Scientists predict that gluons, the particles that bind quarks, also bind to one another, but they have never unambiguously observed globs of pure ‘glue.’
Researchers have created a novel membrane platform for studying the structure and function of membrane proteins in their realistic environment.
Neutron and X-ray scattering shed light on exotic states that determine the electronic properties of materials.
Scientists track down coexistence of multiple shapes in the Nickel-64 nucleus: a spherical ground state and elongated and flattened shapes.
Researchers address the challenge of integrating the hot core and the cooler edge of a fusion plasma.
A newly designed X-ray oscillator may enable atomic level precision with intense X-ray pulses.
Tracking particles containing charm quarks offers insight into how quarks combine.
Data from the first observation of a neutron-star collision combined with input from modern nuclear theory narrow the range of neutron star radii.
Scientists use a machine learning algorithm to reduce tuning time of a dozen instruments at once.
A novel terahertz laser achieves the performance goals critical for new applications in sensing and imaging.
An X-ray image taken with a novel X-ray wavefront imager results in high precision measurements of intensity and direction of the X-ray beam.
To help researchers examine important cloud processes, a DOE user facility activity combines high-resolution simulations with real-world observations
