Hi everyone!
I'm going to show you in great detail how
a Van de Graaff generator works,
right down to the level of what the protons
and electrons are doing.
Those of you who already know all about electrons,
protons, positive and negative charges,
you can skip ahead to around 1 minute and
35 seconds in.
For everyone else, here's a quick introduction
to those things.
There are three things to keep in mind as
I explain how Van de Graaff generators work.
First, all matter is made up of atoms.
I'll use the simplest model for an atom since
it suits our needs just fine.
In the middle of each atom are protons and
neutrons
and spining around them are electrons.
The protons stay in the atom but sometimes
the electrons are free to move away.
Second, the protons are positively charged
and the electrons are negatively charged.
The neutrons are not charged at all so we'll
ignore them.
What does charge mean?
Charge is simply a way of saying how the electrons
and protons will behave.
Things that have the same charge will repel
each other.
So two negatively charged electrons will repel
each other,
as will two positively charged protons.
And things that have opposite charges will
attract each other.
So a negatively charged electron will attract
a positively charged proton.
And third, the objects made up of these charged
particles can also be positively or negatively
charged.
if something has more electrons than protons
we say it's negatively charged.
Notice that the protons are still there,
just that there are extra electrons that aren't
paired up with any protons.
Alternatively if something has more protons
than electrons we say it's positively charged.
There are extra protons that aren't paired
up with any electrons.
And if we don't care whether a charged object
is negatively charged or positively charged
we just say that it's charged.
Here are the parts of a Van de Graaff generator.
At the bottom in the back we have a motor
here,
which turns this roller.
That roller turns this belt,
which turns this other roller at the top.
Also at the bottom we have this metal brush.
In this particular Van de Graaff generator
that metal brush is connected to the metal
case,
and that metal case is connected to this ground
wire,
which is a part of the power cord.
So that ultimately goes to Earth ground.
That's not the case in all Van de Graaff generators
though.
In this small one right here,
that bottom brush is connected to this metal
dome right here.
And in some Van de Graaff generators the motor
has a metal case,
and the brush is connected to the metal case.
At the top is another brush,
and in this Van de Graaff generator that's
connected to this metal strip.
I'll just put on the top dome.
And you can see that that metal strip makes
contact with the inside of the top dome.
A Van de Graaff generator is a charge pump.
It literally pumps charge from one end to
the other.
One end is a dome or partial sphere of some
kind, usually on top.
The other end can be a connection to Earth
ground as with this one,
or another dome as in the small Van de Graaff
generator I showed you,
or the metal case of the motor.
What's facinating about Van de Graaff generators
is that
there are so many interesting things
going on in them.
Luckily, those things can be broken down into
just a few steps.
So let's start the explanation of how it works
with the first of those steps.
The purpose of this first step is to charge
the bottom roller.
When the motor is on, the roller turns and
that turns the belt.
Depending on the materials, this causes the
roller to
become either negatively charged or positively
charged.
As the roller turns the inner surface of the
belt
makes contact with the roller here and breaks
contact here.
If you have two different materials like these
making and breaking contact
then they become charged.
Electrons move from one to the other.
This is called the triboelectric effect and
I have a video that goes
into great detail about it.
Because this roller is teflon and this belt
is rubber,
due to the triboelectric effect,
electrons on the belt will move to the roller.
This means the roller will become negatively
charged
and the belt will become positively charged.
We now have what we need for the next step,
a charged roller,
and in this case one that's negatively charged.
In this second step we'll charge the outer
surface of the belt.
That's the charge that we'll be moving up
to the dome on top.
The roller, the belt, this bottom brush and
whatever the brush is connected to,
in this case Earth ground, work together to
do this.
Since this roller is negatively charged due
to all the extra electrons,
it'll be electrons that'll be repelled from
the belt to the brush,
leaving the outer surface of the belt positively
charged.
How will the electrons make their way to the
brush?
After all, they have to cross through the
air
and air is not normally a good conductor of
electricity.
Well, the how is a little complicated so let's
take it one step at a time.
The negative charge on the roller will repel
some electrons
from the sharp points of the brush.
That leaves the sharp points on the brush
positively charged.
That creates a strong attraction between
the abundent negatively charged electrons
on the roller
and the positively charged protons on the
brush.
Because there is this area between the electrons
and protons
where there is this attractive force,
we say that there's an electric field between
them.
We can visualize the electric field
by drawing a line from each extra electron
on the roller
to each extra proton on the brush.
Since the ends of the brush are very sharp,
the protons are tightly packed in there
and so the lines end up being close together.
If we put an atom in the strong field, like
this,
then electrons from that atom may be pulled
away from it
leaving the atom positively charged, what
we call an ion.
In fact so much of this stripping off of electrons
goes on
that we end up with what's called corona discharge
and if you turn out the light you may be able
to see it as a purplish glow.
These positive ions are attracted by the negatively
charged roller.
On the way they collide with other atoms and
produce more ions.
