Daniel and Kelly’s Extraordinary Universe - Could a huge void cause the illusion of dark energy?
Episode Date: September 17, 2024Daniel and Jorge talk about whether our galaxy is in the middle of a giant void that could have fooled us into thinking the expansion of the Universe is accelerating.See omnystudio.com/listener for pr...ivacy information.
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Hey, Daniel, what are we talking about today on the episode?
We are talking about a void.
As in, you're going to avoid my questions?
No voids, as in vast, empty spaces.
Is there a scientist that discovered them?
And if so, is it kind of a scam because you just discovered nothing?
I'd love to get famous for discovering nothing.
That's basically what I've done my whole career.
Same here, same here.
For that, you get the no prize instead of the Nobel Prize.
Oh, you don't get any bells and whistles?
So you do get the Nobel Prize.
I think I want to void myself with these jokes.
Oh, void.
Hi, I'm Jorge, I'm a cartoonist, and author,
of Oliver's great big universe.
Hi, I'm Daniel.
I'm a particle physicist
and a professor at UC Irvine
and I got into this business
to make radical universe
changing discoveries
but I haven't made any.
The whole reason we hear
has been all for nothing.
Well, you know,
research has no guarantees.
You could go out there
into the vast plain
of undiscovered territory
and find all sorts of incredible stuff
or just nothing.
We have no promises from nature.
Well, Daniel,
You sound a little defeated.
Did you have a lot of years ahead of you in your career?
No, I'm not defeated.
I rolled the dice, and I knew there were risks.
And, you know, physics is a lot of fun along the way,
even if you don't make a big discovery.
But don't you have, like, at least 20, 30 years of work still?
Or are you just planning to coast the rest of the way?
On advice of counsel, I'm going to not answer that question.
You're like, it's called being emeritus.
I'm rapidly approaching emeritus.
Well, whether you're emeritus or active, welcome to our podcast, Daniel and Jorge
Explain the Universe, a production of IHeart Radio.
In which we guide you through all the incredible, mind-shattering discoveries of the last
few hundred years that have revealed a universe that's weird, that's bizarre, that's strange,
and yet somehow maybe understandable.
And we also try to guide you through potential discoveries in the next few years or the next
decades, maybe made by me or my team or by some of the listeners to this podcast or their
great, great grandchildren. Whenever those discoveries come, we want you to be prepared for them
by understanding what we do and don't know about the universe. That's right, because it is an
incredibly huge and amazing universe out there full of incredible phenomenon, astounding events,
and also a whole lot of nothing. Indeed, the universe really is something, even if that something
is often nothing.
But there's lots of mysteries remaining
about the nature of the universe,
as much as we've discovered
in the last hundred years,
about how big the universe is,
about how it's expanding,
about how that expansion is accelerating,
about how galaxies swirl around
invisible dark matter.
There's still a lot of pieces
that don't fit together,
which tells us probably
the next few decades or few hundred years
will reveal even more
mind-blowing discoveries
about the nature of our cosmos.
Yeah, the amazing thing about this universe and about science is that all the pieces are out there for us to see,
for us to discover, for us to observe, and for someone, maybe you, maybe us, to put it all together
and make sense of this amazing cosmos.
Oh, wait, wait, sorry, sorry, not Daniel.
He's already given up.
Hey, you know, if it falls in my lap, I'm not saying no, but yeah.
Well, Tzano, like, just throw it in the trash.
You know, the universe is like a giant.
giant mystery novel. Often all of the clues are out there staring us in the face. It just requires
the insight, that moment of clarity, to see how it all fits together into one coherent story.
And currently, we're struggling a little bit to understand all of those clues to tell a story
that makes sense to us and that holds together mathematically. And it could be that some elements
of our current story are drastically wrong. We've certainly done that lots of times in history,
gone down the wrong path for decades or even centuries before having to backtrack
and come up with a completely new radical interpretation of how the universe works.
Yeah, leaving all those other scientists who have discovered nothing.
But all the clues are out there.
But one of the problems is that they're really far away.
That's because the universe is full of nothing.
A lot of big empty void and spaces that are preventing us from reaching and touching
some of the important clues that are out there.
but there is maybe the idea that some of these huge voids of nothingness
could maybe hold the answer to one of the biggest questions in the universe.
That's right.
Maybe the biggest question in modern science today is what is driving the expansion of the
universe?
Why is it going faster and faster every year?
We have a placeholder idea we call dark energy,
but as you'll hear, it's not even really a single coherent concept.
and we might need completely new explanations for it.
So today on the podcast, we'll be tackling the question.
Could a huge void cost the illusion of dark energy?
So wait, what are you saying, Daniel?
The dark energy is not something, and in fact, it might be nothing?
Wouldn't it be a huge dramatic plot twist if the answer?
The biggest question in science was nothing.
I feel like we can already preview that.
Like, what came before the universe?
Nothing.
What's going to happen after the universe?
Nothing.
We're just a blip in the nothingness.
I think the answer to both of those questions is actually we don't know or we have no idea,
which is a little bit different from nothing.
And, you know, philosophically, nothing is a complicated concept.
Like, what does it even mean, right?
We've talked on the podcast about how space is never really empty.
All of it has quantum fields and it's a, what does nothing even really mean?
It's actually quite a deep philosophical question.
It is very tricky.
Yeah, for example, I have a doctorate in philosophically, but I know nothing about philosophy.
So you're saying you know nothing?
Well, you're an expert in nothing.
Well, I guess that's something.
I would say I'm no expert in nothing.
Nothing is actually quite complex.
I lost track of the negatives there.
No, you didn't.
No, I did.
No, I didn't not know nothing about something.
There you go.
Well, let's check in with the listeners to see if they don't not know nothing about nothing.
Yeah, as usual, Daniel went out there to ask people if they think maybe a huge void could be causing what we see as dark energy.
