Daniel and Kelly’s Extraordinary Universe - How can we bring rocks back from Mars?
Episode Date: September 29, 2020How many robots does it take to dig up rocks from Mars and deliver them back to Earth? Learn more about your ad-choices at https://www.iheartpodcastnetwork.comSee omnystudio.com/listener for privacy ...information.
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Yeah, you know, like everyone, I've been clicking on websites rather than visiting stuff online a lot lately?
Yeah, you know, like everyone, I've been clicking on websites rather than visiting stuff.
Yeah, you don't need a mask when you click, I guess.
It is pretty amazing how inexpensive it is these days to get stuff sent to your house from around the world.
Even if it comes from the other side of the planet, it can just be like a few cents per gram to ship it to your house.
Yeah.
You know, I wonder when we can start ordering stuff from even further away.
I've been trying to order some moon rocks.
I wonder how much is the shipping on those things?
Well, I heard NASA spent about $300,000 per gram to get some moon rocks.
Roggs, but, you know, I think it's cheaper if you have Prime.
You know, Jeff Bezos is starting his own rocket company, so he's probably going to link
that up and make it super cheap.
Yeah, why visit other planets when you can just order a little bit of them online?
and the creator of Ph.T. Comics.
Hi, I'm Daniel. I'm a particle physicist,
and I would love to have a little bit of Jupiter delivered to my house.
Really, huh? Isn't Jupiter mostly gas?
So you just want it like a canister or just to like release it in your home?
To know that you breathe it in a little bit of Jupiter.
Well, you know, Jupiter is mostly gas,
but some of that gas is in a really weird state, like metallic hydrogen.
And that makes me really curious.
I really want to see what metallic hydrogen looks like.
Does it need to be like super under pressure?
Hey, these are all engineering details.
I just want the metallic hydrogen order to my house.
I'm just clicking and waiting.
I want a little bit of that gas from the red eye of Jupiter.
Like, is the gas also red?
What's going on there?
I think we did a whole podcast episode on that one.
I guess you'd listen to it.
But welcome to said podcast, Daniel and Jorge Explain the Universe,
a production of IHeart Radio.
In which we let you stay at home and order in information about the whole universe.
delivered to your ears without any effort on your part.
We talk about things in the universe that are super far away.
We talk about the tiny particles that are swimming inside your body.
We talk about everything and anything and we try to explain all of it to you.
That's right.
We try to bring the universe and the cosmos and everything in between to your brain free of charge.
Because wondering belongs to everybody and the questions that you have about space and physics
and the universe are the questions.
that everybody has and the same questions that scientists want answers to.
Because we're all still learning about the universe and part of that learning is exploring,
is going out into the cosmos, into other planets, into the stars and figuring out what's going
on there and what is there for us to discover.
And sometimes it's so depressing to think that we've explored such a tiny little fraction
of our universe.
You know, we've barely gotten off this planet to explore the moon, to land a few rovers
on Mars. It's incredible. What a tiny little dot of the universe we have been able to
explore so far. But what a dot it is. It's a pretty cool dot. And we're lucky that there is
something to explore. I mean, right in our neighborhood, right next door, there's an amazing
planet, Mars, that really has a lot of tantalizing and fascinating scientific questions.
Yeah, Mars is awesome. And so we'd like to know a little bit more about what is there on Mars.
I mean, we can see it. But so far, we haven't been able to really, I don't.
I know, study it up close.
It's pretty hard because it's so far away.
And all we've been able to do so far is send our robots there and have them do science.
But that's sort of like trying to do science with a 10-foot pole or a 10 million mile long pole.
That's not easy to do.
That's kind of a philosophical question, isn't it, Daniel?
Like, if you send a robot out to explore something, have you explored it?
Technically, like if the robot touches Mars, did you touch Mars?
Did you touch Mars?
Yeah, I mean, if you have a robotic hand, you consider it part of yourself.
If you touch something with that hand, then it's part of you.
And so this is just like a spatially disconnected prosthetic, right?
Interesting.
Think about the rovers as part of your body.
Then, yeah, philosophically, I've been on Mars.
I wonder if the Mars rover would disagree.
When he gets to the point that it can disagree, it's no longer part of your body.
It has its own Twitter account.
Did you know that?
The Mars rover has its own Twitter account.
It has more followers than I do.
Yeah. Well, it did get off its couch, Daniel, and actually, you know, went somewhere.
It has accomplished more in its life than I ever will. That's true.
But yeah, we'd love to know more about Mars and whether or not it had life on it, like bacteria or who knows, what else we could discover that Mars had.
But it's really hard to do it from here and even to do it through robots.
It is challenging. And it's amazing to me how open this question remains.
You know, through history, we thought, oh, maybe Mars has life on it.
Then we took a closer look where like, actually it looks pretty dry.
They're like, wait, no, there is water on there.
Maybe there are microbes.
And so it keeps going up and down.
And it's fascinating to me that this planet, this one that's the closest to us,
we still don't know the answer of if there is life on Mars.
Is it similar to Earth?
Did it come to Earth from Mars or to Mars from Earth or to both planets from somewhere else?
It's an incredibly important question.
And it's right there.
It's so accessible.
Yeah, that's a huge question, right?
whether or not life on Earth actually started on Mars because it's possible that there was life on
Mars and then got knocked off on an asteroid and then flew here and landed on Earth.
And that's how life started Earth.
That's a theory, right?
That is a theory.
And it's not just the plot of a science fiction novel.
It's potentially actually plausible and is the kind of question that we could answer if we had
deeper access to rocks on Mars.
Right.
We could all be Martians.
Martians could all be Earthlings.
Who knows? We could all be Jovians.
Yeah, but it'd be great to answer that question.
And I think the only way we're going to answer that question is to actually go there and take a close look at the rocks and the soil and to actually like take a super microscope to it and see if we see any little critters in there.
