that we use in space, in robots and in your mouth.

I'm talking about shape memory alloys.

Like the name says,

these are metals that remember different shapes.

To understand how these metals work,

we've got to talk about atoms and organizing.

Let's talk about atoms first.

Atoms are tiny bits of matter that you cannot see with your eye

yet they make up everything in our world,

from the chair that you're sitting on to your cell phone.

Atoms have some surprising ways of behaving too.

We'll talk about that shortly.

Now, how big is an atom?

Well, imagine pulling one of your hairs out of your head

and whittling it like a stick 100,000 times.

One of those shavings would be the width of an atom.

They're that small.

Now let's talk about atoms and organizing.

You may not know this, but atoms arrange themselves

similar to the way we humans arrange ourselves.

Sometimes they sit in rows, like we do

on a bus or an airplane.

We call that seating arrangement a phase.

Other times they sit diagonal from each other,

sort of like seats in a movie theater or sports stadium.

This is another phase.

When atoms move from one seating to another

this is called a phase change.

Phase changes are all around us.

You may already know about water's phases:

solid, liquid and gas.

Many other materials have phases like that too.

Some of them have several solid phases.

OK. Back to those shape memory alloys we mentioned before.

When we say that the metals remember their different shapes,

what we're really saying is they remember different seating arrangements

of atoms. When the atoms rearrange,

the metal moves from one shape to another.

Let's look at a phase change in action.

Here I have a metal wire that is made out of nickel and titanium.

This metal wire is a shape memory alloy,

and I'm going to make it switch between its different shapes

using heat from a lighter.

Watch this.

I'm going to wrap this wire around my finger

and then heat it.

Amazing!

That wire returns to a straight line, when I heat it.

Let's try that again.

I'm going to wrap it around my finger, and heat it.

Yep, that's still amazing.

Not only is it amazing, this is weird,

because metals generally don't do that.

Here's a paper clip. When I heat it, I get nothing.

What we're seeing is the shape memory wire changing phases when it gets hot.

When the wire is cold, atoms are in a diagonal arrangement,

like the movie theater seating, we talked about before.

We call this a monoclinic arrangement,

and scientists will call this phase martensite.

When I heated up the wire,

the atoms moved into columns like airplane seating.

This is a cubic arrangement.

Scientists will call this phase austenite.

So when we added the heat, the atoms shifted positions seamlessly,

and they'll do this forever.

They have this coordinated motion, just like members of a tireless marching band.

Each makes a small shift, but all together those small shifts

create a totally different pattern.

So that's pretty cool, but where do we use these materials?

Well, if you look in the sky tonight,

shape memory alloys are at work -

on Mars. They're used to move panels on the Mars rover,

so that it can study the environment.

Like our metal straightened when it was heated,

the metals holding the panels will move when electrically heated.

When we stop heating the shape memory metal,

the panel will return back, due to an opposing spring.

Back on Earth, shape memory alloys are used to open up clogged arteries

as stents, which are small collapsible springs

that force open passages.

Shape memory alloys are also used to move robots,

toy butterflies, teeth in braces, and for a perfect fit every time,

shape memory wires are used as underwires in bras.

Now you know Victoria's secret.

By popping a bra into the dryer, it'll be brand new every time.

So whether it's on Mars or in your mouth, small atomic movements

can create huge changes,

and understanding the way atoms behave

allows us to make materials that make our world a better place.