Planetary Radio: Space Exploration, Astronomy and Science - Martian rock collecting: From meteorites to Mars Sample Return
Episode Date: February 22, 2023Exciting updates to the plans to return samples from Mars to Earth are underway. Meenakshi Wadhwa, principal scientist for Mars Sample Return at NASA JPL, shares what we have learned from our studies ...of Martian meteorites and fills us in on the upcoming Mars Sample Return missions. Stick around for our review of the night sky and a look back at this week in space history in What’s Up with Bruce Betts. Discover more at: https://www.planetary.org/planetary-radio/2023-martian-rock-collecting See omnystudio.com/listener for privacy information.
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Looking forward to Mars sample return, 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.
The international effort to collect and return material from the Red Planet is ramping up.
This week, Meenakshi Wadhwa, Principal Scientist for Mars Sample Return at NASA's Jet Propulsion Laboratory,
joins us to share the exciting updates to the plan.
You may have also noticed the dazzling light of Venus and Jupiter in the recent night sky.
Bruce Betts, the Chief Scientist of the Planetary Society, will pop in for What's Up to tell us more.
This week, members of the Planetary Society's communications and space policy and advocacy
teams gathered for a retreat at our headquarters in Pasadena, California.
We have a lot of exciting upcoming projects to share with you all in the future.
But the additional work and bonding this week meant that our team didn't have time to prepare
our usual space mission briefings.
I promise that we'll be back to our regularly scheduled updates from the world of space news in next week's show.
As always, you can learn more about what's going on in space in the Planetary Society's weekly newsletter, The Downlink.
Read it or subscribe to have it sent to your inbox for free every Friday at planetary.org.
Humans have been exploring Mars with robotic spacecraft since the 1960s.
In that time, we've learned a lot about the red planet and its history.
We've discovered that liquid water existed on the surface in the past.
The planet once had a warm, wet environment that could have supported life as we know it.
But there are so many mysteries that we've yet to solve.
How did the planet change over time?
What was the atmosphere like?
How long did its oceans last?
And did life once exist on Mars?
The answers to these questions are captured in the Martian rocks,
the soil, the terrain.
Each grain of dust carries a thousand untold stories as they
blow across the desolation of what was once a world so much like our own.
Humans have done an amazing job of piecing together the mysteries of Mars from afar.
But despite our advances in space technology, there are some questions we just can't answer
without bringing bits of the red planet home to our pale blue dot.
Just one rock from Mars in an Earth-based laboratory could revolutionize our understanding of that world and our place in space.
Mars Sample Return is the next step in that journey.
It's a series of missions by NASA and the European Space Agency to return samples from the Martian surface to Earth.
If everything goes according to plan, we'll have the first samples from another planet by the early 2030s. The Perseverance rover, which is already on Mars, has been gathering precious samples in
preparation. Our guest this week is Dr. Meenakshi Wadhwa, called Minnie by those who know her.
She's a planetary scientist and isotope
geochemist who's now the principal scientist for Mars sample return at NASA's Jet Propulsion
Laboratory. She's also the school director and foundation professor in the School of Earth and
Space Exploration at Arizona State University. During her time at ASU, she served as the director
of the Center for Meteorite Studies for over a decade. She
studies Martian meteorites to learn more about what bits of Mars can tell us about its history
and about our solar system's formation. She's here to give us an update on the Mars sample
return mission, what I consider to be one of the most exciting upcoming missions of our lifetimes.
Hi, Minnie. Thanks so much for joining me on Planetary Radio.
Great to be here. Thanks a lot, Sarah.
You know, humans have been studying Mars from afar for generations, but we are so close to
finally actually having samples of Mars here on Earth. And as a geologist and someone that's
working on this Mars sample return mission, that's got to be so exciting for you. It is just incredibly exciting.
I mean, you know, I started my graduate career
studying Mars meteorites.
When I first actually found out
that there were meteorites from Mars,
that there were actual samples
that we thought might be from Mars,
I mean, that just blew my mind.
I mean, I just thought, oh my God, you know,
here I am, I'm a geologist,
I'm vicariously, you know, here I am. I'm a geologist. I'm vicariously,
you know, able to be a geologist on Mars. But, you know, I soon realized that, you know, meteorites,
they're useful in terms of understanding some things about Mars, these meteorites from Mars,
but there's some things about these rocks that we don't understand the geologic context where
they came from on Mars. they are certainly not representative of the
planet as a whole. They're kind of a very small subset of the kinds of rocks that are hard enough
to be ejected from the surface of the planet. You know, they really don't record the full geologic
history of the planet by any means. And they've been weathered, you know, sitting here on Earth,
they've been weathered and contaminated and altered. And so, you know, I thought at the time,
hey, wouldn't it be just wonderful to actually be able to go to Mars and collect samples and
bring them back? I won't say how long ago that was, but that was a long, long time ago. And I've
been, you know, dreaming of Mars sample return since then. It's always been 10 years on the horizon,
but this is as real as I've ever felt that it was going to be,
that it's going to happen.
