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The Award database is continually updated throughout the year. As a result, data for FY24 is not expected to be complete until March, 2025.

Download all SBIR.gov award data either with award abstracts (290MB) or without award abstracts (65MB). A data dictionary and additional information is located on the Data Resource Page. Files are refreshed monthly.

The SBIR.gov award data files now contain the required fields to calculate award timeliness for individual awards or for an agency or branch. Additional information on calculating award timeliness is available on the Data Resource Page.

  1. Accelerated Linear Algebra Solvers for Multi-Core GPU-Based Computing Architectures

    SBC: EM PHOTONICS INC            Topic: AF09BT18

    ABSTRACT: High-performance computing (HPC) programmers and domain experts, such as those in the Air Force's research divisions, develop solvers for a wide variety of application areas such as modeling next generation aircraft and weapons designs and advanced image processing analysis. When developing software for HPC systems, the programmer should not spend the majority of their time optimiz ...

    STTR Phase II 2012 Department of DefenseAir Force
  2. Acoustic Intensity Localization System

    SBC: Applied Physical Sciences Corp.            Topic: N04T020

    Applied Physical Sciences Corp. (APS) proposes the Phase II development of an Acoustic Intensity Localization System (AILS). AILS utilizes a vector hydrophone to measure the latitude-longitude offset to an acoustic projector attached to surface buoy whose position is known via GPS. A major advantage of the AILS concept is that it can operate with extreme precision even at relatively low frequenc ...

    STTR Phase II 2005 Department of DefenseNavy
  3. Additive Manufacturing for Naval Aviation Battery Applications

    SBC: STORAGENERGY TECHNOLOGIES INC            Topic: N18AT008

    The objective of the efforts being proposed is to develop high energy density and power density batteries with long cycle life by high-speed additive manufacturing technologies.

    STTR Phase II 2019 Department of DefenseNavy
  4. Additive Manufacturing of Thermoset Polymers Using Projection-based Stereolithography

    SBC: STORAGENERGY TECHNOLOGIES INC            Topic: A20BT010

    Storagenergy proposes a novel methodology that allows for the 3D printing of different thermally cured thermosets in a fast and precise additive manufacturing process. The proposed approach has several advantages over other technologies for additive manufacturing of thermoset polymers including (1) High feature resolution and structure complexity (2) Fast fabrication speed (3) No post therma ...

    STTR Phase II 2022 Department of DefenseArmy
  5. Advanced Neutrally Buoyant Rechargeable Batteries Based on Ceramic Electrolyte Separators

    SBC: Technology Holding, LLC            Topic: N07T022

    A battery is proposed that utilizes a Li+ conducting, solid-electrolyte separator, LiSICON, Li metal anode and high-capacity cathode. The LiSICON ceramic is fabricated using state of the art tape casting methods which allows composite structures of porous and dense layers ~100ƒÝm thick. The layered structure increase mechanical strength and decrease interfacial and bulk resistances. The high-ene ...

    STTR Phase II 2009 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 2011 Department of DefenseNavy
  7. 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
  8. 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
  9. Application of Novel Composite Techniques in the Building of a VTOL Aircraft

    SBC: ELECTRAFLY LLC            Topic: AFX20DTCSO1

    Composites manufacturing using autoclave cured pre-preg materials is expensive, often size limited, labor intensive, and has slow cycle times limiting production. The AFRL reported the need for improved composite research and demonstrations related to the emerging Advanced Air Mobility market. This project will use novel, out of autoclave composite manufacturing methods including composites based ...

    STTR Phase II 2022 Department of DefenseAir Force
  10. A Pressure-Dependent Detailed Chemical Kinetic Model for JP-10 Combustion

    SBC: REACTION ENGINEERING INTERNATIONAL            Topic: N09T011

    Investigations into JP-10 combustion chemistry thus far can be characterized as preliminary. The detailed chemical kinetic mechanisms that have been published are limited in their ability to reproduce experimental data. The combustion chemistry of JP-10 is highly complex, involving hundreds if not thousands of species and thousands of chemical reactions. A detailed kinetic model capable of predict ...

    STTR Phase II 2010 Department of DefenseNavy
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