StarTalk Radio - Cosmic Queries – World Space Week
Episode Date: October 4, 2019To celebrate World Space Week, Neil deGrasse Tyson, Matt Kirshen and astrophysicist Charles Liu, PhD, answer fan-submitted questions on a variety of celestial topics including parallel universes, sola...r energy, speed of light travel, Mars, and more!NOTE: StarTalk+ Patrons and All-Access subscribers can watch or listen to this entire episode commercial-free here: https://www.startalkradio.net/show/cosmic-queries-world-space-week/Thanks to this week’s Patrons for supporting us: David Vives, Kelly Holman, and Nick Bryant.Photo Credit: NASA/Tony Gray and Kevin O’Connell. Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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From the American Museum of Natural History in New York City,
and beaming out across all of space and time,
this is StarTalk, where science and pop culture collide.
This is StarTalk.
I'm your host, Neil deGrasse Tyson, your personal astrophysicist. And this is a Cosmic Queries edition where we are celebrating Space Week.
That would be the first week of October.
That happens to contain my birthday.
I'm just saying.
Woo!
Oh, yeah.
Who's making those whooping noises?
I've got my co-host for this, Matt Kirshen.
Matt, welcome back.
Thank you, Neil.
Excellent.
What came first, by the way,
Space Week or your birthday?
Did it become Space Week
because it was the Neil deGrasse Tyson birthday?
My birthday precedes the official celebration of Space Week.
There we go.
So maybe.
Maybe that was the designation.
Maybe. We got a lot of fun questions coming up. There we go. So maybe. Maybe that was the designation. Maybe.
We got a lot of fun questions coming up.
We sure did.
And I got backup here.
In fact, I'm his backup.
If he's on the show with me, I'm his backup.
The one, the only, the geek in chief, Charles Liu.
I am so happy to be here, Neil.
Thank you.
Friend and colleague, you're a professor at City University of New York at Staten Island.
Correct.
And so you just had a book come out.
Yes, thank you.
Yeah, it's called 32nd Universe.
It's published by Ivy Press in the UK.
Is it because there are 31 other universes and we're in the 32nd one?
Is that what that means?
I asked the very same question.
The parsing is 30-second space universe.
Every decision that's made, the universe splits in two.
He made 31 decisions that nobody wanted, right?
Well, it's only to make 32 decisions.
That's only what?
It's like five?
Five doublings?
That's right.
No, yes, it is about cosmology.
And I have two terrific co-authors who are also astronomy and physics professors.
And we talk.
Co-authors are?
Karen Masters at Haverford University or Haverford College
and Saville Salour at Rutgers University.
Okay, cool.
And we talk about cosmology,
including the idea in quantum mechanics
that you create many worlds with a hypothesis.
With every split.
With every decision you make, you create a new timeline.
Which I believe was originally formulated by the father of the lead singer of one of my favorite bands.
Oh.
I believe it was Hugh Everett, the physicist, who came up with that.
Hugh does get credit for that.
Oh, okay.
Whose son created the band the Eels.
No kidding.
Another connection between science and music.
You got it. You got it. And Matt, you're of course the host of eels. No kidding. Another connection between science and music. You got it.
And Matt, you're of course the host
of Probably Science. That's it.
And I said I would never invite you back until it became
Definitely Science. You're still not there.
The one episode that you were kind enough
to come on, that was the definite episode.
And everything else was just flailing.
You hosted me on your show.
You were very kind to come by that, yeah.
So we've got questions from our fan base,
as we usually solicit for Cosmic Queries.
And this is just, I guess, general,
I haven't seen them,
general questions about space.
You're going to handpick them.
I am.
And you're going to throw down a gauntlet.
Ooh.
And Charles, I'll sit here and eat my lunch.
That's why I bring them on,
so I don't have to work that day.
Okay, so I'll just...
We have very strongly overlapping Venn diagrams in our expertise,
but he takes it another dimension beyond that.
I'm sweating now.
So we're good.
I don't know.
We'll see how it goes.
You know, I'm going to start off with this one,
because this ties into what we were just talking about.
This is from DQFam, who says...
What platform?
On Twitter.
This is DQFam, at FlatNaut on Twitter.
I think that's actually relevant to this question,
because DQFam, a.k.a. FlatNaut, says,
Is there a parallel universe where I,
as an astrophysicist on the flat Earth,
combat the disinformation agenda of the Round Earth Society?
Whoa!
Oh!
Oh! Way to start us off with an easy one well the short answer is no because next question you're wrong but i think we can take this in a
direction where we imagine that he actually is in a flat universe a two-dimensional universe
where somebody says no actually the universe is three-dimensional universe, where somebody says, no, actually the universe is
three-dimensional, right? Now, remember the beautiful book Flatland from decades ago?
A century ago, yeah.
It's been a century.
Yeah, yeah. It was a turn of the century book.
Wow.
Yeah.
Turn of the previous century.
Right. Fair enough. How can we prove that the universe is two-dimensional,
if indeed it is two-dimensional,
where someone is claiming that there's a third dimension, right?
I would approach it this way.
Well, you're talking about the whole universe.
The dude's just talking about Earth.
Right.
I guess if the universe is two dimensions,
Earth has to be a flat disk.
Correct.
Oh, gotcha, gotcha, fine, fine.
So in that sense, right,
then some non-scientific individual comes along and says the universe is a three-dimensional structure and the earth is actually a three-dimensional structure.
