ELECTRICITY LEAVES ONE BATTERY PLATE, THEN RETURNS TO THE OTHER?
Not quite.
In a simple circuit, the actual path of electric current is through
the battery. Some books imply (or even state outright) that whenever a
battery is connected in a complete circuit, the charges only flow in the
wires. They say that one battery plate is the source of electrons, the
other plate collects "used" electrons, and no charges flow in the
chemicals between the battery plates. This is wrong. These books often
contain a diagram of a battery,
wires, and a light bulb. The diagram shows the current in the wires, but
charges aren't shown going through the battery. This is
wrong. The electrolyte is a conductor. There is a large current
flowing between the battery plates.
In any simple electric circuit, the path of the electric current is a
complete circle. It's like a drive belt, and it has no starting point.
It goes through all parts of the circuit including the
battery, and including the battery's liquid electrolyte. Between the
plates of any battery we find a highly conductive liquid. Sometimes its
an acid (as with car batteries.) Sometimes it's alkaline, and sometimes
it's salt water. (But how can a battery even work, if the plates are
connected together with conductive fluid? That's a
separate topic.)
No charges are continuously building up in the battery plates.
There's only a small build-up to "pressurize" the terminals and create the
flow. And if there's
one Ampere
in the wires connected to the battery, then there's
also a 1-Amp flow of charge in the electrolyte between the two plates.
Where does this charge come from? Go down to this section. A battery does not supply
charges, it merely
pumps them. Whenever electric charge flows into one terminal of a
battery, an equal amount of charge must flow through the battery
and back out through the other terminal. In a simple DC battery/bulb
circuit, the charges are forever flowing around and around the circuit,
going through the bulb filament, but also going through the battery.
The battery is a charge pump.
ELECTRIC ENERGY IS CARRIED BY INDIVIDUAL ELECTRONS? Wrong.
Some books teach that, in a simple battery/bulb circuit, each electron
carries energy to the bulb, deposits its energy in the hot filament, and
then returns to the battery where it's re-filled with energy. This is
wrong. Some books give an analogy with a circular track full of freight
cars waiting to be filled with coal. This picture is wrong too. The
energy in electric circuits is not carried by individual electrons.
Instead the electrons flow very slowly while the electrical energy flows
rapidly along the columns of electrons. In AC circuits the electrons
don't flow forward at all, instead they vibrate slightly, even though the
energy flows rapidly from generator to appliance. As with rotating
shafts and drive belts, the energy
is carried by the circuit as a whole, not by the individual particles
in the system.
Here's an analogy which may help explain it:
Imagine a wheel that's free
to spin. For example, turn a bicycle upside-down in your mind. Give the
front tire a spin. When you spin the wheel, your hand injects energy into
the entire wheel all at once.
Now put your hand lightly against some part
of the tire so the spinning wheel is slowed and stopped by friction. Your
hand gets hot. Your hand extracts energy from the entire wheel, all at
once, and the whole wheel slows down.
Finally perform both tasks at once:
rub one hand lightly against the tire, while you use your other hand to
keep the wheel spinning.
Would it be right to tell students that the
"Power" hand fills each rubber molecule with energy, that the molecules
travel to the "Friction" hand and dump their energy? Then the
empty molecules
return to the "power" hand and get refilled? No, of course not! If this
were true then the energy would be forced to travel only as fast as the
rubber. Your "friction" hand wouldn't experience any friction until
those magically energized rubber molecules made their way around the rim.
Part of the wheel would be spinning while part would be de-energized and
unmoving, and this would be really a strange sight to see!
Instead, one hand spins the wheel and fills the whole thing with kinetic
energy... and the rubbing hand sucks the energy back out at the same time.
The wheel rotates, and energy flows almost instantly across the wheel,
going from the "spin" hand to the "friction" hand.
A flashlight circuit is like our bicycle wheel. The electrons in the
copper wire circuit are like the rim of the wheel. Electrons are like an
invisible drive-belt hidden inside the wires. The battery causes
all the electrons in the loop of wire to begin moving. In this way
it injects energy into the whole circuit all at once, just like a
hand that spins a bicycle wheel. As soon as the battery moves the
circuit's electrons, the distant lightbulb lights up. The electrons
moving into the bulb's filament are exactly the same as the ones moving
out; the bulb doesn't change them or extract stored energy from them.
(Did your hand do anything to change the rubber molecules as it rubbed on
the bicycle wheel? No, it just slowed down the entire wheel.) A hand can
extract energy from an entire bicycle wheel instantly, and the hand heats
up by friction. Same thing with the bulb, it slows down ALL the electrons
throughout the entire circuit, and in this way the bulb extracts energy
from the whole circuit as it lights up.
In other words, electric circuits are drive belts, and all wires are
always full of movable electrons.
In discussing the "freight cars" misconception with teachers, I find that
they see nothing wrong with teaching the wrong picture to their students!
After all, the kids instantly grasp the "freight cars with coal" story
since it's very visible and it offers a sensible explanation. What more
can we ask? Yet there is a serious problem here: electrons flow slowly,
and in AC circuits they don't flow at all, instead they wiggle. If the
freight cars only vibrate, and never flow forwards, how the heck does any
coal get to the other side of the circle? (How does AC actually work?)
There's no answer. Students will be trapped.
In order to really understand electric circuits in the
more advanced classes, a student must unlearn the seductive
freight-cars analogy. "Unlearning" rarely happens, and so this wrong
analogy can form a learning barrier which can forever prevent any further
progress. It freezes their understanding of electricity at the
elementary-school level. Yes, if those particular kids will never have
any need to understand how electricity really works, then the
freight-cars analogy is fine. The kids can memorize it, teachers can test
them for it, and everybody is happy. "Learning" has occurred (rather than
actual learning.) But if the kids grow up to become
scientists and engineers and technical people, then the freight-cars
analogy causes them harm. Unfortunately, it only causes future
harm, so the grade-school educators never encounter the negative effects
of the misconceptions they've installed in their kids' minds.
