Planetary Radio: Space Exploration, Astronomy and Science - 2024 NASA Innovative Advanced Concepts Symposium: Part 2 - Stellar imaging and looking for life while mining water on Mars
Episode Date: September 25, 2024We return to the 2024 NASA Innovative Advanced Concepts (NIAC) Symposium for part two of our coverage. Astronaut and NIAC external council member Mae Jemison honors Lou Friedman, the co-founder of The... Planetary Society, for his contributions to the space community and the NIAC program. Then Kenneth Carpenter from NASA's Goddard Space Flight Center and his colleagues pitch their plan for an Artemis-enabled Stellar Imager. Steven Benner from the Foundation for Applied Molecular Evolution and his team tell us about their plan for an add-on to large-scale water mining operations on Mars to screen for introduced and alien life. We close out with Bruce Betts, chief scientist of The Planetary Society, in What's Up, as we celebrate LightSail 2 being announced as one of the winners of this year's Gizmodo Science Fair. Discover more at: https://www.planetary.org/planetary-radio/2024-niac-part-2See omnystudio.com/listener for privacy information.
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We're returning to the NASA Innovative Advanced Concepts Symposium for a dive into stellar
imaging and the search for potential life in the waters of Mars, 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.
Last week we visited the 2024 NASA Innovative Advanced Concepts, or NIAC, Symposium in Pasadena,
California.
We learned more about the program and heard from two NIAC fellows and their teams about
technologies that could help us send swarms of laser sails to the nearest star system
or put humans in hibernation states for interplanetary travel.
Today we're returning to the symposium to meet two more teams.
Kenneth Carpenter from NASA's Goddard Space Flight Center
and his colleagues will pitch their plan
for an Artemis-enabled stellar imager.
Then Stephen Benner from the Foundation
for Applied Molecular Evolution and his team
will tell us about their plan for a system
that we could add on to large-scale
water mining operations on Mars
that could help us screen for introduced or alien life.
But first, astronaut and NIAC external council member Mae Jemison honors Lou Friedman. He's one of the co-founders of the Planetary Society and his contributions to the space community
and the NIAC program absolutely deserve an award. We'll close out with Bruce Betts,
our chief scientist, to celebrate a new achievement for our LightSail 2 mission in What's Up.
Bruce Betts, our chief scientist, to celebrate a new achievement for our light sail 2 mission in What's Up.
Our crowdfunded solar sailing spacecraft, RIP LightSail, is one of the winners of this
year's Gizmodo Science Fair.
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 our place within it.
Before we get into today's show, I want to give everyone a heads up that in a
week on October 2nd, 2024, there will be an annular eclipse in South America.
During an annular eclipse, the moon is centered in front of the Sun but doesn't
completely cover it, so it leaves a ring of sunlight that's visible around the Moon's edges. This upcoming annular eclipse is going to be visible from the southern
tips of Argentina and Chile and some of the surrounding islands. I'll also leave some
resources for observing that on this episode page. I particularly encourage people that are in the
path of that annular eclipse to try to look at the shadows under trees. It's one of the coolest
things ever. Happy observing to all of our South American friends. This
is my second year hosting the webcast for the NIAC Symposium and it was a
blast. There were so many great projects that choosing which ones to feature on
these two episodes has been really challenging. The NIAC program's
imaginative and future shaping projects are based on scientific and engineering
principles.
Not all of them succeed, but the ones that do have the potential to seriously advance
space science and exploration.
This year's NIACFEL has proposed a wide-ranging swath of ideas, from Mars planes to new Tritium
micro-powered sensors, and even wraps for spacecraft propellant depots that use electroluminescence
to help us save fuel on the way to Mars.
I'll leave a link to the entire conference webcast on this episode page of Planetary Radio just in case you want to watch.
I'll also be inviting some of the other NIAC fellows onto the show in the future to talk about their work.
Part of what makes the NIAC program shine is its external council, experts and science communicators that help shape the program and
support the Nyack Fellows as they turn their science fiction dreams into reality. Dr. Louis
Friedman just marked his last year on the external council. I've had the honor of meeting him a few
times over the years. Along with Carl Sagan and Bruce Murray, Lou is one of the co-founders of
the Planetary Society. We're just one year short of celebrating our 45th anniversary,
and selfishly, I know that my life would be utterly different
if Lou and his colleagues hadn't founded
the Planetary Society.
Together, they created the world's largest
and most effective space advocacy organization,
and I could not be more grateful.
Dr. Mae Jemison took to the stage
to honor Lou Friedman's contributions
to the NIAC community.
Mae was the first African-American woman in space, and along with Lou and the other NIAC
external council members, she's been helping to shape the NIAC program for years.
Thank you all, and I am really excited to be here, and there is nothing that could keep
me from coming to acknowledge Lou Friedman.
What I should tell you is I did write some things down
because I want to make sure I don't forget anything, Lou.
It's written on paper from the Alexandria Museum in Egypt.
So that's how important you are to me,
is that I would use my paper from that museum.
But I want to start off by just saying,
and just a little bit more on biography for Lou,
Dr. Lou Friedman is an astronautics engineer, which sometimes I forget because he's so knowledgeable
about everything.
I think he's an astrophysicist, an astronomer, even sometimes that he hangs around in the
life sciences.
But he was a co-founder of the Planetary Society, as you heard, served as an executive director.
At JPL, he was part of the Advanced Planetary Studies and Post Viking Mars programs, Mariner
and Venus, Mercury, the Planetary Grand Tour with Voyager, Haley's Comet, reconnaissance
missions, Arundhava missions. So all of these things I bring out
because of the depth of knowledge and associations
and connections that he brings to NIAC and everything
that he does.
Now, I want to talk about Lou just from my perspective,
because it's just so easy.
There's so many things that he brings to the table.
People from organizations, from governments, individuals
go to him for advice and counsel.
And so I don't recall when I first met him.
