Filter News
Area of Research
- (-) Clean Energy (57)
- (-) Fusion and Fission (7)
- Biology and Environment (24)
- Computational Biology (1)
- Computer Science (2)
- Electricity and Smart Grid (1)
- Functional Materials for Energy (2)
- Isotopes (12)
- Materials (45)
- Materials for Computing (3)
- National Security (13)
- Neutron Science (10)
- Nuclear Science and Technology (1)
- Supercomputing (33)
News Topics
- (-) Biomedical (3)
- (-) Composites (8)
- (-) Computer Science (5)
- (-) Energy Storage (31)
- (-) Isotopes (1)
- (-) Physics (1)
- (-) Space Exploration (1)
- (-) Transportation (22)
- 3-D Printing/Advanced Manufacturing (21)
- Advanced Reactors (3)
- Artificial Intelligence (3)
- Bioenergy (6)
- Biology (4)
- Biotechnology (1)
- Buildings (25)
- Chemical Sciences (13)
- Clean Water (2)
- Climate Change (9)
- Coronavirus (3)
- Critical Materials (4)
- Cybersecurity (5)
- Decarbonization (28)
- Environment (12)
- Exascale Computing (2)
- Fossil Energy (2)
- Frontier (3)
- Fusion (11)
- Grid (20)
- High-Performance Computing (2)
- Hydropower (2)
- ITER (2)
- Machine Learning (2)
- Materials (16)
- Materials Science (8)
- Mercury (1)
- Microelectronics (1)
- Microscopy (3)
- National Security (5)
- Net Zero (3)
- Neutron Science (3)
- Nuclear Energy (18)
- Partnerships (13)
- Polymers (3)
- Renewable Energy (1)
- Security (3)
- Simulation (7)
- Sustainable Energy (19)
- Transformational Challenge Reactor (1)
Media Contacts
A new manufacturing method created by Oak Ridge National Laboratory and Rice University combines 3D printing with traditional casting to produce damage-tolerant components composed of multiple materials. Composite components made by pouring an aluminum alloy over a printed steel lattice showed an order of magnitude greater damage tolerance than aluminum alone.