That's right.
But sending scientists to Mars is unfortunately still many, many years away, decades probably, if ever.
It's really hard.
But we've done it with some things in space.
Like, for example, we've gone to the moon and gone and gone and rocks from the.
the moon and brought them back to Earth. I think you can order them online, right? I don't think you
can order them online. No. You can. Can you get on eBay and like a bit on a piece of moon rock?
I think anything you buy on eBay is not going to be actually moon rock. So please don't waste your
money. But we did actually bring rocks back from the moon. And those rocks have been an incredible
treasure trove of science. We are like still thinking of new things to do to those rocks, to learn
things to figure out answers to new questions about the science of the moon. So it's incredibly
valuable to have here in our Earth laboratories a sample from the moon or from somewhere else.
Yeah, I have actually held at Moon Rock. I was at JPL visiting ones and they let me hold a little
bit of moon dust. And did you feel transported? I accidentally breathed some in and sneeze.
Had you go in there for a second. That sounds like the opening scene of a terrible science
fiction novel. Jorge gets infected by a moon-based pathogen. And that's why I have superpowers.
You gain the moon's proportional strength. I get the ability to moon people. You cause tides,
right? You'd be some sort of lunar superhuman. That's right. I'm like the villain in the next
Aquaman movie. That's right. You're like DC version of Magneto, right? You just insulted me twice
over there. You just confused a DC character with a Marvel character. No, I'm trying to bring one from the other, right?
Magneto controls metals, and so Lunar Jorge controls tides, right, in the DC universe.
But anyways, so the question is, can we just go to Mars, pick up some rocks and bring it back, and then study them, and then we would know if life potentially came from another planet.
That would be incredible.
And so to the end of the program, we'll be asking the question, can we bring rocks back from Mars?
Or more optimistically, how can we bring rocks back from Mars?
Oh. Oh. So you're feeling good. You feel like it's not an if question. It's not a physics question, right? There's nothing in physics that prevents us from moving rocks from Mars to Earth. It's definitely an engineering question. And as you'll hear, it's a tricky one. So as usual, we were wondering how many people out there had thought about this question or wondered whether or not it's possible to bring something back from Mars. So Daniel went out there into the wilds of the internet to ask people, how can we retrieve rocks from Mars to study this?
them on Earth. So these are the answers I got from random folks on the internet who were willing
to speculate baselessly without any Googling about the questions I asked them. If you'd like to
participate and hear your voice on the podcast some point in the future, please write to us to
questions at danielanhorpe.com. Here's what people had to say. I think that we should send a rocket
to Mars and then maybe the Mars river that are coronary on Mars should take the rock samples and put them
inside the rocket and then we could somehow program the rocket to fly back to Earth on its own.
Perseverances on his way there right now and hopefully the next generation of perseverance will be
able to bring them back to study. I thought that that was part of the upcoming Mars mission or maybe
for the next mission to have some sort of return capsule. It's really difficult to get things back
from Mars so I imagine that we probably have to send some sort of probe there that would then have
to do a lot of the analysis there on Mars.
I think the new Perseverance Rover can actually collect and store Mars rocks for a future
mission to retrieve and bring back to Earth.
I'm envisioning maybe we send something to like enter into Mars's orbit that can maybe
send down an explosive, hits the surface, sends out a bunch of particulates.
The probe gathers these particulates and then breaks out of the orbit, goes back to Earth.
We can gather samples from Mars for study on Earth, kind of
how we went to the moon, except all robotically, right?
And instead of a lem, we have a mem.
Well, I know we already have a mission going there.
And I believe what they're going to do is do little core samples
and then somehow package them and leave them for a recovery mission.
All right.
A lot of excitement about this idea, I feel.
Yeah, a lot of excitement.
People are like, I don't know, but sounds cool.
Somebody out there is like, let's just nuke Mars.
And I have the feeling.
They were just waiting for the opportunity.
Was that a fellow physicist?
I feel like that sounds like an efficient solution to a physicist.
You don't think an engineer would be like,
let's just shoot a string of nuclear weapons at this thing to guide it back to Earth.
I think even a freshman engineer would be like,
maybe there's a better way.
That's right.
And also it would probably destroy the samples and pollute them with radiation.
So it might undermine the very science that we're trying to do.
Right.
That's probably a huge.
part of it, right? Like not contaminating. Oh, yeah. That's a big deal. All right, well, let's dig into this
topic. Let's get some samples of it and retrieve it and bring it to Earth. So Daniel, first of all,
I guess talk about why we would want to get rocks from Mars. I mean, I know that it'd be great to
study them, but, you know, why can we just study them there? Well, we can do a lot of studying on the
surface of Mars, and we have rovers that do that. But it's tricky. You want to do some science on a rover.
you have to pick an instrument which can survive like launch and transit and landing on Mars and
then can get set up automatically without any like grad students tinkering with it.
Every cutting edge lab that I'm aware of here on Earth, the most powerful instruments are
delicate instruments and they require like experts tweaking them and massaging them to make
them work and to calibrate them.
So for something to work on a rover has to be really robust and that really limits the kinds of
science that you can do. Yeah, I guess you need a lab and it's tricky to handle these samples
and to do the science right. That's right. If you had your hands on Martian samples, like right
now, there's like a hundred things you would want to do to it right away. But only a few of
those ever make it onto a rover. So you're really limited. And then you get the answers back. You're
like, oh, look, it has this weird thing in it. Now I want to check with my other funky instrument.
