electromagnetism

Created by

Josephine Beth

Cards (58)

Poles of a magnet 
Places where the magnetic forces are strongest
When two magnets are brought close together 
They exert a force on each other
Two like poles 
Repel each other
Two unlike poles 
Attract each other
Contact or non-contact force
Non-contact
Permanent magnet 
Produces its own magnetic field
Induced magnet 
A material that becomes a magnet when placed in a magnetic field. It always causes a force of attraction. When removed from the field it loses most/all of its magnetism quickly.
Unmagnetised iron 
Will be attracted to a magnet
Unmagnetised iron 
Will not be repelled by a magnet
Magnetic field 
The region around a magnet where a force acts on another magnet or on a magnetic material
Around a magnet, the field is strongest at the poles
Magnetic materials 
iron
steel
nickel
cobalt
Magnetic field line 
A line showing the direction of magnetic force. Many field lines can be drawn around a magnet. The direction of lines tells us the direction of the magnetic field and the spacing of the lines tells us the strength of the field.
Magnetic compass 
Contains a small bar magnet that is free to rotate
Magnetic field lines point from north to south
The Earth has a magnetic field
A compass needle points in the direction of the Earth's magnetic field
The geographic North pole has a magnetic south pole
Investigating the magnetic field around a bar magnet
Use a plotting compass. Place the magnet on a piece of paper. Place the compass next to the magnet. Draw a dot at the red end of the compass needle. Move the compass so that the white end of the needle is next to the dot. Place a new dot at the red end of the compass needle. Repeat to follow the field line dot-to-dot. Start from a different place to find a different field line.
The magnetic field around a bar magnet can be sketched
Factors that set the strength of the magnetic field around a current carrying conducting wire
The size of the current in the wire
The distance from the wire
Solenoid 
A wire wrapped into a spiral (like a spring)
The magnetic field around a solenoid can be sketched
Magnetic field inside a solenoid 
Strong and uniform (the same strength everywhere)
Adding an iron core increases the strength of the magnetic field of a solenoid
An electromagnet is a solenoid with an iron core
Demonstrating the magnetic effect of a current
Place a compass beneath a conducting wire. Align the wire so that compass needle is parallel to the wire. Pass a current through the wire. The compass needle will move to be perpendicular to the wire when the current flows.
Sketch the magnetic field around a wire
When a wire carrying a current is placed in a magnetic field 
It may feel a force
Motor effect 
The force felt by a current carrying wire in a magnetic field
Devices that rely on the motor effect
electric motors
loudspeakers
Fleming's Left Hand Rule 
A rule to work out the direction of the force on a wire in a magnetic field
Thumb in Fleming's Left Hand Rule
Thrust or force
First finger in Fleming's Left Hand Rule
Magnetic Field
Second finger in Fleming's Left Hand Rule 
Current
Three ways to make the force on a wire in a magnetic field larger
F = B I l
An equation to calculate the force on a wire in a magnetic field, where F is force, B is magnetic flux density, I is current, and l is length of wire
Magnetic flux density 
The strength of the magnetic field, measured in Tesla (T)
The equation F = B I l can be applied when the current is at right angles to the magnetic field
DC Electric Motor 
A device that converts electrical energy into mechanical energy using the motor effect