Real-time microscopy and AI reveal how atomic wetting controls tin oxide nanowire growth inside carbon nanotubes, uncovering ...

Another massive shift compared to most quantum computing technology is that light cage memory operates slightly above room temperature and does not require cryogenic cooling. This makes it not only ...

Known as “islands of inversion,” these regions are found among a sea of normal nuclei. Now, a new island may have been ...

Near absolute zero, atoms stop acting like particles and start behaving like waves. In this ultracold world, scientists can ...

At extreme pressures and temperatures, water becomes superionic — a solid that behaves partly like a liquid and conducts ...

An international research team led by scientists from the University of Rostock, CNRS-École polytechnique in France, and ...

Recent research published in Science introduces a promising solid electrolyte material that could improve the performance of ...

Quantum entanglement has shifted from a philosophical puzzle to a design brief for engineers working at the scale of atoms, ...

Tiny 3D-printed “light cages” are giving researchers a new way to catch and hold individual particles of light on a chip, a ...

A multi-disciplinary team of researchers linked atomic-scale features to efficient heat-to-electricity conversion, offering ...

Most of today's quantum computers rely on qubits with Josephson junctions that work for now but likely won't scale as needed ...

A new chip-based quantum memory uses 3D-printed “light cages” to store light in atomic vapor with high precision. Quantum ...