Filter News
Area of Research
- Advanced Manufacturing (1)
- Biology and Environment (4)
- Clean Energy (13)
- Fuel Cycle Science and Technology (1)
- Fusion and Fission (12)
- Fusion Energy (1)
- Isotope Development and Production (1)
- Isotopes (1)
- Materials (22)
- Materials for Computing (2)
- National Security (5)
- Neutron Science (44)
- Nuclear Science and Technology (11)
- Supercomputing (9)
News Type
News Topics
- (-) Neutron Science (56)
- (-) Nuclear Energy (33)
- 3-D Printing/Advanced Manufacturing (50)
- Advanced Reactors (12)
- Artificial Intelligence (31)
- Big Data (12)
- Bioenergy (25)
- Biology (23)
- Biomedical (18)
- Biotechnology (7)
- Buildings (16)
- Chemical Sciences (33)
- Clean Water (1)
- Climate Change (25)
- Composites (10)
- Computer Science (62)
- Coronavirus (17)
- Critical Materials (11)
- Cybersecurity (18)
- Decarbonization (23)
- Education (3)
- Element Discovery (1)
- Energy Storage (44)
- Environment (45)
- Exascale Computing (12)
- Fossil Energy (1)
- Frontier (16)
- Fusion (14)
- Grid (18)
- High-Performance Computing (31)
- Irradiation (1)
- Isotopes (21)
- ITER (2)
- Machine Learning (14)
- Materials (69)
- Materials Science (54)
- Mercury (2)
- Microelectronics (1)
- Microscopy (18)
- Molten Salt (2)
- Nanotechnology (28)
- National Security (20)
- Net Zero (4)
- Partnerships (28)
- Physics (24)
- Polymers (13)
- Quantum Computing (10)
- Quantum Science (28)
- Renewable Energy (1)
- Security (11)
- Simulation (11)
- Software (1)
- Space Exploration (3)
- Statistics (2)
- Summit (21)
- Sustainable Energy (37)
- Transformational Challenge Reactor (4)
- Transportation (32)
Media Contacts
In a finding that helps elucidate how molten salts in advanced nuclear reactors might behave, scientists have shown how electrons interacting with the ions of the molten salt can form three states with different properties. Understanding these states can help predict the impact of radiation on the performance of salt-fueled reactors.
Using neutrons to see the additive manufacturing process at the atomic level, scientists have shown that they can measure strain in a material as it evolves and track how atoms move in response to stress.
The Spallation Neutron Source — already the world’s most powerful accelerator-based neutron source — will be on a planned hiatus through June 2024 as crews work to upgrade the facility. Much of the work — part of the facility’s Proton Power Upgrade project — will involve building a connector between the accelerator and the planned Second Target Station.
The Exascale Small Modular Reactor effort, or ExaSMR, is a software stack developed over seven years under the Department of Energy’s Exascale Computing Project to produce the highest-resolution simulations of nuclear reactor systems to date. Now, ExaSMR has been nominated for a 2023 Gordon Bell Prize by the Association for Computing Machinery and is one of six finalists for the annual award, which honors outstanding achievements in high-performance computing from a variety of scientific domains.
Rose Montgomery, a distinguished researcher and leader of the Used Fuel and Nuclear Material Disposition group at ORNL, has been selected to participate in the U.S. WIN Nuclear Executives of Tomorrow, or NEXT, class of 2023 to 2024.
Technologies developed by researchers at ORNL have received six 2023 R&D 100 Awards.
After a highly lauded research campaign that successfully redesigned a hepatitis C drug into one of the leading drug treatments for COVID-19, scientists at ORNL are now turning their drug design approach toward cancer.
Leigh R. Martin, a senior scientist and leader of the Fuel Cycle Chemical Technology group at ORNL, has been named a Fellow of the American Chemical Society for 2023.
Yarom Polsky, director of the Manufacturing Science Division, or MSD, at the Department of Energy’s Oak Ridge National Laboratory, has been elected a Fellow of the American Society of Mechanical Engineers, or ASME.
The Spallation Neutron Source at the Department of Energy's Oak Ridge National Laboratory set a world record when its particle accelerator beam operating power reached 1.7 megawatts, substantially improving on the facility’s original design capability.