StarTalk Radio - Mars Perseverance, with Jim Green, NASA Chief Scientist
Episode Date: February 15, 2021We’re headed back to Mars – Neil deGrasse Tyson and comic co-host Chuck Nice explore NASA’s Perseverance rover and its red planet mission with NASA Chief Scientist Jim Green. NOTE: StarTalk+ Pat...rons can listen to this entire episode commercial-free here: https://www.startalkradio.net/show/mars-perseverance-with-jim-green-nasa-chief-scientist/ Thanks to our Patrons Nina Barton, Yancey L Sanford, Tyrel Carson, Peter Jacobs, Laura Inger, Samuel Watts, Joshua Allen, Tom Hegedosh, Connor Haberland, and Abhay Joshi for supporting us this week. Illustration Credit: NASA/JPL-Caltech. Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
Transcript
Discussion (0)
Welcome to StarTalk, your place in the universe where science and pop culture collide.
StarTalk begins right now.
This is StarTalk.
I'm Neil deGrasse Tyson, your personal astrophysicist, and we're here with a Cosmic Queries edition.
We love me some Cosmic Queries.
Ain't that right, Chuck?
Yes, sir.
Absolutely.
That's because you collect all the Cosmic Queries,
and I don't know if you bring them to stump our guests,
or do you filter them,
or are they just randomly plucked from the user?
They are actually taken by a randomizer,
so I cannot take credit for
pulling them, which means that
please don't send me your questions
personally.
All right.
So Chuck, today's Cosmic Queries, we're going to
explore the Perseverance rover
of NASA.
This month, we're recording this
in February.
It lands in February, and it was launched this in February, lands in February.
And it was launched, you know, nine months ago,
10 months ago.
And so, but I don't have particular expert.
I know a little bit something about Mars,
but not specifically about Perseverance.
And I think you don't know about either, right?
So we have to bring it. I know about Curiosity.
And I'm not talking about a lander.
All right.
So we've got our friend at NASA, NASA headquarters, Jim Green.
Jim, welcome back to StarTalk.
Thank you so much, Neil.
And Chuck, always a pleasure.
Always a pleasure to see you.
And I was looking at your full bio, and I'd forgotten.
I mean, I remember, but I forgot that you used to be head of planetary science for NASA,
but now you're head of, like, all astrophysics.
Well, I'm just a—
That's badass.
I'm just the chief scientist, so—
Oh, excuse me, chief.
Not just astrophysics.
Chief scientist.
Right.
Defying all categories.
Yes, that's true. So that's badass i'm just saying
that's yeah i've enjoyed that i mean it's really all about uh advising the administrator on
uh new science activities and and wonderful things that are going on in the agency
and the fact that you came to it as a planetary guy means you have good sort of geology
sense as well. So, and if you did planets, it meant you had some good astronomy in there. So
you've got enough of a diverse background to serve the scientific portfolio of NASA. Is that a fair
statement? That is, that is, you know, I've got an undergraduate degree in astronomy.
You know, in fact, I just finished my first exoplanet paper.
Nice.
You know, I've been involved in a lot of planetary magnetospheres and done some solar physics. So I've touched on heliophysics. And of course, one of my favorite planets is the Earth.
That's a good choice.
planets is the Earth. That's a good choice. So this is a Cosmic Queries, but before we get to questions that people have sent our way on Perseverance, just remind us, why is this yet
another rover to Mars? I mean, how many damn rovers are we going to send? What did you not
learn last time that you're going to pick up this time? Well, of course, with curiosity, we learned that
Mars was really quite diverse than what it is today in its past. We explored the past of Mars.
We found out that Mars, four billion years ago, had an enormous amount of water. And the conditions
were such that it could have been habitable. We really didn't know that.
And now we're going to push the next step on that, and that is to go to an area and look for ancient life.
And that's what Perseverance is going to do.
Oh, okay.
So each rover mission stands on the shoulders of the previous mission
in the questions that it gets to ask.
Absolutely.
That's the way it works.
And you have to send a whole new vehicle to do that? Well, it turns out, of course, Spirit and
Opportunity looked so much different than what Curiosity
does. But at the end of
Curiosity's building building we had many spare parts and so i think we had
like 200 million dollars worth of spare parts left over from curiosity it's like an ikea
furniture no that's if you don't know how to build it you have spare parts wait wait jim no
what are you telling me you make a soul a single object, a single thing called curiosity,
and you're telling me they're leftover parts?
This isn't some Heath kit that you bought from Radio Shack.
This is – so what do you mean you have leftover parts?
