Planetary Radio: Space Exploration, Astronomy and Science - An astrogeologic experience with Kirby Runyon
Episode Date: December 13, 2023Sometimes, when you want to learn more about other worlds, all you have to do is step out your door. Mat Kaplan, Planetary Radio's creator and former host, takes us on an adventure with planetary geol...ogist Kirby Runyon as they tour New Mexico, U.S.'s varied geology and compare it to other worlds. They'll explore the dunes of White Sands National Park, the Mars-like geology of Kilbourne Hole, and the rocks in the Carrizozo Lava flow. Then Bruce Betts, the chief scientist of The Planetary Society, and host Sarah Al-Ahmed discuss the most otherworldly places they've been in this week's What's Up. Discover more at: https://www.planetary.org/planetary-radio/2023-astrogeologic-expedition See omnystudio.com/listener for privacy information.
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We're going on an astrogeology adventure.
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.
Sometimes when you want to learn more about other worlds,
all you have to do is step outside your door.
Planetary Radio's creator and former host Matt Kaplan takes us on an adventure today with planetary geologist Kirby Runyon.
They'll take us through the terrain of New Mexico, USA, as they tour locations that can teach us more about the worlds beyond our own.
Then Bruce Betts, the chief scientist of the Planetary Society, will pop in for What's Up and a discussion of the most otherworldly places we've been. He'll also share a new random space fact. 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.
Next week, I'll be talking with the team behind NASA's upcoming Dragonfly mission to Saturn's moon Titan. It's a world that's so similar to our own and yet very alien. It's the only other place
in our solar system with a thick nitrogen atmosphere, but it also has rain and lakes and
rivers. But instead of flowing liquid water, that world is
shaped by liquid methane. There's something really comforting knowing that no matter how distant and
strange the other worlds may be, there's often a hint of the familiar. I've been fortunate to
travel to numerous places on our beautiful planet. My journeys have taken me through cities and forests, vast oceans and vibrant coral reefs.
I've gone to mountains and rivers and even gone on adventures to marvel at the grand feats of
human architecture. Each of these moments is thrilling, but it's the stillness of the desolate
regions where harsh winds and endless sands and icy expanses dominate, that's where my imagination goes to other worlds.
In these stark landscapes that are far removed from the roar of machinery and the hustle of life,
I often find myself mentally transported elsewhere. You and I may never personally
stroll the rippled sand of the Martian craters or the cooled volcanic plains on the moon,
but Earth offers landscapes that are pretty close.
Exploring these earthly analogs not only helps us prepare for space missions and develop new
technologies, it also brings us tangibly closer to the mysterious worlds that are beyond our human
experience. Anyone can have these kinds of adventures by taking a road trip to your local
caldera or desert, but there are also expert tours that you can go on to help you learn more
about what Earth can teach us about other worlds.
So today, we're going to go on a very special adventure with Matt Kaplan,
Planetary Radio's previous host,
as he joins Kirby Runyon and a band of explorers in the varied geology of New Mexico, USA.
They'll explore the dunes of White Sands National Park,
the Mars-like geology of Kilbourne Hole, and the rocks in the Carrizozo lava flow.
Dr. Kirby Runyon is a planetary geologist, a zero-gravity coach, and a space tour guide.
He's been on planetary radio numerous times.
He's a research scientist at the Planetary Science Institute, but prior to that, he had over a decade of experience at the Johns Hopkins University Applied Physics Lab. It takes a keen eye and a brain for mysteries to learn how the
varied bits of terrain on Earth formed and what they can tell us about other worlds.
Here's Kirby Runyon to explain.
Geology is a forensic science. Something happened in the past, some natural processes,
and just like a detective at a crime scene, reconstructs events that happened in the past, some natural processes, and just like a detective at a crime scene
reconstructs events that happened in the past based on the clues in front of them,
geology is the same thing. Some natural processes happened in the past, we read the rock record,
and we can reconstruct past history, past natural history events, and figure out what happened to
make the beautiful landscapes that geologists study.
As is tradition, Matt Kaplan made some new friends during his journey.
Anyone who enjoys rock hunting and thinking about other worlds is definitely our kind of people.
Let's meet Shirley Mullen and Paul Mills.
I'm Shirley Mullen.
I'm Paul Mills.
And you are a couple in spite of the different last names.
We are married, yes.
For a long time.
No, we've only been married 13 and a half years.
That's long enough, I would say.
Listen, what got the two of you out on this trip?
Are you space people, space geeks the way I am?
Paul is a space geek.
So I am more a humanities person, a historian,
philosopher, but when I married Paul one of his intro comments to me was that he
was from outer space and he didn't smile when he said it. So I've just known that
he always loved space and so this is his birthday present to be on this trip.
Happy birthday Paul. be on this trip.
Happy birthday, Paul.
Thank you very much.
I know I said it before, but so what does this trip mean to you?
Well, this is so much more information and I would say knowledge because of the people we're traveling with than I ever imagined.
the people we're traveling with than I ever imagined.
Because we're not only looking at volcanoes,
but we're comparing volcanoes here on Earth with volcanoes on the moon and Mars and other places.
And so that sort of thing is of great interest to me
because I'm interested in going to outer space now,
because I know I'm too old for that now, but still I'm interested in it.
John Glenn made it. He was about your age.
Now I'm going to give you the opportunity.
You can refuse because I know you've said how old you are.
Do you want to mention it?
Well, I'm presentlyly 84 i'll be 85 in
february so you both i think especially you surely have a connection that goes back with our host
kirby even farther than my connection does uh i don't know matt how long their connection is
paul and i are both alumni of the same institution that Kirby is. And the institution honored Kirby in 2018 as being the Outstanding Young Alumnus of the Year.
And you can say its name, by the way.
Oh, Houghton College. Houghton College.
