StarTalk Radio - Cosmic Queries – Black Holes and Dark Energy
Episode Date: February 24, 2020Could the Earth become a black hole? Does dark energy impact your life? Neil deGrasse Tyson and comic co-host Chuck Nice answer your fan-submitted questions on black holes, dark energy, and other myst...eries of the universe. NOTE: StarTalk+ Patrons and All-Access subscribers can watch or listen to this entire episode commercial-free. Thanks to our Patrons Ashod Kuyumjian, Tony Biell, Jon Emerson, Zap Andersson, and Ocean & Dylan McIntyre for supporting us this week. Image Credit: NASA, S. Gezari (The Johns Hopkins University), and J. Guillochon (University of California, Santa Cruz). 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.
StarTalk. Neil deGrasse Tyson here, your personal astrophysicist.
We've got a Cosmic Queries edition for you today.
And I got with me the one, the only, Chuck Nye.
What's up, Neil?
Chuck.
I followed your tweets during the Super Bowl.
They were hilarious.
Oh, thanks, man.
Yeah.
So you were watching the game or tweeting?
What were you doing?
You know what?
I only tweeted during the halftime because I was actually watching the game and enjoying it.
And then halftime came up, and I started watching.
And, of course, it was very Latino.
That's right.
In every dimension.
Very Latino
in every single way.
And you know,
I have a partial Latino household.
Okay.
So, you know,
my wife is Puerto Rican
and Korean.
As is my mother.
Yeah.
So my wife is Puerto Rican
and, you know,
so we're sitting around
and the kids
and we're all looking
at all the Puerto Rican-ness
happening on the screen
and we're like,
yeah, this is great.
And then it occurs to me,
they better get this show over quickly
before Donald Trump deports the whole damn Super Bowl.
Across the border.
But yeah, that was fun.
So we got Cosmic Queries today.
What's the topic?
It's black holes and dark energy.
Okay, I should have sufficient expertise for that.
Yeah.
But if not, we'll get Jan 11 on speed dial.
Absolutely.
We'll have to check in on her.
We'll get a little Black Hole Blues boogieing over here.
Oh, yeah, that's her book, Black Hole Blues.
Yeah, I know.
All right, should we start?
Yeah, so she's my cosmologist at large.
Yes.
Yeah.
Yes.
I'm sorry we didn't have her here.
I love when you guys get into it, man,
because there's always such great information that you two,
you two seem to, it's not quite.
In physics language, it's called resonate.
There's a resonance.
Excellent.
Yeah.
In physics lingo.
Okay.
Yeah, so you have two waves.
So if they're not resonating, they can actually cancel out.
Right.
They can do nothing.
Exactly. If the peaks go with the troughs. Right. And you get nothing. Exactly.
If the peaks go with the troughs.
Correct.
But once the peaks go with the peaks and the troughs with the troughs,
then it magnifies the strength of the wave.
And then you have extra flow.
A little constructive interference.
Oh!
Oh!
Chuck remembered his high school physics lab.
And we're going to stop right there.
I'm going to quit while I'm ahead all right give it to
me all right here we go uh sunil engel from patreon because we always start with a patreon
patron because they give us money uh and we appreciate that so thank you sunil and sunil
wants to know this why are we so sure that there are black holes at the center of ours and perhaps every galaxy.
It could be empty space,
like the eye of a hurricane spiraling outwards.
Oh, wow.
Check this out.
Oh, I love me some eyes of hurricanes.
Right on.
There was a movie back in the 60s.
Really?
You know, the Apollo program was fully up and running,
and so it influenced storytelling.
And there's a movie called Marooned.
Marooned.
Yeah, so there was some spacecraft that got marooned.
It's like they couldn't come back down out of orbit.
Nice.
And so they had to launch.
What do you mean nice?
Nice for a story.
It's great for a story.
That's all space movies.
People go into space and something bad happens.
Exactly.
That's the plot.
All right.
So, of course, it's in Florida.
You know, this space program launch bases are in Florida.
And so they had to ready a craft to get to them before they died.
All right.
So they ready the craft and then a hurricane shows up.
Sweet.
Because it's Florida.
Right.
So they can't launch the hurricane and someone calculates,
wait, the eye of the hurricane
is going to pass directly
over the launch tower.
Right. But will there be a
launch tower left?
That's the problem. No, but they didn't
ask that question. Of course. Okay. But it was like
very cool. That's how I learned that
the center of the hurricane is actually a very silent,
quiet place. Right. And so the eye came over, then they launched, and you see the rocket coming learned that the center of the hurricane is actually a very silent, quiet place. Right.
And so the eye came over, then they launched, and you see the rocket coming out from the center of the thing.
Right.
So what they're asking is, in this question, what Sunil is asking is,
we see all this activity in the center of the galaxy, stars orbiting a big dark area.
Right.
How do we know it's not just like the center of a hurricane?
And the reason why we know that
is because
what we learned
from Kepler
and later Newton
is the orbit
that you have
is the speed
of your orbit
is completely
determined
by the mass
that's sitting
inside your orbit.
Aha.
The mass
around which
you revolve.
Right.
So what you say is, here are these things.
I can see how fast they're moving.
Run back to Kepler's equation and say there must be a mass,
a huge mass, like bigger than the size of the orbit.
Wow.
Wait, wait.
And then you say, but wait a minute.
We don't know anything that's that massive,
that's smaller than the orbit,
except for a black hole.
Gotcha.
Okay?
So in other words,
if it was a star with that much mass,
it would be huge or some other thing,
and you'd see it.
You'd see it, right.
You'd see a glowing thing.
Gotcha.
This is dark,
and it has huge mass,
and it's small.
That's three smoking guns right there.
Right.
That's implicating a supermassive black hole.
Supermassive black hole.
Yes.
And our black hole is less massive than the one in the center of the Andromeda galaxy,
our nearest big galaxy.
Do we have black hole envy?
I think we do.
Yeah, yeah.
Some black hole.
So, but we're talking about hundreds of millions of times the mass of the sun
but it's a black hole
so it's small
for that much mass
wow
and so that's why
so we do it for our galaxy
then we do it for
a neighboring galaxy
wait a minute
go ahead
and we can't
no other galaxies
are far away
so ground based telescopes
you can't see it
so we send up Hubble
and so we say
well if we have it
and we're not really
a special galaxy
in the universe
and Andromeda has it our nearest neighbor maybe this is astronomy And so we say, well, if we have it, and we're not really a special galaxy in the universe,
and Andromeda has it, our nearest neighbor, maybe, this is astronomy think,
these two galaxies have it, maybe every galaxy has it.
