StarTalk Radio - Cosmic Queries – Space Suits with Ana Diaz Artiles
Episode Date: July 5, 2022What’s the future of space suits? On this episode, Neil deGrasse Tyson and comic co-host Matt Kirshen explore innovation in space suit technology with aerospace engineer Ana Diaz Artiles. NOTE: Sta...rTalk+ Patrons can watch or listen to this entire episode commercial-free here: https://startalkmedia.com/show/cosmic-queries-space-suits-with-ana-diaz-artiles/Photo Credit: NASA, 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.
Neil deGrasse Tyson here, your personal astrophysicist.
And today, we're going to talk about spacesuits.
Or we could retitle this, How to Not Die in Space.
And I've got with me co-host Matt Kirshen.
Matt, good to have you, man.
Good to be here. I'm at home right now.
I'm back home, which is another way to not die in space.
It's just stay safe.
Being on Earth is a way to not die in space.
Staying safely in Los Angeles.
That's my tip for this episode.
So this is kind of a hybridized,
it's going to be sort of an info show
on spacesuits, spacesuit design,
what it's protecting us from,
why, why is it necessary,
and then we're going to blend in
some cosmic queries
in the second and third segment.
So I look forward to this.
Well, I know a little bit about spacesuits.
I don't know nearly enough to carry this show.
So we combed the landscape of people with this kind of expertise
and they exist.
Okay.
And we found Professor Ana Diaz-Artiles.
Ana, welcome to StarTalk.
Hi, thank you so much for having me here.
This is great.
I love it.
You're an assistant professor in the Department of Aerospace Engineering at Texas A&M.
And you have developed or are in the process of developing a new spacesuit.
And it's called the SmartSuit.
So I want to totally get into that.
But in this moment, you're coming to us from Barcelona.
Is that correct?
Right.
I'm originally from Spain, although I was born in Canary Islands, but I'm now in Barcelona.
My husband is from Barcelona.
So I'm here visiting some family.
Okay.
I love the Canary Islands.
We have some telescopes there.
It's volcanic and there's some good wine there too.
There's a wine industry.
We got to bring you back.
We'll talk about the Canary Islands.
For sure.
A whole other show.
And Matt, you're not just my co-host comedian.
You host your own podcast, Probably Science.
That's the one.
And I've been a guest on that show.
You have indeed.
And yes, we've got that connection.
The connection I have with Anna
is I've sent in my designs for spacesuits
many times to universities around the world.
No replies so far, but...
Yeah, she'll tell you why.
I'm wondering if the fishbowl
is not using high enough quality material.
I think, because I'm using Target,
you know, just like a standard Target fishbowl,
but maybe you need to go to one of, like,
the specialist pet supply stores or...
Oh, yeah, I mean, the fishbowl inverted on your head.
Is that what you're saying?
Yeah, exactly, you know, that's...
It's a fishbowl and jumpsuit.
What more do you need?
I can't imagine...
I think that's the end of the science, right?
We're done, episode over?
There you go.
Okay, so, Anna, why in just that moment
was Matt a complete idiot?
No, no, Anna, what kills you in space?
Why can't we just hold our breath until we get to our destination?
There could be many things that can kill you in space.
But if I had to pick one, I would say, you know, we do have a lack of atmosphere.
There isn't any pressure put in on your body.
So that lack of pressure is actually going to make all your fluids
basically become gas, and then you're going to boil in space pretty quickly.
Wow. Okay. So that's not even about whether you can hold your breath.
No. Actually, if you hold your breath, that's not a good idea because that oxygen, that
fluid that you're holding, it's going to expand
also because of the lack of pressure. And then, you know, that is not going to be good for your
lungs. I've obviously, I've never been to space, but I have gone scuba diving. And one of the very
first things they tell you that they drum into you very many times is you must not hold your
breath as you come up to the surface for that exact reason, because you've breathed in air at high pressure down in the depth. And then as
you come up to the lower pressure on the surface, you could basically burst, right?
So, Anna, that sounds like exactly the same problem. Is that correct?
I was going to say that's exactly the same problem. It's just the other way around.
When we go into a spacesuit,
we're generally going into lower pressures
compared to the spacecraft that we're having.
And there are many reasons why we want to go to lower pressures.
And one of them is mobility.
We can talk about it.
But then if we think about scuba diving,
the problem is not when you go down,
but it's actually when you go up
because you go from higher pressure to lower pressures.
And this is why, I'm not
a diver, unfortunately, but
this is why you need to
do all these
waiting times, and you cannot just
go up to the surface really quickly.
You need to stage those.
So, Ana, how did you get into this?
I mean, when you were a little child
and said, I want to design spacesuits.
I mean, like, who does this?
Right.
Did you watch some movie?
Like, did you visit someplace?
How does one become a spacesuit designer?
