StarTalk Radio - Physics & Philosophy with Sean Carroll
Episode Date: August 29, 2023Why is the past different from the future? Neil deGrasse Tyson and Chuck Nice explore the universe’s deepest questions like why is there anything, what is the present, and if there could be a unifie...d theory of physics with theoretical physicist Sean Carroll.For more information about the new book: https://startalkmedia.com/booksNOTE: StarTalk+ Patrons can listen to this entire episode commercial-free here: https://startalkmedia.com/show/physics-philosophy-with-sean-carroll/Thanks to our Patrons Nick hemmerich, Kelley Bard, Lou Casagrande, Nathaniel Johnston, Jesus Tamayo, and Leon for supporting us this week.Photo Credit: ESO/VVV, CC BY 4.0, via Wikimedia Commons Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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Sean, Chuck is about to blow a gasket.
No, because you're freaking me out, man!
You are freaking me out!
This is not anything that we bump into in our everyday lives.
If it doesn't make you a little bit uncomfortable,
you're not taking it seriously.
Welcome to StarTalk.
Your place in the universe where science and pop culture collide.
StarTalk begins right now.
I'm Neil deGrasse Tyson, your personal astrophysicist. And I'm Lindsay Nix-Walker,
senior producer of StarTalk. And Neil and I
just co-authored a brand new StarTalk book coming out September 12th. Yeah, this is the third in a
series of collaborations with National Geographic Books. And this one is titled To Infinity and
Beyond. And it's available for pre-order from the StarTalk website, startalkmedia.com slash books.
If you do pre-order the book, you have a special access to a conversation that I'll be having with Lindsay Walker.
She's been my senior producer for years.
She's behind the scenes in practically every StarTalk episode you've ever seen or heard.
I look forward to doing a live stream for our audience.
And they'd be able to submit questions in advance.
So we'll see you there.
We'll see you then.
StarTalkMedia.com slash books.
This is StarTalk.
Neil deGrasse Tyson here.
You're a personal astrophysicist.
I got with me my co-host, Jack.
Nice, Jack.
Hey, what's happening?
All right.
Always good to have you there, man.
Especially when we have cosmic queries.
Fan favorite.
Oh, yeah.
Fan favorite.
We love them.
You get to ask a question with sort of entry-level participation in our Patreon program, just $5 a month.
That's it.
And we collected them.
And you know in advance what you're asking about
because today's topics involve physics and philosophy.
Oh.
People love just talking about stuff
for which there is no answer.
Well, of course, you know why?
Because it makes them feel like they have a stake and a say.
And a say, because nobody has the answer.
Yeah, nobody has the answer.
So I'm just as right as you are, right?
Like, no, you're not.
You're still an idiot, okay?
See, I have a PhD in philosophy and physics.
I have what's called an informed opinion.
You, on the other hand, went on the internet,
saw somebody on Joe Rogan's show say something about something else,
and now you think you're an expert.
Shut up. Shut up.
All right, sorry.
Okay, that's the end of our show.
Well, we're bringing into this an old friend and colleague,
Sean Carroll.
Sean, welcome to StarTalk.
Hey, thanks for having me on, Neil.
Welcome back to StarTalk, I should say.
You've been on at least four or five times.
You are one of the world's experts on not only physics, being a physicist,
but you're also that subcategory of physicist who cares about philosophy
and have engaged philosophers on the frontier of our understanding of physics.
So it's great to have you for this Cosmic Queries. And dare I say, we crafted this Cosmic Queries
around your expertise. So you are the Homewood Professor of Natural Philosophy at the Johns
Hopkins University right there in Baltimore. And you have a joint appointment at the Santa Fe
Institute.
Now that institute,
everything I know about it,
those are deep thinkers about things that it's like,
what?
Like you twist your head
like a dog hearing a high pitch.
It's like, what?
And you're the fractal faculty
at the Santa Fe Institute.
And your expertise in quantum physics,
space-time, cosmology.
Love it.
Emergence, entropy, dark matter, dark energy, symmetry, origins of the universe.
And perhaps most people who know you know you through your Mindscape podcast.
So always good stuff happening there.
Those things that make you tilt your head and scrunch up your eyes,
like that's my lane. That's what I do. That's you. Okay. So I say this lovingly and crazily, stay in your lane. Okay. So tell me what is, first, natural philosophy. I last saw that term with 17th, 18th century philosophers.
Natural philosophy was the then term
for what today we would call physics,
because political philosophy and religious philosophy.
Natural philosophy was physics.
So why isn't that just physics, Professor?
