StarTalk Radio - Protecting Earth from Asteroids
Episode Date: March 18, 2016How can humanity escape the fate of the dinosaurs? Find out when Neil deGrasse Tyson interviews Apollo 9 astronaut Rusty Schweickart, co-founder of the B612 foundation, devoted to protecting Earth fro...m asteroids. With co-host Eugene Mirman. Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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Welcome to StarTalk, your place in the universe where science and pop culture collide.
StarTalk begins right now.
This is StarTalk. I'm your host, Neil deGrasse Tyson, your personal astrophysicist.
And I also serve as the director of New York City's Hayden Planetarium, right here in New York City at the American Museum of Natural History.
And we're featuring my interview this week with Rusty Schweikert.
He's an Apollo 9 astronaut, a genuine Apollo-era astronaut,
and he's been hell-bent on trying to prevent humans from going extinct,
preventing Armageddon by trying to deflect asteroids.
And of course, I need some comedic help in this one.
So Eugene Merman, welcome back onto StarTalk.
Eugene.
Thanks for having me.
So what you've been up to before we get Cosmic?
So I just read in the news that you released a nine-album comedy track.
I released a nine-volume album that's also seven LPs, and you can buy it in the formats.
LP? What year is this? What are we talking about here?
2015.
Oh, so...
The vinyl is getting more popular.
No, no. Okay, so you have comedy for audiophiles.
Comedy for audiophiles, exactly. And there's a volume of sound effects. There's all sorts of stuff.
Okay. I'll have to look for it. I didn't believe it when I saw it.
It's true. Everything about it is true.
Everything that I've read is true.
Gosh.
So Rusty founded what's called the B612 Foundation, and it's private and not for profit.
And all it's trying to do is protect Earth from killer asteroids.
That's all it's trying to do.
Are there, like, how many, how common is this?
There are squillions of them.
No, no, there's tons, but how many are killer?
We don't know.
We know the worst of them out there.
We know where they are and how many there are,
but that might not be the biggest problem because for every one that would render us all extinct,
there are 10 others where they could just totally wreak havoc with civilization.
Okay. Yeah, yeah.
Both sound bad.
Exactly. Now, Rusty Schweikert, he
was in Apollo 9.
People, it's a forgotten Apollo mission.
Apollo 8 were the first people to leave Earth
and go to the moon. They didn't land,
but they went to and took that famous photo
of Earthrise over the moon.
They went near the moon. They went and orbited the moon, but they went to and took that famous photo of Earthrise over the moon. They went near the moon.
And orbited the moon. But Apollo 9 stayed in Earth orbit
to test more apparatus
before Apollo 10
actually went to the moon and also
didn't land. And then Apollo 11
they landed. So what people
forget is these weren't just single
missions boldly going
where no one has gone before from the beginning to the end of the trip.
Every piece of that was tested and verified so that we can protect human life and make it a fun discovery.
Glad they did.
They did it safely.
Not the way I would have gone to the moon.
So he's now retired, of course, as an astronaut.
And he's a business executive.
And he's worked
in satellites and telecommunications, so he's sort of stayed and he's had a foot in the
satellite world, and he's also founder and past president of the Association of Space
Explorers.
Do you know who that is?
That's an exclusive club.
Yeah, you remember?
I think it's only people who have explored space or people who want to.
Yes, exactly.
Yeah, none who wants to.
So it's like less exclusive than presidents of the U.S., but more exclusive.
Yes.
Yes, because there are only how many?
44.
Whatever the number is, right.
And this is in like 500 and something.
And it's international, of course.
Oh.
Yeah, yeah, of course, of course.
Great.
Cosmonauts, too.
So he co-founded B612 Foundation back in 2002, along with a friend and colleague of mine, Pete Hutt, who is an astrophysicist.
And he's also brought on the U.S. astronaut Ed Liu, another friend and colleague.
These are all astrophysicists coming to bear on this.
Who've also been in space.
Ed Liu's been in space, but not Pete Hutt.
Not Pete Hutt.
And there's also another one of my colleagues, Clark Chapman,
who's a planetary scientist. So you have all the
right people who know how to think about the solar
system and protect us from it. So let's go to the
first clip of this interview that I
held with Rusty Schweiker
and just see where he's coming from and why.
B612 really
came out of, actually out of an ASC meeting, an Association of Space Explorers meeting, where Franklin Chang-Diaz, you met Franklin?
Mr. Innovative Propulsion Guy.
Right, VASMR engine.
VASMR engine, plasma engine.
It's a plasma, magnetoplasma engine.
And at one meeting, Franklin gave us a lecture on the status of his VASIMR engine development.
And at the end of his presentation, we're all saying, you know, what do you use it for, Franklin?
How do you see Envision using this incredible, unique breakthrough engine?
And among the things he threw out was pushing an asteroid.
And we kind of looked at each other and said, that could be useful.
And we had a lunch.
After the lunch, all of us looked at each other and said, hey, if anybody picks this up and does anything with it, let's all call one another. And so Ed Liu
was giving a lecture at Princeton Institute for Advanced Studies in 2001 and got together with
Pete Hutt, who was up there, astrophysicist. I was there at that time. You were there?
Yeah. I attended his talk. They got talking about it, and they decided in the end to call a meeting at Johnson Space Center that Ed hosted in the fall of 2001 in October.
This was after 9-11.
The issue was we all knew the people who were there were very sensitive to and aware that we were finding more and more asteroids,
and yet nobody was doing anything about, what do you do about it?
