Cosmic Queries – Alien Worlds and Extremophiles with Kennda Lynch
(Originally Aired February 22, 2022)
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Transcript
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Hey, Star Talkians, Neil here.
You're about to listen to an episode specially drawn from our archives to serve your cosmic curiosities.
Check it out.
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This is Star Talk, Cosmic Queries edition and today's subject is extremophiles an alien world
one of my favorite subjects chuck what do you think about that topic uh kind of sounds like aliens gone wild
call right now it's aliens gone wild you've never seen aliens like this before extremophiles
I love me this sub a little bit of this subject, but we have one of the world's experts on it yeah on star talk today kenda lynch kenda welcome to star talk thanks for having me i'm so excited to be here
excellent excellent you you have a phd
in this stuff and but let me just alert people that your expertise is is some kind of amalgam of
whole fields that were previously distinct from one another.
Because I think of geology and I think of biology and I think of modern astrophysics.
And you just took a big fat stapler and crammed them together and then you and you do all three of these all at once.
How is that even possible?
It's called astrobiology.
No, but you got to know your geology too, right?
You do have to know your, yeah, I mean, so yeah, it's kind of this interesting thing where you just got to learn to wear a lot of hats and
you don't necessarily, you should have, I mean, ultimately you have expertise in one thing a little bit more than the other, but you have to know enough about the others to kind of pull those pieces in because ultimately they all are really interconnected.
And you also have to know when you don't know something and pull in the right people to work with you, but you have to be able to speak their language.
So having that understanding of geology so I can talk to a hard rock geologist about, you know, how I think my bugs are eating their rock, you know, is important.
And being able to have the same, you know, same conversation about it is really important.
Let me tell you something.
This is why I love being on this show.
It's the only time you will ever hear somebody say, and I have to talk to them about how their bugs are eating my rocks.
I did not see that sentence coming.
I did not either.
But Kenda, you work on Earth.
So why?
What does that have anything to do with aliens on other worlds?
Well, I mean, the reality is, is when we're trying to understand life in the universe right now, we only have one data point, and that's Earth.
So.
you know, we have to kind of work on Earth and try to understand life here.
And really, when we think about it, it's a big question.
How did life even come to be on Earth?
How did Earth come to be this big cradle where there's lots of life just kind of crawling all over it and in it and everywhere?
And let me let me help you with that, Kenda.
Uh, bugs started eating rocks.
Chuck, Chuck is not going to shake that sentence for the next five years.
Yum, yum, yum, tasty rocks.
But when we really try to understand looking for life in the universe, you know, a logical first question, and especially since we've tried and hadn't been too successful in the past looking for life on other planets, was, well, how do we, how well do we understand life here on Earth?
Do we understand the extent of where life can live on Earth?
Do we understand how life arose on Earth and kind of what did early life look like on Earth?
And, you know, where can we go to look for it?
And what kind of environments did it live in?
And those are a lot of the questions.
Okay, I'm an old man here.
When I learned about this, it was: we need the 72-degree tide pool for life to thrive on Earth.
Yeah, yeah.
That's how old I am.
That's how old I am.
One of the things that we have learned.
Life is not comfortable and lets its room temperature.
Yeah, no.
And it needs just the right amount of sugars and
it needs this special kind of media.
No, what we have learned is.
Every once in a while, every once in a while, life is just like, who touched that thermostat?
Exactly.
Now, which one of y'all touched that thermostat?
On its Barco Lounger?
That would be us as the life.
we we're the ones that kind of need to we need we are the ones that glamp right but but microbial life man every time we think we got those bucks figured out they do something crazy and we're like wait what do you mean you can live on a nuclear reactor wait what do you mean you can live two kilometers down in a in a subsurface in the subsurface and we find you when we're mining for gold what do you mean you can live
in like like super hot water that's also salty anacidic.
What do you mean?
So.
Okay, wait a minute.
Three sentences ago, you used the word glamp.
Could you please, for anyone over 50, could you just tell people what that word means?
It's like camping, but glamour camping, like bringing your house with you camping.
So you, you maybe have like, you're not really camping.
You're in the wild, but not really, because maybe you like towed a big old
trailer with you and that's your camper.
You know, if you can still watch HBO in your trailer, you're not camping.
Yeah, basically.
Basically, you know, if you've got, yeah, you've got a hot tub and, you know,
and you've got your, and you've got, and you've got your, your, um your Keurig or your Tasimo or your what's the other one you've got that making your coffee you're not camping that's why I camp at the Ritz-Carlton there you go
okay so you're a staff scientist at the at the storied lunar and planetary science institute um is that right is that no just lunar and planetary institute is that what they call it
yes right right and um that's based in houston houston texas and we're especially interested in you today because you um you're featured in episode two of Netflix's docus series, what's it called here?
Alien Worlds.
Yes.
So
pick up the action for us.
Where do we find you?
You find me
as far as in the episode, right when we open up right in the beginning, you see this alien landscape that kind of looks, in my opinion, it looks like Mars.
But we're actually in the Dalal hydrothermal system, which is in the Danikal Depression in Ethiopia.
And the Danikal Depression...
So hydrothermal, this would be heat emerging from Earth's crust, manifesting on the surface somehow.
Yeah, hydrothermal meaning that it's heat coming from
the Earth's subsurface.
And in this case, a hydrothermal system usually meets heat-generated waters, like geo-generated water manifesting up in the surface.
