What's a good primer of band theory (metals and semiconductors).

In summary, the valence and conductance bands are composed of molecular orbitals contributed by each metallic atom joining the molecule. The third band, or conductance band, has a higher energy level than the valence bands because it is half-filled and allows for electron movement between atoms. If the s-band was completely filled, the higher energy p orbitals would form the p-band, creating a band gap between the two. This explanation may not be included in textbooks.
  • #1
aleksbooker
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Edit: I've made some progress on this one, and I now understand that the valence and conductance bands are composed of molecular orbitals contributed by each metallic atom joining the molecule.

For example, three lithium atoms would contribute three total molecular orbitals, resulting in three bands. The bottom two might be the valence bands and hold all the elections, while the third might be the conductance band.

Here's the question:

Why does that third band (the conductance band) have a higher energy level than the valence bands, especially if they were all the same type of orbital (2s) contributed by lithium atoms?
 
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  • #2
aleksbooker said:
Edit: I've made some progress on this one, and I now understand that the valence and conductance bands are composed of molecular orbitals contributed by each metallic atom joining the molecule.

For example, three lithium atoms would contribute three total molecular orbitals, resulting in three bands. The bottom two might be the valence bands and hold all the elections, while the third might be the conductance band.

Here's the question:

Why does that third band (the conductance band) have a higher energy level than the valence bands, especially if they were all the same type of orbital (2s) contributed by lithium atoms?
All orbitals of the same type will contribute the the same band. In the case of lithium, the 2s orbitals will make up the s-band. Since each lithium atom contributes only one electron to the s-band, it is half-filled and electrons can move from one atom to the next, so it is a conduction band.

If the s-band was completely filled, then it would become a valence band, and the higher energy p orbitals would form the p-band, which would be the conduction band, and there would be a band gap between the two, due to the difference in energy between s and p orbitals.
 
  • #3
Oh. That's a great explanation. Why didn't they put *that* in the textbooks?
 

1. What is band theory in relation to metals and semiconductors?

Band theory is a model used to explain the behavior of electrons in solid materials, specifically metals and semiconductors. It describes how electrons are arranged in energy levels, or bands, and how they can move within these bands to conduct electricity.

2. Why is band theory important in understanding the properties of metals and semiconductors?

Band theory helps us understand why certain materials have specific properties, such as electrical conductivity and thermal conductivity. It also explains why some materials are good conductors while others are insulators. This knowledge is crucial in the development of new materials and technology.

3. How do band structures differ between metals and semiconductors?

In metals, the bands of energy levels overlap, allowing electrons to move freely and conduct electricity. In semiconductors, there is a small band gap between the valence band (filled with electrons) and the conduction band (empty). This gap can be overcome with energy, allowing for some conductivity but not as much as in metals.

4. What factors influence the band structure of a material?

The band structure of a material can be influenced by its composition, crystal structure, and temperature. Doping, or intentionally adding impurities, can also affect the band structure of semiconductors.

5. How does band theory relate to the concept of band gaps?

Band gaps refer to the energy difference between the valence and conduction bands in a material. In metals, there is no band gap, while in semiconductors, there is a small band gap that can be overcome with energy. Band theory helps us understand the relationship between band gaps and the electrical and optical properties of materials.

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