There's a joke in philosophy circles
that once an area of philosophy starts making progress,
it gets spun off to a completely different field.
So it never looks like philosophy actually makes progress.
But you're right.
Newton, Galileo, those folks would have called themselves philosophers.
The idea of a physicist hadn't been invented yet.
But what happens is that academia loves to categorize and silo people.
So they invent a physics department
and a philosophy department,
and they examine what questions you could ask,
and they decide which is which.
But what that does is that it means
that all the in-between stuff,
because it's really a continuum here, not a...
The interstitial ideas and things.
Yeah, those just get lost.
And we're at a point in physics right now
where questions like, you know, what is
an observer? What is infinity?
Why is the past different from the future?
What is emergence? Like, these are physics
questions. What makes this night
different from all other nights?
Sorry.
Is that a song lyric?
Is that?
All right.
So you are there to clean up the pieces, is what you're saying.
Well, I'm actually there to understand the universe.
I think that the common thing within natural philosophy is
we're not studying the process of science or anything like that.
We're studying nature.
We're studying reality.
But there's a way of doing it that is kind of foundational,
that takes a step back.
Look, physicists, bless their hearts. You've met
physicists, Neil. I know this.
And ask them
about... By the way, Chuck, anytime
someone prefaces something by bless their heart,
you're about to insult them.
Nothing good
ever.
It's in the same sentence as bless their heart. Especially if you're an old white lady from the south. You know, it's just like... It's in the same sentence as bless their heart.
Especially if you're an old white lady from the South.
You know what I mean?
It's like, oh, bless her heart.
She's just a little whore.
That's all.
Seriously, that's how it goes.
Okay.
I started the book by saying,
you do not need a PhD in theoretical physics
to be afraid of quantum mechanics,
but it doesn't hurt.
And physicists don't want
to dig into the deep questions about quantum
mechanics. They want to calculate their
differential equations. They shut up and calculate.
They shut up and calculate
and that's the opposite of what I like to do
myself. So the philosophers humor
me on that. So just to make
sure all our audience is on the same
page, quantum mechanics
is amazingly successful at predicting and describing reality. But that reality defies
all our common sense. And you reach a point where you just say, okay, I'll just live with that
and continue to calculate.
And Sean, you're telling me
you're not satisfied with that.
You want to understand crazy quantum phenomena
on some level where we can sit down and say,
okay, now I understand it.
Is that what's driving you?
Yeah, absolutely.
Just like it drove professors Einstein and Schrodinger
back in the day, but there was this consensus that developed in the 1920s and 30s by physicists where, like you say, we have some equations, we can solve them, we can calculate them, we can make predictions and beautiful, exquisite agreement between the calculations and the predictions without knowing what's going on, without preying on what's actually happening in the world.
And there's a whole bunch of physicists who will say,
oh no, understanding what is actually happening in the world,
that's not my job.
I'm just here to make predictions.
I strongly feel that's not right.
I'm here to help understand what is going on in the world.
Right, so you're the show your work part of this whole equation.
Explain your work. Show it, play it, hide anything. No in the world. Right. So you're the show your work part of this whole equation. Explain your work.
Show it, play it, hide anything.
No sweeping the rug.
Yeah.
It's okay to come up with the answers,
but we got to know how we got there.
Absolutely.
Yeah.
So Sean, what's been in all the buzz in recent years
is quantum entanglement.
All right.
And let me offer my best explanation and you correct it.
And then, but then give me your understanding of it, all right?
You can create two particles simultaneously
that have sort of complementary properties,
quantum properties to them,
and they can separate and they know about each other.
There I use the word know.
They know about each other's existence
and the moment you make a measurement of one of them,
the other particles' properties manifest to whoever is observing them.
And they manifest instantly, transcending the speed of light.
And so we know that happens.
But Sean, you're going to tell me that you understand it, or will you not?
Well, I think that we have multiple competing ways to understand it.
We have not agreed on the correct way.
My way is...
Like I said, Chuck, in the bar, you just have the beer and nobody agrees, right?
That's the difference.
But like you said, we can make the prediction to exquisite accuracy.
People tested the prediction.
They won the Nobel Prize for it last year.
That was what the Physics Nobel Prize was given for.
And by the way, the whole reason we know and care about entanglement was because Einstein in 1935 was trying very hard to figure out what really is going on, right?
And he didn't quite succeed.
He didn't get the answer there, but it's
that drive to understand that led here. And ultimately, what we can say, I think, with some
confidence is that what the world is, is not a bunch of separate particles doing their own thing.
It looks like a bunch of separate particles under certain very clear circumstances, but in other
circumstances like this entanglement business, it doesn't.