We're already collecting samples.
Perseverance is already collecting samples on Mars,
and we've already established a depot, a first depot of samples
that we have deemed scientifically return worthy.
Yeah, so it's super exciting.
Oh, there's so much going on there.
I mean, have you ever personally found a Martian meteorite?
I know you've spent a huge amount of time studying them.
You know, I've been to Antarctica for two field seasons.
So I spent two and a half months there a couple of times
hunting for meteorites. And we found a lot of different meteorites. And we actually did find,
I believe in the field season that I was in at least one Mars meteorite. I found some meteorites,
of course, in the field, but I doubt I found a Mars meteorite myself.
How do we actually determine the source of these meteorites? What is it about them specifically that tells us that they're from Mars?
It's a bit of a detective story there. These rocks actually contain little pockets of glass.
So the glass is actually melted rock, which basically captured some of the Mars atmosphere.
atmosphere so what happened was that uh at some point in the past and we think maybe you know a million years ago up to maybe 20 million years ago for some of these mars meteorites it was a large
impact on the surface of mars and it kicked out these crustal rocks from the surface and in the
process it actually melted little pockets of the rock which sucked up some
of the mars atmosphere at the time and then of course it solidified almost immediately the glass
and so that glass actually contains these little bubbles of mars atmosphere and so when you heat up
little portions of these rocks that are the glassy material you release these gases and you know lo
and behold they have the exact composition of the mars atmosphere as these gases and, you know, lo and behold, they have the exact
composition of the Mars atmosphere as we know it. And, you know, we know the Mars atmosphere
composition quite well at this point because, you know, a number of our rovers have actually
measured the compositions most recently Mars Science Laboratory did. And in fact, you know,
we've known the composition, we know it better now, but we knew the composition after Viking measured that composition in the late 1970s there.
We were able to make a perfect connection there between these meteorites, which contained basically this Mars atmosphere.
And of course, the fact that these likely came from Mars as a result of some kind of impact.
As you said before, there's a difference between what we can learn from meteorites
because we can't really localize them where they came from on Mars.
So what is it about these new Mars sample return samples that will teach us different
things about Mars that we couldn't determine from these meteorites?
So for one thing, the Mars meteorites that we have in our collection, they are all what we call igneous rocks.
So what that means is that they solidified from magma.
And those are the kinds of rocks that are hard enough to survive the kind of process that it takes to eject and then transport these rocks from Mars to Earth.
What we don't have in these Mars meteorites are sedimentary rocks.
And the sedimentary materials.
These are water lane rocks and we find them all over the earth, of course, and they've been deposited by rivers and in the ocean.
And there's a lot to be learned about the past history of Mars, especially the history of water on Mars from studying sedimentary rocks. And that's actually
really been one of the key types of materials that Perseverance has been after. You know,
the whole point of going to Jezero Crater was to be able to look for these kinds of
sedimentary materials that were deposited possibly by a lake that might have been present within the crater at some point in the past.
There's also a river delta in the area where Perseverance has been collecting samples.
And so some of the deltaic sediments would be really interesting.
And so those are the kinds of materials that Perseverance has been collecting.
We've also, of course, collected some igneous rocks from the crater bottom, Jezero crater bottom.
We'd actually
expected to find all sedimentary rocks, but it was actually serendipitous that we found that the
crater floor is actually made up of igneous rocks. So we've got a diversity of rock types in the
Perseverance collection. Also some minerals that were, you know, created in these igneous rocks as
a result of interaction with water. And so we've got some really, really interesting materials that are not represented
in Martian meteorites. And of course, I mean, the hope is that, you know, these rocks that are
collected by Perseverance are going to be really clean, pristine in terms of not being contaminated
by Earth environment. And so it's going to tell us a lot more about the history of Mars
and certainly things that we can't really hope to learn from meteorites.
Yeah.
And, you know, Perseverance has been kind of adventuring in Jezero Crater for two years.
In fact, this episode will be airing just a few days after the second anniversary of its landing on Mars,
which is fantastic.
