SBIR-STTR Award

The Small Business Technology Transfer Research (STTR) Phase I project addresses the scale-up to kilogram quantities of a novel university laboratory solid-state method of synthesizing metal oxide and metal nanoparticles by mixing common chemical starting materials and baking the resulting precursor material at modest temperatures; and the dispersment of the loosely agglomerated particles for commercial applications. The synthetic method will be, low cost, environmentally friendly and will yield high quality materials. Commercial applications include coatings for abrasion, ultraviolet radiation and heat protection. Because of their small size, high crystallinity and purity, applications as catalysts are being explored. Also, because of their crystallinity, the particles retain the properties (e.g., magnetism) of the bulk material which can be useful for applications as diverse as medical imaging contrast agents and electronic memory. Metal oxide or metal nanoparticles can be made of any transition metal, actinide or lanthanide which can also be doped with metals from Groups I and II, and they can be made with any combination of any number of these metals in any stoichiometric ratio, hence these limitless new compositions are finding unique applications in fuel cells, batteries, catalysts, etc

This Small Business Technology Transfer (STTR) Phase II project aims to develop a manufacturing process to synthesize metal oxide, sulfide and other nanoparticles. The subject method simply involves mixing of common dry chemical starting materials and heating the resulting precursor material to a modest temperature. The objective is to demonstrate feasibility and scalability of this low-cost manufacturing process. Methods of dispersing aggregated particles in aqueous and polar solvents will be also be investigated.The broader/commercial impact of this project will be the potential to offer a cost-effective and environmentally-friendly process to produce a broad spectrum of high quality nanoparticles. Current methods of making nanoparticles involve heavy energy consumption, large amounts of waste, and/or purification problems. The synthetic approach in this project has the potential to become the method of choice to supply novel nanoparticles in many low to high technology applications. It is anticipated to obtain nanoparticles with particle sizes less than 15 nm, size variations within ±10-20%, and purities as high as 99.9999%.