Nasa's revolutionary
juno probe
is on a daring voyage
to jupiter.
Its goal -- to reveal
the the deepest mysteries
of our solar system.
Everything we see
in the solar system today
is affected by jupiter
somehow in the past or now,
all the asteroids,
all the planets,
the moons,
the comets, everything.
So in many ways, juno is
actually giving us a view
into the history
of our planetary system,
even the history of earth.
Juno's mission is risky.
Jupiter could eat
the spacecraft like that.
But by diving
perilously close
to this monstrous world,
juno could change everything
we know about our solar system.
If you want to know
what's happening,
you got to get up
close and personal.
Independence day, 2016--
juno arrives at jupiter
and gets to work.
The probe angles its
high-resolution camera
towards this stormy world.
Juno's snaps do not disappoint.
♪
the images returned from juno
are just beautiful.
♪
♪
plait: Suddenly you have this
magnificent mosaic
of this planet.
♪
as a human being, I'm like,
"oh, my gosh, look at this.
This is amazing. This is
coming back from jupiter."
These are
the closest-ever views
of jupiter,
a world 500 million miles away.
♪
but we didn't send juno
just to take pictures.
One of its main goals is to peer
deep into jupiter's dark heart.
One of the big questions
we have about jupiter is,
does it have a core?
And you'd think, well,
of course it has a core
like every planet has a core.
The earth has a core.
Everything does.
Well, it turns out,
jupiter might not.
Knowing what lies at
a planet's core
allows scientists to wind back
the clock billions of years
to the formation
of the planets.
If juno can reveal what lies
deep within jupiter,
it could change
our understanding
of how the gas giant formed.
If juno finds a solid core,
it could mean
jupiter first formed
as a rocky planet like earth
then kept growing,
but if juno finds no core,
it could mean that
jupiter skipped the rocky stage
and formed straight
from a cloud of gas.
♪
answering this question
could shine a light
on other mysteries, too.
If we can figure out
how jupiter formed,
we can figure out the rest of
the story of the solar system.
♪
so how do you probe down
into the interior of a planet
when all you can really see
are the very tops of the clouds?
Well, incredibly,
you can use gravity.
As juno orbits jupiter,
it can sense in its orbit
tiny little variations
in the gravitational pull
of jupiter.
As juno speeds around jupiter,
gravitational spikes
tug on the craft.
Turns out, some parts of jupiter
are denser than others.
If jupiter were some solid ball,
then as juno passes by it,
as it passes very close
above its cloud tops,
the orbit, the trajectory
would be very smooth,
but in fact,
if jupiter has layers,
or places where
there is more mass
and places where there's less,
then it's gonna pull on juno
a little bit differently.
Passing over areas
of concentrated mass
gives juno a speed boost.
So what they do is,
the engineers back on earth
can basically just say,
"how fast is it moving
right now?
How about now?
How about now?"
and you build up a map of
where the mass is in jupiter
underneath the spacecraft
as it passes around.
Juno's instruments
begin to map out
the heart of gas giant,
revealing the mysterious core
for the first time.
What juno found was
this amorphous mass,
a fuzzy thing
in the center of jupiter.
It's not as solid as we expected
if it were just
a metal and rock core,
but there is something there.
In the center of the planet,
juno detects hydrogen
and rocky material
dissolved and blended together.
It's a type of planetary core
we've never seen before.
Astronomers
describe it as fuzzy.
We thought we were gonna find
an avocado.
Instead, we found
a bowl of chili.
It's a hydrogen fluid
chili con carne.
♪
so none of our models
of the interior of jupiter
turned out to be correct.
That means we have to go back
to the drawing board.
One theory is that jupiter
didn't form from rocks or gas
but from tiny pebbles
less than an inch wide strewn
across the early solar system
4.6 billion years ago.
These pebbles came together.
They accreted to form
a massive object
that was the sort of seed,
the core of jupiter.
The swarm of pebbles
clumped together
to form one giant core
20 times the mass of earth,
but these pebbles can't sustain
this growing planet for long.
Eventually,
we need to make a jump
from those centimeter-size
particles
up to really large things, like
100-kilometer planetesimals,
to really kick-start growth
of a planet.
♪
As jupiter grows,
its appetite becomes insatiable.
