Researchers have discovered a hidden quantum geometry inside materials that subtly steers electrons, echoing how gravity ...

In some solid materials under specific conditions, mutual Coulomb interactions shape electrons into many-body correlated ...

Researchers from Regensburg and Birmingham have overcome a fundamental limitation of optical microscopy. With the help of ...

A stable graphene signal suggests some quantum particles can remember past interactions, a key step toward quantum computing.

The Einstein–de Haas effect, which links the spin of electrons to macroscopic rotation, has now been demonstrated in a ...

Physicists have long relied on the idea that electrons behave like tiny particles zipping through materials, even though quantum physics says their exact position is fundamentally uncertain. Now, ...

Electrons are usually described as particles, but in a rare quantum material, that picture completely breaks down ...

One intriguing method that could be used to form the qubits needed for quantum computers involves electrons hovering above liquid helium. But it wasn't clear how data in this form could be read easily ...

The photoelectric effect, first explained in 1905, transformed our understanding of how light interacts with matter. When high-energy light hits atoms, it knocks electrons loose. This process powers ...

A material cooled near absolute zero produced an electrical signal that physics said should not exist, revealing a new kind ...

Long before quantum mechanics existed, a scientist developed a powerful way of describing motion by drawing an analogy between particles and light.