Unexplainable - Origins: How did Earth get its water?
Episode Date: March 1, 2023Life as we know it needs water, but scientists can’t figure out where Earth’s water came from. Answering that question is just one piece of an even bigger mystery: “Why are we here?” This is t...he first episode in our new three-part series, Origins, about the beginnings and boundaries of life on Earth. For more, go to http://vox.com/unexplainable It’s a great place to view show transcripts and read more about the topics on our show. Also, email us! unexplainable@vox.com We read every email. Support Unexplainable by making a financial contribution to Vox! bit.ly/givepodcasts Learn more about your ad choices. Visit podcastchoices.com/adchoices
Transcript
Discussion (0)
Visit BetMGM Casino and check out the newest exclusive.
The Price is Right Fortune Pick.
BetMGM and GameSense remind you to play responsibly.
19 plus to wager.
Ontario only.
Please play responsibly.
If you have questions or concerns about your gambling or someone close to you,
please contact Connects Ontario at 1-866-531-2,600 to speak to an advisor,
free of charge.
BetMGM operates pursuant to an operating agreement with Eye Gaming, Ontario.
Amazon Present.
Laura versus fruit flies
Swarming your fruit and terrorizing your kitchen
These little freaks multiply at a rate that would make a rabbit say yo
Chill
But Laura shopped on Amazon and saved on cleaning spray
Countertop wipes and fly traps
Hey fruit flies your baby boom ends here
Save the everyday with Amazon
In 1972
three NASA astronauts were heading to the moon.
Before they turned their attention away from Earth,
they turned around and they looked out the window.
I know we're not the first...
The astronauts caught a glimpse of a few continents,
but all that land paled in comparison to the rest of what they saw.
The rest of it is all oceans, the Indian Ocean out.
So they decided to take a picture.
It might be the most famous photo of Earth ever taken.
You've probably seen it before.
It's called the Blue Mark.
Over two-thirds of Earth's surface is ocean.
And when you look at this photo, it's just obvious that water is the defining feature of our planet.
But the fact that there's all this water here at all is kind of confusing.
Because when you start thinking about the history of our planet, Earth being blue doesn't really make any sense.
The issue that scientists have always had is that when Earth formed really, really,
early during our solar system, Earth would have just been too hot to have any kind of condensation of liquid water.
Lydia Hallis, planetary scientist, University of Glasgow.
So it's always been a bit of a problem as how do you get so much water onto Earth?
So let's go back in time about four and a half billion years.
Earth is about to be born and the solar system is a really different place.
It's chaos.
Pieces of dust and rock are floating everywhere.
They're colliding into each other, making larger and larger piles of rock.
And eventually we end up with planet-sized bodies.
These collisions are explosive.
They release tons of energy.
So when these planets form, they're incredibly hot, so hot that they actually melt.
And this happened to the early Earth, so early Earth completely melted.
Which means Earth used to be less of a blue marble and more of a black.
and more of a bright orange molten magma marble,
which raises a pretty major question.
How do you get so much liquid condensing
onto the surface of a planet that should be really, really hot?
How did Earth get its water?
It's a pretty epic question in its own right,
but it leads to an even bigger one,
maybe the biggest one there is.
Why are we here at all?
We only know life as it exists on Earth,
and without water,
life can't exist.
I'm Noah, I'm Hassanfeld, and this is Origins,
a new series from Unexplainable about the beginning of life on Earth
and just how improbable all of this might be.
But to even start answering that question,
we need to figure out how Earth went from a bright orange marble to a blue one.
Where did Earth's water come from?
Every marvelous living creature on our Earth is built of complex living cells.
Life is made up of atoms and molecules and chemical reactions.
But what makes them alive?
How are we in life?
How does this come about?
What is life?
Lydia wasn't always interested in enormous existential questions.
She just liked rocks.
I'm just really interested in minerals.
So I was just born that way.
And she started her reason.
research pretty early on.
Ever since I was little, I would just like digging around in the ground.
As she grew up and became an actual adult scientist, Lydia started noticing how much everything
she would dig up was constantly being shaped and reshaped by water.
It really drives every mechanism on a rocky planetary body from plate tectonics down to
different types of minerals that Earth has.
But water does more than just shape rocks.
It's a perfect environment for the kinds of chemical reactions that actually create life.
It acts as kind of a chemical soup to allow the reactions to start going.
And once life is around, water is what allows it to stick around.
We just need the water to keep our cells intact, really, because cells dehydrate, and they start to degrade.
And then if you don't get water, you die.
Without water, we just wouldn't be here.
And Lydia wanted to know where all that water came from, especially,
given how hot Earth used to be.