And so that's how we got to know Kirby.
we got to know Kirby and we were so impressed with his enthusiasm as a teacher and his desire just to have this large vision of the world and, you know, that invitational spirit to live ever
larger. And I'll just say one other thing, Matt. So as I mentioned earlier, I'm more a humanities
person and there's so many
things in the world right now that are troubling and one of the things that
this trip has done for me is give me that much longer perspective on time and
I think that's one thing all of us need right now in the midst of the complexity
and chaos of the world, this kind of perspective on things.
And so I'm just really grateful for that.
Plus, I've really enjoyed the diversity of people on the trip. Well, I'm glad I can say the same thing.
Well, I think the diversity of information, because this is a world that I'm not familiar with.
And the information on that side,
the way it's presented and then the visuals
that he's taken us to, the craters,
now we're standing right here looking at a lava flow
that's guarded by two mountain ranges on each side.
It's just a magnificent opportunity for an old man to learn something.
The other thing that I would not have known is clearly interest in space is one of those great
mediators between academic astronomers, academic geologists, and what you might call regular people.
And I'm saying that as an academic, because academics, you know, we're sort of a strange group,
although not all academics would appreciate that comment.
But I just think space brings all kinds of people together,
and we need more of those things in our time.
That's one of my boss's favorite sayings, space brings us together.
Well, that's okay. I didn't even knowings, space brings us together. Well, that's,
okay, I didn't even know that, Matt, but I really agree with that. Thank you, folks. We've got a little bit more to do today. I think we're going out to visit White Sands. Yes, looking forward to
it. We'll do some speed runs. I'm going to slide. Matt also encountered a traveler named Brenda Trinidad.
I love what she had to say about the inspiration she takes from these kinds of astrogeology tours.
Thanks. I'm Brenda Trinidad, and I'm currently the experience curator for Insight Science Discovery in El Paso, Texas.
How did you connect with Kirby?
That's a great story.
Texas. How did you connect with Kirby? That's a great story. The Overview Roundtable is this beautiful group of space enthusiasts, movers, shakers, catalysts, changers. And then the one
time that meets every Wednesday and Frank White, thankfully, is the architect of that with the
human. Frank White of the Overview Effect, right? I I try to make it I don't make it as often as I should and I'm so glad that I found it I found so many just amazing
people that I didn't know I needed to connect with and Kirby was one of those so this one time
where he actually introduced or announced that he was doing these astrogeology tours and he said he
was going to be in El Paso Texas so I wait a minute I'm in El Paso let me let me send this
private chat to him and
say, we need to talk. And he goes, oh my gosh, yes. So that's how we met. That's a great connection.
I mean, tell me more about your title that you just gave us and what that means. So this is what
I'm trying to figure out. So experiences. So I'm in the space exploration field more to help
people understand what it means to experience space and i'm still
trying to figure that out um with the overview effect round table and we're thinking about
how do we bring that transformative experience down for people on earth to feel and as i think
about it all in wonder is around us everywhere.
If we stop and figure out what that means for us,
and it could be as simple as we are right now
here in White Sands National Monument,
and just thinking about our place here among these dunes
and the history that's here,
it makes me feel amazingly small
compared to the environment that I'm in.
And this is a dark sky place, not officially, but I'm looking at the moon right now.
And in a week, it's going to be the full moon.
And the public is invited to come out and watch this full moon rise.
And they celebrate it with story and music and then quiet where we can just experience.
and then quiet where we can just experience.
And that's what I want to understand,
how we create those stories that connect people to each other through this thing we call exploring space.
So it's easy to see why you enjoy places like this.
But, I mean, it goes beyond this, right?
You've been an analog astronaut.
I have been an analog astronaut in Poland at Lunaris.
Lunaris. I was like, there's in Poland at Lunaris. Lunaris, I think there's more to that, Lunaris Habitat.
And that happened in 2021.
And it was very serendipitous because of the research that I was doing in the space tourism,
in this idea of how do we give access and participation options to people in space exploration
in ways that they probably don't even think they
know is an option through that i found the analog astronaut community join the analog astronaut
committee then a message came out that says hey there's an opening in two weeks who's available
and i just happen to be in the right place at the right time with the right resources and i said
i can go and they said come. And it was an amazing two
week experience with four other people I never met before doing what I was, I was the communications
officer for that one. At that mission, that meant more trying to report out what we were doing,
not so much the communication on EVAs. And it was a different role. But I got to play everything.
I got to meet amazing people doing amazing biological research,
psychological research,
figuring out why suits don't fit women the same way
because I couldn't go out on EVAs as much
because I couldn't fit into the spacesuits.
But that gave me an opportunity to be on the mission support side
and learn how we take care of our people when they're out on EVAs
and monitoring health metrics and talking to them and all that stuff.
So while it was initially a deficit, it turned out to be a positive.
And I'm ready to go back to another one.
How about for real?
For real? Absolutely.
Absolutely would go in a heartbeat.
Good luck.
Thank you so much.
And it's been a great couple of days with you too.
Oh, I'm so glad that you came along.
I've been learning so much from you
and from everybody else on this,
on this just wonderful adventure.
One of the most stunning natural wonders
in the United States are the dunes of the White Sands National Park in New Mexico.
The park is located in the Tularosa Basin and is home to our planet's largest gypsum dune field.
It stretches for over 700 square kilometers.
That's about 275 square miles.
These gleaming dune fields were the first stop on Kirby Runyon's tour.
square miles. These gleaming dune fields were the first stop on Kirby Runyon's tour.
The main type of dune that we're encountering here are called barkhand dunes, and they sort of have this crescent shape where it's sort of this streamlined upwind, almost ship-like bow that's
facing into the wind. And then on the downwind side, the lee side, the wind separates. There's
actually what's called a flow separation where the wind separates from over the lee side, the wind separates. There's actually what's called a
flow separation where the wind separates from over the dune. The sand settles out onto a steeply
sloping what's called a slip face. And that is always around an angle of 30 degrees or so.
If it gets up to about 34 degrees, it'll avalanche. This is the shape of a typical
Barkan sand dune. Barkan spelled B-A-R-C-H-A-N.