And the images that we're getting back of these sedimentary layers in that river delta have been,
frankly, mind-blowing. The first time I saw it, that looks just like the sediments that we see
here on Earth. I wish that we had the opportunity to bring back every single sample that Perseverance
collects, but how are we making the decision between which samples to return and what happens to the ones
that we leave back on Mars? As you know, we just established a depot on the surface of Mars and
that depot has 10 sample tubes. And so the plan for Perseverance while it was exploring Jezero
crater and the rocks within Jezero, was to actually
collect for every rock that was sampled, to collect a pair of samples. And the goal there was to
basically have one sample that we would deposit in this depot and have another one of a pair
on board Perseverance to take beyond the crater. And so Perse so perseverance in total has 43 sample tubes,
five of which are witness tubes. So that is just basically, you know, those tubes are useful for
characterizing some of the, you know, rover generated contamination, for example. But
there are in addition to these five witness tubes, are 38 sample tubes and so of those 38 tubes
the goal was to collect a pair of samples from each rock within the crater and then after we
established the depot at that point then we would start basically the plan is to start collecting
single samples at this point in the depot that we located within Jezero Crater at the Three Forks region, we've got a stash of 10 tubes of which one is a witness.
And one of them is actually an atmosphere sample.
And so there are eight rock samples that are in that depot.
And all eight of those actually have a pair that's on board Perseverance already.
And so this little depot that we have, it's an insurance policy. It really
is kind of a backup just in case something happens because Perseverance is supposed to be the prime
delivery pathway for us to deposit the samples that are being carried on it to bring it to the
lander that's going to then launch these samples into orbit and then eventually to the earth.
At the moment, we've got the pairs of those eight samples that are on board and then eventually to the earth. At the moment, you know, we've got the pairs of those
eight samples that are on board and then the rest of the tubes. And so in total, we're going to have
maybe one or two extra tubes, then the slots that are available to carry the samples back.
So the sample canister that's going to be coming back has 30 slots in it. And so we're going to have maybe a couple of extra tubes in case something happens
or, you know, we're not able to collect a sample. So just for contingency sake, you know, we've got
a couple extra. Yeah, I mean, we may have to make a decision about which one or two tubes to not
sort of bring back. But that's going to happen probably in a few years time and we'll have some
time to think about it. And so we'll have a great, you know, beautiful set of samples to bring back
that'll represent the diversity of materials from all of the exploration area that Perseverance
will have been to. This brings up an interesting topic, which is that last year there was
announcement that there were some changes to the Mars Sample Return mission.
The primary idea is that they want Perseverance to bring the samples back to the Mars Ascent vehicle.
But in the event that that doesn't work, there are two helicopters that are coming along for the journey.
Can you tell us a little bit about those?
Yeah, that's been an exciting development.
You know, the original architecture when we first started thinking about Mars sample return had been to bring along a sample fetch rover that would help to collect the samples that would have been deposited by Perseverance on the ground and then bring them to the sample retrieval lander or the Mars ascent vehicle on the sample retrieval lander.
on the sample retrieval lander. As a result of sort of refining the architecture, it was actually,
and also because Ingenuity has been performing so well on Mars, you know, over 40 flights at this point, and it's really going strong. And so we realized that, you know, we had the option
to actually use helicopters as a backup option. You know, the other thing that we found out is that,
you know, we expect Perseverance to be healthy and be able to do the job when we need to deliver
the samples to the lander. And so, you know, in estimations of Perseverance's lifetime and
performance, we were able to refine those as well and basically confirm that Perseverance is likely
to be healthy enough to be able to
do the job. And so the architecture has been refined now and perseverance is the main
delivery pathway. And the exciting thing, of course, is that, yeah, we do have these two
helicopters that we are going to bring along. They're going to be very similar to Ingenuity.
So there's going to be a lot of heritage that is associated with this experience that we have, this very successful experience that we have with ingenuity.
And the couple of things that will be different about these helicopters, you know, one is that
they're going to need to be able to grapple or, you know, grip a sample tube. And then the other
is to have a little bit of mobility. So some wheels that are going to allow them to position themselves
over a sample tube, for example, to grip it and bring it to the lander.
Yeah. How are they actually going to pick up these samples in the event that they need to?
Are you testing grabbing arms or some kind of like chomper thing on the bottom of the helicopter?
No, no chomper thing. It's going to be a gripping capability. And that's still something that's being developed at this point. They're going to try to keep it as simple as possible. We don't want to complicate things too much. Basically, it's going to be a small arm that's going to reach out and be able to grip a single tube.