It's more holistic than that.
So people like me, who are advocates of the many worlds interpretation of quantum mechanics,
we have a very simple, straightforward way of talking about entanglement.
But there's other people out there who talk about it differently.
And, you know, that's great.
That's what academia and intellectual
curiosity is all about remind us of the many worlds hypothesis because i think that's now
100 years old right we're we're in the centennial decade of the major discoveries of quantum physics
the 1920s so if you can just remind us what the many worlds i think it was once explained to me
and i said what what are you smoking?
Sure, that's what I said.
When we teach undergraduates quantum mechanics, we say that a quantum system has two different ways of evolving.
There's one way it can evolve when you're not looking at it.
And that's what Schrodinger and Heisenberg and their friends figured out back in the day.
But just to be clear, just to be precise, I know how you're using the word evolved,
but to a biologist, the word evolved means something completely different.
So you mean it unfolds, the events unfold.
Yeah, it changes, it has its dynamics, whatever it's doing,
whatever its behavior is.
But then there's a whole other way that we need to describe that behavior
when we make a measurement, when we observe the system.
Famously in quantum mechanics,
you can't predict
deterministically precisely with 100%
confidence what answer you're going
to get. You can predict a probability
distribution over different possible
answers. And Einstein said
God does not play dice.
That's what Einstein said, yes. With the universe.
It kind of looks like you are playing dice.
I'm just saying.
And by the way, what a presumptuous statement on Einstein's behalf.
I mean, who knows?
Sean, didn't Niels Bohr say, Einstein, stop telling God what to do?
I mean, who's to say that God's not down on one knee going,
Papa needs a new pair of shoes.
You don't know that.
You don't know that.
So was it Neal's War?
Somebody said it to Einstein.
Who was it?
I think it was Neal's War.
I think the better advice would be, like, don't play dice against God.
You're not going to win if that's, you know.
Okay.
There you go.
That makes sense.
So what is this going on with this weird thing?
You don't expect measurements, observations,
looking at things to be part of the fundamental nature of reality, right?
It never was before quantum mechanics came along.
So you can ask yourself, what if all of that was unnecessary?
This whole idea that we need a separate rule
for what happens when we measure something.
What if you just erase that from the rules of quantum mechanics?
And the answer is that what you find is that every possible measurement outcome comes true,
but in a different world, in a different part of the overall quantum universe,
you get parallel worlds where different measurement outcomes are true.
That's when I asked what the guy was smoking. Wow.
Now, wait a minute. So, these different worlds are in the same
realm? Is that the case?
Or are we talking about completely
different
unfoldings that create completely
different scenarios that
make the whole thing work?
Or another way to ask that,
do you have access to these other worlds?
There you go.
Thank you.
If you have an iPhone,
you can download an app called Universe Splitter.
And if you're ever stuck on what decision to make,
you know, should I have a hamburger?
Should I have pizza for dinner tonight or whatever?
Ask the Universe Splitter
and it will come back with an answer.
And you can be guaranteed
that there's a whole nother universe
which you can never interact with or talk to in which you do the opposite thing so there's
it's split in that instant right in that instant yes at the decision instant okay okay it's a
physical quantum process but and that's because of the entanglement because they couldn't exist simultaneously. They have to exist in those
positions at the time of the decision so that when one does it, the other does the opposite,
or when one does something, so there's an action and there's a reaction, but there can't be action,
action. It has to be so that they're existing and then reacting differently.
Is that...
Sean, Chuck is about to blow a gasket.
No, because you're freaking me out, man.
You are freaking me out.
This is not anything that we bump into in our everyday lives.
If it doesn't make you a little bit uncomfortable, you're not taking it seriously.
Okay.
All right.
Wow.
Hey,
I'm Roy Hill Percival,
and I support StarTalk on Patreon.
Bringing the universe down to earth.
This is StarTalk with Neil deGrasse Tyson. show i really should have taken a gummy before this one dog going all right here we go again these are from our patreon supporters thank you all for what you do for us all right chuck you
got your your ipad there all right i do so here we go this is from sai uh says hello dr tyson dr It says, hello, Dr. Tyson, Dr. Carol, Dr. Haha. First time Patreon member.
I know, right?
First time Patreon member here.
Huge, huge fan.
I am Sai Anurag Lakharju from India.
Chuck, if you get my name right, I swear to God, I will double my Patreon membership.
Yeah, well, I guess you're in no danger there, are you?
Yeah, I think he's going to have it after what you just did to his name.
But all right.
That was funny.
