Planetary Radio: Space Exploration, Astronomy and Science - A City on Mars
Episode Date: November 8, 2023Can we build permanent human settlements in space? It might be more complex than you think. Kelly and Zach Weinersmith join Planetary Radio this week to discuss their new book, "A City on Mars: Can We... Settle Space, Should We Settle Space, and Have We Really Thought This Through?" Then Bruce Betts, the chief scientist of The Planetary Society, and host Sarah Al-Ahmed chat about some of the most significant challenges humanity might face as we build habitats beyond Earth. Discover more at: https://www.planetary.org/planetary-radio/2023-a-city-on-mars See omnystudio.com/listener for privacy information.
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Can we settle space? It might be more complex than you think. This week on Planetary Radio.
I'm Sarah Al-Ahmed of the Planetary Society, with more of the human adventure across our
solar system and beyond. Kelly and Zach Wienersmith join us this week to discuss their new book,
A City on Mars.
Then Bruce Betts, the chief scientist of the Planetary Society and I,
will talk about the most significant challenges humanity might face when we build habitats in space.
If you love Planetary Radio and want to stay informed about the latest space discoveries,
make sure you hit that subscribe button on your favorite podcasting platform.
By subscribing, you'll never miss an episode filled with new and awe-inspiring ways to know the cosmos and your place within it.
As space fans, many of us dream about a future where humans live all across the worlds of our
solar system. Imagine living on the moon, calling up your friend on Mars, and then taking a vacation
together on a spinning space station in orbit around Saturn.
Humanity has made a lot of progress toward this goal, and there's so much to be hopeful for,
but the task is much more complicated than people think. As governments and commercial space companies race to meet the challenge, it's a good moment to take a step back and
really make sure that we're thinking it through. Our guests this week, Zach and Kelly Wienersmith,
were so excited about the
prospect that they decided to write a book on this subject. Of course, the more they learned,
the more they realized that it's not as simple as we all hoped it could be. Classic. Kelly and
Zach Wienersmith are a wife and husband research team that spent four years trying to understand
what it would take for humans to settle space. Kelly is a biologist and Zach is a cartoonist. You may have
seen his work on Saturday Morning Breakfast Cereal. With the powers of science, historical context,
and humor, they went on a mission to understand this complex topic, attending conferences,
conducting interviews, and reading books and papers to produce what I think is one of the
most well-rounded analyses of human habitation of space that I've read in a long while. Their new book called A City on Mars, Can We Settle Space? Should We Settle Space?
And Have We Really Thought This Through? was released on November 7th, 2023.
Hey, Zach and Kelly, thanks for joining me.
Thanks for having us. Yeah, we're thrilled.
And I understand you are both Planetary Society members.
That's really cool to have you come on the show.
And I got to tell you, reading this book was very vindicating for me.
I feel like as space fans who really want humanity to get this right and to hopefully
someday be Star Trek and across the universe, it's really easy to get carried away with
yourself.
But we really need to do this mindfully.
And I feel like that's what this book is all about.
Thanks.
We didn't know how careful you'd have to be when we started writing the book,
but we are,
yes,
now very much convinced it needs to be done carefully,
but we hope we get to Star Trek and across the universe.
Is that why you felt so compelled to write this book?
Well, so we felt compelled to write the book because we had written a book about emerging
technologies. And with the drastically dropping cost of SpaceX's space, our rocket launches,
we thought, oh, man, the thing that's holding space settlements back is that you need all this
equipment to keep humans alive. And now we can afford to send it. And all these asteroid mining
companies, they're going to
make it so that we can build habitats out of the asteroids. And so this might happen in our
lifetimes. And we're sci-fi geeks. So let's write the book about what's coming in the next few
decades. And that's what we told our editor we were going to write. But that's not the book we
ended up writing. Because we ended up thinking it's not that close, actually.
That's so funny. Because as with any good good science thing the more you learn about it the more you dive down that rabbit hole
the more complex it gets yeah and i loved the dedication that you put on the front end because
clearly you had to talk to a lot of people in order to write this book really dive into their
research but i wanted to read this just to give everyone a little bit of context for what this book does. The dedication reads,
to the space settlement community, you welcomed us and you shared your wisdom, also your data.
We worry that many of you will be disappointed by some of our conclusions, but where we have
diverged from your views, we haven't diverged from your vision of a glorious human future.
from your views. We haven't diverged from your vision of a glorious human future.
I love that. And that's a beautiful apology. Why did you think it was necessary to include that?
To be honest, in addition to whatever we felt was necessary, we're like very anxious people.
If you come out with a book about how something awesome is going to happen tomorrow,
whether people believe you or not, they enjoy the enthusiasm and you get together and it's fun.
And everybody's having a beer and congratulating each other. And we ended up just feeling like we couldn't write that book based on what we had found out in our research. And we felt very
anxious about that because these people become our friends. They are still our friends. I don't
want to act like we've like, you know, to our knowledge, we have not been disowned by anyone,
but we ended up having to say upon research, it appears much more difficult and in some ways questionable.
All these people who I asked for interviews when I was like, yay, space settlements.
They're going to think that I was lying to them when the book was nay space.
And so, yeah, we just wanted to apologize.
And thank goodness for our editor who eventually was like, look, you clearly have changed your mind about space settlements.
