New materials - chemical compounds - are at the core of advanced technologies, such as fuel cells, blue-ray DVD players, smart phones, and lasers. The challenge lies in not only discovering a new material, but also understanding its technologically relevant properties. If advancements in technology are to occur - and such advancements are critical if the United States is to remain the leader in science - the discovery and understanding of new materials are critical. This fundamental research project, supported by the Solid State and Materials Chemistry Program in the Division of Materials Research, involves the design, discovery, and crystal growth of new materials for advanced technologies. Specifically, the research team is focused on new materials for laser applications. The aim is to discover materials that enable lasing technologies, i.e. coherent radiation, in the ultraviolet and deep-ultraviolet wavelengths - below 300 nanometers. Coherent radiation in these wavelength ranges is critically needed for advanced technologies and devices, and the proposed materials will positively impact these technologies. Finally, there will be a specific emphasis on recruiting underrepresented groups in STEM to the research group as the University of Houston is designated as a Hispanic-Serving Institution (HSI).
This research project, supported by the Solid State and Materials Chemistry Program in the Division of Materials Research, involves the design, synthesis, structure, functional property characterization, and structure-property relationships of new functional inorganic materials - mixed alkali and alkaline earth borate oxyfluorides and mixed alkali and alkaline-earth metal nitrates - for ultraviolet (UV) and deep-ultraviolet (DUV) nonlinear optical (NLO) applications. An ongoing challenge in inorganic solid-state chemistry is the ‘rational design’ of new materials - to design and synthesize precise stoichiometries that will exhibit specific, and ideally, technologically important properties. Meeting this challenge not only requires synthetic expertise, but also a deep understanding of the various bonding and crystal chemistry requirements for the desired physical property. To further this understanding, the research team at the University of Houston not only synthesizes new materials, but also develops structure-property relationships. In addition to bulk phase synthesis, the growth of large, centimeter size, crystals is planned. Large single crystals are crucial in order to thoroughly investigate and understand the functional properties. Top-seeded solution growth methods can be employed for the crystal growth. The materials are characterized structurally by X-ray diffraction - powder and single crystal - and physical property measurements will include, thermogravimetric analysis, differential scanning calorimetry, and second-harmonic generation measurements. Through this holistic approach - synthesis, crystal growth, characterization, and structure-property relationships - the research team aims to profoundly advance the field.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