One of the challenges that Ingenuity has faced while it's been on Mars, and it's a happy
challenge because it only occurred because Ingenuity has lasted way longer than expected.
But when the seasons changed on Mars, it necessarily meant a change in the air density, which the
team had to account for in order to make Ingenuity continue doing its flight.
So is the timing of Mars sample return in any way affected by the changing seasons on Mars,
knowing that we need these helicopters to actually lift off and potentially carry samples?
We are trying to design these helicopters to be able to accommodate at least some, you know,
changes in atmospheric density. They're going to be capable, for example, I mean, within Jezero
crater, the air density is a little bit different than, you know, 500 meters above that beyond
the crater, you know, so the elevation is a little bit different, the air density is going to be a
little bit different there. And so, you know, these helicopters are going to be designed to
be able to accommodate that difference as well. And so, yes, absolutely. I mean, I think,
you know, the plan is to be able to design them to be able to perform under the set of conditions
that we expect at the time that we are going to be seeking to collect these samples. This is a
backup plan. You know, again, hopefully Perseverance is going to be our primary pathway.
Yeah. And so far it's doing well. I mean, I fully believe after seeing all of these other Mars rovers completely outlast what we expected, that Perseverance is going to go strong for quite a while.
And maybe, you know, still bring that little rock that it's been hanging out in its wheel, carry that along for the ride with it.
Exactly.
the ride with it. Exactly. You know, these changes to the mission have been so exciting that we wrote an article on this subject just a few months ago. So I'll link that underneath all the other
information on the page for this episode at planetary.org slash radio for anyone who wants
to learn more of the details. But getting all this gear to Mars in order to accomplish the
sample return is going to take more than one launch. So can you give us any updates on the latest launch dates for the Earth Return Orbiter
and the sample return vehicle?
Yes. So the current plan is for the set of launches to be no sooner than 2027.
Basically, at the present time, we are expecting that we would launch the Earth Return Orbiter
in 2027, and then the sample
retrieval lander would depart or be launched in 2028 so that's that's our current plan and so
we're proceeding with that assumption when does that mean that we're actually going to get the
samples back here on earth yes so that means we'll have the samples back uh 20. That's so exciting. That's less than a decade away. I know. I know. It's just,
yeah, it's really kind of, it's really exciting for me to think about that because I've been
really dreaming about this moment for such a long time. And this actually is starting to really,
you know, it feels real at this point because things are happening.
You know, wheels are in motion and we are collecting rocks on the surface of Mars and we're going to bring them back.
Yeah. And they're going to land here in the United States in Utah. Is that right?
Yeah. The Utah test and training range.
Why was that the site that was selected for this landing?
Why was that the site that was selected for this landing?
Well, so, you know, we have had a number of other sample returns, including the Stardust mission from the comet that used the same area.
The Genesis mission returned there, too. And so I think we have experience with this particular site.
It seems like a good place because there's obviously there's not a lot of, you know, not a lot of vegetation or human population there, of course,
and there's a big area for us to work with.
Obviously, we plan to have fairly well-constrained landing parameters
for when we return the canister of samples.
The Earth Entry Vehicle, which is going to be bringing back the orbiting sample canister.
It's mainly that we do have a lot of experience with this particular site we'll be right back
with the rest of my interview with minakshi wadhwa after this short message hello I'm George Takei
and as you know I'm very proud of my association with Star Trek. Star Trek was a show that looked to the future with optimism,
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Society and boldly go together to build our future. With previous sample returns from other missions, say the samples that we got back
from asteroid Ryugu, in a lot of cases they just crashed those samples straight into the
Earth.
Is that going to be the situation here?
So for Mars sample return, we really wanted to make the planning for the landing of the
samples on Earth as robust as possible against any kind of failure. The previous sample returns
that we've had in the Utah Test and Training Range, the Stardust sample return, for example,
that had a parachute that helps to slow down the capsule. The Genesis sample, on the other hand,
it was also planned to have a parachute there, but it did not deploy for some reason. And basically it ended up that, you know, obviously
the capsule crashed. We were able to, of course, get a lot of science still from that, but we don't
want that, you know, obviously to happen with Mars temperature. And we wanted to make the capsule
really robust against any kind of breakage upon landing. And so the idea is to actually not use a parachute
and make the system strong enough
to be able to withstand the impact
at the speed that we expected
to basically impact the earth.
And we've done a number of tests to test that
and we'll be obviously doing many more
and making sure that it's a robust system.
Yeah. Is there any concern that that deceleration will in any way impact the samples, maybe break them up a little bit?