How would you counter that?
Right.
And so that makes it a more interesting question.
And I would say one of the first things you would try to do is to see if you can prove that the two-dimensional universe cannot project into the third.
In other words, you cannot find a way to extend the universe in an orthogonal direction to both.
Yeah.
Excuse me.
You can't extend something perpendicular to both length and width.
Now, can you do that in any... but what you're saying is in in our current
universe yeah we have a height width depth yes and you're saying that the version of that question
to us would be find another place to stick out a line that's at right angles to those three other
right angles and we don't know how to do that right and so that would be the way that someone
in a true two-dimensional universe
is trying to say that there is no third dimension.
Am I right in thinking there are some theories of physics
that involve higher spatial dimensions in our universe?
Oh, completely.
But those dimensions are not visible to us.
Okay.
And one of the well-known formulations of this is something called a compactified dimension.
But, Charles, you're okay with this. There are these extra dimensions a compactified dimension. But Charles, you're okay with this.
There are these extra dimensions, you just can't see them.
You're okay with this.
I'm not okay with it yet.
But they haven't been disproven.
Here's the idea of the compactified dimension.
If our length was actually, you zoom in further and further and further,
and you find out that our length actually has length, width, and height.
But it's so small compared to even atoms
or subatomic particles
that that width and height
is not detectable in our universe.
It's tantamount to just being a one-dimensional string.
It's as if it were one-dimensional
for all intents and purposes.
Is that where they use the word compactified?
Yeah.
It's contained tightly within the other dimensions.
You can imagine, for example,
looking at the Alaska pipeline. If you're standing
right next to the Alaska pipeline,
it is obviously both
with length and width. Additionally,
it has height. So it's a three-dimensional object.
You step a little further away, it just becomes
like a long strip. So you think it has height
and length, but you can't see the depth anymore.
And then if you fly away,
say to Canada, and you look at the Alaska pipeline anymore. And then if you fly away, say, to Canada,
and you look at the Alaska pipeline from a distance,
it only looks like a line.
By that same token, we could compactify dimensions
into our linear dimensions.
So that's how you get the higher dimensions,
even though you can't experience them.
Right.
And somehow, if you think that those compactified dimensions
can affect our universe in ways we can't measure,
then you can, say, set up a universe with multiple dimensions.
And what you're saying is we're too big.
We are.
Isn't that cool?
Yeah, that's cool.
Yeah.
In a universe for which we are very, very tiny,
we are still way too big to see hypothesized compactified dimensions.
And we're too small to see that Earth is a sphere.
Yes.
We just
walk in a straight line, and it's
a straight line to you, but if you
back out, you're walking on the surface
of a sphere, and you don't even know it. Fantastic.
And so that's how you would try to address
two-dimension, three-dimension, more-dimension
type things. I love the question.
Really good question. I love the question, and I love that
answer. Okay.
So, this is more of a practical question
from Seamus Star on Instagram.
Will we focus more on habitable planets
or all rich planets in the future?
That's O-R-E.
Oh, okay.
Or rich planets.
Yes.
Or, or, or.
Or, or, or.
Because I would focus on rich planets
if it's just or rich because then I could like, you know, do business with them.
But or rich planets, I think, are not as interesting as habitable planets.
And the reason is to go to another planet that is trillions of miles away to get a little bit of ore and then bring it back to Earth is really impractical.
You can't hardly imagine a substance currently known to science
for which that would be profitable or economically feasible, right?
You have, of course, the science fiction world
where you imagine something called, oh, I don't know, unobtainium.
Sure, yeah.
Which could not be obtained here on Earth,
and therefore you must go far away to get it.
But that seems extremely unlikely to me.
So I would much rather find the blue-skinned creatures
than the unobtainium.
All right, so I think there will be,
I agree with you scientifically.
Okay.
But as like a practical guy, as a realist, I think the drive to obtain resources and possibly unobtainium will be greater than the drive to find other life.
And the more busy we are in space, the less will be the need to bring the resources back to Earth compared with bringing the resources to other on-site locations.
So that has value.
You're thinking much further in the future
than I am. Yeah, that makes a lot of sense.
Because I can certainly see...
Asteroids might have this.
That's the thing that I wanted to point out.
I still claim the first trillionaire
will be
the person who exploits the natural
resources of asteroids.
There is a connected question here from Saigai Kai on Twitter.
Okay.
What are the most common precious metals and useful elements found in asteroids?
Could we mine asteroids to build components for starships in space shipyards?
I would say the rare earths are more important for asteroid mining.
Yeah, well, I think all of them.
I mean, you know. Micro chips and things like that. Yeah, the rare earths. By the way, the rare earths are more important for asteroid mining. Yeah, well, I think all of them. I mean, you know.
Microchips and things like that.
Yeah, the Rare Earths.
By the way, the Rare Earths are not particularly rare.
They're just mostly in China.
So access to them is not as free and smooth as we might want for the future of our technology.
And as Charles noted, the rare earth elements are fundamental
to what is our electronic components
to making them work and do their thing.
So, yeah, I think it's the first trillionaire.
And they're all there on the asteroids.
They are there.
Yeah, the challenge is to get them back to earth.
You got to get there, fine.
But then you have to mine them
and you got to bring them back.
And mining is actually pretty complicated.
There's a lot of engineering.
Build a ship in space, dude.
Don't bring it back to Earth.
It's a waste of a whole journey.
Build your...
That's what the question is, right?
