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blogfast25
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Suitable ferric compound for redox titrations?
I want to carry out some redox titrations using Fe3+ as an oxidising agent and I'm wondering what would be the best Fe (III) compound for this
purpose, in terms of general stability, deliquescence/loss of crystal water, etc.
The choice would probably be between ferric ammonium alum (dodeca hydrate), ferric chloride (hexa hydrate, PCB etchant) or
ferric oxalate (unknown amount of crystal water, available from silverprint.co.uk), because these are the ones I can get my hands on.
Also, a standard to determine strength (precise molarity of a ≈ 0.1 M ferric titrant), preferably something OTC or home made, would be
necessary.
Any suggestions are most welcome!
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ScienceGeek
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What are you titrating against?
You don't have to answer if Iron compounds are your only source of an oxidising ion, but usually there are better oxidising agents than Iron(III) and
Iron(II).
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blogfast25
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I'm titrating against Ti3+, there Fe3+ is commonly used.
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Ozone
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It depends upon your needs, specifically pH, concentration and whether or not the counter-ion is tolerated. Also not that the reactivity of the ferric
oxidant is effected by what it is ligated to.
FeCl3 is my ferric iron of choice because it is cheap (600lb at 36% m/m was 140 USD, with freight) and has a high aqueous solubility (my oxidations
are aqueous). The down side is that the solutions are highly acidic (high HCl equivalence) and this can wreck your reaction. Any pH greater than 4.5
or so leads to the immediate precipitation of colloidal Fe(OH)3. For water treatment, this is good. For your REDOX (particularly of phenolic species)
this is bad (you products will be quite intimate with the floc).
Try Ferric sulfate as well. Both the chloride and sulfate are widely used in water treatment (cheap and readily available).
A good assay involves doing your oxidation and sampling an aliquot against o-phenanthroline (Fe2+(o-phenanthroline)3, ABS 510nm). When standardized
against Fe2+ (or Fe3+ with added hydroxylamine), this should tell you how much of your Fe3+ was converted to Fe2+ in the process (beware of pseudo
catalytic kinetics with phenolic compounds if air is present) and, hence, the extent of reaction (with knowledge of the stoichiometry).
Cheers,
O3
[edit] Oh yes, remember to assay your starting ferric compound as well. In my experience, FeCl3 at ~78,000 mcg/g made under N2 with degassed water
contains approximately 0.6-1.4 % Fe2+. This is required for background correction.
[Edited on 5-5-2008 by Ozone]
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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blogfast25
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Thanks, Ozone, but my needs are a lot simple than that: redox titration of Ti3+ in highly acidic conditions with Fe3+ (using SCN- as indicator) is a
very robust procedure for most sample situations. My purpose here is to assay thermite made Titanium metal by dissolving in HCl or conc. sulfuric and
titrometric determination of the Ti (as Ti3+) with Fe3+/SCN-. This procedure is used the world over at various stages of Titanox production (I used to
work in such a plant, but do not recall what the source of Fe3+ used was... it's over 20 years ago)
[Edited on 5-5-2008 by blogfast25]
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Ozone
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In that case, the chloride (which you can get) or sulfate should be ideal. Pick your acid .
[edit] What Woelen says, below, is true. Solutions do not keep and will eventually precipitate what looks like hydrated ferric hydroxide.
If you use FeCl3 (because it is easy to get), be sure to standardize your material before use. o-phenanthroline both with and without hydroxylamine
will give you total iron and iron(II). Make it fresh and standardize it every day.
Good luck,
O3
[Edited on 6-5-2008 by Ozone]
-Anyone who never made a mistake never tried anything new.
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woelen
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I do not agree about the chloride. FeCl3.6H2O usually is a very unreliable compound, because it is deliquescent and the amount of water in the
commercial stuff is highly variable. I have seen the PCB etchant stuff, which was perfectl dry and rather dark brown, and I have seen wet stuff of a
mustard-like color, and even solutions of variable concentration.
The salt FeNH4(SO4)2.12H2O would be the best option if you can obtain that.
Ferric oxalate is an even worse choice than ferric chloride, it is not a true oxalate, but a rather messy complex, containing oxalato-aqua coordinated
iron(III). Actually, ferric oxalate is not a well-defined compound, similarly like ferric ammonium citrate, which also is not a well defined compound.
Thye compound ammonium ferric oxalate is well defined, it better can be described as ammonium trisoxalatoferrate(III) and it is well-crystallized and
air-stable. This also could be an option. I'm not sure though how the oxalato ligand affect oxidizing power of the iron(III).
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blogfast25
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Quote: |
The salt FeNH4(SO4)2.12H2O would be the best option if you can obtain that.
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The ferric alum was kind of my compound of choice all along and I've found some Google references in which it is described as a source of Fe3+ for
redox titrations. So I'll settle for that.