Well, we have duplicate parts.
Oh, God.
So when we bought –
I'm trying to picture – wait... I'm trying to picture the
engineers, you know,
standing around. It's like this.
Alright, so what are we going to do with this?
Guys?
Does it fit here?
Guys? Any suggestions,
guys, on this?
I'm sorry to interrupt. Go on.
For every one of our missions, no problem. For every one of our missions, no problem.
For every one of our missions, we want to be able, indeed, to have spare parts around or extra parts such that if there's a failure, we can immediately bring in the new part and not worry about ordering or supplies.
Makes sense.
So it's a real critical, real critical thinking.
It's a necessary redundancy.
Indeed.
Wow.
Okay.
You got me there.
Okay.
I'll let you slide on that one.
But that's the last time I'm letting you slide.
And tell me, you're going up there with a helicopter.
So what's up with that?
So one of the elements, one of the important elements of this mission is actually enabling the
future. And to do that, we're going to push the envelope and our understanding of getting around
on Mars. And a helicopter is really a unique idea to do that. You know, so this is what we call a
technology demonstration.
We're going to be able to hopefully drop this helicopter off the belly pan of the rover, drive away, let it unfurl, and then order it to start flying.
And we'll do a variety of tests.
And it will go up and then come down.
And then we'll go up and translate and then come down.
So translate means it will just go horizontally when you say translate in its position.
Correct.
Okay, so Chuck, you know what this would look like if a cartoonist drew this?
The Martians would be watching this, and the rover drops the helicopter out of its belly, and it thinks it was pregnant.
Right.
And gave birth to a flying object. It's like, guys, we're babysitting all of a sudden.
Right. And gave birth to a flying object. It's like, guys, we're babysitting all of a sudden.
So now I'll ask both of you then, what kind of helicopter, if I'm not mistaken, Mars has a different atmosphere than Earth.
So wouldn't we have to have a different helicopter?
Indeed. Indeed. So it's drone-like in many ways. You know, it has a small body, but it has very long, you know, rotors. And they're about a meter, you know, a box like a CubeSat.
You know, it's about 10 or 12 centimeters by 10 or 12 centimeters in a cube.
That enables this then to be lofted and fly great distances, you know, 50, 60, 70 meters before it sets down again.
So, but the real problem is the Martian atmosphere is really thin.
So you have to compensate by having bigger rotors.
Is that the solution here?
And the counter rotation helps the stability so that we don't need a rotor on the tail.
So it's a design feature.
Now, if you can imagine this working, then the next set of missions could indeed leverage this concept and lay down additional helicopters to then survey massive regions up close on the surface of Mars.
So it's what we'd call an enabling technology demonstration
for future missions. Beautiful.
Beautiful. Cool.
All right. Why don't we get to some Q&A
here?
All right. Oh, and one last thing.
Is this landing on Mars the same
way Curiosity
did? It does.
It does.
It looks very Rube Goldbergian, you know, with the drogue chute and retro rocket and who came up with that? Well, the
JPL engineers are some really fantastic jet propulsion labs, jet propulsion lab
engineers, fantastic people that had a long experience in landing craft on Mars.
And the whole concept evolved.
You know, we started with Pathfinder.
And Pathfinder is a platform for which the Sojourner rover rode on.
We landed that, and then the Sojourner rover came off the platform.
And then we had Spirit and Opportunity.
You didn't land that one.
You bounced that one, if I remember correctly.
We bounced it.
We bounced it.
You bounced it with some airbags.
We did.
We did.
And we used that same concept for Spirit and Opportunity.
Spirit and Opportunity.
And they bounced, of course.
And then when we deflated the bags,
the rover sits upright on a platform
and then drives off.
I just loved how low-tech it was
for something to do something high-tech afterwards.
I'm going to say, yeah,
there's something really genius about using a hoppity-hop
to land a sophisticated piece of space machinery.
That's incredible.
You know, for Spirit and Opportunity, we believe it bounced perhaps as much as 30 times
before it actually settled down on the surface,
where we could deflate the bags and then move it off the platform.
So imagine this now. Now we're going to
build a bigger rover. Okay. Spirit and Opportunity are less than 200 kilograms. Okay. And now we're
going to do one metric ton. Okay. So 2,000 kilograms, 1,000 kilograms. 1,000 kilograms. Five times what Spirit and Opportunity were.
Okay.
So the concept is, well, we start out with a platform.
Can we put it on a platform and then figure out how to land the platform?
The problem was the center of gravity was too high.
So if it's on the platform, it's going to flip over.
