Planetary Radio: Space Exploration, Astronomy and Science - Europa in reflection: A compilation of two decades
Episode Date: September 4, 2024With less than two months to go until the highly anticipated launch of NASA's Europa Clipper mission, we take a look back at over twenty years of Planetary Radio episodes about Jupiter's most intrigui...ng moon. You'll hear from Elizabeth 'Zibi' Turtle, planetary scientist at Johns Hopkins Applied Physics Lab, Bob Pappalardo, project scientist for Europa Clipper, and many more, as we reflect on all of the dreams and science it took to make the upcoming mission a reality. Then, Bruce Betts, our chief scientist, joins in for What's Up as host Sarah Al-Ahmed gears up for next week's NASA Innovative Advanced Concepts symposium. Discover more at: https://www.planetary.org/planetary-radio/2024-europa-in-reflectionSee omnystudio.com/listener for privacy information.
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It's time for a Europa Fest, this week on Planetary Radio.
I'm Sarah Alahmed of the Planetary Society, with more of the human adventure across our
solar system and beyond.
We're now just two months away from the highly anticipated launch of NASA's Europa Clipper
mission.
This week we're going to take a look back at over 20 years of Planetary Radio episodes about Europa,
as we cheer on the scientists who have worked so hard to bring us to this moment.
That means you'll hear from me, but also Planetary Radio's creator and previous host, Matt Kaplan.
Then Bruce Betts, our chief scientist, will join me for What's Up as I gear up for my trip to next week's NASA Innovative Advanced Concept Symposium.
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.
Jupiter's icy moon Europa has captivated humanity for hundreds of years.
Interest in Europa dates back to 1610, when Italian astronomer Galileo Galilei aimed his
homemade telescope at Jupiter and discovered the now famous Galilean moons, Io, Europa,
Ganymede, and Callisto.
Centuries later, the Voyager spacecrafts image Europa during their flybys of the Jovian system
in 1979.
Both Voyager 1 and Voyager 2 captured detailed images of that moon, revealing its smooth,
icy surface.
Those images were the ones that sparked the interest in Europa as a potentially habitable
world for the subsurface ocean.
Since then, we've had several missions to the Jovian system, each of them providing even more insights into Jupiter and its moons. In 1989, NASA launched the
Galileo spacecraft. Data from that mission to Jupiter indicated even more strongly that
beneath Europa's icy surface might lie a subsurface ocean containing more water than
we have in all of Earth's oceans combined. Then, in 2011, NASA's Juno mission blasted off to explore
Jupiter in more detail. Along the way, it grabbed a bunch of images of Europa and other
moons. Juno is still out there in the Jovian system exploring to this day. And of course,
in 2023, the European Space Agency's Jupiter Icy Moons Explorer, or JUS, mission took off
for Jupiter. That mission is still cruising its way through space on its way to Jupiter now.
While all of these missions have been groundbreaking
in their own right, a dedicated Europa mission
has been the dream of planetary scientists for decades.
And now, finally, after years of advocacy
from scientists and space enthusiasts alike,
the Europa Clipper mission will soon take off
from Florida in October, on a journey
to investigate one of the most intriguing moons humanity has ever encountered.
Europa Clipper is managed by Caltech near our headquarters in Pasadena, California.
NASA's Jet Propulsion Laboratory leads the development of Europa Clipper in partnership
with the Johns Hopkins Applied Physics Lab.
APL designed the main spacecraft with the help of JPL,
Goddard Space Flight Center, Marshall Space Flight Center,
and the Langley Research Center.
It's been a big team effort.
The Europa Clipper engineers and technicians deployed
and tested the spacecraft's giant solar arrays
in late August, 2024.
The moment is almost here.
To mark this momentous occasion,
today we're going to
take a look back at over 20 years of planetary radio interviews about Europa.
From the days when a dedicated Europa mission was just a twinkle in the eye of
a planetary scientist, to the moment that Bob Popolardo, project scientist for
Europa Clipper, visited Planetary Society headquarters to show off the
beautiful message that humanity would be sending on that mission, inscribed on the vault plate that will protect the mission's instruments
as it orbits Jupiter.
We begin over two decades ago in 2003, when Elizabeth or Zibi Turtle joined a fledgling
planetary radio to talk about the ices of Europa. At the time, she was a senior research
associate in the Department of Planetary Sciences at the Lunar and Planetary Lab at the University of Arizona. She went on to become a planetary
scientist at Johns Hopkins Applied Physics Lab and became the principal investigator
of the upcoming Dragonfly mission to Saturn's moon Titan. At the time of this interview,
we weren't entirely sure yet that Europa had a subsurface ocean.
Yes, there may in fact be liquid water under the ice shell on Europa.
There are several lines of evidence that suggest that.
I guess we've certainly determined because we've had good observations that Europa seems
to be encased in this layer of ice.
But for one thing, how do we have any idea how thick that ice is and how do we have any
idea that it is water and that there's liquid water underneath it?
We know from spectroscopic observations that it's water ice and we know how much water
ice, water and ice there is, liquid and solid there is from gravity measurements actually
that the Galileo spacecraft made as it flew by Europa.
So we know there's an outer layer of solid and liquid water that's somewhere between
80 and 170 kilometers thick.
Unfortunately the gravity can't distinguish between the phases of the water, whether that's
liquid or solid, but there are other lines of evidence such as the surface geology and
the use of the surface that have suggested that there's still liquid water underlying the ice.
When we simulated the later stages of the impact cratering process,
what we found is that as the impact crater opens up, the ice isn't breached.
However, often as the impact crater collapses back, the water does breach the surface if the ice is thin enough.
the water does breach the surface if the ice is thin enough. And our results indicate that if the ice thickness, if the thickness of the ice is comparable to the diameter of the
initial crater cavity that's opened up, then the ice can be breached by water as the crater
collapses late in the impact cratering process. Now when I say late in the impact cratering
process, I should specify that that's only a few minutes. Impact cratering is a very rapid process, so late is on the order of a couple of minutes. And
what this means is that in order for craters of the morphology we observe on Europa to
form, the ice really needs to be at least 10 to 15 kilometers thick.
