Into the Impossible With Brian Keating - Did Stephen Wolfram Finally Prove the Second Law of Thermodynamics? (#388)
Episode Date: January 19, 2024Please join my mailing list here 👉 https://briankeating.com/list to win a meteorite 💥 Has the second law of thermodynamics finally been proven? The second law of thermodynamics has been shroud...ed in mystery for a century and a half. Now, after building on the recent breakthroughs in the foundations of physics, Stephen Wolfram has finally provided a resolution to the mystery. Stephen Wolfram is a computer scientist, physicist, and businessman. He is the founder and CEO of Wolfram Research and the creator of Mathematica, Wolfram Alpha, and Wolfram Language. Over the course of 4 decades, he has pioneered the development & application of computational thinking. He has been responsible for many discoveries, inventions & innovations in science, technology, and business. In this in-depth interview, he shares his findings, shines a light on some of the most misunderstood concepts in physics, and answers some of our most pressing questions about the nature of the second law, entropy, and the dark side of the universe. Tune in! Key Takeaways: 00:00:00 Intro 00:02:27 Judging a book by its cover 00:11:28 Proving the second law of thermodynamics 00:15:00 What is time? 00:18:20 What is temperature? 00:28:20 The role of the observer 00:43:08 What do we know about dark matter so far? 00:52:16 Black hole entropy 01:01:25 Classical mechanics vs. quantum mechanics 01:13:35 The consequences of dimension fluctuations in physics 01:21:55 Questions from the audience 01:32:55 Outro — Additional resources: 📢 Ownership of your health starts with AG1. Try AG1 and get a FREE 1-year supply of Vitamin D3K2 and 5 FREE AG1 Travel Packs with your first purchase 👉 https://drinkag1.com/impossible ➡️ Follow me on your favorite platforms: ✖️ Twitter: https://twitter.com/DrBrianKeating 🔔 YouTube: https://www.youtube.com/DrBrianKeating?sub_confirmation=1 📝 Join my mailing list: https://briankeating.com/mailing_list ✍️ Check out my blog: https://briankeating.com/blog.php 🎙️ Follow my podcast: https://briankeating.com/podcast Into the Impossible with Brian Keating is a podcast dedicated to all those who want to explore the universe within and beyond the known. Make sure to subscribe so you never miss an episode! Learn more about your ad choices. Visit megaphone.fm/adchoices
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I think I now finally am beginning to understand quantum mechanics.
Today on the Into the Impossible podcast, we welcome for the third time
the world-renowned computer scientist Dr. Stephen Wolffrom.
Stephen's been responsible for many breakthroughs in computer science,
including many inventions that you may even have on your phone right now.
He's been a pioneer in developing and applying computational thinking,
going as far as to develop his own programming language.
Computational reducibility says you can't cheat the passage of time.
Most recently, he claims to have some.
the mystery behind the most perplexing law of nature, the second law of thermodynamics.
And it's doing all the things that the second law of thermodynamics says you shouldn't be able to do.
Tune in and find out if you agree that Stevens unlocked the mysteries of the thermodynamic universe.
Today he's here to prove what many will have come before him have failed to do.
And along the way we'll go into a fascinating journey in the dark side of the universe,
a way that only Stephen Wolferman and I can take you.
So let's tune in.
Any sufficiently advanced technology is indistinguishable from magic.
Open the pod bay doors, Hal.
Welcome everybody to the third round of my conversational interdial aquiturization with this phenomenal
phenomenal guest today.
This is Stephen Wolffron.
As I say, third time guest on the podcast, Dr. Steve Wolfram, joining us from the East Coast.
How are you tonight, Stephen?
Just fine.
It's late for you.
for me. So it's even later for you. I really appreciate you staying up so late on the East Coast.
I'm a late worker. You're a night out. This is the middle of my day. You were on first time three years ago when I first started the podcast. And in the intervening three years since we've had our conversation, you have written many books. But the two books that have really piqued my interest and millions of people around the world are the books you wrote this year. And those are what is GPT doing? And we'll talk about that.
briefly and we'll talk primarily, I believe, about the second law and you're kind of paragon.
You know, I realized you said you want to talk about these books.
I went to my bookshelf and I realized this is my, that's, those are the books that I wrote
during the pandemic.
It's kind of a big pile.
It is.
No, it's very productive.
I'm impressed with myself.
I think, yeah, I think my audience will want to know, are you writing a book as we speak with
one of your hands?
It would not surprise me.
But Stephen, since you came on three years ago, I added a new segment on the podcast called Judging Books by their covers.
And so I'd like you to take either one of the books.
Let's start with the Chat GBT, GPT book maybe.
And I want you to explain the cover title, the design, and any of the artwork.
Yes.
So can you please explain what gave you the title and cover?
I wrote this little book because Chat Chaptee came out.
I know something about these kinds of things.
and lots of people asked, what is chat GPT doing, and why does it work?
So I decided to write a book with that title.
And actually, it was originally a blog post.
And then a chap, I know actually the person called Paul Graham, who's the founder of Y Combinator, sent me mail saying, you know, this was a really good blog post.
You should turn it into a book.
And I said, it's too small to be a book.
It's too short.
So you should turn into a book anyway.
So I told my publishing team, we're going to make a book in the next couple of weeks.
This was a book made very quickly.
It's about what it says.
You know, what is ChatGPT do?
Why does it work?
This kind of large-scale overview of how an AI system like this works, it was rather easy for me to write.
It took me a very short amount of time to write this.
But it's something which still, I believe it's really quite unique.
And a lot of people read it in both, particularly in the technology world, sort of the execs and the technology world widely read by those people.
It's kind of a, you know, it's kind of the high level overview of what chat GPT is doing.
And the question that I was really interested in is, why does it work?
And that's really a thing that I realized that it's really telling us a science fact.
It's telling us human language, which is sort of a pinnacle of our achievement, is in some sense not as complicated as we thought.
There are irregularities in human language which chat chbtee or the LLM, the large language model, discovered that we kind of should have known were there for the last couple of thousand years, but we didn't.
You know, we kind of knew that that language was made up in kind of sentences that went, you know, noun, verb, noun and so on.
But what chat, GPT and so on is showing us is something.
about the kind of the further structure, the kind of the way that you put together sentences
based on the kinds of combinations of words that can mean things.
