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Weak base–strong acid titrations

For the titration of a weak base with a strong acid, the pH curve is initially basic and has an acidic equivalence point (pH < 7). The section of curve between the initial point and the equivalence point is known as the buffer region. At the half-equivalence point, the concentrations of the buffer components are equal, resulting in pH = pKₐ (where pKₐ refers to the conjugate acid of the weak base). Created by Jay.

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  • blobby green style avatar for user emilrichardwang
    I might be a little paranoid, but at I'm really confused why the initial solution has a more steep titration curve than the "buffer region". I feel like it would be much more effective in terms of neutralizing acid, since looking at the Henderson Hasselbalch equation, we have pH=pKa+log([NH4+]/[NH3]). The larger NH3, the less drastic the change in [NH4+]/[NH3] once we add acid. Thus, I'm really confused. What am I missing?
    (3 votes)
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    • leaf red style avatar for user Richard
      Before any titrant is added, the analyte solution is mostly the weak base, ammonia, with a very minor amount of weak conjugate acid, ammonium, present. When we add the acid titrant, ammonia reacts with the acid vigorously and shifts the ammonia neutralization reaction to the right. If you think of it as an equilibrium problem, adding acid disturbs equilibrium and Le Chatelier’s principal speeds up the forward reaction to relieve the stress and restore equilibrium.

      After this initial burst of neutralization, we begin to produce appreciable amounts of ammonium. And now a solution with appreciable amounts of a weak base and its conjugate acid is a buffer solution which obstructs the drastic change in pH. So we would expect the change in pH to slow as we create a buffer with increased titrant volume.

      The steep slope of the titration curve in the beginning corresponds to a large change in pH per mL of titrant added, while the gentler slope of the buffer region corresponds to a small change in pH per mL of titrant added.

      Hope that helps.
      (3 votes)

