A team studied some of the smallest particles in the Universe on the nation’s fastest computer, Summit at Oak Ridge National Laboratory.
Measurements of nuclear charge radii and state-of-the-art nuclear models challenge the magic of neutron number 32 in potassium isotopes.
A material with a disordered rock salt structure could help make batteries safer, faster-charging, and able to store more energy
Extreme-scale turbulence simulation and AI discover a formula to predict the crucial exhaust heat-load width in future tokamak fusion reactors.
Researchers use a supercomputer to understand the mysterious “isotope effect” for better fusion reactors.
Nuclear theorists put pen to paper and code to computer to detail this subatomic particle’s inner structure.
Researchers unveil a new catalytic mechanism in a novel material used for ammonia synthesis, a key component in fertilizer.
Data from the first observation of a neutron-star collision combined with input from modern nuclear theory narrow the range of neutron star radii.
Neutron and X-ray experiments illuminate the magnetic transitions in hexagonal iron sulfide that transform it from a conductor to an insulator.
Nuclear theorists explore the properties of dense neutron matter to get at the core of neutron stars.
New laser-driven experiments and numerical simulations reveal an electron acceleration mechanism relevant to young supernova shock waves.
Machine learning-based algorithm characterizes materials’ microstructure in 3D and real time.
