Daniel and Kelly’s Extraordinary Universe - What's inside a neutron star?
Episode Date: September 8, 2022Daniel and Jorge take a bite out of "nuclear pasta" and dive into the heart of these strange stars.See omnystudio.com/listener for privacy information....
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Hey, Jorge, do you have strong opinions about pasta?
I mean like, am I pro pasta or anti-pasta?
Yeah, but I want to dig a little deeper.
Like, do you have opinions about all of the varieties?
Yeah, no, I love that there are so many kinds of pasta, the more the tastier.
So then, in the opinion of an artist, what is the prettiest pasta there is?
I try not to judge pasta by its looks.
You know, that seems kind of rude.
So I just go by taste.
Well, to me, it all tastes the same.
I mean, fundamentally, it's all made of the same stuff.
Though my kids insist that some of them are tastier than others.
I think it's your kids in an entire country called Italy.
would argue the same thing.
I mean, it's all made of dough, right?
Which is in the end just made of like protons, neutrons, and electrons.
How can it taste different?
It can.
We'll probably get a lot of hate mail from Italians.
Because, you know, you're a physicist, right?
Like, each pasta has a different cross-section and a different ratio of volume to surface area, right?
Welcome to the Physics of Pasta podcasting.
That's right.
We're all Pascist.
Hi, I'm Jorge. I'm a cartoonist and the co-author of Frequently Asked Questions about the universe.
Hi, I'm Daniel. I'm a particle physicist and a professor at UC Irvine, and I seriously can't taste the difference between different kinds of pasta.
And I'm sure there are a lot of Italians right now feeling kind of sorry for you. You can't see. It's like not being able to see colors.
I mean, I don't even understand the chemistry of it, right? Once it gets.
gets into your mouth, it's just sauce and noodle. What does it matter what the shape of the noodle was
when it was on your plate? Explain it to me. What's the science of it? Are you one of those people
that just blends all their food into smoothies? You know, salmon, steak, rice, whatever. It's all
going to get digested, so it might as well blend it together. No, I'm a big fan of texture. I get that
absolutely. But, you know, in the end, the noodles, they don't taste different. They don't have different
texture when they go into your mouth. Maybe I'm overcooking them. I don't know. Yeah. I think
if you overcook them, she's getting a big, giant glob.
But, you know, it's like the ratio between the volume and the surface area, you know,
makes the sauces kind of coat the pasta a little differently, right?
It makes it taste different.
I guess so it definitely makes it look different.
And it gives my kids an excuse to refuse to eat something.
Like my son will not eat or kieta and my daughter will not eat farfalla.
And I'm like, look, it's just pasta but sauce on it.
What's the big deal?
Wow, your kids are pretty picky there.
Maybe I should just blend it into a smoothie before I serve it to them.
There you go.
You could blend it and then make your own pasta.
We do make our own pasta, actually, sometimes.
We start from scratch.
We make the dough.
We roll it out.
It's pretty fun.
Yeah.
I guess it's kind of like bread, right?
Like all breads are basically flour and water, but, you know, you can have a whole range of
different breads and they all taste different.
Oh my gosh.
Don't get into bread with me.
Breads have very different mixtures of flour and water.
You got your moist breads.
You got your drier breads.
You got breads with more fat or less fat.
It's totally different ingredients.
That's what makes different kind of breads delicious.
It's the same ingredients, isn't it?
It's different proportions.
Oh, different proportions.
You mean like different proportions of surface area and volume?
All right, good point.
But anyway, welcome to our, I guess, culinary podcast,
Daniel and Jorge Explain the Universe,
a production of iHeard Radio.
In which two total non-experts argue about pasta,
when we really should be talking about the deepest questions in the universe,
what shape do fundamental objects take?
How do they come together to make this incredible,
incredible universe with all of its amazing and different shapes. How do we get baseballs and fish
and clouds and farfalla and orequietta and spaghetti and capillini and all the incredible shapes
that we find here on our planet and the insane things going on inside our planet and inside stars
and inside neutron stars and inside black holes? We dig into all of it for you. We coat it with a
delicious sauce of explanations and banana jokes and serve it up to you. That's right. It is a big,
beautiful and delicious universe full of oodles and noodles of interesting things to learn and discover
and to figure out how it works because somehow we are able to discover how things work in this
universe using science absolutely we think that it's possible to sit here on the crust of our planet
and to just use our minds and our eyeballs to explore what's going on deep within our planet in
conditions we could never replicate in our laboratories and also what's going on inside crazy things
out there in the universe.
These are minds to try to extrapolate from the situations we can explore from the laws
we have discovered and wonder if those ideas and understandings hold up under very extreme
conditions.
Yeah, because that is one way to do science is to observe things and especially observe the crazy
and the wild and the extreme situations out there in the universe because they do teach us a lot
about what can happen in the universe, even if you don't see it in an everyday basis.
Because one of our goals in physics is not to have a special set of
rules for every situation. We don't want the physics of laundry and the physics of pasta and the
physics of air and the physics of water. Wait, that sounds like a great podcast, actually. Maybe we should
do more of those rather than amplitudeutrons. The physics of laundry? Yeah, I'll listen to that.
It might give me some pointers. You know, like what are the physics of taking out pasta stains out
of your white shirt? Wow, a crossover episode with our culinary podcast series. Yeah, well, that's
fascinating. You know, all the different applications of physics in different conditions.
are interesting how these things emerge, but physics, you know, in the end is reductionist.
We want to go down to the lowest level.
We want to understand a general theory about the universe that applies everywhere, that you
could take to your laundry or pasta or neutron star and say, I can start from these rules and I
can understand what's going on here.
And the way to test that, the way to make sure that the ideas you have are not just specific
to your pasta stains or to the experiments you do in your laboratory, but our general is to
test them under extreme conditions to say, what happens if I make this really, really, really
dense or really, really hot, or we go really, really fast. So that's why the extreme conditions
are the best places to learn where your rules break down and to get clues about how to make
new rules about the universe. Yeah, we like to look at extremes here on the podcast. And we have a whole
series of extreme things that we've looked at in the universe, like the brightest things in the
universe or the hottest things in the universe. And it usually comes out to only a couple of candidates. One of them
are neutron stars. Neutron stars are one of the most amazing laboratories for physics in the universe
because it's one of the few places where all of the forces are important. We talk a lot in this
podcast about quantum field theory and understanding three of the forces, electromagnetism, the weak
force and the strong force, but we don't have many situations where we can put those three forces
up against gravity because gravity is so weak. It's only really in the heart of black holes
that gravity dominates and takes over. But in the inside of neutron stars,
We think that gravity is just about as strong as these other forces.
So it's a great laboratory for understanding how gravity and these other forces talk to each other and play together or don't play together.
Yeah, we've talked about neutron stars before, but we've never sort of dug deeper into them to find out what it's all made out of on the inside.