So she started by checking out some of the ideas that had already been put forward.
So the classical theory is that it was delivered after Earth cooled down.
The idea is that millions of years after Fireball Earth, magma hardened into rock, and then
poof, special delivery.
I see bodies from the outer solar system, so maybe comets would have delivered all the
water that we need to Earth through impacting the Earth.
Comets are mostly made up of ice, and they swing through the solar system all the time.
They're essentially a consistent, interstellar water pipeline.
But this theory isn't perfect, because scientists have a way to actually check.
We can figure out, okay, that's the signature of comet water, and this is the signature of Earth's
water.
All water comes with a particular signature, a kind of fingerprint.
In the H2O, you just look at the H.
Hydrogen is actually really useful for tracing where water came from,
because there are two types of hydrogen.
There's normal hydrogen.
And then there's something called Deuterium,
which is twice as heavy as a normal hydrogen atom.
Because this kind of hydrogen is a bit heavier,
when it's part of H2O, scientists call it heavy water.
And the closer you get to the sun, the less of it there is.
So we can measure the ratio of normal hydrogen versus deuterium in any water from any part of the solar system.
And we can kind of piece that together and try and figure out where Earth got its water from.
But that fingerprint in Earth's water, it doesn't match comets.
We need to get that water from somewhere else.
So Lydia came across another even wilder explanation, wandering planets.
So people tend to think that the plants.
planets were born and they've been in the same place since they formed, but that's not true.
A lot of models suggest that Jupiter and Saturn moved right in, actually, towards where Earth is
orbiting now, and then they went back out again.
After the early Earth formed, Jupiter may have been pulled inward by the Sun's gravity.
As it moved, it would have pulled tons of objects from the outer solar system along with it,
including ice-covered asteroids that were far enough from the sun
that their ice hadn't already vaporized.
Lots of those water-rich asteroids were actually brought in to where Earth was orbiting around the sun
in the inner solar system.
And it caused lots of collisions with Earth.
So without Jupiter, Earth might not have had any water.
But without Saturn, things could have been even worse.
It seems as though our solar system is very special in that we have had,
We had Jupiter, but we also had Saturn, which pulled Jupiter back.
When Jupiter wandered in, it might be that the only reason Earth didn't just fall into the
Sun was gravity from Saturn.
The masses are just correct, and the distances between the planets are just correct,
so that you end up with Jupiter migrating back out again and leaving behind these four rocky
planets that have formed in quite a special situation.
Without this improbable balancing act, if Jupiter and Saturn were even slightly different sizes,
there wouldn't be an Earth.
No water on it. No life as we know it.
Scientists often talk about the Goldilocks zone, that Earth isn't too far from the sun for warmth and liquid water.
It's also not too close that we'd burn up.
But it turns out there's this whole different Goldilocks zone on the other side.
We're just the right distance from Jupiter and the sun that we got water.
And then Jupiter is just the right distance from Saturn that the solar system didn't completely burn up.
This whole thing almost reminds me in one of those Rube Goldberg type contraptions,
where you pull a string and launch a ball, which lands perfectly in a cup, which lights a match or something.
One tiny thing goes wrong, and the whole thing falls apart.
All of these things had to match up to make Earth.
the planet that it is today, and that seems like quite a rare and special situation.
If the wandering Jupiter theory is true, the fact that we have the right conditions for life
at all is essentially a miracle. Maybe a planet like ours is just rare, and there isn't any
other life out there. Maybe the universe is just kind of lonely. But Lydia wasn't so sure. She thought
this whole Rube Goldberg machine might not be necessary at all.
So she went back to the very first assumption.
And she questioned it.
Do you form a rocky planet completely dry and then wait for this kind of lottery of delivery
from asteroids and the outer solar system to get water?
Or is there water there actually primordial water that's in there in the first building
blocks of Earth?
And to me, it seems improbable that you could actually form any mineral completely dry within the solar system.
Lydia goes primordial water hunting.
After the break.
It's all about you.
And when you fly with Virgin Atlantic in their upper class cabin, they take the VIP treatment to the next level.
With a private wing to check in and your own security channel at London Heathrow,
you can glide from your car to their clubhouse.
a destination in its own right in 10 minutes or less.
On board, you can treat yourself to your own private suite to stretch out in
with lots of storage space, a lie flat bed, and delicious dining from beginning to end.
Just be sure to leave room for dessert.
Their mile high tea with all the little cakes and sandwiches is a showstopper.
Go to virginatlantic.com to learn more.
This episode is brought to you by Defender.
With its 626 horsepower twin-turbo V8 engine,
The defender, Octa, is taking on the Dakar rally.
The ultimate off-road challenge.
