Daniel and Kelly’s Extraordinary Universe - Is the whole Universe spinning?
Episode Date: May 24, 2022Daniel and Jorge talk about whether the whole Universe can spin, and whether it is.See omnystudio.com/listener for privacy information....
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Hey, Daniel, do you ever get frustrated by, you know, asking the biggest questions in the universe all the time?
Never. I live for it. I mean, what could be more fun?
How about finding the answers sometimes?
Oh, there are always answers out there waiting for us to discover them, you know?
Oh, really?
You think all the big questions in the universe have answers to them?
What if they don't?
I think that even the deepest, hardest, craziest questions in the universe have answers and one day some human will know them.
Hopefully that human is you?
Or one of our listeners?
What if the big questions don't have answers?
You mean like, is white chocolate really chocolate?
Or can you just say, I don't know?
That's what I tell my kids all the time.
That's an answer, right?
How about ask your mother?
Is that an answer to the question?
Who ate all the chocolate?
That one is also Ask Your Mother.
Hi, I'm Jorge, I'm a cartoonist and the creator of PhD Comics.
Hi, I'm Daniel.
I'm a particle physicist and a professor at UC Irvine,
and I will continue to eat chocolate until all the questions are answered.
I thought you were going to say that you ate all the chocolate, but I guess you still have answers to find.
That's right. As long as they keep making chocolate, I'll keep asking questions and looking for answers.
I'm not sure where there's correlation between answers and chocolate came from, Daniel.
Are you sure you're not just making that up?
I'm not making that up. You know that there's a tight correlation between the amount of chocolate consumed per capita
and the number of Nobel Prizes won per capita for countries.
Switzerland is like knocking it out of the park.
Isn't that weird, though? Isn't the Nobel Prize?
based out of Switzerland? No, it's Sweden, man. Oh, Sweden. Wrong S-W country. We're clearly
Sweden just needs to eat more chocolate. Clearly, everybody needs to eat more chocolate. I mean,
it's good for everything. It's good for your mind. It's good for your soul. I'm not sure it's good
for your waistline. Or your heart. A little bit. That's a true correlation, right? Like,
if you make a plot of the countries that have Nobel Prizes and the amount of chocolate they eat
per capita supposedly, I mean, I haven't looked into the data, but I suppose that there's a
correlation, right? Yeah, I think we have a plot of that in the opening of one of our books. So the data is there. The correlation is true. The causality, I'm not exactly sure. It doesn't mean that you should force feed chocolate to your school children in order to get Nobel prizes in 20 years.
You mean like the causality could be the other way around. Like winning a lot of Nobel prizes could cause you to eat a lot of chocolate.
Yeah, maybe they're just celebrating their Nobel prizes by eating chocolate, right? Or maybe there's a chemical in chocolate. It could be big chocolate, you know, just be a big conspiracy.
Oh, a conspiracy between big chocolate and big Nobel.
Yeah, big science and big chocolate.
They're all just trying to make us all bigger, I guess.
That's right, exactly.
We're asking bigger questions by making our scientists even bigger.
Especially around the waistline.
I occupy a larger and larger fraction of the universe every year.
That's right.
If you occupy a larger fraction of the universe, there's less of the universe to explore, technically speaking.
Yeah, well, that must be what dark matter is after all.
It's just overweight physicists, I guess.
Eating dark chocolate because white chocolate, not chocolate.
I mean, that's what happened out in space.
Like all these aliens that are more advanced, you know,
sort of reach the chocolate singularity and just faced out of the electromagnetic spectrum.
See how much progress we've made already?
I don't think anybody ever said the phrase chocolate singularity before.
So that's progress right there.
Chocolate fueled progress.
Yeah, just talking about chocolate makes you win a Nobel Prize.
Boom.
But anyways, welcome to our podcast.
Daniel and Horhe explained the universe,
a production of iHeard Radio.
In which we eat our way towards answers
to some of the biggest, tastiest,
most delicious questions humans have ever asked.
Questions about the size of the universe,
the shape of the universe,
the motion of the universe,
the fundamental nature of the reality
we find ourselves in
as curious, conscious beings,
trying desperately to understand
what's going on and where is my next piece of chocolate coming from.
That's right,
because the universe is full of amazing and incredible things like delicious snacks and dark matter
and sometimes dark delicious snacks at all at the same time.
And we're all just wondering what's going on, what's out there, and how does it work?
And some of us get to do that for a living.
I mean, ask questions, not eat chocolate.
Nobody pays me to do that yet.
But it does fuel my curiosity about the fundamental nature of what things are like out there.
Yeah, I guess you're a professional question asker, Daniel?
Would you say that's that you can describe a researcher?
Yeah, everybody who has decided to spend their life doing science
is done so because there's a question that drives them.
Of course, I'm curious about lots of questions in science
that I don't personally work on.
But everybody who's a scientist has their own personal questions
that drive them to spend their life asking it.
You know, maybe it's about how birds communicate
and choose partners.
Maybe it's about how the earth was formed.
Maybe it's about the fundamental nature of space and time.
I mean, it's this personal curiosity that drives science forward.
Yeah, and you forgot the very important question.
How do you make chocolate fat-free?
That would also move science forward a lot, apparently.
You mean, how do you make chocolate-free?
How do you make chocolate still delicious, but a little healthier maybe?
Yeah, the answer to that one is you can't.
The unhealthiness is part of why it's so delicious.
Oh, I see.
It's the guilty pleasure of it that you like.
Oh, my goodness.
This just got a little extra dark.
But I guess, yeah, you're a professional question asker, which means you're also sort of a professional head spinner, right?
Because, I mean, your job is not just to answer questions, but your job is to find answers to crazy questions and find crazy answers, right, that leave people's head spinning.
That's right. Sometimes when you ponder these deep questions about the universe, you wonder, like, how can we even get started?
How do we take that first step towards that future where some human knows the answer to those questions as like an actual fact?
sometimes it can be inconceivable to probe such big questions and know like how to get started.
Yeah, and hopefully it's a future where not just one human knows the answer.