So today on the program, we'll be asking the question.
What is inside a neutron star?
And what would Italians call it?
neutrinos? No, that's taken. I think I know what the answer to this question is, though, Daniel. What's inside a neutron star? Isn't it just neutrons? Done. Thanks for joining us. See you next time. I thought you were going to say, what's inside a neutron star? I mean, that's like the ingredients, right? It's like, what is pasta made out of? Pasta. Is that what you're saying? Is that what physics has come down to? Giving up? Yes, exactly. No, of course, neutrons are inside a neutron star, but what are they doing, man? What's the conditions?
How dense are they?
Do they form weird objects and shapes when they're in that crazy conditions?
Are they even really still neutrons or are they squeezed down into some other weird kind of matter?
Maybe even a quirk gluon plasma.
Wait, wait, wait.
Neutron stars might not be made out of neutrons?
I smell some misnaming here.
Exactly.
That is the question of the podcast.
Are neutron stars fundamentally misnamed?
That seems to be the mission of the entire program here.
You're just trying to undermine people's confidence in physics, man.
Or physicists.
Is there confidence in physics?
I mean, think about all the technology you're using to make this podcast and to listen to this podcast.
All of that is based on fundamental physics that we understood through basic research.
So I think on one hand, we've been doing a pretty good job of exploring the universe and learning how to manipulate it for our benefit.
On the other hand, we definitely don't understand a lot about the universe.
So there's a huge amount left to discover.
Yeah, no, physics is just a big confidence game, right?
That's right.
Keep paying us and we'll keep teaching you the secret.
of the universe, except in this confidence game, the secrets are true.
Or at least as true as you think they can be.
But I think maybe what you're saying that the question is in this episode is actually more
like what's it like inside a neutron star.
What's it like, you know, like what's going on inside a neutron star?
Yeah, exactly.
We did an episode on what's it like inside the earth where we dug into the crust
and talked about, you know, the different layers.
You could have answered that question what's inside the earth by saying earth, but that's
not that satisfactory in answer.
So yeah, we want to understand like, are there layers that?
Is it one big soup of neutrons?
You know, are there different phases of matter as you get the crazy, hot and dense?
What is going on inside a neutron star?
Can you find pasta inside?
And apparently the answer is yes.
There is pasta inside of neutron stars.
If Michael Bay could film a movie about Journey to the Center of a Neutron Star,
what would he show you on the screen?
You would have to bring in some Italian consultants because apparently the answer is pasta.
Pasta is everywhere.
It turns out to be the fundamental building block of the universe.
block of the universe. Well, as usually we were wondering how many people out there had thought about
this question, what's going on inside of a neutron star? So Daniel went out there to the wilds
of the internet to get people's opinions. And I'm eternally grateful to our volunteers who
answer these random questions and give us a sense for what people know and what they might
be curious to learn about. Thank you very much. And if you are out there listening and have
never been on the podcast, we would love to have your voice to add it to our library. So please
write to us to Questions at Danielanhorpe.com. It's free, it's easy, it's fun. So think about it for a
second. What kind of pasta would you like to see inside of a neutron star? And what do you think it's
doing? Here's what people had to say. I've heard you guys talk about this in the past. I know like
there is a crust. And then as you go down deeper towards the core, there's like, I think they
call it quantum spaghetti. And then at the very center, I've heard you guys talk about
Gluons and the neutrons are no longer associated, so it's just like this soup of quarks and gluons floating around.
Well, I would say it's pretty tight. I wouldn't want to be in there.
Actually, and neutron stars are made out of nutrients, and the core I would think is the densest part of a star.
So I would say there's a lot of nutrients, really, really packed with neutrons.
I would imagine it's hot and bright and chaotic, and if it had a high enough mass and you were actually inside it, then you might be able to find out what's in a black hole.
Oh, boy.
Very hot, very dense, very angry.
I wouldn't want to be inside of a neutron star.
A neutron star other than a black hole is the densest known object in the universe.
It is so dense, in fact, that it has high enough pressure to murder.
to push all of the electrons and the protons together to form neutrons.
Fusion is over, but it is very hot, and it is emanating very high-frequency, black-body
radiation.
And I know it must be spinning very fast due to the laws of the conservation of angular momentum.
Well, it's very compressed, extreme pressure, lots of heat, radiation, extreme electromagnetic
like fields, dizzying, spinning, and death.
I can only imagine that being inside a neutron star is like being inside of a bag of popcorn
that is being cooked in the microwave.
There's a lot of pressure, a lot of buildup.
It's hot and there's no escape.
Seems like a prison.
All right.
People aren't painting a very pleasant picture here of neutron stars.
Yeah, but they're reaching for a lot of food analogies.
You know, we got soup, we got spaghetti.
we even got popcorn.
I guess did you pull people right before lunch or something?
I think there's a deep and unexplored connection between physics and food.
You know, I think that's what we're discovering here today.
Because physicists like to eat a lot of food.
Or is that just your personal perspective, Daniel?
You know, I'm not a big eater.
I don't eat anything actually during the day.
I only eat at night.
So, you know, I can do physics all day long on an empty stomach.
But I think that people reach for these analogies because they're trying to explain something weird.
and unfamiliar in terms of something that's familiar.
And in the end, that's what physics is, right?
We explain the unknown in terms of the known.
So when you see something weird and new,
you try to say, hmm, that reminds me of.
And then you look for something familiar around you,
like whatever you're having for lunch.
Yeah.
And most people here seem to have an idea
that neutron stars are really hot and dense and compressed.
A lot of the answers were sort of people describing
a pretty intense environment inside of a neutron star.
Yes, exactly.
And that's what get physicists excited, right?
because we think it's a situation unlike any other in the universe,
one that's very hard, if not impossible, to recreate in our laboratory.
And yet there it sits out there, actually doing its thing.
And if we could know what was going on inside those neutron stars,
we would have the answers to lots of questions about crazy conditions that we're curious about,
you know, what happens when you squeeze these particles really close to each other?
Because remember that at the heart of a neutron star,
these things are dominated by the strong force,
battling it out with gravity.
And these are two forces that we do not understand very well.
Of all the fundamental forces in the universe,
we understand the weak force and electromagnetism the best.
We understand the strong force and gravity the worst.
And so to get to see them fight it out helps us understand both of them.
It's a strong mystery.
Break it down for the audience here.
What is exactly a neutron star?
So a neutron star is one of the most amazing and weird objects in the universe.
And it's also left over from one of the most dramatic kinds
of events we have in the universe, which is a supernova. So you know, you start with a normal star
which burns and they have the typical battle between pressure from gravity squeezing in and
fusion and radiation pushing out. And it burns for millions or billions of years depending on its
size. And at some point, the core of it gets so heavy because it's fused all of these lighter
elements into heavier elements, carbon, neon, oxygen, you work your way up the periodic table.
