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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. Rotary Steerable Motor System for Deep Gas Drilling

    SBC: Aps Technology, Inc.            Topic: N/A

    70860 Current drilling systems (e.g., steerable systems and rotary steerable tools) have limitations when drilling deep wells, particularly in applying high torque to the drill bit. Hole tortuosity causes steerable systems to generate a high degree of drag; drag also reduces the drill-bit-torque in rotary steerable tools. Other systems (e.g., percussion) develop high vibrations that can damage ...

    SBIR Phase I 2003 Department of Energy
  2. Preceramic Precursor Routes to Tailorable, Low-Activation, Silicon-Carbide-Based Joints

    SBC: Technology Holding, LLC            Topic: N/A

    72957S03-I Energy from thermonuclear fusion systems offers a long range option for decreasing U.S. dependence on foreign energy sources, enhancing national security, and mitigating climate change. Of the current options available for first-wall materials, composites made from silicon carbide fibers, incorporated in a matrix of silicon carbide (SiCf/SiCm), are a leading candidate. In order to ut ...

    SBIR Phase I 2003 Department of Energy
  3. Perovskite/Oxide Composites as Mixed Protonic/Electronic Conductors for Hydrogen Recovery in IGCC Systems

    SBC: Technology Holding, LLC            Topic: N/A

    70103 Integrated Gasification Combined Cycle (IGCC) systems are promising new alternatives for highly efficient and environmentally friendly power generation. In order to make these systems commercially viable, a portion of the hydrogen in syngas needs to be recovered as a value-added byproduct through the use of hydrogen separation membranes such as proton-conducting membranes. Since curren ...

    SBIR Phase I 2003 Department of Energy
  4. Tailorable, Environmental Barrier Coatings for Super- Alloy Turbine Components in Syngas

    SBC: Technology Holding, LLC            Topic: N/A

    72505S03-I Integrated gasification combined cycle (IGCC) coal combustion has the potential for significantly improving the efficiency of converting coal power and for reducing emissions. However, corrosion in the syngas environment limits the lifetime of IGCC components and increases cost. This project will develop low-cost, dip-coated ceramic coatings to prevent the high temperature corrosion ...

    SBIR Phase I 2003 Department of Energy
  5. Advanced Net-Shape Insulation for Solid Oxide Fuel Cells

    SBC: Technology Holding, LLC            Topic: N/A

    73138S03-I As solid oxide fuel cell technology matures, it is becoming increasingly important to lower the cost of insulation. Currently available low-cost insulation cannot be used in these applications because it contains silica, which volatilizes and degrades the anode. Therefore, new low-cost, net-shape options for solid oxide fuel cell insulation are needed. This project will develop a no ...

    SBIR Phase I 2003 Department of Energy
  6. Molecular-Sieve-Based Nano-Cathode Structures for PEM Fuel Cells

    SBC: FuelCell Energy, Inc.            Topic: N/A

    72714S03-I The Proton Exchange Membrane (PEM) fuel cell uses an electrochemical process to generate electricity with zero emissions and high efficiency. Current state-of-the-art PEM fuel cells, operating at ambient pressure, have a power density of 100milliWatt/cm2 at 0.8V. However, power density enhancements greater than 200% would be required to meet the cost and performance targets for autom ...

    SBIR Phase I 2003 Department of Energy
  7. A GEM of a Neutron Detector

    SBC: Instrumentation Associates            Topic: N/A

    72488S03-I Current neutron detectors will not be able to adequately handle the expected instrument data rates at the DOE¿s new neutron beam research facilities, nor do they have sufficient position and time resolution. This project will develop a new class of neutron detectors that employ the gaseous electron multiplier (GEM). These detectors not only will have significantly better position an ...

    SBIR Phase I 2003 Department of Energy
  8. Improved Silicon Carbide Materials for Very High-Temperature, Fast-Spectrum Nuclear Energy Systems

    SBC: Lightweight Solutions, Inc.            Topic: N/A

    72556B03-I Advanced materials are sought that can meet the very demanding conditions required for a fast spectrum nuclear energy system to operate at temperatures greater than 900¿C. Silicon carbide (SiC)-based materials are prime candidates and have received extensive investigation; however, there remains a need for improved material performance, reduced manufacturing costs, and improved fabri ...

    SBIR Phase I 2003 Department of Energy
  9. LSGM Based Composite Cathodes for Anode Supported, Intermediate Temperature (600-800 degrees C) Solid Oxide Fuel Cells (SOFC)

    SBC: Materials and Systems Research, Inc.            Topic: N/A

    70437S02-II Increasing the power density of solid oxide fuel cells (SOFC) can substantially reduce the costs of SOFC technology by decreasing the stack size, which in turn decreases the amount of materials necessary, reduces the size of the balance of plant, and decreases the size and amount of requisite stack hardware and insulation. Likewise, lowering the operating temperature of SOFC lowers ...

    SBIR Phase I 2003 Department of Energy
  10. DNA Amplification of the Whole Genome from a Single Cell

    SBC: MOLECULAR STAGING, INC.            Topic: N/A

    70555S02-II DNA sequencing is currently not possible when starting from single bacterial cells because of the limited amount of DNA present. Typical medical and biological samples contain a heterogeneous mixture of species; therefore, obtaining a sufficient amount of DNA requires a time-consuming and labor-intensive approach involving the isolation and culture of bacterial cells. Since most ...

    SBIR Phase I 2003 Department of Energy
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