Asymmetric hydrogenation aromatic

Hu, A.G., Yee, G.T. and Lin, W.B. (2005) Magnetically recoverable chiral catalysts immobilized on magnetite nanopartides for asymmetric hydrogenation of aromatic ketones. Journal of the American Chemical Society, 127 (36), 12486-12487. 

Table 19 Asymmetric hydrogenation of simple aromatic ketones... 

Table 22 Asymmetric hydrogenation of acyclic aromatic imines ...

A chiral catalyst consisting of Irans-RuC]2(xy]binap)(daipen) and (CH3)3COK in 2-propanol effects asymmetric hydrogenation of a-, / -, and y-amino aromatic ketones [128]. Hydrogenation of 2-(dimethylamino)acetophenone catalyzed by the (R)-XylBINAP/(R)-DAIPEN-Ru complex [(R,R)-31D] gives the R amino alcohol in 93% ee (Fig. 32.36). The optical yield is increased up to 99.8%, when... 

Much like the enol systems discussed in Sect. 6.1, enamines are predictably difficult substrates for most iridium asymmetric hydrogenation catalysts. Both substrate and product contain basic functionahties which may act as inhibitors to the catalyst. Extended aromatic enamines such as indoles may be even more difficult substrates for asymmetric hydrogenation with an additional energetic barrier to overcome. Initial reports by Andersson indicated a very difficult reaction indeed (Table 14) [75]. Higher enantioselectivities were later reported by Baeza and Pfaltz (Table 14) [76]. 

R)-BINAP/l,2-diphenylethylenediamine ruthenium(II) complexes covalently attached to polystyrene (Scheme 4.32) promote the asymmetric hydrogenation of aromatic ketones and of a, yS-unsaturated ketones [125]. The catalysts (52) and (53) were reused at high substrate/catalyst molar ratio (S/C) of 2470 in 14 experiments. Remarkably, the enantiopurity of the products remained high after each run, constantly being in the range of 97 to 98% ee. 

Finally, the asymmetric hydrogenation of a series of a-hydroxy aromatic ketones in methanol catalyzed by Cp lr(OTf)(MsDPEN) (42, MsDPEN = N-(methanesul-... 

Substituents on imino nitrogen influence both reactivity and enantioselectivity in hydrogenation of imino compounds. Figure 1.32 shows two successful examples. An f-BINAPHANE-Ir complex effects asymmetric hydrogenation of A-aryl aromatic imines.On the other hand, an Et-DuPHOS-Rh complex (see Figure 1.2) is effective for hydrogenation of A-acyUiydrazones. ... 

The asymmetric hydrogenation of unfunctionalized ketones is a much more challenging task than that of functionalized ketones [3 j, 115]. Many chiral catalysts which are effective for functionalized ketones do not provide useful levels of enantioselectivity for unfunctio-nalized ketones, due to a lack of secondary coordination to the metal center. Zhang demonstrated the enantioselective hydrogenation of simple aromatic and aliphatic ketones using the electron-donating diphosphane PennPhos, which has a bulky, rigid and well-defined chiral backbone, in the presence of 2,6-lutidine and potassium bromide [36]. 

Aromatic Ketones The DIOP-Rh [116] and DBPP-Rh [117] complexes, in conjunction with a tertiary amine, have been employed in the asymmetric hydrogenation of acetophenone, albeit with moderate enantioselectivity (80 and 82% respectively Tab. 1.10). The asymmetric hydrogenation of aromatic ketones was significantly improved by using the Me-PennPhos-Rh complex, with which enantioselectivities of up to 96% ee were achieved [36]. Interestingly, the additives 2,6-lutidine and potassium bromide were again found to be crucial for optimum selectivity, although their specific role has not been determined. 

Remarkable activity and enantioselectivity in asymmetric hydrogenation of aromatic ketones were reported when ionic liquids were used as solvents for a rhodacarborane catalyst precursor having an alkene ligand, [closo-l,3 p-(ri -3-CH2= CHCH2CH2) -3-H-3-PPh3-3,l,2-RhC2B9Hio] 215). In ionic liquids... 

Ruthenium-Catalyzed Asymmetric Hydrogenation of Aromatic Ketones... 

The procedure for getting the polymer-bound ligands is very easy to reproduce. Three jS-functionalized aromatic ketones were successfully reduced to the corresponding alcohols by heterogeneous asymmetric hydrogen transfer reaction with formic acid-triethylamine azeotrope as the hydrogen donor. One of the product alcohols (19c) is an intermediate for the synthesis of optically active fluoxetine. 

The enantioselective hydrogenation of olefins, ketones and imines still represents an important topic and various highly enantioselective processes based on chiral Rh, Ru or Ir complexes have been reported. However, most of these catalysts failed to give satisfactory results in the asymmetric hydrogenation of aromatic and heteroaromatic compounds and examples of efficient catalysts are rare. This is especially the case for the partial reduction of quinoline derivatives which provide 1,2,3,4-tetrahydroquinolines, important synthetic intermediates in the preparation of pharmaceutical and agrochemical products. Additionally, many alkaloid natural products consist of this stmctural key element. 

Thus transition metal complexes capable of effecting cyanation reactions on aromatic nuclei under mild conditions have been discovered Cassar et al. describe such a catalytic system. The past few years have also seen the discovery of asymmetric catalysis. Asymmetric catalysts contain optically active ligands and, like enzymes, can promote catalytic reactions during which substantial levels of optical activity are introduced into the products. This volume contains examples of asymmetric hydrogenation and asymmetric hydroformylation catalysis in the papers, respectively, by Knowles et al. and Pino et al. 

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