Semiconductors are at the heart of most electronics, but have you ever wondered how one works? In this article, we explain what semiconductors are; how they work, with an eye to N-type vs. P-type ...

As few as five electrons in a semiconductor can exhibit collective behaviour, forming a “Coulomb liquid”, according to researchers in Europe. This extends the study of correlated systems to electron ...

In conductors, the valence band (which holds electrons) and the conduction band (where electrons move freely) overlap, enabling easy electron flow. Insulators, by contrast, have a large band gap ...

This electron requires minimal energy to be excited into the semiconductor’s conduction band. Increased Conductivity: With the introduction of donor atoms, ...

In semiconductors, however, the gap between the valence band and conduction band is very small. In our highway analogy, this gap might be analogous to a narrow strip of pavement that cars can easily ...

A quantum dot is a semiconductor nanostructure that confines the motion of conduction band electrons, valence band holes, or excitons (bound pairs of conduction band electrons and valence band ...

The energy gap separating the valence and conduction bands is referred to as the bandgap. Pure materials like silicon or germanium are considered intrinsic semiconductors, which possess a valence band ...

Definition: Band Gap Engineering is a process used in semiconductor material science to tailor the energy gap between the valence and conduction bands.This manipulation affects how electrons and holes ...

A condition long considered to be unfavorable to electrical conduction in semiconductor materials may actually be beneficial ...

Research indicates that electron-phonon interactions in atomically thin semiconductors enhance conductivity, paving the way ...