A pioneering team at the University of Maryland has captured the first-ever images of atomic thermal vibrations, unlocking an ...

Most people envision vibration on a large scale, like the buzz of a cell phone notification or the oscillation of an electric ...

Creating complex structures at the tiniest scales has long been a challenge for engineers. But new research from Georgia Tech ...

The reliable separation of some gases from others could be highly advantageous for a wide range of applications. For instance ...

High-responsivity and low dark current resonant-cavity-enhanced (RCE) Ge PIN photodiodes with a monolayer graphene absorber were demonstrated on a 200 mm insulator. Ge was grown on the donor Si wafer, ...

Japanese researchers have developed a simulation-based technique to measure the bending rigidity of graphene sheets with ...

Researchers use electron ptychography to capture atomic vibrations in twisted 2D materials with record-breaking precision.

Researchers use DNA nanotechnology to build layered lattice structures that produce new interference patterns with unique physical properties and nanoscale control.

Spintronics are promising devices that work utilizing not only the charge of electrons, like conventional electronics, but ...

Researchers show that twisting stacked atomic layers can unlock new quantum properties, offering a fresh strategy to engineer ...

Cryo-EM is a technique that allows researchers to determine the 3D structure of proteins and viruses at near atomic resolution. With cryo-EM, researchers can see every molecule in the virus, enabling ...

Twisted materials—known as moiré structures—have revolutionized modern physics, emerging as today's "alchemy" by creating entirely new phases of matter through simple geometric manipulation. The term ...