And the cover in this particular case is a piece of the innards of chat GPT showing kind
of the flow of information through the neural net that is the, it's kind of a, it's this
a neural net is kind of like a giant mathematical function with, in the case of chat GBT,
of billions of parameters, and you feed in a piece of text that you've given so far,
and out comes its statement of what it thinks the next word should be in the piece of text
that you're generating.
Actually, it's kind of fun to see the, you know, we, the translations of this book into
different languages have lots of different covers, including some very wild, no doubt,
AI generated covers that I kind of wonder what the prompt was that led to those covers.
try to reverse engineer the prompt. Yeah, I'm always worried about, you know, they had mad cow disease back in the 90s.
And now that bots are training other bots, I'm kind of worried about mad bot disease. But maybe we'll get into that after you describe the second law book.
That really has captivated me. And I have a lot of questions, not only just from me, but for my audience is dying to ask you questions.
I've taken some on Twitter and from YouTube comments section. So explain what we're looking at there.
The second law. Right. So I mean, and, you know, what's, what?
But this cover has an interesting story.
Okay?
So it begins 51 years ago.
So I was a 12-year-old kid, and I'd got an interest in physics.
I'd originally been an interest in space, but that kind of segued into an interest in physics,
and I'd been starting to read physics books and so on, and I was graduating from English
elementary school, more or less.
That's the English system.
That's sort of an age 12 thing.
And I kind of the as a sort of pseudo graduation gift, I suppose,
that translated into modern American culture would be,
I'm going to get these books.
And there was a series of five books about physics,
the actually the Berkeley Physics course series,
the undergraduate physics textbook series.
And so I got these books and I was in June of 1972.
And I kind of in those days, I used to write my name and the date
when I got books and the books.
I stopped doing that at some point.
which was a shame.
But so I kind of know when I got these books.
So it turns out that book, well, the fifth book in that series was about statistical physics,
was about kind of the physics of systems that have so many components.
You have to use statistics to say how they work.
So, for example, molecules and a gas, things like this.
And the cover of that book, if I can hold up, that's the book cover that that, that,
that showed...
Was that Ketel and...
Was that a Ketel book?
Yes, that's...
That's...
The person who made that cover
was a chap called Bernie Alder.
And Fred Rife was the guy who wrote the book.
But it was kind of connected with Ketel and that whole crowd.
That book cover was kind of a...
Claim to be a simulation of kind of gas molecules in a box,
starting off in this kind of very...
On one side of the box,
kind of ordered on one side of the box, and then progressively with time becoming more
disordered and eventually kind of randomly filling the box.
And that was kind of a thing that was sort of a core feature of statistical physics, the
second law of thermodynamics, the law of entropy increase, and so on, illustrated on this book
cover.
I got really interested in this, partly because this was a case where the book was claiming
you could derive a law of physics from not just be told.
oh, relativity works, or quantum mechanics works, it was you can actually derive the
raw of physics from something that is more fundamental, just something essentially mathematical,
something formal, you could derive this law of physics, this law of entropy increase,
this idea that things tend to get more random over time.
I thought that was pretty interesting.
I didn't fully at that time at age 12 or whatever, I don't think I fully understood the math
that was in this book, and I didn't fully believe it, actually.
and I said, I'm going to simulate this thing that's on this book cover.
And at that time, I had access to a computer, very primitive computer by today's standards.
It was about the size of a large desk, and it was programmed with paper tape, things like this.
And I'm like, I'm going to simulate this thing and see whether I can get the same results as are on the book cover.
Well, I didn't succeed.
And, you know, as it turns out, years later, I realized the fact that I didn't succeed was actually showing me something
very interesting, but at the time, I kind of wasn't ready to understand that point.
Anyway, so the end result of that I was interested in the Second World of Thermodynamics.
Second World Thermodynamics has this funny history.
You know, it was kind of first mentioned in the 1820s, and then kind of really people started
talking a lot about it in the 1860s, and people said, well, you know, we're not even sure
molecules exist.
So the Second Law of Thermodynamics is about sort of randomization of molecules.
We don't even know molecules exist.
And so it was all very confused.
And by the beginning of the 1900s, when people realized molecules do exist, it was kind of like,
oh, and by the way, the second law was proved mathematically back in the past.
Well, it never had been.
And this led to many confusions over the years of people saying, you know, is the second
law really true?
Is it, you know, what is the cause of it?
How does it work?
We can talk about this more.
Folks, I have to be honest.
I'm disappointed in you.
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Guys are listening and watching, I know you're enjoying it.
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Stephen Wolfer. Or Stephen, how about this quote from your fellow countryman, Sir Arthur Eddington,
he said, in 1915, the year of Einstein's, you know, one of his miracle years, if your theory is
found to be against the second law of thermodynamics, I can give you no hope. There is nothing for it
to collapse in deepest humiliation. And yet, you're right. Nobody had proven it. I think by that point,
Right? I mean, that it was.
No, no.
The stuff I've done recently is the closer to we've got to kind of prove it
in the Second World of Thermodynamics and understanding what its real origins are.
Yes, I was never very impressed with Eddington, I have to say.
And that was not, you know, I'm aware of that quote.
I mean, you know, in fact, in this book, one part of the book is devoted to my efforts
to trace the history of the Second World of Thermodynamics, which I have to say,
I was very surprised nobody had written a definitive history of the Second World of Thermodynamics.
After I worked on it, I understood why they hadn't.
It's really complicated.
And you have to know a whole bunch of stuff about kind of the technical side of what's going on
to be able to untangle what's happening.
But, yeah, Eddington was a late stage person because really by the beginning of the 20th century,
people had sort of said, we know the second law is true.
Actually, I'll tell you a story about the second law and proving the second law.
So, you know, Einstein, you mentioned 1915, general relativity.
1905 was Einstein's kind of miracle year where he introduced.
he introduced photons, and he introduced kind of brown in motion that proved molecules existed
and relativity.
Okay, so big, big year.
Okay?
So I was studying the second law, and I was interested in who had worked on trying
to prove the second law.
Well, it turns out one name I didn't know was going to be on there is Albert Einstein.
So in 1902, 1903, 1904, he wrote three papers.
They were all on the second law, and they all purported to be essentially proofs of the
second law, and they were all wrong.
He had actually been working on the second law right up to the time when, and he never
worked on the second law again after 1905, but what was really interesting to me was the
kind of thinking that went into his attempts to prove the second law was this kind of philosophical
way of thinking about science, that he kind of got a little bit from Boltzmann.