Thanks very much to everybody who sent in their answers.
I would love to hear your voice on the podcast.
That's right.
I'm talking to you.
You've been listening for years but never chimed in.
Today's the day.
Write to me to Questions at Daniel and Horhe.
So think about it for a second. Do you think dark energy could be explained by a huge amount
of nothingness? Here's what people had to say. I don't think so. Even without the accelerated
expansion of the universe, it's still possible to have huge voids in space. Perhaps if we were
able to detect that a huge void wasn't there before, we might be able to use that as evidence
towards the cosmological constant. But I think that would take a long time.
Perhaps the void is filled with dark energy, which we cannot yet detect.
So perhaps these areas could be responsible for the accelerated expansion rate.
If only we could learn what dark energy truly is.
I'm going to assume in your definition of space, you ascribe to quantum field theory.
And a void in space would be an area where the fields from all the fundamental particles are somehow blocked from this area.
One could posit that some of these fields might feel a sort of pressure to fill the void causing anything.
expansion. So sure, I'll say it could.
Aha. Dark energy explained.
Sure. It could be space expanding into a void, but then where is that void? What is that
void made out of? And how is it expanding into it? And what does that even mean? I don't
know about this one. I'm confused by that comment. What's the difference between a huge amount of
nothingness and a small amount of nothingness if they're all nothing? It's like 10 times zero versus one
time zero. I think the difference is nothing. Nice. Well, I like these listeners answer some really
well-informed thoughts here. You seem surprised, Daniel. No, I'm impressed as usual. Had you given up on
our listeners as well? I think your reaction is based on nothing. I have nothing but respect for these
listeners. Their efforts to understand the universe, their willingness to contribute, I'm in awe.
Well, they do have some interesting answers here. And it's kind of an interesting question.
that maybe the biggest part of what we see in the universe,
95% of all the mass and energy in the universe,
maybe is not really something or mass or energy.
Maybe it's just something that can be easily explained with nothing.
Yeah, that's right.
In order to explain this accelerating expansion of the universe,
we've had to add into our equations something very weird, very awkward,
something we really struggle with.
And so people have been working for a long time
to find alternative explanations,
sort of more prosaic ideas that would explain the strange things we see out there in the universe.
My question, Daniel, is, why didn't we think of this before?
I mean, when you see something mysterious, shouldn't the first thing you ask be, maybe it's nothing?
Yeah, it's a good question.
This particular idea that we're going to talk about today is uncomfortable in other ways for scientists.
It violates some, like, philosophical principles that they really hope the universe respects.
And that's why it's a little bit weird, a little bit uncomfortable to consider.
But, hey, sometimes when the universe confronts you with data, you just got to accept it.
I mean, after like 20, 30 years of trying to explain it in other ways, I guess.
Yeah, exactly.
Just because it makes it uncomfortable.
I like that the universe makes us uncomfortable.
I like when we go, what?
That doesn't make any sense all.
How could the universe be that way?
Those are the moments we really learn something.
When we really have to confront some fundamental assumption that is probably wrong.
Right, right.
You like it, but only if you're sitting comfortably in your couch, right?
Yeah, exactly.
Let me get comfortable before you make me uncomfortable.
Yeah, let's draw a line here.
I want to be physically comfortable, but intellectually uncomfortable.
Is that what you're saying?
Yeah, serve me some chocolate while you tell me the results of this study.
Yes, absolutely.
A little bit of sugar makes the medicine go down.
Right, right.
You've given up, even getting up for your couch.
But anyways, Daniel,
For those of us who are sitting in our couch is waiting to hear the answer.
Why don't you start us with the basics?
What is this thing that we call dark energy?
Yeah.
So the thing that we're struggling to explain is something we call dark energy.
But dark energy is not really like a theory as much as a description of something we observe in the universe, for which we don't have a great explanation.
And that's the fact that the universe is expanding.
And it's not just expanding the same rate every year.
it's expanding at an accelerated rate.
It seems like the distances between clusters of galaxies is increasing, so that's expansion,
but it's increasing faster and faster every year.
This is something we discovered about 25 years ago now when we first learned how to figure
out how far away things are in the universe.
And it was really a shocker.
You know, people before that were wondering how quickly the expansion of the universe was
slowing down.
That was the big question in science.
Because you have the universe expanding when it's very, very young, but then it's filled with matter.
There's all this heavy stuff in the universe, galaxies and black holes and whatever, that tends to pull stuff back together.
And so people were wondering, hey, is there enough gravity to pull stuff back together to make like a reverse big bang, like a big crunch?
Or is there not enough?
And it's just going to gradually slow down for a long time to keep drifting apart.
And when they went out to measure it, they discovered shocker.
Neither of those were true.
The universe preferred secret answer C, which is.
is that things are getting further apart faster and faster.
And so dark energy is sort of like our placeholder name to explain how that might be happening.
So I think we've known that the universe is expanding for about a hundred years, right?
But you're saying it's only recently we figured out it's accelerating.
Yeah.
If you want to go further back into history, around the time that Einstein was developing the theory of relativity,
we thought the universe was static.
We thought that there was just like our galaxy hanging out there in empty space and that was it.
Then Edwin Hubble and Henrietta Levitt developed this way to measure the distance to things in the sky to tell how far away they were.
And what they discovered is that some smudges we saw in the sky that we thought were just like clouds of gas in our galaxy were actually much further away.
They were further than any of the stars in the sky.
There were actually other galaxies.
And on top of that, those galaxies were moving away from us.
So we discovered that the universe was not only just our galaxy, it was filled with galaxies, and that the universe was.
expanding everything was running away from us that was about a hundred years ago and
how do we know they were moving away from us from the red shifting the Doppler effect yeah exactly
you can look at the light from those galaxies and you can see how its frequency shifted things
that are moving away from us as you say the Doppler effect the light from those things is shifted
in frequency and you can tell because we have an idea for what frequency of light should be emitted by
galaxies that have these particular fingerprints and so when they're shifted over 20 nanomero
meters or 100 nanometers or whatever in wavelength, then we can tell and that we use that
to measure the velocity.
