Page 1 of 31 5.6 Electricity - Electromotive force and internal resistance 1 – Questions Q1. A battery of emf 9.0 V and internal resistance, r, is connected in the circuit shown in the figure below. (a) The current in the battery is 1.0 A. (i) Calculate the pd between points A and B in the circuit. answer = ____________________ V (2) (ii) Calculate the internal resistance, r. answer = ____________________ Ω (2) (iii) Calculate the total energy transformed by the battery in 5.0 minutes. answer = ____________________ J (2)
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5.6 Electricity - Electromotive force and internal resistance 1 – Questions
Q1. A battery of emf 9.0 V and internal resistance, r, is connected in the circuit shown in the figure below.
(a) The current in the battery is 1.0 A.
(i) Calculate the pd between points A and B in the circuit.
answer = ____________________ V (2)
(ii) Calculate the internal resistance, r.
answer = ____________________ Ω (2)
(iii) Calculate the total energy transformed by the battery in 5.0 minutes.
answer = ____________________ J (2)
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(iv) Calculate the percentage of the energy calculated in part (iii) that is dissipated in the battery in 5.0 minutes.
answer = ____________________ % (2)
(b) State and explain one reason why it is an advantage for a rechargeable battery to have a low internal resistance.
Q2. A battery of e.m.f. ε and internal resistance r is connected in series with a variable resistor R as shown in Figure 1. A voltmeter is connected as shown.
Figure 1
(a) (i) State what is meant by the e.m.f of a battery.
(b) In order to measure ε and r, an ammeter is used in the circuit, as shown in Figure 2.
Figure 2
The value of R is decreased in steps and at each step the readings V and I on the voltmeter and ammeter, respectively, are recorded. These are shown in the table.
reading on voltmeter/V reading on ammeter/A
4.0 0.07
3.0 0.14
2.0 0.21
1.0 0.28
(i) Plot a graph of V (on y axis) against I (on x axis) and draw the best straight line through the points.
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(ii) Determine the values of ε and r from the graph, explaining your method.
Q5. A battery of e.m.f. 12 V and internal resistance r is connected in a circuit with three resistors each having a resistance of 10 Ω as shown. A current of 0.50 A flows through the battery.
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Calculate
(a) the potential difference between the points A and B in the circuit,
(ii) If the resistor in part (a) is replaced by the lamp described in (b), determine how many cells, each of emf 1.5 V and internal resistance 1.2 Ω, would have to be connected in series so that the lamp would operate at its proper power.
Q7. In the circuit shown, a battery of emf and internal resistance r is connected to a variable resistor R. The current I and the voltage V are read by the ammeter and voltmeter respectively.
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(a) The emf is related to V, I and r by the equation
= V + Ir
Rearrange the equation to give V in terms of , I and r.
(b) In an experiment, the value of R is altered so that a series of values of V and the corresponding values of I are obtained. Using the axes, sketch the graph you would expect to obtain as R is changed.
(2)
(c) State how the values of and r may be obtained from the graph.
(ii) When the switch S is open, the voltmeter, which has infinite resistance, reads 8.0 V. When the switch is closed, the voltmeter reads 6.0 V. Determine the current in the circuit when the switch is closed.
Q10. A battery of emf and internal resistance r is connected in series to a variable resistor R and an ammeter of negligible resistance. A voltmeter is connected across R, as shown in the figure below.
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(a) (i) State what is meant by the emf of the battery.
(b) A student wishes to measure and r. Using the circuit shown in the figure above the value of R is decreased in steps and at each step the readings V and I on the voltmeter and ammeter respectively are recorded. These are shown in the table.
Q11. The heater in a kettle, designed to operate from the 12 V battery in a car, has a power rating of 130 W.
(a) Calculate the current drawn from the battery by the kettle.
current ____________________ A (2)
(b) The energy needed to raise the temperature of two cups of cold water to boiling point is 170 kJ. Calculate the minimum time, in minutes, that it would take to raise the temperature of this water to its boiling point.
time ____________________ minutes (3)
(c) The internal resistance of the battery affects the efficiency of the transfer of energy from the battery to the kettle. Explain what causes internal resistance and why this affects the efficiency.
(b) A resistor of value 470 Ω is connected across the terminals of the power supply in parallel with the voltmeter, as the figure below shows. The voltmeter reads 14.5 V.
Q14. A car battery has an emf of 12 V and an internal resistance of 9.5 × 10–3 Ω. When the battery is used to start a car the current through the battery is 420 A.
(a) Calculate the voltage across the terminals of the battery, when the current through the battery is 420 A.
(b) The copper cable connecting the starter motor to the battery has a length of 0.75 m and cross-sectional area of 7.9 × 10–5 m2. The resistance of the cable is 1.6 × 10–3 Ω.
Calculate the resistivity of the copper giving an appropriate unit.
Q15. The circuit in the diagram below contains four identical new cells, A, B, C and D, each of emf 1.5V and negligible internal resistance.
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(a) The resistance of each resistor is 4.0 Ω.
(i) Calculate the total resistance of the circuit.
answer = ____________________ Ω (1)
(ii) Calculate the total emf of the combination of cells.
answer = ____________________ V (1)
(iii) Calculate the current passing through cell A.
answer = ____________________ A (2)
(iv) Calculate the charge passing through cell A in five minutes, stating an appropriate unit.
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answer = ____________________ (2)
(b) Each of the cells can provide the same amount of electrical energy before going flat. State and explain which two cells in this circuit you would expect to go flat first.
Q16. (a) The rating of a car headlamp is 12 V, 55 W.