Right.
Okay?
Because why should we be special?
Right.
It's called the Copernican principle.
You're probably not special.
Right.
Exactly.
Copernican is better known as my father.
You're not so special. I don't know what you think, but go as my father. Not so special.
I don't know what you think, but go ahead.
Your father interacting with you.
Exactly. Okay, thank you.
So we hypothesize that maybe all galaxies have black holes.
So you invoke Hubble, who can see farther away galaxies,
and measure the movements of stars down deep in the middle,
and they were moving fast too.
Right.
And every next galaxy, and so we've now done enough.
We're just resigned to the fact that every galaxy's got a black hole.
Even some of the smaller galaxies that might not have,
they got black holes.
They still have black holes, right.
So, no, we haven't measured every one of the 100 billion galaxies in the universe,
but every galaxy we measured, the big ones, the small ones.
It's like taking a poll.
Yeah, except even better.
Right.
Because the universe doesn't have weird people living in back roads who think weird stuff.
Actually, it might.
The universe could have some weird galaxy that we've never discovered before.
Every galaxy that fits into a category of galaxies that we've observed, it's got a black hole of different masses.
And the more massive the entire galaxy,
then the more massive the black hole is.
Gotcha.
Yeah, there's some
that have billions of times
the mass of the sun
as a black hole
sitting in the middle.
Wow.
Yeah.
Da-da-ling-ding-ding-ding-ding-ding.
That's a very dated reference.
It is.
1974.
It really is.
It's a great, great movie and scene.
Deliverance.
Deliverance, that's right.
That movie was so great,
I have on purpose never seen it a second time
because it was so disturbing.
It is a disturbing movie.
It's the most disturbing movie I've ever seen in my life.
It's really, yeah.
Which is why I have it on a loop.
That explains, Chuck.
Okay. That explains, Chuck. Okay.
That explains it.
Sorry.
So that had Ned Beatty.
It had a boy.
What's his name?
Burt.
Burt Reynolds, right?
Burt Reynolds.
Yeah.
In a serious role.
Yeah.
At a time he was making comedies.
That's right.
Yeah.
He was very good.
Super cool.
Really good.
All right.
I guess we'll move on.
Wait.
Why not do another Patreon?
We took way too long to answer that question.
That's not true.
All right.
I know you always want to answer more.
We took a poll.
But here's the thing.
We took a definitive poll.
Yes, we did.
And you know what they said?
What?
They said, so these folks said, we want, keep the long answers.
Right.
And other people said, no, we want more questions.
This is true.
But guess what?
Let's split right down the middle.
Everybody wants that, though.
There's always going to be people who are like, I love your long answers.
It's entertaining.
I find out stuff, you know,
that I otherwise wouldn't have thought about.
Did you want to know about the movie Marooned from 1960?
I love that.
This is why I...
It's how I learned.
As a kid, how am I?
Ten years old?
Eye of hurricanes.
It's a quiet place.
As far as I'm concerned,
that's what makes the show good.
But listen.
And here's the thing, people.
And just listen to me.
Just trust me.
Actually, good point.
Here's the point. What? We're going to get to your question at some point. At some point And here's the thing, people. And just listen to me. Just trust me. Actually, good point. Good point.
Here's the point.
What?
We're going to get to your question at some point.
At some point.
Here's the thing.
At some point.
You raise an interesting point.
If I just gave answers, then you don't really need me.
No, you'd just be black Google.
Black Google.
Neil de Black Google. Black Google.
Sorry. Right. So these are not Google answers.
These are sort of fleshy.
Notice like, again, I'm just dating myself here.
In the old days, when you look something up, you go to an encyclopedia.
That's right.
But you never, it would take you an hour to get to the thing you were looking up.
Right.
Because you stumble.
Stop all along the way.
All along the way.
That's right.
There was a whole journey to find your answer.
And see, kids, this is what you're missing out on by not having an encyclopedia.
Because that experience you just said right there is one of the best things in the world.
It is.
You go look up in your world book.
Same with dictionaries.
You get lost.
Oh, I know about that word.
Where did that word come from?
Obstreperous?
What the hell is that?
Right?
You know, it's, no, and that's the fun of it.
And this is kind of what we're doing.
So, yeah.
All right.
All right, here we go.
Alex wants to know this.
I'm glad you pronounced his name correct.
Please.
Okay.
Alex from Omaha, Nebraska.
I was just in Omaha, Nebraska
You were where?
Yeah
Nice
Yeah, every time I hear Omaha
All I think of is Peyton Manning
Can a small blood
Really?
Is he from Omaha?
No, he's not
But he screams that out
When he's at the line of scrimmage
He goes
345
Omaha
Does he really?
I swear to God, yeah
And I have no idea
What it means in football
Or anything
But maybe somebody will write it and then let us know.
This is what Alex Betts wants to know.
Can a small black hole orbit a bigger black hole?
And if so, can it be a stable orbit where it would never fall into
or merge with the larger black hole?
It can't be black Google here.
Ready?
The answer is yes.
Boom.
Okay, next question.
Let's move on.
No, no, no.
So here's the thing.
I don't think a black hole knows it's a black hole.
Really?
It's just a lump of mass out there looking for love, okay?
That's why it's a black hole.
In all the wrong places.
Now I get the black part.
No.
So the point is, so a way to answer that is,
if Earth today turned into a black hole,
it'd be a mini black hole like the size of,
I calculated it once, of a plum, okay?
Oh, really?
Yeah.
So you mean all of this Earth got down into the size of a plum okay oh really yeah so you mean all of this earth got down into
the horizon it would be deep within the plum right but the the plum is the size of our event horizon
with the mass of the earth yes holy crap black holes don't play dude okay so let me ask before
we go on further with this i just gotta because you know you just really freaked me out. I know, but where's the space come from?
So as you're collapsing, why don't you run out of space inside of what's collapsing?
Okay.
You're wondering, isn't there a point beyond which you cannot compress it any further?
Yes. Okay. Yes. All right. All right. You're wondering, isn't there a point beyond which you cannot compress it any further? Yes!
