Neutron experiments revealed microscopic details about a special 3D-printed superalloy that could potentially reduce component costs.
Opposing teams of water-loving and oil-loving molecules separate metals called lanthanides that are important in developing clean energy technologies.
A newly discovered excited state in radioactive sodium-32 has an unusually long lifetime, and its shape dynamics could be the cause.
Crystalline nanoribbons synthesized to resonate with infrared light for imaging, sensing, and signaling pass a crucial test.
Understanding how methanogenic bacteria can “bio-mine” minerals advances biotechnology and helps scientists understand the Earth’s geological history.
Using two methods is better than one when it comes to observing how solar cells form and improving cell properties.
Scientists map atomic-level changes in the components of a running internal combustion engine using neutron techniques.
A new approach for measuring nuclear recoils in superconducting quantum sensors enables the first limits on sterile neutrinos from beryllium-7 decay.
New measurements provide insights for geochronology and reactor design.
Harnessing the intensity of a terahertz laser pulse brings the resolution of electron scattering closer to the scale of electron and proton motion.
Oil-free, nanoscale solid lubricant creates ultra-slippery layer between sliding surfaces in machinery
Built with detector technologies used in nuclear physics experiments, the system monitors radiation treatments in hard-to-reach areas.
