The Cassini probe has been orbiting Saturn
for almost thirteen years, and in that time
it’s sent back some of the most incredible
pictures and data we’ve ever seen.
It’s found underground oceans on Enceladus,
methane lakes on Titan, mysterious hexagons
at Saturn’s poles, and so much more.
Its mission ends in September, when it’ll
dive down into Saturn’s clouds in a blaze
of glory.
But Cassini still has a lot to do in the meantime.
It just finished a risky dive between Saturn
and its ring’s -- something no probe has
ever done before.
And it’ll repeat the trick 21 more times
before September.
Sending Cassini through the rings will let
scientists map Saturn’s gravity and magnetic
fields like never before, because nothing
else has ever gotten this close.
It was just too dangerous.
The rings are made of rocks and ice moving
dozens of kilometers a second, so they aren't
the safest place for a spacecraft with lots
of sensitive electronics.
Cassini did fly through the 30,000-kilometer
gap between the inner and outer rings when
it first got to Saturn in 2004.
But we only sent it through that big gap because
we already knew it was pretty empty.
Now that the mission is finally winding down,
there’s not much left to lose.
So it's time to send Cassini on some way more
dangerous dives.
The plan is to thread the needle between Saturn
and its innermost ring 22 times.
That gap is ten times smaller than the gap
it went through back in 2004.
Cassini finished its first dive last week,
but there were a few tense hours back here
on Earth when we weren’t sure if it made
it through.
The probe used its dish-shaped antenna as
a shield, just in case anything was in its
path, but that also meant that it couldn’t
let us know if it survived until about 20
hours after it passed through the rings.
Cassini made it, though, and collected data
the whole trip!
Since we’ve never sent anything through
that gap before, hopefully we’ll learn some
totally new things about Saturn and its rings.
A lot of the data will take a while to process,
but Cassini already sent back a few of those
incredible photos that we’ve all gotten
used to for the last 13 years.
Like this close-up of a storm on Saturn.
Pictures like that will keep flooding in over
the next few months, telling us more about
how Saturn’s atmosphere moves and evolves.
In the process, we’re getting perspectives
on Saturn and on the entire solar system that
no one has ever seen before, which is a pretty
cool And bonus: gorgeous!
Speaking of new perspectives on the solar
system:
Last week, a team of researchers published
a paper in the journal Nature claiming that
the Sun’s surface might not be quite as
complicated as astronomers thought.
The Sun has two main kinds of eruptions where
particles shoot out from its surface: Coronal
Mass Ejections, or CMEs, and coronal jets.
CMEs are the big ones that we need to watch
out for.
Each one launches billions of tons of plasma
at millions of kilometers an hour, and they
can endanger astronauts and interrupt communications
around the world if they hit Earth.
Coronal jets also fire out plasma, but they’re
way smaller and have much less energy.
Astronomers have known for a while that both
kinds of eruptions involve the Sun’s magnetic
fields twisting and crashing into each other
until plasma breaks free and flies off into
space.
But for years, they thought that’s where
the similarities ended.
It didn’t seem like the same kind of twisting
and splicing could make both giant, explosive
CMEs and those smaller jets.
As astronomers studied more eruptions, though,
they discovered that they’re actually really
similar — so similar that there’s probably
one main process causing both CMEs and coronal jets.
Just on different scales.
So this group of researchers used simulations
to try and figure out what kind of twisting
in the Sun’s magnetic fields could cause
both types of eruptions.
They decided to try simulating mini-CMEs,
way smaller than the ones we see on the Sun.
The fields in regular CMEs stretch over big
sections of the Sun and have huge loops of
plasma that eventually explode out when the
magnetic fields get twisted together and rearranged.
So the team tried shrinking down the fields
to see if the process that causes CMEs would
produce something like a jet on a smaller
scale.
And it did!
They found that even with the same sorts of
things happening to the magnetic fields as
in big CMEs, the resulting eruption looked
pretty different on a smaller scale.
As the magnetic fields twisted, the plasma
got pushed together instead of spreading apart.
And when it finally broke free as the fields
rearranged, it all rushed out along a single
line -- just like what we see in coronal jets.
If this is really what’s happening on the
Sun, that means the only real difference between
gigantic CMEs and those smaller jets is the
strength of the magnetic fields involved.
Big fields tend to spread out and make CMEs,
while small fields clump together to form jets.
We’re still not sure if this is actually
what happens, since these are just simulations.
But if it is, then we now have one unified
theory to explain all kinds of eruptions.
And that makes it a lot easier to study and
compare them.
Either way, we’re one step closer to understanding
the giant, and sometimes dangerous, explosions
bursting out of the Sun.
And hopefully someday we’ll be able to use
that understanding to make better predictions
about when they’ll happen, and give ourselves
a few precious extra moments if a massive
CME is about to head right for us.
Thank you to our patrons on Patreon for helping
make this show possible.
If you want to help us keep making episodes
like this, you can go to patreon.com/scishow.
And if you want to watch more episodes like
this, there’s probably some in the side bar.
It’s actually on that side…
And if you want to subscribe and watch a new
one, twice a week, that would also be great,
at youtube.com/scishowspace … or just there’s
a button under the video.