And that's how the dune moves downwind. It moves in a series of avalanches from the slip face.
But the whole slip face doesn't avalanche at once. You get individual tongues coming down at
different times and it adds up. And in fact, when I was doing my PhD, I was measuring Martian bark can dunes,
images taken from NASA's HiRISE camera.
And in images of bark can dunes taken above in subsequent years, you could clearly see where the slip face had advanced downwind.
Where bark can dunes tend to link up, the arms or the horns tend to link up,
they get referred to as barkanoid dunes.
And here in White Sands, the further downwind you go, so the further to the northeast you go,
the wind slows down because it's losing its momentum to all the sand grains.
And that means that vegetation can start taking hold and the roots cemented in place even more.
And then you get sort of what looks like superficially like a reverse barcan,
where the horns start pointing upwind because
the vegetation roots are holding them in place. We don't have that problem on Mars. Again,
it's a pesky vegetation getting in the way of the rocks, and sand is just very tiny rocks.
Next up they travel to Kilbourne Hole, a volcanic crater in southern New Mexico. It's just a
short drive southwest of White Sands National Park.
Despite their proximity, though, Kilbourne Hole is a stark contrast to the gypsum dune fields nearby.
Kilbourne Hole is a mar, a type of volcanic crater formed by explosive eruptions when magma comes in contact with groundwater.
So where we're going first is Kilbourne Hole. Now this is a picture that I took out of an airplane window.
I was flying home from Tucson and we were skirting the U.S.-Mexico border and we flew just south of Kilbourne Hole.
Now this crater was blown in the ground about 47,000 years ago over the period of about 1 to 10 years.
Not sure exactly how long it took to form.
And I've been looking at this on Google Maps
for a long time, and when I finally saw it
with my own eyes, it was like a veil had been lifted.
And seeing something with your own eyes
versus only seeing it in pictures is huge.
A magma body deep underground intruded
beneath this groundwater aquifer and flashed it to steam.
It is literally a steam explosion and it just
blew holes in the ground just from magma seeping up into groundwater exploding
that into steam and it's not just steam there was bits of rock in there too. I
mean the magma would get mixed in with the water and it blew out chunks of rock.
You'll see that there's this whole volcanic ash deposit that you'll see it
looks like it's been blown by the wind but it's not it was it was blown by its own steam
some of the wall rock which is currently slumping into the crater forms things
that look like I think they look like french fries standing up but they're
they're hexagonal columns sometimes when lava is in kind of ideal conditions it
cools and it cracks into hexagonal noodles. The angles on a
hexagon are 120 degrees. That is the angle that the rock can use to minimize the stress as it
fractures. Devil's post pile in California as well. Is that right? Yeah, there's a ton of these around.
There's a few places on Mars where we think we've seen this kind of columnar jointing. It's called columnar
basalt. The rock type is basalt. That's the most common volcanic rock in the solar system, really,
not just on Earth. But in this wall of a crater on Mars, if you look really closely, there's
actually that columnar fracturing and jointing in there as well. If you walk east around the
crater about a mile, so budget about 20 minutes,
there's a type of rock there called a mantle xenolith. Xenolith literally means alien rock,
the prefix xeno. Now, it didn't come from space. It came from deep underground
where there's a green mineral called olivine, gem variety peridote, if you're familiar with that.
What happened was a lot of the lava,
or excuse me, the magma from deep underground,
as it passed through the mantle and trained,
got a lot of that rock type caught up with it
and erupted it to the surface.
And that's the only way we have samples
of Earth's deep interior in the mantle.
We can't drill that deep.
We rely on volcanic eruptions and explosions like this
to bring up rocks from the mantle. You'll see it's this beautiful green coating on the rock. You can't drill that deep. We rely on volcanic eruptions and explosions like this to bring up rocks from the mantle.
You'll see it's this beautiful green coating on the rock. You can't miss it.
Astronauts have trained here for over 50 years. This is on more people's radar.
Also, this type of crater, I guess I haven't used the name, it's a Mar Crater, M-A-A-R, and that just refers to the magma steam explosions.
I guess I haven't used the name.
It's a Mar Crater, M-A-A-R, and that just refers to the magma steam explosions.
And this is one of the prime examples in the solar system.
We're standing at it right now.
You were saying earlier in the car, this kind of formation, we should expect to see more of them on Mars, but we don't?
That's right.
Yeah, we think that Mars, because of the ground ice and Mars' long history with water and lava and magmatic processes, should have lots of Mar craters. And nothing conclusive has been found. The closest
thing we've found are called rootless cones. And it's sort of the reverse of a Mar crater, where
a Mar crater has a hot magma body coming up into a water aquifer, flashing that into steam.
A rootless cone has water-saturated ground that then a lava flow from above come and flows over, and then steam erupts through that lava.
We find those in numerous places around Mars, especially Athabasca Vallis.
I did my master's degree there.
And a few other places, especially around cerberus paulus
but yeah nowhere else and it's kind of a mystery why we don't see these either they don't form on
mars or they're not preserved and jerry's still out on that we'll probably need more ground truth
is this related to i mean there was for many years the thought that mars might be completely
dead geologically uh and we've learned with even evidence coming from InSight still sitting on Mars, that's not really true.
You're right with InSight.
We found that there have continued to be earthquakes in Mars up to the present.
We think the Cerberus Fossae, this region near the Elysium volcanic province,
is still undergoing some growing pains,
is still groaning and creaking.
There could still be lava eruptions in the future that haven't happened yet.
We think the lava eruptions at this really young site around the Cerberus Fossae
could be only 2 million years old, which is basically now, geologically speaking.
So Mars could still have some little eeks of volcanic activity left,
and it's not too late to form a Mar Crater on Mars.
So get busy, Mars.
Ooh, this might be rhyolite.
How did this get here?
What?
Oh, this is a welded tuff.
Okay.
Are you getting all this?