No. I mean, I think, again, this is something that we have been testing and will be testing further as well. capsule is designed and the sample canister is designed to enclose the sample tubes in a way
that it kind of protects the samples adequately against any kind of disruption and mechanical
breakage and things like that. And so there's a lot that, you know, has to go into the design and
implementation of these systems, but they are being designed with that in mind to make sure that
the samples are protected against any kind of damage.
These samples are going to tell us a lot about the history of Mars, but one of the ultimate
goals for this project and one of the primary reasons why we landed Perseverance in Jezero
Crater is because we want to learn more about the watery history of Mars and potentially
its habitability. So if we do go through these
samples, what are some clues that might actually hint toward the watery history of Mars or
specifically life on Mars? You know, we already know from previous missions, the rover missions
that have been there, Mars Science Laboratory, and even Spirit and Opportunity and all of the missions before that, that there is evidence of liquid water on the surface of Mars. There's
obviously a lot that we've learned from these previous missions. But at this point, the goal
of bringing the samples back is to really assess in a very thorough manner whether there's evidence of ancient life in these rocks.
So we know that there was water, but was that environment, the water-rich environment that
we're looking at in which some of these sedimentary rocks were deposited, was it capable of actually
supporting life in the past? One of the things that sort of, you know, also want to make clear is that, you know, the current environment on Mars and the conditions, especially near the surface,
are such that we don't expect that there will be any, you know, extant life. What we're looking
for is evidence of ancient life. And so basically, I think, you know, we'll be able to perform,
we'll be able to bring to bear the full arsenal of state-of-the-art technologies and techniques that are present in Earth-based laboratories to studying these rocks.
We'll be able to study these samples, you know, in these synchrotrons, very, very high resolution, and be able to image the samples at very, very high resolution at, you know, nanometer scale or less.
And so, you know, we'll be able to see if maybe there's things that look like potentially fossilized materials in there.
And so, yeah, the hope is to be able to really study these samples potentially at the atomic scale and be able to learn a lot about past habitability and past conditions on the surface of Mars and how Mars evolved as a planet.
Yeah, that would be the jackpot right there.
If we could find fossilized bacteria or something in these samples, that would be amazing.
And this is funny because last summer I was on an airplane.
And as you do when you're just kind of hanging out on an airplane, I was watching a random
movie.
And the movie I watched was called Life with Rebecca Ferguson and Ryan Reynolds.
And the basic plot of this movie was that Mars sample return,
return samples to the International Space Station.
And the scientists there find out that there's actually life in these samples.
I'm not saying there's going to be life in these samples.
That's highly, highly unlikely.
But this movie did bring up an interesting point,
which is what kind of quarantine might we be giving these samples?
Are we going to be treating them the same way that we did with samples from asteroids and comets or samples from the moon?
So, you know, of course, I mean, movies do like to sensationalize things.
As I just talked about here, the current evidence and everything that we know about Mars at the present time from having been there with rovers and with orbiting missions and
studied Mars for a long time. You know, of course, NASA specifically, I mean, we've been sending
these orbiters and rovers there for a while now. And we know that, you know, at the present time,
the surface environment on Mars is not a very hospitable place. In the past, yes, absolutely.
I mean, we do see evidence that there was liquid water on the surface.
There might have been standing bodies like lakes within Jezero Crater.
You know, we are looking for evidence of ancient life.
But at the same time, I think, you know, we are still in the interest of being very cautious, just making sure that things are as they should be or as we expect.
These samples are going to be treated as if they were hazardous to start with.
But I think the plan is to have them be enclosed and quarantined within a BSL level four type facility that's a clean facility.
They will be assessed.
There'll be an initial period when they will verify
that these are safe to be distributed. And then they will be distributed ultimately to
all the best laboratories in the world to make the analyses. There's also the possibility,
of course, that we could sterilize some component of the samples and distribute the samples
early to make sure that we get some really exciting science results early.
The plan is definitely to treat these samples very carefully and to make sure, of course,
that there are no untoward impacts as a result of bringing these samples back. Again, the probability
of any kind of extended life in these samples is minuscule, extremely, extremely, extremely small.
But we are going to treat it with an
abundance of caution and I'm going to basically quarantine them and make sure that these are
safe before we release them for analysis. And thanks for answering that question. I have to
add it in there because our audience on social media asks this all the time. So I want to make
sure that they feel safe knowing that these samples will be treated, you know, carefully. Absolutely. Will you be personally involved in actually
investigating some of these samples when they return to Earth? I sure hope so.