Sooner or later, we're going to find one.
It's a collision course.
Yeah, at some point.
We're going to find it.
But nobody's even thinking about that.
The two immediate questions were, number one, can anything be done about it?
And we took about two days.
And it was clear that, yeah, if you knew about it early enough, yeah, you could do something about it.
And then the second question was, can we do anything to bring that something about that was you got to form an
organization you can't just do it by thinking so that's that was the origin of b612 foundation
cool and we named it b612 because in ed lu's kitchen afterward he and pete and i were sitting
around you know drinking beer and we're saying what the heck do we call this thing?
And Pete said, I think that the little prince, number one, the little prince came from an asteroid.
But I think it had a name.
And so we went on.
Dig it up.
Before Google, we went on the Internet.
And Pete, sure enough, found that it was B612, was the little prince's asteroid.
And so we decided to name it.
That is so cute.
It's cute, yeah.
B612, that's the cutest thing you ever heard.
So the author of The Little Prince is Antoine Seine-Chupere,
who's a highly literate, poetic even, aviator.
So he got to describe his experiences back in the day
when very few people ever flew
or saw what a cloud looks like from above.
And so he's written some of the most compelling statements
about what it is to explore and to go where you haven't been.
And a little bit of that is in The Little Prince
because he hangs out on an asteroid.
So it's a little obscure, and you've got to be
sort of child book literate.
It has been explained.
And so,
yeah, have you ever
worried about getting hit?
Yeah, I mean, I kind of, I'm glad to know
I figured someone like Rusty
was out there figuring something out.
You hoped that, you expected that
to be the case.
I was like, I'm a little worried,
but some people who have a better sense of it
are probably like, oh, I think I have a plan.
Though I didn't think the plan,
it sounds like their plan is to attach engines
to asteroids and fly them away.
We don't have a plan yet.
It's an idea.
It's an idea.
Yeah.
Right.
We have ideas for plans.
Because if you blow it up,
little parts will come and destroy all of it.
So there are complications in almost all of these scenarios.
But I don't know if viewers know the difference between a meteor, a meteorite, and a meteoroid.
Do you know the difference between all of them?
I think one is one that has already crashed and destroyed Russia and one that is on its way to destroy it.
That's the difference.
I think one is one that's on Earth and one that's heading toward Russia.
Yeah, so a meteorite, after it hit and you pick it up, it's a meteorite.
Right.
Right.
And by the way, I think there are too many words for this stuff.
It's unnecessary, but we have it anyway.
So here they are.
So if you pick it up and it fell from the sky, it's a meteorite.
While you observe it moving through the atmosphere, it's a meteor.
Yeah.
And usually it's going so fast
it's rendered a glow as
its kinetic energy converts to thermal energy.
A shooting star, but it isn't really a
shooting star. No, no, no. Yeah, it's not like
a shooting star. It is what a shooting
star is describing. Right, right. Yes. And of course
it's not a, or a falling star.
It's fun to watch what things get named
because they're reminders of how much, how
little we knew about what the hell we were talking about.
Yes.
It was named when people were just like,
I wonder what that is.
I think we're being attacked by stars.
Falling.
They're falling out of the sky.
There's also a part of the Bible in,
in revelations where it describes one of the signs of the end of times is the
stars fall from the sky and land on earth.
Oh yeah.
And then the first time people noticed,
I guess, meteors, they must've been like, Oh, this is the end of times. And they were like and land on earth. Oh, and then the first time people noticed, I guess, meteors,
they must have been like, oh, this is the end of times. And they were like, wait a second, no, it's not.
Somebody figured out it was not.
And one of the most famous ones of recent past, Russia's got both of them.
One happened in 2013 in, was it February, just earlier in the year.
It blew up in the sky or it hit?
Yeah, it was a sky blast
and the shockwave shattered windows
and people got lacerated from the,
yeah, about 1,600 people.
I call it the Band-Aid
because no one died,
but what an awesome shot across a bow that is.
Right.
That made people go like,
Rusty, what's our plan?
What is the plan?
Yeah.
And so that happened near the town of Chelyabinsk in the Urals of the western edge of Siberia.
And one back in 1908, Tunguska, that's a real famous one, another air blast, but it incinerated 10,000 square kilometers of forest.
The air blast and the energy from it did that.
Why aren't we weaponizing this?
airblast and the energy from it did that.
Why aren't we weaponizing this?
And so that area, that 10,000 square kilometers that got destroyed by the Tunguska blast,
it's about the size of the San Francisco Bay area.
And so that's bad.
I mean, if you can incinerate trees in Siberia, then we're all at risk.
Right, right.
Yes.
Then it would also probably hurt a city. If those had better aim that's just what what what would happen if we if there was a
even more vengeful god and so uh what do you do with these do you blow them up do you deflect them
and the reroute them yeah yeah well that's what deflecting would be is a rerouting essentially
well i guess i think of deflecting as away from Earth and rerouting as like, I hate that guy. Oh, okay.
Well, in space, it's
tantamount to the same thing. Okay.
So, an interesting question is
if you go to deflect it, suppose
you fail, it's going to hit like
the United States, let's say, and then we deflect
it, and then it doesn't deflect
completely. Right. And then it hits.
It goes to like Ottawa. Not Montreal.
Let's not get crazy, but it's like ottawa
and that's not good either so let's find out what kind of thinking rusty has already done on this
subject check it out in order to eliminate the risk to everyone there are nations who will have
to accept a temporary increase in their risk in order to enable that elimination of the risk for everyone.