OK, what if you were using the "freight cars w/coal" analogy, but you also
had to explain how "AC" works? In that case the freight cars are moving
back and forth but not progressing forwards. How can they deliver their
coal to the far end of the track? I suspect that teachers encounter this
problem, but rather than recognizing that "freight cars" is a
misconception, they instead pile another misconception: the wrong idea
that electrons in wires flow at the speed of light. After all, if
the coal-filled freight cars traveled instantly to the far end of the
track, then dumped their coal, then traveled instantly back, that
would be
alternating current. Right?!! Wrong, because electric currents are
actually very
slow flows of charges. During AC those "freight cars" only wiggle back
and forth a few inches on their tracks.
The bicycle-wheel analogy has no problem explaining AC. Just wiggle the
bicycle wheel back and forth instead of spinning it continuously. The
wiggling wheel will rub upon the distant unmoving "friction" hand, and
will heat up that hand. Energy can essentially travel instantly across
the bicycle wheel, even though the wheel itself rotates slowly. Energy
can travel instantly between the two hands, even if the wheel moves back
and forth instead of spinning. What determines the direction of this
energy travel? It's simple. If one hand spins the wheel, it throws
energy out into the wheel, and if another hand rubs on the tire, it
extracts energy from the wheel. Notice that the energy doesn't care about
the wheel's rotation. The energy flows one-way, from one hand to the
other, even if the wheel reverses direction, and even if the wheel
vibrates back and forth rather than continuously turning. And most
important: both paths through the tire are sending energy in one
direction: towards the frictional load. In one side, the energy is going
backwards against the direction of current.
The "filled freightcars" analogy only becomes seductively appropriate when
used
to explain Direct Current. However, when explaining Alternating Current,
the analogy breaks down completely. Each freight car wiggles back and
forth, so how can those energy-filled buckets move from the "battery" to
the "light bulb?" They cannot. The analogy doesn't work, and students
who have learned the analogy will find it impossible to understand AC.
In grade-school they were taught about batteries and bulbs, but never
about power plants and AC electric heaters.
Again, this is fine if the kids have no hopes of entering any kind
of technical career; if their science learning will cease after fifth
grade...
How about another analogy about this analogy (grin!) Sound waves are much
like electrical energy in circuits. So, how do sound waves work? Ask
yourself this: would it be OK to teach kids that your vocal chords place
energy into air molecules, then each air molecule zooms out of your
mouth
at 720MPH, then flies across the room almost instantly, then
eventually crashes into the ears of distant listeners?
That's silly. There's no supersonic wind coming out of our mouths. I
would think that any author who use this kind of explanation should be
ashamed. Yes, the explanation "works", and it is easy for the kids to
grasp. But it is totally wrong: sound is carried by waves in the
air, not
by individual air molecules launched at immense velocities out of your
mouth. And
any kid who believes this "launched molecules" sound-explanation will
eventually have
terrible difficulties should they ever have need to understand how sound
really works.
All of this is an analogy for wires and circuits: electrical energy is
wave energy; electrical energy moves along the columns of electrons like
sound waves move through the air, and when electrical energy flows across
a circuit, the electrons DON'T flow along with it. Electrons are a
wave-medium, and all electrical energy is wave-energy. (Don't forget
that electrical energy has another name: electromagnetism.) Yank on a
rope, and the rope moves towards you, but the "jerk" flies rapidly in the
other direction along the rope. The "jerk" is the energy. It travels as
a wave through a medium. But this means ...electric circuits have a rope
inside! Exactly right. That's why you need a complete circuit,
since if there is a blockage anywhere in the, ahem, "circuit," the ring of
invisible electricity-rope cannot move.
BATTERIES STORE CHARGE, AND THIS CHARGE FLOWS IN WIRES? No.
The word "charge" has more than one meaning, and the meanings contradict
each other. The "charge" in a battery is energy (chemical energy), while
the "charge" that flows inside wires is part of matter, it is electron
particles. And those wires, even though full of charge... are neutral and
uncharged! The term "charge"
refers to several different things: to net-charge, to quantities of
charged particles, and to "charges" of energy. If you are not very
careful while using the word "charge" in teaching, you might be spreading
misconceptions.
For example, even when metals are totally neutral, they contain vast
quantities of movable electrons, immense charge. So, should we say that
they contain zero charge because they are neutral? Or, should we say that
they contain a very large amount of electric charge, because they are
filled with many Coulombs of electrons? Don't answer yet, because your
answer might be inconsistent with how we describe capacitors (further
below.)
Another: if I place an electron and
a proton together, do I have twice as much charge as before, or do I have
a neutral hydrogen atom with no charge at all? What I do have is
confusion. Misuse of "charge" makes descriptions of electric circuits
seem complex and abstract, when the explanations are really just wrong.
Another: electric currents in wires are actually a motion of "neutralized"
charge, where every electron has a proton nearby. If we teach our kids
that a wire
is uncharged, and we also teach that electric current is a flow of
charge, how can anyone make sense of a situation where a wire has no
charge at all, yet contains an enormous flow of charge? We could say "Oh,
but most electric currents are usually a flow of Uncharged Charge."
WHAT? What would a student make of that statement? Can you see the
problems that arise because of the word "charge?"
Another one: as you "charge" a battery, you cause an electric current to
appear in the electrolyte, and this motion of electric charges causes
chemical reactions to occur upon the surfaces of the battery's plates.