You know, I've really kind of obviously spent much of my career studying, you know, Mars from
the perspective of these Mars
meteorites and to have some actual samples back. I would love to actually be able to analyze some
in my laboratory. But yeah, I mean, you know, I'm hoping for that. Absolutely.
And this is an international mission between the European Space Agency and NASA. So how can we make sure that everyone in the world benefits from these samples?
Are other space agencies going to ask for some of these samples so they can test them as well?
You know, these samples are absolutely going to be made available to the best laboratories,
the best investigations, to the best scientists in the world. It's not going to be just the
scientists in the U.S. and just the scientists in Europe. They will be made accessible for the entire
science community at large. So yes, I think certainly NASA and ESA are the primary stakeholders
in this in terms of the investment being made towards bringing these samples back. But this is
going to be humanity's legacy, right? I mean,
this is going to be such an incredible achievement. This is, I mean, it's the most ambitious robotic
mission that NASA and ESA have ever done. We'll learn so much from this, but we'll only learn so
much because only because of, you know, we plan to include the whole world in this
adventure. And I think, you know, the best scientists and the best laboratories should
certainly have access no matter where they are. And if we did find some evidence of life in these
samples, what would that mean to you personally after all these years of just hoping to be a
Martian geologist? You know, to me, it's a bigger
question than just the question about life in these rocks. That's, of course, of fundamental
importance. And I think everybody in the world kind of understands the importance of that.
I think it would be a game changer, of course, if there was evidence that showed that, you know,
there might have been life in the past on Mars. But at the same time, I mean, to me personally, as a planetary scientist and a geologist,
I look at it holistically as understanding the history of this planet and life,
the evolution of life possibly on it is one part of that.
You know, from the perspective as, you know, as a human being, of course, I mean,
knowing that life may have originated in another place in the solar system, that does change how we think about ourselves and
about our place in the solar system and the universe. And so, I mean, obviously, it's going
to have wide ranging implications, you know, not just in the sciences, but in the humanities and
how, you know, how we think of sciences, but in the humanities and how,
you know, how we think of ourselves as what it means for us as humans on this planet,
you know, at this current time. But for me, you know, as a scientist, I'm interested in
understanding the planet as a whole and life, the evolution of life on it is a part of that.
Yeah. And I know that your passion for geology started when you were a
small child. I've heard online that a big part of why you got into this field is because you grew
up in India, kind of looking up at the Himalayas. So how did you go from studying earth rocks to
falling in love with Mars specifically? Yeah. It wasn't a linear path by any means. I mean, I started to study geology when I was living in the northern part of India, again, in the foothills of the Himalayas.
And I was always just really fascinated by these, you know, incredible forces in nature that could produce these tremendous, you know, mountain ranges.
produced these tremendous, you know, mountain ranges. And, you know, you'd be able to find fossils in these rocks that were these, you know, mountains. And so clearly at some point in the
past, these rocks were somewhere, you know, at the bottom of the ocean and then things kind of,
you know, tectonics brought these to the surface and mountain ranges. So, I mean, it's just kind of,
to me, it was just really incredibly fascinating to sort of imagine what what the past of our own planet looked like and how things have
changed it was almost like learning about another planet altogether if you look into the deep time
on the earth it's not the same planet as it is today and so just as part of that i mean i kind
of felt like hey you know wouldn't it be just super cool if we could understand the geology of other planets in our solar system and the same kind of, you know, detail that we understand from our own planet and, you know, use the same kind of geological tools to do that.
It was just kind of a dream at that point.
And I, you know, when I started to go to graduate school, I really didn't know that there was such a thing as Mars meteorites.
It just kind of blew my mind that, hey, you know, you've got these rocks that formed on another planet next door on Mars.
And these rocks were ejected and we have them as meteorites now.
But, you know, I can apply the same kinds of tools that I apply to Earth rocks and learn something about the geology of Mars. And so I just love doing that. And that
was really kind of what got me hooked, studying rocks from other places in our solar system,
which of course, meteorites are representing all kinds of asteroids. And we have meteorites we
think are from the moon. Of course, we have a lot of lunar samples from the Apollo missions,
and hopefully we'll have some from the Artemis program too soon.
But learning about the record of these rocks tells us something about the planets on which they evolved.
And I just kind of was fascinated by that.
So that's kind of what brought me here.
But I don't know if that's ever going to be possible in my lifetime, but I hope that there'll be geologists that'll get to explore
Mars firsthand. And in the meantime, I'm just thrilled that we're going to be able to bring
back some rocks from that planet within a decade.
