Tag: Idaho National Laboratory (INL)

Idaho National Laboratory to play a key role in Midwest hydrogen hub

Newswise — As the United States works to achieve net-zero carbon emissions by 2050, different energy sectors will require different solutions.

Renewables and nuclear energy will help decarbonize electricity production, and the light-duty transportation sector will reduce emissions primarily by switching to electric vehicles. Natural gas will continue to displace coal-fired power plants as carbon capture and sequestration also advances.

But other energy sectors are more difficult to decarbonize. Many industries require more than just electricity to run their processes. Some, such as steel and cement production, also need heat, while the ammonia used to make fertilizer requires hydrogen. And today’s batteries charge too slowly and are too heavy to efficiently power semitractor-trailer trucks and other heavy machines.

To solve these challenges, experts envision an economy where carbon-free hydrogen serves as a transportation fuel, a chemical precursor, an energy storage medium and a source of high temperature heat for industry.

Now, Idaho National Laboratory is poised to play a key role in forming a hydrogen economy. On Oct. 13, the Midwest Alliance for Clean Hydrogen, LLC (MachH2) announced that it was selected by the U.S. Department of Energy’s (DOE) Office of Clean Energy Demonstrations to develop a Regional Clean Hydrogen Hub. The MachH2 hub is one of seven hydrogen hubs planned by DOE.

The hub will establish a supply chain for producing, storing, distributing and using hydrogen. The hub is expected to create thousands of jobs during construction and operation.

INL researchers will lead efforts to identify potential end users, perform technoeconomic analyses, and develop and commercialize next generation hydrogen and advanced nuclear technologies for the hub.

The supply chain starts with hydrogen produced and used across three states: Illinois, Indiana and Michigan. MachH2 will use electrolysis technology and three main energy sources — nuclear energy, renewable energy and natural gas with carbon sequestration.

Hydrogen can go to storage facilities or be delivered to end users that could include hydrogen-powered buses, freight trucks, and glass, chemical, fertilizer and steel manufacturing, and eventually, sustainable aviation fuel production.

“One of the reasons we went to Michigan, Indiana and Illinois is that they are central to the nation’s freight sector,” said Seth Snyder, an INL researcher and chief commercialization officer for the hub. “We’re creating a hydrogen corridor, an ecosystem around hydrogen.”

Design and buildout of the hydrogen hub is expected to start immediately, followed by construction within a year and operation of the hub within five years. Project managers estimate the seven hydrogen hubs will collectively cut 25 million metric tons of carbon dioxide emissions each year — roughly equivalent to the emissions from 5.5 million gasoline-powered cars — and create tens of thousands of jobs.

The hydrogen economy is within reach

Recent advances in carbon-free hydrogen production technologies — specifically low- and high-temperature electrolysis — have brought the idea of a hydrogen economy within reach. Much of this progress is due to investments from DOE’s Hydrogen and Fuel Cell Technologies Office.

For now, nuclear and renewable hydrogen production will rely mainly on low-temperature electrolysis, a commercially available technology that uses electricity to split water into hydrogen and oxygen.

Federal funding for the hub is up to $1 billion, which will allow the team to evaluate how deployment and use of up-and-coming technologies such as high-temperature electrolysis — which splits high-temperature steam instead of water — and advanced nuclear reactors could improve energy efficiency and reduce carbon dioxide emissions.

“INL will continue to look at advanced nuclear applications and high-temperature electrolysis, which is more efficient, to accelerate it toward commercialization,” Snyder said.

INL is the premier laboratory in the nation for demonstrating high temperature electrolysis. Researchers at the laboratory helped lay the groundwork for the MachH2 hub to use the technology by helping industry develop solid oxide electrolysis cells and by setting up hydrogen production test platforms for companies to demonstrate their technologies.

The efficiency of high-temperature electrolysis is 20% to 25% higher than low temperature electrolysis. Plus, the process is carbon-free if you use the high-temperature heat and electricity supplied by a clean energy source like nuclear during times of low grid demand.

