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KoiosPhoebus

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posted on 20-3-2023 at 08:24

Oxygen scavengers for working with Iron(II) and Manganese(II) salts?

Hi everyone!

I'm trying to prepare some complexes of Fe(II) and Mn(II) (I've got some discussion of my progress on the glycine complexes at the bottom of this topic - https://www.sciencemadness.org/whisper/viewthread.php?tid=15...).

Unfortunately, Fe(II) salts oxidise very readily in solution to Fe(III). Mn(II) is more oxidation-resistant but will also follow suit in an organic solvent and/or at alkaline pH (or if left exposed to air for a while). The usual solution of working at a low pH is not a viable option as the complexes often form adducts with acids. e.g. the conjugate base of the amino acid glycine has sufficiently strong affinity for H⁺ that the following reaction is able to proceed:

Mn(Gly)₂ + 2 H⁺ + SO₄^2- → Mn²⁺ + 2 GlyH + SO₄^2-

With the product being ferrous glycine sulphate or manganous glycine sulphate instead of the desired ferrous bisglycinate/manganous bisglycinate.

Additionally, many acidic reducing agents like oxalic acid or citric acid form their own complexes with Fe(II) and Mn(II), so instead of synthesising Fe(Gly)₂.H2Oxalate, I might end up with Fe(Oxalate).(GlyH)₂.

Another alternative I've read about is working at elevated temperatures to reduce the solubility of gases. This does seem to work somewhat; however in my experience oxidation still occurs after some time, especially for the Fe(II) salts. Additionally, I have one methodology (https://doi.org/10.1016/S0020-1693(00)82257-4) where slow crystallisation from ethanol/water mixture is required - constant heating would make that difficult.

Does anyone have any suggestions on how I might prepare a non-oxidising environment for me to work with Fe(II) or Mn(II) salts? I've read some stuff on inert atmospheres but a lot of it seems to require specialised equipment which I don't currently have e.g. glove boxes. Is there an equivalent for the home chemist or another reasonably inexpensive way to replicate an inert atmosphere or deoxygenate a solvent at home?

Thanks in advance for any advice!

DraconicAcid

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posted on 20-3-2023 at 09:31

If you put a bit of metallic iron in the solution, then the iron will stay at Fe(II),

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unionised

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posted on 20-3-2023 at 12:59

Have you considered bisulphite.
I don't think it's completely immune from complex formation but it's not bad.

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posted on 20-3-2023 at 13:23

Quote: Originally posted by unionised

I don't think it's completely immune from complex formation but it's not bad.

Huh? Example?

Acids and Bases: Brønsted–Lowry Theory (an interactive educational SM thread)

Quantum Mechanics/Wave Mechanics in Chemistry SM Thread

Solvation, solubility limits and solubility products: basic theory with worked examples (SM thread)

Calculus for beginners (SM thread): table of content

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KoiosPhoebus

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posted on 20-3-2023 at 16:35

Quote: Originally posted by DraconicAcid

If you put a bit of metallic iron in the solution, then the iron will stay at Fe(II),

Thanks, I'll keep that in mind. I'm a little unsure as to how well that works in an organic solvent as I've always seen it used in water; the low solubility of most Fe salts in organic solvents might reduce the rate at which Fe⁰ is able to reduce any Fe³⁺ formed. Additionally, I'm not sure how this would work if I'm trying to crystallise out the ferrous complex - how would I go about separating the iron from the desired salt?

Quote: Originally posted by unionised

Have you considered bisulphite.
I don't think it's completely immune from complex formation but it's not bad.

Bisulphite (as in HSO₃^-) is acidic so there's a good chance it'll react with the complex. Sulphite (SO₃^2-) is an interesting option I'll consider, but as far as I can tell, sodium sulphite and potassium sulphite are considered insoluble (or "sparingly soluble") in ethanol. They might be useful when I'm running aqueous reactions (and I'll keep them in mind for those), but not so much when I'm working in organic (or mixed aqueous/organic) solvents.

