I keep on hearing that magnetism is just another form of electricity and vice versa. If that's the case why can't we use magnets as batteries, and why aren't my batteries magnetic?
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$\begingroup$ Related: physics.stackexchange.com/q/5573/2451 $\endgroup$– Qmechanic ♦Commented Jan 6, 2012 at 10:14
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6 Answers
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One way to interpret the statement "electricity is another form of magnetism" (or vice versa) is through special relativity. If I look at a classical stationary electric charge, it sets up a purely electric field - the Coulomb field, which is responsible for generating the phenomena of static electricity. However, if I now look at this same electric charge, but from the standpoint of a reference frame which is moving with respect to it, what I now see from my new point of view is a moving electric charge, in other words an electric current. An electric current sets up a magnetic field (Ampere's law).
Thus we find the same physical source generating a field which looks like either a magnetic field or an electric field depending upon how you look at it. This transformation between electric and magnetic fields is perfectly described by the Lorentz transformations of special relativity.
Returning to the specifics of your question, permanent magnets generate their magnetic field through two main mechanisms - firstly there is the orbital motion of electrons around the nucleus. Since the electrons are charged, this is equivalent to an electric current and sets up a magnetic field. Secondly, there is the spin of the electrons themselves - this again creates a magnetic field (although it is tempting to think of the electron as a little spinning charged object of finite size, this would be incorrect, the proper description being a quantum mechanical one). The net effect is that the atoms behave as tiny magnets.
In ferromagnetic materials the motion has the right "collective" properties such that the atoms, which behave like a tiny magnets, are able to align their magnet's directions (in local units called magnetic domains) to provide a large magnetic field. However (1) the orbital motion of the electric charge in the atoms is cyclical, and (2) the spin of the electron doesn't move the charge from one place to another whereas what you'd need for a battery is a movement of charge which results in separation of positive and negative charge, to make available at the terminals. Thus permanent magnets can't function as batteries.
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There is a catch though: You can never get a pure magnetic field by reference frame change from a pure electric field, and vice versa, for
$$F_{\mu\nu} F^{\mu\nu} = \ 2 \left( B^2 - \frac{E^2}{c^2} \right) = \mathrm{invariant}.$$
In other words, starting with a pure electric field, you can only obtain a mixed electric and magnetic field, but never a pure magnetic field.
In this sense, magnetism is not just another form of electricity, though they are closely related.
answered Feb 21, 2012 at 1:12
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$\begingroup$ Could you explain what the symbols mean and what the equation tells? $\endgroup$– tvoCommented Apr 29, 2016 at 13:57
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$\begingroup$ @tvo: F is the electromagnetic field tensor, B is the magnetic induction field, E is the electric field. The equation simply means that the scalar is invariant under Lorentz and general transformation. $\endgroup$ Commented Apr 30, 2016 at 2:29
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$\begingroup$ What do you mean by "the scalar"? And what are Fuv and Fvu? $\endgroup$– tvoCommented Apr 30, 2016 at 23:53
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$\begingroup$ [EnsteinFeldEquns& EM theory][1] [1]: file.scirp.org/Html/9-7501400_36094.htm $\endgroup$ Commented Jun 26, 2017 at 11:14
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I'm guessing you mean to say: you hear that ELECTRICITY is just another form of magnetism.
Magnets ARE used as generators of electricity - the generator in your car or a hydro-electric dam, etc.
But they are different forms of electro-magnetic energy and are related by the (Faraday-Maxwell) formula: ∇×E=−∂B/∂t. Which basically says: the curled electric field is related to the time varying magnetic field.
Sp when your car revs up, it creates a magnetic field in your generator/alternator, from which an electric field is generated that charges your battery.
Batteries store a static potential electric field. Static, so there is no time variance to create a magnetic field. It's in a different form. Batteries are basically the electrical form. Whereas the motion of magnets (-∂B/∂t) can be used to transform the motion energy into the electric form.
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In addition to the other answers, you can get an idea of the relationship of the electric and magnetic fields by thinking of an electric motor and a generator as the same thing. When passing current through the coils of the motor, the magnets will spin. On the other hand, if you instead spin the magnets it will create a current in the coils.
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Electricity and magnetism are two forms of the same fundamental "thing", or are two ways of perceiving the same fundamental "thing". Electricity flowing through a wire creates a magnetic field. A moving magnetic field -- like in a generator -- creates electricity.
The fact that you can't use a magnet as a battery or vice versa is among the reasons why it took people so long to figure out the connection. But a little thought will show this is not proof that the theory is false. Paper is made from trees. A sheet of paper is fundamentally the same "thing" as a tree. But you can't build a house by taping sheets of paper together, and you can't write a letter on a tree. Steam and ice are the same fundamental "thing", but appear and act very different. Etc.
Sometimes the greatest advances in science come from the discovery that two things that "look" different are really the same thing, or different forms or views of the same thing.
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I have an excellent example, that would help your intuition in understanding why electricity and magnetism are two sides of the same coin.
Suppose there are 2 observers $A$ and $B$, and observer $B$ is on the ground and observer $A$ is an elevator moving with some uniform velocity $v$. There is an infinitely long wire with current in it. Now, say, there is a charge which moves continuously upwards with a velocity the same as $v$ parallel to the elevator.
With respect to observer $B$, the charge is moving and experiences a lorentz force, and is attracted to the wire, due to the magnetic field created by the wire. But, with respect to observer $A$, the charge is at rest and and the magnetic field (if any) cannot exert any force on the charge.
Something is definitely fishy here!
We zero down to two alternatives -
1) Either, Maxwell's equations are frame dependent,i.e, they are different for different frames of reference.
2) Or, Maxwell's equations are frame independent,i.e, they are the same everywhere.
Experiments suggest that the first case isn't true, and therefore Maxwell's equations take the same form irrespective of the frame chosen. In fact, this very result led to the the conclusion that the speed of light is the same in every frame!
The whole answer comes down to the fact that the phenomena of electricity and magnetism are really just two different aspects of the same phenomena - electromagnetism. When confined to a certain frame of reference, the two phenomena behave independently. This leads to a very important point - Electricity and Magnetism are unified.
Magnetic materials are ferromagnetic; i.e, they have electrons which contribute to the magnetism, through their spin, motion. They don't cause the material to have a flow of current, or, create a potential difference in them for charges to flow!