It is so exciting. And I'm sure out there right now is a whole new generation
of children that are just now falling in love with space. And maybe someday they'll be the
ones walking around on the surface of Mars
doing this science.
It's really exciting.
I know it is super exciting.
What would you say to those kids about chasing that dream?
I know that you've had to overcome so many things in order to achieve this
moment for you working on Mars sample return.
What advice would you give them?
I would just tell them to follow their dreams.
I mean, I think, you know,
there's so much, so much exciting thing. There's so much that's happening in space, especially
right now with our ability to explore places that we never dreamed of before. And so, you know,
we're going to go back to the moon, you know, very soon, hopefully. And hopefully we'll be able to have humans on Mars, you know,
not too long into the future as well. I'm hoping that it'll be within my lifetime, for sure.
There's so much excitement. I mean, I think especially with commercial space and all of the
interest in exploring other places and so much happening, even with exoplanets, you know,
we're learning so much more about the workings of our universe and how common planets really are and the habitability of these places.
And so, you know, this is a super exciting time to be someone just starting out, going, you know, going to school and learning about these things.
The world's going to be a much different place, you know, 10, 20 years from now. And, and so much is going to be happening. I think there'll be so,
so many great opportunities to be part of this sort of exciting space exploration and
planetary exploration. I think just follow your dreams. These are the moments I dreamed of when
I was a child, and I'm so excited for everyone that gets to be a part of this in the future.
I dreamed of when I was a child and I'm so excited for everyone that gets to be a part of this in the future.
No.
Thank you so much for talking with me, Minnie.
And I can't tell you how excited I am about this mission and all of us here at the Planetary Society. We really want to wish you and everyone on your team good luck as you undertake this, because this might be one of the coolest missions in the history of space exploration.
I absolutely believe that.
Not that I'm biased or anything,
but yes, thank you so much, Sarah.
It's been great talking to you.
To say that I'm looking forward
to Mars sample return
would be an astronomical understatement.
I cannot wait to learn more.
And I'm so excited for people like Minnie
who've dedicated their lives
to helping humanity solve the mysteries of Mars.
I imagine that one day I'll see an image come through my social media feed of Minnie in a clean room with Mars rocks, living out her dreams as a Martian geologist.
Now we turn to Dr. Bruce Betts, the chief scientist of the Planetary Society, for What's Up and our space trivia contest.
Hi, Bruce. Hi, Bruce.
Hi, Sarah.
So, what's up, Bruce?
All sorts of hunky-dory swell, keen, peachy stuff.
That sounds very nice and lovely.
I would like to hear about that.
So, Venus now just dominating over in the west after sunset, looking super, super bright.
Right when this show comes out on February 22nd, it'll be
hanging out next to the crescent moon. Then the moon over the next five or so days will migrate
up across the sky and end up next to Mars on February 27th. And Jupiter's above Venus, but
it's closing in on it. So March 1st, Jupiter and Venus, the two brightest planets in the night sky, brighter than the brightest star in the night sky, will hit each other and explode.
No, no.
But they will get very close to each other as seen in the sky, about the equivalent of one moon diameter apart, about half a degree.
And it will look cool over in the west.
That's March 1st.
You can watch them grow closer to each other over the next few days and then
grow apart after that.
A bunch of our planetary society coworkers were walking to dinner the other
night,
looked up in the sky and the two shiniest dots in the sky,
clearly Venus and Jupiter.
But we had to think for a second,
which one was which?
And clearly Venus was the shinier one.
It is.
It's so shining.
If you catch the two and you're confused about the two shiny dots, go with Venus. That's the shinier one. It is. It's so shiny. If you catch the two and you're confused about the two shiny dots, go with Venus.
That's the shinier one.
Shiny.
All right.
Let us move on to this week in space history.
We start with a dark note, but a remembrance, which is 1966.
The Gemini 9 prime crew of Elliot C. and Charles Bassett crashed in their T-38 and were killed.
So they switched to a different crew,
so we remember them. On a much happier note, 2007, New Horizons headed out to Pluto, thought,
hey, I will stop by Jupiter or at least fly by really, really fast and get some really cool data.
So this week, 2007, New Horizons flew past Jupiter and a few years later would go past Pluto.
Those New Horizons images to this day are just absolutely bonkers.
I still sometimes look at that picture of Pluto and just think about how much effort it took that we got there and how beautiful those pictures are.
I can't say it enough.
If you haven't seen these pictures of Pluto, please look them up.
It's worth it.
Yeah, the whole Pluto system, quite awesome. Like pretty much everywhere we go,
more complicated than we ever imagined.