Hopefully that person gets to tell other humans.
Yes, but there's always a first human, right?
That's the joy of discovery to be the first person to know something about the universe that nobody else knows.
Just like there was a first person to taste every kind of fruit on earth or first person to see every single mountain or to walk along a beach.
there's always a first, and that's the joy of discovery.
You want to be the one who figures it out,
not reading about it in the science times of the newspaper.
Right, right?
Although the way science works, you're never quite the first human, right?
Because you always need things to be peer reviewed, right?
Like, somebody needs to check your answer.
You can't just, like, come up with an idea
and have absolute certainty that it's true, can you?
You can't ever be 100% certain,
but there are moments when you do an experiment
and the results are just very conclusive.
These moments of discovery,
where you've designed your experiment in a way to, like,
corner the universe to revealing some truth to you.
We did a podcast about Pulsar discovery last year
in which we played audio of the astronomers
watching the data come in in real time
and having that moment of discovery.
They almost shouted Eureka live on the tape.
So sometimes there really are those moments
when you know something about the universe.
Yeah, I guess then you want to be the first human to be
like 95% sure.
You know something.
But it does leave your head spinning,
this search for truth in the cosmos
and searching for the idea of how things work
and the explanation for why things are the way they are,
including some very interesting questions
about whether or not things are even spinning in the first place.
That's right, because we see lots of things spinning in the universe.
We know the earth is spinning and the earth is spinning around the sun,
which is spinning around the center of the galaxy,
which is itself spinning, which is moving around the center of the galaxy cluster.
And so naturally, as a curious human being,
you wonder, how far does that spinning go?
Yeah, so to the end of the program,
we'll be asking the question.
Is the whole universe spinning?
So, Daniel, how are we spinning this question?
Is the question itself spinning?
Is that what you're saying?
This question definitely makes my head spin.
And it's been one that's been debated
sort of on the boundary of physics and philosophy
for a few hundred years.
You know, not just the question of,
is our universe spinning, but could it be spinning?
What does it mean for the whole universe to spin?
Spinning relative to what?
You know, could you even tell if the whole universe was spinning?
It's a really fascinating question that tells us a lot about the nature of space itself
and what is absolute and what is relative.
Right, because I guess you can, you know, ask if space itself is spinning, right?
Because, you know, we know sort of space is kind of a thing that can bend and twist and ripple.
what if the space itself is turning around.
Well, you just blew my mind, man.
Did I make your head spin?
Did it make you want to eat more chocolate?
That's always the case.
That's a pretty low standard.
But yeah, you can ask questions like,
is the stuff in space spinning?
Is space itself spinning?
What would space itself be spinning relative to?
All sorts of really fun, big, mind-blowing head-spinning questions are involved.
Well, I guess the question we're asking today is,
is the universe spinning.
So really, we're asking about the whole shebang, like everything, right?
Mm-hmm. Yeah.
Now, here's another one, Daniel, is the multiverse spinning.
It's definitely spinning money for the Marvel universe.
The Marvel universe is spinning out cash.
Yeah.
They're shooting out of Spider-Man's spinning web shooters.
If the universe is spinning and that spin is random,
then you can imagine there might be a whole set of universes,
which each have their own different random spin.
And then if we measured our universe to have a particular spin,
we could ask like, well, why this spin, not some other spin?
You can add the multiverse to basically any question.
But then the multiverse would be infinite
and it would average out to nothing or not.
I think this conversation is spinning out of control then.
I think so.
Let's get it back on track here.
Yeah, so as usual, we were wondering
how many people out there had thought about this spinning question,
whether or not the whole universe is spinning or not.
And so Daniel went out there into the wilds of the internet to ask people the question.
Is the whole universe spinning?
And thanks again to our cadre of volunteers who participate in these difficult to answer questions without any chance to do any Googling.
If that sounds fun to you and you'd like to hear your voice on the podcast, we would love to hear from you.
So please don't be shy.
It's free.
It's easy.
It's fun.
Write to us to questions at danielandhorpe.com.
Think about it for a second.
do you feel or think that the universe around you is spinning?
Here's what people had to say.
It wouldn't surprise me if the whole universe is spinning
because so many things are spinning.
You know, we're on a spinning earth that in turn is revolving around the sun,
which in turn is revolving around the galaxy,
and the galaxy itself is spinning.
And then our galaxy is probably spinning around other galaxies
in the local group,
which then itself probably is spinning within the bigger group.
Well, I feel like we know it's expanding,
but I have no idea if I've heard that it's spinning or not.
Everything else in the universe is spinning,
so why wouldn't the universe spin?
Yes, without question, the universe is definitely spinning.
There's a center of gravity,
but I don't think that there is a center of gravity
across the entire universe.
I think there are local galactic clusters that rotate.
But yeah, because they share a center of gravity.
I don't think that there's a center of gravity across the universe.
So I'm going to say, no, it's not.
Spin is all relative, right?
So in order for it to be spinning,
it would need to be spinning relative to something outside the universe.
So that's really a question.
Is there anything outside the universe for which the universe could be spinning relative to?
When I think about the universe, I think of everything, like, it's just a word that is sort of all-encompassing.
And I don't know if we were, if the universe is all-encompassing, what would it be spinning relative to?
Is it that like space itself is spinning, which doesn't make a lot of intuitive sense to me?
I mean, you could probably figure out if it was spinning using, I don't know, like the Michelson-Morley experiment with like the ether or whatever.
You could like test for that kind of a thing, I guess.
If the whole universe was spinning, then everything would be moving at the same time.
So I don't know how we'd be able to tell.
But maybe it is.
All right, a wide range of answers.
Some people said, yes.
No hesitation there.
Yes, it's spinning.
We got the whole range of answers here.
we got from yes, it's spinning, to what does that even mean, to how could you even tell?
It really pretty much represents the entire spectrum of possible answers.
Right.
Even a little bit of a maybe there.
Maybe it's spinning.
So it's a fascinating question.
Is the whole universe spinning?
And so let's get into the particulars of that question.
I have questions about it.
