Rhodium-chiral phosphine catalysts homogeneous

II. Homogeneous Rhodium-Chiral Phosphine Catalyst Systems. 85... 

Homogeneous Hydroformylation of Olefins in the Presence of Chiral Rhodium(I)-Phosphine Catalysts... 

Table 3.12 surveys current industrial applications of enantioselective homogeneous catalysis in fine chemicals production. Most chiral catalyst in Table 3.12 have chiral phosphine ligands (see Fig. 3.54). The DIP AMP ligand, which is used in the production of L-Dopa, one of the first chiral syntheses, possesses phosphorus chirality, (see also Section 4.5.8.1) A number of commercial processes use the BINAP ligand, which has axial chirality. The PNNP ligand, on the other hand, has its chirality centred on the a-phenethyl groups two atoms removed from the phosphorus atoms, which bind to the rhodium ion. Nevertheless, good enantio.selectivity is obtained with this catalyst in the synthesis of L-phenylalanine. 

Following Wilkinson s discovery of [RhCl(PPh3)3] as an homogeneous hydrogenation catalyst for unhindered alkenes [14b, 35], and the development of methods to prepare chiral phosphines by Mislow [36] and Horner [37], Knowles [38] and Horner [15, 39] each showed that, with the use of optically active tertiary phosphines as ligands in complexes of rhodium, the enantioselective asymmetric hydrogenation of prochiral C=C double bonds is possible (Scheme 1.8). 

Wilkinson s (I) discovery that the soluble rhodium(I) phosphine complex, [Rh(PPh3)3Cl], was capable of homogeneous catalytic hydrogenation of olefins immediately set off efforts at modifying the system for asymmetric synthesis. This was made possible by the parallel development of synthetic methods for obtaining chiral tertiary phosphines by Horner (2) and Mislow (3,4, 5). Almost simultaneously, Knowles (6) and Horner (7) published their results on the reduction of atropic acid (6), itaconic acid (6), a-ethylstyrene (7) and a-methoxystyrene (7). Both used chiral methylphenyl-n-propyl-phosphine coordinated to rhodium(I) as the catalyst. The optical yields were modest, ranging from 3 to 15%. 

Homogeneous rhodium(I)-chiral tertiary phosphine catalysts have been used to hydrogenate ketones directly and to hydrosilylate ketones and imines thus accomplishing, after hydrolysis, indirect hydrogenation. 

Chiral hydrogenation catalysts. Rhodium and ruthenium phosphines are effective homogeneous catalysts for hydrogenation. Chiral ligands can be attached to accomplish asymmetric induction, the creation of a new asymmetric carbon as mostly one enantiomer. 

The chemistry of secondary phosphine oxides, R2P(H)0 and their phosphi-nous acid tautomers, R2POH, has continued to attract attention. The study of the phosphinous acid tautomers has been aided by the development of stereoselective procedures for direct conversion of secondary phosphine oxides to the phosphinous acid-boranes (83). Treatment of the secondary phosphine oxide with either a base-borane complex or boron trifluoride and sodium borohyd-ride provides the phosphinous acid-borane with predominant inversion of configuration at phosphorus. The phosphinous acid tautomers are usually trapped as ligands in metal complexes and further examples of this behaviour have been noted. Discrimination of enantiomeric forms of chiral phosphinous acids, Ph(R)OH, coordinated to a chiral rhodium complex, has been studied by NMR. °° Palladium complexes of di(t-butyl)phosphinous acid have found application as homogeneous catalysts.A lithium salt of the tellurophos-phinite Ph2PTeH has been prepared and structurally characterised. ... 

These developments were achieved despite the known technological difficulties associated with the practical use of homogeneous chiral metal-complex catalysts. They have low durabilities and repeatabilities, the chiral phosphine ligands are difficult to synthesize, the catalytic complexes are not recoverable fi om reaction mixtures, and the most effective catalysts based on rhodium complexes are very cjqiensive to synthesize. 

An important milestone in the history of asymmetric homogeneous catalysis was the development of asymmetric homogeneous hydrogenation catalysts based on rhodium complexes with chiral phosphine ligands. Scientists at Monsanto, over a period of years, developed catalysts for the production on an industrial scale of L-Dopa [31-33]. The key step is the asymmetric hydrogenation of an enamide (Scheme 7.6). 

Two new chiral phosphine ligands (293) and (294) have been prepared from D-mannitol, and their cationic complexes with rhodium(i) are catalysts for the homogeneous hydrogenation of dehydro-amino-acids (5)-amino-acids are produced with optical yields of 80— 90%. ... 

When steric hindrance inhibits hydrogenation on one face of a double bond, addition will take place exclusively to the less hindered face. This principle has been used to develop enantioselective or so-called asymmetric hydrogenation. The process employs homogeneous (soluble) catalysts, consisting of a metal, such as rhodium, and an enantiopure chiral phosphine ligand, which binds to the metal. A typical example is the Rh complex of the diphosphine (R,R)-DIPAMP (margin). After coordination of the alkene double bond and a molecule of H2 to rhodium, hydrogenation occurs via syn addition, just as in the case of insoluble metal catalysts. 

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