The cores of other
would-be planets are drawn in
by its immense pull
and absorb on impact,
causing jupiter's core
to transform.
Huge chunks of incoming rock
are mixed up with gas
and the pebbles
that originally built the core.
We think that core material that
might've been there is actually
dissolved and mixed in
with the rest of the planet.
This mix of rock,
gas, and pebbles
leaves the core
in a strange state
somewhere
between solid and liquid
or, in other words, fuzzy.
Once jupiter's core reaches
a critical mass,
its gravity pulls
in all nearby hydrogen gas,
building the jovian atmosphere
and leaving the fuzzy core
trapped beneath thousands
of miles of thick clouds.
And that is what formed jupiter
as we know and love it today.
Juno's discovery of
jupiter's fuzzy core
could rewrite the book on
jupiter's early years, but juno
is just getting started.
We haven't even scratched
the surface
of the number
of mysteries there are.
There's more to
jupiter than meets the eye
as juno's instruments
begin to reveal a darker side
to this giant world.
Jupiter's environment
is one of the most vicious
in the solar system,
and that's because
of its incredibly
strong magnetic field.
And juno is caught
right in the middle of it.
♪
The gas giant jupiter
holds clues to the mysteries
of our solar system,
and in 2011,
nasa launched a billion-dollar
mission to uncover them.
Man: Three, two, one, ignition.
And liftoff of the atlas v
with juno on a trek to jupiter.
To reach its target,
juno embarks
on a five-year journey.
♪
sending any spacecraft
to another planet
is gonna be tough,
but sending one to jupiter
is really
pushing things pretty hard.
Juno weaves through
the solar system
with extreme precision.
The craft battles violent
temperature changes
and navigates carefully
through the asteroid belt.
If there's a fleck of dust
in your path
and that thing slams
into your spacecraft,
it could do significant damage.
1.7 billion miles
into its mission,
juno finally nears its target,
but the probe is hurtling
towards jupiter
at 165,000 miles an hour.
Juno is moving really fast.
It's one of
the fastest spacecraft ever.
You need to go fast enough
to get there, but then you need
to be slow enough to be captured
by the gravity of the planet.
You need to get it just right.
Entering orbit around
jupiter is the trickiest part
of the mission.
Get it wrong and juno could slam
into the planet
or drift out into deep space.
To successfully get juno
to enter a stable orbit around
jupiter
as almost the same as, say,
sh**ting a basketball
from london
and having it on the land on
the front of the rim in new york
and just sitting there
balanced.
I could do it, but can nasa
do it with juno?
[ laughing ]
Nasa has a neat game plan.
Juno performs a backflip
in space
and fires its thruster
towards jupiter.
Everything is going smoothly.
We're continuing to burn
and change our velocity.
The rocket burns for
35 nail-biting minutes,
reducing the craft's speed
by 1,200 miles an hour.
♪
[ cheering ]
Finally, the probe
achieves orbit around jupiter.
Bolton: Right on July 4th
during the fireworks
we just got into orbit.
In many ways,
we're f*ring a rocket motor.
I mean, it is fireworks.
Safe in orbit,
juno turns
its instruments to the planet
for a crucial part
of the mission --
investigating jupiter's
magnetic field.
♪
deep below the stormy surface,
liquid metallic hydrogen
flows endlessly
around the planet,
producing a huge
magnetic field.
This magnetosphere
stretches over 600 million miles
beyond the planet,
reaching all the way to saturn.
If your eyes could actually see
jupiter's magnetosphere
and you tried to look at it
while standing on earth,
it would look about as big
in the sky as the moon.
And within this magnetic field,
juno faces an invisible thr*at.
Jupiter has an enormous
magnetic field.
It is so enormous
in terms of space,
but also in terms of power.
High-energy particles
from the sun
are funneled into
deadly radiation belts
guided by the giant
planet's magnetic field.
The magnetic field traps charged
particles coming from the sun
and circulates them
around that system
and just bombards
anything in the vicinity,
including our fragile
little spacecraft.
Closer to the planet,
radiation levels are up to
30 times greater
than they were inside
the reactor core room
during the chernobyl disaster.
This is radiation.
This is bad news.
These particles,
they would hit you.
They would rupture your dna,
rupture your cell structures,
and you would die.
