Tiny magnetic "flowers" engineered by physicist Anna Palau are redefining how we manipulate magnetic fields. These ...

Pioneering new research could help unlock exciting new potential to create ultrafast, laser-driven storage ...

The new phase comes in the form of a pattern of electron spins—half of which are highly ordered, or "cold", and the rest of ...

With a new measurement imminent, the Courier explores the experimental results and theoretical calculations used to predict ...

A flower-shaped structure only a few micrometers in size made of a nickel-iron alloy can concentrate and locally enhance ...

Brookhaven National Laboratory have discovered a new phase of matter while studying a model system of a magnetic material.

A flower-shaped structure only a few micrometres in size made of a nickel-iron alloy can concentrate and locally enhance magnetic fields. The size of the effect can be controlled by varying the ...

The g factor of boron-like tin ions is determined with an uncertainty of only 0.5 parts per billion. The second ...

In an ultra-cold, high-magnetic-field setting, ZrTe5 defies expectations by showing quantum heat oscillations. Researchers ...

In theory, as Earth spins through its magnetic field, any conductive material placed on its surface should experience a force ...

Topological materials are revolutionizing semiconductor manufacturing, offering enhanced conductivity and efficiency for next ...

The ability to conduct heat is one of the most fundamental properties of matter, crucial for engineering applications. Scientists know well how conventional materials, such as metals and insulators, ...