Daniel and Kelly’s Extraordinary Universe - What will the DragonFly mission find on Titan?
Episode Date: December 17, 2020NASA is building an awesome drone to fly around the surface of Saturn's moon. What will it find? Learn more about your ad-choices at https://www.iheartpodcastnetwork.comSee omnystudio.com/listener fo...r privacy information.
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December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, everything changed.
There's been a bombing at the TWA terminal.
Just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, terrorism.
Listen to the new season of Law and Order Criminal Justice System
On the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam.
Maybe her boyfriend's just looking for extra credit.
Well, Dakota, luckily, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend's been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other, but I just want her gone.
Hold up. Isn't that against school policy? That seems inappropriate.
Maybe find out how it ends by listening to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Hi, it's Honey German, and I'm back with season two of my podcast.
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You didn't have to audition?
No, I didn't audition.
I haven't auditioned in like over 25 years.
Oh, wow.
That's a real G-talk right there.
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We'll talk about all that's viral and trending
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And of course, the great bevras you've come to expect.
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Hey, Jorge, you're a robotics expert, right?
Well, I have a PhD in robotics, so I think that might qualify me.
Awesome.
Well, how do you feel about using robots to explore space?
I think it's great.
Better them than me.
Yeah, because on some dangerous missions, we send robots rather than people.
But do you ever, like, worry about the robots?
Well, we try not to program feelings into them.
So I guess not so much.
Even though the robots don't always make it
I think that's okay
I think we are proud still
of what the robots achieve
I think it's weird sometimes though
that we never bring those robots home
we send them out to space
we run them into the ground
and then we just sort of abandon them
well what do you think would be cool
to bring them home and throw them a parade?
Yeah maybe all the other robots
would be so proud
but then who would clean up all the ticker tapes
we have to send robots to clean up after the parade
robots should make their own robots
and that's how it all ends Daniel
Hi, I'm Horam, a cartoonist and the creator of PhD comics.
Hi, I'm Daniel. I'm a particle physicist, and I'm looking forward to working with robotic physicists.
With robot physicists or four robot physicists? Which feature do you foresee for science?
Whatever gets us to the deep truths of the universe, I'm on board for that.
Really?
You would subjugate yourself to the AI overlords in exchange for deep secrets of the universe?
Yeah, I'm not going to put my ego in front of revealing the truth about nature.
None of this, I have to be in charge because I'm human, even though you're much smarter than I am.
Absolutely not.
I'm happy to work for a genius robotic physicist.
Do you think robots would be interested in the deep secrets of the universe?
What would be their motivation?
Yeah, that's a good question.
We would have to program them to be interested.
We have to like train robots to be excited about it and then set them loose and hope that the answers they find are things that we can even understand.
I feel like we're so bad at raising children now.
The idea of raising super intelligent robots doesn't sound like a good idea.
Well, wouldn't you prefer to program children rather than raise them?
That's what television is there for, Daniel.
That's why they make kids' TV shows.
But anyways, welcome to our podcast, Daniel and Jorge Explain the Universe,
a production of iHeartRadio.
In which we try to understand the entire universe
before our AI overlords do it for us.
We think about all the crazy questions out there.
Where is life? Where could it start?
What are tiny little particles doing anyway?
What's going on inside the heart of a black hole?
We take these mysteries, we join them with your curiosity,
and we try to find explanations that make sense to you.
Because the universe is huge and there's a lot to explore.
There are a lot of mysteries out there in the vast reaches of space
and other galaxies and other galaxy clusters and black holes.
And there's also a lot of mystery right here in our own backyard, universally speaking.
Yeah, that's right.
It's incredible how much of the universe we can see just from our tiny little perch on this rock.
Using our incredible telescopes, we can see things that are super far away and answer,
really big and vast questions about the nature of the universe.
But sometimes you want to get off your rock and you want to actually go to another place
and get like up close pictures or see through cloud cover or dip your robotic toe into
some alien ocean and see what's actually there.
Yeah, because it's sort of funny now that I think about it, the difference between how far
we can see and how much of the universe we know about and how much of it we've actually
been to, which is almost nothing.
Like we hardly ever left this little ball of rock that we call Earth.
Yeah, we've explored almost literally nothing of the universe.
It's sort of like we're trapped on this tower and we can look out these windows.
We can see this incredible view, right?
So far away.
But it's so difficult to get anywhere.
We've explored basically almost nothing.
But, you know, there are a few opportunities nearby.
We can hop to one or two nearby towers.
But yeah, we're basically in a little tower prison.
Yeah.
And also, it's hard to get off your couch, you know, sometimes.
I mean, it's a lot of work to get out of that tower.
You have to, like, put together a rocket.
You have to strap in.
Is this your application to be an astronaut?
Because it's not going very well.
My application not to be drafted into Space Force.
This is my deferment application.
I don't think you have to apply to not be an astronaut.
I think that happens automatically.
But good luck.
Well, it is fun because there are a lot of things in our backyard,
in our own solar system that we don't know about.
lot of fun places we could go and explore and maybe even visit one day.
Yeah, and there are surprises around the corner. There are lots of weird things happening in our
solar system, things that we don't understand, things we would like to see up close. And every time
we open up a new kind of eyeball to the universe or land on a new surface, there's always something
new and weird waiting for us, something that scientists didn't even know to look for, something
that people are shocked to discover, something that teaches us something about life or how the
universe works. So this is a very exciting time to be exploring our neighborhood, solar systemly speaking.
Yeah, we don't even know that there is life at all in the solar system. There could be life in
other planets or moons in our very own solar system. Yeah, I think the history is sort of fun.
Like for a long time, people imagined there might be life nearby on Mars. It was sort of like,
wow, there could be life everywhere. And then we sort of didn't see obvious signs. And I feel like
the public impression is that, well, there isn't any life in the world.
the solar system other than us, we have to look further.
But now people are starting to realize that's not true.
There are still lots of opportunities to discover life in our solar system.
From subsurface water on Mars to some of these oceans of the moons of Saturn and Jupiter,
there's all sorts of crazy stuff going on right here in our solar system.
Yeah, so today we'll be talking about a pretty cool project that's happening right now,
which is to send robots to a moon of Saturn.