And so back then did we think or measure that everything was moving away from us at the same
speed or we just didn't know enough to know at what rate things were moving away from us?
Back then, Hubble's discovery allowed us to measure the distance to other galaxies, but sort
of only in a nearby sphere.
Hubble couldn't tell that the universe was expanding and accelerating because he couldn't measure
the distance to far away enough stuff.
He and Henrietta Levitt developed this technique to measure the distance to stuff
looking at these particular variable stars called sephids.
But you had to be able to see them.
And if galaxies were far enough away, then you couldn't see those stars in the galaxies.
So he could have sort of only see a little bubble.
But about 25 years ago, we developed a new technique that allowed us to see much further
and to measure the distance much further.
And so then we could see the change over time as we look back into the history of the universe.
and we noticed this effect.
So Hubble couldn't see it because he didn't have like enough data.
He didn't have a long enough lever arm in history to see things changing.
It was being able to tell how far away things were.
And then measuring on top of that, their velocity that led us figure out that things were accelerating.
Yeah, exactly.
It was the development of this technique using type 1A supernova.
Supernova, of course, the implosion of stars leading to an extraordinarily bright explosion.
So bright that they outshine the galaxies therein.
And so you can measure these things for very, very distant galaxies.
And understanding the physics of it and understanding how bright they are at their source
without knowing how far away they are,
lets you figure out how far away they are by looking at how bright they are here on Earth
because things here are dimmer when they arrive.
So that lets you know how far away things are.
And that's absolutely crucial because knowing how far away something is
tells you when the light left it.
And so as we look further into space, we're looking further back in time.
So that's how we can see the history of the expansion of the universe.
We can see how fast is stuff moving away from us that's close by, i.e. recent history.
And then we can ask how fast it was stuff moving away from us earlier in the universe by looking further away.
So this is absolutely crucial to understanding how dark energy works and also how it might be wrong.
What we see is that the expansion is faster for things that are closer to us.
And we interpret that to mean the expansion is speeding up.
So deeper into space, the expansion looks slower.
Closer to us, the expansion looks faster.
That's what leads us to conclude that the expansion is accelerating.
So the things we can tell are really far away.
Don't have as much of a red shift as the things that we can see that are closer to us?
They're further away.
So their actual distance, the red shift is larger, but it hasn't accumulated over time.
Right.
And so the acceleration is like the slope of that velocity curve.
So those things are very far away.
they are very, very red shifted, but the change in that slope, we can see over time as we look
at these things from further away to closer in.
All right.
So then that tells that the universe is expanding more and more rapidly.
And we have a name for that, which is dark energy, or at least the thing that might be
causing this acceleration, that's what we call dark energy.
Yeah, we call it dark energy.
And I feel like there's a lot of confusion out there about what we do and don't know.
And I think this is a really interesting insight into sort of the way physics works.
Like we often begin thinking about an idea before we have it all worked out.
We just sort of like start fleshing it out the way you might like design your house,
starting from what you wanted to look on the outside,
before you figured out like, hey, what are all the structural supports and can I really have pipes over here?
And is it possible to have a shower on the roof or whatever?
You know, you haven't always figured out the details, some of which might be absolutely essential.
And so if you look at the beginning days of the development,
Yeah, no, every house should have a shower on the roof.
My wife is a big fan of an outside shower.
She's always wanted to put one in.
So I'm always suggesting, let's put it on the roof.
And I don't know why that's not a popular idea.
But anyway, if you look at the history of the development of big ideas and physics, this is how it works.
And so we've done that with dark energy.
We're like, wow, this is weird.
How do we explain this?
Okay, first let's give it a cool name.
Now let's start to think about how it might be possible.
And we definitely don't have all the details worked out.
We have some conception of how in general relativity you might generate this effect.
We definitely don't have all the pieces together.
And we say that it's 95% of the energy mass and energy of the whole universe because that's how much energy you need to explain something that's accelerating the entire observable universe.
Yeah, it's something like 70%. Dark matter and dark energy together make 95%.
But the dark energy portion is 70%.
Yeah, and you're exactly right.
And the way we get that 70% is a few different ways, but one way is to say, all right,
how in general relativity could you cause the universe to expand?
Because usually gravity causes things to come together, right?
You have two masses in space.
They curve space.
They tend to move together.
But general relativity is much more complex than Newtonian gravity,
includes all sorts of complicated terms and effects in there.
And one of the possible effects in general relativity is, if you have a field in space,
like the electromagnetic field or the weak field or the electron field.
We know space is filled with these fields.
But if these fields have a lot of potential energy,
meaning they have like stored energy inside of them
because of their configuration,
the way the Hicks field does, for example,
having a lot of potential energy in space
will generate this expansion.
Just like part of the mathematics of general relativity,
you have a negative sign in front of this term in the equations,
and so it generates expansion of space.
So if you had a field with a lot of potential energy,
it would generate the expansion.
So we calculate how much potential energy do you need?
And that comes out to be about 70% of the energy in the universe.
Hmm, so this whole idea that dark energy is 70% of the universe comes from the assumption,
if I'm understanding, right?
The assumption that what's causing the acceleration of the universe is something kind of baked into space itself.
Yeah, exactly.
And there's some supporting evidence for it.
And there's also a bunch of stuff that doesn't work about it.
Like one supporting piece of evidence is that we can go out and measure all of the energy in the universe,
because it affects the overall curvature of the universe.
Like, is the universe overall flat or curved negatively or curved positively?
That depends very sensitively on how much energy is there in the universe.
