Why does the resistance decreases with increase in temp for semi- conductors?

In summary, the relationship between temperature and resistance in semiconductors is that the resistance generally decreases as temperature increases due to more charge carriers being created. Semiconductors behave differently from conductors and insulators because of their unique band structure which allows for changes in resistance as temperature changes. The band structure of semiconductors is related to temperature and resistance because as temperature increases, more electrons are able to jump to higher energy levels, making them more mobile and resulting in a decrease in resistance. Impurities and defects in the crystal lattice of semiconductors can affect resistance at different temperatures by acting as roadblocks for electron movement. Practical applications of the temperature-dependent resistance in semiconductors include devices such as thermistors which
  • #1
Abhishakes
5
0
Why does the resistance decreases with increase in temp for semi- conductors?
 
Physics news on Phys.org
  • #2
Essentially because there are more electron-hole pairs (which contribute to conduction) when temperature rises. This effect wins from the standard effect in metals which increases the probability of scattering and hence the slowing down of the carriers (very crude picture) with increasing temperature. In metals, the first effect is absent, as all or most of the carriers are already available.
 
  • #3


The resistance of a semiconductor decreases with an increase in temperature due to the behavior of its charge carriers. In a semiconductor, the charge carriers are electrons and holes, which are responsible for conducting electricity. As the temperature increases, the thermal energy of these charge carriers also increases, causing them to move more freely and at a faster rate. This increased mobility of charge carriers leads to a decrease in resistance.

Additionally, at higher temperatures, more electrons are able to break free from their bound states and become available for conduction. This increases the number of charge carriers and further reduces the resistance of the semiconductor.

Furthermore, the atomic lattice structure of a semiconductor also plays a role in its resistance. As temperature increases, the atoms in the lattice vibrate more vigorously, creating more thermal energy. This thermal energy can disrupt the regularity of the lattice, making it easier for charge carriers to move through it, thus reducing resistance.

In summary, the decrease in resistance of semiconductors with an increase in temperature is due to the increased mobility of charge carriers, the availability of more charge carriers, and the disruption of the atomic lattice structure. This phenomenon is important in understanding and designing electronic devices that utilize semiconductors.
 

What is the relationship between temperature and resistance in semiconductors?

The resistance of a semiconductor generally decreases as temperature increases. This is because at higher temperatures, more electrons are able to break free from their atoms, creating more charge carriers and allowing for easier flow of electricity.

Why do semiconductors behave differently from conductors and insulators when it comes to temperature and resistance?

Unlike conductors, which have a constant resistance regardless of temperature, and insulators, which have a resistance that increases with temperature, semiconductors have a unique band structure that allows for changes in resistance as temperature changes.

What is the band structure of semiconductors and how does it relate to temperature and resistance?

The band structure of a semiconductor refers to the energy levels available for electrons to occupy. As temperature increases, more electrons are able to jump to higher energy levels, making them more mobile and resulting in a decrease in resistance.

How do impurities and defects in the crystal lattice of a semiconductor affect its resistance at different temperatures?

Impurities and defects in the crystal lattice can act as roadblocks for the movement of electrons, increasing resistance. At higher temperatures, these imperfections become more active, resulting in a greater decrease in resistance compared to a pure semiconductor.

Are there any practical applications of the temperature-dependent resistance in semiconductors?

Yes, the temperature-dependent resistance of semiconductors is utilized in devices such as thermistors, which can measure changes in temperature based on the corresponding changes in resistance. This is also a key factor in the functioning of electronic devices in different temperature environments.

Similar threads

I Why does increasing resistance in a conductor decrease power dissipation?
    • Electromagnetism
Replies
7
Views
977
B The resistance of an ohmic conductor
    • Electromagnetism
Replies
4
Views
967
I A smaller cross-sectional area increases the resistance of a conductor?
    • Electromagnetism
Replies
7
Views
855
I Alternating current in a perfect conductor
    • Electromagnetism
Replies
11
Views
755
I Work done by electric field of an irregularly shaped conductor
    • Electromagnetism
Replies
3
Views
484
B Uniform charge distribution in a conductor
    • Electromagnetism
Replies
5
Views
1K
I Electric field, flux, and conductor questions
    • Electromagnetism
Replies
14
Views
1K
Resistance of Platinum decreases with an increase in temperature ?
    • Electromagnetism
Replies
2
Views
7K
E-Field immediately outside a charged conductor
    • Electromagnetism
Replies
5
Views
1K
Conductivity of an electrolyte
    • Electromagnetism
Replies
1
Views
1K

Hot Threads

Recent Insights

Back
Top