Features

Nuclear medicine has come a long way since Henri Becquerel first observed the penetrating energy of radioactive materials in 1896. Today, technetium-99m alone is used in more than 40 million diagnostic procedures every year—from cardiovascular imaging and bone scans to cancer detection—making it the undisputed workhorse of nuclear medicine. That single statistic tells you something important: An enormous portion of modern diagnostic medicine rests on a surprisingly narrow foundation, one built around a small number of aging research reactors that were never originally designed for continuous isotope production.

The noticeable exuberance within the nuclear community as a whole appears to have spilled over into the waste management sphere as well, judging from the 2026 Waste Management Conference, held March 8–12 in Phoenix, Ariz., and sponsored by Waste Management Symposia.

The theme of this year’s conference was “Efficient and Innovative Nuclear Materials and Technology Solutions,” and many of the scheduled panels and technical sessions revolved around how nuclear growth and technological advancements are affecting the back end of the fuel cycle, as well as how the cleanup of legacy sites is enabling new nuclear development.

For 45 years, Duane Arnold Energy Center operated in Linn County, Ia., near the town of Palo and just northwest of Cedar Rapids. The facility, owned by NextEra Energy, was the only nuclear power plant in the state.

In August 2020, a historic derecho swept across eastern Iowa with winds approaching 140 miles per hour. Damage to the plant’s cooling towers accelerated a shutdown that had already been planned, and the facility entered decommissioning soon after, with its fuel removed in October of that year. Iowa’s only nuclear plant had gone off line.

Today the national energy landscape looks very different than it did just six short years ago. Electricity demand is rising rapidly as data centers, artificial intelligence infrastructure, advanced manufacturing, and electrification expand across the country. Reliable, carbon-free baseload power has become increasingly valuable. In that context, Linn County has approved the rezoning necessary to support the recommissioning and restart of Duane Arnold and is actively supporting NextEra’s efforts to secure the remaining state and federal approvals.

As part of a future consent-based approach by the federal government to site new deep geologic repositories for nuclear waste, local communities and states that are considering hosting such facilities are sure to have many questions. Currently, the Waste Isolation Pilot Plant in New Mexico is the only example of such a repository in operation, and it offers the opportunity for state and local officials to visit and judge for themselves the risks and benefits of hosting a similar facility. But its history can also provide lessons for these officials, particularly the political process leading up to the opening of WIPP, the safety of WIPP operations and transportation of waste from generator facilities to the site, and the economic impacts the project has had on the local area of Carlsbad, as well as the rest of the state of New Mexico.

U.S. nuclear capacity additions are falling short of ambitious expectations set (and then reset) in recent years. Despite construction permits submitted or approved at this writing, new commercial, utility-scale nuclear generation is still a few years away from operation.

As the United States faces surging electricity demand driven by artificial intelligence, data centers, and a push to bring manufacturing back home, Idaho National Laboratory is leading an effort to modernize and expand the nation’s nuclear power capabilities by revamping the Department of Energy’s Light Water Reactor Sustainability (LWRS) Program.

Before the Fukushima Daiichi accident in March 2011, nuclear power from 54 reactors provided about 30 percent of Japan’s electricity. In the wake of the disaster, Japan shut down every one of its reactors.

Recently, the country has been restarting its nuclear power plants. Among its current fleet of 33 operable reactors, fewer than half have been restarted. Nuclear power is currently providing about 8.5 percent of Japan’s electricity (with natural gas and coal accounting for more than 60 percent).

The Japanese government’s present energy plan, announced last year, calls for nuclear power to meet 20 percent of the country’s electricity needs by 2040. While the government views nuclear as a crucial asset toward meeting its goal of net zero emissions by 2050, public support for nuclear energy also continues to increase. A 2012 Pew Research poll—conducted one year after the Fukushima Daiichi disaster—indicated that 70 percent of the public opposed nuclear power. However, a 2022 poll by Nikkei Business Publications suggests that now, more than 50 percent of the public supports nuclear power—if safety can be ensured.

Contributing their expertise to these restarts in recent years are young nuclear industry professionals who were trained a decade ago in a mentorship/training program involving U.S. institutions.

This “Super Engineer Project” was sponsored by Japan’s Ministry of Economy, Trade, and Industry and Hokkaido University from 2015 to 2017. METI sponsored the project to improve the Japanese nuclear safety culture by learning from the U.S. safety culture.

Last September, in the Chicago suburb of Lemont, Ill., Argonne National Laboratory hosted its first AI STEM Education Summit. More than 180 educators from high schools, community colleges, and universities; STEM administrators; and experts in various disciplines convened at “One Ecosystem, Many Pathways–Building an AI-Ready STEM Workforce” to discuss how artificial intelligence is reshaping STEM-related industries, including the implications for the nuclear engineering classroom and workforce.

Admiral William Houston

As U.S. Navy submarines surface through Arctic ice during Ice Camp 2026, they demonstrate more than operational proficiency in one of the harshest environments on Earth. They reaffirm a technological truth first proven in August 1958, when the USS Nautilus completed its submerged transit of the North Pole: nuclear power enables access anywhere, anytime.

The Arctic is unforgiving, with vast distances, extreme cold, shifting ice, and no logistical infrastructure. Conventional propulsion is constrained by fuel, air, and endurance. Nuclear propulsion removes those constraints. Only a nuclear-powered submarine can operate anywhere in the world’s oceans, including under the polar ice, undetected and at maximum capability for extended periods. Nuclear power provides sustained high speed and the endurance to reposition across the globe without refueling.