At some point, the core gets so heavy that gravity wins and the thing collapsing.
You get this shockwave that rushes in towards the heart of the star and then bounces back and comes out and you get a supernova.
And that blows out most of the stuff from the star.
You know, huge amounts of energy comes out in neutrinos and in photons and in just mass of the stuff of the star.
But it leaves behind this very, very dense core.
And so that's what the neutron star is.
It's the remnant of a supernova from a super giant star.
Yeah, that's something that I think, I know we've talked about before, but it's still pretty cool because I don't know.
think a lot of people sort of realize that a supernova, you know, we think that maybe it's like
an explosion or something reacts and explodes, but it's actually like what happens when stars and
suns collapse. It's actually like the collapse of a star and it's that collapse that kind of
causes the big explosion. Yeah, you have this supersonic shockwave traveling inwards and then
traveling outwards, right? It bounces back and explodes. And so it's a lot like, you know,
the way a fusion bomb works, or we talked about laser fusion recently on the podcast where you have
this symmetric implosion, which creates very fast runaway fusion, which then triggers an
explosion, right? And so it's really a dramatic end. It's incredible also the time scales,
because these stars burn for millions or billions of years happily in almost a steady state.
And then the end comes very quickly. You know, you think of cosmic objects having long time scales.
They should do everything slowly. But when it dies, it dies very quickly. And it leaves behind
these little remnants, these neutron stars. And they're super small.
You know, these things have a radius of like 10 to 20 kilometers.
So again, we're talking about astrophysical objects.
You used to thinking about like millions of kilometers.
These things are billions of light years away.
But we're talking about things like the size of Manhattan or Los Angeles.
And yet they're super massive.
Like they still have the mass of an entire sun, like our sun.
So these things have a mass of like one to maybe three masses of our sun compressed into a tiny little space.
Yeah, that's exactly why.
feel when I visit Manhattan, actually, super dense and compressant and hot as well. But what's
interesting, too, is that, first of all, not every star goes supernova. And not every supernova turns into
a neutron star, right? That's right. The final fate of the star is determined almost entirely by how
massive it was when it was born. If it has a mass between like 10 and 20 or 25 times the mass of
our sun, then it'll go supernova and then go neutron star. If it has more mass than that, it'll go
supernova, but it'll leave a black hole at the center instead of a neutron star. So if you have
enough mass, then you can overcome even the strength of the neutron star and collapse it even
further to a black hole. So gravity wins there if you add more mass. If you don't, if you had less
mass, like less than 10 times the mass of the sun, then you don't get a supernova and you get what's
going to happen to our sun, which is it's just going to leave behind the original core, which will be
a white dwarf. So then for a neutron star, you start with a regular star. That's about 10,
25 times the mass of our sun.
He's supernova that.
Most of it, I guess, blows out in the supernova,
but some of it, like one to three masses of our sun,
stays in the middle in this super duper dense state
that, I guess, had its origin when the star collapsed, right?
Exactly.
So you take the core of the star and you squeeze it down
to this tiny little dot, this neutron star.
So it's like a white dwarf that's been compressed by a supernova.
And it's fascinating to me because it's like the last step
before a black hole.
You know, gravity is a runaway effect.
If you only had gravity and no other forces in the universe, everything would eventually just collapse to a black hole.
There'd be nothing to stop it because gravity just pulls stuff in and it gets denser and denser and the denser it gets, the stronger it is.
And then the stronger it is, the denser it gets, et cetera, et cetera.
So the way to avoid becoming a black hole is to have something pushed back against gravity.
So a star doesn't collapse into a black hole while it's burning because a fusion provides pressure outwards.
The earth doesn't collapse into a black hole right now because all that dirt has structural integrity.
But as the mass gets stronger and stronger, you need stronger forces to resist it.
And eventually, it just gives up and becomes a black hole.
And a neutron star is like the last line of defense against gravity.
It's like the densest thing in the universe that's not a black hole.
Right.
Like if you squeeze it a little bit more, you would get a black hole.
But if you stop squeezing it or adding more mass right before it turns into a black hole, then that's what you get.
You get a neutron star.
Exactly.
And so it's this object which has enough strength to resist the incredible mass and the incredible
gravity that it does have. But if you add it a little bit more, yeah, it would collapse into a
black hole. And so it's really the perfect way to understand this balance between the strong
force and the quantum mechanics that's resisting collapse and the gravitational pressure
that's squeezing down on it. So like how many plates of pasta would you have to throw in to turn a
neutron star into a black hole? It's a great question. We don't know actually what is the maximum
mass of a neutron star. Biggest ones we've seen are like two and a half of a little.
up to maybe three times the mass of the sun.
There's some speculative observations for larger ones,
but we think it's probably impossible
to have anything much more than three times the mass of the sun.
Well, that was kind of my next question,
which is, you know, have we actually seen these things?
Or are they like sort of like black holes
that were sort of theoretical for a long time?
We have seen these things.
So they are not easy to see.
These things don't have fusion inside of them.
So they're not glowing very, very brightly.
Most neutron stars are kind of dim, right?
They just sit there and they're cooling gradually.
Though, you know, they can get bigger if something else comes by and like dumps a huge load of pasta on them.
So they're hard to see unless they're like in a binary system.
So for example, there's another star nearby and their strong gravity is affecting that star.
So if you see like a normal star and then nothing nearby it, then you can say, oh, there must be something there because of its gravity.
You can argue about whether it's a black hole or a neutron star based on its mass.
So that's one way to know that they are there.
you can also see them directly if they are pulsars.
So a neutron star is this heavy, heavy object.
It's also spinning really, really fast, right?
Because remember angular momentum is conserved.
If you take an object which was big in spinning and compress it,
it's still going to be spinning and now it's going to spin much, much faster
in order to have the same angular momentum.
So sometimes these neutron stars spin super fast and they also sometimes shoot out energy from
their poles.
And if there's a misalignment between where they're shooting energy out and the spin axis,
then this beam that they shoot out sort of sweeps across the universe.
And if it passes Earth, then we see it.
And that's what a pulsar is.
So some fraction of neutron stars we can see because they are pulsars and they're pointed
right in the exact direction where we can see them.
But most neutron stars, we cannot observe directly.
Right, because we call them stars, but they're really not sort of shining in the bright
night sky unless like you said they somehow have this bin and it's somehow shooting a beam in a
particular direction which is what pulsars are yeah you can argue about exactly what is a star
and whether these count you know there's sort of the end point of the life of a star you definitely
wouldn't call a black hole a star right even though it's also the end point of the life of a star
so these things do emit some light and so the one way to see them is if there are pulsars
another way to see them is to see x-rays from their surface so they don't glow in the visible
light, but sometimes x-rays leak out of their surface.
If there's like a crack in the surface of the neutron star or like a hot spot, it can
emit some x-rays.