My question pertains to Dr. Carroll's research, which says that the universe is infinitely old and Big Bang is just one of many events
resulting from quantum fluctuations
of a vacuum energy in a cold,
desitter space.
Please throw some light on
what kind of space is this?
How can I visualize it better
in order to understand it more
fully?
Good, very good. I love it, you know,
hanging out on the wrong street corners.
I don't know where they pick these
things up. But yes, this is all driven by
the very famous philosophy question, why
is the past different from the future?
Why is there an arrow of time? Because the fundamental laws of physics have no arrow of time in them. The answer is entropy and the second law of thermodynamics. The universe used to be more organized, lower in entropy. The whole history of the universe is just entropy increasing, disorder and chaos developing all around.
We're all going to die.
It's not your fault necessarily,
but you're contributing to the disorder and chaos all around us.
And that started about 14 billion years ago near the Big Bang.
At the moment of the beginning of the universe,
our universe was exquisitely orderly.
It doesn't necessarily look that way,
but you run through the numbers and it's true.
Why? Why is that true? Why was the early universe so orderly. It doesn't necessarily look that way, but you run through the numbers and it's true. Why? Why is that true? Why was the early universe so orderly? And so I've long wondered about this,
and I wrote a paper years ago now with a woman who was a graduate student of mine at the time, Jennifer Chen, where we proposed that the Big Bang was not the beginning of our universe.
Other people proposed that in different contexts,
but we made the case that you don't need
a fine-tuned, special, organized,
low-entropy beginning of the universe.
The universe can be eternal.
It can last forever.
But what happens is it empties out,
just like our universe is doing.
A universe can be completely empty.
The future of ours will be,
but it still won't be perfectly quiet.
There are still quantum fluctuations
that can lead to whole new universes
coming into existence.
And as that happens,
they all start in low entropy conditions
and the entropy grows
and gives that little part of the universe
an arrow of time.
And the fun part is,
the far, far past, the same thing
happens, but in the other direction.
So there's sort of a symmetric
shape to the universe, where the
future is a story of more and more
universes being created, and the arrow
of time pointing in that direction.
The past is a story of more and more
universes being created, with
people in them who think that we
are in their past.
I'm going to tell you right now.
If Cy understands what the hell you just said,
then they need to be the co-host of this show.
Because I am not going to lie. Wait sean wait sean so you lost me at the end i need i need you
to do the end again so sean what you're saying is there's some symmetric point among these universes where we're in one direction where entropy increases.
But in principle, there's a whole other realm
where entropy decreases.
From our point of view, from the people living in it,
they will always see entropy increasing
because we always define the past
as the direction in which entropy was lower. So it's a big U-shape that is perfectly symmetrical.
I get it now. So we're in their past because they're looking at us and seeing a decreasing
entropy, which is indicative of traveling backwards because we're moving towards a more ordered universe.
But we cannot be moving towards a more ordered universe
if we're moving into the future
because we are always moving towards entropy.
So if you are observing that,
then you are in my, I am in your past.
So, because you're looking at me going towards order.
Chuck gets it.
We're done.
Fuck yeah, man.
Fuck yeah.
Chuck gets it.
Oh, my God.
And it's insane.
Chuck, you're blowing out the volume level on the microphone.
That's insane.
Oh, my God.
Okay, wait.
So, Sean, before we get to the next question,
these are ideas.
Is there any way to experimentally verify any of this?
Well, we're trying, but the short answer is we don't know yet.
We don't have... That's not like a no.
Just say it.
No, it's very much not a no.
Oh, okay.
All the words, Neil.
All the words matter here.
Okay.
But this is a more, a broader idea, right?
There are plenty of tentative, preliminary scientific ideas,
which are too ill-formed yet.
I'm with you.
Predictions.
Einstein's gravitational waves.
Einstein's gravitational rings. Yeah, I'll give you that. We'll get there. Einstein's gravitational rings.
Yeah, I'll give you that.
We'll get there.
We will get there.
Send money.
We'll do it.
Just trust us.
In your lifetime?
My lifetime is getting shorter every year, so I don't know.
All right, Chuck, what else you got?
All right, let's go on to Doug Sherman.
Doug Sherman says, hi, Neil.
Hi, Sean. Hi, Sean.
Lord, nice.
This is Doug from Frisco, Texas.
All right.
All right.
Way to go, brother.
Doug says, I thoroughly enjoyed Sean's debate on God and cosmology against William Lane Craig.
Although, I'm still trying to get my head around everything Sean explained.
