StarTalk Radio - Cosmic Queries – Building Space Civilizations with Ariel Ekblaw
Episode Date: April 18, 2023When will we create a livable habitat in space? Neil deGrasse Tyson and Matt Kirshen explore the possibilities of tessellated space structures, artificial gravity, and other challenges with Founder of... MIT Space Exploration Initiative, Ariel Ekblaw.NOTE: StarTalk+ Patrons can listen to this entire episode commercial-free here: https://startalkmedia.com/show/cosmic-queries-building-space-civilizations-with-ariel-ekblaw/Thanks to our Patrons Rafael Pérez Pastor, Jay Patel, Justin Sharkey, Nick Wood, Debbie Karimullah, and Patrick for supporting us this week.Photo Credit: NASA/Donald Davis, Public domain, via Wikimedia Commons Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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Welcome to StarTalk, your place in the universe where science and pop culture collide.
StarTalk begins right now.
This is StarTalk Cosmic Queries Edition.
Neil deGrasse Tyson here, your personal astrophysicist.
I got with me co-host Matt Kirshen.
Matt, welcome back.
Thank you so much.
How's it going?
All right, dude.
You host Probably Science.
And you're based out in LA, right?
Is that right?
I am.
And I'm briefly back there.
I've been, I think every time I've recorded with you recently, I've been in a different
hotel room.
But this is...
I don't need to know your private life.
Why are you giving me that much information?
I didn't ask.
Did I ask?
Just, I'm the highest bidder. We'll take wherever you need me that much information i didn't did i ask just i'm the
highest bidder we'll take wherever you need me to go just excellent so matt this is a cosmic queries
edition on everybody's favorite subject space civilizations oh my gosh oh i love thinking about
it but i claim no particular expertise in it so we combed the landscape and we found somebody who was all up in it, all up in space civilizations.
And someone that goes by the name of Ariel Ekblow.
Ariel, welcome to StarTalk.
Thank you so much for having me. It is such a treat to be here.
Excellent. Excellent. And so I'm looking at your having me. It is such a treat to be here. Excellent.
Excellent.
And so I'm looking at your resume here.
It's like, what?
What?
I feel like a dog hearing a high-pitched whistle.
You're CEO of the Aurelia Institute.
Okay.
I'll read some more here, and then you're going to have to do some explaining here. Founder and director of the MIT Space Exploration Initiative.
Author of Into the Anthropocosmos.
Got it.
One word there.
Whoa.
And your research focuses on Tesserae platforms,
which sounds very acronym.
So let's see if we can unpack that.
Tessellated electromagnetic space structures
for the exploration of reconfigurable adaptive environments.
And you want people to buy that?
Terribly tortured acronym, never again.
I learned my lesson.
Oh my gosh.
You could call it just, let's go to space, right?
So tell me what all this is.
So what is the Aurelia Institute?
What's your background first? What's your background? Yeah, so background, my parents are both
pilots. Grew up with a real love of science fiction. In undergrad, I studied physics, math,
and philosophy. Always really loved big picture questions about the universe, but I decided I
want to get more concrete, not just, you not just studying physics and cosmology and particle physics.
So I transitioned in grad school to do space exploration.
And my PhD was Tesserae, looking at robotic self-assembling systems to build habitats out in orbit that are way bigger than your biggest rocket payload ferry.
Wow.
So I remember going decades back.
Wow. So I remember going decades back. Who's the guy who had the L5 Society? He was founder of it, I think.
Oh, I don't know. This is the L5 Society?
Jerry O'Neill.
Mr. O'Neill, right. He was into big space colonies. High Frontier, like his vision for life in space,
I think was really compelling.
We'll do it a little differently now.
It's a little different than how it was consumed up in the 60s and 70s, but yes.
Right, because he was almost cult-like.
And I'm presuming you're born well after that man was long gone,
but you're now trying to res...
That's why I asked Matt instead of you,
because he might've been alive,
but you dug up his ashes and you're're trying to reassemble the man's ashes.
Yes, yes.
Because I've seen artist's illustrations of what he was imagining.
Is that what you're imagining?
That is what we're imagining.
The secret keystone of our system is going to have Jerry O'Neill's ashes in the 70s.
I have Jerry O'Neill's ashes in the 70s corner.
I'm joking.
Okay.
But no, it is very much a source of inspiration,
which is large-scale, science-fiction-worthy space structures.
How do you build them?
And then how do you think about the society operating and hopefully thriving, not just surviving inside of them?
So tell me, Tesla lady, we've all seen that word,
and we think we know what it means.
And I think I know what it means, but you've got it applied to space here.
So tell me what's going on here.
Because when I think of tessellated, I think of a same shape repeated, but maybe, but shifted a little bit so that you can, you can build a surface out of it.
A pattern.
A pattern.
Right.
Tell me more about it.
Tessellating.
So the idea of tesserae is to take pentagons and hexagons.
They tessellate in 3D.
And when you have enough of them, they form a buckyball.
Again, really inspired by Buckminster Fuller,
Space, Earth.
People have seen geodesic domes before,
but it's a particularly efficient shape for space.
You want to maximize your interior volume
for a given surface area.
So a sphere would be super efficient.
What's a little bit more easy to build than a sphere?
It is more modular, a buckyball.
And so the tiles of the Tesserae are pentacons and hexagons that can pack flat in a rocket.
Basically think about it like a glorified PEZ dispenser.
Once you're out in orbit, those tiles are...
Now we're speaking my language.
Yeah, now we're like, okay, we're good.
Does it have a little duck head on it?
It has a little PEZ on it? It has whatever you like.
You just pop out the
basic bricks,
basically. The bricks, exactly.
Your construction unit.
We sometimes talk about them like space Legos
if Legos had magnets.
So it's meant to be really simple.
They find each other. The tiles have some
sophisticated code and sensors and electronics
that help them dock.
The magnets supply the docking.
