Additionally, nanostructuring—altering the material's structure at the nanoscale—has emerged as a powerful method to engineer band gaps. Despite its potential, Band Gap Engineering faces challenges, ...

As new technologies and artificial intelligence advance, the demand for efficient and high-performance semiconductors is ...

The corresponding energy gap in the band structure makes the material an insulator because it will not conduct electricity at absolute zero, although some insulators can carry a current at room ...

a number of new wide-band-gap semiconductor donor materials have been developed, yielding higher efficiencies than traditional systems that were paired with fullerene derivatives,” the ...

This comprehensive, applications-oriented survey of Electromagnetic Band Gap (EBG) engineering explains the theory, analysis, and design of EBG structures. It helps you to understand EBG applications ...

Researchers at the University of Minnesota have achieved a new material that will be pivotal in making the next generation of high-power electronics faster.

Semiconductors power nearly all electronics, from smartphones to medical devices. A key to advancing these technologies lies in improving what scientists refer to as "ultra-wide band gap" materials.