Explain one of the demonstrations (jumping disk, jumping wire, or falling magnet). Be sure to show...
Explain one of the demonstrations (jumping disk, jumping wire, or falling magnet). Be sure to show how you can predict the behavior.
Homework Answers
JUMPING RING
The Demonstration:
An aluminum ring is launched off of an electromagnet. With the iron bar in the electromagnet, it goes even higher.
Quick Physics:
An electromagnet is just a coil of wires with a current running
through it. Electrons are like tiny magnets and when they move (as
in a current), they create a magnetic field. The iron core
increases the magnetic field of the electromagnet. The ring feels a
greater magnetic force, which pushes it higher. The colder the ring
it, the less resistance there is and the more current can flow
through it. More current means a bigger magnetic field and the ring
goes even higher!
The Details:
The jumping ring makes a metal ring jump up into the air using an
electromagnet like the one described earlier. It is actually two
electromagnets in one. Wire is wrapped around a base made of iron.
The wire is connected to the electricity and when current flows in
the wire, the iron becomes a very strong magnet. The second magnet
is a metal ring. It sits on top of the iron base. The magnetic
field from the iron in the base causes electricity to flow around
through the ring. The electricity in the ring is called an eddy
current. The eddy current causes the metal ring to become a magnet.
The two electromagnets are arranged so that their north poles point
at each other. Two north poles repel each other, so the base and
the ring push each other away. Since the ring is very light, it
gets pushed up into the air.
When you add an additional iron bar into the electromagnet, it increases its strength. (This is why we used a nail in the previous electromagnet experiment.) A stronger magnet makes the ring jump much higher! If you add a second ring, you might expect it not to go as high because there is twice as much mass. But, there is also twice as much ring to turn into a magnet that will be repelled and it launches just as high.
We can make the ring jump much higher by using liquid nitrogen to make it very cold. When things are very cold, electricity can flow more easily. Since the electricity can flow through the ring better, the ring becomes a stronger magnet and jumps a lot higher.
If the ring gets cut, it won’t jump. We said some of the electricity in the wire gets into the ring to make it into a magnet. But, electricity has to flow in a complete circle to make a magnet. Since there is a cut, the electricity can’t get all the way around. The cut keeps the ring from turning into a magnet.
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