According to my concept,every magnetic field must have a magnet{ from where it is created } having north pole and south pole.i got the direction of the very field {of a current carrying wire } using maxwell‘s right hand rule but where are the poles ? or the field created by current differs from that of a magnet ??
The poles of a magnet come from the fact that what you are dealing with in permanent magnets you are dealing with magnetic dipoles. You can have electric dipoles, too, with a positive and a negative end of the dipole, and the electric field lines look exactly the same as magnetic dipole field lines. For a moment, forget about permanent magnets and just consider magnetic fields derived from electric currents. You have the magnetic field that curls around the wire, and that's easy enough to picture as long as you're not trying to think of where the poles are. Now take the wire, cut off a small section and take that section and make it a circle, with the same current flowing through it. If you look at the magnetic field lines there, they form sort of a donut around the circle, with the exact center having a stronger field line pointing in from one side and out the other. For reference, the field lines point out of the north side and into the south. Anyway, if you take that current carrying wire and reduce its radius and reduce the current proportionally, then you will see that same structure, but with the magnetic field in the center having the same strength as before. Shrink the radius again and again, reducing the current by the same proportion every time, and when you have shrunk the radius to 0 you have a magnetic dipole. Now imagine a whole bunch of those trapped pointing in the same direction inside of a bar. That is essentially what a permanent magnet is. The electron has a relativistic quantum mechanical property called spin which is the cause of the magnetic dipole.
Good question! The magnetic field wraps around a current carrying conductor in closed loops - there is no north or south pole. You only see poles on magnetic materials, e.g. magnets or electromagnets that have an iron core. In these cases, the total B-field in the core is the sum of the contributions from the electrical current outside the core (i.e. in the windings of the coil) and the bound currents inside the core (i.e. atomic properties of the core material). These two types of currents are represented by the magnetizations H ( from the coil) and M (from the bound currents): B μ0(H + M) The poles we find on the ends of a bar magnet are due to the M component and due to the discontinuity that exists between the ends of the magnet and the surrounding air. Note that if the bar magnet was a continuous donut of iron with a current carrying wire passing through the hole, the poles would disappear. If you were to cut a chunk out of the donut, the poles would reappear.
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