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  • Only a few elements can be permanent magnets - iron is one. Copper is not. But if you pass

  • an electric current through any metal it becomes a magnet - an electromagnet. But how does

  • this work? Well strangely enough, it's a consequence of special relativity.

  • Special relativity is the fact that in our universe, length and time aren't absolute;

  • they're perceived differently by observers moving relative to each other (hence, "relativity").

  • For example, if you measure carefully enough, you'll find that time passes slower for observers

  • moving relative to you.

  • Hey Derek, when did you last shave? Derek1: Six hours ago.

  • MovingDerek: Actually it was five hours, 59 minutes and 59.99999999999 seconds

  • And moving objects are also contracted in their direction of motion.

  • You're looking slim. Only in your frame of reference.

  • So when an object is moving relative to you, it actually takes up less space than when

  • it's not moving. And even though this effect is obviously way tinier than we've shown,

  • length contraction IS what makes an electromagnet work.

  • Picture a copper wire - it consists of positive metal ions swimming in a sea of free negative

  • electrons. Now the number of protons is equal to the number of negative electrons so overall

  • the wire is neutral. So if there were a positive charged, err... positively charged cat nearby,

  • it would experience no force from the wire on it at all.

  • And even if there were a current in the wire, the electrons would just be drifting in one

  • direction, but the density of positive and negative charges would still be the same,

  • and so the wire would be neutral, so no force on the kitty.

  • But what if the cat starts moving? Imagine for simplicity that that the cat is moving

  • in the same direction as the electrons with the same velocity. Well now in my frame of

  • reference, the wire is still neutral and so there should be no force on the cat, but consider

  • the same situation in her frame of reference.

  • In the cat's frame of reference the positive charges in the wire are moving, so according

  • to special relativity their separation will be ever-so-slightly contracted. Also, from

  • this perspective the electrons aren't moving so they'll be more spread out than before

  • - remember, objects take up more space when they're not moving than when they are. These

  • two changes together mean there's a higher density of positive charges in the wire, so

  • it's no longer neutral - it's positively charged! Which means that the positively charged cat

  • will feel a repulsive electric force from the wire.

  • But in my frame of reference this seems mysterious: there's no force on a stationary charged cat,

  • but a moving cat is somehow repelled from this neutral wire.

  • How do you account for this force? Well we say it is the magnetic force, and that's mainly

  • because a wire with current in it deflects nearby magnets. So really, what this experiment

  • shows is that a magnetic field is just an electric field viewed from a different frame

  • of reference.

  • In the cat's frame of reference, it is repelled from the wire due to the electric field created

  • by the excess positive charges produced by the effects of length contraction. In MY frame

  • of reference, the cat is repelled from a neutral wire due to the magnetic field generated by

  • current flowing in the wire.

  • So whether you see it as an electric or a magnetic field just depends on your frame

  • of reference, but in either case the results are the same. So an electromagnet is an everyday

  • example of special relativity in action.

  • Now that might seem crazy since electrons drift through wires at about .0000000001%

  • the speed of light - so how can special relativity have anything to do with it? Well the truth

  • is there are enough electrons in a wire, and the electric interaction is so amazingly strong

  • that even the minuscule effects of length contraction can produce significant charge

  • imbalances that produce a noticeable force.

  • So special relativity explains electromagnets - but what about permanent magnets?

  • Yeah! I mean there can't be electrical currents flowing around inside lumps of rock, can there?

  • Click here to go to MinutePhysics where we'll explore magnetite, compasses and all the wizardry

  • of permanent magnets.

Only a few elements can be permanent magnets - iron is one. Copper is not. But if you pass

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B2 中高級

狹義相對論是如何讓磁鐵工作的? (How Special Relativity Makes Magnets Work)

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    hzd_zw2004 發佈於 2021 年 01 月 14 日
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