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In solid state physics and related applied fields, a band gap, also called an energy gap or bandgap, is an energy range in a solid where no electron states exist. For insulators and semiconductors, the band gap generally refers to the energy difference (in electron volts) between the top of the valence band and the bottom of the conduction band; it is the amount of energy required to free an outer shell electron from its orbit about the nucleus to a free state.

1 In semiconductor physics
2 In photonics and phononics
- 2.1 Materials
- 2.2 List of electronics topics
3 See also
4 References
5 External links

In semiconductor physics

Semiconductor band structure.

A material with a small, but not null or negative, band gap (arbitrarily defined as < 3 eV, although some definitions place the upper limit at 4 eV) is referred to as a semiconductor^[1]. A material with a large band gap is called an insulator.

In semiconductors and insulators, electrons are confined to a number of bands of energy, and forbidden from other regions. The term "band gap" refers to the energy difference between the top of the valence band and the bottom of the conduction band; electrons are able to jump from one band to another. In order for an electron to jump from a valence band to a conduction band, it requires a specific amount of energy for the transition. The required energy differs with different materials. Electrons can gain enough energy to jump to the conduction band by absorbing either a phonon (heat) or a photon (light).

The conductivity of intrinsic semiconductors is strongly dependent on the band gap. The only available carriers for conduction are the electrons which have enough thermal energy to be excited across the band gap.

Band gap engineering is the process of controlling or altering the band gap of a material by controlling the composition of certain semiconductor alloys, such as GaAlAs, InGaAs, and InAlAs. It is also possible to construct layered materials with alternating compositions by techniques like molecular beam epitaxy. These methods are exploited in the design of heterojunction bipolar transistors (HBTs), laser diodes and solar cells.

The distinction between semiconductors and insulators is a matter of convention. One approach is to think of semiconductors as a type of insulator with a low band gap. Insulators with a higher band gap, usually greater than 3 eV, are not considered semiconductors and generally do not exhibit semiconductive behaviour under practical conditions. Electron mobility also plays a role in determining a material's informal classification.

The band gap energy of semiconductors tends to decrease with increasing temperature. When temperature increases, the amplitude of atomic vibrations increase, leading to larger interatomic spacing. The interaction between the lattice phonons and the free electrons and holes will also affect the bandgap to a smaller extent^[2]. The relationship between bandgap energy and temperature can be described by Varshni's empirical expression,

In a regular semiconductor crystal, the bandgap is fixed owing to continuous energy states. In a quantum dot crystal, the bandgap is size dependent and can be altered to produce a range of energies between the valence band and conduction band.^[3] It is also known as quantum confinement effect.

$E_g(T)=E_g(0)-\frac{\alpha T^2}{T+\beta}$ , where $E g (0),-$ and $-$ are material constants.^[4]

Band gaps also depend on pressure. Band gaps can be either direct or indirect bandgaps, depending on the band structure.

Mathematical interpretation

Classically, the ratio of probabilities that two states with an energy difference -E will be occupied by an electron is given by the Boltzmann factor:

$e^{\left(\frac{-\Delta E}{kT}\right)}$

where:

$\, e$ is the exponential function

$\, \Delta E$ is the energy difference

$\, k$ is Boltzmann's constant

$\, T$ is temperature

At the Fermi level (or chemical potential), the probability of a state being occupied is ½. If the Fermi level is in the middle of a band gap of 1 eV, this ratio is e ^-20 or about 2.0-10^-9 at the room-temperature thermal energy of 25.9 meV.

Photovoltaic cells

The bandgap determines what portion of the solar spectrum a photovoltaic cell absorbs.^[5] A luminescent solar converter uses a luminescent medium to downconvert photons with energies above the bandgap to photon energies closer to the bandgap of the semiconductor comprising the solar cell^[6].

List of band gaps

Material	Symbol	Band gap (eV) @ 300K	Reference
Silicon	Si	1.11	^[7]
Germanium	Ge	0.67	^[7]
Silicon carbide	SiC	2.86	^[7]
Aluminum phosphide	AlP	2.45	^[7]
Aluminium arsenide	AlAs	2.16	^[7]
Aluminium antimonide	AlSb	1.6	^[7]
Aluminium nitride	AlN	6.3
Diamond	C	5.5
Gallium(III) phosphide	GaP	2.26	^[7]
Gallium(III) arsenide	GaAs	1.43	^[7]
Gallium(III) nitride	GaN	3.4	^[7]
Gallium(II) sulfide	GaS	2.5 (@ 295 K)
Gallium antimonide	GaSb	0.7	^[7]
Indium(III) phosphide	InP	1.35	^[7]
Indium(III) arsenide	InAs	0.36	^[7]
Zinc oxide	ZnO	3.37
Zinc sulfide	ZnS	3.6	^[7]
Zinc selenide	ZnSe	2.7	^[7]
Zinc telluride	ZnTe	2.25	^[7]
Cadmium sulfide	CdS	2.42	^[7]
Cadmium selenide	CdSe	1.73	^[7]
Cadmium telluride	CdTe	1.49	^[8]
Lead(II) sulfide	PbS	0.37	^[7]
Lead(II) selenide	PbSe	0.27	^[7]
Lead(II) telluride	PbTe	0.29	^[7]

In photonics and phononics

In photonics band gaps or stop bands are ranges of photon frequencies where, if tunneling effects are neglected, no photons can be transmitted through a material. A material exhibiting this behaviour is known as a photonic crystal.

Similar physics applies to phonons in a phononic crystal.

Materials

List of electronics topics

References

^ http://www.chem.ufl.edu/~reynolds/member_resources/images/Barry%20Thompson%202005.pdf
^ Hilmi, Unlu. A Thermodynamic Model for Determining Pressure and Temperature Effects on the Bandgap Energies and other Properties of some Semiconductors. Solid State Electronics, Vol 35:9, 1343-1352. Pergamon Press Ltd, 1992.
^ -Evident Technologies-
^ http://ece-www.colorado.edu/~bart/book/eband5.htm
^ http://www.nrel.gov/csc/proj_nanoscale_material.html
^ http://socrates.berkeley.edu/~kammen/C226/Berkeley-C226-EnergyConversionFilms.pdf
^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r ^s ^t Streetman, Ben G.; Sanjay Banerjee (2000). Solid State electronic Devices (5th edition ed.). New Jersey: Prentice Hall. pp. 524. ISBN 0-13-025538-6.
^ Madelung, Otfried (1996). Semiconductors - Basic Data (2nd rev. ed. ed.). Berlin Heidelberg New York: Springer-Verlag. ISBN 3-540-60883-4.

External links

Direct Band Gap Energy Calculator

Retrieved from "http://en.wikipedia.org/wiki/Band_gap"

Categories: Condensed matter physics | Semiconductors

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