pH buffer question help (1 Viewer)

MyHeadee · Mar 7, 2021

What is the pH change of the following buffer solution?

25mL buffer solution which has equimolar concentrations (0.1011M) of acetic acid and sodium acetate. What will the pH be if I add 5mL of 0.1032M NaOH to this?

Thanks

bigwilly69 · Mar 7, 2021

thush@decode · Mar 7, 2021

Henderson-Hasselbach equation:

pH = pKa + log_10 ([Ac-]/[HAc]) = pKa + log_10 (n(Ac-)/n(HAc))

Given we are only looking for the change in pH, we just need to see how "log_10 (n(Ac-)/n(HAc))" changes since pKa is constant.

Initially, log_10 (n(Ac-)/n(HAc)) = 0, as the acid and conjugate base are in equal concentrations and amounts initially.

Now we just need to find what the new value of the fraction n(Ac-)/n(HAc) would be.

Initially, n(HAc) = n(Ac-) = 0.025 x 0.1011 = 0.0025275 mol (yes I am being sloppy with sig figs)

When you add in NaOH, the OH- will pull the protons off the HAc to form Ac-.
Now, n(NaOH) = 0.005 x 0.1032 = 0.000516 mol.
So, 0.000516 mol of HAc will be converted to Ac-.
Hence

n(HAc)_new = 0.0025275 - 0.000516 = 0.0020115 mol
n(Ac-)_new = 0.0025275 + 0.000516 = 0.0030435 mol
log_10 (n(Ac-)/n(HAc)) = log_10 (0.0030435/0.0020115) = 0.180

Therefore, log_10 (n(Ac-)/n(HAc)) increases from 0 to 0.180 - increases by 0.180.

This means that pKa + log_10 (n(Ac-)/n(HAc)) will have increased by 0.180 (as pKa is constant).

Hence, pH change would be +0.180 (ignoring sig fig rules).

bigwilly69 · Mar 7, 2021

thush@decode said:
Henderson-Hasselbach equation:

pH = pKa + log_10 ([Ac-]/[HAc]) = pKa + log_10 (n(Ac-)/n(HAc))

Given we are only looking for the change in pH, we just need to see how "log_10 (n(Ac-)/n(HAc))" changes since pKa is constant.

Initially, log_10 (n(Ac-)/n(HAc)) = 0, as the acid and conjugate base are in equal concentrations and amounts initially.

Now we just need to find what the new value of the fraction n(Ac-)/n(HAc) would be.

Initially, n(HAc) = n(Ac-) = 0.025 x 0.1011 = 0.0025275 mol (yes I am being sloppy with sig figs)

When you add in NaOH, the OH- will pull the protons off the HAc to form Ac-.
Now, n(NaOH) = 0.005 x 0.1032 = 0.000516 mol.
So, 0.000516 mol of HAc will be converted to Ac-.
Hence

n(HAc)_new = 0.0025275 - 0.000516 = 0.0020115 mol

n(Ac-)_new = 0.0025275 + 0.000516 = 0.0030435 mol

log_10 (n(Ac-)/n(HAc)) = log_10 (0.0030435/0.0020115) = 0.180

Therefore, log_10 (n(Ac-)/n(HAc)) increases from 0 to 0.180 - increases by 0.180.

This means that pKa + log_10 (n(Ac-)/n(HAc)) will have increased by 0.180 (as pKa is constant).

Hence, pH change would be +0.180 (ignoring sig fig rules).

you're a gentleman and a scholar, thank you

Qeru · Mar 8, 2021

The Henderson-Hasselbach Equation isn't in the syllabus so a derivation is probably required. It's not too hard to prove:

The $K_a$ is defined as:

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

$[H_3O^+]=K_a \times \frac{[HA]}{[A^-]}$

$-\log{[H_3O^+]}=-\log\left({K_a \times \frac{[HA]}{[A^-]}}\right) \quad \text{taking the $-\log$ of both sides}$

$-\log{[H_3O^+]}=-\log{K_a}+\log{\frac{[A^-]}{[HA]}} \quad \text{ log laws}$

$\therefore pH=pK_a+\log{\frac{[A^-]}{[HA]}}$

CM_Tutor · Mar 8, 2021

You can also skip the HH equation completely by solving the problem using an ICE table.

pH buffer question help (1 Viewer)

MyHeadee

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thush@decode

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