Voltage and current
As was previously mentioned, we need more
than just a continuous path (circuit) before a continuous
flow of electrons will occur: we also need some means to
push these electrons around the circuit. Just like marbles
in a tube or water in a pipe, it takes some kind of
influencing force to initiate flow. With electrons, this
force is the same force at work in static electricity: the
force produced by an imbalance of electric charge.
If we take the examples of wax and wool
which have been rubbed together, we find that the surplus of
electrons in the wax (negative charge) and the deficit of
electrons in the wool (positive charge) creates an imbalance
of charge between them. This imbalance manifests itself as
an attractive force between the two objects:
If a conductive wire is placed between the
charged wax and wool, electrons will flow through it, as
some of the excess electrons in the wax rush through the
wire to get back to the wool, filling the deficiency of
electrons there:
The imbalance of electrons between the atoms
in the wax and the atoms in the wool creates a force between
the two materials. With no path for electrons to flow from
the wax to the wool, all this force can do is attract the
two objects together. Now that a conductor bridges the
insulating gap, however, the force will provoke electrons to
flow in a uniform direction through the wire, if only
momentarily, until the charge in that area neutralizes and
the force between the wax and wool diminishes.
The electric charge formed between these two
materials by rubbing them together serves to store a certain
amount of energy. This energy is not unlike the energy
stored in a high reservoir of water that has been pumped
from a lower-level pond:
The influence of gravity on the water in the
reservoir creates a force that attempts to move the water
down to the lower level again. If a suitable pipe is run
from the reservoir back to the pond, water will flow under
the influence of gravity down from the reservoir, through
the pipe:
It takes energy to pump that water from the
low-level pond to the high-level reservoir, and the movement
of water through the piping back down to its original level
constitutes a releasing of energy stored from previous
pumping.
If the water is pumped to an even higher
level, it will take even more energy to do so, thus more
energy will be stored, and more energy released if the water
is allowed to flow through a pipe back down again:
Electrons are not much different. If we rub
wax and wool together, we "pump" electrons away from their
normal "levels," creating a condition where a force exists
between the wax and wool, as the electrons seek to
re-establish their former positions (and balance within
their respective atoms). The force attracting electrons back
to their original positions around the positive nuclei of
their atoms is analogous to the force gravity exerts on
water in the reservoir, trying to draw it down to its former
level.
Just as the pumping of water to a higher
level results in energy being stored, "pumping" electrons to
create an electric charge imbalance results in a certain
amount of energy being stored in that imbalance. And, just
as providing a way for water to flow back down from the
heights of the reservoir results in a release of that stored
energy, providing a way for electrons to flow back to their
original "levels" results in a release of stored energy.
When the electrons are poised in that static
condition (just like water sitting still, high in a
reservoir), the energy stored there is called potential
energy, because it has the possibility (potential) of
release that has not been fully realized yet. When you scuff
your rubber-soled shoes against a fabric carpet on a dry
day, you create an imbalance of electric charge between
yourself and the carpet. The action of scuffing your feet
stores energy in the form of an imbalance of electrons
forced from their original locations. If this charge (static
electricity) is stationary, and you won't realize that
energy is being stored at all. However, once you place your
hand against a metal doorknob (with lots of electron
mobility to neutralize your electric charge), that stored
energy will be released in the form of a sudden flow of
electrons through your hand, and you will perceive it as an
electric shock!
This potential energy, stored in the form of
an electric charge imbalance and capable of provoking
electrons to flow through a conductor, can be expressed as a
term called voltage, which technically is a measure
of potential energy per unit charge of electrons, or
something a physicist would call specific potential
energy. Defined in the context of static electricity,
voltage is the measure of work required to move a unit
charge from one location to another, against the force which
tries to keep electric charges balanced. In the context of
electrical power sources, voltage is the amount of potential
energy available (work to be done) per unit charge, to move
electrons through a conductor.
Because voltage is an expression of
potential energy, representing the possibility or potential
for energy release as the electrons move from one "level" to
another, it is always referenced between two points.
Consider the water reservoir analogy:
Because of the difference in the height of
the drop, there's potential for much more energy to be
released from the reservoir through the piping to location 2
than to location 1. The principle can be intuitively
understood in dropping a rock: which results in a more
violent impact, a rock dropped from a height of one foot, or
the same rock dropped from a height of one mile? Obviously,
the drop of greater height results in greater energy
released (a more violent impact). We cannot assess the
amount of stored energy in a water reservoir simply by
measuring the volume of water any more than we can predict
the severity of a falling rock's impact simply from knowing
the weight of the rock: in both cases we must also consider
how far these masses will drop from their initial
height. The amount of energy released by allowing a mass to
drop is relative to the distance between its starting
and ending points. Likewise, the potential energy available
for moving electrons from one point to another is relative
to those two points. Therefore, voltage is always expressed
as a quantity between two points. Interestingly
enough, the analogy of a mass potentially "dropping" from
one height to another is such an apt model that voltage
between two points is sometimes called a voltage drop.
Voltage can be generated by means other than
rubbing certain types of materials against each other.
Chemical reactions, radiant energy, and the influence of
magnetism on conductors are a few ways in which voltage may
be produced. Respective examples of these three sources of
voltage are batteries, solar cells, and generators (such as
the "alternator" unit under the hood of your automobile).
