Julie S. answered • 08/25/16
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Same deal here - the equivalence point is reached when you add enough OH- to react with all of your H+.
The balanced equation for this reaction is:
H2CO3 + 2LiOH → Li2CO3 + 2H2O
I showed you the long (but safe!) way to calculate the concentration of the H3PO4 on that other one. Now I'll show you the "shortcut" way. ;)
Since the moles of acid (H+) must equal the moles of base (OH-), we can look at how to find those and set them equal to each other. Isn't the number of moles of H+ provided by the acid equal to the moles of acid times how many H's it has? Therefore, the moles of H+ should equal:
(Volume of acid) • (molarity of acid) • (number of H's per mole of acid) = moles of H+
Same thing for the base, the moles of OH- should equal:
(Volume of base) • (molarity of base) • (number of OH's per mole of base) = moles of OH-
The formula to relate these uses "n" for the number of H+ or OH- per mole of acid or base, V = volume, and M = molarity.
nAMAVA = nBMBVB
If you do a titration, figure out what "n" is for the acid and the base by looking at the formulas. H2CO3 has 2 H+ on it, so nA = 2. LiOH has one OH- on it, so nB = 1. The question says that 47.0 mL of a H2CO3 solution were titrated with 37.5 mL of a 0.215 M LiOH. The only missing thing is the concentration of H2CO3. And the cool thing about the formula is that you can use the volume in mL or L, as long as they are both the same they will cancel out! ;)
Rearrange the formula to solve for what you are missing (molarity of the acid) and plug in the known values.
MA = nBMBVB / nAVA = (1)(0.215 M)(37.5 mL) / (2)(47.0 mL) = 0.0856 M H2CO3 :)
