Make Potassium (from versuchschemie.de)

Quote: Originally posted by plastics

There is certainly initial generation of gas after gentle warning and I am able to get the tert butanol to reflux successfully (see pictures). After a couple of hours I just end up with a sludge of magnesium turnings and white powder (? MgO ? Mg(OH)2 this is definitely not the KOH flakes I started with)

I also tried the experiment twice. Both experiments failed.

One time I tried the safe way in a sand bath with temperature monitoring. The temperature remained between 200 C and 250 C during the entire experiment. I used a 10 times as small a scale as Pok did.
Below follow pictures of the setup I used. The third picture shows that the test tube is filled with white fumes and the glass is wetted. There is some refluxing of t-butanol. The fourth picture shows a typical temperature readout during the experiment and the final picture shows the result.

Unfortunately the result is no potassium at all. Definitely there is some reaction (evolution of gas and formation of a white solid, other than KOH), but no potassium metal is formed.











[Edited on 11-12-10 by woelen]

So, in the first experiment I had no results. I added the t-butanol, dissolved in some paraffin oil in two steps with 20 minutes in between by letting it run through the thin glass tube (I did not want the air to be replaced inside the test tube). Initially, before heating, I flushed the air in the test tube with butane gas to be sure that no oxygen remained. I capped the glass tube with a thick dash of paper tissue which was wetted. At the start of the experiment a small amount of gas was released through this outlet, lateron, I pushed it firmly on the tube and no exchange of gas seemed to happen anymore.
I have kept the test tube in the hot sand bath for around 1 hour and then I allowed it to cool down slowly (which took another hour). Not the faintest sign of formation of potassium. No shiny globules. Pok states that in 20 minutes, but certainly in 30 minutes after adding the tert-butanol one should clearly see shiny globules of potassium. Nothing at all!


In the second experiment I did something unwise

I went outside, took a test tube and put in fresh reagents and with a clamp, I kept the test tube above (not in!) the flame of a propane torch. I did this outside just in case the test tube would crack and the very hot mineral oil would catch fire. With this setup much higher temperartures are possible. I had a very vigorous reaction in this experiment. A thick white cake formed, sticking at the glass and excess Mg-powder was floating around in the mineral oil. I allowed this situation to last for around 30 minutes after adding the tert-butanol, but again no potassium is formed. Part of the Mg reacts, a lot of gas and white smoke is produced, but no K-metal. The vigorous reaction only lasts for a few tens of seconds, after that I had a clearly visible formation of gas, but it was not violent at all.

The KOH, used in my experiments is in the form of half-spheres, diameter around 4 mm and thickness at most 2 mm. The Mg is in the form of moderately fine powder (according to label it is 65 um to 100 um particle size).


Tomorrow I hope to find the time to try the reaction with Mg/Al instead of Mg. My Mg/Al is a fine powder, sold to me as magnalium for pyro purposes. It, however, also is a fine reductor and that is what I am using it for.


[Edited on 11-12-10 by woelen]

@woelen:

I bet you are, so are we all (disappointed).

You’re starting from the assumption that pok’s results are genuine (and not a hoax) and that they are dependent on some ‘hidden parameter’, right? It’s possible. It just doesn’t really ring true with me.

Most likely (again assuming his experiment is genuine) it would be some overlooked form of catalysis.

Next we’ll be holding a collection for a representative of SM to fly to Germany and go watch <i>jackpok’s</i> ‘magic’ in the flesh (I just hope he’s not an illusionist as well as a hoaxer!

Quote: Originally posted by woelen

Yes, up to now I assume that Pok is honest. It might be that he won the 'jackpok' but if that is the case then it is a job for us (and him) to find out what is the 'hidden luck' behind this. Maybe something in the ShellSol D70, maybe in the magnesium he used or even in some of the other chemicals. It might be that we even need more info from Pok himself. Maybe he should try with another batch of magnesium metal. Anyway, I have an order outstanding at Kremer right now for 1 liter of ShellSol D70. Hopefully they dispatch at the start of next week and then I migt have the stuff next weekend. Shipping times usually are two to four days from Germany to the Netherlands.

I DID MAKE SOME POTASSIUM!!!

I have had the whole setup in the sand bath cool down completely and I found it was time to cleanup the mess. I added some water to the paraffin oil with the sticky goop inside which is mostly white, but also contained some remains of unreacted magnesium. I was met with a crackling and roaring noise as soon as water went into the test tube and bubbles of gas were produced. I decided to allow the concentration rise somewhat by pressing my thumb on the open end of the test tube and wanted to light the gas with a cigarette lighter, just testing for hydrogen. Suddently, while I still had my thumb on the open end of test tube, the gas mix above the oil exploded and immediately after the explosion there was a fairly strong underpressure. Luckily the test tube did not crack and I did not drop it! My heart skipped a few beats

After I recovered , I took the test tube (it still made a crackling noise) and swirled it somewhat and suddenly a 5 cm long pinkish flame erupts from the test tube and a WHOOP sound is produced. My heart skipped another beat ...