That's right. It's very difficult to send people to actually walk on these surfaces to go take these long trips.
So instead, we send our future robotic overlords on these missions to go and explore these surfaces for us.
Do you think there'll be a good excuse when they try to take over?
We'd be like, but look, we send you to Mars. I mean, you can't complain that we never take you anywhere.
I don't know if that'll be in the plus or in the minus call of.
Like, you know, do you think they'll think that we treated those robotic explorers well, you know, just having abandoned them on
the service of Mars.
Yeah, well, what do dogs think about Lyca?
But anyway, so today on the program, we'll be asking the question,
What will the dragonfly mission find on Titan?
And the dragonfly mission is this super amazing, incredible robotic mission to explore Saturn's Moon Titan, which I am very excited about.
Yeah, so it's a lot of fun words there, dragonfly mission, Titan.
I feel like, you know, it'd just be cool to say you work on this project.
It does.
It sounds sort of like a future Michael Bay movie, doesn't it?
The Dragonfly mission.
Do you think Bruce Willis would come out of retirement?
Is he retired?
I don't know.
He's not allowed to retire.
I think there's an executive order preventing him from retiring.
But this is a pretty exciting mission.
And as usual, we were wondering how many people out there had heard of it or know what they're trying to find on that moon of Saturn.
So Daniel went out there into the wilds of the internet to ask,
What will the Dragonfly mission find on Titan?
And as usual, I am deeply grateful to those of you who are willing to answer random questions from a physicist without any preparation or looking up in reference materials.
So thank you very much.
And if you would like to participate and answer questions for future episodes without any briefing or preparation, please write to us to Questions at Daniel and Jorge.com.
So here's what people had to say.
I've heard that Titan might have liquid ocean.
of methane.
I might discover or research alternative forms of life.
If a dragonfly wasn't Titan, the first thing I'm sure that the dragonfly would realize
or would see would be the space shuttle that brought the dragonfly there, I'm guessing.
Second thing probably would be the big Jupiter in the background in the sky.
But other than that, I don't really know.
I actually didn't know there was a mission to Titan, but if I remember correctly,
Titan is a moon of Saturn, and Saturn has a crazy environment with diamonds floating around.
So there will probably be a lot of interesting compounds up there.
I know there's a lot of ice locked in the rings,
so it would be interesting if the moon was harboring some complex organic molecules.
Aliens, it looks like it is the focus of all NASA's mission for today
to investigate the early solar system in its formation.
Oh, I'm starting thinking like Juverne type of stories now.
My son finds something organic, who knows?
But I don't think it can be called quite alive.
But I'm seriously curious to find out.
Maybe Dragonfly discovers that Titan is a much friendlier place than Mars,
and then Elon Musk has to change his plans.
All right.
Pretty cool.
I like aliens.
Aliens was a good answer.
Well, I'm with one of the listeners here who said they didn't even know there was a mission to Titan.
I did not know there was a mission to Titan.
You know, usually people talk about Europa, which is a moon of Jupiter, or they talk about landing more things in our moon here on Earth.
But Titan, you don't really hear a lot about it.
Yeah, and one reason might be that this mission is still sort of deep in the future.
But, you know, they take a long time to plan, to build, to organize, to actually arrive at these distant locations.
And so it's like a 20-year life cycle of these missions.
And so that's why it might not be in people's minds right now.
Wow, it's a 20-year mission for real?
Oh, absolutely.
It takes years just to get there, years to plan it, years to fund it.
We're going to be getting data from this thing in like 2036.
Oh, my goodness.
And we assume there's going to be a civilization here to receive those signals.
Well, we're going to teach our robots to get those messages, right?
So they benefit from our work.
It's going to be in our collective will.
Oh, by the way, some of your ancestors might be calling at around 2036.
Pick up the call.
That's right.
And please, can we be last authors on the paper you eventually write?
But who would read the paper?
Other computers?
God.
Yeah, it'd be like that weird corner of YouTube where bots make videos for other bots.
Oh, my goodness.
Bots making science papers for other bots.
That is the future for sure.
Well, maybe a lot of people don't know what Titan actually is.
Or this might be the first time they hear that there's a moon on Saturn called Titan.
Daniel, what do we know about the moon of Saturn called Titan?
It's awesome. It's Titanic.
I mean, this thing is...
That's not a good analogy, Daniel.
I mean, it's not going to crash into an iceberg.
I just mean that it's huge and awesome.
Yeah, and it has Leonardo Capri in it.
What could go wrong?
That's right.
We're going to send Celine Dion actually to stand on it and sing as our first emissary to Titan.
No, it's 50% bigger than our moon.
It's bigger than Mercury.
It's huge.
Wow, it's bigger than one of the...
planets in our solar system? Yeah, exactly. If it wasn't orbiting Saturn, then you would
definitely call this thing a planet. And if you were standing on the surface of Saturn, if
Saturn had a surface, this thing is so big that it would be like 12 times larger in the sky of
Saturn than our moon is in our sky. It would be huge. It would be huge. Yes, exactly. So it'd be
pretty dramatic. Yeah, because Saturn has several moons. So you're saying, is this one of those moons or is this
the biggest one? This is one of those moons and it's the biggest one. And so it would dominate the
sky of Saturn. You couldn't actually see it though from Saturn because Saturn is just so cloudy.
You can't see out through its atmosphere. But that's how big and that's how close it is to Saturn.
So it's sort of a fun mental image. Does Saturn have like huge tides then? I'm just thinking
about the moon here. It affects the tides. Yeah, absolutely. Saturn squeezes Titan and titan squeezes
Saturn. And one of the reasons that Titan is so interesting is that it's not just a frozen ball. And part of that
is because it gets this tidal squeezing from Saturn.
Like also some of the moons of Jupiter have this effect
where they're getting pulled on by their home planet
and that squeezes them and keeps them from freezing solid.
And so just like some of those other moons,
we think that underneath the ground on Titan,
there are these vast oceans of liquid ammonia.
But there also might be liquid lakes on the surface of Titan.
Wow. Wait, do we have pictures of Titan?
Have we ever flown a satellite or probe nearby
and taking pictures?
Can I Google that?
You can actually.
You can get pictures
from the surface of Titan
because in 2005,
we had a lander that landed on Titan.