Maybe that's really what the question is.
Yeah.
So I'm just a traditional aerospace engineer.
Just a regular aerospace engineer. Just a regular aerospace engineer.
Just the kind you bump into.
You bump into them on the street all the time.
I've always been fascinated with space.
And yes, there was a movie.
It was actually a TV series, From the Earth to the Moon.
I don't know if you remember this.
Yes, of course.
Like 1997,
if I remember correctly.
And, you know,
we didn't have Netflix
or anything at the time.
So you just had to be there
on Saturdays at 7 p.m.
Otherwise, you missed the whole thing.
Or wasn't streaming.
Yeah, yeah, yeah.
And yeah, it was at the time
that I was finishing high school and just like, what do I want to do with my life and such.
So, yeah, I said, this is what I want to do.
I want to do space.
And I started working my way into that.
So I went into aerospace engineer and then I went to industry for a while.
So I didn't do research right after my degree.
And I...
But let's be clear, Matt, if you didn't know this, she could go on for more education,
or she can make a boatload of money going into industry immediately.
That is the choice.
Is that correct, Anna?
Tell, fess up, this is what happened, correct?
Well, I was launching
rockets. I was in operations
and related to space, so
very far away from research, but
still space-related.
And I was there for a while. I was there
for a few years, that's true.
Okay, okay.
That's always been my issue
whenever anyone, to take us marginally
off topic, whenever anyone, there there's climate change or evolution arguments,
and they're always like, these academic elites.
Do you have any idea how un-elite academics are?
That's correct.
Compared to what they could be doing with their learning and their brains?
How much money they don't make compared to how much money they could.
They've turned down the C-suite for hacky sacks and sandals.
So, yeah, so I'm impressed that this TV series
had an impact on you,
because do we fully,
do we really know how much influence
our media has on people's ambitions?
I don't think we think about it enough.
We just think of it as entertainment.
But my gosh, if it puts you on a path to where you are now, people need to know that.
It did.
And I feel like I've told this story before.
I feel like I'm always repeating myself.
But certainly it was a game changer for me.
And at the time, also, we didn't have this huge social media or social presence.
So that's something that I definitely try to contribute. And with this podcast and, you know,
trying to tell especially little girls and, you know, STEM and girls in particular, because they,
you know, it has been shown, they sort of start not becoming interested in STEM disciplines anymore.
So I'm trying to do my part on that.
Right, right, right, right.
So, okay, so getting back to the inventory of all that will kill you in space.
So one of them is your blood begins to boil
and outgas. Okay, that can't
be good for what's going on
inside your skin. So what about
the temperatures? You start
getting very cold
to the point that eventually you will
freeze, but I
believe you will die way before
that.
You will die because you don die way before that. You will die because...
So don't worry about freezing.
The temperature will just preserve the corpse that's already there.
Yeah, you will die because of asphyxiation
in two minutes or less.
And then, you know, you start getting cold
and eventually you will be like a freeze rock in there.
I don't think it will happen
very, very quickly,
but it will eventually happen.
Yeah, because all the heat
has to still come out of your body
and that would take time, I guess.
Right.
But wait, so do you asphyxiate
before your blood boils?
What happens first?
Well, I don't have
experience with this,
thankfully.
I guess you can't just
put a person out there
and say,
well, you'll be out
test case.
Right.
Right.
So I've been reading
a little bit about it too
to see, well,
let's see what we think
this will happen.
But I believe you will
asphyxiate first.
You will pass out first
and then eventually die
30 seconds later
because you don't have
any more oxygen going anywhere
because there is no
oxygen to take from.
Also, your blood
is not liquid anymore. It's not bringing oxygen
to your tissues
anymore.
So this is a matter of minutes.
This is a matter of minutes, you're saying.
Yes.
So here's a question I really wanted to get to.
I grew up a little bit before you, or a lot before you,
and astronauts wore spacesuits.
So I didn't think to myself,
I need to go into spacesuit design
because they already had them.
So did you see a flaw or a need that others didn't in spacesuit design for it to attract you as one of its students and then ultimately one of its researchers?
Yeah, yeah.
And I have to give all the credit to my PhD advisor, one of my PhD advisors, Dr. David Newman.
And this is how I did get
into spacesuit design.
Going back to that I was in industry,
then I decided to go back
to academia and get a PhD.
And I was lucky enough
to get into MIT
when I started working
with Dr. David Newman.
And she has been doing-
Wait, wait, Anna.
Just wait, Anna, Anna, Anna.
Anna, it wasn't luck, right?
If you're good, they'll take you.
There's no luck involved.
Let's be clear about this, okay?
Okay, I'll reword that sentence for you.
They realized how important I would be to their group,
so they brought me on, okay?
That's it.
Now, pick it up from there.
That's it, that's it.
