woelen
Super Administrator
Posts: 8014
Registered: 20-8-2005
Location: Netherlands
Member Is Offline
Mood: interested
|
|
A new riddle
This is a very simple experiment and easy to obtain common chemicals are involved, but still this experiment puzzles me. When S2O8(2-),
peroxodisulfate, and hydroxide ion are mixed, then a yellow compound is formed.
This compound only appears at very high concentrations of hydroxide. I made a little web page about this.
http://woelen.homescience.net/science/chem/riddles/persulfat...
[Edited on 22-1-12 by woelen]
|
|
plante1999
International Hazard
Posts: 1936
Registered: 27-12-2010
Member Is Offline
Mood: Mad as a hatter
|
|
I suspect the yellow compound to be en intermediat in peroxodisulfate reduction to O2 and Na2SO4.
I never asked for this.
|
|
unionised
International Hazard
Posts: 5126
Registered: 1-11-2003
Location: UK
Member Is Offline
Mood: No Mood
|
|
I can't think of a mechanism off hand but superoxide ions are the right colour and have the right elements present.
http://en.wikipedia.org/wiki/Superoxide
They are also unstable so that fits too.
Do you have an ESR spectrometer handy?
[Edited on 22-1-12 by unionised]
|
|
Huk40
Harmless
Posts: 9
Registered: 10-10-2010
Member Is Offline
Mood: No Mood
|
|
I had similar experience with sulfur compounds.Onto a little pile of Resorcinol i added dropwise H2SO3.A compound with a yellow color formed.After
addition of water da yellow color dissapeared.
PS:If it would be any help.
|
|
kotze
Harmless
Posts: 5
Registered: 22-1-2012
Member Is Offline
Mood: No Mood
|
|
This could be sodium ozonide. It has been prepared from solid NaOH and ozone and is relatively stable at room temperature; it is described as a yellow
to red compound. You could try treating dry NaOH with ozone and see if the resulting compound has similar properties.
|
|
unionised
International Hazard
Posts: 5126
Registered: 1-11-2003
Location: UK
Member Is Offline
Mood: No Mood
|
|
Ozone is a known by-product of the decomposition of hydrogen peroxide so that's possible.
|
|
AndersHoveland
Hazard to Other Members, due to repeated speculation and posting of untested highly dangerous procedures!
Posts: 1986
Registered: 2-3-2011
Member Is Offline
Mood: No Mood
|
|
The yellow color is probably due to the transient formation of radicals, either superoxide ions, ozonide, or possibly sulfate radicals.
Quote: |
A mechanism for the base activation of persulfate [involves] the base-catalyzed hydrolysis of persulfate to hydroperoxide anion and sulfate followed
by the reduction of another persulfate molecule by hydroperoxide. Reduction by hydroperoxide decomposes persulfate into sulfate radical and sulfate
anion, and hydroperoxide is oxidized to superoxide. Stoichiometric analyses confirmed that hydroperoxide reacts with persulfate in a 1:1 molar ratio.
Addition of hydroperoxide to basic persulfate systems resulted in rapid decomposition of the hydroperoxide and persulfate and decomposition of the
superoxide probe hexachloroethane. The presence of superoxide was confirmed with scavenging by Cu(II). Electron spin resonance spectroscopy confirmed
the generation of sulfate radical, hydroxyl radical, and superoxide.
Mechanism of base activation of persulfate. O.S. Furman, A.L. Teel, R. J. Watts, Department of Civil and Environmental Engineering, Washington
State University, Pullman, Washington, USA.
|
Decomposition of peroxide compounds in a wide variety of reactions are known to produce several different reactive radicals. Ozone is a known
byproduct of the decomposition of persulfate.
Quote: |
Formation of Ozone from Peroxides
28 grams of ozone per cubic metre of oxygen evolved, by gently heating small quantities of powdered barium peroxide in eight times its volume of
concentrated sulphuric acid. Hydrogen peroxide is likewise formed in small quantities under these conditions. The same investigator showed that
similar results were obtained with other peroxides, notably those of magnesium, zinc, sodium, and potassium.
