Calorimetry (Oxford AQA IGCSE Chemistry)
Revision Note
Written by: Alexandra Brennan
Reviewed by: Stewart Hird
Calorimetry
We can experimentally determine the relative amounts of energy released by a fuel
We do this using simple calorimetry
The apparatus for this experiment is shown below
Diagram to show the set up of calorimetry equipment
The steps are:
Measure a fixed volume of water into a copper can
Weigh the spirit burner containing a fuel using a balance
Measure the initial temperature of the water
Burn the fuel and stir the water
Wait until the temperature has risen by approximately 20 oC and extinguish the flame
Record the final temperature of the water and re-weigh the spirit burner
To calculate the energy released by the fuel we can use the data obtained from the experiment above and the specific heat capacity of water
The specific heat capacity, c, is the energy needed to raise the temperature of 1 g of a substance by 1 °C
The specific heat capacity of water is 4.18 J/g/°C
The heat energy change is calculated using:
Q = m x c x ΔT
Q = the heat energy change, J
m = the mass of the substance being heated, g
c = the specific heat capacity, J/g/°C
ΔT = the temperature change, °C
Worked Example
1.023 g of the fuel propanol was burned in a spirit burner and used to heat 200 g of water in a copper calorimeter.
The temperature of the water rose by 30 oC.
Calculate the heat energy change, Q, for the combustion of propanol using this data.
Answer:
Q = m x c x ΔT
Q = 200 g x 4.18 J/g/°C x 30 °C = 25 080 J
Combustion is an exothermic reaction so the energy change should be negative
This calculation gave you a positive answer so you need to add a minus sign in front = - 25 080 J
Calculating Energy Changes
We can compare the amount of energy released per gram and per mole for different fuels
In both cases, the energy released (Q) is calculated first
To calculate the energy released per gram of fuel:
energy released per gram= energy released / mass of fuel burned
To calculate the energy released per mole of fuel:
energy released per mole= energy released / number of moles
The energy released per mole is also known as the molar enthalpy change
The units are kJ / mol
Worked Example
In a calorimetry experiment, 2.50 g of methane is used to heat up 100 g of water. The temperature increases by 43 oC.
The specific heat capacity of water is 4.18 J g-1 °C−1
What is the total energy released per gram of methane burnt?
Answer:
Step 1: Q = m x c x ΔT
m (of water) = 100 g
c (of water) = 4.18 J g-1 °C-1
ΔT (of water) = 43 oC
Q = 100 x 4.18 x 43 = 17 974 J
Step 2: This is released by 2.50 g of methane
Energy released by 1.00 g of methane:
17 974 ÷ 2.50
= 7 189.6 J/g
= -7.189 kJ/g
Worked Example
The energy from 0.01 mol of propanol was used to heat up 250 g of water.
The temperature of the water rose from 25 °C to 37 °C .
The specific heat capacity of water is 4.18 J/g/°C.
Calculate the enthalpy change in kJ/mol.
Answer:
Step 1: Q = m x c x ΔT
m (of water) = 250 g
c (of water) = 4.18 J /g/°C
ΔT (of water) = 37 – 25 °C = 12 °C
Q = 250 x 4.18 x 12 = 12 540 J
Step 2: Calculate the energy released per mole
ΔH = Q ÷ n
12 540 J ÷ 0.01 mol = 1 254 000 J/mol
– 1254 kJ/mol
Examiner Tips and Tricks
When you determine Q your answer will be in joules, but enthalpy change is measured in kJ/mol. Make sure you convert Q to kilojoules by dividing by 1000.
Reactions where energy has been released / the temperature has increased are exothermic- this means your answers for enthalpy changes should be negative.
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