Science Friday - Our Inevitable Cosmic Apocalypse
Episode Date: April 4, 2024When it comes to the eventual end of our universe, cosmologists have a few classic theories: the Big Crunch, where the universe reverses its expansion and contracts again, setting the stars themselves... on fire in the process. Or the Big Rip, where the universe expands forever—but in a fundamentally unstable way that tears matter itself apart. Or it might be heat death, in which matter and energy become equally distributed in a cold, eventless soup.These theories have continued to evolve as we gain new understandings from particle accelerators and astronomical observations. As our understanding of fundamental physics advances, new ideas about the ending are joining the list. Take vacuum decay, a theory that’s been around since the 1970s, but which gained new support when CERN confirmed detection of the Higgs Boson particle. The nice thing about vacuum decay, writes cosmologist Dr. Katie Mack in her book The End of Everything: (Astrophysically Speaking), is that it could happen at any time, and would be almost instantaneous—painless, efficient.The End Of Everything is our SciFri Book Club pick for April—you can join in on the community conversation and maybe even win a free book on our book club page. In this interview from 2020, Mack joins Ira to talk about the diversity of universe-ending theories, and how cosmologists like her think about the big questions, like where the universe started, how it might end, and what happens after it does.Also, Nobel Prize-winning psychologist Dr. Daniel Kahneman died this week at the age of 90. His work turned many traditional ideas about economics upside-down, arguing that people often make bad decisions that go against their own self-interest. It’s something he continued to study throughout his career, and that he wrote about in the 2022 book Noise: A Flaw in Human Judgment. At the end of this segment, we revisit an interview from 2022 with Kahneman in remembrance of his long career studying cognitive biases.Transcripts for each segment will be available after the show airs on sciencefriday.com. Subscribe to this podcast. Plus, to stay updated on all things science, sign up for Science Friday's newsletters.
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Okay, let's face facts here.
One of these days, the universe is going to end, not just the Earth, not even just our galaxy, but all of it.
Every star, every nebula.
I'm not fully comfortable with the idea that I'm going to die, and I'm certainly not comfortable with the idea that the whole universe is going to die.
But it seems like that's the way of things.
It's Thursday, April 4th, but every day is Science Friday.
I'm John Dankowski.
There are a lot of possibilities about how exactly that cosmic content.
catastrophe might happen. Coming up, we're going to talk with someone who's been thinking a lot
about the end of the universe. But first, let's remember someone who spent his career thinking
about how people make decisions. Psychologist Daniel Connman. He died last week at the age of 90. His
work turned many of the traditional ideas about economics upside down. He argued that people
often make bad decisions that go against their own self-interest. It's something he
continued to study throughout his career and he wrote about in a book called,
noise, a flaw in human judgment. He co-authored it back in 2022, and here he is talking with
Ira Flato about that book. Daniel Kahneman, welcome to Science Friday.
My pleasure. Nice to have you. All right, let's begin talking about this. The title of your book is
called Noise. What is noise, and how is it different from bias? Well, the starting point really is
that judgment is a form of measurement. We call it a measurement where the instrument
in the human mind.
And so the theory and the concepts of measurement are relevant.
Bias in the theory of measurement
is simply an average error that is not zero.
That's bias.
Noise in the theory of measurement is simply variability
so that, you know, you could measure a line
and measure it repeatedly.
You're not going to get, if your ruler is fine enough,
you are not going to get the same measurement
twice in a row.
There's going to be variability.
That variability is noise.
And you can see that noise is a problem for accuracy,
because assume that there is no bias.
That is that the average of your measurements is precisely equal to the length of the line.
It's still, obviously, you're making mistakes
if your judgments or your measurements are scattered around the value.
So that's noise and that's bias.
So why do people make those mistakes? Why do we have people measuring things and then coming up with different results?
Well, there are several reasons. One reason is that really people are inherently noisy so that, you know, when you sign your name twice in a row, it doesn't look exactly the same.