So I joined this amazing group of individuals
and for my first two years in grad school, Pick it up from there. That's it. That's it. So I joined this amazing group of individuals.
And for my first two years in grad school,
I worked on a project on spacesuits and trying to understand
how humans interact with these spacesuits.
So the human-spacesuit interaction.
Like spacesuit as a system,
you put this system around a human
and this human has to move
and not get
injured and being able to do all
these tasks. Right, because they did look a little
bulky on the moon. That looked like
that's a lot of spacesuits they wear in there.
Yeah. Right, so these
injury aspects, it was the one that I
started looking into at the time
and unfortunately it's really hard
to move inside the spacesuits. It's like this
big pressurized balloon that causes a lot of problems and musculoskeletal issues.
And lots of astronauts actually had surgeries in their shoulders because of the spacesuits.
It's a big, big issue that maybe, you know, we don't think often about it.
And this is how I got first exposed to start thinking about all these issues with spacesuits.
Okay, so now, before we go to a break, we've seen new design spacesuits, like a SpaceX, I guess.
Those look kind of even stylish, right?
And they're not so bulky as we saw the astronauts going to the moon wear.
So, does anyone care, like, what they look like?
Is their style involved as well?
There is, but before getting into that,
the SpaceX spacesuits,
these are spacesuits designed for inside the spacecraft.
So, these are IVA spacesuits,
intravehicular activity.
And the bulky ones that you imagine
when going back to the moon
and all those big ones, these ones are EVAs,
so extravehicular activity. So these are very, very
different type of spacesuits. And it's
normal that the ones for
inside the spacecraft are way, way thinner
and way, way less bulky about that.
Okay, so Matt, I heard tell that this extravehicular activity term,
NASA has finally, at some level, simply called it spacewalking.
Okay?
Yep.
They've just cut out, yeah.
There's too many acronyms already or initialisms.
Too many syllables.
Just tell it like it is.
Spacewalk.
But then they're floating, really.
They're really space floating.
Space swimming.
I never really liked.
For now, they are just floating.
But when we are going to the moon, we need other things.
Oh, she's ready.
Okay, excuse me.
Okay.
Excuse me.
I don't mean to hold you back.
Okay.
Going to the one.
All right, so do you think much,
and we'll get more of this in the other segments,
do you think much about how the role of the spacesuit,
depending on how strong the gravity is on the object you're going to use it?
So on the moon, it's like one-sixth gravity, right?
So the suits they wore on the Apollo astronauts were very heavy on Earth.
But when you divide by six, it's not so bad.
So I presume there's a different design for what would be a moon suit versus a Mars suit,
where Mars you weigh like 40% of your current weight.
So how do you think about the gravity field that you're in?
Yeah, no, that's a great question.
And I don't think we have been thinking about that very much
because it's not like we go to different gravity levels every day
and we can just pick the gravity level that we want.
But yeah, certainly now we are starting to think about,
or the last few years, to think about moon spacesuits.
And I think they want to do those spaces a little bit lighter.
Right, because a spacesuit that might be too heavy for Mars
might be just right for the moon.
I guess that's really all I'm commenting on here.
Yeah, yeah.
So somebody has to go in there and figure that out for that.
Well, why don't we take a quick break, and I just want to talk a little bit more about
the design of current spacesuits and any specific changes you are making to them, or any, more
interestingly, I think, any particular innovations that no one even thought to do that would make going into space that much more pleasurable than anyone had experienced before.
So we're on StarTalk, all about spacesuits.
And we'll get to cosmic queries in a minute.
And I'm with my co-host, Matt Kirshen, and Dr. Ana Diaz-Artiles,
aerospace engineer and expert on spacesuits when StarTalk continues.
Hi, I'm Chris Cohen from Haworth, New Jersey, and I support StarTalk on Patreon.
Please enjoy this episode of StarTalk Radio with your and my favorite personal astrophysicist,
Neil deGrasse Tyson.
We're back.
StarTalk Hybrid Cosmic Queries Edition.
We're really trying to learn about spacesuits.
And we have one of the world's experts on it,
Professor Ana Diaz Artides at the
Texas A&M Department of Aerospace
Engineering. And
remind me what town Texas A&M
is in? It's in College Station,
Texas. Oh, of course, College Station, Texas.
That's right. That's right. And
A&M, of course, stands for
Agriculture and
Mining, I guess? Mechanical.
Mechanical.
Okay.
Yeah, so this is one of the land-grant institutions
where science for better living
has been a fundamental part of their mission statements.
There's a bunch of them across the country.
And so there it is.
And you know, in Texas,
because Texas has the Johnson Space Center
and it's the seat of the Manned Space Program,
you'd expect Texas to be a little more up
on just what you're telling us
and what you specialize in,
because it's in their backyard, right?