You can't avoid that. When you deflect an asteroid, you shift the risk profile from where it was going
to impact across a bunch of countries on the way to getting that impact point entirely off the earth
in either that direction or the opposite direction, right? And therefore, you've got this geopolitical
binary decision to make. Do we make it pass in front of the Earth or do we make it pass behind
the Earth? So if I have NASA and I'm the big man on campus because I got all the rocket engines
and I'm going to push it so that it doesn't hit the United States. Maybe. How are you going to
tell me to not do that? Well, by having this a collective decision of the international community.
And we don't know, again, we do not have the answers.
It's not as if the ASE, in taking this to the United Nations, had the answers.
We have the questions that they've got to face.
And we're rubbing it in their nose.
And they might not have thought about this because they don't know about orbits
or anything.
They will not have thought about this because they don't know about orbits or anything. They will not have thought about it. And what we're doing is clarifying the
nature of the decision that somebody is going to have to make. And because it involves nations
across the whole planet, it's got to be the collection, the international collection of
nations. Now, how you do that, you've only hit one problem. Who does it? If one side of the line
goes across Russia and the other end of the line goes across the United States,
which way do you push it when you've got the U.S. and the Russia as the big dogs, right?
But it's got to be a collective decision, and you base that, let's say, a possible criteria, which we've identified.
I can't even think of one other than that it's our rockets.
No, no, no, no.
Well, cost.
It could be very cheap to move in one
direction very expensive to move it in the other it could be that it takes less time to move it
across one way good the other way it could be could be that the other country's my enemy it
could be that the pop no no because we're all we have to make this collectively so there aren't
enemies okay we're all together in this thing how How nice for you to think that. We are. We really are.
The other one is integrate the population
on that red line one way and
integrate the population on the red line the other way.
Integrate mathematically, not
culturally. Yeah, integrate mathematically.
When you say integrate a population, normally that doesn't
mean perform mathematics.
Count.
Add up. You say it to me.
Some. Sigma people. okay that that's a sensible
impact that that's an interest i wouldn't that's so obvious and i'm embarrassed i didn't think of
that or maybe it's not that maybe it's not the integrated number cost maybe it's big city along
this short leg and no cities along the big the long line even though the total number is greater
so there are all different kinds of criteria.
This is what I refer to as the meat, which has to be hung on the bones,
a skeleton that we have created in the United Nations now.
That's a carnivore right there.
He's talking about hanging meat.
So he wants to, so when he says integrate,
he doesn't mean like the people from one city move to the place of another.
And mate with other people.
No, no, that's not what he's talking about.
What does he mean exactly?
Well, in calculus, if you want to add up the value of a curve line, of a function over some parameter, you integrate over that parameter.
And so he's being calculus fluent in a conversation that I was having with him.
Nice. I'm glad that he knows calculus, which is one of the things that I'm glad about him.
So, you know, the B612 now, that's not so much what they go under.
They go under the name the Sentinel mission.
And their priorities have changed over the years because, yeah, we want to deflect it,
but that takes a lot of money right now.
Let's at least catalog everything that could do damage,
and we didn't have really good ways to do that.
So now they have a list of—
No, it's a list in progress.
Yeah, yeah.
No, not a—I understand that it's not complete,
but meaning they're collecting a list of potential dangers.
Yeah, so they're trying to collect data on, discover, and catalog
at least 90% of the asteroids larger than about 140 meters.
And by the way, asteroids normally hang out between Mars and Jupiter.
That's the asteroid belt.
But some of them are rogue, and they cross Earth orbit.
So those are the near-Earth objects.
And that's a separate subcategory of asteroids
that this is designed to at least try to find.
Then when you have one headed our way directly
and you can confirm that, I think that
will motivate people.
Yes. Well, I mean, the Russia one
was pretty terrifying.
Yeah, yeah.
I saw the footage on that and it was great.
So now you can ask, speaking of how terrifying it is
and how much power they –
some of these have the collision energy of a thousand nuclear weapons, such as what was dropped on Hiroshima.
So you might ask, if you have the power to deflect it to save us, do you have the diabolical power to deflect it and destroy on purpose?
Yes.
Yeah, so that –
Do we have to ask Rusty?
We'd rather ask Rusty.
Even though I'm going to say, yeah. Check it out. Let's so that we do. But we have to ask Rusty. We've got to ask Rusty. Even though I'm going to say, yeah.
Check it out.
Let's see what he says.
If you build the power to deflect an asteroid out of harm's way,
it's been argued that if you're diabolical, you can do the opposite.
Oh, yes, yes.
Take a harmless asteroid and...
Called the deflection dilemma.
Deflection dilemma.
Right, and it was written up by Steve Ostro and Carl Sagan.
Carl Sagan, yeah.
And it is, for fairly technical reasons. Are there evil people working in your organization?
No, it is, what do you call it, a chimera? Yeah, a chimera. It's a chimera. It sounds
like it's right, but it's not right at all. And here's the reason. If you want to wipe out a city,
you got to use a rock that's something like 30 to 40 meters in diameter. How
often does that happen? That one comes
close enough to the Earth that you might be
able to move it to hit the Earth. Once every
300 years? That's not much
of a weapon, right?
Yeah, in 300
years we'll take you out, but let's have coffee
for them. If it doesn't happen to be in the right orbit
where that red line happens to go
over the enemy you have today,
then you've got to make new enemies so you can hit them with a rock, right?
So the rock lines up with the country you have to hit.
It's not real.
So you choose your foreign policy that way.
Yeah, that's right.
Build your foreign policy around what happens to Santa's asteroid.
So the deflection dilemma is not a dilemma.
Right, it's much easier to use missiles.
Yeah, exactly.
not a dilemma.
Right, it's much easier to use missiles.
Yeah, exactly. We already can send a missile, an intercontinental
ballistic missile, between any
two points on Earth within 45 minutes.
So to wait around for an asteroid, what are you
doing? Right, and no one will think it was an accident
because they'll see you moving it. You can't be like,
oops, that engine.
And that paper that he was referring
to that was co-authored by Carl Sagan
came out in 1994.
And I got the title here.
The Deflection Dilemma.
Use versus misuse of technologies for avoiding interplanetary collision hazards.
Why was it called I'm Very Paranoid?
That's the subtitle.
Oh, yeah.
Oh, yeah.
Subtitle, I'm Very Paranoid.
And forget about regular missiles.
And so, of course, asteroids have plenty of other uses.
Imagine mining and things like that.
Right, because we can go and get all their gold.
Yeah, get all the gold and no one's going to fight you for it.
Right.
Well, if you go that, that's true, if you go far enough.
Yeah, the asteroidarians.
Yeah.
And other stuff.
Can you mine and bring back to Earth,
or is there virtually nothing that's worth that?
Yeah, so that's a great question.
So to move things around in space
is much cheaper than bringing it back down to Earth.
Right.
And so it might be that when you mine,
you're doing it for other activities
that you would be conducting in space.
Oh, right, right.
You wouldn't be getting all the platinum bring here.
You'd be getting it to build a platinum bridge to the moon.
Just as an example of a thing you might try to do.
What interstate number that would be.
When we come back, let's find out how much this kind of mission would actually cost,
because that has to matter at some point on StarTalk.
I'm with my co-host, Eugene Merman.
Eugene.
Hello.
And we've been talking about protecting Earth from asteroids.
Yeah.
By the way, asteroids took out the dinosaurs and allowed us to rise up and become something more ambitious.
Right.
Maybe there'd be some sort of human slash dinosaur that would rise once we were destroyed.
Well, that's what I'm saying.
So asteroids, they can be bad for you if you're alive at the time.
Yeah.
And good for you if you survive it and then you have more biologically ambitious species in mind.
We could easily become winged.
We could easily become winged.
So to get a handle on this, we're featuring my interview with NASA Apollo 9 astronaut Rusty Schweikert.
And what I had to find out, I had some sense of it, but I needed to know what would a mission to deflect an asteroid actually cost. And he, as founder of the B612 Foundation and the Sentinel mission.
Right, which originally we wanted to just put a little prints on
So let's let's see what he says about the cost
An actual deflection mission you're probably talking a billion dollars
Okay, total something at 500 million to a billion dollars. Well, that's well under our funding radar
We could write a check tomorrow for that
Well an impact even a relatively small one, would cost you probably $100 billion.
At least.
For example, Apophis, which is 280 meters, which is a medium-sized asteroid,
there was a cost model made for an impact, and that came out to be about $400 billion.
Is this an ocean impact with tsunami taking out the West Coast?
That's right.
The big cities of the West Coast and the expensive homes.
How much is that?
$400 billion?
$400 billion.
Okay.
Total damage profile.
And that's almost true whether it hits in the ocean or whether it hits on land.
It's not.
Land is bad.
It is sensitive, but not.
Ocean is also bad.
Yeah.
They're both bad. But that's a magnitude of letting something hit of that size compared with a billion dollars to prevent it from hitting.
So it's a no-brainer.
So it's a no-brainer.
Yeah, I mean, a billion dollars.
Hey, we piss that in Washington.
Yeah, though it's funny because as if there'd be like, well, it's going to hit this town and it's like one billion to save the town.
Well, the problem is, yes, it's not just a thing that hits a thing.
It's a thing that hits a thing and creates havoc in a huge radius beyond the actual impact point.
But they almost all do.
Or no, they wouldn't.
I guess it could be like Russia.
So stopping the one that hit Russia wouldn't
have been worth it.
Is that what he's saying?
It kills like eight people.
Yeah, I'm just saying, if you hit a thing,
you'll destroy the thing, but you'll also
destroy a huge area surrounding it.
If it hits the ocean, it'll destroy...
And the land. I mean, it doesn't
either. It's going to have
devastating effects for far beyond the spot that gets to show that it has the crater.
Yes.
Yes.
And this is one of the great revelations of computer simulations of the consequences of impacts on global climate, on our transportation chains, our communication outlets.
So it'll basically completely disrupt civilization.
And he mentioned asteroid Apophis.
Its official name is 99942 Apophis,
named after the Egyptian god of death and darkness.
Seems fair, even though it's only medium-sized.
Yeah.
So it's about the size of a stadium.
Okay.
And a professional football stadium. Yeah. of a stadium. Okay. And, you know, a professional football stadium.
Yeah.
Or rock stadium.
I like that you've decided what happens at this stadium.
Okay.
It was not built for rock concerts, so I think I'm legitimate in that claim.
All right.
But that one is, we have our eye on that one, because that's going to make a close approach
on April 13th in the year 2029.
Oh, wow. So we have, like like a thing that we might try to deflect well if you had any testing of your
apparatus that would be a way to do it because it's it's we know it's not going to hit so you
can sort of poke it and see what happens and play we wouldn't accidentally turn it to hit us you
would hope not right um but that april 13th you know what day of the week that is? I'm guessing it's a Friday.
It's a Friday.
You're a smart guy.
I'm one of the best guesstimators we have
in America.
So that would be a
valuable
testing ground
for any of ideas. And give us enough time.
I brought
the right amount of time, so it's about the right amount of time.
So it's about 15 years away.
Yeah.
So I could build it by that point.
And I don't know anything about engineering.
So let's find out.
Rusty's thought about the difference
between hitting the ocean and hitting land.
And out of the box,
you might think hitting the ocean is worse
because it sends a shockwave throughout the ocean.
You have tsunami hitting every place that touches the ocean. I'm going to a shockwave throughout the ocean you have tsunami hitting
every place that touches the ocean i'm gonna wait to hear what rusty thinks before i decide which i
think is worse so we'll see let's find out where he takes us what's worse hitting the ocean or
hitting land depends on the size of the asteroid if it's a big asteroid which and i'm just going
to arbitrarily say let's say over 250 meters in diameter, something like that.
Apophis would count.
Yeah, Apophis would count.
Right.
It's worse if it hits in the ocean.
Okay.
And the reason that's interesting, it's an interesting scientific reason, because if you think of something like an airburst, the energy with distance goes down as the inverse cube of the radius or the distance.
In water, which is two-dimensional, it goes down with the inverse square.
So the energy that's deposited in the water ends up going much, much further before it dies out.
Okay, so the inverse cube is because in airbursts,
the energy is diluting into a spherical volume,
whereas basically the ocean is flat and horizontal.
So it only goes into two dimensions.
And the energy transfer into the water is quite efficient.
So you got basically the same amount of energy to radiate,
and water, you end up with over-the-horizon problems
that people didn't know.
Interesting.
Yeah.
I mean, this is way more complicated than you think.
Right.
So it's if it's very big, water is worse.
If it's a little small, air is worse.
Yeah.
Air is better.
I mean, we're talking about...
Sorry.
Yeah, yeah, yeah.
I'm like,
from the point of view of the asteroid,
that's trying to really make things
very bad for humanity.
Yes.
Yeah, yeah.
So here's what's interesting to me.
Movies that do it right
typically show asteroids hitting the ocean
because nearly three quarters of Earth's surface is ocean.
Right.
And so the movie Deep Impact did just that.
It hit the ocean.
They still wanted to destroy New York, but you get to do it with a tidal wave, with a tsunami wave.
And so, but movies like Armageddon, where-
Well, they sent miners to drill, and then they played the Aerosmith song.
It's just different.
Did they play Aerosmith's song?
Is that because his daughter is in the movie?
Well, I think their only number one hit
is like a sort of ballad for that movie.
Really?
Now you know, listeners of StarTalk.
So there's an interesting cross-pollination
in the research that one would do with the consequences of an asteroid hit, depositing energy into the world, burning things.
And climate change is a general exercise.
And if something happens in one place on Earth, what effect does it have elsewhere?
Yeah.
And so it's a fascinating challenge.
And so it's a fascinating challenge.
And it has a lot of the same problems with making accurate predictions going forward.
What do your models tell you about the orbit?
You're going to have to crash some asteroids into a few cities just to kind of get a really good idea.
Just to find out.
Of how to stop it better. Is it so big that it would be better if it hit the land than if it hit the ocean?
So all of these calculations.
Where do we deflect it to?
Can we deflect it away from Earth?
Ideally, but it might be too late that you can't.
And so maybe you can then push it to another spot on Earth.
So I talked to Rusty about increasing the accuracy of these predictions
so we can actually have an actionable statement on which to base our behavior. Let's check it out
You may have to launch four or five
Deflection missions only to find when you get up there that it's not going to hit anyway
Okay, because when you get there, then you get a really accurate trajectory on that
So what we really need is some way to put low jack on each of these
Asteroids so it can reports back to us where exactly it is in space
Yeah, but let me get into numbers here now
You're talking a million s or it put a low jack on that fly a million missions to these things just to put the thing
No, no, no, no, you wait until it's at work from the ground
Indicates that it is a potential threat then you send an observer mission to get the accuracy.
So it's a transponder, I guess is what you call them.
And it broadcasts where it is, and then we can know with high accuracy.
And then we don't have these uncertain paths where it might hit Earth that shrinks down that error circle, right?
Well, you get something on the order of 50 times better accuracy.
You reduce the uncertainty in your knowledge that you get from ground-based telescopes by about a factor of 50.
Well, that's important, right?
It is, because it makes a difference between is it going to hit or not.
It may still be several hundred or even thousand kilometers uncertainty on the earth if you're evacuating towns and townships
that helps oh yeah knowing nowadays you see hurricane maps where they show right the possible
paths hurricane maps are great because we're learning how to read those now people understand
there's a probability it may go this way it may go that way right and they change the color as you
come off the center line and from day to day
there's more data and they change a little bit so people are gradually with the national weather
system getting to understand that we don't know these things and can't know these things for sure
and in fact we're much better in space because you're dealing basically with gravity it's
pure gravity it's not the chaos of the atmosphere in the ocean. That's right. Yeah, so these are complex issues.
We're glad people in charge have the confidence.
Of their own organization.
I'm glad a bunch of astronauts were like, wait a second, this might be bad.
And we should also be glad he knows calculus.
Yeah, yeah.
Just to get back to that point on it. Now, just to quantify some of this, the explosion over Chelyabinsk, that was an asteroid about 17 meters across.
It was stony, made of stone.
There are several kinds of asteroids.
What are some of the different?
Others are really metallic.
So you get asteroids typically from a planet that never fully formed.
Oh.
And then it got...
So sorry.
And then there's such activity out there,
it ends up getting shattered.
But while the planet is trying to form,
it's in a kind of a liquid state or a fluid state.
And when you're in that state,
the heavy things fall to the middle
and the light things float to the top.
So then when it begins to harden,
you have a center with a ready-filtered supply
of heavy elements like platinum and iridium and gold and iron.
Are metallic asteroids particularly more dangerous?
Yeah, well, because they will completely come through the atmosphere.
It's hard to bust them apart just colliding with us.
So different kinds of asteroids are out there,
and it makes for fascinating different uncertainties,
but what kind of damage it would make.
Right.
So the scariest form of asteroid would be the core of an unformed planet.
Yes.
That one is just get the hell out of the way.
So we would try to then move Earth.
Superman would have to push Earth out of the way.
So something Batman could not
conceive of doing. So Superman
or Archimedes. Yes.
Either one of the, whichever one we have access
to.
Archimedes, you know my favorite quote of his.
What does he say? He says you can't push the earth
out of the way of a moving asteroid. No, he would have
said it differently. He would have said, well I'll quote
him directly. Give me a place to stand and I can move the world.
You want people like that around in situations such as this.
So Archimedes was badass, just so you know, in case you didn't.
I did not think he wasn't.
He was the Batman of the old days.
Exactly.
And so in that meteor that fell over at Chelyabinsk,
they calculated how much energy that was.
And it was about 20 times the energy of the bomb over Hiroshima.
And so here's the difference, of course.
That bomb over Hiroshima killed 50,000 people, 20,000 people.
Right.
And later from radiation sickness.
And so how come nobody died in Chelyabinsk?
I'm also curious.
You might ask.
I am asking.
All right.
So the one in Chelyabinsk exploded 20 miles above Earth's surface.
When you're going 40,000 miles an hour, however thin Earth's atmosphere is at that altitude,
it's as though it's hitting a brick wall.
So the explosion is the abrupt encounter with Earth's atmosphere causing an air blast.
So now all that energy dilutes into a 20-mile radius sphere before it hits the ground.
And so the shockwave was still significant, but it wasn't so bad that everyone died.
And it was, wait, how many miles again?
20?
20 miles up.
Okay.
And Hiroshima, how far was that up?
Half a mile up.
Oh, yeah.
Very big.
We were also trying to hurt them.
Well, that's how it was calculated.
It wasn't accidentally detonated that high up.
Right.
It's the kind of calculation you do in warfare.
You know why?
They didn't want to drop it too low, explode it too low, because then half the energy would
just go and make a crater.
Yeah.
And too high, it would become to dilute.
Yeah.
So there's the optimum, again, it's a military calculation done with the cold, dispassionate way that they do these things.
The way war is.
The way war is.
War with industrialized nations.
And so you calculate that and you figure the maximum damage to people and things would happen at about a half a mile up.
And so that's what they did.
So my point is...
I hope asteroids don't find that out.
And so the metallic asteroids would get deeper in the atmosphere
and possibly even collide.
Right.
So we want to know...
Would colliding be worse than exploding a half mile up?
Yes.
It would?
Yes.
Yeah, but the metal holds itself together so well
that it generally will survive.
So the biggest surviving meteors on Earth are metal.
Oh, wow.
And we've got two of them in, you know.
You have two of them.
You have two of them.
I, oh.
Do you ever, like, secretly chip a little away
and bring it home?
Like, I have one of the two, a little of the two meteors.
Or meteorites.
Yeah.
So, Eugene, we've got to wrap up this segment.
But when we come back,
more of my interview
with Rusty Schweiker,
and we're going to find out
do we treat asteroid impacts
like any other
large natural disaster?
What's the thinking on that?
Because clearly,
we have thought about
other natural disasters.
How different would
asteroid strikes be from that?
When StarTalk continues.
This is StarTalk.
Welcome back.
I'm here with my co-host, Eugene Merman,
and we've been featuring my interview with former NASA astronaut,
Apollo astronaut, that is, Rusty Schweikert,
and co-founder of the B612 Foundation and what they now call themselves
the Sentinel Mission.
And it's very Google-able, by the way,
if you want to...
Sounds like something you could
totally look up and verify.
So the asteroids,
I don't think enough people
are thinking about asteroids.
Well, how close are some of the near misses?
Like how close are some of the ones that have almost hit?
Well, let's just put some numbers on this.
Our crack team of researchers got this.
So consider that less than 1% of the million asteroids larger than 40 meters have been identified.
Now you might say, well, 40 meters, that's nothing.
Except that's not what matters.
The size is not so much what matters.
It's how much energy does it carry.
Because that energy, kinetic
energy, the energy of motion, once
the asteroid hits and is no longer moving,
where does the energy go? It goes,
it explodes. It explodes. It goes in,
destabilizes the object, it explodes,
it burns forests, it makes a crater,
it kills people, knocks over
buildings. So all of this
is going on in an asteroid. And so
the smaller you get,
the smaller is your threshold of wanting to
track. The fewer,
the lower percentage of the total
we've actually recovered
that's out there. And so another problem
is you can find an asteroid when it gets close
and just misses us.
But then if you want to keep tracking it, it goes farther away from us.
And then it's so dim you can't track it.
And you have to hope you find it on its next time around.
Is it orbiting our asteroids?