Daniel, could the university spinning?
It's a really interesting question just to ask like, what does that mean, first of all, right?
Like, could the universe be spinning?
Spinning relative to what?
We've talked on this podcast for a while about relativity.
You know, we talked to Carlo Rovelli, for example, about relative motion.
He made the really interesting point that we've talked about a few times that if you, for example, lived in a universe all by yourself, there was nothing else in the universe, then velocity would have no meaning because velocity is purely a relative quantity.
You can only be moving relative to other stuff.
And so in an empty universe, velocity has no meaning.
Wait, what if the universe has a like an extent, you know what I mean?
Like a border or an edge, then you could be moving relative to that, even if you were
alone in the universe.
In our understanding of relativity, space is isotropic and homogenous, meaning there are no
special locations in space.
The kind of cosmology you're talking about, what there are special locations in space
would break a lot of the rules that we think we understand, you know, like conservation of momentum.
And so for now, let's operate in a universe that's essentially either infinite in extent
or where every location in space is the same.
So you can't be moving just relative to space.
You have to be moving relative to other stuff in space.
So from that point of view, you can't ask questions like,
is the whole universe moving, right?
Now imagine a universe filled with stars and galaxies just like ours.
It doesn't make sense to ask, is all of that stuff moving?
Because it would have nothing to move relative to if you're talking about the whole universe.
So from that point of view, things like, you know,
velocity are purely relative.
And the question then is like, is the same thing true for spin?
If you were alone in a universe all by yourself, an empty space, could you tell if you were spinning?
Right, because velocity, like you're saying, is relative, but acceleration is not relative, right?
Like, you could also ask the question, is the universe accelerating?
And that one would have meaning, right?
Because moving could also apply to acceleration.
Yes, velocity is purely relative, but acceleration is absolute.
Some, you can measure the acceleration of an object.
If you were alone in the universe, you could build a little device that would tell you whether or not you were accelerating.
And it's not a complicated device.
You could just like have a ball in a box and hold it steady.
And if the ball moves towards one side, it means you are accelerating in the other direction.
That's just how an accelerometer works.
Or if you're inside a box, you can tell whether you're accelerating because you would feel an effective gravity against one side of the box, right?
You can build an accelerometer.
You don't have to be accelerating relative to any other thing.
You can be accelerating relative to absolute space time.
It's interesting the history of how we came to these realizations.
The first person to think about this question, whether spin is absolute or relative, you know,
can you be spinning relative to space or do you have to spin relative to other stuff was actually
Isaac Newton?
Right.
Yeah.
Because I guess the question is whether or not we're spinning or not.
And that one can be relative, right?
Or not relative.
So that was a question.
And if you're spinning, what are you spinning relative to?
Are you spinning relative to space or are you only spinning relative to other stuff
out there in the universe?
Right.
So is spin sort of like acceleration or is it more like velocity?
And at the time, of course, of Newton, Newton thought that velocity was absolute, that you
were moving relative to space itself.
But he proposed a really fun thought experiment as a way to sort of like measure whether
or not you're spinning.
And basically like, you know, a spinometer in the same way you can build an accelerometer
to see if you're accelerating he thought let's build an experiment that measures whether or not
you're spinning and it's pretty simple you take a bucket of water and you know the surface of the water
is flat and then you start spinning the bucket you spin it sort of along its axis you could like
twist a rope on the handle or something like that now what happens of course is that the bucket starts
spinning and then eventually the water gets dragged along by the buckets and now the water is also
spinning and what happens is that the water gets pushed up against the sides of the bucket so the
surface of the water is no longer flat, it's now concave.
And so this, he says, is a way to measure whether or not you're spinning.
Because even if you're like on the bucket, if you're like an ant on the bucket,
you can still tell that it's concave, right?
Everybody will agree that the surface of the water is now concave.
So it's like a way to measure the fact that you are spinning.
Right.
It's sort of like it's trying to measure whether or not there are centripetal acceleration or forces on you
because, like, if you're spinning, something must be causing you to spin.
to change directions all the time. And that's what the centripetal acceleration is pulling you
towards the center. It's changing your velocity vector. So you're moving in a circle, for example.
Centrifugal acceleration is the fictional force that you feel because you're in a non-inertial
reference frame so that the ant, for example, or the water feels that force pushing them
outwards. You know, the same way, for example, if you were on a spaceship out in deep space
and it was spinning, you would feel an effective gravity. You would be able to walk along the inside
of that spinning can as if there was gravity. This is one plan for having effective gravity
in deep spaces, make your spaceship spin. And so Newton thought, well, obviously, then spin is
absolute, right? That you're spinning relative to space because you can build this thing that
measures it. And even if you were in the frame of the bucket, if you were spinning with the
bucket, you could still tell that the bucket was spinning. So now imagine that bucket in deep and
empty space. You should be able to tell whether you're spinning or not based on whether the
water is concave or whether it's flat. So Newton was like, I'm very sure that spin is absolute.
Meaning that you could tell maybe if the universe, the whole universe was spinning, right? Like if
we were just sitting here and we felt this interpidal acceleration, even though nothing seemed to be
moving, then maybe you can tell that everything was spinning. Exactly. And if spin is absolute,
then you could measure the spin of the universe, right? Because the whole universe could be
spinning in space. And if that was happening, according to Newton,
you could measure it.
But not everybody agreed with Newton.
There was a guy named Ernst Mock who came along and said,
no, no, no, that's not true at all.
Spin is purely relative.
Motion is relative after all, right?
Like if you're moving through space, that's purely relative.
So Mock said maybe everything is relative.
Maybe all motion in the universe, acceleration and velocity.
And this is before relativity, right, before Einstein.
Mock said, maybe everything is relative.
And then people said, well, what about the bucket, right?
The bucket can tell if you're rotating.
And Mock said, well, the bucket is rotating relative to the stars out there.
That's why the surface of the bucket get concave because it's rotating not relative to space,
but to the stars out there in the universe.
That doesn't make a lot of sense.
It doesn't make a lot of sense to me either.
