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 ...

By squeezing terahertz light beyond its usual limits, researchers have exposed hidden quantum "jiggles" inside a ...

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 ...

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 ...

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 ...

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