So I love it. I love it.
So what about the threat of sort of ionizing radiation from the sun?
When we think of sort of the solar wind,
we think of them as sort of innocent charged particles
deflected by our magnetic field on Earth,
and you get the aurora.
But if you're bare-assed in space,
or sorry, if you're in a spacesuit in space,
are the spacesuits you're designing
protecting astronauts from that as well?
That's the million-dollar question.
So I'm going to start by saying I'm not a radiation person.
But what I understand
from radiation
is that
we don't really know
what to do about it
very much.
Basically, we just hide
whenever we know radiation
is coming.
That works every time.
And I apologize
if there are radiation people
out there with better answers
than me. I apologize for there are radiation people out there with better answers than me.
I apologize for that.
But hiding works is what you're saying.
Hiding works.
And we do have the means to know when there is something coming from the sun
and a coronal mass ejection or a flare.
We know when those are coming.
And we can just seek shelter.
We don't do EVAs or spacewalks when we know there are sand activity coming our way.
So that's the way to deal with it today.
As far as I know, this is how we do it.
And what's interesting is we do call it, NASA calls it space weather.
And just like if it was thunderstorms outside, you either wouldn't go out until it stopped or you would bring on special protection.
So I guess in terms of how you would react to that information, it's not fundamentally different from what we do daily, just in life, when we're preparing for the weather.
Absolutely.
And the other way to deal with it, and I guess this is more transportation.
If we want to go to the moon or we want to go to Mars, the other way
is just go faster, so you
are exposed less time
to it. Oh, of course, yeah.
The other way. That takes more fuel.
It takes more fuel to go faster.
And we don't know how to go that fast
yet to Mars, but I
guess other people are looking into
those new technologies to get
faster.
So, Matt, what we need is a wormhole between Earth and Mars.
You just step through it and enjoy it.
And then the coronal mass ejection comes,
you just step back to Earth, protected by our atmosphere.
See, it's easy when you put it that way.
My idea was just to move Mars closer.
I love your ideas Matt
I'll show you my drawings later
yeah of course
and you did them in crayon I bet right
well you've got to make an effort
this is science
I can't just do black and white
exactly full color
crayola
it's really colorful
do you have questions from our Patreon members?
I do. So as well as radiation,
a couple of our listeners,
Salvatore Scuri and Alan in the Stars,
are both asking about micrometeorites,
like the one that knocked the mirror
out of the JWST out of alignment.
And also Salvatore says,
what are the chances of micro-sized meteors
puncturing spacesuits,
and what can be done to mitigate the consequences?
And how does it feel to them, Alan wants to know.
And I want to add to that,
is there's presumably a trade-off
between how much protection a suit gives you
and how less useful it becomes.
Because you can just put people out there in a cement block or whatever,
and they'll be fully protected, but you can't do anything in it.
So do you ever think about those kind of engineering trade-offs
between safety and utility?
Yeah, yeah, absolutely.
So in terms of protection,
the current spacesuit has up to 14 different layers.
And one of them, or a few few of them are just for protection.
So there's thermal protection.
And there is this other one, which is exactly what this listener is asking for, micrometeorites.
That doesn't mean every, you know, there's like a big thing coming your way.
It's going to make you a hole in the spacesuit.
That's a risk that we know
that exists. And actually, that's one
of the risks that we want to
attack from the kind of
smart suit things
that they were doing.
But there's always a risk for that, although there is
some layer of protection in there.
Wait, so what is a smart suit then?
So the smart suit is
our new space suit architecture
that we are studying.
And we got some NASA funding to do some research on this.
So this smart suit, it's still a gas-pressurized suit.
And we haven't talked about mechanical counterpressure suits.
We can do that too.
But basically, we're adding cool technology to the current spacesuits
and one of those technologies is to have a self-healing membrane on the outside of the
spacesuit so for example in the case of a puncture no hannah i've only seen that in science fiction
movies what are you talking about well it is a little bit science fiction we are making this a
reality and when you have a hole,
you can just put some pressure on it
and then it's just going to self-heal.
So you can come back to safety
and maybe later do better repairs,
but at least it keeps you alive
and you can come back to your shelter to do that.
Okay, so actually, if you get punctured
and then it self-heals,
you'd be a collecting device
for micrometeorites.
You'd be full of micrometeorites
and you just bring them all back down
for analysis.
That could work, right?
Yeah, well, it depends
if it passed through.
Maybe it just goes away
from the other side.
So the little bit I know
about sort of ballistic protection,
clothing protection, is if you have many, many layers,
if an impactor hits the top layer,
that energy now has to sort of work its way to the next layer,
and there's a lot of dissipation at each layer.
So is that why there are so many layers, to spread the energy out?
I think it's more about all the functionalities that we need in this space suit.
So we definitely need temperature management.