Vastly more complicated than I thought it would be, for sure.
Speaking of complicated, we move on to...
All right, I didn't know where that one was going. That was kind of a surprise for me, too.
So I work pretty hard trying to not repeat random space facts in over 20 years, and I did it for years before that.
It's tricky.
So I'm cheating a little bit because I'm kind of combining two, but I just think it's so cool.
I'm going to give a combined two that in the distant past I've used.
So we just had the Super Bowl for those paying attention to American football. At the start of the game, they of course do the coin
flip. If our solar system out to Neptune is the size of that coin sitting there on the field,
the nearest star system, Alpha Centauri, would be about four football fields away.
But wait, don't order yet. The Milky Way galaxy at this scale, you're four football fields away. But wait, don't order yet. The Milky Way Galaxy at this scale, you're four football
fields away at Alpha Centauri. The entire Milky Way Galaxy at this scale will be bigger than North
America. That definitely puts it into context, but it's also funny. It speaks to the American
need to turn everything into football fields for context comparison. Yeah, but I figure a football field with American football is about the same length
as a soccer field known as football elsewhere. I'm turning it into football fields, but it's
more of a generic football field. That was way too much explanation. All right, we move on to
the trivia contest. And we asked you about the wonderful picture, what astronaut included
his two rescue dogs in his official NASA photo? How do we do? And do we have any fun stories?
We got a lot of answers on this one, because obviously it involves puppies and everybody
loves dogs. So people wanted to respond to this one. And across the board, everyone agrees that
this is the best astronaut photo. So I hope other astronauts bring dogs or cats into their photos. But the answer is Leland
Melvin. It's not only an astronaut, but a dog rescue advocate. So in 2008, when he was selected
to be on a space shuttle mission, it was a perfect time to take a new astronaut photo.
And people are allowed to bring some family members in there, but he wanted to
bring his four-legged family members with him. So he brought two rescue dogs, his dogs Jake and
Scout at the time. And I'm going to put a copy of this picture on the page for this Planetary Radio
episode at planetary.org slash radio. So you can see how cute this is because these dogs are so
adorable. Yeah, it's adorable. They're always really good.
And my impression was there was some sneaking involved in getting them onto JSC, but I'm
not sure.
I've heard rumors that it was sneaky, sneaky, but it would be really fun to bring him on
the show sometime and ask him about his caper with pups.
How do you get dogs into your astronaut photo?
You know, not because I want to know or anything.
But our winner this week is airton yuzak from
phoenix arizona usa and airton you've just won a good night oppie 12 ounce thermal bug so we will
send that to you and we did we got some really cute dog stories and things like that but uh
you know just across the board everyone says it is the official best astronaut photo of all time.
And I like this one too, because it does.
It pertains to football.
Daniel Culp from Fort Walton Beach, Florida, wanted us to let everyone know that Leland Melvin was also a football player prior to becoming an astronaut.
Yeah.
And he said, basically, he was a receiver who took going deep to a next level.
Ah!
Hey, Lelandela go deep no man not that deep switching gears mars missions is the topic mars is a tricky little bugger back in the day how many missions to mars were tried but
failed for any reason before mariner 4 was the first successful mission at Mars?
How many failed missions were attempted to Mars before Mariner 4 succeeded?
Go to planetary.org slash radio contest.
And you have until Wednesday, March 1st at 8 a.m. Pacific time to get us the answer.
Remember, space is hard, so there's probably quite a number of these.
But whoever wins this is going to be receiving another Good Night Oppie 12-ounce thermal mug.
I know several people really, really wanted this as the prize.
So here's your second chance to get one.
And for anyone who hasn't had the pleasure of watching the Good Night Oppie documentary,
it's on Amazon Prime Video, and it's all about the Opportunity Rover.
And if you love Mars, or you need a moment to
feel inspired or just need a good ugly cry about robots on another planet i really recommend this
one it was adorable everybody go out there look up the night sky and and think about
tears falling in popcorn thank you and i'm sorry good night
we've reached the end
of this week's episode
of Planetary Radio,
but we'll be back next week
to tell you more
about the Canadian Space Agency's
upcoming lunar rover.
Planetary Radio is produced
by the Planetary Society
in Pasadena, California
and is made possible
by our stellar members.
You can join us
to help support missions
like Mars Sample Return at planetary.org slash join.
Mark Hilverda and Ray Paoletta are our associate producers.
Andrew Lucas is our audio editor.
Josh Doyle composed our theme,
which was arranged and performed by Peter Schlosser.
And until next week, Ad Astra.