And if they do it wrong,
if the two tiles come together incorrectly,
they pick up on that themselves.
They have this intelligence
embedded into each building brick,
into each unit.
And then over time,
they're able to assemble a large dome
or a self-assembling habitat.
You have intelligent bricks, basically,
self-assembling pieces here.
Exactly.
Well, if they're that intelligent,
why would they misattach in the first place?
Gotcha.
You got me.
I was going to ask the tough questions.
Well, we don't want to over-constraint them.
And so there's some freedom of the magnets
to dock in and out of plane.
It's important for some of some freedom of the magnets to dock in and out of plane. It's important for
some of the flexibility of the system overall. And so then being able to have self-corrective
logic is an important piece of it. The other aspect is the beauty of a modular habitat is
very different than any other type of space habitat we have right now. If there's a micrometeorite
impact that hits a tile or in a happier situation, maybe you're having a conference in
space and where you had a window tile yesterday, now you need a birthing port to be able to welcome
10 other spaceships to come join you. With a reconfigurable modular habitat, you can pop tiles
on and off at will. And so you can have essentially a habitat that evolves to your mission needs
over any period of time.
Wow.
Okay, so it is Legos.
It is Legos.
Yes, space Legos.
I don't like my Lego being smarter than me.
You know, that could give people some angst out there.
Yeah.
Right, right.
No, no, no.
They're very friendly.
They're very friendly.
No angst out there. Yeah. Right, right. No, no, no. They're very friendly. They're very friendly. No angst allowed.
How do you deal with gravity?
How do we deal with gravity?
Are you rotating?
What do you have going there?
Yes.
So the initial conception is using microgravity
to help themselves assemble, right?
So they're floating in space.
And then some of the work of Aurelia Institute
that you had alluded to earlier
is moving beyond these just kind of
passive pressure containing orbs
to actually rotating them to get artificial gravity.
So the next series of projects
that we're working on designing
are around the artificial gravity direction.
But the way that we work at Aurelia
is we test out these concepts in miniature
in space demonstration missions, technology
demonstration missions. So the technology behind Tesserae, the small tiles have been tested twice
now on the International Space Station. They're still under development and we're just beginning
to conceive of a similarly small scale test bed that will help us learn more about bearings and
rotating large, you know, pieces of architecture in space to get artificial gravity.
But it's all part of this larger tech roadmap.
All right.
So one thing to have the house.
Now, where's the food come from?
Ah, the space food.
Well, fermented food.
We're thinking about what are all of the accoutrements that need to go inside of that habitat to make it a real life,
worth living, where more people see themselves in that environment.
I think a lot of
people look at the International Space Station and it's very impressive, but it looks like a science
lab. Not everybody wants to live inside a science lab. So the other things that we had worked on
for the last six years at the MIT lab, that's where I started before we spun out Aurelia Institute,
we were looking at fermented food, miso. We flew miso to the International Space Station.
We designed musical instruments that could only play in microgravity
so that we're inventing new cultural artifacts for life in space.
Looking at biophilia and how do you surround yourself with plants
that's more than just a factory farm in space.
What is a musical instrument that can only work in microgravity?
How does it physically differ?
Right. So there's kind of a couple ways to do it. One is that the physical mechanisms
only make sound when they're floating. So when they're passive and they're on Earth,
there's just passive, there's not anything happening, but they actually have some agency.
And as they begin to float or are tossed between two human players, two musicians in orbit,
that's where the sound is generated. The other way to do it is with accelerometers. So Nerd Nugget, a way that we're actually able to use sensors to measure the
presence or absence of gravity and acceleration. And so you can also do it with accelerometers and
essentially a synthesized digital music. So you can have a whole zero G orchestra.
That would be hilarious. I love that you just said that. That's exactly what we have been working up towards, is we have
a few instruments, and the idea is to have a
zero-gravity orchestra.
Okay, but you know what you definitely need, though? What?
You need a theremin. Oh, we so need a theremin.
That's very popular. Okay, a theremin doesn't need gravity.
I think it's just electromagnetic fields.
And you know a theremin, Matt?
I do, yeah. A friend of mine
had one. It was a lot of fun. It's the official
sound of aliens in 1950s movies. That's so true. Um, yeah. Yeah, yeah. A friend of mine had one. It was a lot of fun. It's the official sound of aliens in 1950s movies.
It's so true.
Have you actually tried, like,
I'm aware of the idea of rotating a spacecraft
to generate artificial gravity.
Has that been tried in real life?
Or is this just something that's theoretical?
So it's theoretical, but it's very practical.
So it's not an open science question that we have to solve.
It's more like open engineering, logistics, design.
Very important distinction.
Excellent distinction there.
Right.
It's not like, well, how do we do it?
No, it's just like rotating gravity.
Yeah.
Right.
Yeah, got to build it.
Yeah.
So we're working on small scale mock-ups to get us there.
And then the idea is to learn enough about the ways that subsystems interact
that when we actually build the big one
that we've learned enough to make that
a successful project.
Well, I can't believe we made this like a whole
subject for this show, which means
we solicited from our Patreon
members questions on
this subject. And Matt, you have them all. I haven't seen them.
I do, yes. So, yeah, see what you can
slip one in before we end the first segment.
I can certainly do that.
So Cameron Bishop says,
I've seen a lot of artist impressions
of future human exploration
in places like Cloak's proximity
to Jupiter or Saturn.
Apparently, Neil, you've even said
you want to do ice fishing
on one of those moons.
Yeah, I want to cut a hole in the ice
and go ice fishing.
Get in there.
But aren't those planets and their close orbits encasing shells of in the ice and go ice fishing. Get in there. But aren't those planets
in their close orbits
encasing shells
of very high energy belts
of radiation?
How are we going to ensure
that future explorers
aren't microwaved
like a hot pocket
when visiting the awesome planets
in our solar system?
Nobody wants to be a hot pocket.
Okay.