You need to write the book about why space settlements are not good.
So, yes, we're sorry.
But sometimes you come across a conclusion that's inevitable.
It's not that we're never going to go to space, but that if we do it the wrong way, we might cause some serious pandemonium. When I talk to my daughter, I say we're the space wet blankets.
And so, you know, she's nine. Yeah. Right. Right. Yeah. So when we go to parties, we're like,
everyone's all space settlement. You're writing about how we're going to live in those glass
domes on the moon. And we're like, no, you'd be fried by radiation and they're like oh go home
well happily this book does a really cute thing and that in between all of these like deep
thoughtful bits of expounding on these complex ideas it includes all these cute little drawings
and cartoons along the way and i understand you did that because you, Zach,
are a cartoonist. How did you make the decision to do that? Did you do that in your previous book,
or did you feel like you needed to do it with this one in order to add some levity?
It was a couple things. Yeah. So the previous book did have, we actually requested for this
book that we would keep the illustrations because it's like a tone we do. But the ones in this book
are, there are a few ones that are just jokes, but mostly they're like illustrations with a joke that are like trying to explain something.
One, I think the audience recognizes a certain style that we do, so we wanted to preserve some of that.
But also when you're trying to do pop science, there are basically two approaches you can take.
You can either simplify a lot so the audience doesn't get bored when you're like getting into the details.
simplify a lot so the audience doesn't get bored when you're like getting into the details,
or you can get into the details, but try to lard it with jokes and drawings and stuff that'll keep the audience going. Because there is some stuff that's tough to understand, but it's really,
really, really important. And so we would rather keep it coming thick and just try to get the
audience through it than try to make it too easy and lose some of the important nuance.
Yeah. So we've got four or five chapters on international law that we think are absolutely
critical for understanding how going to space could go poorly and how you might be able to
structure it so that peace is preserved. And so, you know, we told our editor, we're like,
we're thinking four to five chapters on international law. And she was like, oh,
thinking four to five chapters on international law. And she was like, oh, you guys, you guys better make that funny. So we did a lot of outside reading. So in addition to Zach's great artwork,
we try to include as many like funny stories as we can by reading broadly about what's happening
in that time period to try to lighten it up. So at the end, we hope people really understand the
like international law situation regarding global commonses.
But there is a section on whether space cannibalism is legal, which will help motivate you.
That's right. There was a big debate about putting that in the book or not, but it stayed.
Well, that's it. There's so many of these like nitty gritty complex things that people don't really think through when they're thinking of going to space.
What do you do with an entire colony's poop while they're up there? These are really important details, but you have to get far enough into the process of figuring out how to put
people somewhere before you even get to think about these ones, which is just good to think
about it now. And that's why we think that the timelines that, for example, Musk puts forward are really unreasonable. So he wants boots on Mars by 2029 or something and a million people
by two or three decades after that. And the biggest closed loop experiment that has happened
so far was Biosphere 2 in the 90s, where there were eight people in a 3.14 acre facility.
And we couldn't even get that to work.
And that's substantially larger
than anything we could build on Mars.
And there are definitely lots of smaller experiments,
but they often have things break.
And if something breaks on Mars
and you didn't bring enough equipment,
it's not, oh, that's a bummer.
It's, oh, everybody's dead,
which could be bad for future missions to space
if inspiration is part of the goal.
We're just gonna have to figure out what redundancies we need and at what level in
order to sustain that many people because woe unto you if your toilet breaks on the way to Mars.
Yes, no, absolutely. And man, we read a lot about toilets.
Every astronaut tells you about their experience with the space toilet and apparently it's what
they're asked the most the toilet section in our book is drastically cut down from a much
more ambitious toilet section you need to put that in the addendums or something i would i would read
it see if it makes b for yeah for 50 more babies on the toilet. I think something that I hadn't really grappled with
in my own heart was the motivations
that we're using to justify going to space with humans, right?
There are so many ways that we tell ourselves
that this is a great idea.
It'll inspire the future.
Maybe there's a planetary defense reason.
We don't want to keep all the humans on Earth
just in case we get hit by an asteroid.
Maybe there's monetary gain.
But as I
was reading this, I began to understand that maybe a lot of my thinking around this was not very deep.
I hadn't even really considered that maybe asteroid mining won't be lucrative. Maybe
sending people to space could actually cause space wars, and we'll get ourselves in some serious trouble. So just even analyzing that by itself, why should we go to space? Do you think there is a compelling
reason for why we should attempt this? Yeah. So we spent a lot of an opening section
discussing reasons we think are not plausible. But we argue there are at least two arguments that are potentially
not bad for going in space. We call this the hot tub in the cathedral spectrum.
So a hot tub argument is just a stupid joke. But the idea is essentially... And a lot of space fans
will say this. They'll say, well, you authors or international scholars or whoever can say we
shouldn't do it or that there's no good reason to do it or whatever you want to say.
But that's true of most things humans do. Right. So when you go to buy a hot tub, there's not a third party that says, is this really advisable?
You want to buy it and there's someone selling it. You're good. It's just a regular sort of transaction.
