KonkreteRocketry
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Iron III Nitrate Fe(NO3)3 synthesis ?
I found an interesting equation on the net in making Iron III nitrate with some easily found chemicals. Fe2O3 + 6 KNO3 = 2 Fe(NO3)3 + 3 K2O Can any
one tell me if this reaction between Iron oxide and Potassium Nitrate this true. And if it is true, is the Iron III Nitrate i get Anhydrous ? or some
other hydrates ?
Thanks.
Also, how shall i do this ? Fe2O3 is not even soluable in water.. and.. K2O will react with Water.. umm.. and how shall i purify the Iron III Nitrate
?
Well i do have Acetone that dissolves it but can any one tell me if KOH is soluable in Acetone ? thx.
[Edited on 2-3-2013 by KonkreteRocketry]
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weiming1998
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Quote: Originally posted by KonkreteRocketry  |
I found an interesting equation on the net in making Iron III nitrate with some easily found chemicals. Fe2O3 + 6 KNO3 = 2 Fe(NO3)3 + 3 K2O Can any
one tell me if this reaction between Iron oxide and Potassium Nitrate this true. And if it is true, is the Iron III Nitrate i get Anhydrous ? or some
other hydrates ?
Thanks.
Also, how shall i do this ? Fe2O3 is not even soluable in water.. and.. K2O will react with Water.. umm.. and how shall i purify the Iron III Nitrate
?
Well i do have Acetone that dissolves it but can any one tell me if KOH is soluable in Acetone ? thx.
[Edited on 2-3-2013 by KonkreteRocketry] |
The reaction you suggested doesn't work. Fe2O3 will not dissolve in any solvent without reacting with it and K2O is far too basic to coexist with
Fe(NO3)3 (which is quite acidic).
The (as far as I know) only reliable route to Fe(NO3)3 is dissolution of iron in nitric acid/nitrogen oxides.
Edit: I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt
will melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You
should forget about using it as an oxidiser and stick to KNO3.
[Edited on 2-3-2013 by weiming1998]
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Motherload
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I don't believe that reaction will proceeded in aqueous conditions at all..
May happen if a stoicmetric mix was ignited or heated. Water can not be used at all to separate K2O from the mix as KOH will form and will react with
Fe(NO3)3 converting it to a oxide or hydroxide and both are soluble in Alcohol and Acetone
FeCl3 might react with NH4NO3 in an alcoholic solution.
"Chance favours the prepared mind"
"Fuck It !! We'll do it live !!"
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KonkreteRocketry
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| Quote: Originally posted by weiming1998 | | Quote: Originally posted by KonkreteRocketry |
I found an interesting equation on the net in making Iron III nitrate with some easily found chemicals. Fe2O3 + 6 KNO3 = 2 Fe(NO3)3 + 3 K2O Can any
one tell me if this reaction between Iron oxide and Potassium Nitrate this true. And if it is true, is the Iron III Nitrate i get Anhydrous ? or some
other hydrates ?
Thanks.
Also, how shall i do this ? Fe2O3 is not even soluable in water.. and.. K2O will react with Water.. umm.. and how shall i purify the Iron III Nitrate
?
Well i do have Acetone that dissolves it but can any one tell me if KOH is soluable in Acetone ? thx.
[Edited on 2-3-2013 by KonkreteRocketry] |
The reaction you suggested doesn't work. Fe2O3 will not dissolve in any solvent without reacting with it and K2O is far too basic to coexist with
Fe(NO3)3 (which is quite acidic).
The (as far as I know) only reliable route to Fe(NO3)3 is dissolution of iron in nitric acid/nitrogen oxides.
Edit: I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt
will melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You
should forget about using it as an oxidiser and stick to KNO3.