Okay, this is welded volcanic ash.
It's really pink with a lot of white mineral and black mineral flecks in there.
This is probably welded volcanic ash that came from the phreatomagmatic, the steam magma explosion.
I haven't seen that here, but it's out of place.
It's out of context, so interesting.
It's out of place.
It's out of context.
So, interesting.
I mean, the fact that you are finding things that are surprising you,
that are not in the literature about places like this,
we still have a lot to learn, don't we?
We have a lot to learn about our own planet,
but it's all synergistic, learning with our planet and other planets in the solar system.
So, yeah.
I mean, also, it speaks to, you've got to get your boots on the ground if you want to do geology to the max.
Yeah, because those don't look like they should be here.
Oh, wait, wait, right here, right here.
This is more in place, same kind of rock.
But it's embedded in this wind-deposited lust, which is basically just wind-blown dust that's kind of gotten into the nooks and crannies of all the rocks.
Oh, wow.
So, what is it? It's welded?
all the rocks um oh wow i mean it's welded so yeah that's that's what happens when sometimes when uh volcanic ash it's really hot it's got a lot of gas in it and it welds and fuses itself
together after it's been deposited as a as a fluffy but hot deposit this is all wonderful
but what makes this the place that nasa chose to train astronauts to be geologists?
I think Kilburn Hole is one of many places that astronauts train, and NASA and also private astronauts, too.
It's very otherworldly.
Yeah, it's not an impact crater, but impact craters and volcanic craters are all big holes in the ground with uplifted rims.
It's a rugged terrain.
You get to test your powers of observation here.
Like, I just, you know, rediscovered Volcanic Tough,
and Brenda found some olivine basalt where we weren't supposed to find it.
So it really tests an astronaut's ability to make real-time observations,
real-time serendipitous discoveries.
NASA astronauts use a philosophy called flexicution, flexible execution,
where you have a detailed plan, a geologic field traverse plan,
but you're flexible in how you execute that plan
because you make serendipitous discoveries like this.
And I like to call serendipity.
It's the ability to answer scientific questions you're not smart enough to ask.
Do you remember the story?
I think it was Apollo 17, the last Apollo mission,
the only one that had a geologist on the trip, Harrison Schmidt.
And they went off the track.
And it was not at that point NASA didn't really want people to deviate from the plan,
but they picked up one particular rock.
Do you know the one I'm talking about?
I think I know what you're talking about. So I think it might've been Apollo 15,
where the crew was, they were not professional geologists, but Dave Scott and Jim Irwin were
very well-trained in geology, maybe close to the equivalent of a master's or at least an
advanced bachelor's degree in geology. And they were on the rover heading back to the lunar module.
Mission Control wanted them to get back, but they found a rock.
In fact, it was a vesicular basalt in a sea of non-vesicular basalt.
That is rock without any little holes in it.
They found a bubbly rock, in other words.
And Dave really wanted to stop and pick it up, but didn't want to say anything to Jim because Houston would hear and then tell them no.
And so they made up some excuse about needing to check their seatbelts.
And like, stand by Houston for a seatbelt check.
You'd have to go look at the actual transcript. But they my understanding is they made hand motions to each other.
And Dave reached down off the rover and picked up that rock.
And you can go if you go Google images for seatbelt basalt, you can see pictures of it.
And it's geologically interesting because it's like I said, it's this bubbly rock in a sea of non-bubbly volcanic rocks on the moon. And the little story that it tells
contributes to the bigger story of understanding the moon's history and therefore Earth's history.
So you got to love serendipitous science.
You know, you were telling us you grew up in this geologically not quite as interesting part of Michigan.
And then you started coming to places like this. Yeah, I hope I don't offend any fellow Michiganders
that I grew up in a geologically boring area. But yeah, I started coming out west. I started
seeing the planet poking through the undercover and the open expanses of the southwest deserts and the
incredible varied volcanoes and explosion craters like kilbourne hole here really got me hooked
brenda where did you find that right there we were just walking my where oh my goodness where
okay i can backtrack us so what are we looking at okay so um brenda do you want to describe this it's that green you were telling us about but i don't remember the whole scientific
biggie but is that that this is the peridot uh-huh wow but um the back side of it looks like that
volcanic but then the front side is just at first i thought it was moss but it's like there's no
water and then i saw this little baby wow that gorgeous. So what we're looking at here is the outside of the rock is basalt,
but we would call this an olivine basalt, or also it's a mantle xenolith.
So there's this gorgeous, almost Wizard of Oz green color here.
And this guy is the most...
This is the mineral olivine, and it's really common in volcanics.
And it's what the mantle of rocky planets like Earth and Mars and the moon are made out of.
A xenolith?
Yes, alien rock, a xenolith.
Alien rock, meaning that it didn't come from space, but it did come from deep underground,
brought up by a magma or a volcanic eruption.
As magma went through the mantle of Earth, it entrained a lot of these rocks with it and then erupted them onto the surface.
And because we can't drill deep enough into Earth's mantle, or at all, we have to rely on these sort of volcanic processes to show us what the inside of our own planet looks like.
So this came from way deep down below.
Way below the crust, below the lithosphere, in the mantle.
Wow.
And it's this gorgeous green that coats outside of this room
okay so we're headed down toward the floor of the crater now and it's not that steep but it's quite
slippery so we're actually not on the rim the rim the actual rim is is right up there you see like a
cliff face yeah i do we're headed to that so we're headed down the wall of the crater okay the scarf and uh once we get to the scarf oh if you
look back behind you there's some really beautiful cross-bending now Oh, that is beautiful. Now, I remember seeing things that look like that from,
I don't know if it was Curiosity or, but yeah, just very much like that. That's what we're
looking at now. You're right. Curiosity on Mars has imaged a lot of that kind of cross-bedded
sandstone. Gale and Jezero Crater, we do see a lot of this stuff, but in those cases,
in the case of Gale Crater, it was formed from windblown sediment, sand dunes, sand ripples.