A couple of other options I've been considering:

Reducing agents from photography, e.g. pyrogallol, pyrocatechol, metol, hydroquinone. However, these are quite pricey and I'm not very familar with their use (e.g. which one has more reducing power) and whether they might complex the metal cations.
Working in a sealed bag with reducing gases. e.g. placing an evaporating dish in the bag with dissolved potassium metabisulphite, or preparing my initial metal salt using a strong acid (so instead of adding manganese chloride, I'd add manganese metal to hydrochloric acid to evolve hydrogen gas). This could work but I'm unsure as to how effective it would be - I've heard of people using similar methods a la the "balloon transfer" method and it apparently wasn't very effective - https://www.researchgate.net/post/What-are-the-possible-ways...). Additionally I'm a little iffy on how safe it is to work with gases like SO₂.
Working in a sealed bag, but using an "oxygen trap" to remove the oxygen within. e.g. placing a dish of cold ascorbic acid solution to remove as much of the oxygen as possible into the bag, then running my reaction in said bag. Again, I'm unsure how effective this is as well as the practicalities of working in such an environment.

If anyone has used any of these methods before, or has any other suggestions I'd love to hear them!

Texium

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posted on 20-3-2023 at 17:21

Phenols aren’t a good option: they complex iron (I don’t know about manganese, but I wouldn’t be surprised if they did) and their iron(III) complexes are an intense dark purple color.

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KoiosPhoebus

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posted on 20-3-2023 at 21:06

Quote: Originally posted by Texium

Phenols aren’t a good option: they complex iron (I don’t know about manganese, but I wouldn’t be surprised if they did) and their iron(III) complexes are an intense dark purple color.

Ah, okay. Thanks for letting me know! (and saving me quite a bit of money in the process)

I do wonder if they could still be used in an "oxygen trap", but there's cheaper chemicals (like ascorbic acid) which could also be used there.

woelen

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posted on 21-3-2023 at 02:34

Maybe you could use sodium dithionite. That's a strong reductor. It is important though that the pH of the solution does not become low, because dithionite is unstable at low pH and decomposes to sulfur, sulfur dioxide, and other (acidic) oxo species of sulfur.

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posted on 21-3-2023 at 03:00

There are ways of making a glovebox using plastic containers. You might also rig up an inert environment with an argon balloon attached to some normal glassware.
I don't have a lot of experience but I have seen both done with reasonable success.

KoiosPhoebus

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posted on 21-3-2023 at 04:41

Quote: Originally posted by woelen

Thanks for the input woelen. Is there a particular reason you suggest dithionite instead of metabisulfite? The latter is more commonly available where I am, and I'm under the impression that it's also more reduced?

Quote: Originally posted by j_sum1

Thanks for the input, I might look into the rigging up a glovebox stuff. The ResearchGate thread I posted above did however suggest that the "balloon transfer" method (unsure if this is what you're referring to?) resulted in carbon dioxide and water vapour levels returning to atmospheric levels after a few minutes. It's probably not the biggest deal with Mn(II) but my experience is that Fe(II) compounds oxidise given relatively small exposure to oxygen when in basic solutions.

Does anyone know if a vacuum desiccator would also work for this purpose? I'm considering buying one anyway as some of the complexes simply will not dry out even under strong heating or being placed into a bag with calcium chloride. I've never used one before though so I have no idea if it'll purge the insides of oxygen, and they're rather pricey so I'd want to be sure it'll do the job before buying it.

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posted on 21-3-2023 at 07:21

So, when, for example, you mix water solutions of MnSO4 and barium glycinate, do you experience any Mn(II) oxidation?
Also there is another published method, mixing alcoholic solution of Mn(NO3)2 and aqueous lithium glycinate in the molar ration 1:2. The precipitate should be washied with alcohol and dried in vacuum at 70C

[Edited on 21-3-2023 by teodor]

woelen

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posted on 21-3-2023 at 12:05

Dithionite is a MUCH stronger reductor than metabisulfite. Dithionite must not be confused with the very tame dithionate! It contains sulfur in (average) oxidation state +3, while metabisulfite (and also sulfite) contain sulfur in oxidation state +4. Dithionite is such a strong oxygen scavenger, that it even can ignite in air, when it is made humid. If you take some solid Na2S2O4 and make the powder damp, while keeping it in contact with air, then the powder becomes hot, due to the reaction with oxygen from the air.

I myself have used Na2S2O4 in reactions with Mn(OH)2, which I wanted to keep pale pink. Without the Na2S2O4 the suspension of Mn(OH)2 immediately turns brown in contact with air, but with Na2S2O4, the mix remains white or pale pink.

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KoiosPhoebus

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posted on 21-3-2023 at 17:17

Quote: Originally posted by teodor

So, when, for example, you mix water solutions of MnSO4 and barium glycinate, do you experience any Mn(II) oxidation?
[Edited on 21-3-2023 by teodor]

I use calcium glycinate or histidinate in place of barium, but broadly speaking as long as the temperature is kept close to boiling I have not seen much oxidation. The complexes formed are dark red (and Mn(III) is brown) so I've tested for oxidation by pipetting a small amount into a solution of NaOH; typically a white/cream precipitate forms with at most traces of brown.

