Planetary Radio: Space Exploration, Astronomy and Science - InSight's revelation on Mars’ rotation
Episode Date: October 18, 2023Data from the now-retired NASA InSight mission suggests that Mars' rotation is speeding up. The InSight RISE instrument's principal investigator, Sebastien Le Maistre, from the Royal Observatory of Be...lgium, joins Planetary Radio to get into the details. The Planetary Society's Digital Community Manager, Ambre Trujillo, shares her experience observing the October 14 annular solar eclipse and her adventure to the OSIRIS-REx sample return capsule opening at Johnson Space Center. Then, our Director of Government Relations, Jack Kiraly, shares the triumphs of The Planetary Society's in-person Day of Action. Stick around for What's Up with Bruce Betts, the chief scientist of The Planetary Society, as he shares an asteroid mission-themed random space fact. Discover more at: https://www.planetary.org/planetary-radio/2023-insight-mars-rotationSee omnystudio.com/listener for privacy information.
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Mars' rotation is speeding up, 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.
Data from the now-retired NASA InSight mission is providing new details about how fast Mars rotates and how much it wobbles.
The InSight RISE Instruments Principal Investigator, Sebastian Lemaester, from the Royal Observatory of Belgium, joins us this week to get into the details.
Hiyo will share her experience observing the October 14, 2023 Annular Solar Eclipse and her adventure to the OSIRIS-REx sample return
capsules opening at the Johnson Space Center. Then our Director of Government
Relations, Jack Curley, will share the triumphs of our most recent Planetary Society
Day of Action and update all of us on the status of the Mars sample return
mission. Hang on until the end for What's Up with Bruce Betts, our
Chief Scientist, as he shares an asteroid mission-themed random space fact. And for those of you looking forward
to our upcoming episode about diffraction solar sailing, which we announced on last week's show,
don't worry, we're still going to be hearing from that team in the coming weeks.
If you love Planetary Radio and want to stay informed about the latest space discoveries,
make sure you hit that subscribe button on your favorite podcasting platform. By subscribing, you'll never miss an episode
filled with new and awe-inspiring ways to know the cosmos and our place within it.
Before we delve into today's episode, I want to take a moment to acknowledge current world events.
Our hearts are with everyone impacted. In times like these, we hope that
taking a moment to reflect on our tiny shared place in this vast cosmos inspires all of us
to treat each other with kindness and to build a better future for everyone on this precious planet.
No matter who you are or where you hail from, we're glad you're with us.
On October 14, 2023, an annular solar eclipse passed over
parts of North and South America. Solar eclipses happen when the moon passes in front of the sun
from our perspective here on Earth, but annular eclipses are something special. They occur only
when the moon is a little farther from the Earth in its orbit. The smaller angular size of the moon
in the sky means that it can't fully cover the disk of the sun as it does during total solar eclipses.
This creates a beautiful phenomenon that some people call a ring of fire.
Amber Trujillo, our digital community manager, is here to share her experience on that day
and her journey to Texas a few days earlier on October 11th for the unveiling of the NASA OSIRIS-REx asteroid sample return capsule's contents.
Hey, Amber.
Hi.
It's cool seeing you in the office being able to record together.
This is amazing.
I wish we could do this all the time.
I know, right?
It's our co-working week here at the Planetary Society.
So for the first time since the COVID pandemic began, we have the entire crew in the office.
So it's just a really magical time for all of us.
But it's also been a really big moment in space history for the last few weeks.
And you've been lucky enough to witness several of these events, starting with the annular solar eclipse that happened this last weekend.
You were actually there in the place where you could see the full annular eclipse.
How was that?
It was amazing.
I was in the path of totality.
I went with my parents and my nephews to a little place in New Mexico called Torreon. We have a ranch out there. And I had never seen an eclipse before. This was my first time ever.
Really? Yeah. So it was really special to experience that with my family. I made sure the nephews had their super safe solar eclipse glasses that actually build knives. So they were all set up. They're ready to go. And
I couldn't decide if I was more excited to see the annular eclipse or to watch my nephews
experience the annular eclipse. So it was really cool to be able to see that.
It's always one of those moments whenever there's a big eclipse, I always try to get all the eclipse
glasses and give them to all the younger members of my family because these are those events that
even as an adult, when you experience them, they kind of change the way you personally feel about space.
Because it's altering your reality.
The light changes.
You see all the effects.
But as a child, it's one of those moments that honestly could change the arc of your life and interest you in science in a way that you never could be before.
Yeah, there's very few events here on Earth that can bring space to you.
And definitely the eclipse is one of them.
Yeah.
Of course, this is kind of like a precursor moment for us.
An annular eclipse is very different from a total solar eclipse.
And we do have a total solar eclipse coming up in the United States next April, in April 2024.
So this has been kind of like a test moment for a lot of people that are looking forward to that eclipse.
But annular eclipses are a little different. What was the experience like?
Yeah. So I have never seen a total eclipse and I hear from everybody that it is a completely
different experience than an annular eclipse, but it was really cool. The main difference
being that the annular eclipse kind of shows that ring of fire. So it's fun to watch the moon kind of move into
that little perfect disc with the little red rim around it. So that was really fun. It also got
very, very cold. I can't imagine how much the temperature will drop for the total eclipse,
but yeah, it definitely got a little cold. It was interesting. You actually heard the birds start to chirp less, which was
really interesting. It definitely got a little gray outside. So it was a very cool event, but I
will say that it makes me look forward to the total eclipse even more. I'm so excited.