Oh, I see. Well, that strikes me as a finding in and of itself that was going to be useful in research
elsewhere in the solar system, perhaps beyond some day.
But also that conclusion that the ice may be quite a bit thicker than some people were
hoping must come as a disappointment to some folks who would love to drill down through
that ice, get into that ocean, and find out what might be in there.
Yes, it certainly makes it harder to get to the liquid water
that we believe is beneath the ice.
However, what we looked at on Europa
is only a few impact craters.
There only are a few impact craters.
And those can only constrain the ice thickness
at the locations and the times at which they formed.
There may well be other places on Europa
where the ice is thinner.
So it doesn't rule out the possibility
that one could get through to a water layer in some locations on
Europa. I see. And rule that out. So we should not assume that that layer of ice is the same thickness all the way around.
It may not be. Yeah.
Shortly after Zippy joined us on the show, NASA planetary scientist Chris McKay came on.
Chris is a senior scientist for NASA Ames Research Center.
He speculated about whether Europa, among other worlds in our solar system, could potentially
harbor life.
Mars didn't have life, or if the life there was just the same as us, the next place to
find an alien life form, a second genesis something different, would be, I think, Europa.
There in the ocean that we think exists underneath the icy surface, there may be life there.
And the chances of that life sharing a common origin with Earth slash Mars maybe is much
less.
And so if there was a second Genesis and we don't find it on Mars, maybe we'll find it
on Europa.
And so much harder to reach for tourists.
Much harder to reach.
It's a long way out there.
There's dangers, radiation fields from Jupiter.
It's a much harder search on Europa.
Then when you reach there, you might find stuff on the surface or you might have to
drill down.
It's just a much more daunting task and much harder to imagine a direct role of humans
in the search for life on Europa than on Mars. Now we go forward a few years to 2006. Bob Pappalardo,
project scientist for Europa Clipper, had only just begun his time working at NASA's
Ship Propulsion Laboratory as a principal scientist. He hoped very much that someday
a dedicated mission to Europa would become a reality, but I don't know if he had any clue at the time that he
would still be working on it almost 20 years later.
Europa is an incredible place for so many reasons, but the chief one is
astrobiology. A critical question in understanding our place in the universe
is whether life is common or rare, as the
planetary society is well aware.
Europa we're pretty sure, say 90% sure or so, that there's an ocean beneath the surface
of Europe, the icy surface.
There's a chance that Europa has the chemical energy necessary for life. And so Europa is one of the key targets in understanding whether there might be other
life in our solar system today, Mars of course being the other one.
Now we have a large program that's sending spacecraft to Mars every couple of years,
but as of the moment we don't have a follow-up mission to Europa.
We're working on that.
The other thing besides the astrobiology, we can talk more about that, is the geophysics.
We don't get Europa yet.
It's about the most complicated planetary situation that you could think of.
It's ice, which has very complicated rheology, the way it flows and behaves.
It's tidal interactions with Jupiter.
It has resonances with its neighboring moons,
Io and Ganymede.
It's a complex system to understand that complexity,
that geophysical complexity,
is what also makes it astrobiologically interesting because there is tidal heating which maintains
liquid water below and activity which may pump chemical energy into the water
and potentially allow for life there. Well we were all extremely curious about
that that big ocean. The surface itself is so fascinating,
it's so rich in features that I guess
are still puzzling folks like you.
Exactly, again, we don't get it,
and that's what keeps it interesting.
Maybe I shouldn't say, my favorite moon,
if you ask me, is probably Ganymede, okay?
Europa's neighbor.
We get Ganymede somewhat.
We can look at Earth and look at Ganymede and go,
okay, I kind of recognize how these types of features
might form by extension of the icy crust
over more mobile and flowing ice beneath.
But we look at Europa and we say,
what the heck is that, right?
It keeps us investigating.
Europa's covered by these double ridges
like a plate of spaghetti.
They're overlapping one another.
But you look at any individual one, and it's not just one ridge, but it's a pair of ridges like a plate of spaghetti. They're overlapping one another. But you look at any individual one,
and it's not just one ridge,
but it's a pair of ridges traveling together
across the surface.
So what's made this sequence of ridges cross-cutting
one another, and especially traveling across the surface
in pairs like this?
Well, one idea is that the surface has been pushed upward somehow, like a tree
root growing beneath an asphalt sidewalk and warping it upward into a double ridge. But
then, you know, there aren't trees growing there, so what's underneath pushing up on
the surface? And there are various models that involve the combination of water or warm
ice to push up the surface, and perhaps even to squeeze out on the surface.
And then the other main type of feature on the surface is this model terrain, these freckles and spots.
Some of the larger ones show evidence that ice plates have been mobile and moved around the surface
and translated and rotated and then there are competing models for that.
Again, we don't really
understand what's going on. One model says the surface has literally melted
from below, that there's enough heat that some of these features are the result of
melting, complete melting of the ice crust. Another model and the one I tend
to favor is that the ice shell is thick enough that it actually convects,
overturns like a lava lamp,
where warm ice below is tidally heated,
comes up toward the surface, colder ice sinks down.
You usually don't think of solids flowing,
but lava lamp is a nice analogy,
or the inside of our planet, right?
The Earth is convected.
Sure, yeah.
With warm pockets of rock moving up,
and colder ones sinking down.
So those are some of the models, but again, at meetings and through the scientific literature,
there are debates going on.
How did these things form?
What does this mean for the interior?
What does it mean for the plausibility of life or, for that matter, for where we might
find life if we were to send a lander to Europa.
I'm assuming that one of the reasons you're happy to be at JPL now
is because it may be a really good place for you to
try and push this mission to Europa that
you and so many people would like to see. Well, JPL has
has been taking the lead in looking at the feasibility
of such missions and scenarios
for mission to Europa.
Now the first mission that we've been talking about, dedicated Europa mission, would be
an orbiter.
There is a possibility of having a small lander attached, but the key scientific questions
we want to get at, the first step, is to do an orbiter.
Sort of do for Europa what Mars global surveyor did for Mars
We don't have a good idea of the topography of Europa to confirm whether there's an ocean and really characterize the ice shell and
And the presumed ocean beneath we need gravity and altimetry
measuring the distance the surface and
Through measuring the gravity field understand how Europa is warping tidally as it moves in its eccentric orbit around Jupiter.