For Mn(II), the problem with the double displacement is not that it oxidises (it's mostly fine as long as kept hot), but that I could not get the complexes formed out of solution. So far, I've attempted:

Precipitation with organic solvents (acetone/ethanol). Introducing the organic solvent has thus far produced a creamy organic solvent layer and a water layer, which then becomes this oily, gooey mess. Stirring does not help as the complex/water mixture just becomes these sticky clumps; filtering off the organic solvent layer (or precipitating in organic solvent and filtering that off) has so far also failed as the precipitate simply blocks filters. When in organic solvent, the complex also oxidises much more readily, probably due to the increased solubility of oxygen in said solvents.
Very strong heating, practically boiling. The complex/water mix gets to a point with very little water, and then forms this viscous goo. Further heating results in vigorous bubbling and the formation of a sticky, harder goo with the texture of melted rock candy. Further heating simply resulted in the formation of more bubbles but not any change in the texture or structure of the hard goo.
Heating it to reduce the volume of liquid, and then placing it into a sealed bag with calcium chloride. After leaving it for a couple of hours, the solution remains as a relatively flowable liquid, with no apparent drying-out. Additionally, while I never got around to testing it for oxidation, I suspect more of the Mn(II) would have oxidised in this method as the dish containing the complex would cool down over time in the bag, increasing the solubility of oxygen.

Note that the "minimal oxidation while kept hot" statement only applies to Mn(II). With Fe(II), the complex oxidises even when the solution is kept at near-boiling temperatures, forming red ferric oxide on the side of the dish and a layer of Fe(II,III) oxide on the surface of the solution which can stick to magnetic stir bars etc.

Fe(II) will also oxidise even when citric acid or L-ascorbic acid are added into the solution. I prefer not to add compounds which might complex with the metal, but I saw this done in a patent and in a separate publication so I thought I'd try it out as well; unfortunately it did not prevent oxidation.

Additionally with ascorbic acid, the solution rapidly turned purple, which is a sign of the formation of Fe(Ascorbate). I suspect citric acid does something similar as the solution remained green, which is usually a sign of Fe(Citrate) formation as Fe(Gly)₂ is yellow-brown in solution. However I'm not 100% sure if Fe(Citrate) was formed as Fe²⁺ is also green in solution.

Quote: Originally posted by teodor

Also there is another published method, mixing alcoholic solution of Mn(NO3)2 and aqueous lithium glycinate in the molar ration 1:2. The precipitate should be washied with alcohol and dried in vacuum at 70C
[Edited on 21-3-2023 by teodor]

Yep, I've heard of this method as well though with FeCl₂ instead. The problem is that oxygen dissolves much more readily in alcohol solvents than in water, so the Mn(II) complex oxidises very readily in alcohol-water mixtures. Within minutes, the orange/cream mixture (depending on which amino acid is used) turns brown, presumably oxidising to Mn(III).

Quote: Originally posted by woelen

Thanks for correcting me on that.I'm not sure I can find dithionite but I'll keep it in mind.

Would anyone happen to know if a vacuum desiccator would prevent oxidation if I pulled a vacuum on the dish?

DraconicAcid

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posted on 21-3-2023 at 19:30

Quote: Originally posted by KoiosPhoebus

Precipitation with organic solvents (acetone/ethanol). Introducing the organic solvent has thus far produced a creamy organic solvent layer and a water layer, which then becomes this oily, gooey mess.

Don't use acetone for that- it far too easily gets salted out. Methanol is your best bet.

That being said, I had similar trouble trying to isolate nickel glycinate complexes- I eventually just gave up.

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posted on 22-3-2023 at 01:15

Quote: Originally posted by KoiosPhoebus

For Mn(II), the problem with the double displacement is not that it oxidises (it's mostly fine as long as kept hot), but that I could not get the complexes formed out of solution.

So, I think those are important points:

1. The molar ratio. Mn(C2H4NO2)2 * 2H2O could be isolated, but the solution is typically the mixture of Mn(HGly)2+ and MnGly(HGly)+ ions (HGly = zwitterion)
2. The temperature colse to 70C. I think this is the zone where dihydrate crystallizes.
3. The method with lithium glycinate wich forms "white precipitate" probably is dependent on the initial concentration of solutions, try to vary it (the original publication was in a soviet union magazine, I have no idea how to access its archives).

