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

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

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

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

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 ...

Scientific Achievement: By resolving the atomic structure of individual layers in twisted bilayers, this work provides unprecedented access to dopant and defect distributions that were previously ...

Researchers identify hierarchical moire patterns in 2D materials, enabling a tunable platform for designing next-generation quantum materials at the atomic scale.

A new AI-powered method is changing how scientists measure the universe. Developed by researchers at the Flatiron Institute and their partners, this technique offers a far more accurate way to ...

First-ever atomic-scale identification of hierarchical moiré structures in 2D materials / - Opens new possibilities for programmable quantum material design ...

The new Samsung G90XF and 4K OLED G81SF are impressive, but they both have a huge downside.

The combination of low TBR and high thermal conductivity significantly reduced hotspot temperatures, setting new benchmarks in thermal design for power electronics. We further explored the anisotropic ...

Moiré patterns in nanomaterials emerge when two atomic layers are slightly rotated relative to each other, creating intricate interference patterns. Typically, these angle adjustments are minimal.