So the first three layers are for something that we call the liquid cooling and ventilation
garment, which is a garment that has water circulating.
So then you can regulate if you are too hot,
you can increase the flow
and then that's going to help you with temperature regulation.
Then you have another layer that it's for the pressure.
It's the pressure bladder,
like the one that holds the pressure of your spacesuit.
Then there is another one that it's called the restrain layer.
And that's basically to avoid
the bladder to be like a balloon
in any shape and form.
Oh, interesting.
Otherwise, it would puff up.
Yeah.
Interesting.
And then you have all these other
like thermal protection,
micrometeorite protection.
And I think it's more about that.
The case of puncture,
again, these spaces were designed like 50 years ago,
but there are some layers to protect you
or trying to protect you from that.
But unfortunately, this happens regularly
or sometimes in the ISS too,
like there is like a hole just coming
and we just need to put it.
So it's one of those risks that are up there
and we try to manage it the best we can.
But if there is like a big one coming really fast,
I'm not sure we can do something about it,
at least today.
If it's big enough to knock your head off,
the spacesuit is not going to be that helpful, right?
It's got to be a category of meteor that just, like,
the spacesuit does not help.
But let me ask this another question.
At what point can the spacesuit become kind of,
I'm not using the right word here, but it's the word that comes
to my mind, an exoskeleton where the spacesuit is empowered with tools and machinery or software,
whatever, so that it's not just smart because it's keeping you alive better. It's smart because it's keeping you alive better it's smart because it's an extension of what it
is you need to do in your environment so the answer is as today there isn't any sort of
exoskeleton helping you out but that's the second feature and i guess that we are i mentioned three
different features so we talked about the self-healing membrane and then the exoskeleton, soft exoskeleton
is the second one that we are trying to implement.
And that's exactly what you said.
It's just so hard to move
within this highly pressurized environment
that we can use a little help
to bend your arm or bend your knee,
walk around. And even we can think a little help to bend your arm or bend your knee, walk around.
And even we can think a little bit more smart than that, right?
Like the suit can anticipate your movements and just helping you walk naturally if the
suit knows that you're going to walk and do certain tasks or something like that.
Exactly.
I mean, why not engage the suit in part of what your body is
trying to do? So it's not just an enclosure for you, it becomes an extension of you.
Right, right. And instead of the traditional exoskeletons that we can think about, which are
typically hard, you know, hardware and hard and humans are never good with one another.
So we are looking into soft exoskeletons.
These are very compliant materials that you can put inside your spacesuit
and can make that human spacesuit interaction a little bit easier,
avoid injuries and all those things.
I just realized just in this moment,
but of course it's surely something you guys think about all the time, that advances in your field often depend on advances in material science.
You've got to read their journals to find out if there's something that you could exploit
for your own needs, right? So how much do you guys talk to material scientists?
Yes, I'm glad you brought that up because I definitely want to mention my colleague
and co-investigator, Professor Rob Shepard.
He is a professor at Cornell University.
I used to be at Cornell, so this is why I know him very well.
And this is a project from both of us,
and he's the materials guy and he's the robotics guy.
Okay.
All this technology, and then I'm bringing more of this space knowledge
and the space components on it.
So he's got a foot in both camps.
You see, Matt, I keep thinking, you know,
do comedians have material comedians?
They're called prop comics.
Prop comics.
Oh, prop comics.
Those are the ones that have,
that pull stuff out of a bin
and then use it for their jokes.
They'll collaborate with like an umbrella
glued to a phone guy at a different institution.
Oh, okay.
So those are the material science comedians.
Yeah, the materials comedians.
We do have, while we're talking about pressure,
John David Newman wrote in saying,
why does our current space suit have 4.3 PSI?
Is that a consequence of the suit itself or was 4.3 PSI? Is that a consequence of the suit itself
or was 4.3 PSI a health and safety
requirement? Granting better mobility
from lowering the PSI is great, but are there
any health risks of lowering the pressure on our body
in space? Well, wait, so regular
pressure is like
15 pounds per square inch, right?
14.7
I think, PSI. Oh, okay, I was way off.
Okay.
Okay. right 14 14.7 i think psi oh okay i was way off okay so 14.7 at sea level and so this person clearly like they either know what they're talking about or they don't they're just coming in saying
4.3 which is obviously much less than sea level. So if that's correct, are we susceptible to
this boiling problem under such low pressures? Yeah. So going back to your question about trade
offs. So here we have a really, really interesting trade off between pressure in the suit. You want
to have less pressure because it's easier to move.
Decompression sickness that you mentioned,
we need to be careful if we go very low.
And if we do, we need to make sure
we are going to make sure we do it safely.
And that requires lots of time
of free breathing, pure oxygen.
And then the third aspect, I guess, is mobility.
