SBIR-STTR Award

Titania (TiO2) is known to be a photocatalyst, in that when illuminated with ultra-violet (UV) light equivalent in energy to the bandgap of titania, it becomes an electrically active semiconductor and can generate enough surface energy to dissociate hydrogen and oxygen from water. However, there is very little of UV of the required wavelength in solar light, and so hydrogen generation in sunlight is extremely inefficient. We have discovered, however, that we can shift and lower the bandgap of titania into a region where it become photocatalytically active with visible light, by creating and managing tremendous pressures within the titania thin film layer. This is done by a combination of layer thickness, template geometry, and thermal mismatch between the polycarbonate substrate and the titania. Because the layer of titania is so thin, extremely high stresses can be induced, and with them, large bandgap shift. And because of the template geometry, the thin titania stays intact in spite of the large stress because of superior mechanical and chemical adhesion to the substrate. In addition, titania has a high refractive index of 2.4, and so makes for very powerful light concentration within the film. POTENTIAL COMMERCIAL APPLICATIONS Chemical storage of solar energy in the form of hydrogen, clean hydrogen fuel generation and desalination by-product for coastal cities and third world countries, photo-activated decontamination of water, recharger for micro fuel cells.

Phase II will continue developing the efficient production of hydrogen from water using sunlight and nanostructured titania thin-film semiconductor electrodes achieved in Phase I, delivering a solar hydrogen generator. Titania?s (TiO2) absorption cutoff is moved from UV (414 nm) to visible (529 nm) by shifting the energy bandgap to 2.0 eV , through stress induced by the nanostructured template. The disorder/strain distribution forms amorphous/strained titania with a high density of states localized within the energy band gap. Absorption of 29% of the solar spectrum is achieved, more than 5X improvement over single-crystal TiO2. The nanostructures enhance total absorption through multiple total internal reflections, eliminating the need to track the sun. A prototype three-electrode electrochemical cell evolves hydrogen at 2 mL/(s?W?m2) ? a solar-efficiency of 8% after light source correction; electrochemistry data shows 20% efficiency is attainable. Efficient conversion of water to hydrogen fuel with sunlight is ideal for closed environments like the International Space Station, with continuous recycling of hydrogen from contaminated water back to clean water when combined with a fuel-cell electrical generator. With possible water on the moon, Mars, and other bodies in the solar system, this technology will greatly reduce the mass of space ships for future missions.