Required Practical: Charging & Discharging Capacitors
Aim of the Experiment
- The overall aim of this experiment is to calculate the capacitance of a capacitor. This is just one example of how this required practical might be carried out
Variables
- Independent variable = time, t
- Dependent variable= potential difference, V
- Control variables:
- Resistance of the resistor
- Current in the circuit
Equipment List
- Resolution of measuring equipment:
- Voltmeter = 0.1 V
- Stopwatch = 0.01 s
Method
- Set up the apparatus like the circuit above, making sure the switch is not connected to X or Y (no current should be flowing through)
- Set the battery pack to a potential difference of 10 V and use a 10 kΩ resistor. The capacitor should initially be fully discharged
- Charge the capacitor fully by placing the switch at point X. The voltmeter reading should read the same voltage as the battery (10 V)
- Move the switch to point Y
- Record the voltage reading every 10 s down to a value of 0 V. A total of 8-10 readings should be taken
- An example table might look like this:
Analysing the Results
- The potential difference (p.d) across the capacitance is defined by the equation:
- Where:
- V = p.d across the capacitor (V)
- V0 = initial p.d across the capacitor (V)
- t = time (s)
- e = exponential function
- R = resistance of the resistor (Ω)
- C = capacitance of the capacitor (F)
- Rearranging this equation for ln(V) by taking the natural log (ln) of both sides:
- Comparing this to the equation of a straight line: y = mx + c
- y = ln(V)
- x = t
- gradient = -1/RC
- c = ln(V0)
- Plot a graph of ln(V) against t and draw a line of best fit
- Calculate the gradient (this should be negative)
- The capacitance of the capacitor is equal to:
Evaluating the Experiment
Systematic Errors:
- If a digital voltmeter is used, wait until the reading is settled on a value if it is switching between two
- If an analogue voltmeter is used, reduce parallax error by reading the p.d at eye level to the meter
- Make sure the voltmeter starts at zero to avoid a zero error
Random Errors:
- Use a resistor with a large resistance so the capacitor discharges slowly enough for the time to be taken accurately at p.d intervals
- Using a datalogger will provide more accurate results for the p.d at a certain time. This will reduce the error in the speed of the reflex needed to stop the stopwatch at a certain p.d
- The experiment could be repeated by measuring the time for the capacitor to charge instead
Safety Considerations
- Keep water or any fluids away from the electrical equipment
- Make sure no wires or connections are damaged and contain appropriate fuses to avoid a short circuit or a fire
- Using a resistor with too low a resistance will not only mean the capacitor discharges too quickly but also that the wires will become very hot due to the high current
- Capacitors can still retain charge after power is removed which could cause an electric shock. These should be fully discharged and removed after a few minutes
Worked Example
A student investigates the relationship between the potential difference and the time it takes to discharge a capacitor. They obtain the following results:
The capacitor is labelled with a capacitance of 4200 µF. Calculate:
(i) The value of the capacitance of the capacitor discharged.
(ii) The relative percentage error of the value obtained from the graph and this true value of the capacitance.
Step 1: Complete the table
- Add an extra column ln(V) and calculate this for each p.d
Step 2: Plot the graph of ln(V) against average time t
- Make sure the axes are properly labelled and the line of best fit is drawn with a ruler
Step 3: Calculate the gradient of the graph
- The gradient is calculated by:
Step 4: Calculate the capacitance, C
Step 5: Calculate the relative percentage error of the value obtained