Video transcript

- [Instructor] Ammonia is an example of a weak base and hydrochloric acid is an example of a strong acid. And if we're doing a weak base-strong acid titration, that means that ammonia is the analyte, the substance we're analyzing, and we're titrating ammonia with hydrochloric acid and therefore hydrochloric acid is the titrant. And when ammonia reacts with hydrochloric acid, the product is an aqueous solution of ammonium chloride. For our complete or overall ionic equation, since ammonia is a weak base, we show it as NH3 in our complete ionic equation. However, since hydrochloric acid is a strong acid that ionizes 100%, we show it as breaking up into its ion, so H+ and CL-. Ammonium chloride is a soluble salt, therefore we would show ammonium chloride in aqueous solution as ammonium cations and chloride anions. To write the net ionic equation, we leave out spectator ions. And since we have chloride anions on the left side and on the right side, chloride anions are the spectator ions. And leaving those out, we get the net ionic equation, which is ammonia NH3 plus H+ goes to NH4+. So this is one way to write to the net ionic equation for this weak base-strong acid titration. Next, let's look at the titration curve for our weak base-strong acid titration. pH is on the y-axis and milliliters of acid is on the x-axis because we're adding our strong acid to our aqueous solution of our weak base. Looking at the first point on our titration curve, the pH is relatively basic. So this is before any strong acid has been added. The reason why the pH is basic is because we have an aqueous solution of our weak base, ammonia, which reacts with water to produce ammonium cations and hydroxide anions. And it's these hydroxide anions that cause the pH to be relatively high. However, the equilibrium favors the reactants for this reaction. So we have mostly ammonia and very little ammonium at this point in the titration curve. Next, we think about adding some acid to our aqueous solution of ammonia. And from our net ionic equation, when ammonia reacts with H+, that forms the ammonium cation, NH4+. Looking at the titration curve, as we add more and more acid, the pH starts to decrease. However, in this range, there's a slow decrease in the pH. As more acid is added, more ammonia is turned into the ammonium cation. Eventually, we reach a point where all of the initial ammonia has been neutralized by the addition of the acid. This point is called the equivalence point. And the way to find the equivalence point on our titration curve is to first look for this sharp decrease in the pH. And then we can draw a straight line here. And approximately halfway down that straight line is a good estimate of the equivalence point for this titration. To find the pH of the solution at the equivalence point, we simply go over to where the equivalence point is on the y-axis. And so for this pH, we can see the pH at the equivalence point is less than seven. So let me go ahead and write that down here. The pH is less than seven for a weak base-strong acid titration. The reason why the pH is less than seven at the equivalence point is because all the ammonia that we started with has been completely neutralized and turned into the ammonium cation, NH4+. The ammonium cation is a weak acid and reacts with water to form hydronium ions, H3O+, and ammonia, an aqueous solution. At 25 degrees Celsius, water has a pH of seven. However, since the ammonium cation is a weak acid and we're increasing the concentration of hydronium ions in solution, that decreases the pH, therefore the pH is less than seven at the equivalence point. In addition to ammonium ions, there are also chloride anions in solution. However, chloride anions do not react with water and therefore do not affect the pH. Going back to the equivalence point on our titration curve, if we dropped down here to the x-axis, we can see the equivalence point occurs after 50 milliliters of acid has been added. Therefore, if it took 50 milliliters of acid to neutralize all of the ammonia that was initially present, it would take half that volume or 25 milliliters of acid to neutralize half of the ammonia. So if we go back up here and we draw a dashed line to our titration curve, this point on our titration curve represents the half equivalence point. So this point represents the half equivalence point on our titration curve. And since we've neutralized half of the ammonia that was initially present, that means there are equal concentrations of ammonia and the ammonium cation at this point. Let's go back to our equivalence points where all the ammonia that we started with has been neutralized. Therefore, if we add some more acid to the solution, there's no more ammonia for it to react with. And therefore we see the pH drop. So this portion of the titration curve is the region of excess acid. Let's go back to the half equivalence point on our titration curve. Remember at that point, the concentration of ammonium cation is equal to the concentration of ammonia. The ammonium cation and ammonia are a conjugate acid-base pair. And when there are significant amounts of a weak conjugate acid-base pair, there's a buffer solution. Therefore, at the half equivalence point, we have a buffer solution, and we can calculate the pH at that point by using the Henderson-Hasselbalch equation. So pH is equal to the pKa of the weak acid, plus the log of the concentration of the conjugate base, divided by the concentration of the weak acid. For this example, the base is ammonia, NH3, and the conjugate acid is the ammonium cation. NH4+. Therefore, this pKa value in the Henderson-Hasselbalch equation is referring to the pKa value of ammonium. And because the concentrations of ammonium and ammonia are equal at the half equivalence point, the ratio of their concentrations is equal to one and the log of one is equal to zero. Therefore, at the half equivalence point, the pH is equal to the pKa value of the weak acid. So if we wanted to find the pKa value for the ammonium cation, we would find the half equivalence point and we'd draw our dotted line over to where the intersects on our y-axis and whatever pH that is, that's the pKa value of ammonium. So in this case, it looks to be a little bit over nine as a good estimate for the pKa value of the ammonium cation. Next, let's think about how our titration curve can tell us about the relative concentrations of our weak conjugate acid-base pair. We know that at the half equivalence points where the pH is equal to the pKa value, the concentration of ammonium cations is equal to the concentration of ammonia. So let's think about a point just to the left of our half equivalence point, which I'm gonna call point P. At point P, the pH is greater than the pKa value. And we know the initial point on our titration curve was almost all weak base, almost all NH3. Because point P is in between the initial point where there was almost all NH3, and the half equivalence point where there was equal amounts of NH3 and NH4+, at point P, there must be more NH3 than NH4+. Therefore, when the pH of the solution is greater than the pKa value, we know the concentration of ammonia is greater than the concentration of the ammonium cation. Or you could say the concentration of ammonium is less than the concentration of ammonia. We could have also figured this out using the Henderson-Hasselbalch equation. However, it's often easier just to think about the shape of the titration curve and where the point in question is in relation to important points. For example, in this case, the initial point and the half equivalence point. Next, let's think about a point just to the right of the half equivalence point. And I'm gonna call this point Q. At point Q, the pH of the solution is less than the pKa. Point Q is in between the half equivalence point and the equivalence point, which is approximately here on the titration curve. Remember at the equivalence point, all the ammonia that we started with has been converted into ammonium, NH4+. And because point Q is in between the half equivalence point where the amount of NH3 is equal to the amount of NH4+, and the equivalence point where all the NH3 has been converted into NH4+, all of the initial NH3. That means that at Q, there must be more NH4+ than NH3. Therefore, when the pH is less than the pKa value, we can say the concentration of ammonium, NH4+, is greater than the concentration of ammonia, NH3. The half equivalence point, point P and point Q are all a part of the buffer region on the titration curve. Remember that buffers resist large changes in pH, and that's why we see a slow decrease in pH as acid is added at this part of the titration curve. At the very beginning of the titration, we had almost all ammonia and therefore we did not have a buffer solution. However, as acid was added and the ammonia was converted into the ammonium cation, NH4+, when significant amounts of both are present, we do have a buffer solution. And that represents the buffer region on our titration curve, so in here. However, as more and more acid is added, we can see a sharp change in pH start to occur right about here, so we're no longer in the buffer region as we approach the equivalence point. So when we think about the titration curve of a weak base-strong acid titration, and we think about the half equivalence point where the pH is equal to the pKa value of the weak acid, it's important to remember that there's a buffer region or a buffer zone around that half equivalence point.