One amongst many arguments I found interesting was Sean's rebuttal against Mr. Craig's technological
argument that the finely tuned universe was evidence for the existence of God. I don't
recall the specifics, but I believe Sean stated that in some models, the finely tuned universe
approaches. Then he says, could Sean once again go through the perspective of the fine-tuned argument? I also reject the technological argument, but for more simplistic
reasons than my flawed brain can rationalize. So just for context, William Lane Craig is a
proponent of basically a God-created universe. And he's not the Bible-thumping person
in such a conversation as others might be.
He's trying to stay grounded in the natural world,
taking you to a precipice where you say,
okay, God must be there.
So I'm pretty sure Sean wouldn't debate
just anybody on that subject.
So William Lane Craig has some debating
respectability in that regard. Did I
characterize your opponent
accurately, would you say?
Yeah, that's fine.
But the fine-tuning argument for the existence
of God is what I
think is the best argument for
the existence of God. I also think
it's a terrible argument, but still
it's the best
of the ones that they have. So I'm glad when they refer to it. And the idea is that you look around
the world, the world in which we live, the universe we find ourselves in, and you say,
there are features of this universe that need to be the way they are in order for life to exist.
If they were different, life couldn't exist, but they easily
could have been different, right? The things like the amount of energy in empty space could have
been so large that it would rip planets apart before they ever formed. But we seem to have
gotten lucky. We seem to find ourselves in a universe that allows for our existence.
And so the argument is, I know why. It's because God did it, because God created a universe that allows for our existence. And so the argument is, I know why.
It's because God did it,
because God created a universe in which that's possible.
A very common counter argument is,
well, it also could just be a multiverse, right?
You're not in all the others to have this conversation, right?
So they help play an explanatory role
in accounting for why our universe looks so fine-tuned.
So two things going on here. One is the
proponents of this argument tend to
exaggerate the degree of fine-tuning
that they need, and that's what the
questioner is referring to. There's
certain things that Liam Lane Craig and
others say, oh, I just don't get it,
that's so fine-tuned, but you can raise
your hand and say, actually, physics has
completely explained that one now. We
don't need to go beyond the realm of physics to account for that.
But in other ways, it still looks fine-tuned. And my favorite rejoinder is actually,
this is a great argument for the non-existence of God. Because if God existed and God created
life,
God is not beholden to the local laws of physics.
God can create life however God wants to,
because he's God.
God can do anything.
You don't need the physical conditions to allow for the existence of life,
unless God does not exist.
All right, now let me just ask a question here
just to further clarify.
What if instead of needing the laws of physics,
the laws themselves are a reflection of what God has done?
So it's not necessarily that the laws are needed. It's that the laws exist
because they just happen to be a byproduct of the creation itself.
That is completely possible. And Neil will raise his hand here and say,
how do we observationally test that hypothesis?
Okay. Listen, I'm 100% on board with that. Okay, good. I just wanted to make sure that
that could be an argument to be had. That's all. But look, for the last 500 years, as science has
done more and more to explain why the universe is the way it is, the role for God as an explanatory
move has gone away, has diminished, right? And so you are left-
It continues to do so, yes.
And so you're left with, if you want to believe in God,
and there's plenty of very, very smart people who do,
they tend not to rely on God to account for the things that we observe in the natural world.
Gotcha.
Wow, fascinating stuff.
All right, Chuck, keep going.
We've only gone through two or three questions.
Let's see if we can speed it up.
We just have to have Sean back.
That's all. This stuff is too good.
We cannot rush through this.
This is too good.
At one point, get a double wide episode with him.
Yeah, absolutely.
All right, here we go.
Tom P. Knight says this.
Hello, I'm a Patreon supporter of both StarTalk and Mindscape.
Great to see Sean on the show.
Do voids in the cosmic web, like the Eridanus supervoid, violate the cosmological principle?
What could be the cause of these structures?
Thank you for your service.
Okay.
Good one.
Eridinus is a constellation.
I think it's a waterfall,
or it has something to do with water.
It'll put my memory serves.
But anyhow, Sean, what you got there?
This is a great question,
but there's a lot going on here.
I'm going to try to keep it brief here.
You know, there's something called
the cosmological principle
that says that if
you squint and look at the universe on very
large scales, everything looks the same
everywhere, right? The same number of galaxies
and whatever. It's a dopey
thing to call a principle because it's not
a principle. It's just a fact that you see
about the universe. It could easily have been otherwise.
