Diphosphine rhodium catalysts

Acetylenic esters react with arylboron reagents in the presence of rhodium diphosphine catalyst to give cyclic ketones.409 Equation (61) shows an example which may involve ortfe-metallation and ketone formation. A catalytic, enantioselective reaction was also achieved (Equation (62)). These processes presumably involve unprecedented addition of organorhodium species to the ester carbonyl group. 

Rhodium diphosphine catalysts can be easily prepared from [Rh(nbd)Cl]2 and a chiral diphosphine, and are suitable for the hydrogenation of imines and N-acyl hydrazones. However, with most imine substrates they exhibit lower activities than the analogous Ir catalysts. The most selective diphosphine ligand is bdppsuif, which is not easily available. Rh-duphos is very selective for the hydrogenation of N-acyl hydrazones and with TOFs up to 1000 h-1 would be active enough for a technical application. Rh-josiphos complexes are the catalysts of choice for the hydrogenation of phosphinyl imines. Recently developed (penta-methylcyclopentyl) Rh-tosylated diamine or amino alcohol complexes are active for the transfer hydrogenation for a variety of C = N functions, and can be an attractive alternative for specific applications. 

The rhodium-diphosphine catalysts are generally sensitive to oxygen, hence the reactions have to be carried out under strictly inert atmospheric conditions. A decrease in the yield or the enantiomeric excess can be due to a lack of sufficient precaution during the procedure or to the inactivation of the catalyst when exposed to oxygen. However, the reactions using rhodium complexes as catalysts give very good results which correlate well with the published material. 

Figure 19. Immobilization of chiral rhodium diphosphine catalysts (5) to A1-SBA-15/A1-MCM-41 [85].

L-Dopa was produced industrially by Hoffrnann-LaRoche, using a modification of the Erlenmeyer synthesis for amino acids. In the 1960s, research at Monsanto focused on increasing the L-Dopa form rather than producing the racemic mixture. A team led by William S. Knowles (1917—) was successful in producing a rhodium-diphosphine catalyst called DiPamp that resulted in a 97.5% yield of L-Dopa when used in the Hoffrnann-LaRoche process. Knowles s work produced the first industrial asymmetric synthesis of a compound. Knowles was awarded the 2001 Nobel Prize in chemistry for his work. Work in the last decade has led to green chemistry synthesis processes of L-Dopa using benzene and catechol. 

Figure 1.13 Generation of rhodium-based supramolecularcatalysts by assembly of pyridine/hydroxypyridine pairs (a) Self-assembly modes of pyridine-based phosphines, (b) Alkene hydroformylation with supramolecular rhodium-diphosphine catalysts (c) CAChe minimized 3D structure ofthe rhodium-diphosphine complex (other ligands from the metal omitted for clarity).

P-31 NMR Comparisons of the Crystalline and Solution States of Rhodium(I) Diphosphine Catalysts... 

We previously prepared surface-bonded rhodium phosphine complexes in Al-MCM-41. In a solution of dichloromethane, [Rh(acac)(chiraphos)] and Al-MCM-41 react to a surface bonded [(Os)x-Rh(chiraphos)] complex due to an exchange reaction of the acetylacetonato ligand and surface oxygens of the acidic support12. Here we present a heterogeneous Rhodium diphosphine catalyst and its application in the enantioselective hydrogenation of dimethylitaconate. The results indicate the localisation of the complex inside of the mesoporous channel system. 

FIGURE 27 Self-assembly of diphosphine catalyst for asymmetric rhodium-complex-catalyzed hydrogenation the catalyst contains titanium as the assembly metal (96). (For a color version of this figure, the reader is referred to the Web version of this chapter.)... 

Application of this cyclization reaction to a large variety of 4-pentenals with the aid of the rhodium complex has been reported. The first example of an asymmetric cyclization of 4-pentenals via hydro acylation using a chiral rhodium diphosphine catalyst was published by Sakaki et al. in 1989 [ 104]. The diphosphine ligand ((lS,2S)-rraws-l,2-bis(diphenylphosphinomethyl)cyclohexane) having a cyclohexane backbone in the chiral center shows the better asymmetric induction than DIOP ligand. Various types of enals are applicable to this asymmetric intramolecular hydro acylation reaction [105,106]. The use of BINAP ligand as the chiral auxiliary improves the optical yield to >99% ee when 4-substituted 4-pentenals are used as the substrate (Eq. 49) [106]. Steric repulsion between the substituent at the 4-position and the substituent on the phosphine atom controls the enantiofacial selection. 