But you can't do that kind of thing all in advance. When you send your rover over, you have to plan very
far in advance exactly what you're going to do to every sample. You can't respond to what you've learned
with new ideas. Whereas if you bring the rocks back, then you can keep coming up with new ideas
and also you have access to future instruments, right? Cool techniques we're going to develop in 10
years or in 20 years that we haven't even thought of now. If we have the rocks here, rather than
sending the machines there, then we can use new machines on old rocks. Right. I guess it's, you know,
And it's really hard to take stuff to Mars, right?
I mean, like every gram cost like a million dollars or something.
And these lab equipment machines are really big sometimes.
They are really big.
And a lot of the engineering challenges of building a rover are how to miniaturize, right?
How to make these things really small.
It's got to be like the size of a shoebox and fit on the edge of a stick and be totally robust.
Like you have to just be able to send it one command and it boots up and starts up.
It's got to have a little bit of AI in there to get itself.
going. You can't just like crawl out there with your screwdriver and fix it. Once you send it,
it's gone. Yeah. You can't just call IT to fix it. And they'll say, have you tried turning it off
and turning it on again? Did you update your windows installation? You're like, I can. It's on Mars.
I can't even turn it on and off. No, and you can't even like drive something on Mars. Remember,
these rovers operate semi-autonomously because Mars is so far away that it takes light minutes to get there.
So you can't have the kind of feedback loop you need to real-time drive something on Mars.
It's like you drive forward, you stop, you take a picture, you send it back to the folks in NASA.
They figure out what to do next.
And so having it be so far away makes it really limited.
It has to survive the trip, too.
Like launching from the Earth into space is not easy, right?
Like there's huge forces and, you know, you're basically strapped onto a giant explosion.
It has to survive that and also the landing on Mars, which can be pretty tough.
Like sometimes they just fall into the ground and bounce around and they'd have to survive that.
Right. Like that's the landing strategy.
That's the design strategy, right?
I mean, remember all those movies about astronaut training.
Like, they put those folks through some tough stuff.
They spin around.
They shake them a lot.
Basically take your most sensitive science instruments and put them through astronaut training to see if they have the right stuff.
Most of the time, it's just going to fall apart.
Like, you go into a random geology or microbiology lab here on Earth, most of the
those instruments are very delicate.
They don't let people in there poking and prodding.
So you're right.
Surviving all the shaking and the landing and all that stuff, it's not easy.
So this whole categories of instruments, nobody's figured out how to miniaturize and make
robust enough to send to Mars.
Okay.
So it would be a lot better for science if we could bring some Mars rocks back.
So we can study them and, you know, you can do a whole bunch more tests than you could
on a robot in Mars.
But it's really hard.
And apparently, it can't just study meteors from.
Mars. Like, that's another possibility, but it's not as, I guess, fresh. Yeah, the amazing thing is that we
actually already have Mars rocks, right? Like, what you were talking about sort of as a joke actually
happens. Sometimes big rocks hit the surface of Mars, right? Impact craters and stuff gets thrown out
into space. You know, this can be really big impacts. And some of those rocks get tossed out into
space and eventually a small fraction of them hit the surface of the Earth and then are recovered.
And how do we know they're from Mars?
Do they have like a made in Mars tag?
Well, they went through customs, right?
And so we can tell, they just look at the forms.
They declared it.
I mean, can you tell?
Does it have a special like cue of red or something?
You can tell because of the geology.
Every object in the solar system has a different history and a different composition.
And that tells you where it comes from.
And so when you get a meteor from outer space, when you get a chunk of space rock, first of all, you can tell it's a space rock because of what it's made out of.
It's made of stuff you don't find on Earth.
And then you can tell roughly where it came from based on the details of what's in it.
And so most of the rocks that land on Earth come, for example, from the asteroid belt.
And we can tell based on the blend of metals and also the organization of the metals in them that tells you something about its history, like when it was last melted and how long it's been frozen for.
And some of these things have composition and geology that's only consistent with the surface of Mars.
Interesting.
So, yeah, we have like dozens of these objects that have landed on the.
Earth from Mars, which is fascinating and incredible and wonderful opportunities to do science,
but it's not good enough.
Right, yeah.
You need like fresh rocks.
Like those asteroids are kind of stale.
They've been floating around space and who knows where they came from.
It's not just that you need fresh rocks.
It's that you need to know where they came from.
Like, it's just a random sample.
You don't know where on Mars it came from.
So you can't really, like, fit it into your science picture of what's going on on Mars.
What you'd like is to have a rover travel around and make judicious decisions and say,
I'm going to get a little bit of this kind of rock,
and I see where it is.
It's on the downflow of a slope.
I'm going to get that piece of rock over there,
and I know the scientific context.
It's sort of just like getting a piece of pottery
and having no idea where it was dug up from.
It's much less valuable scientifically.
It's also kind of like when you go to a Las Vegas buffet,
you know, you want judiciously pick a little bit from everything
and know where you got it from so you can go back
and get the stuff you liked.
That's right.
And so you know what made you throw up
And what you actually enjoy it.
Yeah.
All right.
So it sounds like it would be a lot better if we can get, go to Mars, get some rocks, bring
them back and then study the heck out of them to answer these big questions about life in the solar system and about Mars and the history of Mars.
But it's a tough problem.
And so let's talk about how we would actually do that and what has been and is being done to do it.
But first, let's take a quick break.
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All right, Daniel, we are.
are souvenir shopping in the solar system.
We're trying to get some original, authentic rocks from Mars,
but it's a tough problem because Mars is really far away
and you don't just have to get the rocks, you have to come back with them.
You've got to come back with the rocks, right?
Like, we've done the one-way thing.
We've sent something to Mars and it's dug up rocks and studied them,
but they're still on the surface of Mars.
And so now we need to do the second bit, the round trip,
come home and deliver them to scientists,
in a pristine condition
so that we can finally answer
some of these
incredible long-standing science questions.
And I feel like the problem is
it's not just double, it's like squared
because it's hard enough to take
off from a planet and land on another planet.