So there's water flowing the subsurface, passing over usually like what we call a magma pocket.
There's a big pocket of lava.
And there's water flowing over it, getting superheated and then pushing up to the Earth's surface and boiling out and spewing out all sorts of hot gases and everything like that and that's called a high thermal so at those at those high temperatures does it absorb a lot of minerals from the rocks that it passes through it absorbs a lot of minerals so there's a lot of um what we call um
anions and cations there's a lot of dissolved constituents um chemical constituents and especially in the dalal system it also goes through a subsurface salt deposit so not only is it getting minerals from like the the from just like the the ground the subsurface rock like over the magma pocket pocket, but it's also picking up all these minerals and dissolving all these salt minerals.
And so Dalal is amazing because it is, it's hydrothermal, really hot, and super salty, hypersaline.
And it's also acidic because there's also all this iron and sulfur that make it super acidic.
So and that's where you want to find life.
Yeah,
it's what we call a poly extreme environment.
And it's so amazing and it's a it's a crazy challenge for life.
And yet,
you know, there's multiple teams of us working there that are finding evidence for life
in this environment.
And okay, so the Dead Sea, which is a highly salinic body of water, could only have been named that by people who did not have access to a microscope.
Yeah, because there's a lot of life in the Dead Sea.
Salt,
just no fishes, no vertebrate fishes.
Kind of get the feeling that the Dead Sea was named because somebody drank it, and then everybody else was like,
You see what happened?
Everybody, don't, you see what just happened.
There you go.
Water, water, all around and not a drop to drink.
There you go.
There you go.
So tell me about the, I read something about there's an algae pool nearby or in some other parts of your work.
What's going on there?
In Dalal or in other sites that I work at.
Oh, well, just, I just, I just have notes that I'm piecing together here just pools of algae and a toxic liquid what's going on there?
So we have these bubbling pools right and they're literally like you literally have elemental sulfur precipitating out of these waters and you can see like sulfur.
So it stinks.
Oh it's it stinks and it's like
you think the Dead Sea is deadly?
Oh no.
Dalo is deadly.
You'll see when we're walking through there, you literally see if you get too close in the ground, there's so much hydrogen sulfide gas and carbon dioxide gas.
And if you get wait, you gotta tell chuck tell chuck what hydrogen sulfide gas smells like um rotten rotting eggs i listen no no you can he's a comedian you can do better than i knew what he was and i'm sitting here
i'm sitting here like holding himself holding himself down at my best
you have no idea the amount of restraint i just exercise
I have 15 fart jokes right now that are bubbling up in me.
I shouldn't say bubbling up.
That's the wrong way to talk about a fart joke.
But
Chuck has,
fartio's backed up in that whole time you're talking about this.
I was ready to explode with fart.
This is all I'm saying.
Okay, so hydrogen sulfide, H2SO4 is actually.
H2S, actually.
Oh, just H2S.
Oh, H2SO4 is sulfuric acid.
And that's what's in the water.
It's the H2S.
The sulfuric acid is actually, there's H2S, low molarity.
So, I mean, well, I don't know.
I haven't touched the water, but in other acidic environments, usually the H2S is kind of low molarity because I've also worked in the Rio Tinto acid river system.
And so the H2S is pretty low.
Like, it's not going to immediately burn your skin off.
You know, you'll get a nice peel, though, from it.
Okay, so that's the place if you're going to eat beans, no one will blame you for anything.
Because you got, yeah, you got total the whole landscape to blame it on.
Yeah, right.
I would do very well there.
Yes,
I would do very well there.
Yeah,
nobody's going to miss this.
Chuck, for one night only, an evening of fart jokes.
It's so crazy.
Hey, so Kenda,
where did you grow up?
I grew up, and I'm a Midwestern kid.
I grew up in a town called Rockford, Illinois, which is just west of Chicago,
about 90 miles.
I went into Chicago a lot for going to see shows.
Well, just to be clear, if you are just 90 miles west of New York City, you are across New Jersey into Pennsylvania.
So
to index your location to be 90 miles in any direction from Chicago, does that mean there's no other big city you can tell us what you're near?
No, not where I am because I'm west.
If I was east, I could say, you know, Detroit's not far away.
Detroit.
You know, Detroit, all right.
But I'm west.
So, no, it's kind of open plains and cornfields and stuff.
North of me, though, is Green Bay.
If I head straight north, you'd be in Great Bay in a few hours.
We've all all heard of Green Bay.
So I'm a Bears fan, so you know, let's not go there.
Oh,
the Bears.
So how did you,
so how do you land on Extremophiles as a career goal?
Oh, well, you know,
this is interesting because I had a different hat on when I started my career.
I actually started learning how to try to grow food and keep astronauts alive on other planets.
I started out as a system.
That's cool too.
Both of these are cool.
I started out as a systems engineer working on space station and trying to keep people alive.
But in my education, I dual, I was, I'm nuts and I did a dual degree.
I literally have two bachelor's degrees, one in engineering, one in biology.
But generally, if you're nuts, you don't have to tell that to other people because it's just completely clear.
It is.
By the way, all you have to do is say, I got two bachelor's degrees at the same time.
And people will look at nuts and go,
you must be nuts.
And so part of, yeah, so, yeah, well, yeah.
And I like pain, apparently.
So, you know, there's that.
