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Acids and Bases - Calculations involving acids and bases (HL only)

Grade 12IBChemistry

Review the key concepts, formulae, and examples before starting your quiz.

🔑Concepts

The ionic product of water, Kw=[H+][OH]K_w = [H^+][OH^-], is temperature-dependent. At 298 K298\text{ K}, Kw=1.0×1014K_w = 1.0 \times 10^{-14}. In pure water, [H+]=[OH]=Kw[H^+] = [OH^-] = \sqrt{K_w}, which means pH=7.0pH = 7.0 only at 298 K298\text{ K}.

For weak acids (HAHA), the acid dissociation constant is Ka=[H+][A][HA]K_a = \frac{[H^+][A^-]}{[HA]}. For weak bases (BB), the base dissociation constant is Kb=[BH+][OH][B]K_b = \frac{[BH^+][OH^-]}{[B]}.

The relationship between KaK_a and KbK_b for a conjugate acid-base pair is Ka×Kb=KwK_a \times K_b = K_w, which implies pKa+pKb=pKwpK_a + pK_b = pK_w.

Buffer solutions consist of a weak acid and its conjugate base (or a weak base and its conjugate acid). They maintain a relatively constant pHpH when small amounts of acid or base are added.

During a titration of a weak acid with a strong base, at the half-equivalence point, [HA]=[A][HA] = [A^-]. At this point, pH=pKapH = pK_a.

Salt hydrolysis occurs when ions of a salt react with water. Salts from a strong acid and weak base produce acidic solutions (pH<7pH < 7), while salts from a weak acid and strong base produce basic solutions (pH>7pH > 7).

📐Formulae

pH=log10[H+]pH = -\log_{10}[H^+]

pOH=log10[OH]pOH = -\log_{10}[OH^-]

Kw=[H+][OH]=1.0×1014 (at 298 K)K_w = [H^+][OH^-] = 1.0 \times 10^{-14} \text{ (at 298 K)}

pKa=log10Ka and pKb=log10KbpK_a = -\log_{10}K_a \text{ and } pK_b = -\log_{10}K_b

pH+pOH=pKw=14.00 (at 298 K)pH + pOH = pK_w = 14.00 \text{ (at 298 K)}

[H+]=Ka×[HA]initial (for weak acids where dissociation is small)[H^+] = \sqrt{K_a \times [HA]_{initial}} \text{ (for weak acids where dissociation is small)}

pH=pKa+log10([base][acid]) (Henderson-Hasselbalch equation)pH = pK_a + \log_{10}\left(\frac{[base]}{[acid]}\right) \text{ (Henderson-Hasselbalch equation)}

💡Examples

Problem 1:

Calculate the pHpH of a 0.100 mol dm30.100\text{ mol dm}^{-3} solution of ethanoic acid (CH3COOHCH_3COOH) at 298 K298\text{ K}. Given Ka=1.8×105K_a = 1.8 \times 10^{-5}.

Solution:

[H+]=Ka×[CH3COOH]=1.8×105×0.100=1.8×1061.34×103 mol dm3[H^+] = \sqrt{K_a \times [CH_3COOH]} = \sqrt{1.8 \times 10^{-5} \times 0.100} = \sqrt{1.8 \times 10^{-6}} \approx 1.34 \times 10^{-3}\text{ mol dm}^{-3}. \ pH=log10(1.34×103)2.87pH = -\log_{10}(1.34 \times 10^{-3}) \approx 2.87.

Explanation:

Because ethanoic acid is a weak acid, we assume the equilibrium concentration of the acid is approximately equal to its initial concentration (0.100x0.1000.100 - x \approx 0.100).

Problem 2:

A buffer solution is prepared using 0.20 mol dm30.20\text{ mol dm}^{-3} propanoic acid (pKa=4.87pK_a = 4.87) and 0.10 mol dm30.10\text{ mol dm}^{-3} sodium propanoate. Calculate the pHpH of the buffer.

Solution:

pH=pKa+log10([A][HA])pH = pK_a + \log_{10}\left(\frac{[A^-]}{[HA]}\right) \ pH=4.87+log10(0.100.20)=4.87+log10(0.5)=4.870.30=4.57pH = 4.87 + \log_{10}\left(\frac{0.10}{0.20}\right) = 4.87 + \log_{10}(0.5) = 4.87 - 0.30 = 4.57.

Explanation:

The Henderson-Hasselbalch equation is used to find the pHpH of a buffer. Here, the concentration of the salt (conjugate base) is half that of the acid, making the pHpH lower than the pKapK_a.

Calculations involving acids and bases (HL only) Revision - Grade 12 Chemistry IB