Well, this is just one of the cool space things you've gotten to do recently.
You're one of the people who actually got to go be there when they opened the OSIRIS-REx sample return capsule recently.
What a week.
What a few weeks for us.
But, I mean, how did you end up on that journey?
Yeah, so I was able to go out to Johnson Space Center in Houston, Texas, and be there when they unveiled the sample from OSIRIS-REx.
And it was amazing, as usual.
I mean, NASA, obviously their productions are absolutely incredible.
It was amazing to be there with the people who worked so hard to make this a reality
because you see in them how excited and how moved they are by this.
I had the opportunity to talk to Dr. Kimberly Alums,
who is the lead engineer,
having to do with the curation of the samples.
She led the team for creating the glove box
and the clean room and how to get the samples.
And that was one fascinating to speak to her
about the work that went in.
Just speaking to her, she was trying not to cry
because this was such a huge moment in not only her life,
but in lives of so many.
And I know that just from what she expressed,
what it meant to the team,
because they spent years away,
putting so much time into this away from their family.
And so to see it become a successful mission, flawlessly, pretty much.
And even when they did come up with, they came into any kind of obstacle, they overcame it perfectly.
And she spoke to what it means when you have a team that worked really well together.
So that was really nice to see, just seeing her express that.
And I also got to speak to Dr. Dante Loretta, who's the principal investigator.
And I mean, he is just, he knows everything in and out.
And it was just really cool to be able to chat with him about what this means for humanity
and what we can look forward to when it comes to not only rewriting the textbooks for solar system
formation, but also how life got here, you know, the origin of life and what that could mean for
if we hold the ingredients for life from an asteroid, they could have also landed on Venus
and Mars and the moons of Saturn and Jupiter and what that could mean for the search for life.
Like, it's just, it's so mind blowing that we're able to get these samples from so far
away.
And so, yeah, it was really cool to just be in that moment and to be around the people
that made it happen.
So, yeah, it was a really wonderful experience.
And already just the beginning science that we're getting out of this is already telling us a lot.
We have samples from some other objects in space, even other asteroids, comets.
But in this tiny amount of time, even before they got into the core samples,
we've found water and we've found carbon compounds, both of which we know are key for life. And if this is something that happens so readily in our solar system,
it would be highly unlikely to say that that's not common across all the worlds in our galaxy
and beyond. Yeah. It's exciting for the search for life, for sure. And I'm really excited to see,
I mean, we've seen the science that comes from
samples from the moon, from the Apollo missions, and how we're still getting science from that.
I'm excited to see, you know, how they utilize these samples, what we can learn from it. And,
you know, maybe we can grow something out of this. And so I don't know, there's so many things that
the list is long, but it's, I look forward to seeing what comes from it.
And as our person that does social media, I'm sure you've gotten to see a lot of the reactions from people online.
What has that been like?
It's really cool.
I think definitely the most exciting thing for people is the search for life to see what can come of this.
And also panspermia.
I have gotten so many panspermia comments. They're just like, we knew it And also, panspermia. I have gotten so many panspermia comments.
They're just like, we knew it. It was panspermia. So it's really cool to see people ask questions.
So it always brings me such joy when people are like, oh my gosh, I love these questions. I have
so many questions. Like, yeah, keep asking questions. I love it. So it's been very positive
from the world of social media. That's always good to hear. That's what we're here for. And
that's really what this is all about. We're learning wonderful things about the solar system
and our place in space, but we're also giving people the opportunity to feel truly inspired
about not just where we're at right now, but about the things we can do together in the future.
Yeah. I mean, that's what brings us together, right?
It's space.
We're all on this rock together.
Well said.
Well, thanks for joining me, Amber.
Thank you.
Adventures like that remind me
why sharing space science and exploration
and advocating for the missions that matter
really makes a difference.
On Monday, September 18th,
we held our 2023 In-Person Day of Action.
The Planetary Society took to the halls of the U.S. Congress to advocate for a balanced and
robust budget for planetary science. It was Jack Kiriles, our Director of Government Relations,
first time organizing the event. Hey, Jack.
Hey, Sarah.
Good to be here in person with you.
It's fantastic to be here in person with you and the whole team.
I know, right?
You're usually off in Washington, D.C., which is where we need you, you know.
You recently were in charge of a mammoth task, which was getting hired here at the Planetary Society, then being in charge of our day of action.
And, of course, you know, Casey Dreyer is usually in charge of doing our day of action in Washington,
D.C., but Casey was on paternity leave, so all the perfect reasons. But it put you in a position as
a new person to have to do this organization all by yourself. How was that? It was exhilarating,
I think is the word I'd use to describe it. Having been a past participant in the day of action,
I wasn't totally new to the concept,
neither for the Planetary Society or in general, but it was fantastic. I am just really happy with
how everything turned out. And I'm sure not everybody is completely familiar with what
our Day of Action is, especially after the last few years. We've done this event, but we've had
to hold it virtually, and this was our first time doing it in person again. So what is the vibe of this event? And what are you trying to accomplish?
Well, you do like really small things like change the world and, you know, influence,
you know, government policy and funding for space missions, just really small stuff like that.
