Abstract: The exponential dependence of resistivity on temperature in germanium is found to be a great big lie. My careful theoretical modeling and painstaking experimentation reveal 1) that my equipment is crap, as are all the available texts on the subject and 2) that this whole exercise was a complete waste of my time.
Introduction
Electrons in germanium are confined to well-defined energy bands that are separated by "forbidden regions" of zero charge-carrier density. You can read about it yourself if you want to, although I don't recommend it. You'll have to wade through an obtuse, convoluted discussion about considering an arbitrary number of non-coupled harmonic-oscillator potentials and taking limits and so on. The upshot is that if you heat up a sample of germanium, electrons will jump from a non-conductive energy band to a conductive one, thereby creating a measurable change in resistivity. This relation between temperature and resistivity can be shown to be exponential in certain temperature regimes by waving your hands and chanting "to first order".
Experiment procedure
I sifted through the box of germanium crystals and chose the one that appeared
to be the least cracked. Then I soldered wires onto the crystal in the spots shown in figure 2b of Lab Handout
32. Do you have any idea how hard it is to solder wires to germanium? I'll tell you: real goddamn hard. The
solder simply won't stick, and you can forget about getting any of the grad students in the solid state labs to
help you out.
Once the wires were in place, I attached them as appropriate to the second-rate
equipment I scavenged from the back of the lab, none of which worked properly. I soon wised up and swiped
replacements from the well-stocked research labs. This is how they treat undergrads around here: they give
you broken tools and then don't understand why you don't get any results.
Fig. 1: Check this shit out. |
Results
Check this shit out (Fig. 1). That's bonafide,
100%-real data, my friends. I took it myself over the course of two
weeks. And this was not a leisurely two weeks, either; I busted my
ass day and night in order to provide you with nothing but the best
data possible. Now, let's look a bit more closely
at this data, remembering that it is absolutely first-rate. Do you see
the exponential dependence? I sure don't. I see a bunch of crap.
Christ, this was such a waste of my time.
Banking on my hopes that whoever grades this will
just look at the pictures, I drew an exponential through my noise. I
believe the apparent legitimacy is enhanced by the fact that I used a
complicated computer program
to make the fit. I understand this is the same process by which the top
quark was discovered.
Conclusion
Going into physics was the biggest mistake of my life. I should've declared CS. I still wouldn't have any women, but at least I'd be rolling in cash.
http://www.cs.wisc.edu/~kovar/ hall.html: above bio.html: "My undergraduate work was at Stanford, where I majored in physics."