Hello Ding-a-lings.
My name is Michale Stevens and you are here
just in time for another episode of Michael’s
Toys.
Have you ever spun a penny?
It’s amazing.
Watch this.
As the penny comes to a stop it’s wobble
will become more and more vigorous.
That’s what you’re hearing but its spin
will decrease.
Watch how Abraham Lincoln spins slower and
slower and slower.
Of course a penny will not spin forever here
in the real world because air resistance,
friction, vibration, all those kinds of things
rob it of energy and it eventually runs out
and lays flat right down there on the table.
But how long can a coin spin for?
Well, in 1990 Joseph Bendik invented Euler’s
disk.
It’s a spinning course.
Of course the coin in this case is a very
large and heavy steel disk.
There are no batteries here.
There’s no magnets.
Nothing like that.
It’s just a piece of metal spinning on a
mirror but the design is pretty much a trade
secret but watch how well this spins.
Your ready?
Here we go.
Euler’s disk.
Quite phenomenal.
The
disk spins because that’s what I made it
do at first but then it begins precessing
because of gravity.
Precession is a change in the orientation
of an object’s rotational access.
As far Euler’s disk goes, precession works
like this.
When I first spin the disk, it spins around
a vertical access that runs through this,
whoa!
We’re not ready for the tilting yet.
It spins around an access like this right?
But unless I spin it perfectly such that it
never tilts, it will eventually tilt and then
gravity will do it work and gravity causes
that access of rotation to precess like this
so we’ve got a disk spinning this way and
then all of a sudden its rotation begins pointing
all around in a circle.
Ahh yeah, I’m actually getting pretty good
at doing precession with just my hands.
A little precession puppeteering, you’re
welcome.
Now the reason Euler’s disk spins for so
long is that its spin’s specifically designed
to lose energy as slowly as possible.
Now we don’t know exactly how the inventor
did this because like I said, it’s kept
as a trade secret.
Only one company sells this toy but you can
tell that the mass of the disk matters.
If it was lighter it wouldn’t have as much
inertia and air resistance and friction, that
kind of stuff would take more of its motion
away more quickly.
But if it was too heavy.
If it was heavier than this it might have
more of an issue with greater friction and
deformation of the base of itself because
of its weight and that would rob energy from
it.
It also has this interesting curve on one
side and that’s the side that you want it
to roll along.
The way that curve works as opposed to the
sharp corner on the other side must help the
disk lose less energy as its angle to the
table changes.
The final result is phenomenal.
In many ways Euler’s disk operates like
a gyroscope.
It’s why it precesses and it’s why it
doesn’t just flop over like that.
So let’s take a look at a gyroscope but
first let’s talk about precession.
What is it?
Well, it we imagine that this baseball is
a satellite orbiting around the Earth and
that the satellite’s orbit is somewhat like
this, sort of around the ecliptic, perfect.
Now what happens if, while it’s orbiting
in this horizontal plane I come in and I push
it down?
I apply a force, a quick little impulse, boom,
right there, to the satellite.
What will happen?
Will it get hit by the force and go straight
down?
No.
The acceleration induced by my impulse will
just combine with the velocity the ball already
has in the horizontal plane.
So we have this kind of motion.
The motion from my force going down and we’ll
wind up with a combination, a sort of diagonal
motion.
That means that the ball will when struck,
let me use this hand, the ball when struck,
BOOM!
Will start orbiting like this and what is
in relation to us sort of a diagonal orbit.
Now this is really really interesting because
it means that the effect of my force which
is pushing down is not felt within the line
of that force but instead is seen 90 degrees
ahead in the original rotation.
Take a look at my favorite demonstration of
this happening.
I just love to play with this as like a fidget
toy.
Little disk of cardboard and a pencil.
If the disk is not spinning and I blow here
on this side that’s near me it tilts down.
The part that I blow on is pushed down.
It’s pretty obvious especially if you’ve
seen my episode on spinning in which I literally
do this same demonstration but watch what
happens when I get the disk rotating and I
do the same thing.
I blow on the back.
It tilts to the right.
Keep in mind that the disk is spinning when
looked at from above clockwise.
And just like what I was saying with the orbiting
satellite, the effect of my force, my air
blowing down on the disk here is seen 90 degrees
ahead in the rotation so instead of the disk
going down here it goes down 90 degrees ahead.