Especially because it's not
exactly true and that's what the question is
getting at. There are places in the
universe where matter is very dense
there's places where it's very empty and
so forth the way that modern cosmologists
think about this question is to say the
early universe it was even smoother than
it is now it was very very smooth there
was only a difference in one part in a
hundred thousand as you went from place
to place number, why was it
not perfectly smooth? But number two, why
was it pretty darn smooth? And number
three, how did it evolve, using the word
evolve again, from that condition 100,000
years after the Big Bang to our
conditions now? The last one, how it
evolved, is the one we have the best
handle on. It was gravity doing the work.
Gravity turns up the contrast knob on the universe.
So if you have a slightly emptier region, it empties out.
If you have a slightly heavier region, it collects matter onto it.
And so we went from very faint ripples, if you look at the cosmic background radiation,
to these very vivid voids and galaxy clusters that we see today.
We still don't know where those first ripples came from.
Inflationary cosmology is a favorite thing to talk about,
but that's a whole other episode.
Wow.
There you go.
So I like the way you said that.
We observe these fluctuations in 100,000,
and you say, well, how come it's not perfectly smooth?
How come it's one part in 100,000?
How come it's not anywhere near that today?
That's a fun way to think about that problem.
Because it's easy to say, oh, here's the answer,
and then move on.
But wait a minute.
Why isn't it something else?
Yeah.
Right. And not enough of that goes on, I think.
Well, it's once again a reflection of the fact
that the early universe had low entropy
because gravity was so strong in the early universe.
A more common generic random configuration
would have been wild fluctuations
like black holes here and empty space there.
And so the fact that it was so smooth
does kind of demand an explanation,
and we're not sure what the explanation is.
Mm-hmm. Mm-hmm.
Okay.
All right.
Keep this going.
Chuck.
And that one was from the overlap of the Venn diagram
between Mindscape and StarTalk.
Love it.
Yeah. uh this is malcolm marfan and malcolm says hello dr tyson dr carol and chuck maybe okay um
okay i love these people man they love Chuck, no matter what they call you.
I know.
Well, Malcolm Marfan here, all the way from Trinidad and Tobago.
Oh, nice.
He says, Dr. Carroll, I came across your 2018 paper, Why Is There Something Rather Than Nothing?
And thought, wow, this guy's really dedicated to the lot of brain coward to the concept of nothing. Now, since you've clearly become an expert in nothingness,
can you shed some light on the various layers of nothing? Specifically, how do these layers of
void stand apart and how are they intertwined with the head-spinning realms of cosmology and
quantum mechanics? P.S. Can I get a philosophy or
physics degree with nothing
from, with nothing
for my thesis?
I think
our questioner missed the point of the
title of my paper, which is that there is
something, like, you know, we can contemplate
that there wouldn't have been anything and there's just
nothing. But what I say in the
paper is,
can we really contemplate that?
I mean, I think that we have this informal training
from our everyday lives, right?
Where we have boxes with things in them
and boxes with nothing in them.
And so we think that there's an option.
There can be things
or there could be nothings.
But when it comes to the universe,
it is not at all obvious that there is an alternative to the universe existing. What when it comes to the universe, it is not at all obvious that
there is an alternative to the universe
existing. What does it even mean for
nothing to exist? How does nothingness
even exist? I mean, that's kind of what
I'm getting at in the paper, which is
that it's not at all clear that the
reason why the universe exists is the
kind of thing that has an answer to a
why question. Maybe we
just have to accept it as a brute fact
and be lucky about it. So I do think this
stuff is fun to talk about, but I don't
think that it is nearly as down-to-earth
and simple and physical as certain
physicists who like to talk about this
make it out to be. It's fundamentally a philosophy question.
Wait, but Sean, if there were no quantum physics,
in principle, you could talk about space as having no particles
and none of these virtual particles that quantum physics forces into it.
You just say, remove the atoms and all known particles.
That's as pretty good a nothing as anyone would hope to describe, isn't it?
No, it's something.
It's space.
It has...
Because you have a word for it, okay?
You call the empty space space, and I call the empty space nothing.
Aren't we just semantically differing there,
not fundamentally differing?
Is empty space three-dimensional?
I don't know.
I don't know how you can mention that.
You just don't want to answer it because you know.
Okay, so let's say it's three-dimensional
and exists on a time continuum.
Sure.
So it has a property then.
It's not nothingness.
There's a way it could have been different.
Well, you invoke a way to measure stuff in it.
I wouldn't call that an inherent property
of the empty space.
It's different than four-dimensional
empty space. Okay, so how about this?
How about this? Okay.
Again, one of the
reasons why I don't like
arguing with philosophers, because ultimately
it comes down to how you're defining the words that you're
using in your sentence in so many
of those arguments. So, let
me just say, if we define
something versus nothing as something
is there's a thing there, and I take everything out so that as Chuck said, there's, as you said,
there is no thing, nothing there, then that's nothing. Okay, now you're saying there's a grid
system there that we can invoke or it's inherent. So that's a thing. Okay, so now I add
to my inventory of a thing
particles plus grid system.
