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Topic 3.1.6: Equilibria - Exam Practice

AQA A-Level Chemistry • Physical Chemistry • Exam Practice

Exam Practice

Topic 3.1.6: Chemical Equilibria & Kc Exam Practice

Test your understanding of dynamic equilibrium, Le Chatelier's Principle, and equilibrium constant Kc calculations.

Chemical Equilibria & Kc Exam Practice

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📋 Structured Questions

Complete each question on paper, then check your answers against the mark scheme.

Question 1: Le Chatelier's Principle

8 marks

Methanol is manufactured industrially by the reaction of carbon monoxide with hydrogen: CO(g) + 2H2(g) ⇌ CH3OH(g) (ΔH = -91 kJ mol^-1). Predict and explain the effect of the following changes on the position of equilibrium and the rate of the reaction:

(a) The temperature of the system is increased. [4]

(b) The pressure of the system is increased. [4]

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(a) Temperature increase:

  • Rate: Increases because particles have more kinetic energy and move faster, leading to a higher collision frequency. More importantly, a much larger fraction of colliding molecules have energy greater than or equal to the activation energy. [2]
  • Equilibrium position: Shifts to the left. [1] Since the forward reaction is exothermic, the reverse reaction is endothermic. The system shifts in the endothermic direction to absorb heat and oppose the temperature rise. [1]

(b) Pressure increase:

  • Rate: Increases because gaseous reactant molecules are compressed into a smaller volume, increasing the number of molecules per unit volume, which increases the collision frequency. [2]
  • Equilibrium position: Shifts to the right. [1] There are 3 moles of gas on the left-hand side (1 CO + 2 H2) and only 1 mole of gas on the right-hand side (1 CH3OH). The system shifts to the side with fewer gas moles to decrease the pressure and oppose the pressure rise. [1]
Examiner tip: Separate "rate" and "equilibrium position" clearly in your written answers. For temperature rate effects, remember that the collision frequency change is minor; the main driver is the fraction of successful collisions. For pressure, always state the number of gas moles on each side of the equation.

Question 2: Equilibrium Constant Kc calculation

5 marks

A student mixes 2.00 mol of ethanol (CH3CH2OH) and 1.50 mol of ethanoic acid (CH3COOH) in a closed flask. The mixture is left to reach equilibrium at a constant temperature: CH3COOH(l) + CH3CH2OH(l) ⇌ CH3COOCH2CH3(l) + H2O(l). At equilibrium, the mixture contains 0.85 mol of ethyl ethanoate (ester). Calculate the value of the equilibrium constant Kc for this reaction at this temperature. [5]

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Set up ICE table (moles):

Species CH3COOH CH3CH2OH CH3COOCH2CH3 H2O
Initial 1.50 2.00 0 0 [1]
Change -0.85 -0.85 +0.85 +0.85
Equilibrium 0.65 [1] 1.15 [1] 0.85 0.85 [1]

Calculate Kc:

  • Kc expression: Kc = [CH3COOCH2CH3] * [H2O] / ([CH3COOH] * [CH3CH2OH])
  • Since the total volume V cancels out (same number of moles on both sides):
    Kc = (0.85/V * 0.85/V) / (0.65/V * 1.15/V) = (0.85 * 0.85) / (0.65 * 1.15)
  • Kc = 0.7225 / 0.7475 = 0.967 (or 0.97) [1]
  • Units: None (all units cancel).
Examiner tip: In esterification, water is a product and is liquid, so its concentration must be included in the Kc expression. Do not ignore water here. Since the total moles of reactants equals the total moles of products, volume cancels out, which simplifies the calculation. However, you should state that volume cancels.

Question 3: Factors Affecting Kc

4 marks

Explain why the value of the equilibrium constant Kc for the following reaction: N2(g) + O2(g) ⇌ 2NO(g) (ΔH = +180 kJ mol^-1) increases as the temperature increases, but remains unchanged when the total pressure is increased. [4]

Show Mark Scheme
  • The forward reaction is endothermic (ΔH is positive). [1]
  • When temperature increases, the position of equilibrium shifts to the right (in the endothermic direction) to absorb the added heat and oppose the change. [1]
  • This increases the equilibrium concentrations of the products (NO) and decreases those of the reactants (N2 and O2), resulting in a larger value for the ratio in the Kc expression, so Kc increases. [1]
  • Increasing pressure increases the concentrations of all species, but they adjust so that the ratio in the Kc expression remains constant, meaning Kc is unaffected by pressure changes. [1]
Examiner tip: Remember the fundamental rule: only temperature changes the value of Kc. Pressure and concentration shifts will alter individual concentrations, but they shift in such a way that the ratio is restored to the original Kc value.

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