Asymmetric transfer hydrogenation defined

Noyori and coworkers reported well-defined ruthenium(II) catalyst systems of the type RuH( 76-arene)(NH2CHPhCHPhNTs) for the asymmetric transfer hydrogenation of ketones and imines [94]. These also act via an outer-sphere hydride transfer mechanism shown in Scheme 3.12. The hydride transfer from ruthenium and proton transfer from the amino group to the C=0 bond of a ketone or C=N bond of an imine produces the alcohol or amine product, respectively. The amido complex that is produced is unreactive to H2 (except at high pressures), but readily reacts with iPrOH or formate to regenerate the hydride catalyst. 

Figure 1.25 exemplifies the strucmres of certain efficient precatalysts for asymmetric transfer hydrogenation of ketones. Precatalysts C1-C3 use the NH effect described above. A turnover frequency, defined as moles of product per mol of catalyst per hour, of 30,000 h is achieved by using of C2 and an alkaline base in 2-propanol. A Rh complex C3 is an isolobal to the corresponding arene-Ru complex (see Figure 1.23). The Ru complexes C4 " and C5 without NH group in ligand catalyze the reaction by different mechanisms. A higher than 90% optical yield is achieved by using C5 in reduction of certain aliphatic ketones.

Chirality transfer in catalytic asymmetric hydrogenation can be achieved not only by using powerful chiral ligands such as BINAP or DuPhos but also by the formation of a dynamic conformational isomer. The availability of many enantiomerically pure diols allows the production of electron-deficient, bi-dentate phosphate in the form of 27. The backbone O-R -O can define the chirality of the 0-R2-0 in complex 28, hence realizing the chirality transfer.44... 

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