Part of it, part of my training was to also learn about microbes because when growing, trying to grow plants and develop earth microcosms, you know, microcosms, you have to understand, you know, not only how humans live, but how everything else that's going to interact lives.
So I took classes in, you know, aquatic ecology.
I took classes in lake ecology.
I took classes in plant biology, you know, and I took classes in microbiology.
And so.
Well, wait, so at the end of the day, you realized you took two different majors worth of courses.
Is that what happened there?
Yep.
So what are the two majors?
What were the two?
The first one was basically systems engineering.
So it was all of, I took a full course of engineering classes, and then I took the full course of general biology classes.
And my engineering degree lets me specialize.
So I was able to use a couple of my upper-level biology classes for my specialization in engineering.
Wait, wait, wait.
So your PhD, what was the title of your PhD thesis?
A geobiological investigation of the hypersaline sediments of Pilot Valley, Utah, a terrestrial analog to ancient lake basins on Mars.
Wow.
Wow.
Okay.
That's why I had to read it.
I can't remember.
I got to tell you right now, I'm sorry he asked.
I retract the question.
The funny thing is, my PhD was still an engineering degree.
I unintentionally got three engineering degrees along the way.
I'm liking it.
Oh, the master's along the way?
Yeah, aerospace engineering for my master's.
Okay, so you were totally loaded.
Think about, since you're a microbiologist and you were talking about growing food as one of your tasks when you were working on space stations, what do you think about Matt Damon growing poop potatoes on Mars?
Poop potatoes on Mars.
We need the
final word there.
He would have had some problems with his thyroid because of all the perchlorate in the
regolith.
So yeah.
Wow.
So basically, wait, wait, just be clear.
Wait, wait, I got to unpack that.
Wait a minute.
Wait a minute.
So on Earth, we have soil right which is rich in microbes that participate in the ecosystem yep on the moon and on mars there is no soil yep
whatever the dust is there is like ground up rock basically yes and so and you call it regolith
we call it regolith because it has not been processed by microbes that we know of on the like definitely not on the moon and on Mars not that we know of and and we're not sure what the origin is of the organic matter that we have found so far on Mars.
So
we call it regolith because it's not soil like we know it on Earth that has been processed over years by microbes and
other
life elements.
And there's not a significant amount of organic matter making it kind of a
So he would have had a thyroid problem.
So when they picked him up to save him, he basically would have had a goiter.
Probably, or some other crazy issues.
his metabolic system would have been having some weird issues because perchlorate protect you know actually kind of competes with iodine to bind on your thyroid and we know that mars has an abundance of perchlorate in the regolith and that's actually something that um you know i'm working on with other scientists i'm it's kind of funny in my astrobiology life i'm starting to kind of go back to my to my human spaceflight roots um and bringing my astrobiology knowledge and my human space flight knowledge together as we're getting ready to go back to the moon.
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Hi, I'm Ernie Carducci from Columbus, Ohio.
I'm here with my son Ernie because we listen to Star Talk every night and support Star Talk on Patreon.
This is Star Talk
with Neil DeGrasse Tyson.
So Chuck, this is a Cosmic Aquarius.
So we put out the call and so what did you get?
Well,
we've got a bunch of people who actually,
believe it or not, are super interested in this subject.
I believe it.
I believe it.
It's like weirdly interesting.
It really is.
It really is.
Okay.
Let's start off with our favorite.
This is Violetta and her mom.
It says,
isn't that child grown up by now?
In college by now, Violetta.
She used to write it when she was like 11 and 12.
No, when she was 11 and 11 and a half.
Yep.
And 12 and 12 and a half.
Okay, well, here we go.
This is, hi, Neil.
Hi, Chuck.
Hi, Kenda.
Violetta here, the 13 and a half year old.
She's a full-up teenager.
Okay.
So you said it, Neil.
She did 11 and then 12, 12 and a half.
Now she's 13 and a half.
And a half.
All right.
Okay.
She says, I'm writing in from Washington, D.C., and my question is, what is the most surprising?
fascinating life form or trait about a life form here on earth that you have discovered or learned about in your career so far?
How did this impact the way you think about what life might look like elsewhere in the universe?
Thanks, guys.
And I just want to say to Dr.
Lynch, that the world needs more scientists that look like you.
Whoa.
By that, she means fabulous.
Looking fabulous.
Fabulous.
She says, thank you so much for doing and being an inspiration.
Thank you so much, Violetta.
So, oh my gosh, there's so many, there's so so many crazy.
What's the weirdest bug out there?
You probably have posters that rank the weirdest.
Don't tell me that you don't know what your answer is.
I'll give you my number one favorite because I just think it's so crazy.
The thought of it is just so crazy.
My favorite bug is
the one that can live on nuclear reactors.
It's literally the...
And does it have a name?
Yes, and I'm trying to remember the name.
It's not the tardigrade.
It's not the tardigrade because the tartride is not.
That tardigride is a micro, is a small organism, but it's a multicellular organism.
It's,
oh my gosh, my brain is, it's, but it's.
Okay, but tell us more about it.
So it can live like inside a nuclear action.
They found it living on nuclear reactions.
It could take these high doses of radiation, and it's got this cool shape.
It's actually kind of like a cube almost shape.
And that's what I'm saying.
Okay, in Japan, those things turn into Godzilla.
I was going to say.
That's how you got all those
Japanese monsters.
You're talking talking about a Marvel origin story right now.
Yes.