Eventually some of these positive ions arrive
in the area of the roller.
But the belt is in the way of the roller
and so it's the electrons from the outer surface
of the belt
that get pulled to these positive ions.
That leaves an area of the belt positively
charged.
The belt is then rotated by the roller,
moving the positively charged area along
on it's way to the top of the Van de Graaff
generator.
The result is that electrons are transferred
to Earth ground
while the outer surface for the belt becomes
positively charged.
And that's the end of step 2.
One more thing to mention before we go on
to step 3.
It was important that the ends of the brush
be sharp points.
Look at the electric field lines if a smooth
surface was used instead.
Each electron on the roller would repel an
electron from the surface of the brush
and the remaining unpaired protons would be
spread out more.
The electric field lines would be less dense
which just means the electric field would
be weaker.
Electrons wouldn't be pulled from air molecules,
so no positive ions would be produced and
there would be
no positive ions ending up at the belt to
strip electrons from it.
It wouldn't work very well at all.
Recall that inside the dome at the top here,
there's another roller interacting with the
belt.
In most home use or school lab Van de Graaff
generators
this roller is either metal like this one,
something that's triboelectrically different
than the belt,
or something that neutral triboelectrically
with respect to the belt.
Before talking about my metal one,
let's talk above the triboelectric ones.
Remember that we charged the bottom roller
by using the triboelectric effect.
We can do the same with the top roller but
we want the opposite charge.
To do that we look at the triboelectric series
table.
This belt is rubber, which is in the middle
of the table.
The bottom roller is teflon which is at the
negative end of the table,
meaning it gets charged negatively.
So we would want something that's at the positive
end of the table,
as far away from rubber as we can afford so
that it'll be charged a lot.
As an example,
many small Van de Graaff generators use glass
by using the glass from a fuse or a small
bulb.
What would be the effect of using a glass
roller on top?
Due to the triboelectric effect,
when it breaks contact here the belt will
take electrons from the roller
making the roller positively charged.
What about the belt at that point?
On the way up, and while it moves over the
top of the roller,
the inner surface of the belt is positively
charged.
With the addition of these electrons now it
either
has the same number of electrons as protons
or has more and is negatively charged.
What about a roller that's made of material
that's triboelectrically close in the table
to the belt's material,
rubber in this case?
In that case we can ignore the charging of
the roller.
And that brings us back to this particular
roller, which is metal.
As this positively charged belt moves up
it pulls electrons from the metal,
not due to the triboelectric effect though.
It does so because metal is electrically conductive
and gives up those electrons pretty freely
as the positive charges on the belt attract
them.
That means that on the way back down,
as with the triboelectrically charged top
roller we just talked about,
the inner surface of the belt
either has the same number of electrons as
protons
or has more and is negatively charged.
This is ideal because the bottom roller wants
those electrons!
So together the two rollers, with the help
of the belt,
reinforce each other's charging.
Keep in mind that we've been talking about
the roller's interaction
with the inner surface of the belt.
Up to this brush, the outer surface is still
positive.
We've talked a bit about the top roller and
the belt,
now let's see how the top brush is involved.
Step 4 is to use the now charged outer surface
of the belt
to move charge between the belt and the top
brush.
A similar thing to what happened at the bottom
in step 2 will also happen here.
We again have an air gap with non-conductive
air
that needs to be made conductive.
Due to the charged belt, the sharp points
on the brush,
and possibly a built up charge on the roller,
there's a strong electric field,
ie. strong repulsive and attractive forces.
This field either transfers electrons from
the brush to the belt
or from the belt to the brush.
With this Van de Graaff generator the belt
and roller are both positively charged
so this time electrons will be repelled from
the brush
and attracted to the belt.
The strong electric field pulls electrons
from the sharp ends of the brush
and forces them onto uncharged atoms
turning the atoms into ions.
But unlike in the bottom where our ions were
missing an electron,
these have an extra electron.
Instead of positive ions we have negative
ions.
We also still have collisions between ions
and other atoms
resulting in more ions, some of them positive
ions.
But basically, we again have a corona discharge.
But unlike at the bottom of this Van de Graaff
generator
where the brush was positive,
with a negative brush things are more complicated.
After a collision has occurred,
one of the atoms may lose energy by releasing
a photon.
This photon strikes an atom in the brush
and causes it to release an electron.
This is called the photoelectric effect.
It's these additional released electrons that
contribute a lot
to the electrons that eventually reach the
positively charged belt.
Anyhow, once the ions arrive at the positively
charged belt,
the belt takes the extra electrons from the
ions.
This causes the atoms on the outer surface
of the belt
either to no longer be charged
or to be negatively charged.
And this means the half of the belt returning
down to the bottom
is either not charged or negatively charged.
Anyway, that's how charge, in this case in
the form of electrons,
is moved from the brush to the belt.
But where do the electrons come from?
We'll find out in our final step, step 5.
