The movie Avatar got me interested in the subject, but so far I only found sophisticated articles loaded with unfamiliar words. Is there a simple way to explain how magnetic field affects superconducting materials in a way that causes them to float?
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asked Jan 5, 2013 at 13:07
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$\begingroup$ Your profile is empty. If you ask us to explain this phenomenon in familiar wording, then you should at least tell us what your background is. $\endgroup$– jippieCommented Jan 5, 2013 at 13:18
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$\begingroup$ I'm a hobbyist programmer, almost no bg in physics, so as simple as possible, please :) $\endgroup$– user1306322Commented Jan 5, 2013 at 13:21
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2 Answers
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Superconductors float not just because of the Meinssner Effect. They Float because of quantum locking. Very small weak points in a thin superconductor allow magnetic fields to penetrate, locking them in. These are called Flux Tubes.
The Meissner Effect is only if you make a conductor into a superconductor while the magnet (or magnetic field) is near it. Placing a magnet near an existing superconductor is an example of electomagnetic induction producing magnetic levitation.
Most examples of the Meissner Effect and Electromagnetic Induction are done with a floating magnet. Attempting to float a thick superconductor without quantum locking would quickly cause it to fly off due to unstable magnetic fields. Any example of a floating superconductor is done with a thin superconductor exhibiting quantum locking.
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$\begingroup$ How can a semiconductor can move back and forth on a magnetic track if it is "pinned" to the magnet? $\endgroup$ Commented Dec 22, 2020 at 1:36
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$\begingroup$ @sagar because the magnetic forces are weak. It's just enough to hold it in place until an outside force is applied. The quantum pining will provide some friction like affect and will slowly cause it to slow down though. $\endgroup$– cdeCommented Dec 22, 2020 at 7:08
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A magnetic field cannot penetrate a superconductor; since there's no resistance to the flow of electrons, a current is immediately created in the superconductor by the field, and the field produced by that current opposes the original field. This is ordinary magnetic induction, but with zero losses because of the superconductivity.
Essentially, whenever a magnet is brought near a superconductor, the superconductor immediately becomes an opposing magnet, producing the force that keeps the two objects apart. The magnitude of this force depends on the strength of the original magnet.
There is also a releated phenomenon known as the Meissner Effect, which describes how a magnetic field is actively excluded from a substance as it makes the transition to the superconducting state.
Another related phenomenon is flux pinning, which occurs in thin layers of type-II superconductors. When this occurs, magnetic field "lines" are trapped by the superconductor, passing through non-superconducting tubes that are isolated from the superconducting regions by vortices of current. This creates the effect that the superconductor "prefers" to be in the same magnitude of field that existed when it was created, actively resisting movement to a region of higher or lower field strength.
Flux pinning can also be created on a macro scale by forming a superconductor (any type) into a ring (torus) shape.
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$\begingroup$ Are there any dependencies on the amount of power needed to bring afloat a superconductor of known mass? $\endgroup$ Commented Jan 5, 2013 at 13:24
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1$\begingroup$ Your source says you are wrong: It should thus be noted that the placement and subsequent levitation of a magnet above an already superconducting material does not demonstrate the Meissner effect, while an initially stationary magnet later being repelled by a superconductor as it is cooled through its critical temperature does. $\endgroup$– passerbyCommented Jan 5, 2013 at 14:25
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$\begingroup$ I should also add that calling this subtance (the room-temperature superconductor) "Unobtanium" in Avatar really cracked me up. That term is an engineering in-joke from long ago, meaning any item that you need but can't get. I've often wondered whether James Cameron intended for that name to be replaced with something else before the script was finalized for shooting. $\endgroup$– Dave TweedCommented Jan 5, 2013 at 14:45