Catalysts systems polymer-supported

Kashiwa, N. Yoshitake, J. Toyota, A. Studies on propylene polymerization with a highly active MgCl2-supported TiCU catalyst system. Polym. Bull. (Berlin) 1988, 19, 333-338. 

The solution to this problem has been to attach these catalysts to polymer supports. The ideal polymer-bound catalyst must satisfy a formidable list of requirements. It should be easily prepared from low cost materials. The support must be compatible with the solvent system employed, and be chemically and thermally stable under the reaction conditions. The catalyst should show minimal losses in reaction rate or selectivity when bound to the support, and should be able to be recycled many times without loss of activity. Finally, the interactions between the catalytic site and the support must be either negligible or beneficial. The development of polymer supported rhodium-phosphine catalysts for the asymmetric hydrogenation of amino acid precursors illustrates the incremental process which has led to supports which approach the ideal support. 

Montedison and Mitsui Petrochemical iatroduced MgCl2-supported high yield catalysts ia 1975 (7). These third-generation catalyst systems reduced the level of corrosive catalyst residues to the extent that neutralization or removal from the polymer was not required. Stereospecificity, however, was iasufficient to eliminate the requirement for removal of the atactic polymer fraction. These catalysts are used ia the Montedison high yield slurry process (Fig. 9), which demonstrates the process simplification achieved when the sections for polymer de-ashing and separation and purification of the hydrocarbon diluent and alcohol are eliminated (121). These catalysts have also been used ia retrofitted RexaH (El Paso) Hquid monomer processes, eliminating the de-ashing sections of the plant (Fig. 10) (129). 

An inverted system based on the C02-soluble catalyst Pd(OAc)2/PtBu3 has been utilized for Suzuki-coupling of resin-bound substrates [33], The use of scC02 with polymer-supported substrates seems highly attractive owing to the known plasticizing... 

There are several polymer supported transition metal hydrofomylation catalysts (42 ). Most are attached by phosphine ligation and suffer fron catalyst leaching. There are no n5-cyclo-pentadienyl half sandwich systems despite the potentially, clearly advantageous presence of the relatively strong Cp-metal bond (43,MO. Resin 5 was used in the following brief study in which the potential of polystyrene-supported CpCo(C0)2 to function as a hydrofomylation catalyst was tested. 

Study of the kinetics of the oxidation of asymmetric secondary hydroxylamines to nitrones with H2O2, catalyzed by methylrhenium trioxide, has led to the elucidation of the mechanism of the reaction (104). Full transformation of N,N -disubstituted hydroxylamines into nitrones upon treatment with H2O2 occurs on using polymeric heterogeneous catalysts such as polymer-supported methylrhenium trioxide systems (105). 

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