Okay, fine. Then that's
there. So now we have to ask, can we take
away the grid? What I think is a more interesting
question is, do the laws of physics
apply in that
volume? And
therefore it can't be entirely
nothing because laws of physics apply even though
there's nothing there to manifest them. Ooh, now you're getting deep. So I like it because
you're invoking not what the system is, but counterfactual properties of what would happen
to the system if you changed it a little bit, which is fine. It's a fine thing to do.
Look, you're absolutely right that there is no pre-existing definition
of the word nothing to which we're referring here.
You could have different ideas.
I think that the deepest level of this question is,
why is there a universe at all versus complete non-existence,
not even space?
I mean, even you had to preface your question by saying,
imagine there was no quantum mechanics
and for that matter, secretly imagine there's no
general relativity either because...
Okay, yeah.
You're throwing away all of known physics to
even ask your question, but of course
within known physics, you can ask
plenty of questions about why
isn't space empty? Why
is space three-dimensional? Those are perfectly
good physics questions.
It's a little bit different than the question
of why there's a universe at all.
You can ask both of them separately.
It's not a right or wrong thing to ask.
Right, yeah.
All right.
Well, that's so cool.
What a great question.
Yeah.
Yeah, because when someone says,
why is there something rather than nothing,
and I look out in the universe,
which is mostly nothing,
I say, there's a lot of nothing in the
universe.
So,
whatever something we have that's
side by side with a lot of nothing,
until you start invoking other
definitions for what nothing can be.
So that's my only point there.
Well, there you have it, Malcolm. We have
discussed your question, and we have
achieved nothing.
Okay.
Okay.
Okay.
All right.
All right.
Keep it going.
This is Javier Ortega, who says,
Hi, you guys are just the best.
Greetings from my artificial limbs development lab in Panama.
Just a quick question that will not let me sleep.
To the speed of light,
we can only see the past
while looking into distances of the cosmos.
How do we know we are in the quote unquote real present?
We sense everything with delay, even short distances.
Also, there's a delay between
our senses and our brain. Are we sure that we perceive now as now? Maybe it's just something
relative to us, like movement. Maybe we are five hours in the past or 200 million light years in
the past, according to some other arbitrary timeline or other
alien beings that could
travel instantly to our place.
Everybody's been smoking before these days.
Let me tell you, man, I told you.
I told you.
He says, I hope you read
this message from the past.
Please keep looking up.
He makes an interesting point
that
what does the present
even mean if
everything we do to interact
with the world has some kind
of time delay?
I like that idea, the brain, our understanding,
our senses. That's true.
My
hand is not as it is, as it was
a billionth of a second ago.
So what does it even mean to talk about the present?
Yeah, there's a science answer here
and a philosophy answer here. I'll give you the science answer
because it's quite good.
Our brain does not perceive
the present. Our brain
puts together a picture of the world
that is on a slight time delay.
Like our brain wants
to be able to bleep out things it doesn't like. If you watch someone dribble a basketball and
they're right next to you, you will see the basketball hit the ground and you will hear
the thump of the basketball against the ground and they coincide, they go along with each other.
If that person walks away, still true. You see and hear the same thing at the same time, even
though the light gets to
you much quicker than the sound. And what
happens is if they keep walking away,
suddenly, they
will go out of sync. The
vision of the basketball hitting the ground
and the sound of it. Because... That happens suddenly.
So your brain was correcting
for it. Holy sh... Because your brain
corrects for it. As long as it's near enough, your brain was correcting for it. Holy shit. Because your brain corrects for it.
As long as it's near enough,
your brain says, this is all now.
And you can even measure how much it is.
It depends on what sense you're talking about
and what perception.
But roughly think about 40 or 50 milliseconds of time
is a little window in which your brain collects things
and says, I'm going to put this together
into a picture of the present.
A millisecond is a thousandth of a second.
So 40 to 50 thousandths of a second would be like five hundredths of a second.
There you go.
Good make.
Okay.
Excellent.
Yes.
Wait, so what you're saying is there's a point where the brain just gives up recreating the present
and said, I can't compensate for this.
It's too much.
It's too hard.
It's too much.
I can't do no more.
No, you do. Deal with it. Go's too much. It's too hard. It's too much. I can't do no more. No, you do.
Deal with it.
Go on without me.
Oh, God. It's just...
I can't take it.
