<P> Semiconductors are defined by their unique electric conductive behavior, somewhere between that of a conductor and an insulator . The differences between these materials can be understood in terms of the quantum states for electrons, each of which may contain zero or one electron (by the Pauli exclusion principle). These states are associated with the electronic band structure of the material . Electrical conductivity arises due to the presence of electrons in states that are delocalized (extending through the material), however in order to transport electrons a state must be partially filled, containing an electron only part of the time . If the state is always occupied with an electron, then it is inert, blocking the passage of other electrons via that state . The energies of these quantum states are critical, since a state is partially filled only if its energy is near the Fermi level (see Fermi--Dirac statistics). </P> <P> High conductivity in a material comes from it having many partially filled states and much state delocalization . Metals are good electrical conductors and have many partially filled states with energies near their Fermi level . Insulators, by contrast, have few partially filled states, their Fermi levels sit within band gaps with few energy states to occupy . Importantly, an insulator can be made to conduct by increasing its temperature: heating provides energy to promote some electrons across the band gap, inducing partially filled states in both the band of states beneath the band gap (valence band) and the band of states above the band gap (conduction band). An (intrinsic) semiconductor has a band gap that is smaller than that of an insulator and at room temperature significant numbers of electrons can be excited to cross the band gap . </P> <P> A pure semiconductor, however, is not very useful, as it is neither a very good insulator nor a very good conductor . However, one important feature of semiconductors (and some insulators, known as semi-insulators) is that their conductivity can be increased and controlled by doping with impurities and gating with electric fields . Doping and gating move either the conduction or valence band much closer to the Fermi level, and greatly increase the number of partially filled states . </P> <P> Some wider - band gap semiconductor materials are sometimes referred to as semi-insulators . When undoped, these have electrical conductivity nearer to that of electrical insulators, however they can be doped (making them as useful as semiconductors). Semi-insulators find niche applications in micro-electronics, such as substrates for HEMT . An example of a common semi-insulator is gallium arsenide . Some materials, such as titanium dioxide, can even be used as insulating materials for some applications, while being treated as wide - gap semiconductors for other applications . </P>

A shell made of material of electrical conductivity