Filter News
Area of Research
- (-) Clean Energy (33)
- (-) Materials (30)
- (-) Neutron Science (9)
- Biology and Environment (55)
- Biology and Soft Matter (1)
- Climate and Environmental Systems (1)
- Computational Biology (1)
- Fusion and Fission (20)
- Fusion Energy (4)
- Isotopes (2)
- Materials for Computing (2)
- National Security (14)
- Nuclear Science and Technology (17)
- Quantum information Science (2)
- Supercomputing (43)
News Topics
- (-) Advanced Reactors (3)
- (-) Artificial Intelligence (7)
- (-) Clean Water (6)
- (-) Climate Change (8)
- (-) Coronavirus (8)
- (-) Microscopy (8)
- (-) Nuclear Energy (11)
- (-) Physics (11)
- (-) Security (4)
- (-) Sustainable Energy (15)
- 3-D Printing/Advanced Manufacturing (26)
- Big Data (2)
- Bioenergy (13)
- Biology (5)
- Biomedical (8)
- Biotechnology (1)
- Buildings (11)
- Chemical Sciences (8)
- Composites (3)
- Computer Science (17)
- Cybersecurity (6)
- Decarbonization (16)
- Energy Storage (23)
- Environment (25)
- Exascale Computing (1)
- Fossil Energy (2)
- Fusion (2)
- Grid (13)
- High-Performance Computing (4)
- Isotopes (6)
- Machine Learning (4)
- Materials (26)
- Materials Science (24)
- Mathematics (2)
- Mercury (1)
- Microelectronics (1)
- Nanotechnology (10)
- National Security (2)
- Net Zero (1)
- Neutron Science (37)
- Partnerships (5)
- Polymers (5)
- Quantum Computing (2)
- Quantum Science (2)
- Simulation (1)
- Space Exploration (3)
- Summit (4)
- Transformational Challenge Reactor (2)
- Transportation (19)
Media Contacts
![Schematic drawing of the boron nitride cell. Credit: University of Illinois at Chicago. Schematic drawing of the boron nitride cell. Credit: University of Illinois at Chicago.](/sites/default/files/styles/list_page_thumbnail/public/news/images/schematic1.jpg?itok=iYCttAg3)
A new microscopy technique developed at the University of Illinois at Chicago allows researchers to visualize liquids at the nanoscale level — about 10 times more resolution than with traditional transmission electron microscopy — for the first time. By trapping minute amounts of...
![Ryan Kerekes is leader of the RF, Communications, and Cyber-Physical Security Group at Oak Ridge National Laboratory. Photos by Genevieve Martin, ORNL. Ryan Kerekes is leader of the RF, Communications, and Cyber-Physical Security Group at Oak Ridge National Laboratory. Photos by Genevieve Martin, ORNL.](/sites/default/files/styles/list_page_thumbnail/public/Ryan%20Kerekes%20Profile%20lab1_0.jpg?itok=btnfhbaJ)
As leader of the RF, Communications, and Cyber-Physical Security Group at Oak Ridge National Laboratory, Kerekes heads an accelerated lab-directed research program to build virtual models of critical infrastructure systems like the power grid that can be used to develop ways to detect and repel cyber-intrusion and to make the network resilient when disruption occurs.
![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.
For the past six years, some 140 scientists from five institutions have traveled to the Arctic Circle and beyond to gather field data as part of the Department of Energy-sponsored NGEE Arctic project. This article gives insight into how scientists gather the measurements that inform t...
![ORNL’s Xiahan Sang unambiguously resolved the atomic structure of MXene, a 2D material promising for energy storage, catalysis and electronic conductivity. Image credit: Oak Ridge National Laboratory, U.S. Dept. of Energy; photographer Carlos Jones ORNL’s Xiahan Sang unambiguously resolved the atomic structure of MXene, a 2D material promising for energy storage, catalysis and electronic conductivity. Image credit: Oak Ridge National Laboratory, U.S. Dept. of Energy; photographer Carlos Jones](/sites/default/files/styles/list_page_thumbnail/public/Sang_2016-P07680_0.jpg?itok=w0e5eR_U)
Researchers have long sought electrically conductive materials for economical energy-storage devices. Two-dimensional (2D) ceramics called MXenes are contenders. Unlike most 2D ceramics, MXenes have inherently good conductivity because they are molecular sheets made from the carbides ...