The Day of Action, it's our flagship advocacy event. Like you said, we do this every year,
albeit virtual the last two years in 2021 and 2022.
And this was our return to in-person.
And it really is.
We have in this year the same over 100 members of the Planetary Society and our supporters descend on D.C.
to influence legislators at critical junctures in the funding of our federal government and in the direction of U.S. space policy.
I think what's really cool about this is that it gives people an opportunity not just to advocate for space,
but to be put face-to-face with their representatives and have an in-person conversation
about something that they're really passionate about.
So how many of these sessions did you end up setting up with all of our legislators?
Yeah, so like I like to say, democracy is not a spectator sport. It involves showing up. And
over 100 Planetary Society members showed up on September 18th. We had 164 meetings,
which is phenomenal. 164 meetings. That is, it's, I think, across 36 states that those members of Congress represent. That's over half of the United States, right?
And, you know, really can have a tremendous impact on government policy.
And I'm, you know, like you said, I'm based in D.C.
And I talk to these legislators and their staff all the time.
And they're often telling me, oh, your day of action is something that we talk about constantly within
our offices. And the impact that a constituent can have on their legislator is tremendous.
And if you've never participated outside of, say, voting in an election, this is that next step,
right? To actually engage with your member of Congress, engage with your representatives in Washington, and air your concerns, right, or your hopes and desires for
your federal government. That's what the system is designed to do. And it was a fantastic experience.
And in addition to our in-person participants, we had over 300 people participate virtually
in a complimentary session, writing to their members
of Congress detailing what our specific policy priorities are for this year's Day of Action.
It's cool. I always, every year during the Day of Action, write my Congress people about at least
one thing that I care about. And thankfully, we've got a really easy website for doing this kind of
thing. Planetary.org slash action. Right. Of course, I've already signed
all those petitions. So I had to get a little personalized this time. But it's always very
meaningful to feel like you're throwing your voice behind something that you care about.
Here in the United States, we have a really robust system for being able to do this. But no matter
where you live, just voicing that you care about these things to either your family members or
your representatives in whatever country you live in can have a huge impact on the future of space exploration.
And we see it all the time through this event.
We do.
We do.
And yeah, that's a great point you made there about the international component to this
because we don't live in a world, we don't live in a time where there's only one major
space actor.
And a lot of governments have mechanisms, although different
and in different configurations than maybe here in the United States. And, you know, being well
versed in the US system, there's a way that things are done. But there's ways to engage with your
government at all levels, local, state and federal, and across governments, right, influencing within
the European Space
Agency or affiliated countries that their space agency participates in that alliance. And being
able to engage with your legislators, your representatives is a hallmark of democracy
and something that can really influence the future of humanity's presence in the stars.
So what were we trying to influence during this day of action? Because there
are so many different things that we advocate for as an organization, but we must have picked
some key priorities for this event. Well, our timing for this event could not have been better.
Honestly, normally we do this event in the spring. It's usually timed around when the
president's budget request comes out, which is February-March time frame. And it allows us to, at the start of this annual appropriations or funding process for the federal
government, allows us to stake our priorities out. This year, in particular, there is a big
discussion happening in D.C. And you turn on the news, you can see this discussion happening in
real time about the role and nature of the federal government and the process by which we're going to fund the federal government.
And our timing in September of 2023, when there seemed to not be a path forward for funding the federal government in fiscal year 2024, which began just last week on October 1st, which, hey, we're sitting here.
There is a federal government.
We are funding it.
Like, there are discussions and negotiations are happening, which is a great thing to see.
But as we're having those discussions and as Congress goes into negotiations on this full-year budget, we were making sure that our priorities were staked out. And that is portfolio of planetary science missions.
priorities were staked out, and that is portfolio of planetary science missions. That includes our big, you know, high, big ticket items, Mars sample return, right, which is really three flagship
missions wrapped into one, returning those samples that the Perseverance rover has already collected
and cached on the surface of Mars, these scientifically robust samples that could,
of Mars, these scientifically robust samples that really will give us an insight into 3.7 billion years of Mars geologic history.
But in addition to that, right, balance is not just the flagship missions, but it's also
those medium and small missions.
So your New Frontiers missions, you know, think like OSIRIS-REx was a New Frontiers
mission.
So, you know, the next one in that series is going to be Dragonfly,
which is set to launch later this decade to the moon Titan of Saturn. So really making sure that
is supported. This is an octocopter. What's our phrasing for it? The nuclear-powered octocopter
that's going to soar the skies of Titan that represents almost a primordial Earth.
that's going to soar the skies of Titan, that represents almost a primordial Earth.
All the secrets there to this really interesting place in our solar system and supporting that endeavor. Veritas, which we've talked about before on this show, the first U.S.-led orbiter to Venus
since 1989. And then on top of that, making sure that research and analysis funding
gets the funding it needs. All of this comes from that, making sure that research and analysis funding gets the funding it
needs. All of this comes from that decadal survey document. For planetary science, ours just came
out last year. And so sticking to that this early in the decade is so vitally important. Because if
you deviate from that now, it could really change the course that has already been plotted out,
by the scientific community. There's
a consensus around what the focus should be, the foci should be for the coming decade, and making
sure that is front and center for legislators to know that, hey, these decisions that you're going
to be making impact not just that one mission or that one program line, but the entire balance of the planetary
science division and science writ large within NASA. Because it's not just planetary science,
it's astrophysics, right? And heliophysics and earth science and making sure that this decadal
survey process that we go through, that the scientific community goes through painstakingly,
you know, coming up with what the community wants to do for the next 10 years.
