Moiré patterns occur everywhere. They are created by layering two similar but not identical geometric designs. A common example is the pattern that sometimes emerges when viewing a chain-link fence ...

Researchers at IMDEA Nanociencia have developed an analytical method to explain the formation of a quasi-perfect 1D moiré pattern in twisted bilayer graphene. The pattern, naturally occurring in piled ...

Twisted graphene, also known as twisted bilayer graphene, is a unique structure that may be created by stacking two layers of graphene at a tiny angle, often somewhere between one and two degrees.

Researchers now reveal how various physical manipulations of graphene, such as layering and twisting, impact its optical properties and conductivity. When it comes to electrically conductive ...

A study published in Nano Letters by researchers from the Florida State University Department of Physics and FSU-headquartered National High Magnetic Field Laboratory explores how physical ...

An interference pattern that emerges from three stacked and twisted layers of graphene, called a supermoiré pattern, can uncover hidden properties of simpler moiré materials. SEAS physicists used a ...

Twisted graphene stores memory by combining strain-induced hysteresis and nonlinear response, enabling reprogrammable, low power memory in a pure carbon system. (Nanowerk Spotlight) Electronic memory ...

The nano-IR imaging set-up for studying the moiré graphene lattice. (Courtesy: G Ni) Researchers at the University of California at San Diego (UCSD) are the first to have used infrared nano-imaging to ...

Physicists have developed a technique to precisely control the alignment of supermoiré lattices by using a set of golden rules, paving the way for the advancement of next generation moiré quantum ...

BUFFALO, N.Y. – Moiré patterns occur everywhere. They are created by layering two similar but not identical geometric designs. A common example is the pattern that sometimes emerges when viewing a ...