And we go out and we measure that and we measure the energy out there in the universe
to be exactly what we need to make it flat and to add up very nicely with this 70% number.
So the dark matter, the normal matter, and the dark energy in the universe all adds up perfectly
to make the universe flat, which is what we observe.
That's very cool.
Oh, interesting.
Well, let's get into the things that don't work about dark energy
and why maybe nothingness could be the key to understanding how it all works.
So let's stick into that.
But first, let's take a quick break.
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My boyfriend's professor is way too friendly,
and now I'm seriously suspicious.
Well, 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?
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,
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December 29th, 1975, LaGuardia Airport.
The holiday rush,
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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
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The Good Stuff Podcast, Season 2, takes a deep look into One Tribe Foundation,
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September is National Suicide Prevention Month,
so join host Jacob and Ashley Schick as they bring you to the front lines of One Tribe's mission.
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I got blown up on a React mission. I ended up having amputation below the knee of my right leg
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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.
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No, I didn't audition.
I haven't auditioned in like over 25 years.
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That's a real G-talk right there.
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We're talking about dark energy and giant voids in the universe.
And could those two things be related?
Could dark energy just be a whole bunch of nothing?
Could it be explained by perhaps the absence of things in space?
So we talked a little bit about dark energy.
what it is, but we know about it.
But Daniel, there's something wrong with that picture of dark energy.
What's wrong with it?
What's wrong with it is that we have no idea
where all this potential energy would be coming from.
In order to have the universe expand and accelerate at the rate that it has been,
we need space to be filled with some kind of potential energy.
Well, here's a question.
Like, does dark energy need to be something that's like a field or baked into space?
Or could it be some maybe hidden property of gravity, perhaps,
or electromagnetism, or is that the same thing?
You could definitely be something totally brand new,
some new kind of physics we've never seen before
or a change in general relativity.
That's definitely possible.
And there are people out there working on other crazy ideas.
But sort of the mainstream effort is to say,
like, well, can we incorporate this into general relativity?
Because it's kind of interesting
that general relativity has this capacity already.
It's something that Einstein's relativity can do,
expand space and accelerate that expansion.
The problem is that to make that happen, you need to fill space with all of this energy.
Either you say, look, that's just the way it is.
You just put a number in there, and that's called the cosmological constant.
And you say, like, it's not explained.
That's just the nature of space.
It just has this energy, kind of unsatisfying.
Or you find the source of that energy.
You say, oh, look, it's this particular quantum field that can do it.
And we look through our list of quantum fields.
We ask, well, how much potential energy do they have?
And one of them has a lot of potential energy.
The Higgs field is filled with potential energy.
Remember that most of the fields in the universe like to relax down to zero.
They like to be in their lowest energy state.
But the Higgs field is really weird, has this wrinkle in it, so it sort of gets stuck at high potential energy.
When the universe is cooling, the Higgs field doesn't collapse down to zero the way the other ones do.
It has all this potential energy.
All right, so this is really exciting, right?
Dark energy needs some field filled with potential energy to explain the accelerating expansion in the universe.
over here we have a field filled with potential energy awesome so people sat down to do the calculations
and say does the higgs field have enough energy to explain the accelerating expansion in the universe
the answer is uh no and it's not even close the answer is off by 10 to the 120 so the fields we have
can definitely not explain the expansion of the universe as we see it but i guess if it's not a field
maybe if it's something else would it still account for 70% of the universe or
Like, what are some of these other things that could be?
Ooh, not a field.
Man, that blows my mind.
Currently, our theories of the universe are that everything is a field, right?
Like, all the particles are ripples in fields and all the energy out there is stored in some kind of field.
So mostly people are developing, like, new kinds of fields.
Maybe there's some other kind of field, not the Higgs field, something else out there in the universe that contains all of this energy.
And then you have to explain, like, why we wouldn't have seen it and it has no other effects that we could detect.
For example, that's the way.
way a lot of people are going, non-field explanations for the accelerating expansion in the
universe, those are pretty far out of the mainstream. But, you know, it could be right.
Physicists tend to work within the framework of the ideas we have. It doesn't mean that
that's where we're going to find the answer. Or what if it's like a part of gravity itself or
general relativity? Like maybe gravity turns negative if you get really far away from something,
or would that still be a field technically? I don't think that's compatible with general
relative so in order to have that be the explanation you have to change general
relativity and the thing people like about this dark energy framework is that you don't
have to change general relativity because it's been tested up and down the wazoo and it really
is accurate for huge distances for huge distances yeah i mean it explains an enormous amount
about the structure of the universe as we see it and so changing general relativity is pretty
uncomfortable except in places where it hasn't been tested like inside black holes or the very very
early universe, things we haven't been able to observe yet, basically where quantum mechanics
arises. So it's difficult to make changes to general relativity without messing up a lot of other
stuff. That would just be uncomfortable and also require a lot of work. And it could be the path
to huge discoveries. But, you know, the way physics works is, hey, let's try the easiest thing
first. And so there is this door open in general relativity. Like, let's see if we can explain it
using the framework we have, which requires discovering this field that explains,
where all the energy is, and that we don't have an answer for.
So then that's the problem with our current theories about dark energy,
is that you think it requires a field,
but we don't know what field it could be,
because it needs to have more energy than anything we know about.
Yeah, that's the major problem, sort of the conceptual problem.
There are also a few smaller problems, experimental problems,
like our picture of the universe as being mostly dark energy
and a big chunk dark matter and a little bit of barionic matter, normal matter.
It explains an enormous amount.
It explains how the universe started out filled with radiation, and then that radiation got diluted, and it was matter dominated, and it was expanding, but that expansion was slowing down.
But the expansion led to more dark energy, which then accelerated the expansion, and the universe became dark energy dominated, like six billion years ago.
It's an amazing, beautiful story that explains an enormous amount, but it doesn't quite explain everything.