We cannot, in fact, exactly repeat ourselves. We're in a series of states and those states have an effect on the judge.
we make. We call that occasion noise. So, you know, a judge passing sentences is not the same
in the morning and in the afternoon. The judge is not the same when in a good mood and in a bad mood.
And then there are two other kinds of noise. To understand the next form of noise, the easiest is,
well, let's stay with a judge. So some judges are more severe than others. Some judges are lenient.
We call that level noise because the level of their judgment, there is an individual bias.
But then the most interesting source of noise is that judges do not see the world in the same way.
That is, if they had to rank defendants or crimes, they would not rank them alike.
Some judges are really more severe with young defendants than with old defendants.
for other judges, it's the opposite.
Those differences, which we call pattern noise,
they're really interesting,
and they are in quite a few situations.
They are the main source of noise.
Is that because that's where biases may influence the noise
because people have different biases that makes it noisy?
That's exactly it.
Noise is really produced by the fact that is certainly pattern noise,
that people have different biases.
One last question. I've been following your career for a long time, and I've always wondered what got you and your long time former psychologist partner, the late Amos Tversky, so interested in human biases and studying. Where did you, you fellows, decide this was something you wanted to study?
Well, it was really ironic research. We found that we were prone to mistakes. It was all about statistical.
thinking when we started. And we noticed that we had wrong intuitions about many statistical problems.
We knew the solutions, and yet the wrong intuitions remained attractive.
Can you put a finger on why we have so many flaws in our intuitive judgment?
So it's not that we could perform surgery and excise all the sources of biases from human
cognition. If you removed all the sources of biases, you would remove a great deal of what makes
cognition accurate in most situations. So we are built to reach conclusions, not necessarily in a
logical way, but in a heuristic way. And heuristic ways of thinking always necessarily lead to some
mistake, although on average they could lead to correct judgment and faster than reason would do.
That's the esteemed Nobel laureate Daniel Connman, talking with Ira Flato back in 2022.
He died last week at the age of 90. Dr. Katie Mac's book, The End of Everything, astrophysically speaking,
is about just that. It's about how our universe might meet its end. It's the SciFry Book Club
pick for April. And if you don't know much about the book club, you can find out more at
Science Friday.com slash book club. Now, back in 2020, when this book came out, Ira sat down to talk
with Dr. Mac. So let's listen in. Dr. Mac is a cosmologist and assistant professor of physics at North
Carolina State University in Raleigh. Welcome, Dr. Mack. Hello. Thanks. Thanks. Thanks for having me.
So tell me, I've got to say this, this is an awfully cheerful book about the end of the universe.
Is that how you feel?
I think I'm just excited about big things happening in the universe, and I guess I have some professional
remove from the idea of everything really ending, although there are some points in the book where I do
sort of wrestle with that idea that, you know, we will have no legacy in the cosmos ultimately,
and that is a scary idea. But it's fun to think about these big, powerful, destructive forces.
Does that bother you that we're not going to have any legacy? I mean, do you think about that as a
scientist? I do think about it sometimes. And sometimes I think, you know, that's fine. We're just doing our
thing. And someday that'll be over and that's how it should be. And other days, it's a little bit unsettling.
I mean, I'm not fully comfortable with the idea that I'm going to die. And I'm certainly not
comfortable with the idea that the whole universe is going to die. But it seems like that's the way of
things. Give us a short tour of what could possibly go wrong to end our universe. Well, there are several
possibilities based on different ways that we look at the data and how we extrapolate
what's happening now in the universe into the future. So in the book, I talk about the big crunch,
which is this idea that the expansion of the universe that's currently happening now could
reverse and everything could kind of come crashing back together. That's probably not how it's
going to happen, but that's an idea that's been kicked around for decades as one of the possibilities.
Let me stop you there and tell us why that's probably, use a scientist to know or feel it's probably
not going to happen that way. Well, when we look at the expansion of the universe,
one of the things that we can observe about it now is that the expansion of the universe is speeding up.
