Daniel and Kelly’s Extraordinary Universe - Winter solstice listener questions
Episode Date: December 31, 2024Daniel and Katie answer a question about building super duper long structures in spaceSee omnystudio.com/listener for privacy information....
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So Daniel, you do a lot of cooking.
what is the biggest kitchen implement that you have?
Do we measure kitchen implements by size now?
Is the biggest one the most important?
It is to me.
I got one giant ladle, and that is the most important.
What is, let's talk about sheer volume.
What takes up the most space for you?
Well, actually, we went out and bought a huge soup pot last time.
We made soup for about 100 people.
100 people for dinner?
That's a lot.
Yeah, well, you know, we were out celebrating the solstice and you got to go a little crazy on the solstice.
So we had 100 people over for a sit-down dinner and we made a lot of soup.
I would rather burn my kitchen down in a ritualistic bonfire than do 100 sets of dishes after that.
That sounds like a great way to celebrate the solstice, actually.
Kitchen bonfire.
Kitchen effigy.
There we go.
No more washing dishes.
Hooray.
It's the solstice.
magic.
Hi, I'm Daniel.
I'm a particle physicist and a professor at UC Irvine, and I'm not into astrology, but I do
love the solstice.
I am Katie Golden.
I host podcast on animal behavior called Creature Feasties.
and I am super duper into solstice magic such as logs in the house and putting stones up such that they make
interesting shapes and the light hits them in just such a way.
I see you're building Katie Hinge.
Katie Hinge.
You know, okay, for the summer solstice one, I actually did talk about Brutaboy.
but I also want to talk about how there's a wood hinge as well as the stone hinge.
And the word hinge actually comes from the idea of an thing hanging, like a hinge, hanging.
So stone hinge is like hanging rocks.
And woodhenge is another ancient people's way of creating basically an annual sundial.
and that was made out of wooden timber.
I just always thought they were trying to hinge their bets.
I was thinking about starting a hinge fund, you know.
Oh, my God.
Well, we do need to teach Daniel about the difference between a hinge and a hedge.
Well, could you have a hedge hinge?
You know what?
It's never been done as far as I know in gardening science,
but that never doesn't mean never.
Well, okay, how about a biology one that a hedgehog hinge?
Hedgehog hinge? Well, you know, maybe there's a hedgehog hinge for hedgehogs looking for love.
All right. We'll hedge our bets until we get there. But anyway, welcome to the podcast, Daniel and Jorge Explain the Universe, a production of IHeart Radio, in which we do not hedge our bets. We go all in on trying to understand how the universe works and explain it all to you. We tackle the biggest questions from the very nature of the universe to the smallest questions about quantum particles and the fundamental nature of space and time.
and everything in between, including how to get your hedgehogs out of your hinge.
So there is a question I always get about hedgehogs, and it is, how do they reproduce?
And my answer is very carefully.
That's a very pointed answer, Katie.
And people have questions about the universe.
They wonder about hedgehogs.
They wonder about quantum particles.
They wonder about quantum hedgehogs.
They wonder about hinges and what ancient people saw in them.
They wonder what the soul.
this means and they wonder what's going on between us and distant stars and that's all part of doing physics you don't have to be a professional academic to be a physicist you just have to wonder about the nature of the universe and then share that curiosity with everybody else and we hope you share it with us if you have a question about how the universe works and you can find an answer on google or chat gpt or your friendly neighborhood physicist please write to me to questions at danielanhorpe.com we will answer it
Everybody gets an answer in their inbox, and sometimes we take an answer and put it right here on the podcast, also because we've been missing you and we wanted to hear from you again.
So 99% of a particle physicist's job is asking the right questions, and 1% is, you know, math or whatever.
And this is also got to be rub in there for napping.
Napping is crucial.
Right, right.
And like a little bit of grant writing.
Occasionally. And so on today's episode, we'll be answering.
Listener questions. Winter solstice edition.
Happy holidays and New Year and Solstice to everybody out there who celebrates whatever it is you celebrate.