Like there's this discrepancy between our observation of how fast the universe is expanding now and how fast it was expanding the very early day.
This is called the Hubble tension because the Hubble constant is kind of a measure of the expansion rate.
And that's not something we can really explain.
We don't really understand how the expansion or the universe connects for the expansion in late times.
At first it was very fuzzy measurements.
We thought, oh, we'll figure it out.
But as we make more and more precise measurements, they don't really agree.
So that might require a tweak to this, or it might be a crack that undermines the whole theory.
So it's not like it's a perfect description of everything we see,
even if you knew where this energy was coming from.
this energy was coming from.
So then I guess what's the alternative if it's not something like a field?
So one of the alternatives is to question one of the basic assumptions of this whole
picture of the universe that we've been talking about.
We usually talk about the universe in terms of density, like when we say 70% or 25%,
we're saying take a random chunk of the universe, how much of that is dark energy or how much
of that is normal energy.
When you do that, you're kind of making an implicit assumption that all chunks of
the universe are about the same.
The stuff is spread out through the universe basically evenly.
Like, we know it's not completely evenly.
There's definitely clumpiness.
Like, we're a big clump in the universe, the earth, the sun, the galaxy is a clump.
But that if you zoom out far enough, the universe is evenly spread out.
On the giant scales, the universe is basically the same everywhere.
That's kind of a philosophical preference.
They call it the cosmological principle or the Copernican principle.
But one of the ideas to explain the accelerating expansion of the universe is to say,
Maybe it's not expanding in an accelerating way.
Maybe it just looks like it is because we're stuck at the center of a huge void
where there's less stuff in this bubble than outside of it.
And that gives us the illusion that the universe's expansion is accelerating,
even if it isn't.
Whoa, whoa, wait a minute.
How does this even work?
Is the idea then that maybe outside of the observable universe,
there's a whole bunch of nothingness for a while?
Is that kind of what the picture you're thinking about?
The idea is that the bubble we're living in,
even though it has galaxies and stars and whatever is less dense than the stuff outside some bubble.
But then wouldn't we be able to see those things outside the bubble and tell if it's more or less dense?
Yeah, and we can get into the observations and whether this idea actually lines up with what we see in the universe.
But if this bubble exists, it'd be a little tricky to see because we'd be looking really, really far out.
And our sort of 3D map of the universe is best for close-by stuff and it sort of fades out a little.
little bit as you get further out. It's hard to make these big 3D maps to the universe.
And this void, if it exists, would basically describe everything we see so far. So it's sort of
suggesting that out there in the deep, dark reaches of space, where we haven't really mapped
very well yet, galaxies might be a lot denser than they are here. And that might be confusing
us about the expansion of the universe. Wait, I think you're saying that maybe, you know,
the galaxies we've seen to come to the conclusion that the universe is expanding.
in an accelerated way, you know, we use galaxies we've seen,
but maybe those galaxies we've seen don't go all the way to the edge of the observable universe.
Is that what you're saying?
We've used those galaxies and they do go all the way to the edge of the observable universe,
but it might be that things change as you go from here to the edge of the observable universe,
and that could be confusing us about this accelerated expansion.
The key concept is, remember that we decided that the expansion of the universe was accelerating
because we saw that changing as we look further and further into space.
And we decided that's because things are changing over time.
But what if things aren't changing over time?
They're just changing over space, right?
What if the universe is different as you go further away than it is here?
What if the universe is denser further away and then it is closer by?
And that's what's creating this effect.
We see an effect in space and we're assuming that it means an effect over time.
But what if it's just an effect over space?
What if the universe is different further away?
I see what you're saying.
I think you're saying that some of those galaxies we're using to measure the expansion
of the universe, maybe they're not where we think they are.
I'm saying that we see faster expansion close by and slower expansion further away, right?
And we interpret that to mean that there was slower expansion earlier in the universe
and there's faster expansion later in the universe, so the expansion is accelerating.
But what if the universe is just denser further away?
And so it's not expanding as fast because there's more gravity.
It's holding stuff together.
And so what if we're confusing nearby faster expansion for expansion increasing more recently, right?
What if it's not increasing more recently?
It's just we're in a bubble that's expanding faster.
If you go further away from us in the universe, things are expanding more slowly because the universe is denser there.
There's more gravity to hold it together.
So instead of saying, oh, the universe was expanding slower further away, back further in time,
and is expanding faster closer to us more recently, what if it's a universe?
It's not a function of time.
It's just a function of space because we're in this bubble that happens to be under dense
and so has faster expansion because it's less stuff to hold it together.
Whew.
I feel like my mind is a void right now, Daniel.
Yeah.
If you have more stuff in the universe, if there's more galaxies, for example, then there's
more gravity to battle against this expansion.
Stuff stays closer together.
So there is still an expansion of the universe?
Yes, there would still be an expansion, but it wouldn't be accelerating.
It's just expansion depends on how much stuff you have around you, which makes perfect sense.
So you're saying that there is an expansion of the universe, that's still happening.
Yeah.
But you're saying maybe, what if it's maybe even and not accelerating?
Maybe it's just a constant, steady expansion of the universe, which would still be a mystery, though, right?
No, you can have the expansion in the universe without any sort of like weird dark energy in the universe.
Okay, so then we are assuming still a steady expansion, but you're saying that maybe it's,
accelerate that expansion looks faster around us, even though it's not, it just looks faster.
It is faster around us. It's just that it's faster around us because there isn't as much stuff,
not because the expansion is changing over time. There's less stuff near us,
and so there's less stuff to hold stuff together, and so that's why it's expanding faster,
closer than further away. Oh, because you're saying that gravity somehow affects the expansion
of space. Absolutely, yes, gravity holds stuff together. If there was more stuff in the universe,
then things expand more slowly because gravity is pulling on them, right?
Well, but space itself, it doesn't hold space together or does it?
Is that what you're saying, that it somehow holds space itself together?
Absolutely.
The more stuff you have in the universe, the slower things move apart from each other.
Remember, we talk about creating new space, but really we're talking about increasing the distance between galaxies.
And that's all we can measure, right?
Space itself is not something where you can measure distances relative to space.
It's always distances measured between objects.
The things are being held together because, you know,
the same way that I'm being held together with the Earth?
Or are we talking about some, you know, relativistic or something, something?
No, the first way.
Yeah, the same way that you're being held near the Earth.
Okay.
But I always thought that like I'm being held to Earth.
And so I'm not expanding away from the Earth, but the space that we're both sitting in is expanding.
Yeah, there's two effects happening there, right?
Gravity's holding you together and dark energy is expanding that space.
But gravity wins because gravity is much more powerful.
were great distances, gravity weakens, right? And you can't hold things together. So dark energy
takes over. Right, but like right here on Earth, I'm sitting here on Earth and being held together
on Earth. I'm not expanding away from the Earth, but sort of like somebody's moving the chair under
me or somebody's stretching the rug under me, the space we're sitting in is expanding, isn't it?
Yeah, that's a helpful way to think about it, but it can also be misleading, right? Like, really what we're
saying there is if you deleted the Earth and replaced it with like a point particle, a proton, for
example, would dark energy be increasing the space between you and that point particle, that
proton? Yes, absolutely, because there is dark energy everywhere. That's the point of that
comparison. But these are like two things happening in the equations at the same time. The net
effect, because gravity dominates, is that you and the earth stay close to each other. You can't
really separate them out and say they're both simultaneously happening. It's like two force
vectors that you add together. If you have a huge amount of force on an object from two directions,
it adds up to zero force, right?
There's net zero force.
You can talk about what would happen if you removed one
or you could talk about what happened if you removed the other,
but you can't really say that there's any force on that object
because they balance each other out.
In the same way, dark energy tends to push things apart
and curvature tends to pull things together.
So you could talk about what would happen if you only had one or the other,
but really what's happening to you is a combination of the two.
All right.
So then the idea is that maybe we're wrong
that the universe is expanding faster and faster.
It just sort of looks like it because things are denser out there,
and so they're moving apart from each other less.
Yeah, exactly.
So as we look further into the universe,
which is further back in time,
we see less expansion.
But maybe that expansion isn't changing with time.
Maybe it's fixed with time,
but it's happening less further away than closer by
because there's more stuff further away.
Maybe we happen to be in some huge,
bubble where the stuff near us is underdense, there's less stuff in our bubble.
And so things can expand further and further away because there's less mass to sort of counteract
that expansion.
I guess what's confusing me is that if it's denser out there in the far reaches of space,
things are being held together there, but wouldn't I still see an acceleration or not
an acceleration from relative to me?
An acceleration of the expansion?
Yeah.
Like, I always thought that the acceleration of the expansion is because, like, the thing I see really far away is moving away from me slower than the things that are closer to me.
Yeah, that's exactly right.
But maybe the reason things are moving away from you closer is because of an under density, not because of a change in the expansion over time.
And maybe everything has the same expansion over time.
The things that are farther away have a smaller expansion because of the conditions over there, not because of the conditions.
not because of some change in the universe over time.
Right, we can only see this one slice of the universe in space and time.
We can look further back in time.
We can see the universe really far away as it was a long time ago,
and we don't know what is that part of the universe like now.
And so we see this one particular slice where we can see close by stuff recently
and far away stuff a long time ago.
And so it's hard to tell the difference between things that change over space
and things that change over time.
And we see a change in that story,
and we interpret that as a change over time,
but it could be that it's the same over time
as just changing over space.
Meaning that we are measurements
of the distance of those things,
how far away they are from us
or from each other is wrong.
How far away they are from us, yeah.
Imagine you looked out into the universe
and you saw that aliens on nearby planets
were all eating white chocolate.
And as you look deeper and deeper in the universe,
you discovered, oh, they're all eating dark chocolate.
And you say, well, oh, well,
that's older information.
the dark chocolate information has taken a long time to get here.
And so maybe what's happened over time is that everybody switched from dark chocolate to
white chocolate.
And that explains why my older observations from distant galaxies, the aliens are eating
dark chocolate.
And my recent observations from nearby galaxies, the aliens are eating white chocolate.
And then another scientist goes, no, no, no.
Maybe they just prefer dark chocolate out there in the deep reaches of space.
And we live in a white chocolate bubble where everybody seems to eat white chocolate.
Those two explanations both work.
One is a change over space.
The other is a change over time.
And we can't tell the difference because we have this one set of observations linked in space and time.
I'm not sure adding flavor to this is helping.
So then you're saying maybe what's explaining dark energy is that there's more stuff in the periphery of the universe.
There's more stuff in the perimeter of our vision or of what we can see.
Yeah, exactly.
But still within the observable universe.
Still within the observable universe, yes.
of course this is a big idea and if it's true you have to make sense of it and why we would be living in the middle of this big void and what else it would mean and there's lots of ways we can check this idea all right well let's dig into how we're testing this idea is it a stretch or is it a whole bunch of nothing as well so let's dig into that but first let's take another quick break
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My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Well, 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.
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.
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.
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.
I had this, like, overwhelming sensation that I had to call it right then.
And I just hit call, said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation, and I just wanted to call on and let her know.
There's a lot of people battling some of the very same things you're battling.
And there is help out there.
The Good Stuff Podcast Season 2 takes a deep look into One Tribe Foundation,
a nonprofit fighting suicide in the veteran community.
September is National Suicide Prevention Month,
so join host Jacob and Ashley Schick as they bring you to the front lines of
One Tribe's mission.
I was married to a combat army veteran, and he actually took his own life to suicide.
One Tribe saved my life twice.
There's a lot of love that flows through this place, and it's sincere.
Now it's a personal mission.
I don't have to go to any more funerals, you know.
I got blown up on a React mission.
I ended up having amputation below the knee of my right leg and a traumatic brain injury because I landed on my head.
Welcome to Season 2 of The Good Stuff.
Listen to the Good Stuff podcast on the Iheart Radio app, Apple Podcast, or wherever you get your podcast.
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. This is the hard part when you pay down those credit cards. If you haven't gotten to the bottom of why you were racking up credit or turning to credit cards, you may just recreate the same problem a year from now. When you do feel like you are bleeding from these high interest rates, I would start shopping for a debt consolidation loan, starting with your local credit union, shopping around online, looking for some online,
online lenders because they tend to have fewer fees and be more affordable.
Listen, I am not here to judge.
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It's really easy to just like stick your head in the sand.
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And in fact, it may get even worse.
For more judgment-free money advice, listen to Brown Ambition on the IHeart Radio app,
Apple Podcast, or wherever you get your podcast.
All right, we're talking about nothing, Dan.
Is this like the Seinfeld episode of the podcast, just about nothing?
As long as I can be Seifeld instead of George, then sure.
Yada, yada, yada, the universe.
Or maybe I should be Kramer.
I don't know.
As long as I'm not Newman.
Oh, man.
I want to be a lean she's the coolest one
she definitely is
it is a really fun idea
and it's always cool to think about
how your conception of the universe
could be totally different
from what everybody's been imagining right
the biggest ideas are the sexiest
because they also give you those moments
you're like wow the universe is this way
and not some other way
and this would be a pretty big idea
I mean this would be putting our galaxy
near the center of an enormous cosmic feature.
In order to explain the red shifts that we are seeing
to fit this to the data,
you have to have a big void,
something that's 3 billion light years in radius,
a gigaparsec.
And that's the only way this works, or what does that mean?
That's the only way this works.
It's the only nothing explanation that fits what we currently see.
Yeah, because when we look out into the universe,
we see the sort of same history in every direction, right?
So if you look in one direction, you see things closer by expanding more quickly than
things further away.
If you look in another direction, another direction, another direction, it's very isotropic.
And so to explain that by like a coincidence of the density, you need the universe to be more
dense, basically in every direction, which requires a huge void, and it requires us to be
at the center of it, and it requires that void to be basically
spherical. So you have the same weird density as a function of distance effect
in every direction. And so yeah, that's kind of a big cosmic coincidence if it's true.
Meaning like we're right smack in the middle of this giant void. Yeah. And like it doesn't
have to be exactly in the middle to within like a centimeter, but on cosmic distance
scales, we'd have to be very close to the center because we've measured this expansion
effect in lots of different directions. And it seems the same in every direction. So yeah,
we'd have to be at the center of it.
And this really violates this Copernican principle,
this idea that, like, the universe is basically the same everywhere.
And like, yeah, there's a little bit of clumpiness,
but there's no huge features that make this neighborhood
totally different from that neighborhood.
And, you know, that's not something we know.
It's just something we've assumed.
It makes sense.
It fits with the way we like to think about the universe.
Until nature shows us that it's not true,
we're kind of going to go with it because we like the idea.
It doesn't mean that it is true.
right doesn't mean that the universe has to be the same everywhere i guess you know what's confusing
me is like couldn't we tell if we were in a void like you know we can look with our telescopes and
we can see galaxies all the way out to the observable universe wouldn't we have noticed by now that
there are more of them further away than what we can see close to us yeah absolutely we could tell
if we had seen all the galaxies out there and map the density but you know things that are really
far away are hard to see in order to see things super duper far away you have to point a very
powerful telescope at them and you have to look for a while because these galaxies are very
very dim and they're very very red shifted so we have a telescope that can do that like
james web has been breaking records and seeing galaxies really really far away into the early
universe but james web is very expensive and we have one of it and it can only point in some directions
at a time and space is extraordinarily vast the number of galaxies we're talking about are huge
So we basically just haven't really looked far enough.
Like we've seen nearby stuff
and we like to think that we've seen
to the edge of the observable universe,
but we only have really done that in a few tiny directions.
And so like our detailed 3D map of the universe
definitely does not extend all the way out to the observable universe.
There are lots of places out there where it's very fuzzy.
But I guess you wouldn't need to see all of the universe.
You would just need to see whether things are denser out there
near the edge of the observable universe
than they are here.
Isn't that sort of a easy check?
Well, we don't see any evidence of that, right?
But they could still make the data fit
because our observations are still limited,
they can make this data fit.
And so you can come up with a theory of the universe
that respects general relativity
and describes all the red shifts that we see
from type 1A supernova
and our observations of galaxy density so far
and doesn't require any dark energy.
But it does require this sort of like
bubble where the density of the universe is smaller in her neighborhood, but you can still do that
and be consistent with all of these observations. I know that sounds crazy. Oh, I see what you're saying.
You're saying like maybe it could be that all of our checks of the density of the universe out
there where somehow we just looked in the wrong places, kind of. Is that what you're saying?
Kind of. And I think probably people overestimate how much we've looked into the deep universe.
We really don't have that much data, so it's not that hard to tweak it a little bit and still
be consistent with the deep images of the distant universe because those are pretty rare.
But there are other ways that we could tell whether we were in a bubble.
There are other impacts this theory has on things that we can measure much more precisely
than just like actually looking and measuring the density.
This idea has consequences for other things that we have very sensitive probes for.
All right.
What are some of those ways?
Well, maybe the most powerful is the cosmic microwave background radiation.
Like we look at the structure of the universe now as you're saying how much density is
there, where are the galaxies?
But all that structure is seeded in little density fluctuations from the early universe, right?