Then how do you get the people
from Earth to the spaceship?
You still need another spaceship, don't you?
Robots do it.
Robots build a spaceship
and then you go up when it's time to go.
Why not? Sure. There's an app for that.
Your spaceship is ready, sir.
You are definitely looking
much further along the time horizon
than I am, and I think that's a fair statement.
I will agree with you if we're talking
centuries, not decades. Money drives
things more than curiosity, unfortunately.
The ideal part is to
combine the curiosity with the money.
And then it happens like that.
Here is a
Twitter question from George
Xenophontos. This is
more of an Earth-based question. Why haven't there
been a greater number of advancements
on solar energy, given
that it's literally a constant free source
of energy? Okay. Yeah, Charles.
I have been on my soapbox on this
with my astronomy students
ever since I started teaching.
Okay.
Solar energy is so plentiful
and it's so free.
You make the calculation, in fact.
What does so free mean?
Okay, that's my point.
Free is free.
That's my point.
It means that I don't need to pay for the energy to arrive to my house.
Free.
Okay, that's the free.
The rest of it is the thing that costs money, right?
Think about this.
The amount of energy that the sun sends onto the surface of the earth is what we call a unit of insulation, right?
Insolation
with an O
as opposed to insolation.
That's a real word?
Yeah, insolation.
The Earth scientists use it.
That's why we don't know it really.
Insolation.
Insolation, yes.
It's just the amount of sunlight.
Yeah.
So, sol is Latin for sun.
Right.
It's the amount of sunlight
that hits the Earth,
well, any planet,
but in this case,
the insulation onto Earth
is at a rate of 1,400 watts per square meter.
Okay, what does that mean?
Our typical LED light bulb is now 14 watts.
At most.
Yeah, right.
So, just on the table in front of us, just on any...
Coffee table.
just on the table in front of us, just on any coffee table, on any surface, you are getting enough light energy, if it were properly converted, to be able to illuminate a hundred light bulbs
worth of light. Continuously. Continuously, forever. A hundred light bulbs. Most houses
don't have a hundred light bulbs. That's right right so you can literally light every house in the world on this free energy if we just figured out
a way to exploit it and i believe sadly that the main reason we have not done so is because people
find it more profitable to exploit energy sources that are much older in their origins.
Our ability...
Just say it, oil.
Just say it.
Say it.
Oil.
Or other resources.
Yeah, I don't want to diss older sources of energy.
Because as much trouble as they have caused us
on environmental levels,
they have also advanced civilization.
Yeah, they have advanced us so much
in so many ways
in the past couple of centuries.
Gold, coal,
Gold, oil.
Oil, coal, natural gas.
These fossil fuels
have really spurred our human ability to be where we are
today. But it is time to switch over. And as with anything in society, switching over from something
old to something new takes time. There's resistance. The resistance should move away at this point.
There is no more reason for us not to switch except for trying to preserve the prosperity and the interests
of those who have become wealthy from the old technology. I've seen technologies like, I don't
know how far along it is, but I know they've trialed things like road surfaces that have
solar cells built into them. That's right. You could put solar cells on buildings. Not just on
the roofs, but there are windows now where people can put a film on them.
And if you want shade in your room, you just turn the film over and then all that sunlight, instead of going into your room, gets absorbed by this film, which can then be converted into electricity.
as we are willing to take a short-term hit on profits, we will have a long-term benefit by using more solar energy.
Maybe it won't happen until we figure out how to make it instantly profitable.
Who would have thought that after millennia of riding horses, within a dozen, 15 years,
we switched over to cars?
It was amazing. At some point,
somebody said,
this car is more economical
than my horse.
Right.
Than feeding my horse
and the care and feeding
of a huge animal.
And so,
at some point that happened
because nobody had to have
special programs
to get you to buy a car.
Yeah.
All right?
Everybody bought cars.
Is there a tipping point?
That's the point.
That's the point.
There you go.
Tipping point.
I don't see an obvious one.
Neither do I.
Unfortunately.
How does it work?
Also, the resource,
we were just talking about mining for rare metals and elements in the universe.
The resources needed currently to make solar cells,
do we have enough of those?
Yes.
I don't know, Charles.
Do we?
Yeah, we do.
The vast majority of what we need is just really good silicon.
Okay.
And so that's sand.
We can basically take sand from pretty much anywhere and turn them into solar cells.
Silicon dioxide.
Yeah.
Yeah.
SiO2.
It is not hard.
Okay.
It's just at the moment it costs money.
And people would rather not spend that money.
I myself am guilty of saying, gee, I should really put solar panels
on my roof and things like that.
And then you just go home and eat a cheeseburger and watch TV.
Yes, because it is much less expensive
for me as a consumer
to heat my home with natural gas right now
or to light my home with coal power.
First adopters tend to be rich
and they'll do it so they have bragging rights
that they're more green than you are.
But that helps to change their infrastructure when they have it.
The good news is that prices for solar electricity generating things are going down rapidly.
I will add, before we take a quick break, that solar power is also hydroelectric.
Because how do you think the water gets up to the lake
before it comes through the turbines?
The sun evaporates it off the ocean.
It goes to cloud.
The cloud moves over land.
It rains.
So that's technically solar power.
And so is wind energy.
It's all from the sun.
The unequal heating of the Earth's surface
creates air currents that drive.
So the sun manifests in more than just
whether you need a solar panel.