It's vitally important for future policymakers at future key decision points.
And this day of action, we are championing that, the decadal survey, championing balance,
and championing those missions that make up a balanced portfolio.
Sample return, Dragonfly, New Horizons,
research and analysis, Veritas.
There are so many exciting missions.
And Neo Surveyor, let's not forget Neo Surveyor,
the planet killer finder, right?
Looking for those asteroids that might potentially at some point in Earth's future cause us harm.
We need to find those.
Yeah, that's been a priority for us for quite a while.
So it was really wonderful seeing that we got support for NeoSurveyor through these previous advocacy events. But even now,
still needs our advocacy along with a lot of these other missions. I know something that I've been
personally on the edge of my seat about is the Mars sample return mission. A lot of us didn't
think that was even in any way potentially on the chopping block. But it is a possible future that Mars sample return could see budget
cuts or even a potential cut entirely. And I know you have given me some hope on this in the past.
So what's your hot take on this? So one of the timing components of all this, right,
of our day of action happening on September 18th, I think it was that Thursday following it,
a major report came out, the Independent Review
Board that had been convened earlier this year to take an independent look at the Mars sample
return program. And note I say program and not mission, because again, it is three missions in
one. It is a lander. It is a Mars ascent vehicle. How cool is that? So cool. And an Earth return orbiter to bring those samples back.
And that report details, or really they were given sort of carte blanche to review and
analyze the Mars sample return program, their plans for the future, and see if it's feasible.
Right?
This is a massive undertaking.
See if it's feasible, right?
This is a massive undertaking.
We have never, ever sent something to another planetary body and returned it, right?
We've never launched off the surface of Mars.
We've done this on the moon, right?
Sample return.
We've done this from asteroids with something like, you know, Osiris-Rex just a few weeks ago.
And Mars sample return is that next big step in Mars exploration. and it's the next big step in just planetary exploration writ large.
The IRB was given carte blanche, meaning they could have gone in and said, this program is unsustainable.
We need to cut it or gut it or cancel it entirely, but they didn't.
cancel it entirely, but they didn't. The IRB definitively came out and said that although there is cost overruns, right, on the current architecture and that they instructed NASA and
JPL to go back to the drawing board on some of the components to make sure that it's robust and
resilient to future changes in whether it's the infrastructure available at Mars, right? We have
the Perseverance rover on the surface that has a shelf life, right?
We have our orbital assets that have shelf lives.
The conditions on Mars vary from year to year, from Martian year to Martian year.
And making sure that whatever we send as a part of Mars sample return is resilient to delays,
resilient to the conditions on the surface,
resilient to the infrastructure available to support the mission. So long as we do all that,
this is still the top priority of the planetary science community. And it has been for the past
two decades. So I mentioned the decadal surveys, the previous decadal survey from 2012, Visions
and Voyages, and the current decadal survey, Origin, Worlds, and Life, OWL, that's how you remember it. Origins, Worlds, and Life, both list Mars sample return as the top
priority. And the IRB is yet another document in that corner saying, yeah, it's going to be
difficult. This is the first time we're ever going to try and do something like this. It's going to
cost money, and we don't know how much it's going to cost right on the outset, right?
And budgets are going to change, and our expectations for budgets will change.
And NASA's keeping a tab on that, and the IRB was keeping a tab on that.
There's some great charts in their report.
But at the end of the day, these are scientifically significant samples that we have painstakingly taken the time to use the Perseverance rover, our assets on the surface, to find samples that are
going to unlock secrets of Mars' geologic history, 3.7 billion years. It blows my mind, right, what
we're going to be able to, even thinking about what we might be able to uncover with these samples.
They're going to surprise us. You know they're going to surprise us.
Oh, they will. And they're going to change, they're going to rewrite textbooks based on these samples. And
this is the greatest undertaking that the U.S. has ever endeavored to do. And it's not just the U.S.
This is an international mission. Let's not forget that. The European Space Agency is providing a lot
of support, not just in the form of the Earth Return Orbiter, but is also a part of the sample retrieval lander in the
Mars Ascent Vehicle.
There's components that are international in every aspect of this program.
And it does a disservice to our international allies.
At a time of great geopolitical tension right now, the U.S. needs to show a strong face
and continue Mars sample return. Yes,
it's going to be a costly endeavor, but doing it in a fiscally smart and sustainable way
is a recommendation of this IRB. And it probably, according to the IRB, not going to happen in 2028,
but we're looking at 2030 launch dates into the mid to late 2030s. There are a number of opportunities.
And the sooner we can do it, obviously the better, but doing it in a way that is fiscally
smart is also of importance to the IRB.
So anyway.
And I think it's always important in these cases where we're talking about budget and
numbers for NASA, just to point out that NASA's budget is a very small part of the federal budget,
something like 0.5%. So a lot of people think that we spend a bunch of money on these space
missions. And if you look at the numbers on paper, it can seem that way in the context of our
everyday lives. But in the context of the federal budget, this is not a huge amount of money that
they're asking for to accomplish something that could literally change the entire way we think of ourselves and our solar system and the history of our solar system.