Chemical "fuel" accumulates, but charge does not: the charges flow into
(or out of) the surfaces of the plates and do not accumulate there. (The
path for electric current is through the battery. Through, and
back out again.) A "charge" of chemical energy is stored in the battery,
but electrical charge is not. And when a battery is being "discharged",
it's chemical fuel drives a process which pumps charge through the
battery. During discharge the battery's fuel will eventually be
exhausted, but the total electric charge within the battery will never
decrease!
Here's a way to imagine the process: a battery is like a spring-driven
"wind up" water pump. Send water backwards through this pump, and you
wind up the internal spring. Then, provide a pathway between the inlet
and
the outlet of the pump, and the spring-motor will pump the water in
a circle. But now think for a moment: the water is the charge, yet
our wind-up pump does not store water! When we "charge" our
wind-up pump, we send the charge (water) through the pump, and this
stores energy by winding up the spring. Same with a battery: to
"charge" a battery, we send electrical charges through the battery
and back out again. This causes the chemicals on the battery
plates to store energy, just like winding up the spring in our
spring-powered water pump. See how "charging" and "charges" can
create a horrible mess of misunderstandings? When this mess gets
into the K-12 textbooks, and educators start teaching it to kids, the
kids end up believing that Electricity is far too complicated for them
to understand. Yet the fault does not lie with the students!!!!
Another one: if you "charge" a capacitor, you move charges from one plate
to the other, and the number of charges within the device as a whole does
not change. Or from an engineer's perspective, you drive charge
through the capacitor, which causes potential across the plates to
rise, and the rate of rise is proportional to the charge-flow. But
capacitors have exactly the same total charge within them
whether they are "charged" or not! Whenever we take an electron from one
plate, we put an electron onto the other plate. Whenever we speak of
"charging" capacitors, we've suddenly stopped talking about charge, and
started talking about electrical energy. A "charged" capacitor has quite a
bit more energy than an "uncharged" capacitor (but exactly the same
net-charge, and the same quantity of + and - particles inside.) This
basic concept reinforces the idea of charge-conservation, and
is very important in understanding simple circuitry, yet it is rarely
taught. The misleading term "charge" stands in the way of understanding.
I suspect that students are not the only ones being misled. Many teachers
misunderstand simple physics, and they truely believe that the purpose of
a capacitor is to store electric charge.
Think like this: both capacitors and inductors (coils) store
energy. They store energy in the form of fields. Coils don't store
any electric charge. Capacitors don't
store any electric charge. Yet electric charge is the medium of
energy-storage in both coils and capacitors. In capacitors, energy is
stored in the form of "stretched charge", or electric potential energy,
where positive and negative charged particles are pulled away from each
other and held separated. Coils store energy in the form of relative
moving charge which contains a sort of electrical kinetic energy.
However, we don't put any charge into a capacitor when we "charge" it, any
more than we put charge into a superconductive ring-inductor when we give
the ring a "charge" of electromagnetic energy.
"STATIC ELECTRICITY" (CONTACT ELECTRIFICATION) IS CAUSED BY
FRICTION? Wrong.
"Static electricity" is not caused by friction. It appears when two
dissimilar insulating
materials are placed into intimate contact and then separated. All that's
required is the touching. For example, when adhesive tape is placed on an
insulating surface and then peeled off, both the tape and the surface will
become electrified. No rubbing was required. Or when a plastic wheel rolls
across a rubber surface, both the surface and the wheel become electrified.
Intimate contact is sufficient, and no rubbing is needed. In a
VandeGraaff generator the rubber belt pushes against the plastic roller,
then peels away again. Of course if one of the
two materials is rough or fibrous, then it does not give a very large
footprint of
contact area. In this case the process of rubbing one material upon another
can greatly increase the total contact area. And the heating of the
fibers can make the materials even more electrically "dissimilar", which
aids the charge-separation process. But this rubbing is not the cause of
the electrification.
"STATIC ELECTRICITY" IS A BUILDUP OF ELECTRONS? Wrong.
It is not a buildup of anything, it is an imbalance between
quantities of positive and negative particles already
present.
During contact-electrification it is usually only the negative electrons
which are moved. As negative particles are pulled away from the positive
particles, equal and opposite areas of imbalance are created. In one
place you'll have more protons than electrons, and this spot will have an
overall positive charge. Elsewhere you'll have more electrons than
protons, for an overall negative charge. You've not caused a "buildup",
you've caused an imbalance, an un-canceling, a separation. In fact, the
scientific term for static electrification is charge separation.
The law of Conservation of Electric Charge requires that every time you
create a region of negative charge, you must also create a region of
positive charge. In other words you must create a separation of opposite
charges. If you want to call it a "buildup of electrons", then you also
need to call it a "buildup of protons," since you can't have one without
the other.
"STATIC ELECTRICITY" IS ELECTRICITY WHICH IS STATIC? Wrong.
"Static electricity" exists whenever there are unequal amounts of positive
and negative charged particles present. It doesn't matter whether the
region of imbalance is flowing or whether it is still. Only the imbalance
is important, not the "staticness." To say otherwise can cause several
sorts of confusion.
All solid objects contain vast quantities of positive and
negative
particles whether the objects are electrified or not. When these
quantities are not exactly equal and there is a tiny bit more positive
than negative (or vice versa), we say that the object is "electrified" or
"charged," and that "static electricity" exists. When the quantities are
equal, we say the object is "neutral" or "uncharged." "Charged" and
"uncharged" depends on the sum of opposite quantities. Since "static
electricity" is actually an imbalance in the quantities of positive and
negative, it is wrong to believe that the phenomenon has anything to do
with lack of motion, with being "static." In fact, "static electricity"
can easily be made to
*move* along conductive surfaces. When this
happens, it continues to display all it's expected characteristics as it
flows, so it does not stop being "static electricity" while it
moves along
very non-statically! In a high voltage electric circuit, the wires
can
attract lint, raise hair, etc., even though there is a large current in
the wires and all the charges are flowing (and none of the electricity
is "static.") And last, when any electric
circuit is broken and the charges stop flowing, they do *not* turn into
"static electricity" and begin attracting lint, etc. A disconnected wire
contains charges which are not moving (they are static,) yet it contains
no "static
electricity!"