By measuring the topography and altimetry as Europa orbits, we can characterize that
ice shell and the ocean.
So you really have to be in orbit around Europa, which is not an easy thing to do, right?
You're in the huge gravity well of
Jupiter. So it takes a lot of propellant, that takes a lot of mass, and so it's a difficult
mission.
Lauren Henry Torrance Johnson was the project scientist
for the Galileo mission to Jupiter, but he also worked on the Voyager mission team. While
the Voyagers gave us a beautiful glimpse of Europa, Galileo gave us our first close-ups. In 2006, Torrance
joined us to discuss the state of our technology and whether or not a Europa mission was going
to be viable in the upcoming years.
The most recent major survey of the entire planetary science community recommended a
Europa orbiter as the highest priority new flagship mission, and they established a number
of goals for it, which are fairly obvious if you've been interested in Europa.
You want to find out whether that ocean is really there.
You want to find out how deep beneath the ice it is.
You want to characterize what's going on.
You want to see whether the water has been coming up to the surface recently.
You want to take the type of data that would prepare you for the next stage of exploration
just like we're doing on Mars now.
Okay, bottom line is with enough mass for shielding, the Europa mission can be done
now with current technology that will last long enough to really do an exciting mission
at Jupiter and at Europa.
Torentz Johnson had been speaking at NASA Ames Research Center that day.
Shortly after, Chris McKay discussed what Europa could mean for comparative astrobiology. At the time, Chris was a researcher at
Aims and a member of the Astrobiology Institute.
Why is life on other worlds interesting? What are we hoping to find on Europa?
What we're hoping to find on Europa is the possibility that there's a separate
type of life there, the second genesis of life. That's what astrobiology would really like to find.
Life not as we know it,
life different from the life we have on Earth.
And why is that interesting?
Well, first, from a practical point of view,
it would allow us to do comparative biochemistry.
Everything we know about biology,
everything we know about biochemistry
is based on studying the one example we have here on Earth.
We could study it in incredible detail and not learn what we would learn by having another
example to compare it to.
So that would be important scientific information.
Also it would tell us that if in our own solar system life started twice, once on Earth and
once on Europa, then life is common in the universe.
That's really an interesting thing to know.
And I put my little editorial comment there, yay, that'd be great to know that life is
common in the universe.
We all think that it's true.
Some of us seem to have personal, private evidence that it's true.
But scientifically, we don't have any data to support the notion that life is common
in the universe.
We'd like to know that.
On Earth, life is made of carbon and lives in water. Does that mean all life everywhere in the universe has to be based
on carbon and live in liquid water? Well, maybe, maybe not. But it knows at least that
we know that that's at least a good place to start. And here in our solar system, we've
got two worlds with water. That's the logical place to look for life first. That's where
we're going. Europa is the target. So I want to ask the question, given liquid water, is it
plausible that there was an origin of life on Europa, a
separate origin?
And is there plausible ecology?
Is there something for the folks to be
eating there on Europa?
The current theory that's the most popular in the scientific
community, which is that life started as a result of chemical
reactions involving hot water and hydrogen and sulfur, just
the sort of thing that's coming out of the vents
that John Delaney's studying,
that's the most popular theory now
for the origin of life on Earth,
and that one works well for Europa.
So maybe life could have started on Europa.
We're on much better ground when we talk about
is there food to eat on Europa.
On Europa, below the ice in the ocean,
there won't be any light, there won't be any oxygen,
and there won't be any free food coming from plants at the surface.
Do we have any ecosystems on Earth that work without light and without oxygen?
Well, we know of two that work on chemical energy.
This reaction is the basis of their biology, is hydrogen plus oxygen going to methane and CO2,
and these are just the papers that report that.
So we have examples on Earth of ecosystems
that are profoundly independent of light and oxygen
and don't rely on someone else providing them with food.
So could such an ecosystem work on Europa?
Yeah, it could.
You could imagine that there's water and CO2 in the ocean.
The organisms consume that to form methane,
just like the ones in the subsurface on Earth.
And then thermal circulation, like what John's reporting
for the, on the plate spreading centers on Earth,
could process that ocean water and at temperatures
as low as 500 degrees, the hydrogen and the CO2
be recreated, completing the cycle.
This could be a plausible ecosystem for life
in the ocean on Europa.
We can point the ecosystems on Earth and say,
we have ecosystems, not just individual bugs,
but whole ecosystems that work the same way.
So if Europa has an ocean, we're pretty sure it does,
if that ocean has life,
it's gonna be hard to get to that ocean.
As Bob indicated, the ice may be 20 kilometers thick.
That's a lot of ice to dig through.
But Bob also indicated these features that, surface features that may contain material
upwelling through the ice cover.
And if so, they may contain biological material that's coming from the ocean.
Or as one lag put it, frozen fish on the surface, right?
Now we don't expect fish on the
ocean of Europa, but frozen microbial European fish, if you want to think that way.
In the meantime, while the planetary science community was advocating for a Europa mission,
scientists on Earth were already working to learn more about what our oceans could teach
us about the worlds beyond. Oceanographer John Delaney came onto our show to speak about the challenges of modeling Europa's oceans.
We still have so much more to learn about how the ocean works on this planet.
Are we anywhere near the point where we could model it in a place like Europa?
I suspect that it would be possible to develop a suite of models that would not
be in any way testable
for a number of years. But they may guide the kind of exploration programs we might
put together. I think it would probably be a very valuable effort to have a group of
very bright modelers and observationists and geochemists and at least microbiologists
thinking carefully about what the circulation
patterns of the Europa Ocean might be, because therein lies a big piece of whatever the tail
will be when we get through the ice.
There are first principles, that is, if the ocean is heated from below and it's cooled
from the top, then it's going to turn over.
If it turns over rapidly enough, then it's not going to be very stratified. In other words, it won't have strong layering of different densities.
