# Is it possible to separate the poles of a magnet?

It might seem common sense that when we split a magnet we get 2 magnets with their own N-S poles. But somehow, I find it hard to accept this fact.(Which I now know is stated by Gauss's Law)

I have had this doubt ever since reading about the quantum-field-theory and I know I might sound crazy but is it really impossible to separate the poles of a magnet?

What about black holes? They attract matter and everything else only inwards into them, right? So then, are they the only such case/exception?

Am I being naive? Is there some proof/explanation that can give closure to this question of an independently existing pole?

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## 8 Answers

Well, in order for this splitting to be possible, the magnet would have to be made of two magnetic monopoles (like charged particles, but with "magnetic charge" instead of electric charge) bound together. No known magnet is actually constructed this way; all real magnets that have been studied are made of either little current loops, or particles that have a spin magnetic moment (and these basically act like little current loops).

It's still an open question whether or not magnetic monopoles exist. Some theories predict that they should, but most have nothing to say about it either way. I am not aware of any theories that prohibit the existence of these monopoles. Quantum field theory in general falls in the second category; that is, there is nothing inherent in QFT that requires magnetic monopoles to exist or not exist.

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Of course the totalitarian "rule" would suggest either the existence of monopoles or some---as yet unknown---rule that prohibits them. Stay tuned. –  dmckee Nov 28 '10 at 23:45
As I understand it, there are theories that hold that magnetic monopoles do exist, but in ridiculously small numbers-- a handful of them in the entire visible universe. Which would let you get the benefit of charge quantization without needing really large numbers of them running around. –  Chad Orzel Nov 29 '10 at 0:38
Also, there's a semi-famous experiment to look for magnetic monopoles that saw one signal of exactly the type they would've expected for a monopole within the first few hours of operation. And then never saw anything like it again. It was almost certainly a glitch, but it's kind of amusing to imagine that they really did see the one monopole in the Local Group right when they first turned their detector on... –  Chad Orzel Nov 29 '10 at 0:40
Monopoles are prohibited by Maxwell's equations, specifically $\nabla \cdot B = 0$. If you want monopoles you need to modify this particular equation. –  Joe Fitzsimons Jan 22 '11 at 6:42
@Joe: of course, but Maxwell's equations were designed the way they are to reflect the fact that magnetic monopoles are not observed in nature. I don't consider that a fundamental reason why they couldn't exist. –  David Z Jan 22 '11 at 23:55

This is basically how a magnet's atoms look like:

so, when you split it into two, you do not change anything but the length of the magnet. As you can see the North poles(Black sides or "K" as it's in a different language) face north and south poles face south in each part of the magnet.

IF there are such things as monopoles, then it is possible to define a magnetic charge which would allow us to separate a unit magnet into two monopoles. However there are no confirmations for magnetic monopoles so we'll have to accept magnets as a whole for now.

As for black holes, their attraction is gravitational, and not very different from the gravity earth applies on you.

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What you are talking about is the creation of magnetic monopoles (effectively magnetic charges). In classical electrodynamics, such objects are inconsistent with one of Maxwell's equations. Specifically the $\nabla \cdot B = 0$ equation specifically prohibits the existence of magnetic monopoles. In order for them to exist, you need to modify this equation so that it is proportional to the magnetic monopole density. While there are some unverified theories which could give rise to magnetic monopoles, all of our observations so far are consistent with the non-existence of monopoles.

Further, the way magnets that you may have encountered work is via the magnetic field induced by moving charge, not by the presence of monopoles. Usually this field is caused by the angular momentum of charged electrons.

Hope this clarifies matters.

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Seriously? A down vote with no comment? What exactly is incorrect with this answer? –  Joe Fitzsimons Jan 23 '11 at 15:40

Magnetic monopoles certainly exist. This does not require a GUT, they exist in any theory where the electromagnetic U(1) is compact (i.e. where charge is quantized). This follows only from the semiclassical behavior of black hole decay, and so does not require unknown physics.

The reason is essentially the one you state--- you can polarize a black hole in a strong magnetic field, and let it split by Hawking radiation into two oppositely magnetically charged black holes of opposite polarities. Magnetically charged black holes exist in classical General Relativity, as are arbitrary electric-magnetic charge ratio holes, and you can't forbid them, at least not for macroscopically sized black holes, without ruining the theory.

When you let the monopolar black holes decay, you find relatively light monopoles. The lightest monopoles will be lighter than its magnetic charge, so that two such monopoles will repel magnetically, not attract. Presumably, the monopole you find will be a (small multiple of) Dirac's magnetic monopole quantum.

To me, this is as certain as the existence of the Higgs. We haven't observed either one, but the theoretical argument is completely convincing.