Formation of Ozone from Persulfate
By the thermal decomposition of the persulphates, small
quantities of ozone are likewise disengaged, Malaquin (" J.
Pharm. Chem.," VII, 3, 329, 1911) gives the following details
for the preparation of ozonised oxygen by this means.
Twenty gms. of dry and freshly prepared ammonium persul-
phate are mixed with 15 gms. of nitric acid in a small flask;
the air is subsequently displaced by carbon dioxide, and the
mixture cautiously raised to 65° to 70° C. The reaction,
which is strongly exothermic, proceeds somewhat vigorously
when once started, and the resulting oxygen, after removal
of the carbon dioxide, contains 3 to 5 per cent, of ozone and
small quantities of nitrogen.
|
I have never read this anywhere. Do you have a reference?
[Edited on 23-1-2012 by AndersHoveland]
|
|
unionised
International Hazard
Posts: 5126
Registered: 1-11-2003
Location: UK
Member Is Offline
Mood: No Mood
|
|
It was in a very old text book of my dad's.
|
|
woelen
Super Administrator
Posts: 8014
Registered: 20-8-2005
Location: Netherlands
Member Is Offline
Mood: interested
|
|
In the meantime I did some experiments with peroxodisulfate. One thing which I conclude from these experiments is that no hydrogen peroxide or
peroxide is formed from peroxodisulfate. Some experiments which lead to that conclusion:
1) Peroxodisulfate does not lead to formation of dark blue complexes based on CrO(O2)2 with dichromate in acidic solution, nor to formation of
red/brown peroxo complexes based on Cr(O2)4(3-) in alkaline solution. You get simply orange dichromate or yellow chromate.
2) A strongly alkaline solution of Na2MoO4 turns deep yellow when dilute hydrogen peroxide is added and this becomes very dark red/brown when the
concentration of hydrogen peroxide rises above a few percents. With peroxodisulfate the solution remains colorless, regardless of concentration.
3) Alkaline peroxodisulfate is capable of instantaneously oxidizing of light green Ni(OH)2 to a black solid, probably hydrous NiO2 or hydrous Ni2O3.
When hydrogen peroxide is added to Ni(OH)2, suspended in a solution of NaOH, then nothing happens. On the other hand, when peroxide is added to a
suspension of the black material in alkaine solution, then it immediately looses its color and becomes light green again, so peroxide and the black
nickel compound cannot coexist.
Based on experiments (1) and (2) one can conclude that peroxodisulfate does not decompose to hydrogen peroxide and sulfate or bisulfate, not in
alkaline solution, nor in acidic solution, otherwise I would see peroxo complex of chromium or molybdenum.
Based on experiment (3) I come to the conclusion that peroxodisulfate gives an amazingly strongly oxidizing species in alkaline solution of sufficient
high pH. This species must be an even stronger oxidizer than peroxodisulfate itself, because peroxodisulfate in acidic or neutral solution is not
capable of oxidizing nickel(II) to an higher oxidation state.
The yellow species as mentioned in my first post might be the strongly oxidizing species I found in experiment (3). I have looked up some information
and ozonide might be a candidate. This ion is unstable, but it can exist for some time, also in contact with water. Superoxide does not seem to be a
candidate to me. Superoxide decomposes in water immediately and gives hydrogen peroxide as one of the decomposition products. I would have noticed
that with the dichromate and molybdate experiments and this also would not lead to the formation of the black compound with nickel(II).
[Edited on 23-1-12 by woelen]
|
|
AndersHoveland
Hazard to Other Members, due to repeated speculation and posting of untested highly dangerous procedures!
