
A Rare Quantum State Realized in a New Material
A revolutionary material harbors magnetism and massless electrons that travel near the speed of light—for future ultrasensitive, high-efficiency electronics and sensors.
A revolutionary material harbors magnetism and massless electrons that travel near the speed of light—for future ultrasensitive, high-efficiency electronics and sensors.
Machine learning and neural networks are the foundation of artificial intelligence and image recognition, but now they offer a bridge to see and recognize exotic insulating phases in quantum materials.
Electrons are forced to the edge of the road on a thin sheet of tungsten ditelluride.
Detector measures the energy a neutrino imparts to protons and neutrons to help explain the nature of matter and the universe.
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.
Lasers reveal a new state of matter—the first three-dimensional quantum liquid crystal.