This blistering
radiation is bad news
for the spacecraft as well.
The charged particles thr*aten
to destroy electronic
and navigational systems,
but juno has armored up.
Plait: It's not some delicate,
beautiful, gossamer thing
that you are sending
to orbit jupiter.
It's more like a t*nk.
You have to protect this thing
or else
it's not going to last
very long at all.
We've got a couple hundred
pounds of titanium
on the spacecraft
just trying to shield us
from what jupiter
might throw at us,
so it is in a sense we're like
an armored t*nk going into w*r.
Lightweight titanium is tough.
Juno's 1/2-inch-thick
shielding blocks 99%
of jupiter's vicious radiation.
But even at this reduced rate,
juno can't survive
the bombardment for long,
so the craft sets itself
on a unique orbit
around the gas giant.
It actually has a very
long orbit
where it spends
most of its time far away,
and then every once
in a while dives in and goes,
"oh, hot, hot, hot, hot.
I zoomed in too much,"
and then goes safely away
to communicate and process
and then back in again.
Juno takes a mighty gamble
diving deep
into these radiation belts
to achieve
one of its key objectives --
mapping jupiter's
giant magnetic field,
and as juno swoops
around the planet,
it reveals something scientists
have never seen before.
When you look at the earth,
we have a fairly
simple magnetic field.
It's like a giant bar magnet
with a north
and south magnetic pole.
Well, jupiter has that as well.
This is called a dipolar field.
It's got two poles,
but it also has a third pole.
Juno's magnetic field maps
show a north and south pole
and a bizarre magnetic
disturbance at the equator.
And it's like jupiter
just sprouted a third arm,
and that's kind of mysterious.
On magnetic field maps,
north poles show up red
and south poles blue,
so scientists are calling
this second south pole
the great blue spot.
Everyone knows about
the great red spot,
but jupiter now has
a great blue spot as well.
This magnetic
disturbance reflects
jupiter's stormy interior.
You have these fast-moving winds
blowing on the magnetic field,
and they're actually
shearing it apart
and moving the field around.
Bolton: It's not
necessarily a storm,
although it could be.
It maybe is better to think
of it as a magnetic storm.
♪
Turbulence inside
jupiter could be
twisting up the magnetic field
to drive the great blue spot
and the deadly radiation belts
that juno must navigate through.
Unlike earth, jupiter
is not really a solid mass
for the most part,
so all of its clouds and gases
are moving
at slightly different rates,
and that actually makes
the magnetic field
that's generated very variable
and highly changing.
For us to have a variable
magnetic field
like jupiter does,
the entire earth
would have to be molten.
We really don't want
that to happen.
With each orbit,
juno unravels more mysteries
of this giant planet,
but jupiter's deepest secret
could shine a light
on our own origins.
If we want to understand
the earth
and our place
in the solar system,
juno has found that a lot
of those mysteries
are locked up there in jupiter.
♪
♪
The juno spacecraft
is uncovering
the secrets of jupiter
from its swirling cloud tops
to its dark heart,
but juno's discoveries
go beyond the gas giant itself.
They could also solve mysteries
surrounding our own planet.
Jupiter is the key
to the formation
of the solar system,
which means it's the key
to understanding
how the earth formed.
Juno is actually giving us
a view
into the history
of our planetary system,
even the history of earth.
4.6 billion years ago,
a cloud of hydrogen gas
and cosmic dust collapses,
sparking nuclear fusion.
From the resulting chaos,
one star, four rocky worlds,
and four gassy giants are born
and form our solar system.
There's these distinct zones
of the solar system --
rocky and metallic
in the inner part,
gaseous and water-rich
in the outer part,
and even without thinking
about that too hard,
it kind of makes sense
because in close to the sun,
it's warmer.
Out farther away from the sun,
it's cooler.
But the earth
breaks the mold.
Our planet has far more water
than theories predict.
The earth formed in a part
of the solar system that,
well, you'd think normally
should be probably pretty dry
because it was pretty
close to the sun.
Our planet is just
150 million miles from the sun,
putting us inside what
scientists call the snow line.
Inside this line,
the sun is powerful enough
to evaporate water
during a planet's formation.
Inside the snow line,
the temperatures are high,
and there's a lot of energy
from the sun nearby.