So pressure, mobility, and decompression sickness,
which translates into operations.
People in the space station now can pre-breathe pure oxygen
during up to four hours
just to make sure they don't experience decompression sickness.
So that's a huge investment.
So that's the bends you're describing.
That's what scuba divers call them.
Yeah, I think so.
Yeah, exactly.
The bends.
A scuba person would say it was the bends, right?
Right.
It is.
Yeah, it is exactly what it is.
So we don't know of any incidents of the benzene phase.
But yeah, it's definitely a risk.
And the lower you go, it's great for mobility,
but then you need to be more careful with this sort of thing.
Okay, so it's the trade-off that you're describing.
Very interesting.
Okay.
All right, why don't we take another break?
And when we come back,
we'll go all Cosmic cosmic queries from our fan base
and just find out how they're thinking about our future in space when StarTalk returns.
We're back, StarTalk, talking about spacesuits.
And we've got Professor Anna with us to tell us all about it.
And of course, Matt Kirshen.
Just to find out where everybody is on social media.
Matt, how do we find you on social media?
I'm at Matt Kirshen on Twitter.
I'm at Matt underscore Kirshen on Instagram,
which I almost never use.
And if you just Google something vaguely close to my name
and bang the keyboard, Google will find me.
Okay. And
your podcast, where can we find it?
At a podcast dealer near you?
Probably sign some of the podcast places.
That's where we find you on social media. But do you also
do stand-up and things? We see you in person?
Yeah, I tour around. I'm mostly
in the US these days, but I'm sometimes internationally.
So yeah, find me. I normally tweet out when
I'm gigging. You can...
Oh, good. Excellent.
You can find me at a Pestero Comedy Club
near you to have me on.
And Anna, how do we know about
what you do from a social media perspective?
Are you guys active?
Is your group active online?
Yeah, so we have Twitter.
I have my own personal Twitter
and then the lab at Texas A&M,
it's called the Bioastronautics and Human Performance Lab.
And again, I think if you Google my name or the lab's name or Texas A&M spacesuits, it's just going to pop up.
You should find it.
And your name, Ana with one N.
With one N, yes.
And Artiles with one L. Artiles, yeah.
And okay.
So, excellent.
So, I want to bring back up your smart suit.
And just to learn from you,
what's the smartest thing you're putting in the smart suit
that wasn't there before,
that Neil Armstrong didn't have
as he bounded around the lunar surface?
Right.
So, as I mentioned,
the smart suit has three technical innovations
that current spacesuits don't have.
The first one,
I guess I'm going to start with the subrobotic layer
that we mentioned.
So imagine this internal layer
that is the smart subrobotic
that helps you move around.
It's really hard to move inside.
People basically have to fight
against the spacesuit.
And as Jeff Hoffman mentioned to me,
former astronaut,
he said,
the spacesuit is always going to win.
It's a brilliant sentence.
And you don't want that to be the case.
You don't want that to be the case.
You want the human to win.
So, okay. so if the suit senses
that I want to bend my elbow
and then helps me do it,
is that what you're saying?
That's the future.
That's the idea.
And this project also,
I would mention,
this is really futuristic.
We were funded by NASA
with the NASA Innovative Advanced Concepts Project.
Okay.
And this is a program that only funds really crazy ideas,
like 10 years down the road.
Yeah, high risk.
I'm familiar with them.
It's great.
And in fact, that wasn't always there.
I mean, I think people had to lobby for that.
And I don't mean literally lobby,
but just describe why it's so valuable
and to fund a crazy idea, because sometimes they'll come true.
And the person who does it has to be a little crazy themselves.
And that's okay, too.
Yeah.
And sometimes things don't work.
And I guess that's fine.
At least what they want to do, they want to fund.
So they are a wonderful people and program.
So we were funded with these guys.
And all that to say that we are in the very early stages
and we are getting great research
and really promising results,
but it's still a little bit down the road
to have this fully functional smart space
that anticipates your movements and this.
Got it.
So when are you going to have a prototype?
We do have a couple of neat soft robotic prototypes
that we have been characterizing, but just on a table, not on a human.
That would be the next stage.
Okay, when can I try one on?
Well, I mean, if we get more funded,
I try one on?
Well, I mean, if we get more funded,
we were planning to do
a glove prototype.
So we can implement all this.
You know, we need to start small
and such,
but sort of integrate
all these technologies
that we're talking about.
And I guess I never told you
the third one.
So we have the robotic um layer the
self-heating membrane on the outside and then embedded in the self-heating membrane the idea
is to have optoelectronic sensors that are um display visually pressure of movement or are able
to to enhance your interaction with the environment.
Because with these bulky gloves,
you can't feel anything.
It's really hard to do things with your hands or even with the rest of your body.
Maybe you have portions in your body
that are stretching too much
and the cell pilling membrane is going to break.