To help mature these technologies for the MachH2 hub, INL has proposed a 4- to 10-megawatt (MW) hydrogen proving ground at its desert site.

“We want to get high-temperature electrolysis up to speed,” Snyder said. “Now we’re demonstrating 1 megawatt systems, and we need to get it to 10 megawatt and beyond.”

INL has also partnered with industry for low- and high-temperature hydrogen production demonstrations at three commercial nuclear power plants in the United States. Some of these systems began operation in 2023.

These demonstration projects have helped prove technologies and reduce the technical, economic and safety risk of coupling nuclear reactors with hydrogen plants.

Technoeconomic and life cycle analysis

In the near term, INL, along with Argonne National Laboratory, Northwestern University and the University of Michigan, will support MachH2 by providing the technoeconomic and life cycle analyses of the hydrogen hub.

INL’s technoeconomic analyses will include modeling the construction and operation of the various components of the hub and determining how the economics of those components fit within the marketplace. The life cycle analysis — performed by Argonne — will eventually determine the carbon dioxide emissions reductions, using operational data to confirm the calculations and predictions.

“We are going to be spending time and resources to basically determine how the infrastructure should be operated and look for ways to incorporate technologies that INL is researching,” said Dan Wendt, an INL researcher who leads the technoeconomic analysis team. “That includes how the hub could use advanced nuclear and high-temperature electrolysis to further improve impacts and economics.”

Certain aspects of the technoeconomic analysis will be investigated using HERON, a modeling tool set that determines optimal integrated energy system configurations and operating strategies to maximize economics. It’s a complicated question. Researchers will need to build a model capable of balancing the demands of the grid with the needs of hydrogen consumers while considering the overall economics for the entire system.

“We want to know how these systems are going to work together to achieve the greatest impact while still being economically competitive,” Wendt said.

The chicken or the egg?

In the end, the hydrogen hub is a complex mixture of several different hydrogen sources and many different projects including transportation networks, storage facilities and a multitude of end users.

By integrating these components into a single system, MachH2 “helps address the chicken and egg question,” Wendt said. “What comes first, the markets or the production capability? It gives you a foothold for helping the hydrogen economy take off.”

“Our team can play a major role in helping inform how the MachH2 hub components can work together to ensure reliability, competitiveness and large impacts in CO₂ reductions,” he said.

The MachH2 hub represents “a transformative opportunity for the lab,” Snyder said.

Richard Boardman, INL lead for Nuclear-Hydrogen Systems Integration, agreed.

“As the lead lab for nuclear energy applications, INL will use its computational and testing capabilities to ensure the commercial success of hydrogen production and use by industry,” he said. “The express purpose of INL’s capabilities is to validate electrolysis stacks and integrated electrolysis modules that are capable of flexible operations.”

To learn more about INL’s research on hydrogen, visit https://inl.gov/integrated-energy/hydrogen/.

Idaho National Laboratory (INL)

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November 9, 2023
How Molten Salt Could Be the Lifeblood of Tomorrow’s Nuclear Energy

Newswise — Salt isn’t just for popcorn anymore. In fact, molten salt has caught the eye of the nuclear industry as an ideal working fluid for reactor cooling, energy transfer, fueling and fission product absorption. Many of the salts being considered are inexpensive, nontoxic, and easily transportable. In fact, table salt is one of the constituents many reactor developers are choosing to use.

Heightened interest in molten salt reactors (MSRs) has led to increased investment in their research and development. Idaho National Laboratory has already dedicated efforts to establish comprehensive molten salt capabilities. In the coming years, these efforts will establish a molten salt characterization facility, irradiate fuel salt and, for the first time, start up an experimental “fast” reactor that runs on molten salt.

“Molten salt research is essential for the future of nuclear energy, and INL is the ideal resource for industry projects in this area,” said Advanced Technology of Molten Salts Manager John Carter. “MSRs are an attractive option for future power generation, and we are prepared to make significant progress toward full-scale operations.”

