Chemical Forums
Chemistry Forums for Students => Analytical Chemistry Forum => Topic started by: 21385 on March 25, 2008, 12:23:31 AM
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Calculate the solubility of CaC2O4 in an aqueous solution buffered at pH 4.0.
The relevant reactions are CaC2O4=>Ca2+ + C2O4 2- Ksp
H2C2O4=>HC2O4- + H(+) Ka1
HC2O4- => C2O4(2-) + H(+) Ka2
I know how to obtain the solubility by using the mass balance equation, and I got the correct answer.
I balanced it like this: [Ca2+]=[C2O42-] + [HC2O4-] + [H2C2O4], solved for [Ca2+] and got the right answer
But however, when i used the charge balance equation: 2[Ca2+] + [H+] => 2[C2O4(2-)] + [HC2O4-] + [OH-], and solved for [Ca2+] but i didn't get the correct answer.
Can anyone tell me why I can't use the charge balance equation for this question?
Thanks
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Show more details of your work for both cases. At this level of generality it can be everything.
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At first look, the equation
2[Ca2+] + [H+] => 2[C2O4(2-)] + [HC2O4-] + [OH-]
is not balanced for charge (I am assuming +ve and -ve charge should match).
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is not balanced for charge (I am assuming +ve and -ve charge should match).
Equation is OK. [] means concentration, it is not the same as balancing reaction equation.
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is not balanced for charge (I am assuming +ve and -ve charge should match).
Equation is OK. [] means concentration, it is not the same as balancing reaction equation.
My error, I assumed that the equation I copied which was identified as the "charge balance" equation should actually balance the positive and negative charges.
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I assumed that the equation I copied which was identified as the "charge balance" equation should actually balance the positive and negative charges.
Well, this is correct assumption - it should. But not in terms of molecular charges, but in terms of solution neutrality.
If you mix equimolar quantities of KCl and NaCl charge balance of the solution is
[K+] + [Na+] + [H+] = [Cl-] + [OH-]
and everything is OK, as [Cl-] = [K+] + [Na+].
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Mass Balance Method (correct answer):
[Ca2+]= [C2O4(2-)] + [HC2O4-] + [H2C2O4]
Ka1=[H+][HC2O4-]/[H2C2O4]
Ka2=[H+][C2O4(2-)]/[HC2O4-]
[Ca2+]= [C2O4(2-)] + [H+][C2O4(2-)]/Ka2 + [H+]^2[C2O4(2-)]/(Ka1Ka2)
Sub in values, and solve for [Ca2+]
[H+]=1E-4
Ksp=1.30E-8
Ka1=5.60E-2
Ka2=5.42E-5
[Ca2+]=1.92E-4 M
Charge Balance method: (wrong answer?)
2[Ca2+] + [H+] => 2[C2O4(2-)] + [HC2O4-] + [OH-]
2[Ca2+] + [H+] => 2(Ksp/[Ca2+]) + [H+][C2O4(2-)]/Ka2 + Kw/[H+]
2[Ca2+] + [H+] => 2(Ksp/[Ca2+]) + [H+]Ksp/(Ka2[Ca2+]) + Kw/[H+]
put everything in numerical values, and times every term by [Ca2+], with Kw=1.0E-14
2[Ca2+]^2 + 1E-4[Ca2+] - 5E-8 =0
Quadratic formula
[Ca2+]=1.35E-4 M
which is the wrong answer
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2[Ca2+] + [H+] => 2[C2O4(2-)] + [HC2O4-] + [OH-]
I wonder... this is not a complete equation, your solution was buffered at pH 4, so it contains other ions as well. They don't have to balance by themselves - when your oxalate was dissolved, it has disturbed original composition of the solution.
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Right Right, thank you guys
I forgot about the buffer part....and since it is impossible to find out the ratio of base to acid of the buffer, we can not use the charge balance for this question, right?
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Topic split:
http://www.chemicalforums.com/index.php?topic=24770.0