And we have x-ray telescopes that are able to see those x-rays, see the photons from these
distant stars, and that can help us see that a neutron star is there.
So we think there's like a billion of these things floating out there in our galaxy, but
most of them are basically invisible to us.
Yeah, I was going to ask next, whether we have a picture.
picture of a neutron star, but actually then I realized we don't really have a picture of anything
outside of the solar system, right? Like we don't really have a full on picture of any star out there
in the universe. We just know them as pinpoints. That's interesting. I mean, we certainly have a
picture of them, right? Even a pinpoint is a picture. It's light from the star. So yeah, I guess we do
have some, you know, pictures of these stars, but not in a lot of great resolution, certainly not the
way we can look at our own sun, for example. But yeah, we don't have pictures of these neutron stars at all.
In most of the cases, all we have is like a stream of x-rays.
So like a time series where we say, oh, we saw some x-rays.
Oh, we didn't see anymore.
Now we saw some more.
Because the entire neutron star doesn't emit x-rays, just little cracks and hotspots on the surface.
And so sometimes the hotspot will be like around the back of the neutron star.
And sometimes it'll be on the front of the neutron star.
So you can learn a lot about the neutron star from these x-rays.
Yeah, and maybe it'll let you see inside of them, like regular x-rays.
And so let's get into more amazing facts about neutron stars.
and also talk about what could be going on inside of them.
But first, let's take a quick break.
December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and order, criminal justice system is back.
In season two, we're turning our focus to a threat that hides in
plain sight that's harder to predict and even harder to stop listen to the new season of law and
order criminal justice system on the iHeart radio app apple podcasts or wherever you get your podcasts
my boyfriend's professor is way too friendly and now i'm seriously suspicious oh wait a minute sam
maybe her boyfriend's just looking for extra credit well dakota it's back to school week on
the okay story time podcast so we'll find out soon this person writes my boyfriend
has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now, he's insisting we get to know each other, but I just want her gone.
Now, hold up.
Isn't that against school policy?
That sounds totally inappropriate.
Well, according to this person, this is her boyfriend's former professor, and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person to believe him because he now wants them both to meet.
So, do we find out if this person's boyfriend really cheated with his professor or not?
To hear the explosive finale, listen to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
A foot washed up a shoe with some bones in it.
They had no idea who it was.
Most everything was burned up pretty good from the fire that not a whole lot was salvageable.
These are the coldest of cold cases, but everything is about to change.
Every case that is a cold case that has DNA.
Right now in a backlog will be identified in our lifetime.
A small lab in Texas is cracking the code on DNA.
Using new scientific tools, they're finding clues in evidence so tiny you might just miss it.
He never thought he was going to get caught, and I just looked at my computer screen.
I was just like, ah, gotcha.
On America's Crime Lab, we'll learn about victims and survivors,
and you'll meet the team behind the scenes at Othrum, the Houston Lab that takes on the most hopeless cases,
to finally solve the unsolvable.
Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Hey, sis, what if I could promise you you never had to listen to a condescending finance, bro, tell you how to manage your money again.
Welcome to Brown Ambition.
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We're talking about neutron stars and what's going on inside of them.
I'm guessing it's non-neutral things if we have a whole episode about them.
Well, there's definitely a lot of neutrons inside there.
It's hard to imagine, like to really conceptualize what this stuff.
is that's inside a neutron star because you've taken normal matter and you've squeezed it down to
incredible densities. You know, this stuff, whatever it is, is 100 trillion times denser than
anything we have on Earth. You know, you think you ate a heavy lunch. That's nothing compared to like
a spoonful of neutron star. Yeah, like how much is a spoonful of a neutron star weight? Well, here on
earth, it would weigh three billion tons, right? Just one tablespoon of neutron star.
material. Of course, if you had it here on Earth, it would explode because it's under great
pressure. But, you know, just to sort of like conceptualize how dense it is when it's in its
location, it's a crazy amount of mass. It would explode in your mouth, I guess. Like a flavor
explosion. Like a flavor explosion, exactly. They should have like a summer drink called Neutron
Star, you know? Add it to our online store. I was thinking like a 7-Eleven crossover episode,
you know?
what you mean like an icy kind of like a slushy yeah neutron star slurpy you know my daughter went
in to get a slurpy recently and she came back with one and I said what flavor is it and she said
blue and I was like blue is not a flavor and she said well the guy asked me what flavor I wanted
and I said blue and this is what he gave me hmm I thought you was going to say all of him
isn't that what you're supposed to do mix it them all up I don't know then when you'll get
gray won't you nobody wants to eat a gray slushy and I think it comes out to
chocolate. Coca-Cola's chocolate color. That sounds delicious. Maybe it's like neutron star chocolate.
But anyways, back to neutron stars. I guess the question is, what would it look like if I'm
sitting in front of a neutron star? I know we want to get into it, but like if I was sitting
outside of it and like, you know, a few light year or half of a AU from a neutron star, what would
I be seen? So if you're close enough to it, you know, this thing is hot. So it's going to emit some light.
And you're also going to see hot spots from its surface. But one thing about a neutron star is
that the gravity is so strong near the neutron star,
that it distorts the space around it,
sort of the way a black hole does.
We're used to thinking about this for black holes.
You know that if you're in front of a black hole,
you're looking at the event horizon,
you're not only seeing the part of the event horizon
that's on your side of it.
You can also see around the back of the black hole,
because photons emitted near there
would be bent by the curvature of space
and come to your eyeballs.
The same thing is true around neutron stars
because they are so incredibly
dense, right? The gravitational field at the surface of a neutron star is 200 billion times stronger
than the gravitational forces on the surface of the Earth. So if you're looking at a neutron star,
you can not only see the front of it, you can also see the back of it at the same time. So if you were
on a neutron star, you would weigh 200 billion times more than you do now. Yeah, so start working out.
So I can stand up. Is that what you mean? Or so I can lose weight? So you can survive, man. That thing would
tear you two shreds. Not only is the force of gravity very, very strong, but it varies very
quickly. You know, and so you get tidal forces. The difference between the gravitational force on
your head and on your shoulders would be very strong, enough to rip your head off of your
shoulders. So I wouldn't recommend a trip to a neutron star. Would there be a spigitification
point, like in a black hole? Yeah, well before you got to the surface of the neutron star, you would
be torn apart because the tidal forces would be very, very strong. Remember, this thing only has the
mass of the sun, right?
So far away, it has the same gravitational force as the sun, but you can get much, much closer to all of that mass because it's compressed down to just like, you know, 10 or 20 kilometers, whereas our sun is huge.
So if you're on the surface of our sun, you're very far away from the gravitational center of mass.
Whereas if you're on the surface of the neutron star, you're only 10 kilometers from an entire star's worth of mass.
That's why the gravitational forces are so much stronger for the same amount of mass because you can get closer to it.
So you and the spaghetti you had for lunch would turn into spaghetti.