WHY SALT?

Molten salt, as a coolant and nuclear fuel, offers numerous safety, efficiency and flexibility benefits.

Interestingly, molten salt fuel comes with an inherent safety feature. If the salt overheats, it naturally expands and makes the fission reaction less effective, which shuts down the reactor. The MSR reactor core naturally changes its power level to match heat removal for electricity production, allowing it to appropriately meet consumer demand.

Another benefit: fuel flexibility. Uranium, plutonium and thorium all form salts that can be used as fuel for MSRs. At reactor operating temperatures, the salt is liquid, which means new fuel can be introduced and in-use fuel can be cleaned, filtered and managed during operation. This eliminates the need for refueling outages.

Molten salt fuel opens a whole new world of possibilities to reactor designers. The characteristically high temperatures in MSRs translate into efficient electrical power conversion, but the low-pressure feature eliminates the need for costly, thick-walled pipes and tanks.

The use of fast neutrons has its own set of benefits as well.

WHAT ARE FAST NEUTRONS?

A fast-spectrum nuclear reactor uses fast, high-energy neutrons to sustain the nuclear reaction. Fast neutrons are more effective than slow neutrons at consuming certain waste products. This greatly reduces the amount of long-lived waste that must be isolated from the environment.

While fast-spectrum reactors can produce clean and reliable electricity for the grid, they can also provide thermal energy for industrial needs such as water desalination, aluminum and steel production, hydrogen production, and carbon capture. Today, those processes burn fossil fuels to generate high-temperature heat. Getting that heat from the power of fission instead would further reduce the globe’s dependence on carbon-based energy sources.

With these benefits in mind, the prospect of adopting a fast-spectrum, salt-based MSR design is a high priority for the nuclear energy industry, the United States and international governments.

WHAT RESEARCH IS HAPPENING NOW?

INL researchers and engineers are helping answer some outstanding questions about MSR technologies.

For instance, as part of the Molten Salt Research Temperature Controlled Irradiation project, a Laboratory Directed Research and Development project at INL, researchers have designed the first fuel-bearing molten chloride salt irradiation experiment. This experiment places encapsulated fuel salt into an operating reactor to better understand how chloride fuel salt properties change during irradiation. The test is planned for later this year.

Another project, the Molten Salt Thermophysical Examination Capability, is a state-of-the-art facility where researchers will use specialized equipment inside a shielded glovebox to handle and closely examine irradiated fuel salt. Researchers hope to learn how materials will behave under operating conditions by observing their density, heat capacity and viscosity. The team should complete this National Reactor Innovation Center project next year.

INL is also part of a team developing the Molten Chloride Reactor Experiment (MCRE), a six-month sub-scale test that will demonstrate the first operational fast spectrum molten salt reactor in the world. In partnership with Southern Company and TerraPower, INL will synthesize and handle the fuel salt, load and operate the reactor, and perform all post-operation deactivation and disassembly work. The test-bed experiment, a public-private partnership under the Department of Energy Office of Nuclear Energy’s Advanced Reactor Demonstration Program, is expected to begin operation as soon as 2027 and will provide the data necessary to take the next step toward licensing a commercial Molten Chloride Fast Reactor.

“It is incredible to see so much knowledge and talent come together for the MCRE Project” said Nick Smith, MCRE Project Director. “We are leveraging INL’s experience in fuel and reactor demonstrations, combining that with the innovative ideas and sense of urgency of our industry partners, and working through the engineering of a technology no one has ever built before. It is the most exciting thing I have ever been a part of.”

INL is also leading research related to molten salt properties, risk mitigation and MSR condition optimization with the help of dedicated computational modeling efforts.

Multiphysics computer modeling and simulations have been developed or customized specifically for MSRs using INL’s open-source Multiphysics Objected-Oriented Simulation Environment, or MOOSE, code. This application allows researchers to create precise digital models across multiple scales, materials and research areas. These high-fidelity simulations, informed by real-world experiments, help researchers and industry enhance MSR safety and performance by reliably predicting molten salt properties, thermodynamics and irradiation behaviors.

