Charge Carrier
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Charge Carrier

In physics, a charge carrier is a particle or quasiparticle that is free to move, carrying an electric charge, especially the particles that carry electric charges in electrical conductors.[1] Examples are electrons, ions and holes. The term is used most commonly in solid state physics.[2] In a conducting medium, an electric field can exert force on these free particles, causing a net motion of the particles through the medium; this is what constitutes an electric current.[3] In conducting media, particles serve to carry charge:

  • In many metals, the charge carriers are electrons. One or two of the valence electrons from each atom is able to move about freely within the crystal structure of the metal.[4] The free electrons are referred to as conduction electrons, and the cloud of free electrons is called a Fermi gas.[5][6] Many metals have electron and hole bands. In some, the majority carriers are holes.[]
  • In electrolytes, such as salt water, the charge carriers are ions,[6] which are atoms or molecules that have gained or lost electrons so they are electrically charged. Atoms that have gained electrons so they are negatively charged are called anions, atoms that have lost electrons so they are positively charged are called cations.[7] Cations and anions of the dissociated liquid also serve as charge carriers in melted ionic solids (see e.g. the Hall-Héroult process for an example of electrolysis of a melted ionic solid). Proton conductors are electrolytic conductors employing positive hydrogen ions as carriers.[8]
  • In a plasma, an electrically charged gas which is found in electric arcs through air, neon signs, and the sun and stars, the electrons and cations of ionized gas act as charge carriers.[9]
  • In a vacuum, free electrons can act as charge carriers. In the electronic component known as the vacuum tube (also called valve), the mobile electron cloud is generated by a heated metal cathode, by a process called thermionic emission.[10] When an electric field is applied strong enough to draw the electrons into a beam, this may be referred to as a cathode ray, and is the basis of the cathode ray tube display widely used in televisions and computer monitors until the 2000s.[11]
  • In semiconductors, which are the materials used to make electronic components like transistors and integrated circuits, two types of charge carrier are possible. In p-type semiconductors, "effective particles" known as electron holes with positive charge move through the crystal lattice, producing an electrical current. The "holes" are, in effect, electron vacancies in the valence-band electron population of the semiconductor and are treated as charge carriers because they are mobile, moving from atom site to atom site. In n-type semiconductors, electrons in the conduction band move through the crystal, resulting in an electrical current.

In some conductors, such as ionic solutions and plasmas, positive and negative charge carriers coexist, so in these cases an electric current consists of the two types of carrier moving in opposite directions. In other conductors, such as metals, there are only charge carriers of one polarity, so an electric current in them simply consists of charge carriers moving in one direction.

In semiconductors

There are two recognized types of charge carriers in semiconductors. One is electrons, which carry a negative electric charge. In addition, it is convenient to treat the traveling vacancies in the valence band electron population (holes) as a second type of charge carrier, which carry a positive charge equal in magnitude to that of an electron.[12]

Carrier generation and recombination

When an electron meets with a hole, they recombine and these free carriers effectively vanish.[13] The energy released can be either thermal, heating up the semiconductor (thermal recombination, one of the sources of waste heat in semiconductors), or released as photons (optical recombination, used in LEDs and semiconductor lasers).[14] The recombination means an electron which has been excited from the valence band to the conduction band falls back to the empty state in the valence band, known as the holes. The holes are the empty states created in the valence band when an electron gets excited after getting some energy to pass the energy gap.

Majority and minority carriers

The more abundant charge carriers are called majority carriers, which are primarily responsible for current transport in a piece of semiconductor. In n-type semiconductors they are electrons, while in p-type semiconductors they are holes. The less abundant charge carriers are called minority carriers; in n-type semiconductors they are holes, while in p-type semiconductors they are electrons.[15]

In an intrinsic semiconductor, which does not contain any impurity, the concentrations of both types of carriers are ideally equal. If an intrinsic semiconductor is doped with a donor impurity then the majority carriers are electrons. If the semiconductor is doped with an acceptor impurity then the majority carriers are holes.[16]

Minority carriers play an important role in bipolar transistors and solar cells.[17] Their role in field-effect transistors (FETs) is a bit more complex: for example, a MOSFET has p-type and n-type regions. The transistor action involves the majority carriers of the source and drain regions, but these carriers traverse the body of the opposite type, where they are minority carriers. However, the traversing carriers hugely outnumber their opposite type in the transfer region (in fact, the opposite type carriers are removed by an applied electric field that creates an inversion layer), so conventionally the source and drain designation for the carriers is adopted, and FETs are called "majority carrier" devices.[18]

Free carrier concentration

Free carrier concentration is the concentration of free carriers in a doped semiconductor. It is similar to the carrier concentration in a metal and for the purposes of calculating currents or drift velocities can be used in the same way. Free carriers are electrons (or holes) which have been introduced directly into the conduction band (or valence band) by doping and are not promoted thermally. For this reason electrons (holes) will not act as double carriers by leaving behind holes (electrons) in the other band. In other words, charge carriers are particles/electrons that are free to move (carry the charge).[19]

See also


  1. ^ Dharan, Gokul; Stenhouse, Kailyn; Donev, Jason (May 11, 2018). "Energy Education - Charge carrier". Retrieved 2021.
  2. ^ "Charge carrier". The Great Soviet Encyclopedia 3rd Edition. (1970-1979).
  3. ^ Nave, R. "Microscopic View of Electric Current". Retrieved 2021.
  4. ^ Nave, R. "Conductors and Insulators". Retrieved 2021.
  5. ^ Fitzpatrick, Richard (February 2, 2002). "Conduction electrons in a metal". Retrieved 2021.
  6. ^ a b "Conductors-Insulators-Semiconductors". Retrieved 2021.
  7. ^ Steward, Karen (August 15, 2019). "Cation vs Anion: Definition, Chart and the Periodic Table". Retrieved 2021.
  8. ^ Ramesh Suvvada (1996). "Lecture 12: Proton Conduction, Stoichiometry". University of Illinois at Urbana-Champaign. Retrieved 2021.
  9. ^ Sou?ek, Pavel (October 24, 2011). "Plasma conductivity and diffusion" (PDF). Retrieved 2021.
  10. ^ Alba, Michael (January 19, 2018). "Vaccum Tubes: The World Before Transistors". Retrieved 2020.
  11. ^ "Cathode Rays | Introduction to Chemistry". Retrieved 2021.
  12. ^ Nave, R. "Intrinsic Semiconductors". Retrieved 2021.
  13. ^ Van Zeghbroeck, B. (2011). "Carrier recombination and generation". Retrieved 2021.
  14. ^ del Alamo, Jesús (February 12, 2007). "Lecture 4 - Carrier generation and recombination" (PDF). MIT Open CoursWare, Massachusetts Institute of Technology. p. 3. Retrieved 2021.
  15. ^ "Majority and minority charge carriers". Retrieved 2021.
  16. ^ Nave, R. "Doped Semiconductors". Retrieved 2021.
  17. ^ Smith, J. S. "Lecture 21: BJTs" (PDF). Retrieved 2021.
  18. ^ Tulbure, Dan (February 22, 2007). "Back to the basics of power MOSFETs". EE Times. Retrieved 2021.
  19. ^ Van Zeghbroeck, B. (2011). "Carrier densities". Retrieved 2021.

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