[Edited on 2-3-2013 by weiming1998] |
thank you, but KNO3 have only 40 meh % oxygen and FeN3O9 have almost 60%
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weiming1998
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| Quote: Originally posted by KonkreteRocketry | | Quote: Originally posted by weiming1998 | | Quote: Originally posted by KonkreteRocketry |
I found an interesting equation on the net in making Iron III nitrate with some easily found chemicals. Fe2O3 + 6 KNO3 = 2 Fe(NO3)3 + 3 K2O Can any
one tell me if this reaction between Iron oxide and Potassium Nitrate this true. And if it is true, is the Iron III Nitrate i get Anhydrous ? or some
other hydrates ?
Thanks.
Also, how shall i do this ? Fe2O3 is not even soluable in water.. and.. K2O will react with Water.. umm.. and how shall i purify the Iron III Nitrate
?
Well i do have Acetone that dissolves it but can any one tell me if KOH is soluable in Acetone ? thx.
[Edited on 2-3-2013 by KonkreteRocketry] |
The reaction you suggested doesn't work. Fe2O3 will not dissolve in any solvent without reacting with it and K2O is far too basic to coexist with
Fe(NO3)3 (which is quite acidic).
The (as far as I know) only reliable route to Fe(NO3)3 is dissolution of iron in nitric acid/nitrogen oxides.
Edit: I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt
will melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You
should forget about using it as an oxidiser and stick to KNO3.
[Edited on 2-3-2013 by weiming1998] |
thank you, but KNO3 have only 40 meh % oxygen and FeN3O9 have almost 60% |
Yes, but the hydrous salt also contains anywhere up to 9 molecules of water per molecule of Fe(NO3)3. It is like pouring water on a pyrotechnic
composition. It becomes much harder to light and it will often not burn (there are exceptions). The decomposing salt will also absorb heat, making
ignition even harder.
The anhydrous salt is extremely hygroscopic. It is also a reactive nitrating agent. You'll be hard-pressed to keep it anhydrous for long out in the
open. It might also react with your fuel in unexpected ways (especially if the fuel is organic).
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DraconicAcid
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| Quote: Originally posted by KonkreteRocketry | | Quote: Originally posted by weiming1998 | | I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt will
melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You should
forget about using it as an oxidiser and stick to KNO3. |
thank you, but KNO3 have only 40 meh % oxygen and FeN3O9 have almost 60% |
If that's your only consideration, then switch to water- it's 88% oxygen!
Please remember: "Filtrate" is not a verb.
Write up your lab reports the way your instructor wants them, not the way your ex-instructor wants them.
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AndersHoveland
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When not in presence of water, Iron(III) nitrate is a mild lewis acid. It might not give up its water of hydration so easily. (in other words, the
nitrate may decompose at the same time the water is released)
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KonkreteRocketry
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| Quote: Originally posted by DraconicAcid | | Quote: Originally posted by KonkreteRocketry | | Quote: Originally posted by weiming1998 | | I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt will
melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You should
forget about using it as an oxidiser and stick to KNO3. |
thank you, but KNO3 have only 40 meh % oxygen and FeN3O9 have almost 60% |
If that's your only consideration, then switch to water- it's 88% oxygen! |
but water is neither a nitrate nor an oxidizer, so u can't compare them directly,
but u can compare nitrates to nitrates, chlorates to chlorates, and so on. here KNO3, O took 47% of the mass, while in Fe(NO3)3 oxygen have 60% mass
of oxygen, so in same amount of nitrate oxidizers, one have 13% more, so in stoichiometry, Iron III nitrate needs only 95% of weight of KNO3 needed in
any pyrotechnical mix. and therefore iron 3 nitrate would be better, u can not compare H2O to nitrates.
| Quote: Originally posted by weiming1998 | | I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt will
melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You should
forget about using it as an oxidiser and stick to KNO3. |
Is there any way to convert KNO3 to any other nitrates ?