Yeah, so, Errol,
what are you doing?
I mean, not only, obviously,
Jupiter has a very hostile
radiation environment,
but even if you're outside of Earth's protective magnetic blanket,
what protections do you have?
It doesn't sound like your triangle, your pentagons and hexagons could do this.
Can they?
It depends on what materials we choose.
So we're modeling some of the structures for around lower orbit,
similar to what
the ISS is, so a stuffed Whipple structure. But once we're actually beyond lower orbit, beyond the
Ben Allen belts, there is a much more significant radiation load. And so some of the proposals,
I wouldn't take credit for inventing them, we're building on the shoulders of giants here at NASA
and others, but things like water walls or additional metal shielding, other types of radiation protection that can be built into the habitat infrastructure for a longer duration mission.
Because water is highly absorbent of high energy radiation.
So you're thinking maybe that your sphere, your bucky sphere, it has a layer of water on its outer surface, perhaps?
And it's a good way to also get what we call the environmental control and life support system going.
There's a lot of water that needs to be recycled in a space habitat.
Gray water, like what you do in a building on Earth.
We do recycle urine in space.
And so being able to make use of those liquids in other contexts, maybe for water walls or radiation protection, is one of the proposals that's out there.
So you recycle urine as well as like body sweat that evaporates into the air, right?
Right, right.
All of that.
All of that.
It's important.
It's a closed loop ecosystem.
The best that we can do to really make it a closed loop recycling ecosystem is super important.
Ariel, if I'm going there, I'm going to lasso a comet so I have fresh water every morning.
There you go.
Y'all could drink the pee.
Recycled pee.
I'm going to have my own tap of keg right out the window.
Nice question.
I would have got my own damn comet.
Yeah.
Yeah.
So, okay.
So, it's an engineering challenge that does have solutions waiting to be invoked.
But you don't foresee, for example, hanging out near Jupiter anytime soon.
Is that right?
Probably not in our particular habitat.
Not in the Tesseract. But we're working on different models. Who knows? I think other interesting
points like Europa, there are other good justifications for getting out to Europa for
the search for life in the universe. But the habitats that we were just talking about, the
Tesseract model is really meant for Earth, Moon, and Mars, like the near neighborhood of our solar
system. Got it. But if we find life on Europa, I think we should
call them Europeans.
I'm pretty sure of that.
Matt, what do you think of that?
I'll claim that. I'm a European, technically.
Okay.
I'll claim it. All right. Let's get one more
question. See if we slip one more in. Go.
Okay. So, well, you've answered
the first half of this about microgravity,
but Brady Harmon says,
have there been any developments in artificial gravity?
Is it all sci-fi or can we do it?
And also Brady says,
Vegemite serving tip of the day spread on a hard-boiled egg.
I'm guessing Brady is from Australia.
In fact, Brady.
Yeah, he can only be from Australia
if he's giving culinary tips for Vegemite.
Yeah.
Let's take a quick break,
and when we come back with our guest Ariel Ekblad,
we're going to find out about how do we make artificial gravity.
They do it in sci-fi with or without rotating space stations.
So let's find out when we return.
I'm Joel Cherico, and I make pottery.
You can see my pottery on my website, CosmicMugs.com.
Cosmic Mugs, art that lets you taste the universe every day.
And I support StarTalk on Patreon.
This is StarTalk with Neil deGrasse Tyson. engineeringly trained person thinking about this, not just crazy sci-fi people who just make stuff up.
So we have an authentic person making stuff up.
So Ariel, Matt, where do we leave off?
We had a question about artificial gravity.
So yeah, we had Brady from Australia who,
as well as Vegemite serving tips,
wanted to know if there'd been any recent developments
in artificial gravity.
Yeah, other than a rotating platform, Ariel, is there any other way to do this?
It doesn't seem like there would be.
That's what we're focusing on is the rotating platform.
I think one interesting tidbit for Brady, there's a couple different ways to do it, right?
You can do a smaller ring and rotate it fast, but that's going to be uncomfortable for the astronauts or the future spaceflight participants. Or you can do the really big ring and rotate it slowly,
but then it's a bigger challenge to build and to operate.
And so we're trying to find that sweet spot, the right size of an artificial gravity station.
And a quick, fun, recent update, there's a group called Gravity Labs that's looking at making real
a technology that was described in Hail Mary,
Andy Weir's latest book.
We love Andy Weir. We love Andy Weir.
I know we love Andy Weir. I also love Andy Weir.
But that tether approach,
a very basic approach to generating
artificial gravity, even before you have some
beautiful ring that's like fully encased.
There's a cool company out there, Gravity
Labs, that's looking at doing that for a
science lab,
not necessarily to put humans in it just yet,
but to be able to test out that platform.
So there's definitely some kind of gondola
at the end of a tether that gets swung around.
And in that gondola, you'd have the gravity that you see.
I love that, you know, the most high-tech science
to get the stuff up there,
but underneath it, it's no more complex
than when you're a kid and you swing a bucket on a rope.
It's fundamental physics. It turns out the laws of physics are supposed to behave somewhat
consistently throughout the universe. Yeah. Yeah. Not only when you're a kid,
but when you're in space. Yeah. So, all right. Cool. What else you got, Matt?
I'm going to combine these two questions because they're sort of opposite sides of
the same coin. So, Craig Cordwell from Bedford, UK says, Craig is 33, and do you think
it'll be possible within my lifetime to visit space in some form of another or for a reasonable
price? I know you can go at the moment for a ridiculous price, but I imagine like most things,
it'll become more affordable for everyday people in the future. And I love the show. And then Andrew
O says, why should I care about space tourism? It'll likely never be something I could afford
and wouldn't frequent rocket launches increase CO2 needlessly
all for the rich to get a front row seat
to the fruit of their labor.
Oh, wait.
So Ariel, tell me about the exhaust
of the main rockets in modern rockets.
Yes.