Too close to the sun,
those gaseous and ice-rich
materials just can't exist.
They're evaporate away
by the heat of the sun.
Our watery world
should be a dry rock in space.
Understanding how water got
to the earth is so important
because it wouldn't be there
in the very, very beginning.
But jupiter could hold
the answer to this mystery.
To solve the riddle
of earth's water,
juno aims to discover
where our jupiter was born.
Understanding how and where
and when jupiter formed
is critical
because it has really dominated
the entire evolution
of the solar system.
It's the biggest planet by far.
It's the biggest thing out there
that's moving everything around.
Any water in the early
solar system
could've been moved around
by jupiter's mighty gravity,
so if juno can trace the history
of this giant planet,
that could explain why we find
h2o where it's least expected.
We know that planets can move
closer to the sun
and farther out
while they're forming
and even after they form,
so how do we figure out
where jupiter formed?
The key is how much water is
locked up inside jupiter.
If we can understand how jupiter
built a relationship with water,
we can understand
how water got distributed
all throughout the solar system,
including here on earth.
If juno can measure
the water content of jupiter,
it will solve
a 20-year-old mystery.
♪
December 1995 --
nasa's galileo probe
begins a fatal dive
into jupiter's atmosphere.
When it did, it was able to
measure the atmosphere around it
and detect water,
and the thing is -- it didn't.
It didn't find any,
and that's weird.
Everything was bone-dry,
so why in the world
did jupiter's atmosphere
look dry?
If the results from
the galileo probe are correct,
then 4.6 billion years ago,
jupiter formed
closer to the sun,
but that's not the whole story.
20 years later, nasa sends
juno to get a second opinion.
Juno is an orbiter, and so it
is loaded with instruments
and detectors
to look down on jupiter
and try to figure out
everything that's going on.
Juno doesn't have to risk
its life to hunt for water.
The craft peers through
jupiter's thick clouds
using a microwave radiometer to
detect h2o from a safe distance.
Using these microwaves,
juno builds up a global map
of jupiter's water.
What juno has found is,
yeah,
there's plenty of water
in jupiter,
it's just that galileo
happened to hit a dry spot,
but in fact, if it had
come in almost anywhere else,
it would've seen
plenty of water.
Juno's findings
may give a clue
to where jupiter
originally formed.
It seems apparent now that
jupiter
didn't form
in its present location.
The leading theory is that
jupiter formed
just beyond the snow line,
the boundary between
the dry inner solar system
and the wet outer
solar system.
But we find jupiter is twice
as far away from the sun
as where that original
snow line would've been,
so this is telling us
something interesting.
Jupiter may have wandered from
its original position,
causing unimaginable chaos.
As jupiter moved around,
things got hit
and knocked out
of the solar system.
Walsh: It essentially scatters
everything in its path.
It's the biggest player.
It's the biggest planet.
Everything moves for it.
As jupiter bulldozes
toward the outer solar system,
it slings ice-rich asteroids
and comets in towards the sun
and towards the earth.
♪
jupiter would literally
in some sense
have snowplowed
into the inner solar system
a whole wave
of water-rich planetesimals
that would've delivered
much of our earth's oceans.
Juno has helped answer
why our earth is habitable
despite being so close
to the sun.
So it was worth going all
that distance,
sending juno all the way out
there to get that closer look.
♪
Juno continues to explore
jupiter's mysteries
and its famous features.
There is nothing more iconic
about jupiter
than the great red spot.
And juno reveals
that this 300-year-old cyclone
may soon vanish.
♪
Our solar system plays host
to some epic natural wonders --
the ice geysers of enceladus,
the giant rings of saturn,
the martian mega volcano
olympus mons,
but in July of 2017,
nasa's juno probe skims
the surface of jupiter
and photographs the most famous
natural wonder --
a fierce, hurricane-like storm
that's been raging
for hundreds of years.
When you think of jupiter,
one of the most
visually stunning
and most iconic features
of the atmosphere
is that great red spot.
There is nothing like
jupiter's red spot
in our entire solar system.
As juno soars
over the great red spot,
it looks down onto a storm
over 10,000 miles across.
♪
thaller: This is
the most extreme storm.
The winds are
blowing continuously
at 400 miles an hour.