“The research activities going on at INL will help advance the technical readiness level of advanced molten salt reactors,” said research scientist Toni Karlsson. “INL has technical staff members with a passion for molten salts and unique experimental capabilities for actinide and irradiated salts not found anywhere else in the world. Along with industry partners, we are bridging the gap from advanced reactor development to deployment.”

About Idaho National Laboratory
Battelle Energy Alliance manages INL for the U.S. Department of Energy’s Office of Nuclear Energy. INL is the nation’s center for nuclear energy research and development, and also performs research in each of DOE’s strategic goal areas: energy, national security, science and the environment. For more information, visit www.inl.gov. Follow us on social media: Twitter, Facebook, Instagram and LinkedIn.

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June 19, 2023
First-of-a-Kind Technology: INL Demonstrates Mobile Hot Cell for Radioactive Source Recovery

Newswise — A crowd gathers around a black wooden box that resembles a short refrigerator, waiting for the motion of a pair of robotic arms sitting just outside the box. When the arms move, a wave of excited energy in the room at Idaho National Laboratory conveys how this simple action may alter the future of international radioactive source removal and disposal.

The team was observing the first demonstration of a mobile hot cell that could fundamentally change how a certain class of radioactive materials is handled. The robotic and mobile nature of the hot cell is poised to improve economics, employee safety and national security.

“In some of the areas where we plan to use this mobile hot cell, radioactive sources are just left on the shelf once they’ve been spent, where they are extremely vulnerable to theft and producing harmful emissions,” said Kathy McBride, the project manager for INL’s Radioactive Source Recovery Project. “Having access to a proper disposal method could be a game-changer for many of these facilities and their staff.”

WHAT IS SOURCE RECOVERY?

Across the world, radiological materials play an important role in medical research and commercial facilities. If these radioactive sources were to fall into the wrong hands, they could be used in a radiological dispersal device (dirty bomb) or in other acts of terrorism. Safe removal of used radioactive sources requires new techniques and fabricated containers, which expand secure transportation opportunities.

The National Nuclear Security Administration’s Office of Radiological Security (ORS) has funded INL’s efforts to develop a mobile hot cell.

“Our job is to recover used, abandoned and unwanted radioactive sources,” said Kevin Kenney, the relationship manager for INL’s Radioactive Source Recovery Project. “We’ve already been doing domestic removals. However, this hot cell will enable our program to take these efforts internationally.”

WHY A MOBILE HOT CELL?

This mobile hot cell project began about two years ago, with the goal of fabricating a first-of-its-kind mobile source recovery tool, or hot cell. ORS leaders hope to use this tool to reduce global radiological threats by providing tools and expertise to help international partners improve radioactive source end-of-life management. While standards for safely recovering and handling radioactive sources are strict in the United States, many other countries do not apply the same rigor.

As Kenney described it, the hot cell’s mobility is more like a carnival than a recreational vehicle. It is designed to be assembled and shipped in multiple pieces, which are created with maximum shipping weights in mind. The shielding walls are constructed like a Russian stacking doll, with between four and five walls of increasing size that can be added or removed as necessary based on the maximum source activity of the irradiators.

“Another thing that distinguishes this from traditional hot cells is that it uses robotics, as opposed to manipulator arms,” said Ted Reed, a mechanical engineer on the project. “This way, we can position our operators 50 feet away from the hot cell.” This distance allows for reduced shielding needed to protect source handlers, decreasing the weight of the cell and to follow principles for handling radioactive material.

IMPROVEMENTS AHEAD

Although it’s a vast improvement to current methods, the robot is still not perfect. Its joints can be damaged and rendered inoperable from the radiation of the sources. To mitigate this issue, the source recovery team prefers to preprogram the robot to perform discreet tasks, lessening the time it must spend moving around inside the hot cell.