But that's an open question, and that's a very controversial issue about the dynamics
of what the Europa Ocean might be. There may be other factors that are involved in the
patterns of circulation. It's possible that the Coriolis effect enters into
the global circulation of the Eropa Ocean and it's possible that it actually enters
into rising plumes that may be coming off of erupting underwater volcanoes. There are
an entire host of possible model components that I think could be put together by the
right folks, of which I am not one. And the hope is 10 to 20 years from now,
we will be able to export much of what we have learned
in this robotic remote sensing in situ scientific approach
that we will be taking into how our own ocean works.
And I hope some of that will flow over
into a Europa program,
which I am desperately hoping will happen before I die.
Flash forward seven years.
Alyssa Rodin, a NASA postdoctoral program fellow for NASA's Goddard Space Flight Center at the time,
was studying Jupiter's moon Europa from a distance.
She and her colleagues were working on projects to help everyday people help us study Europa. Matt Kaplan asked her why Europa should be our target,
rather than going to other tantalizing moons,
like Saturn's moon Enceladus.
Why Europa first? Or why Europa next?
That's really the question.
And I think Enceladus is a large part of the answer to that question.
So we went off to the Saturnian system,
the Cassini mission, which has just been stellar,
and we found this tiny little body.
I mean, if you drew it on a map of Earth, it would fit over the British Isle.
I mean, it's a tiny little moon.
It's active.
It has these jets of water and ice erupting from the South Pole.
All the models, the theoretical models said this would never happen, could
never happen. Such a small body would have cooled off too quickly, it shouldn't have
a lot of heat, it shouldn't be active, it should be frozen. And now we know so much
more. So while Cassini is still there getting data on Enceladus, those of us who are used
to thinking about Europa are going, wait, this could be happening on Europa too. You
know, we just don't have the data to know is the surface active, are there, wait, this could be happening on Europa too. You know, we just don't have the data to know,
is the surface active?
Are there eruptions?
What's going on in the ice shell?
There's so much we don't know.
So I wouldn't pose it as why Europa
at the expense of Enceladus,
but more Enceladus has given us even more motivation
to go back and see what is really going on at Europa.
I suppose another reason to push for Europa as the next step is that there is this mission,
which has come up on this program before, the Europa Clipper.
What will it do for us if it can get the support that it desperately needs?
It's going to do a lot for us.
It's going to do some very basic things to begin with, right?
We're actually going to get image coverage, global image coverage.
That to me is huge right off the bat, being able to see all the different surfaces at
very high resolution and in three dimensions. We're going to be able to get topography.
We're going to be able to get stereo images. Another hallmark of this mission concept is
ice penetrating radar, which is really exciting, especially for people interested in habitability.
The idea is that the radar is transparent to the ice,
but it wouldn't be transparent to water.
So if you had subsurface lakes,
which have been proposed as part of these chaotic trains
that we see manifested on the surface,
if there really are lakes in the ice shell of Europa,
the radar should be able to ping down and find those, and we would be able to start mapping out the plumbing of Europa's ice shell of Europa, the radar should be able to ping down and find those, and
we will be able to start mapping out the plumbing of Europa's ice shell. To
clarify, this is based on this hypothesis that not all of the water, not all the
liquid water, is deep deep down in the ocean, but some of it may be quite a bit
higher, quite a bit closer to the surface in these lakes that you mentioned.
Exactly. So shallow subsurface lakes could
potentially exist on Europa in the ice shell. Those might be really great places to find
organisms if life exists there. That's really exciting.
Finally, it's 2015 and we've just gotten the good news about Europa Clipper. The mission is going
forward. Matt Kaplan caught up with Bob Pappalardo, the mission's project scientist, at JPL's ICY Worlds Day.
Bob, I get the feeling that after a long, long wait, congratulations are in order.
Thank you. I think so. This has been a wonderful day, a wonderful few hours. We've been working
on concepts for missions to explore Europa for about 15 years.
And today the NASA administrator said we're going forward to the next phase,
which seems to mean phase A, as it's called, becoming an actual mission.
And that, he said, instruments will be selected in the spring.
This spring, spring of 2015?
That's what he said.
Have we overcome, have we, have you guys overcome the big challenges?
And they are big challenges making a mission like this work.
Oh, absolutely.
One of the biggest challenges is the radiation environment at Europa.
And the concept we had been talking about was a Europa orbiter. If you're
orbiting Europa then you stay in the radiation environment for the whole
mission. So the whole mission can only be a few months long or guaranteed to be.
Instead now we're talking about a multiple flyby mission that dips into
the radiation zones as it's orbiting Jupiter, flies by Europa, dips into the
radiation zones and then out again and does that in our candidate mission scenario about 45 times and that way
build up coverage through those three years of Europa encounters. The mission
designers have been so clever and so responsive to the desires of the science
community. Science community says oh oh, that's great.
You can make flybys of Europa, but we want to see all parts of Europa.
And we want the orbits to be like this and crossing like that.
And through that iteration, we have come up with a really outstanding mission design
for covering most of Europa's surface, multiple flybys,
kind of like Cassini has been doing at Titan, right?
The Cassini spacecraft is Saturn, flies by Titan lots of times, and we're putting together
this global map of that moon.
But this mission would carry instruments to address scientific questions specifically
related to Europa's ocean and its potential habitability.
This thing we're standing next to, this mock-up, would seem to be additional evidence of how
far along this mission is.
Tell us about this.
Oh, absolutely.
So this is a mock-up of what we call the vault.
The concept comes from the Juno mission, which is headed to Jupiter and has a vault to protect
its electronics.
That is, there's a lot of shielding there.
And so we're building on that in the Europa mission concept.
So the vault would have a bunch of shielding, a bunch of metal that protects the sensitive
electronics of the spacecraft, the brains of the spacecraft.
This is kind of the skull of the spacecraft, if you like.
The most sensitive electronics would be buried the deepest
with the most shielding.
But of course the instrument sensors would be out
in the breeze, as we like to call it.
And so the instrument proposers need to worry about that.
And those instruments will then get incorporated
into the one vault as we're envisioning it now.
We'll be right back with our Europa Lookback after this short break.
Hi y'all, LeVar Burton here.
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to the explorer in your life. With the good news about Europa Clipper lighting up the imaginations of planetary scientists
all over the world, the scientific community began thinking about the next steps in the
journey.
How could we take it one step further to actually determine whether or not Europa was habitable?
