A long-standing mystery in materials science is beginning to unravel as researchers directly probe the hidden atomic complexity of relaxor ferroelectrics.

Strain engineering, which involves deliberately stretching or compressing a crystal lattice, is used to boost the speed of electron flow in a device. Even a fraction of percent change in lattice ...

MIT researchers uncover a hidden 3D atomic structure in relaxor ferroelectrics using electron ptychography, resolving a ...

Quantum melting observed: Scientists melted electron crystals in tantalum sulfide, revealing a process similar to solid melting but affecting only electronic properties. Potential tech impact: ...

Geological faults hold many secrets that may help us answer important questions about the nature of our planet and what ...

In 1982, materials scientist Dan Shechtman observed an unusual tenfold symmetry in an aluminum-manganese alloy, defying the ...

Scientists have pulled off a mind-bending quantum experiment that sounds almost impossible: they showed that tiny metal ...

Eighty years on, a fragment of fused desert sand is still upending materials science, researchers have now identified two ...

This article explores LIG’s SMAL lenses, including their design principles, manufacturing methods, and performance in ...

Optical super-resolution resolves 137 nm features, matching SEM performance and exceeding a standard 100x objective.

A new chip-making technique exploits a material's crystal structure to create nanoscale patterns at room temperature directly onto hard materials used in devices, including silica. The method could ...