But remember, at the time, people didn't really understand the notion of space and time and relativity.
And these questions were sort of up in the air.
You know, people wanted to know, for example, if velocity is relative, as we all accept,
then why isn't acceleration relative?
Like you said it earlier, that velocity is relative, but acceleration is not.
But why not?
And at the time, people didn't understand.
And so this was sort of a beautiful idea to say, well, maybe everything is actually relative.
And the reason that the surface of the bucket gets concave is somehow because of the distant stars.
And on the other side, people said, well, that's ridiculous.
Like, are you saying that if you spun a bucket in empty space, that it would stay flat, right?
He said, absolutely, if you spin your bucket and then you start removing the stars out there in the universe,
that the surface of the bucket would go from concave to flat,
that somehow those distant, distant stars are telling the bucket surface what to do.
I feel like Mach should have stuck to like sound research.
Maybe not try to do astronomy here.
But I guess you're saying that's kind of the thinking at the time.
Like maybe if you sort of like removed a reference frame
and maybe that's kind of what he was getting at,
it's like if you remove the reference frame of the stars,
then somehow maybe you lose all relativity.
Yeah, Mach said that's been.
If you're not spinning relative to something else, then you're not spinning.
That spinning in an empty universe has no meaning, that you could never tell.
You know, that if you were in an empty universe and I started to spin you, you wouldn't feel your arms get pushed out towards the side.
If you built a spaceship and spun it in an empty universe, you wouldn't feel effective gravity.
That comes somehow from the distant stars that are defining a reference frame.
And this was a beautiful idea, and even Einstein liked it.
Einstein thought, ooh, this sounds really nice.
and he tried really hard to work it into his theory of relativity.
Because Einstein's idea was that motion is relative, right?
Like everything is relative.
So Einstein basically came up later and said,
actually turns out Newton is wrong and also mock is wrong.
They're both wrong in slightly different ways.
All right, well, let's get into how Einstein proved them wrong
and whether or not the whole universe is spinning.
Because my head is spinning a little bit right now,
and I kind of need a little break.
So we'll be right back.
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And they're saying like, okay, pull this, until this.
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It's just, I can do it my eyes close.
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All right. All right. We're asking the question. Is the whole universe spinning? I am getting a little dizzy just thinking about and talking about this question. And where we left off was that Einstein looked at Newton and then he looked at another researcher back in the day and he said, you're both wrong. Actually, maybe spinning is also relative.
So Einstein said definitely Newton is wrong because Newton said that all motion is absolute,
that space is like its own absolute frame and velocity is absolute, that in an empty universe,
an object moving in his train line, you could somehow measure its velocity relative to absolute space.
So Einstein said, no, that's ridiculous.
There is no preferred location in space.
There is no preferred velocity in space.
That doesn't make any sense.
And he built that into his theory of relativity.
But he also said that mock was wrong because mock wasn't.
wanted to go even further and say, well, even acceleration is relative.
And Einstein liked that idea, but he found that it didn't actually work.
And so what Einstein says is that space is relative.
And we've talked up on the podcast a few times about how time is relative.
Also, different observers in the universe feel time differently.
But when you put the two together, space time, you actually do get something absolute.
Einstein didn't actually like calling his theory relativity theory because he thought it
oversold the relativity aspect of it.
He wanted to call it invariance theory.
But anyway, what he found was that space is relative and time is relative,
but that space time together had some absolutes in it
that lets you measure whether something is accelerating.
And spinning counts as accelerating.
So acceleration and spin are absolute, but velocity is relative.
I guess it sort of maybe depends on your definition, right?
Like is spinning motion also motion?
or is spinning motion like something that's not motion?
Do you know what I mean?
Like maybe you're saying, you know, spinning involves acceleration
and therefore it's not sort of the same as moving with a constant velocity.
Exactly.
Spinning is definitely a kind of acceleration.
So then the question really is, is acceleration absolute?
If acceleration is absolute,
you could measure acceleration out in deep space,
that means that spinning is absolute.
That you could also measure spin in deep space.
And so Einstein's theory,
of relativity shows us that velocity is relative, but that acceleration is absolute, that you can
tell if an object is accelerating. Which also means you can tell if it's spinning, right? Which
means that if you, even if you were alone in the universe, you can still get dizzy. You can get dizzy
in an empty universe. And we've seen this other times when we talked about Einstein's theory of
relativity and spin. Because Einstein's theory, for example, predicts a difference between the gravity
of an object that's spinning, a gravity of an object that's not spinning. A spinning object has this
weird effect frame dragging where like drags space along behind it a little bit and newton doesn't
predict that because Newton says there's no difference between the gravity of a spinning object and a
non-spinning object and that wouldn't make any sense if spinning was purely relative right so spinning
objects have a different gravitational effect and therefore you must be able to tell the difference
between spinning and non-spinning objects right but I wonder if that is that something I guess
that's just kind of built into the laws of the universe that we that we can tell like why does
the universe draw the line between velocity and acceleration? Because, you know, mathematically it's
just like one derivative over. It is just one derivative over, yeah. Like it could have been
acceleration is also invariant, but then the derivative of acceleration, the next one over, is not
relative. It does seem sort of arbitrary to like draw the line at the first derivative and not
the second derivative. And there are a lot of really deep ideas here. One of them has to do
with symmetry and conservation laws. We'll talk about that in an episode coming up soon on Nuther's
theorem. I think the best way to think about it is to think about what is invariant, what is
preserved in the universe. The reason, for example, that you can tell that something is accelerating
versus something is not is because of their path through space time. This has to do with things
like free fall. If you are just moving through space without accelerating, you don't feel any
forces. What you're effectively doing is making a straight line through space time. Like your path
through space time is just a straight line. If you're accelerating, you're like burn your rocket
or if you're being pushed by something,
then you make a curve in space time.
So the reason that you can tell
whether something is accelerating or not
is because everybody agrees,
all observers agree,
whether or not you're making a straight line in space time
or a curve in space time.
That's what it means to say
that space time itself is absolute,
that the universe can tell the difference
between straight paths in space time
and curved paths in space time.