Okay.
Yes!
All right.
Alex, we're getting back to your question.
I'm sorry.
But this is really freaking me out right now.
And I just got to know.
Okay.
So there are various states of matter.
Okay.
Okay.
Why is a rock a rock?
Because something is preventing it from collapsing.
Right.
Okay.
So what is it?
Well, it's the forces between molecules and atoms.
Okay.
Okay.
Right.
So they're called electronic forces, they're called.
I got that.
Right.
That's why we all have...
Right.
That's why I can't put my hand through my leg.
Through your leg.
Or through this chair.
Correct.
Okay.
Correct.
Okay.
I got you.
Unless you're an invisible man or something or some other...
All right. So now it turns out under high enough pressure, you can collapse that. Okay. And close
down the gaps that are between those atoms and molecules. Okay. All right. Now they get closer
together. Right. Okay. And you get something called electron degeneracy.
That's what it's called.
It has nothing to do with its moral compass.
That's it.
Of electrons.
Right.
Exactly.
Okay?
So electron degeneracy, they're so tightly packed, okay,
that you're trying to cram electrons into the space of other electrons,
and they don't allow that, all right, from quantum physics.
Okay.
All right?
So they keep their own identity within the structure.
And then we have matter out there that resembles it,
and it's called white dwarfs.
White dwarfs are electron degenerate, and they're extremely dense.
Mm-hmm.
Okay?
Wait a minute.
You can go further.
Okay?
There's still the gap between the nucleus of an atom
and the electrons themselves.
Right. Let's collapse that gap.
And that is the biggest gap of them all.
Ah.
Okay?
You know what that gap is?
Take a football stadium.
All right.
Okay?
And then put, I don't know, a mustard seed.
Okay.
Or something tiny.
Tiny is a mustard seed.
A poppy seed.
A mustard seed is biblical. Right. But let's take? A poppy seed. A mustard seed is biblical.
Right.
But let's take like a poppy seed.
All right.
Put that in the middle of the stadium.
Right.
That's the nucleus
and the outer side of the stadium
is the orbits of the electrons.
Wow.
Atoms are mostly empty space.
Gotcha.
And the first dude to determine this,
his name was J.J. Thompson
and he performed the experiment
by firing particles through a very thin film of gold.
Gold, you can hammer it so thin,
you can have practically one layer thick of atoms, okay?
It's very malleable is the chemistry term.
Make it really thin.
And he fired particles, and he's ready to see them.
Some bounce back, careen to the left, to the right,
and 99.999999%
of them went
straight through like nothing was there.
He was the first person to realize
that matter is mostly
empty space.
And the next morning he is rumored
to be afraid to step onto the floor
getting out of bed.
That he might fall through it.
Because he alone knew how empty
matter was.
So the next stage is collapsing everything down and you're cramming the electrons into the protons
because no longer can they separate themselves.
All right?
But they're not going to occupy the same space anymore.
They're crammed together.
If you combine a proton and an electron,
what happens to the charge?
It becomes what?
I don't know.
Proton.
Thank you for that admission of total.
All right.
Electron has a negative charge. A proton has a positive charge.
They cancel out.
How much charge are you left with?
Neutral. So you put them together, you
create a neutron.
So you don't have the electron
degeneracy, and you have
a pack of neutrons.
That is the densest matter that exists out there that is not a black hole.
Okay?
So these are called neutron stars,
because in my field we tell it like it is.
All right?
And neutron stars that rapidly rotate have magnetic fields.
They pulse in radio waves.
We call those pulsars.
Pulsars.
Okay, that makes sense.
The person who discovered pulsars, Anthony Hewish, won the Nobel Prize for it back in the 1960s.
And started a watch company.
Little known fact.
People always taking our words.
Exactly.
We got Milky Way candy bar.
Excuse me.
Can we get some royalties for that, please?
Okay.
The Mars bar.
I know it's a family name, but still, I'm taking it.
Right.
All right?
And you know how many car names are astronomically named?
Uh.
Okay?
There's like the Astro.
That's the name of a minivan.
That was a, oh my God, there is an Astro minivan.
Yes, yes.
I made a whole list.
I got a whole list.
We'll do a whole show on just car names.
Okay.
Car names.
All right.
A whole show.
All right.
I could do a whole show.
Okay, got you.
Don't get me started.
Don't make me go there. Okay. Car names. All right. A whole show. All right. I could do a whole show. Okay, gotcha. Don't get me started. Don't make me go there.
Okay?
A whole show on names of stuff that came from my field.
That came from your astrophysical.
Yeah, okay.
Okay, gotcha.
Promise.
We'll do a show.
Okay.
All right.
So.
So now we're at Pulsar.
Okay, now Pulsar.
That stuff is there.
So that's, if you take, want to know how dense that is?
Pulsar.
Okay, no, pulsar.
That stuff is dense.
So that's, if you take,
want to know how dense that is,
take a herd of 300 billion elephants and cram them into a thimble.
Holy crap.
Okay.
Wow.
All right, so now you can calculate
how much pressure that makes
to stop it from collapsing further.
And you can calculate that.
And then you figure out in a black hole,
the collapsing force
is even greater.
Damn.
So,
we don't know,
we got no physics anymore
after that.
Right.
So,
in a black hole,
it's denser
than the density
of 300 billion elephants
in a thimble.
Crammed into a thimble.
Right.
Okay?
And just imagine
trying to do that.
Yeah.
You know,
with your...
Definitely need a crowbar or something.
Something.
Push it in.
Just right.
So.
Wow.
So, yes.
I can get you to the neutron star density.
After that, it's all black holes.
It's all black holes.
It's all black holes.
Wow.
All right.
So now, Earth becomes a black hole.
We just continue to orbit the sun.
The gravity between us and the sun is determined just by our masses.
Our mass didn't change.
Right.
Okay?
It's still the same mass.
Who cares if we're a black hole?
Right.
All right?
Now, if you turn the sun into a black hole, we don't care if it has the same mass.
Right.
So we're this mini black hole orbiting a blue black hole, and there you go.
Right.
So we'd just be orbiting the little mini black hole.
That's all.
No, we'd be the mini black hole
orbiting...
Oh, no, I'm saying
if the sun became a black hole,
we would just continue
to orbit that little black hole.
But we're littler.