But now you've got to do it again,
take off from there and land here,
but it still has to be the same
machine that you send out.
Like the same machine you send out
has to do both of those things.
Yeah, it's complicated and it's not just squared.
As you're going to hear, there's a lot of moving parts.
It's more like to the ninth power or something.
It's pretty ridiculous little dance of machines that we have to get working all together
to get those rocks back from Mars.
And you know, what you just said, nobody has ever done that before.
We've never successfully launched a rocket from the surface of another planet.
Right.
Well, we've done it for the moon, but the moon is kind of easy to take off from.
That's right.
The moon is pretty low gravity and it's not a planet and it's not remote, right?
There's somebody in there driving that thing.
Right.
So now we have to remotely launch.
from the service of another planet.
I mean, that's hard enough to do from Earth.
So, yeah, it's a big challenge.
Luckily, you volunteered to go to Mars, right, Danny.
I volunteered to press the big red button when the time comes.
Oh, yeah.
I'm first in line for that.
Which one, the takeoff button or the abort button?
Whatever, man.
Just put a big red button in front of me, and I will hit it.
That's my job.
That's how these podcasts get started.
You hit a big red button.
Hey, you don't get to live your dream if you don't ask for it.
So this is my official request to get invited to press the big red button.
NASA button pusher.
All right, but we've actually tried before.
Like, this is not a crazy idea that you and I just came up with here on the podcast.
The U.S., the Soviets have been trying to do this for really like 40, 40, 50 years.
Yeah, and they've been trying and failing, but the failures have been political and financial.
It's not like we've sent a mission that's attempted to do this and then not succeeded.
The mission has been thought up and planned and organized and then canceled many times in the past.
Really?
The Soviets thought about it.
in the 70s, but they couldn't get their rockets to work.
NASA had a plan in 1979 that was canceled because it was too complicated.
And then recently, NASA and the European Space Agency had a plan that was in 2012
that people thought it was going to happen, but then it was aborted again because it was
too complicated and too expensive.
This cancel culture is out of hand, Daniel.
Yeah, and I think that especially was really traumatic for the sort of Mars science community.
People really believed that that one was going to.
be the one. It was finally going to come to fruition. So when that was canceled, it was a bit like
the superconducting super collider was for particle physics. It left a bit of like PTSD on the community.
There's a little bit more cynicism than there was before. So it sounds like people get excited about
it. They start the program, but then they realize it's too hard so they cancel it. And it's happened
over and over. It's a little bit of a political problem, though, because it's one of these projects
that takes years or decades to pull off. So even if you're committed to spend
a lot of money over many years,
you need all the people who are in charge
after you to stay committed,
to not have their priorities changed.
And so it takes consistent support
over many, many years
for this kind of thing to actually happen.
All right, so there was a big program at NASA
that got canceled in 2012,
but now, now it's sort of been revived, right?
Now there is some activity at NASA
to actually do this.
That's right.
It has been revived.
There's a new plan,
and it's a pretty reasonable plan
in comparison with the other crazy plans,
although I think you'll still find it fairly absurd and amazing.
This is the level-headed conservative plan.
This is the least ridiculous plan that we have going.
Is that how they pitched it to Congress?
We have a new less ridiculous plan.
You guys are going to love it.
Now, 40% less crazy.
And the most exciting part is that the first part of it has already launched.
What?
Like the first element of this multi-stage plan to bring rocks back from the surface of Mars
is already on its way to the red planet.
Wait, what?
This is already happening.
It's already happening.
They have a new clever strategy,
which is they break it up into pieces,
and so they're easier to sell,
and the first piece works no matter what.
Like, the first piece is something you want to do,
even if you're not going to bring the rocks back.
Oh, I see.
They're clever now about the mission planning.
Yeah, they're a little bit more cynical,
I guess you could say, or more experienced.
And so this first piece is a rover
that launched on July 30th.
It's the Perseverance rover.
This year.
And it's this year, yeah, just a few weeks ago.
And it's on the way to Mars now.
And it's an awesome piece of technology.
You may have heard about it.
It's going to be the heaviest rover ever landed on Mars.
It's going to have a little helicopter on the top of it that can fly up.
The first helicopter operate on the surface of Mars.
That is so sci-fi.
Yeah, it's going to be really cool.
It's kind of a little laser on it.
But most importantly, it's going to have a device that can drill
into the surface of Mars and extract cores,
which you can then store in a little sample container.
I feel like now we're getting to really transform our territory.
You know, like we're sending a box,
and then when the box lands,
it's going to transform into a drilling machine with lasers and a helicopter.
That's right. It's Optimus Prime.
That's what they should have called it.
That's right. Forget perseverance or something inspiring.
Just go with Optimus Prime.
Yeah, so this thing is going to have a year's long mission,
and it's going to drive around and it's going to collect like rock chorus from maybe 39 different
locations and each one is pretty small.
You know, they're like a centimeter wide and a few centimeters long.
But that's gold for scientists down here to have a few cubic centimeters of rock from
several dozen locations around Mars.
It's incredibly valuable.
So it is a rover like the ones we've sent before and it's going to run around and collect samples
and then keep them, keep them in like a box?
So it's got its own science mission.
It's a good idea anyway, even if Mars sample return doesn't happen.
But then it's going to collect these rocks and it's going to put them in a little sample container.
And then it's going to leave them on the surface of Mars for the next stage to come and retrieve.
Wait, what?
It's going to be littering.
It's going to be preparing a gift for us, man.
It's not trash.
But why not collect them?
It's going to really leave them out where it would found them?
Yeah.
It's going to seal up in tubes and then it's going to leave it out where the next.
next mission can come and collect it.
But why not bring them all together so that it's easier to pick up?
No, it's going to collect them all into one container.
Oh, I see.