And on top of that, right, it's a precursor mission to future human exploration.
And the IRB says it as much, that the ultimate goal of the Artemis program, the ultimate
goal of NASA's human spaceflight program is to send humans to Mars.
And this isn't just something that's written down on the back of a napkin right now,
we should send humans to Mars. This is federal policy that NASA needs to lay out a plan
for getting humans to Mars. And this is part of it, right? Sample return. If you can send a rocket there, launch it back into orbit autonomously,
mind you, right? There's a 46-minute delay, right, for the time it takes for signals to travel
between Earth and Mars. You need to be able to do that autonomously with a robot. And that's going
to be really important technology to sending future human missions.
So Mars sample return is in the same way with the Apollo program.
We did sample return as a part of our lead up to Apollo 11.
Mars sample return is that precursor mission to future human missions. We maybe at this juncture don't know what those missions will be called, Ares or whatever name we eventually give them.
They might be the missions in the Martians.
I don't know.
You're right.
This is why it sounds so familiar.
It's a good name.
It's a very interesting name.
And yeah, Mars Sampler Turn is that precursor mission.
And there's an international,
obviously the international partnership component,
but there's some international competition too, right?
The IRB points out that this is of
not just scientific importance, but of national importance, right? The IRB points out that this is of not just scientific importance, but of national
importance, right? Strategic importance to the US. And that's because the Chinese National Space
Agency has also identified Mars sample return as a goal for their space program. And they've
very impressively been able to get to land and operate a rover on the surface of Mars on their first try.
Nailed it.
I love seeing this race to Mars, right? And now it's a race to get to Mars and back.
And that's just going to lay the groundwork for future human exploration, future robotic
exploration. If we're able to do that, imagine all the things we're going to be able to do,
all the technology breakthroughs that we're going to have between now and bringing those
samples back. They're going to enable further exploration of other places in the solar system.
So cool. Thanks for joining me and for helping to do this ginormous thing. You should be so proud
of what you accomplished during your first time doing the Stay of Action. And I'm hoping next
time I'm there with you. And I know Casey will be with us there on the Hill next time, it's going to be an even bigger party than it was this
time. Oh, absolutely. So mark your calendars for early 2024. We're going to be coming back.
Keep an eye on your inbox. We'll be announcing the next Day of Action very soon.
And if you want to know more about what actually happened during the Day of Action,
you can check out Jack's article.
It came out on September 21st.
It's called The Day of Action Returns to Capitol Hill.
I'll put that in the links for this episode of Planetary Radio.
Thanks, Jack.
NASA's InSight spacecraft, which is short for Interior Exploration Using Seismic Investigations, Geodesy, and heat transport, launched to Mars in May 2018 and landed
later that year in November. The lander's mission was to learn more about the interior structure of
Mars so scientists could compare the red planet to all of the other worlds in our solar system.
The mission ended in December 2022, and scientists worldwide have been combing through the data,
including the findings from the
spacecraft's Rotation and Interior Structure Experiment, or RISE. The RISE Instruments
Principal Investigator, Sebastian Lemaistre, from the Royal Observatory of Belgium and the Catholic
University of Louvain, recently spoke with our Senior Communications Advisor, Matt Kaplan.
His team's research suggests that Mars' rotation is speeding up.
Their new paper, called Spin State and Deep Interior Structure of Mars from Insight Radio
Tracking, was published earlier this year in the journal Nature.
Sebastian, welcome and thank you for joining us, and congratulations on the release of this paper
published in the journal Nature that tells us much more about Mars,
especially the deep interior of Mars.
Again, thank you for joining us.
Thanks for inviting me.
It seems that what RISE has told us about the accelerating rotation of Mars,
that might be the somewhat sexier result.
In fact, it was the headline in
the press release that I saw. But really, if you'll pardon the pun, the core of your work
seems to be what you've been able to tell us, what RISE and your team has been able to tell us
about what's happening down inside Mars. So tell us, what have we learned about Mars's core?
So tell us, what have we learned about Mars' core?
So we have learned a lot, not only thanks to RISE, specifically to the picture is
the shape and the size
of the core
that was
very not expected
I would say.
First of all,
the RISE experiment
had as a main objective
to constrain the
very deep interior that we didn't think we could infer from seismic data.
And the role of RISE was to basically monitor
the rotational dynamic of the planet with high accuracy.
And with that accuracy, try to identify
if we were seeing some signature of the very deep of the planet.
And that's what we did.
We needed a lot of time to accumulate a lot of data
because we want to see, you know, arising from the noise,
the signature of the deep interior.
So that was a very exciting work.
Also very, let's say, challenging because the signature we were looking for, so the signature of
the liquid core of Mars is extremely small. So we are talking here about something that corresponds
to a motion of the surface of Mars of about 40 centimeters over a Martian year. So it's extremely small. And we wanted to detect that from Earth
with a radio link between the Mars surface, so between the RISE instruments and the ground
station on the Earth, the DSN station that are well known and that corresponds to gigantic
antennas that are used to track the space props. So we had to accumulate those data over time.
And from that, at some point,
we identified what we call a rotational normal mode.
So something that only exists
if there is a liquid layer beneath the solid mantle of Mars.
And we detected that after hundreds of days.