Boltzmann had been the person who had been very much involved in kind of understanding
the idea of molecules, understanding the sort of foundations of the Second Law, and had had this
very philosophical approach to thinking about science.
And this kind of idea of thought experiments, the idea that you can figure things out just
by kind of logical reasoning was a very Boltzmann type idea, which Einstein picked up on,
and first of all, tried to apply it to the Second Law and failed.
It kind of had that strange history, but by the time of people like Eddington, it was like,
Yep, it's true.
You know, we're sure it's true.
You know, in textbooks, you know, when I was a kid,
by sort of nowadays, I would say one of my favorite things is some book that explains the second law.
One of the mysteries of the second law is that you can kind of prove this thing called Boltzman's H theorem
that says that, oh, the entropy will increase with time.
But you can take that same proof.
You can reverse it and you can say that also proves the entropy decreases with time.
And so there's a well-known textbook which ends its chapter on this saying,
this point is often puzzling to the student.
Well, it was puzzling to everybody else as well for about 100 years.
And we can kind of unravel how that really works.
I would like to go there.
I would like to also, though, I mean, I've had many great conversations,
including those with you.
But encoded in the second law is a notion of time.
And I wonder if we could start there.
in the kind of most primitive essence.
How do you conceptualize time or how can you define time?
What is time?
What is time?
And how does it emerge in Wolfram Physics?
I understand not only time, but space emerges.
So talk us through what is time?
So as far as I'm concerned, time is the inextual progress of computation.
If we think about things in the world as being governed by rules, then what happens in the
course of time is those rules get applied. And that's a process, the sort of what the thing that
changes through time is that we've applied these rules more and more and more times. And it's sort of
an interesting thing because one had imagined when one thinks about time in mathematics,
usually time is a parameter in an equation. You get some formula. It says, you know, the planet
will be at this position at this time. You can pick any value for that time. You just
dial in the time and you say what the answer is.
Well, that's kind of a view of time that came from sort of the mathematical way of thinking.
From a computational way of thinking, it's more you have these rules and then you run the rules
and you run them this step, this step, this step, and you see what happens.
And one of the important phenomena that I kind of first started identifying in the 1980s
is this phenomenon of computational irreducibility.
This question of when the computations happen, you do this step, this step, this step,
Is there a way to jump ahead?
Is there a way to do what kind of mathematics says you can do
and just dial in the value of time and say,
this is what's going to happen,
or do you have to follow every step,
follow this sort of irreducible computation to see what's going to happen?
And the thing that was sort of a discovery of mine in the 1980s
is that it's very common to have systems which are computationally irreducible,
where the only way to work out what will happen in them
is just to run every step and see what happens.
And that's kind of the sense in which that process of running the steps, that is the passage of time.
And it's sort of an interesting thing that the computational irreducibility says you can't cheat the passage of time.
You can't jump ahead and say, I'm going to figure out by being a smarter computer, so to speak, what's going to happen, by being a smarter brain, whatever, I can figure out what's going to happen.
That doesn't work.
There's this sort of irreducible process you have to go through.
That's a limitation on science.
In a sense, for us feeling good about ourselves, it's a big positive because it means that
you have to live the time, so to speak.
There's no way to just say the answer to life, the universe, everything, whatever is 42 or
whatever, you have to actually live through it to get to the answer.
There's no kind of way to jump ahead.
It's a shortcut.
You cannot short cut.
Yeah, right.
It's an irreducible process.
So for me, kind of time is this computational process of the sort of progression of the universe
figuring, applying these rules to see what comes next, so to speak.
Can computation occur at zero temperature?
It has nothing to do with temperature.
I mean, temperature is an overlay far above that kind of issue.
So computation is just the following of rules that you specify.
they might be rules that you could specify for, you know, a line of black and white cells.
You can talk about temperature.
Let's talk about temperature for a minute.
There's a very different kind of thing.
So, you know, actually, it's a very interesting story because in the early 1800s, people knew about heat.
They knew heat flowed from hotter bodies to colder bodies and things like this.
And they said, what is heat?
They said, well, heat must be, you know, it must be like a fluid.
The only thing we know that flows is a fluid like water.
So they called it caloric.
Caloric fluid was what was the embodiment of heat
and flowed from sort of a hotter body to a colder body.
And temperature was a sort of characterization of amounts of,
was related to sort of this characterization of how much heat was there, there, more or less.
Well, so this theory of what heat was turned out to be completely wrong
because what is heat?
Heat is the randomized motion of molecules.
Heat is a feature of the microscopic structure of matter.
If matter wasn't made of molecules, there wouldn't be heat in the same sense.
And so the concept of temperature is a feature of a characterization of sort of the amount of randomness in these molecules.
It's really the, you know, it's just the average energy, the average energy of motion,
the average kinetic energy of molecules is just that's what defines temperature,
is this average kinetic energy of molecules.
That level of description of talking about molecules and moving around and so on,
the second law is vastly more general than that.
The second law is essentially a computational statement of the fact that systems that start
simple to describe will typically become complicated to describe.
It's kind of like encryption.
You're saying you start with that simple initial seed and then you run this thing and you
get something which for all practical purposes looks random.
That's what's happening in these systems.
It doesn't have to do with molecules running around.
It doesn't have to do with the specifics of temperature and so on.
It really is a very basic computational phenomenon
that actually is a consequence of this phenomenon of computational irreducibility.
I do want to say one thing about temperature and heat and so on,
which is something close perhaps to your interests.
So one of the questions is, actually I should say more about our theory,
but I want to make sure to come back to this question of caloric,
fluid because I'm going to give you an aphorism.
Okay.
My aphorism is dark matter is the caloric of our times.
And that it will be in the phlogiston and the phrenological approach.
The reason I want to say that I brought up temperature is because, as you know, in all
the Maxwell relations in the Gibbs, Helmholt's, you know, entropy, you always have
temperature and entropy interrelated.
They're coming in and derivative.
pairs. And so the reason that I'm sort of asking about that is because it would seem that,
you know, there is from from things like louder entropy and and so forth. There is a minimum amount
of heat as tangible to a human being, unlike entropy, which is abstract and mathematical. It doesn't
mean it's any less real. But I guess the question I have is, is you're saying computation is
fundamental and it may be more fundamental than even the Maxwell relations themselves, right? It may be
that the actual operations themselves, which don't have time in them, right?
There are these kind of abstract things, differentials.
But I always kind of feel like there's a little interlocutor saying, well, it's changing
with respect to time.
