Electromotive force and potential difference
14 flashcards to master Electromotive force and potential difference
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Define electromotive force (e.m.f.).
Electromotive force (e.m.f.) is the electrical work done by a source in moving a unit charge around a complete circuit. This work done is measured in Joules per Coulomb (J/C) or Volts (V).
A battery transfers 12 Joules of energy to move 4 Coulombs of charge around a complete circuit. What is the electromotive force (e.m.f.) of the battery?
e.m.f. = Work Done / Charge
e.m.f. = 12 J / 4 C
e.m.f. = 3 V
The electromotive force of the battery is 3 Volts. It represents the energy provided by the battery per unit charge passing through it.
What unit is electromotive force (e.m.f.) measured in?
Electromotive force (e.m.f.) is measured in volts (V).
Volts (V) are the SI unit for electrical potential difference, including e.m.f.
A student measures the electromotive force (e.m.f.) of a battery. They record the value as 1.5. What is the unit missing from this measurement?
The unit missing is volts (V).
Therefore, the correct measurement is 1.5 V. E.m.f is always measured in volts.
Define potential difference.
Potential difference is the work done per unit charge when charge flows between two points in a circuit. It is measured in Volts (V). This means 1 Volt is equal to 1 Joule per Coulomb (1 V = 1 J/C).
A lightbulb has a potential difference of 6.0 V across it. Explain what this means, in terms of energy transfer and charge.
A potential difference of 6.0V across the lightbulb means that for every 1 Coulomb of charge that passes through the bulb, 6.0 Joules of electrical energy is transferred into light and heat energy. The charge loses 6.0 J of energy as it moves through the bulb.
What unit is used to measure potential difference?
The unit used to measure potential difference is the volt (V).
Explanation: Potential difference, often referred to as voltage, quantifies the electrical potential energy difference between two points in a circuit. It is the 'push' that drives current.
A battery is labelled as '3.0 V'. What does this label tell you about the battery?
The label tells you that the potential difference (p.d.) across the terminals of the battery is 3.0 volts.
Explanation: This means the battery provides 3.0 Joules of electrical energy per Coulomb of charge that passes through it.
Describe how you would use a voltmeter to measure the potential difference across a resistor in a circuit. Include details about the connections required.
1. Select an appropriate range on the voltmeter. If the expected potential difference is unknown, start with the highest range and decrease until a reading is obtained without exceeding the scale.
2. Connect the voltmeter *in parallel* with the resistor. This means connecting one terminal of the voltmeter to each end of the resistor.
3. Ensure the positive terminal of the voltmeter is connected to the point in the circuit with the higher potential (usually the side connected to the positive terminal of the power supply).
4. Read the potential difference from the voltmeter's scale or digital display. The voltmeter displays the potential difference.
You have an analogue voltmeter with ranges of 3V, 15V, and 30V. You need to measure the potential difference across a component in a circuit. You estimate the potential difference to be approximately 12V. Which range should you select and why?
You should select the 15V range.
Reasoning: The 3V range is too low as the reading (12V) would exceed the scale and potentially damage the meter. The 30V range could be used, but it would result in a less precise reading as the needle would deflect less, making it more difficult to read accurately. Selecting 15V gives an appropriate reading on the scale.
A battery with an internal resistance of 0.5 ohms delivers a current of 2.0 A to a circuit. If the terminal potential difference across the battery is 5.0 V, calculate the electromotive force (e.m.f.) of the battery.
Formula: e.m.f. = V + Ir
e.m.f. = 5.0 V + (2.0 A * 0.5 Ω)
e.m.f. = 5.0 V + 1.0 V
e.m.f. = 6.0 V
Explanation: The e.m.f. is the total energy supplied per unit charge, which is the sum of the terminal potential difference (V) and the potential drop across the internal resistance (Ir).
Explain why the terminal potential difference of a battery is always less than its electromotive force (e.m.f.) when the battery is supplying current to a circuit.
When a battery supplies current, some energy is dissipated as heat due to the internal resistance of the battery. This energy loss results in a voltage drop (Ir) within the battery itself. Therefore, the terminal potential difference (V), which is the voltage measured across the battery's terminals, is equal to the e.m.f. minus the voltage drop due to the internal resistance (V = e.m.f. - Ir). Since Ir is always positive when a current is flowing, the terminal potential difference is always less than the e.m.f.
A 6.0 V battery transfers 1200 J of energy to a circuit. Calculate the charge that flows through the circuit.
Formula: V = W / Q, where V = potential difference, W = energy, and Q = charge.
Rearranging: Q = W / V
Calculation: Q = 1200 J / 6.0 V = 200 C
Answer: The charge that flows through the circuit is 200 Coulombs (C).
Explain, in terms of energy transfer, what is meant by a potential difference of 9.0 V across a component.
A potential difference of 9.0 V across a component means that 9.0 Joules (J) of energy are transferred per Coulomb (C) of charge that passes through the component. The charge loses 9 J of electrical energy to the component, which is then converted to other forms of energy.
Key Questions: Electromotive force and potential difference
Define electromotive force (e.m.f.).
Electromotive force (e.m.f.) is the electrical work done by a source in moving a unit charge around a complete circuit. This work done is measured in Joules per Coulomb (J/C) or Volts (V).
What unit is electromotive force (e.m.f.) measured in?
Electromotive force (e.m.f.) is measured in volts (V).
Volts (V) are the SI unit for electrical potential difference, including e.m.f.
Define potential difference.
Potential difference is the work done per unit charge when charge flows between two points in a circuit. It is measured in Volts (V). This means 1 Volt is equal to 1 Joule per Coulomb (1 V = 1 J/C).
What unit is used to measure potential difference?
The unit used to measure potential difference is the volt (V).
Explanation: Potential difference, often referred to as voltage, quantifies the electrical potential energy difference between two points in a circuit. It is the 'push' that drives current.
About Electromotive force and potential difference (4.2.3)
These 14 flashcards cover everything you need to know about Electromotive force and potential difference for your Cambridge IGCSE Physics (0625) exam. Each card is designed based on the official syllabus requirements.
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- 4 Definitions - Key terms and their precise meanings that examiners expect
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After mastering Electromotive force and potential difference, explore these related topics:
- 4.2.2 Electric current - 12 flashcards
- 4.2.4 Resistance - 10 flashcards
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