And then leaves a container there.
Seal it all nice.
And then the next stage is going to come and pick it up.
And so if you're keeping track, there's three major stages to this mission.
Stage one is perseverance.
Go and create the samples, pack them up in the container, leave it on the surface.
It's also going to study them, but also going to leave them there.
Okay.
The next stage is to get it off the surface.
surface of Mars.
Wow.
All right.
And each of these is like a different mission.
It's kind of, I think that's what you're saying.
Like, don't put it all in one mission that could fail, but do one mission.
And if that one succeed, then do the next mission.
And if that one succeed to the next mission.
Yeah.
So there's three separate launches from Earth.
Like we're sending three different devices from Earth.
They're all going to work together to make this happen.
Three different transformers.
Uh-huh.
The first one lands on the surface and makes these samples.
The next one is, I think, maybe the craziest.
and it's the one that's going to land on the surface of Mars
and then it's going to deploy a mini rover,
like a little rover that just runs out,
picks up the sample container, comes back, right?
Loads that into a rocket
that it has landed on the surface of Mars,
that wraps that all up,
and then launches from the surface of Mars,
sends the sample container up into space.
Wow.
So on a rocket, we'll be sending another rocket
and a launching pad,
and a launching pad and a little tiny retriever robot and a mini rover yeah exactly so the job of this thing is to land there pick up the sample container and it has a robotic arm that will take it from the rover and put it into the rocket and then yeah remote launch from the surface of another planet maybe the most valuable sample ever to be collected wow this feels kind of comical to me like you know like this giant machine lands opens up oh there's another rocket in there this little robot
comes out, picks up something, runs back, sticks it in the rock, and then it just launches back
somehow it feels comedic, like something out of a cartoon.
It does seem a little loony tunes.
Yeah, you're right.
And if this thing works, it definitely needs that sort of like comedic music in the background
to inspire you, you know.
It'll be pretty funny.
But this is not set to go for another five years or so.
So we're talking about launching this next bit.
in 2026.
Wow.
So wait,
so there must be working on it now.
Like,
it's being built right now.
It's being built right now.
So Perseverance will have years on the surface of Mars to collect these samples.
And also we'll have an idea like,
how did that go,
right?
How well are things going?
We could change our plan based on where perseverance is or how things go for perseverance
or what it learns or how the sample container looks.
And so that's another part of it.
You build in these delays so you can change your plans as things develop.
So, yeah, they're working on that now, and they're going to launch it in 2026, and the idea is it would arrive on the surface of Mars in 2028.
Remember, it's a two-year trip and then grab it and launch it out into space.
But it only has the power to get it into orbit around Mars.
It can't bring it all the way back to Earth.
Oh, that's still just phase two.
That's just phase two, right?
The actual Looney Tunes crazy comedic value comes in the next stage.
All right, so what's phase three?
So phase three is we launch a third rocket from Earth, and this one at the same time as we're launching the second one.
But this one just stays in orbit around Mars.
And this is called the Earth Return Orbiter.
So this one's concurrent.
Like we're not going to wait for the second one to finish.
We're going to send two and three.
It's like filming the sequels at the same time.
Yeah, exactly.
So the third one hangs out in orbit and it helps communicate and do a bunch of stuff.
And then its most important job is to catch the sample container.
because the surface rocket is going to launch from the surface of Mars
and get out near orbit, right?
It can't go all the way out, actually out into space.
And the one that's in orbit has to lower itself down to lower orbit.
And then they're going to pass the sample container from one rocket to the orbiter.
Robots are going to do this.
Robots are going to do this in space.
You know, same thing Daniel is starting to seem a lot easier.
I know.
And the sample container, it has no radio beacon, it has no tracker on it, has no transmitter, it has no thrusters.
It's just an inert white ball.
And the orbiter just has to catch it.
Wait, it doesn't have like a GPS on it even or?
Nope.
It's just white.
They're like, let's make it white.
Then you can see it in space, right?
Wow, that is audacious to say the least.
I guess my question is, why can't the rocket just go straight into orbit?
You can't put enough fuel on it?
something or what? That definitely takes a lot more
power to get all the way into orbit. And so
yeah, I mean, you have to launch this thing from Earth
and then send it to Mars. And so
there's a lot of risks and costs here that they're
trying to balance. And this was what they decided
was the least crazy
plan. I guess
it would be a lot to like
land a rocket that can make it
all the way back to Earth. I guess this
is smarter to like, you know, make this
rocket smaller and then
save the spaceship part of it
for another phase. Yeah. And now
now the part the orbiter only ever has to live in space.
It doesn't have to go down to the surface.
So you have one thing that's dedicated to going down to the surface.
It's good at that.
And another thing that's dedicated at orbiting Mars, catching this soccer ball with the most
valuable cargo humans have ever created and then flying on its own all the way back to Earth.
It sounds like, you know, kind of like a whole bunch of robots that together make one big robot.
Yeah.
It's a bit of a Rube Goldberg machine, right?
They should have called this the Rube Goldberg Mars mission.
It's pretty hilarious.
All right, well, let's get into what happens next, phase three.
But first, let's take a quick break.
December 29th, 1975, LaGuardia Airport.
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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 plainly.
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my boyfriend's professor is way too friendly and now i'm seriously suspicious
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He doesn't think it's a problem, but I don't trust her.
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That sounds totally inappropriate.
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I mean, do you believe him?
Well, he's certainly trying to get this person to believe him because he now wants them
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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.
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On a recent episode of Culture Raises Us podcast, I sat down with Warren Campbell, Grammy-winning producer, pastor, and music executive to talk about the beats, the business, and the legacy behind some of the biggest names in gospel, R&B, and hip-hop.
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All right, Daniel, we are talking about transformers in Mars
and robots that we're going to send there
and work together on their own to land on Mars,
get some rocks, shoot them back up into space,
hand it off, and then bring it back.