Well, you want to know about it
and we can put sensors all over that helps you
with that. Right, and sensors today
are very small compared to the old days.
So you can be sensing everything you need,
right? Right, absolutely.
Pressure, stress, everything.
That's good.
Okay, so you're saying
I can come by next week and I can try
on a suit? Right, yeah.
I heard you say that, I thought.
Come to the lab and we can try you around.
And once again, whenever you come to LA,
you can try on my design and it's... Your new design, yes, yes, man.
I'm just going to say, does the MIT Cornell one
have a little bit of elastic that joins the two gloves together
so you can't lose them?
I don't think so.
Oh, I see.
It goes through your jacket.
That would be funny.
Yeah, like for little children.
Yeah, it's smart.
It's got their name sewn into the back.
I've thought of everything.
You have, by the way, with your questions and answers,
you've covered a bunch of the Patreon questions
that have come in, like Jesse Desmond from Alaska
was asking about having visual data within the helmet and voice
commands. Nice.
So it sounds like that is something you're implementing
very much so.
Loads of people, I think I'd
be doing them a disservice if I didn't push you further
about this self-healing thing
because... It'd be good if you could mention their
names too. Yeah, absolutely.
Anthony Shainer from
Plymouth, Alejandro
Drorinosso,
one of the people who's asked about this,
and
I hope
there are other people as well.
I'll throw in the extra names in a second, but
they all want to know basically how this
self-healing works,
whether nanotechnology is involved.
Oh, Tom Lindelus also wants to know,
I read it's supposed to have an outer layer
of self-healing material
and heard about it being used in things like rotor blades,
but yet to understand what this material actually is.
What does self-healing mean for material
and how does it work?
And what are its limitations?
Ask Alejandro.
So Anna, I think everyone wants to know
about this self-healing material,
but your co-researcher is the expert in that, correct?
Yes, yes, he's the expert.
Okay, so my sense is if anyone is not an expert in the self-healing material, it's just magic.
Well, I would say it's a little bit of magic to me as well.
But it's really great.
And the work that we have been able to do,
he has been able to do in his lab.
We had, you know, it's a little piece like this,
this big of self-healing material
with a sensor, optoelectronic sensor embedded on it.
And you can get a knife and cut through it.
So you're going to cut the membrane
and also the optoelectronic sensor on it.
So you can see that the signal is just going away.
And then pretty much two minutes later,
you get all this signal back up to 80%.
And if you wait 24 hours,
the signal was completely back up to 100%.
Like I said, it's magic.
So the office-y clock.
Yeah, yeah, yeah.
Any sufficiently advanced technology
is indistinguishable from magic.
Okay.
So to everyone but Anna and her colleagues,
it's magic.
We'll take that.
We'll take magic, Anna.
We're fine.
So is this an ingredient that you can tell us what, I mean, is it a substance we've seen or encountered or not?
Yeah, I think you need to know the right formulation and be able to know how to put it together and then make it in the lab. And it's what we were able to do.
The next steps will be to really figure it out if this is going to work in extreme temperatures
or extreme vacuums.
Oh, yes.
Oh, my gosh.
That's another thing we don't know yet.
And I have to emphasize there,
when we build space vehicles,
it's not good enough just to work in the lab.
You got to shake it and bake it and heat it and cool it
and all the
lubricants have to work
under all those conditions and the
metals can't expand too much or too little.
I mean, yeah, you can't
emphasize that too much
about testing it in actual
in real
cases.
Case studies, real conditions.
I've just recently been binging on the Isaac Asimov story foundations now streaming.
And a big part of it, it's just in the background, there are people you can infuse your body
with nanobots and they know how to heal an injury for you.
And so, because they just work their magic,
they're like healing nanobots.
And so I think that's why, Matt,
that person asked about nanobots,
whether it's a nano thing going on. There's definitely been a couple of questions, yeah,
about that, whether it can sort of fix people as well.
Right, right, okay.
There's a really interesting question
that comes in from Ruhan Perichery from the Bay Area. He says,
Is there anything we are sacrificing to make this suit so light?
I find it incredible we're able to
cram all the tech from the old spacesuits into this new
smaller model, but were there any features
cut during the process?
Wait, wait. I have to interact.
Interject. I must interject.
Smaller was my edition, by the way.
Sorry.
It was yours? Okay.
So 100 years ago,
the radio was a piece of furniture in your living room.
Yeah.
Okay.
And now it is an uninteresting addition to your smartphone.
So I refuse to believe that you made things smaller but somehow lost effectiveness.
So Anna, I will not believe you
if you say, well, 10 things we couldn't do
because we made it littler.
So tell me, where are we on this?
Yeah, I wonder if the question goes
more towards a different spacesuit concept,
which is called the Biosuit,
and it's about all mechanical counterpressure.
