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.
Theory predicts that bending a film will control spin direction and create a spin current for next-generation electronics.
Cage-like molecules with internal chemical hooks remove three times more hazardous radioactive iodine compounds than current methods.
Lasers reveal a new state of matter—the first three-dimensional quantum liquid crystal.
Unexpectedly, a little chemical substitution stabilizes unusual magnetic phase of vortexes called skyrmions.
New, unexpected paradigm discovered: Disorder may actually promote an exotic quantum state, with potential for ultrafast computing.
Shining light on a growing semiconductor modifies its interface with the surface and could improve the optical properties of each.
Novel defect control in graphene enables direct imaging of trapped electrons that follow Einstein’s rules.