Today we're going to be celebrating by answering a really fun question from a listener,
a question he thought of while he was in his backyard shed, maybe building his own
hinge. Here's the question from Alex. Hi guys. I was working in my back out on my shed and I was using
a metal crowbar to help out one day when I just realized holding it how strong it was. So my question
that came to me was what is actually the longest physical possible crowbar made of metal that
that could exist in space.
Is it possible that you could build one?
One could exist that's long enough to stretch between stars,
especially if you didn't have to worry about adding to its length with unlimited supplies.
And if it was nowhere near any other gravitational objects.
What would the ramifications be of having it like a crowbar
where one end was light hours away from the other
or even light years away from the other?
It seems a bit weird to travel light speed and not get from one into the other on one particular object.
Thank you.
So, you know, I have a similar question, but once I just saw a crowbar on the ground,
I think there were some people working on something like a manhole or something sort of nearby.
But also, I wondered if the world operates by video game rules,
which is if you find a crowbar, is that yours now?
Do you pick it up and put it in your inventory, or is that still stealing?
I don't know.
Maybe the world operates by checkoff rules.
If you find a crowbar in Act 1, then you're going to have to break into something with it in Act 3.
I mean, that is just video game rules also.
Yeah, exactly.
Exactly.
I used to play like Kings Quest back in the day.
And every time you found like a weird magic wrap mushroom, you put it in your back pocket
because you knew you were going to need it to solve some puzzle later on.
Get ye bucket.
You're going to need that bucket for the draft.
at the end of the game.
Exactly.
You can't go back so get the bucket now.
Alex is wondering about like the practical limits of how big we could build something.
Like could you build a crowbar that's long enough that you can use it to like poke people on
other planets?
That's pretty crazy thought, Alex.
It's interesting, right?
Because sure, you could have like a large object, but the bigger it gets like there's a lot
of questions here, right?
We need to know about a, what are crowbarians?
bar is made out of steel iron steel and so it's like I guess a lot of it is basically the strength
like the steel you know the what steel is made out of how that would work but also you know how
even if it made out of any material right like let's say crowbar made out of whatever material
the strongest hardest material you could get like is there a limit to the size of physical
objects in the universe before something wacky starts happening.
Yeah, this is really fun.
And there's a really important lesson here about how we do physics anyway, because an important
sort of often implicit step that we don't talk about when we do physics is building a simplified
model of the universe.
Like you want to answer a physics question, you know, like a piano is falling from a window.
Is you going to squish that little doggy?
No.
Oh, no.
We hope the answer is no.
But to answer that physics question, what you have to do is simplify it first because you don't care about a lot of the details.
You don't care about the color of the P&O.
You can probably ignore the crosswinds.
You build a simplified model that just contains the information necessary to answer the question.
Like the breed of the dog.
For example, yeah, we don't care.
I mean, we care, but doesn't change the answer.
And so the trick there is to make a model that's simple enough that you can actually answer it because you've included all the details of all the quantum particles and be intractable, but is sophisticated.
that it still provides a realistic answer.
That's the sweet spot for doing physics.
And the interesting thing is that that's a different model in every scenario.
You can ignore the winds in this case,
but if you're solving a different problem,
like what's going to happen to this leaf in a tornado,
you can't ignore the winds.
So every time you solve a physics problem,
you need to ask yourself,
am I including the right assumptions
or the assumptions I'm making going to ruin it?
And so I run into this all the time
with these very long space rods.
That turns out, Alex is not the only person to think about really long rods.
It comes up a lot because people have this idea that a rod is sort of like infinitely rigid.
Like if I'm across the room from you and have a dowel, like a wooden stick, if I push it, then you're going to feel me pushing it.
You're holding the other end.
You're going to feel it.
And people imagine that sort of happens instantaneously, that if I push on the stick on one side, you feel it instantly.
And that's mostly true.
