Permanganates

Not sure about the air oxidation, I haven't tried it.

It seems to me that the electrolysis is something that can easily be done on an industrial scale, but is a lot of messing around for the home amateur. In the last electrolysis I carried out (above), I failed to take into account the extra frothing caused by the increased current. The lid I had made did not have an "o" ring so it did not seal perfectly and hot alkaline electrolyte ran down the outside of the cell and etched the polished surface of my hotplate.... as well as putting brown stains all over it. Manganese compounds are such a pain, they seem to change oxidation state just by being looked at...

As I said before, the electrolysis is a lot of messing around for little return!

Possibly some refinements to the cell design could be made to make the operation more efficient but I don't know what!

Regards, Xenoid

MnO2 Types

Just a thought, but quickly precipitated solids usually have a much larger surface area and energy than 'dry' ones. How about preparing MnO2 in-situ by adding NaOCl to MnCl2 solution. If you have a manganese salt or MnO2 this can easily be prepared. By using the chloride you are not adding further unnecessary ions to the solution, just a slight excess of chloride. Well, actually a bit more than that because of the chloride from the reduced hypochlorite too.

I would try dissolving the MnO2 with HCl outside - unless you are partial to breathing chlorine - and filtering then crystallising the MnCl2, then dissolving that in a decent amount of water and adding hypochlorite with good stirring.

Edit- actually, you may end up with less chloride, since you are not oxidising carbon.

[Edited on 5-12-2007 by Antwain]

Bretfi method
Dear friends, I confirm that direct fusion of MnO2 and NaOH can lead to NaMnO4. I've done an empirical experiment which proved succesfully.
For this experiment was used:
- pottery grade MnO2,
- domestic use NaOH,
- tap water.
Description:
1. In a large tray was melted a teaspoon NaOH then powdered about the same quantity of MnO2 over melt then mixing for about 1/2 hour until a dark green liquid is formed. If cooled will crystalize like a glass film which breakes and care should be taken because small pieces when cooling can jump around; ( for this first step using a large tray is not a good idea). This product contains probably Na2MnO4, NaOH and MnO2; we call it Product A.
2. In a large tray, Product A is melted in a thin layer. MnO2 in excess is added until mixture becomes powdery and abrasive. Continue mixing for 1/2 hour so the mix to be well aerated while from time to time pulverize some water over powdery mix. Stop watering and keep heating for another 1/2 hour while mixing. Product B is formed, dark, which probably contains Na3MnO4, MnO2 etc.
3. Let the product B cool and then disolve it the cold water. Wait for an hour when the dark blue like plums is formed togeter with some mud residue. Decant the liquid and heat until a purple color is formed. Can be boiled untill concentrated. The purple color is also formed without further heating, after a while. What we obtained is NaMnO4 with very little impurities.
As stated before, this exp. was done empirically and a overwhelming positive result was not expected. Some of the parameters (time, quantity) might be slightly innacurate.

above someone mentioned the following reactions:
$$$$$$$$$$$$$$$$$$$$$$$$$$$$$
KMnO4 + AgNO3 -> KNO3(aq) + AgMnO4(s) red precipitate : wiki claims 0.9g/100g water @ 20*C, but don't trust it

2AgMnO4 + BaCl2 -> Ba(MnO4)2(aq) + AgCl(s)

Ba(MnO4)2 + H2SO4 -> BaSO4(s) + 2HMnO4(aq)
$$$$$$$$$$$$$$$$$$$$$$$$$$$$$

I find this interesting: ppt-out the AgMnO4 from the watery solution of any melt or electrylytically processed melt; from there getting any desired HMnO4-salt ...

But: In a half- or not-at-all elecrolyzed melt from (K,Na)(NO3,CO3,OH) + MnOx there may be a lot of things going on .. : Is the AgMnO4 the only Salt to fall out with AgNO3 ?

That would seem to be the Kings way, most easy of all ...

Ion exchange

Looks like you are in the running for a Darwin Award

Maybe we should get together: I'm a thermite nut (at least for the moment) and manganese is the one thermite that's hard to control in terms of actually obtaining the metal itself and not just pyrotechnics. I've produced w/o many problems Si, Fe, Cr, V, Ti, Co, Cu and often alloys of these as well, I would easily make Nb and Sc if I could get the oxides, but Mn remained the elusive one, at least up to recently.

I've been working on a workable solution for weeks using different oxides like MnO and Mn2O3 and combinations thereof, gradually making progress. Most of my Mn thermites now produce metal of good quality (visually speaking) but the yields remain frustratingly small (typically less than 30 % theor. yield). Yesterday I had a bit of a breakthrough with a 50 g reaction based on an equimolar blend of MnO and Mn2O3. Although yield was again poor (37 % theor.) there was at least one 7.3 g clean lump of metal, oblong, about 1 inch long. Today I'll be running another variant and shortly will open a thread on my experiments on making metallic manganese, using thermite, as well as ideas on the use of other reductants.