The final step is the charging of the outer
surface of the top dome
due to the Faraday ice pail effect.
In this Van de Graaff generator that charge
will be a positive charge.
The outer surface of the dome will have more
protons than electrons.
This makes sense since in step 4 we were moving
electrons
from the top brush to the belt.
So the answer to step 4's question,
where do the electrons come from, is the outer
surface of the top dome.
When an electron is attracted from the top
brush to the belt,
that leaves a missing electron in that position
on the brush,
meaning that area of the brush is now positively
charged.
This positively charged area attracts an electron
from further along the brush,
now leaving a missing electron further up
the brush and hence,
another positvely charge area.
This causes an electron further along the
brush
to be attracted to replace that one
and so on along the brush until we get to
the dome.
The next question though is
why are electrons ultimately coming from the
outer surface of the dome
and not the inner surface?
That's where the Faraday ice pail effect comes
into play.
One key to the answer lies in that the dome
is
all solid electricallyconductive metal
which allows electrons to flow anywhere attraction
and repulsion causes them to.
Another key is that as long as there is a
repulsion or attraction somewhere
then electrons will move around the metal
until there is no more repulsion or attraction.
Until all forces balance out.
Let's do that again.
We remove an electron, leaving another unpaired
proton.
But this time there's no unpaired electron
around on the inner surface.
So one will be attracted from the inside of
the metal itself
or from the outer surface.
But that may leave a lone, unpaired proton
on the outer surface!
That's okay because there are plenty of unpaired
electrons in the air
in the room outside the dome, in the walls
of the room,
or in the nearby trees if you're outdoors.
The big difference between the inner surface
and the outer surface
is that the number of unpaired electrons and
protons
that can attract inside the dome
is very limited and quickly runs out.
This leaves the only way to interact with
new ones
by going through the metal dome.
But for the unpaired electrons and protons
on the outer surface
there's a whole wide world of other unpaired
things to be attracted to.
And so the outer surface will be charged
and the inner surface will not be charged.
But that all helps to understand another,
simpler, explanation
for why the outer surface is charged.
Remember that like charges repel each other;
negative charges repel negative charges
and positive charges repel positive charges.
So when we pump electrons up to the dome,
once they get there they'll try to get
as far away from each other as they can.
And the farthest they can go is to the outside
of the dome.
But this Van de Graaff generator is pumping
electrons away from the dome,
leaving unpaired protons.
The problem is,
protons can't leave the atom and wander around
like some electrons can.
So they may want to repel each other
but since they can't go very far how do they
spread out?
The answer is, they don't.
As we pull electrons from the dome,
the remaining "electrons" spread out.
Notice that there are still more protons than
electrons,
but because the electrons spread out,
that also leaves the extra protons spread
out too.
There's still another question though.
We've built up this huge positive charge on
the dome's outer surface.
Meanwhile we have this relatively small positive
charge
on the belt and the brush
that's trying to attract electrons away from
the dome.
It looks like we have an uneven tug of war.
Wouldn't the positive charge on the dome
win
and the electrons not be attracted away?
Well since it works, the answer is obviously
no, but why?
Remember, we're taking those electrons through
the inner surface of the dome.
And the inner surface is not charged.
So from the perspective of the belt and brush,
they're attracting electrons from an uncharged
object.
If we had instead connected the brush directly
to the outer surface of the dome
then the belt and bush would lose the tug
of war
and the Van de Graaff generator wouldn't be
able to build up a huge charge like it does.
And lastly, since there's a whole world for
the dome's charges to attract to,
does that mean we can keep building up charge
forever?
Well, not quite.
The outer surface is rounded, not sharp like
the top and bottom brushes.
But just like with the brushes,
all those unpaired protons on the dome form
an electric field
with things in the surrounding room.
If you keep pumping charge,
eventually you'll pack in so much charge
that the electric field will become very strong
and once again we'll have corona discharge.
In fact if the other object is also not very
sharp
then electrons will pile up on one side
until the air becomes conductive enough
that it breaks down as an insulator altogether
and we get a sudden rush of electrons moving
through it.
That's why the rounder the dome,
and bigger ones are less round than smaller
ones,
the weaker the electric field between it and
surrounding objects
so the less corona we'll have.
The higher voltage it can produce.
And now you know in great detail
how a Van de Graaff generator pumps charge
from one end to the other
and also a bit about the triboelectric effect,
corona discharge, the photoelectric effect,
the Faraday ice pail and more.
Well thanks for watching!
Be sure to check out my youtube channel, rimstarorg,
for more related science and tech videos,
especially in the science and tech playlist.
Click to watch the triboelectric effect video,
or my video on how to make a small Van de
Graaff generator,
one on exploring magnetic fields, and many
others.
I'd like to give a special thanks to 1011basic
for doing some proofing on the second version
of this video.
Be sure to check out his channel.
And be sure to subscribe if you like these
videos,
or give a thumbs up or leave comments or questions
below.
See you soon!