And so that would be in contrast to something like nuclear weapons, right, where we say actually third parties do get a say.
something like nuclear weapons, right? Where we say, actually, third parties do get a say. I actually looked up, even if you look at the most libertarian people, they usually are not cool with
private transactions for nuclear weapons. So then the question is, a lot of the aspects of space
potentially create dangers for Earth. And then the question is then how much does a third party get
to wag its finger? But the basic argument is at least plausible. We don't need an argument. If Mr.
Musk wants to spend $100 billion sending
some cool stuff to Mars, why does he need anybody's permission?
And then the second argument, we basically say there's really no good human existential
risk argument in the short term. People say, we got to get off Earth because we're going
to blow it up somehow or an asteroid is going to come. And basically those arguments aren't
good essentially because asteroids like that are extremely rare. Space itself is quite awful, much worse than an earth
hit by an asteroid. And anyway, we can't do it in the allotted amount of time to stop climate
change or whatever else you're worried about. But if you see it as a sort of long-term Star
Trek eagle, like in the year 2250, it might be a reasonable move to have a multi-planetary humanity for like species safety,
or even just purely aesthetic reasons, then there's work to do. And so we should be doing
that. That's the second argument. And then a lot of the book is just exploring all the little
questions to try to add up to answers to whether those remain good arguments.
to whether those remain good arguments.
Yeah, my gosh.
It's such a giant topic.
And I love that you've given us the opportunity to actually think through all these consequences.
And let's just actually start chewing through this
because there's so much to consider.
Part one of your book is all about
caring for the space faring,
caring for people who are actually going to space.
Which of these things do you think are going to be the biggest hurdles for us to overcome as far as caring for people who are actually going to space. Which of these things do
you think are going to be the biggest hurdles for us to overcome as far as caring for people in space?
So I think that's a really hard question to answer because we know so little. And this has been,
this is maybe the thing that surprised me most when we started doing the research. You know,
I pulled out the space medicine textbook and I'm like, all right, we've had over 500,
maybe 600 astronauts and cosmonauts in space.
We've been running the International Space Station
for what, more than 20 years.
We probably know a lot
about how the human body responds to space.
So we'll summarize all of that.
But very few people are proposing
that you set up space settlements in low earth orbit
that aren't rotating.
And so they're proposing maybe the moon as a starter spot so we can figure out what we're
doing. Mars is probably the most popular option. And then there's the rotating space settlement
people. And for all of those locations, you don't learn what you need to know from the International
Space Station. So the International Space Station is protected from radiation by Earth's magnetosphere.
And space has a different kind of radiation than we've got on Earth.
We don't understand it very well.
And the astronauts are not giving us good data, not just because they're not being exposed
to it, but also because they're only up there for like weeks or months or the longest consecutive
stay was, I think, 437 days by cosmonaut Polyakov.
And so we're not getting the kind of data we need on how radiation
impacts the human bodies. We are not getting information that we need on how partial gravity
impacts the human body. So yes, when you're doing, if you had to do surgery on the International
Space Station, the bowels inside that person would be floating around. You'd have to be working
around them. If any blood got out, it would be floating around in the air, forming these little spheres moving through your habitat. That would be tough.
But on the moon or Mars, you have partial gravity. So we don't know yet if that partial gravity is
going to be enough for your bones and your muscles to be as strong as they need to be.
So on the International Space Station, every month people in their hips
lose something like 1%
of their aerial bone mineral density.
And that is a measure for osteoporosis.
So astronauts in space over just a month
are progressing towards osteoporosis slowly.
Now, if you go to Mars
and instead of losing 1%,
you lose 0.2% per year.
So maybe it's way slowed down and under Martian partial gravity, but I still don't want to
be the first woman at age 20 who's keeping my fingers crossed that my hips hold up and
that was enough when labor kicks in.
And so there's a lot that we don't know about how partial gravity is going to impact our
body.
And again, all the data come from adults. And our book is about space settlements. And settlements are all about having babies and
being able to like have generations like your plan B society isn't going to be helpful if you
can't grow it on site. And babies become particularly scary because if radiation or
development are impacted by space radiation or partial gravity,
what is going to happen to the babies? Not to mention the fact that Mars, its soil is 1%
perchlorates, which is a hormone disrupting chemical that binds to thyroid hormones and
messes them up. We need those. We don't know what a growth spurt would be like for a teenager on Mars.
But at the end of the day, we felt like we knew so little about how to safely have babies in space.
We felt like it essentially is experimentation on humans if you just go to Mars and start having babies because there's all this stuff we don't know. And the rodent data on the International
Space Station, there's some other animal research that's been done, but it's not systematic and it's over short periods of time and it's on different stations,
different conditions. And, you know, the International Space Station was not sent up
to get us the data we need for settlement. That wasn't the goal. And so not surprisingly,
we don't have good data on stuff like that. Yeah. It's a really complex thing because I don't know
how many people know this, but no woman has been beyond low Earth orbit yet. So when they did that Artemis One launch, part of what was so great about that was that they were for the first time testing radiation and other things on a mannequin that was female presenting.
Like, that's where we're at with this level of research. So we still have no idea whether or not you can get pregnant in space, whether or not you could carry that pregnancy to full term, and then what the consequences would be for that little one when they're stuck on Mars for the rest of their lives? Leave aside the fact that maybe they have that growth spurt and they end up eight feet tall or something.
There's so much complexity to that.
And I'm not even sure how we would begin to test that ethically.