On earth, the most
powerful category 5 hurricanes
can unleash
almost total destruction,
but these are less
than half as powerful
as the storm on jupiter.
The great red spot is
the greatest hurricane
that you've ever imagined.
But that's not all.
Juno's microwave radiometer
allows scientists to see through
jupiter's cloud layers
for the first time.
Juno has instrumentation
that's able to look underneath,
so one of the things
we did was we looked
at how deep are the roots.
Juno peers down into the eye
of this monstrous storm.
It spots temperature changes
far below the surface
that follow the storm's
iconic shape,
tracing the roots
of the great red spot
deep into
the jovian atmosphere.
They found out that
it goes down over
200 miles
deep into the atmosphere.
There's nothing
like that on earth.
♪
The greatest cyclones
of our own planet
can reach heights
of around 10 miles,
but jupiter's great red spot
is over 20 times taller.
I think that really brings
into perspective
the massive scale
of this planet.
♪
Jupiter's vast,
turbulent atmosphere
hosts the deepest storm
mankind has ever seen,
and juno's discoveries
get scientists wondering.
Could the great red spot
help explain
another of jupiter's mysteries,
the planet's surprisingly
warm atmosphere?
Jupiter looks out
in our outer solar system
where everything
is very cold.
The sun is very dim
when you get that far away.
Jupiter is five times farther
from the sun than we are,
so it's only getting 4%
of the amount of energy
from the sun that we do.
Thaller:
But there's something heating up
the atmosphere of jupiter.
There are parts of it
that are many times warmer
than we could explain
with sunlight.
The question is, of course,
where is that energy
coming from?
Juno swoops in for
another pass on jupiter,
turning its
high-resolution cameras
on the raging storm below.
The storm unleashes
vicious turbulence
into the surrounding atmosphere,
giving scientists the clue
they need
to explain
the planet's high temperature.
The great red spot
is a giant hurricane
that's powered by heat deep
in the core of jupiter,
but it has such violent
and chaotic motion,
it's mixing up
the atmosphere around it.
♪
the thunderstorms on jupiter
are gonna be generating
booming thunder
just the same way
that they do here on the earth.
Thunderclouds send sound waves
rippling through the storm.
A sound wave is a wave
of pressure,
of compression
where air molecules
or water molecules
get compacted.
They get squeezed together,
and when you squeeze
something together,
they're a lot closer together
and they're gonna
get pretty hot.
♪
These sounds waves sh**t up
500 miles above the storm
where they break, converting
sound energy into heat.
These sound waves,
they crash together,
creating a tremendous
amount of energy
and heating the gases
around them.
Jupiter's great
red spot has helped heat
the jovian atmosphere
for hundreds of years,
but new images suggest that
this may be about to change.
Jupiter's red spot is so big,
I mean, it's bigger than earth
by a long sh*t.
It seems like it would be
an incredibly stable thing.
It's just there and it's always
been there and always will be.
Recently,
we've seen it changing.
When nasa's voyager
space probe visited
jupiter in 1979,
it observed a storm
twice the diameter of earth.
♪
in 2017, juno's images
show the great red spot
has lost a third of its width,
but that's not all.
Despite the storm shrinking,
it's actually getting taller.
The great red spot is being
stretched and forced
into jupiter's upper atmosphere.
The storms in
the great red spot,
it's kind of like the clay
on a potter's wheel,
where as you bring your hands
closer together
to draw the clay in,
the closer your hands are,
the taller the pottery becomes,
and similarly, for the storm,
as it becomes
smaller at the base,
it raises taller toward
the upper atmosphere.
It's getting taller,
and we see storms
do the same thing on earth,
and when it does that,
the wind shear will actually
take the top of the storm off
and drag it apart,
and so we'll be watching it
very intently
over the next few years
to see if that's what happens on
jupiter as well.
It may be only
a matter of time
before jupiter's
high-altitude winds
tear this iconic storm
to shreds.
The most famous storm
of the solar system
may soon disappear,
but juno reveals other storms
hidden in the strangest
of places.
The storm in the great red spot
is one,
but not the only, giant storm
that's happening on jupiter.
♪
♪
Nasa's juno probe
has traveled billions of miles
across the solar system
to reveal the mysteries
of gas giant jupiter,
but there's one part
of jupiter
that has remained hidden
until now.
