Simple Conduction2.212000/08/012007/08/21 10:25:08.132 GMT-5BillWilsonwlw@madriver.netBillWilsonwlw@madriver.netLiqunWangliqun@rice.eduBrentMichaelHendricksbrentmh@rice.eduGerardWysockigerardw@rice.educonductionIntroduction of simple conduction, including the basic ideas and models of conductor.
Our initial studies will more or less be a review of topics in
electricity that you may have seen before in physics. However,
if experience is any guide, there is no great harm in going back
over this material, for it seems that for many students, the
whole concept of just how electricity actually works is just a
little hazy. Considering that you hope to be called an
electrical engineer one of these days, this might even be a good
thing to know!
Most of the "laws" of how electricity behaves are really just
mathematical representations of a number of empirical
observations, based on some assumptions and guesses which were
made in attempt to bring the "laws" into a coherent whole.
Early investigators (Faraday, Gauss, Coulomb, Henry etc....all
those guys) determined certain things about this strange
"invisible" thing called electricity. In fact, the electron
itself was only discovered a little over 100 years ago. Even before
the electron itself was observed, people knew that there were
two kinds of electric charge, which were called
positive and negative. Like charges
exhibit a repulsive force between them and opposite charges
attract one another. This force is proportional to the product
of the absolute value of positive and negative charge, and
varies inversely with the square of the distance between them.
Different charge carriers have different mass, some are very
light, and others are significantly heavier. Electrical charges
can experience forces, and can move about. Since force times
distance equals work, a whole system of energy
(potential as well as kinetic) and
energy loss had to be described. This has lead to our current
system of electrostatics and electrodynamics, which we will not
review now but bring up along the way as things are needed.
Just to make sure everyone is on the same footing however, let's
define a few quantities now, and then we will see how they
interact with one another as we go along.
The total charge in some region is defined by the symbol
Q and it has units of Coulombs.
The fundamental unit of charge (that of an electron or a proton)
is symbolized either by a little q or by e. Since we'll
use e for other things, in this course we will try to stick
with q. The charge of an
electron, q, has a value of
1.6-19 Coulombs.
Since charge can be distributed throughout a region with varying
concentrations, we will also talk about the charge
density,
ρν, which has units of
Coulombscm3. (In this book, we will use a modified MKS system of
units. In keeping with most workers in the solid-state device
field, volume will usually be expressed as a cubic centimeter,
rather than a cubic meter - a cubic meter of silicon is just far
too much!) In most cases, the charge density is not uniform but is a
function of where we are in space. Thus, when we have
ρν distributed throughout some volume, VQνVρν describes the total charge in that volume.
We know that when we apply an electric field to a charge that
there is a force exerted on it, and that if the charge is able
to move it will do so. The motion of charge gives rise to an
electric current, which we call I.
The current is a measure of how much charge is passing a given
point per unit time (
Coulombssecond).
It will be helpful if we have some kind of model of how
electricity flows in a conductor. There are several approaches
which one can take, some more intuitive than others. The one we
will look at, while not correct in the strictest sense, still
gives a very good picture of how electrical conduction works,
and is perfectly fine to use in a variety of situations. In the
Drude theory of conduction, the initial hypothesis
consists of a solid, which contains mobile charges which are
free to move about under the influence of an applied electric
field. There are also fixed charges of polarity opposite that
of the mobile charges, so that everywhere within the solid, the
net charge density is zero. (This hypothesis is based on the
model of the atom, with a positively charged nucleus and
negatively charged electrons surrounding it. In a solid, the
atoms are fixed in position in the lattice, but it is assumed
that some of the electrons can break free of their "host" atom
and move about to other places within the solid.) In our model,
let us choose the polarity of the mobile charges to be positive;
this is not usually the case, but we can avoid a lot of
"minus ones" this way, and have a better chance of ending up
with the right answer in the end.
Model of a conductor.
As shown in , the model of the
conductor consists of a number of mobile positive charges
(represented by the balls with the "+" sign in them) and an
equal number of fixed negative charges (represented by the bare
"-" sign). In subsequent figures, we will leave out the fixed
charge, since it can not contribute in any way to the conduction
process, but keep in mind that it is there, and that the total
net charge is zero within the material. Each of the mobile
charge carriers has a mass, m, and
an amount of charge, q.