So that's phase three, is bringing the samples from Mars back.
That's right.
That's phase three.
So it has to catch this soccer ball in orbit around Mars, right?
It like opens a door on the side of the ship and the ball just like drifts in.
Because remember the ball is not powered.
So it just has to like match it in orbital speed and get in front of it and then slow down a little bit and just sort of like mate with this thing.
What?
Yeah.
It's going to catch it.
It's going to catch it.
And it has to then keep it somehow sterile.
It can't like let the sample container or anything that was on it infect the rest of the ship.
ship. Oh, I see. It had to catch it and isolate it. Catch it and isolated. Fly it all the way back
to Earth, right? That's not that big a deal. You just have sort of point in the right direction and have
enough power left. And then it has to drop it off on Earth. Wow. It's going to drop it off or it's
going to land? It's not going to land here on Earth. It's just going to drop it off. And the sample
container is essentially just going to fall to the surface. They were like, should we add parachutes or
something to slow it down. But that seemed too complicated. They're like, no. Can't you just call
like Uber to pick it up or? Build a huge catcher's mitt or something. Why not build another
robot to go up there and catch it? Why not? Well, they thought this was simplest and, you know,
they already used up their quota of crazy robots on this mission. So they're just going to toss it into
what, the ocean? No, it's going to land on the surface and land around 90 miles per hour on the surface.
What? And it's not going to explode or baby?
It's not going to vaporize that. It should be able to survive that. And, you know, the samples themselves shouldn't be that delicate, right? It's not like they're glass containers or, you know, anything that's going to break. It's just rocks we're bringing back. I thought they were going to be on like, you know, test tubes. But I guess you want something a bit more sturdy. Yeah. But the question is like, can we keep it safe and contained? We're basically shipping a chunk of Mars onto the surface of the Earth. And we want to isolate it so that we can study it for, well, a couple of reasons.
is like, who knows what's in that thing.
And if there really is, like, weird life on Mars,
the last thing we want to do is, like, eradicate all life on Earth
because we imported some pathogen.
It didn't wrap it in a plastic bag first.
I've seen that movie.
It's pretty good, unless you're living it.
But the other thing is, we want to keep it sterile
so that if we do, like, find weird bugs in it that are similar to bugs on Earth,
we want to know they came from Mars and not from, like, the Utah desert where it landed.
Wow.
Well, this seems like a super audacious and amazing and amazing.
Incredible plan. And Daniel, you actually got to talk to somebody who works on this, somebody from NASA.
Yeah, there is incredible excitement in the community for this project. People are hoping beyond hope that they'll get to get their hands on some of these rocks.
So I reached out to Dr. Nina Lanza. She's a Mars rover instrument scientist. She built some of the things that are going on perseverance right now.
And I asked her a bunch of fun questions about this project.
Yeah, it's a great interview. So we'll play that for you right now. So here's Daniel talking to
Dr. Nina Lanzah, Mars Rover Instrument Scientist.
So it's my pleasure to be talking to Dr. Nina Lanzah.
Would you introduce yourself for our listeners?
Sure. I'm Nina Lanzah. I work at Los Alamos National Laboratory, and I'm a planetary
scientist. Awesome. And so our questions today are mostly about getting your hands on samples
from Mars or the signs you can do with stuff on Mars. So our first question has to do with the
rovers that we have over there and that we're sending over there. What do you think are the most
important scientific questions that those instruments on the rovers are asking? Well, it's important
to remember that each of these missions had a different goal and they build on each other, right? So
when we first started sending rovers to Mars and even landers, you know, we didn't know a lot. We
know a lot more after all the missions we've done. So initial missions were just to figure out, you know,
What's on Mars? What's it like? And subsequent missions have been trying to find out the details of that. What has the history of Mars been like in terms of climate, in terms of geology? Now we're asking questions about habitability. Is or was the Martian environment habitable in a way that we understand? So habitability is not looking for life, but rather places where life, as we understand, it could exist. And so now after our most recent missions, you know, we feel really
confident that Mars was absolutely a habitable place in the past and is kind of habitable now
for certain terrestrial microbes. And so our next goal is to find out whether or not life ever
existed in the past on Mars. And so that's really exciting. So I think it's not that one of those
questions is more or less important. It's really that they are building upon each other.
And so are the questions that are being asked by these rovers or instruments designed for these rovers that are inspired specifically by things you learned on previous generations?
Like, oh, we saw this and now we have a follow-up question.
Oh, certainly. Gosh, and there's so many examples of that.
I mean, there are some big questions.
For example, we've seen from remote sensing these huge mineral provinces, specifically clay minerals and carbonates, maybe less huge on the carbonates, right?
We've seen these from orbit.
And so the question is, can we ground truth this and find this on Mars in a geologic context that we can interpret?
We've certainly found quite a bit of clay on the surface with the Curiosity rover.
So, yay, success.
But now we're looking for those pesky carbonates.
Carbonates are predicted to have formed on Mars, but we've never really encountered them in any kind of abundance.
And so it's one of these ongoing mysteries.
And so as we have moved forward, looking at Mars in detail with curiosity, we still haven't seen.
all that many carbonate. So it's still this question, why not? And we're hoping to answer that with
the Perseverance Rover in its new landing site, Jezero Crater. Cool. So I know when you start a project,
you have sort of like optimistic hopes for what, you know, might happen or fantasies about data you
might collect or whatever. So if you let your imagination run wild and you hit all the home runs,
what's like the best case scenario for what you could discover using these rovers? Well, I think it would
be just incredible and paradigm shifting if we could find signs that life existed somewhere
not Earth. We know there's life on Earth, you know, but how did it start? We don't really
understand a lot about our own origins, and we don't know how common it is. Right now, we only
have one example of life on a planet, and that's our planet. If we could find evidence of life
on a different planet, could be remarkable and incredible. What would that look like in terms of the
the rovers that we have now or the rovers that are en route, what would that discovery look like?