That’s because the acceleration from my
breath combines with the velocity all the
mass of the disk already has.
If I blow here, tilts to the right.
If I spin the disk counterclockwise it should
tilt to the left.
Pretty awesome right?
So this is where gyroscopic stability and
precession come from.
Now watch what happens if I always blow on
the side of the disk that is down.
The lowest part of the disk.
It precesses.
Its access of rotation moves around.
This is exactly what happens in a gyroscope.
Of course its not breath moving around.
It’s just gravity constantly putting a torque
on the object according to how it’s oriented.
Let me show you what I mean.
Here’s a gyroscope which consists of just
a spinning disk on an axel surrounded by a
cage so that it can be held and manipulated
and the effects of rotation can be felt.
If the disk is not rotating and you balance
it on its axel it falls off.
But if the disk is spinning you’re going
to see the same behavior you saw form this
cardboard disk.
It’ll balance but because no one’s perfect
there will always be just a tiny amount of
skewness that causes a torque from gravity.
Gravity operates from the center of gravity
of this top which is well let’s just assume
it’s pretty much right there in the middle
but the base is exerting a normal force like
this.
Those two forces are not in line so we get
a torque right?
Rotation.
Well if gravity starts pushing this way what’s
going to happen?
We know that that effect of gravity will be
seen 90 degrees ahead in the rotation so the
disk is rotation clockwise when seen from
above.
A torque this way will manifest as motion
this way.
90 degrees ahead of the rotation but look
what’s happening now.
Now because the center of gravity is here
and the base is sort of in front of the center
of gravity from my perspective, the torque
is now going to move the gyroscope down this
way if it weren’t spinning but it is so
now gravity’s effect is seen 90 degrees
ahead of the rotateon here.
So the gyroscope tilts that way.
Now the torque operates like this which means
its effect will be seen 90 degrees ahead this
way.
So it’ll tilt like this and all of a sudden
we’ve got ourselves a gyroscope that just
doesn’t fall over.
Instead it precesses.
Alright let’s see this in action.
I’m gonna take a string and poke it through
a hole in the axel of the gyroscope.
This end is a little sharper.
Ow.
Okay perfect.
Now I’m going to turn the gyroscope and
wind the string around that axel.
Perfect.
When I pull the string while holding the cage
not the disk.
The disk will spin up really quickly and it’s
going to be spinning clockwise when seen from
above.
But I think I’m gonna turn it over so that
the notched side which is for balancing on
the string is not the one on the base.
So the disk will be spinning counterclockwise
which means we should see counterclockwise
precession.
Here we go.
I’m holding the cage, pulling the string,
turning the gyroscope over, and tada!
It appears to be defying gravity but in reality
all it’s doing is taking the effect of gravity
and constantly relocating it around in a circle
so gravity never has time to fully topple
the thing over.
But as the disk slows down due to friction
and air resistance and vibration, gravity
torque becomes a larger part of the influence,
the velocity, every piece of mass on that
disk has and the precession becomes greater
and greater.
As you can see the precession is much more
dramatic now and the gyroscope will continue
lowering and the precession will speed up
until the gyroscope is no longer able to stay
up and it falls down to the ground.
It’s pretty dang amazing.
Spinning objects can behave quite unintuitively.
And what is Euler’s disk but a spinning
disk?
Well a few other things.
Euler’s disk has no axel and there’s no
cage to hold it.
So when it precesses instead of moving around
like this balanced on the edge of a spoke
here, it just sticks one of its edges right
down on a surface which means that because
of Euler’s disk’s precession it also rolls.
One of the edges is in contact with the surface
as it precesses.
And there’s a relationship between the speed
of precession, the angle the disk is at, and
how quickly it spins.
That relationship is caused by the fact that
the higher the greater the angle between the
disk and the table, the smaller the circle
is that the disk rolls around due to its precession.
Once the disk is really low like this as it
precesses the edge touching the table traces
out a circle that’s much closer in size
to the circumference of the disk itself.
At the limit when the disk is flat on the
table the edge of the disk touching the table
is touching a circle with the same circumference
but up here it’s really tiny.
You can observe this effect yourself.
I’m gonna use a roll of tape because this
is really nice and easy to see.
If we mark off a line on the circumference
right here, perfect, and then we carefully
roll without slipping the ring of tape around
a circle we can see that if that circle is
a lot smaller than the circumference after
rolling all the way around will still have
some space left if we roll in this direction
across that part of the tape we won’t come
back to the purple line that I’ve drawn
if we started there.
