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How does energy transform matter? - OCR 21st CenturyPractical - Measuring specific heat capacity

When energy is added to matter its temperature will rise. The temperature rise will depend on the mass which in turn depends on its density.

Part of Combined ScienceMatter - Models and explanations

Suggested practical - Measuring specific heat capacity

Jonny Nelson explains specific heat capacity with a GCSE Physics practical experiment

There are different ways to measure specific heat capacity. In this required practical activity, it is important to:

  • make and record potential difference, current and time accurately
  • measure and observe the change in temperature and energy transferred
  • use appropriate apparatus and methods to measure the specific heat capacity of a sample of material

Learn about the specific heat capacity practical in this podcast.

Aim

To measure the specific heat capacity of a sample of material.

Method

  1. Place an electrical immersion heater into the central hole at the top of a weighed metal block.
  2. Connect the heater in series with an ammeter and in parallel with a voltmeter.
  3. Place the thermometer into the smaller hole. Add two drops of oil into the hole to make sure the thermometer is surrounded by hot material.
  4. Insulate the block by wrapping it with cotton wool.
  5. Record the temperature of the block.
  6. Connect the heater to the power supply and turn it on for ten minutes. Record the current and potential difference.
  7. After ten minutes, turn the heater off. The temperature will still rise even though the heater has been turned off and then it will begin to cool. Record the highest temperature that it reaches.

Results

Record results in a suitable table. The one below shows some example results.

Current (A)Potential difference (V)Initial temperature (掳C)Final temperature (掳C)
3.6510.8015.038.0
Current (A)3.65
Potential difference (V)10.80
Initial temperature (掳C)15.0
Final temperature (掳C)38.0

Analysis

  1. Calculate the change in temperature. For the example results, this is: (38.0 - 15.0) = 23.0掳C.
  2. Calculate the electrical energy transferred.
    • time = (10 脳 60) = 600 s
    • energy transferred (J) = current (A) 脳 potential difference (V) 脳 time (s)
    • energy transferred in the example = 3.65 脳 10.80 脳 600
    • = 23,652 J
  3. Use the answer to step 2 to calculate the specific heat capacity of the block.
    • mass of block in example = 1.00 kg
    • change in thermal energy = mass 脳 specific heat capacity 脳 change in temperature

Rearrange the equation:

\(specific~heat~capacity = \frac{change~in~thermal~energy}{mass \times change~in~temperature}\)

\(specific~heat~capacity = \frac{23,652}{1.00 \times 23.0}\)

The actual value for the specific heat capacity of aluminium is 900 J/kg掳C. The calculated value does not match exactly but it is in the correct order of magnitude.

Evaluation

The accepted specific heat capacity of aluminium is 900 J/kg掳C. If the example results were for a block of aluminium, why is the experimental value different?

The experimental value is greater than the accepted value. This means that more energy was transferred than is needed for the aluminium alone. Some energy was transferred to the insulation and the surroundings instead.

Hazards and control measures

HazardConsequenceControl measures
Hot immersion heater and sample materialBurn skinDo not touch the heater when switched on and position it away from the edge of the bench. Allow time to cool before packing away equipment. Treat any burn by keeping the affected area under cold running water for at least 10 minutes.
HazardHot immersion heater and sample material
ConsequenceBurn skin
Control measuresDo not touch the heater when switched on and position it away from the edge of the bench. Allow time to cool before packing away equipment. Treat any burn by keeping the affected area under cold running water for at least 10 minutes.