To sort out this craziness, simply remember that "static electricity" is
not a quantity of unmoving charged particles, and "static electricity" has
nothing to do with unmoving-ness. If you believe that "static" and
"current" are
opposite types of "electricity," you will forever be
hopelessly confused about electricity in general.
ELECTRIC POWER FLOWS FROM GENERATOR TO CONSUMER? Wrong.
Electric power cannot be made to flow. Power is defined as "flow of
energy." Saying that power "flows" is silly. It's as silly as saying
that the stuff in a moving river is named "current" rather than named
"water." Water is real, water can flow, flows of water are called
currents, but we should never make the mistake of believing that water's
motion is a type of substance. Talking of "current" which "flows"
confuses everyone. The issue with energy is similar. Electrical energy
is real, it is sort of like a stuff, and it can flow along. When electric
energy flows, the flow is called "electric power." But electric power has
no existence of its own. Electric power is the flow rate of another
thing; electric power is an energy current. Energy flows, but power never
does, just as water flows but "water current" never does.
The above issue affects the concepts behind the units of
electrical measurement. Energy can be measured in Joules or Ergs. The
rate of flow of energy is called Joules per second. For convenience, we
give the name "power" to this Joule/sec rate of flow, and we measure it in
terms of Watts. This makes for convenient calculations. Yet Watts have
no physical, substance-like existence. The Joule
is the fundamental unit, and the Watt is a unit of convenience which
means "joule per second."
I believe that it is a good idea to teach only the term "Joule" in early
grades, to entirely avoid the "watt" concept. Call power by the proper
name "joules per second". Only introduce "watts" years later, when the
students feel a need for a convenient way to state the "joules per second"
concept. Unfortunately many grade-school textbooks do the reverse, they
keep the seemingly-complex "Joule" away from the kids, while spreading the
"watt" concept far and wide! Later they try to explain that joules are
simply watt-seconds! (That's watts times seconds, not watts per
second.)
If you aren't quite sure that you understand watt-seconds, stop thinking
backwards and think like this: Joules are real, a flow of Joules is
measured in Joules per second, and "Watts" should not interfere with these
basic ideas.
PROTONS CANNOT FLOW? Not so.
In metals, yes you're right, the protons of the metal atoms cannot flow
along. But never
forget that metals aren't the only type of conductor. So, where would we
encounter some flowing protons?
First, note that proton currents are typically called something different.
From a chemistry viewpoint, a single proton is really nothing but a
hydrogen atom which is lacking any electrons. So, the
other common name for proton is H+, or "positive Hydrogen ion!" Where do
we find
electric currents made of + hydrogen ions? Car batteries, of course.
When H2SO4 is added to water, it splits up (ionizes) to become the
negative SO4 ion plus two H+, two mobile protons.
In acids the electric current is a flow of protons in one direction and
negative ions in the other. The protons are much more easily moved, so
most of the electric current in acid solutions is from the proton flow.
And besides acids, pure water also is a conductor where the currents are
+H ions (protons) and -OH negative ions, each travelling in opposite
directions. (Instead of metal wires full of electrons, imagine a long
hose full of water. Push one proton into one end, and immediately a
proton pops out of the far end! That's proton flow.) Interesting
fact: ice that's made from fresh water is not a perfect insulator, instead
the OH- ions are immobilized in the ice crystal: it's a proton conductor.
Recently with the rise of green-energy topics we have another common
proton conductor. These are called ...proton conductors.
They're used in fuel cells. Another name for them is "solid electrolyte."
In these types of conductors the charge carriers are protons.
PS Why do chemistry texts call protons by the name "hydrogen ion?" Part
of this is just tradition: we knew about hydrogen, and then about atom
ionization, long, long before we knew about protons. (Heh, so why don't
chemists call Helium by the name "alpha particle?") But also, protons are
extremely reactive chemically, and it makes sense to view them as positive
charged hydrogen, the first element in the Periodic Table. Also, hydrogen
isn't pure protons, it's not a pure isotope. When hydrogen is present, a
tiny fraction of a percent is actually deuterium, a proton plus a neutron,
and far smaller fraction has two neutrons: tritium. Your water is mostly
made of protons and oxygen, but a bit of it is heavy water, and a slight
amount is radioactive. To conceal this complexity, we could pretend that
it's all protons. Or we could avoid the issue and just call it Hydrogen.
And finally, please notice that all of this goes directly against the
common widespread misconception that "all electricity is really electrons."
LIGHT AND RADIO WAVES TRAVEL AT 186,000 MILES PER SECOND?
No.
They only travel at 186,000 miles per second while in a perfect vacuum.
Light waves travel a bit slower in the air, and they travel lots
slower when inside glass. And radio waves move much slower than 186,000
miles/sec when they travel within plastic-insulated coaxial cable. The
term "speed of light" is misleading, because the complete term actually
reads "speed of light in a vacuum." There actually is no set "speed of
light" because light waves and radio waves (and electrical energy) can
travel at
many different speeds depending on the medium through which the waves
propagate.
[NOTE: I receive complaints insisting that the speed of light is always
the same, and that glass slows the light waves by atomic absorption and
emission. Yet this is a very distorted viewpoint, since it denies the
existence of extremely useful mental models called "transparent medium"
and "EM wave." Also it wrongly teaches us that matter is not matter, but
is really a vacuum. Yet light waves really do travel at various speeds
(traveling slowly within glass,) and optical materials really are not a
vacuum. The atoms of the glass do not absorb waves, they absorb
photons. Our focusing so completely on atom/photon interactions
denies the wave nature of light, pretends that E and M fields don't exist,
and also entirely misses the existence of macroscopic phenomena such as
transparency. It also makes a fundamental mistake: declaring one physics
model to be "real," then pretending that this can make other useful models
UNreal. But all physics models are merely mental abstractions, they are
tools. The photon concept does not eliminate the fields/waves concept.