That means that the distant galaxies that are moving away from us are moving away from us faster and faster all the time.
And that suggests that there's something in the cosmos that's accelerating the expansion of the universe.
We don't know what that is. We call it dark energy.
But in the presence of dark energy, it's hard to imagine that accelerated expansion stopping and turning around and everything coming back.
Now, we don't know for sure because we don't understand dark energy.
But based on what we do know about it, it looks like it's probably something that's just going to keep going the way it's going, and the universe will continue to expand forever.
Okay, let's go to option door number two.
Well, that's the heat death.
This is what we think is probably the most likely based on how we see the universe evolving now.
Again, this is just the universe keeps expanding forever.
And the end result of that is that everything gets more and more isolated.
So galaxies get farther apart from each other.
everything gets more and more sort of contained in its own little space. It's harder for things to
interact with each other over these increasing distances. And so over time, the universe just gets
more and more diffuse, darker, colder. There are no new stars forming after a while and
particles decay and everything kind of fades and decays away. And ultimately, you're left with basically
just the waste heat of the cosmos. Okay, let's go to option number three. Well, this is a
dramatic one. This is called the big rip. And this is based on the idea that maybe dark energy
is not what we currently think it is. So our best guess about dark energy right now is that it's
something called a cosmological constant. Basically, just a property of the cosmos that space time
has this sort of expansion built into it. And so if you have some space, it'll have a tendency to expand.
We think that that's probably what the dark energy is. We're not entirely certain. If it's something else,
If it's something that isn't just a property of space,
but some kind of field in the universe that changes over time,
it could be something that gets more powerful over time.
And if that's true, then it could actually,
instead of just moving galaxies away from each other,
it could start pulling galaxies apart
and pulling stars away from the planets,
then pulling apart planets and stars themselves,
and eventually ripping apart atoms
and sort of tearing space itself asunder.
Very interesting.
I love talking about dark energy, dark matter,
I mean, we talk about we don't know what 96% of the universe is made out of, right?
Dark energy and dark matter.
So then how can we make predictions about anything if we don't know what most of the universe is made at?
Well, we don't know what it is, but we know a lot about how it acts.
For dark energy, it's whatever it is, it's something that's making the universe expand faster.
And we can see the expansion of the universe.
We can see how galaxies are moving apart from each other.
And because we can see into the past in the universe, by looking at very distant things,
We're looking at things as they were billions of years ago.
We can see how that expansion has changed over time.
And so we can deduce what dark energy is doing to our universe from those observations.
We can survey galaxies all over the universe and see how they're moving and how they're relating to each other.
With dark matter, dark matter is a very different phenomenon.
Dark matter is some kind of invisible matter.
So something that has gravity, it has mass.
But we can't see it.
And it seems to be the stuff that's holding galaxies together.
It's sort of this extra gravity where there are clumps of this invisible matter and galaxies and clusters
of galaxies and so on are embedded in these clumps of this invisible dark matter.
Now, we don't know what dark matter is made of, but we can map it out.
We can figure out what it's doing and where it is by how it affects the regular matter,
the stars and the galaxies that we do see in the universe.
So we might see stars at the edges of galaxies moving around faster than we would expect.
and we can say, oh, that must mean there's extra gravity holding them in.
We know a lot about where it is and how it acts.
We just don't know what it's made of.
Now, we have an option number four that we, is sort of a relatively newcomer, is it not?
Yeah, yeah.
So my personal favorite cosmic apocalypse is called vacuum decay.
It's sort of been around since maybe the 70s or 80s,
but it's gained a lot of prominence recently because as we've learned more about particle
physics, and as we've done things like Discover the Higgs boson, which is this particle associated
with the Higgs field, a kind of energy field that pervades all of space, it's allowed us to
understand our model of particle physics a little better, and what we've found is that it looks
like maybe particle physics or maybe the physics that governs the universe isn't quite as stable
as we thought. What we're predicting now is that the way that physics works in our universe is
not really the only option. And the Higgs field, which is this energy field, it can have different
properties and it can change. And so there's a possibility that somewhere in the universe, there will be
a quantum event that changes the Higgs field in that point, in some single spot in the universe.