Posts: 1986
Registered: 2-3-2011
Member Is Offline
Mood: No Mood
|
|
The decomposition of peroxydisulfate under alkaline or acidic conditions only leads to formation of oxygen, but hydrogen peroxide can be
formed if concentrated sulfuric acid is used.
|
|
AndersHoveland
Hazard to Other Members, due to repeated speculation and posting of untested highly dangerous procedures!
Posts: 1986
Registered: 2-3-2011
Member Is Offline
Mood: No Mood
|
|
The decomposition of peroxydisulfate under alkaline or acidic conditions only leads to formation of oxygen, although hydrogen peroxide can be
formed if concentrated sulfuric acid is used.
|
|
woelen
|
Thread Pruned 23-1-2012 at 14:08 |
kmno4
International Hazard
Posts: 1497
Registered: 1-6-2005
Location: Silly, stupid country
Member Is Offline
Mood: No Mood
|
|
Your yellow something is surely Na2O2. Its hydrate (x8H2O, colourless) can be prepared from 30% H2O2 and NaOH(aq) + ethanol (see Inorg. Synth.)
Again, I would suggest giving amounts in "mg" or "g", because "spatula" means nothing.
One must remember that reduction of S2O8(2-) gives HSO4(-) and it cause self-propagating, exothermic reaction with NaOH (releasing O2) in
concentrated solutions.
I would try experiments with mixing cold, concentrated (~20-30%) solutions, with additional ice bath during addition of NaOH to Na2S2O8 (or vice
versa).
|
|
woelen
Super Administrator
Posts: 8014
Registered: 20-8-2005
Location: Netherlands
Member Is Offline
Mood: interested
|
|
I do not agree with you that it surely must be Na2O2. I have some reagent grade anhydrous Na2O2 and its color is much lighter than what I observe. See
wikipedia for a picture of a sample of my Na2O2.
And also have a look at the experiments I did with dichromate, molybdate and nickel(II). I described these in my previous post. All these experiments
evidently show that no peroxide is formed. The color must really be due to some other compound.
|
|
kotze
Harmless
Posts: 5
Registered: 22-1-2012
Member Is Offline
Mood: No Mood
|
|
This is certainly sodium ozonide. "The inorganic ozonides" by Petrocelli and Chiarenzelli sheds some light on these fascinating compounds. Alkali
ozonides (or "ozonates") are known to be formed from cold alkali hydroxide solutions and ozone, the color ranging from yellow to red-brown. Even
cooled ammonia solution shows dark red coloration when treated with O3. Solid ozonides have been prepared from moist(!) alkali hydroxides and ozone
gas at room temperature. There're conflicting reports on the stability of sodium ozonide, ranging from full decomposition within a few days to showing
now signs of decomposition after 18 month of storage @RT. The presence of moisture is deemd to be essential to the formation of ozonide, and in the
case of tetramethylammonium ozonide, the presence of impurities actually increased(!) its stability. Solid ammonium ozonide (one scary fellow for
sure!) is stable only at -126°C.
It is known that persulfate thermally decomposes yielding ozone gas, and it is quite possible that this is through some ozonide, O3- intermediate.
Even "ozonic acid", HO3, seems to exists, as cold water treated with ozone colours blue litmus red and increases electrical conductivity.
|
|
AndersHoveland
Hazard to Other Members, due to repeated speculation and posting of untested highly dangerous procedures!
Posts: 1986
Registered: 2-3-2011
Member Is Offline
Mood: No Mood
|
|
http://pubs.acs.org/doi/abs/10.1021/ja01151a024
The question is whether the decomposition of persulfate under alkaline conditions liberates any ozone.
|
|
Panache
International Hazard
Posts: 1290
Registered: 18-10-2007
Member Is Offline
Mood: Instead of being my deliverance, she had a resemblance to a Kat named Frankenstein
|
|
Do you have reference for this or if not was the result through infernence or actual collection or direct reaction of the ozone. In otherwords can it
be used as a convienent ozone source as i have a couple kilos of the persulfate sitting around bored in the dark and i am quite sick of it emailing me
constantly asking for something to do.
|
|