Different model explaining semiconductor

In summary, the explanation for why doped semiconductors conduct is that the dopant atoms, such as As, have loosely bound valence electrons that can be delocalized with thermal energy. This delocalization allows for the formation of a conductive band, as described by the band diagram in physics. Both the chemistry and physics explanations are describing the same situation, with varying levels of detail.
  • #1
tomz
35
0
Hi everyone, I have a question here on what cause doped semiconductors to conduct. (such as Silicon with some As present, this is one atomic number higher)

On my chemistry book, it says As covalently bond with 4 Si atoms as Si does, so the lattice is preserved, and 1 of its valence electron is free (as it have 1 more electron in outer shell), and therefore the material is conductive.

On my physics book, it says the reason is that As atom provide a energy level that is very close to the conductive band of Si lattice, and the original energy difference between conductive and valence band of Si is much larger. So the material is now conductive (thermal energy supplied, electron transit)

My question is, which explanation is correct? Or is it coincident that every doped element provide energy level that close the the existing band so a jump is possible? (because not just As, a lot of element will cause increase conductivity of semiconductor)

thanks
 
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  • #2
They are the same explanation.

When you doped with the As atom, one of its valence electron is rather loosely bound to the atom. The thermal energy is sufficient to delocalize that electron.

And if you translate that situation in terms of the band diagram, that is what you get from your physics text. They are both describing the same, identical situation, to varying degree of exactness. The band diagram, if one can drive it, is the more exact description.

Zz.
 
  • #3
ZapperZ said:
They are the same explanation.

When you doped with the As atom, one of its valence electron is rather loosely bound to the atom. The thermal energy is sufficient to delocalize that electron.

And if you translate that situation in terms of the band diagram, that is what you get from your physics text. They are both describing the same, identical situation, to varying degree of exactness. The band diagram, if one can drive it, is the more exact description.

Zz.

Thank you!
 

1. What is a semiconductor?

A semiconductor is a material that has electrical conductivity between that of a conductor and an insulator. This means that it can conduct electricity to a certain extent, but not as well as a conductor like copper or gold.

2. How do semiconductors work?

Semiconductors work by controlling the flow of electrons through the material. They have a band gap, which is an energy gap between the highest energy level where electrons can move freely (the conduction band) and the lowest energy level where electrons are bound to atoms (the valence band). By adding impurities or applying electric fields, the number of electrons in the conduction band can be controlled, allowing for the manipulation of electric current.

3. What is the difference between the p-type and n-type semiconductor?

A p-type semiconductor has impurities added that create an excess of holes (positively charged carriers) in the material, making it more conductive. An n-type semiconductor has impurities added that create an excess of electrons (negatively charged carriers), also making it more conductive. This difference in charge carriers allows for the creation of diodes and transistors, essential components in electronic devices.

4. What are the main models used to explain semiconductors?

There are two main models used to explain semiconductors: the classical band theory and the quantum mechanical theory. The classical band theory describes semiconductors as a mix of conductors and insulators, with a band gap that determines their conductivity. The quantum mechanical theory, on the other hand, takes into account the behavior of individual electrons and their energy levels, providing a more detailed and accurate explanation of semiconductor behavior.

5. How are semiconductors used in technology?

Semiconductors are used in a wide range of technologies, including computers, smartphones, solar cells, LED lights, and more. They are essential for creating electronic devices that require control over the movement of electric current. They also play a crucial role in renewable energy technology, as they are used in solar panels to convert sunlight into electricity.

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