Award Data

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The Award database is continually updated throughout the year. As a result, data for FY19 is not expected to be complete until June, 2020.

  1. 6000297

    SBC: Chip Design Systems LLC            Topic: AF18AT017

    We propose to develop an innovative concept of the high speed dynamic IRSP that combines components and devices from proven suppliers with novel system-level research topics from CDS and University of Delaware. Having previously built and delivered working LED IRSPs to users gives CDS a unique advantage. In line with system theme of the solicitation, our phase 1 research topics are focused on syst ...

    STTR Phase I 2018 Department of DefenseAir Force
  2. A High Temperature (400 to 650oC) Secondary Storage Battery Based on Liquid Sodium and Potassium Anodes

    SBC: Materials and Systems Research, Inc.            Topic: 15

    This project will develop technolgy for integrating a high-temperature (400 to 700ºC), high-efficiency (greater than 90%) secondary battery with a 3 to 10 kW solid oxide fuel cell (SOFC) system. The battery will be based on an alkali-metal-ion-conducting, highly refractory, beta alumina solid electrolyte (BASE) and a non corrosive metal salt. The battery is expected not only to meet or exceed w ...

    STTR Phase I 2006 Department of Energy
  3. A miniature, low-cost black carbon sensor for unmanned platforms

    SBC: Handix Scientific LLC            Topic: 17b

    Achieving a systems-level understanding of science associated with climate change is a key topic within the DOE mission. Light absorbing particles are an important atmospheric constituent and have a direct impact on climate. They also impact air quality and health and human activities play a major role in their abundance and distribution. There is a critical need for improved observational capacit ...

    STTR Phase I 2016 Department of Energy
  4. A Multiscale Modeling and Simulation Framework for Predicting After-Burning Effects from Non-Ideal Explosives

    SBC: Reaction Engineering International            Topic: N10AT002

    The primary objective of the proposed effort is to develop a validated computational tool to predict the afterburning of non-ideal munitions containing metal and hydrocarbon fuels. The activities outlined devise a well-coordinated collaboration among researchers from Reaction Engineering International (REI) and the State University of New York at Buffalo (UB). The activities proposed will build on ...

    STTR Phase I 2010 Department of DefenseNavy
  5. A Multiscale Modeling and Simulation Framework for Predicting After-Burning Effects from Non-Ideal Explosives

    SBC: Reaction Engineering International            Topic: N10AT002

    The objective of the proposed Phase II STTR effort is to develop a validated computational tool to predict the afterburning of non-ideal munitions containing metal and hydrocarbon fuels. The activities outlined devise a well-coordinated collaboration among researchers from Reaction Engineering International (REI) and the State University of New York at Buffalo (UB). The activities proposed will bu ...

    STTR Phase II 2011 Department of DefenseNavy
  6. A Multiscale Modeling and Simulation Framework for Predicting After-Burning Effects from Non-Ideal Explosives

    SBC: Reaction Engineering International            Topic: N10AT002

    The objective of the proposed Phase II STTR effort is to develop a validated computational tool to predict the afterburning of non-ideal munitions containing metal and hydrocarbon fuels. The activities outlined devise a well-coordinated collaboration among researchers from Reaction Engineering International (REI) and the State University of New York at Buffalo (UB). The activities proposed will bu ...

    STTR Phase II 2015 Department of DefenseNavy
  7. A Novel Noninvasive Microwave Sensor for Quantitative Assessment of Degree of Sensitization in Marine Aluminum Alloys

    SBC: ALPHASENSE, INC.            Topic: N09T022

    In phase I, we have proven the feasibility of using the microwave cavity perturbation technique to detect and quantify DoS in marine aluminum alloys. We implemented an alpha version sensor prototype, characterized and validated its performance using ASTM G67 method. We also identified methods to further enhance the sensor sensitivity, so that DoS in the low (a few mg/cm2) to moderate range can be ...

    STTR Phase II 2010 Department of DefenseNavy
  8. A Novel Noninvasive Microwave Sensor for Quantitative Assessment of Degree of Sensitization in Marine Aluminum Alloys

    SBC: ALPHASENSE, INC.            Topic: N09T022

    In this proposal, AlphaSense, Inc. (AI) and the Pennsylvania State University (PSU) detail the development of a novel noninvasive microwave sensor to quantify the DoS in marine aluminum alloys. The key innovations of this proposal include the following: a) DoS quantifications based on the correlation between the surface resistivity with the microstructures of the aluminum alloys, b) measurements o ...

    STTR Phase I 2009 Department of DefenseNavy
  9. A Phase I Program to the Low Temperature Performance of Li-ion Batteries

    SBC: Yardney Technical Products, Inc.            Topic: 17b

    79758B Safety concerns over the susceptibility of large Li-ion cells to thermal runaway during overcharge are one of the problems preventing the commercialization of these cells. This problem will be addressed by developing new materials that will be substituted for the cell component believed to be involved in the runaway process. In particular, electrolyte systems that form less a resistive i ...

    STTR Phase I 2005 Department of Energy
  10. A Platform-Independent Framerwork for Efficient Massively Parallel Execution

    SBC: EM PHOTONICS INC            Topic: OSD11T02

    Next-generation high-performance computers (HPCs) are built as massively parallel systems where the parallelism exists at many levels. These systems are a collection of nodes all working together. Each node generally contains more than one processor and each processor contains multiple cores. Managing and efficiently utilizing the different parallelism in such a system is a complex task. Furth ...

    STTR Phase I 2012 Department of DefenseAir Force
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