Exactly.
You would be postified.
Right.
Well, I guess the big, good question now is why is it even called a neutron star?
Like, is it full of neutrons, basically?
And how did a regular sun, which is what it was before, it's supernova and collapsed into a neutron star,
it was made out of all kinds of stuff, right?
Like iron and all kinds of complex elements and electrons and protons and protons.
But now it seems to have collapsed into something that you now call a neutron star.
So is that everything just turned into neutrons or what?
Yeah, everything.
turns into neutrons. You have your atom, which has neutrons, protons, and electrons in it, right?
Well, what happens if you squeeze that down really, really far? If you really push a bunch of that
stuff together. Well, if you get the electron and the proton close enough to each other,
well, you know, they have opposite charges. And so they actually kind of like to hang out together.
So if you squeeze them down enough, the proton captures the electron. The electron gets like eaten
by the proton, and that converts it into a neutron.
It's exactly the opposite process of neutron decay that we talked about recently on the podcast,
where a neutron turns into a proton and electron.
This is the reverse process.
So you put enough energy into it.
You can reverse basically anything that happens in the universe.
And so this is what happens if you squeeze down matter.
All the protons and electrons merge and become neutrons.
So usually electrons and protons are attracted to each other, but they don't get together and merge.
right? What's keeping them apart? Well, what's keeping them apart usually is that the electron is in a
stable state just the way, for example, the earth is in a stable state around the sun. The earth
and the sun attract each other. There's gravity there, right? Why doesn't the earth collapse into the
sun? Because it has enough energy to resist that, right? It can stay in a stable orbit. And so you
shouldn't be thinking about electrons as orbiting protons, but they have enough energy. They have a
minimum energy in their stable solution to avoid collapsing into the proton. And so here you're
overcoming that, right? You are like squeezing the electron down. You're applying external
pressure. And so that's why an electron doesn't collapse into the proton because it has enough
energy to avoid it. But that's if it's by itself. If you squeeze on, if you push on it from
the outside, if you confine it to a location, the size of the proton, then it gets captured by
the proton. And then what happens? The proton eats the electron, right? Because a proton is made
out of three quarks and a neutron is made out of three quarks. So then does the electron just sort of like
flip one of the quarks or something?
Yeah, that's exactly what happens.
Remember, a proton is two upcorks and a down.
And a neutron is two down corks and an up.
So what happens when an electron is captured is that you're converting one of those
upcorks into a down quark.
And so that converts the proton into a neutron.
There's also one more step because you can't just delete electrons from the universe.
So you also need to create an electron neutrino.
Interesting.
So it's like the proton eats.
the electrons, and then they become neutral.
And then what happens to all of these neutrinos?
They just get spit out into space?
Yeah, they get spit out into space
because neutrinos mostly see stuff in the universe
as transparent, right?
They hardly interact with anything.
They can go through a light year of lead
without interacting.
And so mostly they just get shot out
while it's collapsing.
Remember, supernova is the process
that produces these neutron stars
emit most of their energy via neutrinos,
something like 99% of the energy
of a supernova is not emitted visually, not in the optical, not via photons at all, but via neutrinos.
And so this is part of the process that creates all of those neutrinos when the supernova happens.
Yeah, supernovas are known to be silent but deadly, silent and invisible.
Supernovas are incredible because you can see them with a naked eye, right?
That's how bright they are.
All of a sudden, a star becomes as bright as the entire galaxy.
And that's just the visible light we're talking about.
It turns out there's a hundred times more energy in the neutrality.
We had a whole fun podcast episode about how supernovas can be seen first in neutrinos with our neutrino telescopes.
And so this is part of the process.
Creating those neutron stars means making neutrons, which also requires you to make the neutrinos because you've got to balance the books of particle
physics in the end.
Right.
So they're called neutron stars, but actually not all of it inside our neutrons.
And so maybe can maybe step us through a little bit like as the supernova is collapsing and as things are getting
squeezed together, like what's happening to all those atoms of the bigger elements? They're just
getting broken up and squeezed together or they just explode? What's going on? So some of them get
broken up and it depends on where they end up. So we'll learn about it as we step through the layers
of the neutron star. But near the outside of the neutron star, for example, the atoms don't get
broken up. You get atomic nuclei still, for example. So the outer crust of a neutron star is atomic
nuclei. You can have helium there. You can have carbon. You can have oxygen, this kind of stuff. It's only as you
get deeper in that these nuclei get squished together so far that the separation between the nuclei
break down. And then you just get like a sea of neutrons or maybe a sea of corks or maybe even
weirder stuff. And so you can't really think about it as like lead or iron or carbon anymore because
it's gotten broken up into its constituent bits. That's at the very center. But you're saying that
At the crust of a neutron star, you could get, you just have regular stuff then.
Yeah, at the crust, you just have regular stuff.
Like, you might be able to, like, stand on it, maybe.
Or is it all sort of, like, in a liquid or gas form?
So there is an atmosphere of a neutron star, actually.
There is, like, a gaseous atmosphere, but it's micrometers thick, like micrometers.
So this thing is like 10 kilometers or 15 kilometers wide and it has an atmosphere that's like
micrometers of gas just above the surface.
And then the surface itself is hard.
it's like brittle. It's like a crunchy, right? And it's made of atomic nuclei. So these are things that
used to be part of the star, carbon, oxygen, nitrogen, whatever. And now it's crystallized into this
like lattice on the outside of the star, which is very, very smooth because the gravity is so strong
that you basically can't form any hills. So they think that like the maximum elevation on the
surface of a neutron star might be like one millimeter or gravity like pulls it back down.
So if you're standing next to a neutron star, what you would see is basically a big shiny smooth ball, right?
Made out of some of these heavier elements.
Almost perfectly shiny smooth ball.
It's really incredible how spherical this thing will be.
But there'll be some exceptions because the crust is brittle.
The crust can crack.
It's under incredible pressure.
Gravity is squeezing it down.
And sometimes you get like a little bit of a weakness.
And so you can get like a star quake because you get a crack in this crust.
and things like adjust a little bit.
And that's when, for example, x-rays can leak out.
So the reason you get x-rays is from these hot spots,
which can cause these little neutron star quakes on the surface.
Well, what if it's spinning?
Wouldn't it also kind of give it a weird shape?
Right, it is spinning.
And so that changes it from a spherical a little bit, right?
But it's also very, very compact gravitationally.
How far something goes from spherical is a balance between how fast it's spinning
and also how strong the gravity is.
So we've never seen one of these things, but you're right,
It wouldn't be perfectly spherical, though it still would be very, very smooth.
All right.
So I'm standing on top of a neutron star.
I weigh 200 billion times more than I normally do.
And so I take a pickaxe and I crack the surface.
What do I see inside?
So you've got to dig a little bit width.
So inside the neutron star is a little bit more crust.
