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.
A new route to make metal beneath a layer of graphite opens potentially new applications in solar cells and quantum computing.
Read more about Getting Metal Under Graphite’s Skin
Discovery of new boron-containing phase opens the door for resilient flexible electronics.
Researchers capture detailed images of polymers, using electron-based imaging and computer simulations.
New method could enable studying the fastest interactions of ultrabright X-rays with matter, a vital way of learning about chemical reactions.
Titan supercomputer tells origin story of nanoparticle size distributions with large-scale simulations.
New method provides ultrafast switching of electronic structure and illuminates fundamentals of charge ordering, potentially offering a simple path for next-generation data storage.
Read more about Bursts of Light Shape Walls Between Waves of Charge
Neutron scattering reveals supersonic particles that carry heat and may improve electronics and sensors.
Read more about Beyond the “Sound Barrier” to Get the Heat Out
Detailed view of atoms opens doors for new designs to convert atomic displacements to electrical energy.
Read more about New Insights into a Long-Standing Debate About Materials that Turn Motion into Electricity