Yeah, it's definitely scary.
So like when we were reading some papers to go back to Biosphere for a second.
So those closed loop ecosystems, they require tons of time. I think they spent something like eight hours a day,
seven days a week, just on like subsistence farming.
And that's probably what early settlements will be like,
just a lot of time maintaining the toilets,
growing your plants and just until things get big enough
and you can have people who have specialties,
a lot of your time is going to be spent
on fixing these things. And it's gonna be a dangerous environment. And so we came across
some papers that were saying early settlements will not be able to handle having people around
who can't pull their weight. And so we are going to maybe have to change our threshold for valuable
life. And maybe if we discover that someone's going to have a child with a disability, we're going to have more liberal abortion policies, which to me read as we're going to say, I'm sorry, you can't have this, this baby.
And, and to us, it was like, well, then why would we do this now?
If we're going, if you talk about space as a important, because you need a plan B civilization, do you really want to set up a plan B civilization under conditions where you think they're going to have different values for human life? And they're going to think that
people with disabilities are not worth having around? And what happens when an adult falls
or something and becomes quadriplegic? And then of course, there's a lot of disabilities that you
don't know about until your child is like maybe three years old or something. Are we going to be
kicking toddlers out of the airlocks?
Like what are the implications here?
And so we ended up feeling like we need a lot more research
and then we should wait until you can go big
and have a big enough facility and a big enough community
where if you have people who for whatever reason,
it turns out they can't contribute
either for a short period of time
or maybe for their whole lives,
you are still in a position to value their life and to want to work together and to keep them around. And so that's
one of our big arguments for why we should wait till we know a lot more and then go big all at
once so that we can take care of some of these ethical quandaries. Yeah, it's funny because I
feel like space has the opportunity to allow people who are hurt here on Earth to maybe escape some of that pain.
Imagine a world where if you can't use your legs, you get to go live on the space station where gravity is no longer a burden to you.
We want space to be something that sets us free and makes us better and kinder to each other and not a space where democracy goes right out the airlock with the person that can no longer work.
Like we are valuable despite our work ethics.
So it's yikes.
100% agree.
Yeah.
And Charles Cackel is well known for talking about how the environment of space is not
really conducive to liberty to begin with.
So you've got this habitat where oxygen needs to be rationed and someone gets to decide
how the resources get used.
We're not so great at
sharing resources equitably on earth. And that's when we all are getting like all the oxygen and
the water that we need very easily, at least in the US where my husband and I live, it's easy to
get oxygen and water. But like when you also have that sort of stuff controlled by whoever it is,
who's managing your habitat, that gets scary also.
We'll be right back with the rest of my interview with Zach and Kelly Wienersmith after this short break. Greetings, Bill Nye here. How would you like to join me for the next total solar eclipse
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Donate $10 or more for your chance to win.
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So don't let time slip away.
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It looks like at least if we're going to go to space, we have these three major options.
Do you think we're going to end up colonizing all of those? And then particularly
for Mars, I mean, other than perchlorates, what do you think will be the biggest, at least,
physical impediment to keeping those settlements running?
Yeah. So one way to say it is the solar system is big, but the actual places you could go to live
plausibly are quite small. You really only have three options. You have the moon, you have Mars, and some people have proposed built stations in space.
The problem though, the moon cannot sustain life without a lot of amelioration.
One of the most mind blowing facts we came across was that the moon is low in carbon,
which I think your audience is nerdy enough to know what that means, which is we here
talking are each about 20% carbon.
You cannot get more carbon without bringing it.
It has to be made in stars.
So we joke, it's not like you have to modify the soil a little.
You have to literally bring the soil.
You have to bring the farm to the moon.
So the moon as a long-term place for humans to be permanent,
to survive loss of contact with Earth is not plausible.
And then we essentially argue that rotating space
stations aren't really serious either because in order to make them work, you have to have
the kind of infrastructure you would need to build a space settlement somewhere better.
And also they're just very, very basic foundational problems. Like the smallest plausible rotating
space station is far bigger than the International Space Station. And we joke about, there are a couple of papers written on this very basic idea,
which is that if the rotating space station gets unbalanced,
you get that same problem if you've ever used a centrifuge
or your washing machine got unbalanced, it's not good.
And it would be really not good if you were like in a survival bubble in your centrifuge.
So that leaves Mars. And I can say all the downsides of
Mars, like the soil and the dust storms that claim the whole planet for weeks at a time,
and the fact that it's probably six months inbound and outbound. And even then you have
to stay for a while until Earth and Mars are close to each other. We're on a good trajectory.
But here's the good thing about Mars. Mars has like the buffet of elements we need on Earth to survive.
And it also has an atmosphere made of carbon dioxide.
It's very thin.
Generally speaking, you don't want to breathe pure carbon dioxide,
but it is made of carbon and oxygen,
which are valuable for all sorts of applications.
They're also what plants need to breathe.
So with all of its problems and the great distance it takes to get there,
including the fact that the largest distance,
it takes 22 minutes just to send a message.
Mars is really the only place you could seriously consider putting that plan B
for humanity.
And then how do you keep them all and the water?
I mean,
you could get water from the moon from the permanently shadowed craters at the poles, but that's still way less accessible than it is on Mars.
Well, and there's not that much of it, which is what always blows our mind when we hear that people are thinking about setting up gas stations on the moon for rockets.