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KonkreteRocketry
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| Quote: Originally posted by weiming1998 | | Quote: Originally posted by KonkreteRocketry |
I found an interesting equation on the net in making Iron III nitrate with some easily found chemicals. Fe2O3 + 6 KNO3 = 2 Fe(NO3)3 + 3 K2O Can any
one tell me if this reaction between Iron oxide and Potassium Nitrate this true. And if it is true, is the Iron III Nitrate i get Anhydrous ? or some
other hydrates ?
Thanks.
Also, how shall i do this ? Fe2O3 is not even soluable in water.. and.. K2O will react with Water.. umm.. and how shall i purify the Iron III Nitrate
?
Well i do have Acetone that dissolves it but can any one tell me if KOH is soluable in Acetone ? thx.
[Edited on 2-3-2013 by KonkreteRocketry] |
The reaction you suggested doesn't work. Fe2O3 will not dissolve in any solvent without reacting with it and K2O is far too basic to coexist with
Fe(NO3)3 (which is quite acidic).
The (as far as I know) only reliable route to Fe(NO3)3 is dissolution of iron in nitric acid/nitrogen oxides.
Edit: I see that this is posted in the Energetic Materials section, so you're probably thinking of using Fe(NO3)3 as an oxidiser. The hydrous salt
will melt and decompose, releasing water and nitrogen oxides, and the anhydrous salt is difficult to prepare on a small scale, let alone large. You
should forget about using it as an oxidiser and stick to KNO3.
[Edited on 2-3-2013 by weiming1998] |
so, if i put Iron in Dilute nitric acid solution, it would work ?
I can make a nitric acid solution around 10% by making NO2 going into water. I heard nitric acid can have hydrates, so my Iron III Nitrate i get from
it will have hydrated too ? And also, i dont have pure iron but i can make Fe2O3 with a 90% Iron, steel anode. can Fe2O3 work with a dilute nitric
acid ? will it be hydrated ? thx a lot.
Also i think this equation is correct ?
2Fe + 3Cu(NO3)2 → 2Fe(NO3)3 + 3Cu
but i heard u get Fe(NO3)2 also, so can i use Fe2O3 again here ?
[Edited on 6-3-2013 by KonkreteRocketry]
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AJKOER
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Add NH4NO3 to aqueous Fe(HCO3)3, and slowly heat to concentrate and drive off ammonia and CO2. Add alcohol and let the solution evaporate to hopefully
recover Fe(NO3)3 and not Fe(NO3)3.9H2O (the hydrate). No guarantees it will work.
Reactions:
3 NH4NO3 + Fe(HCO3)3 <--> Fe(NO3)3 + 3 NH4HCO3
3 NH4HCO3 --Heat--> 3 NH3 (g) + 3 CO2 (g) + 3 H2O
Do not heat in an open vessel with O2 exposure as it can decompose Fe(HCO3)3 to Fe(OH)3, moving the 1st reaction to the left. To prepare aqueous
Fe(HCO3)3, try reacting FeCl3 (note, iron dissolved in Bleach + vinegar makes a contaminated form of a Ferric salt) with aqueous NaHCO3 (preheated to
remove O2).
[Edited on 6-3-2013 by AJKOER]
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KonkreteRocketry
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| Quote: Originally posted by AJKOER | Add NH4NO3 to aqueous Fe(HCO3)3, and slowly heat to concentrate and drive off ammonia and CO2. Add alcohol and let the solution evaporate to hopefully
recover Fe(NO3)3 and not Fe(NO3)3.9H2O (the hydrate). No guarantees it will work.
Reactions:
3 NH4NO3 + Fe(HCO3)3 <--> Fe(NO3)3 + 3 NH4HCO3
3 NH4HCO3 --Heat--> 3 NH3 (g) + 3 CO2 (g) + 3 H2O |
I don't have NH4NO3, do u know if Fe2O3 + Cu(NO3)2 can work ?
