Hypochlorous acid can exist even in conc. HCl?

First of all, I want to wish you all a lucky, succesful and interesting new year I started the new year with a simple but interesting set of experiments and learned something new (at least for me).

While doing an experiment on manganese chemistry I found a remarkeble thing. Manganese(II) in conc. HCl is not converted to a dark solution with chlorine gas, nor with TCCA. But when a solution of manganese(II) is mxied with a solution of calcium hypochlorite in conc. HCl, then the liquid quickly turns dark brown/green.

Here I describe a complete set of experiments, which demonstrate this peculiarity:

<url>http://woelen.homescience.net/science/chem/exps/exppatt.cgi?compound=manganese%20chloride%20tetrahydrate</url>

Is it really the HOCl in concentrated HCl which makes this reaction possible? I always had the impression that HOCl cannot exist in HCl, certainly not in concentrated HCl.




[Edited on 2-1-09 by woelen]

According to article (ACS, ja01326a002), HOCl is "stable" in strongly acidic solution.
Besides, this acid is in equilibrium with Cl2O, which can be extracted with CCl4 etc.

And the plot:

The most interesting literature I could find is from the Kirk‑Othmer Encyclopedia of Chemical Technology.
Dichlorine Monoxide, Hypochlorous Acid, and Hypochlorites.

I would do experiment - add some CCl4 to some concentrated HCl(aq) and add - with stirring and cooling - some hypochlorite* . Next I would add extracted Cl2O in CCl4 to Mn(II)/HCl(aq) mixture... Unfortunately I cannot do this - I used up all my Ca(ClO)2 long time ago

* for better "proving" existence of HOCl <--->Cl2O, hypochlorite should be added to HCl(aq) and later (after few minutes) CCl4.
Of course, question is if it work at all......

[Edited on 2-1-2009 by kmno4]

I did kmno4's experiment with extracting Cl2O and/or HOCl.

I proceeded as follows:

1) Prepare a solution of MnCl2 in conc. HCl and divide this over two test tubes.
2) Take 2 ml of conc. HCl and slowly add a spatula full of Ca(OCl)2 while swirling. Wait till the fizzling is over and the liquid is clear again. Wait one more minute. Then add 1 ml of CH2Cl2 and shake well. Let the DCM settle at the bottom.
3) Take 2 ml of conc. HCl and add a few granules of TCCA while swirling. Again, wait till most of the fizzling is over. The liquid becomes turbid (due to finely divided cyanuric acid). Add 1 ml of CH2Cl2 and shake well. Let the DCM settle at the bottom.

At this stage, there are two blobs of DCM, both clear and light green.

4) Pipette away the DCM from both test tubes and transfer the lightgreen DCM from the test tubes with the chlorine-generating solutions to the solutions of MnCl2 in conc. HCl, as prepared in step 1. The transfer of the DCM is done very carefully, assuring that no aqueous solution is transferred as well.


The result of this experiment is striking. Around the blob of DCM, resulting from step (2) a nice brown layer is formed, which on swirling makes the entire liquid look brown. The blob of DCM, resulting from step (3) does not cause any formation of brown color.

A picture is attached to show the difference. The left test tube contains the DCM, uses for extracting from the conc. HCl + calcium hypochlorite and the right test tube contains the DCM, used for extracting from the conc. HCl + TCCA. The blobs are light green/yellow. One can also see that around the blob in the left test tube, the aqueous liquid is somewhat darker than in other areas.



[Edited on 2-1-09 by woelen]

There is another nice observation. On the blob of DCM, used for extracting from the conc. HCl + calcium hypochlorite, slowly a bubble of gas is formed. It starts as a tiny speck, slowly growing to a size of a few mm, until it looses contact and goes to the surface of the liquid.

This bubble can be tapped off the blob of DCM, but after a minute or so there is a new bubble of gas. Only after a few more minutes, no new bubble was formed anymore. The picture shows the bubble of gas on top of the blob of DCM. I can imagine that this bubble of gas is oxygen, due to slowly decomposing HOCl and/or Cl2O.


[Edited on 2-1-09 by woelen]

I eagerly await your findings, Woelen!

KMnO4, that agrees with my findings. Although, from pH 3.5-12, I ruled out Cl2O. Of course, in concentrated HCl, it's anyone's guess. I'll have to get a scan and see. Unfortunately, that will have to wait until monday.

I might try this with reduced (bisulfite) KMnO4 (the only Mn salt I have handy) tomorrow. Confirmation is good.

Cheers,
\
O3



[Edited on 2-1-2009 by Ozone]

The weather is also vile here. I'll see if I can get some more DCM and I'll repeat what I can. IIRC, there was a lengthy list of experiments that you did with a link from the first post. Today, I can only find experiments 1 and 2? It would be a good idea to review the previous experiments in detail before attempting to repeat them.

Good call with the bisulfite.

Cheers,

[Edited on 3-1-2009 by Ozone]

Sorry for the inconvenience of the link. You should click experiment 2 and then you see what you used to see. I need to make a technical change to my website. Right now, all experiments have an index (the particular experiment you mean has index 517), but this index only is valid as long as the server is running. Each time when the server is restarted another index may be assigned to experiments, making all existing links to such experiments incorrect.

The technical solution to this is to have an index not pointing directly to an experiment description, but to another index, where the second index points to the experiments. This technique allows for constant URL's for experiments. It works a little bit like a Java Virtual Machine where each object has a reference to a reference, allowing moving around of objects through memory (e.g. for garbage collecting), while the most outer reference remains the same. I need some time though to make such a technical change, it is not trivial and there are more interesting things to do . If you have ever programmed in C and you have done some more advanced memory management tricks then you most likely exactly understand what I mean, and otherwise simply forget my blurp on this subject

Ah yes, if you can do absorption measurements, then surely you also have the suitable filtering equipment

I have done the experiment with DCM again. I added a pinch of solid Ca(OCl)2 to conc. HCl swirled a little and waited till all bubbling was over. Then I added the DCM and swirled again for quite some time to extract as much as possible.