The worshippers of screwdrivers think that hammers are a sort of "inferior
screwdriver," and should be abolished? Silly, because hammers really
aren't screwdrivers, and screwdrivers are genuinely worthless for certain
tasks.
ELECTROMAGNET COILS USE UP ENERGY TO MAKE MAGNETISM? Not right.
Sustaining a magnetic field requires no energy. Coils only require energy
to initially create a magnetic field. They also require energy to defeat
electrical friction (resistance); to keep the charges from slowing down as
they flow in wires. But if the resistance is removed, the magnetic field
can exist continuously without any energy input. If electrically
frictionless superconductive wire is used, a coil can be momentarily
connected to an energy supply to create the field. Afterwards the power
supply can be removed and both the current and the magnetic field will
continue forever without further energy input.
VOLTAGE
See: What Is Voltage
ELECTRIC CHARGES ONLY FLOW ON THE SURFACES OF WIRES? Wrong.
During a Direct Current in a simple circuit, the flow of charges takes
place throughout the whole wire. The flow is not just on the surface.
If the level of current is very high, then the wire will become hot, and
the current will heat up the inside of the wire as well as its surface.
Thin hollow pipes make poor conductors; their electrical resistance is too
high. To avoid overheating the metal we should use thick solid bars
instead.
There is a persistent 'rumor' that the path for flowing charges is
entirely on the surface of metals. This mistaken idea probably comes about
through a
misunderstanding of the nature of electric charge. After all, when some
electric charge is deposited onto a metal object, it distributes itself
over the surface of the object. It makes sense that, since charge is only
on the surface of metals, a flow of charge must take place only on the
surface of metals, right? Wrong. Unfortunately, the word "charge" refers
to two different things. When electric charge is placed on a metal
object, the
added charge is just a drop in the bucket compared to the amount of
charge already in the neutral metal. "Uncharged" wires contain
an enormous amount
of movable charge inside, even though they may be "neutral" and so have
zero charge on average.
Are you confused yet?
All metals contain enormous amounts of free, movable electrons. During an
electric current it's these electrons which flow along. However, each
electron is near a proton, and so the metal is said to be "uncharged."
In a wire, electric current is a flow of this "uncharged" charge. Weird
but true. Now if we were to place extra charge upon a wire, that
would be like pouring a teacup into the ocean. The "water level" would
rise a tiny bit. The currents inside the "ocean" would be unaffected.
Yet extra charges on a wire also create a very noticeable electrical
imbalance (they attract lint, deflect electroscopes, make sparks, etc.)
It isn't so strange that we might accidentally assume that the
extra surface charges are the metal's only charges. Yet in
reality, electric currents happen in the "ocean" of the wire, and the
extra "teacup" of unbalanced charge on the surface has little effect on
the overall charge-flow. The charge-flow (current) is not just on the
surface, and during electric current, the whole "ocean" flows.
A second source of misunderstandings: during high frequency AC, the value
of electric current in a conductor is higher at the surface than it is
within the bulk of the metal. This is called the "skin effect." It is not
very important for thin household wires at 60Hz. Perhaps some people
heard about the Skin Effect but did not realize that it only works for
very thick wires or for high frequency AC. At extremely high frequencies,
only the charges in a thin "skin" on the surface of large wires are the
charges which move. For circuits involving high-current and
high-frequency such as radio transmitters, it makes sense to use copper
pipes as conductors. All the charge-flow is on the surface of the
conductors, so use inexpensive hollow conductors. All the heating takes
place on the surface, and not deep within the metal. But note well that
the thin "skin" of current is a *different* thing than the thin "skin" of
excess charge-imbalance found on an electrified wire.
ELECTRIC CHARGES ARE INVISIBLE? No.
Electric charges are easily visible to human eyes, even though their
motion is not. "Electricity" is not invisible! Never has been. When you
look at a metal wire, you can see the charges of electricity which would
flow during electric currents. They are silvery/metallic in color. They
give metals their mirrorlike shine. Some metals have other colors as well,
brass and copper for instance. Yet in all cases, the "metallic"-looking
stuff is the metal's electrons. A dense crowd of electrons looks silvery;
"electric fluid" is a silver liquid. And if metals weren't full of
movable electrons, they wouldn't look metallic.
During electric currents in metals, the atoms stay still, but the silvery
electron-stuff flows slowly along. Unfortunately the human eye cannot see
the electric flow. That's part of the reason that "electricity" is so
mysterious. Think about it... in an aquarium full of water, you cannot
see any water flowing unless there are bubbles or dirt being carried
along. And whenever clean water is flowing through a transparent hose,
you can't see any flow. Even if the water is flowing very fast, the
water-filled hose just looks like an unmoving glass rod. Same with wires:
there's no bubbles or dirt being carried along by the electric current,
therefore you can't see anything moving. You can see the stuff
that flows, just as you can see the water in an aquarium, but you can't
see any flowing stuff.
Even if human eyes could see single electrons, we still couldn't see an
electrical flow since the current is extremely slow. Electrons in metals
typically flow at a few centimeters per hour, even during high currents.
That's slower than the minute hand on a clock! Electric currents
ooze along like silly-putty flowing across a tilted board.
------
SEEING IMBALANCES OF CHARGE
Here's a somewhat-separate topic. While the metallic-looking sea of
charges in a metal is easily seen, imbalances of charge remain
invisible. This gets confusing, since many authors call imbalances of
charge by the name "charge." They will tell you that charge is invisible,
yet they really mean that net-charges or charge-imbalances are invisible.
