Sulfur dioxide is a colourless, toxic gas that is soluble in water and more dense than air - Scottish Highers Chemistry - Question 5 - 2017

In the second box, the drawing should depict a gas jar or a gas collection tube. It is critical to indicate that this apparatus is placed in a safe and controlled environment, away from any reactive substances.

To determine the limiting reactant:

1. Calculate the moles of sodium sulfite:

   ext{Moles of Na}_2 ext{SO}_3 = rac{0.40 ext{ g}}{126.1 ext{ g mol}^{-1}} \ = 0.00317 ext{ mol}.

2. Since the reaction requires 2 moles of HCl for every mole of Na2SO3, we need:

   ext{Moles of HCl required} = 2 imes 0.00317 ext{ mol} = 0.00634 ext{ mol}.

3. Calculate the moles of HCl available:

   ext{Moles of HCl} = c imes V = 1 ext{ mol l}^{-1} imes 0.050 ext{ L} = 0.050 ext{ mol}.

4. Since we require only 0.00634 mol of HCl and have 0.050 mol available, sodium sulfite (Na2SO3) is the limiting reactant.

The overall enthalpy change for the reaction can be calculated using Hess's law:

ext{ΔH} = (	ext{ΔH of products}) - (	ext{ΔH of reactants})

1. From the information given:

   ext{Reactants: } C_2S_2 ext{ and } 3 O_2 ightarrow ext{Products: } CO_2 ext{ and } 2 SO_2

2. For this reaction:

   ext{ΔH} = [(-393) + 2(-296)] - (+87.9) \ = -393 - 592 + 87.9 \ = -897 + 87.9 = -809.1 ext{ kJ mol}^{-1}.

3. Therefore, the enthalpy change ext{ΔH} = -897.1 ext{ kJ mol}^{-1}.

From the graph, at a temperature of 10 °C, the solubility of sulfur dioxide is approximately 150 g l⁻¹.

The difference in solubility can be attributed to molecular structure and polarity:

• Carbon dioxide (CO2) is a linear molecule with non-polar characteristics, resulting in weak interactions with water molecules.
• In contrast, sulfur dioxide (SO2) has a bent shape and polar characteristics; thus, it is better able to interact with water molecules through dipole-dipole interactions.
• The polarity of SO2 promotes stronger hydrogen bonding with water, leading to its much higher solubility.