So somebody made some...
It's, oh, yeah, the name will come to me and I'll spit it out at some point later.
Okay.
I know I will.
All right.
So you'd like the radiation resistance?
I just think it's amazing that.
Again, it's this whole thing about every time we think we got bugs figured out, like, okay, here's their radiation limit.
Here's their life water limit.
Here's their cold limit.
Here's their hot limit.
And then bugs are going to be, yeah, no.
And they blow us right away.
And they're like, no, we figured out ways.
Yeah, we got this.
We got this.
All right.
So, so is this a single-celled organism?
This is a single-celled organism.
Yes.
Got it.
Okay.
Whereas the tardigrade is a whole macroscopic object with legs and
it's a multicellular organism, but it's still small and it's still something that has amazing, amazing resilience and can survive incredible, incredible environments.
So I'd be excited if we could find something like the tardigrade like on another planet, because it definitely has developed strategies to live in crazy environments.
It kind of basically desiccates itself and like goes dormant and goes into like a, it's like, you know, it's, they call it a water bear.
So it goes into hibernation, this really crazy, like dehydrated hibernation.
And it can survive all sorts of
insane environments, including being exposed to space.
Oh man, there's a whole episode of Star Trek Discovery devoted to a space tardigrade that they find that helps them navigate the mycelium network.
And the mycelium, cosmic mycelium network is this thing that allows you to move faster than light because you enter this network that kind of transports you almost instantaneously to different locations throughout the universe.
I love it.
I love it.
I found a tardigrade in there.
But who would have thought tardigrades were also spacefaring?
Well, if they came from space, initially, that's the big thing.
Cool.
Let's get the next question.
Chuck, what else you got?
All righty, let's do it.
Here we go.
This is uh-oh.
uh nander
nander sirkel
okay okay all right that's his that's your name now man
take it or leave it okay here we go
he says i often wonder when we're looking for life out there aren't we a bit biased by our own conditions for life itself like water or breathable air.
Even when considering silicon life forms, this still still assumes creatures living on planets.
Do you think it would be reasonable to consider, for example, other scales of life in size and space-time?
Maybe some life forms would be the size of planets, even galaxy, or quantum particles moving in time so fast that we, as slowpokes, can't even see them.
Whoa.
So, Kendra, what part of your PhD thesis dealt with
quantum life forms?
Not much of it, but I'll tell you, I was a fan of Star Trek Next Generation, so I'm there with this person's questions, you know.
But
quantum life forms.
So not part of that, but in astrobiology, we really do think about
what we call as life as we don't know it, or what some people like to call weird life.
And we try to think when we're looking for life, we try to do, we're developing this way to try to think what we call agnostically about life, which means life is we don't know to we're life.
So yeah, there's the problem.
We only have one data point, earth, and life.
And life on earth has these.
And even your extremophiles are part of that one data point.
Even though they're extreme and they can live on radio,
you know, live on reactors or breathe iron or, you know, eat other crazy, you know,
metals and things like that.
Rocks.
Eat rocks.
Yeah.
And even though they can do these crazy things, they all still have the same amino acids as we do.
They have the same stereochemistry as we do.
And we all have the same fundamental basically code.
We have DNA and RNA.
We all have the same fundamentals.
We all have that same base code of life that kind of builds the structure of life.
So yeah, when we think about life on another planet, we have to think about life as we don't know it.
What if they use a completely different stereochemy?
What if they use a different set of amino acids to build their proteins?
What if they have a different liquid?
I was just getting asked this in a previous conversation about
what about Titan where we have lakes of methane.
It's a fluid and life needs fluid for a chemistry.
Titan's Saturn's largest moon.
Yeah, where we've actually been there.
And we're sending a beautiful little helicopter that's going to go and land and study.
um the surface and those lakes and some of the organic sands there and try to try to understand um the possibility for prebiotic chemistry on titan and that's the question is is prebiotic chemistry possible in that kind of environment?
And what would it look like?
And what could life look like being, you know, arising in that kind of environment?
So yeah.
One of my favorite New Yorker comics was there's a crash flying saucer in the desert, and these two aliens are just crawling along the sands and one says to the other, ammonia.
Totally.
I mean, that's totally it, right?
I mean, it doesn't, I mean, on Earth, it just happened that water was the thing that was going to be, you know, the basis for life's chemistry, but that doesn't necessarily mean that that's how it's going to work on other planets.
And that's something that we do have to think about.
You know, and then thinking about the larger scale of life, we do have scientists that are, you know, they look at things called techno-signatures.
So we try to understand the scale of, you know,
contacting other
intelligent, you know, what we call intelligent, I mean, forms of life.
And get me started on the intelligent comet, you know, I don't know.
Yeah, we're not even that yet.
Right, right.
So the jury's still out on us.
The jury's still out on us.
Yeah, so, yeah, exactly.
So can I ask both of you this?
Is there a finite chemistry in the universe?
I know we have the pretty periodic table.
Is there anything that could be outside of that that could
actually contribute to life that is not on our periodic table?
No.
No.
That can't be a question.
No, no.
Everything that we know.
Now, there may be other elements that we haven't discovered just because we haven't discovered them yet, but no, I mean, because all life begins with stars, you know, all of our elements come from stars.
So the star stuff, that's the one common thing that makes it possible for us to really think about this question is that
the ingredients in the kitchen are the same across the universe.
So that's helpful.
