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  • In the grand scheme of things, we haven’t been at the space-exploration game very long,

  • but we've already learned a ton about the solar system.

  • Weve sent probes to planets and asteroids and comets.

  • We know what they look like, what they're made of, their temperatures, atmospheres,

  • and so much more.

  • But you know what’s even more amazing?

  • What we don’t know.

  • The truth is, there's still a lot we don't understand about our little corner of the

  • universe.

  • So let's look at just a few unsolved mysteries of the solar system.

  • [1: What causes the Sun's magnetism?]

  • First off, the Sun's magnetic field.

  • Magnetic fields everywhere are created by the movement of charged particles.

  • On Earth, for example, a flow of charged particles deep inside the outer core of our planet generates

  • the magnetic field that makes your compass point north, and protects us from dangerous

  • solar radiation.

  • Now, we know that the Sun has a magnetic field too.

  • Maybe that's not surprising.

  • After all, the Sun's made of plasma—a kind of gas in which electrons and ions have separated

  • and are free to move around -- a recipe for a magnetic field.

  • But we still don't know exactly how it works, or where it forms.

  • Does it start near the solar surface, or deep inside the Sun?

  • How do the different layers affect each other?

  • Getting to the bottom of this matters, because it'll help us understand everything from solar

  • flares, to the northern lights,.

  • Plus, it could help us predict what the magnetic fields of other stars might be like.

  • But above all, unlocking the secrets of the Sun’s magnetism will help us figure out

  • why our star is so ... inconsistent.

  • The Sun follows an 11-year cycle.

  • At the peak of this cycle, the Sun is brighter, and there are more solar flares and sunspots.

  • We call this peak the solar maximum.

  • But what's interesting is the way the Sun's magnetic field changes during the cycle.

  • The lines of its magnetic field get more and more messy as it nears the solar maximum,

  • and then a series of explosions -- known as coronal mass ejections -- smooth it out again.

  • The best we can tell, the field lines start out running straight from pole to pole, like

  • they do on Earth.

  • But then, because of the Sun spinning, they get wrapped around it like cotton candy.

  • Eventually these stretched and pulled field linessnaplike a rubber band stretched

  • too far, producing explosions and calming the field back down to where it started.

  • But all of this is based on what we can observe on the surface of the Sun.

  • What we can’t figure out is how these phenomena are created by what’s happening beneath

  • the surface.

  • Maybe theyre caused by forces between the outer layers of the Sun that are churning

  • in convection currents, like pots of hot water, and the parts below them that aren’t.

  • Maybe it’s more about the motion in the convection currents themselves.

  • We still have a long way to go before we'll understand where exactly the field originates.

  • To get our answers, we'll need to look much deeper.

  • [2: Why is Venus so different to Earth?]

  • Now a little further out from the Sun: the stormy planet Venus.

  • Venus has always been a bit puzzling.

  • It's been described as Earth's twin.

  • It's a roughly similar size, and it’s well inside the Sun's so-called habitable zone,

  • where liquid water could be a thing.

  • But it turns out ... not so much.

  • In many ways, Venus is more like our evil twin.

  • It's a planet of unrelenting storms, raging at 300 kilometers an hour, and a runaway greenhouse

  • effect that's given it an average temperature of 462 degrees Celsius.

  • That is hot enough to melt lead.

  • So, why is it so different from Earth?

  • And what got that greenhouse effect started?

  • Well, we know what's causing the greenhouse effect today.

  • The atmosphere is 95% carbon dioxide.

  • That's a powerful greenhouse gas, the same gas that's the main cause of climate change

  • on Earth.

  • When you consider that Earth’s atmosphere only has 0.04% CO2, you can see why 95% might

  • be a problem.

  • The question is, why does Venus have so much?

  • Scientists think Venus was once a lot like the Earth, with liquid water and not so much

  • CO2.

  • But at some point, it got warm enough that the water evaporated, and since water vapor

  • is a powerful greenhouse gas, too, this just made the heating worse.

  • Eventually it got hot enough that carbon that had been trapped in rocks was released, which

  • ended up filling the atmosphere with CO2.

  • The million dollar question is: What got the heating started in the first place?

  • Was it because the planet had a little too much CO2 to start with?

  • Was it maybe a tad too close to the Sun?

  • Or could it have been because of some catastrophic event?

  • It's anybody's guess.

  • Despite all the questions we have about Venus, we've only sent three missions there, so we

  • have a lot more exploring to do.

  • In future missions, we could study its atmosphere, to better understand the weather patterns,

  • and figure out what chemical reactions happen in each layer.