Wires contain enormous amounts of movable negative charge in the form of
electrons, but they also contain positive charge in the form of protons
within the metal atoms. If the number of protons and electrons are equal,
don't they cancel out? Doesn't that mean that no charge exists? No. It
means that no imbalance of charge exists. It means that, while the
wire is full of mobile charge, the net-charge remains zero.
An "uncharged" wire is still full of charge, it still contains positive
and negative charge in huge but equal quantities. The word "uncharged"
doesn't mean "without charge," instead it means "without
charge-imbalance." Yet even if there are more electrons than protons, or
fewer electrons than protons, this imbalance is invisible. It's invisible
because the greatest difference attainable is yet incredibly tiny when
compared to the amount of charge that's already there. If an object is
highly charged; even charged up to millions of volts, the extra charge is
like a teacup poured into an ocean. Fractions of micro-coulombs. The
difference is far too small to be seen.
To get some visual/intuitive insight on this, go play with
Red and Green Electricity, colored plastic sheets representing the
populations of mobile
charges within conductors. Red laid on green gives black, no color. Yet
the green can still move relative to the red, even though the green has
been cancelled out. In general, electric currents are flows of this
"uncharged charge."
ATOMS HAVE EQUAL NUMBERS OF ELECTRONS AND PROTONS? Not in
conductors!
Many students misunderstand how electric circuits work. One reason for
this is
that they think the electrons in a metal are trapped on individual metal
atoms. They also think that an applied voltage is needed to "free" the
electrons and to change metal into a conductor. They aren't aware that
the "sea" of free electrons always exists inside metal all the time. I
suspect that
this is part of a more general misconception that all atoms in a material
are always neutral. This is wrong because all conductors contain
charged, movable particles. The very definition of "conductor" is "a
material which contains mobile charges." If all atoms were truly neutral,
then conductors could not exist.
For example, a metal is made of positively charged atoms immersed in a
sea of loose electrons. Apply a voltage to a metal, and its electrons
begin flowing. Salt water is full of positive and negative ions. In our
world a neutral sodium or chlorine atom is a very rare thing. Sodium
atoms
lack their
outer electron and as a result have one too many protons, while chlorine
usually has one extra electron: it's a negative ion. Glowing gases
(fluorescent lights, neon signs, sparks) are full of movable electrons and
movable positive ions. Metals, electrolytes, and plasmas; these three are
the most common electrical conductors, and
they owe their conductivity to the presence of non-neutral atoms, to
movable charged particles which occur naturally.
A "CONDUCTOR" IS A MATERIAL WHICH ALLOWS CHARGE TO PASS THROUGH
IT? Not exactly.
The scientist's definition of the word "conductor" is different than the
one above, and the one above has problems. For example, a vacuum offers
no barrier to flows of electric charges. If conductors allow charges to
pass, then a vacuum should be a perfect conductor. Yet, vacuum is an
insulator. Vacuum is nothing, so how can it act as a barrier to
electric current? Also, there's a similar problem with electric currents
in air: electric charges placed into the air can easily move along, yet
air is an insulator. Or look at salt water versus oil. Oil is an
insulator, while salt water is a conductor, yet neither liquid is able to
halt the flow of any charges which are placed into it. How can we
straighten out this paradox? Easy: remove the misconception. Instead,
start using the proper definition of the word "conductor."
Incorrect definition:
Conductor - a material which allows charges to pass through itself
Better:
Conductor - a material which can support an electric current
Best:
Conductor - a material which contains movable electric charges
Here's an analogy:
Conductor - like a pipe which is already full of water
Insulator - like an empty pipe: tilt it, and nothing flows downhill
Insulator - like a pipe with frozen liquid; a pipe plugged by ice
If we place a Potential Difference across either air or a vacuum, no
electric current appears. Air and vacuum are insulators. This is
sensible, since there are zero (or very few )movable charges in air or
vacuum, so any voltage placed across them is unable to cause an electric
current. Or instead, if we place a voltage across a piece of metal or
across a puddle of salt water, the charges present in those materials will
flow, and an electric current will appear, since these substances are
always full of movable charges, and therefore the "voltage pressure"
causes their charges to flow. In metal, the outer electrons of the atoms
are not bound upon individual atoms but instead can move through the
material, and a voltage can drive these "liquid" electrons along. But if
we stick our wires into oil, there will be no electric current, since oil
does not contain movable charges.
If we were to inject charges into a vacuum, then we would have
electric current in a vacuum. This is how TV picture tubes and vacuum
tubes work; electrons are forcibly injected into the empty space by a hot
filament. However, think about it for a second: it's no longer a vacuum
when it contains a cloud of electrons! <grin> Maybe we should
change
their name to "electron-cloud tubes" rather than "vacuum tubes", since the
electron cloud is required before there can be any conductivity in the
vacuum between the plates. (But vacuum tubes already have another name,
so this would just confuse things. They are called "hollow-state
devices." As opposed to "solid state devices?" Nyuk nyuk.)
HUMID AIR IS CONDUCTIVE? Mistake.
Electrostatic experiments don't work very well under humid conditions.
Some books state that the water vapor in the air makes the air conductive.
Wrong.
In reality the problem is caused by the liquid water that becomes adsorbed
on surfaces of objects.
In order to make the air conductive, we'd have to fill it with movable
charged particles. Evaporated water is not made of charged particles
(ions,) instead it's made of neutral molecules, so the high humidity does
not significantly affect the conductivity of the air. Even suspended
water droplets (fog) does not significantly affect conductivity. For fog
to be conductive, the individual droplets would have to possess an
electric charge.