At the end of September 2022, the team demonstrated a mock-up of the mobile hot cell with all of its components in place. The mock-up will be used to evaluate and optimize the design features over the next year.

Already, INL’s hot cell’s design stands out. Current designs use sand for shielding, which requires significant effort to set up and tear down. Because hot cell operators can stand a safe distance away from a source with INL’s design, the mobile hot cell enables a safe, rapid deployment.

Additionally, the mobile hot cell will allow radioactive sources from multiple devices to be prepared for consolidation into a single cask for transportation. This is a vast improvement over the current recovery method. It will minimize the resources required to complete any source recovery trip to remove several distinct devices from a country’s inventory.

WHAT’S NEXT?

During fiscal year 2023, the research team will finalize the design and it will undergo safety analyses. If all goes well, the hot cell will be demonstrated and deployed both internationally and domestically.

“Occasionally, we will encounter an irradiator in the U.S. that can’t be shipped in a cask due to limits on the amount of material that can ship at once,” Kenney said. “That’s another case where it would be essential to have a mobile hot cell that can be deployed.”

Eric Egan, the principal investigator within the source recovery team for the mobile hot cell project, emphasized the team effort required to complete this project. “This impressive accomplishment would not have been possible without support from inside and outside INL. This includes the technical expertise and advice from Southwest Research Institute, as well as the invaluable skill of our INL machinists, facility and nuclear safety engineers.”

About Idaho National Laboratory
Battelle Energy Alliance manages INL for the U.S. Department of Energy’s Office of Nuclear Energy. INL is the nation’s center for nuclear energy research and development, and also performs research in each of DOE’s strategic goal areas: energy, national security, science and the environment. For more information, visit www.inl.gov. Follow us on social media: Twitter, Facebook, Instagram and LinkedIn.

Idaho National Laboratory (INL)

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May 1, 2023
From Atoms to Earthquakes to Mars: High Performance Computing a Swiss Army Knife for Modeling and Simulation

BYLINE: Idaho National Laboratory (INL)

Newswise — Researchers solving today’s most important and complex energy challenges can’t always conduct real-world experiments.

This is especially true for nuclear energy research. Considerations such as cost, safety and limited resources can often make laboratory tests impractical. In some cases, the facility or capability necessary to conduct a proper experiment doesn’t exist.

At Idaho National Laboratory, computational scientists use INL’s supercomputers to perform “virtual experiments” to accomplish research that couldn’t be done by conventional means. While supercomputing can’t replace traditional experiments, supercomputing is an essential component of all modern scientific discoveries and advancements.

“Science is like a three-leg stool,” said Eric Whiting, director of Advanced Scientific Computing at INL. “One leg is theory, one is experiment, and the third is modeling and simulation. You cannot have modern scientific achievements without modeling and simulation.”

HIGH-DEMAND RESOURCES

INL’s High Performance Computing program has been in high demand for years. From INL’s first supercomputer in 1993 to the addition of the Sawtooth supercomputer in 2020, the demand for high-performance computing has only increased.

Sawtooth and INL’s other supercomputers are flexible enough to tackle a wide range of modeling and simulation challenges and are especially suitable for dynamic and adaptive applications, like those used in nuclear energy research. INL’s supercomputers are one of the Nuclear Science User Facilities’ 50 partner facilities and its only supercomputers.

Whether it’s exploring the effects of radiation on nuclear fuel or designing nuclear-powered rockets for a trip to Mars, INL’s High Performance Computing center is the Swiss Army knife of advanced computing.

THE POWER OF 100,000 LAPTOPS

On a recent tour of the Collaborative Computing Center, Whiting led the way through the rows of Sawtooth processors. Each row looked like dozens of tall black refrigerators standing side by side. The room hummed with the pumping of thousands of gallons of water needed to keep Sawtooth cool.

Sawtooth contains the computing power of about 100,000 processors all dedicated to very large, high-fidelity problems, which means orders of magnitude more processing power and memory when compared to a traditional laptop computer.