Everybody's orbiting the sun.
Okay.
Everybody's orbiting the sun.
Even an asteroid that might hit us.
Even an asteroid that crosses Earth's orbit is orbiting the sun.
Okay.
That's right.
And of course, most of them cross our orbit when we're not there.
Right, when we're not looking.
When we're not looking.
When we're sleeping.
When the Earth is asleep, asteroids.
No, when you cross the street, trucks have been on that street, but they're not hitting you because you're crossing them at a different time, even though you're in the same place.
You've really planned your street crossing quite well, and asteroids don't have that level of planning.
Exactly.
And so you can end up just getting hosed by them.
And so just something to keep in mind.
And so the near ones, so we have a list of the ones that come nearby.
By the way, there's upwards of a half a dozen asteroids that we're tracking that come within a few Earth-Moon distances.
Oh, but meaning, so how far is the Moon?
And we call those close approaches. How far is the Moon? It's a quarter million miles distances. Oh, but meaning, so how far is the Moon? We call those close approaches.
How far is the Moon?
It's a quarter million miles away.
Okay.
But that's not how you should think about it.
Think about it as, remember the schoolroom globe?
Yes.
Yeah, maybe a foot across.
I do.
So ask yourself, if that is the actual Earth in your hands,
and the Moon is actually your fist, which is about the right size ratio,
where would you have to put the Moon to be the right distance from Earth?
Seven miles away? I don't know. I'm making up a number.
About 30 feet away.
Oh, I was really making it up.
Not right next to it, as school books typically show,
because they would have to fit it on a page.
About 30 feet away.
So if an asteroid comes and it's twice the moon distance or four times, I don't, you
know.
60 feet, 80 feet, 100.
Yeah, I don't, to me those are not buzz cuts.
Right.
If you come within our.
Between the moon.
Cis lunar space, that's the official name of it.
That's what the military calls the new high ground basically.
Then, yeah, that's what I'm.
How often does that happen?
That sounds much scarier.
You get that maybe a few times a year.
Oh, really?
Yeah, yeah.
And, and, I don't know the latest numbers, but. You get that maybe a few times a year. Oh, really? Yeah, yeah. And I don't know the latest numbers, but last I checked, it was a few times a year.
And Apophis on Friday the 13th in the year 2029 will come so close that it will dip below our communication satellites.
Here's a question.
Didn't Rusty say we're 50 times off our measurements, potentially?
Or if we went into space and tagged it, we would be 50 times more accurate.
Oh, easily.
So aren't we potentially super inaccurate about where this asteroid coming for us will be? Yes, but the good thing about it is that we can quantify that ignorance.
How does that work?
That's something we need to find out.
Yeah, so what you do is you just
have a wider uncertainty
path that you must confront.
Oh, I see. So it's like a hurricane where you go
like, it'll be in this range, but you know it's not
actually going to go to France or something.
Exactly. It's not going to make a bank a turn and go to
the Bahamas if it's
landfell. So
this is how you would do that.
And so Apophis is going to come within our communication satellites. Those are 23,000 miles up.
So to me, that's fighting.
Will it disrupt our texting and our swiping right and left?
I don't remember if it's metallic or not, but not likely.
Okay.
It would make everyone swipe right.
We should find out if it's metallic.
Those sound a lot worse. That would be funny. would make everyone swipe right. We should find out if it's metallic. Those sound a lot worse.
That would be funny.
It made everyone swipe right.
Exactly.
By accident, it created hundreds of marriages.
The asteroid marriage.
That's cute.
Yeah.
So, you know, we have had to deal with natural disasters in the history of the world.
And I wondered how different would this be from those.
And I checked with Rusty to see what he says.
So a question for you.
This asteroid that struck over Russia, a thousand people needed band-aids.
Yeah, 1,500.
Yeah, the glass broke in their face.
Why is that any different from a hurricane or a volcano?
People get injured.
We don't go bat crazy over it.
I mean, we do, but not in some kind of so organized a way as you are suggesting to deflect asteroids in the future.
Why not view the occasional asteroid strike as another natural disaster and we pull ourselves up by the bootstraps and get over it?
Well, the reality is we are going to do that for the ones that are too small for us really to detect ahead of time.
And Chelyabinsk objects...
Was just such an object.
Yeah, it was just such an object.
We're never really going to be...
We will find some of them.
Make no mistake, we'll find...
But we're never going to get anywhere near the total population of objects that size.
So we're...
99% of the time that we get hit by something that's, let's say, 30 meters or smaller,
we're not going to know about it ahead of time.
But above that, where you can do serious damage, like wipe out a city,
we can know about those ahead of time.
We can predict an impact coming, and we can deflect it if we know about it early enough.
So in this enterprise, they're the ones you know we can deflect.
The ones that are too small you can't see,
those come under the category of all the other natural disasters.
You need disaster recovery planning.
The lower part, the lower region of the ones that you can find
but are going to cost too much to deflect, you're going to use...
Because there's so many of them, they're so small.
to cost too much to deflect, you're going to use... Because there's so many of them, they're so small.
Yes, because they're so small, it is cheaper to evacuate the impact zone than it is to try and deflect them. It's probably not purely economic. You're going to have real geopolitical components
to that decision. But in the work we've done with the UN, we have identified
that this threshold or this break, this line has to be defined by the nations of the world.
It's got to be defined geopolitically.
It's not a technical decision.
Yeah, I mean, the more he talked, the more I thought we were just screwed because there's
too much. There's too much.
Too many factors. Too many factors.