This kind of behavior can ONLY be explained by assuming that some potassium is formed. It only is a minute quantity and it is not formed in the form of nice globules, but definately some potassium is formed. The potassium reacts with water, giving hydrogen gas and when the liquid is swirled, then potassium at the liquid/air interface can form very hot spots, capable of igniting the hydrogen air mix above it.


The second experiment with the test tube above a flame of a propane torch indeed did not make any potassium. So, high temperature and fast reaction is not favorable. Slow reaction in a sand bath is one requirement for making potassium.


[Edited on 11-12-10 by woelen]

Spurred by woelen, I too added water to the white/grey sludge left after my previous attempt (photos I displayed earlier). The water sank to the bottom and after swirling around I too was greated with a very effervescent reaction which eventually caused the whole mixture to heat up very quickly and boil (picture attached). No actual flames but not what I was expecting

Now to pour some cold water on everything, I have had Shellsol D70 busily refluxing with Mg turnings and tert-butanol for 3 hours and no potassium beads. I will see what happens when everything is coll and I add water.

I too still have some hope but there is still something missing





[Edited on 11-12-2010 by plastics]

Quote: Originally posted by woelen

I added some water to the paraffin oil with the sticky goop inside which is mostly white, but also contained some remains of unreacted magnesium. I was met with a crackling and roaring noise as soon as water went into the test tube and bubbles of gas were produced.

Quote: Originally posted by woelen

@blogfast: I also realize that my Mg may be too fine for this purpose. I do have filings, but these, on the other hand, are very coarse with a size of 5 mm and a thickness of 1 to 2 mm. I unfortunately have no block from which I can easily file something and crushing my filings to something smaller is very difficult. The big filings are too coarse, the powder is too fine.

Between a rock and a hard place...

And sod it, I’m going to have a go tomorrow. I’ve put together my ‘apparatus’ today. My main problem is that I only have 2-methyl-2-butanol, a tertiary alcohol but not t-butanol.

My experiment will be close to pok’s (same scale but with injection of the alcohol straight into the mix, and using an equivalent amount of 2-methyl-2-butanol). I’ve been messing with a sand bath to find a (gas) setting that takes the reactor slowly to 200C and beyond. I’m as ready as I can be with a bit of a plan to investigate any resulting gunge properly.

Below the ‘magical ingredient’, Shellsol D70. It really is remarkably odourless:

Quote: Originally posted by woelen

I have a source of very coarse reagent grade Mg powder (250 um particles, more or leass spherical). What do you think of that? Would that be suitable? I did not yet order it, minimum amount is 1 kg at around EUR 25 including the price of shipping. This is a decent price, but what must I do with 1 kg of Mg-metal if I it is not useful for making K-metal?

Quote: Originally posted by blogfast25

Watson’s idea of a work up with a lower viscosity solvent is very reminiscent of example 2 in the patent: sodium from NaOH. There the original solvent Shellsol D70 is removed after reaction and metal recovery carried out with dioxane (1,4-dioxacyclohexane), a low viscosity, low BP (101C) solvent. It's also polar and possibly a better solvent for alkoxides.

I'm glad that you've done it, woelen.

About the Mg size: At the photo you can see the Mg I used. It looks coarse (scale is in cm - so about 200µm broad), but these are mainly rolls of very thin (maybe < 50µm thick) Mg "foil" - an effect of filing. So if you use 20-50µm spherical Mg powder or so I think this should be the best size. I'm pretty sure that only 2 Mg properties will effect the outcome: surface area (depends on particle size) and purity (98%-100%).

@ woelen: did you also see small flashes of light (besides the explosion noise) when you added water to the mix? At least at 0.5mm K balls I always observed light flashes when I cleaned the erlenmeyer with water after the experiment. Maybe in your experiment the K was too much dispersed and too small to produce light flashes.

An advantage of a larger reaction volume (e.g. 50ml) is, that failures like income of some oxygen or loss of tert.butanol can be accepted up to a certain amount. But if the same amount (for example due to an equally large hole in your balloon or elsewhere) affects 5ml reactions the relative effect would be 10 times higher. Larger scale also is easier to handle (for exampe: stepwise addition of t-butanol within 30 min might be difficult if your total t-butanol is 0.6ml). But you obviously showed that even in small scale the experiment gives potassium.

I will repeat the synthesis as well in the next time to see if it still works as in the past. If it works, I will try to make Cesium as described in the patent. Making the needed dry CsOH may even be more difficult (for me) than making Cesium from it .



[Edited on 13-12-2010 by Pok]

Quote: Originally posted by NurdRage

I might try this with ACS grade Tetralin rather than Shellsol D70. I only got t-amyl alcohol at the moment, hopefully it'll be compatible.

Well this has been encouraging so far! As I mentioned previously, I have a source of t-Butanol that's reasonably inexpensive in Canada, so perhaps I could buy a 500 ml bottle and split it with one or two folks from north of the border? If anyone is interested, PM me and we'll figure things out.

Right now, I have most of the hardware, but i'll have to find an inexpensive source of KOH and something equivalent to the Shellsol (might as well get as close to the original recipe as possible to ensure success). I've been measuring the exact setting on my hotplate to get near the range of temperatures needed for the sandbath. A big thick-walled 500ml bomex round bottom flask will be used instead of an erlenmeyer, will this be ok?