I know it had to be when I was in the astronaut corps,
but I don't actually remember.
I just know that I always knew about Lou Friedman
and you can count on him to be there.
And I remember now my first reintroduction
was during a DARPA workshop looking at interstellar flight.
And having been invited to Tiburon,
being part of this group, I was there, Lou was there,
and it just felt like, oh, home week,
because Lou has never been afraid of interstellar.
Where sometimes people sort of would back off from Interstellar, Lou was never afraid
to live there on the edge, including writing a book about star sailing, solar cells, and
the Interstellar flight in 1988, when I first became an astronaut.
And I bring that up because also he can talk you into doing anything, including me going
to Italy to replace him at a conference and talk about sun diver maneuvers and solar cells
and getting to interstellar.
I bring that up because that's not my specialty.
But I would do that and it turned out to be very interesting, a great thing to do. But he also put together a Keck workshop
that was about science and technologies
to study in the interstellar medium.
And what was interesting about this is that when I, again,
sort of a co-conspirator, he helped pull me into it,
and can I help work on it?
But what was interesting about it
is there were all these people in the room
and everybody was looking at doing large, big old probes
and whether or not we can actually get there
and could NASA fund it.
And this is 2014 and nobody really wants
to talk about interstellar.
So that's where a lot of the swarm stuff came out
because Mason Peck was there.
There were the issues with small, you know, the small chip satellites.
And so Lou grabbed a group of people and pulled them over to the side and we're gonna talk about doing smaller satellites, right?
Our smaller probes.
And so the whole idea of swarming came swarming out of that meeting with this small group of people who were led by Lou.
And I bring all of that up because he's
talked about gravitational lenses, asteroid grappling,
all of those things that bring us to the edge.
But that's the kind of person he is who is provocative, who
would allow you to bring forward, and for me,
always someone who is incredibly important to the work
that we do and to NIAC-Bain here over 13 years.
And this award, can I talk about it, the Lightning Award?
I'm not sure where it got the name, but what I want to say that it's for me, it would be
lighting the path.
And taking to paraphrasing Michelle Paradise yesterday, the showrunner from Star Trek. I think it's lighting the edge
and what Lou has always done is to live on the edge of imagination and pull us
along with him. Lou, it's a great award. It's wonderful to have known you and to be
a part of your world.
I really appreciate this. Normally I'd make a 45 minute speech, but I'm a little choked up after that and I thank
you very much.
It's been a great honor and great pleasure to work with NIAC for I guess more than a
decade now and to be part of this. The one thing I'll say is that both at the Planetary Society
and with NIAC, the joy I had is working
with really terrific people, working with smart people.
And it's not just the NIAC External Council,
it's been the involvement with all of the fellows
over all of these years.
You get a lot out of that. And that's where
all the imagination and creativity comes from. So thank you.
Congratulations, Lou. An award well deserved. On the second day of the symposium, I spoke
with Dr. Kenneth Carpenter from NASA's Goddard Space Flight Center and his team. Their team's
NIAC project is the Artemis-enabled Stellar Imager, or EASY.
Kenneth and his team are hoping that the Artemis program is going to allow humanity to construct
a large-scale optical imaging interferometer on the Moon.
It would specialize in high-resolution imaging at visible and ultraviolet wavelengths
to resolve the surfaces of stars, accretion disks, and potentially even the surface features
and weather patterns of nearby exoplanets.
Right here I have a group with us.
First we'll start with Ken Carpenter from NASA Goddard.
Your project is an Artemis-enabled stellar imager.
Good, you got it.
How do you pronounce that acronym?
We use E-Z, although it's not really an easy project but that's
the way the letters worked out so we're stuck with it. Well see now I'll be able
to remember it right? And thankfully you brought other members of your team could
you please introduce yourself to everyone online? Hi I'm Dr. Joy Arau I am a
NSF program director and a NASA astrophysicist and I'm co-managing the
study with Ken and leading the science team.
All right.
And hi, I'm Dr. Sarah Peacock.
I'm a research scientist also at NASA Goddard
and co-managing the project with these two standing next to me.
So your proposal is that you want
to build this long baseline interferometer on the moon.
And that is enabled by the Artemis program.
Think the stars, humanity is going back to the moon.
We're going to be able to do this kind of science. But why would you want to put an instrument
like this on the moon as opposed to say putting an interferometer in space that
could do similar science? We actually have studied the in-space version
previously and that seemed at the time the obvious way to go but that was
without any existing infrastructure on the surface of the Moon. Now with the prospects of very good possibly supportive infrastructure
there and astronauts nearby, we thought it was time to take a look at, well how
does it compare if we've done on the Moon? Is it easier, harder, cheaper, more
expensive? And it's looking now that it's very competitive. We think there
are certain advantages to being on a solid surface. When you're trying to move
mirrors around and get everything in phase,
there's nothing to push against in space.
So if you move a mirror, you've got to put jets shooting the other way on the surface of the Moon.
You've got the Moon there to push against.
So that's easier and we don't have to do the precision formation flying
that we have to do with multiple spacecraft that are in free space.
You can do it either way, but it's looking now if Artemis is there and has the ability to support us at some level
for deploying the instrument or for maintaining it that that could tip it in
the direction of wanting to go to the lunar surface. Plus that could increase
the longevity of something like this. It kills me inside that we have all these
wonderful observatories out there that are either you know losing funding or losing fuel or just losing their ability to maneuver because they've been out there so long.
I'm so sorry, Hubble, that you're going through this.
But this means that we can actually take this approach and keep revamping this kind of interferometer.
But in order to do it, you're gonna need to build quite a large thing. And as with our exploration of the moon,
we're gonna have to do it kind of one step at a time, one phase at a time. So can you take
us through a little bit of your idea of the timeline and how you would put this
thing together on the moon? I think one advantage of being in this situation is
we can build it up a bit at a time. The overall design in the end would have
something like 30 separate mirrors scattered in an ellipse
that has maybe a kilometer in diameter along the long axis.