So this is a great question about the environmental impact
that the space industry might have. Right now, the space industry's carbon footprint,
much lower than aviation, right? But if we succeed in our goals of having way more frequent launches,
then there is a significant potential impact. And so there's some fantastic research already
into green propellants, how to try to, before we get as deep into things as the aviation industry,
is actually try to solve this up front.
I am not a rocket scientist.
I am a space habitat engineer and designer,
but we are very closely looking
at the carbon footprint
and the environmental impact
for this scaling up of life in space.
Okay, and when is it going to be cheap?
Okay, this is the question.
Their answer to their question
is absolutely in their lifetimes.
They will get to go and it will be more affordable in it is now. Okay. This is the question. The answer to their question is absolutely in their lifetimes. They will get to go and it will
be more affordable
in it is now. Yep. So if we're looking
at the next, if they're 33,
right, in the next 30 years,
we are at the cusp right now
of an explosion of new
technology. Explosion, maybe it was not the right word to use
in this context. Bad word.
Don't talk about rockets and
explosions of anything.
Okay.
But we are at this inflection point where the cost of going to space is coming down.
Multiple different companies and not just governments.
And that's why it's a big deal.
There's actually an economy growing up around this now that's more sustainable.
And the cost will be dropping.
Okay.
I'm older than our 33-year-old guy.
I don't have another 33 years to wait this out.
So can you do it in my lifetime?
Okay, thank you.
We'll get going.
For you, Neil, anything.
Call me when you... Okay.
I feel like you know some people
who work at some of these companies, Neil.
I feel like you're nearer
at the top of the guest list than most of us.
What related to that as well,
Amelia Silver asks,
what do you think is the next most important technological advancement
that we need to make in order to bring down the cost of space travel?
Duh, it's warp drives.
Everyone knows that.
Next question.
Okay.
Or just really big bottles and really big pumps.
Where is the biggest cost?
Is it in the engineering setup?
Is it the launch cost? Is it in the engineering setup? Is it the launch cost?
Is it keeping you alive once you're there?
It seems to me those expenses have been shifting relative to each other over the decades.
I think they really have been.
Right now, people would still say it's mass to orbit, so it's the launch costs.
But reusable rockets, like SpaceX's reusable platform, have actually been succeeding in really bringing those costs down.
SpaceX's reusable platform have actually been succeeding in really bringing this cost down. So there will be a point where the cost transition to maybe what is more driving it is the length of
standing in orbit or the number of people or the logistics, the supply chain that you're trying to
support once we have a large human society up there. But right now it is large costs.
So per pound, what is it today per pound?
It varies really wildly. Usually quoted per kilogram,
it can be in the thousands,
like tens of thousands,
hundreds of thousands
per kilogram right now
to put like a small CubeSat
into orbit
because the price
is a little different
depending on what you're
paying to go up.
A small CubeSat,
about $200,000
to go up to orbit.
Okay, so I have
a middle-aged man belly.
So each pound of that man belly
is like tens of thousands of dollars.
But now you have to measure it in CubeSats.
Like you have to give me the years.
And then I can give you an accurate quote.
Okay.
So I need like ripped abs
and no excess fat.
And then I get a cheaper ride into space.
That's what you're telling me here, I think.
It is.
Yeah, it's still mass driven.
But we're getting there, I think,
because it's not just SpaceX is the only game in town.
Now Blue Origin, right?
They're aiming to get Orbital, Starship,
next generation SpaceX, ULA and others.
It's a really fantastic ecosystem
that's going to make it possible
for your guests to go in their lifetime.
So you haven't mentioned it until just now,
but is a lot of what you're doing
on the backs of launch companies that are coming online right now?
It is.
Absolutely.
We need the road to space to be built to be able to empower this next generation of life in space.
So, absolutely.
Yeah.
And we work really closely with a lot of these launch companies to get experiments to orbit, right?
Even before we're building the big habitats, all of those other things we talked about,
we tested the musical instruments
on zero-gravity flights.
I've flown in zero-gravity
nine times over the course
of my career to MIT,
hundreds of parabolas
to test all this stuff.
And that, yeah,
it's incredibly amazing
to get to work on the shoulders
of those companies.
It's empowering.
Just for people that don't
otherwise know,
so you can experience zero-G without, quote, going into space.
Yes.
You get on one of these vomit comets.
I think they don't want to call it that anymore.
Affectionately known as the vomit comets.
Affectionately known.
And so they can go very high and execute an arc.
Yes.
Where that arc is basically in free fall back to Earth.
But it's only for seconds, right? How much time do you get in free fall back to Earth. For how much? But it's only for seconds, right?
How much time do you get in free fall?
Yeah, it's 15 to 20 seconds,
but it's like a roller coaster in the sky
because you do that arc that you described,
that parabolic arc, 30 to 40 times.
Oh, my God.
I think I would love that.
My favorite ride in theme parks rather than the roller coaster
is I love the pirate ship.
The one that just rolls back and forth.
Oh, the one that goes up and down.
Yeah.
The sort of little...
Can you feel it?
The zero gravity feeling in your belly
or when you go over a hill quickly
on your little hump in the car.
I love that feeling.
Yeah, but wait a minute, Ariel.
I would take that all day.
You don't just transition to zero G.
It's zero G
and then you come out of zero G
to more than one G.
Right.
And then you go,
so my stomach will be floating.
I know.
I'm made of the inadequate stuff. I think you'd love it. I think you'd love it. And that you go, so my stomach will be floating. No, I'm made of the inadequate stuff.
I think you'd love it. I think you'd love it. And that's one of the cool things about the space
industry. It's actually some of the work we're doing with Aurelia Institute is to welcome everyday
people onto the zero G flight. So we have an application program where you can come through
Aurelia. We bring outreach partners and the people love it. I hate roller coasters, but I love the Zero-G flight.
It's actually far smoother.
