What is the Difference Between Valence Band and Conduction Band?
🆚 Go to Comparative Table 🆚The main difference between the valence band and the conduction band lies in the energy level and the location of the electrons within the atomic structure. Here are the key differences between the two:
- Energy Level: The valence band is a lower energy state, while the conduction band is at a higher energy level.
- Location in Energy Band Diagram: The valence band is located below the Fermi level (forbidden energy gap) in the energy band diagram, while the conduction band is located above the Fermi level.
- Electron Density: The electron density in the valence band is high because it has more electrons per unit volume, whereas the electron density in the conduction band is low.
- Electron Behavior: Electrons in the valence band experience strong force by the nucleus, while the nucleus exhibits very weak or almost negligible force on the electrons in the conduction band.
- Conditions: In metals, the valence band and conduction band overlap, resulting in a high conductivity. In semiconductors, there is a small gap between the valence and conduction bands, allowing for some conductivity, while in insulators, the gap is very large, making it difficult for electrons to move between the bands.
In summary, the valence band consists of electrons that are tightly bound to the atomic nucleus and require a significant amount of energy to be excited, while the conduction band consists of electrons that are less tightly bound and can be excited with less energy. The energy difference between the highest occupied state of the valence band and the lowest unoccupied state of the conduction band determines the electrical conductivity of a material.
Comparative Table: Valence Band vs Conduction Band
The valence band and conduction band are two different energy levels in a material, separated by a certain amount of energy. The main difference between them is that the valence band specifies the energy levels of electrons that are bound to the nucleus, while the conduction band holds electrons responsible for conduction. Here is a comparison table highlighting the differences between the valence band and conduction band:
Property | Valence Band | Conduction Band |
---|---|---|
Energy Level | Lower energy state | Higher energy level |
Abbreviation | VB | CB |
Fermi Level | Below the Fermi level | Above the Fermi level |
Occupancy | Usually partially or completely filled at room temperature | Generally empty or partially filled at room temperature |
Electrical Conductivity | Low conductivity, as electrons are tightly bound to the nucleus | High conductivity, as electrons can move freely within the material |
Band Gap | In semiconductors and insulators, there is a band gap between the valence band and conduction band | In conductors, the bands overlap, and the distinction between valence and conduction bands is meaningless |
In insulators and semiconductors, electrons can be excited from the valence band to the conduction band, which is responsible for electrical conductivity. The energy difference between the highest occupied energy state of the valence band and the lowest unoccupied energy state of the conduction band is called the band gap. The band gap is indicative of the electrical conductivity of a material.
- Electronic vs Ionic Conduction
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- Energy Level vs Energy Band
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- Conduction vs Induction
- Valence vs Core Electrons
- Conductivity vs Conductance
- Direct vs Indirect Band Gap
- Conductor Semiconductor vs Insulator
- Superconductor vs Perfect Conductor
- Electrovalent vs Covalent Bond
- Metallic vs Electrolytic Conduction
- Semiconductor vs Superconductor
- Concert Band vs Symphonic Band
- Electrovalency vs Covalency
- Valency vs Charge
- Saltatory vs Continuous Conduction
- Conductivity vs Molar Conductivity
- Band vs Orchestra