Particles act in a way that justifies extrapolating simulation results to astrophysical scales.
Engineers can model heat distribution in reactor designs with fewer or no approximations.
Researchers use advanced nuclear models to explain 50-year mystery surrounding the process stars use to transform elements.
Titan supercomputer tells origin story of nanoparticle size distributions with large-scale simulations.
The Fusion Recurrent Neural Network reliably forecasts disruptive and destructive events in tokamaks.
Antiquark spin contribution to proton spin depends on flavor, which could help unlock secrets about the nuclear structure of atoms that make up nearly all visible matter in our universe.
With user facilities, researchers devise novel battery chemistries to help make fluoride batteries a reality.
Researchers demystify how the nitrogenase enzyme breaks bonds to learn a better way to make ammonia.
Researchers find gusty winds increase surface evaporation that drives summer rainstorms in the Tropical West Pacific.
Surprisingly, a magnetic island does not necessarily perturb the plasma current in a dangerous way and destroy fusion performance.
Researchers modeled design concepts for innovative, opposed-piston engine on Titan supercomputer.
Read more about Supercomputing Low-Emission Engine
The two most abundant elements in the universe, hydrogen and helium, were previously thought to be impossible to measure by X-ray photoelectron spectroscopy.
Read more about X-ray Spectroscopy of Hydrogen and Helium
