Chemical Forums
Chemistry Forums for Students => Analytical Chemistry Forum => Topic started by: plu on January 07, 2006, 10:54:07 PM
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Hello there! I was recently approached with a question that I could not answer. :-[ Here it is:
A student was to determine the equilibrium constant for the reaction between iron(III) and thiocyanate ions. A standard reference solution was prepared by mixing 18.0 mL of a 0.20 mol/L Fe3+ solution with 2.0 mL of a 0.0020 mol/L SCN-. The absorbance of this solution was found to be 0.520. A second solution was prepared with the same 0.0020 mol/L SCN- and dilute 0.0020 Fe3+ solutions. Solution #2 contained the following: 5.0 mL Fe(NO3)3, 2.0 mL KSCN, and 3.0 mL H2O. The absorbance of the second solution was found to be 0.138. Assuming FeSCN2+ follows Beer's Law, find the equilibrium constant for the reaction. Note: The molar absorptivity of FeSCN2+ is 7.00 x 103 L/cm.mol.
I can work the question out if I assume that the pathlength used is a standard 1.00-cm cell. However, it is apparently possible to solve the question without knowing the pathlength :-\ Assistance requested!
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Its a common assumption to assume the path length is 1cm.
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We are doing this lab in class right now, so I might be some help. According to my teacher, we can use the first testube, our reference test tube to figure out the molarities of others throug cross multiplication. This means we don't need to use Beer's Law or at least not directly.
So it would be setup like this:
0.002M ?M?
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0.520 0.260
Does anyone here see a problem with this method?
Btw, we had to cancel the lab because the concentration of KSCN was too high so the resulting solution was too dark and we couldn't get the reading. Doing it next class!
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if law of Lambert-Beer is applicable to the experiment (that is: when extinction and concentration are proportional to each other), than there's no problem using cross multiplication
--> remember that when E and c are proportional, when E get's 2 times higher c does too. Now cross multiplication is no problem.
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So it would be setup like this:
0.002M ?M?
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0.520 0.260
How are you getting the 0.260?
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How are you getting the 0.260?
Random number I made up for my example.
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Random number I made up for my example.
Ah, I see :D How would you complete the solution then?
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Ah, I see :D How would you complete the solution then?
You mean calculate the unknown concentration? Well, since the absorbance reading is directly proportional to the concentration, halfing it would also half the concentration. So my number is for a 0.001M concentration of Fe(SCN)2+ For less nice numbers, just use cross multiplication.
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You mean calculate the unknown concentration? Well, since the absorbance reading is directly proportional to the concentration, halfing it would also half the concentration. So my number is for a 0.001M concentration of Fe(SCN)2+ For less nice numbers, just use cross multiplication.
Oy, but you would have to again assume a pathlength of 1.0 cm since you don't know the concentration of FeSCN2+ for either of the two trials :-\
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No. Try to solve the question using symbols and assuming pathlenthg l - it will cancel out at the end. That's why cross multiplication gives correct result immediately.