Nuclear Energy Projects Next Generation Nuclear Plant (NGNP) One part of this program to develop improved nuclear power plants is the "
Next Generation Nuclear Plant" or NGNP, which would be the demonstration of a new way to use nuclear energy for more than electricity. The heat generated from nuclear fission in the plant could provide process heat for
hydrogen production and other industrial purposes, while also generating electricity. And the NGNP would use a high-temperature gas reactor, which would have redundant safety systems that rely on natural physical processes more than human or mechanical intervention. INL worked with private industry to develop the NGNP between 2005 and 2011. It was commissioned to lead this effort by the United States Department of Energy as a result of the
Energy Policy Act of 2005. Since 2011, the project has languished and funding for it ceased. The design for this reactor is currently owned by Framatome.
Fuel Cycle Research & Development (FCRD) The Fuel Cycle Research & Development program aims to help expand nuclear energy's benefits by addressing some of the issues inherent to the current life cycle of nuclear reactor fuel in the United States. These efforts strive to make nuclear energy's expansion safe, secure, economic and sustainable. Currently, the United States, like many other countries, employs an "open-ended" nuclear fuel cycle, whereby nuclear power plant fuel is used only once and then placed in a repository for indefinite storage. One of the primary FCRD goals is to research, develop and demonstrate ways to "close" the fuel cycle so fuel is reused or recycled rather than being shelved before all of its energy has been used. INL coordinates many of the FCRD's national research efforts, including: • Continuing critical fuel cycle research and development (R&D) activities • Pursuing the development of policy and regulatory framework to support fuel cycle closure • Developing deployable technologies • Establishing advanced modeling and simulation program elements • Implementing a science-based R&D program
Light Water Reactor Sustainability (LWRS) program The
Light Water Reactor Sustainability Program supports national efforts to do the research and gather the information necessary to demonstrate whether it is safe and prudent to apply for extensions beyond 60 years of operating life. The Program aims to safely and economically extend the service lives of the more than 100 electricity-generating nuclear power plants in the United States. The program brings together technical information, performs important research and organizes data to be used in license-extension applications.
Advanced Test Reactor National Scientific User Facility (ATR NSUF) INL's Advanced Test Reactor is a research reactor located approximately from Idaho Falls, Idaho. The Department of Energy named
Advanced Test Reactor (ATR) a National Scientific User Facility in April 2007. This designation opened the facility to use by university-led scientific research groups and gives them free access to the ATR and other resources at INL and partner facilities. In addition to a rolling proposal solicitation with two closing dates each year, INL holds an annual "Users Week" and summer session to familiarize researchers with the user facility capabilities available to them.
Nuclear Energy University Programs (NEUP) DOE's Nuclear Energy University Programs provide funding for university research grants, fellowships, scholarships and infrastructure upgrades. For example, in May 2010, the program awarded $38 million for 42 university-led R&D projects at 23 United States universities in 17 states. In FY 2009, the program awarded about $44 million to 71 R&D projects and more than $6 million in infrastructure grants to 30 U.S. universities and colleges in 23 states. INL's Center for Advanced Energy Studies administers the program for DOE. CAES is a collaboration between INL and Idaho's three public research universities: Idaho State University, Boise State University and University of Idaho.
Multiphysics Methods Group (MMG) The Multiphysics Methods Group (MMG) is a program at Idaho National Laboratory (under the
United States Department of Energy) begun in 2004. It uses applications based on the
multiphysics and modeling framework
MOOSE to simulate complex
physical and chemical reactions inside
nuclear reactors . The ultimate goal of the program is to use these simulation tools to enable more efficient use of
nuclear fuel, resulting in lower electricity costs and less
waste products. The MMG focuses on problems within nuclear reactors related to its fuel and how heat is transferred inside the reactor. "Fuel degradation" refers to how uranium pellets and the rods they are encased in (several rods bundled together is what makes a "fuel assembly") eventually wear out over time due to high heat and irradiation inside a reactor. The group states three main objectives: "The mission of the MMG is to support the INL goal to advance the U.S. nuclear energy endeavor by: • Furthering the state of computational nuclear engineering • Developing a robust technical basis in multidimensional multiphysics analysis methods • Developing the next generation of reactor simulation codes and tools" The work done by the group directly supports programs such as the
Light Water Reactor Sustainability Program's research into advanced
nuclear fuels.
National and Homeland Security INL's National and Homeland Security division focuses on two main areas: protecting critical infrastructures such as electricity transmission lines, utilities and wireless communications networks, and preventing the proliferation of weapons of mass destruction.
