Filter News
Area of Research
- (-) Nuclear Science and Technology (10)
- (-) Supercomputing (51)
- Advanced Manufacturing (5)
- Biological Systems (2)
- Biology and Environment (54)
- Clean Energy (90)
- Computational Biology (2)
- Computer Science (2)
- Electricity and Smart Grid (2)
- Fusion and Fission (6)
- Fusion Energy (8)
- Isotopes (5)
- Materials (49)
- Materials for Computing (12)
- National Security (17)
- Neutron Science (21)
- Nuclear Systems Modeling, Simulation and Validation (1)
- Quantum information Science (2)
- Sensors and Controls (1)
- Transportation Systems (2)
News Type
News Topics
- (-) Advanced Reactors (9)
- (-) Bioenergy (3)
- (-) Biomedical (12)
- (-) Grid (1)
- (-) Materials Science (11)
- (-) Security (1)
- (-) Summit (27)
- (-) Transportation (4)
- 3-D Printing/Advanced Manufacturing (4)
- Artificial Intelligence (22)
- Big Data (17)
- Biology (7)
- Biotechnology (1)
- Buildings (2)
- Chemical Sciences (2)
- Climate Change (14)
- Computer Science (61)
- Coronavirus (9)
- Critical Materials (3)
- Cybersecurity (2)
- Decarbonization (3)
- Energy Storage (2)
- Environment (17)
- Exascale Computing (13)
- Frontier (14)
- Fusion (8)
- High-Performance Computing (23)
- Isotopes (3)
- Machine Learning (8)
- Materials (5)
- Mathematics (1)
- Microscopy (2)
- Molten Salt (4)
- Nanotechnology (6)
- National Security (3)
- Net Zero (1)
- Neutron Science (8)
- Nuclear Energy (29)
- Physics (4)
- Polymers (2)
- Quantum Computing (14)
- Quantum Science (13)
- Simulation (11)
- Software (1)
- Space Exploration (5)
- Sustainable Energy (4)
- Transformational Challenge Reactor (2)
Media Contacts
![The electromagnetic isotope separator system operates by vaporizing an element such as ruthenium into the gas phase, converting the molecules into an ion beam, and then channeling the beam through magnets to separate out the different isotopes. The electromagnetic isotope separator system operates by vaporizing an element such as ruthenium into the gas phase, converting the molecules into an ion beam, and then channeling the beam through magnets to separate out the different isotopes.](/sites/default/files/styles/list_page_thumbnail/public/6_1_17%20Ru_NF3_530uA%5B2%5D.jpg?itok=3OLnNZqa)
A tiny vial of gray powder produced at the Department of Energy’s Oak Ridge National Laboratory is the backbone of a new experiment to study the intense magnetic fields created in nuclear collisions.