Learn more at landrover.ca.
Lager in a vase full of water.
Lydia had assumed that because Earth was so hot when it formed,
it must have gotten its water after it cooled down,
which would have meant that the only reason we have water at all
is because we won this giant interstellar lottery
of wandering planets balancing just right.
But then about 10 years ago, just as Lydia was finishing up her PhD,
scientists were examining moon rocks, and they found something shocking.
They found that there was water content inside the rocks that were brought back by the Apollo missions.
These rocks showed that there was likely water deep inside the moon.
The last place that you would ever expect there to be water, and there is a measurable water content.
Just like the Earth, the moon was incredibly hot when it formed.
but somehow it still had water in its rocks.
It just goes to show that water clings around in very high-temperature environments.
So Lydia had an idea.
Maybe water was locked so deep inside Earth that it didn't evaporate.
If that were true, it would mean Earth's water and all that life that ultimately came from it
isn't as improbable as scientists thought.
So she set out to find some of the oldest, deepest, most undisturbed,
on the planet to see if she could find primordial water locked inside Earth's original building blocks.
I'd heard about these lava flows near Baffin Island in Canada that were thought to be from a source
that is unaffected by any plate tectonic recycling or any surface effects for around about four billion
years. These lava flows had hardened into rocks a long, long time ago. But they have large,
what are called olivine crystals inside them.
It's a green mineral.
And these crystals are thought to crystallize really, really deep down.
And my thinking was that if those contain water,
then some of that water might be from the Earth's earliest formation.
So Lydia hooked up with a group of professional climbers,
and they headed to the Arctic Circle.
It's an area called Palavik Island,
which is off the southeast coast of Baffin Island,
near a very isolated town called Kikatarovik,
which you can only get a plane in and out of.
There's no train, there's no road that goes there.
So it's a very isolated place.
Not totally isolated.
It's also infested with polar bears,
so we had to get a boat out there,
and the boat captain actually pointed out that there were two polar bears
overlooking where we were going to be dropped off.
And I thought, oh, that means we're going to go somewhere,
else. And he was like, okay, then bye. And he just left us there with the polar bears.
But they were nice polar bears.
Most of them just sit and stare at you and make sure that you don't go anywhere near them.
And if you avoid them, they're quite happy to avoid you.
The main problem was less polar bears and more just getting to the actual rocks.
The lavas form these huge big cliffs. So to actually sample the rocks is very deep.
difficult and quite dangerous because they're just in huge big cliffs that are kind of on this
uninhabited island and that fall down into the sea. So I really appreciated the help of professional
climbers. She got ready to climb up and she grabbed some extremely technical scientific tools.
I just had a hammer and I was just trying to get a fresh piece of the rock out of the cliffs.
But the issue is they're also quite crumbly. So then if you start to climb the cliffs, there's big chunks
just coming off in your hand and they're quite dangerous really.
Eventually, Lydia was able to climb,
and she managed to get a fresh piece of rock out of the cliffs.
She cracked it open, looked inside, and she found it.
Primordial water, H2O.
But it wasn't liquid.
It was locked inside what looked almost like glass.
Tiny little glass beads that are trapped within those big green crystals of olivine
that I was looking for, that's been protected by those crystals ever since it erupted
and has been sitting around on the surface of Earth.
Lydia was pretty sure these rocks were from the initial formation of Earth, which meant
this primordial water had been here the whole time.
But she still needed to figure out where this water actually came from.
We could measure Earth's very first primitive water and see what kind of area in the solar
system that primitive water's hydrogen matches up to.
Lydia's work is still ongoing.
It involves not just these rocks, but other similar ones she's been collecting for years.
But so far, she's found a big clue.
When she looks at hydrogen fingerprints and rocks like these, they don't match comets or
the asteroids brought by Jupiter in the early solar system.
Some of this water must have come from somewhere else.
The only signature that matches in the solar system, the solar system, the only signature that matches in the
solar system is the sun. So it's suggested that Earth has at least some of its hydrogen and water
directly from the sun. Just think about that for a second, that some of Earth's water might have come
from the sun. It's hard to wrap your head around exactly what that means, but here's how it
could work. The sun is constantly shooting out solar wind, this type of radiation mostly made up
of hydrogen.
And rocky bodies in our solar system
are mostly made up of silicon and oxygen.
And when you introduce hydrogen into that mix,
sometimes the silicon oxygen bond can be broken
and hydrogen actually attaches itself to that oxygen.
So you end up forming water inside the rock.
You take hydrogen from the sun,
you add it to oxygen in the rock,
and you get H2O.
It's not liquid, it's not gas, and it's not ice.
It's water that's actually entwined into the rock itself.