In the case of Jezero Crater, deltas, river deltas can make similar kinds of sedimentary crossbedding.
And this looks superficially the same, except that it was formed almost instantaneously in a volcanic blast.
This is the kind of stuff now that in those deltas, Perseverance is picking up samples because it's that delta where hopefully that stuff's going to come back here someday.
Hopefully someday, yeah.
So what we're looking at formed 47,000 years ago
in a series of volcanic eruptions.
But the story starts about 255 million years ago
during the breakup of the supercontinent Pangea.
And if we fast forward that 255 million years ago during the breakup of the supercontinent Pangea. And if we fast forward that 255 million years ago, the continents are pulling apart.
Oceanic crust is making way for these continents to move by getting buried underground and
actually descending to the core mantle boundary beneath Earth.
Going back to 66 million years ago, the dinosaurs were on their way out.
Two things were happening 66 million years ago. One, there were enormous volcanic eruptions in
what is now Siberia. And that was causing catastrophic climate change. I mean, these
are volcanic eruptions that would have coated all of northern Russia, like seas of lava that we can't comprehend. At the same time that was happening and the planet was undergoing
catastrophic climate change from all that volcanic degassing, an errant asteroid slammed into what
is now the Yucatan Peninsula, blasting so much debris into the sky it blocked out the sun,
also starting forest fires for thousands of
miles around there as the hot rock that was ejected from that crater re-entered the atmosphere
and landed, starting forest fires.
So we had mass forest fires, massive climate change from the volcanoes, then punctuated
with an exclamation mark of an asteroid impact, and the dinosaurs died off.
Now mammal life had already started, and that continued through that mass extinction.
So fast forward from 66 million years ago to only 35 million years ago, the dinosaurs
had already been extinct for 31 million years.
And at 35 million years ago, early North America, the continents had started to move to their present locations,
but early North America was starting to rift apart.
Deep beneath our feet, there's a plume of hot rock coming up from near the core mantle boundary, deep underground,
and it's pushing up on this part of North America, causing this uplift in the Colorado Plateau.
And just like baked cookies in the oven will start to rise and then crack at the surface,
that exact same kind of rising and stretching and cracking is what's happening right here
in what's called the Basin and Range Province.
Basically, west in this part of New Mexico all the way to California,
you see it most in Nevada and Utah.
But the Basin and range refers to a series,
it's like this washboard terrain. You get these series of mountain ranges and then down-dropped
basins in between there. We're in a section controlled by what's called the Rio Grande Rift.
And this started rifting apart about 35 million years ago. And it really started accelerating
rifting apart between 10 and 25 million years ago.
And as it's pulling apart, that's making way for underground magma to come up through all these newly formed cracks, this plumbing in the ground.
The pressure is getting kind of taken off.
And so when you take pressure off hot rock, it melts, it forms magma.
And we started getting volcanic eruptions happening all around here. And so from 1.2 million to a few tens of thousands of years ago, there were volcanic eruptions going off everywhere. And tomorrow,
we're going to one of the youngest volcanic flows. It's only 5,000 years old. This is 47,000 years
old. And we're standing right here in front of this piece of rock here. This is a type of rock
called basalt. It's the most common type of volcanic rock on the surfaces of rocky planets in the inner solar system. And all the holes in here, anyone have
an idea what caused all the little holes? You'll see this everywhere around here. This is, they're
called vesicles. So we call this a vesicular basalt. And all the little holes are from outgassing.
basalt and all the little holes are from out gassing magma has a lot of dissolved gases in it just like soda does and when you take the pressure off the magma and
it erupts as lava it fizzes it bubbles just like opening a opening champagne or
pop or I'm from Michigan we say pop or beer and and and so this is probably a
volcanic bomb so this was probably a volcanic bomb.
So this was probably part of a volcanic eruption.
This was ejected out of the crater
and then landed here or not too far from here.
And these are all over the place.
Would that be a heavier type of rock
than another kind of rock the same size?
It's a little denser.
So this would be a little bit heavier than a chunk of granite the same size probably.
Correct.
The minerals in here have a lot of iron and magnesium in them, whereas granite doesn't have so much.
Granite's more aluminum.
The things that make granite granite and not basalt are more aluminum, calcium, and sodium as opposed to iron and magnesium in this rock right here
Let's see
The closest we have to like I said the closest we have to these sorts of rocks on Mars
They're called rootless cones, and that's what I was mentioning in the car. They look like a cone shaped volcano again
There's an outstanding mystery why we don't see stuff like this on Mars and there's no other place in the solar system
We would really expect this,
where you have this combination of groundwater and lava.
Mercury is out, too close to the sun, too hot, no water.
Venus is out, although probably not early Venus.
We think Venus had oceans up until about a billion years ago.
So for its first three and a half billion years,
Venus could have had these,
although they would have been erased
from subsequent volcanic and tectonic activity.
Moon doesn't. There's maybe a chance we're just in the last few months, we're getting surprising results from asteroid sample return missions that have returned
samples from the asteroids Bennu and Ryugu that show that water has played a huge role
in altering some of those minerals. So that's a huge surprise just for me, especially in the
last few months. We never expected, or I never expected, water alteration on asteroids. So
looking out at the crater, the walls of the crater kind of exposing the geologic record,
the bottom most layers are from ancient stream beds, the ancestral Rio Grande River.
As we move up, and that's kind of the pink, the kind of the pinky rocks,
you can see kind of the pink orange over here to the left.
Above that is a basalt flow called the Afton Basalt.
And then above that, if we walk on down here,
we get to the ash layers.
And as you examine the ash layers, you really begin to see
where it looks like it was windblown. But of course, that wasn't from the wind. That was just
from the eruptive force from the blast and the steam explosion as the magma vaporized the groundwater.
We'll be right back with the rest of Matt Kaplan's astrogeology adventure with Kirby Runyon after this short break.
