smart in any particular field you have to go talk to the experts. This is why I went

to Germany to a guy named Jörg Sprave. [thunder] Now today we're gonna learn about

the physics of slingshots but before we do that, let's just have some fun shooting.

You're getting Smarter Every Day.

So today we are in Germany at a 300 year old dairy farm in a small village.

Jörg, so what are we gonna do? - Well we're gonna see Tobias

shooting, and Tobias is actually the current world record holder for the

strongest handheld slingshot, so getting more than a hundred joules

with the handheld slingshot. So we're gonna try to kill this good German beer.

We've been shaking this a bit. Let's hope for the best.

[cheering]

Oh man.

[laughing]

Ja. That's the way.

[music]

[laughing] Oh man.

(Jorg) It's really dark red love the color. (Destin) Arrgh it looks like a skull.

It's pretty wild (Destin) It is dark red.

(Destin) Awesome. High five! We give high fives in America.

[laughs] High five Jörg. Nice.

Elastic is a pretty interesting material.

Alright so here's our graph. So if we want to add energy to the system,

meaning increase the potential energy on the bands of the slingshot,

all you have to do is pull back the bands, obviously. But the thing

about this is when you pull the bands back, the further you pull the more difficult it

gets to pull. Let me show you. If you look at this force gauge the further I pull

the more difficult it becomes. If I were to plot the

potential energy going into the system versus the displacement as I pull back,

because it gets harder it's not a linear graph, it's actually a curved function.

So here's something else. As I release the projectile and then it begins to accelerate

out of the pouch down towards the fork, it's going to also

have this curved function because of the material properties there, but here's

the interesting part. If you were to add up the potential energy still left

in the band, and the kinetic energy of the projectile going towards the fork

at any point along the displacement going back towards the fork, they would equal

approximately the total energy that I put into the system. OK the last

property of elastic I didn't understand until I saw some of Jörg's experiments. As you pull the bands

back they heat up. But if you hold them there and allow them to cool off,

you're losing energy. So what this means is the total potential energy

in the system is going to go down, so your projectile will be slower if you

sit there and wait and let your bands cool off. Why do you think that happens?

Jörg you want to explain it a little bit? (Jörg) Yes. Tobias' record shot

was shooting a 20mm steel ball at 83m/s

which is 115 joules. (Destin) OK ready.

(Jorg) How he acheives that is by

drawing out and firing immediately without any kind of break,

so that the rubber is still at full force and it doesn't lose

power through the hysteresis that otherwise happens.

Oooh! [laughing]

(Destin) Good grief. How thick is this?

Oh yeah.

This is a Frustum. A frustum is when you try to distribute a stress throughout a material.

OK here I have two bands and they're C-clamped to the barn, and as I go down the length of

the band you can see the one on the left is tapered to a smaller width than the one on the right.

So clearly if I put weight on each of them,

then the one on the left you would assume would stretch more because it has less material

resisting the stretch right? OK yeah, that makes sense.

So if we were to fire a slingshot with both a tapered band and an untapered

band, I would assume that the one on the right, the untapered band would

accellerate the projectile faster right? No. That's not what happens

at all. And the slingshot community has known this for years but they never had the rock solid evidence.

So that's what Jörg and I did with the Phantom high speed camera. We fired

two different slingshots at 1000 frames per second. The one on the top here

is an untapered band, the one on the bottom is a tapered band. The top band

is clearly accellerating slower than the bottom band.

My theory is pretty simple. Every solid material has what is called a stress strain curve

Stress is the force per unit cross sectional area on the material as you pull it.

Strain is the percentage that it elongates as you pull it.

You are probably putting more strain energy into the system.

OK in summary, we went to two different continents, I learned two things and I'm gonna

ask you two questions. First thing I learned. The potential energy in a stretched

rubber band is conserved, however it is rapidly dissipated in the form of heat.

The second thing, for slingshots a tapered band is more efficient or effective at

converting potential energy into kinetic energy. Here's a little bonus.

In 1660 a guy named Robert Hooke discovered the law of elasticity, or

Hookes Law. Here's the interesting thing. The rubber in

a rubber band does not obey the law of elasticity. I'll leave a link

in the description so you can read about that, but spoiler alert, some of your physics books might be wrong.

Anyway, here's the two questions for you. Number one. Why does rubber

lose energy when it cools off? I.e. I can shoot a rubber band farther

if I just pull it back and let it go. And the second thing, why are tapered bands more efficient?

Help me figure this out. I'm Destin. Thank you very much for watching.

Enjoy the outtakes.

Jorg's really good, and I wanted to go from a superficial

knowledge about how elastic works to a deep understanding. But before we look into the physics

of slingshots... let's just shoot. I just messed that up.

even though I hit it. Blah! We're using less reactive

material to fire something faster [goat bleating] Come on in.

Come on in.

...talk about slingshots. I wanted to learn...

[whispered] oh no.

When I first saw you I

though you were kind of a sissy so I'm glad to see that you're not. [laugh]

I'm only talking like this because his hand is

hurt and he can't punch me.

...so I wanted to go from a deep...

I'm killing myself here. I can't talk.

...tapered one actually deflects more. But here's the interesting part. It.. goat.. really.

... I wanted to learn about the elasticity of...

Aah!

...Jörg Sprave [thunder] Now today we're gonna learn about the physics of slingshots but

before we do that, let's just have some fun shooting. You're getting Smarter Every Day.

I finally said my words right!

Now that the lightning's here. [laugh]

[ Captions by Andrew Jackson ] captionsbyandrew.wordpress.com