Well, I guess that's kind of what I mean.
Like, you know, you said it's all sort of depends
or it's all because of some symmetry in the universe,
but then, like, what if the universe didn't have those symmetries?
Or what if we lived in another universe without those symmetries,
would those rules be different?
Or is that invariant about velocity and acceleration
kind of baked into math itself?
It's not baked into math.
You could construct cosmologies where things were different.
This is the universe that we find ourselves in.
These are the rules that we discover.
It's sort of like asking the question,
why is momentum conserved?
And the answer is space is the same everywhere?
All right.
Well, why is this?
space the same everywhere. It's not required by mathematics. You could have a universe where the
rules of physics vary from place to place. We just don't seem to have that universe. So this is sort of
like a discovery of ours. The universe seems to obey this principle and these are the consequences
of that principle. Why does it obey this principle? We don't know, but we've discovered it. It's
sort of like saying, okay, the speed of light is invariant for everybody. Everybody measures
a speed of light to be the same. Why? We don't know, but here are the consequences of it. This is the
invariance that Einstein discovered, that space is not invariant, but space time is.
Another way to think about these paths is to think about like, you know, imagine how you get from
your house to your work. Somebody could draw like a set of axes X, Y, Z and say, oh, Jorge gets
from his house to his work, from this coordinate to that coordinate. But somebody else could come
along and say, well, I have a totally different set of coordinates for Jorge's path from home to
work. And those are totally different coordinates, but it doesn't matter. And it doesn't matter
because the path itself is the same.
The two observers would look at the path and say,
oh, it's a straight line or no, it's a wiggle
because he stops at the fridge on the way from his bed
to his cartooning studio, right?
So people agree about the shape of the path,
even if they don't agree about the actual coordinates.
That's what it means that space time,
your path through space time is absolute,
even if your coordinates are arbitrary.
Well, sometimes I work from bed all day.
Even everyone would agree that it's a short commute.
Yeah, exactly. If your path is a point, then everybody would agree.
Yeah, that's the whole point of being a cartoonist, is to live in a point.
But I think what you're saying is that, you know, it's sort of baked into the loss of at least this universe that we live in, that you can tell if something is spinning.
Like, it's not something that you can hide or it's not something that you can, like, maybe never tell.
But the question we're asking today is whether the whole universe is spinning, which kind of makes me wonder.
Like, I feel like now it could go either way because, yes, you can tell if something is spinning.
in the universe, but what if the universe itself is spinning, could you tell?
Here, I think we have to be careful about what we mean by the universe.
And I'm talking now about the matter in the universe, like take all the stuff, the galaxies,
the dust, the gas, the dark matter, is all of that stuff spinning?
And here it's spinning relative to space time.
Space time itself can that spin?
Like, well, what would that be spinning relative to?
There's no external metric for space time itself to spin.
So we're talking about like, you know, the Earth is spinning.
Is it possible that everything else is also spinning in that same way that the Earth is spinning?
Oh, I see.
You've been spinning this question the whole time, Daniel.
You're really asking, is the whole stuff in the universe spinning?
You're not asking if the universe is spinning.
Well, it depends on whether you're including space time in that spin.
And I would say it doesn't make sense for space time itself to spin, but stuff in space time can spin relative to space time.
Well, I guess maybe let's explore that a little bit.
Like we've talked about space being a thing.
How do you know it's not spinning?
It could be spinning even if it's not relative to anything, right?
In the same way that we talk about expansion of space time,
we don't say that space time is expanding into something else.
We only have intrinsic measurements.
We are in space time.
There's nothing outside of space time to measure.
So we can only measure internally, right?
So we say space is expanding.
People ask, what is it expanding into?
Well, it's not expanding into anything.
It's just increasing the relative.
distances between stuff in space.
So in the same way, you can't really ask what is space time rotating in?
It's not in anything.
It just sort of is.
And so there's no sense in which space time could spin.
But I thought you were going the other way because, you know, you can say that space is expanding,
but it's not expanding relative to anything.
Couldn't I just say space time is spinning, but it's just not spinning relative to anything.
Then what does that mean for it to be spinning?
What does it mean for it to expand into nothingness?
It means that the distances between stuff are getting larger, right?
But what does it mean for space time itself as a whole to spin?
You can tell whether something is spinning relative to space time.
Same way you can tell whether distances are growing.
But you can't tell whether space time itself is spinning.
You could, baby.
Like maybe if I was alone in the universe and I got dizzy.
You know what I mean?
I guess what I'm wondering is could there be like an inherent centripetal acceleration to the universe?
I think it's possible mathematically.
there is always an ambiguity there, even in the case of expansion, because general relativity
has this weird difficulty by talking about the velocities of things that are very far away.
You can always define either relative velocities or velocities relative to space.
And so probably there's a way you could construct a universe that had a rotating space time
that had an inherent and built in centrifugal acceleration.
You know, for example, a curvature of space would give you that effect.
if space was curved in such a way that you effectively felt a negative gravity.
And there are some folks out there that argue that dark energy may partially be due to some
inherent centrifugal force due to the rotation of space time itself rather than some
like expansion of space.
Whoa.
Wait.
So like the space time could be spinning and it might be the answer to dark energy.
That's one thing people were probing.
We'll talk about how people use type 1A supernova to try to answer that question.
in a little bit when we talk about how to measure
whether space is spinning.
All right, well, leave that for another episode.
But I guess in this episode, we are now
shifting the question to is everything in the universe
in space time itself spinning?
Because, you know, it could be spinning, right?
Like you said earlier, the Earth is spinning
and we're spinning around the sun
and the sun is spinning around the galaxy
and the galaxy, it's probably spinning around
some larger cluster of galaxies.
And that could also be spinning relative to other clusters.
you know, is everything may be spinning.
It's a really fun question.
And what we expect, what physics predicts,
is sort of counterintuitive.
Because on one hand, we see that everything is spinning,
as you say, the Earth is spinning, the galaxy is spinning.
But we don't actually expect on very, very large scales
for all the stuff in the universe to be spinning.
