A novel experimental geometry at the Linac Coherent Light Source reveals, for the first time, how silicon responds to shocks similar to those in a planet’s core.
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
The 3.7-billion-year-old structures were considered the first evidence for life on the planet; new evidence suggests differently.
Scientists use implanted silicon ions and electricity to increase the spin time of quantum bits, moving closer to the tech needed for quantum networks.
Element-selective method reveals interfacial properties of materials used for water purification, catalysis, energy conversion, and more.
Scientists can now measure 3-D structures of tiny particles with properties that hold promise for advanced sensors and diagnostics.
New method can make films of atomically thin carbon that are over a foot long.
A new approach to atom probe tomography promises more precise and accurate measurements vital to semiconductors used in computers, lasers, detectors, and more.
Scientists uncover a way to control terahertz radiation using tiny engineered particles in a magnetic field, potentially opening the doors for better medical and environmental sensors.
Efficient generation of photon pairs from modified carbon nanotubes shows path to new types of light sources.
Researchers developed a new self-generating lubricant with great potential for industrial applications.
Researchers design self-assembling nanosheets that mimic the surface of cells.