You've got to dig a little bit into it before you get to sort of like the next layer.
And we're not sure, of course, about any of this.
A lot of this is speculation.
These are models that we've developed based on our calculations from our understanding
of the strong force and gravity, et cetera.
But we think that this outer crust is like 300 to 500 meters thick.
Once you penetrate through the crust, then these elements are no longer able to hold
onto themselves, right?
They're squeezed together by pressure.
And so you get this like soup of neutrons that we think are just sort of like floating
around there, where the atoms themselves are getting broken up.
So they're no longer really like have their identity as an element.
I see.
So in the shell, you still had the heavier elements like lead and car.
But then now they're being squeezed together so much, they, what, they like, they just break
apart the nuclei or they merge together?
They do both.
It sort of varies as you go in near the outer layers of this part.
They first merge together because they're getting squeezed together.
And so you have weird fusion happening.
You have like weird heavy elements that couldn't exist in other situations, you know,
that wouldn't be stable out there on their own in the universe.
But under this crazy pressure, we think you can form like ridiculously heavy elements, you know,
things with huge numbers of neutrons on them. As you go further and further in, things become
more and more neutrony, right? It's not pure neutrons. You still have some protons and some
electrons. Not every single proton and electron has been converted into a neutron. But as you go
inwards, you have like a higher and higher fraction of neutrons. Because I guess as you squeeze
this stuff together, that's what it all ends up as, right? Just plain neutrons, because all of the
electrons and the protons on the protons eat each other. Exactly. And we think that overall, there's
going to be a charge balance. So there is a proton for every electron. And so you squeeze it hard
enough and they'll find each other eventually. So as you go deeper and deeper in, you get like a higher
and higher fraction of neutrons. And then what happens as you go in deeper? As we go in deeper is
where the real mystery is. Right. And so you have this inner core where we don't really know what's
going on. Like we think maybe there's some super fluid neutron matter there. Like we think that maybe
under these conditions, the neutrons just like slide around past each other.
have all this weird chemistry. This is a lot of where the question marks are. You might wonder like,
well, why is it a question mark? Can't we just take the laws of physics that we have, gravity and the
strong force, and do the calculations and say, what does it predict? It's not always so easy, right,
to say, I know what the laws are, what's going to happen? We can't even do that for lots of situations.
You know, if you just gave me quantum mechanics and a baseball and said, here's 10 to the 29 particles,
what do they do next? It would be very, very hard for me to come up with.
like parabolic motion. It's not easy always to go from the underlying laws to predicting what's
going to happen on the macroscopic scale. And especially when things are very, very strong,
when the forces are very powerful. Here you have gravity, which is unusually powerful because
it's so dense. And you have the strong force doing its thing. With very short distances,
these things are exchanging incredible numbers of gluons. So we just don't know how to do that
calculation. Even if the laws that we have, the ideas that we have about what's fundamentally
guiding it are true, we don't know how to take those and predict in great detail what's going on
inside. It just gets too crazy. It just gets too crazy. It's too many things to keep track of. So we've
tried and we have a few ideas. People make approximations this way or approximations that way.
They say maybe it's like this or maybe this equation will work. But everybody's reaching past the
edge of what they really know. So there's a bunch of speculative ideas. And
And they're all really different.
They're all totally different from each other.
And so we'd love to see it.
We'd love to understand what's going on there because it would tell us, oh, this idea is correct.
Or actually, none of your ideas are correct.
And something totally weird and unexpected happens.
So that's what we're trying to do.
Unfortunately, of course, we can't see the inside of the neutron star.
We have to just try to guess what's going on based on what we can see from the outside.
All right.
Well, let's get to the core of this mystery and think about what exciting and maybe delicious things could be inside at the core of
neutron stars. But first, let's take
another quick break.
December 29th,
1975,
LaGuardia Airport.
The holiday rush. Parents
hauling luggage, kids gripping
their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing
at the TWA train.
Apparently, the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and order, criminal justice system is back.
In season two, we're turning our focus to a threat that hides in plain sight.
That's harder to predict and even harder to stop.
even harder to stop.
Listen to the new season of Law and Order Criminal Justice System on the IHeart
Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Oh, wait a minute, Sam.
Maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now, he's insisting we get to know each other, but I just want her gone.
Now, hold up.
Isn't that against school policy?
That sounds totally inappropriate.
Well, according to this person, this is her boyfriend's former professor, and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person to believe him because he now wants them both to meet.
So, do we find out if this person's boyfriend really cheated with his professor or not?
To hear the explosive finale, listen to the O.K.
Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
Hola, it's Honey German, and my podcast, Grasias Come Again, is back.
This season, we're going even deeper into the world of music and entertainment with
raw and honest conversations with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't audition in, like, over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We've got some of the biggest actors, musicians, content creators, and culture shifters,
sharing their real stories of failure and success.
I feel like this is my destiny.
You were destined to be a start.
We talk all about what's viral and trending
with a little bit of chisement, a lot of laughs,
and those amazing vivas you've come to expect.
And of course, we'll explore deeper topics
dealing with identity, struggles,
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You feel like you get a little whitewash
because you have to do the code switching?
I won't say whitewash because at the end of the day, you know what I'm me?
Yeah.
But the whole,
pretending and cold, you know, it takes a toll on.
Listen to the new season of Grasas Has Come Again as part of My Cultura Podcast Network
on the IHart Radio app, Apple Podcasts, or wherever you get your podcast.
A foot washed up a shoe with some bones in it.
They had no idea who it was.
Most everything was burned up pretty good from the fire that not a whole lot was salvageable.
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Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever you get your
podcasts.
All right, we're talking about neutron stars and what is inside of him.
And I'm sort of getting the picture, Daniel, that inside of a neutron star are not necessarily
neutrons.
There seem to be a lot of other stuff.
This should be called mostly neutron stars.
Neutron-ish star, yeah.
Or neutrino stars.
Well, all the neutrinos have left the building, right?
They took their little weak forces and they ran away.
I see.
There are no Italians in the room anymore.
You're free to make whatever pasta you want.
That's right.
All the rules are out the window.
How Aldente is the inside of a neutron star?
So we cracked the heart surface of a neutron star.
We dug in a little bit.
And you get the soup of electrons and neutrons,
maybe like super duper heavy atoms.
But eventually those break down as you go deeper and deeper into the neutron star until you get basically just neutrons, right?
Like a sea of neutrons.
But then what happens as you go even further in?
So we don't know what those neutrons do.
And that's fundamentally the question.
Like if you have a bunch of neutrons and you squeeze them into these incredibly dense situations, what do they do?
Do they form a super fluid or do they do something else, something weird?
