Acid-base equilibria

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Created by
Ashling Asirifi

Cards (61)

  • Bronsted-Lowry acid

    A substance that can donate a proton
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  • Bronsted-Lowry base

    A substance that can accept a proton
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  • HCl (g) + H2O (l)
    H3O+ (aq) + Cl- (aq)
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  • Each acid is linked to a conjugate base
    On the other side of the equation
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  • pH
    • log [H+]
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  • [H+]
    Concentration of hydrogen ions in the solution
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  • Calculating pH of strong acids
    1. Strong acids completely dissociate
    2. The concentration of hydrogen ions will be the same as the concentration of the acid
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  • Finding [H+] from pH
    [H+] = 1 x 10-pH
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  • Ionic product for water (Kw)
    [H+ (aq)][OH- (aq)] / [H2O (l)]
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  • At 25°C, the value of Kw for all aqueous solutions is 1x10-14 mol2 dm-6
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  • Finding pH of pure water
    [H+ (aq)] = [OH- (aq)] = √Kw = 1x10-7 mol dm-3, so pH = 7
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  • Increasing temperature
    Pushes the water dissociation equilibrium to the right, increasing [H+] and decreasing pH
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  • Calculating pH of a strong base
    Use Kw = [H+ (aq)][OH- (aq)] to find [H+ (aq)] from [OH- (aq)]
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  • Weak acids
    Only slightly dissociate when dissolved in water, giving an equilibrium mixture
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  • Weak acid dissociation expression
    [H+ (aq)][A- (aq)] / [HA (aq)] = Ka
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  • Ka
    Acid dissociation constant, the larger the value the stronger the acid
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  • Calculating pH of a weak acid
    Assume [H+ (aq)] = [A- (aq)] and [HA (aq)] ≈ initial [HA (aq)], then use Ka = [H+ (aq)]2 / [HA (aq)]
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  • pKa
    • log Ka
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  • pH calculations involving neutralisation reactions
    Determine moles of acid and base, find which is in excess, calculate concentration of excess H+ or OH-
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  • Such as Ba(OH)2
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  • Calculating pH
    1. Moles HCl = 0.0075mol
    2. Moles Ba(OH)2 = 0.01575
    3. Moles OH- = 0.0315
    4. Moles of OH- in excess = 0.024
    5. [OH-] = 0.48 mol dm-3
    6. [H+] = 2.08x10-14 mol dm-3
    7. pH = 13.68
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  • Calculating pH
    1. Moles H2SO4 = 0.0175mol
    2. Moles H+ = 0.035
    3. Moles NaOH = 0.0165
    4. Moles of H+ in excess = 0.0185
    5. [H+] = 0.28 mol dm-3
    6. pH = 0.55
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  • Weak Acid and Strong Base Neutralisations
    • Work out moles of original acid
    • Work out moles of base added
    • Work out which one is in excess
    • Work out new concentration of excess HA
    • Work out concentration of salt formed [A-]
    • Rearrange Ka = [H+] [A-] / [HA] to get [H+]
    • pH = -log [H+]
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  • Calculating pH of weak acid-strong base neutralisation
    1. Moles CH3CO2H = 0.0275mol
    2. Moles NaOH = 0.00875
    3. Moles of CH3CO2H in excess = 0.01875
    4. [CH3CO2H] = 0.234M
    5. pH = 4.44
    6. [CH3CO2-] = 0.109M
    7. [H+] = 3.64 x 10-5 M
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  • Weak Acid at Half Equivalence
    • At half neutralisation [HA] = [A-]
    • pH = pKa
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  • pH = pKa = 4.77
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  • Diluting an acid or alkali
    • pH of diluted strong acid: [H+] = [H+]old x old volume / new volume, pH = -log [H+]
    • pH of diluted base: [OH-] = [OH-]old x old volume / new volume, [H+] = Kw / [OH-], pH = -log [H+]
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  • Calculating pH of diluted strong acid
    1. [H+] = 0.0136 mol dm-3
    2. pH = 1.87
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  • Buffer Solutions
    • Acidic buffer: weak acid + salt of weak acid
    • Basic buffer: weak base + salt of weak base
    • Buffer solutions resist changes in pH when small amounts of acid or alkali are added
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  • In a buffer solution there is a much higher concentration of the salt conjugate base ion than in the pure acid
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  • How buffer solutions work
    • If acid is added, the conjugate base reacts with it to remove the H+ ions
    • If alkali is added, the equilibrium shifts to produce more H+ ions
    • The ratio [HA]/[A-] stays almost constant, so pH stays constant
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  • Calculating pH of buffer made by adding salt solution
    1. Moles ethanoic acid = 0.0045 mol
    2. Moles sodium ethanoate = 0.0075 mol
    3. [H+] = 1.02x 10-5 mol dm-3
    4. pH = 4.99
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  • Calculating pH of buffer made by adding solid salt
    1. Moles ethanoic acid = 0.04 mol
    2. Moles sodium ethanoate = 0.0134 mol
    3. [H+] = 5.07x 10-5 mol dm-3
    4. pH = 4.29
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  • Calculating pH of buffer made by partially neutralising a weak acid
    1. Moles CH3CO2H = 0.0275 mol
    2. Moles NaOH = 0.00875 mol
    3. Moles excess CH3CO2H = 0.01875 mol
    4. [CH3CO2H] = 0.234 mol dm-3
    5. [CH3CO2-] = 0.109 mol dm-3
    6. [H+] = 3.64 x 10-5 mol dm-3
    7. pH = 4.44
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  • Calculating the pH of Buffer Solutions
    • Use the weak acid dissociation expression: [H+][A-]/[HA] = Ka
    • Assume [A-] is due to the added salt only
    • Assume [HA] has remained constant
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  • The salt content can be added in several ways: a salt solution, some solid salt, or by partially neutralising a weak acid with alkali
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  • pH
    • log[H+]
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  • Calculating pH of Buffer Solutions
    [H+
    (aq)][A-
    (aq)]/[HA (aq)] = Ka
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  • We still use the weak acids dissociation expression
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  • We assume the [A-] concentration is due to the added salt only
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