Right.
Yeah.
It's just the rest of the, we do, we're doing better than that because we have created elements that the universe has never seen before in our laboratories.
Yeah.
So we've, we, we created two dozen more elements or 20, yeah, 20 or 20, yeah, about 20 more elements than we're currently there.
So
let me ask you this,
Kenda.
If
chemistry is the same
and basically geology is the same, right?
You put a geologist on a planet, oh, I know what rock this is, or we might have a different kind of minerality, but it won't be so foreign to them that they'll be befuddled.
Is there any reason, and the physics is obviously the same.
So if I have the same physics, the same chemistry, the same geology,
why can't we think that maybe biology
will all focus towards the same forms as we have here if everything else does that in the other branches of science?
I mean,
that's a load of question because it's not,
it's,
I mean, we can expect some of the same principle things to happen.
Like, there's going to be some kind of cell wall structure.
There's going to be an encoding system.
There's going to be some way to transfer information.
There's going to be some way to move energy and generate energy.
There's going to be some way to move things in and out of an interior environment.
Those kinds of things, yeah, we can kind of figure out that those kind of are the common elements that are going to make life happen for biology.
And those are the kind of things that we agree.
We agree that we actually kind of agree there's a common set of
about eight things that all life, you know anything we call life would probably have going on now how they get it and how they put it together that's where that chemistry is different and that's where the the environmental context that made the geology is probably different you know that's going to be and that's where you know you know and that's where maybe some of the physics because the gravity is a little different so some things are slightly different that help you know drive that environmental context.
So does that make sense?
I can say that you're not going to expect life forms the size of galaxies.
No.
Can I tell you why?
I'll tell you why.
Okay.
Okay.
So our galaxy is 100,000 light years across.
Okay.
100,000.
If that were a life form
and one part of it had an itch,
how long would it take to scratch that itch?
If you can't, you can't move faster than the speed of light.
So it has an itch and then it brings one part of it over to the other part to scratch it.
100,000 years later, it scratches the itch.
This is not primary, in fact, fact,
this is not a this is not a coherently functioning organism.
Exactly.
And if evolution requires a lot of experimenting,
then the life form has to be able to change either on purpose or by accident
fast enough so that you can have enough of these experiments for it to take on interesting forms.
And if you're really, really big, that doesn't
mean that.
And if it takes 100,000 years to scratch an itch, just imagine how uncomfortable it would be when its underwear gets stuck in its butt.
Okay.
I'm more thinking about the size of the underwear at this point, you know.
So just like I know.
Sorry.
Well, just to be clear, I wear boxer briefs, and boxer briefs don't get stuck in the butt.
Oh, okay.
Oh, look, it's you, sexy dragon.
So let's see if we can squeeze one more in before the break.
All righty, let's do it.
Here we go.
This is
Achillesha.
Kashyap.
Man,
y'all just messing with me now, man.
That ain't a real name.
Okay, it's A-K-H-I-L-E-S-H.
Achillesh.
Achillesh Kashyap.
C-K-A-S-H-Y-A-P.
Kashyap, I hope.
Okay.
Okay.
Hello, Dr.
Tyson.
I'll give you a B minus on that one.
I get an A minus.
Okay.
A B minus.
Oh, B minus.
Damn.
You just keep, I keep going down.
Before you know it, it's just like you're expelled.
Hello, Dr.
Tyson.
Hello, Dr.
Lynch and Lord Nice.
Oh, okay.
I am a first-time Patreon member.
Nice.
And my question is, if we discover life on a restricted body, like Europa or Enceladus, are we allowed to study them only through orbiting satellites?
Or can we bring something back home and cut them open for science, of course?
I mean, you went dark there.
You went dark at the end, bro.
Okay.
You started off with,
real good.
You started off with our continuing mission
to seek out new life, new civilizations, and then you ended up with, let's just cut these suckers open.
Well, be careful.
There's some folks around where Kendra hangs out in Texas.
Where, can we bring it back and barbecue?
Yeah, yeah, I agree.
We will get to that answer after the break on Star Talk Cosmic Aquarius with astrobiologist Kendra Lynch.
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We're back for the third and final segment of Star Talk Cosmic Aquaries.
Kenda Lynch is with us, who's an expert in microbes on Earth as possible analogues to microbes in the universe.
So,
Kenda, over the break,
you remembered this
radioactivity-loving microbe.
Yes.
The name of it.
What's it called?
It's called Dinococcus Radiodurans, and they love they literally can live on um they found them on nuclear reactors and they are very um you know dinococcus
dinococcus yes radio durant this sounds like a rock group it does doesn't it it really does you know
chicago are you ready
dinococcus radio durant check it out
wow that's cool
okay so we we left off with a question
about.
What was it, Chuck?
So he wants to know that if we discover life on
a restricted body like Europa or Enceladus.
It's protected by NASA laws, basically.
So, you know.
Can we actually study it just through satellites orbiting, or can we bring back something and cut it open?
Well, I mean,
you know, to cut it open.
Wow.
So, I mean.
Well, let me just back up for a second.
So NASA has a department of planetary protection.
And
there's a code within them, which is
not a computer code, but a behavioral code, whereas they're these selected objects in the solar system that may have life.
We don't mess with them, or if we do, we go in a highly sterilized way.
And if we bring anything back to Earth, we want to keep that quarantine to make sure it doesn't kill us.
That's their job.
