After start point and before stoichiometric point of titration

How do we mathematically describe the titration curve of weak monoprotic acid versus a strong monoprotic base after the start point and before the stoichiometric point?

We shall make three assumptions:

- [H⁺] from water is negligible, i.e. H⁺ in the flask containing the weak acid is solely due to that of the acid, [H⁺]_a, as the dissociation of water is again suppressed at this stage.
- For a weak acid, [HA] is approximately equal to the concentration of the undissociated acid, [HA]_ud, i.e. the dissociation of the weak acid HA is negligible and the remaining concentration of HA after the addition of base is [HA]_r= [HA]_ud– [A^–]_s.
- [A^–] is approximately equal to the concentration of the salt, [A^–]_s, in the solution, i.e. A^–is completely attributed to the salt formed, with no contribution from the further dissociation of HA.

The equation for the dissociation of a weak monoprotic acid is

$HA(aq)\rightleftharpoons H^+(aq)+A^-(aq)$

with the equilibrium constant after start point and before stoichiometric point being:

$K_a=\frac{[H^+]_a[A^-]_s}{[HA]_r}$

Taking the logarithm on both sides and apply the definitions of pH and pK_a,

$pH=pK_a+log\frac{[A^-]_s}{[HA]_r}\; \; \; \; \; \; \; \; (2)$

Eq2 is known as the Henderson-Hasselbalch equation, which is a good approximation of the pH curve after the start point and before the stoichiometric point for a strong base to weak acid titration with K_a≤ 10^-3(or a strong acid to weak base titration with K_b≤ 10^-3).

Question

Rewrite eq2 to include the volume of acid V_aand the volume of base V_b. What will the pH curve formula be if we disregard the 2^nd and 3^rd assumptions?

Answer

$pH=pK_a+log\left ( \frac{[B]V_b}{V_a+V_b}/\frac{[A]V_a-[B]V_b}{V_a+V_b} \right )$

$pH=pK_a+log\left ( \frac{[B]V_b}{[A]V_a-[B]V_b} \right )\; \; \; \; \; \; \; \; (2a)$

where [A] = [HA]_udand [B] is the initial concentration of the monoprotic base. See this article for the derivation of the pH curve formula without the 2^nd and 3^rd assumptions.

The diagram below is the superimposition of a green curve (the Henderson-Hasselbalch equation, eq2a) on a blue curve (the complete pH titration curve, which disregards the above three assumptions), for the titration of 10 cm³ of 0.200 M of CH₃COOH (K_a = 1.75 x 10^-5) with 0.100 M of NaOH.

Even though the two curves appear to fit perfectly (apart from the initial bit before 1.00 cm³), they do not actually coalesce and are still two separate curves (discernible when the axes of the plot are scaled to a very high resolution). However, for practical purposes, the Henderson-Hasselbalch equation is a very good approximation of a pH curve for the region after the start point and before the stoichiometric point for a strong base to weak acid titration.

When [A^–]_s= [HA]_r, eq2 becomes

$pH=pK_a\; \; \; \; \; \; \; \; (3)$

Eq3 occurs when the amount of salt formed equals to [HA]_ud/2, i.e. when half of the acid is neutralised. This stoichiometric relation corresponds to the curve’s inflexion point, which is also called the maximum buffer capacity point.

Question

Why does the solution have maximum buffer capacity when half of the acid is neutralised, i.e. at the half-way volume point between the start point and the stoichiometric point?

Answer

For the buffer to be most effective, it has to resist to the greatest extent the change in pH versus the change in volume of base added. This means that the maximum buffer capacity corresponds to the point where the gradient of the function of eq2a is a minimum, i.e. at the inflexion point (see above diagram).

Taking the 2nd derivative of eq2a with respect to V_band letting $\frac{d^2pH}{dV_b^2}=0$ , we have

$\frac{n_b}{n_a}=\frac{1}{2}$

where $n_b=\left [ B \right ]V_b$ and $n_a=\left [ A \right ]V_a$ .

Therefore, the inflexion point occurs when half of the total volume of base required for complete neutralisation of the acid is added.

If you want a full mathematical description of the maximum buffer capacity of a weak acidic buffer, read this article in the advanced section.

For a strong acid to weak base titration, we have the following weak base equilibrium:

$BOH(aq)\rightleftharpoons B^+(aq)+OH^-(aq)$

$K_b=\frac{[B^+][OH^-]}{[BOH]}$

Taking the logarithm on both sides of the above equation and rearranging,

$pOH=pK_b+log\frac{[B^+]}{[BOH]}\; \; \; \; \; \; \; \; (3a)$

Eq3a is the basic form of the Henderson-Hasselbalch equation.

With reference to eq2 (or eq3a), knowing the pH of a strong base to weak acid titration (or knowing the pOH of a strong acid to weak base titration) at the half-way volume point, we can calculate the pK_a (or pK_b) of the weak acid (or weak base).

Question

Show that pK_a + pK_b = 14.

Answer

$HA(aq)+H_2O(l)\rightleftharpoons A^-(aq)+H_3O^+(aq)$

$A^-(aq)+H_2O(l)\rightleftharpoons HA(aq)+OH^-(aq)$

$K_a=\frac{[A^-][H_3O^+]}{[HA]}\; \; \; \; \; \; \; \; K_b=\frac{[HA][OH^-]}{[A^-]}$

$pK_a+pK_b=-log\frac{[A^-][H_3O^+]}{[HA]}-log\frac{[HA][OH^-]}{[A^-]}$

$=-log[H_3O^+][OH^-]=-logK_w=14$

After start point and before stoichiometric point of titration

Question

Answer

Question

Answer

Question

Answer

next article: stoichiometric point of titration

Previous article: start point of titration

Content page of strong base to weak acid titration curve

Content page of intermediate chemistry

Main content page

Leave a Reply Cancel reply