6-6 shows the results when asymmetric hydrogenation of 63 catalyzed by RuBr2[(R)-BINAP] yields threo-64 as the major product. 

In contrast to their success in the asymmetric hydrogenation of functionalized ketones, BINAP-Ru catalysts fail to give good results with simple ketone because such substrates lack heteroatoms that enable the substrate to anchor strongly to the Ru metal. 

In summary, the asymmetric hydrogenation of olefins or functionalized ketones catalysed by chiral transition metal complexes is one of the most practical methods for preparing optically active organic compounds. Ruthenium and rhodium-diphosphine complexes, using molecular hydrogen or hydrogen transfer, are the most common catalysts in this area. The hydrogenation of simple ketones has proved to be difficult with metallic catalysts. However,... 

The reaction of allenes with peracids and other oxygen transfer reagents such as dimethyldioxirane (DM DO) or hydrogen peroxide proceeds via allene oxide intermediates (Scheme 17.17). The allene oxide moiety is a versatile functionality. It encompasses the structural features of an epoxide, an olefin and an enol ether. These reactive intermediates may then isomerize to cyclopropanones, react with nucleophiles to give functionalized ketones or participate in a second epoxidation reaction to give spirodioxides, which can react further with a nucleophile to give hydroxy ketones. 

The best studied systems are the Raney Ni/tartaric acid/NaBr combination, for the hydrogenation of / -functionalized ketones, and the Pt- and Pd-on-support/cinchona alkaloid systems for the enantioselective hydrogenation of a-functionalized ketones. 

Although Ru(OCOCH3)2(binap) exhibits excellent catalytic performance on asymmetric hydrogenation of functionalized olefins, it is feebly active for reaction of ketones. This failure is due to the property of the anionic ligands. Simple replacement of the carboxylate ligand by halides achieves high catalytic activity for reaction of functionalized ketones. 

Figure 1.13. Asymmetric hydrogenation of functionalized ketones catalyzed by BINAP-Ru complexes.

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