And that would create a bubble of a different kind of space where physics works differently
inside that space. And that bubble would expand outward at about the speed of light and just destroy
everything in the universe. And it would be an unpredictable event. We wouldn't
know when or where it would happen, but it would be a totally inescapable bubble of doom.
Now, there are reasons that we're not convinced that that's definitely going to happen, because,
first of all, it depends on the idea that we really understand all of particle physics, and we're
not quite that arrogant. We know that there are pieces missing to our puzzle, and so it may be that
something will come up that'll prove that vacuum decay can't happen, but the current equations kind
of point that way, which is a very interesting consequence of the calculates.
people have been doing recently.
If there's a bubble that bubbles up
inside our universe, could there be a bubble
that bubbles up outside our universe
too and have another universe?
Well, you know, outside of our
observable universe, the region of
space that we can actually see with telescopes
and so on, we have no idea what's going on
out there. There could be vacuum decay happening
there. There could be new universes popping
up out of the larger space we're embedded in.
There could have been many
universes being created around the same time
as ours or popping out of some
larger space. There's a lot that could happen beyond the realm of our observable universe,
which is this volume about 46 billion light years across that we can actually get any information
from. So what we visibly can see is not what might be out there. There might be a lot of other
stuff out there that is beyond our horizon. Yeah, yeah. And our horizon is defined by how far away
something can be where the light from that thing can have reached us by.
now in the age of the universe. So if there was a galaxy 46 billion light years away and the light
left that galaxy at the moment of the creation of the universe, it would only just be reaching us
now. So that defines the distance we can see because anything farther away from that, there just
hasn't been enough time for the light to reach us. It turns out that because the universe is
expanding faster and faster, we're actually never going to be able to see things that are beyond
that point because they're being carried away from us faster than light can travel by the
expansion of the universe. So there's this real hard edge to what we can see. There's a lot of
interesting mysteries around what might be beyond our horizon. Now, I know as a theorist, you're not
just inventing these ideas out of thin air. My question is, where does the data come from? That's most
useful and important to you. Well, there are a lot of different things we can study. We can look at
how galaxies are moving through the cosmos. During the expansion of the universe, we can see
galaxies moving apart. We can look at very distant galaxies and see how they're different from
galaxies that are nearby and that tells us something about how the cosmos has been changing
over time. And we can look at actually the background light from the Big Bang itself. One of the
most important pieces of data we have about the early universe, about the evolution of the universe,
comes from the fact that we can see the afterglow of the Big Bang. So if we look at a galaxy
that's five billion light years away, you know, we're looking back billions and billions of years,
if we look farther away than that, if we look as far out as we can see, we can see the universe as it was at the very beginning.
Because it took 13.8 billion years for the light to get to us from that point, we can see it as it was in the very, very early stages of the cosmos.
And what we see when we look as far as we can see is we see this glowing light, this light from a universe that is so young, it's just finishing up the Big Bang.
and it's still in that primordial fire stage.
So the early universe was hot and dense and sort of roiling with plasma,
and we can see that because we can look so far away
that we're looking so far back in time
that we see that hot, early young universe.
And that light has in it patterns of little blips of higher density here
and lower density over there,
and it tells us what the sort of seeds of the structure of the universe
looked like and how the universe went from being this kind of fiery,
roiling plasma state to this big, cool cosmos with galaxies and clusters of galaxies and so on in it.
That's cosmologist Katie Mack, talking to Ira in 2020 about her book, The End of Everything.
Astrophysically speaking, it's our sci-fri book club pick for April.
You can find out all you need to know about the book club, including upcoming events and how to win a free book on our site,
Science Friday.com slash book club.
Coming up on our next episode, we'll sit down with Umer Fon,
from Fox Media to talk about the big science news of the week.
Hope you can join us.
I'm John Dankosky, and we'll talk to you soon.