And then we tried to interpret that. So with colleagues more expert in the geophysics
of Mars, we identified that the shape of
the core was not what we expected. The size was quite
close to what had been observed
using, let's say, quite close to what had been observed using, let's say, other methods like the seismic data or like the tidal measurements.
But the shape was quite different.
So it puzzled us at the beginning.
And we came up with some explanation of why the core looks really much like the core of a liquid planet, if you wish,
a planet that would be liquid rotating on itself, what we call the hydrostatic shape of the core.
So RISE had this specificity of characterizing the core itself, its size, its shape, its composition, its moment of inertia, as we call that,
which is basically the distribution of mass inside the core, the density jump.
So basically the density of the core with respect to the density of the external part of the planet.
with respect to the density of the external part of the planet.
So those are the specific things that rise broad to the picture of Mars interior.
Whenever I talk to someone like you who conducts what we know as radio science,
I am blown away by the exquisite sensitivity.
I mean, we're talking here about using the Doppler effect, right?
But to do this at the level of being able to detect a 40 centimeter change over the course of a year, could this have been done, I mean, years ago, let's say by the Viking
landers in the 1970s or maybe even in the years after that?
Yeah, no, actually not.
And the idea of looking for that specificity of the planet rotation was already in the
minds decades ago, but we couldn't reach that because of the accuracy of the previous data.
So Viking had stayed on Mars and operated on Mars for a long period, which is necessary, as I said, to accumulate the signal and to have a chance to see it.
But actually, the Viking data was using other frequencies, lower frequencies in the signal that were more sensitive to propagation noises.
So these data were not precise enough to see this signal.
And so we had to wait.
And also, I mean, orbiters are also sensitive to the rotation of a planet through the rotation
of the gravity field.
But here, again, the precision was not good enough.
And so we had to wait for a new mission stick and, you know,
to the surface.
And that would be providing data for a long time span and with very high
accuracy. And actually even, even that rise provided us,
even if we, you know, we, we spend years to prepare the mission, even that, RISE provided us, even if we spent years to prepare the mission,
to prepare the models, to implement the softwares, to get ready of what kind of observable we expect,
what kind of ranges we expect, etc.
And in the end, everything was not what we expected.
And also, in terms of accuracy, we didn't expect the spacecraft to provide such a good set of data.
So we had to improve the models of all kinds.
The model regarding the calibration of the data.
We had now to introduce, for instance, models to calibrate the Martian troposphere data noise.
models to calibrate the Martian troposphere data noise and also the dynamical model of Mars rotation had also to be improved too much and to be representative of the data.
We'll be right back after this short break.
Greetings, Bill Nye here, CEO of the Planetary Society. Thanks to you, our LightSail program is our greatest shared
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Thank you.
I always love it when a scientist or engineer tells me that one, their instrument performed even better than they expected after a lot of work, and two, that they got unexpected results, because isn't that the most exciting thing in science?
time that Mars might be so geologically dead that perhaps it doesn't even have a liquid core, which now your data, other data, including the data from that also exquisitely sensitive seismograph,
seismometer, we know that it does. And in fact, it's kind of sloshing around a little bit,
causing these perturbations. Yeah, that's true. That's true that for a while we didn't know.
We expected it from, you know, planetary formation scenarios,
but we didn't know.
And the first clue about the liquid core existence was obtained
from orbiters that measured the tidal signal in the gravity field.
And that was already almost 20 years ago.
And so here we come with a totally different measurement,
something that has nothing to do with tides,
that has nothing to do with seismometry,
and that confirmed this state.
Now, RISE brings something else, okay,
that is still, you know, under study,
which is a piece of answer to the question of the inner core,
what we call the inner core,
which is the solid part inside the liquid core.
We have that on the Earth, and that is a witness, let's say,
or a consequence of the magnetic field that we can see on Earth
and that doesn't exist on Mars.
And so there is this big question of the inner core.
Is there an inner core on Mars, yes or no?
Because there is no global magnetic field.
And we think that there were one billion years ago,
but we don't see anything anymore.
And here we digged into the RISE data to also detect, if any, the signature of such an inner core.
And we didn't detect any.
So basically, our RISE, I mean, it's always very complicated to prove the absence of something, right?
It's easy to prove that there is something, but it's very complicated to prove that there is nothing.
Hard to prove a negative, yeah.
Yes.
I'm not saying that there is none.
I'm just saying that in the RISE data, at least the analysis we've done on it, we didn't detect the signature of the inner core.
Obviously, still more to learn.
Let me turn now to that other headline-making finding by RISE, which is that Mars, its rotation, it's actually spinning faster and faster.
It's accelerating, which is pretty fascinating.
I mean, we would expect from physics, a planet, to slow down, if anything, right?
What is this?
What is going on here?
Why is it speeding up?
And by how much?
Yeah, by how much is by very little, actually.
It's like almost, yeah, let's say one microsecond per year.
So it's very, very, very little, right?
second per year. So it's very, very, very little, right? But if you consider that at geological timescales, then it can be significant. Yeah. And the mass of a planet speeding up. I
mean, there's a lot of energy there. Yes. Yes. Clear. But actually, if you do the math,
you can have many different explanations. First of all, we don't have any clear explanation for that yet.
So we are working on it. But if you do the math,
you can really identify a dozen
or half a dozen of explanations that would be
just a slight change in the shape
of Mars, a slight change in the shape of Mars, a slight change in the thickness of the polar caps.
