Only one pole in a horseshoe magnet

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A horseshoe magnet cannot have only one pole, as magnetic monopoles have not been observed in practice. When current flows in the same direction at both ends of a horseshoe magnet, it creates two south poles that largely cancel each other's magnetic fields, resulting in a weak and complex net field. This configuration effectively reduces the inductance and does not produce a true single-pole magnet. Magnetic field lines will always connect from north to south poles, maintaining the integrity of the magnetic field. Therefore, the concept of a horseshoe magnet with only one pole is not feasible.
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Is it possible for a horseshoe magnet to have only one pole? For example, if i take a horseshoe shaped iron core and wind a conductor such that both the ends of the horseshoe have current flowing in the clockwise direction, then both ends are south poles. Is this possible? In that case how are the domains aligned?
 
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You create the equivalent of two permanent magnets with equal poles held together: The fields will largely cancel each other and you get a complex and weak sum of the two fields.

You cannot create magnetic monopoles that way. While these might exist as elementary particles, no magnetic monopole has ever been found - if they exist at all, they must be incredibly rare.
 
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Fiona Rozario said:
Is it possible for a horseshoe magnet to have only one pole? For example, if i take a horseshoe shaped iron core and wind a conductor such that both the ends of the horseshoe have current flowing in the clockwise direction, then both ends are south poles. Is this possible? In that case how are the domains aligned?
As mfb pointed out, you are connecting the two coils in series opposition. This way, you are reducing the net magnetic field inside the magnet by effectively reducing the inductance of the coil (look up series-aiding and series-opposing coil connections).
 
mfb said:
You create the equivalent of two permanent magnets with equal poles held together: The fields will largely cancel each other and you get a complex and weak sum of the two fields.

You cannot create magnetic monopoles that way. While these might exist as elementary particles, no magnetic monopole has ever been found - if they exist at all, they must be incredibly rare.

Thank you...
 
Fiona Rozario said:
Is it possible for a horseshoe magnet to have only one pole? For example, if i take a horseshoe shaped iron core and wind a conductor such that both the ends of the horseshoe have current flowing in the clockwise direction, then both ends are south poles. Is this possible? In that case how are the domains aligned?
You are proposing, effectively two solenoids, connected by an iron bar, joining S pole to S pole. I cannot find an image of the fields round that particular setup but the images in this link may give you an idea of what to expect. You will see that the lines of force that you were thinking would somehow disappear will, in fact, bend round from S to N poles. The result will not be symmetrical but those lines will still find their way from N to S, whatever you do with them. In all the possible set ups you can see, the lines are complete - sometimes going through both magnets.
 

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