Research & Applications

This flowchart is housed in a library of Sankey diagrams at flowcharts.llnl.gov and is also available as a PDF. Source: Department of Energy/LLNL, based on EIA data

Every year, Lawrence Livermore National Laboratory releases flowcharts illustrating U.S. energy consumption and use. The flowcharts, called Sankey diagrams, allow scientists, analysts, and other decision makers to compare the contributions made by various energy sources, including nuclear power, and the end uses of those sources, including residential, industrial, commercial, and transportation markets. Taken as a series of annual snapshots, energy use trends and opportunities quickly become apparent.

This year, in addition to releasing the 2019 energy flowchart, the lab issued state-by-state energy flowcharts for 2015–2018 and carbon emissions charts for 2014–2017. It is currently at work on charts of international energy use that it hopes to release by the end of the year.

Fuel compact cross section showing dozens of individual TRISO particles.

Tristructural isotropic (TRISO) coated particle fuel is a robust, microencapsulated fuel form developed originally for use in high-temperature gas-cooled reactors (HTGRs). The particles consist of a spherical fissile kernel surrounded by several layers of pyrocarbon and a silicon carbide (SiC) layer. The particles are formed into cylindrical or spherical fuel forms using a resinated graphite matrix material for insertion into an HTGR. The kernel and coating layers together act to retain fission products within the particle during normal reactor operation and during postulated accidents; TRISO particles can maintain structural integrity at extremely high temperatures, reaching as high as approximately 1,600 °C in limiting HTGR accidents. This limits the fission product activity circulating in the helium coolant and the activity released to the environment during accidents. Acceptable performance of TRISO particles is therefore essential for reactor safety.

Undergraduate students work on the molten salt test loop at Abilene Christian University’s NEXT Lab. Photo: Jeremy Enlow/Steel Shutter Photography

Abilene Christian University (ACU) is leading a consortium called NEXTRA—the Nuclear Energy eXperimental Testing Research Alliance—with the Georgia Institute of Technology, Texas A&M University, and the University of Texas at Austin. NEXTRA was formed in spring 2019 to design, license, and commission a molten salt–fueled research reactor to be hosted on ACU’s campus in the central Texas city of Abilene. ACU and its partners recently announced funding of $30.5 million over the next three years from Abilene-based Natura Resources.

The Department of Energy is asking for input on an Energy Storage Grand Challenge (ESGC) Draft Roadmap and Request for Information (RFI) and recently extended the response deadline to August 31. While there is no “N” for nuclear in “ESGC,” nuclear is definitely part of the DOE’s plan for future energy storage technologies and integrated energy systems designed to improve the efficiency and reliability of U.S. energy markets. In fact, the House Energy and Water Appropriations Committee has called for $4 million in the Office of Nuclear Energy’s Fiscal Year 2021 budget to support energy storage.

With the Democratic Convention now under way, it is good to remember that all the leading climate scientists say that we cannot address climate change without significant nuclear power, Jim Conca noted in his opinion column on the Forbes blog site. Supporting nuclear power - or not - is a clear signal about how serious a candidate is about climate change and supporting science over mere activism, Conca said.

The Department of Energy established the Consortium for Advanced Simulation of Light Water Reactors (CASL) at Oak Ridge National Laboratory in 2010 as a national collaboration of government, academia, and industry to help the nuclear industry extend the life of the current reactor fleet and develop more efficient next-generation reactors. On August 13, ORNL issued a news release and video to celebrate the achievements of CASL, which concluded its mission in June.

PPPL physicists Raffi Nazikian (left) and Qiming Hu, with a figure from their research. Photo: PPPL/Elle Starkman

Stars contain their plasma with the force of gravity, but here on earth, plasma in fusion tokamaks must be magnetically confined. That confinement is tenuous, because tokamaks are subject to edge localized modes (ELM)—intense bursts of heat and particles that must be controlled to prevent instabilities and damage to the fusion reactor.

Researchers at the Department of Energy’s Princeton Plasma Physics Laboratory (PPPL) and at General Atomics (GA) recently published a paper in Physical Review Letters explaining this tokamak restriction and a potential path to overcome it. They have developed a new model for ELM suppression in the DIII-D National Fusion Facility, which is operated by GA for the DOE. PPPL physicists Qiming Hu and Raffi Nazikian are the lead authors of the paper, which was announced on August 10 by PPPL.

On August 4, the Department of Energy announced it will provide $57.5 million over five years to establish two multidisciplinary teams to take advantage of DOE supercomputing facilities at Argonne National Laboratory, Lawrence Berkeley National Laboratory, and Oak Ridge National Laboratory. The goal is to spur advances in the use of artificial intelligence and machine learning. Funds of $11.5 million have been made available for Fiscal Year 2020, with future funding contingent on congressional appropriations.

The Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E) is at work developing and demonstrating novel energy technologies and connecting those technologies with private-sector investors. The researchers and innovators behind ARPA-E want to tell you all about it in a series of “Energy Briefs” available through the agency’s YouTube channel.

This vial contains traces of actinium within a mixture of thorium and uranium. Photo: Isotek

An article recently published in Chemical & Engineering News describes TerraPower’s efforts to extract actinium-225, a radioisotope with therapeutic potential, from highly radioactive uranium-233 owned by the Department of Energy and slated for disposal. While others are working to ramp up production of Ac-225 by using a linear accelerator or cyclotron, TerraPower hopes to harvest between 200,000 and 600,000 doses a year from U-233 to increase the global supply.

Separation of Kr-85 from spent nuclear fuel by a highly selective metal organic framework. Image: Mike Gipple/National Energy Technology Laboratory

According to a story published by the Massachusetts Institute of Technology on July 24, the capture of gaseous fission products such as krypton-85 during the reprocessing of spent nuclear fuel could be aided by the adsorption of gasses into an advanced type of soft crystalline material, metal organic frameworks(MOF), which feature high porosity and large internal surface areas that can trap an array of organic and inorganic compounds.

The Department of Energy’s National Nuclear Security Administration on July 30 issued a funding opportunity announcement (FOA) to foster commercial-scale domestic production of the medical isotope molybdenum-99 without the use of high-enriched uranium. Mo-99 is used in more than 40,000 medical procedures in the United States every day.

Through the FOA (DE-FOA-0002303), the NNSA is soliciting applications from U.S. companies to help achieve commercial-scale Mo-99 production by December 31, 2023. Companies have until September 30 this year to respond to the FOA with proposals.

An Atlas V rocket with NASA’s Mars 2020 Perseverance rover on board launches on July 30. Photo: NASA/Joel Kowsky

The launch of the Mars 2020 Perseverance rover went ahead as scheduled on July 30, lifting off from Space Launch Complex 41 at Cape Canaveral Air Force Station in Florida at 7:50 a.m. (EDT) . The rover was onboard a United Launch Alliance Atlas V 541 rocket.

Minutes later, NASA reported that all flight milestones were being met as planned. There are several more milestones to reach before Perseverance—the fifth rover that NASA has sent to Mars—lands on the Red Planet in seven months.

Those attending the livestreamed July 28 celebration in person (shown here from above) followed recommended social distancing measures.

First-of-a-kind components have been arriving in recent months at the ITER construction site in Cadarache, France, from some of the 35 ITER member countries around the world. The arrival on July 21 of the first sector of the ITER vacuum vessel from South Korea marks the beginning of a four-and-a-half year machine assembly process for the world’s largest tokamak, a magnetic fusion device designed to prove the feasibility of fusion as an energy source.

Brent Park, NNSA deputy administrator for Defense Nuclear Nonproliferation. Photo: NNSA

The National Atomic Testing Museum is hosting a free webinar on July 30 at 9 p.m. (EDT) featuring Brent Park, the National Nuclear Security Administration's deputy administrator for Defense Nuclear Nonproliferation. Registration is required.

The webinar is part of the museum’s Distinguished Lecture Series.

Park, a nuclear physicist with 30 years of experience at Department of Energy national laboratories, currently leads the NNSA's efforts to prevent nuclear weapons proliferation and reduce the threat of nuclear and radiological terrorism around the world.

Representatives from African countries assembled in 2019 at an event hosted by Nigeria to discuss the need for assistance in nuclear medicine and radiology. Photo: NNSA

The U.S. National Nuclear Security Administration has awarded grants totaling $1.5 million to support an increase in medical staff and the building of facilities and equipment in sub-Saharan Africa, the agency announced on July 27.

The grants of $750,000 each were awarded to the Radiological Society of North America (RSNA) and the Society of Nuclear Medicine and Molecular Imaging (SNMMI).

The Bruce plant near Kincardine, Ontario. Photo: Bruce Power

Bruce Power announced on July 20 that it has signed a memorandum of understanding with Isogen, a joint venture of Framatome and Toronto-based Kinectrics, and BWXT ITG Canada to advance feasibility work for the production of molybdenum-99. Mo-99 is the radioisotope most commonly used in nuclear medicine for diagnostic imaging and the detection of disease, along with other medical isotopes that are growing in demand.

The radio frequency quadropole has been matched with the ion source and the low-energy beam transmission line at UCLouvain, an SCK-CEN partner site. Photo: SCK-CEN

The MYRRHA accelerator team has successfully sent a proton beam through the radio frequency quadrupole (RFQ) of a project billed as “the world’s first large-scale accelerator-driven system.” MYRRHA, which stands for Multi-purpose hYbrid Research Reactor for High-tech Applications, will be built at SCK-CEN’s site in Mol, Belgium, and will consist of a subcritical lead-bismuth eutectic (LBE)–cooled nuclear reactor driven by a high-power linear accelerator (LINAC).