There's not that much of it.
If you want to have a settlement there, you probably don't want to burn it into the vacuum of space
where you'll never get it back.
And so, yes, you could get some from the moon.
There's not that much.
Mars has lots on the poles and even at the equator,
if you dig down, you're gonna find some.
So water is much more plentiful
and easier to acquire on Mars.
Mars, probably the place.
Even if I want to hang out on the moon,
imagine you build your settlement on the moon and then 20 years in you've hit peak water and now you're in trouble
because you have a whole settlement there.
Yep. That would be disappointing. We do note that one plausible argument for rotating space
stations is that if it turns out that that partial gravity thing is a problem and that,
for example, women can't go through labor with weakened hips.
Rotating space stations can be spun up to be whatever gravity you want. And so we could
figure out what is the minimum gravity required to make all of this stuff okay. And you could
live on rotating space stations or live your reproductive years on rotating space stations,
but that comes up with some weird social problems. But anyway,
in general, we think rotating space stations are a difficult sell unless it turns out that
this partial gravity thing makes Mars just totally off the table.
Yeah, we're going to have to do some serious research just to even know whether or not that
is something that we require. I'm guessing probably based on the bone density loss of people just in low Earth orbit. But
we're just beginning with this kind of thing. So it does scare me, the idea of trying to rush there.
Yeah, no, us as well.
And of course, I mean, there's so much to get into about the workings of a human terrarium
and how you can even make that work. But I think for me, the thing that I feel is most complex
that might take the longest for us to figure out how to deal with is the space law behind it.
Like all of these scientific challenges, I think with enough time and enough thought,
we can tackle them. But the complexity of how to get all of the nations around the world and
commercial entities to buy in on some kind of space agreement is really hard. Right now, we've got our space
treaty from 1967. But as you point out in the book, that was great for 60 years ago, doesn't
cover what we're dealing with today. So how do we even begin to tackle this problem of thinking
about how law will work in space? Well, it's really complicated. And I agree, it's going to be tough to get everybody on board. There's a couple places that you can look for inspiration. So outer space, Antarctica, and the deep seabed, these are all places that have been designated as global commons. And they were designated as global commons around the same time and around the time that technology started to make them accessible.
time and around the time that technology started to make them accessible. And so right now,
according to the Outer Space Treaty, you can go out into space, but you are not allowed to claim sovereignty over anything in space. So you can't land on the moon's poles next to that water and
say, this belongs to the United States. But there is ambiguity about whether or not you're allowed
to say, hey, we know this land doesn't belong to us,
but we're gonna go ahead and extract the water
and sell it as rocket fuel and resource extraction.
We think that's different and we think that's okay.
And right now the Artemis Accords backs that up
and the Obama administration backed up that interpretation
of the Outer Space Treaty.
Trump put out an executive order
backing that interpretation of the Outer Space Treaty. Trump put out an executive order backing
that interpretation of the Outer Space Treaty. This is maybe the only thing our political parties
can agree on. And the Artemis Accords states that two and a bunch of countries, maybe something like
20 now, have signed on to the Artemis Accords to agree with that interpretation. And so that seems
to be the interpretation that's gaining traction. China and Russia haven't signed on, partly because
they can't for a variety of geopolitical reasons. But there's still this ambiguity about what's
going to happen when we get out into space and what are we allowed to do with the resources.
In Antarctica, there is this system where they've decided to prioritize peace over concerns about a
scramble for land and a scramble for resources. And so you are not
allowed in Antarctica to even look for where the valuable minerals are. You cannot extract them.
You cannot try to figure out where they are. There is a moratorium on resource extraction
that lasts until I think 2048. And even then it can only be overturned by all of the countries
that are signed on to the ATS, Antarctic Treaty System.
They all have to agree to overturn it. And that's probably not going to happen. And the reason that
that was set up that way is because people were concerned about what it would do to the Antarctic
environment and what it might do for conflict between nuclear-wielding powers on Earth. So
they decided peace is more important than resources. For the deep seabed,
the United Nations came up with the Convention on the Law of the Sea. And after a bunch of
different iterations and amendments, it's now widely ratified and signed. And the deal for that
area is there's an international seabed authority that can figure out who can extract what. So for
example, there are these polymetallic nodules down there and
they have metals that are useful in things like creating batteries for electric cars.
So there's a lot of desire to extract those amongst certain groups. And so the International
Seabed Authority right now is figuring out the rules for when is a company allowed to extract
and what do they have to do to try to make sure that everybody benefits. And so I think
one proposal that was floated for a while was that a company could say, this stretch of land,
we would like to do some resource extraction and then we'd like to sell it. And then half of it
gets put aside for developing countries that can work with the International Seabed Authority
to extract resources in that other half. And I think that that did not end
up being the final rule. But the point is, they're trying to figure out the rules right now. And this
was another system where they said, okay, we instead of trying to maximize profits, we're
going to try to make sure that everybody gets some benefit, we're going to try to do this peacefully,
and it's going to be slow and bureaucratic. and no doubt about it, there could be better ways to make money than the way it's being managed right now. On the other hand,
nuclear wielding powers aren't fighting over these resources. And so we could decide that space was
going to be like Antarctica, where resource extraction is not allowed, or that space should
have an international space authority that decides how the...
