what i mean exactly what is the position of Fermi energy for semi conductor materialsDrDu said:it would be helpful if you could rephrase your question in complete sentences.
M.A.M.Abed said:I ll do
I didZapperZ said:You didn't..
Zz..
I know that it doesn't necessarily in the center.DrDu said:The precise definition of the Fermi energy is the value of the chemical potential of the electrons in the limit ##T \to 0 ##K. This value may or may not coincide with an energy level of the system. In semiconductors it is somewhere between the upper end of the valence band and the lower end of the conduction band, not necessarily in the center.
yea the density of at it equal to zeroDrDu said:In the energy gap there is no level, so it makes no sense to say it is empty or not. In a semiconductor you have a well defined Fermi energy, but no Fermi level.
M.A.M.Abed said:also is there any importance to define a work function for semi conductor or insulators since Fermi level in the energy gap ??
Thnx in advanceZapperZ said:Yes, there is an "importance" to defining a work function for a semiconductor. In some cases, it is defined as the sum of the energy gap and the electron affinity. It is important because many semiconductors are being used a photocathode in an electron source, and the work function here defines the photoemission threshold.
Zz.
M.A.M.Abed said:Thnx in advance
last question sorry the Fermi energy at insulators is the top level of valance band
and Fermi level for ideal case in the middle of energy gap am i right ?
for pure semiconductor at T=0 KZapperZ said:No, this is not correct. The Fermi level for insulators is somewhere in the gap.
Ideal case of what?
Zz.
M.A.M.Abed said:for pure semiconductor at T=0 K
there is a misunderstanding between fermi level and fermi energy
just tell me where fermi level and fermi energy exist at zero absolute temperature for semiconductors
yea this is the Fermi levelZapperZ said:For an intrinsic semiconductor, it is located in the middle of the gap. For any other semiconductor or insulator, it is SOMEWHERE in the gap.
Zz.
No, because the density of states is usually different in the valence and conduction band. At finite temperatures, this would lead to an excess of electrons in the band with the higher DOS. Hence the chemical potential has to be further away from the band with the higher DOS. This also holds in the limit of zero temperature.ZapperZ said:For an intrinsic semiconductor, it is located in the middle of the gap.
DrDu said:No, because the density of states is usually different in the valence and conduction band.
M.A.M.Abed said:yea this is the Fermi level
what about Fermi energy (highest occupied energy at T=0 K)
The Fermi energy for semi-conductors is the energy level in a material that represents the highest occupied energy state at 0 Kelvin. It serves as a reference point for determining the probability of electrons occupying higher energy states.
The position of Fermi energy in semi-conductors is determined by the type of doping present in the material. N-type doping results in a decrease in Fermi energy, while P-type doping results in an increase in Fermi energy.
Fermi energy and band gap are inversely related in semi-conductors. As the band gap decreases, the Fermi energy increases, and vice versa. This relationship is important in determining the electrical conductivity of a material.
In semi-conductors, the position of Fermi energy increases with increasing temperature due to the thermal excitation of electrons to higher energy states. This results in an increase in the number of charge carriers and an increase in electrical conductivity.
The position of Fermi energy is crucial in understanding the electrical and optical properties of semi-conductors. It determines the number of charge carriers and their energy states, which in turn affects the material's conductivity, band structure, and optical absorption. It also plays a key role in the design and performance of electronic devices.