The differential is changed with respect to time.
So it's interesting to say that it's not necessary to consider temperature, even to have
computation.
Yeah.
No, temperature is a very derived concept that has to do with energy and so on.
The fundamental phenomenon of the second law has nothing to do with energy temperature,
those kinds of things. To talk about entropy, entropy is in a sense a lower level concept. So what is
entropy? Entropy is, you know a certain number of things about a system, a certain amount about a
system. Like you say, there are gas molecules and they're all in this box, and there are a billion of them.
And that's all you know. Then the question is, well, how many possible configurations of the system
could there be that are consistent with those constraints that we know? And it's a bit easier to figure
that out if you don't let the gas molecules
been in any position, but you just say as
Boltzmann actually originally did,
that it's sort of quantized and
that the gas molecules are just in some
grid of possible positions. You just
say, how many possible positions are they in?
Oh, it may be, you know, two to some
very big power. Okay?
So entropy is just the logarithm,
the power, the exponent
there of how many possible
configurations are consistent
with these constraints that you know
about the system. That's
that's the definition of entropy. In the original formulations of entropy, it was all kind of
complicated to understand because it involved continuous variables and you have to kind of
discreetize the continuous variables to figure out what's happening. It's just a mathematically
complicated thing. But this question about does entropy increase, which is sort of the core
second law of thermodynamics, the question is, if you are saying, I've got this way of
describing the system and I can describe it, I can sort of immediately say, oh,
I'm looking at this pattern of molecules, and I can immediately say every molecule is on an even-numbered
square, let's say.
That's a very sort of short description.
Now, if I let the system run, and it's this irreducible computation happens, the thing that
will happen is those molecules will be sort of computationally scrambled up.
And then we ask the question, when we look at them later, can we similarly sort of say very
easily what constraints they satisfy. And the answer will be no, in a sense, the configuration
of molecules was encrypted relative to how it started. And it's this phenomenon. So the second law
is really a story of the interplay between computational irreducibility of these underlying processes
and the fact that when we observe these systems, we are computationally bounded in what we can
notice about these systems. If we were computationally very sophisticated, we could just say about
these molecules. Well, I know, and by the way, one feature of molecular dynamics is it's reversible
in the sense that if you see a collision between two molecules, you're just seeing that collision,
it's like the billiard balls bounce, they bounce off. If you ran that movie in reverse,
it would be an equally valid movie of the billiaballs, you know, moving back the way they came
and so on. At the level of individual billiaballs, at level of individual molecules,
everything is reversible in that sense. And so you could say, well,
if I know exactly where all the molecules are, then I could just run this computation in reverse.
People have concentrated a lot on knowing where the molecules are.
It's also important to be able to compute what will actually happen
when these molecules sort of do their thing and have all their collisions and so on.
And the point is that to know sort of where the thing came from, you have to be able to do that computation.
But that computation is an irreducible computation.
And if we, as observers of the system, are bounded in the computations we can do, we don't get to be able to do that irreducible computation.
So we have to kind of just throw up our hands and say, what looks random to us.
And that's why we say it appears that the entropy increases, because we say we can't decode this sort of encryption.
We can't say, well, actually, it came from this very simple initial condition.
That's at the level of sort of how things with entropy work.
When it comes to dealing with energy, for example, in the case of molecular dynamics,
it's a sort of a separate overlay.
And essentially what you're saying is, well, it doesn't just these squares that are bouncing around.
We're also going to assign a number to every square, and we're going to say that the energy is conserved,
when there are interactions between these squares.
It's kind of a slightly higher level of kind of detail that isn't really part of the core point of the second law of thermodynamics.
But it turns out when you do that, you end up with this exponential distribution of energies
that where the scaling for that exponential is temperature,
and then you get the Maxwell distribution,
and you get all the various properties of statistical mechanics and so on.
And in fact, in the end, I mean, it's a bit technical and mathematical.
What confused people back in the day was, when I say back in the day,
I mean, back in the 1860s, 1870s, was before our time.
What confused people was there was sort of an elegant mathematical structure
that James Clerk Maxwell and other people noticed in connection
with all these different parameters that defined them in dynamics.
And some people like actually Josiah Willard Gibbs,
early American physicist at Yale, was, you know, his,
first big work in the 1870s was about kind of seeing what the consequences of kind of the mathematical
structure, the geometrical structure of the relations between all these things about temperature
and free energy and entropy and so on were. Those are things which have their own kind of life
that are very relevant for practical thermodynamics, practical chemical thermodynamics, things like
that. It's a separate thing from the foundational question of kind of how does, how do things
end up tending to get more random.
And that doesn't depend on that kind of overlay of energy and temperature and so on.
Yeah, no, it's more fundamental.
I guess the thing that, you know, is most striking to me and the question I have for you
now is, you know, could this have come, you know, in an alternate universe, could this book
have come 30 years ago?
In other words, were there things that you needed to discover through the Wolfram Physics
project, through things like the Ruliad, which I hope we're going to get into, and the
colonization thereof. But could this have been discovered, you know, could, could Hawking Beckenstein,
could Gibbs, if he were still alive, could Maxwell have discovered what you have proven in this book
in 2023? Or did it require the work of the Wolfram Physics Project in order to instantiate it
into the world? I was pretty close to this book back in the mid-1980s. When I figured out computational
irreducibility, I kind of knew that something like this was there. I didn't work out the details,
and there was one important piece that had to do with the role of the
observer and thinking about the observer as an important participant in the creation of physics,
so to speak.
And, you know, again, to kind of skip ahead a little bit, the thing that to me is, you know,
we have these three big theories of 20th century physics.
Statistical mechanics, second law of thermodynamics is sort of the big shining piece of that,
general relativity, and quantum mechanics.
And it's always seemed that, well, the second law is almost something you can just prove
from pure thought.
You know, general relativity, it's like, no, you know, general relativity is something you
kind of have to wheel in from the outside and say, well, the universe happens to work this way.
Quantum mechanics is the same thing.
The thing that has been truly remarkable and that's really emerged in the last couple of years
in the things I've been doing, we've been doing, is all three of those theories of 20th century
physics seem to be derivable.