@DerAlte

Yes, we're probably going to get shafted for being OT, so I'll keep it short.

Your reaction enthalpy values are correct. Interesting how you express them per mol of Mn produced, not per mol of oxide reduced.

MnO is by far the coolest running but it needs help to get to a molten slag/metal mix from one of the higher oxides. Yield is always quite low because the MP of alumina and BP of manganese being so close together.

I've made my MnO by decomposing MnCO3 at 400 - 500 C under a stream of CO2 (I had to build a CO2 generating "apparatus" for that - very a la Frankenstein movies - lol). The Mn2O3 is made be decomposing MnCO3 in the same conditions but in open air. Neither products are particularly pure but in thermite conditions they do exactly as "it says on the tin".

Provided I can get my hands on Mg powder, I'll now be gunning for the MnCl2 + Mg ---> Mn + MgCl2 reduction (ΔH = - 161 kJ/mol of MnCl2).

++++++++++++

The synthetic Fe3O4 is magnetite alright. It's the basis for homemade ferrofluids. Here's a bit of info and some links on ferrofluids. Mine worked well but not well enough to get the famous "hedgehog effect". The fluid was strongly magnetic though.

Quote: Originally posted by Formatik

It needs to be dehydrated also to form the compound. I've added some KMnO4 powder to reddish fuming HNO3 with a density of about 1.52, no Mn2O7 formed, and all of the acid fumes turned white. The same is in the well-known chlorine generator reaction of KMnO4 with conc. HCl, though the permanganate can also oxidize the conc. acid to some ClO2, which is explosive.

Quote: Originally posted by monoceros4

(cut) A practical note that doesn't come across well in the notes (I need to improve my note-taking): I cracked a lot of cheap porcelain crucibles doing this. Thermal stress was no doubt sometimes to blame: my sources of heat are poor, comprising only an alcohol lamp (wretched), a couple of different propane torches (one the standard pencil torch, another with a fairly broad flame), and an electric range. But even using the electric range and gradual heating to the maximum value, the porcelain cracked, sometimes extensively. I know that alkaline melts attack porcelain but I'd underestimated how much it would weaken it.(cut)

Quote: Originally posted by JohnWW

More resistant materials than porcelain (or borosilicate glass) should be used as crucibles for reactions involving fused or hot concentrated alkalis. The reaction mixture would become contaminated with silica and alumina. The first step upwards would be fused zirconia, or failing that, graphite or nickel; or better still, platinum if it could be afforded.

By the atached diagram, it doesn't look as if air would do the job under aqueous conditions.

For alkaline fusions, iron or nickel is acceptable. There will be some contamination, especially if chlorates or perchlorates are added as oxidiser - halogens are bad news even under alkaline conditions.

Quote: Originally posted by not_important

By the atached diagram, it doesn't look as if air would do the job under aqueous conditions.

Quote: Originally posted by chief

(thoroughly washed, filtrated, pre-glowed with some nitrate to remove the graphite first !)

Quote: Originally posted by chief

Ah yes, the acidification: I preferred to ppt. out with Ba(NO3)2, to get the insoluble BaMnO4

Quote: Originally posted by Formatik

... Though as far as oxidation of HCl by KMnO4 goes, this is said by at least several references in Brethericks to have given a sharp explosion when conc. HCl was added to solid KMnO4, the explanation was that there is a remote possibility of the permanganate oxidizing the Cl2 to "chlorine oxide". ...

An equimolar amount of NaOH and KOH forms an eutectic that melts well below 200 degrees. So I tried that with MnO2, and tried to oxidize it to manganate with equimolar KNO3 and NaNO3 ... equimolar to keep the Na/K ratio constant and the melt molten.

The MnO2 reacted only slowly, and the nitrate seemed to have no effect. The melt turned green on the surface from reacting with oxygen, but the bulk stayed black/grey.

The photo is after adding the nitrate. You can see the dark bulk of the melt with blue manganate on the surface.
The melt bubbled slowly like thick boiling mud. Most of the MnO2 did not go into solution after 40 minutes of heating.

My reason for doing this was to make the manganate, then stir in zinc oxide to form a zincate/manganate melt. Then to cool, dissolve up in water, filter, and precipitate zinc manganate by lowering the pH with CO2. ZnMnO4 is a mild oxidizer like BaMnO4 with a very easy workup ... you just filter it off.

Edit --- another attempt to upload the photo.
The quantities were NaOH/KOH/MnO2/NaNO3/KNO3 44/61/47.2/23/27.5


[Edited on 17-5-2010 by Paddywhacker]



[Edited on 17-5-2010 by Paddywhacker]