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Award Data

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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.

Displaying 1 - 10 of 3879 results
  1. Pigeon- An Urban Atmospheric LiDAR

    SBC: MICHIGAN AEROSPACE CORP            Topic: C5516a

    Urban atmospheres need altitude resolved information about aerosols and winds. Measurements of these parameters in urban settings is difficult due to how quickly winds and aerosols change in space in time in congested urban settings. To enable measurements of winds and aerosols in urban atmospheres Michigan Aerospace Corporation is proposing a Phase I effort to develop and test an atmospheric Ligh ...

    SBIR Phase I 2023 Department of Energy
  2. Diamond Rheometer for the Measurement of High-Temperature Molten Salts

    SBC: GREAT LAKES CRYSTAL TECHNOLOGIES INC            Topic: C5512c

    Small, modular nuclear reactors (SMRs) offer the promise of reliable, base-load energy that is not dependent on weather. Currently, around a dozen nations have programs to develop and deploy MSRs. Challenges to the deployment of MSRs are due primarily to the corrosive and dynamic molten salt. For safe operation of the reactor it is paramount to accurately monitorandcontrolthemoltensalt properties. ...

    SBIR Phase I 2023 Department of Energy
  3. LOCAETA: Local Climate Air Emissions Tracking Atlas

    SBC: CARBON SOLUTIONS LLC            Topic: C5516c

    Air quality data from top-of-the-line platforms, such as satellites, are difficult to obtain without a high- level of technical knowledge. For this reason, local air quality patterns and trends are often inaccessible to disadvantaged communities (DACs). Many technologies that will be used for deep decarbonization of industrial and power facilities have the added co-benefit of reducing non-CO2 poll ...

    SBIR Phase I 2023 Department of Energy
  4. NECTAR: The Negative CO2 Emission Transition Roadmap

    SBC: CARBON SOLUTIONS LLC            Topic: C5322c

    C53-22c-271119Meeting climate-stabilizing energy transition goals requires using hybrid-energy CO2 capture systems like Direct Air Capture (DAC) to remove billions of tonnes of CO2 from the atmosphere. Deploying this capacity will be difficult because it is complex and energy intensive infrastructure, and there must also be buy- in from communities living in locations best suited for it. The chall ...

    SBIR Phase II 2023 Department of Energy
  5. Dielectrophoresis-Enhanced Capture of Metal Cations in Produced Water

    SBC: SCION PLASMA LLC            Topic: C5628b

    Approximately 21 billion barrels of produced water are generated each year in the United States. A lot of produced waters contain significant concentrations of sodium, magnesium, calcium, and other cations. A sufficient treatment will not only harvest the metals, but also provide freshwater for irrigation, municipal demands, mining, livestock, and manufacturing. The currently mature technologies f ...

    STTR Phase I 2023 Department of Energy
  6. Li-ion Batteries with 3-D Structured Anodes to Minimize Inactive Materials and Improve Safety

    SBC: ARBOR BATTERIES LLC            Topic: C5612a

    In order to accelerate widespread electric vehicle adoption, improving battery energy densities, charge rates, manufacturing costs, and safety is imperative. Herein, we propose a scalable manufacturing process to improve LIB cell design using 3-D electrode architectures which will minimize inactive material (30% decrease) leading to a 15% increase in cell energy density (330 Wh/kg) and a 10% decre ...

    STTR Phase I 2023 Department of Energy
  7. Design and prototyping of a novel lightweight wave energy converter (WEC) for marine energy harvesting and self-powered marine monitoring

    SBC: 4D MAKER, LLC            Topic: C5614d

    This project will develop and prototype a new class of lightweight, high-performance wave energy converters for short-duration deployment and installation in smaller-scale applications. It is anticipated that the size of the wave energy converter will be in meter or submeter scale, the weight is in kilogram level or less, while the output power will be 5~10 W/m3 or 50~100 mW/kg. The novel energy h ...

    STTR Phase I 2023 Department of Energy
  8. Ruggedized, Turn-key Sensing Package for AZMI Pressure Monitoring

    SBC: AIRFLOW SCIENCES CORP            Topic: C5625e

    C56-25e-272785The emission of carbon dioxide gases from industrial facilities can be harmful to the environment and contribute to global warming. By using existing technologies to capture and store these gases in deep underground reservoirs, industry can meet emissions goals while still satisfying energy demand. To ensure permanence and prevent environmental impact, the carbon dioxide storage site ...

    SBIR Phase I 2023 Department of Energy
  9. Shared Mobility Optimizer

    SBC: TERRACITY LLC            Topic: C5610c

    In the United States, transportation is the leading source of emissions among major industries. This puts pressure on cities to optimize transportation infrastructures to meet decarbonization goals. City planners are required to ingest data from a variety of sources and balance a wide array of priorities ranging from mobility and equality to safety and sustainability. Making decisions for optimal ...

    SBIR Phase I 2023 Department of Energy
  10. Li-ion Batteries with 3-D Structured Anodes to Minimize Inactive Materials and Improve Safety

    SBC: ARBOR BATTERIES LLC            Topic: C5612a

    In order to accelerate widespread electric vehicle adoption, improving battery energy densities, charge rates, manufacturing costs, and safety is imperative. Herein, we propose a scalable manufacturing process to improve LIB cell design using 3-D electrode architectures which will minimize inactive material (30% decrease) leading to a 15% increase in cell energy density (330 Wh/kg) and a 10% decre ...

    SBIR Phase I 2023 Department of Energy
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