Synthesis of nanoparticles of TiO(2), Pt, CdS, and their binary and ternary combinations were made on zeolite Y starting from molecular precursors that are ion exchanged into the zeolite. Nanoclusters of TiO(2) in the anatase form were formed from titanyl ions at low loadings of Ti (1 per 2.5 Supercages). CdS (hexagonal form) and metallic Pt were formed from Cd(2+) and Pt(NH(3))(4)(2+) ion exchanged into the zeolite. Binary dusters of TiO(2)-Pt and TiO(2)-CdS were also synthesized. Electron microscopy and elemental analysis suggests colocalization of the distinct nanoparticles. Photocatalytic H(2) evolution is the strongest indicator of colocalization, since improvements in H2 evolution rates of similar to 100 for Pt/TiO(2)-zeolite over TiO(2)-zeolite and similar to 18 for CDS/TiO(2)-zeolite Y over CdS-zeolite Y were observed. These improvements exceed colloidal binary systems reported in the literature. However, improvements in the H(2) evolution rate of the ternary system Pt/CdS/TiO(2) was not as marked, as compared to the best colloidal ternary systems reported in the literature. A model is proposed that explains the colocalization of nanoparticles, mediated by the zeolite via a self-assembly process. This model also explains why the ternary system is not optimal; since the Pt needs to be associated only with TiO(2) for best H(2) evolution, and the zeolite-based assembly promotes a statistical colocalization of the three nanoparticles.

• 出版日期2011-2-24