So,
this is an experimental result,
Sean. You know, look, as
I'm sure you already know,
neuroscience, biology, psychology.
That's a whole frontier right there.
It's way harder than physics or astronomy.
Way harder, way harder.
Yeah.
Okay, I did not know this.
So interesting.
So the brain constructs a present
so that we can help make sense of the world
in our own moment that we make decisions.
It's actually doing that with everything all the time.
Your brain, because there's just too much input for your brain to actually process in real time.
So most of what it's doing is kind of creating a construct
and then painting a picture of what it is.
And then it looks for changes in that construct.
Wait, so Sean, this tells me that
if the brain can't complete the picture,
it'll make stuff up to fill out the picture.
Absolutely.
That's why there are so many black men in prison right now.
I was going to say optical illusions, but sure.
Yes, racial incarceration inequalities.
That's another one.
Yes.
This is the philosophy part of the answer,
which is that there is a real world out there.
I mean, there is objective physical reality,
but there's also the picture, the image,
the model of the world that our brain puts together.
And they're related, but they're not the same.
And our brain is doing a lot of work
to take all the many sense inputs that it has
and sew them together into coherent picture.
So cool.
Yeah, and a clever optical illusion
will hijack that ability.
Hacking the brain.
Make you think something that is not,
is very far from true as being true.
Right, but it doesn't quite true as being true. Right.
But it doesn't quite make sense.
Yeah.
Yeah.
All right.
We got time for one last question.
Chuck, what do you have?
Oh, my God.
This is over already?
I know.
Right?
Right.
Jeez.
We got to do this again.
This is fantastic.
I think he's got other stuff to do.
You know, he's working on books.
You know, the man writes books.
Okay.
What's this latest book you just wrote?
One right now during this episode.
Yeah, I'm almost done.
That's excellent.
Wait, you've got a book,
The Biggest Ideas in the Universe, Volume 1,
and you're working on Volume 2.
That's right.
This is a physics book where you got equations in there
and you are not apologetic about it.
No.
I mean, we don't assume that you know any math.
We teach you the math.
So I teach you calculus and what have you.
I love that.
Just in case you missed calculus, you know, in your school.
It's in the first couple of pages, right?
A couple chapters, but yes.
And then you move on and you learn tensors and differential geometry
and Einstein's equation for general relativity.
And this is for the public.
You just want to boost the public's math literacy a bit.
And their self-esteem.
I love the public.
I want them to feel like they can get this stuff into their heads.
It's not so hard, really.
I love what you said to us offline that when you were 16,
you wished someone had written a book like this for you to consume
at that time of your life.
Quantum mechanics and quantum field theory
and particles and symmetries and
gauge theory. Well, had you had such a book,
imagine how much smarter you would be.
We'd have figured this all
out by now.
One last quick question. This is Hamed Daoud who says this. Hi last quick question.
Okay.
This is
Hamed Daoud
who says this.
Hi, StarTalk.
This is Hamed
from Montreal, Canada.
My question,
are we still chasing
the dream of a unified
theory of physics
or is that
just a dead end?
Can it ever be achieved?
There you go.
Love it.
Yeah, I'm still chasing it
because there is the universe.
The universe is telling us what it does.
It's just up to us to figure it out.
So it might...
No, no, Sean, it's a philosophical bias
that you presume everything can be explained
under one field equation and everything derived.
Isn't that a bias?
Maybe the universe is fractured in this way
with multiple forces that can't talk to one another.
Yeah, that's completely fine.
I did not say it was just going to be one equation.
I was just about to say it might be a terrible mess.
We don't have any right to say that the final theory
of the whole universe will be simple or elegant
or easily understandable by us.
But we can shoot for it.
We can try and we can give it our best shot
and see what happens.
That's what we're trying to do.
Because we got bad history there in astronomy
where Kepler, he's a mathematician
and he knows that geometry is beautiful and perfect
and there's certain number of platonic solids.
There's like the cube and the
pyramid and the dodecahedron
and he thinks that relates
to the orbits of the planets and he
embeds one in the other. He is
philosophically driven with some
idea that the universe is
beautiful and perfect. And he spent
15 years wasting his time
until he threw it all away. No, planets just have
weird elliptical orbits.
And sure enough, that's the answer.
So we've been through this in my field, Sean.
I'm just telling you.
If it was as hard as Kepler, I'd be very, very happy.
All right, we got to call it quits there.
Sean, it's been a delight to see you again
and chat with you.
All right, we out of here.
Chuck, always good to have you, man.
Neil deGrasse Tyson here, your personal astrophysicist.
I'm bidding you to keep looking up.