So this is the record
for the most distant surface
that we've ever landed an Earth probe on.
And it landed just in one spot.
And one interesting thing about Titan
is that it has a really dense atmosphere.
Most of these moons have no atmosphere.
And Titan itself actually has a really dense atmosphere,
but that makes it hard to see the surface from space.
So we had an orbiter going around,
Titan for a while taking pictures, but you couldn't really see the surface because of the dense
cloud cover. It just sort of looks like Jupiter does. Did you see clouds? Yeah, or Venus. Exactly.
So we dropped a probe onto the surface and you can get this picture from the surface of Titan.
I mean, all you see basically is a plane with a bunch of rocks in it. But you can tell from how that
surface looks that like, you know, water used to flow on the surface. It's sort of awesome and fascinating
to see a picture from a foreign surface. Oh, wow. So we actually landed the probe? We didn't just
crash it, like it landed and took pictures. It landed and took like a picture and sent it back.
But it was sort of stuck in one location, right? It just landed and stuck there. It wasn't a rover.
Couldn't move around. And so it was pretty exciting, but kind of limited. So we have visited Titan
before and we have landed something on it. But the dragonfly mission we're going to talk about
today is going to explore it in much more depth. And we think the Titan is pretty interesting.
Titan, we think actually looks a lot like Earth. I mean, there's like dunes and rivers and lakes.
the sort of the geology of the surface
we think is very similar to what Earth looks like.
Oh, wow. So wait, from space,
you can't see the surface because of the
clouds, but once you're in it,
you can sort of look around and
see the landscape.
Yeah, and from the surface, you can do things like
radar and stuff like that. You can see
that there are lakes on the surface.
This is the only other place in the
solar system we know about that has
surface liquid. Now, it's not
surface water. Most of this is like
methane. So, tighten it's
sort of like Earth, but you take away all the water
and you replace it with liquid methane.
Wow, that sounds like it would smell
terribly. Exactly. But
you have like methane lakes and methane
rivers and methane rain
and you have wind. And you
can see a lot of this stuff from the orbiter
because you can see through the cloud
using some radar, etc.
So we know that there are lakes on the
surface. We know this stuff happening. This erosion.
There's all this geology.
It's fascinating. So it looks rocky.
Like here, like if you were, it looks
It's like a rocky landscape with pools of ammonia.
Yeah, exactly.
And rivers, you know, and rain and all sorts of stuff.
Rivers of ammonia.
Rivers of ammonia.
Yeah, and lakes and all sorts of stuff.
I don't know if there are alien fish jumping up from idyllic lakes, you know, nestled in mountains or anything.
But that's sort of what the mission is aiming to look for.
Wow.
Well, there probably are fish.
They're just holding your nose the whole time.
No, they're used to it.
They love it.
They think water smells terrible.
All right.
So then what is the atmosphere made out of?
It's like breathable air or is it poisonous gas?
Well, like Earth's atmosphere, it's mostly nitrogen.
It doesn't have oxygen in it so we couldn't breathe it.
But it's a very, very dense atmosphere.
That actually plays a really big role.
We'll talk about in a minute into how this dragonfly mission works.
All right.
Let's talk about the mission that's going to explore this moon on Saturn.
And then actually, Daniel, you have an interview with the two leads of the project.
And they're going to fill us in on what it's like to lead.
this mission and to think about what to find on Titan.
But first, let's take a quick break.
December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal, glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and order, criminal justice system is back.
In season two, we're turning our focus to a threat that hides in plain sight.
that's harder to predict and even harder to stop.
Listen to the new season of Law and Order Criminal Justice System
on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam.
Maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging.
he out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now, he's insisting we get to know each other,
but I just want her gone.
Now, hold up.
Isn't that against school policy?
That sounds totally inappropriate.
Well, according to this person, this is her boyfriend's
former professor, and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person to believe him
because he now wants them both to meet.
So, do we find out if this person's boyfriend
really cheated with his professor or not?
To hear the explosive finale, listen to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
I had this overwhelming sensation that I had to call her right then.
And I just hit call.
I said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation.
And I just wanted to call on and let her know there's a lot of people battling some of the very same things you're battling.
And there is help out there.
The Good Stuff Podcast Season 2 takes a deep look into One Tribe Foundation, a nonprofit fighting suicide in the veteran community.
Community. September is National Suicide Prevention Month, so join host Jacob and Ashley Schick as they bring you to the front lines of One Tribe's mission. I was married to a combat army veteran and he actually took his own life to suicide. One Tribe saved my life twice. There's a lot of love that flows through this place and it's sincere. Now it's a personal mission. Don't have to go to any more funerals, you know. I got blown up on a React mission. I ended up having amputation below the knee of my right leg and a traumatic brain injury because I landed on my head. Welcome to Season 2.
of the good stuff.
Listen to the Good Stuff podcast on the IHeart Radio app,
Apple Podcasts, or wherever you get your podcasts.
All right, Daniel, we are sending dragons, flying dragons to tiny.
Well, sort of.
We're sending a drone.
This thing is super awesome.
Basically because all the advancements in drone technology here on Earth,
You know, everybody has like a drone to do everything.
We're now turning our robotic probes into other surfaces into drones as well.
So this is an actual NASA mission.
It's on now and it's going to be on for the next 20-something years.
And the idea is to send literally a drone like a flying little machine to explore the surface of time.
Yeah, exactly.
It's an octocopter.
It has eight of these rotors.
Each one is like a meter wide.
And it can fly around the surface and the course.
thing is that that allows it to like really explore the surface sort of the way a rover does
but without having to like drive slowly from place to place.
This thing can go like 10 meters per second.
That's like the speed of Usain Bolt, you know, so we can really explore the surface of Titan.
Wow.
Yeah, because I guess we send robots to Mars and then they're really slow, right?
They are really slow.
They can't like they get stuck inside of holes or they can't go for mountains or rocky terrain.
So this is like a perfect solution.