However, during humid conditions most insulators develop a surface layer
of conductive water mixed with contaminants (including dissolved salts
which makes this layer of water conductive.) If you find that you can't
separate any charges by rubbing a balloon on your head, it's because the
humid air has made the balloon and the hair very slightly damp. The air
remains nonconductive, but surfaces of insulators become conductive when
damp. Conductive surfaces don't separate any opposite charges when rubbed
together. Cure this by warming them (drying them) with a blow-dryer. If a
pair of insulators is sufficiently dry, it will "generate charge" even
under very humid conditions. If conductive air were the culprit, this
cure couldn't work.
8. LIGHTNING RODS DISCHARGE THE CLOUDS? Mistake.
UNDER CONSTRUCTION
Make a model "landscape", install some lightning rods on the tiny houses,
then bring a "storm cloud" nearby: bring the metal sphere of a
VandeGraaff Electrostatic generator over your small town. The strong
electric charge on the sphere will vanish. Doesn't this prove that
lightning rods can discharge a thunderstorm? Nope.
The above demonstration was thought at one time to be accurate, and this
old mistake still appears in many books. In reality, lightning rods
cannot
remove the charge-imbalance from a thunderstorm. The scale of the typical
demo is wrong. The stormcloud is a few miles up, and a few miles across,
yet lightning rods on houses are microscopic: only a few feet tall.
Therefore in our model the
metal-sphere "cloud" should be fairly large, and "Rods" should be far less
than 1mm tall and attached to a wide metal ground plate. They
aren't like wires. They're more like felt-fuzz.
The typical demonstration doesn't illustrate a lightning rod, it
illustrates a kilometers-tall radio tower or extremely tall office
building.
Think about it: how can a tiny needle affect cubic kilometers of strong
e-field? How could the relatively tiny current from a metal rod discharge
a cloud that's over 1KM away. It can't! To do so, it would have to emit
a hurricane wind made of ionized air. Unfortunately the lightning rod on
your roof only emits about the same current as the needle in the model
town: it emits a few microamperes. In other words, the scale model is not
correct because the current coming from a *real* lightning rod is way too
low. In order to be at the proper scale, the current in the model rod
would have to be hundreds of thousands of times smaller; too small to
have any effect upon the VDG machine's charge.
"ELECTRICITY IS WEIGHTLESS? Nope.
If by 'electricity' we mean the electrons, then 'electricity' is not
weightless. Take a copper wire for example. Each atom weights about
115,000 times larger than the weight of an electron.
If each atom supplies one electron to the "electric fluid" sea, then that
sea is very light, but it is not weightless. The flowing "electricity"
weighs about a hundred thousand times less than the copper metal. It's
like a low pressure gas rather than like a liquid (but never forget that
a gas is still matter!) One KG
of copper would contain about ten milligrams of the movable
electron-stuff which can flow as an electric current.
THE "TWO FLUIDS" THEORY WAS DISPROVED? Not exactly.
In the early days of electrical science, researchers were sure that there
were two kinds of electricity: "vitreous electricity" and "resinous
electricity," which were later named positive and negative electricity.
Scientists imagined that these represented two kinds of "electric fluid"
which were somehow created by rubbing various materials together. Ben
Franklin proposed a different concept: he imagined that there was only one
kind of electric fluid, positive electricity, and believed that "negative
electricity" was simply a lack of electric fluid.
Some scientists objected to Franklin's idea. They rightly pointed out
that, if Franklin were correct, then matter itself must be made up of
negative electricity, otherwise a rubber rod wouldn't become negative when
Franklin's electric fluid was removed from it. They noticed that Franklin
was not proposing a single kind of electric stuff. Instead Franklin was
saying that two opposite kinds of electricity exist, but only one of them
is a movable "fluid." The other kind would be solidly connected to
the material of an object.
In hindsight we can see that Franklin was wrong. During electric currents
in batteries, in salt water, or in human flesh, the electric
current is a
flow of both positive and negative ions moving in opposite directions.
Two flows of "electricity" take place in the same conductor. In
your brain and nervous system, electric current is a flow of positive and
negative atoms going in opposite directions. During electric currents in
neon signs, in sparks,
lightning, etc., there is a flow of both positive ions and electrons. The
same is true for liquid metals. And when two materials are rubbed
together, sometimes positive or negative ions are transferred, and
sometimes electrons are transferred. In Franklin's language, two electric
fluids do indeed exist, and Franklin's "one fluid" theory is wrong.
Franklin was somewhat correct about two things. He was right about
electric current
in solid (non-liquid) metals. During electric currents in wires, it's the
negative
"electric fluid" which flows along, while the positive stuff behaves as an
"electric solid" and cannot flow. But melt the metal and this frees up
the positive atoms so that they can flow too. Also, Franklin was
right in
suspecting that, in some situations, "positive electricity" and "negative
electricity" differ greatly in mass. Protons are about 1800 times heavier
than electrons, and positive ions heavier still. But when electric
current is a flow of ions alone, the negative and positive ions can be
very similar in mass, or the negative ions can even be far heavier
than the positive.
The complexity of electric charge was far greater than Franklin and his
contemporaries knew. Franklin was right about metals, but he was wrong
about conductivity in general. Modern science recognizes that positive
particles can flow, and recognizes the existence of both positrons and
electrons, therefore it rejects Franklin's "one fluid" theory of
electricity.
ELECTRIC ENERGY TRAVELS INSIDE OF WIRES? Wrong.
When an electric company's distant generator lights up your lamps, the
electric energy travels along the power lines at almost the speed of
light. Most K-12 textbooks teach that the energy is trapped inside of
electrons, and these electrons flow inside the wires. Doesn't this mean
that electrical energy flows INSIDE the metal wires? Nope, since
electrical energy is not trapped inside electrons. Instead the energy is
made of invisible magnetic fields and electric fields which surround the
electrons, and these fields surround the wires. Electrons don't flow fast
like the energy does, instead they ooze along slowly to produce an
electric current. But
how can electrons flow slowly if the energy flows
fast? It's because the energy can leap from electron to electron.