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About 100 kilometers or 60 miles northeast of Kilbourne Hole is a place called Carrizozo
Lava Flow. It's a vast field of volcanic rock that stretches 70 kilometers, or 44 miles.
It's one of the youngest and best preserved flows in the continental United States.
Carrizozo Lava Flow was created by an eruption about 5,000 years ago
and left behind this otherworldly field of black, rugged terrain.
Day two, Kirby, and much better weather today. We got chased off the side of a volcano
yesterday by wind and lightning and hail. And hail. Oh yeah, and rain. We were trying to explore
Aden Crater, which is not an impact crater. It's a volcanic crater in the Potrillo Volcanic Field
of Southern California. And it's this beautiful 1,700 foot or so diameter
volcanic crater that just has this extensive lava flow surrounding it. And it is
a bugger of a place to get to. I mean, you remember the roads we were driving over?
Oh yeah, I do. I was in the third seat, so I was bouncing. It was a thrill ride.
You didn't hit your head on the ceiling, did you?
Not too many times. Oh good, yeah. But it was was a rough road and we were walking up to the crater as we
started getting uh pelted with rain we got in the suburban and then we the hail started and we
we peeled out of there because we didn't want to get stuck back there it is it is hard to get to
but the lava float the crater itself uh is a perfect microcosm for so many summit volcanic calderas on Mars.
So if you think of the summit caldera on Olympus Mons or the smaller Tharsis volcanoes like Arcea Mons, Pavonis Mons, and Ascreus Mons,
the summits of these volcanoes basically look exactly like Aden Crater.
They're just way bigger.
you know, basically look exactly like Aden Crater. They're just way bigger.
And in fact, I've been, some of my planetary geology colleagues use Aden Crater as this perfect terrestrial analog for these Martian calderas. And we will get in a couple minutes
to where we are now as we continue to walk along this beautiful trail. Oh my God, that is a gorgeous
formation right there. I better stop now and say, what are we looking at? So, right
now, we're looking at a piece of uplifted basaltic tumulus.
So, what is that? So, we're looking at part of a lava flow
from 5200 years ago, the Carrizozo Lava Flow and we're
looking at this portion of the lava flow that literally
inflated from the lava being pressurized in the
tube beneath it and pushing up and cracking open the crust sort of like the
way a muffin or a cookie cracks when you bake it and it's towering above us I
don't know what is that 20 feet up oh yeah and we're just looking at this
almost not quite vertical but it's like maybe 60 70 degrees tilted and these
beautiful ropes
of pahoehoe lava like what you'd see forming in Hawaii right now coming down
the side of that and it's it's just this imposing mass of almost black rock in
front of us so when was this formed when was this molten lava yeah so or magma
actually well it was lava on the surface so so so 5,200 years ago this is the
second youngest
lava flow in the continental united states uh and so over the span of about 30 years
5 000 years ago or so this 75 kilometer long 45 kilometer long lava flow got emplaced through a
tube-fed volcanism where a lava river literally creates the tube that it insulates and allows it
to flow for so many tens of miles or kilometers. Lava tubes, one of the most exciting things that
we're beginning to look for are places like the moon and Mars. So, I mean, this is kind of the
point of this trip, right? What are the parallels between this place and what we see elsewhere
around the solar system yeah well so
basaltic lava is really the most common rock type on the surfaces of planets of
rocky planets in the solar system from Mercury to the moon Venus Mars even some
large asteroids are covered with basaltic lava flows our whole ocean
basins which is most of the surface area of Earth underneath the water that's all
basalt and so's all basalt.
And so any basaltic lava flow you get to explore is immediately analogous to basaltic flows around the solar system.
Now, I'm pointing out as we walk along,
so we're on a paved trail at the Valley of Fires Recreation Area,
the Carrizozo Flow.
And just off to our right here, you can see the domed roof of a small lava
tube. Yeah, it's gorgeous. And is that something you'd want to be in a space suit and try to wedge
yourself into? I don't know. I might want to send a robot first. Sure. Yeah. Well, it's only like
two feet tall. So that's most lava tubes right there. But we're looking down into this, a little
bit of an inflation pit right here where you can see kind of the roof of the small tumulus has
collapsed down into it. I got to take a picture of picture of this but i'm gonna keep talking for a moment um and and this
is this is a miniature example yes of some you showed us picture of an earthbound lava tube
that's big enough to walk in and we expect right that we're gonna find big ones like that on the
moon and mars we'll probably find them on the moon and mars we've certainly seen a lot of collapsed pits on the moon uh there's some interesting uh spacecraft
concepts for how you'd get robots down in there and then maybe eventually humans um but there's
just a lot of unanswered questions we we know from a few uh sideways looking oblique images
from the lunar reconnaissance orbiter narrow narrow angle camera that they do extend underneath
the roof a little way. So we know that they, at least a few of them, are limited extent caves
and not just pits. If you had some sort of like a cable car system for future astronauts,
that might be the ideal way to comfortably get down in there. And as we've seen in some science
fiction as well, might be a good place to live
and stay out from under the micrometeorites
and a lot of the radiation.
Maybe.
I'm going to channel a little bit of our friend Bill Nye here
and say, do you really want to live in a cave?
I would not, actually.
So, great place to visit,
great place to have a scientific research outpost.
I like windows and natural light personally.
Yeah.
Oh, God, look at this.
Yeah.
Got to get a picture of this.
Where we are has these, and the various places we're visiting,
have these parallels to things we are seeing more and more of all over the solar system.
Right.
Yeah.
You know, I'm frequently surprised when I talk to people about the moon that people have no concept that the moon is basically a volcano planet.
So many of the landforms we see on the moon are either from impact cratering or from volcanoes
or some form of volcanism. So all the dark areas you see on the moon just with your naked eye,
those are all cooled lava planes. And if you really zoom in using spacecraft images from like
the lunar reconnaissance orbiter you can clearly see the jagged outlines of lava flows we see
volcanic vents that are often oval in shape we see some volcanic cones like you see out in arizona
and new mexico so the moon is just riddled with signs of volcanic features same thing with mars
So the moon is just riddled with signs of volcanic features.