We've got to take a quick break, and when we come back, more
of our Cosmic Queries Space Week
edition.
Bringing space and science
down to Earth.
You're listening to StarTalk.
We're back on StarTalk, Cosmic Queries, Space Week edition.
Charles Liu, friend and colleague.
Thank you.
He's my expertise here, and I'm just going to color comment.
If I think he misses something, which he hardly ever does, I'm in there.
But generally, I'm not saying a thing.
Matt Gershon, welcome back.
Thank you so much.
Take us there.
You've got questions.
All right, I do.
Call from our fan base.
I love this fan base.
This one is from... They're snarky, and they're funny, and they're... They're smart. Yeah, and smart. Really, really got questions. All right, I do. Call from our fan base. I love this fan base. This one is from... They're snarky
and they're funny and they're... They're smart.
Yeah, and smart. Really, really good questions.
This one's from Kyle Yoakum, who has helpfully given
a pronunciation guide.
That's in case we have Chuck Nice,
because Chuck can't pronounce anything.
Kyle is from Tennessee
and asks, how would we identify
something as truly being
of another universe rather than just
a newly discovered part of our own?
Oh, wow. And I think I know the answer
to that, and it's antennae.
Oh!
Yeah, just tell the Andorians that.
Yeah, they'd be very irritated.
No, they're from our universe too.
That's a good one.
I would have to think
to chemistry.
If an object is made of something that is an element of something we have never seen before,
something that wouldn't fit on our periodic table for any reason,
that one would have to come from a place where the laws of physics are different,
and thus a different universe.
I agree entirely.
Our periodic table of elements is full.
We're incrementing at the top end in our labs,
but there are no more slots at all.
And if they come up with something that is a base element,
then it's going to be an element configured in some way
that our elements are not configured.
And we say, yep, this is a weird bird right here.
It's similar in a sense that an expanded version of how we know that there is material in our solar system that came from outside our solar system, like before the sun was born.
There are grains that contain carbon, nanodiamonds, basically.
It doesn't have to be before our sun was born.
It doesn't have to be.
That's true.
It could just be visiting. Yeah, it could just be visit like floating into our solar system. But we know if
it's from outside our solar system, if we compare their isotopic ratios or their structures and we
see that there's nothing that matches that age or that mixture that is actually of our solar system.
So we have ways to do this. But that's fine.
But then you say, how did it get here?
Yeah.
What portal through the space-time continuum
connected two different universes with two different laws of physics?
That's what the real issue will be.
Well, I was going to do a different question,
but since you talked about portals through the space-time continuum,
I'm going to...
You went there, Neil.
Oh, I went there.
You went there.
I went there first.
I'm going to go with
Tony in the 845
on Twitter, who asked,
even if we somehow
discovered the tech to travel at
or faster than light, would the passengers
of the vehicle survive?
Oh.
Well, you know how the Flash does it, right?
Does he have atmospheric separators in front of him
yeah
the Flash
can go up to the speed
of like
superhero
fake science
all that right
but if he's giving someone
a piggyback
yeah
that person is toast
really
what's
note to self
I went off
for a piggyback ride
by the Flash
what are we doing
are we just doing like a donkey ride around the living room
or are we going by speed?
I'm taking the bus on that one, yeah.
Well, yeah, so the issue here is that
if we take something up to the speed of light
and it can survive going the speed of light,
then it has to be able to protect whatever's inside it
to be able also to match the speed of light.
So remember that as you get closer and closer
to the speed of light,
and once you reach the speed of light,
you cannot have mass anymore.
You are energy by definition.
So the way to get up to the limit
is to have really good strong shielding
of whatever's there.
But then getting past it will require...
Shielding from what?
Interstellar particles, for example.
Okay, stuff that could slam into you.
Yeah, stuff that hits you.
Okay.
If something hits you at the speed of light, that would hurt.
Yeah, a lot.
Okay.
Unless it's light.
Unless it's light.
Then it just feels good.
Yeah, right.
That would be funny.
You want to be...
Ouch!
Yeah.
That's what the sunscreen is for.
That's what it is.
It's literally a street.
Yes, that's right.
Or a force field.
Yes.
You would have to find a way for this vehicle itself to survive.
And by extension, whatever's inside the vehicle would survive as well.
Anything piggybacked, though, probably would be burnt to a crisp.
But I want to make something clear that speed does not kill.
It's acceleration that kills.
Right.
Okay, so you can be cruising at 99.99% the speed of light.
No one will know and no one will care.
But if you abruptly come to zero, or if you abruptly speed up to that,
then you're a pile of goo at the back of the spaceship.
So if you could be magics into the middle of something
that was already moving at the speed of light, or at 99% of the speed. So if you could be magics into the middle of something that was already moving at the speed of light
or at 99% of the speed of light.
Well, the problem is...
Or you can accelerate there slowly.
You can do that.
In fact,
they have spaceships,
we, I mean, people,
engineers,
have conceived of spaceships
that accelerate at 1G,
1 Earth gravity.
And then it just feels like
you're just sitting here
like we're having this conversation.
But we're going faster
and faster and faster. And do you remember how quickly you get to the
speed of light near the speed? It's pretty, like six months or something.
It's not that bad.
It's not that bad.
Within a year.
Within a year.
But then doesn't...
Then you have to slow down. It also takes...
Well, no, you just turn the ship around and slow down in that direction. And so you still...
Right.
But doesn't your mass then increase as...
