Imagine computer hardware that is blazing fast and stores more data in less space. That's the promise of antiferromagnets, ...

A research team at Fudan University in Shanghai has achieved a breakthrough in the study of a class of magnetic materials ...

A laser trick in nanometer-thin magnets hints at faster storage and computing without exotic laboratory conditions ...

UD researchers develop optical method to detect magnetic behavior of antiferromagnets, paving the way for advanced computing and quantum technologies ...

Scientists from the RIKEN Center for Emergent Matter Science and colleagues have developed a new way to fabricate three-dimensional nanoscale devices from single-crystal materials using a focused ion ...

A research team at Fudan University in Shanghai has achieved a breakthrough in the study of a class of magnetic materials that could help pave the way for faster and more energy-efficient computer ...

The key to future technologies can sometimes be found in the past. What Ravi Kishore is working to perfect, for example, has ...

Scientists have shown that twisting a crystal at the nanoscale can turn it into a tiny, reversible diode, hinting at a new era of shape-engineered electronics.

Scientists from the RIKEN Center for Emergent Matter Science and colleagues have developed a new way to fabricate three-dimensional nanoscale devices ...

Georgetown University researchers have discovered a new class of strong magnets that do not rely on rare-earth or precious metals—a breakthrough that could significantly advance clean energy ...

An international group of researchers has found that chiral phonons can create orbital current without needing magnetic elements – in part because chiral phonons have their own magnetic moments.

By shining a focused laser beam onto a sample of material, a team at the Paul Scherrer Institute (PSI) and ETH Zürich showed ...