Ultrafast X-rays track how associated pairs of atoms find new locations when triggered by light.
New particle-in-cell simulations show how lasers heat plasmas, a key interaction in the next generation of powerful scientific instruments.
Dark fiber lays groundwork for long-distance earthquake detection and groundwater mapping.
Models use a fraction of the computational cost of today’s best atom-based water models.
Supercomputer validates mathematical approach for describing geological features.
Low-momentum (wimpy) quarks and gluons contribute to proton spin, offering insights into protons’ behavior in all visible matter.
Scientists use supercomputers to determine how reliably a popular Earth system model represents precipitation regionally and globally.
A first-of-its-kind computer simulation reveals self-healing cement for geothermal and oil and gas wells performs better than originally thought.
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.