Yeah. And, you know, I always wonder what that's like. I think that for the rovers on Mars, they have to have like meetings. They're like, how are we going to get around this rock? All right. We're going to go this way. They want to turn left and then we're going to stop. We're going to turn right. And it's, you know, pretty crazy. And they have to be pretty crazy because, you know, they flip this thing over and it's like a turtle on its back. So the drone is pretty awesome because, yeah, you can skip over stuff. You can really explore. But you can do a drone on Titan much more easily than you can do a drone on Mars for one really important reason. And that's because Titan has a very dense.
atmosphere. Right. The denser the air, the easier it is to fly. Yeah, exactly. The reason that helicopters
can't go to the top of Mount Everest, for example, is that the air gets too thin. They're like beating
their rotor blades against nothing. And on Mars, it's very difficult to build a helicopter,
though they're going to try that. But on Titan, it's a perfect application for a drone because there's
really, really thick atmosphere. So it's sort of more like swimming than flying. Plus, the gravity is
pretty low. So flying around Titan is really the best way to get around. So I guess it's smaller than
Earth. So what's the gravity like on Titan? Yeah. So Titan is like 2% of the mass of the Earth. So the
gravity on Titan is definitely much, much less. But the atmosphere is thicker than it is here on Earth.
So it's really a great application for a drone. Wow. So does that mean it's like, you know,
150th the gravity as we have here? It's definitely a lot smaller. It depends also on the radius, right? So
Titan is smaller than the Earth.
And so that's going to enhance the gravitational factor.
But so, you know, approximately like a tenth of the gravity of Earth.
But again, a thicker atmosphere.
And so that allows this thing to really, like, float around the surface and figure out, like, what's going on on Titan, what's here, what's there, what's exciting to look for.
Right.
Catch some ammonia fish.
Sit by a lake.
Take some selfies.
It's a fascinating project because they think, they hope that the surface of Titan is a great place to answer questions like, what did Earth used to look like?
they see it as sort of like an early Earth.
Really? Like our planet used to also be like this, like a full of ammonia and nitrogen?
Well, it has a different atmosphere, right?
We don't think that it had the same chemical composition.
But it's sort of this progress of starting from hydrocarbons.
How do you form the basis of life?
How does that come together to make the chemistry you need and then eventually the biochemistry?
And so Titan is sort of like, you know, behind the earth in that process.
And it gives us a window to understanding like what forms first.
First, how did these things come together?
I guess maybe one question is, you know, this sounds great,
but drones run out of battery at some point,
and it's cloudy in Titan.
How does this get any energy if it's flying around?
Yeah, you can't use solar power,
not just because it's cloudy on Titan,
but because remember, Saturn is really far away from the sun.
So the solar power is really, really dim.
So this thing has a pretty cool system.
The drone itself has a lithium ion battery,
just like the kind of things you find in your laptop.
Then there's like a power station.
that can recharge it.
And it's recharged by a radioactive thermoelectric generator.
That's something that's basically a big pile of plutonium,
which is decaying radioactively and heating up a little system,
which turns that heat into electricity.
Wow, it has like a nuclear power plant on it.
Yes, exactly.
So got a nuclear power plant,
which is going to last for a long, long time,
and then it can fly around for like 10 kilometers and come back,
and then it's got a recharge.
Right.
And this is not new.
I think most of the Mars rover
have a nuclear power plant, right?
Yeah, this is not new.
We've been doing this for decades,
powering distant systems with nuclear power plants.
So that technology is pretty well established.
Cool.
And so how are we going to fly this thing around?
Is it autonomous or is there like a joystick control?
No, it's way too far away for us to control it in real time, right?
The time for light to get to tighten and back is tens and tens of minutes.
So there's no way that you want to be flying this thing around.
So it's going to be pretty autonomous.
It's going to take a lot of AI and careful calculations to drive itself around.
But, you know, flying is simpler than driving because as long as you're above the obstacles,
you know, you're mostly free to move around.
But this thing also has to sort of land autonomously.
And it's got this crazy plan for how to get down to the surface.
Wow.
Let's talk about that.
How is it going to land on, like, are we deploying the little helicopter from space?
Or are we landing like a launching pad and like a whole like mini spaceship and then the helicopter
emerges from that. Yeah, it's pretty crazy. We're sending this thing to tight. It's going to arrive in
2036 and it's got this like dual parachute system to come down closer to the surface. And then when
it's about a mile from the surface, just over a kilometer actually, then the lander is going to be
released for powered flight to the surface. So it's going to fly itself down to the surface
autonomously. It's going to like figure out exactly where to land and how to get there and avoid
boulders and all sorts of stuff. It's going to actually like fly it.
itself to the surface, which is pretty cool.
And, you know, it's 70 light minutes from Earth, which means it's going to happen,
and then we're just going to wait an hour and 10 minutes to hear about whether it crashed
or whether it was successful or what.
Wow, that's crazy.
But I guess we're landing something, like a little spaceship, and then the helicopter
comes from that, or is the whole lander the helicopter?
The whole lander is the helicopter.
It's all in one.
It could fly around, and then when the battery is exhausted, it can sit on the surface,
surface and slowly recharge the battery from the power plant. It uses power faster than the power
plan generates it. So it operates in bursts while the battery recharges. And it's also a plan
that it's only going to explore it during Titan's daytime. Oh, interesting. How often does
the day happen in Titan? Well, night on Titan lasts for 192 hours. It's like eight Earth days.
That sounds like a pretty good nap there. Exactly. So it's got a lot of time to sit there and
recharge and for humans on Earth to make a plan for the next exploration.
So it's going to be a lot of fun.
And then the daytime lasts another 192 hours?
Oh, wow.
Yeah, I don't think I can work that long.
Even if you slept 192 hours, I wouldn't power you.
Maybe we should get a nuclear power plant inside you.
Maybe that would help you.
Yeah, that's what we all need.
Some plutonium in our diet.
All right.
So that's pretty cool.
So it's launching in 2027.
It's going to take really nice.
nine years to get there? It's far away, right? This solar system is huge. And this is basically
the edge of the outer solar system. And, you know, to get there on a low budget, they're going to
pass it by Earth a few times for a gravitational assist. So you don't need to have as like as
powerful a rocket. So yeah, it's going to take a while to get there. It's not going to arrive for
nine years. Wow. So what do the scientists do for nine years? To just like take a break? Like,
all right, we'll go grab some coffee, come back in nine years. They think about all the mistakes.
made in the design and they worry, worry, worry. Wow. Sounds tough. No, and they make science plans for
what they're going to do when it lands. They still have power to control the choices it makes for how
it's going to explore Titan. And so they just get to think about that. But that's a question I asked
the scientists. So you'll enjoy hearing their answer. Yeah, because the drone will have a lot of
cool instruments. Like what kinds of things does it have and what is it going to be looking for?