And it's an incredibly sublime experience to be truly weightless and imagine your life in space like that.
Ariel, you're being badass here.
Roller coasters don't excite me.
Space.
It's like they put me in space.
I don't like roller coasters.
That's for regular people.
I don't like roller coasters.
That's for regular people.
There's a fun video of Stephen Hawking on one of the Zero G flights
where he comes out of his wheelchair
and there's a smile,
if you've ever seen one,
on the man's face.
It's a profound moment.
It's a really profound moment.
Right, right, right.
So Matt, keep them coming.
Well, this feeds very neatly into this
and also overlaps with your parents' profession.
Tarina from San Francisco says,
I remember an episode of Things You Thought You Knew
that explains...
That's one of our spinoffs from StarTalk, yes.
And in that, you explained why people don't throw up on planes
as often as they used to.
How will space tourism manage to help
several nauseated tourists enter orbit?
Throwing up during every trip sounds like a tourism downer.
Especially since if you throw up in zero G,
the throw up just floats in the air.
This is true.
And it's just in the air and it gets in your hair.
And whereas on one G,
you know the splatter pattern on the sidewalk
outside of bars at 2 a.m.?
That's the famous throw-up pattern because gravity brings it down.
All right.
So, Ariel, what are you going to do with all the tourist throw-up?
Well, it's a great question, Neil.
Have you thought about that?
We have thought about it.
There's fantastic anti-motion sickness medication, either Dramamine or Scopalamine, things like that that NASA uses.
But there's also a lot of really great research
here at MIT and elsewhere around space sickness
and how to overcome that,
how to train your vestibular system to behave
or to appreciate it a little bit differently.
But it is something that...
So the vestibular, that's your inner ear?
Inner ear.
Okay, good.
Yeah, so it's a little bit of that cognitive dissonance
of your body feels a different gravity vector than it's used to,
but your eyes are still seeing a stable environment in front of you.
And that cognitive dissonance sometimes in the vestibular inner ear
and versus what your eyes are seeing can make people feel pretty queasy.
My understanding, that's also behind just regular travel sickness, isn't it?
That's why it's easier to look at the horizon when you're on a boat
because when you're inside the boat,
your eyes are telling you everything's stable,
but your body is telling you, no, it's not.
You're bouncing around.
And same with reading at the back of a car as well, right?
Yes, yes.
It's actually so, well, it's funny.
It's not necessarily correlated.
People who get carsick get space sick, but it is related.
Some of the, yeah, some of the feelings and the sensations that you get.
But some astronauts do and some astronauts don't.
And it's actually one of the things
that NASA has the most trouble predicting
when they select astronauts
is who is going to get, you know,
have a little bit of a tough time acclimating to space.
I guarantee I'll get space safety.
Just let them know.
You don't have to wonder about me on that one.
You're going further down the list now, Neil.
You need to, no, I got iron stomach now.
Put me in space right now.
Let's go.
All right.
Yeah, so because in a zero-g bubble,
any throw-up that escapes whatever vacuum you're trying to...
It just stays there, like, forever.
That's so fun.
Yeah, yeah.
That's not the only thing that's interesting
about the human body from a health perspective in space.
We can get into this in a minute,
but if we're talking about space societies,
shape of your eyeballs changes, your heart gets weaker.
You get space face because the fluids redistribute to your body in a crazy way.
So there's all kinds of interesting human physiological...
What is space face?
So space face is because gravity is usually helping your fluids
throughout your body drain towards your toes.
In space, it redistributes and you get puffy
space face. And that's part of why astronauts are obsessed with hot sauce because they can't
taste anything. It's like having a head cold the whole time. And so the hot sauce and the
sriracha really cuts through the space face. And their eyes bulge or something? What happens?
Become slightly more spherical. And so any change to your eyeball shape is also going to affect your lens and your eyesight.
There's bone health challenges because you're not walking against gravity.
So your bones weaken.
This is all why artificial gravity in a space habitat is so important.
Because we really do need to be able to have people spend time in close to 1G to keep their bodies healthy.
Okay.
So Ariel, I'm waiting for 1G.
I'm not paying you a million dollars for my
eyeballs to pop out, my face to explode and to lose taste. No, no, I'm staying here on earth.
Okay. Just so you know. Can I just ask as well. So from a sort of body scientific point of view,
if you do have a rotating spacecraft that generates the equivalent of 1G, will your body experience
that exactly the same as the way someone on earth just in regular 1G. Will your body experience that exactly the same
as the way someone on Earth just in regular 1G would experience it? Or are there different forces
acting on you? Interesting. So if you're actually able to spin the habitat adequately in the super
local space where you're walking in 1G, you will experience it much like you would experience it
on Earth. But there's going to be a gradient as you get close to the center of the ring it'll be more and more and more like microgravity so you
want to basically stay right on the edge of that ring where you're actually going to be able to be
generating the forces that would be more like what you would feel on earth and i think i've seen some
sci-fi where they have ladders yes that connect from the outer ring to the center. And as they move up the ladder, they weigh less and less.
And right in the core, they don't weigh anything.
So that transition is there.
Exactly.
And to your point earlier, Neil, about the L5 Society and Jerry O'Neill,
this is something he writes about in The High Frontier that you could be bicycling.
High Frontier, one of his books.
Yeah, you could be bicycling up a mountain and then be floating and you have a flying bicycle
as you get up to the level of the port of the habitat
that's not rotating, that's not as fast.
So yeah, it's just a wild.
Right, the core, the axis of the rotation.
Right, if the mountain goes up there.
But also, there's something profound here.
Matt, if you didn't know this,
the 1G you experience, minus this gradient effect going towards the center, right at the rotating outer section, is actually indistinguishably identical to the gravitational force that would give you 1G, and that is the foundation of Einstein's
general theory of relativity, and it's called the equivalence principle, and it's one of
the most profound acts of human thought in the history of human thought, is to equate
those two forces.
