
Scientists Take Control of Magnetism at the Microscopic Level
Studies of the nanostructure of a chiral magnet provides insights on controlling magnetic properties for applications in computers and other electronics.
Studies of the nanostructure of a chiral magnet provides insights on controlling magnetic properties for applications in computers and other electronics.
New optics-on-a-chip device paves the way to helping characterize fast chemical, material, and biological processes.
Neutron scattering monitors structures during post-production heat treatment to validate production models.
Unusual filling of different sub-shells due to quantum confinement leads to a stable superatom that is also highly magnetic.
Short and long-range electron transfer compete to determine free-charge yield in organic semiconductors.
Researchers discover key details of how to drive photosynthesis in the shade by studying far-red light acclimation in cyanobacteria.
Neural networks determine the amplitude and phase of X-ray pulses, enabling new, high-resolution quantum studies.
Using two methods is better than one when it comes to observing how solar cells form and improving cell properties.
Scientists capture the short-lived hydroxyl-hydronium pair and the induced dynamic response in ionized liquid water in unprecedented detail.
Photon-deuteron collisions offer insight into the gluons that bind the building blocks of matter—and what it takes to break protons and neutrons apart.
Novel molecular beam scattering apparatus that uses a liquid flat jet can study chemical reactions at the gas liquid interface of volatile liquids.
Discovery of a short-lived state could lead to faster and more energy-efficient computing devices.