@Pok: Thanks for suggesting this great experiment, this is the most fun thing i've read in a long time!

@NurdRage: Will we see a cool video of this synthesis soon?

Robert

Quote: Originally posted by watson.fawkes

Example 3 in the patent uses preformed t-amyl alkoxide (called "tertiary amylate" there). Given Nicodem's comment above, it should be readily formed from KOH and t-amyl alcohol in alkane solution. As far as tetralin, the same example 3 uses decalin as a solvent, the completely saturated version of tetralin, itself the half-saturated version of naphthalene. Shellsol D70 is hydrogen-treated to remove aromatics and alkenes; it has little unsaturated content. I have strong suspicion that somehow this is significant, although I have no particular mechanism to explain why. It might act as a hydrogen scavenger, forcing a side reaction. Double bonds might significant change solvation energy, or preferentially solvate some species and reduce its reactivity. I'm all in favor of exploring the parameter space of this reaction, but at the current stage of maturity, I wouldn't take failure with this solvent as anything like determinative. On the plus side, the boiling point of tetralin is a bit higher than that of decalin, which will make the reaction faster. Tetralin as a boiling point right around the lower boiling point of Shellsol D70. That of decalin is in the range of Gamsol, which is easily available and inexpensive in the US.

Interesting, i hadn't taken into account the presence of (or lack of) aromatic hydrocarbons. I'll still give it a go on small scale since i don't have any other high boiling solvents but I won't let failure dissappoint me in that case thanks for the heads up.

@Arthur Dent
No video soon, i'd like the synthesis to mature a lot before i make a video on it. Ofcourse i'll cite this thread and its contributors.

Well, my experiment didn’t go to plan and needs improving.

After the initial evolution of gas, presumed but not tested as hydrogen, the cork bung of the ‘refluxer’ kept being pushed out. I now have some right sized rubber bungs in the mail.



The question then was to abandon or soldier on without refluxer and I chose the latter, this time putting the temperature probe straight into the open Erlenmeyer. I started heating at 14.35 and gas started to evolve after about 5 mins. This carried on for about 30 mins: the consistency of the KOH/Mg mix changed substantially, becoming more ‘homogeneous’ presumed due to break down of KOH flakes. Then the refluxer started failing and I carried on without it.



At 15.00 I reached 190C with a nice boil and started gradually adding the t-amyl alcohol (2-methyl-2-butanol, BP 102C) over a period of about 15 mins.

At about 15.15 the reaction mix reached 200C. Toggling the gas mark slightly between to settings I managed to keep the temperature quite constant and close to 200C:



Heating to 200C was maintained till 16.00. I saw no perceptible changes in the white/grey mass and no globules of K appeared.

Failure may be due to:

1. t-alcohol distilling off: no K t-amylate formed
2. oxygen: seems rather unlikely; there was a net outflux of solvent vapour all the time
3. magnesium: pok’s is about my size but it has very clearly considerably more surface area: mine’s basically small irregular little cubes. For a solution/solid type of reaction high surface area could be crucial to achieve some rate of reaction
4. t-amyl instead of t-butyl
5. other.

The stuff is now cooling down and a sample of the cold solid matter will be examined for evidence of elemental K. If none is found I may add a considerable amount of t-amyl alcohol and reboil.

Quote: Originally posted by woelen

The reaction with Mg/Al is more vigorous than with Mg alone.

Quote: Originally posted by len1

Potassium reacts with tButanol, this I have done many times to give KOBu. Water is generated. Since it is gasesous at the reaction temperature it should vaporise. The t-Bu actually consumes potassium.

Quote: Originally posted by len1

It cant be that grinding the KOH allowed it to absorb too much water in my experiment because commercial KOH is 10% water anyway.

Yes. But maybe during grinding you raised the water content from 10% to 20% .

Quote: Originally posted by len1

You can get it anhydrous by holding at 450C for extended periods but the experimenter nor the patent mentions nothing on this. It can only be stored anhydrous in hemetically sealed (not ordinarily capped) bottles, and again there is no mention of this.

Quote: Originally posted by len1

And then I have niggles about the potassium. Judging by the dimensions given we have well nigh 4 grams on the photo. If its all from that one run (it seems to have come from the one flask where you see it), its a near 100% percent yield for the reaction, which is well nigh impossible. It must have been from several runs.

Quote: Originally posted by len1

Then potassium in D70 (I have been making it other ways, but with a 20L bucket of the stuff left around from this failed experiment I have used it to clean potassium) attracts all kinds of crap to its surface, and needs extensive puryfing. Yet here its absolutely clean. Thats even more amazing for me that it grows into such large globules.

Quote: Originally posted by len1

Then potassium has weak surface tension and all my globules, larger than about 0.5 are flatenned.

My largest balls were about 3 cm in diameter. Even these were almost round and not flattened. The density of K (0.856) only is slightly higher than that of the Shellsol (0.79), so even at weak surface tension K will form balls (this is what I experienced). If your K in your Shellsol really flattens due to gravity - are you sure that you have Shellsol or potassium ?

Quote: Originally posted by len1

Finally after a few hours in shellsol D70 it acquires first a bluish and finally a purple/gray tinge. Presumbaly the photo was taken straight after formation.

