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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.

  1. Dynamic IR Window Film to Improve Window Energy Efficiency

    SBC: IR Dynamics            Topic: DEFOA0001429

    IR Dynamics, LLC will develop a low-cost nanomaterial technology to be incorporated into flexible window films that will improve thermal insulation and solar heat gain. The team's nanomaterial will incorporate two materials. First, low-cost nanosheets will increase thermal resistance. Second, a new type of nanomaterial will allow heat, in the form of infrared radiation (IR) from the sun, to pass t ...

    SBIR Phase II 2016 Department of EnergyARPA-E
  2. Stationary Wide-Angle Concentrator PV System

    SBC: GLINT PHOTONICS, INC.            Topic: MOSAIC

    Concentrator PV systems using highly efficient multijunction photovoltaic cells hold out the promise of very low-cost solar electricity generation, but their adoption has been hamstrung by the requirement for bulky mechanical trackers that add cost, diminish land use, increase maintenance, and exclude roof-top installations. The Stationary Wide-Angle Concentrator (SWAC) PV system will provides the ...

    SBIR Phase II 2016 Department of EnergyARPA-E
  3. Retrofittable and Transparent Super-Insulator for Single-Pane Windows

    SBC: NANOSD, INC.            Topic: DEFOA0001429

    NanoSD, Inc. with its partners will develop a transparent, nanostructured thermally insulating film that can be applied to existing single-pane windows to reduce heat loss. To produce the nanostructured film, the team will create hollow ceramic or polymer nanobubbles and consolidate them into a dense lattice structure using heat and compression. Because it is mostly air, the resulting nanobubble s ...

    STTR Phase II 2016 Department of EnergyARPA-E
  4. Retrofittable and Transparent Super-Insulator for Single-Pane Windows

    SBC: NANOSD, INC.            Topic: DEFOA0001429

    NanoSD, Inc. with its partners will develop a transparent, nanostructured thermally insulating film that can be applied to existing single-pane windows to reduce heat loss. To produce the nanostructured film, the team will create hollow ceramic or polymer nanobubbles and consolidate them into a dense lattice structure using heat and compression. Because it is mostly air, the resulting nanobubble s ...

    SBIR Phase I 2016 Department of EnergyARPA-E
  5. Dynamic IR Window Film to Improve Window Energy Efficiency

    SBC: IR Dynamics            Topic: DEFOA0001429

    IR Dynamics, LLC will develop a low-cost nanomaterial technology to be incorporated into flexible window films that will improve thermal insulation and solar heat gain. The team's nanomaterial will incorporate two materials. First, low-cost nanosheets will increase thermal resistance. Second, a new type of nanomaterial will allow heat, in the form of infrared radiation (IR) from the sun, to pass t ...

    SBIR Phase II 2016 Department of EnergyARPA-E
  6. Low-Cost Biological Solution for Reducing Carbon Pollution in Chemical Manufacturing

    SBC: INDUSTRIAL MICROBES INC            Topic: 14NCER1A

    Industrial Microbes is developing a green fermentation platform to replace carbon-emitting petrochemical production with newer methods that build chemicals out of methane and carbon dioxide.Chemical production is a major source of carbon pollution, responsible for 18% of direct industrialemissions. Our innovation is an engineered microbe that can consume carbon dioxide and methane and produce a ch ...

    SBIR Phase II 2016 Environmental Protection Agency
  7. Dynamic IR Window Film to Improve Window Energy Efficiency

    SBC: IR Dynamics            Topic: DEFOA0001429

    IR Dynamics, LLC will develop a low-cost nanomaterial technology to be incorporated into flexible window films that will improve thermal insulation and solar heat gain. The team's nanomaterial will incorporate two materials. First, low-cost nanosheets will increase thermal resistance. Second, a new type of nanomaterial will allow heat, in the form of infrared radiation (IR) from the sun, to pass t ...

    SBIR Phase I 2016 Department of EnergyARPA-E
  8. Retrofittable and Transparent Super-Insulator for Single-Pane Windows

    SBC: NANOSD, INC.            Topic: DEFOA0001429

    NanoSD, Inc. with its partners will develop a transparent, nanostructured thermally insulating film that can be applied to existing single-pane windows to reduce heat loss. To produce the nanostructured film, the team will create hollow ceramic or polymer nanobubbles and consolidate them into a dense lattice structure using heat and compression. Because it is mostly air, the resulting nanobubble s ...

    SBIR Phase II 2016 Department of EnergyARPA-E
  9. Biofueled Thermoelectric Cookstove

    SBC: HI-Z TECHNOLOGY, INC.            Topic: 15NCER02

    Over 50 million Indian households cook on a bio-mass fire and have unreliable or no electricity but are anxious to purchase an affordable power stove which will provide on-demand power and lighting to their homes. Annually, projected sales of the power stove could save sixteen million trees, reduce cooking fire particulates by 90%, reduce the two million premature deaths caused from indoor air pol ...

    SBIR Phase I 2016 Environmental Protection Agency
  10. High-Efficiency Nutrient Removal and Recovery for Achieving Low Regulatory Limits

    SBC: MICROVI BIOTECH, INC.            Topic: 15NCER05

    Discharge of nutrients (e.g. phosphorus and ammonia) to surface waters can cause eutrophication and the formation of toxic algal blooms, threatening human health and the environment. However, current phosphorus treatment technologies such as chemical precipitation and conventional biological systems can be costly and ineffective to reliably achieve impending effluent regulatory limits of

    SBIR Phase I 2016 Environmental Protection Agency
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