Detector measures the energy a neutrino imparts to protons and neutrons to help explain the nature of matter and the universe.
Microwave heating significantly alters Alfvén waves, offering insights into the physics of the waves themselves.
Scientists map electrical currents emanating from the boundary of a tokamak plasma, providing new information for reactor design.
International collaborators advance physics basis for tokamak plasma confinement at low rotation, potentially benefiting a fusion reactor.
Large-scale simulations of quarks promise precise view of reactions of astrophysical importance.
Gravitational wave observations combined with optical and gamma-ray data confirm earlier predictions, offer insights into how the galaxy produces lead, mercury, and other elements.
Real-time imaging shows how hydrogen causes oxygen to leave a buried surface, transforming an oxide into a metal.
Simply applying a small voltage dramatically changes the atomic structure, vital to creating materials for advanced computer memory.
A new x-ray beam technique tracks atomic-level changes under real-world operating conditions.
Measured strong coupling of vibrations and electrons could lead to controlled magnetism and electronic properties.
Focused x-ray beam revealed structural changes from laser heating, pinning down elusive melting point.
For one of the strongest known materials, calculations clarify a long-standing debate about how atoms pack together.
