From galaxies to the Sun, new research explains how turbulent motion can produce large-scale magnetic fields that remain ...

Scientists suggest superionic “hot black ice” deep inside Neptune may explain its tilted, offset and chaotic magnetic field, ...

Physicists have watched a quantum fluid do something once thought almost impossible: stop moving. In experiments with ...

A strange, glowing form of matter called dusty plasma turns out to be incredibly sensitive to magnetic fields. Researchers found that even weak fields can change how tiny particles grow, simply by ...

Data from the Relativistic Heavy Ion Collider (RHIC) has revealed that particles retain spin signatures from the quantum ...

Scientists have demonstrated that light alone can reversibly control magnetism in a topological material. Researchers at the ...

All celestial bodies—planets, suns, even entire galaxies—produce magnetic fields, affecting such cosmic processes as the solar wind, high-energy particle transport, and galaxy formation. Small-scale ...

For decades, mysterious magnetic signals in superconductors were attributed to exotic forms of superconductivity. New work ...

Quantum computers, systems that process information leveraging quantum mechanical effects, could reliably tackle various ...

Physicists uncover hidden magnetic order in the pseudogap, showing how electron behavior stays organized before ...

"A strong magnetic field is very important for life on a planet." ...