Cosmic rays may soon stymie quantum computing
Building quantum computers underground or designing radiation-proof qubits may be needed, researchers find.
Building quantum computers underground or designing radiation-proof qubits may be needed, researchers find.
Multidisciplinary team uses metal organic frameworks to extract radioactive krypton from fuel-reprocessing gasses.
New work on 2D and 3D meshing aims to address challenges with some of today’s state-of-the-art methods.
Faculty from the departments of physics, chemical engineering, and mechanical engineering were selected for the 2020 Early Career Research Program.
In certain alloys, exposure to proton irradiation can extend the material’s lifetime, study finds.
Fabrication technique will enable SkyWater Technology to manufacture a range of electronics that can withstand harsh radiation environments.
Exotic states called Kohn anomalies could offer clues to why some materials have the electronic properties they do.
Modeling study shows battery reuse systems could be profitable for both electric vehicle companies and grid-scale solar operations.
Results could help designers engineer high-temperature superconductors and quantum computing devices.
MIT experience with heating plasmas will support novel and low-cost approaches to creating fusion energy.
Carbon nanotubes embedded in leaves detect chemical signals that are produced when a plant is damaged.
Physicists’ discovery could lead to a new family of robust qubits for quantum computing.
Sorting through millions of possibilities, a search for battery materials delivered results in five weeks instead of 50 years.
Consortium includes industry, government, and academic institutions.
Fusion energy community makes unified statement on priorities in report for Department of Energy Policy Advisory Group.