But you're still calling them neutrons because like inside of a neutrons are three.
quarks. But so you're saying at this point like each triplet of quarks is still held together
they're just interacting with other triplets of neutrons or have the corks sort of even broken out
of that. That's one of the options, right? Do the neutrons stay together and form weird shapes,
weird emergent structures or do they break down and really we should be talking about quark matter
and cork gluon plasas? That's one of the options that's on the table. But to me it's a great
example of some of the deepest mysteries at the heart of our understanding of the universe,
you know, like what emerges. You can take the basic rules of physics and incredible structures
emerge, you know, atoms and ice cream and galaxies, all of these things sort of emerge from
the underlying complexity. And it's exciting to see a situation where we just don't know what
will emerge. You put the neutrons in this situation. Maybe they'll just be a crazy chaotic
soup, but maybe new structures will form. Right. And so people have exciting.
ideas for what kind of weird structures might form from neutrons in these configurations.
Right. Because as you said, I think at this point, it's so crazy and so dense, there's only
two forces involved, the gravity that's keeping them all in and keeping them attracted to each
other and also the strong force, which is what, bringing in the quarks together, holding the quarks
together? Or what does the strong force do? Does the strong force repel also? Here it just attracts, right?
The strong force is really, really weird and has a very strange behavior with distance. But
under short distances and will attract quarks and gluons to each other.
And we think of protons and neutrons as sort of like balanced in the strong force,
that all the quarks are bound together into this state that has overall no strong charge,
no color.
But that's not really true if you get close up enough to a proton.
If you get close up enough to a proton,
then you'll be like closer to part of it than to the backside of it.
And so you'll still feel a little bit of that effective color.
And so if you get close up enough,
to a proton with your corks, then your quarks will start talking to the quarks inside that proton.
And that's, for example, why a nucleus holds together.
Remember, a nucleus is filled with protons and neutrons.
There's only positive electric charges there.
Why doesn't it blow apart?
Because the quarks inside the protons and neutrons are talking to each other.
They're making it sticky.
And so inside a neutron star, the strong force is pulling these things together.
Same way gravity is, right?
So you have all these neutrons, then these triplets of quarks held together by gravity.
And you're saying that they can sort of form matter, like they can, you know, arrange themselves in special, maybe delicious ways?
Yeah, well, we don't know for sure, but we have done supercomputer studies where we simulate these things.
We put in the laws of nature and we just see sort of what happens.
And interesting stuff does seem to emerge.
After like 250 computer years of calculations, they see these weird blobs form.
And so as things get denser, they form these sort of semi-spherical blobs of matter.
where things sort of like clumped together into these huge blobs of neutrons with a few protons
mixed in. And so they called these things noki, like the Italian, you know, potato blobs
that people enjoy eating for lunch. I guess it's sort of like if you take a whole bunch of carbon
and atoms, loose atoms, and you squeeze them together enough at some point they'll sort of
form into a diamond or some sort of shape, right? That's kind of what's happening here is that you're
taking these neutrons and you're squeezing them so much, they kind of lock into these shapes.
Yeah. And so instead of having like a complete ocean where everything is just mixed together, they form a blobs of a certain size, right? They like distinguish themselves. Say, oh, we'd like to have this many neutrons into a blob with a few protons mixed in and would have the same thing over there. So instead of being like totally indeterminate, they seem to want to form these structures, right? And if you squeeze even further, then these blobs form these long rod. They like come together to make these long rods, which looks sort of like spaghetti. Well, I mean, they could look like,
a lot of things, breadsticks,
you know,
steel bars,
but you're staying with the pasta analogy.
They sort of look like spaghetti.
I didn't name any of these things.
I'm just enjoying saying them.
But yeah,
they could have called them,
you know,
Twizzlers or breadsticks or whatever,
but they look sort of like spaghetti
and they form these long rods.
They're parallel, right?
Don't think of spaghetti like a big mess on your plate.
Think of spaghetti sort of the way it comes
in the package from the store.
There are all these rods in parallel with each other.
So they call this nuclear pasta.
Right, right.
And so they kept going and all the other shapes that neutrons can form have sort of a pasta analogy, right?
Yeah, you keep going.
You keep squeezing this stuff down and they think or they predict from these calculations
that the spaghetti will merge together to form sheets.
So then you have nuclear lasagna, these like layers of this weird kind of matter that's mostly
neutrons with a few protons in it and it's very, very strong stuff.
In their calculations, this stuff has incredible strength.
like very hard to break it apart. It might be some of the strongest stuff in the universe.
You mean these lasagna sheets of neutrons? These lasagna sheets of neutrons. They're not just like
forming and then breaking up and then reforming. It's not like a crazy gas or a plasma, right? These
things are like very, very strong sheets of a weird kind of matter. It's not like a solid or a
liquid or exactly like a crystal made out of almost all neutrons, right? It's not like a regular
lattice of atoms, like the way we think of like a piece of steel.
Right. And you're saying it's some of the strongest stuff in the universe because it's basically
surviving these intense and crazy pressures inside of the neutron star. But I guess if you took it
out of the neutron star, it would just blow up. Yeah, it would probably blow up. We don't know,
right? Maybe it's strong enough. It'll hold itself together, right? Because, for example,
diamonds are formed under very crazy conditions, but then they're stable. So you pull them out
from the heart of the earth where they were made. They don't explode. So maybe nuclear pasta
doesn't explode. We just don't know. But if you keep squeezing this stuff together, you squeeze the
lasagna sheets together, it forms this thing called anti-spaghetti, which is like a blob of matter
with holes in it, like long, thin spaghetti holes sort of like drilled through it.
Wait, what? Kind of like peni pasta? Like Swiss cheese? More like Swiss cheese, yeah, than
Pente pasta, right? More like Parmesan. Maybe we should say Parmesan or what's an Italian cheese with
holes in it. But those holes are bubbles, right? Here we're talking about holes that are like long tubes.
So it's like wormholes through a block of Parmesan.
It's more like a clump of Bucatini then.
Yeah, perhaps.
Yeah, like a clump of Bucatini.
Anyway, they called it anti-spaghetti because it's like,
take the spaghetti state and flip it so that everything that was matter is now a whole
and everything that was a whole is now matter.
So if you add spaghetti and anti-saghetti together, you get like a complete block of matter.
You get antipastop.
You annihilate your stomach.
And that's not even like the core of the neutron star.
Like if you go further in, then things start to, even the dispostic.
can't survive. Yeah, so they think that this pasta is maybe like a layer that's like a hundred
meters thick. And as you go even deeper, you know, we're in huge question mark territory,
but some people speculate that you might get a cork gluon plasma or something else that
stuff called cork matter. Or as you suggested earlier, you no longer really can think about this
stuff in terms of neutrons and protons anymore because everything's just interacting with
everything else. If there's a high enough energy, if the high enough temperature, it doesn't really
matter that you used to call these three quarks a neutron and those three quarks of proton,
now they're all talking to each other. So it's just like a big sea of quarks and gluons.
I thought at the center you would find Daniel going, oh, this pasta tastes the same.
