A certain mass of calcium carbonate chunks is added to EXCESS hydrochloric acid solution in an open beaker placed on a scale as shown below - NSC Physical Sciences - Question 5 - 2016 - Paper 2

The mass of the contents decreases because carbon dioxide gas (CO₂) escapes into the atmosphere, which reduces the total mass of the system.

The reaction took 6 minutes to reach completion, as indicated by the stable mass of the beaker and contents after the 6^th minute.

To calculate the average rate, use the formula:

$ext{Rate} = - \frac{\Delta m}{\Delta t}$ where:

• Initial mass at 0 min = 192.4 g
• Mass at 1 min = 188.0 g Thus,
• Change in mass, (\Delta m = 188.0 - 192.4 = -4.4 g)
• Change in time, (\Delta t = 1 min)

Therefore,

$\text{Rate} = - \frac{-4.4 g}{1 min} = 4.4 \text{ g/min}$

1. As the reaction progresses, the concentration of reactants decreases, leading to fewer effective collisions between particles.
2. The reaction may generate products (like CaCl₂) that can create a barrier for further reaction, thus slowing it down.

Another substance that is not present is water (H₂O) as it's in liquid state, and it exits the reaction mixture.

The initial mass of the beaker and contents was 192.4 g, and the final mass was 186.7 g after completion. Therefore, the mass of calcium carbonate consumed is:

$192.4 g - 186.7 g = 5.7 g$

A graph should show a downward trend starting from 192.4 g at 0 minutes, decreasing to 186.7 g at 6 minutes, indicating the mass loss due to the escape of gas.

Increasing the temperature to 50 °C will increase the average kinetic energy of the particles. This means that more particles will have sufficient energy to overcome the activation energy barrier, leading to:

1. More frequent and effective collisions per unit time.
2. An overall increase in the reaction rate as temperature rises enhances particle movement and interaction.