Quote: Originally posted by blogfast25

Amazing you can’t get the K to coalesce in Shellsol: I thought that that would be the easy way to faking the whole thing; a dispersion of K and some plausible looking grit and just wait for it to coalesce, big juicy K blobs. It puts a hole in my falsification theory…

Quote: Originally posted by blogfast25

We may have to resort to buying some of pok's magnesium (from the stock that He Actually Used)

My magnesium isn't magic . I think, if you do it like me you will get my results as well.

I must admit that I really was very lucky since the photos from the 50ml run are those of my first procedure ever! ...if it wouldn't have worked I would probably have given up and never tried it again.

These modifications just worked at the first time:

- not grinding KOH chips
- no temperature control
- Mg of suitable surface area (size)
- no stirring

[Edited on 13-12-2010 by Pok]

Quote: Originally posted by len1

@Potassium will coalesce in D70, in fact its better in coalescing in it than in parafin because its less viscous, but only mechanically and only near its solidification point arount 64C. If you try that at higher T's the K is too visocus and the globules just slip past each other no matter how you try to push them together. Falsification - that would have to be bloody stupid because this is one of the simplest experiment one can do - especially now that stirring is not required.

blogfast25, nice that you have also done the experiment.

I still think that a highly likely cause for the failures is that as soon as the t-alcohol hits the surface if the very hot hydrocarbon, it boils of instantly. Because KOH is insoluble in these kind of solvents (at least I expect it's solubility as nearly zero), no or hardly any salt of t-alcohol can be formed, because the KOH is at the bottom of the vessel and not at the surface.

I think this could be solved by adding the t-alcohol at the surface of the KOH, adding the t-alcohol to the mixture when the reaction mixture is not yet at the boiling point (when it's hot I suspect that the K-salt of the alcohol is formed as well, maybe not as fast, but it doesn't matter as it doesn't boil away). After the K-salt is formed, this is no longer volatile, and you can start to heat up. Also some sodium or potassium salt of t-alcohol could be added to the mixture instead of the alcohol to prevent it from boiling away.

Also, maybe the water present in the KOH reacts with the K-butylate forming the alcohol (wich boils off) and KOH.
If this were true, there would be the following reaction:
H2O + t-BuOK <--> KOH + t-BuOH
As the H2O is strongly bound to the KOH (KOH will only go anhydrous at very high temperatures), t-BuOH is the only volatile component in the system and will thus quite fast be removed from the system (ok, it will be condensed, but always some is lost, eventually you will lose all). I think the only way H2O is removed from the system is by the reaction with any formed K-metal. So even if some K-metal is formed, it will react with the H2O, greatly diminishing yields. Now the question is, will Mg react with water in KOH at those temperatures, wich ofcourse also depends on the contact of the KOH and Mg, wich is likely to be very small (unless you use very fine powdered Mg), having two solids.

Maybe a reason for the succes of Pok is that he used very efficient condensing (wet towels) preventing escape of alcohol, while the other reaction (formation of K, followed by reaction with water) removed all H2O before all t-alcohol was removed from the system. So I recommend very efficient condensing. Or better use dry KOH (so fuse at high temperatures for some time (nickel crucible or maybe steel)), cool down while covered, and immediately transfer the dry KOH to the flask filled with Shellsol D70, wich is dried with some Na. if you want to work really dry, you could transfer the crucible with fused KOH to a clear plastic bag, together with flask containing the dry Shellsoll D70 and a small amount of P4O10 to dry the atmosphere, and close the bag. Then transfer the KOH to the Shellsol. Or you can use a glovebox

I am only looking for reasons why it doesn't work most of the time, so some might be wrong, but i think the reason is the H2O in KOH, wich is strongly bound to the KOH, thus shifting the equillibrium to the right side of the above equation.

Woelen, I think your experiment confirms the formation of potassium, but we don't know how much. If you try it again, and you can't extract potassium out of the mixture can you try to determine how much K is in there by covering the mixture with some inert solvent (ligroin) and adding some isopropanol . If it is present hydrogen will be produced in a safe manner, and you can collect the gas formed in a inverted cylinder and calculate the amount of potassium present. If this is a acceptable amount, you can focus on a way to isolate it from mixture. Trying to collect something if you don't know how much there is (maybe it's only a very small amount of K) makes no sense.


[Edited on 13-12-2010 by Jor]

Quote: Originally posted by len1

Pok I think you have misunderstood me. That KOH contains 10% water is not a reflection on anyones skill in handling chemicals, its just a fact of this world. I have ground and not ground KOH many times, the water content is always in the 10-12%

Quote: Originally posted by len1

As for potassium, if its perfectly round and not flatenned at 3cm diameter its not pure potassium, which would be the case if KOH was contaminated with even 10% NaOH, changing its properties drastically.