Yeah, well, it's got cameras, first of all, like tiny little cameras for looking at stuff close up.
and then panoramic cameras, because one of our questions is just like, what does the surface look like?
You know, most of it is shrouded by clouds.
And we've seen this one picture from this one spot that our probe landed, but we're just curious,
like what does the surface look like?
And then there's things like a mass spectrometer.
That's something that can take chemicals and tell you how heavy each molecule is.
So you get an idea for like what's there, which elements are there, which like, you know,
organic molecules have come together.
And then they want to measure the surface composition.
So they have like a little gamma ray and a neutron spectrometer that can ID the surface composition, you know, bouncing things off of it and seeing how they react.
And then they have a seismometer, something that's going to measure like the internal structure of Titan, listen basically for Titan quakes.
Wow, for like iceberg crashes just in case.
Yeah, because they think that there's internal interesting structure on Titan.
They think that there's a lot of ice and rock in there, but there might also be like huge oceans of liquid methane that burp up.
up to the surface, they're like crack up to the surface and make these cryo-volcanoes,
these volcanoes that shoot out water and methane vapor.
Whoa.
But it sounds like mostly it's just sort of too, I mean, there's a lot of great signs,
but it's just really, I mean, the big idea is just to go there and see what it's like, right?
Just to like look around and see how it's different and the same from Earth.
Yeah, exactly.
It's a mission of exploration.
You know, it's like the first time the humans ever walked on a new island or something,
we just didn't know what we would find.
and that's the excitement of exploration is the potential for crazy surprises.
So if what scientists think is happening on Titan is happening,
they'll get a lot of fascinating measurements.
We'll learn a lot about how life started and chemistry and all that cool stuff.
But the really exciting thing about this on top of flying a drone on an alien moon
is the possibility to see something weird, something new, something unexpected, something just like shocking.
And I love imagining that first moment, you know, 20 years into the mission,
when they're going to get the first picture back
from the surface. It's going to appear
line by line on the screens
at NASA. And they're going to be there at the edge
of their seats like, wow, what is this picture
going to show us? Yeah, because they might even
find life, right?
Is that one of the things they're going to be looking for?
Do they have instruments to look for life
on Titan? Yeah, they might find life.
They might find very, very simple life,
you know, microbial life in these lakes, etc.
And it's difficult to identify
life at all.
You know, even here on Earth, if you take
like a sample of water and you give it to a microbiologist and ask, like, are there living
things in here? Basically, they just like use microscopes and look up close and see if they see
things wiggling. It's difficult to do on an alien surface with limited technology. What they plan
to do is like you use the mass spectrometer to figure out like what molecules are being created
and then argue about whether or not those things can be created without life. Sort of like how we
thought we saw phosphine on Venus, remember? And we think that phosphine is only made by life. If you
see things on the surface that we think are only made by life, then you can argue life must be
there. Otherwise, you have to like actually find like a little microbe. But, you know, they have
microscopic cameras. So maybe they'll actually see something wiggling. Cool. Well, that would be
pretty good picture. That would be a historic photograph for sure. Yeah. All right. So Daniel,
you talked to the two leads on the project, Dr. Elizabeth Turtle and Dr. Melissa Traynor. And
they're the like the heads of the project. Yeah, exactly. Elizabeth Turtle is the PI.
and she sort of runs the whole mission, the planning, the projects, sending the thing over.
And Melissa Traynor is sort of the head scientist in terms of the instruments and what questions they're going to be asking.
And so I had a lot of fun talking to them about this mission and what it's like to work on a 20-year-long project.
All right. Well, let's get into your interview with the two leads to the Dragonfly mission.
But first, let's take a quick break.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a nuke.
kind of enemy emerged, and it was here to stay. Terrorism.
Law and Order Criminal Justice System is back. In season two, we're turning our focus
to a threat that hides in plain sight. That's harder to predict and even harder to stop.
Listen to the new season of Law and Order Criminal Justice System on the IHeart Radio app,
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My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Well, wait a minute, Sam, maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now, he's insisting we get to know each other, but I just want her gone.
Now, hold up. Isn't that against school policy? That sounds totally inappropriate.
Well, according to this person, this is her boyfriend's former professor, and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person to believe him
because he now wants them both to meet.
So, do we find out if this person's boyfriend really cheated with his professor or not?
To hear the explosive finale, listen to the OK Storytime podcast on the Iheart Radio app, Apple Podcasts, or wherever you get your podcast.
I had this, like, overwhelming sensation that I had to call it right then.
And I just hit call.
I said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation.
and I just wanted to call on and let her know
there's a lot of people battling
some of the very same things you're battling
and there is help out there.
The Good Stuff podcast, season two,
takes a deep look into One Tribe Foundation,
a non-profit fighting suicide in the veteran community.
September is National Suicide Prevention Month,
so join host Jacob and Ashley Schick
as they bring you to the front lines of One Tribe's mission.
I was married to a combat army veteran
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One Tribe saved my life twice.
There's a lot of love.
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two of the good stuff listen to the good stuff podcast on the iheart radio app apple podcast or
wherever you get your podcast
All right, we're talking about the Dragonfly mission to Titan,
which is to send a flying octocopter with a nuclear-powered energy station
and have it fly around one of the moves of Saturn, which is enough.
I'm sold.
Sounds like a pretty cool project.
And Daniel, you talked to the two leads on the project,
Dr. Elizabeth Fertil and Dr. Melissa Traynor,
about what it's like to work on this long-term and exciting mission.
I did.
I was really glad that they took some time out of their busy schedule.
preparing for this crazy event in 20 years to talk to me about the science.
All right.
So here is Daniel's interview with the leads of the Dragonfly Mission Project.
All right.
So I'm very pleased to have two wonderful science guests on our program today.
Could you two introduce yourselves?
Sure.
I'm Zibby Turtle.
I'm at the Johns Hopkins Applied Physics Laboratory.