  • We could look for hotspots to see if there have been active volcanoes recently.

  • We could even search for signs of past life, and study the planet's geology.

  • [3: s]

  • Now for another stormy place, this time on the outer reaches of the solar system: Uranus.

  • When you get caught in a thunderstorm, it might be sticky and uncomfortable.

  • But that’s nothing compared to some of the storms in the rest of our solar system.

  • And for the longest time, Uranus wasn't seen as particularly crazy in the storm department.

  • That is, until 2014, when astronomers got a surprise.

  • They found clusters of gigantic methane storms sweeping across the planet.

  • Before that, storms on other planets were thought to be driven by energy from the Sun.

  • But the Sun’s energy just isn’t strong enough on a planet as distant as Uranus.

  • And as far as we know, there isn't any other source of energy to drive such huge storms.

  • The only thing that scientists are pretty confident about is that the storms on Uranus

  • start in its lower atmosphere, unlike Sun-driven storms, which occur higher up.

  • Beyond that, though, the actual cause remains a mystery.

  • Maybe were totally wrong about what's going on in the middle of Uranus.

  • The atmosphere could be much more dynamic than it seems from the outside, generating

  • heat that’s powering these storms.

  • And it could be a lot hotter in there than we think, too.

  • It’s possible there’s an atmospheric layer trapping heat inside the planet, making the

  • upper atmosphere cooler, and masking its true inner temperature.

  • The secret may lie in how the different parts of the atmosphere interact.

  • We just can't say for now.

  • At the very least, these storms have taught us that there's a lot more to Uranus than

  • meets the eye.

  • [4: Why does the Kuiper belt end suddenly?]

  • Now we head out beyond the planets we know and love, to the Kuiper belt.

  • The Kuiper belt is a disk of frozen bits of water, methane, and ammonia.

  • It starts at the orbit of Neptune -- 30 astronomical units from the Sun -- and keeps going to about

  • 50 AU from the Sun.

  • But there's one thing about the Kuiper belt that's a huge mystery.

  • Once we get to 50 AU, the belt just... stops.

  • It ends all of a sudden, something the astronomers call theKuiper cliff”.

  • This isn’t easy to explain, but we have a few ideas.

  • It could be that the belt really does continue, but the objects become so small that we can't

  • see them.

  • But this idea doesn't fit with what we know about how the solar system formed.

  • If anything -- because of the complex interactions of the outer planetsorbits -- we'd actually

  • expect objects to start getting larger again at that distance.

  • A more exciting idea is that the objects may have been pulled away by the gravitational

  • attraction of an as-yet-undiscovered planet.

  • Such a planetwhich would be the ninth planet in the solar systemcould be the size of

  • Earth or Mars.

  • Sadly though, it's tough to see anything that far out, so we might be waiting a while for

  • the answer.

  • [5: Is the Oort Cloud a thing?]

  • So the Kuiper belt is pretty far away, but there's one part of the solar system that's

  • even more out there: the Oort Cloud.

  • We all have a picture in our minds of the solar system as a flat disk.

  • But astronomers have hypothesized for a long time that the disk might have a spherical

  • shell around it.

  • This shell, the Oort Cloud, is thought to be made up of icy rockswater, methane,

  • ethane, carbon monoxide, hydrogen cyanide, and other nasty stuffextending out as

  • far as 2 light-years from the Sun.

  • Why do we think it's a thing?

  • Well, every so often, we spot long-period comets -- comets whose orbits take longer

  • than 200 years -- and when we trace back their paths, they seem to come from sources a long

  • way out in every direction.

  • Our mathematical models for how the solar system forms tell us the cloud should be out

  • there, too.

  • As the mess of the early solar system collapsed into the disk we know today, we'd expect small

  • icy objects to be thrown into an outer shell by the gravity of Jupiter and the other gas

  • giants.

  • But even if it makes sense for it to be there, we've never actually observed the Oort Cloud.

  • Being so far away, with so little light, we just don't have the technology to see it.

  • That means for the moment we have no way of proving that it exists, or if it does, how

  • big it is.

  • As these mysteries show, we don't have to go far to find puzzles-a-plenty right on our

  • own celestial doorstep.

  • And really, these five mysteries are only the beginning.

  • Thanks for watching this SciShow List Show, brought to you by our patrons on Patreon.

  • If you want to help support this show, just go to patreon.com/scishow.

  • And don’t forget to go to youtube.com/scishow and subscribe!

In the grand scheme of things, we haven’t been at the space-exploration game very long,

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