| Early transition metals (Ti, V, Zr, Mo, W) have been incorporated in the mesoporous silicate system by hydrothermal and post-synthesis treatments. The materials were studied by diffraction, adsorption and spectroscopic techniques and were found to have catalytic, halogenation activity toward organic substrates at neutral pH.; Intense interest has been shown in the new class of silica-based, mesoporous materials due to their high potential for catalytic applications. Their synthesis occurs via a cooperative self-assembly of surfactant/silicate pairs to form numerous, extended network structures upon silicate condensation based on liquid crystal phases of surfactant/water systems. Surfactant micelle removal by calcination generates a well defined pore system with a narrow pore size distribution. Of these phases, the cubic MCM-48 form possesses a high surface area (1200-1500m{dollar}sp2{dollar}/g), a 3-D array of pores, and a large pore diameter (20-100A) so that selectivity for large ({dollar}>{dollar}10A kinetic diameter) molecules is possible. For this work, the MCM-48 phase was chosen since its branched, bi-continuous pore array would be less likely to clog during use than a one dimensional array.; Two techniques for transition metal incorporation are compared consisting of hydrothermal and post-synthesis treatment. A brief description of an attempt to synthesize mesoporous molybdena will be included. The first approach consists of combining various metal and Si precursors in the starting gel, while exploring a broad region of the multi-component phase diagram. The second pathway involves grafting metal species on a pure silica, MCM-48 support by anchoring them to surface silanols using reactive metal alkoxides.; Bulk structural characterization by X-ray powder diffraction and nitrogen adsorption shows that the pore structure is maintained after incorporation of metal species by both methods. Spectroscopic methods (FTIR/RAMAN and UV/VIS) are used to gain insight into the local metal/silica environments. The post-synthesis and grafted materials have been shown to exhibit activity in the bromination of large, organic molecules such as phenol red at neutral pH and is a first for a non-biological system. In nature, vanadium bromoperoxidase accomplishes this task, effectively producing brominated, marine natural products with interesting pharmacological properties. The five metals were meticulously chosen based on their well known oxidative properties and ease of incorporation into the silica matrix. A discussion of the relative rates of halogenation will be based on the metal's ability to coordinate and activate peroxide ligands. |