Water is present as H2O molecules,
but it's kind of attached within the crystal structure.
So it's a solid part of the crystal.
And so it's protected from being evaporated by high temperatures.
Lydia thinks this could have happened in the very early solar system,
that even before Earth formed,
solar wind would have hit the very first piles of debris floating around
and baked water into those rocks.
So when the earth did form,
that water could have stuck around through the blistering heat.
And then millions of years later,
it could have made its way up through volcanoes.
Where it would be churned out as gas onto the surface.
So you would actually entrap that water into the atmosphere
and then potentially you get rain,
you get rivers, lakes, and eventually oceans.
That's why Lydia was so excited that the hydrogen signature she found in the rocks matched the sun.
And that supports the fact that early on in the solar system,
those first solid minerals that formed in the solar system were irradiated by the sun
and then were incorporated into the earth.
So Earth wasn't formed completely dry.
So it's possible that even without that improbable,
water delivery from a wandering Jupiter, Earth could have become a blue marble.
We don't think it's too long after Earth formed that there's liquid water present on Earth.
And there is chemical evidence to suggest that the very earliest Earth may have had oceans.
Not everyone is sold on this whole idea. There's a chance the hydrogen signature could have
changed over time. So Lydia's analyzing other elements in the rocks to make sure the hydrogen
really did come from the sun. But she's pretty sure that,
that at least some of Earth's water
was here the whole time.
That's not to say that
asteroids didn't hit Earth
later on and deliver some water
because I'm sure they did.
But the initial Earth that formed
wasn't 100% dry. It did have
an initial water content.
Lydia's not sure exactly how
much water was here from the start
or how much water was delivered
later by asteroids along with this
wandering Jupiter situation.
But if she's right, and even
any water was here from the start. If any water survived that early fireball Earth phase,
it has big implications. Maybe it's just that water is everywhere and that it sticks around in the
rocks. And so wherever you form a rocky planet, you're likely to have some water content on that
planet. Maybe our water isn't as rare as it seems. And I think that's the most important thing
to kind of come from this theory is that if you don't need delivery from the outside,
solar system of water and Earth formed initially with its water or at least some of its water,
then anywhere that you form a rocky planet in any solar system, you may end up with a water
content on that planet, which could be supporting life.
And if that's true, it means the chances of finding water on other planets goes up dramatically.
It means the baseline conditions for life may not be all that unlikely.
I think if you'd have spoken to me or someone else sort of 30, 40 years ago,
we would have said that Earth is really special because it's the only water-rich planet.
But the more we look at extraterrestrial materials from other planets and other solar system bodies,
the more we realise that there's water everywhere, sort of even in the outer solar system,
the moons of Jupiter, some moons of Saturn have got maybe liquid oceans beneath their ice crusts
and they're very water-rich.
So it's something that's everywhere.
And if that's important for life,
then it's kind of revolutionary, really,
to know that water's so common.
But water is just the first step.
You need something extra than just a habitable environment.
So you need something extra than just liquid water
and a friendly environment for life.
We don't know what that is.
Next week on Ununexplainable,
the origin of life.
If you asked any two Origin of Life researchers what they think the very first life look like, you will almost certainly get different answers.
This episode was reported and produced by me, Noam Hassanfeld.
It was edited by Brian Resnick and Catherine Wells.
We had mixing and sound design from Christian Ayala with help from Meredith Hadnott, who did a ton of work on the vision of this whole origin series with Brian.
We had fact-checking from Zoe Mullick and some of the best vibes around from Manding Wyn.
win. Bird Pinkerton slowly walked over to the wall and picked up that can of soda. She opened up the
top, but instead of Fizz, a small man hopped out. The name's Pepper. He said.
Dr. Pepper. Special thanks this week to Pan Conrad for her help wrapping my head around all of this
stuff. And if you have thoughts about this episode or ideas for the show, please email us.
We're Unexplanable at Vox.com, and we'd also love it if you left us a review or a rating.
Unexplainable is part of the Vox Media Podcast Network, and we've got more episodes of origins coming your way the next two weeks.
Stick around.
Rosen lasagna, medium power, 15 minutes.
Sounds like Ojo time. Let's play.
Feel the fun with Play-Ojo.
The online casino with all the latest slot and live casino games.
What you win is yours to keep.
With no wagering requirements.
Instant payouts and no minimum withdraws.
Hey, I just won.
Woohoo!
Feel the fun!
Play, oh Joe!
Honey, forget about the lasagna.
Let's celebrate!
19 plus Ontario only.
Please play responsibly.
Concern about your gambling or that of someone close to you.
Call 16-531-2600 or visit connexonterio.ca.