TECHNOLOGY LICENSING OPPORTUNITY: Glass Components Fabricated via Aerosol Jet Printing
Energy, Department of · ENERGY, DEPARTMENT OF
This notice is not accepting responses (deadline was Jun 29, 2026, 8:00 PM EDT).
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- Response deadline
- Jun 29, 2026, 8:00 PM EDT
- Posted
- Apr 29, 2026
- Solicitation
- S-166756
- Set-aside
- No Set aside used
- PSC
- GENERAL SCIENCE AND TECHNOLOGY R&D SERVICES; GENERAL SCIENCE AND TECHNOLOGY; APPLIED RESEARCHAJ12
- Place of performance
- Los Alamos, NM, USA
- Contracting office
- TRIAD - DOE CONTRACTOR · Columbus · OH
- Source
- SAM.gov · updated May 9, 2026
Description
An additive manufacturing method for micron-scale glass component fabrication Micron-scale glass components are widely used in optical, photonic, and micro-fabricated systems. These components are commonly produced through grinding, polishing, and milling processes that require tight tolerances and specialized equipment. As device architectures become more compact and geometrically complex, these approaches can constrain design flexibility and integration. Los Alamos researchers developed an additive manufacturing process that builds glass components layer by layer using aerosol jet printing. Glass particles suspended in an aerosolizable carrier solution are deposited onto a substrate and then sintered to form monolithic glass structures. This approach enables controlled fabrication of small glass features without bulk glass melting or post-fabrication machining. Value Proposition This technology enables the fabrication of micron-scale glass components using an additive manufacturing approach. Conventional fabrication methods rely on subtractive machining, which can limit achievable geometries and increase processing complexity at small scales. By depositing glass material directly into its final geometry and sintering it into a dense structure, this method provides an alternative pathway for producing small, high-precision glass features. Advantages Enables additive fabrication of micron-scale glass components Reduces reliance on precision subtractive glass machining Supports complex geometries and embedded glass features Compatible with multiple glass compositions and substrates Integrates with existing aerosol jet printing platforms Technology Description The method uses aerosol jet printing to deposit fine glass particles or sol-gel-based materials with micron-scale resolution. Deposition conditions are adjusted to build glass features to a specified thickness and geometry. After deposition, the printed material is sintered to remove the carrier and bond the particles into a dense glass component. Demonstrations show that the process can produce continuous, monolithic glass features on planar substrates. The method supports multiple glass compositions and allows components to be fabricated directly in their final configuration. Market Applications This additive glass fabrication method is relevant to technologies that require small, high-precision glass components, including: micro-optics and micron-scale lenses optical waveguides and photonic interconnects optical filters and coatings glass-to-metal seals and microfluidic structures photonic and optical packaging platforms These and related applications benefit from increased flexibility in the fabrication of glass features at small scales. TRL 3 US Patent pending LA-UR-25-28977 LANL Tech Partnerships: Unlock the Innovative Potential Los Alamos National Laboratory offers a wide range of cutting-edge technologies and capabilities that may provide your company with a competitive edge in the market and unlock the innovative potential that can enhance, refine, and revolutionize your products. LANL�s licensing program focuses on moving inventions developed by our researchers to commercial innovations. Patented and patent pending inventions and copyrighted software are available to existing and start-up companies through exclusive and non-exclusive licensing agreements. For specific discussions, please contact licensing@lanl.gov. Note: This is not a call for external services for the development of this technology. https://www.lanl.gov/engage/collaboration/feynman-center/partner-with-us/licensing-technology m.lanl.gov/tech-search
What similar awards have paid
Real federal awards already on the books in a similar lane — so you can size the opportunity, not guess. This is public history, not a bid price, cost estimate, or prediction that you will win.
Typical award size
$849,857
Middle of the pack for similar past awards
Most similar awards fall between $250,000 and $899,964
Who has won work like this
Public awardees in this lane — useful for competitor scan or teaming ideas, not a ranked list of “best” firms.
- 1THE UNIVERSITY OF IOWA1 award$176.74M
- 2THE EMMES COMPANY, LLC1 award$150.33M
- 3UTAH STATE UNIVERSITY SPACE DYNAMICS LABORATORY1 award$51.49M
- 4RIDGEBACK BIOTHERAPEUTICS LP2 awards$33.76M
- 5WAKE FOREST UNIVERSITY HEALTH SCIENCES1 award$31.31M
- 6BATTELLE MEMORIAL INSTITUTE3 awards$18.81M
- 7NANOBIOSYM INC1 award$14.62M
- 8MOTIV SPACE SYSTEMS, INC.4 awards$11.85M
Recent examples
A few of the newest similar awards in our index.
- ANTA BIOTECHNOLOGIES CORPORATIONSep 30, 2025National Aeronautics and Space Administration$174,499Source
- LEIDEN MEASUREMENT TECHNOLOGY LLCSep 30, 2025National Aeronautics and Space Administration$899,913Source
- FIBERTEK, INC.Sep 30, 2025National Aeronautics and Space Administration$849,371Source
- AFFEKTA LLCSep 30, 2025National Aeronautics and Space Administration$180,000Source
- AURORA ENGINEERING LLCSep 29, 2025National Aeronautics and Space Administration$79,954Source
- THE LONGBOW GROUP, LLCSep 29, 2025National Aeronautics and Space Administration$899,340Source
Drawn from official USAspending contract records in our index. Always confirm requirements on the SAM.gov notice before you bid.
Intelligence only — not legal advice or a guarantee of award. Always verify requirements on the official SAM.gov notice. Past award amounts are public history, not a suggested bid or prediction. Notice ID 5f44d6a1e5624cadb51e3c4644e34d1f.