The force of rotation or acceleration, right?
Like what you'd have in a rotating object, and standing here on Earth, what he said was these are indistinguishable from each other.
In principle.
And built all mathematics and a whole branch of physics based on it.
Yeah.
It's crazy.
This is such a great point, Neil, too, because as a space person, I get asked a lot about zero gravity.
And that's why we try to be careful to say microgravity.
Because there really is no zero gravity right newton tells us the law of gravity tells us that there's always a gravitational attraction between objects but if you're in
free fall you're feeling like you're not being acted upon by gravity but you very much are
and so that's a nuance but i still don't like i just don't like microgramming. He's just mad about the C0. I'm a zero G guy.
You're not getting me to say microgramming.
Okay.
Unless I'm saying it to say that I'm not going to say it.
I'll take my wins where I can get them.
As long as we get you into space, Neil, I'll be fine.
All right, Matt, give me one more before we go to our next break.
Yeah, so Andrew Atkins says,
do you think that the future of space exploration and tourism
will depend on our ability to develop some sort of cryogenesis or stasis for humans,
or will we work more towards sending out machine-based AI to do all the traveling for us?
Love the show. Ooh, because it seems to me, Ariel, it's a great question, but I think that
questioner, what's the fellow's name? That is Andrew Atkins.
I think Andrew is thinking,
are we going to travel to the stars or something where we take decades or maybe even centuries
where we'd have to somehow put ourselves in suspended animation?
But all your destinations, you can get there in a few days, right?
Right, right.
It's a great question because the search for exoplanets
and Goldilocks planets is raising these questions about if we find some, would we want to go out and travel to them?
How would we get to them?
How would we do suspended animation?
But for our near-term habitats in the area of the solar system that we're contemplating, we would not need to put humans in that level of stasis.
But also, the future of human space exploration will absolutely be one in symbiosis with humans and robots.
And so there's a really large role to play for robot probes and AI systems,
even with the future of chat and GPT and other AI tools
that I think will be really significant for the future of life in space.
And I want to get back to you on that after this break,
what role AI might play in this.
When we return, StarTalk Cosmic Queries. This is the Space
Civilization Edition. When we return. We're back.
StarTalk.
This is a space civilization edition of Cosmic Queries.
And we've got one of the world's experts.
I say the world's expert in thinking this stuff through, Ariel Ekblah.
Ariel, how do we find you?
Are you on social media?
You have a footprint there?
I am on social media.
I'm at Ariel underscore Ekblah on Twitter.
You can also find our team.
You've got to spell Ekblah.
You can't just say it by and not spell that.
The usual way, Neil.
The usual way.
The way you always spell Ekblah.
The way you always spell Ekblah.
E-K-B as in boy, L-A-W.
Ariel underscore Ekblah.
And Ariel, not the way we spell in the Disney princess
actually the same way
actually the same way
it's A-R-I-E-L
underscore
Ekblah
E-K-B-L-A-W
Ekblah
okay and so
that's your
that's my personal
yep Twitter
and then
Aurelia
A-U-R-E-L-I-A
Aurelia underscore
labs
for both Twitter
and Instagram
for the Aurelia
that's what you're CEO of
yes that's what I'm CEO that's Yes, that's what I'm CEO of.
That's the new Habitat building lab.
That's meant to be the Bell Labs of space.
And so you spun that off from your time at MIT, is that correct?
I did.
Or is MIT still an umbrella to you?
Yeah, so I'm still, I'm actually here at MIT today.
I'm sitting here at MIT.
But we have passed the baton for the lab that I founded at MIT to another amazing person,
Cody Page, who's going to take that forward.
And so I ran that lab at MIT for seven years.
But we'll still continue to support it because it's my baby.
So I love it.
You birthed it.
Okay.
But now, but you spun off and now you have like, you pay rent on a different space.
Is that correct?
Yep.
It's yeah.
That's, I love that you asked that.
That's what makes it real.
It is so true. I pay rent on a different space. What that correct? Yep. I love that you asked that. That's what makes it real. It is so true.
I pay rent at a different space.
So then what money is paying for this
if this is not going to happen for 30 years?
So this is the benefit of being a nonprofit.
We're not a for-profit.
And that was very intentional
because I wanted the freedom to think
really long-term for Humanities for Horizons
and do a lot of education and outreach work
like the Zero-G flights that we've run for Aurelia.
But it's philanthropic support.
It's support from companies
and support from grants like NASA.
Okay.
All right.
Very good.
Very good.
We got my vote.
Thank you.
If you need a vote.
Thank you.
Well, you should come and visit sometime, Neil,
when I talk to...
All right.
Next time I'm in Cambridge.
I'm totally...
You're in Cambridge, I guess.
I'm in Cambridge, yes.
Yeah.
All right. Okay. Cambridge, America. guess. I'm in Cambridge, yes. Yeah, all right.
Cambridge, America.
Yeah, I know.
Cambridge, man.
The other Cambridge, too.
Yeah.
So, Matt, give me some more.
Give me another question here.
So, Christian Holmes says,
Hello, Director Ekblor.
Are there any plans for terraforming planets in the future?
If not, what would be viable ways for an advanced species to
terraform a planet, you know, hypothetically?
So she doesn't want to
terraform a planet because she wants everyone to live in her
habitat. How did you know?
I bet
I know the answer to this question.
It's going to say, terraforming, that's for
centuries from now. Okay, let's
listen. Okay, Ariel, what's
your answer to that question? Terraforming, that's for centuries from now. Well, let's listen. Okay, Ariel, what's your answer to that question? Terraforming, that's for centuries from now.
Well, yes, yes and no.
There's two answers to the terraforming question.
One thing, I just want to give a quick plug for Earth.
There is no planet where humans have co-involved
in the way that we have co-involved on Earth.
So I think terraforming is an amazing concept,
but it's not going to create a plan B planet.
So when we go out to do space exploration, we should be still really protecting and preserving Earth, honoring that.