So now we can't land it on the you don't want that don't want that
i can tell that right now okay so then the next evolution in thinking is okay let's put the
platform on top of the rover all right and that gives it retro rockets all the way down to the
surface and you land it then the problem is how do you get the platform off the rover?
So then the unique idea is let's hover it and lower the rover down to the surface while the platform is hovering at about 20 meters.
So you're lowering it like with a joist or something, right?
Well, yes.
That's called the sky crane.
Sky crane.
Yeah, the sky crane.
And when you think about that, that's a process we do here on Earth with helicopters every day, dropping off cargo, picking them up, going through that process.
So why couldn't we engineer that for a Mars mission?
Excellent.
Excellent. Excellent.
So it's brilliant to know.
I mean, engineers, they live for this, right?
Yeah.
They know what has worked in one application and they modify it, add to it.
I love it. I love it.
So Chuck, what kind of questions do you have?
Hey, let's jump into it.
We'll start with Leslie Murray.
By the way, let me just say Jim, people
love NASA.
Like, you guys
need to
take a little bit more advantage
of the public goodwill
that you enjoy
and get more money
because people love NASA.
Not only domestically, but internationally as well.
True.
Yeah.
Yeah.
I mean, people are so excited here.
It's great.
Anyway, this is Leslie Murray.
This is from Patreon.
Jim Green.
This is a Patreon question.
Leslie does not say.
Oh, actually, Patreon.
Yes, sir.
Thank you.
Thank you very much.
Thank you, Patreon folk.
These are Patreon folk first.
And as we say, we certainly enjoy anyone who supports us on Patreon because we certainly enjoy money.
So thank you.
Chuck.
I'm just being honest.
Please forgive Chuck.
He's still in training in this process. Listen, I'm just being honest. Please forgive Trump. He's still in training in this process.
Listen, I'm sorry.
I don't know how to diplomatically say thank you for giving us money.
It's very hard for me to figure out the proper way to say that.
We'll debrief you after the show.
Okay, good.
All right, so what's that first question?
All right, this is Leslie Murray, a Patreon.
She says this. Jim Green, very excited to ask you if you could have added just one more instrument to the rover, what would have what would it have been?
I love that question. I like this. She says this. Like every rover.
I'm sure this one was on a weight loss plan.
rover, I'm sure this one was on a weight loss plan.
Well, I have to tell you, of course, I was head of planetary.
We'd landed Curiosity, that worked great.
And we began the concept of, well, we need to bring back samples. We need to go and get the rock samples that tell the history of Mars.
We need to bring them back.
And that was the thrust of what Perseverance is going to do and how we were able to convince NASA and the administration and then Congress to support this next move.
So the instrument I wanted that I dearly would have loved to have on it, I actually got it on.
that I dearly would have loved to have on it, I actually got it on.
And that is an audio instrument.
You know, we've never landed on Mars and listened, you know, to the wind, to what we can hear.
And I have two microphones on.
When you said audio instrument instrument you meant a microphone
I know I meant a microphone
yeah cause I gotta tell you Jim
when you said audio instrument I was like
what a waste of money
you sent a radio to Mars
who why not put some
cup holders on it who was listening
who was listening to whatever?
But no, yeah, exactly.
But no, the microphones, that's super cool.
Okay, so it adds another dimension to our senses.
It does.
For what we think of and feel about Mars.
Very good.
Okay.
So, oh my God.
So when this thing lands and you deploy these microphones,
we're going to be able to go to NASA and listen to what Mars actually sounds like?
But even before we land, we're going to turn on one of the microphones during the landing process.
Oh, my God. So we will hear what's going on inside the capsule as it hits the
top of the atmosphere and in huge temperature variation just outside the heat shield is going
on as it's burning away the material on the heat shield and then the sky crane all the way down to the surface. So we turn it on right away.
Okay. Now, since I've been Zooming for 11 months now, I just want to make sure,
do you have a mute button? Because that can be problematic.
Well, not that I'm aware of. We do have an on and off button.
Okay, good.
Our hope is that everything will survive intact and we'll be able to use this engineering microphone as it went over some rough terrain, the rocks were literally breaking the aluminum
wheels, you know, poking through them. And so the engineering microphone is designed to hear the
creaking and the cracking and the moving. And then that's an element of the diagnostic of the
environment that we're in that helps manage the rover and its assets to keep it going.
This is that old story.
You take your car into the shop and they ask you, well, what's wrong with it?
You say, well, it's making this sound and it goes like.
There's the acoustic diagnostics.
In this case, we'll be able to play it.
Play it back.
Just before we go to break, is the carbon dioxide atmosphere such that frequencies will come across differently in the sound?
Yeah, really good point.
Will you have to shift it to like an earth spectrum of audio so we'll actually know what's going on or
just going to enjoy um the higher or lower frequencies commensurate with the well it'll be
lower you know so turn up your bass uh you know the the atmosphere is heavier and you know carbon
co2 is heavier than oxygen and nitrogen and of course we talked about, it's a much thinner atmosphere. So sounds that we
would normally hear as high pitch will be very low. You know, it will be base level. And of course,
once we have that data, we can change the range and enhance it. But I think it'll be absolutely
fascinating to hear the real sounds of Mars based on the atmospheric composition and the it. But I think it'll be absolutely fascinating to hear the real sounds of Mars
based on the atmospheric composition and the pressure.
I think it'll be more fascinating
if you turn the microphone on and you heard,
ladies and gentlemen,
thank you for tuning in to Radio Mars.
Wait, wait, wait.
It'll be, wait, wait.
And now, this is the Martian version of Barry White.
And then it's a frequency so low you can't even hear the frequency.
Right.
So we're taking a quick break.
We're going to come back with Jim Green, chief scientist of NASA.
We're talking about the Perseverance rover on StarTalk. I'm Joel Cherico, and I make pottery.
You can see my pottery on my website, cosmicmugs.com.
Cosmic Mugs, art that lets you taste the universe every day.
And I support StarTalk on Patreon.
This is StarTalk with Neil deGrasse Tyson.
We're back.
StarTalk Cosmic Queries, Mars Perseverance Edition.
I got Chief Scientist James Green.
Jim, just welcome back to StarTalk.
It's always great to know you're there for us.
And NASA has a huge social media presence.
I think your biggest handle there is just at NASA, right?
Yeah, it is.
A squillion followers on at NASA, not only in Twitter,
but especially in Instagram, where you're knocking it out of the park every time you put out something on the universe.
Just congratulations to all of you for creating those images and the social media team for navigating them in ways that the public can embrace.
This really, to me, shows that the public is very inquisitive. I mean, it's an element of our nature
to really try to see
and uncover new phenomena
in new regions
and take new views
of the universe we live in.
Not to mention,
seek out new life
and new civilization.
He left out that part.
Thanks for controlling.
To boldly go.
To boldly go.
Yeah, where no human has gone before.
There you go.
So, Jim, not only does NASA have their handles, social media handles, but you have a podcast with the greatest name ever, Gravity Assist.
Very cool.
What kind of guests do you have on there? Oh, Neil, I have some of the fabulous working scientists that are uncovering some of the
secrets of the universe that, you know, really won't end up in textbooks for many years.
And it's a...
So Chuck, he's compiling the secrets of the universe.
I am. I am.
I'm not telling anybody.
Indeed. Indeed.
Okay. That's what that is.
So I just ended my fourth season and the podcast is called Gravity Assist. Can't lose with that. Okay. Good luck with that. Good's what that is. So I just ended my fourth season, and the podcast is called Gravity Assist.
Can't lose with that.
Okay, good luck with that.
Good luck with that.
So let's move on.
All right.
This is Nathan Hui.
Nathan Hui says, will there be any live footage capturing the Perseverance's exciting landing and maneuvers.
And if so, how will it be recorded and how can we watch?
Thank you and good luck, Nathan.
You know, that's kind of cool because how do you record the thing that you're in unless you have something else recording it?
Yeah, a camera out on a boom or something.
So what are you doing there?
Yeah, right.
So what, of course, happens is we'll begin to unfurl a variety of things.
So one of the first things that will come up will be our major camera.
And this is as tall as a human is.
And this is as tall as a human is.
In fact, if I stood next to Perseverance, I would just be looking into the camera lenses that are on the mast.
This gives us a wonderful opportunity to view the area as a human would.
Okay, but that's after you've landed.
That's after you've landed.
Yeah, that's after you've landed.
You've got nothing for us while you're plunging through the atmosphere?
We do.
We have a whole series of cameras in many different locations. And so what we'll see is we'll see the parachute deploy.
We'll see that.
We'll also see the heat shield drop away and the ground below us come up rapidly.
And then we'll see that view of the ground as we land it with the sky print.
Cool.
Sweet.
Well, that is cool.
I mean, this is really going to be an exciting thing.
Oh, one other thing.
Of course, Mars is many, many light minutes away.
So if we watch this, what we think of as live is really delayed by how much?
Well, light travels, you know, an enormous speed,
but it's still going to take close to 8 to 10 minutes
before we actually get the signal.
Damn, so Mars is like 100 million miles away.
Damn, when this is happening.
Yeah, it's a ways away.
So the whole thing could have just exploded and busted up on landing,
and then we would just sit there and think everything is fine for another eight minutes.
Indeed.
We won't have any knowledge of that. And so that's, you know, what you're bringing up is a perfect point. Everything has to work the first time perfectly. And we can't joystick it. We can't make any mobs. When it hits the top of the atmosphere, it is on its own.
It is on its own.
Very cool.
All right.
Again, a shout out to the engineers who made that work.
Okay.
Chuck, give me some more.
Here we go.
Neil, Chuck, Jim, my name is Violetta.
I am 12 and a half years old, and I have a very important- 12 and a half.
Make sure you got that half in there.
Absolutely.
That's important.
Right.
I am still using halves and quarter years.
What is your advice for the next generation of NASA scientists in regards to space exploration?
We study and dream of now if we expect to one day be the first generation that travels to Mars.
This is a 12 and a half year old asking this.
So that's really cool.
Well, it's really all about following your passion.
Get involved in an element, whether it's engineering or some aspect of the science, and just immerse yourself.
Enjoy it.
And let it lead you to these different opportunities.
Whether it's an opportunity to work in a company or industry or a laboratory that are involved in building instruments or in one of the NASA centers, and even getting involved in building space vehicles for humans.
And just to be clear, NASA collaborates with companies like Lockheed Martin and Boeing
and other places to build spacecraft.
So NASA doesn't build all their own spacecraft and space programs, correct?
Right.
Right.
All their own spacecraft and space products, correct?
Right.
Right.
For Perseverance and, of course, the Ingenuity helicopter, we built those.
NASA did build both of those.
But it required instruments to be built by many different groups and universities.
Okay.
So what that means is what we think of as NASA's budget goes not only to NASA, but to innovative corporate companies, engineering companies that also do work in the service of NASA.
So they would get a paycheck that's not signed by NASA, but signed by their own company.
But ultimately, it came from all of us supporting that enterprise.
Did I capture that accurately?
Yes, you did.
Okay.
All right.
Beautiful, beautiful. What you're saying, Jim, is that it's one thing to say, oh, they're doing this now.
Let me train so I can do that when I'm their age.
That's one thing. Another thing is I am so passionate about this thing, whatever it is, maybe it's my passion that will create an opportunity that doesn't even exist there today.
Yes, indeed.
That is really the case.
Okay, so just want to make it clear.
Yeah, to dream big and then follow your passion, follow your dream.
And then maybe other people will beat a path to the door of your passion,
and then you'll be the leader, the next leader of the science at NASA.
That's right.
And have a badass business card.
Yeah.
All right, Chuck, keep it coming.
All right, here we go.
This is Toby Sonnenberg, who says,
Hey, Neil and Jim, how can NASA predict which rocks may hold signs of an ancient biochemistry if that biochemistry is completely alien to us?
I think, yeah, that there may be some assumptions being made in that question, but still, yeah.
No, no, they're excellent assumptions.
So, Jim, if we're looking for life as we know it, are you going to miss life as we don't know it?
As we don't.
Wow.
Indeed, we don't want to just look for life as we know it.
We need to be open-minded.
And that requires getting the samples back.
The ancient history of Mars is in that rock record.
And we're going to, you know, create it.
that rock record and we're going to, you know, create it.
So a core is basically a cylinder that you extract from the object and then you have the full record of layering within it.
That's right.
So somewhere in this time history, life may have arisen on Mars.
All right.
life may have arisen on Mars.
All right?
So now we have to bring this back because we can't in any way interrogate this sample on the surface of Mars.
Where were you on the night of July 10th?
You can't use the word interrogate in front of black people.
They have a whole other understanding of that word.
Okay?
Sorry.
Not your fault.
Not your fault.
I'm just saying.
Oh, God. That was funny.
Okay.
Oh, God.
You're interrogating your core sample.
Go.
Yes.
To do that analysis,
you know,
we then want to put the core in a sleeve
and then we'll lay it on the ground for later pickup by another mission.
And so we're actually planning now to pick up the sticks, to pick up the cores.
Yeah.
Brilliant.
We're building a Mars Ascent vehicle to bring it back.
Now, the analysis of the rock record is forever.
If we get it back here on Earth, we can interrogate it.
We can create theories on, hey, we might see different types of life than we expected.
The record is here to continue that discussion and then eventually prove your theories or disprove them.
And tell us about what Mars could have harbored life in its
past. Wow. So at the risk of stating the obvious, the geologists can see back in time simply because
the stratification of geologic forms and structures preserves that. And that is their
analog to what we do in astrophysics,
whereas we look out in space, we look back in time, because light takes time to reach us. So
the farther away we look, we can see a thousand years into the past, a million, even a billion.
So I've always felt geologists were our kindred souls. One looks down, the other looks up
in this exercise of decoding the history of nature.
So in the same analogy, astrophysicists look at different
frequencies of light because it tells them different things.
When we bring this rock record back, we're going to use different
instruments to determine the
mineralogy.
In other words, how material is put together.
The composition of what those nodes are in the mineralogy.
The state of the matter in terms of what we call isotopes.
And so now we can interrogate all those different dimensions because we have the rock record
right here at home so it's a bit of so it's geochemistry geochemistry yes all in yeah
so neil uh do astrophysicists ever interrogate the light that they find from we there when
they're studying one day one day we will do an explainer video of all the stuff we extract from light and it is a stupefying
amount of information contained within light yeah yeah yeah we'll do that chuck remind me
no use holding out on us x-rays we know what you did okay
we know where you've been
you gotta watch out for
you're right over your shoulder there.
All right.
Give me another question.
Maybe we can squeeze one in before we go to the break.
This is Rob Carter.
He says, hello, I was wondering what protection this rover has from the Mars fine dust
after the Mars digger issues last month.
This is somebody who's following along, that's for sure.
After the Mars digger issues last month, this is somebody who's following along, that's for sure.
Is there a way of stopping the dust from gathering on the solar panels?
And if so, what's another major issue that the rover will have to overcome?
And we will only learn about that after the commercial break.
See what I did there?
Stay tuned, Rob. Stay tuned.
See what I did there?
Stay tuned, Rob.
Stay tuned. When we come back, more cosmic queries on StarTalk, all about Perseverance on Mars. Hey, it's that time.
Time to give a Patreon shout-out to the following Patreon patrons.
Yancey L. Sanford, Tyrell Carson, and Nina Barton.
Guys, thank you so much for the gravity assist that allows this show to traverse the cosmos.
Without you, we couldn't do it.
this show to traverse the cosmos. Without you, we couldn't do it. And for anyone listening who would like their very own Patreon shout out, please go to patreon.com slash StarTalk Radio
and support us. We're back. StarTalk. Cosmic queries. Perseverance perseverance speaking of perseverance i i had nothing to
do with this show but i gotta say it this morning took my 92 year old mom to get her
covid vaccine yay that is amazing wonderful up at harlem hospital so uh so there it is 92
and she's ready she's ready for more She's ready to rock and roll now. Rock and roll.
She's ready to rock and roll.
She's like, Neil, where are we going?
Where are we going now?
Let's go.
Where are we going?
We can get out of the house.
I said, I don't get my shot yet, okay?
My category hasn't come up yet.
Okay, so Chuck, give me some more questions for Jim Green, chief scientist at NASA.
Okay, so when we last left off, Rob Carter had asked about the protection of the Mars rover from the very fine dust of Mars, citing the digger issues of last month.
I don't know what that is.
And then he says, is there a way of stopping the solar panels from gathering dust as well?
the solar panels from gathering dust as well? And what other issues have you foreseen that the rover will overcome? So those are all of his questions.
So indeed, Perseverance looks just like Curiosity, and it has its own power system.
It's using radioisotope power. It's using plutonium-238. And plutonium-238 is really hot.
You put this against a thermal couple, which creates a voltage difference, which charges a
battery. And then it's like having your iPhone plugged in the wall all the time. All your
instruments work. So this can be coated with dust. We don't care because we've brought our own power supply.
And you work at night as well, right?
It doesn't matter if the sun is up or down.
Okay.
Yeah.
But what's really exciting from the question,
I think your listener is interested in what's happening also with InSight, which has
solar panels. And the solar panels, of course, will accumulate dust. But one really exciting thing
that this InSight, the name of the lander on Mars, is seeing is the dust is being blown off.
And it's not from, you know, the twisters that it has seen,
Spirit and Opportunity does, but it's from the same phenomena.
It's just not visible.
So the atmosphere has these vortices that indeed blow the dust away,
and we don't need a dust devil to do it.
Well, okay, but how about the machinery and the moving parts?
You know, you can't bring anything to the beach here on Earth
because sand might get in it, and that ruins everything.
You certainly don't want to ride a bicycle on the sand.
So won't the dust get inside the moving parts, and isn't that bad?
Well, that's a good point.
But indeed, the rover is really sealed well.
And the compartments that it has, like Curiosity, would be meant to acquire material and then shut off.
So we don't see that as a problem.
You know, it's like keeping your windows up and your car doors shut.
All right. And you can operate well inside, even during snowstorms.
Remind me what InSight was.
InSight is a lander that landed on Mars in November 2018
and deployed a seismic system that allows us to hear Marsquakes.
Cool.
And it's measured over 500 of them since then.
Marsquakes.
Indeed.
And this is telling us a lot about the inside of Mars
and the fact that we now believe that Mars,
at least partial part of the core, is liquid.
We didn't know that before.
Very nice.
Chuck, keep going.
All right.
Let's go to Mikey Taylor from Illinois.
How do rovers, most sensitive instruments, survive entry?
And is there a chance that they could be damaged? I like that.
Yeah, that's a really important question because we now know that we have to build them to be
rugged. So understanding that right off the bat is critical in developing the right capability to survive what we call the vibrations and the loads
that occur by moving quickly you know so there's the launch sequence and the shaking of the rocket
and and moving at high g and then there's the landing you know where we're going to go from
the top of the atmosphere to the surface in seven minutes,
going through various loads.
So once you know that, you have to design it and build it that way, and then test it.
So you have a bunch of shock absorbers for everything built into the structure of the system, right?
Otherwise, the accelerations will be felt directly by the instruments themselves.
You want to absorb that away somehow, I guess.
That's the task.
Well, that's one method of doing that.
You know, yeah, other methods are let it shake,
and then you have to build it such that it will withstand those vibrations.
Oh, okay. It's stabilization kind of.
Nice.
I hadn't thought of it.
Forgive me. Stabilization kind of. Nice. I hadn't thought of, I hadn't, forgive me,
I hadn't thought about build the sucker so that it can shake and bake.
And then it doesn't matter.
Then you don't have to waste weight on building cushions for it.
That's interesting.
I like that.
I like that idea.
Okay.
Cool.
All right.
This is ST20IC says, will this take better quality photos?
So are we talking iPhone 5 or iPhone 12 Pro?
What are we looking at?
What are we looking at photo wise?
Well, we're indeed looking at the beautiful Mars photos in higher resolution.
We're also having high resolution cameras on the end of the arm so that we can get up really close to the rocks, hit them with x-ray, look at the glow and image that
and really understand a lot about the mineralogy and the composition before we
decide to drill a hole and bring back that sample. Wow. Wait, is that that famous alpha proton x-ray spectrometer? Yeah, it's similar.
This is called PIXL. It's designed to zap the rock with x-rays, let it fluoresce, but also image it,
also image that, okay? So is that an acronym for something? PIXL? Yeah, because i'm going to tell you something in the name department you guys are losing alpha proton alpha proton uh x-ray spectrometer the geologists love that instrument
because it sounds like it sounds like my tax dollars went to do something
you know you you gotta you gotta hype it up j got to hype it up. You can't just be like, so we got this great technology.
It's called Pixel.
You know.
No.
You got to hype it up.
You know, we got to be great.
Make it sound like a diabolical weapon on Batman.
Right.
Alpha, beta, you know, bio, aqua, do loop, something.
All right.
So this instrument sits on the end of the arm and fires a ray gun at really high intensities,
glowing the rock, heating it up,
and letting it tell us what it's made of.
Give that man an extra billion dollars just for that sentence.
There you go.
We're going to call it our photophaser spectrograph.
Photophaser.
It's our photophaser spectrograph like something.
Yeah.
Just make it sound like something that would be on Batman.
Out of Batman's utility belt.
It's not the ray gun on stun.
You know, it's on kill.
It's on vaporize.
Yes.
There you go.
Vaporize.
Nice.
All right, Chuck.
We're in lightning round mode right now.
So how many questions you can get through?
And Jim, you're in soundbite mode.
Okay.
Okay.
Here we go.
Samuel King.
Samuel King wants to know this.
Tell the truth.
Jim, is this one of the first steps to terraforming Mars?
Could be. And the reason why is we're going to learn so much about the environment
that we'll then take that knowledge to terraform Mars.
Ooh, okay.
Foundational knowledge.
I like that.
Good soundbite, too.
Got A-plus on that soundbite.
Nice.
Okay, Chuck, give me another.
All right.
All right.
Seishio Shiro wants to know this.
How do you guys pick the right place to land?
We want to go to the best place where we can get samples,
and that's why we're going to a delta,
an ancient area on Mars where water and sediment is landed on the bottom
and created rock.
A delta like the Mississippi Delta.
Mm-hmm.
Guaranteed to have layers.
Yeah.
Because it's been sedimented.
Sediment.
Nice.
And implicit there is, of course, Mars has deltas, right?
This is an interesting fact, all right?
Yeah.
Delta's enough for you to pick one to land on.
Okay.
Keep going, Chuck.
That's why I love the Martian blues.
Okay.
So Selku Kilman-Wan says this.
What will happen to the other rovers?
Will they just retire and leave it there as space trash?
All rovers and all instruments that are working on Mars, we want to keep them working.
Keep making new and exciting discoveries until they die.
And they will be there for us to explore as humans when we land.
And in fact, you might need those to beam signals back to Earth the way...
Matt Damon did.
Matt Damon, Mark Watney.
Was that his name, Mark Watney?
Yeah.
Yeah, Mark Watney.
So you need those.
Yeah, yeah, you need those in case you have to rewire them
and send signals back to Earth.
Of course.
Duh.
Okay, Chuck, keep it going.
A couple more.
We've got time for a couple more.
This is Beer Games, who says,
Hello, will this rover be responsible for any preparation for humans to travel to Mars?
So, I mean, yeah.
The answer is yes, because we have an experiment that brings in the atmosphere and creates oxygen that we can breathe.
Ooh. Ooh.
It's called the oxygenator on the movie, The Martian,
but we call it Moxie on Perseverance.
Oxygenator sounds a little better.
I was gonna say, once again,
you guys gotta work on these terms, man.
Work on, yeah.
Oxygenator sounds way better.
Yeah, exactly.
We have to turn on the oxygenator.
Yeah, oxygenator sounds way better.
Yeah, exactly.
We have to turn on the oxygenator.
Yeah, and we'll be back to get it.
So what you're doing is you're breaking apart the carbon dioxide molecule.
Right.
Right.
All right. This is Chris Cherry, if you want.
Chris Cherry says, what is, for this mission, your chief and primary goal?
And what is something you secretly hope to discover?
We want to search the past from the rock record to see if Mars could have supported life.
And my secret wish is that we find it.
Okay. Well, like a fossil bone sticking out of the rock? I mean, what do you, what do you, what?
So a creature that crawls out from under a rock? No, we don't anticipate getting fossils.
I don't anticipate getting fossils, but the chemical composition is just right for which there's potential cells or microbial indications that life could have survived on Mars early on in its history.
Okay. All right.
I'm going to take host privileges and ask you one last question.
We launched Perseverance to Mars, was it June, was it?
July.
July. July.
July.
And did anyone else launch at around that time?
Because, you know, this is the months over which Earth and Mars are nicely configured for just that kind of journey.
And can we shoot them down if they do that?
Well, we have the lasers, but they're going to be used on Mars.
Every 26 months, Neil, you're right. Everything
lines up where we can launch from Earth and make it to Mars as fast as possible. But we are not the
only nation going. So the Chinese have launched a mission to Mars with an orbiter and a lander
and a rover. All right? And in addition to that,
United Arab Emirates has also launched a mission that will get into orbit
and make atmospheric measurements
and image the surface.
So the road to Mars is open and it's busy.
I love that.
And are we collaborating?
Are we sharing information with everybody?
I mean, you scientists all love each other.
So, I mean, is that happening or is it more like governments?
No, indeed.
Everyone knows about the other missions.
We know when they're going to launch.
We know how they're going to operate.
You know, for instance, Perseverance is going to be dropped right onto the surface.
You know, we're not going to get into orbit.
So it's like hitting a golf ball in New York and having the ball go in a hole in L.A.
You know, it's just one straight shot.
The Chinese have a different approach.
They will first get in orbit, spend some time there,
and then drop their capsule with their rover down to the
surface at a later time. Everybody has different tactics. They're different tactics, yeah. Cool.
Okay, so this is great. And it's a reminder that science really, at the end of the day,
knows no national boundaries because it is the one true unifying language, not only of us all, but between us and what might be aliens that we greet one day,
because they will surely be using the same science we are
to get around the house and around the backyard.
And that's great as long as America wins.
America.
America.
All right, we got to end it there.
Jim Green, great to have you back on StarTalk.
Anytime, Neil.
Excellent.
Thanks, Jim.
Chuck tweeting at ChuckNiceComic.
Keep that going.
Thank you, sir.
Yes, I am.
All right.
Neil deGrasse Tyson, your personal astrophysicist, as always bidding you to keep looking up.