And for basically every problem you're going to solve here on earth, that's basically the case because the information
travels very, very fast. But then people wonder, all right, what if I take a rod and I build it so it's like
four light years long and I stretch it from here to Alpha Centauri and some alien is holding the other
side? Can I tap on my side and use that to communicate faster than the speed of light? That's a very
common question I get. And the answer is obviously no. You can't break special relativity with a
dowel that's four light years long. Even dowels have their limits, I guess. Yeah. And the reason
is that you've broken the assumptions. Down here on Earth, it works to assume, yeah, the information
travels instantly, that when you push one side of the dowel, the other side moves instantly.
But that doesn't work anymore when the dowel's really, really long because the time it takes
now matters. Because the dowel, even here on earth, doesn't transmit information instantly.
What happens when you push on one side of the dowel is that you don't immediately move the other
side. You push on one side, and it moves the layer of molecules that are next to the edge,
the next layer, which move the next layer, which move the next layer, because a dowel is not
infinitely rigid. It's like a very stiff version of a tube of water or like a string. You're pushing
on it and there's a wave of information that travels down the dowel. So here on earth, you push on one
side of the dowel, the other side moves very shortly afterwards, but not instantly. It takes time
for that information and move down the dowel. Now when your dowels four light years long, that time
is no longer something you can ignore. It plays a big part in how.
long it takes for the information to get there. And if you ignore that, then you're violating
special relativity. And it seems like you could send information to the stars faster than the
speed of light, which, of course, you can't. This is actually the same problem from a biological
perspective of having like a giant brain, right? Could you have a enormous brain that could
like communicate instantly, right? Like some galaxy-sized brain. And the problem is that the way
our brains work in the same way that you talked about how like the molecules have to push on
the other molecules like our brain is all physics based our whole bodies are basically a big
ruby goldberg machine of molecules bonking into other molecules which creates things like thought
and so if you have a say a giant enough brain the time it would take to like have a single thought
would be incredibly slow so the bigger the brain the more galaxy's
the brain actually the slower it would take to have a thought.
Yeah, exactly.
And so if you're ignoring that when you're just thinking about a small brain,
you can no longer ignore that in a large brain.
So the lesson is when you're doing physics,
you have to always think about what are the assumptions we're making
and are those assumptions still valid for this scenario?
In the case of the like five light year long rod,
if you assume instantaneous motion from one side of the other,
then you're assuming special relativity is broken.
So you can't then go and say,
oh, look, this rod breaks special relativity.
Well, you assumed it was broken, and that's why you broke it.
And so there's a lot of unpacking of those assumptions in these questions.
But Alex's question is a little bit different.
He's not trying to communicate with aliens.
He's just trying to build a really long rod, and he's wondering, like, how big could you make it anyway?
And I think that's exactly what he's digging into, like, what would break down?
What assumptions we make about building long rods would break down if we try to make one that's like a light year long, which is a really cool question.
Yeah, because, I mean, there's.
a lot of things that we could say like on earth right like we could try to build a really
long crowbar and then at a certain point it could collapse under its own weight but if something's
in space we'd have to figure out what kinds of forces or how gravity would be acting on something
in a way that's different from earth right like yes you can you know it's like have you ever
whiteboard pins like you create a big old lightsaber out of whiteboard pens and it is
certain point. There's too many and it collapses. But that's all using Earth physics. So you could
make a much longer whiteboard pin lightsaber out in space because gravity is not impacting it in the
same way that it is on Earth. But then once you get big enough, right, with this pin dowel or iron crowbar
or whatever it is, something's happening. And this is where I would like you to talk.
Yeah, exactly. So let's take this question out into deep space. And the first thing to wonder is like, well, what's the biggest thing that we've built in space so far? And that's the international space station. It's not that impressive long. It's about 36 meters long. But you know, it's not very far out in space. And they're not trying to build something super duper long. I think the longest thing that's ever actually been in space is more like a kilometer. They build a space tether, which is like a really long wire that you dangle from a spaceship to try to like.
like generate electrical current or to learn to steer using magnetic fields.
So like a kilometer long is the biggest thing that we've ever put into space.
But again, that's also just the near-Earth orbit.
So let's go deeper out in the space and try to build something that's really long.
And think about the forces involved.
Like when you build a rod out of steel or even a dowel out of wood or whatever,
how are you actually building that thing?