"Perfectly round"? Who claimed that?? I said that my largest balls were "almost round". You can see it here http://www.versuchschemie.de/upload/files3/64730229_4948.jpg
Not pure potassium?
My KOH is techn. pure. It will contain much much lesser than 5% Na. A probable worst case alloy of 95% K and 5% Na wouldn't affect the density so much that it could form round balls instead of flattened balls. And even if it would effect it: Na is more dense than K: so an alloy would most probably be even more flattened than pure K. My produced K burns with a brillant purple flame without any trace of yellow Na light. It has a melting point of exactly that of literature potassium (+-1°C for measurement reasons). An eutectic alloy of Na an K has a melting point below room temperature! Sodium impurities would strongly decrease the melting point. Sodium also isn't produced as easily as potassium in this method (see examples for sodium in the patent). I'm sure my K contains 0.00% Na ...OK, maybe 0.01% Na.

Quote: Originally posted by len1

A 70-80% yield from a solid state reaction? - that I do not believe.

Quote: Originally posted by len1

You can only get this if its a liquid-solid interaction

Quote: Originally posted by len1

What are these 3cm balls of K you talk about?

Quote: Originally posted by len1

Thats about 14gms - yet you claim you made 3gms?

Quote: Originally posted by len1

The other times you ran the reaction you say you only got small globules. That means you must have coalesced them, yet it is clear from what you write that you do not know how to do that.

Quote: Originally posted by len1

Then why are the K balls perfectly shiny?

Nice, uh?

Quote: Originally posted by len1

The reaction produces water too.

Quote: Originally posted by len1

And fine MgO which should stick to the K surface like glue.

Quote: Originally posted by len1

Then I have made potassium t-butoxide before, its solubility in hexane is tiny - in D70 even less

Quote: Originally posted by len1

Probably the round shiny balls we are seeing are woods metal.

Yeah. Probably, probably, probalby....probably you made some mistakes in your experiment???

--- I try to answer questions. But if your next question is "Is this really an erlenmeyer in which you did the reaction? I assume its a tea cup" - then I will not answer anymore. For me, this is a waste of time. I wanted to give the people on versuchchemie a new method for potassium synthesis. I was INVITED to come to sciencemadness. I said "OK" - But if you, by all means, just want to believe that I made a hoax - I don't care anymore. You will be able to get my results if you simply simply do what I did. Some of you will do this and then I can go home ---

[Edited on 14-12-2010 by Pok]

Quote: Originally posted by len1

A 70-80% yield from a solid state reaction? - that I do not believe. You can only get this if its a liquid-solid interaction which my previous experiments preclude - because stirring would aid the reaction in that case. It would only hinder it if this is a solid-solid reactio.

Quote: Originally posted by condennnsa

I think woelen proved beyond a doubt that this reaction yields potassium. Eversince I first read Poks synthesis on versuchschemie, I believed it's real . The reason I had was because he said at the end "I am extremely proud of my so easily and cheaply produced potassium and expect praise!! " I reckon a forger would not say this

Quote: Originally posted by blogfast25

One way forward would be for pok to make available the two most variable ingredients in Goldilock's Mix: the magnesium and the KOH.

Do I understand this correctly: you want me to send you some of my Mg and KOH? If yes: I could do it (send me some money for shipping! ). But you shouldn't waste your money for shipping costs. I'm absolutely sure any 98-100% Mg of suitable size will do it. And I got my KOH from ebay. Any good technical KOH will do it, I'm sure. The patent doesn't specify the purity or size of KOH / Mg. This indicates that there isn't any hidden and difficult mechanism with other catalysts than t-butanol. I think the mechanism is absolutely simple: somehow the mechanism that you (blogfast25) assumed once.

I really made it some times successfully. And therefore I can't imagine that the experiment depends on a special method or so:

most important:
- avoid oxygen
- add the t-butanol gradually (within 30 min)
- ensure totally reflux of t-butanol
- stirr occasionally, not continiously
- don't grind KOH chips, add them as they are (qickly taking, weighting and putting into shellsol/Mg mix - to avoid water absorption from air)

and:
- use t-butanol (quite pure)
- use shellsol D70 (quite pure)
- use 20-50µm Mg (quite pure)

PS: I'll be back next year or so - or if I see the first pictures of large K balls here . I think my presence isn't needed anymore. Read the patent, read versuchschemie.de, read here: you will do it - if I forgot about this thread: keep me in mind as the hero who gave you somehow the "gold of the hobby chemists". - have a nice chrismas ....

[Edited on 14-12-2010 by Pok]

Quote: Originally posted by len1

Potassium balls that size are not even 'nearly round '.

@len1: Please do not say Pok is a troll. Let's keep this constructive My experiment at least shows that K-metal can be made. Now we need to find a method to make it more effective and to have the K-metal clump together into balls. Remember, we are talking about making K-metal, something which is not supposed to be easy at all. So, I am determined to put more effort in this to find out how this can be optimized.

Your remark about a solid-solid reaction is correct, but I agree with Pok that this does not need to be a solid-solid reaction. In my experiment I saw the KOH liquefying when the temperature went through 200 C or so. The Mg touches the somewhat liquiefied KOH (I actually think it is a liquid layer around the solid material, the liquid maybe some K-butoxide and KOH mixed). So, occasional stirring helps, bringing fresh Mg to the KOH, but constant stirring does not help, because then the Mg particles float around in the paraffin oil and do not get in contact with the KOH/K-butoxide.

