Well, the short version is; it didn't work.
The slightly longer version is that it did work, but not as intended. I set up my reaction cell:
I made three, as originally planned, but the general setup was the same, so to save space I'll only post the one. I made 2 with an Iron anode and one with Lead. I measured out 150ml of my dirty AP-solution after it had been bubbling over night with a bunch of copper to cement out any valuables. To one of the Iron-anode-cells I also added Ammonium Sulphate to precipitate out the Lead from solution, as described in a previous post. Then in went the 150ml of AP into each of the cells. I also tested the sulphate on a small batch beforehand, and though I have no tests to prove it, there was visible white, insoluble precipitates formed upon addition that I assume are Lead Sulphate. I will, however, go through my old chemistry book to look for other sulphates that might form and drop out as well.
Having looked a bit closer at the reduction potential of the metals, I calculated that an Fe/Cu-cell would generate around 0,6V of potential, while the Pb/Cu would be somewhere slightly below 0,3V. The measurements were inconclusive, but lower for Pb/Cu than the two Fe/Cu ones, though all three were way below estimated, at 0,08V, 0,13V and 0,14V respectively.
So it looked like this would take a while, and as I prepared to push the cells to the back of the hood and do something else, I noticed a curious thing; Both electrodes were visibly plated with Copper:
Naturally, I stopped the experiment, removed the electrodes and rinsed them well before gathering up the electrolyte (the dirty AP solution, now with Ammonium Sulphate added), and paused to review the results.
It appears that geedigity had a very valid point: the Copper does indeed plate out on the Iron as well, though judging from the look of the electrodes, Copper was deposited on both sides.
For now, my working theory is that the electric potential of the reaction is too small to overcome the proclivity of Iron to 'trade' electrons with Copper completely, thus creating a situation where there is a reduction of Copper taking place at both electrodes.
What I don't get, is why the Copper metal formed at the Iron electrode is plated onto it, rather than just formed as a free-flowing precipitate. It might be that the possibility of making a metal bond with Iron exhibits some kind of force as well, but that is outside my realm of knowledge.
Another curious thing also happened, and this one I throw out to you guys: The Copper cathode paired with the Lead anode did not get a covering of bright Copper as the others, but instead a dull, whiteish Copper-colour:
Anyone care to take a guess at what happened to the Cu-cathode here?
On a side note, the Ammonium Sulphate appears to do a fairly good job of removing the Lead from the waste-AP, so I gathered up the various small amounts of AP from the cells and mixed it with an excess of (NH4)2SO4 to see if I can get the Lead out before dropping the Copper. Obviously, this will add a step to the waste treatment, but the idea of ridding the solution of Lead seems like a good one, and I will gladly spend the time to precipitate and filter out the Lead Sulphate if that gives me a less dangerous Cu-powder to use in my Stock Pot later on.
