Valence and conduction bands

 ( Electronic Band Structures ) 

In solid-state physics, the valence band and conduction band are the bands closest to the Fermi level, and thus determine the electrical conductivity of the solid. In nonmetals, the valence electron band is the highest range of electron energy in which electrons are normally present at absolute zero temperature, while the conduction band is the lowest range of vacant . On a graph of the electronic band structure of a semiconducting material, the valence band is located below the Fermi level, while the conduction band is located above it.

The distinction between the valence and conduction bands is meaningless in metals, because conduction occurs in one or more partially filled bands that take on the properties of both the valence and conduction bands.

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Band gap In semiconductors and insulators the two bands are separated by a band gap, while in conductors the bands overlap. A band gap is an energy range in a solid where no electron states can exist due to the quantization of energy. Within the concept of bands, the energy gap between the valence band and the conduction band is the band gap.

P. A. Cox (1987). 9780198552048, Oxford University Press. ISBN 9780198552048

Electrical conductivity of non-metals is determined by the susceptibility of electrons to be excited from the valence band to the conduction band.

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Electrical conductivity

In solids, the ability of electrons to act as depends on the availability of vacant electronic states. This allows the electrons to increase their energy (i.e., accelerate) when an electric field is applied. Similarly, holes (empty states) in the almost filled valence band also allow for conductivity.

As such, the electrical conductivity of a solid depends on its capability to flow electrons from the valence to the conduction band. Hence, in the case of a semimetal with an overlap region, the electrical conductivity is high. If there is a small band gap (E_g), then the flow of electrons from valence to conduction band is possible only if an external energy (thermal, etc.) is supplied; these groups with small E_g are called semiconductors. If the E_g is sufficiently high, then the flow of electrons from valence to conduction band becomes negligible under normal conditions; these groups are called insulators.

There is some conductivity in semiconductors, however. This is due to thermal excitation—some of the electrons get enough energy to jump the band gap in one go. Once they are in the conduction band, they can conduct electricity, as can the electron hole they left behind in the valence band. The hole is an empty state that allows electrons in the valence band some degree of freedom.

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Band edge shifts of semiconductor nanoparticles The edge shifting of size-dependent conduction and/or valence band is a phenomenon being studied in the field of quantum dot. The radius limit of occurrence of the semiconductor nanocrystal is the effective Bohr radius of the nanocrystal. The conduction and/or valence band edges shift to higher energy levels under this radius limit due to discrete optical transitions when semiconductor nanocrystal is restricted by the exciton. As a result of this edge shifting, the size of the conduction and/or valence band is decreased. This size-dependent edge shifting of conduction and/or valence band can provide plenty of useful information regarding the size or concentration of the semiconductor nanoparticles or band structures.

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See also

• Electrical conduction for more information about conduction in solids, and another description of band structure.
• Fermi liquid
• HOMO/LUMO
• Semiconductor for a full explanation of the band structure of materials.
• Valleytronics

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Citations

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General references

• Charles Kittel (2025). 047141526X, Wiley. 047141526X

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External links

• Direct Band Gap Energy Calculator

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