The next breakthrough was obtained when iridium was used instead of rhodium. This idea was inspired by results from Crabtree who had described an extraordinarily active Ir-tricyclohexylphosphine-pyridine catalyst that was able to hydrogenate even tetra-substituted C=C bonds. For the MEA imine hydrogenation very good ee values were obtained with an Ir-bdpp catalyst in the presence of iodide ions (ee 84% at 0°C) but the activity was disappointing. Turnover numbers (ton) of up to 10000 and tof numbers of 250/h (100 bar and 25 °C) but somewhat lower ee values were obtained with Ir-diop-iodide catalysts [10, 11], A major problem with these new Ir-diphosphine catalysts was an irreversible catalyst deactivation. 

Catalytic decarbonylation of benzaldehyde using several iridium complexes has also been examined. Results of these experiments are shown in Table 8. The main points to be made here are (i) [Ir(P-P)2] catalysts have activities that are ca. twenty times lower than their Rh analogs (ii) the iridium mono-diphosphine catalysts are better than the 6w-diphosphine Ir catalysts (opposite trend noted using rhodium, see Table 5) and (iii) IrCl(CO)(PPh3)2 is a much better catalyst than RhCl(CO)(PPh3)2 and is also better than most of the iridium diphosphine catalysts. The results for the [M(P-P)2] catalysts may be explained in terms of the proposed mechanistic scheme in Figure 11.3. Since Ir-P bonds should be stronger than Rh-P bonds, the value of ki will be smaller for the Ir catalysts, thus... 

The rates of catalytic decarbonylation of benzaldehyde using mono-diphosphine complexes of Rh and Ir provide an interesting comparison. First of all, the mono-diphosphine complexes of Rh and Ir are not robust under the conditions of the catalytic reaction and therefore are of little practical use. However, they do provide useful data for mechanistic arguments. With Rh, the bis-diphosphine catalysts [Rh(P-P)2] are always more active than their mono-diphosphine analog [Rh(P-P)] when neat aldehyde is used as solvent. Although Rh-P bond rupture is not necessary with the coordinatively unsaturated mono-diphosphine complexes, the rhodium may not be electron-rich enough to promote facile oxidative addition. In support of this argument, the presence of the diolefin cod in the coordination core, [Rh(cod)(dppp)]", increased the activity of decarbonylation by a factor of 6 compared with [Rh(dppp)]. With Ir... 

The linear-to-branched product ratios for the hydroformylation of 1-hexene 12 for various ligands was reported by van Leeuwen (Table 2-2). Both Casey and van Leeuwen have proposed and given good evidence that the regioselectivity in rhodium-diphosphine catalysts is partly related to the ability of the chelating diphosphine to maintain a chelate bite angle of-120°. This is also referred to as the bite angle hypothesis. ... 

Rhodium-Diphosphine Catalysts. The mechanism of rhodium-catalyzed asymmetric hydrogenation is one of the most intensively investigated and best understood. Reaction pathways have been accurately studied both experimentally and theoretically (138,162,213-221). In early studies, Halpern (222) and Brown (214) established that the hydrogenation proceeds according to the reaction sequence presented in Figure 51 for the hydrogenation of a dehydroamino acid with a chiral diphosphine-rhodium complex. Many variants on both catalyst and reactant have been described. Stereoselectivity takes place via the difference in reactivity of the involved diastereomeric square-planar... 

The most effective catalysts for enantioselective amino acid synthesis are coordination complexes of rhodium(I) with 1,5-cyclooctadiene (COD) and a chiral diphosphine such as (JR,jR)-l,2-bis(o-anisylphenylphosphino)ethane, the so-called DiPAMP ligand. The complex owes its chirality to the presence of the trisubstituted phosphorus atoms (Section 9.12). 

---