Semiconductor: Difference between revisions

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A semiconductor is a material with an electrical conductivity that is intermediate between that of an insulator and a conductor. A semiconductor behaves as an insulator at very low temperature, and has an appreciable electrical conductivity at room temperature although much lower conductivity than a conductor. Commonly used semiconducting materials are silicon, germanium, gallium arsenide and indium phosphide.

A semiconductor can be distinguished from a conductor by the fact that, at absolute zero, the uppermost filled electron energy band is fully filled in a semiconductor, but only partially filled in a conductor.

The distinction between a semiconductor and an insulator is slightly more arbitrary. A semiconductor has a band gap which is small enough such that its conduction band is appreciably thermally populated with electrons at room temperature, whilst an insulator has a band gap which is too wide for there to be appreciable thermal electrons in its conduction band at room temperature.

In the parlance of solid-state physics, semiconductors (and insulators) are defined as solids in which at absolute zero (0 K), the uppermost band of occupied electron energy states, known as the valence band, is completely full. Under absolute zero conditions, the Fermi energy, or Fermi level can be thought of as the energy up to which available electron states are occupied.

At room temperatures, there is some smearing of the energy distribution of the electrons, such that a small, but not insignificant number have enough energy to cross the energy band gap into the conduction band. These electrons which have enough energy to be in the conduction band have broken free of the covalent bonds between neighbouring atoms in the solid, and are free to move around, and hence conduct charge. The covalent bonds from which these excited electrons have come now have missing electrons, or holes which are free to move around as well. (The holes themselves don't actually move, but a neighbouring electron can move to fill the hole, leaving a hole at the place it has just come from, and in this way the holes appear to move.)

It is an important distinction between conductors and semiconductors that, in semiconductors, movement of charge (current) is facilitated by both electrons and holes. Contrast this to a conductor where the Fermi level lies within the conduction band, such that the band is only half filled with electrons. In this case, only a small amount of energy is needed for the electrons to find other unoccupied states to move into, and hence for current to flow.

The ease with which electrons in a semiconductor can be excited from the valence band to the conduction band depends on the band gap between the bands, and it is the size of this energy bandgap that serves as an arbitrary dividing line between semiconductors and insulators. Materials with a bandgap energy of less than about 3 electronvolts (eV) are generally considered semiconductors, while those with a greater bandgap energy are considered insulators..

The current-carrying electrons in the conduction band are known as "free electrons", although they are often simply called "electrons" if context allows this usage to be clear. The holes in the valence band behave very much like positively-charged counterparts of electrons, and they are usually treated as if they are real charged particles.

When ionizing radiation strikes a semiconductor, it will often excite an electron out of its energy level and consequently leave a hole. This process is known as the creation of an electron-hole pair. A useful concept is the exciton which describes the electron and hole being bound together into a quasiparticle. The details of the specific processes through which electron-hole pairs are created are not well known, however, it is known that the average energy needed to create an electron-hole pair at a given temperature is independent of the type and the energy of the ionizing radiation. In silicon, this energy is equal to 3.62 eV at room temperature and 3.72 eV at 80 K.

One of the main reasons that semiconductors are useful in electronics is that their electronic properties can be greatly altered in a controllable way by adding small amounts of impurities. These impurities are called dopants.

Heavily doping a semiconductor can increase its conductivity by a factor greater than a billion. In modern integrated circuits, for instance, heavily-doped polycrystalline silicon is often used as a replacement for metals.

An intrinsic semiconductor is a semiconductor which is pure enough that the impurities in it do not appreciably affect its electrical behavior. In this case, all carriers are created by thermally or optically excited electrons from the full valence band into the empty conduction band. Thus equal numbers of electrons and holes are present in an intrinsic semiconductor. Electrons and holes flow in opposite directions in an electric field, though they contribute to current in the same direction since they are oppositely charged. Hole current and electron current are not necessarily equal in an intrinsic semiconductor, however, because electrons and holes have different effective masses (crystalline analogues to free inertial masses).

The concentration of carriers in an intrinsic semiconductor is strongly dependent on the temperature. At low temperatures, the valence band is completely full, making the material an insulator (see electrical conduction for more information). Increasing the temperature leads to an increase in the number of carriers and a corresponding increase in conductivity. This principle is used in thermistors. This behavior contrasts sharply with that of most metals, which tend to become less conductive at higher temperatures due to increased phonon scattering.

An extrinsic semiconductor is a semiconductor that has been doped with impurities to modify the number and type of free charge carriers present.

A semiconductor which is doped to such high levels that the dopant atoms are an appreciable fraction of the semiconductor atoms is called degenerate. A degenerate semiconductor acts more like a conductor than a semiconductor.

The purpose of n-type doping is to produce an abundance of mobile or "carrier" electrons in the material. To help understand how n-type doping is accomplished, consider the case of silicon (Si). Si atoms have four valence electrons, each of which is covalently bonded with one of four adjacent Si atoms. If an atom with five valence electrons, such as those from group 15 (a.k.a. group V) of the periodic table (e.g. phosphorus (P), arsenic (As), or antimony (Sb)), is incorporated into the crystal lattice in place of a Si atom, then that atom will have four covalent bonds and one unbonded electron. This extra electron is only weakly bound to the atom and can easily be excited into the conduction band. At room temperatures, virtually all such electrons are excited into the conduction band. Since excitation of these weakly bound electrons does not result in the formation of a hole, the number of electrons in such a material far exceeds the number of thermally generated holes. In this case the electrons are the majority carriers and the holes are the minority carriers. Because the five-electron atoms have an extra electron to "donate", they are called donor atoms. Note that each movable electron within the semiconductor is never far from an immobile positive dopant ion, and the n-doped material normally has a net electric charge of zero.

