Honestly, after reading everything I still have no idea what your problem is.
Ok how about I take it a little slower and tell you guys step by step. I think I'm giving information backwards which may make it confusing, ill give you the experiment set up what we did and maybe that may help a little bit. Thanks for being patient :+)
What we did was Add 0.080M of I_2 [For the first run, I_2 M was the changing factor] as a solute and the solvent was 200 mL of DI water and 50 mL of Hexane added to that as well. (Reasoning for adding the hexane to the water and I_2 I'm not sure.) Then we put a stopper in the flask and shook it up for near five minutes and let it rest in a water bath at (25-26 C) for about 10 minutes, then shook again and repeat for an hour. Then we let the solution rest until the layers separated.
We extracted the aqueous layer out and place into another flask filled with 10 mL of 0.1M of KI. We then pulled the hexane layer out and place it into another flask filled with 10 mL of 0.1 M of KI.
Then we titrated both of the layers separately with Thiosulfate solution with a starch indicator, until the solution turned clear.
And we repeat these steps for the rest of the runs 1-3 which the only thing changes is the Molarity of I_2
Runs 4-6 two factors change where in addition to the molarity of I_2 changing, the experiment asked for 200mL of KI to be added before titration, each with different molarities.
Run # Hexane (50 mL) MolarIty I_2 Molarity KI
1 0.080 0
2 0.040 0
3 0.020 0
4 0.080 0.15
5 0.040 0.15
6 0.080 0.03
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So that was the required experiment that was performed.
From my understanding the experiment is about equilibrium and layer separation and how well they separate with different molarity of I_2.
That's why we added the hexane layer and shook up the flasks really well for 5 minutes, so that the layers mix up properly.
When we extract the layers we placed the different layers each into a 10mL 0.1 M KI which is suppose to reduce the loss of I_2 from the aqueous solution by evaporation while trying titrate, which in the ends forms a less volatile I_3-
(Did I think that out properly there? Not sure there but the numbers look that way-) Then we titrated the samples with thiosulfate solution which the reaction that should be taking place should be...
2 S_2 O_3^(-2) + I_3- ---> S_4 O_6 ^(-2) + 3 I -
That means the I_3- formed when we added the 10 mL of KI gets converted to I- when we titrated with thiosulfate
So the experiment went from I_2 to I_3- to I- .
Overall this experiment was suppose to show the distribution of molecular iodine I_2 between two immiscible solvents, water and hexane. (Or I think at at least, by looking at the changes.)
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[Question]
[color= red]So, where I'm stuck at is the idea of how am I suppose to find the equilibrium concentrations of I_2 , I_3- and I- in aqueous solutions. (Based on results of runs 4-6) [/color]
The equations the book gives me is:
(I_3- ) = T - (I_2 ) [eq 4]
and
(I- ) = C - ( I_3- ) [eq 5]
Where T = (I_2) + (I_3-) and C is suppose to be the initial KI solution concentration.
The real problem I have identifying which is suppose to be which at equilibrium concentrations.
Because initial I start out with 0.080 M of I_2 but that gets converted over to I_3- by the 10mL of 0.1 M KI then gets converted over by titration with thiosulfate to I-. Which how am I suppose to identify my I_2, and I_3- if they don't really exist anymore.
I am assuming that the endpoint of my titration with Thiosulfate tells me that all of the I_3- have been converted over to I-.
I hope this makes my question a little bit clearer. Thanks for taking the time to read all this :+)
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Topic: Chemical Equilibrium in Solution: Lab help: (Read 18997 times)