And I mean, that sounds awesome.
So we probably should do that.
We should probably do that.
Immediately.
And maybe that organization could decide which resources can be extracted,
how they get shared amongst humanity, and what the general rules are.
So there's other places we can go to get inspiration for how resources can be managed.
But at the moment, it does seem like
different countries are coming up with their best interpretation of the Outer Space Treaty,
and it doesn't necessarily agree with what other countries, including what other space-faring
countries, might be thinking is the right way to go. And we would like to see there not be conflict
when different countries go out there and actually are able to start extracting
these resources. The tough bit there is that in order to incentivize an entire settlement,
there's got to be an incentive. And probably that incentive is going to be commercial.
I would love a world where we just send pods of scientists to Mars. And maybe that's a good
functional way to do that.
But again, you're probably not going to end up with a settlement of 2 million Mars scientists
all living together. So what then would be the incentive? How do you do it without sparking
disagreements over territories or resources? I'm not sure.
Yeah, I would add, I mean, so we're not convinced that there is right now or for the
near-term future, a plausible economic case for anything beyond geosynchronous orbit. So space is
obviously quite valuable for remote sensing, navigation, data transmission. Anything past
that is pretty implausible. And we go down the line on some of the cases people make, helium-3 on the moon,
metals on Mars, asteroid mining, and basically the case is not super good.
Historically, the reason lots of money has been poured into human spacefaring is inevitably
and always prestige for nations. And it waxes and wanes with animosity between countries.
And so there are, I think, unfortunately,
a number of space geeks who are salivating
for Cold War Part II so they can watch
the Cache floodgates open,
which I hope for obvious reasons is undesirable,
but also we argue it might even be scarier at this point
because Space Race Part I is to see
who can do a cool thing on the moon first.
Space race part two seems to be shaping up around permanent bases. And that's potentially
dangerous because the actual good spots on the moon are extremely limited. As you say,
there are places with water. There are very few of them and there's not much water. There are
places that get sunlight almost all the time. There, again, very few. I think we totted up the total area and it's
some number of hundreds of acres. It's very small. And then when you pair that with the
Artemis Accords, which say you can designate a quote unquote safety zone around your base,
zone around your base, it starts to get, it feels turf-like. Legally, you can't claim sovereignty.
Nobody who goes there is going to say,
we're claiming sovereignty.
But there's going to be sovereignty-ish behavior
happening on the moon, which is frightening.
And we should say we understand why the safety
zones were created.
You do have to worry if a rocket lands
and it blows regolith on a pre-existing station, that could be catastrophic for the station that's there.
And so you do need to find ways to like keep your facility safe, but it does end up essentially
feeling like you've walled off this area and other people aren't supposed to come into it.
And that starts feeling like sovereignty. And whereas with the Soviet Union, it was a race to
get there and then leave,
now we're staying. And that seems like it's a much more potential source of conflict,
especially if people convince themselves there are resources worth getting there,
which to be honest, we don't agree with. It's a great point, too, that the Cold War created this space race. And we like to say
that space brings people together. It sparks this international collaboration in space. But as you point out in the book, every once in a while, there are these international tensions, and then things shift and change. You can see even today how our relationship in space has changed with both China and Russia.
inspirational. We want to get to a place where we're actually working together. And it does spark that international collaboration and scenarios where we might not be able to have
it other ways. But we could end up with a scenario where it actually creates extra tension,
especially if there really are resources that we find. Whoever was the first person to get there
suddenly has this giant bonus of stuff that they can bring to Earth and that in and of itself could
create tensions.
Yeah. The one little thing I would add to that is I actually don't even think the resources need to be there. Famously, when Sputnik went up, both Khrushchev and Eisenhower were surprised how
much people cared. I think in part because they knew it wasn't significant in a military sense
or anything else. It was just like the public at large, like around the world had a perception of
what was there.
So we have people in government and industry saying it's really valuable to do stuff on the
moon and that may be enough. There doesn't actually have to be something worth doing
in the financial sense.
And then we end up with all these space states in space doing their own thing.
Hopefully, maybe we have some kind of governing authority in space
to help us deal with everything. But what happens when one nation or one commercial entity decides to
throw someone out an airlock? Who's legally responsible for that?
How do you even create a framework to deal with that?
It's super complicated. I will say so. according to the Outer Space Treaty, if someone
goes to space, they are the responsibility of some government. So if Elon Musk goes to Mars,
sets up a Mars settlement, and things go catastrophically wrong, or he starts breaking
international law, it's on the United States to clean that mess up. And often people will push
back when we say that,
and they'll say something to the effect of, well, what can you do when Musk is on Mars?
But Musk cannot launch his rockets without FAA approval. I mean, maybe he could launch them in
some other country. It would be a thing. But the United States government could say, we are no
longer allowing your rockets to bring resupply to Mars until you start following international law again. So there are ways for nations on Earth to control the behaviors of people in space if they
choose to do so. So that's where the problem is. It's not the idea of doing cool stuff in space.
We're all for that. It's these geopolitical factors that are dangerous. When we talk to people,
we've come across people who will say things like, well, SpaceX,
they haven't done anything impressive.
They got government money. And I just, clearly he has done something that nobody has been able to do before.
And the government has had lots of government money and we haven't been able to do it.