Control systems cybersecurity Idaho National Laboratory (INL) has conducted vulnerability assessments and developed technologies related to infrastructure resilience. In collaboration with industry partners, the laboratory conducts work on electric grid reliability, control systems cybersecurity, and physical security systems. INL conducts advanced cyber training and oversees simulated competitive exercises for national and international customers. The lab supports cyber security and control systems programs for the departments of
Homeland Security,
Energy and
Defense. INL staff members are frequently asked to provide guidance and leadership to standards organizations, regulatory agencies and national policy committees. In January 2011, it was reported by
The New York Times that the INL was allegedly responsible for some of the initial research behind the
Stuxnet virus, which allegedly crippled Iran's nuclear centrifuges. The INL, which teamed up with
Siemens, conducted research on the P.C.S.-7 control system to identify its vulnerabilities. According to the
Times, that information would later be used by the American and Israeli governments to create the Stuxnet virus. The
Times article was later disputed by other journalists, including Forbes blogger Jeffrey Carr, as being both sensational and lacking verifiable facts. In March 2011,
Vanity Fair's magazine cover story on Stuxnet carried INL's official response, stating, "Idaho National Laboratory was not involved in the creation of the Stuxnet worm. In fact, our focus is to protect and defend control systems and critical infrastructures from cyber threats like Stuxnet and we are all well recognized for these efforts. We value the relationships that we have formed within the control systems industry and in no way would risk these partnerships by divulging confidential information."
Nuclear nonproliferation Building on INL's nuclear mission and legacy in reactor design and operations, the lab's engineers are developing technology, shaping policy and leading initiatives to secure the nuclear fuel cycle and prevent the proliferation of weapons of mass destruction. Under the direction of the National Nuclear Security Administration, INL and other national laboratory scientists are leading a global initiative to secure foreign stockpiles of fresh and spent highly enriched uranium and return it to secure storage for processing. Other engineers are working to convert U.S. research reactors and build new reactor fuels that replace highly enriched uranium with a safer, low-enriched uranium fuel. To protect against threats from the dispersal of nuclear and radiological devices, INL researchers also examine radiological materials to understand their origin and potential uses. Others have applied their knowledge to the development of detection technologies that scan and monitor containers for nuclear materials. The laboratory's expansive desert location, nuclear facilities and wide range of source materials provide an ideal training location for military responders, law enforcement and other civilian first responders. INL routinely supports these organizations by leading classroom training, conducting field exercises and assisting in technology assessments.
Energy and environmental projects Advanced Vehicle Testing Activity INL's Advanced Vehicle Testing Activity gathers information from more than 4000 plug-in-hybrid vehicles. These vehicles, operated by a wide swath of companies, local and state governments, advocacy groups, and others are located all across the United States, Canada and
Finland. Together, they have logged a combined 1.5 million miles worth of data that are analyzed by specialists at INL. Dozens of other types of vehicles, like hydrogen-fueled and pure electric cars, are also tested at INL. This data will help evaluate the performance and other factors that will be critical to widespread adoption of plug-in or other alternative vehicles.
Bioenergy INL researchers are partnering with farmers, agricultural equipment manufacturers and universities to optimize the logistics of an industrial-scale biofuel economy. Agricultural waste products—such as wheat straw; corncobs, stalks or leaves; or bioenergy crops such as switchgrass or miscanthus—could be used to create cellulosic biofuels. INL researchers are working to determine the most economic and sustainable ways to get biofuel raw materials from fields to biorefineries.
Robotics INL's robotics program researches, builds, tests and refines robots that, among other things, clean up dangerous wastes, measure radiation, scout drug-smuggling tunnels, aid search-and-rescue operations, and help protect the environment. These robots roll, crawl, fly, and go under water, even in swarms that communicate with each other on the go to do their jobs.
Biological Systems The Biological Systems department is housed in 15 laboratories with a total of at the INL Research Center in Idaho Falls. The department engages in a wide variety of biological studies, including studying bacteria and other microbes that live in extreme conditions such as the extremely high temperature pools of Yellowstone National Park. These types of organisms could boost the efficiency of biofuels production. Other studies related to uncommon microbes have potential in areas such as
carbon dioxide sequestration and groundwater cleanup.
Hybrid energy systems INL is pioneering the research and testing associated with hybrid energy systems that combine multiple energy sources for optimum carbon management and energy production. For example, a nuclear reactor could provide electricity when certain renewable resources are not available, while also providing a carbon-free source of heat and hydrogen that could be used, for example, to make liquid transportation fuels from coal.
Nuclear waste processing In , construction of a new liquid waste processing facility, the Integrated Waste Treatment Unit (IWTU), was nearing completion at INTEC on the INL site. It will process approximately 900,000 gallons of liquid nuclear waste using a steam reforming process to produce a granular product suitable for disposal. The facility is the first of its kind and based on a scaled prototype. The project is a part of the Department of Energy's Idaho Cleanup Project aimed at removing waste and demolishing old nuclear facilities at the INL site.
Safety and Tritium Applied Research In May 2022, CNBC reported the Safety and Tritium Applied Research (STAR) program has been set up to looking into the production and safety protocols for working with
tritium, the fuel that many startups are working on to commercialize
fusion power.
Interdisciplinary projects The Instrumentation, Control and Intelligent Systems (ICIS) program at Idaho National Laboratory (INL) conducts research in safeguards, control system security, sensor technologies, and robotics. The research relates to energy security and
homeland security." ICIS research in resilient control systems includes work on human systems, security, and complex interdependencies. ==Outreach==