Yeah, and that's the Planetary Protection Office.
And the answer is we're moving into this phase of science where we are trying to bring things back because we realize that we need to bring things back to be able to study them better, to understand if there's life in them or not.
Right now, we're in the process with the Perseverance rover
in Jezreel Crater for the Mars 2020 mission.
They're caching samples that we're going to send a...
a lander to go and pick up those samples and hand them off for the rover.
And we're going to bring those samples back to Earth from Mars.
And we actually are have missions that are being developed to go to try to land on both Europa and Enceladus.
And Enceladus is my favorite.
It's one of my favorite icy moons, by the way.
I love Enceladus.
To try to understand, to look at the surface and maybe eventually try to get a sample, a sample that that came up from the subsurface ocean on both of those planets, you know, that we can study in Situ.
And maybe someday we can figure out how to bring those back.
But right now, the goal is to just try to get to land on the surface and try to study samples in situ to see if we can find evidence for
possible biosignatures of life.
So I may be mistaken with this question, but I'm just going to ask it.
Did we not learn from what's Madam Saturn, what Carolyn, Carolyn Porco, that they're going to try to fly something through one of the plumes of Enceladus and maybe collect what's being you know pushed out of the uh the ice?
Yeah, we have a we have a mission that's going to try to do that.
I um well, we also have Europa Clipper that's going back to Europa
that's going to, that's going to, that might even be able to do that with Europa Clipper.
But we're also trying to fly through the plumes of Enceladus.
We have the Enceladus orbit lander concept that is looking at doing that, like orbiting, but also sending a lander down to the surface to pick up, to do some in-situ science on the surface of Enceladus, hopefully near one of the tiger claws where all this stuff is pewing out.
Okay, so that's that's the third time you said in situ.
Sorry.
In five sentences.
In situ means.
In situ.
Excuse me, Madam Latin there.
That's all science, especially biology.
We like throwing Latin around everywhere.
You've thrown that Latin.
Everything has a Latin name.
Everything has a Latin name in biology.
Yeah, yeah, it's Latin.
So, so let me emphasize something that I think you said, but just wafted by it.
The ice on Europa is very thick, but it also cracks and then water seeps up in the cracks and refreezes.
So
you're going to be astrophysically lazy.
And instead of trying to dig through the ice, you're going to try to see if there's anything that came up through the ice and froze there that requires no digging at all.
Well, I mean,
yeah, I mean, there's, it might require some digging for the, you know, the subsurface, but there are, you know, we have some really brilliant scientists, not me, but some of my colleagues that are really brilliant that study the kind of the ice.
Other brilliant scientists.
Other brilliant scientists, not me, because I don't study ice dynamics.
I'm a, you know, I'm I'm the biology one, but they study kind of that geology of those ice dynamics, and they found that there is likely water that is seeping up from the ocean and kind of connecting in the shallow subsurface and doing things that they can actually see on the surface from remote sensing.
And if that water below the surface had life, it would have gurgled up and frozen in place.
You'd have freeze-dried life.
Yeah, exactly.
If we can access some of those areas where that life kind of gurgled up.
And then Enceladus, of course, we've got, you know, the tiger claws just spewing, you know, stuff out into space.
So we can try to capture some of that and then we can also land on the surface
and we can see that maybe kind of fell back down if anything you know okay so how sterilized do your probes have to be to land on a protected
that's the challenge of doing this is that yeah you've got to make sure not only that the lander is very sterile but that um that you know all the instruments that you're working on are very sterile everything everything there are they're even working on concepts a coronavirus found on yeah yeah just make the make the lander wear a a mask.
Yeah, that's all everything, Chuck.
Just like, make sure you wear your mask, Lander.
Use hand sanitizer, right?
Use hand sanitizer and show us your vaps card before you touch that.
So, yeah.
All right, Chuck, give me another one.
Another question, Chuck.
All right.
You know what?
I got to ask this just before we go.
I know I'm not a Patreon.
But.
So when you talk about this water underneath this, basically, you know, this planet,
you got the ice like a crust and and then the water underneath, but then you have other bodies in space that are just frozen solid pieces of water.
Why doesn't the planet just freeze all the way down?
Why is there water underneath that ice that can
on the moons?
Yeah, on the moons, not the planet.
I'm sorry.
Why do we have these ocean worlds on moons around Jupiter?
On moons.
Well, first of all, a couple of different things.
First of all,
there is, we get heating from the gravity, the extreme gravity that causes what we call tidal heating.
And
Neil could probably explain that better, that kind of pushes and flexes and causes heating, that kind of adds some heating to the planet and keeps it warm.
Plus, these waters have lots and lots and lots and lots of salt, lots of salt, that are keeping, that are depressing
the freezing point.
So
the water is able to stay liquid because there's so much salt in it that that freezing point gets lowered because there's so much salt in it keeping it liquid.
It's been rumored that zero on on the Fahrenheit scale is the freezing temperature of a supersaturated solution of
brine, of salt water.
It's been rumored.
And so that's where you get a zero.
That's the coldest liquid they could get that would freeze.
And then regular water just goes, freezes at the warmth of 32 degrees on the Fahrenheit scale.
But yeah, no, you said it perfectly, Kenda, just the tidal stress between Jupiter and the tugs of other surrounding moons are pumping energy in.
And so now there's a heat source that has nothing to do with the sun.
I learned in my biology books, you need sunlight for life.
