Filter News
Area of Research
- (-) Materials (15)
- (-) Neutron Science (10)
- Advanced Manufacturing (3)
- Biology and Environment (16)
- Clean Energy (35)
- Computational Biology (1)
- Computer Science (1)
- Fusion and Fission (3)
- Isotopes (2)
- Materials for Computing (1)
- National Security (19)
- Nuclear Science and Technology (4)
- Quantum information Science (2)
- Supercomputing (18)
News Type
News Topics
- (-) 3-D Printing/Advanced Manufacturing (6)
- (-) Coronavirus (3)
- (-) Cybersecurity (1)
- (-) Machine Learning (4)
- (-) Microscopy (8)
- (-) Security (1)
- (-) Space Exploration (2)
- Advanced Reactors (1)
- Artificial Intelligence (6)
- Big Data (2)
- Bioenergy (4)
- Biology (1)
- Biomedical (6)
- Buildings (1)
- Chemical Sciences (8)
- Clean Water (3)
- Composites (2)
- Computer Science (12)
- Decarbonization (2)
- Energy Storage (8)
- Environment (8)
- Exascale Computing (1)
- Fossil Energy (1)
- Fusion (3)
- Grid (2)
- High-Performance Computing (2)
- Isotopes (6)
- Materials (23)
- Materials Science (26)
- Mathematics (1)
- Nanotechnology (11)
- National Security (1)
- Neutron Science (38)
- Nuclear Energy (10)
- Partnerships (3)
- Physics (13)
- Polymers (6)
- Quantum Computing (2)
- Quantum Science (1)
- Summit (2)
- Sustainable Energy (2)
- Transformational Challenge Reactor (2)
- Transportation (6)
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...
![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 ...