Same thing with Mars.
You know, we see lava vents in so many places and lava channels and lava flows many places across the moon and Mars.
And even Jupiter's moon Io, we were talking about that earlier.
Even some of the spacecraft images brand new from the Juno orbiter are showing us brand new pictures of the surface of Io, which is constantly changing and all of those lava flows are also basalt.
I've often said, boy, the worst job in the solar system would be to be a cartographer,
a map maker on Io.
Yes, exactly.
No, as soon as you make your map, it's obsolete for Io.
All right.
One thing that is clear from all of us, so here is another
Caved in there's a little bit of a caved in lava tube right there, so
Here's here's a context view from this is Sir Richard Branson spaceflight two years ago
Looking out the back of the spaceship spaceship unity, and this is the car is those a lava flow where we're at right here And and this is White Sands. So this picture is just from the International Space Station.
Like we said in the car, it's 75 kilometers long.
It was in place 5,200 years ago over the course of about 30 years.
Now, what makes this flow interesting is that it's confined between the mountains on the west and on the east.
And it's a type of lava flow called a tube-fed lava flow,
where you would have rivers of lava.
I took this still from active flows in Hawaii.
But what happens, as the lava's flowing along,
it'll cool on the top,
and then that cooled top crust acts as insulation
for the lava underneath.
To stay hot.
To stay hot, exactly, yeah.
And so towards the end of that river or tube system, for the lava underneath. To stay hot. To stay hot, exactly, yeah.
And so towards the end of that river or tube system,
the lava will break out.
It's literally called a breakout.
And it'll continue flowing.
The top will cool, and then it'll stay hot,
and it'll keep flowing.
And so it creates the tube that insulates it.
It creates its own tube for it to continue traveling through.
And that's how you're able to have a lava flow 75 kilometers long from Little Black Peak,
way up north there,
40-some miles, 75 kilometers south that way,
is because it was a self-insulating flow.
Lava also has the property that it's like ketchup,
in that you can have a pile of ketchup on your plate,
and when you dip a french fry in it, it flows.
It's called a Bingham plastic. Your blood is the same way it's got a certain what we call yield stress where it acts
sort of like a soft solid until you nudge it hard enough and it begins to flow what that means for
lava is that it also creates its own levees that it flows through so the lava on the edge of the flow is in contact with and it cools in place.
Gosh. Yeah. One of the things that is obvious in hearing you across this trip is your enthusiasm,
your excitement about all of this, which is great to hear because you've been at this for a while,
but isn't this kind of also what you're hoping to share with others, I mean, those of us on this trip,
but also if things go well with a lot of other people.
Yeah, thanks for asking.
I'm transitioning in my career from full-time research scientist to part-time research scientist,
part-time really tour guide.
That's a scientific that I call informed enthusiasm, the scientific type tours that aren't just
for scientists. I want everyone to be able to come along maybe on, say, host trips monthly to the planetary analog terrains in New Mexico
and get to basically let people have their vacations on the moon and Mars without leaving Earth.
And I've also had the privilege of leading Virgin Galactic ticket holders,
people that have paid and they are going to fly in space,
of showing them the landscape beneath them
that they are going to see from space.
And I call this perspective from space to in your face.
Right now we're in the in your face part
because we're just a few feet away from gorgeous lava flows.
But this is the exact lava flow
that suborbital private astronauts see from suborbital space,
whether that's with Virgin Galactic or with Blue Origin. You know, Frank White is our friend, our space philosopher friend,
who's coined the term the overview effect for this mental cognitive shift that people undergo
whenever they see Earth from space. And I want to help people who experience the overview effect
have a more informed overview effect so they can understand the same lava flow or the
same sand dune field from a millimeter perspective to a tens or hundreds of kilometers perspective
and hopefully blow their minds even more kids or more their teachers oh man uh well my answer is
always going to be everybody but i'm really going for teachers right now teachers are have it rough
i mean they're always
in, they're in classrooms, they're teaching out of textbooks so often, they're oftentimes teaching
to the test. And it's rare, I think, that they can teach from their firsthand experience and
their own excitement and enthusiasm. So what I'm really hoping that we get to do is to have
sponsored teacher trips out here where teachers can take a few days of a break,
come out here, come outside, not sit in front of a computer, get up close and personal with the rocks,
get up close and personal with the planet as a stand-in for other planets and moons,
be able to learn from their own experience and bring that same informed enthusiasm back to their
classroom, whether that's kindergarten through 12th grade or community college. Those are really the target teacher audiences I'm after.
I hope this works. I mean, I love your phrase, informed enthusiasm, which you are really good at.
I have to bring up one other thing, because, you know, you and I go way back.
Planetary Radio playing a part in your, leading you in this direction.
That's right.
But also my former colleague, Emily Laktawalla.
Yes.
What was her role?
Wow.
I hope Emily is listening.
Hi, Emily, if you're listening.
Because her blogs on the Planetary Society website, planetary.org, were instrumental
for me pursuing a career in planetary geology.
In the mid to late 2000s, I was was a physics major and I would procrastinate from doing my physics
homework by reading her planetary geology blog, uh, where she would take a spacecraft image,
maybe from the Mars exploration rover spirit and opportunity, or a picture of maybe one of the
moons of Saturn from the Cassini orbiter. And then she would walk the reader through the geology of
the image. And I got hooked on geology because of the space connection
with Mars, the moon, the moons of Saturn.
And I ended up pursuing that for my master's and PhD
and then now my research career.
And now I hope to hopefully inspire people from all walks of life,
just from the space curious to the space tourists
and everyone in between about the geology that shapes not our planet,
not only our planet, but moons and asteroids and planets around the solar system.
And Emily and the Planetary Society were definitely big parts of that.
So you're pretty early yet in this process.