And so we are impressed with SpaceX.
Clearly Musk has done incredible things to drop the cost of rocket launch.
What scares us is that he also says things that suggest he's willing to flaunt international law or drop international law.
And he seems to be trying to hurry this up at a pace that we think is probably not safe for either the humans who get sent or the humans who are left behind if he sparks geopolitical conflict.
if he sparks geopolitical conflict.
This is why I'm so glad that there are whole new schools of space law
and a bunch of people just now at this moment in time
getting into this field
because commercial entities sometimes
can really speed along the process.
It's just, there's so much there
and we don't have time to get into it.
So I'm really glad that people are gonna be able
to pick up your book, begin reading it.
And this next month, if anybody out there is a Planetary Society member, we're going to be
reading this book in our book club in our member community app. So we're going to have a fun time
kind of chewing through all these hypotheticals together. Yeah, yeah. In the end, I don't want to
spoiler your conclusions. But in this scenario, where we know it is very difficult for humans to build these settlements off of Earth, is there hope?
Is there still a reason for us to try to overcome these obstacles?
Well, so we end the book by pointing out that, first of all, Zach and I have no power.
out that, first of all, Zach and I have no power. The most you can say about our clout is that Zach is a good cartoonist and I'm president of a regional tiny parasitology society. We don't
get to say that this can or cannot get done. We can talk about the roadblocks, but we don't get
to say no. And in the meantime, there's lots of cool work that can be done when you try to do
this safely. We would love to see there be a research station on the moon
where we start getting the data that we need
on can generations of rodents safely reproduce on the moon
with no sort of reproductive problems.
And you've got scientists who are out there for like a decade.
Do they seem okay?
Can they return safely to earth?
And there's tons of really interesting international law
stuff that needs to get worked out,
tons of research on closed loop ecosystems, which is a fascinating topic.
And of course, the better you understand how the various parts of an ecosystem work together,
seems like that could only help our planet at a moment like this where we're worrying
about climate change.
And so the research between now and when we can safely do space settlements is fascinating
and exciting.
There's lots of cool stuff to do.
And maybe settlements won't happen in our lifetime.
I think, to be honest, I hope that it doesn't happen in my lifetime because I think racing
could have lots of problems.
But there's cool work to be done in the meantime.
Yeah.
And as to the question of whether there's hope that we'll do it, I think we basically
feel there is,
it's just the list of prerequisites is quite extensive.
So there is technological stuff having to do
with reproduction and ecosystems,
which as you said, is probably something
that can be solved with science.
It can't be solved quickly
because it involves biology, which is finicky,
and it can't be solved by scaling the rockets,
although that doesn't hurt.
So that needs to be solved.
But then the legal stuff is trickier.
You really want to be in a world,
given how much heavy, fast stuff is being put into space
or would be put into space under the scenario,
given how many different actors
would have some level of control over it,
you really need a more harmonious Earth
to be able to do this safely,
unless we get like tractor beams or some crazy start drinking stuff.
So that's something worth working towards.
And I do think there is some world in which eventually we do have enough advancement and
enough of a harmonious Earth that we choose to go to Mars, not because it's going to make
us rich, because it probably won't, but because we all want to go and it's just awesome. And it would
be sad to just stay here in this one place, but, but then it's fundamentally an aesthetic choice.
It's the thing we do because it's amazing, not because it's going to make us rich or wise or
better in any particular way. But that's enough. Yeah, that's fine. Let's do it. It's cool.
It's cool stuff up there. Personally, I think that's the best motivation to do anything.
Because it's cool.
Because we can become better along the way.
And it's funny, but when I was a kid, my mom always used to tell me that she thought that maybe this venturing into space would be the thing that really forced us to confront these issues.
forced us to confront these issues. Maybe we have to confront our territorialness and our inability to be kind to one another if we're really going to make this work. Because otherwise,
we put ourselves in the space and we really magnify what those issues do to us. So I remain
hopeful that hopefully we learn some really cool science along the way. And maybe we actually begin
to think thoughtfully about how to get through these issues together. The wet blankets remain hopeful as well.
Well, thanks for joining me, Zach and Kelly. And I hope everyone enjoys this book. I'm going to put
a link to how they can find it on this page of Planetary Radio. Please join us in our member
community for this book club because I think we're to have a really good time. Thanks so much, Sarah. We had a blast. You know, for being self-identified wet towels
about the subject of human space habitation, those two are a lot of fun to talk to. I'll leave a link
to the website for their new book, A City on Mars. Can we settle space? Should we settle space? And
have we really thought this through? On the website for this episode of Planetary Radio
at planetary.org slash radio. And while you're at it, you can check out their other book. It's called Soonish,
10 Emerging Technologies That'll Improve and or Ruin Everything. It's definitely on my list.
Now let's check in with Bruce Betts, the chief scientist of the Planetary Society for What's Up.
What's up, Bruce Betts?
The sky.
Clever.
Yeah, I'm clever today.
Are you clever today?
No.
All right.
No, always, though.
You're always one of the most clever people I know, even when you are sleepy, Bruce.
So.
Well, thank you.
I think.
We just had a really great conversation about all of the things that
could make it really difficult for humans to go and live on Mars.
And I'm wondering what you think the biggest challenges are for humanity
trying to go to Mars at this point.