Another reason why occasional stirring might help is that it brings back t-butanol in solution. In my experiments I noticed formation of droplets, sticking to the glass (you can see that in one of the pictures I made) and when you shake, then these droplets again are brought into the solution again.

I am eagerly waiting for my ShellSol D70 to arrive. I still did not receive it, while the order already was confirmed by Kremer-Pigmente last Friday When it arrives, I will exactly copy Pok's experimental setup, using my 65...100 um magnesium powder and then I'll let it reflux for 4 hours or so. If this setup still does not work, then maybe we should consider purchasing some of Pok's Mg-metal, but for the time being I am inclined to believe that any source of decent quality Mg, any source of decent quality KOH and any source of t-butanol should do the job. I indeed think that the size of the magnesium particles is critical and that this is the hard part of this, simply because Pok made the particles himself from larger pieces of Mg-metal.

This is what I expect the reaction to look like at the end even if it where successful yet poks reaction displayed no precipitate,



It is the results of Peters first experiment you can see what I would expect and that is a flask full of Magnesium hydroxides(oxides?) precipitate. You suggested it was a weak argument but im not so sure im as easy to convince and even less so now that I see an experiment repeating poks that looks the way I would expect it to.

I wish he had taken pictures of the so called formed K that came up with the addition of IpOH at the end so I could come to something more conclusive.

Quote: Originally posted by blogfast25

@Sedit: Hmmm… looks to me that Peter’s precipitate is simply more floccular than pok’s but what does that mean or prove to you?

Quote: Originally posted by blogfast25

The bottom gunge does look quite different from what magnesium powder/sand is supposed to look like but photos are notoriously deceptive in these circumstances.

Quote: Originally posted by len1

Destructive is when you try to bring another persons argument down with no good reason. And there is plenty of this around here. However when a person is lying to you, its constructuve to put an end to it.

Quote: Originally posted by Pok

I'll be back next year or so - or if I see the first pictures of large K balls here . I think my presence isn't needed anymore. Read the patent, read versuchschemie.de, read here: you will do it - if I forgot about this thread: keep me in mind as the hero who gave you somehow the "gold of the hobby chemists".

Quote: Originally posted by Len1

and you can see the reason for his desire to quickly disappear from here.

Next year = 2 weeks of Christmas vacation. Perhaps pok is going sailing in the Caribbean.

Quote: Originally posted by len1

The reasomn the nuggets are flattened in D70 is that at its solidification point the density of K rises to about 0.89

Quote: Originally posted by len1

that of D70 is about 0.75

Quote: Originally posted by len1

- a differential of 0.14 gm/ml.

Quote: Originally posted by len1

As you can see 3cm 'nearly round' globules are impossible in D70.

Quote: Originally posted by len1

So a merry troll Xmas to Pok, and you can see the reason for his desire to quickly disappear from here.

Quickly? I've answered ANY question here. Even strange ones. Merry troll Xmas to you as well, len .

@ woelen

Quote: Originally posted by woelen

If this setup still does not work, then maybe we should consider purchasing some of Pok's Mg-metal

Quote: Originally posted by Sedit

Its not so much that Poks precipitate looks off what strikes me as odd is the complete lack there of. [...] The more I look at it [...] It just looks like [...] I don't see [...]

Quote: Originally posted by Sedit

I don't see a change in the KOH

Quote: Originally posted by len1

hes having a great time watching you all.

No. I'd rather see my experiment reproduced. You shouldn't be so aggressive only because I did the experiment successfully where you made mistakes. Everyone makes mistakes. Even me (remember my not willing to coalesce tiny K globules).

Quote: Originally posted by len1

a person who knows not the difference between water of crystalization locked inside a dry powder and water picked up from the atmosphere by a deliquesent substance

You really must be joking now . I told you at the first time: I know that techn. KOH contains water. I also said: thats why hydrogen is evolved before t-butanol is added. I said "But maybe during grinding you raised the water content from 10% to 20%."

Quote: Originally posted by len1

categorically state that this is a solid-liquid reaction, without having shown any inclination towards theory

Quote: Originally posted by len1

He did this of course to get out of a tight situation in what he thought would be the best way he could.

Quote: Originally posted by condennnsa

Pok, if you are truly genuine, you have the responsibility to stick with us all the way

Quote: Originally posted by Magpie

Next year = 2 weeks of Christmas vacation. Perhaps pok is going sailing in the Caribbean.

No. I'm just bugged by questions I already answered . Or by statements which don't deserve an answer (e.g. "woods metal"). Caribbean would be nice - but Xmas without snow? .

Quote: Originally posted by len2

Here's my advice:

Quote: Originally posted by len2

Learn to read english sentences

I'll try it. And you please learn german ...and hindu .
The only sentence I can imagine what youre aiming at is len1's statement that I don't know the difference between "water of cristallization locked inside a dry powder" and a "wet" compound. I know that KOH can contain water of crystallization. But it doesn't matter in which form the water is in the KOH. KOH * H2O also absorbs water from the air and forms KOH * 2H2O or even KOH * 4H2O. The amount of H2O molecules will increase in bought KOH (containing a little KOH*H2O) if you don't handle it as fast as you can (not grinding) while keeping it in air (e.g. for weighting). It can take up to 4 molecules of water (wikipedia says) and will still look dry. THAT (more or less) may have happened during grinding in len1's case.

