Award Data

In this STTR program we will first develop a high power, very narrow linewidth (CW), tunable, compact, room temperature terahertz (THz) spectroscopic system and then use this to begin development of experimentally obtained THz spectra. The THz source is based on our previous simulation and initial experimental demonstration of a novel nested waveguide structure using difference frequency generatio ...

The University of Arizona has demonstrated high-average-power all-solid-state ultraviolet (UV) lasers based on harmonic generation in borate crystals. TIPD is proposing the development of a compact, stable high power UV laser source based on the University"s exsisting CsLiB6O10 laser, developing these sources for a wide variety of applications, both commercial and defense.

NP Photonics proposes to develop an ultra-stable, compact, and highly reliable deep ultraviolet (UV) laser source for Raman spectroscopy. For this, we will draw on NP Photonics"long experience with the commercialization of single-frequency fiber lasers and amplifiers. In cooperation with the University of Arizona, we offer two technical approaches to produce the deep UV laser source. (1) High powe ...

Bridger Photonics and the University of Arizona will develop a passive multi-band compressive sensor for imaging and object recognition applications. The Army has identified a need for multi-band imagery for intelligence, surveillance and reconnaissance missions among others. Multi-band systems offer enhanced discrimination capability and the ability to perform in adverse conditions (at night, smo ...

NP Photonics proposes to develop a fiber-based, compact, tunable, THz spectroscopic/fingerprinting system that offers ultra-high resolution (< 1 MHz), high sensitivity and room temperature operation over the 1-3 THz range. This proposed system will provide high resolution molecular fingerprint information by leveraging NP Photonics high power and narrow linewidth fiber-based THz source, which is b ...

Highly scalable parallel random number generators (RNGs) will be developed, evaluated and implemented for use in high performance computing on thousands of multi-core processors and general purpose graphics processing units. The main contributions are: (a) design and implementation of new parallel test methods that capture the inter-stream correlations exhibited in practice and complement the curr ...

This STTR project seeks to develop a new manufacturing system for large-scale, low-cost production of bulk ultrafine grained (UFG) or nanostructured metals in plate, sheet or bar forms. These capabilities will be based on scale-up of a new class of machining-based processes called large strain extrusion machining (LSEM) that has been effective at creating high strength, nanoscale microstructures i ...