The first plasmas created in FuZE-Q, shown here during assembly, represent a key step towards fusion experiments with net energy output. (Photo: Zap Energy)
Zap Energy has created the first plasmas in its FuZE-Q machine—the company’s fourth prototype machine and the one it hopes will demonstrate a net energy gain from a Z-pinch fusion plasma just one millimeter in diameter and half a meter long. Zap Energy announced that engineering achievement and the close of $160 million in Series C funding in late June.
A shot from a coal mine in Poland. (Photo: IAEA)
The new IPS installed in Bruce Power’s Unit 7 will produce Lu-177 for treating cancer. (Photo: Bruce Power)
An international collaboration between Bruce Power, Isogen (a joint venture of Kinectrics and Framatome), and ITM Isotope Technologies Munich SE, announced a milestone marking the first time that lutetium-177, a short-lived medical radioisotope, has been produced in a commercial nuclear power reactor.
A rendering of the MCRE. (Image: Southern Company)
The Gateway for Accelerated Innovation in Nuclear (GAIN) awarded vouchers to Orano Federal Services and TerraPower on June 22, giving them access to specialized facilities and expertise at Department of Energy national laboratories. Orano is partnering with Oak Ridge National Laboratory on a new technical study that updates the physical chemistry limits for the safe transport of uranium hexafluoride (UF6) gas enriched up to 10 percent in existing shipping containers, and TerraPower is turning to Los Alamos National Laboratory’s neutron testing capabilities to measure the properties of chlorine isotopes and determine how they will behave in the Molten Chloride Reactor Experiment (MCRE).
The Spherical Tokamak for Energy Production (STEP), shown here, is a government-backed prototype fusion energy plant planned for operation in the U.K. in the early 2040s. (Image: UKAEA)
Future fusion energy facilities will continue to be regulated by the Environment Agency (EA) and Health & Safety Executive (HSE), the U.K. government announced June 20, and existing law on nuclear regulations will be amended to exclude fusion energy facilities from nuclear fission regulatory and licensing requirements. The move was announced by the United Kingdom Atomic Energy Authority (UKAEA) with the expectation it would provide “clarity to developers of prototype/demonstration fusion facilities currently being planned to support rapid commercialization.”
A conceptual illustration of a fission surface power system. (Image: NASA)
Three teams have been picked to design a fission surface power system that NASA could deploy on the moon by the end of the decade, NASA and Idaho National Laboratory announced today. A fission surface power project sponsored by NASA in collaboration with the Department of Energy and INL is targeting the demonstration of a 40-kWe reactor built to operate for at least 10 years on the moon, enabling lunar exploration under NASA’s Artemis program. Twelve-month contracts valued at $5 million each are going to Lockheed Martin (partnered with BWX Technologies and Creare), Westinghouse (partnered with Aerojet Rocketdyne), and IX (a joint venture of Intuitive Machines and X-energy, partnered with Maxar and Boeing).
(Photo: Clean Core Thorium Energy)
The Advanced Test Reactor (ATR) at Idaho National Laboratory will soon be irradiating fuel pellets containing thorium and high-assay low-enriched uranium (HALEU) developed by Clean Core Thorium Energy for use in pressurized heavy water reactors (PHWRs). Clean Core announced on June 14 that it will proceed with irradiation testing and qualification under an agreement with the Department of Energy; the plans have been in the works since at least 2020, when the DOE filed a National Environmental Policy Act (NEPA) disclosure for the work.
Roadmap for the China Initiative Accelerator-Driven System project development. (Image: Zhijun Wang/CAS)
Researchers at the Chinese Academy of Sciences’ Institute of Modern Physics are making strides with their China Initiative Accelerator-Driven System (CiADS) technology, which is being developed to get more life out of used nuclear fuel. Defense One, an online news source that focuses on “the future of U.S. defense and national security,” describes the prototype system as a step in moving China toward energy independence and advancing that nation’s “global leadership in climate-friendly technology.”
Ambassador Philippe Étienne (sixth from left) and staff from the Consulate General of France with senior leaders from General Atomics at the GA Magnet Technologies Center in Los Angeles. In the background are two partially completed ITER central solenoid modules. (Photo: GA)
General Atomics’ Magnet Technologies Center in Poway, Calif., played host last week to French ambassador Philippe Étienne, the company announced June 16. During the visit, which was hosted by Vivek Lall, chief executive of the General Atomics Global Corporation, Étienne viewed ITER central solenoid modules—all destined for shipment to France—in several stages of the fabrication process.
“General Atomics and French organizations have a strong relationship in both the defense and energy sectors, as well as in the unmanned field, that meet both France’s and the United States’ important interests,” Étienne remarked during his visit.
A cutaway of the Integral Molten Salt Reactor and balance of plant. (Image: Terrestrial Energy)
Ammonia is a carbon-free energy carrier that could be produced using thermal energy from nuclear power plants. Terrestrial Energy announced June 9 that it has signed an agreement with engineering firm KBR to explore the use of its Integral Molten Salt Reactor (IMSR) for both hydrogen and ammonia production.
IAEA director general Rafael Mariano Grossi addresses workshop attendees. (Photo: IAEA)
The International Atomic Energy Agency convened a workshop last week to explore how nuclear techniques backed by the IAEA’s Zoonotic Disease Integrated Action (ZODIAC) initiative could be used to avoid outbreaks of monkeypox and Lassa fever. The meeting, held in Vienna, Austria, on the sidelines of the IAEA Board of Governors meeting, was organized to assist countries in using nuclear and related techniques to detect, mitigate, and understand the behavior of the viruses.
“It is important that we are reacting quickly, as things happen. I am happy that concrete work is being carried out on something before it becomes a very difficult problem,” said IAEA director general Rafael Mariano Grossi as he opened the one-day summit.
A depiction of an electrolyzer from Bloom Energy. (Photo: Bloom Energy)
Using nuclear power technology to produce clean hydrogen is getting a visibility boost as the Department of Energy hosts a virtual three-day (June 6–8) Annual Merit Review and Peer Evaluation Meeting on the agency’s efforts to accelerate clean hydrogen production. On June 6, the DOE announced a notice of intent (NOI) to fund the Bipartisan Infrastructure Law’s $8 billion program to develop regional clean hydrogen hubs (H2Hubs) and the launch of a new Hydrogen Shot Incubator Prize that seeks “disruptive technologies” to reduce the cost of clean hydrogen production. That same day, Westinghouse Electric Company and Bloom Energy Corp. (a maker of solid oxide electrolyzer technology) announced a letter of intent to develop electrolyzers for use in the commercial nuclear power market and said they are “well positioned to support the U.S. Department of Energy’s developing hydrogen hubs.”