That leaves the problem of a standardising material, preferably an OTC. I might actually go for high purity Titanium to determine the titration
factor, as my purpose is to assay various thermite Ti metals and alloys...
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Klute
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To standardize your Fe3+, you could added an iodide in excess, and back titrate the formed I2 with thiosulfate. KI and Na thiosulfate are readibly
available. Na thiosulfate is pretty accurate when preparing solutions, but you could standardize it by titrating with an solid iodate, or dichromate.
Good luck!
\"You can battle with a demon, you can embrace a demon; what the hell can you do with a fucking spiritual computer?\"
-Alice Parr
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blogfast25
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Thanks, Klute, but that would potentially lead to a 'standardisation cascade' .
But back-titrating KI --> I2, with thiosulphate/starch, I think I'll try that...
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JohnWW
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The trouble with aqueous Fe+++ salt solutions is that they are extensively hydrolysed, except in very strongly acid solutions, or except if
comprehensively complexed by a strong sequestering ligand like porphyrin or EDTA. Also, if HCl (or other halo-acid) is used to prevent hydrolysis, the
Fe+++ is converted to the FeCl4- anion. The hydrolysis is liable to interfere with attempts to standardize Fe+++ solutions used as oxidants in
titration.
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blogfast25
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I'm not sure whether hydrolysis would play an important part as a contributor to error, especially in acidic conditions and were the ferric solution
is used as a titrant (and not the other way round):
Fe(H<sub>2</sub>O)n<sup>3+</sup> + H<sub>2</sub>O
<--->FeOH(H2O)<sub>n-1</sub><sup>2+</sup> + H<sub>3</sub>O<sup>+</sup>
Obviously, at pH << 7, this equilibrium shifts strongly to the left.
But when the weakly hydrolised ferric solution hits the excess of Ti<sup>3+</sup> in the titrated sample, reacting the Fe (+III) away
further pushes this equilibrium to the left. Potential problems, at too high pH, could occur near the end-point.
To be certain, I'll supplement my NH<sub>4</sub>Fe(SO<sub>4</sub><sub>2</sub>.12H<sub>2</sub>O solution with H<sub>2</sub>SO<sub>4</sub> to avoid hydrolysis
of the mother solution... Probably 0.1 M Fe<sup>3+</sup>/0.05 M H<sub>2</sub>SO<sub>4</sub>, something like
that...
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woelen
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Not 0.05M H2SO4, better is 1M H2SO4. Ti(3+) also has a tendency to hydrolyse and when it flocculates as hydroxide, it is sufficiently strongly
reducing to reduce water (giving H2), so be absolutely sure that you remain on the acidic side.
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blogfast25
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Woelen:
1 M sulfuric is perhaps better as a precaution than 0.05 M but bear in mind that the Ti<sup>3+</sup> is held in a very acidic solution, as
it's obtained by dissolving Ti (or alloy) in conc. HCl or conc. sulfuric. Still, an excess acid in the titrant solution is probably a good safeguard
against premature hydrolysis of the Ti bearing sample solution...
[Edited on 7-5-2008 by blogfast25]
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Klute
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To dissolve Mohr's salt (the Fe2+ alum), which cna be long with pur dH2O, we suspend the salt in 2/3 the amount of water needed (~650mL for 1L of
solution for ex), and add conc H2SO4 in portions with stirring until the salt dissolves completly with the heat liberated.. I suppose you could do
the same the with Fe3+ ammonium sulfate, except if it is already readibly soluble in water.
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12AX7
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Quote: | Originally posted by woelen
Not 0.05M H2SO4, better is 1M H2SO4. Ti(3+) also has a tendency to hydrolyse and when it flocculates as hydroxide, it is sufficiently strongly
reducing to reduce water (giving H2), so be absolutely sure that you remain on the acidic side. |
Not to mention absolute exclusion of air (a purple solution of Ti(3+) quickly (over days) turns colorless when the metal is removed).
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blogfast25
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The speed at which Ti<sup>3+</sup> oxidises to +IV by air oxygen is often overstated, I feel. I have several quite concentrated solutions
Ti<sup>3+</sup>, some have been transferred in open air from one container to another. No signs of oxidation whatsoever, although it's
possible that the fairly high Ti<sup>3+</sup> concentration masks that...
The trick to titrate it correctly is to add some Al strip prior to titrating, let that dissolve and the nascent hydrogen reduces any
TiO<sup>2+</sup> back to +III. Then add sodium bicarbonate, the CO<sub>2</sub> will flush out remaining hydrogen and provide a
protective blanket against air oxygen. This was the standard procedure where I worked in QC/PC all these years ago. Today they may use potentiometric
end-point determination but other than that, I doubt if the procedure has been changed much...
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blogfast25
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Ok, I've chosen ferric alum solution in 1 M HCl (the titrated solution is about 5 M HCl, so sulfuric acid wouldn't be very practical as an acidifier).