You know, you can imagine a lot of a few explanations that can really be physically sounded and that can explain what we see.
we could also imagine that there is let's say a glitch
in the data that we
consider to be
associated with
an acceleration and that wouldn't be
I mean
there is a big chance that
this signal actually exists because
first we
once we saw that for the
first time we were really puzzled and so what we did is we used different softwares.
We also looked at it in the orbiter data.
So this is not in the publication, for instance, and we actually see the same
signals. So there is a real belief that
it's there, but we still need to identify
the source.
I want to come back to the possible explanations for this acceleration,
because there's a wonderful analogy. I don't know if it's yours or was added by whoever wrote
the press release, but it was compared to an ice skater. And let's think of an Olympic ice skater
spinning in one position on the ice with her arms extended. And, you know, let's think of an Olympic ice skater spinning in one position on
the ice with her arms extended. And when she brings her arm in, conservation of motion,
angular momentum, she speeds up. So if Mars becomes a little bit taller, right, with more
ice on the pole, you would expect it to speed up a little bit. Do I have that right?
you would expect it to speed up a little bit.
Do I have that right?
Yes, exactly.
That's exactly that.
Indeed, yes.
That's why I was talking about ice accumulation at the pole, because it means that the matter would, you know,
go closer to the spin axis and would, as you say, make Mars taller.
You could also imagine like on the Earth that at some point you would have ice, what we call the post-glacial rebound on Earth.
So basically after the ice removed from the cap, the solid Mars would relax to reshape.
would relax to reshape.
And so would in the same way than what you just said,
would elongate if you wish along the spin axis.
So all these are possibilities. One also is, for instance, the tidal torque from the moons of Mars.
So Phobos, for instance, is one of the two moons of Mars,
which is the biggest one, is falling down to Mars.
And so it accelerates Mars.
We know that.
But in fact,
Phobos is responsible
for an acceleration,
which is three order of magnitude
smaller than what we observe.
So it cannot be that.
We could also imagine that,
you know, you have an impactor
that would have brought
some angular momentum to the planet just by impact,
as the planet basically, you know, when they formed,
they got their rotation speed just certainly thanks to those impacts.
But it's also the first calculation about that show
that it's unlikely because it would require a very big impactor or very many of them, which is very unlikely.
It seems obvious that, and it's no surprise, we have much more to learn.
You had four years of data from RISE over the course of InSight's lifetime on Mars.
Brilliant work by the entire spacecraft team. But are we done? from RISE over the course of InSight's lifetime on Mars.
Brilliant work by the entire spacecraft team. But are we done?
Is there more to learn from not just the data from RISE,
but from the other instrument on this mission,
the seismometer?
So clearly, no, we are not done.
There is a bunch of data that are still, you know, under the eyes of the scientists of the team and of the scientists of the entire scientific community worldwide.
Because now the data are available so everybody can use and process the data.
everybody can use and process the data. For the case of
RISE, the specific case of RISE,
as I said, because it's
radio science, you often need
to wait. It's not an event that you
want to interpret. It's not a picture
of the surface. It's really some
dynamical effects that you want
to see. So you really have to
look at it
once the entire set is there,
which is the case now.
So we have many other, other stuff that,
that we can do that we will do.
That's great to hear. I'll leave you with this.
I'm just curious about how you got into this business of sending exquisitely
sensitive radio receivers and transmitters to other worlds,
because you have worked on so many missions.
It just seems like a fascinating line of work, but one that takes a good deal of patience.
Yeah. Yeah, indeed. Yeah.
I am an aerospace system engineer.
And so at some point I was hired to work on Mars Express,
which is a European mission and on the radio science of Mars Express. So I came to the team in Belgium.
I'm French.
And that's how I started.
Just, you know, because I had the opportunity.
I was not expecting that from my childhood.
I mean, even if I was super interested by space
and aeronautics,
but that's
just a matter of chance, I would say.
And then, from that point,
I mean, I got in love with
the field, of course.
Sébastien, stay in love
and I look forward to hearing
more results from
this data, from InSight and the other work that you are doing from missions all around our solar system, including missions to come like MMX, that sample return mission that the Japanese and an international consortium plan to send to Mars.
Thank you again very much for joining us.
Thanks a lot for your invitation.
for joining us.
Thanks a lot for your invitation.
My guest has been Sebastien Lemaistre,
the principal investigator
for the RISE instrument
on Insight, RISE,
the Rotation and Interior
Structure Experiment.
He's also the lead author
of the paper in Nature
with the results
that we've been talking about.
And we will put up a link
to that paper
on the episode page for this week that you can find at planetary.org slash radio.
Now let's check in with Bruce Betts, the chief scientist of the Planetary Society for What's Up.
Hey, Bruce.
Hi, Sarah. How are you doing this fine and glorious day?
I mean, it's been super fun seeing everyone around the office. It was good hanging out
with you yesterday. It's a weird thing
to see everyone in the real world.
They're so three-dimensional.
I know. That's a trip.
Maybe more dimensional. Who knows?
Did you get to see the annular eclipse,
Bruce? I did. It was
super, super duper cool.
I took pictures.
I watched it. I hang out with my old family and
sons and stuff. And we looked and it did what it was supposed to do. And I pondered. I pondered.