What you really need is just energy.
Take the physics angle on it.
You just need energy.
And you pump energy in from tidal forces.
You got it.
And what they think is going on in Enceladus is they actually think that heat is also generating kind of, and maybe it's maybe some residual heat, but probably more of the tidal forces in Enceladus, generating heat that's causing hydrothermal.
hydrothermal vents like what we see on earth you know the deep sea hydrothermal vents with the black smokers and things that you see like on the National Geographic videos.
They think that that's what they're seeing in the in Enceladus.
And that's kind of what's kind of helping to kind of possibly generate the tire clause, pushing that energy out.
And that is creating a lot of cool chemistry that
life could take advantage of.
So, Kenda, we've had Natalie Starkey on the show, who wrote a book recently on all the cool, literally and figuratively, things in the universe, volcanoes, hot and cold.
And she describes Enceladus as an ice volcano.
Yeah, cryo-volcanism.
And the plumes are just where you just need extra pressure buildup.
It didn't have to be hot compared to us.
It could just be pressure in its own environment, even if it's very cold.
So very cool.
Chuck, keep it coming.
You can't keep it coming in that.
That's so cool.
Cryo-vulcanism.
Yes.
If that doesn't make you love science, you're dead.
I know.
I want that on my business card.
Exactly.
I'm a cryo-vulcanist.
What are you?
Okay.
All right.
Here we go.
This is William D.A.
Thank you, William.
Thank you.
He says,
given that humans have always been fighting a war with tiny bacteria, viruses, and prions, et cetera, how likely do you think?
it is that there's a planet out there with a tiny microscopic organism and it wiped out the more complex life.
What would such a planet look like long-term?
And
that's what he said.
So, if we're in a war,
if we all got killed by a virus here,
then what happens long-term, even if it's just here on Earth?
Yeah, ultimately, do all the little things kill all the big things, and you just have a planet full of viruses
or single-celled organisms?
Yeah, what is it?
Where does the biology go?
Hey, what's up, Corona?
What's up, Strepococtis?
Hey, Rhinovirus, how you doing today?
Yeah, everybody's just chilling.
They got cities and things.
Get out of here, herpes.
You weren't invited to the biology.
You got invited, man.
You know, given that we've already had multiple mass extinction events on the planet already,
where we've, we're like not necessarily microbes have taken out our bigger organism but something else usually an asteroid or something else took out our larger eigen organisms life has just kind of rebounded and yeah for a while the the little guys were you know the little guys were in charge but life eventually kind of picked back up and and and organisms got more you know there's there's an advantage on earth for multicellular multicellularity.
And so life eventually kind of worked its way back to multicellularity at some point, you know, and those small guys got bigger and bigger and more complex and more complex each time.
But we've, you know, so
I would say is if we had a micro-generated mash extinction event, my guess is, yeah, for a while, the little guys would be in charge.
But then eventually,
you know, depending on the, you know, the environment of Earth.
If it's advantageous to take advantage of resources and to keep yourself alive to become multicellular, life would probably go back to being multicellular or having a multicellular component on the planet.
That's an excellent argument because if we've done it multiple times in the past, why not again?
I mean, after the KT extinction, nothing bigger than, you know, a suitcase or something.
Whales and rats and like small rats.
Yeah, a duffel bag, which is the biggest sized life form.
And now we have, you know, the blue whale swim in the ocean, the largest animal there ever was.
So, a very good argument there.
Yeah, I'm with you on that.
That's very cool.
Very cool.
Chuck, we got time for like one more, I think.
What do you got?
All right.
Let's
go to Kevin, the sommelier.
sommelier.
Kevin says.
I like Kevin.
Yes.
We're going to party with you, Kevin.
Kevin says, you know, when I'm sitting around drinking a Chateau Neuf de Pas, I often...
But no, did I?
I know he doesn't.
No.
No, no.
I just threw that in there.
Okay.
I thought that'd be cool.
All right.
That was cool.
I wish he did start like that.
Kevin says, astrobiology used to be termed exobiology.
Was this just a rebranding to make people more interested in it?
Like when Coke introduced new Coke,
but had to go back to classic Coke?
Well, keep drinking up, Kevin the Samonier.
That's a very good question that I'm thinking about here because, you know, the reality is, is that when I fell in love with this, it was exobiology.
When I was, and I'm not going to date myself, but when I got my first lecture, it was from this gentleman named Donald DiFincenzi, who was a part of what was called the exobiology office at NASA and FYI.
NASA always had an exobiology office.
NASA started with an exobiology office.
So this has been a question that NASA has wanted answered since the beginning of NASA.
So this has been kind of part of our charter from the beginning.
And so I think the big transition came obviously after the Viking results, but I think the big transition came after
the Allen Hills Rock and the discovery of the organics in the Allen Hills Rock, and
the hypothesis that these organics were made by Martian microbes, and these kind of microbes made these special, you know, the whole argument about the biogenicity of the organic structures in the Allen Rocks.
The Allen Hills Rock is about the size of an Idaho potato, been sitting on the shelf for years.
We knew it was a meteorite, but no one really knew much about it until, like you said, the Viking mission, we have accurate measurements of of the atmosphere of mars from that mission and pot air pockets trapped in that rock matched that air exactly and oh my gosh a rock from mars
rocks um meteorites was born i never mind looking ignorant because it's my specialty
please tell me what the allen hills rock is the allen hills is a mars meteorite we know as as neil said that it came from mars because we look at these little little bubbles in it that keep gases in it and we're able to extract the gas and look at the gas composition.