But the alum (from SilverPrint.co.uk) didn't dissolve 100 %, there was some cloudiness (looks like Fe(III) (hydr)oxide), so filtration was called for.
For standardising I'll be using Klute's suggestion of back titration with I2/thiosulphate. But it's a long time ago since I've done this. I seem to
remember that S<sub>2</sub>O<sub>3</sub><sup>2-</sup> reacts with dilute HCl and forms Sulphur. Should I run
the back titration in alkaline conditions or is the oxidising reaction of the thiosulphate with the iodine much faster than the sulfur generating
reaction?
A couple of methods I've come across on the net seem to call for pH < 7, not alkalinity...
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Klute
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No, no alkaline conditions or your formed iodine will dismute to iodate and iodide... the acidic conditions aren't a problem, as you correctly
guessed the thiosulfate reacts with the i2 much faster than with any acid.
You can use thiodene as an indicator, although it is already pretty clear when the iodine colour disappears.
Once you've added your excess iodide, leave the erlen covered in the dark for 10-15min to leave the iodine the time to completly form and not
sublimate out or get degraded.
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blogfast25
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Thanks, Klute!
That leaves me with one other question. The Na<sub>2</sub>S<sub>2</sub>O<sub>3</sub> I bought very recently turns
out to be anhydrous, not the usual pentahydrate (it's a photo developer's grade). I'm wondering whether it's suitable for this purpose or whether I'm
better crystallising it to pentahydrate... The anhydrous powder seems stable, a well-formed powder, not at all clumpy... I haven't dissolved any of it
yet though.
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Jor
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Now that we're talking about iron(III)-compounds...
I have 100g of iron(III)sulphate. This has a really low density and is a light brown very dry powder (not crystalline). It dissolves only VERY slowly.
So slow, that I'm not patient enough to wait for it to dissolve. Wiki states iron(III)sulphate nonahydrate is very soluble (440g in 100cc of water , @
20C). Why is mine so insoluble? Do I have an anhydrous salt maybe?
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woelen
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Anhydrous ferric sulfate does dissolve very well in water, but it takes time. It takes several days before all of it has dissolved. A similar thing is
true for anhydrous nickel sulfate. I made the anhydrous salt from the hydrated salt. The anhydrous salt does dissolve, but again, it takes days, maybe
1 week.
You have the anhydrous salt.
[Edited on 16-5-08 by woelen]
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Klute
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The anhydrous thiosulfate should be fine, it's just that you can't really be sure of it cocnentration by analytical weighing, as it could be partially
hydrated. So unless you standardize the thiosulfate, you better be off either:
-keeping the anhydrous in a dessicator a day prior weighing an ddo it quick
-form the pentahydrate, dry it well enough, and weigh this.
I would go for the totally anhydrous method. Just accord the weight according to the stoechiometry. You can make a rough titration to be sure you are
in a tight margine (sp?).
\"You can battle with a demon, you can embrace a demon; what the hell can you do with a fucking spiritual computer?\"
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blogfast25
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Klute:
Thanks. For now I'll stick with the anh. thiosulphate and perhaps run a few tests drying it at 110 C, 1 h (230 F) to see if there's any weight change
at all. I have no proper lab dessicator, I'm afraid, but could always 'concoct something': anhydrous CaCl<sub>2</sub> should be available
where I live. Drying at RT would definitely be more desirable.
I've also got K permanganate and K dichromate (but no redox indicator for the latter), So there's scope for alternative methods of standardising.
Yesterday I ran a first real titration of an actual Ti<sup>3+</sup> sample (thermite Titanium metal dissolved in 32 w% HCl) with the as yet non-standardised 0.1 M ferric alum solution in 1 M HCl using KSCN as an indicator
and it went quite well. The end-point determination will take a little practicing as well as a blank titration because the transition from very pale
violet to yellowy - orange (dilute FeSCN<sup>2+</sup> isn't very sharp.
[Edited on 17-5-2008 by blogfast25]
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Klute
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To use the dichromate, you can add a precisely weighed amoutn of solid dichromate, add excess iodide, and back titrate the formed iodine with
thiosulfate. That should be precise enough.
Of course you can do the same with the permanganate, but i think it's less precise to weigh the permanganate.
Keep the dichromate in a custom dessicator afetr keeping it inthe oven a while, to insure it's anhydrous; I often use a tupperware with a bed of
CaCl2 covered by a thick layer of toilet paper as a cheap dessicator for general purposes, or a small jar can with a layer of NaOH/KOH or P2O5 mounted
by a plastic screen, avoiding any contact with those agressive materials, for more thorough drying conditions.
Glad to hear it worked out nicely!
\"You can battle with a demon, you can embrace a demon; what the hell can you do with a fucking spiritual computer?\"
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