I thought, oh, look, orbs moving relative to one another in the sky that we don't usually
appreciate their movement relative to each other. And then I thought that was almost profound. And then I moved on. It was a moment for me though. I felt like a
superhero. All of my neighbors were outside staring up at the eclipse without eclipse glasses.
And I just happened to be one of those nerds with a full bag full of eclipse glasses. So
I went out there just like, and you get eclipse glasses, and you get eclipse glasses.
But it was a good time, and I'm glad people got
a chance to see that. And now we're all kind of
mentally prepared for the next big
eclipse coming up on April 8th,
2024? Yes.
Yes.
Sneaking up on us. Well, I mean,
time. Keep slipping.
Slipping. Slipping.
Into the future.
And speaking of time, uh, this weekend, uh, international observe the moon night is coming
up on Saturday, October 21st.
Well, time is on our side.
Are you going to go outside and check out the moon?
Uh, I sure.
It's always good to check out the moon.
It's a, it's a underappreciated thing to stare at,
whether it's just with your eyes or with binoculars or with a telescope.
Yeah, moon. Good. It hangs out up in the sky. You're going to go check it out?
I'm considering setting up my telescope and showing my neighbors, that kind of thing,
since I had such a great time earlier this week. But maybe I'll check out one of the local events.
If anybody's interested in finding an Observe the Moon Night event near them,
I'll put a link to the website for it on our page for this Planetary Radio episode,
because there's nothing cooler than just hanging out with strangers
and having a moment to ponder the universe, you know?
Wow.
Yeah.
You had me at hanging out with strangers wow it's been a good couple of weeks
for space nerds i feel between osiris-rex sample return and psyche mission launching
it's just a good time it is and uh they actually things are working really well. So it is exciting and looking forward to Psyche getting out there and seeing some metal.
Metal.
Those pictures are going to be bonkers.
At least I hope so.
I hope it's really cool.
I hope we get all these weird jagged pits where like craters formed on this metallic asteroid instead of it being like really boring on the outside.
And then we'll have to send a mission to excavate down to find the cool metal jagged pits band name i call
it that's fair you can have it as long as i get to be your drummer sure do you know how to drum
a little bit that'll do all right, shall we dive into some random space facts?
So, I'm going to dig into the mystery of the fact that if you look at things more broadly,
the fact that if you look at things more broadly the lucy mission which will encounter an asteroid its first asteroid uh this weekend from when we're recording november 1st 2023 uh why lucy
is named after lucy o'donnell vodden why exactly that's the cryptic look on your face I was looking for. Well, I mean, I've extrapolated. So Lucy is named after the Lucy hominin fossils from Africa that were found because the study of the Trojan asteroids could reveal, quote, fossils of planet formation.
See, there's a fossil tie.
Clever.
So it's named after the strangely
famous old hominid
skeleton. And
that was
named after Lucy
in the Sky with Diamonds by the Beatles.
I was going to say! That's
a great connection. They were playing
it in camp, apparently,
the day they found it. So they named
it Lucy. And Lucy in the Sky with Diamonds
was named after a classmate of four-year-old at the time Julian Lennon who he did a drawing which
he called Lucy in the Sky with Diamonds about Lucy O'Donnell later Lucy O'Donnell Vauden
who has since passed away but that is why I view the Lucy mission
as indirectly named after a British woman named Lucy.
That's so cool.
I remember learning when I was younger that Lucy, the hominid,
was named for that Beatles song, just because I was a huge Beatles fan as a kid,
but that makes it even more special.
And then they'll be encountering Dinkinesh, the
asteroid which they named
for the Lucy fossil.
That will be their first asteroid encounter
coming up, and that's
based upon the Ethiopian name for
the Lucy fossil, which
means you are marvelous
in the Amharic language.
There you go.
Every time there's a name for one of these missions,
it's like you go down the rabbit hole of how it got named,
and it just gets cooler and cooler.
The more interesting little factoids you get about these,
the more I feel connected to everyone who did it.
That's a fun story.
It's fun stuff.
And so I'm looking forward to seeing another asteroid.
It's a 700-meter, I believe, main belt asteroid. Have you got anything from
anyone out there? Yeah, we had a lot of great comments in our member community this week
and in previous weeks as well. But we got a message from Keith Ables, one of our members,
that said, that's so cool. We'll be mining asteroids before we know it. It was in a
reference to the OSIRIS-Rex sample return.
Ah, yes.
Whenever I think about the Psyche mission, I always in my brain tie it to asteroid mining.
I think I've told this story in a previous show, but a little kid came up to me and said that
he was going to be a rich scientist someday.
A what?
And I asked this kid, I'm like, how are you going to do that?
And this kid's like, asteroid mining.
Have you heard of the asteroid Psyche?
This kid was like 10, you know?
So I think go in someplace, that kid.
Apparently Psyche.
Oh, I also wanted to say a few weeks ago, we made a portal reference on the show.
You close out the show by saying that, you know, think of Sarah playing Portal 2, which I've definitely done.
But we had a member, Devin O'Rourke, write into the community and say, oh, my goodness, portal references on this week's Plan Rad, and then sent an emoji of a piece of cake.
It's beautiful.
What reference will we make today?
Who knows?
Maybe none.
We're pretty boring.
We're pretty boring today.
All right, let's take it out.
All right, everybody, go out there, look up at the night sky,
and think about what fossil you would name your child after.
Thank you, and good night.
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