Too many factors.
It's not just bat the thing out of the sky.
But basically, the little ones are like just regular natural disasters.
But the big ones could destroy mankind.
Yes, yes.
So those we should really stop.
So the one over Chaya Binks, I said it was about 17 meters across.
That one, by the time you know that's in our atmosphere, it's too late.
And there's nothing, is there anything you can fly into it or anything?
That low?
Yeah.
No, because-
It's traveling it.
So it's not only the speed, is if you break a thing into two pieces, now you have to evacuate
two locations instead of one.
If they're split and they keep separating.
And you haven't reduced its energy.
It's all about the energy.
Right.
The energy is still there. The energy is still there. Even if's all about the energy. Right, the energy is still there.
The energy is still there.
Even if you break it into a million pieces,
the energy is still there.
They might explode at higher up
and be a little less damaging.
Right.
But nonetheless, the energy gets...
And there's no option where you slow it down
or catch it with some sort of gigantic...
Lasso it.
Yeah.
Lasso it.
Well, something has to be holding the net.
Oh. Yeah, what are you going to attach the net to? Rockets that are leaving Earth. Yeah. Lasso it. Well, something has to be holding the net. See? Oh.
Yeah, what are you going to attach the net to?
Rockets that are leaving Earth.
Okay.
Maybe a giant sheet with rockets on every corner, an opposite parachute.
So, yeah, so these are, for me, fascinating frontier challenges on this.
So does he have an actual plan of how it would be stopped,
or he's going to go, UN, we're in serious danger?
No, he's hosted conferences where they invited engineers
to come up with solutions.
And some people who are the kind,
look, we've got the nukes in the silo.
Let's blow the sucker out of the sky.
You've got some of those people.
That's a bad idea, right?
Well, we're really good at blowing stuff up
here in the United States, but less good
at knowing where the pieces
fall after you've done so. Whereas
a deflection mission, you can
judge
how well you're doing
while the mission is in progress. Right.
But we also, would it make
sense to blow something up in space, or no?
If you can get it early enough and completely blow it to smithereens so that when it does hit Earth,
they're just harmless meteors falling through the sky, it would be a hell of a meteor shower.
Right.
Yeah.
So that might make sense.
But once it gets to Earth.
If you knew you would accomplish that, if that's what you're betting on, I don't know that that's the right way to do it.
Right, right.
It's not a great plan.
Right.
I don't recommend it. That isn't my recommendation after hearing all the evidence.
And you want to know who's really going to lead this.
Is it Rusty? Are there countries?
There's a whole other geopolitical layering on this.
Forgetting the science.
Just who's accountable for something that could hit one country versus another?
I ask that of Rusty. Let's find out. What's really left, frankly, is taking responsibility. And the question is,
with everything else going on, why should I as a president or congressman or whatever,
why should I add this to the list? 88% of Congress gets reelected every two years.
But the fact of the matter is the public, as they come to understand this with Chelyabinsk
and other, you know, the next ones that are going to hit, they're going to understand
at some point, they're going to get that it's not expensive to do this because the image
in everybody's head is this has got to be terribly expensive.
It's not.
It's less than one half of 1% of NASA's budget to do it up in gold.
So you're not talking displacing the whole National Space Program.
Why doesn't NASA have such a program?
Because NASA has no responsibility for public safety.
Oh.
NASA is to do space science and exploration.
This is neither space science nor exploration.
It is public safety.
That's the naivete of the founding
documents. It is. And we have made recommendations to the Congress, changed NASA's Space Act to make
them responsible for this one and only cosmic natural hazard. And they have not done it,
nor has any nation in the world yet assigned this kind of explicit responsibility and that's what's got to
be done you know the more i talk to him the more you just want to kiss your ass goodbye you know
so he wants nasa to have responsibility if if not nasa then who and if not now then when well i
don't know i guess it would be msnbc would be a bad choice they barely do any space exploration
MSNBC would be a bad choice.
They barely do any space exploration.
Hardly any.
Yeah, exactly. And I can't think of a band that would be good.
U2, maybe.
They would probably.
And by the way, there's another layering of challenge here.
Some asteroids that have less density that we measure
than what we know is the density of the rock that it contains.
And so that tells us maybe it's a pile of rocks.
And when we calculate the bulk density,
we're adding in all the space between the rocks,
having it come out less than what we think it should be.
If that's the case, how do you deflect a pile of rocks?
I don't know, a rock-eating monster?
Well, that's what I'm saying.
If you attach a retro rocket to one of the bits of it,
then it could just pull one of those rocks away
and leave all the rest.
Not all of them.
Would you maybe blow those up?
Well, that's what I'm saying.
So these are the challenges that confront the
deflection engineer, right?
It's not a, and is the thing strong enough to
move one piece of it and have all the rest of it
follow?
That's really what it comes down to.
Gravitationally, you mean?
Well, so one of the great ones is gravitationally.
That way you're not tugging on one piece versus another.
So that is, Eugene, the frontier of our species, survival in this world.
And you're from Russia, and all these like hitting Siberia, so maybe.
Well, Russia's very, very big.
Is that why?
That's probably, I think, why they get hit a lot.
It's like they're the ocean of land.
Yeah, I like that analogy.
So, Eugene, we've got to wrap it up.
Thanks for being on StarTalk.
Thank you for scaring me about asteroids.
Okay.
I'm Neil deGrasse Tyson,
your personal astrophysicist.
And as always,
at the end of these programs,
I bid you to keep looking up.