And I'm the principal investigator of the Dragonfly New Front.
eteer's mission to tighten.
I'm Melissa Traynor.
I work at NASA Goddard Space Flight Center, and I'm working with Zibi on the Dragonfly
Mission.
Wonderful.
Well, thanks very much for coming on our program and answering a bunch of our science
questions.
I want to dig into the science of your mission and how it's all going to work.
But first, I have a request from my daughter.
She's 11 years old, and when I told her I was going to be interviewing you, too, she said,
she had a question for you, which was, how do you get to work on such a fun NASA project?
So maybe you could each tell us a little bit about how you're going to be.
got to be where you are. Sure. I've always been interested in the planets, you know, in the
stars and, you know, astronomy and planetary science. And so I studied a lot of science and math
in high school and college. I majored in physics and college at MIT. And I then went on to
graduate school in planetary sciences at the University of Arizona. And I've worked in a few
different missions over the course of my career so far, including the Galileo mission that went to
Jupiter and the Cassini mission that went to Saturn and, of course, studied Titan among lots of
other things in the Saturnian system, and the Europa Clipper Mission, as well as Dragonfly, and a few
others as well along the way. Very cool. So you knew from the beginning the kind of things you wanted
to study. Yeah, I've just always been interested in planetary science and astronomy. I can't remember
learning the planets. I've always, like they were part of my geography from before I remember
learning them. Cool. And you, Melissa? Sure. So a lot like what Zibby said, I was always very
interested in science and math when I was in elementary school and high school. But I decided to
go ahead and major in chemistry because I really love doing hands-on lab work. So my original
thought wasn't necessarily that I would be studying planets, although I found them fascinating. But when I
went to graduate school. I was thinking I was going to study Earth's atmosphere to do atmospheric
chemistry on Earth. Turns out Earth's the planet. So a lot of the same rules and interest apply.
And I actually ended up doing a really interesting project that was studying the type of organic
synthesis that happens in Titan's atmosphere and drawing connections not to Earth today,
but to Earth billions of years ago, what the planet might have been like a long time ago.
And the atmosphere had a different composition, and you might see chemistry like what we found Titan.
So I wasn't involved in any missions. I was in graduate school, but the type of work I did,
I also studied some processes that we thought might be occurring in Mars was the atmosphere.
And the types of tools I used in the lab work I did, ultimately is how I got my job at Daughter Space Flight Center and working in a group that builds instruments that go to other planets.
So that's when I got involved first in the MSL mission or curiosity as part of that science team.
But my research interest and my real scientific baby had always been Titans and studying Titan's chemistry.
And so that led me to working with when I first was working with Vidby actually and others who are now on Dragonfly on a prior mission concept.
That's when I first got involved in thinking of new ideas or what we can do if we get to go back to Titans.
And then ultimately, we had the amazing opportunity to start conceiving of dragonfly.
Very cool.
Well, that takes me directly to my next question, which is, what do you think are the most sort of important science questions that might be answered by the instruments that you're building on dragonfly?
What could we learn?
What can this do that the 2005 lander could not do?
There are a lot of unanswered questions that remain after the Cassini and Huygens missions in terms of different aspects of Titan.
Titan is a very complex system, like the Earth, right?
It's a very, you know, it's a very complex interconnected system.
And, you know, we have the Huygens probe that descended down through the atmosphere,
made a lot of measurements, the atmosphere landed on the surface
and provided some information in one view of the surface.
It was completely tantalizing.
And, of course, the Cassini orbiter that really revealed the global geology of Titan
and followed Titan through almost half a Titan year.
This attorney in year is 29 a half year.
and Cassini was active in this training system for about 13 years.
So we got to watch the weather change on Titan over almost half a year and follow the seasonal changes.
So there was a lot of information we gained, but there are really fundamental questions about Titan that remain,
including what the materials on the surface are, the solid materials on the surface.
We still don't really know their compositions.
even, you know, even at the high level, we know that they're organic materials and
their materials with water ice, but not a lot of the details. And so that's really what we want
to understand with dragonfly, especially because the materials on Titan, the chemistry that's
occurring on Titan may be very much like the chemistry that occurred on the early Earth that
eventually here on Earth led to biology. And because we can't always, you know, study in the
laboratory and certainly can't study on earth what those chemical processes were because it's all
kind of overprinted by biology here now. Titan, where these processes may be happening today,
is a great laboratory for looking at what materials are available and how far organic synthesis
can progress in this kind of environment. Melissa, how about you? Which pieces of information are you
most excited to learn when that thing lands on Titan? Which data are you going to look at first when it arrives?
Specifically, to my real true area of interest, I will say, is in the surface composition
and in looking at the types of organic molecules that are there, and particularly ones,
not just that were produced in the atmosphere and potentially deposited on the surface,
but ones that may have then undergone sort of advanced chemical processing towards things
that would look familiar to us, like building blocks of life, things like amino acids or
nucleot gases. You know, a lot of this is grounded in a combination of all the great discoveries
that Cassini Huygens made, as well as just decades of lab work that has been done
and trying to think through what are some of the key processes that might be happening on
Titans. And we know that in the laboratory, we take analogs of Titans organic and we let them
sit in water for a while, even for cold temperatures, for a year or two, you can get some,
you know, molecules that are really important for life as we know it. And so the question is,
you know, we know that process could happen, but did it, does it? And there are times in Titan's
past where there would have been liquid water on the surface even as long as a thousand years or
maybe even 10,000 years because of impacts or other events. And so what will we find if we're going
and we're, you know, drilling a sample out of one of those, one of those locations.
I love the mystery of these missions.
Like, there's so much we just don't know, such a blank canvas in our minds and in our
ideas and in our understanding.
And then we go and we actually get data.
So then my question for you is, what is your sort of most optimistic hope?
What's your, like, fantasy scenario, best case scenario for what this thing sends back to us?
Are you looking for, like, prebiotic building blocks, you know, amino acids that could
stitch together into life?
Or are you secretly hoping you're going to find?
and microbes on the surface?
What's your fantasy scenario?
For me, finding like a ray of amino acids,
a couple different ones,
maybe some other compounds that we know
could come out of this synthesis,
this hydrolysis that we're hoping took place.
