No.
You could use another magnet with marked poles to determine the poles of the unmarked magnet. By observing how the unmarked magnet interacts with the marked magnet, you can identify the north and south poles of the unmarked magnet based on attraction and repulsion.
What is little known, is that the whole of the UK is a giant magnet. This is why poles are attracted to it!
Like poles repel, opposites attract. So a N pole of one bar magnet will repel the N pole of another bar magnet. And the same applies to two S poles.
The opposite poles of a magnet are the north and south poles. These poles attract each other, meaning that the north pole of one magnet will be attracted to the south pole of another magnet. Conversely, like poles (north-north or south-south) repel each other.
The north and south poles.
It doesn't
a mineral magnet can stick to a magnet because a mineral magnet has to poles the north and the south poles
poles
Of course . You can make such a magnet easily using a safety pin. Take a safety pin and magnetize it using a permanent magnet. Then unfold it. The ends will have same poles and at the middle you will have the other. So you can have a magnet with three poles. Verify it using compass.
A magnet has two poles which are known as north and south poles.
Answer. Two properties of a magnet are: (i) A magnet always has two poles: north pole and south pole.
You could use another magnet with marked poles to determine the poles of the unmarked magnet. By observing how the unmarked magnet interacts with the marked magnet, you can identify the north and south poles of the unmarked magnet based on attraction and repulsion.
North and South (Poles) :)
A magnet can have a minimum of 2 poles (north and south poles) and a maximum of an infinite number of poles if the magnet is divided into smaller and smaller sections.
One pole in a magnet which is n stands for north , and the other pole on a magnet which is s , stands for south. Those are the two poles on a magnet.
Nothing happens, except that now you have two magnets. The poles of a magnet are not actually localized at the two ends of the magnet but are inherent to the magnetic properties of the magnet. As the magnetic properties are not altered by a modification of the magnet such as cutting it in half, there will be no effect on the poles of the magnet.
dipole magnet