All that computing power allows researchers from around the world to run dozens of complex simulations at the same time. “If your program is designed right, it runs thousands of times faster than the best-case scenario on your desktop,” Whiting said.

Some of these simulations — modeling the performance of fuel inside an advanced reactor core, for instance — require the computer to solve millions or billions of unknowns repeatedly.

“If you have a multidimensional problem in space, and then you add time to it, it greatly adds to the size of the problem,” said Cody Permann, a computer scientist who oversees one of the laboratory’s modeling and simulation capabilities. Modeling and simulation started decades ago by solving simplified problems in one or two dimensions. Modern supercomputers, like INL’s Sawtooth, significantly increased the accuracy of these simulations, bringing them closer to reality.

To solve these complicated problems, researchers break down each simulation into thousands upon thousands of smaller units, each impacting the units surrounding it. The more units, the more detailed the simulation, and the more powerful the computer needed to run it.

THE ATOMIC EFFECTS OF RADIATION ON MATERIALS

For Chao Jiang, a distinguished staff scientist at INL, a highly detailed simulation means peering down to the level of individual atoms.

Jiang’s simulations, funded by the Department of Energy Nuclear Energy Advanced Modeling and Simulation program and the Basic Energy Sciences program, help nuclear scientists understand the behavior of materials when their atoms are constantly knocked around by neutrons in a reactor core. These displaced atoms will create defects, changing the microstructure of the material, and therefore its physical and mechanical characteristics. These changes in microstructure can damage the materials and reduce the lifetime of the reactor. Understanding these changes helps scientists design better and safer reactors.

“The work we are doing is extremely challenging,” Jiang said. “They are computer-hungry projects. We are big users of the high-performance computers.”

Understanding the radiation damage in materials is difficult. This change involves physical processes that occur across vastly different time and length scales. “When the high energy neutrons hit the material,” Jiang said, “it will locally melt the material.”

Heating and cooling inside an operating reactor takes place in picoseconds, or one trillionth of a second. During this heating and cooling, the material will re-solidify, but will leave defects behind, Jiang said. “These residual defects will migrate and accumulate to form large-scale defects in the long run.”

While large defects, such as dislocation loops and voids, can be directly seen using advanced microscopy techniques, there are many small-scale defects that remain invisible under microscope. These small defects can significantly impact the materials, making the use of computer simulations to fill this knowledge gap critical. INL computational scientists combine their simulations with the advanced characterization techniques performed by material scientists at INL’s Materials and Fuels Complex to advance the understanding of material behavior in a nuclear reactor.

SIMULATING THE IMPACTS OF EARTHQUAKES ON REACTOR MATERIALS

Another INL scientist, Chandu Bolisetti, also simulates the damage to materials, but on a much different scale.

Bolisetti, who leads the lab’s Facility Risk Group, uses high-performance computing to simulate the effects of seismic waves — the shaking that results from an earthquake — on energy infrastructure such as nuclear power plants or dams.

In early 2021, funded by the DOE Office of Technology Transitions, Bolisetti and his colleagues performed a particularly complex type of simulation — they simulated the impacts of seismic waves on a nuclear power plant building that houses a molten salt reactor.

A molten salt reactor is a particularly difficult physics problem because the coolant/fuel circulates through the reactor in liquid form. The team also placed their hypothetical reactor on seismic isolators, giant shock absorbers that help reduce the impacts of earthquakes on buildings.

Bolisetti’s team ran the simulation using MOOSE, which stands for Multiphysics Object Oriented Simulation Environment, a software framework that allows researchers to develop modeling and simulation tools for solving multiphysics problems. For these earthquake simulation problems, Bolisetti’s team uses MASTODON, which they developed using MOOSE specifically for seismic analysis.