That if you add it up all the stuff in the universe,
we actually predict that it should have zero spin.
Right, because it seems kind of implausible almost
that everything would not be spinning.
that it would be sort of standing still.
It doesn't.
It's actually a very specific prediction of inflation.
Remember, inflation is this prediction that the universe started out much, much, much
more compact, and then spread out and expanded and blew out.
And that all the structure we see in the universe comes from like the little quantum fluctuations
and density from the early universe.
And it's that expansion itself that we think would have killed effectively any rotation.
Remember what happens when you're spinning, if you're like on ice and you're a figure
skater. If you pull your arms towards yourself, then you start to spin faster. And that's why,
for example, the earth is spinning because it started out from a cloud of stuff that was very
gently spinning and then collapsed and is now spinning faster. But expansion has the opposite effect.
So as the universe expands, we expect it to spin less and less. And because inflation expanded the
universe by like 10 to the 30, than any tiny random rotation of that initial blob of stuff,
we would expect that to be effectively zeroed out by inflation. Right. I guess. I
I guess maybe I'm getting a little confused here because of what we're actually asking.
Like, I guess are we asking whether all the stuff in the universe has a zero or non-zero average spin?
Do you know what I mean?
Like, for sure, I can spin in my chair here and the Earth is for sure spinning and the sun is definitely spinning and the galaxy and the galaxy clusters are definitely moving relative to other things.
I guess is the question like if you average out everything, all the stuff in the universe, does it have a spin to it?
or does it all cancel out to exactly zero?
Is that kind of what we're really asking here?
Yeah, draw a line through space
and measure the spin relative to that line
and then ask, is that overall spin?
All the stuff in the universe,
is that zero or not?
Right.
Sort of like if you have a snow globe,
maybe I'm thinking, you know,
you can have all the snowflakes inside
moving and twirling and looking chaotic,
but overall you can sort of tell
whether or not this stuff in it is spinning relative to the globe.
What you're saying is that it
maybe has to do with the beginning of the uterus.
Like if the stuff at the beginning of the universe had a little bit of a spin,
that's the only way it could still have spin today.
Yeah, because angular momentum is conserved, right?
If you are spinning, you will always be spinning.
There's no way to stop something from spinning unless you're coming in from the outside
with some other spin to cancel it out.
If you're talking about the whole universe, then there is nothing outside.
And so if the whole universe somehow started out spinning, it should still be spinning today.
although that spin would get dampened out
and go to very, very small values
because of the expansion of the universe
like a figure skater
shooting her arms out
for like millions and millions of miles.
Her spin would then go to effectively zero.
So that's what we're talking about
is is there spin to this stuff in the universe
and it should persist if it's there.
Right, because I think what you're saying
is that if the universe had no spin
at the Big Bang when it was super, super tiny, small and dense,
if it had no spin,
there's no way for it to gain spin
since then. Like it can't like push off against anything, right? To get spin. There's no way to spin
the entire universe. There's nothing to like push against. Right. If you're talking about the whole
universe, there's nothing that you can push against because that would mean something outside the
universe and the universe is everything. Right. Unless maybe like space time itself has a like a lean
to it right or something, you know, like it has a preference for matter and not antimatter.
It has a preference for certain things, you know, forwards in time and not backwards in time.
Could it also have like a little bit of a spin preference?
Yeah, we usually ask this question under the assumption that space time is homogenous,
meaning it's the same everywhere and in every direction.
But it's certainly possible if we discovered an overall spin to the universe to wonder where that comes from.
And, you know, could it be generated by like some features in space time that aren't the same everywhere?
I see.
But your basic answer is that the stuff in the universe has any spin now.
It must be due to any kind of spin it has at the beginning of the universe.
but even if it had a little bit of a rotation at the beginning of the universe,
that would have all sort of gone to almost zero by now.
Yes, so we would be very surprised if we look out into the universe,
measure its overall spin, and find it to be spinning at any significant rate.
That would be a big shock.
It would make all your head spin, for sure,
relative to all the chocolate you're eating.
It would be a fantastic and delicious discovery
because it would be a clue that something we think is true is not,
that there's something else going on,
that we don't understand, and like the biggest, most delicious scales.
All right, well, let's get into how we could tell if the universe, or at least the stuff
in the universe, is spinning at any significant rate because I think Daniel is hungry.
So let's get that answer ASAP.
But first, let's take another quick break.
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All right, we're talking about whether or not all the stuff in the universe is spinning.
Dana, you said it's unlikely for it to have any kind of spin
because expanding the universe would have killed any sort of momentum.
But what if I'm thinking, what if the universe was spinning a lot at the beginning?
Couldn't it also have some sort of remnant spin to it at this point?
Yeah, it would.
And we might be able to measure that if we devise tests that are very, very sensitive.
And so you're right that the current theories of physics
suggest that spin is dampened by expansion,
but we don't have an idea for why the universe would or would not be spinning originally.
So if the universe was somehow born spinning super duper fast,
we could still measure that today.
And that would be interesting because our cosmology allows for the universe to spin.
It's possible for the whole universe to have been born spinning.
Or to have been a spinning baby.
Shut out of the universe womb.
and doing a triple lutz.
And remember, we don't really know much about that birth.
We talked about possible theories of like inflaton fields decaying into normal matter.
Those are really just placeholders for like where to have future ideas, the shape of those
ideas.
But we definitely don't have ideas firm enough to where we can say like the universe should
not have been born with any spin for sure.
There's a huge opening there for ways the universe could have been born and allowing for
it to spin.
And definitely Einstein's theory of relativity says it is.
possible it's meaningful for the stuff in the universe to be spinning right so i guess that means that if
you do discover that all the stuff in the universe is spinning right now it maybe shouldn't be that
surprising you'll just tell you if it was spinning at the beginning or not it would tell you that it was
spinning a lot at the beginning and then you'd have to go into your theories and say like well how do i
make that happen you know is it a multiverse where the spin is somehow random and we just got a big
serving of it is it necessary because of some property of the universe beforehand the universe is
inherently always spinning, it'd be a lot of really fun questions. Yeah, or maybe the universe
mom just ate a lot of chocolate before the baby universe was born and made the baby universe
spin out of control. All right. So then what are some of the ways that we could maybe test
today, like where we are now in this spinning or not spinning universe, whether or not things are
spinning, whether or not everything is spinning? So people have been thinking about this for decades.