So we're the plum-sized black hole.
Right.
The sun is the big black hole.
The sun is the bigger black hole.
Bigger.
Right.
So the point is,
the reason why we see black holes
have such high gravity
is they have high surface gravity.
But if you step
the same distance
away from it
that you were
before it became
a black hole,
there's not any
difference at all.
Nothing's going to happen.
Right.
It's just that you can
get real close
to the center of gravity
and the power
of the gravity
keeps getting,
the force of gravity
keeps getting higher
and higher and higher
and higher and higher.
Okay.
So that's how that works.
That's awesome.
So the answer is yes.
The answer is yes.
We've got to take
our first break.
When we come back,
more Cosmic Queries,
black holes, and dark Energy on StarCraft. We're back.
StarTalk.
Cosmic Queries.
Chuck Nice.
That's right.
The basic ingredients.
You, me, Cosmic Queries, StarTalk.
That's it.
That's it.
Let's take it from there.
Let's take it from there.
All right.
And topic again?
Dark energy and black holes. Let That's it. That's it. Let's take it from there. Let's take it from there. All right. And topic again?
Dark energy and black holes.
Let's do it.
I think I can get through that topic.
So far, so good.
All right.
Let's jump right back into this with a question from Facebook and Kent.
Bayaker.
Mm-hmm.
Yep, Kent. Kent, people, would you please give like phonetics pronunciation guides for chuck yes okay
yes because reading is fundamental and i think you guys are just screwing with me to be honest
i really do anyway he goes like this chuck chuck chuck please ask neil if a black hole can reignite
into a star once it has lost enough mass through Hawking radiation?
Oh, really?
What a great question.
Good question.
Interesting.
No.
Okay.
There you go, Kent.
Because if somehow the black hole could stay the same size and you pulled mass out. Right.
Then, I don't know, I have to think that through.
But what happens is as you pull mass out,
the black hole gets smaller and smaller and smaller
to be the appropriate size black hole
for the mass that's left over.
Okay.
Okay, so that's what's happening.
Gotcha.
So the black hole just continues to shrink,
keeping all of its parameters,
the sort of black hole proper.
Ah, gotcha. So that hole proper. Ah, gotcha.
So that's why.
Gotcha, gotcha.
There you go.
All right.
That's pretty cool.
All right, this is John.
But that's, I mean, that'd make a good sci-fi story.
Someone in the future figures out a way to undo black holes
and turn them back into sort of masses that they once were.
Right.
Yeah, okay.
That's kind of cool.
Let's do it. If you could do that, you were. Right. Yeah. Okay. That's kind of cool. Let's do it.
If you could do that, you probably could just create a black hole.
Yeah.
Once you start controlling black holes, they will bend to your whims.
And then the first thing people do is weaponize it.
Of course.
Yes.
This is what humans do.
Now, that's a great sci-fi story
instead of some stupid
like Death Star.
Right.
Like you actually have
a killer black hole.
No, no.
They did that in Star Trek.
Oh, they did?
Yes.
It was this drill
that would drill down
to the center of a planet
and then drop red matter
and then it would
turn this planet
into a black hole.
That's right.
So, yeah, they've been there. Yeah, damn. I'm late i'm late on that one you're right that was the red matter
that yeah again why destroy the whole planet wouldn't you want to keep the planet if you
don't if you're enemies with who's on the surface get rid of them by some diabolical means right but
keep the real estate yeah what are you doing and doing? And it's always about, like, revenge.
Like, you know, it's not going to bring your wife and children back.
Okay?
Get over it.
All right.
Here we go. John Feltron.
A black hole warps space-time around it.
A star does the same.
Yes.
What happens to the gravitational well that the star has formed if the star begins to fall into the gravitational well
formed by the black hole?
Does it dissipate at the same rate
as the amount of mass being stripped?
Or do both wells combine?
I love the people.
This is some good.
This is so good, John.
You're just showing off.
That's what you're good, John. You're just showing off. That's what you're doing, John.
John probably worked right here at the museum.
John is downstairs.
Sending us questions through, babe.
All right.
All right.
Wow.
There's a lot to...
Okay.
So if you think of it as the classical distortion in like a rubber sheet.
Right.
The rubber sheet model.
So the black hole is like a very deep hole in the rubber sheet.
Right.
But everybody's got a dimple in the rubber sheet.
Okay.
Okay.
You have your own...
I have my own little dimple.
Your own little dimple.
Right.
They're adorable.
Depending on the mass,
depending on the mass,
it determines how deep the dimple is
in the fabric of space and time.
Right.
Okay.
As you merge two dimples,
if the black hole,
if it's a black hole in a star,
if the black hole begins to flay the star,
as black holes are known to do,
then its dimple will get deeper, and the black hole's dimple will get deeper,
and the star's dimple will get shallower in response to this.
Welcome to Cooking with Black Holes.
Today, we're going to fillet a star.
Go ahead.
I didn't say fillet.
I know.
You said fillet.
Fillet. Right. Fillet. You know what that means? Go ahead I didn't say filet I know you said Filet Filet
Right
Filet
That's a
You know what that means
It means to disperse
No
Oh
What's it mean
No
I thought it meant like to
No
Pull apart
It's to
Skin
Got you
Okay
I'm pretty sure
Listen I'm not
Let me
I'm checking right now
I thought it meant to pull apart
But to skin Well it could be Generally if you're thought it meant to pull apart, but the skin, I'll take it.
Well, it could be.
Generally, if you're pulling someone apart, you would do it with the skin first because that's the outer layer.
So maybe that could have led to your hypothesis that, all right, let's just do this.
Okay.
And we go here.
I love that he actually looks it up instead of just going, hey, Siri.
Okay.
Here we go.
Flay. To. Here we go.
Flay.
To strip off the skin.
You're correct.
Or outer covering of.
Right.
So it's not really pull apart.
It is indeed skin.
Because stripping is skinning.
And then you metaphor it and it's like to criticize or scold with scathing severity.
Oh.
Okay.
You just got flayed.
Flayed. And here's another one. To deprive or strip of money or property. Oh. Okay. You just got flayed. Flayed. Exactly.
And here's another one.
To deprive or strip of money or property.
Oh, that's mine.
Because these are your outer accoutrements.
Exactly.
Gotcha.
Better known as divorce.
Oh, that's what it is.
So divorce is a legal flaying.
It's legal flaying.
That's all.
Sweet.
All right.
So anyway, the star is flayed by the bigger dimple of the black hole.
Yes. And so if you flay that, so the dimples change size relative to the mass that has changed hands.
All right.
So it is possible for the black hole to flay the star completely so that it no longer has a dimple
and it has consumed all of its mass.
Gotcha.
And then it is the sum of the two dimples together.
Gotcha.
All right?
Otherwise, you can have a star that's getting flayed while it's orbiting the two.
And so you have two dimples just in orbit with a slow change in the two until one just
disappears completely.
This is kind of fun to watch.
Right.
I mean, you can imagine that.
Right.
Yeah.
Okay.
So there you go.
There you have it.
So that's how it is.
Okay.
All right, let's go to Love Marauder.
You know how to pronounce that.
Yeah.
Okay, go.
How big of an impact
does dark energy have on my everyday life?
None.
Okay, next question.
It's not always about you, Love Marauder.
It's not always about you.
Okay, so the thing is,
dark energy is this still mysterious pressure
in the vacuum of space
that's forcing the universe to accelerate in its expansion
against the wishes of all the galaxies and their gravity trying to slow the thing down.
Right.
And so some people thought of it as an anti-gravity force.
Could we one day harness it and make spaceships out of it?
So there's an interesting sci-fi frontier
there. But what I can tell
you is, because it's manifesting
in the vacuum relative
to where there isn't a vacuum,
there's not much
vacuum here. No. Right?
So gravity and electromagnetism
and all these other things are really dominating
where you happen to be.
So no, there's no known visible or measurable effect on anything you will do in your life.
Right.
That's what I'm saying.
There you go.
If you're not a galaxy, don't worry about it.
Right, yeah.
If you're not a galaxy among other galaxies in the expanding universe, just chill.
Just chill.
Chill on that.
All right, well, there you go.
That's it.
Love, Mar you go. That's it.
Love Marauder.
I hope you find that sufficient to continue your love exploits.
All right.
All right.
This is Brian Bull,
and he wants to know this.
Does a black hole still produce light
or other radiation
that just can't escape the black hole's gravity?
So, yeah. Yeah, there's a lot of energy and matter inside escape the black hole's gravity. So, yeah.
Yeah, there's a lot of energy and matter inside of a black hole.
Right.
So, if you're in the black hole.
In.
Yeah, he's probably bright as I don't know what.
Right, right, exactly.
Because the light got no place to go.
Right, it's got no place to go.
Yeah.
And so, it's all in there.
So, now, we don't have direct evidence of this.
Chuck, you want to be?
Chuck, call me when you get back.
I'm going to find this out.
Let me go get on this. Yeah, you report back. I'm going to find this out. Let me go get on this.
Yeah, you report back.
I'm going to full report on my desk in the morning.
I'll be like Matthew McConaughey in that string theory movie.
Damn, what was the name of that movie?
Interstellar.
Interstellar, yes.
What do you mean that's string theory?
Interstellar.
Interstellar.
Get with the program.
Listen, I'm on new medication.
It's really bothering my memory.
All right.
So, yeah, there's no reason why you wouldn't still see light and other things inside the black hole.
Right.
Right.
It's just not getting out.
Cool.
Yeah.
Excellent.
Excellent.
Excellent.
All right.
Oh.
You know what else you'd see?
Go ahead.
If you tried to look outside the black hole, you'd see all the stuff coming in.
Oh, really?
Oh, that'd be really bright.
Oh, yeah.
That's kind of cool, actually.
Yeah.
Not a bad, yeah.
The only problem is you'd just be like, don't come in here.
There's no way out.
No, don't come in.
You know.
What's that guy saying down there?
All right.
This is RYP.
Thank you, RYP, for just using your initials.
Okay. RYP wants to knowYP For just using your initials Okay
RYP wants to know this
Maybe that's his name
Rip
Like yeah
That's cool
Rip wants to know this
Could dark energy
Or matter
Dark matter
Or dark energy
Is it possible
To manipulate it
To use it as a fuel
Of some sort
Interesting So here's the problem Dark energy Is it possible to manipulate it, to use it as a fuel of some sort?
Interesting.
So here's the problem.
Dark energy, we don't know how to interact with it.
We just measure its effects on the universe.
Dark matter reveals itself to us through its gravity.
Okay.
But it doesn't reveal itself to us in any other way that we normally interact.
So we can see its effects, but not what it is itself.
Not materially.
Not materially.
That's correct.
Because materially, what do you do?
You touch it.
You pinch it.
You weigh it. I mean, you grab a piece of it, put it on a scale.
You do all this.
And dark matter, in order to have something,
you are this person called Chuck.
Right.
Because all your atoms
are all attached to each other.
Thank God.
Okay?
Yes.
They're all there.
Right.
Dark matter
not only doesn't attach to your atoms.
Right.
It doesn't attach to itself.
Ooh.
So, as far as we know, there are no lumps of dark matter out there.
There are no dark matter planets.
No dark matter galaxies.
In the cosmos that is oatmeal, there are no lumps of dark matter.
You don't like lumps in your oatmeal?
No, I do not.
I used to as a kid because you would roll them in sugar
and then eat them like oatmeal candy, but go ahead.
Sorry.
Wow.
That was early.
You were early out of the box with granola.
Yeah.
Those are rolled oats.
With dipped, rolled in sugar.
So you take the oatmeal lump, you roll it in some sugar,
and you eat it.
It's oatmeal candy.
So there you go.
All right.
Yeah.
So, yeah, there's no, we have no way to harness it in that it. Yeah. So there you go. All right. Yeah.
So, yeah, there's no,
we have no way to harness it in that sense.
Gotcha. If you can't grab it
because your hand goes straight through it
and it doesn't make itself,
give itself any kind of density.
Sweet.
You can't.
There's nothing you can do to it.
Right.
So you can see it.
No, no, you can see its effects.
You can see its effects,
but you can't see it and you can't can see it. No, no, you can see its effects. You can see its effects, but you can't see it,
and you can't interact with it.
It is literally invisible.
Wow.
Because not only do your molecules and atoms not interact,
light doesn't interact with it.
Oh, my gosh.
And light and molecules and atoms are all related to each other.
Correct.
They all interact.
You reflect light.
Right.