For now, we won't go into detail as to how each of these
voltage sources works -- more important is that we
understand how voltage sources can be applied to create
electron flow in a circuit.
Let's take the symbol for a chemical battery
and build a circuit step by step:
Any source of voltage, including batteries,
have two points for electrical contact. In this case, we
have point 1 and point 2 in the above diagram. The
horizontal lines of varying length indicate that this is a
battery, and they further indicate the direction which this
battery's voltage will try to push electrons through a
circuit. The fact that the horizontal lines in the battery
symbol appear separated (and thus unable to serve as a path
for electrons to move) is no cause for concern: in real
life, those horizontal lines represent metallic plates
immersed in a liquid or semi-solid material that not only
conducts electrons, but also generates the voltage to push
them along by interacting with the plates.
Notice the little "+" and "-" signs to the
immediate left of the battery symbol. The negative (-) end
of the battery is always the end with the shortest dash, and
the positive (+) end of the battery is always the end with
the longest dash. Since we have decided to call electrons
"negatively" charged (thanks, Ben!), the negative end of a
battery is that end which tries to push electrons out of it.
Likewise, the positive end is that end which tries to
attract electrons.
With the "+" and "-" ends of the battery not
connected to anything, there will be voltage between those
two points, but there will be no flow of electrons through
the battery, because there is no continuous path for the
electrons to move.
The same principle holds true for the water
reservoir and pump analogy: without a return pipe back to
the pond, stored energy in the reservoir cannot be released
in the form of water flow. Once the reservoir is completely
filled up, no flow can occur, no matter how much pressure
the pump may generate. There needs to be a complete path
(circuit) for water to flow from the pond, to the reservoir,
and back to the pond in order for continuous flow to occur.
We can provide such a path for the battery
by connecting a piece of wire from one end of the battery to
the other. Forming a circuit with a loop of wire, we will
initiate a continuous flow of electrons in a clockwise
direction:
So long as the battery continues to produce
voltage and the continuity of the electrical path isn't
broken, electrons will continue to flow in the circuit.
Following the metaphor of water moving through a pipe, this
continuous, uniform flow of electrons through the circuit is
called a current. So long as the voltage source keeps
"pushing" in the same direction, the electron flow will
continue to move in the same direction in the circuit. This
single-direction flow of electrons is called a Direct
Current, or DC. In the second volume of this book
series, electric circuits are explored where the direction
of current switches back and forth: Alternating Current,
or AC. But for now, we'll just concern ourselves with DC
circuits.
Because electric current is composed of
individual electrons flowing in unison through a conductor
by moving along and pushing on the electrons ahead, just
like marbles through a tube or water through a pipe, the
amount of flow throughout a single circuit will be the same
at any point. If we were to monitor a cross-section of the
wire in a single circuit, counting the electrons flowing by,
we would notice the exact same quantity per unit of time as
in any other part of the circuit, regardless of conductor
length or conductor diameter.
If we break the circuit's continuity at
any point, the electric current will cease in the entire
loop, and the full voltage produced by the battery will be
manifested across the break, between the wire ends that used
to be connected:
Notice the "+" and "-" signs drawn at the
ends of the break in the circuit, and how they correspond to
the "+" and "-" signs next to the battery's terminals. These
markers indicate the direction that the voltage attempts to
push electron flow, that potential direction commonly
referred to as polarity. Remember that voltage is
always relative between two points. Because of this fact,
the polarity of a voltage drop is also relative between two
points: whether a point in a circuit gets labeled with a "+"
or a "-" depends on the other point to which it is
referenced. Take a look at the following circuit, where each
corner of the loop is marked with a number for reference:
With the circuit's continuity broken between
points 2 and 3, the polarity of the voltage dropped between
points 2 and 3 is "-" for point 2 and "+" for point 3. The
battery's polarity (1 "-" and 4 "+") is trying to push
electrons through the loop clockwise from 1 to 2 to 3 to 4
and back to 1 again.
Now let's see what happens if we connect
points 2 and 3 back together again, but place a break in the
circuit between points 3 and 4:
With the break between 3 and 4, the polarity
of the voltage drop between those two points is "+" for 4
and "-" for 3. Take special note of the fact that point 3's
"sign" is opposite of that in the first example, where the
break was between points 2 and 3 (where point 3 was labeled
"+"). It is impossible for us to say that point 3 in this
circuit will always be either "+" or "-", because polarity,
like voltage itself, is not specific to a single point, but
is always relative between two points!
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REVIEW:
-
Electrons can be motivated to flow through
a conductor by a the same force manifested in static
electricity.
-
Voltage is the measure of specific
potential energy (potential energy per unit charge)
between two locations. In layman's terms, it is the
measure of "push" available to motivate electrons.
-
Voltage, as an expression of potential
energy, is always relative between two locations, or
points. Sometimes it is called a voltage "drop."
-
When a voltage source is connected to a
circuit, the voltage will cause a uniform flow of
electrons through that circuit called a current.
-
In a single (one loop) circuit, the amount
current of current at any point is the same as the amount
of current at any other point.
-
If a circuit containing a voltage source
is broken, the full voltage of that source will appear
across the points of the break.
-
The +/- orientation a voltage drop is
called the polarity. It is also relative between
two points.
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