Notes

Electromagnetic induction (Higher)

The generator effect

If a conductor moves through a magnetic field (or a magnetic field changes near a conductor), an emf (potential difference) is induced across the conductor. This is the generator effect — it is the reverse of the motor effect.

Three things must happen for an emf to be induced:

A conductor and a magnetic field.
Relative motion between them, OR a changing field.
The conductor must cut field lines.

If the conductor forms a complete circuit, an induced current flows.

Factors that increase induced emf

Faster relative motion (cut field lines more quickly).
Stronger magnet (denser field lines).
More turns on the coil.
Larger coil area.

Direction of the induced current — Lenz's law (qualitative)

The induced current flows in the direction that opposes the change producing it. If you push a magnet north-pole-first into a coil, the coil acts like a magnet whose north pole faces the incoming magnet, repelling it. This is energy conservation in action — you have to do work against the repulsion, and that work becomes electrical energy.

Reverse the direction of motion (or flip the magnet) and the induced current reverses.

AC generator (alternator)

A coil rotates inside a magnetic field. As the coil rotates, the rate at which it cuts field lines changes:

Coil parallel to field → cutting fastest → maximum induced emf.
Coil perpendicular to field → not cutting → emf = 0.

The emf alternates direction every half rotation, producing alternating current (ac). Slip rings and brushes connect the rotating coil to the external circuit.

A graph of emf vs time is a sine wave; frequency = rotation frequency of the coil. Mains UK frequency is 50 Hz.

DC dynamo

Same as an alternator but uses a split-ring commutator (like a motor) instead of slip rings. The commutator reverses the connection every half turn, so the output is always positive — direct current with a pulsing magnitude.

Microphones and dynamos in everyday life

A moving-coil microphone uses the same effect: sound waves move a coil through a permanent magnet's field, inducing a tiny ac voltage that mirrors the sound wave. Bicycle dynamos drive lights from rotation of the wheel.

Edexcel exam tip

For "explain how the size of the induced current can be increased" the marks come in pairs: one method + the reason it works. "Use a stronger magnet so more field lines are cut per second" earns 2 marks; just "stronger magnet" earns 1.

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Practice questions

Try each before peeking at the worked solution.

Question 13 marks
Conditions for induction
Edexcel Paper 2H (Higher)

State three changes a student could make to increase the size of the emf induced in a coil rotating in a magnetic field. (3 marks)
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Question 24 marks
Push a magnet into a coil
Edexcel Paper 2H (Higher)

A bar magnet is pushed N-pole-first into a coil of wire connected to a galvanometer.

(a) State what is observed on the galvanometer while the magnet is moving. (1 mark)
(b) Explain why a force is felt opposing the motion of the magnet. (3 marks)
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Question 34 marks
AC generator output
Edexcel Paper 2H (Higher)

A simple ac generator consists of a rectangular coil rotating in a magnetic field, connected to an oscilloscope by slip rings.

(a) Explain why the output is alternating. (2 marks)
(b) State two changes that would increase the peak emf. (2 marks)
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Flashcards

CP11.1 — Induced potential difference (HT): generator effect; ac generators and dynamos; Lenz's law qualitatively

7-card SR deck for Edexcel GCSE Combined Science — Leaves (batch 3) topic CP11.1

7 cards · spaced repetition (SM-2)

CP11.1Induced potential difference (HT): generator effect; ac generators and dynamos; Lenz’s law qualitatively