It's not about abandoning Earth.
What do you mean co-evolved? Co-evolved with what?
With the biosphere, the geology, and the geophysics of Earth.
This is the place where our human biology and the biology of the planet have lived in symbiosis, have lived in together in concert.
That's what terraforming is going to be.
Well, you tell me we can't figure that out?
Maybe we can figure it out.
We will evolve if we succeed in it.
Then humans will continue as a species, right?
Natural selection to evolve with terraforming.
But Mars is usually where people talk about terraforming.
One of the challenges is there's no liquid iron core
moving in the center of Mars to produce a magnetic field
like what we have on Earth,
which helps protect our atmosphere.
So if you are going to terraform Mars,
you're going to have to be constantly replenishing
the atmosphere that you're trying to keep
around the planet.
NASA and some others have some fun ideas for this.
You could put basically a shade
at a certain point in space
and block the cosmic wind, block
some of the solar radiation that would be coming and blowing your atmosphere away. But that's one
of the big challenges to get terraforming going. And then the final answer is exactly what Neil
said. Yes, just come live in my floating space habitat, my space, my Jerry O'Neill space city.
It will be better. There's no perchlorates in the soil. It's a much better place, I promise.
Oh, man. Okay. Fresh soils.
That's what we want.
Are you going to have farm animals there too?
In the images, I saw the Jerry O'Neill space habitats.
There were these, there was farming communities.
And it was all on a sort of rotating inside surface of a rotating cylinder.
And so you look at it, there's farm, plots of farm, animals, silos.
And so you look at it, there's farm plots of farm, animals, silos.
So would you, I presume you wouldn't want supply ships to bring you food.
You'd want it to be self-sustaining.
Self-sustaining.
Correct.
This is one of those lovely things that has changed a little bit since the 1960s.
It's delightful to look at those Jerry O'Neill images, but they're a little bit like 1960s suburbia or rural taken up into space.
We have a chance now, whether it's lab-grown meat
or sophisticated urban architecture and agriculture
in resource-constrained environments to design,
we could design a more urban landscape
within one of those habitats.
So there's a lot of choice now
in how we think about the urban planning
kind of at planetary scale or urban planning at this really massive habitat scale.
In a city, people are stacked high because there's not much space.
But if you're in space, why would you ever need a city?
You stack radially.
You stack radially. You stack radially.
You grow in three dimensions in a way you never could on Earth.
Oh, okay.
All right.
They're a good answer.
You know, the other cool thing that I just want to sneak in here is to spin those cities.
Right now, for artificial gravity, we're thinking motors, a lot of energy.
There is a model where you could have a city in space that spins on the power of light alone.
So you have solar sails like Planetary Society, right?
And they're able to pick up the photons, that incident energy, and spin your habitat around.
Right, but once it's spinning, it'll just keep spinning, right?
It does take energy to start it, but you don't need energy to sustain it, presumably.
Yes, energy to sustain it and also to slow it down, to stop it.
You don't need energy to sustain it, presumably.
Yes, energy to sustain it and also to slow it down, to stop it.
So you do also have to design in those features to basically be able to retract the solar sails if you need to be able to.
That's when people start throwing up,
when you start speeding it up and slowing it down.
That's true.
You're reminding me, keeping me honest.
It's the fun times.
I'm still thinking about the throw up.
All right, Matt, what else you got?
So Matthew Swider, I hope I pronounced that closer correct,
says, what safeguards are we putting into place
to protect the planet from space debris
with a push for space tourism?
I love it.
Because it seems to me, Ariel,
a lot of space debris might be closer to Earth
than this place you might build your space station,
your space habitat.
So there's space debris that we're responsible for,
and then there's just
meteors that Earth plows through several hundred tons of meteors a day. And that's just stuff in
space. So if Earth is doing it, you're going to be doing it too. So what's your shield for this?
On the man-made debris side, this is actually one of the topics that's near and dear to my heart.
We put out a book a few years ago called Into the Anthropocosmos.
And the idea was, how do you be good stewards of the space commons?
And over the last few decades, we really haven't been.
There's so much debris, like Neil said, between where we are on the surface and where I want my habitats to be that we have to pass through now.
through now. And to answer the question from the audience member, one of the ways that we could address the man-made debris would be to do an approach kind of like Pac-Man in space.
A large spacecraft of some sort goes and physically captures debris, maybe with a net,
maybe with other mechanisms. A mass.
Or its mouth.
With its mouth. Yeah, just like Pac-Man.
You said Pac-Man.
A net for a mouth. A net for a mouth.
It's got to eat it. Okay.
Like some kind of space goat that you can. A space goat a mouth. He's got to eat it. Okay. Like some kind of space goat that you can…
A space goat.
A space goat.
That's how you sell it.
Oh, Matt.
That's how you're going to sell it.
Yeah, Matt, that's how we're going to sell it.
You've got to talk to Astroscale and some of these companies and tell them to…
I have a better idea.
I got it.
I got this.
Everyone participates in it.
So you control your own Pac-Man space eater.
Oh, like Twitch.
Twitch plays Pokemon, but Twitch plays Pac-Man in space.
Right.
And so you see where a piece of debris is
and you navigate to it
and you chomp it.
And it's a contest.
So you can eat the most you can.
I love it.
Boy, you clear up space like that.
No, actually,
we put crowdsourced citizens.
If you gamify it.
Oh, my gosh.
Yeah, all right.
Let's do this.
You got it.
You got it.
But you can't stop meteor showers
from slamming into your... So what do you do about that? who's looking at building next generation skins of habitats. So I'm working on the shell.
She's working on these skins that can pinpoint
exactly where a impact happened,
maybe detect a gas leak or detect something from this impact
and then try to be able to self-heal the habitat.
That works for small stuff.
As Neil was saying, there's also big stuff
that you just need to be able to navigate around it.
