Electromagnetic Induction

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Hi. It’s Mr. Andersen and this AP Physics essentials video 71. It is on electromagnetic

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induction which is the ability of a magnetic field to create current inside a conductor.

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Now scientists like Hans Christian Orsted have already shown that if you have current

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in a wire like this it creates a magnetic field. And that magnetic field could affect

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this compass needle which is really a small little magnet. And so current can produce

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magnetic fields. But what scientists like Michael Faraday wondered is could you take

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a magnetic field and produce current from it? In other words was the opposite true?

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And this is the apparatus that he used to study that. And so we have basically have

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two parts. We have a ring of iron but on the left side we have an electromagnet. So you

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are going to connect this to a batter and that is going to produce magnetic fields over

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on the left side. And so the hope is on the right side, that could produce current inside

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this wire. And then we would be able to measure that using a galvanometer. And so he set it

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up like this and then he closed the switch. And so what what happens to the current in

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the wire on the right side as I close that switch. And you can see that we generate a

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little bit of current. But then it goes away. And this is puzzling. So he opened up the

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switch and watched what happened. We have a little bit more current but it is in the

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opposite direction. So let me kind of close that switch and we have a little bit of current.

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But it goes away. And then we open the switch and we have a little bit of current but its

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going in the other direction. And so that is electromagnetic induction. But what he

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wondered is why is it only occurring right when I close the switch? So to understand

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that you really have to understand the specifics of electromagnetic induction. And to understand

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that you have to understand what magnetic flux is. Magnetic flux is how a conducting

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material or any material for that matter is affected by a magnetic field. And so what

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would be something similar? It would be how you or any material on our planet is affected

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by light from the sun. And so it is going to be the amount of light from the sun. But

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it is also going to be the angle at which that light hits. And so magnetic flux is going

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to be the product of the strength of the magnetic field, how much or how large that magnetic

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field is and then we are going to multiply that times the surface area perpendicular

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to that magnetic field. And so imagine that this right down here is a wire loop. And so

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we have a little bit of a wire. And then we have a magnetic field. And so if we ever have

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change in that magnetic flux, then we are going to have electromagnetic induction occurring.

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And so what happened right when he closed that circuit? Well the magnetic field before

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he closed the circuit was zero. But then he added this magnetic field, so was there change

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in magnetic flux? Yes. And so was there electromagnetic induction? Yes. So it created current. What

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would happen if we were to increase the magnetic fields? So let’s double the magnetic field.

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Well for a moment as we are doubling the electromagnetic field, are we getting a change in the magnetic

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flux? Yes. Are we getting induction? Yes. And therefore we are going to have current

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in that wire. And so by varying the amount of that magnetic field we can get induction,

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or we can get current in that wire. Now what is another way we could go at that? Again

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we could look at the surface area that we are impacting. And so if you think of this

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as a wire, all of these magnetic field lines are perpendicular to this wire. And so we

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are going to have a large magnetic flux. But watch what happens when I turn it at an angle.

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And a good way to do this is simply count the lines of the magnetic field that it is

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hitting. You can see there is a reduction. And so the number of lines is different but

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also these are not hitting it straight on. It is not perpendicular so we would have to

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use a little bit of trigonometry to figure out what component of that magnetic field

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is actually perpendicular to the surface area. But did it change between those two rotations?

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Yes. And so was there electromagnetic induction? Yes. And so there would be current as well.

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And so let’s say we turn it like this. The magnetic flux is going to be zero because

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none of these magnetic field lines are going to be perpendicular to the surface. But it

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changed between those two points. And so we are going to have induction and we are going

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to have current. So that seems a little non intuitive, but it has real world applications.

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And so the electricity that you are using right now and the microphone that I am using

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right now as well, use this idea of electromagnetic induction. And a great way to look at that

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would just be looking through a generator. And so how does a generator work? Well in

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a magnetic field what we can do is we can take these wires and we can start to rotate

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them. And as we rotate them we are getting huge changes in magnetic flux and so we are

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going to have huge changes in the current itself. And so if we look at the equation,

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magnetic flux or phi sub B is going to be a product of the magnetic field, how big that

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magnetic field is, times the cross-sectional area perpendicular to that magnetic field.

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And so if I take this wire, right here and I compare it to this wire right here, which

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one is going to have a larger magnetic flux? It is going to be the one on the left. And

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the reason why is we are going to have more of those magnetic field lines go through it.

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What is a good way that we could increase magnetic flux is we could just wrap that wire

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a bunch. And so each of those wires, we are going to have the magnetic flux of that individual

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wire. And so by changing the magnetic field or by changing the size of that area we can

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change magnetic flux. But also remember we could angle it. And so if I angle it like

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this, we are going to have fewer of those magnetic field lines go through it and so

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we are going to get a change in the magnetic flux. And here we would actually have no magnetic

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flux. But it is not a measure of magnetic flux that is important in producing current.

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It is are we getting changes over time. And so this is a PHET simulation that gets at

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that. And so we have magnet over on the left side. And then on the right side we simply

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have a wire hooked up to a galvanometer or it is a voltmeter. It is going to measure

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the amount of voltage. And you can see that there is no current right now. But as I start

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to change that position of the magnet, I am starting to get current. And you can see,

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you can even see the electrons moving in the wire. And so if I increase the number of wires

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I can increase how much I am deflecting that needle. How much current I am actually moving

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inside the wire itself. Why is that? Now the magnetic field lines, you can see the magnetic

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field lines are changing. And as they change we are getting change in magnetic flux. And

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so we are getting current inside the wire. Now another way to look at this would be through

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a generator. And so in this set up what I have is a magnet down here on a wheel so that

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I can spin that magnet. I have my wire again. And I am trying to induce current inside that

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wire. And then I am going to measure the amount that I am going to change. And so watch what

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happens now when I start to turn on the water inside that faucet. It is changing the position

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of the magnet. As is it changes the position of the magnet it changes the magnetic field.

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You can see the magnetic field lines are changing. And so I am starting to get a little bit of

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current. What happens if I increase the speed of that water? I am getting more current.

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You could even have a light bulb connected to it. And so now I am starting to get usable

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energy. Watch what happens as I increase the number of wires. I even have more energy coming

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out. Now if I increase the water again I even have more energy being produced. And so we

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are taking that energy of the flow of the water and actually making electromagnetic

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energy out of it. And so this is how the generators in a dam would work. We have the water flowing

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down through the dam. It is spinning these magnets and it is creating that electricity.

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And so did you learn to construct an explanation for how a simple electromagnetic device, like

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a generator, works? I hope so. And I hope that was helpful.