The United States is leading in a new era of nuclear power. From small modular reactors to microreactors and next-generation high-temperature designs, a chain of new projects is changing the future of nuclear energy across the United States. These projects do not just provide a carbon-free power source but also help contribute to energy security and assist in updating the United States’ energy infrastructure.
U.S. Upcoming Nuclear Projects
Using data from the World Nuclear Association, the following table highlights 10 notable nuclear projects in the U.S., each helping to build a more reliable, secure, and pollution-free energy system for the future. The table below is sorted based on the overall project significance:
| Project Significance | Project Name | Location | Reactor Type / Technology | Capacity | Status (as of 2025) | Key Development. |
| 1 | TerraPower Natrium Reactor | Kemmerer, Wyoming | Sodium-cooled fast reactor with molten-salt energy storage | 345 MWe (up to 500 MWe in peak mode) | Early construction (non-nuclear); licensing underway | Replacing a retired coal plant. Infrastructure, backed by DOE, is a major milestone for fast-reactor tech. |
| 2 | Oklo Aurora Fast Reactor | Idaho National Laboratory | Fast microreactor (updated 2025 design) | ~75 MWe | Site characterization completed; early-phase construction prep | One of the first fast microreactors, designed for long fuel cycles and small footprints. |
| 3 | Kairos Power Hermes | Oak Ridge, Tennessee | Fluoride-salt-cooled high-temperature reactor | Pilot-scale (non-commercial prototype) | Construction is starting in 2024 and is aimed at operation by ~2027 | Revolutionary FHR technology for greater safety and efficiency. |
| 4 | X-Energy Xe-100 SMR Project | Benton County, Washington | High-temperature gas-cooled SMR (HTGR) | 12 reactors totaling ~960 MW | Development & licensing stage | Designed to pair with industrial heat applications; strong federal support. |
| 5 | Holtec Palisades Restart + SMR-300 Plan | Covert, Michigan | Existing pressurized water reactor (restart) + future SMR-300 units | Restarted plant: 800+ MW; future SMRs: 300 MW each | Regulatory review for restart; development plan for SMRs | First potential restart of a closed U.S. nuclear plant; major step for nuclear fleet revitalization. |
| 6 | Project Pele Microreactor | Idaho National Laboratory | Transportable microreactor (defense-led) | 1.5 MW | Under development; slated for demonstration by 2026 | First U.S. military-backed mobile reactor; serves remote/critical installations. |
| 7 | Blue Castle Nuclear Project | Green River, Utah | Two large-scale reactors | 1,500 MW each (3,000 MW total) | Pre-licensing; facing financing & water-rights challenges | One of the largest proposed nuclear projects in the U.S., a long-term clean baseload. |
| 8 | Kewaunee Site New Reactor Proposal | Wisconsin | Potential SMR/advanced reactor site | TBD | Exploratory & feasibility phase | Will reuse existing grid and nuclear infrastructure; cost-effective redevelopment. |
| 9 | Westinghouse AP300 SMR Program | Multiple potential locations (U.S.) | Light-water small modular reactor (SMR) | 300 MW | Design certification planned; pre-application engagement with NRC | Uses proven AP1000 tech; targeted for industrial power + fast deployment. |
| 10 | Reactor Restarts & Life Extensions (fleet-wide) | Nationwide | Upgrades, restarts, and license renewals | Various | Ongoing | Preserves the life of the U.S. nuclear fleet, the quickest means to retain carbon-free baseload power. |
Credit: U.S. Department of Energy and World Nuclear Association.
Conclusion
U.S. upcoming nuclear projects will be shaped by transformation, innovation, diversity, and targeted investments. From big ideas to small microreactors, every undertaking is part of an overall national drive to realize cleaner baseload power and a more adaptable modern grid. But with challenges yet to navigate, including licensing, cost, and fuel supply. These projects are a potent indicator of the usage of nuclear power and are a keystone of the energy future. As technologies continue to evolve and new alliances develop, the U.S. has a unique opportunity to take ownership of an international transition toward safer, more efficient, and sustainable nuclear applications.
FAQs
1. Why are SMRs compared to traditional nuclear plants?
2. What is the purpose of Project Pele Microreactor Idaho?
3. Are these new nuclear ventures safe?
4. What are the objectives of Advanced Light-Water SMR Projects?
5. How are nuclear projects funded?
Disclaimer: Any opinions expressed in this blog do not necessarily reflect the opinions of Certrec. This content is meant for informational purposes only.