But we don't have to start building all 30.
We start with maybe seven elements, have them deployed, collecting the light from the target,
sending it to the central hub, which combines them and helps us create an image.
You could then later on have another launch, another landing
of the moon that deployed another seven elements and get up to 15. And then you could you know do
the same thing until you get up to 30. And even at a modest number of seven you can do really good
science. But when you get up to 30 you get to a point where you can get almost instantaneous
photographs at very high resolution on the sky.
When you've only got seven elements, you have to take data, move them around,
take data, move them around again before you can get a really good image.
So that's why we want to go eventually to the larger number.
But you can do some really spectacular high resolution imaging,
even with a modest number of mirror elements to start with.
Yeah, I'm thinking about the wild success of the Event Horizon
telescope and the imaging of black holes,
or getting as close as we can with that.
Imagine what we could do in this case.
You're talking specifically about visual light, part
of the spectrum, correct?
Or are you going to be branching into other parts as well?
So we are aiming for both optical,
so visual part of the electromagnetic spectrum,
but also ultraviolet.
So the advantage also in that case of being on the moon, so in space, is that we don't
have the Earth atmosphere, and so we can observe actually in the ultraviolet, which is by the
way where Apple observes now, but we will be able with interferometry to have actually
very ultra high resolution images of the surface of stars,
eventually the interaction between stars and exoplanets of
active galactic nuclei and many other stellar and space phenomena.
And being able to observe in the ultraviolet gives us access to very hot, much hotter plasmas than you see if you just look in the optical.
Yeah, it'd be really interesting to be able to actually see these kinds of solar storm features on other stars and compare them to our own system.
And of course the interaction between our sun and our world dictates a lot of whether
or not it's habitable.
If you can do both that kind of science and potentially image actual worlds, the combination
of those two things could be very powerful. Do you think that this is going to have enough capability to
actually send us images of other exoplanets? I mean we really hope in the
ideal scenario one of the cool phenomenon that we know that happens in
other planets is if you have a world Jupiter like world close to the star it
can have an evaporating atmosphere off the back and the way that we detect that is in the ultraviolet.
So as long as we can get high enough sensitivity,
we might be able to actually see the tail of this planet
atmosphere trailing off behind the planet.
So that would be really cool to see.
So what we want to observe with EZ
is the interaction between the planet and their parent star
in these exoplanetary systems.
Yeah, so we would hope to be able to characterize the impact of the central star
on surrounding exoplanets. I don't think with this instrument we'll be able to
image the actual exoplanets. That's going to require a larger interferometer, maybe an
interferometer made up of smaller interferometers to eventually get to that point. But if we can
characterize the systems, look at the atmosphere of surrounding planets,
like Sarah's talked about, we get a long way along the path to the eventual Holy Grail,
which is imaging the surfaces of exoplanets instead of other stars.
All right.
I mean, this is the beginning of a much larger set of technologies that we're hoping to go
for in the future.
But what kind of long baseline are we talking like here? How wide across are you hoping this thing is going to be?
We're aiming for a kilometer as the maximum outer diameter for the moment. Of course,
there's nothing aside from lunar terrain that might prevent us from going to larger baselines
if we need it. But if you go to larger and larger baselines, you'd like a few more mirrors
added in so you don't get too sparse, too sparse an array going through there. And we have the ability, the optical
elements are on rovers so we can move things in and out. So if we have a very large target on the
sky, we can pull everything in. If we have a very small target, then we can expand the baselines,
you know, anywhere from 500 meters to one, two, you know, or more kilometers
until we run into the lunar mountains and that might cause some issue.
But still way easier than trying to accomplish something like that on Earth.
I mean, we've got all these trees in the way, all these people and animals on the Moon,
it might be a little easier to rove your light source or your telescopes around.
I should say there are working interferometers on the Earth and we're using them to inspire
how to do this in space.
But you have other problems that are caused by the 24-hour night-day cycle, which limit
the length of observations.
You have problems caused by the atmosphere distorting the incoming wave fronts that make
it hard to do some of this stuff.
So we can do it in most cases better in space once we get the material up there and install, that's a little
tricky. But we think we know how to do it. And the study has been completely instrumental. The
funding from NIAC has really enabled us to make huge gains in designing this and making sure it's
a realistic, incredible project. How far along are you in actually designing this thing? Well,
we have a baseline design, and I think our goal was to come up with something that
we knew we could do.
And there's a bunch of enhancements that we would like to put in, but we wanted to show
we had a basic design that we could build now if we were given the funding and go ahead.
We've done that, I think.
A few technologies need a little further maturation, but I think we could do that.
And then we would like to investigate some items that would make it better,
like being able to use a remote power source so the array doesn't have to have self-contained
power or huge batteries, you know, put a power station up on a nearby peak,
maybe put a nuclear generator on the far side of a hill to send power down,
and then you can operate
more during the lunar night. Right now we have a conflict between wanting to
observe in dark if we can but also wanting to generate power which you know
we prefer to be in the daylight so if we can get the power remotely then we can
observe more continuously through the entire day night cycle. And then dealing
with the temperature changes and all the other ways that impacts your instruments
there's so much to consider there.
Thankfully we have the Artemis program to help us enable this kind of thing, but
have you been in contact with any of the members of the Artemis team trying to
pitch this for the future? Because you're gonna need an incredible amount of
human power to put this thing actually on the ground in the lunar regolith. We
have a person at Goddard that works with Artemis. It's basically his job nowadays to be our liaison to them.
So we're at the stage of trying to make a credible concept first
before we go too far with that.
We would appreciate having their support,
either from the astronauts or from robots,
maybe controlled from there.
And I think they would like to be supporting something that's
obviously productive like this and enabling you know great new things to be
done. Something I'm really passionate about more recently just because we're
near solar maximum right now is understanding the cycles of sunspots on
these other stars. Obviously we're beginning to understand it better on our
own star using many of the other instruments that are out there but what
could we learn about other stars beyond our own
and this kind of cycle over time?
