The sun is around 4.5 billion years old, and just like you and I, it's aging.
The sun is around 4.5 billion years old, and just like you and I, it's aging.

In just over a billion years, the sun will have expanded so much that the heat will begin
In just over a billion years, the sun will have expanded so much that the heat will begin

to melt the earth's surface.
to melt the earth's surface.

So, is there any way us Earthlings can avoid this detrimental event?
So, is there any way us Earthlings can avoid this detrimental event?

Can we save ourselves from the suns ultimate death?
Can we save ourselves from the suns ultimate death?

Sure, none of us will be here, assuming we don't find the secret to everlasting life.
Sure, none of us will be here, assuming we don't find the secret to everlasting life.

But, at the billion year mark, the sun will have used up the hydrogen fuel in its core,
But, at the billion year mark, the sun will have used up the hydrogen fuel in its core,

forcing it to burn at its surface.
forcing it to burn at its surface.

The increased radiation will boil away all of the water on Earth creating an international
The increased radiation will boil away all of the water on Earth creating an international

desert.
desert.

Flash forward about 5 billion years, and the swelling sun will begin literally melting
Flash forward about 5 billion years, and the swelling sun will begin literally melting

mountains, with most, if not all life on earth now extinct.
mountains, with most, if not all life on earth now extinct.

Around 7.5 billion years, the expanding sun - now a Red Giant - will engulf the Earth
Around 7.5 billion years, the expanding sun - now a Red Giant - will engulf the Earth

entirely.
entirely.

Sounds bleak -- so can we avoid this hot mess?
Sounds bleak -- so can we avoid this hot mess?

It turns out; our best bet lies in something called "Gravity Assist".
It turns out; our best bet lies in something called "Gravity Assist".

A technique we've been using for years, only to launch space crafts throughout our solar
A technique we've been using for years, only to launch space crafts throughout our solar

system.
system.

Anytime a spacecraft or satellite comes in close proximity to a planet, gravity grabs
Anytime a spacecraft or satellite comes in close proximity to a planet, gravity grabs

hold.
hold.

And if the spacecraft arrives at the perfect angle, it's able to use some of the planets
And if the spacecraft arrives at the perfect angle, it's able to use some of the planets

velocity to catapult it further into space.
velocity to catapult it further into space.

This 'extra' energy comes from the planet's own energy of motion around the sun.
This 'extra' energy comes from the planet's own energy of motion around the sun.

But, as Newton famously said "To every action, there is an equal and opposite reaction".
But, as Newton famously said "To every action, there is an equal and opposite reaction".

As the spacecraft uses the Earths gravity to speed up and move towards Earth, the planet
As the spacecraft uses the Earths gravity to speed up and move towards Earth, the planet

will ever so slightly slow down and move towards the spacecraft.
will ever so slightly slow down and move towards the spacecraft.

Of course, the spacecraft's mass is so small, comparatively, that it gets launched incredibly
Of course, the spacecraft's mass is so small, comparatively, that it gets launched incredibly

far, while the planet experiences little change.
far, while the planet experiences little change.

But, if we were to increase the spacecraft's size -- or use an asteroid -- we could potentially
But, if we were to increase the spacecraft's size -- or use an asteroid -- we could potentially

move the Earth's orbit away from the sun.
move the Earth's orbit away from the sun.

This would take millions of years, and involve large objects coming just close enough to
This would take millions of years, and involve large objects coming just close enough to

not collide with Earth, but hey, we've got a billion year head start!
not collide with Earth, but hey, we've got a billion year head start!

It may seem far-fetched, but it's already happening!
It may seem far-fetched, but it's already happening!

On October 9th, 2013, Earth will be used to gravity assist a spacecraft called Juno, which
On October 9th, 2013, Earth will be used to gravity assist a spacecraft called Juno, which

is on its way to Jupiter.
is on its way to Jupiter.

As Juno flies within 559 kilometers of us, it will use Earth's gravity as a slingshot
As Juno flies within 559 kilometers of us, it will use Earth's gravity as a slingshot

to boost its velocity by 7.3 km/s; Meanwhile, Earth will have been moved by a fraction.
to boost its velocity by 7.3 km/s; Meanwhile, Earth will have been moved by a fraction.

Juno will later arrive at Jupiter, in 2016, where it will study the interior of the planet
Juno will later arrive at Jupiter, in 2016, where it will study the interior of the planet

and help to unveil many new spectacular mysteries of our Solar System.
and help to unveil many new spectacular mysteries of our Solar System.

In order to move the Earth within our billion year timeline, we would need approximately
In order to move the Earth within our billion year timeline, we would need approximately

1 encounter every 6,000 years, using an object with a mass of approximately 10^19kg.
1 encounter every 6,000 years, using an object with a mass of approximately 10^19kg.

That's 19 zeros - somewhere around the size of a 100 km-wide asteroid.
That's 19 zeros - somewhere around the size of a 100 km-wide asteroid.

In between passes, the asteroid would slingshot around the sun, fly out to Jupiter, and then
In between passes, the asteroid would slingshot around the sun, fly out to Jupiter, and then

be gravity assisted back to Earth - like one long version of catch between planets.
be gravity assisted back to Earth - like one long version of catch between planets.

Over millions of years, this would move Earth to a comfortable 225 million kilometer orbit
Over millions of years, this would move Earth to a comfortable 225 million kilometer orbit

out from the sun.
out from the sun.

And while it is feasible, even with today's technology, it doesn't come without risks.
And while it is feasible, even with today's technology, it doesn't come without risks.

For one, we may lose the moon, which could ultimately create some extreme weather patterns.
For one, we may lose the moon, which could ultimately create some extreme weather patterns.

Not to mention, the Earth's spin may increase, making days only hours long.
Not to mention, the Earth's spin may increase, making days only hours long.

The surrounding planets, like our new neighbor Mars, would likely have their own orbits destabilized.
The surrounding planets, like our new neighbor Mars, would likely have their own orbits destabilized.

And...you know...the asteroid could come plummeting into Earth by accident.
And...you know...the asteroid could come plummeting into Earth by accident.

But, perhaps these are the risks we need to take to give our descendants, the planet and
But, perhaps these are the risks we need to take to give our descendants, the planet and

all life on it a few extra billion years.
all life on it a few extra billion years.

Got a burning question you want answered?
Got a burning question you want answered?

Ask it in the comments, or on Facebook and Twitter.
Ask it in the comments, or on Facebook and Twitter.

And if you want to learn more about Juno?
And if you want to learn more about Juno?

Check out its awesome interactive website we have linked in the description.
Check out its awesome interactive website we have linked in the description.

Special thanks to NASA for inspiring and supporting this episode, and subscribe for more weekly
Special thanks to NASA for inspiring and supporting this episode, and subscribe for more weekly

science videos.
science videos.