Most magnets are predictable. Cool them down, and their tiny magnetic moments snap into ...

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

Physicists have discovered that hidden magnetic order plays a key role in the pseudogap, a puzzling state of matter that ...

Research in the lab of UC Santa Barbara materials professor Stephen Wilson is focused on understanding the fundamental ...

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

Quantum materials can behave in surprising ways when many tiny spins act together, producing effects that don’t exist in ...

When quantum spins interact, they can produce collective behaviors that defy long-standing expectations. Researchers have now shown that the Kondo effect behaves very differently depending on spin ...

Quantum mechanics has revealed that magnetic fields exert profound influences on microscopic systems, modulating quantum states and facilitating emergent phenomena with global technological potential.

UD researchers develop optical method to detect magnetic behavior of antiferromagnets, paving the way for advanced computing ...

Metasurface converts Gaussian beams to uniform light via polarization encoding, boosting NMR co-magnetometer sensitivity 23% for compact quantum sensors.

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

Quantum computers, systems that process information leveraging quantum mechanical effects, have the potential of outperforming classical systems on some tasks. Instead of storing information as bits, ...