In 2020, Jet Propulsion Lab astrobiologist Kevin Hand, the author of Alien Oceans, The Search for
Life in the Depths of Space, spoke with Matt about what it was going to take to actually
truly determine Europa's habitability.
Let's jump back to Jupiter and Europa.
We could spend the rest of our time just talking about the upcoming Europa Clipper mission
that so many of us are looking forward to.
But it is an orbiter, a Jupiter orbiter, and a lot of people don't realize.
What would a Europa lander be able to tell us that the Clipper probably won't be able to?
Mike Hichesky Clipper is a fantastic mission that has an incredible payload of instruments
that will map out at a global and regional scale, just about everywhere on Europa.
It'll take images, it'll take spectra and visible to infrared spectra, and it'll also
collect mass spectra as it flies by and hopefully finds plumes.
And it's got ice penetrating radar on board.
So there are many different ways in which the Clipper mission will help us better understand Europa
as a world in and of itself.
But when it comes to actually searching for signs of life, looking for biosignatures,
that's when you really need to get down to the surface and scoop up a sample and look
in detail at some material that you've collected.
And so a lander on the surface of Europa, or any ocean world for that matter, is really
the key to searching for signs of life.
And coupled with that, such a mission also provides critical ground truth to all of those
remote sensing observations that have been made. And that's really critical. Think about the Mars program. We've had lots of
orbiters that have done remote sensing around Mars, but it's really only once
you get down to the surface and really put a rover or some sort of vehicle that
can sniff around and directly analyze the geology and geochemistry, that
the full remote sensing data set all of the sudden makes a lot of sense.
So biosignatures and ground truth are the big ticket items for a lander on the surface
of Europa.
Steve McLaughlin It was looking pretty good, at least in Congress,
for a Europa lander mission to get some kind of a start a while back.
And maybe doesn't look quite as good now.
But from what you told me, when we were talking just before we started recording this conversation,
there's still an awful lot of interest in the science community in a lander.
That's right.
We were planning on having a conference about a Europa Lander or more broadly, we like to
also refer to it as an ocean worlds lander. The technology that we developed for landing on Europa can
also be used for Enceladus and Ganymede or Pluto. The first mission to land on an ocean
world, an airless ocean world, will be the template for many of the ocean worlds. This
conference, unfortunately due to a global pandemic, had to be canceled, but we were
just thrilled to see how much excitement there was in the number of people that registered
for the initial conference and the number of people that are signing up to listen to
the latest in the development of the Europa Lander mission concept.
So it really is a roller coaster when you look at the ups and downs of these mission
cycles.
And oftentimes the scientific community doesn't want to do one thing, they want to do a different
thing.
But one of the things that we're finding is that when it comes to the search for life
within these alien oceans, the microbiologists, the oceanographers, a whole new sector of the scientific community
is getting engaged with planetary science and astrobiology. And that's a really powerful
kind of scientific transition. Normally when we think about planetary science, we think
about a field full of remote sensors of people that are used to flying by worlds
and analyzing pictures captured from afar and spectra captured from afar.
Obviously, Mars has made a bit of a transition and Mars has become a real world for geologists.
Earth geologists love to work on Mars now because we've got in situ robotic capabilities.
Well, when it comes to landing on Europa or Enceladus or any of these worlds,
we're seeing a lot of excitement from the Earth oceanographic community and microbiologists and
cryospheric scientists, et cetera, because it represents this possibility of getting down to
the surface and really understanding the physics,
the chemistry, the biology, and so on and so forth.
Let's say that Europa lander that you're advocating for
lands and sure enough finds some pretty complex molecules,
organics on the surface of that moon,
that lead us to believe that something is swimming around in that
ocean down below, now moving into your speculations.
Do you believe that those oceans, if we had something that melted its way through the
ice and went down there, that would you be surprised to find that it was more than microbes?
That maybe we'd find multicellular life? Well, as you know, I love this question.
To be clear, I would be through the moon, to use an appropriate phrase, with finding
even the tiniest of microbes on or within a distant alien ocean, because such a discovery
would revolutionize our understanding of biology.
But specifically with the case of Europa, there's a really interesting dynamic going
on and that is that the surface ice of Europa is being bombarded by charged particle or
radiation from Jupiter's magnetosphere.
And make no mistake, the engineers don't like that radiation because it poses problems for
robotic vehicles.
But when it comes to the chemistry of Europa and perhaps the chemistry of Europa's ocean,
what we see spectroscopically on Europa's surface is condensed phase oxygen, O2, hydrogen
peroxide, sulfate, a bunch of compounds that are made as these
charged particles split apart water and some of the O recombines into O2 and OH combines
with OH to make H2O2, peroxide, etc.
And if some of those oxidants, if some of that oxygen makes it into the ocean below, now you might actually be charging
up that ocean with enough chemical energy to potentially give rise to multicellular
life.
All we have to do is look at the evolution of life on Earth and see that it was really
the rise of oxygen in our own atmosphere made possible by photosynthesis, by cyanobacteria,
pumping oxygen into our atmosphere.
That abundance of oxygen helped drive the evolution towards multicellular life, and
that's what drove the Cambrian explosion, which of course then led to us
and all these large creatures. Well on Europa, photosynthesis is not likely a
viable niche given that its ocean is beneath a relatively thick ice shell of
at least a few kilometers or so. But this radiation-produced oxygen might
allow for multicellular life to exist there. And it's
a lot of fun speculation, but there's enough tethers there to real data that I think it's
worth pondering.
The year is 2021. The Europa Clipper team is navigating the complexities of producing
a mission while the world grapples with the COVID-19 pandemic,
and dealing with the harsh environment that the spacecraft will encounter when it gets
to Jupiter. Mission system manager Al Kangahuala spoke about the strides that the mission had
made and the challenges that they were still working to overcome.
Europa has been a destination of high interest for decades. And many different mission architectures have been proposed for studying Europa, including
that of a dedicated orbiter.
One of the challenges is dealing with the fact that Europa is orbiting in this high
radiation environment.
Due to the strong magnetic field of Jupiter and the high energy particles trapped in it,
if you're orbiting Europa, you're in
the midst of that high radiation environment.