Sure, so different stars have different cycles, right?
So with such kind of interferometer
that has a super high angular resolution,
we can really look in detail not only at a star,
but really through the atmosphere,
so studying, for example example where the dust form,
but also looking directly, imaging their surfaces
and so observing something like in sunlight stars,
the sunspots or the conductive motion on the surface of the stars
or even more with astrosystemology,
we can observe really the cycle of different
type of stars. So this will be really revolutionary in this respect. This has
never been there before to observe the plage and other phenomena on stars.
I think one thing that's maybe familiar to the audience here is that the Sun has
an 11-year solar cycle and the spots tend to start at high latitudes and move
down to where the equator as the cycle progresses. The ability to image the
surface of stars like this allows us to see that kind of cycle on other stars.
We don't know if the butterfly diagram, the butterfly pattern on the Sun is
common on other stars or not. So resolving the surfaces allow us to study
that and we hope by comparing other stars and how their activity cycles go with that of the Sun that we
can get a better model of magnetic activity and the internal dynamo of the
Sun and that might allow us to actually get a better predictive model for what
the next solar cycle, the next stellar cycle might be in terms of strength, in
terms of starting time. Right now we still have a lot of uncertainty when we
try to predict what the next solar cycle is going to be.
This might be the data we need for the theorists
to finally nail it.
And therefore, by interference, also trying
to understand what's the weather cycle on nearby stars.
And so, for example, so on planet hosting stars,
so to understand what they call the exo-weathers.
Yeah, I think another really important thing is
understanding something called the transit light source
effect.
So we know that there are spots in other stars.
And right now, when we try to detect different molecules
in different exoplanet atmospheres,
we have to disentangle the stellar atmosphere
from the planet atmosphere.
And we detect water.
And we don't know if it's coming from a star spot or from the planet atmosphere, and we detect water, and we don't know if it's coming from a star spot
or from the planet atmosphere.
And with EZ, where we can actually
resolve the surface of the star and see the different spots
that will really help us understand and interpret what
we're actually measuring, is this molecule from the planet
or is it from the star?
I'd be curious to know, too, if that kind of cycle over time
is different on different sized stars based
on their metallicity and all kinds of stuff there's so so many mysteries left
there to unpack so this could be very powerful. You also mentioned not just
looking at stars and their interactions with their worlds but you mentioned
specifically active galactic nuclei that that is you know a totally different
distance scale we're talking about here as opposed to something within our own
galaxy in our own worlds far beyond doing that kind of science. Is there
anything you'd have to do differently in order to enable that kind of science at
a distance? Well we're lucky that the active galactic nuclei, even though
they're much further away, are much larger scale. So on the sky their angular
extent is actually very similar to the size of a disk of a star. That's what
allows us to do this. We don't have to necessarily change the array diameter
or anything to probe that. We might not get down and resolve the very details of
the central engine, but we ought to be able to see the overall geometry of it.
There's a conflict in the community about the geometry of the central engine
and the inclination and how that changes in different kinds of HEN, active
galactic nuclei
that we look at.
So again, being able to go into the ultraviolet, seeing hot material, there's going to be a
lot of hot material around the center of AGM, which are basically a black hole, you know,
creating material.
So it's exciting that, you know, once you get a capability like this, which is basically
going from like your standard definition TV to a high definition TV, you're going to learn
a whole bunch of new things,
some of which you'll anticipate,
like looking at the center of AGNs
and the surface of stars,
and a whole bunch of things
that maybe you never even thought of are gonna be revealed.
One thing that I do wanna mention is that
looking at this higher resolution,
you see things move across the sky in almost real time.
I mean, we're used to spending, you know,
waiting years or decades between observations
to map the motion of a star across the sky.
We have such high resolution here.
You'll see stars like Proxima Centauri and the like
actually move while you're observing,
which means that all of a sudden the fixed stars
become moving targets in some cases.
It's like, okay, I guess we're a moving target observatory.
I combine that with all that Gaia data. It'd be really intense. But thank you so much for working on this and for joining us today. Thank you.
After my conversation with them, one of their team members sent me this adorable image of their
daughter watching the live stream back at home. Talk about heartwarming. That made my whole symposium.
the livestream back at home. Talk about heartwarming, that made my whole symposium.
Later that day, I spoke with Dr. Steven Benner
from the Foundation for Applied Molecular Evolution.
I'm very passionate about learning
about the potential habitability
of worlds in our solar system, particularly Mars.
His team's project centers on developing
an agnostic life finder, or ALF,
that we can integrate into future
Martian water mining operations.
The ALF system would analyze the water extracted from Martian ice to look for evidence of life.
Here I have Stephen Benner from the Foundation for Applied Molecular Evolution. Thanks for
joining me. And you brought another member of your team. Could you introduce yourself
please?
I am Jan Szpaczek.
And what institution do you work with? The same one? Yes, same one. And also at the AlphaMars, which is a nonprofit we started to
promote the idea to search for life on Mars. And search for life on Mars is
among one of the greatest questions humanity has ever asked ourselves. Trying
to figure out whether or not there's life off of Earth is a complex question,
but if we could find another place, another genesis of life in our own solar
system, that would mean so much for the prevalence of life across the
universe. Your project, essentially what it does is you want to add an add-on onto massive
water mining systems on Mars that we're already going to have to build in order to sustain
permanent human settlements on Mars. For people who aren't aware of the water reserves that
we've potentially found on Mars, could you speak a little bit about where we
might be sourcing that water from? Okay, so on Mars, basically 40 degrees north
towards the pole or 50 degrees south latitude to the south pole, you have a
large deposits of subsurface ice which was deposited during the last high
obliquity period. That's when Mars was tilted more towards the Sun
and now it's more upright. So the ice is now redeposited more towards the polar caps
but still we have subsurface ice under less than meter of over layer regolith
and that's a target for both ISRU for future human learning missions and for
astrobiology. So and you mentioned those large missions, yes that's a primary
target but before they send those huge ISRU missions to mine large quantities
of water they will likely send smaller prospecting missions trying to see if
the ASRU actually works. One such mission is by Honeybee Robotics.
