Filter News
Area of Research
- Advanced Manufacturing (16)
- Biology and Environment (44)
- Building Technologies (1)
- Clean Energy (132)
- Computational Biology (2)
- Computational Engineering (2)
- Computer Science (9)
- Electricity and Smart Grid (3)
- Energy Sciences (1)
- Functional Materials for Energy (2)
- Fusion and Fission (8)
- Fusion Energy (1)
- Isotopes (1)
- Materials (63)
- Materials for Computing (10)
- Mathematics (1)
- National Security (18)
- Neutron Science (19)
- Nuclear Science and Technology (2)
- Quantum information Science (8)
- Sensors and Controls (1)
- Supercomputing (68)
News Type
News Topics
- (-) 3-D Printing/Advanced Manufacturing (90)
- (-) Big Data (50)
- (-) Clean Water (28)
- (-) Energy Storage (76)
- (-) Grid (50)
- (-) High-Performance Computing (69)
- (-) Machine Learning (36)
- (-) Nanotechnology (40)
- (-) Quantum Science (45)
- Advanced Reactors (26)
- Artificial Intelligence (71)
- Bioenergy (73)
- Biology (84)
- Biomedical (45)
- Biotechnology (15)
- Buildings (46)
- Chemical Sciences (49)
- Climate Change (82)
- Composites (21)
- Computer Science (143)
- Coronavirus (32)
- Critical Materials (18)
- Cybersecurity (23)
- Decarbonization (59)
- Education (1)
- Emergency (2)
- Environment (163)
- Exascale Computing (31)
- Fossil Energy (5)
- Frontier (30)
- Fusion (49)
- Hydropower (11)
- Irradiation (3)
- Isotopes (43)
- ITER (6)
- Materials (110)
- Materials Science (101)
- Mathematics (9)
- Mercury (10)
- Microelectronics (3)
- Microscopy (39)
- Molten Salt (7)
- National Security (55)
- Net Zero (11)
- Neutron Science (88)
- Nuclear Energy (88)
- Partnerships (26)
- Physics (41)
- Polymers (22)
- Quantum Computing (28)
- Renewable Energy (1)
- Security (16)
- Simulation (44)
- Software (1)
- Space Exploration (23)
- Statistics (2)
- Summit (39)
- Sustainable Energy (101)
- Transformational Challenge Reactor (4)
- Transportation (72)
Media Contacts
Belinda Akpa is a chemical engineer with a talent for tackling big challenges and fostering inclusivity and diversity in the next generation of scientists.
Through a consortium of Department of Energy national laboratories, ORNL scientists are applying their expertise to provide solutions that enable the commercialization of emission-free hydrogen fuel cell technology for heavy-duty
Oak Ridge National Laboratory scientists proved molybdenum titanium carbide, a refractory metal alloy that can withstand extreme temperature environments, can also be crack free and dense when produced with electron beam powder bed fusion.
Scientists at Oak Ridge National Laboratory have devised a method to identify the unique chemical makeup of every lithium-ion battery around the world, information that could accelerate recycling, recover critical materials and resolve a growing waste stream.
Researchers at Oak Ridge National Laboratory have identified a statistical relationship between the growth of cities and the spread of paved surfaces like roads and sidewalks. These impervious surfaces impede the flow of water into the ground, affecting the water cycle and, by extension, the climate.
Scientists at Oak Ridge National Laboratory successfully demonstrated a technique to heal dendrites that formed in a solid electrolyte, resolving an issue that can hamper the performance of high energy-density, solid-state batteries.
Oak Ridge National Laboratory researchers combined additive manufacturing with conventional compression molding to produce high-performance thermoplastic composites reinforced with short carbon fibers.
Researchers at the Department of Energy’s Oak Ridge National Laboratory and the University of Tennessee are automating the search for new materials to advance solar energy technologies.
A team of researchers at Oak Ridge National Laboratory and Purdue University has taken an important step toward this goal by harnessing the frequency, or color, of light. Such capabilities could contribute to more practical and large-scale quantum networks exponentially more powerful and secure than the classical networks we have today.
Oak Ridge National Laboratory scientists demonstrated that an electron microscope can be used to selectively remove carbon atoms from graphene’s atomically thin lattice and stitch transition-metal dopant atoms in their place.