Indeed, the energy is connected to a whole vast population of electrons in
the wire, and it isn't attached to any single one.
Is this confusing? Here's another way to see it. During an electric
current, the wires become surrounded with magnetic field. This field IS
the electrical energy. Also, whenever a pair of wires is connected to a
battery or generator, the two wires become oppositely charged, and they
become surrounded with an invisible electrostatic field. This field IS
the electrical energy. Magnetic and electric fields exist in the empty
space surrounding your lamp cord, and these fields contain the "wattage",
they contain the flow of electrical energy that powers the light bulb.
Electric and magnetic fields together are "Electromagnetism," the same
kind of energy as radio waves and light. Those "EMFs" that people worry
about; the invisible "EMFs" that surround wires and exist invisibly in our
homes... that's the electromagnetic energy which lights our lights and
runs our appliances. It certainly makes sense that it travels at the same
speed as radio waves and light, since it's made of the exact same "stuff."
So, what would electrical energy look like if we could see it? Here are
some simple
drawings I made. Whenever you plug in a light bulb, the energy that
flows along the lamp cord is like a fuzzy sausage a couple of inches
thick. It follows the two wires of the cord, then it dives into the thin
filament of the light bulb. Is this a very strange description of
"electricity?" Yes and no. It's the same description taught to advanced
engineers in their courses on waveguides and radio physics. It's also
taught to university physics students, especially if they read chapter 27
of The Feynman Lectures. But it's not so terribly advanced, instead it's
just unfamiliar, because so few people know about it or discuss it.
STORM CLOUDS ARE ELECTRIFIED BY FRICTION? No.
Some books claim that the separated charges in thunderstorms come about
because the clouds rub against each other, or because the falling rain
rubs against the air. This is not correct. In fact, the true explanation
for storm electrification is unknown. There are several possible
explanations, but none of them has yet been accepted by scientists, and
all the theories have problems. Here's one current theory:
In a mixture of rain and half-melted hail, the ice and water
become oppositely electrified through contact. The large hail then falls
faster than the small raindrops and spray. Two large regions appear in
the cloud, a lower one that's made of hail, and an upper one that's made
of rain. These regions contain opposite imbalances of electric charge.
So, what caused the clouds to become
electrified? Contact between dissimilar materials, followed by
wide separation of those materials.
BEN FRANKLIN'S KITE WAS STRUCK BY LIGHTNING? Never
happened!
Many people believe that Ben Franklin's kite was hit by a lightning bolt,
and think that this was
how he proved that lightning was electrical. A number of books and even
some encyclopedias say the same thing. They are wrong. When lightning
strikes a kite, the spreading electric currents in the ground can kill
anyone standing nearby, to say nothing of the person holding the string!
So what did Franklin actually do? He showed that a kite would collect a
tiny bit of electric charge out of the sky during a thunderstorm.
Electric leakage through the air caused his kite and string to become
electrified and so
the hairs on the twine stood outwards. Twine is slightly conductive, so
the imbalanced charge spread to all parts of the kite string. Franklin used
the twine to electrify a metal key, and tiny sparks could then be drawn from
the key. (He used a
metal object because sparks cannot be directly drawn from the twine, it's
not conductive enough.) This suggested that some stormclouds carry strong
electrical net-charge. It implied that lightning was just a large
electric spark.
The common belief that Franklin easily survived a
lightning strike is not just wrong, it is dangerous: it may convince kids
that it's OK to duplicate the kite experiment as long as they "protect"
themselves by holding a silk ribbon. Make no mistake, Franklin's
experiment was extremely dangerous, and if lightning had actually hit his
kite, he certainly would have been killed.
ELECTRICITY IS MADE OF ELECTRONS? Wrong.
Other things flow besides electrons. It's true that electric
current in metals is a flow of electrons. But there are many other
conductors besides metals, and in many of them the currents are not caused
by moving electrons. Electric currents can also appear in electrolytes
or in
plasma. During electric shocks, no electrons flowed through your
skin or body!
When an electric current creates the glowing plasma within a neon
sign or electric spark, electrons flow in one direction, while positively
charged
atoms flow in the other. Yes, there is an electron flow in the
glowing gas, but part of the total electric current is also made of moving
positive atoms which flow the other way. (And if the discharge was
in hydrogen gas, the positive current is a proton-flow.)
Also there can be electric currents where no electrons flow at all. The
currents in electrolytes (examples: batteries, dirt, and human flesh) are
entirely composed of flows of ions: electrified atoms. In acids, half the
flowing ions are +H ions, also called "protons." Bare electrons
can't exist in battery electrolytes or within salt water. In
electrolytes, half of the charged atoms have more
protons than electrons, and the other half has more electrons than
protons. During a current, the opposite-charged atoms move in opposite
directions. For example, when an electric current is passing through the
inside of a a battery, it is not made of moving electrons, it is made of
moving electrolyte atoms (ions), and each atom carries a charge imbalance.
The positive atoms flow one way, and the negative atoms flow the
other. Specifically in battery acid, the major portion of the
current is a flow of protons. (Students often miss this basic fact,
since in chemistry classrooms, moving protons are called "+H positive
hydrogen ions.)
The same effect happens when an electric current passes through the
damp earth,
or through the ocean, or through your body. All these are non-electron
currents. If you receive an electric shock,
no electrons flowed inside you. These electric currents are flows of
atoms. All the electric currents in your brain and nerves are composed of
moving chloride, sodium and potassium atoms. No electrons. (LOTS MORE)
See also:
