Science Friday - Unlocking The Mysteries Of A Metal-Rich Asteroid
Episode Date: October 25, 2023Last week, NASA’s Psyche spacecraft launched successfully from the Kennedy Space Center. It’s now on a six-year trip to an asteroid, also called Psyche, located in the solar system’s main astero...id belt between Mars and Jupiter. Unlike previously studied asteroids, it’s not composed mostly of rock or ice. The Psyche spacecraft's target is largely made of metal, thought to be around 60% iron and nickel. The mission won’t actually land on the asteroid—all of its observations will happen from orbit, and will involve imaging, spectroscopy, and magnetometer studies.Scientists aren’t sure if the asteroid is a proto-planetary core, or something else entirely. They’re hoping that studying the metal-rich asteroid might help teach them about how planets form. Some researchers are also interested in learning what 16 Psyche might be able to teach them about the possibility of future space mining operations—though this particular space object is too far away and too impractical to attempt any kind of sample return, let alone its retrieval. (Plus, suddenly selling the amount of metal an entire astroid holds would completely disrupt the global market, making it almost worthless.)Dr. Lindy Elkins-Tanton, the principal investigator for the Psyche mission and vice president for Arizona State University’s Interplanetary Initiative, joins guest host Swapna Krishna to talk about the mission and its goals.To stay updated on all things science, sign up for Science Friday's newsletters. Transcripts for each segment will be available the week after the show airs on sciencefriday.com. Subscribe to this podcast. Plus, to stay updated on all things science, sign up for Science Friday's newsletters.
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NASA's Psyche spacecraft has begun a voyage to an asteroid.
Now we are zooming away from the Earth at about six kilometers per second as we turn on all the subsystems and make sure everything works.
And so far, it's just beautiful.
It's Wednesday, October 25th.
But of course, today is Science Friday.
I'm CyFri producer Charles Bergquist.
The asteroid 16 Psyche, located in the asteroid belt between Mars and Jupiter, isn't the kind of asteroid we've studied before.
made mostly of rock or ice.
This one is made of mostly metal, something like 60% iron and nickel.
Scientists are hoping that studying psyche might help teach them about how planets form.
Here's guest host Swaphnakrishna.
Joining me now for an update on the mission and its goals is Dr. Lindy Elkins-Tanton.
She's the principal investigator for the Psyche Mission and vice president for the
Interplanetary Initiative at Arizona State University in Tempe, Arizona.
Welcome back to Science Friday.
Thank you so much. I'm really excited to talk with you about Psyche today.
So we last spoke with you on this program around six years ago when the whole mission was just a future plan.
How does it feel to have it off the ground literally?
It's utterly surreal.
I wonder if you've had this experience where you've been imagining not even really consciously,
but what an event will feel like and what will look like and what kind of room you'll be sitting in and how it will be.
And I've been imagining that casually now for six years.
And suddenly now I find myself sitting in the operations room with the team,
having watched our spacecraft shoot off into space.
And I feel like I'm vibrating continuously between amazement and reality.
So give us the quick update on the launch and the progress so far.
Is everything going according to plan?
Oh, my gosh.
It surely is, I'm so happy to be able to say.
As you said, it's been a roller coaster getting to this point.
so many challenges overcome, but we couldn't have asked for a more perfect launch from SpaceX,
and then the spacecraft did all of its autonomous behaviors, all the things it has to do by
itself without any commands, right, after separating from the rocket perfectly.
And now we are zooming away from the Earth at about six kilometers per second as we
gradually and methodically turn on all the subsystems and make sure everything works.
And so far, it's just beautiful.
Well, now let's move on to the target, 16th Psyche.
Where is it?
How big is it?
Can you tell us a little bit about it?
16th Psyche, an unusual asteroid, really pretty unique in our solar system.
One of just a few that we think are made mostly of metal, as you said, and also have at least a partially metal surface.
By far the biggest of these and the most likely to be structurally intact from its formation.
So the only one like that in our whole solar system out of about, I don't know, a million,
million and a half asteroids in the main asteroid belt, this is the one we've picked. And it orbits
in the outer main belt, so it's often closer to Jupiter than it is to the Earth. It's very far away.
Sometimes space probe travel involves a lot aroundabout routes, swinging by different planets
for gravity boots. How is the spacecraft psyche getting where it needs to go?
Yes. Unfortunately, it's not like in cartoons where you just retain the rocket and use that
propellant to get all the way to where you're going. We get released from the rocket, and then we're
shooting off in a certain direction orbiting the sun, just like everything else. So our spacecraft is
going to swing around the sun and get a gravity assist from Mars and then continue out towards
Psyche. And a majority of the time, we'll be using our solar electric propulsion system,
which is a very low thrust, but continuously run, adds up to a lot of speed. It will take us 5.8 years to
get out to Psyche with one extra circuit around the sun to get that Mars gravity assist.
So will the spacecraft be doing any fails during that time? For example, during the Mars flyby,
are we going to be taken any readings of Mars or anything like that? Or is it just travel time?
For the science team, it's calibration time. That's what we'll be doing. We just turned on the
magnetometer Tuesday, October 17th. That was the first science instrument to be turned on. And it's
working beautifully. And so we'll be calibrating and testing. But the real thing that's,
spacecraft's going to be doing during its first couple of years is testing this technology
demonstration, the deep space optical communications package. This is completely separate from our
science mission. We're not using it for science and it will not be on while we're at the asteroid.
But during these first two years, that team will be testing its ability to communicate back
and forth between the spacecraft and the earth using lasers instead of radio waves. You can put a lot
more data into a laser than you can a radio wave. And so we joke that this is how eventually
will stream Netflix to Mars. Wow. So the spacecraft will get to 16 Psyche in 2029. So what happens
next? What's the first thing we do when we get there? And what's the goal once we get there?
Well, first of all, we'd be taking approach pictures and Psyche will be getting bigger and bigger.
And I always try to remember to remind everyone that we've already written the software pipeline so
that all the images that we get from the spacecraft via the deep space network are going to go onto
the internet for everyone in the world to look at for free within a half hour of our receiving them
because seeing the thing is a huge thrill and we want to share that with everyone in the world
because that's what space exploration is for. So we'll be going into a high up orbit,
an orbit far from psyche as we learn about its gravity field and then gradually we'll step
down closer and closer. And all the time that we'll be orbiting, we'll be using the imagers,
we'll be taking pictures, we'll be measuring the magnetic field, we'll be measuring neutrons off the
surface of the body, and we'll be measuring the gravity field. All those things will happen
continuously. And then when we get to the closest in orbit, we'll also turn on the gamma-ray
spectrum, or this amazing instrument that allows us to measure the atomic composition of the
surface of psyche while in orbit above it. It uses the effects of intergalactic. It uses the effects of
intergalactic cosmic rays striking the surface of psyche and sending up gamma rays that are then
measured by our beautiful crystal in this instrument. It's amazing instrument. So we'll be doing all
those things in an effort to gather all the data together and understand what this object is.
How was it formed? Is it in fact a part of the metal core of a tiny little planet called a
planetesimal that formed just in the first one million years of our solar system? And it was that
melting and formation of its metal core that gave Psyche its big bulk of metal? Or is it, in fact,
some other kind of object, some sort of material that we haven't sampled yet on Earth from the early
solar system? In either case, it'll be an ingredient for our rocky planets as we try to understand
what made our rocky habitable Earth. And so once we get to Psyche, we're going to study it,
but we're not going to land on it, correct? That's right. We've been spoiled with landers and sample
returns. You're thinking about Osiris Rex and Hyabusa and these amazing feats, those spacecrafts visited
close by asteroids. Psyche is much too far away to make that a practical activity. We'll just be
orbiting. And I would add that having never had a close-up photo of a metal surface, we have no
idea what it's going to be like. It's very hard to plan a lander if you have no concept what the
surface is like. So this is a very important first step to understanding those few, but very
important metal objects in our solar system.
Right. And so since we don't know what the surface is like, it's hard to say if we could even
get a sample easily, but would there be any value in getting a sample of this metal for a future
mission, let's say? Well, there are a couple of different values. One is understanding really what the
very first generation of metal cores was made of. The core of our earth is the result of generations
of merging of metal cores of smaller bodies as they collided and joined our Earth,
culminating with the giant impact that formed our moon about 100 million years after the
beginning of the solar system. So if Psyche formed in the first 1 million years, which we think
it did, it's that very first generation. So that would be wonderful. But there's also the
thought that in the future, humans should get our resources from space if we can and protect
our Earth. And so knowing more about what the metals are that are available would also be nice.
But NASA is not doing asteroid mining, and that is not the primary purpose of the mission.
But it sure would be nice to have a sample for all those reasons. But we're going to have to end up
sampling closer by asteroids, not this one that's even at its closest three times farther away
than Mars ever is to the Earth. How many of these metal asteroids are there out there?
We don't know for sure how many metal asteroids there are out there, but there are about nine that we think are likely made mostly of metal.
And they all belong to a class of asteroids called the M class, but I think it's becoming fairly evident that not all the M class asteroids are made of metal.
They could be dense or have a kind of a featureless reflected spectra without necessarily being made of metal.
But there are a lot of question marks there.
So the answer is we don't really know.
This is just the biggest one.
And so when people hear about these big chunks of metal, one of the questions that comes to mind is, how much must that be worth?
What do you think?
Yes.
Back in 2017, when I got the call from NASA that we were selected, that completely life-changing moment, and then spent what felt like the next 48 hours on the phone being interviewed by members of the press.
And PBS NewsHour asked me, well, you could bring Psyche back and sell it on the metals market.
today in January 2017, what would it be worth? And I thought, well, that's a fun calculation.
And just looking at the iron, I can't even remember right now if I included the copper or any of
the other elements, maybe just the iron, $10 quintillion dollars. So multiples of the gross domestic
product, the economy of the entire Earth. Of course, that was a very, very fun thing to calculate,
but it's false in every possible way. First of all, we have zero technology to bring
psyche back. We can't bring it back to the earth. If we could bring it back to the earth,
it would probably be a really bad day for the earth because we have no technology to put it into
a stable orbit. This is an object, the size of Massachusetts without the Cape. It's surface area,
similar to the surface area of California, and it's very dense. But then even if we could somehow
bring the metal to Earth, it would swamp the market and basically be worth nothing. And so that
That dollar value, I think the value of it is, first of all, to interest some people in space
who had not previously been interested in space, which I love. I think everyone to look out and above
and understand our place in the world. But then also, again, I hope that in the future, people will
be getting resources from near-Earth asteroids. And there are a bunch of companies working on
this now. And so I know it helped attract attention to them as well. We talked earlier about what
some of the possibilities for what psyche is, maybe a planetesimal core. Could it have become a planet
eventually but failed somehow? It should have joined the process that made the other rocky planets.
We think that Mercury and Venus and the Earth and Mars were all the result of many, many
additive collisions, you know, sticking togetherness of these planetesimals. Some of them inevitably
would have fallen into the sun if their orbits were perturbed by all this wild outside.
and impacts, and some of them were thrown out into the outer solar system.
And just a few were stranded in the asteroid belt, like Psyche.
So kind of the shrapnel, the leftover of planet formation.
And, yeah, it could well have ended up differently in that itch, like its brethren,
would have become part of these big rocky planets.
You're listening to Science Friday from WNYC Studios.
If there's stuff coalescing into larger bodies, how do you end up with this metal chunk?
Why isn't it more uniform or round?
Well, first of all, I'll tell you what sort of the scientific consensus is about this stuff,
but I'll just add that I think there's an awful lot we don't yet understand about how planets form.
So lots of question marks.
It seems that the very first material in our solar system that came out of the gas cloud, really,
that formed our sun in our planets, the first solids were just little grains, almost like the size of sand or little pebbles.
and they got crushed together by special kinds of gravitational waves or turbulence in the disc
into these bodies called planetesimals, the size of cities or continents.
And some of them, if they formed early enough, like in that first million years,
would have been heated up by the short-lived radioisotope aluminum 26.
This is a very fascinating sleuth story that was figured out around 1950, 1960, that there was
the short-lived radioisotope that was quite hot, hot enough to melt the planetesimals.
So those tiny grains and pebbles, some of them were rock and some of them were metal.
And they would be intimately mixed, a millimeter or centimeter scale.
But once they melted, the metal would sink to the middle and make that metal core
because it's so much more dense than the rock.
And so that's the process called differentiation.
And it's the same structure as our Earth and the other rocky planets with the metal core
in the middle.
But the metal core is in the middle surrounded by rock.
So why does Psyche have a metal surface and seemingly so much less rock than one would expect?
And we think it's because it's been battered by impacts that it ended up having some of its rock broken off or stripped from it in big collisions rather than being allowed to stay in its whole original state.
And another clue to this is that Psyche's spin axis is laying over into its orbit.
And with the Earth and our other rocky planets, the spin axis is more or less.
vertical spinning like a top, if you compare it to its orbit. And with psyche, it's laying over
on its side like a rotisserie chicken. So something hit it really hard and knocked it over. Those are all
ideas. They're models and hypotheses and then one observation that it's knocked over, which does not
mean that our suggestion of how it was formed is necessarily the answer. It's one possibility
that's non-unique among many. And one of the things that makes this so interesting scientifically is
that we're not looking at a whole population. We can't look at a bell curve, like what's the
average thing that happened to these bodies? There's just one of it. And so with only one to
hypothesize about, it's also possible that it was made in a very unusual way. That's part of the
excitement of going. I think we're going to be quite surprised. And is there any specific outreach with
this mission that you're doing? So much fun. NASA gives us a budget that lets us work with students at
two and four-year colleges in the United States. We have a bunch of projects, capstone projects,
and we have some K-12 outreach done by college students, and we have free online courses that anyone
in the world can take on our psyche.asu.edu.orgia website. But the thing I want to highlight is this
art program. Every year we pick 16 students out of a pool of applicants, and we fund them to make
four original works of art. And we have this amazing gallery on that same website. Everything
from cooking and jewelry to painting and concertos and dance. And it's been a tremendous tool for
outreach. And in the end, we've even ended up with done by a professional musician who just really
loves the mission, a heavy metal tribute song for the mission. Those things I love because they
reach so many more people. We first spoke to you six years ago. Back then, it was around six
years from the initial idea for the mission. But now it won't get to the asteroid for another six
years. What is it like to be on a mission with a timeline of decades? I find it surprising every day
that I'm on this journey because I hadn't really set out to have a giant lifelong project.
We've been working on this for 12 years now and we're about halfway. And last year when we did get
delayed for a year and that meant that there just isn't an opportunity to launch to Psyche at any
given month of any given year. It's much harder to get to than, for example, if you're just
launching it to Earth orbit. You can do it anytime, but psyche is much harder to get to. And so the
trajectory we found for this month is a couple of years longer than the other one. And that made me
sad for a while. And I kind of felt sorry for myself and it was very stressful. And then I realized
probably the biggest first world problem that there's ever been is my spacecraft is launching late.
And so I really got over myself and remembered what a huge privilege it is to work on these
things and that my priority was the happiness and health of the team and sharing this as widely as
I could. And so the longevity does not bother me anymore. I see it as an opportunity. So we are out of time.
Dr. Lindy Elkins Tanton is the principal investigator for the Psyche Mission. She's also the
vice president for the Interplanetary Initiative at Arizona State University in Tempe, Arizona.
Thank you so much for talking with us today. Thank you so much for your time.
I appreciate it.
That's it for today.
A whole bunch of folks like
Annie Nero.
Jason Rosenberg.
Rasha Eriety.
Shoshana Buxbaum.
Helped make the show this week.
Thanks to them.
Tomorrow, a conversation about expanding our perspectives on nature
and what we can learn from the natural world.
I'm Charles Bergquist.
Thanks for listening.
We'll see you next time on Science Friday.