Because when I think about that, that's a very slim small space suit but the technologies that we are
developing in in the concept of a smart suit are are sort of added to the current size of these
spaces so it's not going to be smaller um but the the bio suit of this idea of mechanical counterpressure,
which is something that we are also implementing
in this smart suit, is this
idea of providing the
pressure mechanically
just with some arm
and really, really, really tight.
Like they do for fighter pilots,
right? When they go into high G turns,
something squeezes their legs to
put pressure so that the blood doesn't go someplace where you don't want it or doesn't leave your head when it shouldn't.
Right.
Is that what you mean?
Yeah.
So these are engineering solutions to the pressure problem.
It's the same concept, just putting pressure, really elevated pressure.
But for the spacesuit, you need to get up to 4.3 PSI, remember?
So that's a lot of pressure.
And that's another concept
that has been out there for a while.
And actually Dr. Damon Newman,
my former advisor,
she has been the one pushing that idea,
which is like literally get rid of all the gas
and all the bulkiness
and all the problem with mobility.
And then just put this
super tight garment that actually
looks really good. Going back to your
question about, we want this
to look good and to look, you know.
And
that's another concept that is out there
and I don't think we are ready
to do that much
pressure in
an equal way in your entire body. We don't know how to do that much pressure in an equal way in your entire body.
We don't know how to do it yet.
It's like the concept is great,
we just don't know how to do it.
Okay.
So we're borrowing some of that concept
a little bit in the sense like,
remember that exoskeleton,
soft exoskeleton layer
that we're trying to do?
So that soft exoskeleton layer that we are trying to do. So that soft exoskeleton layer can
also provide some mechanical
counterpressure to help
a little bit with that.
We are not
looking for replacing
the entire gas of
this spaceship with just mechanical pressure.
We can add a little bit of
mechanical pressure so we can
get a little bit less
of gas pressure
and help with mobility too.
That's another trade-off
that we are trying.
Okay.
And by the way,
any good engineering project
will always have trade-offs.
I mean, that's part of it.
How to become clever as an engineer
is figure out how to minimize
the trade-off,
but you're always giving up something.
So Matt, just a couple more minutes left.
You got some fast ones there?
I'll chuck in two quickies.
And I apologize to the people that we haven't...
There's so many really great questions
that came in this week.
James Smith from Indianapolis says,
I wonder if the smart suit
has any other utilization out of space.
Could a football player or swimmer, for example,
take components from your invention
and use them in their suits
to gather any physical or outside data
to use to their advantage? I love it. I love it. Cool. Yeah. So any use of a Nexus Skeleton that can help you
with human movement or human motion, it's a great application for this, a great spin-off for this.
And for data gathering, I mean, if you have your sensors in a football helmet,
and then I can measure by the end of the game how much impulse or how much, you know, acceleration your head goes through.
That's got to be very useful.
Yeah.
So my, and actually I would mention this, remind me, my colleague, Professor Shepard,
he is spinning up some of that technology also for sport applications.
I didn't mention that.
Okay, good.
So it is happening. It is happening. I would have thought also that stuff would have had uses. I didn't mention that. Okay, good. So it is happening.
It is happening. I would have thought also that stuff would have had
uses for people with disabilities as well
down on Earth.
Oh, interesting. On that same note,
Nicholas Lenson says in Scott Kelly's
book, Endurance, he mentions the hassle
it is for an astronaut who has to wear
glasses when they do a spacewalk.
Contact lenses weren't an option, so he had to glue his
glasses on his head in one of his spacewalks to prevent them from
falling. Are you taking visual impairments
into account in the smart suit? How would
that work?
Oh, that's a great question.
I haven't thought much
about it, but that's correct.
And astronauts experience a lot
of visual changes in
space, and that's another area of research
that I'm interested in.
But yeah, no, that's a great comment.
I actually take it as a good idea
for future implementations, for sure.
Cool.
You know, you don't think about it.
If you're wearing glasses inside of a space helmet
and the glasses fall off,
there's nothing you can do.
They're stuck on your chin.
Yeah, I mean, there's a lot that none of us have thought of
that I'm glad somebody out there is on top of the situation, Anna.
Guys, we got to call it quits there,
but this has been fun and enlightening
and very hopeful for what the future of space might be like.
And I presume that you were describing the good-looking spacesuit.
It can't make you look better
than you otherwise would without the spacesuit.
So, I'm just presuming that, right?
We'll get rid of my middle-aged man belly.
Is the design so well?
You feel like vertical stripes,
that's all it needs, just some...
Oh, just some.
Okay.
Anna, it's been a delight to have you.
And Matt, good to have you as always on StarTalk.
Lovely being here.
Excellent.
I'm Neil deGrasse Tyson, your personal astrophysicist.
As always, keep looking up.