And sometimes even the ISS has to boost its orbit and move
out of a cloud of debris that would be coming
towards it. So lots of different approaches.
Way better to have, like, laser blasters.
Yes, yes. A little bit of
Dr. Evil.
Yes, that could work.
No, if something's headed your way, you don't move out of the way of
it, you just vaporize it.
If I remember anything, though, from
80s computer games, if you blast something, it then splits into two slightly smaller ones and then you need vaporize it. That's all. If I remember anything, though, from 80s computer games, if you blast something,
it then splits into two slightly smaller
ones, and then you need to blast them,
and then eventually... No, that would be like a kinetic
kill, but a laser kill, you
thermally vaporize it, and then it's
just dust at that point. I had the wrong weapons in the game.
Gashes, gashes, dust.
That's all. So,
Ariel, tell me about what...
Let's revisit just the role of AI in this.
How do you see it at its most helpful?
And how do you see it where it might be
its least helpful, possibly detrimental to your goals?
Well, the latter first, that would be how.
We definitely don't want a how.
How? You don't want homicidal computers.
Open the pod, bay doors how.
Yeah, we're trying to avoid that version of the AI agent.
But something that even just within the last few weeks,
chat GPT coming online and providing this nature of an AI assistant
that is almost as sophisticated as what we see in Star Trek.
When they talk to the computer and it's a fully useful kind of native language experience,
we have that now with ChatGPT.
And so imagining responsive space habitats of the future with AI Agents Incorporated
will be a really big part of what aerospace nerds would like to call human factors.
Okay, you know what scares the hell out of me?
What?
It's the capacity for language to be thoroughly ambiguous.
True.
That's so true.
So that to say we have language models that understand our language, no, I don't trust
it.
You know, the most famous sentence in that world is time flies like an arrow, fruit flies
like a banana.
Yes.
Okay.
So, these two sentences are identical in structure
with similar words and have completely different meanings.
And so, you say, well, Chad GPT would just know.
But what I'm saying is wars have been fought.
Over misunderstanding.
So, I worry that the absence
of precision of language
should not be mixed
with the precision necessary
to not die in space.
That's my opinion.
That's my public service announcement.
I think you're right
and that extends to many different things
where there's a desire
to integrate chat GPT
all of a sudden really quickly,
but there definitely is a need
for a human in the loop
or some type of AI safety control infrastructure as well, which absolutely would be something for
a mission-critical context like space. I served on a board of the Pentagon for
several years, and AI was becoming that much more visible over those years.
And so we drafted a document such that if any commander is going to, if any AI is in the position to judge
whether a kill order should be given, there has to be a human in the loop. It cannot autonomously
decide to take the life of another human. And so that's a more extreme, of course,
version of what you're saying. You're saying the value of a human uh we want to retain
that otherwise just for philosophical reasons but also we don't want ai to be our overlord
necessarily yes yeah okay you agree with that okay i agree i think human in the loop is a is
an architecture a systems engineering term used in a lot of contexts but you're absolutely right
that's a way to not just philosophically keep humans involved,
but to have a shepherd,
a shepherd of these interactions.
And I think that's what we know more.
Matt, I think she's AI or something.
I think, don't tell her I said that.
Say a paradox at her and see what happens.
Thanks, guys, for the vote of confidence
I've got one last question
and just by the way for reference
I heard that fruit flies like a banana as a kid
and for years I just thought it meant
fruit flies like a banana flies
you know, if you throw a banana through the air
that's how fruit flies
so Tegan Mercia
says, I was wondering
what a colony
on space
would look like
what kinds of jobs
would be available
and which would be
of highest importance
are they similar
to jobs we have
on earth
and it's not
asking this question
but it is implied
how high up the rank
would stand up
comedian slash
podcaster rank
yeah
where do comedians is there a role for comedians Oh, amazing.
Yeah, where do comedians... Is there a role for comedians in your future universe?
That's a...
Yes.
I mean, it seems like a silly quick answer,
but one of the goals of democratizing access to life in space,
building the artifacts of our sci-fi space future,
is to build a really richly envisioned life in space.
And so what I always say to people,
even though I was trained in math and science, we need everybody in the richly envisioned life in space. And so what I always say to people, even though I was trained in math and science, we need
everybody in the future of a life in space.
We need space doctors, space lawyers, space comedians, entertainers.
And that's part of a message I think that we should be getting out to the public these
days, which is math and science, incredibly important.
It is really important to emphasize STEM fields, but there's a lot of-
It's the holistic view of the future of space.
Right, right.
Yeah.
Okay.
I love that.
I love that.
Matt, was that your last question?
That was the last of the Patreon questions that I had in front of me.
Wow.
Micah, we never get through the whole list.
You completed it.
A testament to Ariel for being, like, tight and clean answers.
And we just kept this train moving.
Ariel, this is a first.
We need an award or something.
I'm honored.
Great question.
I don't know what that is.
All right.
All right, guys, we got to call it quits there.
This has been delightful and informative and hopeful.
You know, how many hopeful anythings happen today?
Like, never.
So, Ariel, when you start launching your segments,
give us a call.
I will.
We want to, like, brand one StarTalk or something.
Oh, my God.
I'd be honored.
The StarTalk hexagon.
The StarTalk hexagon.
I'd love it.
You got it. Well, Ariel, it's a delight to see what the arc of your life is and will continue to be.
And maybe one day you'll take the whole StarTalk staff on a Zero-G
plane. That would be fun. We could make that happen.
Make a whole episode.
Film an episode in Zero-G.
But you have to point it away when I throw up.
Yes, I promise. The boss can't be shown
throwing up.
We'll take good care of you.
We should play together.
That would be amazing.
Alright, Ariel.
And Matt, always good to have you.
Always good to be here.
Thanks for having me.
All right.
This has been StarTalk Cosmic Queries.
Neil deGrasse Tyson here, your personal astrophysicist.
As always, keep looking up.