Silicon-based electronics are approaching their physical limitations and new materials are needed to keep up with current technological demands. Two-dimensional (2D) materials have a rich array of ...

Add Yahoo as a preferred source to see more of our stories on Google. Scientists use electron ptychography to image hidden phason vibrations in 2D materials with record-breaking atomic resolution.

(Nanowerk News) A new 2D quantum material has been discovered. The material consists of atom-thin layers of cerium, silicon and iodine (CeSiI) and is the first example of a 2D material with heavy ...

Scientists have discovered that a "single atomic defect" in a layered 2D material can hold onto quantum information for microseconds at room temperature, underscoring the potential of 2D materials in ...

Austrian scientists have achieved a breakthrough by embedding individual platinum atoms into an ultrathin material and pinpointing their positions within the lattice with atomic precision for the ...

The largest two-dimensional crystal of extremely cold, charged atoms ever created could be used to study poorly understood quantum materials, as well as for building quantum computers. Some crystals ...

A novel 2-dimensional quantum substance has been discovered. The material is composed of atom-thin layers of cerium, silicon, and iodine (CeSiI) and is the first example of a two-dimensional material ...

True to Moore’s Law, the number of transistors on a microchip has doubled every year since the 1960s. But this trajectory is predicted to soon plateau because silicon — the backbone of modern ...

Two-dimensional materials are only a few atoms thick yet hold great promise for the electronics of tomorrow. Because they are so thin, they can be piled in strange, twisted configurations that yield ...

Annular dark field scanning electron microscopy images of a bilayer interface after heat pulses at 500° (left), 600° (middle) and 700° (right). Dashed colored lines mark the positions of the interface ...

Two-dimensional materials are only a few atoms thick yet hold great promise for the electronics of tomorrow. Because they are so thin, they can be piled in strange, twisted configurations that yield ...