And it's remarkable that laws of physics could be done.
derivable. You know, that was the thing that first got me really interested in statistical mechanics,
that there might be a fundamental fact about physics that was somehow derivable rather than merely
something you have to be told. That's kind of the story. And that, that idea that these things
might be derivable, that's all sort of come together. And that's been a thing that made this kind of,
this, this story of the second law much more poignant for me, much more something where I, where I thought
I could characterize because what happens is the characterization of the observer necessary to derive
the second law general relativity and quantum mechanics is the same characterization. And so that gives a,
that sort of gives more strength to saying, well, I'm going to pick an observer that works like this.
It's kind of like that that's a bigger pivot point for that. My audience is used to hearing
interpretations of quantum mechanics. But if I understand correctly, you're essentially saying
a classical theory like thermodynamics also needs interpretations and also needs to have a very
well-defined notion of what an observer is or is not. Absolutely. And what, you know, for example,
the fact that the molecules seem to become more random in their motions is something that if you
were an observer who could untangle all the details of how all the molecules work, you wouldn't
believe the second law. And actually, one of the things kind of interesting, there's this idea
of Maxwell's demon, a kind of little critter that is operating down at the level of molecule,
and it's opening and closing doors,
and it's doing all the things
that the Second Law of Thermodynamics
says you shouldn't be able to do,
being able to sort of untangle the randomness
and make a keyhole again.
Unweave the randomness, right.
And so one of the funny things is
that if you look at the physics journals these days,
pretty much every week,
somebody reports the creation of a Maxwell's demon.
And how can that be?
You know, we still believe in the Second Law, don't we?
Well, what's happening is,
these are things which are doing sensors
at the level of individual molecules,
and at the level of small numbers of molecules,
you can untangle the second law.
The second law isn't true for small numbers of molecules.
The second law is a feature of observers like us
who observe these molecules in a computationally bounded way
on a large scale and so on.
So the second law is also a story of the way that we are observing the universe
rather than just the way the universe is.
And again, the sort of the key phenomenon is this interplay,
between computational irreducibility underneath
and the computational boundedness
of us as observers of that system.
One of the things that, I would say,
sort of a wrong turn in science
that kind of started a couple thousand years ago,
is this idea that space is continuous,
that you can just put things anywhere you want in space.
This is sort of a foundational idea.
In Euclid, for example,
the very first postulate,
a common notion actually of Euclid,
is a point is that which has no part.
That's saying there are infinitesimal points.
You can have, there's no shortest distance in space.
Space is just a continuous thing.
Well, now you run forward in time.
You get to the end of the 19th century
and people were wondering,
people were discovering quantum mechanics, for example,
people were wondering whether molecules existed.
The sort of the big question
that had existed up to that time was,
is matter discrete or continuous?
That had been argued about since ancient Greek times,
and some people have been, you know,
some people said, oh, matter is continuous,
it's going over things like a fluid
that's just sort of continuously flowing.
Other people said it's made in molecules.
Well, that didn't get resolved
until the first decade of the 20th century.
Brownian motion was the thing that probably really,
really clinched that particular issue.
You could actually see under a microscope
little pollen grains being kicked around
by individual water molecules.
So that was kind of brown in motion showed matter was discrete.
Then your friend and mine, you know, Einstein in 1905 basically said, well, light is discrete as well.
It has photons.
And so then next thing was discrete.
So the next question was, is space discrete?
And actually, I've been finding more and more that at that time, for the first 20 years, 20, 30 years of the 20th century, the typical physicists believed space was discrete.
And I'm sorry to interrupt, but people nowadays make assertions that space is discretized, including our friend Elon Musk, that there is a fundamental physics attribute called the plank length, which obviously you can define it.
But there's nothing as fundamental about the plank length, as I understand it, as the discretization that you're going to explain to us, correct?
Yeah, I mean, the plank length is more a question of units.
It's a question of how you combine, you know, the different units that we use to measure.
you know, what do we mean by time? What do we mean by length relative to time? What do we mean by energy?
In the way that you are going to describe it. Right. Okay. Please continue. So, so I mean, you know,
back, I think 1916, for example, Einstein had a nice little quote that said, you know, in the end,
space will turn out to be discrete, but we don't have the tools we need to study that yet. So 100 years
later, we do. And so sort of the first thing that's sort of a foundation of our physics project,
from 2020 is this idea that space is in fact discrete and it's made of things,
just like matter is made of molecules.
Space is made of atoms of space.
Atoms of space, there's nothing, an atom of space is just a discrete element.
There is nothing to say about it other than that it has a certain identity, that it exists.
The other thing you can say is how it's related to other atoms of space.
So you can kind of represent that by this giant,
kind of friend network of the atoms of space, this giant network that says how the atoms of space
are related. And so then it turns out that when we talk about, you know, how does time operate on
this? Well, we've got this big network of all these atoms of space, and all we know is how they're
related to each other. And then what's happening is that there's a rule that gets applied that says,
if you have a little configuration of atoms of space
that corresponds to this collection of relations,
then it will be transformed to a collection of atoms of space
with this other collection of relation.
It's a sequence of transformations
between little clumps of atoms of space.
And that process, you run that process many, many, many times,
and it's a little bit like the process
of looking at water molecules.
You know, the water molecules are colliding,
and they're doing their thing.
And on a large scale, when you look at work,
water, it flows, you can pour it, it's continuous, it obeys the equations of fluid mechanics
and so on, but at a small scale, it's just a bunch of molecules bouncing around.
So you apply the same thing in the case of these graphs, hypergraphs, that are the relations
between the atoms of space, you do the same kind of thing that you do in fluid mechanics
saying, well, what's the large-scale behavior of such a system?
And instead of getting the equations of fluid mechanics, you get the equations of space-time.
You get the Einstein equations for space time as something which is derived as the large scale limit of the dynamics of these atoms of space.
There are a bunch of footnotes to that statement.
Among the things that gets complicated very quickly is this network that represents atoms of space, it's not in any particular number of dimensions.
It's not like we can say it's a three-dimensional thing.
It's not a substrate. It's not.
Well, it is, everything in the universe.
I mean, just like imagine that the whole world was made of water,
and all that we could do to make sort of persistent things like us
was have little eddies in the water that sort of persist through the water,
even though underneath there are a bunch of kind of molecules of water that are bouncing around.
For us, the kind of the concept of our models is there's nothing in the universe except space.
And the features of space are the things that we know.
notice. What might be an eddy in water would be an electron in the structure of space.
And actually, the one thing, we don't know how electrons work yet in our models. We do know
how black holes work in our models. And so we can make, you know, we can see how this black
hole exists in the structure of space time. And what you see is that space is very dynamic.
