The Big Bang made matter and antimatter in equal measure, so where did all the antimatter go? This cosmic imbalance may hold ...

A team of researchers at the Hebrew University of Jerusalem has developed a novel technique that utilizes light to detect minute magnetic signals in everyday metals such as copper, gold, and aluminum.

A new method for combining magnetic elements with semiconductors—which are vital materials for computers and other electronic ...

Heavy fermion materials are heavy because their electrons are entangled and slowed down by magnetic ions. These interactions ...

Researchers at the University of Minnesota Twin Cities have made a promising breakthrough in memory technology by using a nickel-tungsten alloy called Ni₄W. This material shows powerful magnetic ...

Scientists have cracked a century-old physics mystery by detecting magnetic signals in non-magnetic metals using only light and a revamped laser technique. Previously undetectable, these faint ...

Researchers in Japan have accelerated muons into the most precise, high-intensity beam to date, reaching energies high as 100 ...

Researchers have found the first new type of magnet in nearly a century. Now, these strange "altermagnets" could help us ...

Achieving accurate transfer maps for realistic beamline elements hinges on obtaining precise 3-D magnetic field data for both straight and curved beamlines. Among various numerical methods for ...

Researchers have discovered why atacamite, a rare mineral found in Chile, spontaneously cools down when exposed to a magnetic ...

The standard way of calculating the electron's magnetic moment using the Dirac equation leads to a value known as the Bohr magneton, named after the Danish physicist Niels Bohr. Unfortunately, this ...

Quantum mechanics has a reputation that precedes it. Virtually everyone who has bumped up against the quantum realm, whether in a physics class, in the lab, or in popular science writing, is left ...