Ultrawide-bandgap semiconductors—such as diamond—are promising for next-generation electronics due to a larger energy gap ...

A research team at POSTECH has developed a novel multidimensional sampling theory to overcome the limitations of flat optics. Their study not only identifies the constraints of conventional sampling ...

Researchers have built a deep-ultraviolet microscope to study hard-to-analyze materials like diamond, offering a new way to probe their electronic and thermal properties at the nanoscale. This ...

As part of the Q-NEXT quantum research center, Randall Goldsmith of the University of Wisconsin–Madison studies the interplay of light and matter, harnessing it for quantum information technologies.

Nanostructures are materials that have dimensions ... precise control over the material properties and structures at the nanoscale. One area of significant interest is the use of molecular ...

This is attributed to changes in lattice parameters, which become more pronounced at the nanoscale. Interestingly, while both nanoparticles and nanostructures exhibit this trend, the band gap ...

An interview on how advanced techniques can be used to enhance silk fibroin and chitosan for drug delivery applications.

Chiral topological textures in BaTiO3 nanoislands demonstrate potential for electrical manipulation, enhancing prospects for future information technologies.

Ferroelectrics at the nanoscale exhibit a wealth of polar and sometimes swirling (chiral) electromagnetic textures that not only represent fascinating physics, but also promise applications in future ...