MIT physicists have built a new microscope that can see quantum motion inside superconductors ...

With the terahertz scope, the team observed a frictionless “superfluid” of superconducting electrons that were collectively ...

Modern imaging is contributing significantly to giving us a better understanding of how our brains work. In the long term, this will also help us to treat learning disorders in a more targeted way and ...

The implications of the breakthrough could ripple through multiple industries. A better understanding of how superconductivity behaves at quantum scales could accelerate the development of ...

Constructed with an LCD digital display, multiple lenses and XY stage plate navigation, the Celestron PentaView feels professional, enables specimens to be viewed by a large audience and is an ...

The superconducting gap sets the basic energy scale that allows electricity to flow without resistance in a superconductor. In high‑temperature cuprates, the paired electrons (Cooper pairs) are mostly ...

Automated DIC imaging with the DM6 M microscope enhances six-inch wafer inspection, providing reproducible results and improved efficiency for defect analysis.

This might be the beginning of arterial calcifications. It is an elekron microscopy image of calcified material forming deposits. This is the first time it was possible to show a biological process ...

A new microscope is capable of live imaging of biological processes in such detail that moving protein complexes are visible. In Nijmegen, the world's first microscope has been installed that is ...