Some light goes through you, but gets absorbed inside of you.
Like x-rays go into your bones.
This is true.
And they can see this on a map.
They shadow your bones.
I absorb a little more light than most, I will say.
That's true.
Yeah.
Exactly.
It's called albedo.
Wait a minute.
We have a word for that.
Albedo.
Yes.
Yes.
Okay.
If you have an albedo of one.
Right.
You reflect 100% of the light that hits you.
Not to be confused with libido. If you have an albedo. one, you reflect 100% of the light that hits you. Not to be confused with libido.
If you have an albedo.
If you have a libido of one.
If you have an albedo of zero, you absorb everything that comes to you.
That would be a black hole.
If you have a libido of zero, you are married.
Go ahead.
How many more libido jokes can you fit into a minute?
I can't help it.
I don't know what it is, but go ahead.
Albedo.
So the point is, yeah, albedo.
So albedo, it's the ability of a surface of something to reflect light.
That's all.
And it's a percent.
So one would be 100%.
Nice.
And zero, zero.
So the moon has a very low albedo.
As bright as it can be, it doesn't reflect much light.
Wow.
Yeah, it's like 10% of the lighters.
I forgot the exact number, but it's absorbing most of the rest of it.
Wow.
Yeah, yeah, yeah.
So where was I?
All I'm saying is if you can't grab something and put it in a box.
You can't harness it.
You can't.
What do we get?
We don't know how to harness it.
We need some other way that we invent,
once we figure out what it is,
we might be able to find a dark matter trap.
How do you figure out what something is
if you can't interact with it?
I know!
Thank you.
He's like, welcome to my world!
I know, thank you.
This is the longest unsolved problem in astrophysics.
It's been with us since 1936.
Wow.
Yeah.
Dude, that is amazing.
That is really cool.
I'm just saying.
So the guy who figures that out.
The person.
The person.
The human.
You're right.
I shouldn't say guy. I don't know how to say.
We're living in 2020 now.
The person who figures that out is going to win a Nobel Prize time 10.
Yeah.
The person who figures out
what dark matter is.
Right.
And then we,
ideally we can control it,
manipulate it,
put some in a box.
That'd be cool.
Nice.
All right.
Yeah, yeah, yeah.
We got to take a break.
Okay.
When we come back,
more StarTalk,
Cosmic Queries,
Black Holes,
Dark Matters,
Dark Energy. the queries black holes time to give a patreon shout out to the following patreon patrons
ashad kuyamjian and Tony Biel.
Thanks so much, guys, for supporting us
and helping us make our little trek through the cosmos.
And anyone else, if you would like your very own Patreon shout-out,
make sure you go to patreon.com slash startalkradio and support us.
We're back.
StarTalk.
Cosmic Query.
Yes.
Chuck Nice.
That's right. Tweeting at Chuck Nice Comics.
Thank you, sir.
Yes, that is correct.
Very good.
So, it turns out we are luxuriating in these answers.
I will execute a privilege and say we will not do lightning round.
Excellent.
Okay.
Good.
We'll just continue to bask in the cosmic knowledge juxtaposed with cosmic ignorance.
Sweet.
And therein is the movie.
Did you just describe the two people who are on this podcast?
Wait a minute.
What just happened?
Chuck, you need more self-confidence here.
I was describing something bigger than us.
Okay.
Okay?
All right, all right.
It's the intersection of cosmic knowledge and cosmic ignorance
that is the moving frontier of cosmic discovery.
Ooh, nice.
I love that.
You should tweet that.
Let me go ahead and tweet that.
Yeah, you should.
That's quite eloquent and elegant at the same time.
All right, here we go.
Martin Cuevas.
And Martin wants to know this.
What would happen to the Earth if it came close or directly in contact with a black hole?
The one being hypothesized to be perhaps the Planet 9 orbit.
So I didn't realize that Planet 9 was actually posited to be a black hole.
I thought that's why they call it Planet 9.
Because it's supposed to be this supermassive object that's out past the Kuiper Belt.
That's new to me too.
Okay.
All right.
Good. I'm just saying. All right, good.
I'm just saying.
All right, good.
Then I'm not alone.
Good.
I don't know who's hypothesizing that we have external black holes.
I don't know.
Right.
Maybe I missed that.
Right.
A new development?
That morning edition of the Astrophysical Journal.
Right.
I might have, you know.
But it's still a fascinating question.
I think about this all the time.
Oh, really?
Yeah.
If earth happened upon a black hole that was traveling through space,
an encounter between earth and a black hole, earth loses.
Gotcha.
Okay.
Right.
Now, because we know about this tidal force that will stretch things,
where the side of the Earth nearest the black hole
will experience a much higher force of gravity
than the side that's farthest.
That means the side closest to the black hole
will pull towards it faster than the side of the Earth.
And so you'll end up stretching Earth.
Now, the problem with the word stretch is,
you know, Earth is not Gumby, right?
Or Elastic Man.
I am Earth, damn it.
I'm sorry.
So it's not like, Earth is not made of rubber.
Earth is made of sort of solid substance.
So if you're going to stretch, put under stress the solid sphere that is Earth,
Earth will basically begin to crumble okay into
smaller and smaller bits of rock so you're looking at massive earthquakes oh yeah but it would happen
and tidal waves oh yeah oh yeah i mean if you're falling straight in right oh oh so yeah so earth
will distort become more and more oblong
until the strength of the materials
can't hold that shape anymore.
Right.
And then it'll start sort of crumbling apart.
And we call that spaghettification,
is when you start becoming this long strand.
But again, spaghetti is one continuous string.
Right.
Right.
Whereas this will be a stream of particles.
That's right.
A parade of particles as they...
So is this Netflixication instead of Spaghetti-fication?
How do you get Netflix in there?
Streaming.
Now, I am going to...
Okay, you have to flub one every now and then.
We're going to cut that out.
We're cutting that one out.ub one every now and then. We're going to cut that out.
We're cutting that one out.
That one was just for me.
You were testing.
New material.
Just testing material.
That was just for me.
You're the person who came up with spaghettification, if I'm not mistaken.
No, I just popularized it.
Really?
Oh, I thought you actually coined the term.
No, I popularized it, but it's traceable to Martin Rees.
Martin Rees.
Sir Martin Rees.
In fact, he's now Lord Rees.
