Rhodium binding

Alternatively, the rhodium complexes of 4 exhibit enhanced performance relative to the ferrocene diphosphine analog 3 which cannot be explained simply as a switch from one binding mode to another. P NMR experiments on in situ formed rhodium complexes are useful for correlating rhodium binding of different ligands in solution when a single species dominates, but are inconclusive when multiple phosphorus resonances are observed. Preparation and isolation of preformed complexes may provide better systems for study by NMR spectroscopy. 

The rhodium binding energy is 0.5 eV higher in the case of the bis-isocyanide derivative. This is in favor of the effective ji back donation from metal to ligand that is also reflected by the energy of the isocyanide stretching vibration in the IR spectrum of the complex. 

In class (1), a range of small molecules adds to rhodium, usually with the loss of one PPh3, thus maintaining the 16-electron configuration, rather than an 18-electron species unable to bind a substrate. 

ESCA data support a rhodium(II) oxidation state in these compounds. Therefore, the Rh 3d5//2 binding energy is c. 309.2 eV in simple car-boxylates, midway between those in typical rhodium(I) complexes (c. 308.5 eV) and rhodium(III) complexes (c. 310.7 eV) [72],... 

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. 

The use of rhodium catalysts for the synthesis of a-amino acids by asymmetric hydrogenation of V-acyl dehydro amino acids, frequently in combination with the use of a biocatalyst to upgrade the enantioselectivity and cleave the acyl group which acts as a secondary binding site for the catalyst, has been well-documented. While DuPhos and BPE derived catalysts are suitable for a broad array of dehydroamino acid substrates, a particular challenge posed by a hydrogenation approach to 3,3-diphenylalanine is that the olefin substrate is tetra-substituted and therefore would be expected to have a much lower activity compared to substrates which have been previously examined. 

An especially important case is the enantioselective hydrogenation of a-amidoacrylic acids, which leads to a-aminoacids.29 A particularly detailed study has been carried out on the mechanism of reduction of methyl Z-a-acetamidocinnamate by a rhodium catalyst with a chiral diphosphine ligand DIPAMP.30 It has been concluded that the reactant can bind reversibly to the catalyst to give either of two complexes. Addition of hydrogen at rhodium then leads to a reactive rhodium hydride and eventually to product. Interestingly, the addition of hydrogen occurs most rapidly in the minor isomeric complex, and the enantioselectivity is due to this kinetic preference. 

Many carbonyl and carbonyl metallate complexes of the second and third row, in low oxidation states, are basic in nature and, for this reason, adequate intermediates for the formation of metal— metal bonds of a donor-acceptor nature. Furthermore, the structural similarity and isolobal relationship between the proton and group 11 cations has lead to the synthesis of a high number of cluster complexes with silver—metal bonds.1534"1535 Thus, silver(I) binds to ruthenium,15 1556 osmium,1557-1560 rhodium,1561,1562 iron,1563-1572 cobalt,1573 chromium, molybdenum, or tungsten,1574-1576 rhe-nium, niobium or tantalum, or nickel. Some examples are shown in Figure 17. 

Poisoning phosphites are particularly undesirable because their smaller steric bulk allows them to bind to the rhodium catalyst and inhibit hydroformylation. 

A very interesting development is the incorporation of an achiral di-phosphinerhodium(I) moiety at a specific site in the protein avidin (268). The protein binds biotin, which was first converted to the cationic rhodium complex shown in 42. a-Acetamidoacrylic acid was converted to N-acetylalanine with 40% ee in aqueous solution at pH 7 (0°C, 1.5 atm H2). 

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