Consider the balanced equation below for a hypothetical reaction that takes place in a sealed 2 dm³ container at 300 K - NSC Physical Sciences - Question 6 - 2021 - Paper 2

The heat of the reaction (ΔH) is NEGATIVE. This indicates that the reaction is exothermic.

According to Le Chatelier's principle, if the temperature of an exothermic reaction is increased, the equilibrium will shift to favor the endothermic direction to absorb the added heat. Therefore, the addition of heat to the system would favor the reverse reaction, which is consistent with ΔH being negative.

To calculate the equilibrium constant (K) at 350 K, we use the formula:

$K = \frac{[PQ]^2}{[P]^2 [Q_2]}$

From the equilibrium amounts:

• P = 1.2 mol
• Q₂ = 0.8 mol
• PQ = 3.2 mol

Substituting these values into the equation: $K = \frac{(3.2)^2}{(1.2)^2(0.8)} = \frac{10.24}{1.44 \times 0.8} = \frac{10.24}{1.152} = 8.89$

Thus, the equilibrium constant at 350 K is approximately 8.89.

The equilibrium constant remains the SAME when the volume of the container is decreased at constant temperature. This is because the equilibrium constant is only affected by changes in temperature.

The yield of PQ(g) will INCREASE because adding more Q₂(g) shifts the equilibrium position to the right, producing more products.

The number of moles of P(g) will DECREASE. This occurs because P(g) is a reactant in the equilibrium reaction; as more Q₂(g) is added, P(g) is consumed to form more PQ(g).