MAGNETISM In studying the electric

MAGNETISM
In studying the electric current, we observe the following relation between
magnetism and the electric current: on the one hand magnetism is produced
by the current and on the other hand the current is produced from
magnetism.
Magnetism is mentioned in the oldest writings of man. Romans, for
example, knew that an object looking like a small dark stone had the
property of attracting iron. However, nobody knew who discovered
magnetism or where and when the discovery was made. Of course, people 26
could not help repeating the stories that they had heard from their fathers
who, in their turn, heard them from their own fathers and so on.
One story tells us of a man called Magnus whose iron staff was pulled to a
stone and held there. He had great difficulty in pulling his staff away.
Magnus carried the stone away with him in order to demonstrate its
attracting ability among his friends. This unfamiliar substance was called
Magnus after its discoverer, this name having come down to us as "Magnet".
According to another story, a great mountain by the sea possessed so much
magnetism that all passing ships were destroyed because all their iron parts
fell out. They were pulled out because of the magnetic force of that
mountain.
The earliest practical application of magnetism was connected with the use
of a simple compass consisting of one small magnet pointing north and south.
A great step forward in the scientific study of magnetism was made by
Gilbert, the well-known English physicist (1540-1603). He carried out
various important experiments on electricity and magnetism and wrote a
book where he put together all that was known about magnetism. He proved
that the earth itself was a great magnet.
Reference must be made here to Galileo, the famous Italian astronomer,
physicist and mathematician. He took great interest in Gilbert's
achievements and also studied the properties of magnetic materials. He ex￾perimented with them trying to increase their attracting power. One of his
magnets, for example, could lift objects weighing 25 times more than its own
weight.
At present, even a schoolboy is quite familiar with the fact that in
magnetic materials, such as iron and steel, the molecules themselves are
minute magnets, each of them having a north pole and a south pole. When
iron and steel are magnetized, the molecules arrange themselves in a new
orderly way instead of the disarrangement in which they neutralize each 27
other.
Dividing a bar magnet into two parts, one finds that each of the two parts
is a magnet having both a north pole and a south pole. Thus, we obtain two
magnets of a smaller size instead of having a single one of a larger size.
Dividing one of these two smaller magnets into two will give us the same
result. Thus, we could continue this process, always getting similar results.
On placing an unmagnified iron bar near a strong magnet, we magnetize it.
Rubbing the magnet is not required for that process. In other words, our iron
bar has been magnetized by the strong magnet without rubbing it.