If I remember correctly, len1 said that both the unchanged and the ground KOH contained 10-12% water. I really have doubts about that. You can't grind KOH in air without raising its water content because air contains water and KOH is highly hygroscopic. A question to len1 would be: (how) did you measure the water content? and how long did you let the KOH remain in air (how long did you grind)?

Quote: Originally posted by len2

check the density of potassium en.wikipedia.org/potassium

It says:
"Liquid density at m.p.: 0.828 g·cm−3" - my 0.07 difference compared to shellsol D70 therefore should be lowered to 0.03 or so - I therefore should thank you for your advice

Quote: Originally posted by len2

learn about the behaviour of density for most liquids with temperature

Quote: Originally posted by len2

stop trolling, and leave these people alone.

stop being aggressive without arguments. this is poor.

[Edited on 15-12-2010 by Pok]

[Edited on 15-12-2010 by Pok]

Quote: Originally posted by len1

An approximate formula for the height of globules is h = sqrt(2 * surface tension/(g * density differential)) giving about 0.5 cm, in rough agreement with my results.

I must admit that I don't know this equation (as I'm not a chemist I don't have to know it ...but its interesting...you always learn) and therefore I don't know whether it is correct. It looks plausible to me. But: where do you got the value (which you didn't show us) of surface tension of K? And: isn't it also dependent on the sourrounding medium? (I only remember water tension which shows differences if its pure or when soap is added) - where do you got this value from?

I rearranged the equation to get your value. If your "g" is 9.81, it should be: 0,0171675 N/m. -> where do you got this from?
After (hopefully correct) recalculating it (0.036 (more exactly than 0.04) instead of 0.14 density difference), it would still only be 0.99 cm height.

possible reasons (because my balls in ca. 3 cm dimensions were nearly round):

- surface tension value isn't correct
- equation isn't correct (or another factor is needed to include the medium properties (shellsol) on surface tension)
- K and Shellsol have even much lower difference in density*
- something I don't know

*the difference in density of K and Shellsol would have to be 0.005 instead of 0.036 to let the potassium height rise up to 2.6cm (if surface tension and equation are correct) - a value quite imaginable in my case. I'm quite sure about the K and Shellsol densities. But the difference of 0.005 and 0.036 only is 0.031 - maybe the densities change in a different way at high temperatures (esp. that of the Shellsol - maybe decreasing in a much lesser extent (or even increasing?) than that of K)- and/or the surface tension or equation may not be correct.

-> I suspect both: (1) different density change at rising temperature and (2) surface tension value is not correct (my calculation based on a rounded figure (0.5cm) based on a probable estimation (?) of surface tension by you).

BTW: you talked about "0.5 cm, in rough agreement with my results" - and I also think you said that you've observed liquid K in Shellsol D70 - I showed you my "balls" - would you like to show me your "balls" now?

[Edited on 15-12-2010 by Pok]

Quote: Originally posted by len2

I see from the general gist of what you are saying and your mistakes

Quote: Originally posted by len2

that you have no idea what potassium does near its melting point.

Quote: Originally posted by len2

You have never worked with it have you?

What a nice question. Everyone shall think that YOU of course did work with it. Am sure you never did. I really think that YOU have never SEEN it.

Quote: Originally posted by len2

Thank you and goodbye

You don't have to thank me. I didn't do it for you .

Quote: Originally posted by len2

Here's my advice: Learn to read english sentences check the density of potassium en.wikipedia.org/potassium learn about the behaviour of density for most liquids with temperature stop trolling, and leave these people alone.

@len2: Please stop flaming! I now have seen enough of it and I am getting tired of it. Whether Pok's results are real or fake is not up to you as long as you don't have any real evidence. All the equations and numbers you are bringing with you do not do justice to Pok's work.

From now on I want to see decent scientific discussion and no more flaming. Further flaming will be removed. Only scientific arguments against or in favor of Pok's experiments are accepted from now on. I really do not want this interesting thread to see derailing into an ordinary flame war.

The fact that no one could reproduce Pok's results for the time being is not an indication of trolling or faking. As Pok has written, no one did the experiment as he did. I am in the process of doing so (waiting for my ShellSol D70) and I think in the next week or so more people will try that when their chemicals arrive. Let's see what all those attempts bring us and then we have new results to base our judgements on.

Let experiments say the final words and not one's adrenalin or hormones

Quote: Originally posted by len1

Destructive is when you try to bring another persons argument down with no good reason. And there is plenty of this around here. However when a person is lying to you, its constructuve to put an end to it. Im used to getting crap from students, although unlike here most of them do it honestly - beating about the bush in that instance is only superficialy constructuve. It actually harms people in the long term. Same here. Further posting a lot of stuff about this before you have been able to reproduce his wonderful balls of K only serves to encourage future trolls - hes having a great time watching you all. Regarding the liquid-solid reaction, its interesting that a person who knows not the difference between water of crystalization locked inside a dry powder and water picked up from the atmosphere by a deliquesent substance, would suddenly categorically state that this is a solid-liquid reaction, without having shown any inclination towards theory before that statement. He did this of course to get out of a tight situation in what he thought would be the best way he could. [Edited on 15-12-2010 by len1]

What woelen said… Totally seconded. Even if all this peters out we’ll still have had some fun, IMHO…

I conducted a simple side experiment to try and show reactivity of 2-methyl-2-butanol (2M2B) (as a substitute for t-butanol, in the post) with KOH, NaOH, Mg ‘powder’ and Al.