Before juno, our view of jupiter
was very limited.
We'd never actually flown
over the poles.
It's something that's very hard
to do on jupiter.
We don't have other missions
that have done this.
In August of 2016,
juno's flight plan takes
the spacecraft
into unknown territory to reveal
jupiter's mysterious polar
regions for the first time.
Well, and the first time
we looked at the pole,
it didn't look anything
like the jupiter we knew.
♪
we never would've guessed
that was jupiter
if somebody had
shown that to us.
♪
Juno's camera reveals
a strange blue expanse
that puzzles scientists.
The electronic color
could be due to chemical changes
in the clouds
brought on by a lack
of sunlight,
but what juno spots
inside the blue clouds
is even stranger --
giant central cyclones spin
around each pole at 200 miles
an hour, with these cyclones
surrounded by eight
stormy vortices in the north
and five in the south.
There are these weird cyclones,
gigantic swirls,
vortices of gas swirling around
jupiter's poles,
and they're
clearly forming patterns.
It's hard to get
a sense of scale here.
Now the north polar
central cyclone,
that one right at the pole,
that's 2,500 miles across.
That is almost as big as
the continental united states.
What is going on there?
This is nothing like
what we see on earth.
♪
On earth, our weather
is driven by heat from the sun
that hits our planet
at the equator
and flows across the surface.
Powerful cyclones form
over tropical waters
and move around the planet,
but the polar regions receive
less energy from the sun,
so cyclones
can't form at the poles.
We see that if you're at
the equator,
it's warmer and it's stormier.
If you're at the poles,
where the sun is slightly harder
to see, that activity goes away.
But the weather on jupiter
couldn't be more different.
We see lightning
and convective thunderstorms
at the poles of jupiter
but not at the equator,
and that's sort of the opposite
of what we see on the earth.
The question is,
what's driving jupiter's storms?
Jupiter is five times further
away from the sun
than the earth
and receives only a fraction
of the sun's energy.
Unlike earth,
jupiter's polar regions
seem to be where the action is.
Something is driving
the planet's weird weather,
and juno's scans of the giant
planet's thermal emissions
suggests it could be
jupiter itself.
We can actually see
the internal heat of jupiter
coming right up through,
and so jupiter
will look very bright in areas
where we can see that heat.
Juno detects
searing heat
beneath jupiter's cloud bands.
Jupiter has so much material,
so much mass,
so much gravity that
the interior is incredibly dense
and very, very hot.
At the core, it's probably at
many thousands of degrees hotter
than the surface of the sun.
This fiery inferno
buried in jupiter's dark heart
is a relic from its birth
billions of years ago.
The violent collisions
that formed the planet
left its core seething hot,
a heat that
remains to this day,
buried under thousands of miles
of insulating gas.
As the heat slowly leaks
outward,
jupiter's fast-rotating
atmosphere
creates vicious cyclones
and thunderstorms.
And that's what's really
driving most of the weather.
It's not the sun.
It's jupiter itself.
And as juno soars
over the planet,
it reveals
another weather mystery.
The craft detects bursts
of radio waves
spiking up
to four times a second --
the telltale sign
of ferocious lightning strikes.
Clouds are moving around
in the atmosphere
and building up electric charge
and causing bolts
of lightning to form,
and we've actually seen this
with the juno spacecraft.
These are mega storms
orders of magnitude bigger
than here on earth.
[ thunder crashes ]
And juno finds there's
more to these thunderclouds
than just flashes of light --
giant icy hailstones of water
and ammonia,
the chemical
which gives jupiter's clouds
their orange color.
High up
in jupiter's atmosphere,
the ammonia is mixing
with the water,
and it becomes a liquid ball
that starts to collect ice
around it,
and it will fall like hail does
deep into jupiter's atmosphere.
On earth, hail falls
to the ground and melts,
but on jupiter,
there is no ground.
And it gets lifted
in the atmosphere
because of an updraft
and then more ice,
and it builds bigger,
and then it falls down,
and then it gets
carried back up,
and so hail is often
many layers being built.
These ice balls grow
layer by layer as they soar up
and down the atmosphere.
If they formed in storms
here on earth,
they'd cause
some serious damage.
So if you were buzzing around
jupiter
and you were near
where these storms were,
you might get hit by hail
coming up or going down.