The resistance in this headlamp is due to a thin piece of wire. At its working temperature, the wire has a length of 5.0 × 10–2 m and a cross-sectional area of 1.9 × 10–8 m2. Calculate, at the working temperature, the resistivity of the metal used to make the wire. State an appropriate unit for your answer.
(ii) The figure below is a circuit diagram illustrating how two of these headlamps are connected to a car battery.
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The car battery has an emf of 12 V.
When the switch S is closed there is a current of 9.1 A through the battery and a potential difference of 11.9 V across the headlamps. Calculate the internal resistance of the car battery.
internal resistance ______________________ Ω (2)
(c) A fault develops in one of the headlamps in the figure above causing its resistance to decrease. State and explain how this fault affects the brightness of the other headlamp.
Q18. A cordless phone handset contains two rechargeable cells connected in series. Each cell has an emf of 2.0 V and, when fully charged, the combination stores energy sufficient to provide 850 mA for 1 hour.
(a) Calculate the total energy stored by the two cells when fully charged.
energy stored ____________________ J (3)
(b) The internal resistance of each cell is 0.60 . Calculate the potential difference across the two cells when they are connected in series across a 20.0 load.
potential difference ____________________ V (3)
(Total 6 marks)
Q19. The graph shows the current−voltage characteristic of the output from a solar cell when light of intensity 450 W m−2 is incident on it.
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(a) (i) Using data from the graph above estimate the maximum power output from the solar cell.
maximum power ____________________ W (2)
(ii) Sketch, on the axes below, a graph to show how the power output varies with voltage for this solar cell for the same incident light intensity.
(2)
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(iii) When the light intensity is 450 W m−2 the cell has an efficiency of 0.15 at the maximum power.
Calculate the area of the solar cell.
area ____________________ m2
(3)
(b) A manufacturer has a supply of solar cells that each have an electromotive force (emf) of 0.70 V and an internal resistance of 0.78 Ω when delivering maximum power.
(ii) The manufacturer uses a number of these solar cells in an array to make a power supply that has an emf of 14 V and an internal resistance of 3.9 Ω when delivering maximum power.
Describe and explain the arrangement of cells the manufacturer has to use in this array. Go on to calculate the number of cells the manufacturer needs to make the power supply.
(c) Communications satellites use solar cells to generate electrical power. Discuss why solar cells are appropriate for this task.
Your answer should refer to:
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• any additional features that would be needed to ensure that the satellite’s electrical systems operate continuously
• whether solar cell arrays are appropriate for space probes that travel to the edge of the solar system.
The quality of your written communication will be assessed in your answer. (6)
(Total 18 marks)
Q20. A cell of emf, ε, and internal resistance, r, is connected to a variable resistor R. The current through the cell and the terminal pd of the cell are measured as R is decreased. The circuit is shown in the figure below.
The graph below shows the results from the experiment.
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(a) Explain why the terminal pd decreases as the current increases.
(b) (i) Use the graph to find the emf, ε, of the cell.
answer = ______________________ V (1)
(ii) Use the graph above to find the internal resistance, r, of the cell.
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answer = ______________________ Ω (3)
(c) Draw a line on the graph above that shows the results obtained from a cell with
(i) the same emf but double the internal resistance of the first cell labelling your graph A.
(2)
(ii) the same emf but negligible internal resistance labelling your graph B. (1)
(d) In the original circuit shown in part (a), the variable resistor is set at a value such that the current through the cell is 0.89 A.
(i) Calculate the charge flowing through the cell in 15 s, stating an appropriate unit.
answer = ______________________ (2)
(ii) Calculate the energy dissipated in the internal resistance of the cell per second.
answer = ______________________ W (2)
(Total 13 marks)
Q21. A student investigates how the power dissipated in a variable resistor, Y, varies as the resistance is altered. Figure 1 shows the circuit the student uses. Y is connected to a battery of emf ε and
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internal resistance r.
Figure 1
Figure 2 shows the results obtained by the student as the resistance of Y is varied from 0.5 Ω to 6.5 Ω.
Figure 2
resistance of Y / Ω
(a) Describe how the power dissipated in Y varies as its resistance is increased from 0.5 Ω to 6.5 Ω.
(b) The emf of the battery is 6.0 V and the resistance of Y is set at 0.80 Ω.
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(i) Use data from Figure 2 to calculate the current through the battery.
current ____________________ A (3)
(ii) Calculate the voltage across Y.
voltage ____________________ V (2)
(iii) Calculate the internal resistance of the battery.
internal resistance ____________________ Ω (2)
(c) The student repeats the experiment with a battery of the same emf but negligible internal resistance. State and explain how you would now expect the power dissipated in Y to vary as the resistance of Y is increased from 0.5 Ω to 6.5 Ω.
Q22. The circuit diagram below shows a battery of electromotive force (emf) 12 V and internal resistance 1.5 Ω connected to a 2.0 Ω resistor in parallel with an unknown resistor, R. The battery supplies a current of 4.2 A.
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(a) (i) Show that the potential difference (pd) across the internal resistance is 6.3 V.
(1)
(ii) Calculate the pd across the 2.0 Ω resistor.
pd ____________________V (1)
(iii) Calculate the current in the 2.0 Ω resistor.
current ____________________A (1)
(iv) Determine the current in R.
current ____________________ A (1)
(v) Calculate the resistance of R.
R ____________________ Ω
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(1)
(vi) Calculate the total resistance of the circuit.
circuit resistance ____________________ Ω (2)
(b) The battery converts chemical energy into electrical energy that is then dissipated in the internal resistance and the two external resistors.
(i) Using appropriate data values that you have calculated, complete the following table by calculating the rate of energy dissipation in each resistor.
resistor rate of energy dissipation / W
internal resistance
2.0 Ω
R
(3)
(ii) Hence show that energy is conserved in the circuit.