Your time is limited unless you brought more and more shielding.
If we were going to expend mass on the spacecraft design, we would rather put that mass into
instruments, scientific instruments.
That would be preferable to more shielding.
Teams that have studied these types of missions in the
past have struggled with it. One idea that came out was to just dip in, do your science during a
period of, let's say, a day or so around closest approach to Europa, then leave the high radiation
environment and downlink data at a more, let's say, more relaxed cadence, and then repeat after a few dozen flybys,
you can start to accrue the coverage that you would have achieved through a dedicated
orbiter anyway.
So we feel like we're getting the best of both worlds.
No pun intended.
So, let's say that Clipper on one of its passes finds some particularly interesting feature
on the surface of this moon.
A plume, let's say.
We should be so lucky.
You got to know that Bob Pappalardo and the rest of the science team are going to be pounding
on your door and saying, how soon can we get back to that?
So how soon would you be able to get back to a feature like that?
That's a great question. And that's really at the heart of the mission operations design
is working with science to understand what can we respond to quickly, what really deserves
more time to respond to. If a particular instrument encounters something interesting, like they
detect a new species on a particular flyby and want to re-optimize their sensors, the operation of their sensors
to be more receptive to particular species, we can do that.
We can support that with relatively little effort.
Our baseline design really accommodates that.
Some of our instruments have gimbals like our narrow angle camera.
What we can do is also support updating the mosaic of images that are going to be generated
from flyby to flyby. We have some ability to readjust that mosaic to respond to findings
from images that have been downlinked along the way. It won't be instantaneous, but we do intend to allow for re-optimizing those profiles.
Moving the trajectory is probably one of the items that requires the longest lead time.
We've worked with science to socialize that and show you making a change here means losing
something that you might have already pre-planned and accounted for.
So we certainly have studied astrodynamics mechanisms to help us cover new things, but
I think studying it and having a well-instrumented, in the case of a plume, having a well-instrumented,
dedicated plume flyby is something that would require more lead time to plan and work out with science.
So to me, responding to findings is part of our job. There's a spectrum of response time
constants and the plume seneer is probably one of the ones with the longest time constants.
It was 2023 and the European Space Agency was celebrating the launch of its Jupiter
icy moons explorer or JUICE mission. The mission isn't solely dedicated to Europa, but the data that it's
going to collect about Europa, Ganymede, and Callisto could someday help us better understand
the differences and similarities between the Galilean moons, many of which we think have
subsurface oceans. We're still awaiting that spacecraft's arrival at Jupiter, but it did
complete a beautiful flyby of Earth and our Moon just recently, slingshotting it ever closer to its target.
JUS project scientist Olivier Vitas shared the details about the launch and what it was going to teach us about Europa.
We are pretty sure there is liquid water at Europa, relatively sure that there is liquid water on Ganymede.
Calisto, there is a question mark, so Calisto is also quite interesting.
And the first thing to discuss when you want to discuss habitability is to really understand
the properties of liquid water. So because we don't know where it is, so at which depth,
or we have some ideas, of course, some indication, but for example, the subsurface ocean at Ganymede
could be at 100 kilometers underneath the surface, but it can be 110,
120, 150, so we need to know. It's important. We don't know exactly the depth of those oceans,
so is it 100 kilometers, 50, 80, we need to know, because we want to know the amount of water that
you have there. And also the composition, we know they are salty
because we detect them with the magnetometer. So we know they are salty. That's an interesting
piece of physics and detection, by the way. But we don't know how much salt do they have
there. And the composition is quite important to characterize liquid water. Is it an interesting
water for life, et cetera. We'll also be studying the radiation environment because it's good to
know the radiation environment. I mean, on Earth Earth we are happy to have the magnetic field, then we have less
radiation coming from the Sun. So what is the case at Europa when there is no internal magnetic
field and Europa is close to Jupiter? What is the case at Ganymede which is a bit further away,
I mean much further away, with an internal magnetic field? That's the only moon to generate own magnetic field. So very, very special. So what is the role of this magnetic field?
Does that help to protect? Not at all. How this interaction between the magnetic field
of Ganymede and the magnetic field of Jupiter. And what is the case at Callisto? The moon,
which is the much further away with the Galilean moons. So in principle, it's better for the
radiation environment
at Callisto. But at the same time, the moon is far from Jupiter, so the tidal activity
is very weak. The moon has probably not evolved since its formation. When you look at the
surface of Callisto, it's plenty of craters. So that means the surface is very young. Probably
there is not much geological activity. So is there a liquid water underneath the surface or not?
That's an interesting question.
And the finding either yes or no will be interesting.
And then you can compare the three moons.
So Europa, which is active with a possible geysers,
very interesting ocean, but close to Jupiter.
Then you have on the other hand,
you have Callisto, which is dead.
We don't know if there is an ocean.
In principle, it's not very interesting
for habitability and life, but who knows? And then you have Ganymede in between. So
a big question mark. So that will be very interesting to know more about those three
moons and then to compare them and to understand better the question of habitability and whether
around Jupiter, there is interesting place to study life. And then to study life, we
need another mission.
The data from upcoming missions like JUS and Europa Clipper are going to be very helpful. But there's still a lot that we can
learn from previous flybys. Kevin Trinh, who was a PhD
candidate at Arizona State University, was still piecing
together the information from the Galileo spacecraft in 2023.
He told us a bit about Europa's formation and how it evolved
over time.
in 2023. He told us a bit about Europa's formation and how it evolved over time.
Our idea of Europa evolving slowly is pointing out that a small moon like Europa could have formed as a cold mixture of ice, rock, and metal, or a cold mud ball, put it that way. And over time,
as we have heating from radioactive isotopes and tidal heating, we'll eventually
melt stuff and slowly convert into a layered structure.
The alternative is to assume that Europa was layered to begin with.
And that's a pretty common assumption in the literature, but it's a hard one to support
given that if we assume all of Europa's accretional energy got converted into heat, then we still
might not have enough of a temperature increase to have that layered start.
So I find it hard to argue for what's typically assumed, which is Europa started out layered.
Instead, we have to overcome these hurdles.