I mean, the group that is out with us today, kind of a test group, right?
We're sort of guinea pigs.
Yeah, that's right.
So some friends have agreed to come along on one of my field trips out here as we go through the field routine and test out logistics and travel options
and how interesting things are. I think it's all interesting, and I hope everyone thinks it's
interesting, but you never know. So this is a little bit of a test run. I've been out here
several times before, but I'm hoping that this can grow into a regular cadence of events.
So I am honored to be in this group as one of your guinea pigs, and I wish you nothing but
success with this. It is absolutely a wonderful experience. We are surrounded by some of the most
beautiful territory I've seen on earth, and it's great to hear you sharing your passion,
I've seen on Earth.
And it's great to hear you sharing your passion,
the PB&J, right?
That's right, PB&J. That passion, beauty, and joy for it.
Is there a way for people to learn more
as you head into hopefully doing more of these?
Yeah, thanks.
I hope people can visit my website,
planx.space.
That's P-L-A-N-E-X dot S-P-A-C-E.
Also, follow me on LinkedIn, Kirby Runyon.
I post regularly about planetary geology and also zero-gravity flights, incidentally.
But my website, my business, Planex, that stands for Planetary Experience.
I want people to experience the planets.
And you've done 16 zero-g flights?
I've done 16 zero-g flights.
I have almost 20 minutes in moon gravity over an hour in zero gravity about 10
minutes in mars gravity mars gravity is underrated by the way i think mars gravity is great all right
i'm gonna stop talking to you now because i'm intensely envious and i gotta get on one of those
flights thank you very much my pleasure matt thank you it's the last stop on our two-day adventure in the Southwest. I'm standing on top of one of the many dunes in White Sands National Park, New Mexico.
And it is yet another gorgeous and entirely unique place,
except that it's not really unique because Kirby was just telling us
how similar it is to places elsewhere around the solar system.
Mars, Saturn's moon Titan, perhaps even Venus.
It has been an outstanding trip.
If you have not been to this part of the Southwest, it's worth your time and trouble.
For Planetary Radio and the Planetary Society, I'm Matt Kaplan.
I've spoken to so many scientists who have started their astrogeology career because of their
experiences exploring the wilds near their homes. You never know when one weird rock could change
your life. If you'd like to know more about Kirby Runyon's astrogeology tours, I'll leave a link to
the website on the show page for this episode of Planetary Radio. I'm also happy to report that we'll be hearing more from Matt Kaplan
in our last show of the year, so keep an eye out for that. Now, let's check in with Bruce
Betts, the Chief Scientist of the Planetary Society, for What's Up.
Hey, Bruce.
Hi, Sarah. How you doing?
Doing really well. I don't know if you can tell. I'm a little hoarse.
I spent all weekend at L.A. Comic-Con talking my face off, like you do.
But I wanted to say, I love that Matt is finally off going on adventures.
When he stepped down from the show, I envisioned him sitting on a beach somewhere.
But I feel like geology adventure in the middle of nowhere is more his style.
Yeah, I'm the one sitting on the beach.
Matt's doing that.
And he did caves a while back when he was doing the show.
He's a wild man.
It's awesome.
Yeah, he's an inspiration.
I wanted to ask, though, like, what are some of the weirdest, like most otherworldly places you've been to on Earth? Because every once in a while, when I'm in the middle of nowhere, I always try to imagine
to myself, what other world might this be like?
Washington, D.C.
But in terms of interesting geology, it's kind of boring because other people who've
been there would say it, but Death Valley, which is huge and has a bunch of weird stuff in different places,
from salt flats to alluvial plains and colored rocks and sand dunes and all sorts of weird stuff.
And also making the mistake of going down inside a volcanic cinder cone
the first time I took that field trip. What about you, Sarah? If you already talked about this.
Yeah, no, I think the sand dunes is what my brain always goes to because I've spent a lot of time kind of camping in the deserts outside of Dubai and Oman.
And just dunes as far as the eye can see.
It's hardcore.
Yeah, it really kind of makes you feel isolated.
But I imagine being on Mars is close to that.
You know what life is about?
Hmm.
Random Space Facts!
Heck yeah.
So we just passed recently the 25th anniversary of the beginning of the International Space Station,
as it was defined by the first couple of big modules coming together.
So I thought I'd do a little ISS stuff. And I'll start with just the most stunning construction
statement, which is it was assembled using 42 assembly flights, 37 on the US space shuttles
and five on the Russian Proton Soyuz.
It just, that's a lot of space flight.
That's a lot of assembly.
And maybe next week we'll talk a little more about an obscure fact that I've found that you will hear first from me.
Stay tuned.
I did want to tell you this story because I feel like it would warm your heart the way
that it warmed my heart.
But I went to LA Comic-Con like you do.
And it was my first time being a panelist.
And we were on a panel called Ad Astra Per Aspera.
Classic, right?
And it was all about lessons we could take from Star Trek. someone who was a member of the Planetary Society came up to me and was just really excited to meet
me there and basically made a statement about how cool it is that there are more women visibly in
science and what that means to her and inspiring other little girls around the world. And I came
away with just so much joy. And then immediately after that, got myself marched down to a booth
in the back to go meet the people from the fleet, which is like an organization of people that dress up in Star Trek outfits.
But they do charity events and that kind of thing.
So I went down there and got myself inducted into the fleet.
So basically, now I'm just going to have more people to space party with.
Wow.
Congratulations.
And should we end on that note?
Let's do it.
I hesitate to say this, but I'm going to try anyway. All right, everybody, go out there,
look up the night sky and think about what initiation ceremony and what secret handshake
Sarah must have been involved with when joining the fleet. Thank you and good night.
and when joining the fleet.
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 with an update from the Dragonfly mission team to Saturn's moon Titan.
A dual quadcopter the size of a rover
flying around one of the weirdest moons in our solar system
is exactly what I want for the future of space exploration. You can help others discover the passion, beauty, and joy of space science and
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