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.
X-ray scattering measures the positions of atoms as they vibrate in a two-dimensional cover sheet.
Scientists reveal oxygen’s hidden talent for filling atomic gaps in 2D semiconductors and the surprising role of electron spin in electronic conductivity
Material traps noble gases at above-freezing temperatures, a difficult and important industrial challenge.
Growing two-dimensional crystals on curved surfaces introduces strain to control the crystal’s light emission.