So while there's a lot that we don't know about Europa, we do have a good idea of how
much and what the mass and radius of Europa is, and that's going to put some constraints
on Europa's formation conditions.
What is the formation timeline that you think is most likely given the data that you've
analyzed? Europa most likely formed, I'd say,
between three to five million years
after calcium aluminum inclusions, or CAIs.
Those are the first solids to have condensed in the solar
system.
So they provide, I guess, a time reference point for us.
But it's also a physically significant one,
because the earlier we form in the solar system,
the more Alunum 26 we have.
That's a short-lived radioactive isotope.
And that contributes a lot of heating.
And it's very sensitive to our uncertainty in the formation time of Europa.
This paper proposes that Europa's oceans may have this metamorphic origin.
And I'm sure a lot of listeners are throwing back
to their early science classes about rocks,
but what would it mean if Europa's ocean
had this metamorphic origin?
To put things in context,
when I use the word metamorphic,
I mean that the ocean self formed as a result
from warming up the rocks.
The alternative is that we melt
ice directly and since water is much less dense than rock and metal, the water
should migrate to the surface and that can form the ocean. Now if you form the
ocean metamorphically, we're taking the oxygen-hydrogen that's directly bonded
to the hydrogen minerals inside of Europa's rocky interior. And at high temperatures, the hydrogen and oxygen
will be released from the rock,
and that can be combined into a fluid,
probably a super critical fluid,
depending on the pressures where the rock is dehydrating.
But this fluid is really hot, it's really reactive,
and it's low viscosity, less than water,
it's going to want to shoot up to the surface.
I haven't done modeling myself, at least not in-depth modeling, on the dynamics and timescales of how that fluid migrates from the interior to the surface.
But the ocean formation process for a metamorphic origin is going to have high temperature and pressure conditions.
So that's going to govern the rate at which chemical reactions proceed.
And that's going to be a very different physical scenario compared to forming the ocean by
melting ice and having that water percolate to the surface.
Finally, it's 2024. We're almost back at the present. Europa Clipper is just a few months
away. Scheduled to launch in October 2024 and arrive at Jupiter in 2030, the mission
team is putting on the last finishing touches on the spacecraft. Project scientist Bob Popolardo's
joy was absolutely palpable the day that he came to our headquarters in Pasadena, California.
He brought a replica of the Europa Clipper vault plate with him.
Humanity's next message, sent with all of our love to a world beyond our own.
When we were inquiring along with our communications team, might we be able to have a message on
our spacecraft, the spacecraft team came back and said, yeah, one of these
vault plates, you can have both sides. And it's about like an eight and a half by 11 piece of
paper cut diagonally with with kind of rounded corners. So that's pretty much the area we had
to work with. And we worked with our communications team to throw out ideas for what kind of messages
we might want to include there. In a lot of other cases, we've sent these messages out into space.
Voyager, as a great example, this vault plate is being compared to the golden record that we sent
out into interstellar space at this point on the Voyager spacecrafts. You know, I imagine that this
is more of a, it's kind of a message for us more than it is a message
to the Europeans or whatever extraterrestrials might find it, which kind of gives you a little
more freedom to add whatever you want to it without having to consider how would an alien
interpret this.
That's right.
Our goal is not to talk to the Europeans.
It is to talk with ourselves.
And of course, the same could be argued for
a pioneer Voyager, but yes there's a chance that it could be found someday. But really
those two are much more to educate ourselves. So okay, so here we'll go with that and say
what do we want to communicate? What do we want to talk with the public, talk with the inhabitants of our planet
in thinking about space exploration.
So we knew past spacecraft have collected signatures and said,
send your name to space.
And we thought, well, we're not any mission.
We want to do something a little more special.
Instead of just sending your name,
what if people are cosigning a message? They're essentially acknowledging this message that's going out
to Europa and being part of that. So then of course the question is, what message? Who
writes it? And for, I don't know, weeks to months, we were tossing out names and thinking about who might
be the right person to write such a message.
And then we all converged on the poet, Gloria, of the United States.
Let's see if she would agree to do it.
And our comms team reached out and gave a presentation.
And I've heard interviews with Ada Lallone who said, well, why are they telling me all this?
And then the ask came, would you write a poem for the spacecraft that's going to Europa? And
thank goodness, fortunately, she said yes. And then she's explained that, uh-oh, she said yes.
Now what?
How to write that message.
No pressure.
No pressure.
I wouldn't want to have to do that.
It means a lot to me personally that we had the poet laureate
write this beautiful poem for Europa.
My mom was first a proofreader and then a special education
teacher and through her whole life wrote poetry. So it's extra special to me that we have a
poem going to Europa.
I hope you're all as excited about the Europa Clipper mission as I am. It's taken so many
decades of hard work and dedication. Here are the words of Ada Limon, the US poet laureate, in her poem, In Praise of Mystery,
a poem for Europa.
In praise of mystery, a poem for Europa.
Arching under the night sky, inky with black expansiveness, we point to the planets we
know.
We pin quick wishes on stars.
From Earth, we read the sky as if it is an unerring book of the universe, expert and
evident. Still, there are mysteries below our sky. The whale song,
the songbird singing its call in the bow of a wind-shaken tree. We are creatures
of constant awe, curious at beauty, at leaf and blossom, at grief and pleasure, sun and shadow.
And it is not darkness that unites us, not the cold distance of space, but the offering
of water.
Each drop of rain, each rivulet, each pulse, each vein. Oh, second moon, we too are made of water,
of vast and beckoning seas.
We too are made of wonders, of great and ordinary loves,
of small, invisible worlds, of a need to call out through the dark.
October is going to be a wild month for planetary science. We've got the Europa Clipper mission
to look forward to, but also ESA's Hera mission that's going to view the aftermath of the
dark asteroid impact and NASA's escapade mission to Mars, along with a few others.
It's going to be a very exciting time. Also, personally exciting for me, next week I'm going to be hosting the webcast for NASA's Innovative Advanced Concept Symposium.
I'll chat about it with our chief scientist, Bruce Betts, up next in What's Up.
Hey, Bruce.
Hey, Sarah.
Man, it is a busy time right now. I'm preparing for NASA's Innovative Advanced Concepts Symposium.