And remember, Einstein's theory of relativity is only about 100 years old.
So this concept that the universe can spin absolutely relative to space time.
He's only about 100 years old.
And it took a while for people to understand what it means.
You know, Einstein actually believed Mock for decades until later in his life when he was like,
no, it's beautiful, but I think he's wrong.
And so it's really only like 50 or so years that people have been thinking about this in a way that they could test it.
And one of the simplest ideas is just like, well, let's just look and see if the universe
appears to be spinning relative to some fixed point.
You mean looking at all the stuff in the universe, not the universe itself?
Yeah, all the stuff in the universe.
And so, for example, are the galaxies, the distant galaxies, are they spinning relative to the Milky Way
or relative to the solar system?
And the cool thing is that you can treat the solar system because it itself is spinning
as a sort of gyroscope.
The solar system is spinning and it's going to continue to spin.
And because of conservation of angular momentum, it has to keep spinning in basically the same
direction. So it defines an axis. And then you can ask, well, is the rest of the universe sort of
spinning around us relative to the Milky Way? What do you mean? How would that tell you if the
universe was spinning? I mean, the stuff in the universe was spinning. Well, it would tell you
whether the universe was spinning relative to the Milky Way at least. We can measure the Milky Way
spin, right? We can tell whether an individual object is spinning. And so that gives us like a reference
point. And then we can ask whether the rest of the universe is spinning relative to us. So we can measure
our spin relative to space time, and then we can measure the rest of the universe to spin
relative to the Milky Way, just by looking at the galaxies and saying, like, are they moving
relative to us? Oh, I see. But isn't that sort of a given? Like, don't we expect the Milky Way
to be, you know, spinning in some weird direction relative to everything else, all the stuff
in the universe? We can measure the Milky Way spin relative to space time because it's absolute.
And then we can measure the motion of the distance galaxies relative to the Milky Way. And if that's
exactly the opposite, then that suggests that the whole rest of the universe is essentially not
spinning. Oh, I see, because you're saying that you can measure the spinning of stuff relative
to space time. There is sort of like a reference frame in the universe, and that's called
space time. And you're saying, because the Milky Way is close to us, we can measure that
pretty accurately. So it gives us sort of a compass of how we're spinning relative to space time. And
then you're saying, let's look at everything else and see if it's rotating relative to that.
Exactly. So say you're spinning around inside of a room. You have a way to measure your own spin. You have like a gyroscope that tells you your own spin. And you can also measure your spin relative to the walls. Those two numbers agree that tells you, oh, well, I guess the walls are also spinning. So that's what we can do. We can measure our spin of the Milky Way. And then we can measure the spin of the Milky Way relative to the distant galaxies. And then we can ask, are the distant galaxies spinning in absolute sense?
Oh, but I guess my question is, why do you even need to go that far?
Like, couldn't I just use a gyroscope here on Earth
and then measure the galaxies relative to my little gyroscope?
Yeah, but the Milky Way is a better gyroscope than your little gyroscope.
The Milky Way and the solar system provide pretty nice gyroscopes
because it's a huge amount of mass and a very long lever arm.
And so they're very precise.
But there are lots of ways you can construct this experiment.
The real limitation, though, is that it's very hard to observe the motion of those distant galaxies
because they're really, really far away.
And so they hardly move at all.
And we've only been looking at them for like 100 years.
It's only Hubble 100 years ago
to even discover that there were other galaxies out there.
So if they are moving,
they're moving very, very slow,
not in a way that we can tell.
Relative to space time, right?
They're moving super slow.
They're moving.
They're expanding, right?
They're moving away from us.
But now we're talking about not radial motion
away from us,
but rotational motion, right?
perpendicular to the line between us and them.
And we haven't seen that kind of rotation.
Like, I think you're saying, like, if you correct for the motion of the earth
and correct for the motion of the earth around the solar system and the Milky Way and all
that, it'd be hard to tell because they're so far away.
Like, for us to see them spinning around and around the cosmos,
it would have to be moving, like, ridiculously fast.
Right.
And because we can measure their velocity in a radial direction pretty well because of Doppler
effect.
measuring their velocity in the other direction, you know, requires seeing a change in their angle
relative to the Milky Way, which requires like, you know, seeing them actually move.
And that's really hard to do for stars and even harder to do for galaxies.
They need to be either moving really, really fast or you have to observe for like a billion years.
And we're only 100 years in.
Yeah, that's the real limitation.
Like, it's possible.
You just need a lot of time.
Or they need to be moving really, really fast in an obvious way that we can see it.
And that's not happening.
Can you just ask him, call him?
All right. So that one has its limitations. You're not going to get a noble prize anytime soon with that method. What are some other ways we can measure?
Other things we can do is to look at the expansion of the universe. So we know that things that are far away from us are moving away from us. And we know that that expansion is accelerating. So this is the discovery of dark energy that something is stretching out the universe. Seems to be creating new space between points all of the time. And the interesting thing is that cosmologists say that if,
the whole universe was rotating, if everything was spinning, then that would look a little different.
That expansion would look different than it would if the universe was not spinning.
And so the way that we measure that the universe is expanding is a couple of ways.
One is that we look at type 1A supernova, these standard candles that we know exactly how bright
they should be.
And so when we see one, we can tell how far away it is because of how bright we see it.
We have these like tracer points in the universe where we can see their expansion over time.
I mean, we could see the history of the expansion of the universe.
And if there was a swirl in that expansion, if the universe was rotating at the same time as expanding,
then that would look a little different than if it was just expanding in a purely radial way.
What do you mean?
Because that would mess with, I guess, the basic motion of things, right?
Because it suddenly has an extra component of velocity and it's feeling an extra component of acceleration.