Applying a potential to a conductor
In order to have some conduction, we have to apply a potential
or voltage across the sample (). We do this with a battery, which
creates a potential difference, V,
between one end of the sample and the other. We will make the
simplest assumption that we can, and say that the voltage,
V, gives rise to a uniform electric
field within the sample. The magnitude of the electric field is
given simply by
EVL
where L is the length of the
sample, and V is the voltage which
is placed across it. (In truth, we should be showing
E as well as subsequent forces
etc. as vectors in our equations, but since their direction will
be obvious, and unambiguous, let's keep things simple, and just
write them as scalers.) Electric potential, or
voltage, is just a measure of the change in potential energy per
unit charge going from one place to another. Since energy, or
work is simply force times distance, if we divide the energy per
unit charge by the distance over which that potential exists, we
will end up with force per unit charge, or electric field,
E. If you are not sure about what
you just read, write it out as equations, and see that it is so.
The electric field will exert a force on the movable charges
(And the fixed ones too for that matter, but since they can not
go anywhere, nothing happens to them). The force is given
simply as the product of the electric field strength times the
charge
FqE
The force acts on the charges and causes them to accelerate
according to Newton's equations of motion
FmtvtqE or
tvtqEm
Thus, the velocity of a particle with no initial velocity will
increase linearly with time as:
vtqEmt
The rate of acceleration is proportional to the strength of
the electric field, and inversely proportional to the mass of
the particle. The particle can not continue to accelerate forever
however. Since it is located within a solid, sooner or later it
will collide with either another carrier, or perhaps one of the
fixed atoms within the solid. We will assume that the collision
is completely inelastic, and that after a collision, the
particle comes to a stop, only to be accelerated again by the
electric field. If we were to make a plot of the particles
velocity as a function of time, it might look something like
.
Velocity as a function of time for charge carrier
Although the particle achieves various velocities, depending
upon how much time there is between collisions, there will be
some average velocity,
v, which will depend upon the details of the collision
process. Let us define a scattering time
τs which will give us that average
velocity when we multiply it times the acceleration of the
particle. That is:
vqEτsm
or
τsmvqE
Now let's take a look at just a small section of the conductor ().
It will have the cross section of the sample,
A, but will only be
vΔt long, where
Δt is just some arbitrary time interval.
Section of the conductor
After a time
Δt has passed, all of the charges within the box will
have left it, as they are all moving with the same average
velocity,
v. If the density of charge carriers in the conductor
is n per unit volume, then the
number of carriers N within our
little box is just n times the
volume of the box
vΔtANnvΔtA
Thus the total charge, Q, which
leaves the box in time
Δt is just
qN. The current flow, I,
is just the amount of charge which flows out of the box per unit
time
IqnvΔtAΔtqnvAq2nτsEAmQΔt
We now have two choices, we can look at our result from a field
quantity point of view, in which case we will be interested in
the current density, J, which is
just the current, I, divided by the
cross-sectional area
JIAq2nτsmEσE
where σ is called the
conductivity of the material. If we look at the
conductor from a macroscopic point of view, then we are
interested in the relationship between the voltage and the
current. The voltage is just the electric field times the
length of the sample, and the current is just the current
density times is cross sectional area. Thus we have
IAJAσEAσVL
or
VLσAIRI
where R is the resistance of the
sample. We have discovered Ohm's law!
Note that tells us that the resistance
of the sample is proportional to its length (the longer the
sample, the higher the resistance) and inversely proportional to
its cross sectional area (the fatter the sample, the lower the
resistance). The sample resistance is also inversely
proportional to the conductivity σ of the sample. Sometimes, instead of conductivity,
the resistivity, ρ, is specified for a resistive material. The
resistivity is simply the inverse of the conductivity
σ1ρ
and thus:
RρLA
And, in an effort towards completeness, there is one other
quantity which you might run into, and that is the carrier
mobility, μ. The
mobility is just the proportionality factor between the average
velocity of the particle and the electric field. That is:
vμE
You should check that the following two relationships are
correct:
σnqμμqτsm
If we take an ordinary conductor (and we will have to define
later what we mean by that) and heat it up, the atoms within the
material start to vibrate faster due to the elevated
temperature, and the carriers suffer significantly more
collisions. The mean collision time τs
decreases, and hence the conductivity goes down, and the
resistance of the sample goes up.