Usually we ignore it and just say, oh, it's some smooth continuous substance.
But if you zoom in, the reason it takes time to propagate information along it is the same thing that's holding it together, which is the forces between those molecules.
All of these objects in the end are like a mesh of molecules.
You have these little bits of matter tied together by forces to build something larger.
And it's those forces that transmit the information also limit how big something can get, right?
And so out into deep space, what is the thing that's limiting us?
Well, those forces can work.
They can tie something together.
They're basically infinitely, there's no limitation there.
You can just keep adding layers and layers and layers to your rod.
The thing that's going to keep you from building that rod light years long or infinitely long,
in the end are going to be the gravitational effects, residual as they are, and the nature
of space and time itself.
But let's first talk about the gravitational effects.
So one effect are tidal forces.
So you say, well, let's be out between the stars.
Alex is actually talking about something which stretches between the stars.
So you have like one end at one star and the other end at another star.
And if you have something that's like five light years long, you can't have it that far away from stars because it's going to be big enough.
There's always going to be some star nearby.
And remember that gravity does more than just pull on things.
It can actually pull things apart.
These are called tidal forces.
And for example, if you're near a black hole, then your head can have a different gravitational tug on it than your feet.
And that can effectively tear you apart.
Like if the black hole is pulling on your feet harder than it's.
pulling on your head because your feet are a little bit closer, then it's going to pull you apart
because its gravity is really, really strong. But if you're really, really long, then you don't
need strong gravity to have tidal forces. Because if one end of this rod is closer to the star
than the other end and the rod is really, really long, that's going to be a very large
difference in the gravitational force from one end of the rod to the other. And that star is going to
tear it apart. Even if the star doesn't have really powerful gravity like black holes, the
sheer length of the rod makes the title forces very significant. I see. So you can't span
Adele from one star to the other because of the same title forces that spaghettifies you in a black
hole. But what if you took away the stars, right? Like could you could you get a like infinity rod if
you took away stars and just had it existing on its own in space without?
hitting anything. Yeah, right. So get rid of the other gravity and you still have the issue of the
gravity of the rod itself, right? You can't build an infinitely massive rod because eventually that
thing is going to have its own self gravity. It's going to collapse into a black hole. Like you can't
just make a blob of metal and keep adding blobs of metal to it and make it as big as you want
because it's going to start collapsing. This already happens for things like planets. Like the earth is
about the largest rocky planet you can make. You could add more rock.
to it, but that's going to mean more gravity, and it's just going to compress the earth further.
So as you add more mass to the earth, it doesn't get any bigger.
It just gets denser.
And eventually, you keep adding mass, you're going to end up with a black hole.
And so there is a limit to how large and how massive you can make something before it collapses
into a black hole.
So something self-gravity will also limit how large you can make an object out of practical stuff,
like steel or wood.
Okay.
so what about a really thin rod now stay with me what if you have a rod that is like one atom per unit right is like one atom thick and then you just stack a bunch of atoms into this very long rod would that still be something that would at a certain point start to collapse in on itself because of gravity or am i already breaking some laws of physics by
trying to create a one atom diameter rod.
Now, you could probably make a carbon nanofiber eventually that's like one atom thick
and super duper long.
I don't think it's a technical problem there.
But what you're going to run into is a problem with the nature of space and time.
And if you can get rid of gravity of the nearby stars and effectively get rid of the
self-gravity by making this thing really, really lightweight, you're going to run into dark energy.
So in short distances, like the size of our solar system and the size of our galaxy,
the dominant force is gravity it holds things together it shapes things it determines the nature
of our universe but over very large distances gravity gets weaker right the further you are away
from something the weaker its gravity is and at those distances something else takes over which is
dark energy meaning the expansion of the universe itself remember that everywhere in the universe
is expanding take any arbitrary chunk of space as time goes on that space is getting larger it's
making new space so between the earth and
the Sun, for example, new space is being made, but the gravity of the Earth and the Sun overpowers
it. Between our galaxy and the neighboring galaxy, new space is being made, but again, the gravity
overpowers it. But eventually, between clusters of galaxies, dark energy becomes more powerful
because you have more of these cubes of space, and each one is expanding, so that adds up. And gravity
gets very, very weak. So take Alex's super-duper long, infinitely thin rod. Eventually, it's going to be so
long that dark energy is going to tear it apart. It's going to be creating new space between those
atoms faster than those atoms can recover and bind themselves together. So you can get
spaghettified by space and time. All right. So we cannot make an infinity rod, unfortunately.