The purpose of p-type doping is to create an abundance of holes. In the case of silicon, a trivalent atom (such as boron) is substituted into the crystal lattice. The result is that one electron is missing from one of the four covalent bonds normal for the silicon lattice. Thus the dopant atom can accept an electron from a neighboring atoms' covalent bond to complete the fourth bond. Such dopants are called acceptors. The dopant atom accepts an electron, causing the loss of one bond from the neighboring atom and resulting in the formation of a "hole". Each hole is associated with a nearby negative-charged dopant ion, and the semiconductor remains electrically neutral as a whole. However, once each hole has wandered away into the lattice, one proton in the atom at the hole's location will be "exposed" and no longer cancelled by an electron. For this reason a hole behaves as a quantity of positive charge. When a sufficiently large number of acceptor atoms are added, the holes greatly outnumber the thermally-excited electrons. Thus, the holes are the majority carriers, while electrons are the minority carriers in P-type materials. Blue diamonds (Type IIb), which contain boron (B) impurities, are an example of a naturally occurring P-type semiconductor.

When a semiconductor is doped, its majority carrier concentration exceeds the intrinsic carrier concentration by a factor that is dependent on the doping level. However, the product of the majority and minority carrier concentrations continues to be equal to the square of the intrinsic carrier concentration. For example, consider an intrinsic semiconductor at a temperature such that the carrier concentrations of holes and electrons are each 10¹³/cm³. If this semiconductior is n-doped to 10¹⁶/cm³, then the hole concentration will be 10¹⁰/cm³. It also follows from this that minority carrier concentrations in doped semiconductors are dependent on temperature to the square of the extent that carrier concentrations in intrinsic semiconductors are, since the majority carrier concentration is effectively fixed at the doping level.

A p-n junction may be created by doping adjacent regions of a semiconductor with p-type and n-type dopants. If a positive bias voltage is placed on the p-type side, the dominant positive carriers (holes) are pushed toward the junction. At the same time, the dominant negative carriers (electrons) in the n-type material are attracted toward the junction. Since there is an abundance of carriers at the junction, the junction behaves as a conductor, and the voltage placed across the junction produces a current. As the clouds of holes and electrons are forced to overlap, electrons fall into holes and become part of the population of immobile covalent bonds. However, if the bias polarity is reversed, the holes and electrons are pulled away from the junction. Since only very few new electron/hole pairs are created at the junction, the existing mobile carriers are swept away to leave a depletion zone; a region of relatively non-conducting silicon. The reverse bias voltage will produce only a very low current across the junction. The p-n junction is the basis of an electronic device called a diode, which allows electric charges to flow in only one direction. Similarly, a third semiconductor region can be doped n-type or p-type to form a three-terminal device, such as the bipolar junction transistor (which can be either p-n-p or n-p-n).

When an electron-hole pair is created in the depletion region by ionizing radiation the two liberated charged particles will be swept out of the area. After the electron-hole pair is created in the depletion region, the hole will be swept towards the p-type region by the electric field, and the electron will be swept towards the n-type region by the electric field. The movement of these charge carriers constitutes a small electrical current which can be measured and analyzed.

Semiconductors with predictable, reliable electronic properties are necessary for mass production. The level of chemical purity needed is extremely high because the presence of impurities even in very small proportions can have large effects on the properties of the material. A high degree of crystalline perfection is also required, since faults in crystal structure (such as dislocations, twins, and stacking faults) interfere with the semiconducting properties of the material. Crystalline faults are a major cause of defective semiconductor devices. The larger the crystal, the more difficult it is to achieve the necessary perfection. Current mass production processes use crystal ingots between four and twelve inches (300 mm) in diameter which are grown as cylinders and sliced into wafers.

Because of the required level of chemical purity, and the perfection of the crystal structure which are needed to make semiconductor devices, special methods have been developed to produce the initial semiconductor material. A technique for achieving high purity includes growing the crystal using the Czochralski process. An additional step that can be used to further increase purity is known as zone refining. In zone refining, part of a solid crystal is melted. The impurities tend to concentrate in the melted region, while the desired material recrystalizes leaving the solid material more pure and with fewer crystalline faults.

Template:BacklinkElectronics

• Semiconductor device fabrication
• Semiconductor devices
  • Transistors
  • Diodes
  • Microprocessors
  • Thermistors
  • Solar cells
  • Piezoresistors
• Semiconductor materials
• Wide bandgap semiconductors
• Spintronics

• Solid state physics
• Solid state chemistry
• Electrical engineering
• Carrier generation and recombination
• Conduction band
• Effective mass
• Electron hole
• Electron-hole pair
• Exciton
• Quantum tunneling
• Valence band

• Yu, Peter Y.; Cardona, Manuel (2004). Fundamentals of Semiconductors : Physics and Materials Properties. Springer. ISBN 3540413235.{{cite book}}: CS1 maint: multiple names: authors list (link)
• Sze, Simon M. (1981). Physics of Semiconductor Devices (2nd ed.). John Wiley and Sons (WIE). ISBN 0471056618.
• Turley, Jim (2002). The Essential Guide to Semiconductors. Prentice Hall PTR. ISBN 013046404X.

• Howstuffworks' semiconductor page
• US Navy Electrical Engineering Training Series
• NSM-Archive Physical Properties of Semiconductors
• Semiconductor Concepts at Hyperphysics
• Principles of Semiconductor Devices by Bart Van Zeghbroeck, University of Colorado
• Semiconductor OneSource Hall of Fame, Glossary