It's a red water red well, or Roderick as well,
where you just make a hole, pump hot water down into the ice,
melt more ice, pump it out.
And so on one of those missions we would like to collaborate.
If that ice were on Earth, as all the astrobiologists would tell you,
it would be infected with bacteria that are living or dormant and readily
revival. So when you're Columbus setting out to sail the Atlantic Ocean, you're
doing exploration, it actually helps to believe that you will find something
that you're looking for. So one of the most important parts of this mission is
to persuade the community there's actually a good chance of finding life
in that ice. And the very statement that we know
from astrobiology studies here on Earth that if that ice were here on Earth it
would be infected as a good motivation to get people to go look at the ice on
Mars. Speaking about community, astrobiological community is rather
convinced that life on Mars is likely. We need to convince the rest of the
community which does not understand our advances in understanding extremophiles on Earth.
So there are a lot of overlaps between extremophiles here on Earth and
conditions which are on Mars. So it would not be a big surprise if we find Martians.
And you know in 2019, five years ago, Michael Meyer, who's NASA headquarters
responsible for a Mars portfolio,
got a bunch of astrobiologists together in Carlsbad and they wrote a report saying, where
you go look, caves, this ice that we're talking about, where, extend life, that is life living
today, not fossil life, which is what these rovers are looking for three billion years
ago, but why life living today is likely to be found.
And that's all in a manifesto.
You can go read it in many, many pages with lots and lots of co-authors.
So as Jan is saying, the astrobiology community is quite well convinced that there's something
to go look for.
That's the motivation to look.
But we have to persuade the rest of the community not only to look because it's likely to be
there, but also because we know how to find it, especially if it's sparse, if it's scarce in that ice and that's what of course this particular
project, NIAC project instrument is building to concentrate sparse life in
that kind of ice. We'll be right back after the short break. Greetings, Bill and I
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Thank you.
Well we already know there are some very mysterious detections, potentially of
methane, that we can't fully explain, right? We had that recent sample that Perseverance collected, the Chayavus
fall sample, that shows potential evidence of ancient, ancient maybe possible biomarkers.
We won't know until we get Mars samples back. Please advocate for that mission so
we can get those samples back and test them. But there's so much potential
here and even if it wasn't the case that there wasn't actually
excellent life on Mars currently, you're just asking to add a system onto existing water
systems.
I would like to know that because if there is some stuff in there that we couldn't detect
otherwise and then you accidentally drink it, come on, there might be some problems
there.
So we persuaded you, that's great.
Well, but it's more than that.
You had 1976 Viking.
There were three life detection experiments. All of them were positive, but because of a
misinterpreted gas chromatography mass spectrometry system, the life detection
positive results were dismissed. I mean, my only contribution to this field was in
1999 we wrote a paper a quarter century ago pointing out that the GC mass spec
results were misinterpreted as implying at the surface of Mars the soil of Mars was
self-sterilizing and therefore unable to hold life. Now we know from rovers that
there is a lot of organic material in that soil and so we know that the GC
mass spec was misinterpreted. We have never bothered to go back and look again at those
Viking 1976 results to understand exactly what kind of life they are indicating is present in
the accessible soil on Mars. But I'm a great believer of going back and thinking about those
data one more time because that's also positive evidence for there being the potential of existing
life, metabolizing life, living today.
Lynn Rothschild was talking about the perchlorates in the Martian regolith, essentially.
We didn't even really know that was a thing back then.
There was so much we didn't know about Mars when we went and did those experiments.
So it is absolutely worth going back to check all of that out.
But in the meantime, you're proposing this project to try to detect not just
exon life that could be in the water, but also potentially life that we might
introduce into the water systems on accident with our presence. And this
entire idea is based off of this agnostic life-finding system, particularly
the polyelectrolyte theory of the gene. I'm not a geneticist so could you please explain a little bit
more about the complexities of this? I guess I better do it. Sure. So synthetic
biologists for 40 years now have been trying to synthesize molecules like DNA
but that are different from DNA that can still support evolution. So the question
is for Darwinian evolution what kinds of molecules are necessary to enable Darwinian evolution. Some of
those molecules must be able to store information and store information in an
evolvable form. So lots of molecules, maybe 300 different examples of
different kinds of DNA have been made in the laboratory to ask the question, what structures must a molecule
have to be able to support the Darwinian, the needs, the informational needs of Darwinian
evolution and what has come out of that from a study of what does work and what doesn't
work is the statement that what does work is a polyelectrolyte.
Now you're familiar with electrolytes, you drink them in your Gatorade to recover salt, but it means that the molecules have to have a
repeating charge in their backbone. So DNA that you have is a repeating
negative charge and all the phosphates that are linking together the DNA
molecules. It's possible also to have repeating charges that are positive,
which are held together. Synthetic biologists have made those as well.
So we have a large number, several hundred examples of what molecules might support dark
weighting evolution. The ones that do have a repeating charge, the ones that do not have
a repeating charge. So the argument is that if you go to Vulcan or go to Kronos and speak
to a Klingon, their DNA may have a
different structure than yours. It may have a different natural history from
your DNA but it will have a repeating charge in the backbone. And that's the
polyelectrolyte theory of the gene. I mean this is a great foundation for
trying to understand life and other worlds because how would we even know if
it was life when we detected it, right? That is a complex question and it sounds
like you're broaching on that subject.
Yeah, so you just mentioned methane
and other potential, maybe, biosignatures.
The problem with biosignatures,
which may be produced by life, like methane,
and there's a problem that they can be produced
abiotically, right, through serpentization.