Your mass increases relative to other
things around you. Okay, so
within the spaceship, that's also moving at that speed.
Right, right. So you and I would
maintain our relative masses,
but you and I would not
maintain our relative masses compared to, you know,
Zorkon, who's out, you know, next
to the ship. It'd be nice if he weighs like 108 pounds.
He's trying to gain
some mass here.
Yeah, how much faster do I have to run than
Zorkon?
Look, beach ready.
Summer's coming up.
While we're talking about summer and atmosphere
and such like,
Times Natural on Instagram asked
if Mars were to be
terraformed, thus given an Earth-like
atmosphere, how would it be possible
to keep the atmosphere from being blown away by solar winds considering mars does not have
the magnetic field that's right it's a good question that's an excellent question um i think
the first question which is even more important is mars doesn't have the gravity to hold on to our atmosphere.
If we tried to put as much atmosphere on Earth,
the tops of it would continuously be going away
before we could develop enough pressure on the surface to get to, say, Earth's atmospheric pressure.
So the answer is it just has to be constantly being generated.
Okay.
But Charles, there's clearly evidence of it once having had running water on its surface. Okay. But Charles, there's clearly evidence
of it once having had
running water
on its surface.
Yes.
So there had to be enough
air pressure
to prevent the water
from just evaporating.
And that had to have been
sustained for some
fair amount of time
because some of the rivers
are meandering.
Yes.
And that's a slow thing.
You don't just get that
for free.
We're talking about
millions of years, right?
Maybe even up to a billion years.
Okay.
When Mars, like any other planet in our solar system, was forming,
the core was slowly aggregating its metals from the surface, right?
It's a differentiation process where just the same way that pulp in orange juice sinks to the bottom,
so too is the metals.
Wait, does pulp sink to the bottom?
Eventually. My pulp floats. Oh, give it time yeah okay give it time um i got floaty pulp wow i want to drink your orange juice
okay um but no i know what you yeah you see please oranges will actually separate that's
right the separation of the orange juice is is an analogy to the separation of like a metal core and a rocky mantle and then a rocky crust on the outside, right? We think of
rocks as heavy, but they're light compared to metal. Yeah. So they float. Right. Okay. So when
the metal sinks, heat is dissipated outward gently, but with vigor into the surroundings,
the crust, and eventually the atmosphere.
In that process, you can get a lot of outgassing from underneath the surface out onto the surface,
which means that you can, for many millions of years possibly,
while it's happening, sustain the atmosphere
that will create meandering rivers that you described.
So I believe that it'll have to be...
It doesn't take a million years to meander a river.
Right.
But it may take that much time to, say, evolve a protovirus.
Yeah, sure, sure.
So the answer is the same answer that, no, we cannot prevent it from going away,
either because of magnetic fields not being there, nor by not enough gravity.
Instead, we just have to keep generating
more and more atmosphere at the surface
so that we can maintain equilibrium
even as the outer layers are going away.
Just to be clear, the magnetic field
shields us from particles from the sun
that would otherwise basically pick off
the faster moving atoms.
Would there be other problems as well,
being on Mars, than without that shielding?
Oh, yes.
Just with the solar winds hitting you?
Right.
When you have energetic charge particles.
It's not just magnetic field.
It's also,
isn't it also the ozone?
Oh, that's true.
Because UV from the sun
will break apart the water molecule
and make it H2O.
And the H is hydrogen,
the lightest element,
and it moves very fast
in any thermal environment.
You lose that.
And so, stranding the oxygen behind.
So, you systematically, molecule by molecule, take out your water.
That's right.
And that had nothing to do with the magnetic field.
Yeah.
There's all kinds of problems.
When you don't have a protection against ionizing radiation of any kind, whether they be light, like gamma rays and X-rays, or whether they be
charged particles.
Let's just go all out and say, if you can
terraform Mars, you can put up a shield.
Just think about it.
Or just a big magnet. How big a magnet?
Thank you. One of those little cartoon magnets.
There you go.
With the zaggy lines on it.
I would love to have that.
Everyone has their own magnet that they walk around with like an umbrella.
Their own magnet?
Yeah.
Like a miner's helmet.
They got their own magnet.
Yeah, the engineers
will find a solution
to that, Charles.
No one can stand
too close to a fridge.
I think the terraforming reality
is that you are going to have
to live in domes
in a place like Mars.
You can't just leave it open.
That would be funny
if they had a magnet
on the helmet.
Get too close
to your refrigerator
and you just get stuck.
Mommy!
It's like the modern version
of getting your tongue
stuck on a frozen pipe.
Yeah, that would be funny.
Which I think,
as a scientist,
you know if that happens,
the best thing to do
is just keep pulling.
Just keep.
Oh, yeah.
Lean back as hard as...
Yeah.
And eventually, it'll snap and then roll up. And roll up. It keep... Oh, yeah. Lean back as hard as... Yeah. And eventually it'll snap and then roll up.
And roll up.
It'll roll up, yes.
That's how it works.
We heard it here from two scientists.
While we've got scientists here as well,
One Hive Gazette on Patreon asks,
I've heard there are benefits
to putting a space telescope
on the far side of the moon,
I think because Earth's radio emissions won't cause interference there.
Do you think there will eventually be a telescope station there?
What exactly would be the benefits?
Oh, that's also, there's a name at the end of that as well.
That's Patrick Follis from Mill Creek.
Well, Patrick, yes, there should be a telescope there.
And there are many benefits.
I attended an entire conference on this in Arizona a few years ago.
Astronomy from the far side of the moon.
And it was a delight just to see.
Because we're nowhere near getting there.
Yeah.
But to see these early ideas of why it's useful.
Yeah, we are a radio noisy place.
And radio telescopes need this radio silence.
It's basically, well, it's noise
in the traditional sense.
It's electromagnetic noise.
Noise signals that you don't want to be there
because you're trying to detect something
that's dimmer than.
And would it all be blocked out
by being on the other side of the moon?
Essentially.
Yeah, it would have to penetrate through the moon.
So there aren't waves that can go around?
There is some diffraction.
A little bit, but on the edges.
But if you're smack dab on the other side of the moon,
Earth is dead to you.
You should be able to avoid it.
So for example, spacecraft now,
which have landed on the far side of the moon,
can communicate with Earth
because there is a satellite in orbit around the moon.
So it's further away.
Oh, so that's what bounces it off.
That's what bounces it off, right.
Exactly.
So any civilization any civilization any colony
would have to
have
some kind of way
to bounce off
of the side of the moon
to come straight back to us
either by permanent stations
like
towers
that can talk to each other
by the way
it's like those
sort of look behind glasses
that spies have
they get from the back
of magazines
what ever happened to those
oh Spider-Man still uses them.
Really?
According to...
He doesn't use Spidey Sense?
He's got to use
Google Glasses
to see behind them?
According to
information from decades ago,
which may have been,
you know,
outpaced by
21st century technology,
Spider-Man's mask
doesn't actually have eye holes.
And he actually
sees through mirrors
that's off to the side.
Really? I didn't know that.
I do also like to think that all spies still buy their stuff
from the back of joke magazines.
Absolutely.
That's how I got my Charles Atlas
body in seven days.
And it is remarkable.
And the x-ray specs.
You want to see the bones, Right. People's bones, yeah.
Which would also enable you to see through the moon
to Earth.
You wouldn't have any of that problem.
Yeah, so it's a great idea, especially for radio telescopes.
And radio telescopes
especially are big.
And that's one of the reasons why you can't
just send them out into space far enough
away from Earth to not
be affected by the radio. Oh, because that was going to be my
next question, is why you can't just sort of put it on
a moon lander and then drive it across to the far
side. I mean, radio telescopes are big, right?
Yeah, radio telescopes are big. They're big
because radio waves are big.
And to get a lot of radio
waves, to focus them, you need a bigger
dish than you'd otherwise think
you'd need. So, yeah, and
since the far side also gets sunlight, it's not the dark side of the moon.
So it's not like you're in eternal darkness, which might be an astronomer's dream state.
But a day on the moon lasts a month.
Right.
So all sides get sunlight.
And radio...
15 days of darkness, 15 days of sunlight.
And radio astronomers can actually work in the daytime.
Although...
Which is one of the coolest things ever.
Which is really, really cool.
Although the sun is a big source of radio noise.
So there are a lot of trade-offs back and forth,
but it's a really cool...
There's a zone around the sun you want to keep clear of it
because it'll be too noisy for you.
It'll be worse than Earth.
Where would the best place to be a telescope?
On the moon?
Yeah, or anywhere.
If you could put a telescope anywhere in the universe, where would you put it?
Ooh.
Wait, if you could do that, what do you mean a telescope?
Just go to the place you're looking
at with the telescope. Yeah. Alright,
well that's a fair point.
Just go there with a notepad.
Between galaxies, where it's dark
and there's no thing, then just go to where you're
looking. Right. Don't you sometimes
want the sort of, the wider view? The comfort of just sitting back and just go to where you're looking. Right. Don't you sometimes want the sort of wider view?
The comfort of just sitting back and being able to repoint?
Right.
No, I would be more excited about getting a big telescope
than putting the telescope in any given location.
If we can get a telescope that's the size of the solar system
or the size of the Milky Way galaxy,
now we can put that anywhere that it doesn't get broken,
and I'm totally cool with that.
Yeah, yeah, that's a good point.
You can make much bigger structures in space,
bigger than Earth itself,
and then you've got the baddest-ass telescope there ever was.
So that would be another use for once you get the technology
to start building stuff with robots.
Ah, yes, yes.
Exactly.
Yeah.
Exactly.
Well, it's the first thing we build with a robot in space
using asteroids, a telescope.
I would.
Yeah.
But there's probably not an economic driver for that.
Probably not.
This question comes from Moz Amu on Instagram, who says,
how would you market, that's in quotes,
space exploration to someone with an extremely utilitarian view?
I'm definitely not the one who needs convincing,
but that type of criticism is abundant nowadays.
And then also, lots of love from your fans in Dubai.
Dubai? Very interesting.
Cool. Well, the answer to that is
we don't have time.
We're going to take a break, and when
we come back, we're going to find out how to
convert the non-believers
in space exploration
when StarTalk returns.
This is StarTalk.
Tyson here.
Charles Liu there.
Hello.
Matt Kirshen there.
And we are commemorating Space Week.
And just to remind people, in case you didn't know, the first week of October happened to have been the week that Sputnik was launched, October 4th, 1957, by the Russians.
The Soviet Union, our sworn enemy, the godless communists, and we lost our shit.
and we lost our shit over here.
It would take us a year,
but a year later, in the first week of October,
we would found NASA.
NASA would become an agency a year later.
So those two events, both happening in October,
as well as many other space missions that have occurred in October,
have made a perfectly good argument to call this Space Week.
Yeah, I think it's great.
So we are Cosmic Queries.
So keep going, Matt.
So this is the question from just before the break, is how would you market space exploration to non-believers?
To someone with an extremely utilitarian view.
Yeah, Charles, what would you do?
You're an educator, scientist, space enthusiast.
What would you do?
Right.
Well, I have to use many different strategies with my students.
I often teach introductory astronomy classes where most of the students are not going to become scientists. Okay. Right. Well, I have to use many different strategies with my students. I often teach introductory astronomy classes where most of the students are not going to become scientists.
Okay.
Right. So how do you convince them that it's a good idea to go out into space?
I think there's a very good, and you have to use many different strategies.
One strategy being in the utilitarian side is to convince people that profit can be made, right?
to convince people that profit can be made, right?
The same way that people came to North America from Europe.
The New World.
Yeah, back in the 1600s was precisely people convincing others that if you send me to America,
I can make money for you and send back stuff for you,
whether it's gold, whether it's beaver pelts,
whether it's agricultural goods things like
that i can name places after you for example yes so they weren't very creative they all begin with
the word new new haven new york yeah new you know everything is new england new england just the
whole place so that profit is a utilitarian thing you can do right another thing is to
is a utilitarian thing you can do, right?
Another thing is to appeal to their sense of grandeur,
grandiosity, vanity, if you will, depending, ego, yeah.
And say, if you go out there,
you could be the person that everyone will remember for all of human history, right?
And a lot of times people will ask me that.
And younger kids, for example,
ask me some scientific question, which we don't know the answer to.
And there are many of those, right?
I will say something along the lines of, you know what?
Nobody knows yet.
Maybe someday you will be the person that discovers that.
And then we will all remember you and your scientific discovery.
I have a better answer.
Here's what you do.
You go to that person who's the non...
Okay, go to that person,
and in the dark of night,
sneak into their place.
Oh, yeah, that's real socially acceptable.
And just take away...
You do this with a search warrant.
Okay, okay.
Then you remove everything in their home
that was inspired or developed
because of space technologies.
So first you take away the smartphone.
Then you take away all integrated circuits and all of this.
Take away their Uber account.
Take away their health, their LASIK surgery.
Their non-stick pans.
All of this.
Their pens that write upside down.
And then they wake up and they say, what the hell happened?
And they take away weather.
What's the weather channel?
Weather forecasting.
All the weather forecasting.
Take away it all.
And then just leave them there bare-assed in their home.
So then they'll learn quickly what role space has played in our lives.
You really can say that space technology, basic science, those kinds of things that do not change the price of bread today can and have changed the course of civilization tomorrow.
And we want to be part of that.
Stop there.
Don't add words to that.
That was perfect.
Okay.
Just the way it came out of your mouth.
All right.
Printed on a T-shirt.
You got to know when to stop the beautiful quote.
It won't change the price of bread today,
but it could change the course of civilization tomorrow.
Yes.
All right, Matt, next question.
Well, I'm going to combine these two questions because they are...
Is that allowed?
Is that allowed?
Judges?
We want to hear who said them.
I absolutely will.
I'll credit both of these people.
It's a continuation of what we were talking about. Do we want to hear who said them? I absolutely will. I'll credit both of these people.
It's a continuation of what we were talking about.
But Jared Decker asks,
in the future, will it be government,
a private sector, or a combination of the both that will continue humanity's journey through space?
Okay.
And then Paul Pundir on Twitter asks,
as Neil Tyson, at Neil Tyson Tyson stated in his book,
military and science flourish together.
There are chances that the next scientific breakthrough happened,
but is classified by the government.
Thoughts?
Oh.
Well, that's already happened.
It's very true that...
Charles, we're not authorized to go that far.
Oh, I'm sorry.
You're right. You're right.'re right sorry okay no it could never happen no no no it would never happen no we are
fine no it just happens we are happy no neil did neil has written very eloquently about this
particular topic and so i'm going to defer to you in your conversation about the military aspect of things. But I will say from my purely civilian point of view, to me, the reason the military and
the government and industry all work together to move us forward in technology development and
innovation is simply because you need a lot of resources in any society to do those kinds of things.
Innovation is almost never just one guy in his basement, right?
That's just not how we're going to move civilization forward.
But that's how you get a movie made after you.
That's right.
If you're the one person burning the midnight oil.
That's right.
He's done it.
If it's 10 people taking five years in a lab funded by five different sources, nobody makes a movie about it.
I think that's right.
funded by five different sources,
nobody makes a movie about it.
I think that's right.
And our reality is, again, as Neil has written,
is that many, many, many hands are necessary and much, much, much money is needed
to make those really fundamental explorations.
What do you think, Neil?
Do you know Christian Huygens?
Yes.
He's a Dutch polymath, really, at the end of the 17th century.
He's credited with the rings of Saturn, identifying them.
For understanding the rings of Saturn.
Understanding that they are rings.
Yes.
He did a wave theory of light.
Yes, yes, yes.
And he actually has a spacecraft, the Huygens probe named after him,
the one that landed on Saturn's moon, Titan.
Detached from...
Yeah, beautiful.
From Cassini.
Show those amazing pictures that showed that on Titan,
there are mountains and rivers and lakes just like we see on Earth,
but they're made of very different substances.
They're made of methane.
