A student carried out an experiment to find the temperature rise for a reaction between hydrochloric acid and sodium hydroxide solution - AQA - A-Level Chemistry - Question 4 - 2018 - Paper 3

To calculate the percentage uncertainty in the temperature rise, first note that the uncertainty in the thermometer readings is ±0.1 °C. The formula for percentage uncertainty is:

ext{Percentage Uncertainty} = rac{ ext{Uncertainty}}{ ext{Value}} imes 100

In this case:

ext{Percentage Uncertainty} = rac{0.1}{1.3} imes 100 ext{ = 7.69 ext{ extperthousand} }

To minimize heat loss, one effective change would be to use a polystyrene cup or insulate the glass beaker. This would help to retain heat within the solution during the reaction.

Another change to decrease the percentage uncertainty could be to increase the magnitude of the temperature change being measured. A larger temperature change results in a higher signal-to-noise ratio, leading to more precise measurements.

The balanced equation for the reaction between ethanoic acid (HOOC(CHOH)) and potassium hydroxide (KOH) is:

$HOOC(CHOH) + KOH \rightarrow KOOCC(CHOH) + H_2O$

To calculate the enthalpy change (ΔH) per mole of water formed, first calculate the heat (q) absorbed using the formula:

$q = mc\Delta T$

Where:

• m = mass of solution (assuming the density is 1.00 g/cm³, the mass of 100 cm³ is approximately 100 g)
• c = specific heat capacity (4.2 J K⁻¹ g⁻¹)
• ΔT = change in temperature (3.2 °C)

Thus, q = 100 g imes 4.2 rac{J}{g imes K} imes 3.2 K = 1344 J

Now, for 0.080 mol of ethanoic acid used: The enthalpy change per mole of water formed is given by

$\Delta H = \frac{q}{n}$

Where n = 0.025 mol (since the reaction produces 1 mole of water for every mole of acid used), leading to:

$\Delta H = \frac{1344 J}{0.025} = 53760 J/mol = 53.76 kJ/mol.$

The difference in enthalpy values can be explained by the strength of the acids involved. Strong acids like sulfuric acid fully dissociate in solution, releasing more energy during the neutralization process compared to weaker acids like ethanoic acid, which do not fully dissociate. Therefore, different acid strengths lead to varying enthalpy changes during neutralization.