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ELECTRICITY
– ELECTRIC CHARGE, ELECTRIC FIELD AND ELECTRIC
CURRENT
Amber is the fossilized resin from trees similar
to a fir or spruce that grew millions of years ago.
Amber is a beautiful, translucent yellow-brown solid.
It has been used as jewelry for thousands of years.
As jewelry it was often vigorously polished with
a soft cloth. Ancient Greeks discovered a strange
property of amber. When it is rubbed with a cloth,
it can attract nearby bits of straw or grain. From
the Latin word for amber, electrum, we get the word
electricity. For more on amber +
Link to Website
All materials show this behavior
to varying degree when rubbed. The classic materials used to explore
this strange attraction were glass rods rubbed with silk cloth and
rubber rods rubbed with fur. Plastic combs or strips rubbed with
wool or combed vigorously through dry hair will also attract bits
of paper. In 1646 it was shown that repulsion was also possible.
When two rods of glass were rubbed with silk, the rods repelled
each other. When two rubber rods were rubbed with fur, the rods
repelled each other. However, a glass rod rubbed with silk attracted
a rubber rod rubbed with fur.
This mysterious attractive or repulsive
property could also be passed to other materials. In the classic
experiment two tiny balls of pith were hung next to each other without
touching. A glass rod was rubbed with silk and touched to each pith
ball. The pith balls would suddenly move away from each other.
These and many more experiments
led scientists to a model used to summarize what they observed.
The model consists of three rules using something called "electrical
charge". The three rules are:
- There are only two kinds of
electrical charge. One is called positive and the
other is called negative.
- Two objects that have been charged alike repel each other.
- Two objects that have been oppositely charged attract each other.
The rules are simple but understanding charge
is more difficult. There have been many theories about the nature
of charge since the 1600s. Modern atomic theory defines charge in
terms of the electron. The electron has a negative one charge. The
more massive proton has a positive one charge. In fact, the proton
is 1000 times more massive than the electron. According to our modern
model when an object has a negative charge, it has an excess of
electrons. When an object is positively charged, it has lost electrons.
The outer electrons of an atom move much more easily than a proton
bound in a nucleus.  The traditional unit of charge is the Coulomb,
named after French physicist, Charles
Coulomb.
Compared with an electron, the Coulomb is a very large charge. Each electron
and proton have a charge of approximately 1.6 x 10-19 Coulomb. If
two objects, each with a net charge of +1 Coulomb, were 1 meter
apart, the repulsive force would be 9 billion Newtons or 1 million
tons. The Coulomb is such a large charge that it is unwieldy in
many applications. Often a micro-Coulomb (10-6) or pico-Coulomb
(10-12) is used.
The influence of the charged object
extends out into the space surrounding the charged objects. In the
example above a meter of space separates the two objects! A force
is exerted on each object, even though the objects are not touching
each other. In the 1600s this was called "action at a distance",
and it was very disturbing to many physicists, including Newton.
Gravitational, magnetic and electrical forces all display this effect. William
Gilbert studied this long-distance effect extensively using
magnetism. He explained the action of a magnet by proposing that
it had a "sphere of influence" surrounding it. 
This region of influence was called a field. One can see the presence
of a magnetic field if one puts a magnet under glass and sprinkles
iron filings on top of the glass.
The iron filings appear to be arranged
along lines.
It is possible to see a similar
effect of an electric field. 
A charged object placed in fine oil with tiny bits of thin thread
will cause the thread to line up in the field.
It might look like the picture to the right.
A drawing similar to the one below
can represent this situation.
Physicists conventionally give a
direction to the fields with the field lines pointed away from a
positive charge and pointed toward a negative. The field lines are
more dense (closer together) near the charge indicating the electric
field is stronger closer to the charge. Field lines drawn close
together represent a strong field.
When two opposite charges are placed near each other in fine oil with
fine bits of thread, the situation looks like the picture to the
right.
If a positive test charge were placed
in the field around a positive charge and released, the test charge
would be repelled and would accelerate away from the positive charge.
If this test charge were in the field of a negative charge, the
test charge would accelerate toward the negative charge. But the
test charge wouldn't 'know' whether it was pushed by a positive
charge or pulled by a negative charge. The test charge would simply
experience the local electric field in a particular direction. Scientists
describe this as due to an electric field producing a force on a
charged object. The size of the force depends upon the local strength
of the field.
The picture (to the left) shows two parallel metal plates that are oppositely
charged. Tiny bits of thread are suspended in oil between the plates.
Notice that the threads line up parallel to each other between the
plates. The threads arrange themselves along curved lines near the
edges.
The drawing below represents what
is happening between the plates. The top plate has
an excess of positive charge and the bottom plate has an excess of
negative charge. The electric field (E) is directed downward (from
positive to negative). The drawing shows the direction of force (F)
the field exerts on a positive charge and on a negative charge. If
the charges were free to move, they would accelerate in the direction
of the force.
Electric fields can, therefore,
cause charges to move. The movement of charges is an important concept
in electricity. Physicists call the net movement of charges an electric
current. In the late 1700's scientists chose the direction of electric
current to be the direction in which positive charges move in an
electric field.  This was before scientists knew that electrons and
protons were the negative and positive charge particles, and that
the electron moved more easily than the proton. We now know that
in a copper wire the outer electrons of the copper atom move relative
to the nucleus of the copper atom. Therefore, the charge carriers
(electrons) move in the opposite direction to the current.
Electric charges, electric fields
and electric current are critical to the study of the structure
of the Sun, solar
wind and the magnetosphere
of the Earth. Moreover, electric current causes magnetic fields
(see Electromagnetism)
that are important to understanding dynamic characteristics of the
Sun and how the Sun interacts with the Earth.
The next section, Electromagnetism,
involves us in a unique and interesting exploration of the science
of two men, Hans Christian Oersted and Michael Faraday, in the early
1800s, and provides us with the background necessary to understand
the magnetism of the Earth.
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