In order for space to be held together, so to speak, it's continually having to get sort of knitted
together by these rules that relate different atoms of space.
Black hole is this region of space that has this event horizon,
where, well, in the formal setup of our models,
it's a causal graph that has certain kinds of disconnection in it.
But anyway, you can set up these black holes.
And so, for example, we just made a few weeks ago a video
of two little tiny black holes and what happens in our models.
And it's pretty neat because you see kind of
Space is bubbling around.
These are very, very tiny black holes.
So they're black holes down at length scales comparable to the elementary length,
comparable to the discretization length for space.
So these two black holes, they're just there,
and they feel the force of gravity.
So they attract each other, and they come together and they merge,
and they produce little gravitational wave ripples.
And so far as we can tell,
it's a pretty accurate rendition of what General Altivity says should happen.
In fact, it's accurate enough that there are a bunch of groups,
that study the numerical versions of Einstein's equations that are sort of taking on this model
as far as they're concerned as a way to think about a discretization of the Einstein equations.
So in other words, for them, what we've done is we've made this discrete network thing,
which on a large scale is like the Einstein equations.
Now, normally when they deal with the Einstein equations, they're typically, you know,
they start with these mathematical equations, and then they usually use our,
product, Mathematica, to kind of grind through and understand how those equations are set up.
And then eventually they'll get sort of simplified equations.
And then they'll say, okay, now we're going to put this on a computer.
But the way they do those solutions is to assume that space is kind of broken into little pieces just for the sake of the computer.
They don't imagine that space really works that way.
They're just doing that for the sake of the computer.
Right.
But so in our model, space really works that way.
And what's kind of neat is that our models are actually a good method for doing numerical general relativity.
And now the thing that I find really fun is there's starting to be some groups using these.
And I think for them, if there's something that is a deviation between our models and general relativity, it's like, oh, this is really terrible.
For us, it's like fantastic.
Now we can see the discreetness of space.
And so one of the things that's pretty interesting is we're starting to try and tease out effects that allow one to detect the discreteness of space.
So one way to put it is brown in motion was the thing that clinched it for molecules.
We want to find the analog of brown in motion for physical space.
What is that thing that is some shot noise in the gravitational radiation from emerging black hole?
what is that difference in the ring-down speed
when black holes merge
that's associated with discreetness?
What's the difference in the way frame-dragging works
around a black hole associated with discreetness of space?
We don't know the length scale for the discreetness of space,
just like people didn't know how big molecules were.
So it's a lot smaller in the plank length.
We know that.
But we don't know how much smaller.
And we don't know, you know, it could be that it's out of the range
of what we can experimentally detect.
It's looking like there are effects,
in, for example, critical black holes that are spinning right at the sort of limits of how fast
they don't actually spin.
It's just a parameter in the equations.
But they drag things around as if they were spinning.
But right at the edge, the structure of space is held together by a small number of relations in this graph.
And so if the black hole kind of spun faster, a piece of space would essentially break off.
And at that moment, at that point where you have this critical black hole, there is probably a, that's a moment where you kind of have a gravitational microscope.
You can start to see effects that probe down to the discreetness length. Maybe. We don't know exactly how that works.
So I just, I can explain my aphorism about dark matter is the caloric of our time.
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Just to refresh the viewers or the listeners, you know, kind of memory, I mean, Chloric was a
fictitious property attributed, thought to be attributed to matter that was storing heat and it's
gone to the dustbin of history. Now, what's interesting about what you're saying is that it may be
the analog of that in the 21st century might be dark matter. And we have abundant, you know,
so to push back with respect, you know, we physicists are, you know, debating now between the
various candidates for dark matter. It's not only that dark matter exists, we have abundant evidence
from the CMB antisotropies that I study to my colleagues who look for direct detection experiments to galaxy clusters from Zwicki back in Pasadena where you used to spend some of your time.
And it goes all the way through Vera Rubin, who spent time here in San Diego.
So for you to say it's going to rankle some people because the-
Well, let me explain what I mean, because there's more to it than just that statement.
Okay.
So and maybe I should have, maybe I should state it slightly differently.
for these purposes. But, first of all, what is dark matter? So, you know, it's, you see a galaxy,
it's got a bunch of star, you know, 100 billion stars in it, and there's a certain amount of
gravity that should be associated with all of those stars. The way galaxies rotate, it's as
if there's a whole bunch more gravitational mass than you can see in the stars in the light matter,
so to speak, of the stars that are lit up. So there's something there,
that has a gravitational effect, but is not like a star where you're seeing light and so on.
And so what do I mean by my statement? Caloric was an interpretation of what heat was.
Nobody was disputing, you know, we still talk about calories today.
Heat is a thing.
Nobody was disputing whether heat existed.
The question is, what was heat?
And at the time, people assumed that heat was this kind of fluid, that matter was kind of had heat inside it.
was sort of a fluid that had worked its way into the pores of the matter, so to speak,
to be the heat that was there.
Because that was the only thing people could imagine heat was.
Turns out what heat actually is, is the microscopic motion of molecules.
So now the question is, in modern times, what is this thing that produces a gravitational
effect that isn't kind of like the matter we know?
Well, the immediate thing for people to say is, well, the only thing we know is particle.
It must be some kind of particles.
So just like people said in the past, heat must be some kind of fluid, because that's the only kind of thing we know, when we're confronted with dark matter and this thing that happens of gravitational effect, the immediate thing for people to say is it must be some other kind of matter that we've never seen, some kind of particles, you know, some particles, this kind of particle, that kind of particle.
I don't think that's right.
I think it's actually a feature of the structure of space.
Just like it turned out heat was this feature.
of the microscopic structure of matter, I suspect dark matter is a feature of the microscopic
structure of space.
So, in fact, and the most ironic thing is that when you look at the structure of space in our models,
there is, at the most microscopic level, there's all this randomness, all this computational
irreducibility, all these different sort of rewrites of this kind of relations that knit together
the structure of space.
It's kind of like heat.
And so it could turn out to be the case that dark matter is basically
space-time heat, that it's basically that there exists a feature of the structure of space-time,
just like heat in matter is these motion of molecules, that there's kind of a space-time analog of
that is associated with kind of activity in the structure of these networks that make up space.