Another project funded by INL’s Laboratory Directed Research and Development program looks at how a molten salt reactor behaves in an earthquake in much more detail. It extends the analysis to include neutronics and thermal hydraulics — in other words, how the shaking impacts nuclear fission and the distribution of heat in the reactor core.

“All three of these physics — earthquake response, thermal hydraulics and neutronics — are pretty complicated,” Bolisetti said. “No one has ever combined these into one simulation. How the power in the reactor fluctuates during an earthquake is important for safety protocols. It affects what the operators would do during an earthquake and helps us understand the core physics and design safer reactors.”

“Real-world experiments to simulate this are close to impossible, especially when you add neutronics,” Bolisetti said. “That’s where these kinds of multi-physics simulations really shine.”

SIMULATING NUCLEAR ROCKETS FOR A TRIP TO MARS

Mark DeHart, a senior reactor physicist at INL, uses MOOSE to simulate an entirely different kind of complex machine: a thermonuclear rocket that could someday take humans to Mars.

The rocket would use hydrogen as both a propellant and a coolant. When the rocket is in use, hydrogen would run from storage tanks through the reactor core. The reactor would rapidly heat the hydrogen before it exits the rocket nozzles.

“The hydrogen that comes out is pure thrust,” DeHart said.

Compared with chemical rockets, thermonuclear rockets are faster and twice as efficient. The rockets could cut travel time to Mars in half.

One big challenge is rapidly heating the reactor core from about 26 degrees Celsius (80 degrees Fahrenheit) to nearly 2,760 Celsius (5,000 Fahrenheit) without damaging the reactor or the fuel.

DeHart and his colleagues are using Griffin, a MOOSE-based advanced reactor physics tool, for multiphysics modeling of two aspects of the NASA mission.

The first project tests the fuel’s performance as it experiences rapid heating in the reactor core. The real-world fuel samples are placed in INL’s Transient Test Reactor (TREAT) where they are rapidly brought up to temperature.

The data from those experiments are used to create and validate models of the fuel’s neutronics and heat transfer characteristics using Griffin.

“If we can show that Griffin can model this real-world sample correctly, we can have confidence that Griffin can calculate correctly something that doesn’t exist yet,” DeHart said.

The second project is designing the rocket engines themselves. Automated controllers rotate drums in the reactor core to bring the temperature up and down. “We’ve developed a simulation that will show how you can use the control drums to bring the reactor from cold to nearly 5,000 F within 30 seconds,” DeHart said.

Without high-performance computing and MOOSE, developing a thermonuclear rocket would take dozens of small experiments costing hundreds of millions of dollars.

AN OPPORTUNITY FOR COLLABORATION

In the end, high-performance computing makes INL a gathering place for researchers with a wide range of expertise, from rocket design to artificial intelligence. About half the system’s users are from national labs, with a quarter coming from universities and a quarter from industry. The resulting collaborations are especially important for nuclear energy research.

“INL cannot attract all the experts in our field, but by sharing a computer, INL’s team can work with 1,200 experts across the United States,” Whiting said. “INL’s supercomputers are helping build the expertise and develop the tools so they can deploy next-generation reactors.”

And the demand for these modeling and simulation resources is only growing. Sawtooth added more than four times the capacity to INL’s high-performance computing capabilities, and already the line of projects waiting in the queue can reach into the thousands.

“We need years of research with the High Performance Computing facility,” said Jiang. “We need to understand the high energy state of nuclear materials as accurately as possible, so we need to explore a huge space. Without high-performance computing, basic energy research would suffer. It’s critical.”

If you are interested in accessing INL’s supercomputers for your work, visit inl.gov/ncrc or nsuf.inl.gov.

About Idaho National Laboratory
Battelle Energy Alliance manages INL for the U.S. Department of Energy’s Office of Nuclear Energy. INL is the nation’s center for nuclear energy research and development, and also performs research in each of DOE’s strategic goal areas: energy, national security, science and the environment. For more information, visit www.inl.gov. Follow us on social media: Twitter, Facebook, Instagram and LinkedIn.

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March 14, 2023