I mean, we're not talking about little critters waving up to the cameras, right?
I mean, I think it's pretty clear that there isn't macroscopic life on Mars, right?
There's no dinosaurs.
We would have seen those things.
So now the question is microscopic life.
Was it there?
And is it there?
So those were actually two different questions, and we have to have different approaches to answer
those questions, right?
The Perseverance rover is looking for signs of past life.
And there's a lot of ways to do that.
And we use the same techniques that we do on Earth.
How do we know when life began on Earth and what were the signs that it left?
So that's our best way of analyzing Mars Rocks to find out if there was life in the past.
I think our best bet is going to be bringing these samples back to Earth.
We have some incredible rovers and they have great payloads of these instruments that just do great things and they're doing them remotely.
It's just amazing what we can do.
do, but it doesn't compare to our gold standard instruments that we have on the earth. And so
there are questions that we can never answer with our current payloads. So we're going to need to
just get that sample back into the laboratory, take a look at it, and then we'll probably
want to do different analyses, right? We don't know what we're going to see, and so we don't
know what the next steps will be. And that's the excitement and the fun part about doing science
like this is that you can only predict the first few steps, but the next steps are all dependent
on what you find.
And why can't we just do those studies on Martian meteors, you know, bits of Mars that have
been blasted off and landed here already?
We're very lucky that Mars has sent us about 150 pieces of itself.
So we didn't actually have to go to Mars to get those pieces of Mars.
So thank you, Mars.
The problem with those meteorites, though, is that they don't have any context, right?
They fell out of the sky.
We don't know where they came from on Mars.
it's very hard to make statements about geology in a broad sense if you only have a hand sample, right?
As a geologist, people come to me all the time with some random rock.
They're like, what's this?
I'm like, well, I could tell you some things, but you know, you just picked that up off the ground.
Where did it come from?
What was the broader context?
We need that context to really be able to answer these questions about Mars.
That's why sample return is so exciting because we know exactly where it came from.
We have documented that location very well.
And so then when we get results from that sample,
we can then integrate that into a larger context.
That makes a lot of sense.
And so if there are critters alive on Mars and little microbes,
and we sample them by chance,
and those samples come back to Earth,
are we imagining that those things could still be, you know,
alive and wiggling?
Who we measure, like, you know, metabolic activity
in the sample that returns to Earth from Mars?
If there are things living near,
the surface of Mars, they have got to be amazing because the radiation environment on Mars is
terrible. You know, it's, Mars doesn't have a magnetic field because it doesn't have a dynamo in its
core. And so the surface environment is just, it's pretty icky for life. There's a lot of life
on Earth that could probably handle it, but it's, it's not that common. So, so I would say the
chances of us finding extant Martians in the near subsurface where we can access it with a rover is very,
very low. But we have to prepare for that possibility. So one of the things that's really critical
that we do before our samples come back is to prepare their housing facility. There are a few
facilities on Earth that already are ready for this. A notable one is at Johnson Space Center,
which is the main repository for all the Apollo samples from the moon. Because we had the same
questions about the moon. Who knows what's up there? And it turns out that the moon is a pretty
sterile place, it turns out, and maybe that was easy to predict in retrospect, but, you know,
we had no idea. So we had to take really a lot of precautions to protect both the samples and
Earth from each other. And so we'll have to do the same for a Mars sample return mission.
And so we know from our experience with Apollo and also just bioscience in general, you know,
the best methods for doing that. And so I think that facilities are going to either be constructed
or old ones retrofitted to be able to handle these new samples.
Awesome.
Well, I hope that happens.
I've been reading a little bit about the history of these missions.
And I note that, you know, Mars sample return has been discussed for decades and even planned
and then canceled and replaned and recalced.
Do you think this latest plan by NASA and ESA is likely to actually happen?
Or do you think the political climate where we change administrations and government every
few years makes it difficult to pull off a long-term project like this? Well, it's certainly above
my pay grade to make political predictions. So I can't really speak to that, but it's true that
these missions are really big. They require incredible amounts of collaboration over long periods
of time, and they require quite a bit of funding. So that is what we need the most. I don't think that
anything is impossible for us if we work together. I think that we've really come up with a great plan
that has a high likelihood of success, the question is whether or not we want to fund that.
And that's not up to me as an individual, if it were, it would be funded right now.
But, you know, we have to make sure that this is aligned with our taxpayers' desires.
There's a lot of things that go into that.
And is this where we want to put our priorities?
I would note that NASA is not funded at the levels that most people think, right?
When I like to play this game, like, what percentage of the total U.S. budget is NASA getting?
and people were like 20%.
And I'm like, that's great.
I wish it were 20%.
I know.
I'm like, that would be amazing.
You know, but unfortunately, at its maximum, NASA has never gotten more than 1% of the total
U.S. budget.
It's much lower than that now.
You know, so we are doing all of this work with really very little funding, which is
amazing.
We don't really need that much more funding to make a sample return mission from Mars reality.
So that's what I would say.
I would say, you know, maybe it feels like it's a little bit of extra money now,
but I think the rewards would be incredible,
and it would absolutely be worth the price tag.
I agree with you.
I think it's incredible when we have the capability to do something,
and the only thing that limits us is the money.
It's like you're at the universe as like knowledge shop,
and you could just buy this information about the universe,
and the money is there, but they're spending it on aircraft carriers.
We need those two.
We need them all.
We need all the things, but we could just, you know,
I think people think of it as more expensive
than it really is. It really is a bargain, what we can do.
