Introduction
By now you should be well aware of the
correlation between electrical conductivity and certain
types of materials. Those materials allowing for easy
passage of free electrons are called conductors,
while those materials impeding the passage of free electrons
are called insulators.
Unfortunately, the scientific theories
explaining why certain materials conduct and others don't
are quite complex, rooted in quantum mechanical explanations
in how electrons are arranged around the nuclei of atoms.
Contrary to the well-known "planetary" model of electrons
whirling around an atom's nucleus as well-defined chunks of
matter in circular or elliptical orbits, electrons in
"orbit" don't really act like pieces of matter at all.
Rather, they exhibit the characteristics of both particle
and wave, their behavior constrained by placement within
distinct zones around the nucleus referred to as "shells"
and "subshells." Electrons can occupy these zones only in a
limited range of energies depending on the particular zone
and how occupied that zone is with other electrons. If
electrons really did act like tiny planets held in orbit
around the nucleus by electrostatic attraction, their
actions described by the same laws describing the motions of
real planets, there could be no real distinction between
conductors and insulators, and chemical bonds between atoms
would not exist in the way they do now. It is the discrete,
"quantitized" nature of electron energy and placement
described by quantum physics that gives these phenomena
their regularity.
When an electron is free to assume higher
energy states around an atom's nucleus (due to its placement
in a particular "shell"), it may be free to break away from
the atom and comprise part of an electric current through
the substance. If the quantum limitations imposed on an
electron deny it this freedom, however, the electron is
considered to be "bound" and cannot break away (at least not
easily) to constitute a current. The former scenario is
typical of conducting materials, while the latter is typical
of insulating materials.
Some textbooks will tell you that an
element's conductivity or nonconductivity is exclusively
determined by the number of electrons residing in the atoms'
outer "shell" (called the valence shell), but this is
an oversimplification, as any examination of conductivity
versus valence electrons in a table of elements will
confirm. The true complexity of the situation is further
revealed when the conductivity of molecules (collections of
atoms bound to one another by electron activity) is
considered.
A good example of this is the element
carbon, which comprises materials of vastly differing
conductivity: graphite and diamond. Graphite is a fair
conductor of electricity, while diamond is practically an
insulator (stranger yet, it is technically classified as a
semiconductor, which in its pure form acts as an
insulator, but can conduct under high temperatures and/or
the influence of impurities). Both graphite and diamond are
composed of the exact same types of atoms: carbon, with 6
protons, 6 neutrons and 6 electrons each. The fundamental
difference between graphite and diamond being that graphite
molecules are flat groupings of carbon atoms while diamond
molecules are tetrahedral (pyramid-shaped) groupings of
carbon atoms.
If atoms of carbon are joined to other types
of atoms to form compounds, electrical conductivity becomes
altered once again. Silicon carbide, a compound of the
elements silicon and carbon, exhibits nonlinear behavior:
its electrical resistance decreases with increases in
applied voltage! Hydrocarbon compounds (such as the
molecules found in oils) tend to be very good insulators. As
you can see, a simple count of valence electrons in an atom
is a poor indicator of a substance's electrical
conductivity.
All metallic elements are good conductors of
electricity, due to the way the atoms bond with each other.
The electrons of the atoms comprising a mass of metal are so
uninhibited in their allowable energy states that they float
freely between the different nuclei in the substance,
readily motivated by any electric field. The electrons are
so mobile, in fact, that they are sometimes described by
scientists as an electron gas, or even an electron
sea in which the atomic nuclei rest. This electron
mobility accounts for some of the other common properties of
metals: good heat conductivity, malleability and ductility
(easily formed into different shapes), and a lustrous finish
when pure.
Thankfully, the physics behind all this is
mostly irrelevant to our purposes here. Suffice it to say
that some materials are good conductors, some are poor
conductors, and some are in between. For now it is good
enough to simply understand that these distinctions are
determined by the configuration of the electrons around the
constituent atoms of the material.
An important step in getting electricity to
do our bidding is to be able to construct paths for
electrons to flow with controlled amounts of resistance. It
is also vitally important that we be able to prevent
electrons from flowing where we don't want them to, by using
insulating materials. However, not all conductors are the
same, and neither are all insulators. We need to understand
some of the characteristics of common conductors and
insulators, and be able to apply these characteristics to
specific applications.
Almost all conductors possess a certain,
measurable resistance (special types of materials called
superconductors possess absolutely no electrical
resistance, but these are not ordinary materials, and they
must be held in special conditions in order to be super
conductive). Typically, we assume the resistance of the
conductors in a circuit to be zero, and we expect that
current passes through them without producing any
appreciable voltage drop. In reality, however, there will
almost always be a voltage drop along the (normal)
conductive pathways of an electric circuit, whether we want
a voltage drop to be there or not:
In order to calculate what these voltage
drops will be in any particular circuit, we must be able to
ascertain the resistance of ordinary wire, knowing the wire
size and diameter. Some of the following sections of this
chapter will address the details of doing this.
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REVIEW:
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Electrical conductivity of a material is
determined by the configuration of electrons in that
materials atoms and molecules (groups of bonded atoms).
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All normal conductors possess resistance
to some degree.
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Electrons flowing through a conductor with
(any) resistance will produce some amount of voltage drop
across the length of that conductor.
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