U.S. secretary of energy Jennifer Granholm and Japan’s minister of economy, trade, and industry Yasutoshi Nishimura lead energy discussions on January 9 in Washington, D.C. (Photo: DOE)
Researchers at Idaho National Laboratory have completed initial testing on a newly developed fuel test capsule that is expected to provide crucial performance data for sodium-cooled fast reactors. The Department of Energy announced on January 12 that the series of fuel testing experiments being carried out now at INL’s Transient Reactor Test Facility (TREAT) was developed through a joint project between the United States and Japan.
A rendering of the planned demo plant. (Image: General Fusion)
IBA Rhodotron TT300-HE (high energy) electron accelerator. (Photo: Business Wire)
Nuclear medicine company NorthStar Medical Radioisotopes announced that it has successfully produced molybdenum-99 at its recently completed accelerator production facility at its Beloit, Wis., campus. According to NorthStar, the event marks a major milestone in advancing the company’s proprietary electron accelerator technology for the non-uranium–based production of the critical medical radioisotope.
The cooling pipes that snake along the surface of the vacuum vessel thermal shield will be removed and replaced. Here, on a right-hand outboard panel, workers determine the impact of pipe removal on the surface of the component. (Photo: ITER Organization)
ITER’s machine assembly phase began about two and a half years ago. Now, staff are reversing some of that assembly work to make needed repairs. According to a news article published by the ITER Organization on January 9, ITER is “facing challenges common to every industrial venture involving first-of-a-kind components.” Over one year after problems were first detected and less than two months after they were made public in late November, tests and analysis are producing a clearer picture of necessary repairs to the tokamak’s thermal shield panels and vacuum vessel sectors.
“There is no scandal here,” said ITER director general Pietro Barabaschi. “Such things happen. I've seen many issues of the kind, and much worse.”
Researchers are looking for the ideal characteristics of molten salt, which can serve as both coolant and fuel in advanced nuclear reactors. (Photo: Argonne National Laboratory)
Scientists are searching for new materials to advance the next generation of nuclear power plants. In a recent study, researchers at the Department of Energy’s Argonne National Laboratory showed how artificial intelligence could help pinpoint the right types of molten salts, a key component for advanced nuclear reactors.
A color-enhanced image of the inside of a NIF preamplifier support structure. (Image: LLNL/Damien Jemison)
On December 5, researchers at the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory achieved fusion energy breakeven. It was a gain for stockpile stewardship that also—as headlines gushed prior to the Department of Energy’s December 13 announcement—boosted the prospects of inertial fusion energy (IFE). The timing of the landmark achievement may have been especially welcome to private fusion companies with inertial or hybrid magneto-inertial confinement concepts, because it occurred as the DOE was getting ready to consider applications for $50 million in funding for fusion pilot plant design work.
The target chamber of LLNL’s NIF, where 192 laser beams delivered more than 2 million joules of ultraviolet energy to a tiny fuel pellet to create fusion ignition on December 5, 2022.
It’s official: Early in the morning on December 5 at Lawrence Livermore National Laboratory’s National Ignition Facility (NIF), the laser-triggered implosion of a meticulously engineered capsule of deuterium and tritium about the size of a peppercorn yielded, for the first time on Earth, more energy from a fusion reaction than was delivered to the capsule. The input of 2.05 megajoules (MJ) to the target heated the diamond-shelled, spherical capsule to over 3 million degrees Celsius and yielded 3.15 MJ of fusion energy output. The achievement was announced earlier today by officials and scientists representing the Department of Energy and its National Nuclear Security Administration, the White House, and LLNL during a livestreamed event.
A figure from the “Multistep Coulomb excitation of 64Ni” that shows the time-of-flight difference between the projectile and target recoils as a function of scattering angle measured with the CHICO2 detector. A clear separation between the Ni-64 (bottom) and Pb-208 (top) ions is observed. (Credit: Physical Review C/American Physical Society)
A study published recently in the American Physical Society journal Physical Review C reveals new findings about the strong nuclear force, the mysterious fundamental force that holds together the protons and neutrons of the atomic nucleus. Experiments conducted at Argonne National Laboratory have shown how the round, heavy nuclei of the nickel-64 isotope (containing 28 protons and 36 neutrons, making it the heaviest stable Ni isotope) changed into one of two shapes—either like a doorknob or a football—depending on the amount of energy exerted on it. A summary of the research on the Phys.org website compares the nuclei shape change to popcorn kernels changing shape when heated in a microwave.
The electron accelerator that will be used for Mo-99 production at NorthStar’s newly completed facility in Wisconsin. (Photo: NNSA)
NorthStar Medical Radioisotopes has completed construction and all equipment installation at its new facility in Beloit, Wis., to produce the medical radioisotope molybdenum-99 without the use of high-enriched uranium, the Department of Energy’s National Nuclear Security Administration announced last week.
A total of about 23 kilometers (about 14 miles) of piping are welded to the surface of the thermal shield panels. The piping on a vacuum vessel thermal shield panel is clearly visible in this photo. (Photo: ITER Organization)
The ITER Organization is working on a new baseline schedule for the magnetic confinement fusion experiment launched in 1985 and now under construction in southern France. First plasma was scheduled for December 2025 and deuterium-tritium operations for 2035 under a schedule approved in November 2016 that will soon be shelved. In addition to impacts from COVID-19 delays and uncertainty resulting from Russia’s war in Ukraine, ITER leaders must now factor in repair time for “component challenges.”
The JET tokamak. (Photo: European Consortium for the Development)
Nuclear fusion “might actually be on the cusp of commercial viability” today, says a recent article in Fortune magazine. The article offers a brief review of recent technical and entrepreneurial developments in fusion energy. It also places these developments in perspective regarding the hurdles that remain before commercialization can be realized.
Diagram of the University of Rochester Laboratory for Laser Energetics’ OMEGA laser system. (Image: University of Rochester)
A study recently published in Nature Communications brings a new perspective on how radiation travels through dense plasmas, potentially leading to a better understanding of the evolution of stars and the development of controlled nuclear fusion reactions. Researchers led by investigators at the University of Rochester Laboratory for Laser Energetics (LLE) achieved their findings by conducting experiments with LLE’s OMEGA laser system. This extensive system, which is 19 meters tall and 70 meters long, consists of 60 laser beams that can focus as much as 30,000 joules of energy onto a target for the study of nuclear and fluid dynamic events.
A rendering of Helga and Zohar side by side aboard the Orion spacecraft. (Image: NASA/Lockheed Martin/DLR)
NASA’s Artemis I mission, successfully launched at 1:47 a.m. EST on November 16 from the Kennedy Space Center in Florida, will travel 40,000 miles beyond the moon—farther from Earth than any human-crewed space mission has flown before. The historic trip was launched by the world’s largest rocket, the Space Launch System (SLS), nearly 50 years after NASA last sent humans to the moon. And while no humans are on board the Orion spacecraft, two fabricated crew members—“Luna Twins” Helga and Zohar—were assembled with thousands of sensors to obtain the best estimates yet of cosmic radiation exposure to human tissues during space travel.