Nuclear rocket propulsion has been investigated for decades, and NASA and the Atomic Energy Commission carried out significant testing in the 1960s as part of the Nuclear Engine for Rocket Vehicle Application program. NERVA chased the potential of the efficiency and energy density of nuclear thermal propulsion to extend our reach to new space frontiers before the program ended in 1973.

Craig Piercy
cpiercy@ans.org

In this month’s issue of Nuclear News, readers will find coverage of the “other” areas where nuclear technology is pushing into new frontiers. From marine nuclear propulsion to nuclear systems that enable planetary exploration, the articles in these pages are a reminder that the influence of applied nuclear science extends far beyond the electric grid.

When many people hear the phrase “civil nuclear technology,” they still think first of power plants—an understandable association. Nuclear power has been one of the most reliable sources of large-scale electricity for decades. It is our storefront.

But nuclear technology has always been bigger than electrons.

The predawn darkness on a cool Florida night was shattered by the ignition of nine Merlin engines on a SpaceX Falcon 9 rocket. The thrust of the engines shook the ground miles away. From a distance, the rocket appeared to slowly rise above the horizon. For the cargo onboard, the launch was anything but gentle, as the ignition of liquid oxygen generated more than 1.5 million pounds of force. After the rocket had been out of sight for several minutes, the booster dramatically returned to Earth with several sonic booms in a captivating show of engineering designed to make space travel less expensive and more sustainable.

When the Department of Energy’s Advanced Research Projects Agency–Energy launched the Optimizing Nuclear Waste and Advanced Reactor Disposal Systems (ONWARDS) program in 2022, it posed a challenge that the nuclear industry had never seriously confronted before: how to design waste management solutions that anticipate the coming shift to advanced reactors and not merely retrofit existing systems built for an older generation of technology. The program’s objectives were ambitious—reduce disposal footprint, enable scalable pathways for unfamiliar waste streams, and build the technical foundations for future disposal—yet also tightly grounded in the realities of emerging nuclear fuel cycles. For the nuclear community, this was a timely call. Advanced reactors were accelerating toward deployment, but the waste management systems needed to support them had not kept pace.

Hash Hashemian (president@ans.org), proud grandfather of 1-year-old Vera Rose Sizemore.

With the 2026 ANS Annual Conference right around the corner, planning is well underway, with many exceptional speakers who will explore how fusion and fission can turn breakthrough innovation into real, scalable power that drives our clean energy future. I am looking forward to seeing the nuclear community in Denver in June.

If you want to hear some of my thoughts on the current state of nuclear power before the conference, you can watch or listen to the March 3 episode of the Blockspace podcast, on which I was a guest (blockspace.media/podcast/americas-nuclear-revival-is-here-w-dr-hash-hashemian/). There, I aimed to both reach a broader audience and promote the peaceful uses of nuclear science and technology.

The episode contains a wide-ranging discussion about the current state of nuclear energy in America, touching on regulatory reform, surging electricity demand, and what it will take to maintain U.S. leadership in nuclear development.

Readers of Nuclear News will have heard of historical applications of civilian maritime nuclear power, like the merchant ship NS Savannah and the USS Sturgis floating power plant. With a few exceptions there has been little action in this area for over 50 years, and there are plenty of reasons and opinions as to why, but over the last few years the dramatic increase in interest from the maritime industry and its stakeholders has been undeniable.

With the significant advances in additive manufacturing (AM), otherwise known as 3D printing, Orano Federal Services and the University of North Carolina at Charlotte recently re-examined the capabilities to print impact limiters for transportation casks used to ship spent nuclear fuel. Impact limiters protect transportation casks (sometimes also referred to as transportation overpacks) and their contents during an accident. Impact limiter designs must withstand testing based on a certain significance level of hypothetical accidents, including drops, crushing, fires, and immersion in water.

A new, more complex nuclear age has begun. Echoing the tensions of the Cold War amid rapidly evolving nuclear and radiological threats, preparedness in the modern age is a contest of scientific innovation. The Research and Development Directorate (RD) at the Defense Threat Reduction Agency (DTRA) is charged with winning this contest.

The nuclear industry has long recognized a shortage of both skilled craft labor and professional talent. As global demand for reliable energy continues to rise—across the United States and internationally—that need has not only increased but has become critical.” This is a truth that nuclear industry consultant Jeffery P. Hawkins understands, and it is why he developed a program called Interns to Industry. The former Fluor Corporation executive said that “there has been a deficit of qualified resources in the nuclear industry, and this is forecasted to be even more so in the future, so I am working with various universities to determine how to customize their curriculums to fit the forecasted needs of the industry.”

Designed for 40 years but built to last far longer, Switzerland’s nuclear power plants have all entered long-term operation. Yet age alone says little about safety or performance. Through continuous upgrades, strict regulatory oversight, and extensive aging management, the country’s reactors are being prepared for decades of continued operation, in line with international practice.

Recent years have seen growing global interest in nuclear energy and rising confidence in the sector. For the first time since the early 2000s, there is renewed optimism about the industry’s future. This change is driven by several major factors: geopolitical developments that highlight the need for secure energy supplies, a stronger focus on resilient energy systems, national commitments to decarbonization, and rising demand for clean and reliable electricity.