New supercomputing capabilities help understand how to cope with large-scale instabilities in tokamaks.
For the first time, scientists modeled the spontaneous bifurcation of turbulence to high-confinement mode, solving a 35-year-old mystery.
Plutonium has more verified and accessible oxidation states than any other actinide element, an important insight for energy and security applications.
Easily manufactured membranes aid efficient chemical separation.
A new uranium-based metal-organic framework, NU-1301, could aid energy producers and industry.
Calculations of a subatomic particle called the sigma provide insight into the communication between subatomic particles deep inside the heart of matter.
A new polymer, created with a structure inspired by crystalline silicon, may make it easier to build better computers and solar cells.
Developing a highly active and acid-stable catalyst for water splitting could significantly impact solar energy technologies.
Researchers succeed in producing larger quantities of a long-lived radioisotope that generates the needed isotope on demand.
Scientists invent a new approach to creating ordered patterns of nitrogen-vacancy centers in diamond, a promising approach to storing and computing quantum data.
Antibody’s molecular structure reveals how it recognizes the virus.
Some pine trees may have trouble gaining a foothold above the treeline.