About 4 ml of 2M2B was subjected to 1 g KOH (tube 1), 2.6 g NaOH (tube 2), 0.2 g Mg (tube 3) and 0.3 g Al (tube 4):



All were subjected with regular 'shaking' to 30 mins of steambath, average temperature about 97C, just below 2M2B’s BP of 102C:



Here are the tubes after wiping dry and cooling:



First off, tube 5 (previously not shown) which is KOH with methylated spirits (EtOH with small amount of MeOH) after boiling. KOH dissolves effortlessly and completely in this solvent to a slightly yellow solution of presumably KOEt, KOMe, EtOH + MeOH and some water. As stated higher up by Nicodem.

Tube 1: KOH and 2M2B started discolouring right way and this continued right throughout the test. But I can’t say whether or not significant amounts of KOH reacted with the 2M2B. 'Something happened'...

Tube 2: similar to tube 1 but less intense discolouration.

Tubes 3 and 4: no reaction or visible change with either the Mg or Al.

It would be tempting to see if 1 and 2 contain some resp. K or Na 2-methyl-propa-2-oxyde but that's not so easy to do. But if any reaction took place it is certainly not comparable in scale to the dissolution of KOH in ethanol/methanol.


[Edited on 15-12-2010 by blogfast25]

Quote: Originally posted by MagicJigPipe

I must take issue with this. Pok doesn't have the responsibility to do shit but post his experiment in the best way that he could.

dissolution of K in t-BuOH

adsorption of K onto Mg surface

Quote: Originally posted by Sedit

It is the scientist goal to prove the experiment at hand not the peer reviewers. its up to the "inventor" to justify his claims or take a hike.

Quote: Originally posted by Sedit

would it kill the fellow to show it reacting in water?

Quote: Originally posted by Sedit

or even physically prove he even has access to t-BuOH?

I could give you a picture of the t-BuOH in the original container - its a crystalline solid at room temperature but very easily supercools (at least in the purity I used) and can thus remain liquid. I also could send you an amount of 1 gram t-BuOH or so. Although this also wouldn't prove anything.

@ watson.fawkes
If my experiences are welcome (although considerred sceptically) I will give some comments about this - otherwise (e.g. not believing me) just ignore me .

Quote: Originally posted by watson.fawkes

If you've got micron-sized Mg particles, I can easily see how its entire surface might become passivated by a layer of K that has not yet merged. On the other hand, a chip or shaving has enough surface area that product K will bead up on the surface, not only increasing its characteristic globule size, but also exposing new Mg surface

Quote: Originally posted by NurdRage

Yeah, I definitely heard that distinctive woosh sound. good to know i'm on the right track. i'll see if i can get larger quantities. The amount of grey gunk produced is staggering, i honestly wonder if its possible to get nice balls of potassium. Thanks for your help.

Quote: Originally posted by len1

Quote: A warning is not sufficient in such cases. Immediate banning is the only thing which works with trolls and this definitely is a troll Who wrote this?

I fully stand behind these words, a real troll must be banned straight away and the guy from that old 2008 thread definitely was a troll. But who's trolling now in this potassium-thread ?
Instead of spending your time on searching and digging up old and off-topic info, you'd better spend your valuable time on replicating Pok's experiment

[Edited on 16-12-10 by woelen]

Quote: Originally posted by Pok

The point with Mg chips or shavings seems very probable to me: I don't think that K builds a layer on the Mg (chips or shavings). After about 20 mins of t-BuOH addition the first K was visible in realy tiny beads. They indeed were attached to the Mg shavings but didn't cover their entire surface. It looked like water drops on a leaf.

Quote: Originally posted by NurdRage

My solvent in this particular run was white candle wax. Yeah, I definitely heard that distinctive woosh sound. good to know i'm on the right track. i'll see if i can get larger quantities. The amount of grey gunk produced is staggering, i honestly wonder if its possible to get nice balls of potassium. Thanks for your help.

Quote: Originally posted by blogfast25

Can you please describe your experiment in much greater detail?

Quote: Originally posted by watson.fawkes

To your best estimate, what was the smallest diameter of the beads of K that you saw? I would surmise that they were somewhere in the 0.1 - 1.0 mm range, but I'd prefer your first-hand account. Thanks in advance.

Quote: Originally posted by NurdRage

In hindsight, i should have added the stirbar first and stirred the mixture while it was heating. candle wax doesn't boil at 220 celsius so there was no self-stirring.

I've been following.

Which is why i didn't do any stirring at first. But i failed to take into account that candle wax doesn't boil near the temperatures we want. Without that self-agitation i'll need to put in some external agitation.

Anyway, i'm looking into various solvents. While i can order anything, i want to stick to the solvents most amateurs have easiest access to. Candle wax is probably the easiest highest boiling solvent, although very far from ideal.

i'm working on it