So, unless we search for some unambiguous biosignatures,
we will need to send multiple missions,
maybe think about it for a couple decades,
but we don't have the time.
I think we can all agree that it's good idea
to find life on Mars or determine if there's life on Mars
before we send humans there.
But it's very surprising that NASA so far
has not been doing it.
Right, if you took all the instruments
we have currently on Mars, send them here on a carpet, they
would probably not find life living in this carpet.
So that's rather surprising and I do think that many people know about this.
So that's what we are trying to fix.
Right, so the distinction of course is that what Jahn's instrument is looking for are
molecules that are necessary to enable evolution. What almost all these other biosignatures are molecules that are the
products of evolution but the problem is they can also be the products of not
evolution. They can be the projects of non-biological processes and so amino
acids, a biological signature, right? We can go try to find amino acids on Mars.
Well, meteorites contain amino acids, right? So how do try to find amino acids on Mars. Well, meteorites contain amino
acids, right? So how do you know what you're looking at is biological or not?
But a polyelectrolyte, a long polymer with a repeating charge built from a
limited set of size and shape regular building blocks is something that does
not emerge spontaneously easily. It will not be sustained unless there's a
Darwinian context for it, and be sustained unless there's a Darwinian context for it.
And it's absolutely necessary to support Darwinian evolution.
And that's why it's agnostic as a life detection system.
But how would you differentiate between these kinds of molecules
and all the other stuff that might be already in that water? How does your system work?
So our system works, it's a stack of membranes with different pore sizes.
On the ends of the stacks you have electrodes.
So you are pulling from a stream of liquid, which is the Martian water,
you are pulling molecules which have charged.
So cations towards cathode, anions towards anode, and then we have size separation.
Okay, so the first membrane, let's pass molecules which are small enough to pass through the membrane but they are
larger than inorganic ions so they are retained in those channels so we are
both desulting and concentrating larger poly electrolytes and we are excluding
mineral particles which might be suspended in the liquid so that's how
you distinguish between the majority of the molecules and particles will be uncharged and from
the smaller part which is charged small inorganic ions are going to be filtered
all the way through while the larger polymers will be captured in those
channels where we are concentrating in from. That way we will capture maybe mixture of molecules,
but subsequent analysis will have much easier time
sorting through those than if you analyze everything.
The DNA, with the repeating negative charge,
will go towards the positive charge electrode,
but it's a polyelectrolyte, so it will go through,
it's still dissolved, it's a molecule,
so it will go through the first membrane.
But because it's poly, it's big, so it won't go through the second membrane.
The electrolyte, chloride, for example, this small ion, which you drink and gatorate,
will go through the second membrane, and so in the first channel, after you do the separation,
you've got all the genetic polyelectrolytes concentrated in that flow.
Now you sit there, collect it, and then you can say, okay, let's analyze it, see whether it has other properties that are expected for molecules that are necessary to support Darwinian evolution.
And at this point, are you just collecting them or have you already proposed a system for analyzing them to actually see what's going on there. Yes, so we proposed systems. We proposed to use biological
Minion for analysis of DNA. That's for the introduced life we'll bring with us.
Minion is, well, it's a tiny pore through which you are threading DNA and you have a protein
which is specific to DNA which is allowing pulling the DNA through.
That would not work for alien DNA which the protein wouldn't recognize so for that we
will need a second device which is again a tiny hole from which you are threading the
poly electrolyte but because you don't have that protein that nicely pulls it through
you have harder time to recognize what
exactly it is but you can tell for example the shape of the molecule you
are pulling through so if you have long molecules with uniform building blocks
in that molecule you can guess that it's likely not a mineral particle or
something like that so that's a biological min- on nanopore, then solid-stain nanopore, then we will
would like to employ mass spectrometry and a classic chemical analysis,
chromatographies and stuff like that. So mass spectrometers have already flown to
Mars. The Minion, I don't think the nanopores have ever flown to Mars at
this point, but they will be very, they're much more simple instruments than the
ones that you need to do mass spectrometry.
And see, that's good.
There's ways of figuring out whether or not
it's Earth life or Mars life.
Most of the proposals I've heard are just
looking at chirality to try to take a guess at it.
It sounds like there's more complicated ways that you could
actually do this kind of science.
And I'm thinking, too, that this could give us a good indicator
of how much basically contamination from our planet
we've introduced to the systems on accident as a total byproduct of this kind of research.
So this will allow us to monitor how much we introduce and if it's in that rhodovel, over time the
bioloath we introduce should decrease. If it's
increasing we have a problem because now the earth bacteria is living on Mars and proliferating which we would not like
to have, right? But we can monitor this and also to monitor life we brought of
course use of PCR is the most straightforward genomic method how to
analyze life we know but for the
unknown life you need those nanopores and mass spectrometers. So this is the
polymerase chain reaction PCR. This has far-reaching consequences not just for
Mars but I'm thinking about all of our other worlds potentially ocean worlds
out there in our solar system that we're also hoping might find life. The samples
that we got from Cassini flying through those jets coming out of Enceladus were
absolutely next level and if we could apply this kind of science to it that
could produce answers that we really need. Well that's right so we're on what's
called an interdisciplinary center for astrobiology research with Brent
Christner trying to implement this general kind of question for the ices of
Europa as
well.
Now your problem with flying through Cassini is that these architectures that go through
that plume are encountering that plume at 11 kilometers per second, 30 kilometers per
second, which will tend to toast almost all the molecules that are present in there.
But you're absolutely right.
We have plenty of water to look at and we don't have a clear understanding of what's
necessary for life to originate
or to be transmitted from one place where it is originated
to another place.
And so we are going to be looking at every body of water
sooner or later with the instrument
that Jan is building.
This is so exciting and answers so many questions for me.
I'm so glad that someone is working on this.