The whole reason we have structure, the reason we have a galaxy here and not a galaxy there
is because in the early universe, there was a little spot that was a little denser and gravity
gathered stuff together to make galaxies, for example.
So we can predict how stuff should be distributed in the universe today based on those fluctuations
in the cosmic microwave background radiation, that light from the very early universe.
that life in the very early universe is very, very smooth, right?
It tells us that there should be no huge features.
It tells us exactly how big those density fluctuations should be.
And it lines up with what we see, right?
The stuff we see in the universe, both close and far away, has just about the right density
fluctuations, meaning like galaxies and clumps of galaxies and actually big voids between those
galaxies.
We have seen huge voids between clusters of galaxies, not as big as the one this requires, but
there are big voids out there in space and all that is perfectly described by the cosmic
microwave background radiation and a huge mega void that we're at the center of is not consistent
with what we see in the CMB there's no fluctuations in it that would give such an enormous feature
like you don't see other voids in the cosmic microwave background but would you see this void
this potential giant void we're in in the cosmic microwave background or does it tell you that
that there is an a void.
The cosmic microwave background tells you
that there should be no huge void.
And it does predict other voids.
It does predict that we should see big gaps
between galaxies.
And we see those and we measure those,
but it suggests that you should not get voids this big, right?
Basically, the size of the wiggles in the early universe
limits how big the features can be in our current universe, right?
You'd need huge wiggles in the CMB to make huge wiggles now.
We only see small wiggles in the early universe.
so we should only have small voids and small clumps now.
And that's basically what we see.
Wait, it tells you that it's impossible or does it tell you that it's rare for us to be in a huge void like that?
I think technically it tells you that it's very, very, very unlikely because the light we're seeing from the C&B is not the light from the plasma that was here that formed our structures.
It's the light from the plasma that was very far away and it's been traveling to us the whole history of the universe.
So we're not actually seeing the patterns that led to the formation of our structure.
We're seeing the patterns that led to the formation, a structure that's very far away now.
And so we can't actually see like the blueprints that led to our structure.
We can just see the blueprints that led to other structure.
And we see nothing like that anywhere else in the universe.
And so it'd be very unlikely for that to happen here if it's never happened anywhere else in the universe.
So that's sort of the argument.
All right.
So the CMB says, probably not.
Yeah.
And there's another argument which has to do with how elements are made.
The early universe was very, very dense, dense enough briefly to cause nuclear fusion to make protons and for some of those protons to make helium.
And the density of that really determines what elements were made.
We have a very good understanding of how that works.
And it lines up very, very well with what we see out there in the universe, how much helium and hydrogen and lithium there was made during the Big Bang.
This whole field is called Big Bang nucleosynthesis.
And so that's a very sensitive probe of the density of the early universe in our neighborhood.
And so if we got that wrong somehow, if the universe weirdly was underdense in our region,
you would see that in the amount of helium made in the Big Bang, and we don't.
And so that's pretty hard to reconcile with what we see.
Also, we've more recently measured a lot more type 1A supernova.
This idea of the big void was very popular like,
10 years ago when we had many fewer measurements of the supernova and there were some gaps
and so it was easier to sort of like fit this to the data.
But more recent measurements by the Sloan Digital Sky Survey, for example, make it much
harder to explain the red shifts using this sort of like weird void bubble thing.
Meaning we have better data about where things are out there.
Yeah, exactly.
We sort of filled in some gaps by taking more and more measurements of type 1A supernova and that
makes it harder and harder to even explain the red shifts.
using this void.
Meaning we're more confident that things are not denser out there?
Yeah.
Or we're just more confident about where things are.
We're more confident about where things are.
And that makes it harder to come up with a consistent picture of us being at the center of a void
as an alternative explanation for the red shifts that we're seeing.
But you know, there's lots remaining to be understood.
Like some of the voids that are out there in space, we don't understand how they formed
and how big they got.
And there's still the Hubble tension, like the expansion of the universe.
So it's not like the explanation we have is perfect.
There's lots of holes in it, lots of things that still don't work, lots of opportunities for other ideas.
But I think this void theory, as cool as it sounds, works less well than the current mainstream dark energy idea.
This idea that there's this mysterious, invisible energy that we can't explain either.
Exactly. It's still a lot of work left to do to make that even like a coherent theory, but it's sort of like our best current idea.
Well, I guess if it has so many counts against it, why are people even considering this?
Why do we just spend an hour talking about it?
I think people are still considering other ideas because the whole concept of dark energy does have flaws and it is a big idea and it's healthy to maintain different directions of research because we could run into a big problem.
You know, in sketching out the details of dark energy, we could discover a fundamental flaw in the whole plan so it doesn't hang together.
You know, it's like when you build the house and you discover, ooh, while the plumbing is just not going to fit with the electrical, like we've got to go back to the drawing board.
So it's important to keep your mind open and consider other ideas.
Plus, it's fun.
Right, other ideas for other people to try to figure out of the truth, right?
Yeah, exactly.
Just not you.
Yeah, maybe I should.
You're done.
Maybe I should just sit on the couch, eat chocolate, and let somebody else figure it out.
Right, but dark chocolate or white chocolate, any?
Which part of the universe are you in?
If our part of the universe is turning into white chocolate, then I'm thinking about moving.
It sounds like you already gave up on the whole.
whole universe, so now you're just giving up on the local universe.
Exactly.
All right, well, an interesting discussion about maybe the biggest mystery in the entire
universe.
What is dark energy?
What's causing the universe to expand faster and faster?
Is it just all a big illusion?
Or is there really some sort of mysterious energy out there?
Well, I think the theory of dark energy is on the right track.
It's really important to think about other ideas.
And it also helps us understand the strengths and the weaknesses of dark energy.
what we do and what we don't really know.
We hope you enjoyed that.
Thanks for joining us.
See you 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
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