December 15, 2023, 4:56PMNuclear NewsDonna Kemp Spangler and Joel Hiller BWXT’s microreactor components would be designed to be transported directly from the factory to the deployment site. (Image: BWXT)
“The tools of the academic designer are a piece of paper and a pencil with an eraser. If a mistake is made, it can always be erased and changed. If the practical-reactor designer errs, he wears the mistake around his neck; it cannot be erased. Everyone sees it.”
Many in the nuclear community are familiar with this sentiment from Admiral Rickover. A generation of stagnation in the industry has underscored the truth of his words. But as economies around the world put a price on carbon emissions, there’s a renewed sense of urgency to deploy clean energy technologies. This shifts the global balance of economic competitiveness, and it’s clear that the best path forward for nuclear requires combining the agility of private innovators with the technology and capabilities of national laboratories.
Applause at the conclusion of COP28. (Photo: Kiara Worth/UN Climate Change)
The United Nations' Climate Change Conference of Parties (COP28) in Dubai, United Arab Emirates, closed on December 13 after debate on a “global stocktake” pushed negotiations a full day past the scheduled end date. Though advocates hoping for a phaseout of fossil fuels were ultimately disappointed and must settle for “transitioning away,” another first—after 30 years of global climate conferences—is the inclusion of nuclear energy among the zero-emissions and low-emissions technologies that still could, if deployment is accelerated, support deep reductions in greenhouse gas emissions to limit global warming to 1.5°C.
STARFIRE is the name of an inertial fusion energy hub led by Lawrence Livermore National Laboratory—one of three hubs announced in early December. (Image: LLNL)
The Department of Energy recently announced that it was establishing three inertial fusion energy (IFE) hubs and funding them with a total of $42 million over four years. The leaders of the three hubs selected by competitive peer review—Colorado State University, Lawrence Livermore National Laboratory, and the University of Rochester—all issued press releases touting the attributes and plans of their facilities and their research collaborators on the same day—December 7.
Concept art for a Hermes plant. (Image: Kairos Power)
Kairos Power has received the go-ahead from the Nuclear Regulatory Commission to build its Hermes demonstration reactor at the Heritage Industrial Park in Oak Ridge, Tenn., making it the first non–light water reactor approved for construction in the United States in more than 50 years.
Concept art of an ARC-100 plant. (Image: ARC)
Small modular reactor developer ARC Clean Technology, Canadian utility New Brunswick Power, and nuclear plant operator Korea Hydro & Nuclear Power have signed a memorandum of understanding to explore opportunities for commercializing ARC technology in Canada, South Korea, and the United States, as well as in other regions where KHNP has business operations.
Carson Noack poses alongside the NEXT Lab’s Molten Salt Test System drainage tank, for which he played a key role in designing and fabricating.
(Photo: Kamryn Kelly)
Carson Noack is a busy young man with a clear vision of the future of energy. The 23-year-old undergraduate is slated to receive his bachelor’s degree in mechanical engineering from Abilene Christian University (ACU) in 2024. He’s also a researcher in the university’s Nuclear Energy eXperimental Testing (NEXT) Laboratory, which has been making news with its plans to build the first new research reactor in the United States in more than 30 years—the Molten Salt Research Reactor (MSRR).