I know many people have wanted to do some kind of extant life search on Mars, but it's underfunded honestly. We're hoping in the future
we're gonna be able to send these missions, but if we know that we're gonna try to have that moon to Mars pipeline that is
foundationally built on the Artemis program
thinking about this now before we take that stepping stone and incorporating it into our plans
This is exactly the moment to be doing this kind of research. Yeah I agree with this point
and there is not much time. The astrobiology missions and the grand
proposals, hoops you need to jump through, it takes about two decades to get from
the initial idea to execution on Mars. We might not have the time for search for
life on the extent life. So we
need to speed things up somehow. I don't know if it's possible to do it with NASA,
we'll try, we'll see. I was on a Mars mission architecture definition team for
sample return in 1999. That's a quarter of a century ago. Now Mike Meyer had his
team together in Carlsbad five years ago and now we're
down to the last, well we don't know, in two new launch cycles, maybe three, four
and six years, the Chinese could very well be sending people to Mars and that
is now actually a short time relative to the mission design process by which
grants are funded in the United States. So we're very much interested in
contacting anybody
who's going to Mars, Elon Musk, anybody who's interested, that we would like to put on the
preliminary robotic mission that's going to Mars first, because you want to set up robotic
water mining before you send people there who are going to depend on that water mining.
You want to make sure it works first. And we have a low cost add-on to actually resolve the question,
is there life there?
Definitely yes, or to a limit of detection, if the answer is no.
So Stephen just suggested the geopolitical angle
of viewing things.
We now know that China is doing the sample return,
likely from subsurface ice on Mars in 2028, likely bringing analyzing
the samples in 2031. So it might be that the Chinese Space Agency is going to be the first
to find life on Mars, which is I would say a big milestone in the new space race. So
that's another thing to consider. Yeah, no matter what nation discovers life on Mars,
it is going to be the greatest moment
in human history.
Not like we're sure it's going to happen, but if it does, I'm just glad everyone's doing
it.
That said, let's start a race so we can get funding in order to get there and get the
science done.
I'm still looking forward to going back to the symposium next year.
Thank you so much to everyone that helped make it happen and to the NIAC program for letting me be
a part of it. And as a bonus, Matt Kaplan, who's the creator of Planetary Radio and I did a special
event after hours at NIAC. We talked with some of the NIAC leadership and a few of the fellows that
you haven't heard from in these episodes. We share that whole thing on our YouTube channel,
and I'll also leave a link for that on this episode page for Planetary Radio. And now it's time for What's Up with Bruce Betts. We're
celebrating our light sail 2 mission. It was just announced as one of the winners of the 2024
Gizmodo Science Fair. The Planetary Society's light sail program demonstrated that solar sailing is a
viable means for propulsion for small satellites. With the help of 50,000 people from around the world, we developed and launched the first fully
crowdfunded space mission in history. Solar sails use sunlight instead of rocket fuel for
propulsion. They're one of the few technologies that could be used for interstellar travel,
as we saw in last week's episode with the team that proposed laser sailing to Proxima Centauri.
in last week's episode with the team that proposed laser sailing to Proxima Centauri.
Our light sail 2 spacecraft was in space from June 2019 to November 2022, when it ultimately descended into the Earth's atmosphere and ended its mission. Hey, Bruce. Hey, Sarah. It's NIAC
part 2. The revenge. The revenge of NIAC. There were some good projects this year and I was really excited to see that there were
so many solar sailing or laser sailing projects.
I mean, I know people are constantly asking us whether or not we're going to do a light
sail three.
So it's nice that some other organizations are like galaxy braining this.
I'm sorry, what?
Galaxy braining.
Yeah.
Okay.
Oh, you kids and your modern lingo.
Do you get like frequent emails about people are like, let's sail to Proxima Centauri
with a bunch of laser sails?
Like I've heard that from so many people.
Yeah, no, they just haven't looked into all the complexities that have to be solved to even pretend to do that.
And it's a huge long list and that goes along with a huge, huge, huge cost if you ever even could do it.
I mean, I think someday you can, but I mean, you have everything from...
I mean, just pick any topic, the communications issue alone.
How the heck do you communicate from four light years away with a little tiny spacecraft Just pick any topic, the communications issue alone.
How the heck do you communicate from four light years away
with a little tiny spacecraft with very limited power?
How do you slow down?
How do you stick a camera on there?
How do you survive for that long in space?
How do you communicate as you're going?
On and on and on.
So it's a beautiful idea.
Someday, indeed, we may get there with solar sails of one kind or another.
It's currently probably the most realistic, but that is still really far away.
So I would temper the expectations at least, but I'm certainly for looking into it in a
realistic manner because eventually we need to do all these things to get to that point,
but there's a long way.
So light sail too is kind of humanity learning to crawl in this technology and that, I don't
know what that is.
That's like a formula one race of the future.
Yeah.
It's going to be really tricky to get out there, but if it happens, it will in part
be because of light sail.
I also met another one of the NIAC fellows, Mahmouda Sultana,
who I believe was from NASA Ames, and they're trying to figure out how they can straight up
encode things like spectrometers using quantum dot technology directly into the sails so they can
send sails out to Uranus and Neptune and places like that. I mean, that would be very helpful if
we could literally produce instruments as flat and light as the sail itself so that we don't have to actually send a whole instrument on one of these objects.
Clearly, even trying to get a CubeSat or three CubeSats stuck together as we do a light sail
was a challenge.
Pete Slauson Obviously, that would be great. And there are groups who have worked on,
have used things. The first solar sail to successfully fly in space
was the Japanese Ikaros.
And Ikaros, they actually put not that on there,
but they had panels that they could change
from dark to light and then try to use that
as their method of using attitude control and steering.
And they weren't able to steer a lot
because they were spinning,
intentionally spinning spacecraft.
So their turning control was very limited,
say compared to ours,
but they had some very clever technology
they were working on building into the sail.