And so that would be kind of an ironic thing for it to turn out that, you know,
it's that what we're missing is something exactly it's just you know science has this habit of sometimes
repeating itself as history does that um that we turn out that the thing we don't know what
in earth it is is actually something that is a direct analog of that molecular process that we saw
in matter but now applied to the atoms of space that are not that are much more idealized structures
than the kind of molecules atoms that we have in in matter so you know the two
challenge. So now the question is, okay, you're an experimentalist. How do you detect this? And
what can you actually look for and stay tuned because we're trying to figure this out.
Well, I just want to again, you know, push back with respect and affection. But to say that,
you know, dark matter doesn't have any instantiations right now that we understand very well,
it wouldn't be true. In other words, we know neutrinos are dark matter. They interact weekly.
they have a tiny mass.
We know what their vast bound is.
We actually are going to measure that with the Simon's Observatory.
We're going to measure turn it from an upper limit plus a lower limit into a detection at several sigma
and other experiments as well.
Weak gravitational lensing will do that.
And we know of another candidate that you just mentioned it a few minutes ago, black holes.
Black holes.
Now, there may not be enough of them to make up the critical closure density, but we know
two of these things exist in particulate form.
And I'm wondering how do you react?
to that. In other words, do we need
another candidate now
to explain the peculiar properties
of galaxies and Zwicki's clusters
of galaxies where he
derived it from the virile theorem? Why do we
need to discretize space? We just need to find an axon,
which we're going to also look for,
and some of claim detections of already.
So why do we need to add in
another ingredient into the mix,
namely discretization of clumping of space time?
You don't, just like you can go look
for features of coloric fluid.
It turns out you won't find him.
I mean, that's the, you know, this is one of these things where it is, our model really has, well, has one parameter, which is the size of the elementary length.
Beyond that, it has no freedom.
There's, you know, whatever it predicts is what it predicts.
We're not, you know, there's no wiggle room, which is not the case.
In most current models in particle physics or something like that, it's like, oh, we can tune this parameter, we can do this, we can do this, we can.
do that. We don't have any of that freedom. To me, what's really exciting about what's happened
the last few years is if you have a model that has no parameters, it's kind of like it's either right
or it's wrong. And what's happened is more and more things have kind of lined up and yep, it explains
that, yep, it explains that and so on. And so that's very encouraging. You know, I don't know yet
whether the dynamics of our models will lead to a phenomenon that corresponds to dark matter.
We don't know that yet.
We probably will know that quite soon.
It's really a detailed question doing these simulations and so on.
But if it does lead to that, then we're just going to say this is what we think is happening.
I mean, you know, and if it turns out it doesn't lead to that, well, we're stuck with axions and things,
and we have to see whether we can find those.
The question is really, is dark matter a clue to a bigger phenomenon?
or is it just a detail of something that is kind of like the particle physics we already knew and so on?
I don't know.
I mean, I say that I've been very sort of my own, if I would guess, I would guess that it's something out of left field.
It's not a, oh, you know, I mean, I used to think dark matter was probably small black holes.
And, you know, then people said, oh, no, it couldn't possibly be that.
And et cetera, et cetera, et cetera.
I mean, it's gone through.
I think neutrinos are not very promising.
for that. But in, you know, different kinds of, and it's not, we don't know yet whether our model says
you should have a phenomenon that corresponds to dark matter. But, you know, I think it is, it is
kind of an interesting thing to think about. And it's a, I think there's a certain kind of, I would say,
intellectual charm to this idea that the thing we might be missing is the same thing that people
missed in the 1800s with respect to the structure of matter and the nature of heat.
And so it's a, but I mean, there are, you know, for us, one of the things that happens is there are dimension fluctuations in the universe.
The universe starts infinite dimensional and gradually cools down.
We don't know why it ends up at three.
My guess is that the three is a feature of us as observers and that we could describe the universe not as three-dimensional.
It is a feature of the way that we are as observers that makes us think that we should parse the universe as a three-dimensional thing.
but in any case, but one of the predictions of our model is that there will be dimension fluctuations.
We don't know how big, but we know that there will be places where space is not three-dimensional,
but it's, you know, 3.01 dimensional, et cetera.
And there are limits.
There are limits from the similar phenomena that we discussed earlier, Black Hole coalescence,
and also Black Hole binary neutron star coalescences.
And I want to get back to Black Halls because I think they do unify your interest in the second law.
and also with gravitational collapse and the phenomena of observer and systems.
So obviously my viewers and listeners are familiar with things like Hawking radiation,
Beckenstein entropy, and other things.
I think it would be a treat if you could kind of work an example.
Can you derive, you know, hawking radiation or the Beckenstein entropy for a black hole
from, you know, from these irreducibly computational framework in a way that we can, and, you know,
note the second law's importance. And as I say, a worked example in sort of words, I don't expect
you to have a whiteboard nearby. I wouldn't surprise me if you do. But can we go through that?
Let's derive. Let's talk about Hawking radiation and Beckenstein entropy. And can we get that?
This is, this is, okay, my young collaborator, Jonathan Gore,
has just been working on this.
And I think he has some paper, which maybe is already out,
or maybe he's about to be out,
about this exact very topic.
And so, okay, it's a bit of a complicated story,
and there are pieces to it that are a bit alien
from the way people have thought about this before.
Let me say that to get to hooking radiation,
things like that, we have to talk about quantum mechanics.
We didn't talk about quantum mechanics yet.
But let me say something even before we get to quantum mechanics.
Let's talk about the intrinsic entropy of spacetime, which is not what one's talking about in black hole entropy,
but in this model where there is a discrete structure of spacetime, you can say, I've got a lump of space time,
and how many different configurations, given that I know that there's a certain curvature to the space in this region of the universe,
how many possible configurations are there of this underlying spacetime structure that are consistent with that overall curvature?
That's something we've never been able to address.
We've never been able to talk about with traditional approaches to general relativity and quantum mechanics.
We now can talk about that.
You can actually start working out the intrinsic entropy of space time.
And given constraints, you can say, given these constraints, given that we know we have, for example, a black hole with certain sort of external metric, external gravitational field, and so on, we can say, well, let's actually count how many possible configurations.
of space time, there are consistent with that. That's something we can imagine doing. We haven't
successfully done that yet. I think Jonathan has made progress recently in doing some of those
kinds of things. But let's talk about, well, let's talk about, it gets a little bit more
complicated when we talk about quantum mechanics. We have to talk about what quantum mechanics is,
first of all. But let me say something about general relativity and the derivation of general relativity.
You've got this underlying network. It's flopping around in all kinds of different ways.
the fact that we even believe that space is continuous,
the fact that we've even had that idea
is a consequence of the way we are as observers.
