Researchers at ETH Zurich have developed a groundbreaking technique to manipulate electrons within materials using artificial ...

Future research aims to explore new computational possibilities through mechanical coupling between memory bits. [2] ...

Newly achieved precise control over light emitted from incredibly tiny sources, a few nanometers in size, embedded in ...

To study the interactions between electrons in a material, physicists have come up with a number of tricks over the years.

A research team has successfully developed a new synthesis technology for 2D semiconductors. This technique enables the ...

MIT physicists have made an exciting discovery: in an ultra-thin material, electrons can form crystal-like structures, acting like tiny frozen blocks of energy. This unexpected finding adds to a ...

A multi-institutional research team has engineered a way to preserve the electrical properties of materials as they are shrunk to the nanoscale. The use of the soft substrate hexagonal boron nitride ...

22 in Nature, the team describes how electrons in devices made, in part, of the new material can become solid, or form crystals, by changing the voltage applied to the devices ... in 2023 they created ...

MIT physicists discovered that electrons can form crystal-like structures in a material only a few billionths of a meter ... In 2023, they made a sandwich with rhombohedral pentalayer graphene and ...

For example, in 2023 they created a sandwich of rhombohedral pentalayer graphene with “buns” made of hexagonal boron nitride (Nature Nanotechnology, "Correlated insulator and Chern insulators in ...