And yes, I didn't know about the quantum dot technology,
but there are a lot of, well, I don't know about a lot,
but there's certainly groups trying to do that
and integrate those things together that someday hopefully will be good stuff.
I'm so impressed with humans. And I'm impressed with, I mean, forgive me for saying it, but
I'm impressed with you and with the light sail team. I mean, between us and JAXA and
all of the collaborations that have been going on, it feels like we've really kind of opened
up the door to a whole new light sailing age. And a lot of these ideas are
really far flung. It's going to take a while for us to reach them. But man, it feels like
it changed a whole lot.
Pete Slauson I didn't really hear much after you said you
were impressed with me.
Lauren Larkin After that just white noise and fruits feeding
into the clouds.
Pete Slauson Blah, blah, blah. After that, just white noise and fruits fading into the clouds.
That is not that part.
I just couldn't resist that.
I mean, that's why we're very proud of what we've done and feel we've made a technology
jump forward and also just raise the profile of solar sailing and the legitimacy of solar
sailing and sailing in space, making it easier for others to propose
it and actually get funding.
Those were our goals by demonstrating controlled solar sailing with a small spacecraft so people
can actually do this with CubeSats.
It's not easy, but you can do it.
And we did it.
And so that's great.
And we're looking for these other entities and the ones with deep pockets such as, oh,
I don't know, NASA to go out there and do it.
And in fact, they are doing it.
They had one mission that failed before it ever got to sail, but now ACS3 is in orbit,
who we worked with and exchanged information and provided our data to them.
And now ACS3 has deployed its sail that's about more than twice the area of our sail and with some fancy
booms technology that they're testing out and they got it deployed, they have not started
last I knew trying to do solar sailing. They're evaluating their deployment still.
Still, that's huge. I'm hoping I can bring someone from their team onto the show in the
future to talk about that. But in the meantime, I also did learn that Lightsail has been awarded once more, we're
one of the winners in the Gizmodo Science Fair.
What is the Gizmodo Science Fair?
It's Gizmodo, the Gizmodo website news source for all things tech, science, etc., etc.
And this is the second year they've done it, they hold
their so-called science fair and basically evaluate a number of different projects that
they think are spiffy. They use better words than that because they write for a living.
So here it is. The Gizmodo Science Fair celebrates the research process and all the challenges
that come with it. This year's winners were selected for their creativity and perseverance
in tackling an important problem or moving a field forward. And so they interviewed us
a few months ago as they picked us out. There was no application. And then we were just
made aware that they had picked their winners. And by the time this show airs, it will be on Gizmodo's website.
And I'm sure we'll put something up soon about it as well.
So we're honored to receive this.
And it's nice that people are still taking a look at what we're doing.
I know the technical side of the world is.
It's nice to think that others have not forgotten us.
And so it's, it's good stuff.
Goes along with some of our previous awards as long as I'm bragging for the Planetary Society, with Time Magazine and Popular Science
voting as one of the innovations of the year in the first year of the mission 2019.
And there was that Smithsonian exhibit that we got to put together. That was really cool.
Indeed. We were in the Futurism exhibit. We were in the Smithsonian for the full duration of
that and gave them a quarter scale model of the sail and then a full scale model of the
spacecraft, the loaf of bread size core of the spacecraft. Well, yes, that was great. We love it.
We love it. We love it.
It's great that they just interviewed you because I had this mental image of you making
one of those science fair boards all about light sail.
Oh, God. Yeah, this was the first science fair I've ever been on a team that won, but
don't tell anyone. I have very traumatic memories from elementary school when I didn't really
understand what science was. But I will have you know that my first ever science fair entry, which was like
second grade, I drew a map of orbits of the planets of the solar system. So I
didn't have a good experiment, but I definitely was already thinking planets.
That's so cute. I wish I had a picture of that. So, yeah. Gizmodo. Rock on.
Pretty sweet. Thanks, Gizmodo.
Alright, what's our random space fact this week?
Oh, yeah.
Uh...
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Oh my gosh, that's coming up so quick.
During the course of its planned mission, it will receive nearly 3,000 times the radiation
dose that would be lethal for humans.
There you go.
I'm so sorry, little Clipper.
It's not human.
It's not even alive.
It's kind of important to remember that.
But it gives you an idea of how nasty that environment is.
And that's with them going out and then coming into near Europe.
That gets worse as you get closer to Jupiter, which is why IO missions pretty much do a
flyby here and there and then don't mess around in close because Jupiter's massive
magnetic field is whipping around all sorts of charged particles and you got a really
nasty particle radiation environment.
So anyway, that's why we have robotic spacecraft.
They can go anywhere.
Well, okay, not anywhere, but they're also robots.
So it's sad in a different way when they reach end of mission.
That's true.
To go where no human could ever go ever.
I'm surprised Juno is still operating.
I'm really impressed with these missions.
Yeah, no, it's impressive what they do.
And a lot of missions last a long time once they get out there, but it's particularly
impressive for something like Juno diving into the radiation so frequently.
Oh, man. October is going to be intense. I'm really wishing all the luck to the Europa
Clipper team and also to the Hera team trying to send that mission out to see what we did
to didimus and Doraemorphus with that DART mission.
Launchtober!
Really though, we need t-shirts.
Well I'll see you next week for more talk of Europa Clipper, I'm sure.
Of course there will be, and in the meantime everybody go out there, look up the night
sky and think about the radiation you're not receiving by hanging out on Europa.
Thank you and good night.
We've reached the end of this week's episode of Planetary Radio, but we'll be back next week to look forward to the launch of the European Space Agency's HERA mission. Remember NASA's double asteroid redirection test that smashed into dimorphis? ESA's going back to observe the aftermath.
And hold on to your space hats
because October is going to be a ridiculously cool month for space launches. Between Hera
and Europa Clipper, we're all going to be on the edge of our seats and hopefully having
many happy moments to toast to the success of all the teams around the world that have
done so much great work to help us understand our star system and its worlds.
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