Magnetism and Electromagnetic Induction

M. Rocha

Physics 10

Magnetism

Magnets are Fun!

How do magnets work?

Origin of Magnetic Force

When electric charges move they create a magnetic field

The magnetic field is due to "distortions" in the electric field caused by motion

The right hand rule tells you the direction of the magnetic field due to a positive moving charge

Magnetism as a Consequence of Special Relativity

When electric charges move they create a magnetic field

The magnetic field is due to "distortions" in the electric field caused by motion

The right hand rule tells you the direction of the magnetic field due to a positive moving charge

Spinning charges are moving charges, thus create magnetic fields

Origin of Magnetic Force

Checkpoint 1

A proton travels in a circular path counterclockwise as shown below. What is the direction of the magnetic field lines at the center?

+

Away from the screen (towards you)

Magnetic Poles

North Pole: Side where field lines point away from the source

South Pole: Side where field lines point into the source

Magnetic Forces

As with electric charges, like poles (N&N, S&S) repel and opposites (N&S) attract.

Unlike electric charges, cannot have just a North or just a South pole

How do Magnets Work?

An iron atom has four electrons whose spin magnetism is not canceled.  Each iron atom is a tiny magnet. The same is true to a lesser degree for the atoms of nickel and cobalt.

How do Magnets Work?

An iron atom has four electrons whose spin magnetism is not canceled.  Each iron atom is a tiny magnet. The same is true to a lesser degree for the atoms of nickel and cobalt.

How do Magnets Work?

Each iron atom is a tiny magnet. Interactions among adjacent iron atoms cause large clusters of them to line up with one another.

clusters of aligned atoms are called magnetic domains

How do Magnets Work?

Magnetic domains can be induced to align by an external magnetic field

Electric Currents and Magnetic Fields

An electric current produces a magnetic field

Electromagnets

Electric current in a coil of wire creates a magnetic field similar to a bar magnet

Current In

Current Out

Origin of Earth's Magnetic Field

Earth is a giant electromagnet

Earth's Magnetic Field Reversal

Northern Lights (Auroras)

Magnetic Force on Moving Charges

Moving electric charges deflect by magnetic fields

Magnetic Force on Moving Charges

Moving charges in an electric current experience a force due to magnetic field

Checkpoint 2

An electron travels to the right within a magnetic field pointing towards the screen, in which direction would it be deflected?

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x

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x

x

x

x

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Magnetic Field

It gets deflected down

Electric Motors

Speakers

Oscillations are created by variations in electrical current, which cause an electromagnet to be pulled towards and away from a second, permanent magnet

These oscillations cause the membrane of the speaker to vibrate with the same frequency as the oscillations in the electrical current.

Electromagnetic Induction

Electromagnetic Induction

Just like moving charges (currents) produce magnetic fields, moving magnetic fields produce voltages and currents

Electromagnetic Induction

Voltage is induced whether a magnetic field moves past a conductor, or the conductor moves through a magnetic field.

The results are the same for the same relative motion

Electromagnetic Induction

Twice as many loops results in twice as much voltage  induced. For a coil with three times as many loops, three times as much voltage is induced

The induced current is proportional to the number of loops

2 v

4 v

6 v

Faraday's Law

The induced voltage in a coil is proportional to the product of the number of loops, the cross-sectional area of each loop, and the rate at which the magnetic field changes within those loops

\mathrm{Induced \ } V \propto \mathrm{Number \ of \ loops} \times \mathrm{Area \ of \ loops} \times \frac{\Delta B}{\Delta t}

How fast magnetic field changes

Checkpoint 1

When a coil with 200 loops is subject to a changing magnetic field it produces 0.5 v. Another coil with 400 loops but half the area is then subject the same changing magnetic field, what is the induced voltage?

\mathrm{Induced \ } V \propto \mathrm{Number \ of \ loops} \times \mathrm{Area \ of \ loops} \times \frac{\Delta B}{\Delta t}

Same, 0.5 v

Electromagnetic Induction

We don’t get something (energy) for nothing by simply increasing the number of loops

More difficult to push the magnet into a coil with more loops because the magnetic field of each current loop resists the motion of the magnet

The work done is proportional to the number of loops

When a current is induced by a changing magnetic field, that current itself produces its own magnetic field. This effect is called self-induction

Self Induction

The self-induced magnetic field is always opposed to the primary magnetic field that induced it

Eddy Currents

Changing magnetic field induces eddy currents within any conductor.

These internal currents produce self-induced magnetic fields

Metal detectors induce eddy currents on metals and detect the self-induced magnetic fields

Electric Guitars

Electric Generators

Electric generators move a conductor in a magnetic field to produce voltage via electromagnetic induction

Electric Generators

Electric Motors

An electric motor is the same as a generator but instead converting mechanical energy to electrical energy, it converts electrical energy into mechanical energy

Transformers

A transformer consist on a primary coil connected into alternating power source, and a secondary coil that produces a voltage by induction

If we place an iron core inside both coils, alignment of its magnetic domains intensifies the magnetic field

Transformers

A transformer consist on a primary coil connected into alternating power source, and a secondary coil that produces a voltage by induction

If the iron core forms a complete loop, guiding all magnetic field lines through the secondary, the transformer is more efficient

Transformers

A transformer consist on a primary coil connected into alternating power source, and a secondary coil that produces a voltage by induction

Voltages may be stepped up or stepped down with a transformer

Transformers

Voltages may be stepped up or stepped down with a transformer, but the power is always constant!

P = V I = \mathrm{(\frac{Energy}{Charge}) (\frac{Charge}{Time})} = \mathrm{\frac{Energy}{Time}}
P_\mathrm{primary} = P_\mathrm{secondary}
V I_\mathrm{primary} = V I_\mathrm{secondary}
\frac{V_\mathrm{primary}}{V_\mathrm{secondary}} = \frac{I_\mathrm{secondary}}{I_\mathrm{primary}} = \frac{N_\mathrm{primary}}{N_\mathrm{secondary}}

N = Number of loops on coil

Checkpoint 2

If the primary coil of a transformer has 10 loops and is connected to a outlet providing 120 v, what would be the output voltage (secondary voltage) if the secondary coil has only 1 loop?

12 v

Checkpoint 3

 1 A

What would be the output (secondary) current if the input (primary) current is 0.1 A?

\frac{V_\mathrm{primary}}{V_\mathrm{secondary}} = \frac{I_\mathrm{secondary}}{I_\mathrm{primary}} = \frac{N_\mathrm{primary}}{N_\mathrm{secondary}}

Power transmission uses transformers to increase voltage for long-distance transmission and decrease it before it reaches your home

Power Transmission

High voltage allows for less current for the same power (P = IV). Less current = less heat (less power loss)

The End

Since force on a wire due to a magnetic field depends on the current, we can use this effect to design a meter to measure current (an ammeter)

Electric Meters

Electric Generators

As the loop rotates, the magnitude and direction of the induced voltage (and current) change

The direction of the current and magnitude of the voltage reverses each half rotation, the result is an alternating current

Current