Next, I transferred the DCM to a separate test tube. Half of the amount I added to a solution of MnCl2 in conc. HCl. The other half I treated with UV-A light from a blacklight tube for 2 minutes and then I added that to a similar solution of MnCl2 in conc. HCl. The DCM, treated with UV-A light lost its ability to oxidize the Mn(2+) completely, while the other half gave the same results as yesterday.

I also took Ca(OCl)2 from a totally different source, just to be sure that not a specific batch of this substance gives such a peculiar reaction, but that is not the case. I now have tried with three sources of hypochlorite (HTH 65% active chlorine, Choc POOL, 70% active chlorine, and ordinary househoold bleach). All show the same peculiar reaction.

Btw, the Choc bottle of calcium hypochlorite tells that the main ingredient is Ca(OCl)2.2H2O instead of Ca(OCl)2.

[Edited on 3-1-09 by woelen]

Interesting paper, KMnO4.

The footnote #5 indicates that "...free radical initiator or UV light had little or no effect..."

This is inconsistent with Woelen's findings which are consistent with mine. I do not think that Cl2O is involved, and the following experiments help to secure this position.

Reagents:

Chlorox Ultra, "6% NaOCl". I did not have time to standardize it via H2O2.

HCl, Mallinkrodt AR Select Trace Metal grade, 36.5-38%.

Water, Nanopure, 18.3 MOhm filtered through a 0.2um membrane. All solutions are aqueous and made using this water.

A solution of bleach was made to contain 1.2 % (DF 5) "NaOCl". Because the sealed cells were no where to be found, and I am not putting fuming acid into the spec unsealed, I made a 1:1 solution of HCl.

1. The absorbance of 1mL 1:1 HCl was measured from 190-500nm at 1200 nm/m using a Beckman-Coulter DU-800 spectrophotometer. The resulting spectrum was featureless until reaching the UV-cutoff of the 6Q cell.

2. The 1.2 % NaOCl solution exceeded the linear range of the detector by a factor of ~twenty. A scan of a dilution to 0.06% gave the expected peak at 290 nm.

3. 0.12% NaOCl adjusted from pH 11.00 to 6.75 was scanned. Note the evolution of the HOCl peak at 230 at the expense of the -OCl peak at 290.

4. To 900 uL of 1:1 HCl was added 100 uL of 1.2% NaOCl. Neither HOCl nor -OCl were detected. Instead new peaks at 223 and 324 evolved. These exceeded the detector range and so were run again at DF 10. The plot indicates a curve of this result multiplied by 2.5 for scale. Addition of EtOH caused the size of these peaks to decrease in size. The expected Cl2O peak (Marsh, et al, 1982) at 260 nm was not evident.

Conclusion:

HOCl is NOT the oxidizing species resulting from the treatment of NaOCl (which Woelen established is equivalent to Ca(OCl)2 in terms of activity) with 1:1 HCl.

The species is oxidative and is probably labile to light. 223 and 324nm are good wavelengths to use in further experiments (a mineral light with 254 and 365 will probably do).

The oxidative species is not Cl2O. The two species evolved are different from HOCl, -OCl or Cl2O. I need to scan chlorine water (unless someone has the spectrum handy).

This was a two-beer post.

Cheers,

O3

Thanks,

Yes, I am aware of this. It was still better than my pool shock with 45% "inert ingredients".

I have some 12% Na hypochlorite from Aldrich. I had previously tested this vs. Chlorox wrt. UV-VIS. The results were identical. I'll standardize both the bleach and the Aldrich material against H2O2 (standardized vs. thiosulfate *sighs*) when I get the chance.

The test sequence provided above is not too intensive and can be repeated with any number of refinements.

It would be a good idea, though, to also scan some NaClO3 for reference. I'd think that the chloride in the presence of strong HCl would be moot? Chlorite was not seen in the spectra.

I am interested in determining some stoichiometry and reactivity of the material with and without light and/or various oxidizable substrates. Of particular interest, it appears, would be toluene which we can use to differentiate between aromatic or aliphatic chlorination.

I wish I had some ethyl or propyl benzene so I could be more sure (benzyl groups tend to have their own specificity).

I do have styrene, though.

Cheers,

O3

Ozone, you lead me into depression with these maesurements.
But not beacuse of same spectra but beause of possibility of their creation. I would like it too...
I attach another literature which brings a little (green) light on your spectra.
Page no.2 is from K-O encyclopedia and reference (13) is on the first page.

Now discussion.
Cl2O exists in H2O solutions mainly as HOCl. .
But there is (fast) equilibrium Cl2O <-> HOCl and K=[Cl2O(aq)]/[HOCl]² is from 1/1000 to 1/100
(data from review cited earlier). From K-O encyclopedia:
Carbon tetrachloride (CCl4) extracts chlorine monoxide but not HOCl from concentrated HOCl solutions. The partition coefficient at 0 C for the equilibrium Cl2O(aq)<->Cl2O(CCl4) is 2.22.
2.22 is rather a small value
If you detected HOCl, then equilibrium amount Cl2O were also present, but below level of detection under these conditions.
To prove anything, measurements must be conducted in CCl4 (or something similar) extracts, not in water.
BTW footnote no.5 says about Cl2 ( a note for those who did not read paper)

[Edited on 9-1-2009 by kmno4]

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