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United States Project Notice - Advance Castable Nanostructured Alloys For First-Wall/Blanket Applications


Project Notice

PNR 53536
Project Name Advance Castable Nanostructured Alloys for First-Wall/Blanket Applications
Project Detail For more than 60 years, fusion research and development (R&D) has focused on attaining the required fuel density, temperature, and energy confinement time of the plasma fuel of a viable fusion energy system. Currently, relatively modest investments have been made in the required and equally critical enabling technologies and advanced materials surrounding the plasma fuel. The GAMOW program supports innovative R&D that will help establish both the technical and commercial viability of (i) all the required technologies and subsystems between the fusion plasma and the balance of plant, (ii) cost-effective, high-efficiency, high-duty-cycle driver technologies, and (iii) novel fusion materials and advanced manufacturing of these materials. Project Innovation + Advantages: Reduced-activation ferritic-martensitic (RAFM) steels are critical structural materials for fusion-energy subsystems such as integrated first-wall and blanket technology. Current RAFM steels cannot operate above ~550° C (1020° F). Castable nanostructured alloys (CNAs), recently developed at laboratory scale, can potentially achieve significantly higher temperatures, offering a pathway to more efficient operation, however. ORNL will establish a new class of RAFM steels based on carbide-strengthened CNAs to demonstrate industry-scale CNA production viability. The innovations could better enable fusion energy system design and fabrication and benefit other industries that use similar materials for similarly demanding applications. High-strength CNAs with superior microstructure and optimal chemistry are expected to improve reliability and expand the performance envelope for fusion reactors while reducing costs. These CNAs can improve safety while reducing material volume requirements and improving environmental sustainability via reduced low-level waste volume. This approach can potentially reduce the required mass and costs of RAFM materials in future fusion power plants by a factor of two while allowing for improved levelized cost of energy via higher-temperature blanket operation. Potential Impact: Successful development of fusion energy science and technology could lead to a safe, carbon-free, abundant energy source for developed and emerging economies.
Funded By Self-Funded
Sector Energy & Power
Country United States , Northern America
Project Value USD 1,650,000

Contact Information

Company Name Oak Ridge National Laboratory (ORNL)
Address ARPA-E Program Director: Dr. Ahmed Diallo Project Contact: Dr. Ying Yang Press and General Inquiries Email: ARPA-E-Comms@hq.doe.gov Project Contact Email: yangying@ornl.gov
Web Site https://arpa-e.energy.gov/technologies/projects/advance-castable-nanostructured-alloys-first-wallblanket-applications

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