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AndersHoveland
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| Quote: Originally posted by AJKOER | | Add NH4NO3 to aqueous Fe(HCO3)3, and slowly heat to concentrate and drive off ammonia and CO2. Add alcohol and let the solution evaporate to hopefully
recover Fe(NO3)3 and not Fe(NO3)3.9H2O (the hydrate). |
I think in this case it would probably form an ammonia complex with the iron instead. Remember, there is no water here to complex to the Fe+3 ions, so
they will be a fairly strong lewis acid.
If found this quick explanation somewhere else:
| Quote: |
Why doesnt iron form ammonia complexes?
Ammonia can function as a Bronsted-Lowry base (proton acceptor) as well as a Lewis base (ligand). In the case of aqueous iron solutions, the greater
tendency is for the ammonia to accept protons from the water molecules that are binded to the iron ion:
[Fe(H2O)6]^+3 + 3 NH3 <=> [Fe(H2O)3(OH)3] + 3 NH4^+1
Another way to think of it is like this: the iron ion is itself a Lewis acid, so it reacts with water prior to the addition of ammonia to form
hydronium ions:
Fe^+3 + 2 H2O --> Fe(OH)^+2 + H3O^+1
So when you add the ammonia, it reacts more readily with the hydronium ions than with the iron ions.
In response to your follow-up question...and please understand that this is just a guess (albeit a somewhat educated one)...my suspicion is that the
Cu^+2 ion is a weaker Lewis acid than the Fe^+3 ion, resulting in fewer hydronium ions in solution and a greater tendency for the ammonia in solution
to replace water molecules as ligands. Again, this isn't guaranteed to be correct; I couldn't find any information online regarding the comparative
strength of Cu^+2 ions and Fe^+3 ions as Lewis acids.
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I do not think you would be able to drive out the ammonia without causing decomposition of the nitrate. (although I am not entirely sure) You could
drive off the ammonia by adding water, but then it would just form the hydrate.
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AJKOER
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Using Copper nitrate, again more likely just a hydrate, Fe(NO3)3.9H2O:
6 Cu(NO3)2 + 4 Fe(HCO3)3 (aq) --> 3 Cu2(OH)2CO3 (s) + 4 Fe(NO3)3 + 9 CO2 + 3 H2O
-----------------------------------------
In a horizontal tube, 1st packed with Cu(NO3)2, then a drying agent and Fe2O3, where both Cu(NO3)2 and Fe2O3 are being heated in a sealed tube (as any
thermal decomposition may reform Fe(NO3)3 on cooling). Reactions:
6Cu(NO3)2 --> 6 CuO + 12 NO2 + 3 O2
2 Fe2O3 + 3 O2 + 12 NO2 --> 4 Fe(NO3)3
more difficult, but perhaps anhydrous Fe(NO3)3.
[Edited on 6-3-2013 by AJKOER]
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KonkreteRocketry
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| Quote: Originally posted by AJKOER | Using Copper nitrate, again more likely just a hydrate, Fe(NO3)3.9H2O:
6 Cu(NO3)2 + 4 Fe(HCO3)3 (aq) --> 3 Cu2(OH)2CO3 (s) + 4 Fe(NO3)3 + 9 CO2 + 3 H2O
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Is it possible to take the hydrate out of Iron III Nitrate nona hydrate ?
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DraconicAcid
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I doubt it. The Merck Index says it melts at 43oC and decomposes under 100oC. While it might lose water at high temperature, it's more likely to
lose nitric acid and form hydroxides.
Please remember: "Filtrate" is not a verb.
Write up your lab reports the way your instructor wants them, not the way your ex-instructor wants them.
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weiming1998
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Maybe something like thionyl chloride might work, but I doubt it, as it will most probably oxidise and/or form nitrosyl compounds with nitrates. Even
if it does work, I would not go through the troubles of acquiring thionyl chloride for a bit of a pyrotechnic oxidising agent. Oxygen content is not
everything, and KNO3 should be far more effective when used as an oxidising agent compared to anhydrous Fe(NO3)3. The hydrous iron (III) nitrate won't
even burn with fuels; it simply decomposes.