What are the things that we really,
really need to tackle before we try to send humans to the red planet for a
permanent settlement? Oh, there are so many. The radiation damage to people out there, especially
outside the magnetosphere for long periods of time. So there's no protection from the solar
wind and cosmic rays. And then that's kind of the duration thing, which you've also just got everything associated with humans in space, bone loss over time, weakness.
What do you do when you get there and you've been in zero gravity, assuming you don't rotate the spacecraft or something?
How do you suddenly function in 38% gravity?
And then there's the trick, which last I knew is pretty well unsolved, which is if you actually plan to go to the surface,
how the heck do you do that? And I think we've discussed that here before, but every time they
increase the mass a little bit going to the surface, they come up with creative ways to do
it and have big challenges. Mars is the worst possible place to land in the solar system at
some level because you don't have no atmosphere, in which case, like the moon,
you can just do retro rockets.
And you don't have a thick atmosphere like Titan or Venus or Earth
where you can use heat shields and parachutes for a very long time.
You've got this thin atmosphere, so you can't turn on the retro rockets right away
or you can't float down for a long
time. So figuring out how to load, because they're going to have to land a much more significant mass
to keep humans alive on the surface. But you can also go there the first times without going to
the surface. That's a possibility and was suggested by a planetary society-led study a few years ago, but you still have all the problems of humans
in long-duration flight in space,
and there are a lot of them.
But hey, it's a challenge for humanity.
We could just put each human in their own individual little pod
and then just sky crane, parachute, everything,
wrap them in bubble wrap maybe, and then just sky crane, parachute, everything, wrap them in bubble wrap,
maybe, and then just have them land that way? Yeah. I'll put you in touch with some of the chief engineers. No, maybe not. You might want to... That sounds great, Sarah.
In my heart, I don't really doubt that we're going to figure out how to do it. There are a
lot of scientific challenges that we'll definitely face along the way, but I do think that we're going to figure out how to do it. There are a lot of scientific challenges
that we'll definitely face along the way, but I do think that we'll be able to figure those out.
What I really question is whether or not we're going to figure out how to treat each other on
the way there, whether or not we figure out the space law and the challenges surrounding commercial
space, and just what happens societally when you send people
to Mars? What happens to the kids who might be born there? Are they going to be mad that they
were born on Mars and they can't really come to Earth? There's just so much that we'd have to
consider there. You're thinking much farther out than I am.
I know. Well, see, that's it. It's like the human challenges, I feel, take a lot longer to solve.
I mean, not the getting along. That makes
sense. But I mean, that's a near term. That's one of your problems is your psychology of a crew for
that type of duration and that type of isolation. But the other ones, I think, are a little further
out. But I tend to try to focus on the technical because it hurts my brain less.
The ones that we can actually solve. But thankfully, there are more and more people
that are working on space policy and space law. So one of these days, maybe we'll have some better
idea about how humans will get treated in space so we don't straight go from zero to the expanse.
Not that I don't love that show or those books, but, you know, I wouldn't want to be one of
those belters is all I'm saying.
One of those belters.
Let's not get into it.
Okay.
Would you like to hear a random spacecraft?
I would.
Our solar system orbits the center of the Milky Way galaxy at a relative speed of about 828,000 kilometers per hour, or 515,000 miles per hour.
It's about 230 kilometers per second.
That's a lot.
So at that speed, if somehow you had the speed of the solar system going around the galaxy, you could go around the Earth in about three minutes.
Huh.
Huh.
I mean, it's funny.
I almost want to think, like, that's both faster and shorter than it could have taken.
I don't know how to quantify that, so that's a great way to brain that out.
It's fast. It's hard to imagine. Yeah, no, I too had weird things. So anyway, and then of course,
of course, it takes us about a quarter billion years to complete one orbit around the center
of the galaxy with some variability. So we're not very old in terms of our galactic birthday.
Do you know off the top of your head, like, how do we make that calculation of how fast
we're going around our galactic core?
I just kind of take an old piece of paper and I write it down and then present it and hope no one
asks.
This is the way.
No, I don't. I'm sorry. I could make something up, but it would probably be better to yield to our listeners or looking it up ourselves.
I'm not sure how we've done that calculation.
I haven't.
Humanity has done that calculation.
I do have another question about that, though.
So we're talking about Earth going around the galactic core in kind of like a circular fashion with all the other things
in that that disc of the milky way but there's also this kind of up and down in and out of that
disc motion going on that's a totally separate kind of velocity i would like to look that up
sometimes see how fast we're bobbing in and out of that disc because we're going around
the yeah well i just try to get people to see the rabbit hole to go down and then have fun.
I'm going to be going down that rabbit hole for a long time.
This was to tease you, and you may prove those exact numbers wrong, and they vary because of
stuff like going in that.
Anyway, yeah, have fun.
Have a good time.
The universe is complicated.
It is.
And I feel like that's a good point to end on.
All right, everybody, go out there,
look up in the night sky
and think about what you would do differently with your life
if you could go around the world in three minutes.
Thank you.
Good night.
We've reached the end of this week's episode of Planetary Radio, but we'll be back next week to
talk about NASA's STEM outreach program. I'm personally really excited to learn more about
how kids can get involved in designing a new flagpole for the next time humans go to the moon.
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