Researchers at Nagoya University in Japan used atomic-resolution secondary electron (SE) imaging to capture the atomic structure of the very top layer of materials to better understand the ...

Superconductivity provides a way to develop energy-efficient components that could impact everything from transportation ...

Ever since their discovery almost four decades ago, high-temperature superconductors have fascinated scientists and engineers alike. These materials, primarily cuprates, defy classical understanding ...

A moiré pattern appears when you stack and rotate two copies of an image with regularly repeating shapes, turning simple ...

Researchers have revealed new insights into rhombohedral stacking in graphene, reporting on how it behaves as a semiconductor ...

It bonds with its silicon neighbor atoms, but one electron is not involved in bonding. Instead, it is free to move inside the silicon structure. A solar cell consists of a layer of p-type silicon ...

The electron beam follows a vertical path through the microscope ... All non-metals need to be made conductive by covering the sample with a thin layer of conductive material. This is done by using a ...

Since electricity is the lifeblood of everything from computers to phones to microwaves, the electron turned out to be interesting to just about everybody.

This ultra-thin layer obstructs lithium ion and electron movement, increasing resistance and degrading battery performance. From electric vehicles to wireless earbuds, traditional lithium-ion ...

The results are worth it, though; stitched together, the electron micrographs show the chip formation process in amazing detail. The aluminum oxide layer on the top of the workpiece is clearly ...