Filter News
Area of Research
- (-) Neutron Science (43)
- Advanced Manufacturing (11)
- Biology and Environment (54)
- Building Technologies (1)
- Clean Energy (138)
- Climate and Environmental Systems (2)
- Computational Biology (1)
- Computational Engineering (2)
- Computer Science (6)
- Electricity and Smart Grid (1)
- Energy Sciences (1)
- Fusion and Fission (19)
- Fusion Energy (6)
- Isotopes (16)
- Materials (65)
- Materials for Computing (23)
- Mathematics (1)
- National Security (19)
- Nuclear Science and Technology (23)
- Nuclear Systems Modeling, Simulation and Validation (2)
- Quantum information Science (6)
- Sensors and Controls (1)
- Supercomputing (59)
- Transportation Systems (1)
News Topics
- 3-D Printing/Advanced Manufacturing (3)
- Advanced Reactors (1)
- Artificial Intelligence (3)
- Big Data (1)
- Bioenergy (3)
- Biology (2)
- Biomedical (7)
- Chemical Sciences (1)
- Climate Change (1)
- Computer Science (10)
- Coronavirus (7)
- Environment (2)
- Fusion (1)
- High-Performance Computing (1)
- Machine Learning (1)
- Materials (3)
- Materials Science (13)
- Mathematics (1)
- Microscopy (2)
- Nanotechnology (7)
- National Security (1)
- Neutron Science (39)
- Nuclear Energy (1)
- Physics (3)
- Polymers (1)
- Quantum Computing (1)
- Quantum Science (5)
- Security (1)
- Space Exploration (1)
- Summit (5)
- Sustainable Energy (1)
- Transportation (2)
Media Contacts
Oak Ridge National Laboratory researchers working on neutron imaging capabilities for nuclear materials have developed a process for seeing the inside of uranium particles – without cutting them open.
Biological membranes, such as the “walls” of most types of living cells, primarily consist of a double layer of lipids, or “lipid bilayer,” that forms the structure, and a variety of embedded and attached proteins with highly specialized functions, including proteins that rapidly and selectively transport ions and molecules in and out of the cell.
An international team of researchers has discovered the hydrogen atoms in a metal hydride material are much more tightly spaced than had been predicted for decades — a feature that could possibly facilitate superconductivity at or near room temperature and pressure.