It really is. So let's say this mission happens. There are several parts to it which seem a little, you know, nerve-wracking, bits being transferred from one to the other.
Say this happens, which part is the most nail-biting for you, which is the moment where you're like, you know, holding your breath, hoping that it works.
I think for me, the most anxiety-ridden part of any mission is launching and landing. Those are the hardest parts that we do.
It's really hard to launch something off of another planet and get it onto another planet safely.
And so, you know, we've done this now for many missions successfully, right?
But we can't never guarantee that it's going to always work out well.
I think we have a good track record.
But we're going to be trying to do some very different things with sample return that we've never tried before.
And that is we've got to first get our rover perseverance to Mars.
So we're already launching, we've already launched off of Earth.
and now we're on route to Mars.
We're going to land on Mars.
Then that rover has to gather samples,
and then we're going to launch another spacecraft
that's going to get into orbit around Mars.
And then that spacecraft's going to launch a lander
with a little fetch rover,
and that rover's going to pick up our samples,
and then get back to this lander
and then launch off of Mars.
This is all by itself, by the way.
No help from us.
Then it's going to rendezvous with that orbiting spacecraft,
and then that spacecraft is going to come back to Earth.
And that's very complicated.
I think we can absolutely do it.
It's absolutely feasible, but there's quite a bit of risk there.
And especially because we can't operate this in real time,
these systems have to be somewhat autonomous.
So then imagine that it's here.
We have Mars samples.
They're sterile, they're pristine.
They're in the laboratory.
And you're the first person to get crack at them, right?
What's the first thing you do to those samples?
What's the first question you want to answer?
Oh, my goodness.
That is such a, I mean, if I'm the first person to see them,
I don't know if I could keep it for my friends.
I'd have to invite everybody over.
we can all look at this together.
I think, I mean, the first step for bringing back samples like this is you must triage them.
So we need to get a general sense.
What kind of rock is this?
What kind of minerals?
You know, just basic characteristics.
Because that will then tell you what the next question should be.
You know, if you have a rock that appears to be igneous, so from a volcano, the next questions
are going to be, you know, more about how did volcanism evolve in this place?
you know, what kind of volcano produced this material? And then what happened to it next?
If you get a sedimentary sample, totally different questions. You're like, okay, so now this is sedimentary.
Was it in place in water? What kind of water? You know, what's the nature, the properties of that fluid?
And then what kind of other minerals were precipitating there? And what does that tell us about the
habitability of that environment? And what kind of things could actually utilize? What are the energy sources that might have been there?
So I think, like, depending on the first canister that I open, you know, you go in a different direction.
So I'm hoping that we get some sedimentary materials that are high in manganese, and we'll know that before they come back from Mars, because we will select these very carefully.
So that would probably be something that we'll already know.
So I would pick, you know, my favorite canister to open first so that I could follow my favorite questions.
And for me, I'm really interested in understanding, you know, are there biosignatures?
that are preserved in sedimentary materials on Mars.
So these are chemical or mineralogical or even morphological features
that are left by life that can tell us something about what it was doing.
And then it can also, depending on the age of the rock,
tell us when it was doing that.
So those are the questions that I'd want to answer first.
All right, wonderful.
Well, I can hear your enthusiasm,
and it makes me excited to get these samples back here.
2031!
So thanks again for coming on our program and for telling us about it.
Yeah. Thanks for having me. It's been great chatting.
All right. Pretty awesome. She's amazing. It sounds like it's totally possible. Like this might work,
Daniel. It's basically a question of politics and money and then, you know, a little bit of luck.
Like if we actually commit to doing this thing and to sending this thing over there, we have a reasonable chance of it working.
Really? You know, something like 50% of missions to Mars fail, but that's a reasonable chance.
50%? Is that our hit rate?
Yeah, that's our hit rate.
And I think we have the best hit rate of any country on Earth.
But it's still, it's tricky.
It's far away.
These things are complicated.
But remember what NASA has pulled off.
Like, they have done amazing things, like the sky crane landing on Mars and all sorts of stuff.
Yeah.
So there's some pretty awesome engineers over there.
I trust them.
I think they deserve a couple billion.
Yeah.
Yeah, you're saying that the biggest challenge is just keeping this project funded because, you know, it takes years and years.
Is it like a 20-year project, 15-year project?
Yeah, if the samples do return, they'll be back here in 2031.
Wow.
And so it just needs constant funding.
And you know how it is these days with politics.
New administration comes in.
First thing they love to do is cancel the projects from the previous administration.
And so it has to be consistently supported by multiple branches of government in order to survive.
Yeah.
Well, sure.
Yeah, let's give him all the billions.
I mean, not all the billions, but a few of the billions.
Think of the things we could learn.
I'm always frustrated when there are opportunities
to learn something important and deep about the universe
and the only barrier is money, money that we have.
I would totally go into the universe knowledge shop
and spend lots of billions of dollars
to learn things about the universe.
You would totally press that red buy now button.
Mars Rock, buy now.
Sample of gas from Jupiter, buy now.
Secrets of the universe, click, click, click.
Deliver tomorrow, please.
Next day delivery.
Please.
All right, well, Dr. Lanser was definitely excited.
We're excited and good luck to the Mara scientists who are working on this.
And tune in in 2013, well, we'll break down for you
the incredible discoveries made by Mara sample return.
That's right.
Today on episode 3,000 of Daniel and Horace,
the universe, remember that time we interviewed one of the scientists?
No, it'll be two robots.
Two robots will have taken over the podcast by then.
Yeah, and together they'll transform.
into an awesome podcast robot.
Actually making good jokes.
That's right.
Banana Punatron.
All right.
Well, thanks for joining us.
Hope you enjoyed that.
See you next time.
Thanks for listening.
And remember that Daniel and Jorge
Explain the Universe is a production of iHeartRadio.
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