So Huygens, in one of his books,
hypothesizes that God put evil people on earth so that good people would have to innovate and wage war against them by inventing new tools and technology.
Wow.
And this is the source of civilization.
Wow.
Because we have bad people on earth.
And this was part of God's plan.
He writes this.
Wow.
Almost like.
This is how connected and convinced he is that innovation and war go hand in hand.
Amazing.
If you're just using military resources and then turning them to purely discovery purposes.
Exploration, discovery, yeah.
Then that's a different dynamic than what you're describing
in terms of the actual desire to wage war.
That's an excellent point.
Oh, so, and to the answer, I think, like Charles said, it'll be a combination.
Government will do some things first, because there's not a profit motive yet,
until the trade winds are mapped and the hostels and the friendlies are established,
then private enterprise can come in.
I say this often, that the first Europeans to the new world
were not the Dutch East India Trading Company.
It was governments who took that first investment
for hegemonistic reasons and economic reasons.
And then, well, long-term economic reasons.
Then once you know and it's mapped,
this is how much it costs, this is how long it took,
this is what you can bring back,
now I can make a business model, I can sell tickets,
and now we have the Dutch East India Trading Company.
Right, right, that's a good point.
We've got to go into lightning round.
Uh-oh.
Lightning round reminder.
Lightning round is Samba Dancers.
Okay.
All right, we're going to see how good you've come.
You've come a long way, Charles. I don't know, I don't know. Let's see, Matt, go. All right. We'll see how good you've come. You've come a long way, Charlie.
I don't know.
I don't know.
Matt, go.
All right.
Corey Moon on Twitter,
no relation to our moon,
says,
has a nuclear bomb
ever been tested in space?
If so, what happens?
Not to my knowledge,
but if it does happen,
then the radiation
just goes a long, long way.
Half of why one would use a nuclear weapon
is for the blast wave
that does most of the immediate damage.
Well, there's three ways atomic weapons work.
One is the blast of light energy
that will vaporize things on the spot.
The next is the blast wave
that any typical bomb would have. The third is the blast wave that any typical bomb would have.
The third is the radiation sickness
that would then kill living things.
In space,
if there is no air,
then the blast wave does not exist.
And half of why you would ever use the bomb
is nullified.
But you do get the radiation.
You do get the radiation.
And you get the light energy
on top of that.
Which is also electromagnetic radiation.
And I don't know if we've ever exploded a bomb in space.
All right.
Thomas Kastner on Twitter says,
Star Trek included many aliens and creatures
that naturally existed in space
outside of planetary atmospheres.
Is that possible?
Anything is possible.
Can it be done with the DNA structure that we're used to?
Probably not.
I agree.
And think about it.
Imagine you drive your energy and your sustenance from inside yourself,
from storage that you've established.
So you can go outside of your spaceship,
and you don't have to breathe the air because you have some source of air
or whatever is your need
for staying alive inside you,
but that only lasts
a certain amount of time.
Is that any different
from an egg laid by a chicken?
The egg cannot survive
in our atmosphere.
And it stays in there
until all the egg resources
turn into a chicken that can.
So an egg is like a spacesuit for an embryo, an eggshell.
Are you with me on that, Tom?
I'm with you on it.
Let me just give one more 10-second quick answer to this question, right?
An astrobiologist once challenged me to tell her why a star is not alive.
And if I was unable to do that,
which I wasn't, right,
then maybe all the stars out in the universe
are a form of life, not DNA,
but just as alive as we are.
Yeah, stars can reproduce themselves.
They are born, live out their lives, and die.
And they have a metabolism.
It satisfies almost every definition of life
a biologist would hold for us.
All right.
Stars are alive!
Alive!
But do they have agency?
Oh, no, no, no.
And when does a star become alive?
Okay.
Next, go.
All right, Christopher Johnson.
I think we only have one more, go.
All right, Christopher Johnson on Instagram asks,
there are soon to be an explosion of cubesats
around earth oh no how do you see our near future shaping out with space becoming more accessible
commercially and to the public oh no this is not a lightning round answer but the bottom line is that
it's very exciting to have all these satellites up there but it's also very dangerous both for
science and for human beings over time we have to be very wise about how we send those things up there it has to be very carefully controlled
otherwise we're going to really regret having all those things can you even keep track of where they
are you can but again it requires a lot of advanced planning you can't just say have a company go send
it up a thousand satellites that's going to cause us all problems yeah i i would say the reason why
we haven't been visited by aliens because because they see all this crap orbiting Earth.
I'm not coming near that place.
That's my sound bite.
So, Charles, thanks for coming on StarTalk.
It was my pleasure.
I had a great time.
Thank you, man.
I really, really like coming on.
You were regular.
We got a little The Flash in there
and Spider-Man.
Always a little superhero action
when I'm around.
Gotta do some superhero.
Love that stuff.
And Matt,
always great to have you.
It's always a pleasure
to be here as well.
Thank you.
With Probably Science.
Thanks for staying.
You just came over
on a red eye.
I did.
So thanks for doing the show.
Thank you.
I'm propped up
by coffee right now.
The museum's finest coffee.
All right.
Keep me going.
Excellent.
This has been Star Talk.
Some of you
might have seen it.
Most will have listened to this episode of Cosmic Queries celebrating Space Week.
I've been your host, Neil deGrasse Tyson, and we've done the show from my office at the Hayden Planetarium at the American Museum of Natural History.
As always, I bid you to keep looking up.