Gotcha.
A little full of himself, isn't he? No, no.
You call me Lord Rees.
Oh, Sir Martin Rees.
That's Lord Rees to you.
What the hell is up with Martin?
Just walking around.
Marty.
Marty.
Marty from the street corner.
What happened to you?
Hey, Marty.
It's Lord Rees now.
What is Marty?
What the hell is your problem, Marty?
Wait, he's not from Brooklyn.
Hey, Marty.
Lord Rees. I command thee to. Martin. Lord Reese.
I command thee to.
I command thee to bring me my spaghettification.
All right.
So.
All right.
Okay.
All right.
Well, yeah.
Did we answer that?
Oh, yeah.
Yeah.
So we just break apart.
So we break apart. If you're sitting here on earth, it would just be an interesting phenomenon to behold.
That's all.
Yeah.
Yeah.
That's cool, man.
All right.
Hey, Martin, great question.
It would break open the very hot liquid core of the earth.
Now, that doesn't sound good.
No.
I'm just going to say.
I don't know if I like that.
Cracking open the earth.
And the whole middle.
And the whole middle.
This is glowing iron nickel ball of molten iron.
Right.
Yeah.
Yeah, that's a bad day for earth.
Yeah, that's not cool.
Right on.
All right, let's go to Todd Tobin.
And Todd says, how does a black hole not consume space time itself?
space-time itself and just go
BS crazy,
bat crap crazy
and destroy the entire universe.
Why aren't black holes running amok?
Did he say BC crazy?
He said bat,
you know,
the bad stuff.
Yeah, the bad word.
Did he say crap or did he say the S word?
No, he said the S word.
Oh, you were translating for us.
Yes, I was.
Because you're acting as your own sponsor.
You know why?
Because...
Acting as your own censor.
These little kids, they write me and they're just like,
hey man, you know, children are listening to this.
And I'm like, well, you shouldn't be.
Stop trying to learn stuff and give up your dreams.
Damn you.
That's a joke, people. Yes, it was. Please. These are jokes. Damn you. That was a joke, people.
Yes, it was.
Please.
These are jokes.
Go ahead.
But anyway, yeah.
So he said BS crazy.
Okay.
Bat crap crazy.
And why aren't they, why aren't black holes running amok?
Wait, wait.
So he's saying why doesn't the whole thing just like, why aren't they out of hand?
Why aren't they just like consuming not only. Oh, I get it. Why aren't they consuming space hand? Why aren't they just consuming not only...
Oh, I get it.
Why aren't they consuming space-time itself?
And just eating away the entire universe.
Just eat it away.
Okay, because black holes are not any more voracious as black holes
than they were as stars before they became black holes.
Interesting.
So it's really about mass.
It's just the mass. It's just the mass.
It's just mass.
That's all.
If you get...
Now, so the thing...
Here's how to think about it.
Think of the sun, okay?
Before you...
How close can you get to the sun?
You get near the surface and you just vaporize, okay?
All right.
So now the sun's surface,
its atmospheric surface,
has a certain strength of gravity there.
Okay.
Now let's cram the sun into a smaller volume.
Same amount of mass.
It's just denser.
You can now get closer to the sun's center of mass.
So its surface gravity is now higher.
Cram it smaller.
The surface gravity is even higher.
Black holes are fun to think about and talk about
because you can get close to them.
If you get closer to Earth's center of mass,
you're leaving half of Earth behind you,
and it's not interesting.
The fun thing about black holes is you can get close to their center of mass,
and their entire mass is between you and their center.
That's why they become interesting.
But puff it back up to the original size,
there's no different.
Nobody cares.
That's right.
So black holes are just,
they're,
they're,
it's,
you can just get,
it's,
they're,
they allow you to get close to them without you knowing how deadly they are in such
a state oh my that's all oh snap that's the difference okay all right so and but technically
their next girlfriend like that they technically they are consuming the space time around them
space folds back on itself so that you cannot even come back out.
You can think of a black hole as completely consuming the volume of space-time in its vicinity.
Wow.
I have no qualms with you thinking of what's inside the event horizon as the black hole having eaten its own space-time continuum.
I have no problems with that.
That is super cool.
Right.
Wow, what a great question then.
And there's that old ancient question,
what happens if a snake starts eating its tail
and continues to do so?
Right.
Will the snake one day disappear?
I don't know, but it certainly won't be hungry.
This we're sure of.
No, just think that through.
If it just keeps eating itself,
but then how does the head eat itself?
It comes in from behind the head.
Okay? If you imagine a completely
flexible snake at all times.
It just keeps going, going, going.
It keeps eating, then it eats.
And there you go.
I love that sound.
That is the sound a snake would make at the end of the meal.
And it's gone.
No more snake.
Right.
That's a black hole.
There you go.
All right.
All right.
That's cool.
All right.
Christopher Karnes, Kairans wants to know this.
Everything in space seems to be spinning and rotating.
Yes.
The planet spins and rotates around stars.
Stars.
So just to be clear, if you rotate on an axis, if you turn on an axis, we say you're rotating.
If you move around another object, we say you're revolving.
Okay.
Okay.
So just, most people don't know that, but since the language can distinguish it, why not?
Right.
And they're not weird words.
We've all used them before.
Okay.
So go.
So stars spin and revolve around galaxy centers.
So spins rotate and then they revolve.
Yes.
Even galaxies are spinning.
Yes.
Is there any evidence that they are rotating around something?
They spin, but do they rotate or revolve? And with the new vocabulary, revolve around something. They spin, but do they rotate
or revolve?
And with the new vocabulary,
revolve around something else.
Revolve around something else.
So in our neck of the woods,
no.
Wow.
Okay, well,
because we don't have
enough galaxies
where we are
to be able to create
an orbital system.
Right.
Right now,
as far as we can tell,
we're on a one-way collision course
with an intrometer. Right. We're not orbiting each other or anything like that. Right. Right now, as far as we can tell, we're on a one-way collision course with the interminable.
We're not orbiting each other
or anything like that.
All right.
However,
there are places in the universe
that have hundreds
and in some cases,
thousands of galaxies
in a sort of a beehive configuration.
You can track those galaxies.
Those would have orbits
around the center of that galaxy supercluster.
We call it superclusters.
Superclusters.
Right.
