Suppression of intervalley scattering observed in the QPI pattern. Credit: Nature Physics (2025). DOI: 10.1038/s41567-025-02864-2 Altermagnets, which exhibit momentum-dependent spin splitting without ...

Magnons are tiny waves in magnetization that travel through solid magnetic materials, much like the ripples that spread ...

Consequently, this energy transfer causes the rearrangement into a magnetic structure, which is stabilized by the subsequent rapid cooling. In follow-up experiments, the researchers aim to observe ...

Magnetic domains can take on a wide range of structures. In certain soft magnetic materials, they form complex zig-zag patterns known as maze domains. These patterns change in complicated ways as ...

The reliability of data storage and writing speed in advanced magnetic devices depend on drastic, complex changes in microscopic magnetic domain structures. However, it is extremely challenging to ...

Scientists have determined the laser intensity threshold that causes expanding fusion plasmas to quickly generate strong magnetic fields. Detailed simulations tracked how these fields form within a ...

Researchers developed 3D printed, muscle-inspired magnetic actuators that push, pull, crawl, and grasp. The research paper describes a family of soft actuators that convert applied magnetic fields ...

New nitride materials could let electricity control hidden magnetic spin patterns, pointing toward faster and more stable ...

Researchers have identified the mechanism by which high-powered lasers can cause rapidly expanding plasmas to self-generate strong magnetic fields within a billionth of a second. The simulations show ...

Altermagnets, which exhibit momentum-dependent spin splitting without spin–orbit coupling (SOC) or net magnetization, have recently attracted significant international attention. A team led by Prof.