Yeah.
Imagine you're like on a merry-go-round and you and a bunch of friends and you all throw ping pong balls out.
If you're spinning or if you're not spinning, then those ping pong balls have a different path, right?
They would curve if you're spinning.
That's one way to measure your rotation.
And so we try to measure the rotation of all the stuff in the universe by looking at the path of these tracers, these type 1A supernova to see, is it consistent with just flying straight out or is it consistent with curving?
We can't observe them for very long, but we have these momentary tracers.
And you can do some sort of like back calculation to say, like, are they consistent with rotation or are they consistent with?
pure expansion. Oh, I see. I think what you're saying is like if everything in a new north was
in a merry-go-round, we would see the stars, the supernova, or at least the stuff around like the
equator, that stuff would be maybe expanding faster, maybe, or moving differently than the stuff
like above and below us on the merry-go-round. Yeah, if there's an overall rotation, that implies
that there's a rotation in some plane, right, some axis around which you are rotating. And that
essentially defines a north and a south. Just the same way like the Earth's rotation,
defines a north pole and a south pole and the solar system has a north and a south defined by
its rotation so that would create different directions in the sky where things look different basically
a huge antisotropy we actually talked about on the podcast once about this axis of evil this idea
that maybe things in the universe do look a little bit different north to south if depending on how you
define it so that's exactly the kind of thing you would expect to see if the universe was rotating
you'd expect to see some difference in one half of the sky versus the other half of the sky right you would
expect it to be a little wider in the middle around the waistline.
The universe is either rotating or been eating too much chocolate.
One of those two.
There's only two possibilities.
You can do similar tests with another very sensitive probe of the universe's expansion.
That's the cosmic microwave background radiation.
That's this light from the very, very early universe.
And we were talking about how if this rotation exists, it should have existed a long time ago.
It's actually much more powerful to see it earlier on before the universe expanded so much
because the rotation would be more dramatic.
And so in the same way that if the universe is rotating,
it would affect the way things are expanding.
It would also affect that plasma that generated that C&B light.
The plasma is very sensitive to like how much dark matter there is
and how it's moving and how the normal matter is sloshing around
into and out of those dark matter gravitational wells.
And if there was an overall spin,
it would affect those patterns in very subtle ways.
And people have studied those and not seen any evidence
for universal rotation.
It's kind of like you, we talked about before how the cosmic microwave background is like a picture of the baby universe, like an early picture of the universe.
And so you don't see any, basically what you're saying is you don't see any spin in that picture, nor do you see it being like the baby's not extra wide around the middle.
Yeah, and it's a little subtle because it's not like you're looking at the actual universe and seeing its spin.
You're looking at like the patterns that spin would cause in the clumpiness of.
the universe. It would make very distinctive patterns. This is actually the most sensitive test we
have for the universe's rotation is this cosmic microwave background light. In the early 80s, people
saw some weird stuff in the sky from radio signals that led them to believe maybe the universe
was rotating. There was a paper in 1982 I read from a guy in Manchester named Birch who claimed
to be measuring the rotation of the universe, a 10 to the minus 13 radiance per year. But this measurement
in the CMB is more powerful and is not consistent with any rotation.
So people think purchase measurement was probably wrong.
Well, I'm getting this sort of the picture that if you're asking the question,
is this stuff in the universe spinning?
If it was spinning, then you would see some sort of, like you said,
an isotropy, meaning like the universe would look differently,
whether you're looking at the spinning direction
or whether you're looking at its waistline or the equator
of the spinning stuff in the universe.
And it seems like for all accounts, looking at galaxies and looking at the baby picture of the universe, there is no different or like preferred direction that you can see.
As far as we can tell, there's a study we talked about on the Axis of Evil episode where people looked at the spin of galaxies and they found that galaxies in one direction of the sky tend to be spinning left more than in the other direction of the sky.
And they claim this is maybe evidence for the universe to be rotating.
But a lot of people criticize that paper and think that it probably underestimates systematic effects that could cause.
that, you know, local gravitational effects
or other uncertainties that they didn't
take into account. So overall, there's
no evidence for universal rotation.
Although our cosmology allows
it, right? It is possible for our universe
to rotate. It just doesn't seem to be
doing that. Right. Or at least
not to 10 to the negative 9
radiance per year, which
sounds like a small number. It's like 0.000,000,
9, and then a 1.
But like you said before, like, you know,
the universe expanded 10 to the, what, like
30, 602 times since the Big Bang.
And so it could just be that these instruments, this way of knowing is not accurate enough yet.
Like there could be a little bit of spin down there still underneath what we can measure.
Yeah, we'll never have infinite precision.
And so either the universe is not spinning or it's spinning very, very gently.
Yeah, it's a kitty merry go around, you know.
Nobody wants us to throw up all that chocolate.
Yeah.
Nobody wants the six flags.
Crazy rollercoaster erosion of the universe.
So I guess the answer is, is the stuff in the universe spinning?
Not that we can tell, but it could still be spinning a little bit.
We just don't know for sure yet.
And fascinatingly, we could tell if the stuff in the universe was spinning.
Spin itself is absolute.
And that tells you something really deep about the nature of space and time and motion.
That velocity is relative, but acceleration is not.
Acceleration is absolute relative to space, time,
itself. Yeah. And it would also sort of tell you that the universe kind of has a direction, right?
It kind of would have a north and a south and a tropical zone. It prefers dark chocolate to white
chocolate. All right. Well, we hope your head is not spinning from all that discussion about
spinning. But we hope that it does sort of make you think about whether or not the things around
you are moving the way you think they are. And whether or not the universe was maybe born a pretty
chill baby or a crazy spinning baby. And I hope you come away a little bit.
in awe of the fact that we can ask such amazing, enormous questions about the nature of the cosmos,
and that we have ways just from this tiny spinning rock of finding initial answers to these questions.
Yeah, and that we can talk about it in an hour.
And only make 47 chocolate references.
That's right. Only make 47 bad chocolate punts.
All right, well, we hope you enjoyed that. Thanks for joining us.
See you next time.
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