Award Data

This Small Business Technology Transfer Research (STTR) Phase II project has the overall objective of developing a multi-component melt spinning approach to produce a new family of high performance fibers using standard low-cost polymers. The new high-strength and/or high-modulus polymeric fiber is to be made using cutting-edge but commercially available spinning technology and an innovative and ...

This Small Business Technology Transfer Phase I project will develop a new system for fabrication and manipulation of carbon nanotube (CNT) composites. The system will use holographic optical trapping (HOT) with a spatial light modulator (SLM) and a new form of nano-controlled photo-polymerization. This tool will allow the creation of a new class of carbon-nanotube polymer composite materials wit ...

This Small Business Technology Transfer (STTR) Phase II project seeks to identify new and improved promoters to create enhanced genetically modified crops. Plant biotechnology relies on the insertion of promoter-gene constructs into plants. The promoter is the portion of DNA that controls when and where a gene is expressed. The relatively few plant promoters in use today have significant limitatio ...

Currently large capacity cryostats, capable of hosting experiments for many qubits, require expensive and hard to obtain liquid cryogens. A few small cryo-free systems exist but they are non-ideal for this use. An opportunity exists for a large scale, c

This Small Business Technology Transfer (STTR) Phase II project is a study to expand the high speed addressing work conducted under Phase I using monochrome Plasma-spheres to color Plasma-spheres. Plasma-spheres are hollow transparent shells that encapsulate a selected pressurized gas. When a voltage is applied across the shell, the gas ionizes and glows. Plasma-spheres are applied to flexible, el ...

Bright coherent light sources in the soft x-ray region of the spectrum are useful for a variety of applications of interest to DOE in the basic sciences, nanoscience and biology, and for technological applications. At Free-Electron Laser Facilities, peak power output of the x-ray pulses is enhanced by using a mid-infrared laser pulse instead of a near-infrared pulse. The current front end for mid- ...

This Small Business Technology Transfer (STTR) Phase II project will develop a multi-functional active fiber Bragg grating sensor technology for the monitoring and management of cryogenic fuel such as liquid hydrogen and liquefied natural gas. The proposed technology uses in-fiber light to actively adjust sensor temperature, which will drastically improve responsivity and sensitivity of fiber sens ...

This Small Business Technology Transfer Phase I project will address the critical need for low driving voltage, adaptive materials providing large phase retardation (for ultraviolet, visible, and infrared wavelengths) within a sub-millisecond time frame. Two technologically innovative tasks will be pursued in parallel and then merged, resulting in the creation of a new class of optical materials - ...

The development of advanced, realtime, operator-in-the-loop tire/track/soil models, which can predict power and energy requirements, is an essential requirement for determining operational profiles for vehicles, especially hybrids, during the design and d

NanoSonic has demonstrated that Shape Memory Metal RubberTM (SM-MR) adaptive skins exhibit reconfigurable and durable RF properties. It is hypothesized that such morphing skins shall also exhibit durable radiation resistance upon morphing; a property that few, if any, flexible materials offer. Typical highly filled or metal evaporated nanocomposites crack and spall upon flexation, and cannot be ...