And hopefully we'll see just a wide array of them.
That's my main optimistic hope.
And then I'll bump it up a little bit.
And if we could see a sign of what we think of
as an important biosignature for Earth.
Like with the amino acids, we carry the capability
to look for an enhancement in one chirality or the other of molecules.
So that's like the left-handed versus right-handedness, you know, on Earth for molecules
that are in our bodies that comprise proteins and DNA, the hand-endness is really important
and it's a signature of life.
Whereas when you find molecules, like amino acids out and comets that are from abiotic
synthesis, they typically have even amounts of both directionality versus, you know, all
of one or all of the other. So if we found not only the kinds of molecules we're looking for,
but a big carol enhancement, that would be amazing. I won't go so far as to suggest that we might
find microbes. But that, for me, that would be a fantastic, tremendous success and an amazing
discovery. As Melissa says, it's fundamentally a chemistry mission to understand the chemistry that's
possible in these environments that we know have all the ingredients necessary for life, as we know,
it certainly. And I think it would be really fascinating if we see differences in the chemical
components that are available in different environments. And one of the really exciting things about
dragonfly is that we can fly from place to place and explore very different places with very
different geologic histories. And so if we see different chemical components available in those
different places that have different histories, including deposits associated with an impact crater
where liquid water and organic material may have been in contact for extended periods of time,
I think that would be fascinating.
One of the other things that I'm really excited about is that we get to put the chemistry,
we have the capability to measure the detailed composition,
but we get to put that in the context of the tightened environment.
And so we get to make measurements of the atmospheric parameters, temperature, pressure,
methane, humidity, wind, etc.
We get to take images and see the surface.
and the landforms and the geologic processes that dictate how the materials on the surface of Titan
are transported and mixed together. And we even can make some geophysical measurements,
including listening for Titan quakes to understand, you know, Titan's geologic activity.
So I'm really excited that we get to put the chemistry into the context of Titan as a system.
Very cool. Of course, all of the answers to these questions are years or more than a decade away.
And while it's very exciting, how do you maintain your sort of emotional energy and excitement for a project when the arc of it is, you know, 10, 15 years?
When you're not going in day-to-day and getting answers to these questions or even making progress on it, what keeps you motivated on the day-to-day basis?
And the development cycle is also a long time.
You know, our launch is scheduled in 2027, which seems like a long way away, but it's actually, you know, we're really busy.
And every day there are new things going on and new tests.
and new design updates and things like that.
And so 2027 is actually going to come really quickly
because we've got so much to do between now and then.
And you, Melissa, what keeps you excited every day?
Well, I think it's kind of touching on it.
It's true that the actual data that we get at Titan is far away,
but in the development process,
there's already so many little problems to solve
or really fascinating questions, you know, to work
just to make sure that we're developing the spacecraft
on the instruments to do exactly what we want them to do.
So you're constantly engaged in the exact type of problem solving
and technical development that keeps us all going.
So I think that that's a big motivator for sure.
Something that always impresses me and amazes me about these space missions
is that once it's out there, you don't get to go and troubleshoot it and fix it.
In my field, if something breaks in the particle accelerator,
we can shut the thing down.
We can go down there.
We can replace it.
We can, you know, put volt meters on it, whatever.
but here it's gone, and it's such an intricate and elaborate and amazing project.
So what part of it worries you the most?
You know, which stage of like flying out there and the entry and turning on the actual rotors,
which part of it sort of from an engineering point of view do you think is the riskiest
or it's going to make you white knuckle it the most?
Each stage of the mission has different risks associated with it and different challenges.
You know, right now, the thing that I see that we need to pay the most attention to
is making sure all the different development pieces progress together so that we get the information
we need from each subsystem to be able to design the other subsystems, right?
Everything kind of has to happen at once.
And so the timing in development is also really, really crucial.
And then you're right.
Once we launch, everything is up to Dragonfly.
And I expect each subsystem would think that they have the most challenges, you know,
in terms of the, you know, that they're the most critical.
Just because there's so many different pieces of it, and you just try to build in as much robustness and redundancy as possible, that's one of the reasons we have the X8 octocopter design with four pairs of rotors so that even if something were to go wrong and one of the rotors weren't to work, we're still able to fly with the other seven.
And so you just build as much, you know, as many contingencies into your design as possible and hope that you don't end up with pathological situations that, you know,
that go in a different direction than the expectations.
And you, Melissa, do you have anything to add about which part of the mission is
the most nerve-wracking for you?
I said most of my time thinking through the sampling system, getting the surface samples
and how we're going to measure the composition.
So as Vivi said, that's, of course, what I will say has a lot of challenges.
You know, what's challenging but also fun about that is if we don't know exactly what we're
going to find, that's why we're going, to learn what the surface is.
comprised of. And so our approach is to try to build, as I've said, the most robust and
sort of flexible and adaptable system that we can using the information that we have. But then
also being prepared when we get there, you know, we have an impressive payload, a really
great complement of measurements that we can take before we even attempt to start drilling. You know,
we can observe the surface visually. We get elemental measurements of the surface. We'll be studying
sort of the meteorology, some of the surface properties. So we're going to sort of use our whole
arsenal as it is as we think through sampling or how we're going to measure a sample. And then on
the instrument side with the mespectrometer, which is what's going to be measuring the molecular
composition, you know, we try to think through how to be as flexible as possible and to your
point about worrying about, well, what if something goes wrong and you can't go replace it,
certainly you instead have to learn how to work around it. And so we spend a lot of
a lot of time on our team thinking through multiple failure scenarios or what could go wrong
and then what would we do to adapt? And in some cases, you identify an area, well, it would
really help us a lot if we just put an extra valve here, you know, just in case. So we do a lot
of that analysis. It's constantly a trade between making sure that we stay in the box, so to speak,
with what our size, our math, power, all those things, but also being ready for the unknowable
kind of.
And how do you figure out how to organize the technology for the mission?
You know, given that the mission takes so long to design and to build, by the time you're
actually ready to construct the thing, you know, technology has moved forward.
Rotar blades are better.
Instruments are smaller.
And a 15-year time scale, you know, technology, by the time this thing arrives on Titan,
it'll be ridiculously out of date.