So it will appear as though the ring is spinning.
Watch this.
I’ll start with the line on the ground and
then I’m going to roll not slide but roll
the tape around a little tiny circle.
And look at that.
I’ve completed one precession but where’s
the purple line.
It’s not down there anymore.
Now it's all the way up here.
The disk has spun quite a bit but if the disk’s
angle with the table is really shallow like
that then a rotation takes us around…well
a precession takes us almost all the way around
the circumference and when we get back the
line has only moved a little bit.
The disk has only spun a little bit so that's
why the spinning penny sounds more and more
vigorous.
That’s because the precessions’ making
that sound even though Abraham Lincoln himself
or the tail side appears to be spinning even
more slowly.
Both of those are true.
The disk is spinning more slowly but precessing
more quickly.
But wait hold on hold on.
Why does the rate of precession increase.
Well just like as we mentioned with the gyroscope
the spinning of the disk slows down due to
friction which means that gravitational torque
becomes a larger proportion of the effect
on all the mass.
But also as the disk loses to gravity and
drops down and the angle between the disk
and the table gets smaller the moment arm
that gravity acts on gets longer.
You can think of the disk like a lever right?
When it’s really steep like this it’s
pivoting from a point, I’ll use the pencil
to point it’s pivoting from a point right
here and it's being pushed down from the center
of mass basically like right there.
But as the disk obtains a shallower and shallower
angle the distance from the pivot point to
the center of gravity increases and gravity
operates more perpendicularly to that lever
arm.
It’s the difference between using a crowbar
like this and pushing down like that and pushing
like this.
You’re gonna get more leverage this way.
For that reason gravity’s torque increases
as the disk loses it’s height.
And precession increases in rate.
Okay I think you guys are ready to see a magic
trick that I learned from the Pillowcase of
Terror.
You ready?
So here we are with just a regular old penny.
In fact the very same penny that was in my
mouth just moments ago.
But watch.
Corn cob.
Whoa!
Amazing right?
But of course this isn't a real penny.
You couldn't spend this in a store.
If you want something of true value try this
one.
Cob corn.
Curiosity Box 12.
Now shipping.
We only have a few of these units left but
it’s amazing.
The stuff inside here is basically a mystery
but a few spoilers.
The deck of cards that we specially designed
are in here.
I tweeted about those earlier.
And this shirt.
This is the shirt in the next box.
It works in very cool ways with the red blue
3D glasses.
Now Euler’s disk and the gyroscope are not
in this box.
Not at all.
However you can buy them in the Curiosity
Box store.
That's right.
Our store is really maturing.
I’m pretty much in love with it right now.
It’s full of fantastic stuff.
Vsauce T-shirts.
Cypher Wheels.
Mobile Microscopes.
Vapor Equilibrium Demonstrators.
Galton boards.
Yeah.
I’m talking the kind of brain food that
does a body good.
But I’ve got some really big news for you
guys.
You know Curiosity Stream?
The streaming service that is just full of
scientific documentaries, historical documentaries.
They’ve got that new one Return to the Moon.
Very good.
Almost all of their content guys is just extremely
handsome.
MM love it.
Anyways they’ve done something really really
awesome.
Because of them the next 1,000 people to subscribe
to the Curiosity Box will get completely free
shipping inside the United States.
If you’re international you’ll get $8
off your shipping but that’s not all.
Are you already a subscriber?
Because of Curiosity stream you’re going
to be getting $5 to spend in the Curiosity
Box store.
Pretty pretty cool.
So thank you so much to them.
Curiosity stream has a great mission.
To get 30 days free you can use the code down
in the description.
Oh by the way that’s not even all they did.
They also enabled us to put an extra item
in this box we otherwise wouldn’t have.
So thank you Curiosity Stream.
Stay curious everyone.
And as always, thanks for watching.
Bonus content alert.
That was just me Michael not a robot.
Gotcha right?
Anyways this is bonus content as my robot
voice said.
This is footage we shot in slow motion of
Euler’s disk.
It’s pretty cool.
We have also an arrow on top so you can see
that as the angel between the disk and the
mirror get smaller the precession gets faster.
And because of that the spin becomes slower
and slower and slower.
As you watch you can see that the arrow rotates
around slower and slower and slower.
Enjoy.
