Filter News
Area of Research
- (-) Neutron Science (10)
- (-) Nuclear Science and Technology (12)
- Biological Systems (1)
- Biology and Environment (64)
- Biology and Soft Matter (1)
- Clean Energy (28)
- Climate and Environmental Systems (1)
- Computational Biology (1)
- Fusion and Fission (15)
- Fusion Energy (5)
- Isotopes (17)
- Materials (17)
- Materials for Computing (1)
- National Security (12)
- Quantum information Science (4)
- Supercomputing (33)
News Topics
- (-) Advanced Reactors (4)
- (-) Biomedical (5)
- (-) Environment (3)
- (-) Fusion (6)
- (-) Isotopes (2)
- (-) Quantum Science (1)
- (-) Space Exploration (2)
- 3-D Printing/Advanced Manufacturing (5)
- Artificial Intelligence (4)
- Big Data (1)
- Bioenergy (2)
- Biology (1)
- Chemical Sciences (1)
- Clean Water (2)
- Computer Science (8)
- Coronavirus (4)
- Decarbonization (1)
- Energy Storage (2)
- Fossil Energy (1)
- High-Performance Computing (1)
- Machine Learning (3)
- Materials (5)
- Materials Science (9)
- Mathematics (1)
- Microscopy (1)
- Molten Salt (1)
- Nanotechnology (2)
- National Security (1)
- Neutron Science (34)
- Nuclear Energy (17)
- Physics (2)
- Polymers (1)
- Quantum Computing (1)
- Security (1)
- Summit (2)
- Transformational Challenge Reactor (2)
- Transportation (1)
Media Contacts
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.
When it’s up and running, the ITER fusion reactor will be very big and very hot, with more than 800 cubic meters of hydrogen plasma reaching 170 million degrees centigrade. The systems that fuel and control it, on the other hand, will be small and very cold. Pellets of frozen gas will be shot int...