That's all the same stuff. I bet a bite of nuclear lasagna and nuclear anti-spaghetti taste just
about the same. Depends on how the, I guess, quart gluon sauce coats the shapes.
But I think what you're saying is that you get to a point where it doesn't make sense to
call things a neutron because like the separation between a triple of quarks and a triple
of corks here is sort of gone.
Like you basically crack open those neutrons and it's just the soup of the what's inside.
Yeah.
And that's the possibility, right?
It might be that the conditions are intense enough to create that.
But we're not sure, right?
It might be that instead other things happen.
So there are other possibilities on the list.
Some people think you might form weird, strange kinds of matter inside, things like Hyperon
matter or K.
Aeon matter. These are other versions of nucleons, but instead of having just up quarks and down quarks,
now you have strange quarks as well.
Interesting.
And then I guess you can't break things down further because quarks are fundamental particles in the universe, right?
Or could you maybe squeeze them down to like just pure energy?
Well, we don't know the corks are fundamental, right?
They are as fundamental as we have discovered.
We don't know that there's anything inside a quark, but we have lots of hints that suggest that they shouldn't be fundamental.
There are all these unexplained patterns among the corks.
The kind of patterns you see when they're made out of something smaller, something more fundamental.
Like we saw patterns in the periodic table.
Those were clues that atoms were actually made of smaller building blocks you could arrange in lots of different ways.
We see similar patterns in the corks that suggest that they should probably be made of something smaller, but we've never seen it.
So it's possible that at the heart of neutron stars, you go beyond cork gluon plasma, and you can even go inside the corks.
and maybe the things inside quarks break open and talk to each other.
We just don't know.
All right.
So then I guess what's inside of a neutron star, the answer is we're not quite sure.
I mean, definitely you had neutrons there, but maybe at the core you get to something that is not even neutrons or maybe even quarks is what you're saying.
Yeah, we just don't know.
It's a big question mark.
And lots of different calculations lead to different predictions, which is confusing and also exciting because it means that we can learn something about the universe.
Unfortunately, we can't see the inside of neutron stars directly, right?
Even if you were near a neutron star, how would you see what's going on inside it?
We have the same question with our own star.
We don't really understand all the plasma currents inside the sun and why it creates this magnetic field,
which flips every 11 years because we can't go inside it.
We can only look at it from the outside.
Well, these are even dimmer objects much further away, so they're even harder to study.
But, you know, we can use our X-ray telescopes to look for these photons.
from these cracks on the surface of the neutron star,
and those can give us a lot of clues.
They tell us something about the mass and the radius of the neutron star,
and we think that knowing the mass and radius of the neutron star
will help us try to figure out what's going on at the core of it
because you're building this neutron star out of different kinds of stuff.
So one idea for what's at the heart of a neutron star
will give you different predictions for the masses and radia you see than another idea.
I guess the problem is like in our sun, the one we have here,
we can sort of look in using our equations because things aren't that extreme yet.
Like the regular loss of physics still work. But, you know, with a neutron star, you're sort of
getting up to that point where things start to get a little crazy, right? Like you're sort of
starting to get into black hole territory where you don't even know if your loss of physics
are the same. Yeah, we don't know if these hold. And, you know, one of the guiding equations
of these things is called the Tolman-Alpenheimer Volkov equation, which is a thing that
constrains the structure of a spirically symmetric object. That's homogenous. It's all one kind of
material, which is in gravitational equilibrium. So that's like the simplest model we have for a neutron star.
And it makes all sorts of predictions. And some of those predictions are, for example, that there's
a connection between the mass and the radius of a neutron star. That if you fix the mass of it,
that also determines the radius. But when we look out into the universe, those neutron stars
don't seem to be following that rule. Like we see some neutron stars that are 25 kilometers wide
that have the mass of 1.4 times the mass of the sun. And other ones that have the mass of 2.1 times the
mass of the sun at the same radius. So they break these rules, which, as you say,
suggests that these rules aren't complete, right? That's something about what's going on
inside the neutron star is different from what we imagine, from what our rules can currently
predict, which might mean that it's like a new complex way that these rules interact and new
structures emerge or it might mean that there is some new physics, something else going on,
a new force, something inside quarks, something weird we haven't even imagined.
But I guess unlike a black hole, like it is maybe possible for us to one day get to a
neutron star and maybe actually sort of like touch it and maybe even send probes into it you think it certainly
is possible right we can't even land probes on the surface of venus right now that last more than like
90 seconds without getting crushed and venus is like you know a day on the beach compared to the
surface of a neutron star but yeah you know if you have a lot of faith in our engineers in our pasta
engineers maybe they can imagine a way to drill into a neutron star and see it yeah it's not technically
forbidden. It's just very, very difficult. Yeah, and they are out there in neutron stars just like
black holes and they have lots of interesting secrets inside of them, right? They do. If we could
know today what's going on inside a neutron star, it would tell us so much about gravity and the
strong force and also just like what our universe can do. Remember that the part of the universe we
experience this liquid, the solid, the gases is just a tiny, tiny slice of what the universe is
capable of. We don't really observe most of what the universe can do. So I would love to let the
universe show its colors, you know, like go crazy in the kitchen universe, make us some weird pasta.
I want to see what you can cook up. Yeah, it's almost like they're kind of little lab experiments,
right? Or like they're like little labs. Like you want to know what happens when you crush two
quarks together. You know, that's what's happening inside of a neutron stars. If you want to know what
happens, go observe neutron stars. Yeah. Go observe neutron stars. Exactly. I wish we could. But it's
wonderful that these experiments are happening, right? Like, we can't create these things
ourselves, but it's fantastic that the universe has arranged for them to happen so that we can
study them. Unfortunately, they're very difficult to approach and very, very far away. So there are
some stumbling blocks there, but maybe one day we'll be able to visit them or we'll just get more
clever about observing them from the outside and using that information to infer what's going on
inside. Maybe it'll be the Italians to do it, since they're the experts. That's right. Maybe they'd be so
offended by these models of anti-spaghetti that they'll be motivated to figure this out.
Yeah, and then your kids will be like, nah, I don't like that kind of pasta.
Not for me, thanks.
I want blue pasta.
I want all the pastas, squish together.
Next, you're going to tell me that different colors of pasta change the flavor.
Well, it depends how they get their color, but they do change the flavor.
Daniel, do you really want to spend another hour talking about this?
Have you never had squitting pasta or vegetable pasta?
All right.
That's a topic for our spin-up.
Pasta Podcast. Daniel and Jorge argue about food. Daniel and Jorge eat the universe. Well,
I hope you enjoyed that discussion and it certainly made me a little bit hungry. I need to go have
lunch now. But thanks for joining us. See you next time. Thanks for listening and remember that
Daniel and Jorge Explain the Universe is a production of IHeart Radio. For more podcasts from IHeart Radio,
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