So, yes, in not all cases, but in some interesting cases,
you do have stars that rotate, orbit the center,
revolve around the center of their galaxies,
as do all the other stars in their galaxies,
and the galaxy itself is orbiting the center of the supercluster.
Yes.
Now, is it possible to see the...
to see the movement of the galaxy
and measure it in such a way
that we could possibly see
if there's something there revolving around,
like a black hole,
or something that's at the center of the supercluster?
Oh, you know, centers are superclusters.
That's an interesting thing.
Yeah, that's what I'm saying.
That would be a really cool thing to find out
if the supercluster is actually revolving around a black hole itself.
Yeah, that's an interesting question.
I don't know.
Wow.
I don't know.
Cool.
Well, please go find out.
Is that my assignment between now and the next time?
Okay, Chuck, I'll get right on it.
I'll get on that for you, buddy.
But it turns out you might ask,
could the supercluster be orbiting around some other concentration
of some metamass of galaxies?
Right.
Here's a problem.
You ready?
Go ahead.
You can look at the speed of galaxies moving
in the largest of the superclusters
because you can measure this with the Doppler shift.
Okay.
That makes sense.
We all know the Doppler shift intuitively.
All right.
So if a car is...
Exactly.
You stand on the edge of a freeway.
Right.
Here.
I can do better than that.
Here.
Go ahead.
Oh, that was good. Oh, sorry. That was a speedway. Right. I can do better than that. Go ahead. Oh, that was good.
Oh, sorry, that was a speedway.
That was, yeah.
Not bad.
So no one ever asked,
why doesn't it sound the same coming towards you
as it does going away?
Why doesn't it...
No, it's...
Okay.
So the pitch changes.
Okay.
Why are you laughing?
I'm trying to teach here, dude.
I love it. Okay. Go ahead. So it's a higher pitch if it's coming towards changes. Okay. Why are you laughing? I'm trying to teach here, dude. I love it.
Okay.
Go ahead.
So it's a higher pitch if it's coming towards you.
Right.
And a lower pitch as it goes.
So it's like compression and expansion.
Exactly.
Gotcha.
And so even though it's only giving the same sound, if the car is parked in front of you,
the engine is making one sound.
Right.
Inside the car, all you hear is...
Exactly.
Exactly.
But here...
No.
Okay.
Got you.
So, if you measure...
Worst Kung Fu movie ever.
No.
If you measure the change
in the frequency of sound...
Right.
...as it comes towards you...
Right.
...and compare it to...
You can...
And you know what that sound should be
is a very simple formula that was developed by Christian Doppler, and compare it to, you can, and you know what that sound should be,
is a very simple formula that was developed by Christian Doppler,
who was a German physicist.
He might have even been a chemist, actually.
But he was, I think this was the 19th century.
He figured this out.
Okay.
And he did it with a railroad train,
the whistle of a train as it came by,
because they didn't have race cars in the 19th century.
So you measure how fast the galaxy is moving
and then you look at how big the galaxy cluster is.
You say, how long will it take
at that speed to cross the cluster?
Got you.
That's a perfectly honest question.
Yeah, no worries.
For the biggest of these clusters,
it takes longer than the age of the universe.
Wow.
So the cluster has not had enough time to have everybody sort of organize into their orbits.
Gotcha.
So for many of these measurements, you can't use the speed as an indication of other stuff that's going on.
Wow.
Yeah.
We don't live long enough.
I know.
Damn it.
I know.
Our time is like that.
During the Super Bowl, I tweeted that.
No, I did not.
See, I read your tweets.
You don't read my tweets?
Now I'm embarrassed.
All I said was, while you're watching, if the hundred yards on the field were a timeline of the universe.
Okay.
Of the 14 billion year universe, and one end zone is the Big Bang.
Right.
And modern day is like the other end zone.
Then the thickness of a blade of grass, the width of a blade of grass at the other end zone, is from 30,000 years in our past to the present.
Just one?
The thickness.
The thickness.
Not the width, the thick, just...
Just right.
The thickness.
Yeah.
Cavemen to modern time.
That's our little...
That's what we occupy.
Well, humans, yeah.
That's what I'm saying.
Cro-magnon.
Cro-magnon humans over that time.
So, that's the entire history of our species Well, humans, yeah, Cro-Magnon humans over that time.
So that's the entire history of our species on a 100-yard-long football field.
Wow.
So were it not for computers to simulate what's going on over timescales longer than we live,
we would not know anything about things that lasted longer than we do.
Damn.
Oh, yeah.
That's pretty wild.
And our ego historically was,
we are the know-everything.
So why should Earth be much older than our history books? Exactly. Right.
Why should it? Why should it?
When this is all about us. Why should
your eyes not
see things that are seeable in the
universe? Right. When I'm the only one that matters.
Right. So even the telescopes
that were first constructed only brought us visible light right so we have better versions of our eyes but it's
still light that we can see to discover infrared x-rays ultraviolet x-ray gamma rays the whole
rest of the spectrum you can't see how dare the universe communicate in ways that our senses
cannot detect wow you know what this is really fascinating because it starts,
as you look at the fact that we are indeed one chromosome away from,
you know, the other apes.
But yet at the same time, we're the only, or are we?
Are other animals thinking about this kind of stuff
that we're talking about right now?
Are there dolphins just like, yeah, I'm telling you right now, man,
there's something more than this ocean.
There was a, we'll end, we got to end right now,
but there's a comic, Gary Larson, you remember the illustrator?
There was a chicken, a horse, a cow, and some other farm animal in the barn.
Right.
They're having a conversation.
Yeah.
Okay.
And the chicken says,
But if you divide by the square root of the mass, you get the same result.
And then, like, the cow said, wait, but you're missing the basic premise of my theory.
And one of them looks out the window, farmer.
Okay.
Farmer's coming towards them.
And the farmer comes in.
Right.
Yeah, that's cool.
So you don't know if they're not talking that way when you're not looking?
No, I'm pretty sure they're not.
It's like the refrigerator light.
How do you know? Right. You don't know if it's on or off with the door closed. How do you know?
Right.
You don't know if it's on or off?
Is it really off?
With the door closed?
You don't know.
All right, we got to go.
We went way over time here.
This has been StarTalk Cosmic Queries.
Chuck Nice, Neil deGrasse Tyson.
You're a personal astrophysicist.
As always, I bid you keep looking at.