[Edited on 22-3-2023 by teodor]

KoiosPhoebus

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posted on 22-3-2023 at 17:11

Quote: Originally posted by DraconicAcid

Hmmm, I'll think about using methanol. I've also tried the same procedure, but with histidine as the ligand and water/ethanol as the medium - water for the lithium histidinate and ethanol for the manganese chloride. This procedure was used in another paper to prepare ferrous histidinate dihydrate (https://doi.org/10.1016/S0020-1693(00)82257-4). For the most part it seemed to work - initial formation of a cream precipitate followed by dissolution of precipitate and the solution changing to orange. However the relatively high solubility of oxygen in ethanol meant that the mixture oxidised very rapidly, going to brown and then black.

Interestingly someone else in the metal glycinates thread (https://www.sciencemadness.org/whisper/viewthread.php?tid=15...) managed to prepare and isolate nickel glycinate by heating on a steam bath. I'm not sure why this worked and heating on a hotplate failed - maybe it has something to do with getting more even heating?

It's been incredibly frustrating to me as I've been able to crystallise compounds which are described as deliquescent, but somehow a couple of metal amino acid complexes elude me.

Quote: Originally posted by teodor

Thanks for sharing that! I've tried both methods - the first is difficult to crystallise (apparently Fe(Gly)₂ is also challenging to isolate this way - see: https://www.researchgate.net/post/How_can_I_synthesize_pure_...), while the second oxidises readily in contact with air.

My hotplate doesn't have a temperature setting, but I've tried drying at quite a few variations of temperature, from near-boiling to relatively cool temperatures (50 deg C). It's possible that I just need to keep the temperature at a steady 70 deg C, but I suspect the bigger factor here might be in the use of a vacuum to dry the solution.

I'm starting to think that the only way out here might be to use a vacuum desiccator to purge the insides of oxygen while drying, and to properly degas the solvents (so far I've just been boiling everything). The paper that I had on preparing iron(II) complexes of amino acids (https://doi.org/10.1016/S0020-1693(00)82257-4) also seems to suggest drying under vacuum or under nitrogen ("They were dried by continuous pumping for several hours"). I have no idea how I'm going to heat it at 70 deg C under vacuum though - the vacuum cabinets large enough for something like that are way out of my price range.

If anyone has any ideas on either drying very stubborn metal complexes or maintaining oxygen free environments when drying a precipitate, I'd love to hear more! The full vacuum desiccator setup is rather pricey and I'd prefer not to have to go down that route if possible.

Also if anyone has any thoughts on whether a vacuum desiccator would actually do the job of keeping the mixture oxygen-free, I'd very much appreciate your input. It'd be annoying to buy the full setup and find that it didn't purge oxygen fast enough to prevent oxidation or something similar.

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posted on 22-3-2023 at 23:26

Quote: Originally posted by KoiosPhoebus

It'd be annoying to buy the full setup and find that it didn't purge oxygen fast enough to prevent oxidation or something similar.

KoiosPhoebus, for your experiment you need:

1. The kettle like this one.

It can keep the constant temperature of water inside. The price - 40EUR.
My can work perfectly with 250ml flasks if I detach the cap of the kettle.

2. A round-bottom flask.

3. A water aspirator. There are good cheep plastic models.

4. A rubber hose.

5. An adapter of hose to a ground glass joint.

6. A vacuum lubricant.

7. Something to fix the flask inside the kettle.

To test your setup put a bit warm water in a flask, apply vacuum and wait till it boils, then boil it until it stops boiling (because it will cool down). Then measure the boiling temperature and find the pressure by a table. Typically, to get good vacuum you should pay attention to the quality of rubber, lubrication of joints and tighting the hose connections as much as possible. The test with boiling water will proof you have the proper setup (the preassure from an aspirator typically is in the range 10-25 mmHg, depending on the time of year and quality of your hose connections).

Also I think in the lithium method they use saturated solution.

I have not so big experience of Fe(II) salts preparation but the method of zink metal in acidic solution worked perfectly for me (to keep the small current of "nascent" H2 in the mixture which prevents Fe(II) from oxidation.

Update:
it is known that H2 bubbling can reduce some compound (e.g. permanganate), I am wondering, can hydrogen reduce Fe(III) to Fe(II) (solvent/temperature/catalyser) ?

[Edited on 23-3-2023 by teodor]

Sciencemadness Discussion Board » Fundamentals » Chemistry in General » Oxygen scavengers for working with Iron(II) and Manganese(II) salts?