| abstract |
The present invention concerns an electronically conductive polymer film comprising colloidal catalytic particles homogeneously dispersed therein. The electronically conductive polymer is preferably polypyrrole although other conductive polymers, for example, polyaniline and polythiophene are also utilizable. The preferred catalytic particles are platinum although other catalytic particles such as RuO2, Ag, Pd, Ni, Cd, Co, Mo, Mn-oxide, Mn-sulfide, a molybdate, a tungstate, tungsten carbide, a thiospinel, Ru, Rh, Os, It, or a platinum palladium alloy (Pt/Pd). The colloidal catalytic particles incorporated in the film of the present invention are less than 100 nanometers in size, preferably about 10 nm in size. In a most preferred composition, the polymer is polypyrrole and the catalytic particles are platinum. The present invention also involves a method of producing an electronically conductive polymer film containing colloidal catalytic particles homogeneously dispersed therein. This method comprises: 1) preparing a colloidal suspension of catalytic particles in a solution comprising an electronically conductive polymer precursor. The catalytic particles may be those listed above, preferably platinum, and the electronically conductive polymer precursor is preferably pyrrole although aniline and thiophene or other monomers leading to conductive polymers may also be utilized analogously. An electronically conductive polymer film is then electrosynthesized, incorporating homogeneously dispersed colloidal catalytic particles. In an important embodiment of the present invention, colloidal platinum particles are produced by citrate reduction of Pt (IV) to Pt0. Most preferably, this citrate reduction involves a sub-stoichiometric level of citrate as compared to the Pt (IV) level. Another important aspect of the present invention is the utilization of the porous conductive polymeric matrix of the present invention which includes homogeneously dispersed colloidal catalytic particles to catalyze a reaction. Such a catalytic reaction involves subjection of reactants to this material in an electrochemically conductive or other context. Advantages of this type of catalysis involves ready retrieval of the catalytic particles, efficient utilization of expensive catalytic particles such as platinum, resistance of the particles to at least high molecular weight poisons which will not penetrate the polymeric matrix and, finally, the lack of saturation of catalytic activity in contrast to that seen with surface coated thin polymer layers. |