Do we know, like, how big something can get before the expansion of the universe starts to
break it apart? It's going to be really, really big. And remember that.
that nearby galaxies are millions of light years away.
And dark energy only really dominates between clusters of galaxies.
So we're talking hundreds of millions of light years.
So if you can overcome the gravity of nearby stars and overcome tidal forces completely
and overcome collapsing due to self-gravity, then you could still build something that's like
hundreds of millions of light years long.
So that's pretty good.
You know what?
That sounds great.
I'm going to write a grant to get started building on the biggest spaghetti that one could make.
Spaghettiissimo.
Yeah.
I bet Italy's government would fund that.
I'm going to write to them.
Yes.
In honor of the winter solstice, I think that's a great idea.
All right.
Well, thank you very much, Alex, for thinking big and wondering about how far we can push our concepts of distance and structure and space and time.
really fun way to explore all of those different factors and really appreciate everybody out there who's thinking about the universe and wondering about it and who's brave enough to write into their favorite internet physicist to look for some answers if you'd like to see my email in your inbox write to me to questions at danielanhorpe.com i'd sure love to hear from you thanks very much katie for pushing the boundaries of space and time and humor today and thank you for signing on to my petition for universe's longest spaghetti
Fund it, fund it, fund it.
All right, thanks everyone for listening and tune in next time.
For more science and curiosity, come find us on social media
where we answer questions and post videos.
We're on Twitter, Discord, Insta, and now TikTok.
Thanks for listening, and remember that Daniel and Jorge Explain the Universe
is a production of IHeartRadio.
For more podcasts from IHeartRadio, visit the IHeartRadio app.
Apple Podcasts or wherever you listen to your favorite shows.
Hi, it's Honey German, and I'm back with season two of my podcast.
Grazias, come again.
We got you when it comes to the latest in music and entertainment with interviews
with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in, like, over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We'll talk about all that's viral and true.
trending with a little bit of cheesement and a whole lot of laughs.
And of course, the great bevras you've come to expect.
Listen to the new season of Dacius Come Again on the IHeartRadio app, Apple Podcasts, or wherever you get your podcast.
I'm Dr. Scott Barry Kaufman, host of the psychology podcast.
Here's a clip from an upcoming conversation about how to be a better you.
When you think about emotion regulation, you're not going to choose an adaptive strategy, which is more effortful.
to use unless you think there's a good outcome.
Avoidance is easier. Ignoring is easier. Denials is easier.
Complex problem solving takes effort.
Listen to the psychology podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Every case that is a cold case that has DNA. Right now in a backlog will be identified in our lifetime.
On the new podcast, America's Crime Lab, every case has a story to tell. And the DNA holds the truth.
He never thought he was going to get caught.
And I just looked at my computer screen.
I was just like, ah, gotcha.
This technology's already solving so many cases.
Listen to America's Crime Lab on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Get fired up, y'all.
Season two of Good Game with Sarah Spain is underway.
We just welcomed one of my favorite people, an incomparable soccer icon, Megan Rapino, to the show.
And we had a blast.
Take a listen.
Sue and I were like riding the lime bikes the other day and we're like,
we're like, people ride bikes because it's fun.
We got more incredible guests like Megan in store, plus news of the day and more.
So make sure you listen to Good Game with Sarah Spain on the IHeartRadio app,
Apple Podcasts, or wherever you get your podcasts.
Brought to you by Novartis, founding partner of IHeart Women's Sports Network.
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professional networks or stereotypes, don't let anything keep you from discovering the half of the
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in the ad council. This is an iHeart podcast.