With this same measurement technique, we found a result that we thought was rather strange and surprising, which we have written up here. Take a moderately long wire, say 120 nm wide and several microns long, made by patterning a 15 nm thick Au film. Hook up basically a volt meter to the ends of the wire, and scan the laser spot along the length of the wire, recording the voltage as a function of the laser position. If the wire is nice and homogeneous, you'd expect not to see to much until you get to the ends of the wire where it widens out into bigger contacts. (There the size variation should make the skinny/wide junction act like a thermocouple.) Instead, we see the result shown here in the figure (fig. 2 of the paper). There is a great deal of spatial variability in the photothermoelectric voltage, like the wire is actually made up of a whole bunch of little thermocouples! Note that your eye tends to pick out a spatial scale in panel (a) comparable to the 1 micron scale bar. That's a bit misleading; the spot size of the laser in our system is about 1.8 microns, so this measurement approach would not pick up much smaller spatial scales of variation.
The metal wire is polycrystalline, and if you look at the electron microscope images in panels (c, d, e) you can make out a grain structure with lateral grain sizes of 15-20 nm. Maybe the wire isn't all that homogeneous? One standard way physicists look at the quality of metal films is to consider the electrical resistance of a square patch of film (\(R_{\square}\), the "sheet resistance" or "resistance per square"), and compare that number with the "resistance quantum", \(R_{\mathrm{q}}\equiv h/2e^2\), a combination of fundamental constants that sets a scale for resistance. If you had two pieces of metal touching at a single atom, the resistance between them would be around the resistance quantum. For our wire material, \(R_{\square}\) is a little under 4 \(\Omega\), so \(R_{\square} << R_{\mathrm{q}}\), implying that the grains of our material are very well-connected - that it should act like a pretty homogeneous film. This is why the variation shown in the figure is surprising. Annealing the wires does change the voltage pattern as well as smoothing it out. This is a pretty good indicator that the grain boundaries really are important here. We hope to understand this better - it's always fun when a system thought to be well understood surprises you.