This is one of the most violent,
energetic atmospheres
in the entire solar system.
Juno is revealing the secrets
that jupiter has hidden
for decades,
including the mystery
of jupiter's northern lights.
When juno studied the lights
coming from the aurora
on jupiter,
it found that something
really weird is going on.
♪
♪
On earth, dazzling
auroras light up the skies
as charged particles
from the sun
interact with atoms high
in the atmosphere.
♪
deep in the outer solar system,
jupiter is too far from the sun
for strong auroras
to form in this way,
but high above
the giant planet's poles,
juno spots a seemingly
impossible light show.
♪
the auroras of jupiter
are tremendously larger
than the ones
that we find here on earth.
In fact, the auroral rings
near the poles
are bigger
than our planet itself.
Jupiter's auroras emit
primarily ultraviolet
and x-ray light,
so you can't see it
with the naked human eye,
but if you could see them
and you were at jupiter,
that would be
an amazing light show
because those auroras
are strong.
These glowing displays are
evidence of charged particles
slamming into
jupiter's atmosphere.
But if they're not coming
from the sun,
where are they coming from?
Hunting for an answer,
juno snaps an image
of jupiter's southern lights
with its ultraviolet
imaging spectrometer.
Inside the aurora,
it glimpses something strange.
When juno studied the lights
coming from the aurora
on jupiter,
it found that they were
even stronger than expected,
and in fact,
when you look at
jupiter's poles in wavelengths
that our eyes can't see,
for example, ultraviolet,
you see a hot spot.
This hot spot marks the point
where huge concentrations
of charged particles
strike jupiter's atmosphere.
Tracing their trajectory
reveals the culprit
of jupiter's dazzling
light shows --
the volcanoes
of jupiter's moons.
♪
jupiter's moon, io has hundreds
of active volcanoes
spewing out materials
way out into space,
and many of those get trapped by
the magnetic field of jupiter.
Io's volcanoes fire
out jets of charged particles,
which are swept by the giant
planet's magnetic field.
It's funneling those
particles down
and slamming into specific spots
in jupiter's atmosphere.
But io isn't
the only moon responsible
for jupiter's
polar light show.
If we go further out,
europa, ganymede,
callisto,
those are more icy.
They don't necessarily
have volcanoes.
These icy moons twist up
jupiter's magnetic field
in their own way.
Some of these moons have
magnetic fields that interact
with jupiter's magnetic field,
and that actually intensifies
the aurora display on jupiter.
Jupiter's moons work together
to energize the greatest auroras
in the solar system,
but in these
beautiful displays
is a stark reminder
of the danger juno faces.
When you look at these pictures
of the aurora on jupiter,
and you think,
oh, that's beautiful.
Wouldn't it be great
to see that in person?
The answer is no,
no, it wouldn't
because they will k*ll you.
What's causing these displays
are subatomic particles
accelerated to tremendously
high speeds
by the magnetic fields
involved.
The radiation around
jupiter is lethal
and not just for humans.
The lifetime of the juno
mission is very limited
by the extreme conditions
it has to survive in.
We think that in the future,
a lot of the instruments
will be so irradiated,
they won't really work anymore.
When juno's titanium
armor finally fails,
jupiter's deadly radiation will
damage the craft beyond repair,
so the team plan to go out
with a bang,
thrusting juno into
jupiter's atmosphere,
where the craft
will be torn to pieces.
Eventually, it'll be drawn down
into jupiter's depths
and become a part
of the planet itself.
But before then,
juno has many
more mysteries to unlock.
We'll answer some questions,
and we'll raise some more.
That's what I expect
and we'll get some
fantastic images.
Every single thing has turned
out to be a surprise.
There are so many things that
juno has opened our eyes to that
I can't imagine
having not sent it.
So we're in for at least a year
more of the most profound
surprises about jupiter.
What we're learning,
what we're unlocking,
not just about jupiter,
but the formation
of the solar system
and potential formation
of life itself
here on earth,
it's mind-blowing.
08x06 - When NASA Met Jupiter
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Science documentary television series that provides scientific explanations about the inner workings of the universe and everything it encompasses.
Science documentary television series that provides scientific explanations about the inner workings of the universe and everything it encompasses.