Available for Licensing: High-Quality Actinide Thin Films via Molecular Beam Epitaxy for Quantum and Optoelectronic Devices
Energy, Department of · ENERGY, DEPARTMENT OF
This notice is not accepting responses (deadline was Mar 14, 2026, 8:00 PM EDT).
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- Response deadline
- Mar 14, 2026, 8:00 PM EDT
- Posted
- Feb 2, 2026
- Solicitation
- BA-1441
- Set-aside
- None listed
- PSC
- GENERAL SCIENCE AND TECHNOLOGY R&D SERVICES; GENERAL SCIENCE AND TECHNOLOGY; APPLIED RESEARCHAJ12
- Place of performance
- Idaho Falls, ID, USA
- Contracting office
- BATTELLE ENERGY ALLIANCE�DOE CNTR · Idaho Falls · ID
- Source
- SAM.gov · updated May 9, 2026
Description
High-Quality Actinide Thin Films via Molecular Beam Epitaxy for Quantum and Optoelectronic Devices Description Researchers at INL have developed a process to deposit high-quality epitaxial crystalline thin films of uranium and thorium, as well as their nitrides, using molecular beam epitaxy (MBE). MBE is a non-equilibrium vacuum deposition technique that provides precise control over the composition and interfaces of the material, making it ideal for fabricating high-purity, defect-free, single-crystalline thin films. Actinide thin films, particularly those of uranium and thorium, present significant challenges for ab initio modeling due to their complex electron correlations. High-quality samples are essential for providing feedback to develop accurate models. Additionally, the strong electron correlations in actinide materials make them promising candidates for next-generation computing technologies. By tuning the growth parameters, including temperature, pressure, growth rate, and flux ratios, researchers can controllably form high-quality actinide thin films. This technique also allows for seamless integration with existing semiconductor technology, facilitating the development of advanced device structures. Key Benefits High-Quality Thin Films: MBE enables the fabrication of high-purity, defect-free, single-crystalline thin films of uranium and thorium, as well as their nitrides. Precise Control: The technique provides precise control over growth parameters, ensuring the formation of high-quality materials suitable for advanced applications. Integration with Existing Technology: the ability to fabricate epitaxial films at wafer scale will facilitate seamless integration with existing semiconductor technology, making it suitable for the development of advanced electronic and computing devices. Advanced Modeling Support: High-quality actinide thin films provide essential feedback for developing accurate ab initio models, facilitating further research and development. Market Applications Quantum Computing: The unique properties of actinide materials can be harnessed to explore new computational paradigms. The precise control and high-quality deposition of actinide thin films make them ideal candidates for developing next-generation quantum computing devices. Advanced Research: The technology can be utilized by researchers focused on studying the complex electron correlations in actinide materials. High-quality samples are essential for advancing theoretical and experimental research in this field. Optoelectronics: The ability to fabricate high-quality crystalline thin films of actinides and their nitrides with strong electron correlations and spin orbit coupling can be leveraged to develop advanced electronic devices. Semiconductor Industry: Epitaxial films are more easily integrated with existing semiconductor technology than more disordered crystals, which can open up new possibilities for creating advanced device structures, potentially leading to innovations in various high-tech applications. Advantage Molecular beam epitaxy (MBE) offers several advantages over other deposition techniques, such as DC sputtering, which has been previously used to form monocrystalline actinide-nitride thin films. MBE is regarded as the pinnacle of vacuum deposition techniques due to its ability to create atomically precise layers and use high-purity sources. While MBE has been used to deposit all-metal alloys, it has not been previously employed for actinide-nitrides. This novel application of MBE differentiates the technology from existing methods and provides a unique advantage in producing high-quality actinide thin films with tunable properties.
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
$69,223
Middle of the pack for similar past awards
Most similar awards fall between $21,956 and $112,836
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.
- 1SPECTRA SYSTEMS CORPORATION1 award$2.00M
- 2MATRIX INDUSTRIES INC1 award$1.55M
- 3STERILIZ, LLC9 awards$764,401
- 4CAMBRIDGE TERAHERTZ INC1 award$749,976
- 5FINETECH1 award$628,110
- 6KURT J LESKER CO1 award$520,650
- 7SUSS MICROTEC INC1 award$417,621
- 8TRU-D SMARTUVC, LLC5 awards$398,940
Recent examples
A few of the newest similar awards in our index.
- RAYTHEON COMPANYSep 26, 2025National Aeronautics and Space Administration$273,770Source
- TRU-D SMARTUVC, LLCSep 26, 2025Department of Veterans Affairs$109,020Source
- CAMBRIDGE TERAHERTZ INCSep 25, 2025Department of the Interior$749,976Source
- VEECO PROCESS EQUIPMENT INC.Sep 22, 2025Department of Commerce$220,930Source
- SUSS MICROTEC INCSep 19, 2025Department of Commerce$417,621Source
- GOVAGE, INC.Sep 18, 2025National Aeronautics and Space Administration$21,908Source
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 0d21d877835e4e05bb8d462bf298e35a.