We performed an undergrad experiment where we looked at the resistance $\rho$ and Hall constant $R_\text H$ of a doped InAs semiconductor with the van der Pauw method. Then we cooled it down to around 40 K and did temperature-dependent measurements up to around 270 K. We were asked to create the following three plots from our measurements and interpret them.
This is conductivity $\sigma = 1 / \rho$ versus the inverse temperature $T^{-1}$. I see that increasing the temperature (to the left) decreases the conductivity. I do understand that higher temperatures do that since the electrons (or holes) have more resistance due to phonon scattering. However, since higher temperatures mean a higher amount of free electrons, I would think that $\sigma$ should go up, not down.
http://chaos.stw-bonn.de/users/mu/uploads/2013-12-07/plot1.png
The density of holes $p = 1/(e R_\text H)$ does increase with the temperature, that is what I would expect:
http://chaos.stw-bonn.de/users/mu/uploads/2013-12-07/plot2.png
And the electron mobility $\mu = \sigma R_\text H$ decreases with the temperature as well:
http://chaos.stw-bonn.de/users/mu/uploads/2013-12-07/plot3.png
Now, I am little surprised that even though $p$ goes up with $T$, $\mu$ and $\sigma$ go down with $T$. Are the effects of phonon scattering and other things that increase the resistance that strong?
Answer
Phonon scattering goes up a lot as temperature increases -- faster than electron numbers increase in the conduction band.
Keep in mind that phonons obey the Bose-Einstein distribution, so their numbers scale like
$$N_{BE}=\frac{1}{e^{\frac{\hbar\omega}{k_b T}}-1}$$
In the large $T$ limit, this becomes
$$\frac{k_b T}{\hbar\omega}$$
So their numbers roughly scale linearly with temperature at "high temperature". For phonons, "high temperature" means above the Debye temperature, but that's only ~650K for silicon; you're a good chunk of the way there at room temperature.
However, electrons follow a Fermi-Dirac distribution, so you'd expect their numbers to scale like.
$$N_{FD}=\frac{1}{e^{\frac{\epsilon}{k_b T}}+1}$$
In the large T limit, this goes to $\frac{1}{2}$.
There's also a chemical potential for the electrons that limits their numbers. Phonons have no such restriction; given the energy, you can have as many phonons as you want.
Even if you're not talking about high temperatures, note that the $N_{BE}>N_{FD}$ is always true.
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