Do you sort of freeze the engineering at some point when you're planning it and then you
just move forward or do you try to catch up as the field moves on as you're building it?
No, absolutely. It's the former. We'll freeze the design as we move forward.
And you're right. By the time we get to Titan, we'll think, wow, that's old technology, right?
The same way Galileo, right, in 2000 was using a tape recorder.
And by 2000, most people weren't necessarily using tape recorders anymore.
So you definitely see that.
But one of the things that is a great advantage for Dragonfly is that we can use existing technology
to apply to the exploration of Titan.
And so that makes the design more robust
because we have knowledge of that hardware
and those components because they have been used before.
In many cases, like the mass spectrometer,
the mass spectrometer is based on the mass spectrometer
that is currently sitting on Mars, right,
and has been operating there.
And so we can take advantage of that
to make sure that we understand,
how the hardware is going to work, how we need to build Dragonfly to support the instrumentation
so that everything will work together in the Titan environment when we get there.
But you're right, we'll look back and think, wow, that's old school.
Yeah, one thing I sort of learned when I got into this business was there's a big difference
between state of the art and state of the flight, something that is like the amazing,
awesome instrument that you would use in your laboratory that we think of a state of the art.
once you think about launching that off the planet and sending it out, you know,
out into the outer solar system or wherever you're going and landing and maybe kind of a,
you know, an intense environment and existing on a, in this case,
and a body that has a surface temperature of 94 Kelvin, right?
Your fancy instrument in the lab is not going to survive that.
So we think about for the cutting edge in face flight instrumentation is different than the
cutting edge and what we might be doing in our research.
Wonderful. Well, then let me ask you one last question, which is a question we usually ask science fiction authors when they're on the program, but you guys are really reaching out into the edges of space and our understanding. So I'm curious what your thoughts are about this. What are your personal answers to the Fermi paradox? You know, even the vastness of space and the number of habitable planets out there and the age of the universe, why do you think we haven't been contacted yet? Are we alone in the universe? Or is there life out there that just hasn't reached out to us for some reason? Pure speculation, no scientific basis.
I think part of it is answered by part of your question, right?
Even if there is life out there, there may well be, space is vast, and it takes a long time
even for light to travel across space.
And so that makes communication hard.
I mean, for Dragonfly to kind of bring it back to Dragonfly for a little bit, the time
it takes to communicate with Dragonfly is 70 to 90 minutes, depending on where Earth and
Saturn are in their orbit, right? And so we have to be able to work with Dragonfly, and
Dragonfly has to be able to do everything it needs to do on its own, because we can't communicate
with it instantly. And that's just communicating with Saturn, right? And so I think the time
scale is involved with a spatial scale of the universe certainly complicates that. And I don't think
we can read into the fact that we haven't been contacted, the assumption that it's because
there's no one trying.
Well, that's optimistic, I think.
How about you, Melissa?
I agree with everything like you said.
And also, I take a very humble approach to it and still wonder if we really know how to be listening.
Do we know what we're listening for?
And this in general is the question that's important in the search for life, whether we're looking for intelligent life or whether we're just looking for microbial life.
It could be a little different than us.
We always have to keep asking ourselves the question, do we know how to listen?
do we know what we're looking for?
Do we know what we're listening for
if there was other life out there?
And it's a field that I think we're getting better and better at
all the time, but it always requires that sort of humble approach.
Very well said.
All right, well, thank you both very much for your time.
And best of luck on the engineering
and, of course, on the launch and the landing.
We'll all be on the edge of our seats in 2027 and 2036
to hear what you guys learned.
So thanks very much for coming on our program
and sharing the excitement of your science with us.
All right. Pretty cool. I like what she said at the end about what it means to her to work on this.
Yeah, exactly. I think this is personal for both of them. We say on this program a lot that science is driven forward by individual people with their curiosity.
And clearly, this is a big project with a lot of people working on it. But it's driven forward by their personal curiosity.
they want to know the answers to these questions.
They have burning questions about the universe
and it's their curiosity that's pushing forward
the envelope of human knowledge
and it's exciting to see that in action.
Yeah, because sort of like
sending a robot with cameras
is probably just as good as sending a human with cameras, you know?
Except again, you don't have to bring the robot back.
Yet, you know, until our AI overlords make us bring it back.
Or maybe when we do eventually
colonized Titan, we will find
dragonfly there, pissed off and
waiting for us. Yeah, and it's
going to be a nuclear arm, so
watch out.
All right, well, it's pretty
exciting, and it's a mission that's happening right now.
You can sort of track it and follow its
progress, I imagine, on the NASA website.
So please check it out
and send them good space vibes.
That's right, and one last fun little
tidbit about this project is that it started
over dinner on a napkin
between two scientists coming up with his
crazy idea. So, you know, next time you have some crazy idea, it might just turn into like a
huge billion dollar 20 year mission to a surface in the solar system. So keep thinking and keep
being creative. Yeah. Don't use napkins for wiping food off your mouth. Just, you know,
keep them around in case you get cool billion dollar space ideas. Well, that was pretty exciting.
Let's stay tuned and see what they find in 20 years. I'm excited to see that first picture.
joining us. See you next time.
Thanks for listening and remember that Daniel and Jorge Explain the Universe is a production
of IHeartRadio. For more podcasts from IHeartRadio, visit the IHeartRadio app,
Apple Podcasts, or wherever you listen to your favorite shows.
December 29th,
1975, LaGuardia Airport.
The holiday rush, parents hauling luggage,
kids gripping their new Christmas toys.
Then, everything changed.
There's been a bombing at the TWA terminal.
Just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, terrorism.
Listen to the new season of Law and Order Criminal Justice System
On the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam. Maybe her boyfriend's just looking for extra credit.
Well, Dakota, luckily, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend's been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other, but I just want or gone.
Hold up. Isn't that against school policy? That seems inappropriate.
Maybe find out how it ends by listening to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Every case that is a cold case that has DNA.
Right now in a backlog will be identified in our lifetime.
On the new podcast, America's Crime Lab, every case has a story to tell.
And the DNA holds the truth.
He never thought he was going to get caught.
And I just looked at my computer screen.
I was just like, ah, gotcha.
This technology is already solving so many cases.
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This is an IHeart podcast.