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK,
NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, NAYAK, N I don't know. It still kind of blows my mind that I get to host NASA webcasts every once in a while.
Do you ever have that moment where you're just like, how is this my life?
Yeah, I'm having it right now.
Right.
Yeah, what are we talking?
NIAC.
Go crazy.
Matt does love his NIAC.
It's rather far future focused.
That's what's really interesting about it for me.
It's almost like space shark tank in my brain.
Since it's going to be in Pasadena this year, right near our HQ, it seems like Matt's going
to be able to come up and attend for a little while. So we'll both get to be there at the
conference. That's good. That'll be fun. Yeah. I just, I wonder what kind of projects they have
for this program that just don't make it through, right? I bet there are just hundreds of these
projects and you've probably dealt are just hundreds of these projects,
and you've probably dealt with a lot of that too,
because we have these grant programs.
Some of the wackier projects do kind of make it through
our ideation process.
Like, I mean, come on, if you get Bill Nye
talking about laser bees, that project's-
Hey, we funded that project.
Okay, for people who don't know, what are laser bees?
No, laser bees is actually a very interesting concept for deflecting asteroids that are potentially headed towards Earth.
So if you discover a dangerous asteroid, you can hit it with a kinetic impactor like the DART mission.
You can do a gravity tractor. If you're late in the game, you can deal with trying to do a nuke.
But laser bees was a concept of the professor at the University of Strathclyde in Scotland.
And it was to have multiple spacecraft, each with a laser that was powerful enough to ablate,
so basically boil away the surface of the asteroid.
And you have as many as you need for however quickly you need to move it, fire up on one
side of the
asteroid and create a jet of gas that pushes you the other way. And so we find it and you can find pictures on our website, a very cool lab work done by
he and his grad student who then got her PhD doing this,
working in the lab and and vaporizing rocks with lasers. And I mean seriously, what's not to love about that?
lab and vaporizing rocks with lasers. And I mean, seriously, what's not to love about that? But it was the early phases of, you know, can you do that with some momentum transfer?
And they published it, so it's out there. Yeah, and that's not even the beginning of
Wacky compared to some of the proposals we've received, especially for our wide open step
grant program. But I mean, I don't want to reference specific proposals, but they range
from, well, they're the ones that are just unrealistic on budget. And I don't want to reference specific proposals, but they range from, well, they're
the ones that are just unrealistic on budget.
And I don't mean like off by a factor of two or three or four.
I'm talking off by factors of tens of thousands, hundreds
of thousands.
We're talking, well, we need to do this
and we'll build 1,000 spacecraft.
And yes, we would like $50,000 for our grant.
For a project that's probably going to be several million.
Billions.
Some of these would be hundreds of billions projects.
And some of them phrased it as they were beginning, but some people phrase it that, no, that's
just that's what we're, we can do that.
And you can't.
Anyway, but we have lots of great projects that come in as well and a lot of great ideas of which we can't fund all the ones that come into our grant program, so I don't want to portray it incorrectly.
But there are other ones that are wild, they're creative.
One of these days I'll come at you with a weird pitch.
Oh, you already have, Sarah.
I mean, just last week or the week before, what were you doing?
You were cooking in space with your cat.
Yep.
Yep.
Yeah.
But that grooved with people.
I saw it in the member community.
People being like, well, what about the cats? We need to be making sure that we can feed the cats in space. So
clearly it's not just me.
So about that episode about feeding people in space, we actually did get a poem related
to something that I asked you, which was what was the first food that we grew on the ISS,
I believe. And one of our members, Jean Lewin, wrote in a poem called Red Romaine Lettuce,
which was the food that they grew in space. So here's that poem.
In Salinas, California, there are acres of this crop available in the produce aisle,
but in space you cannot shop. We need to find a simple way providing food our space crews
need. So growing plants was the first step. At this, we did succeed. Romaine
lettuce seems prophetic for that gastronomic scene because as we find each fiscal year,
NASA could always use more green.
No.
So true.
That's why they were growing it.
Right? Oh man, how much would you give for a head of romaine lettuce on Mars?
Whoa. I was like, nothing, but then you put it on Mars. Actually, that's even less than
nothing because I'm here.
It's true. Well, anyway, what is our random space fact this week?
Random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random,
random, random, random, random, random, random, random, random, random, random, were the size of a basketball. And that basketball is sitting at one end of a
basketball court. Where, what would be going on with the earth? Well, it
turns out the earth would be roughly the size of a sesame seed to a popcorn
kernel kind of size, and it is roughly at the other end of the basketball court. So
basketball at one end, earth at the other end, and earth
being the tiny seed-like object. And that is a scale model in basketball land. Shoots
from the outside and scores!
Swish. Really though, usually scale models make me feel like, wow, that's so much bigger
than I thought. But this is one of those examples where actually like that's smaller than I thought, the distance between those two things.
If it makes you feel better, Neptune would be 30 basketball courts away.
That's a great way to think about it. And also somehow makes it seem shorter, even though
it is ridiculous. Bigger than a sesame seed for sure though.
Yes, it would. Yeah, I don't know ifhand know it's roughly four times the diameter of a
sesame seed. And sesame seed, not the best analogy because it's not round, you know,
a nice sphere.
Maybe a caper.
Caper. Neptune is a caper. 30 basketball courts away. Full court.
Can you tell I'm hungry? We've been talking about romaine lettuce. I'm going to make some
kind of salad tonight. Anyway.
Apparently with capers and maybe some sesame seeds.
Sounds great.
What dressing do you put on that?
Interstellar medium?
Interstellar medium.
We need to create a side hustle.
Planetary society, hot sauces and salad dressings.
Whoa.
Yeah.
Okay.
I'm going to think about that.
Like you should go out there, look up the night sky and think about planetary salad
dressing.
Thank you and good night.
We've reached the end of this week's episode of Planetary Radio, but we'll be back next
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possible by our members who have been advocating for Europa Clipper for years.
You can join us and help many more amazing missions launch to success at planetary.org.
Mark Calverta and Ray Paletta are our associate producers.
Andrew Lucas is our audio editor.
Josh Doyle composed our theme, which is arranged and performed by Peter Schlosser.
And until next week, ad astra.