A subtle twist between atomically thin magnetic layers can generate unexpectedly large and complex spin structures.

At the smallest scales of matter, nature behaves in ways that feel almost counterintuitive. Individual particles follow ...

Researchers have identified unusual magnetism in twisted, two-dimensional chromium triiodide, revealing long-range spin ...

Precisely tuning the spacing between iron oxide nanoparticles optimizes their magnetic interactions to enhance MRI contrast, ...

Organic magnetic materials represent an exciting frontier where the versatility of organic chemistry converges with the phenomena of magnetism. These materials, characterised by π‐conjugated systems ...

Tiny highly uniform magnetic fields are known to pervade the universe, influencing various cosmological processes. To date, however, the physical mechanisms underpinning the generation of these fields ...

Researchers combined high magnetic fields with X-ray scattering to reveal the connection between superconducting vortices (black circles), charge density waves (red wiggles), and spin density waves ...

A non-reciprocal phase transition to a many-body, time-dependent phase is proposed to emerge in driven layered ferromagnets. (Nanowerk News) A theoretical framework predicts the emergence of ...

Magnetic fields thread through galaxies, stretch across cosmic voids, and shape the behavior of charged particles over millions of light-years. Yet their origin remains one of the most stubborn ...

In recent years, there’s been an added demand on connectors: the need to be non-magnetic. Technically, this means the ...

A theoretical framework predicts the emergence of non-reciprocal interactions that effectively violate Newton’s third law in solids using light, report researchers from Japan. They demonstrate that by ...