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A few non-physics comments have been edited/deleted because of flags. Please keep it civil. –  Qmechanic Jan 4 '13 at 20:04
For the downvoters: the question asked specifically about whether black holes can split poles. Within GR, you can make a magnetically charged black hole solution, and there is no real problem because the nonzero divergence of B is hidden behind the horizon. In semiclassical gravity, you can therefore make magnetic black holes by making opposite magnetic charged BH pairs, and the result needs to decay to the lightest magnetic monopoles by Hawking radiation. This is such a clear requirement that it is incorrect in my opinion to dither on this--- modern physics predicts monopoles unambiguously. –  Ron Maimon Jan 9 '13 at 21:28
Hi Ron, could you repost the physics you explained so nicely as an meta answer in your answer here? I wanted to reread it again and now I cant. –  Dilaton Jan 14 '13 at 0:07
Nice answer,+1. In the same way as it is legitimate for more experimentally inclined people to dismiss the existance of magnetic monopoles, theoretical physicists are allowed to explaine why they are rather convinced of their existance from theoretical reasons. This is exactly what Ron nicely does in his answer, so there is nothing wrong writh it from a physics point of view. –  Dilaton Jan 17 '13 at 10:43
To further explain my above comment, it is not necessary to have directly discovered a magnetic monopole (meaning a heavy elementary particle) as Sklivvz thinks, to be convinced that they have to exist (even though they may be to heavy to be accessible by the current technilic possibilities) from theoretical reasons, as Ron explains in his answer. –  Dilaton Jan 17 '13 at 22:09

I suspect your problem is you may want to think about it rhetorically. Magnetic poles are really just a mental shortcut useful to provide a bit of intuition to something that is inherently just math. We don't have physical entities called mag poles, we have a magnetic field, and it works as if it were generated by currents (and maybe spin, which may or may not work like moving charge (a current)). So cut your magnet, and you have two similar, but shorter pieces, and a local concentration of field lines is usually called a "pole", and polarity refers to the signed value of the magnetic field normal to the surface.

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Cutting a magnet in two pieces is like cutting a vector: you can change its length but you cannot change its direction (you cannot make it directionless).

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Magnetic monopoles appear in some Grand Unified Theories and SUSY models of particle physics, but are not possible in the standard model, so we don't know if they really can exist.

However, even in stabdard electrodynamics you can create the illusion of magnetic monopoles by channelling the magnetic flux between two poles along a thin flux tube or "needle".

Recently some condensed matter physicists were able to use this possibility within a spin ice system to make it seem like magnetic monopoles were moving in the material. This effect was described on some blogs at the time so I'm just going to link to the detailed one at Backreaction rather than try to repeat it myself.

Nevertheless, a truly isolated magnetic monopole that could be thrown into a black hole leaving its twin behind is only possible if some GUT theories are correct. People have tried to observe them by watching the current in a coil for the effect of a monopole that passes through it, but without (confirmed) success.

In theory, if they exist they should have been created in abundance in the very early universe at the time of the GUT scale energies. The theory of cosmological inflation was originally proposed to explain why we don't see them. They would be there but in such small numbers that we can't find one. Our only hope would be accelerate and collide particles at the GUT scale of $10^{12}$ TeV but that is currently beyond our wildest dreams.

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No, because found magnet is not composed of poles. Lacking magnetic charges, the creator had to cheat use currents of electric charges. These currents make two poles at once, and these are all magnets found in nature (and stores) today.

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This is not really precise. Actually, creator cheated in a little different way and he used intrinsic magnetic moment of elementary particles to produce magnetism. Some of the magnetism comes from orbital motion (and this can be interpreted as currents) but that is only relevant to diamagnetism and paramagnetism, not ferromagnetism. –  Marek Nov 30 '10 at 21:10
@marek Not only orbital motion means current; spin is, well, to some extent, a current, unless you have a point size. A spinning charged body has magnetic moment because that is electric current. Neutrons have magnetic moment and no electric charge, because it is a compound object which may have inner currents (even though it's strange to associate spin of elementary charged particles with current but this still the correct classical way to look at it) –  Pavel Radzivilovsky Dec 1 '10 at 6:56
that is precisely what I am saying. You are talking just classical perspective and I was correcting you to say that this is not quite correct. Arguably, most of the magnetism comes from the intrinsic magnetic moment of electrons (and this can be classically connected to their spin via gyromagnetic ratio, but that is not important). You can't ever explain that by currents. It is much better explained by solid state physics models and statistical models (like Ising model, Heisenberg model, etc.). Currents have nothing to do with origin of ferromagnetism. –  Marek Dec 1 '10 at 8:46

## protected by Qmechanic♦Jan 4 '13 at 12:47

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