And it tells us that it has the exact same composition of the gases on Mars from our Viking results.
And so we know that this meteorite was a piece of Mars that got blasted off and traveled to Earth and kind of landed on Earth.
And so Allen Hills is one of what we call an SNC or a Mars meteorite that came from Mars.
And
just for background, there's a set of hills in Antarctica called the Allen Hills, where the glacier that is like permanently on Antarctica for now,
as it migrates, it comes up against the hills.
And if any rock fell from space and landed on this glacier, it gets dragged to these hills and deposited there.
So it's a really convenient way to scoop up
meteorites without having to comb thousands of square miles of area.
You let the glacier do it for you.
So it's in Allen Hills and was founded in 1984.
Wow.
And
they still do annual trips, or they have been, I don't know if they stopped because of COVID for a while, to Antarctica to look, to go out and look on the glaciers for meteorites.
Because anywhere else, you actually have to watch it fall to kind of go look for it.
Or you have to, you know, and we've had, we have people send us rocks, especially at the LPI, all the time.
I think it's a meteorite and it's not.
Yeah, it's here.
We call the meteor wrong.
Exactly.
The meteor wrongs.
Yeah, exactly.
No, the point is,
Is it most?
Certainly, possibly as much as half of all meteorites in our collections come from these ice sheets and people wonder well do the meteorite the meteors aim for the ice sheets no that's the only place you would find them if they fell otherwise you have to sift through countless other rocks in the forest to know which one came from space and most of the ones that are verified that weren't fellen on the glacier is because somebody watched it fall and tracked it and that's yeah exactly exactly so but the point the point is is that after you know we got allen hills and this was back in uh i think it was 92 93 is that right um when they this this study came out and they thought that this happened, and everybody kind of disagreed, and we had arguments back and forth about are they life, are they not life?
And then we realized, do we really understand what life is?
And this is about the time that we started learning about, we started learning more about extremophiles and the RNA world,
the vastness of the RNA world.
And we started learning more about biotechnology and our capabilities for
higher sample resolution and
sample detectability
in our instruments got higher.
So all of this kind of stuff made us start to question.
When the instruments got more sensitive.
Yes, thank you.
More sensitive.
Can't find my words today.
That's fine.
But all of these things kind of together kind of, you know, with that Alan Hills discovery.
And at that time, they went back and looked at the Viking results and realized that Viking would not have necessarily caught everything because of
the sensitivity wasn't high enough, right?
So there's all of these things going on.
You know, we started asking the question, like, what do we really know about life?
Do we really understand life on Earth?
Do we really understand the extent of life or what is alive on Earth?
And so that's where astrobiology, because it was looking, exobiology was like looking for life elsewhere, but astrobiology includes understanding how life on Earth also came to be.
How did we become to be a living planet?
So that's where the new term astrobiology came from because it became about looking for life on Earth, looking for life in the universe, but also trying to understand how did we become the data point that we have now.
So I take the meta view, which is everything the astrophysicist does in space has a counterpart here on Earth.
And so you want to glue together astro in front of each of those words.
So we have astrochemistry, astrobiology, astro particle physics.
So astro.
Astro.
We're the push cart for it.
There you go.
I like that one too.
Funny how the astrophysicists become the quarterback of the team.
Oh, I just saying.
Yeah, there you go.
We got appointed by the universe itself
to be that role.
Come on now.
So, Kenda, I remember when that Alan Hill's rock made news, and it was a research paper by some folks at Johnson Space Center making the claim that maybe this has evidence for life, which meant life was on Mars.
I remember it like it was yesterday.
And there was some chemistry within the rock.
And then
there was a photo of a worm-looking thing on the surface.
and
we didn't know what it was it was really tiny but it was just kind of intriguing it made a good headline photo but the the better evidence was from the other chemistry going on in the rock i was on a talk show to comment on this rock and they had me a philosopher and a biologist And the philosopher said, how do we know whether the rock itself is not alive?
Okay, we got that out of the way.
We've got to make that.
Stop smoking it, dude.
We have to get past that.
And then,
so then they put up the photo of this worm thing, and the biologist says, that can't possibly be life.
And I'm thinking, wow, the biologist must know a lot to know that that can't be.
So I said, well, how come?
And he says, oh, because that's one-tenth the size of the smallest microbes on earth.
And I then said, last I checked, this is from my.
it was like, and I realized how narrow the thinking was of biologists.
Because, like you began this program, Kenda, if you, if all you have is a data sample of one,
you have no capacity to think differently.
Everything has to be shoehorned into your own understanding of the world.
And I was perfectly happy to have it be a life form that we don't know anything about.
Deal with it.
And that biologist today is working at McDonald's.
I don't remember who that was.
I don't know.
Probably not.
We got to call it quits there.
Ken, it was been a delight to have you on the show.
I remember you when you were in graduate school and you're all grown up now.
It's so bitchy.
It's such an honor to be here.
I'm so glad that you remember me.
And actually, we finally found you in the ether.
And
we can find you on Netflix, episode two of Alien World.
And we're loving it.
And Chuck, Chuck, always good to have you there, my co-host.
Always a pleasure.
All right.
Emile deGrasse Tyson here, your personal astrophysicist.
Keep looking up.