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AJKOER
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| Quote: Originally posted by AJKOER | ......
In a horizontal tube, 1st packed with Cu(NO3)2, then a drying agent and Fe2O3, where both Cu(NO3)2 and Fe2O3 are being heated in a sealed tube (as any
thermal decomposition may reform Fe(NO3)3 on cooling). Reactions:
6Cu(NO3)2 --> 6 CuO + 12 NO2 + 3 O2
2 Fe2O3 + 3 O2 + 12 NO2 --> 4 Fe(NO3)3
more difficult, but perhaps anhydrous Fe(NO3)3.
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Yes, it appears Wikipedia agrees. To quote (link: http://en.wikipedia.org/wiki/Nitrogen_dioxide ):
"Conversion to nitrates
NO2 is used to generate anhydrous metal nitrates from the oxides:[6]
MO + 3 NO2 → 2 M(NO3)2 + NO "
I would change the procedure, for convenience and reactivity, by forming nanoparticle of Iron and Iron oxides (FeO, Fe3O4, alpha-Fe and at high
temperatures, even some Fe3C) in situ per the decomposition of Ferric oxalate. In other words, a layer of Cu(NO3)2 is heated but only after a layer of
Fe2C2O4.2H2O is thermally decomposed.
For the particulars of the Ferric oxalate reaction, one reference (Centre for Nanomaterial Research, Department of Physical Chemistry at Palacky
University, link: https://docs.google.com/viewer?a=v&q=cache:ux-9_MSRuhEJ:... ) to quote from the abstract:
"Using a device for thermogravimetric analysis, a dynamic study of thermally induced solid-state transformations of FeC2O4.2H2O in the atmosphere
allowing full participation of gaseous products (CO, CO2, H2O) in the reaction system was carried out. Solid phases formed at various temperatures
between 25 and 640 C were identified and characterized using 57Fe Mossbauer spectroscopy, TG and XRD. Up to 230 C, evolution of two molecules of the
water of crystallization takes place. Superparamagnetic nanoparticles of magnetite (Fe3O4) are formed as the primary product of the decomposition of
FeC2O4, together with gaseous CO and CO2. In the next stage above 380 C, the crystallization of magnetite is accompanied by a reduction of the
remaining ferrous oxalate to iron carbide (Fe3C) by carbon monoxide. Thermally induced conversion of iron carbide into a-Fe and carbon is expected
between 400 and 535 C as the major chemical process. In the last reaction step, above 535 C, magnetite is reduced to wustite (FeO) by carbon monoxide
evolved at lower temperatures. On the grounds of quantitative Mossbauer data possible competitive reactions are discussed and a temperature dependent
reaction model is suggested."
Also, the authors note:
"Depending on the experimental conditions, a diversified scale of reactions resulting in solid products varying in composition and valence state of
iron has been reported. From the point of view of the basic research, the mechanism of these solid-state reactions is the key experimental issue as
the published data are very controversial. The practical reason of interest in FeC2O4.2H2O is its easy thermal decomposability yielding various
nanocrystalline phases of iron including oxides with great application potential.31–33 Obviously one can easily come across many experimental
conditions that influence transformation routes, their intermediates and the final products, but the reaction atmosphere represents the most important
one."
I believe this procedure will be successful as elsewhere on this forum, I recall reading a report of the accidental formation of anhydrous Aluminum
nitrate when NO2 escaped and attacked an Al foil covering. Also employing, in an atmosphere of O2 and NO2, a highly reactive form of Iron/Iron oxide
(actually makes fireworks in contact with air see https://www.youtube.com/watch?v=EIe7mH9gHc8 ) would make quite an interesting reaction. Take precautions, possibly a little too
exothermic/energetic reaction between fine Fe powder and any formed Iron nitrate, and I would avoid a closed reaction chamber/confine space (possible
explosion hazard).
[Edited on 15-3-2013 by AJKOER]
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