The fact that we don't say,
oh, space is made of all these atoms of space.
We say space seems to us like it's continuous.
That's because we're pretty big compared to the atoms of space.
The atoms of space might be 10 to the minus 100 meters apart,
so to speak, in some sense.
And we're very big compared to that.
And by the way, there are many aspects
the way we parse the universe that a specific detailed consequence of the way we are as observers.
Let me give another example.
So, you know, we usually think there is a state of the universe at successive moments in time.
We look around the room, we say, that's the state of the room.
Now at a later time, the room will look different.
Okay.
The reason we think that is because as we look around, we're seeing a few tens of meters away,
the speed of light is taking information from tens of meters away to us.
in microseconds, but our brains take milliseconds to update and know what we saw. So it's the fact
that the speed of light relative to our speed of brain operation is the way it is that makes us
parse space time as there's the complete structure of space at successive moments in time. So
sort of a thought experiment is imagine that our brains worked a million times faster. Imagine we
replaced our neural hardware with semiconductor hardware, which runs a million times faster.
what would we think about the structure of space and space time?
Because it would be very different.
We'd be continuously seeing sort of the things that are, you know,
relativistic effects, individual photons.
We'd be seeing, you know, just like we have echoes from sound.
We'd be seeing all these echoes of light and so on.
Very different experience.
And we wouldn't necessarily piece together this, you know,
it's space at successive moments in time.
Same thing if we were much bigger than we are.
If we were the size of the solar system or something,
we would have a very different view of the relationship of space and time.
So the thing to realize is the fact that we perceive general relativity
is a consequence of the fact that we're observers of the kind we are.
And it turns out that this idea of computational boundliness,
we can't untangle the computational irreducibility of underlying processes,
together with another condition, which is actually also needed in second law,
but it's slightly more subtle.
The second condition that we need is that we believe we are persistent in time.
And you might say that's totally obvious.
We're obviously.
We're the same us at the next moment in time as we were at the previous moment in time.
But it's not obvious because we're made of different atoms of space at successive moments in time.
So the fact that we have this belief that it's the same us is a non-trivial thing.
And that is a feature of us as observers of the universe that we believe we have this threat of experience that continues.
And so those two things turn out to inevitably give us general.
So the feature of us as observers, the same features as us observers that gives us the second
law of thermodynamics also gives us generativity.
Okay, so we should talk about quantum mechanics.
So he talked about this network and all these rewrites are happening and we say, well,
the network progresses from this state to this state and so on.
But actually there's a little bit more to it because it's all we say is there are these rewrites
that can happen.
Well, now we can say, well, just run all possible rewrites.
What we'll get is many different paths of history.
There's one sequence of rewrites that give you this sequence of states of the universe, this thread of history, another sequence of rewrites that give you another thread of history.
And what we end up with is what we call a multi-way system where you've got these different threads of history that are branching and merging.
And that's the thing that's continually happening.
There are different threads of history that are branching and merging.
And it's that phenomenon that essentially inevitably gives us quantum mechanics.
Because sort of the core idea of quantum mechanics is that it isn't definite things don't happen in the universe.
Instead, there are many parts of history, and we just get to observe certain probabilities of different paths having happened.
And what happens in our models is there's this multi-way graph that represents all these different parts of history.
And then the thing is, well, why do we even believe that definite things happen?
And why do we believe that we have a single threat of experience?
Yet quantum mechanics has all these different branches that are going.
So it is an assumption of us as observers that we can say that we can aggregate these things
into saying there is a definite thing that happens.
Very similar to what happens in thermodynamics where we say there's a definite pressure to this gas.
Well, pressure from a gas is made up of lots of little individual molecules, you know, hitting our pressure
measuring device. And it's the fact that we aggregate those to say, oh, there's just a definite
pressure. That's why we believe that there's a pressure in the gas and the gas obeys the gas
laws and so on. So similarly, with respect to quantum mechanics, the reason that we believe
that definite things happen is because we are essentially extended objects in this kind of
space of quantum branches. We talk about this thing we call branchial space, the space of quantum
branches, just like we can talk about physical space as being the extension of this hypergraph.
So similarly in this multi-way graph, you can kind of slice the multi-way graph, you get all these
different ends, and they have certain relations that define kind of another type of space
that has distances between things that are distances between different parts of history
for the universe.
And the sort of the big point is that we are extended with respect to that.
We are in that system, and we are, we're kind of, we're observing that by aggregating
across many branches of history.
So that's kind of the very rough idea of how quantum mechanics emerges.
Now, when you talk about black holes.
Oh, sorry, Stephen, could be, before we go there, because I think it's a natural point to
just break.
One thing that's always kind of flabbergasted me is you start with something in classical
mechanics, a Poisson Bracken, and you have commutation.
relations and exact same language and mathematics transmutes exactly over, you know,
into quantum mechanics, except these things are non-vanishing. And in fact, they also involve
the square root of negative one. And it's completely, you know, almost as mind-blowing a fact as there
is, you know, Feynman used to say, as you knew Feynman personally, but, you know, that the most
remarkable relation is, you know, Euler's relation between E and Pi and I and so forth.
But this to me is almost even more remarkable that you get a physical, I mean, that's just
just in the laws of math, ma'am, not minimizing it. But now you've got this thing in classical
mechanics that ports one to one, except for the square root of, what do you make of this?
I mean, is this something, you know, that is just a fact?
No, okay. So how does that work? I mean, it's always so fun because
Dick Feynman always used to say he'd worked on quantum mechanics his own life, his whole life,
and he always used to say, nobody understands quantum mechanics.
And I talked to him about that at great, great length.
It's a shame he isn't still alive, because I think I now finally am beginning to understand quantum mechanics.
And so one question is, like, where does the eye come from in quantum mechanics?
I think it's a confusion, actually.
I think that one of the things that was sort of a wrong turn that was taken in studying space time,
actually was what was done, not by Einstein, but by Minkowski in 1919, when he said, oh, space and time are really the same kind of thing that's packaged them together into this thing we call space time. And he did that. Minkowski was a number theorist, a mathematician, and he said, it's very elegant. We can make these quadratic forms that are X squared for space and T squared for time, and it's X squared minus T squared. It's all very beautiful. We can package together space and time as being the single space time thing.
I think that was a mistake.
I think space is a thing that's very different from time.
Space is this extension of this hypergraph.
Time is the inexorable progress of computation.
It is an emergent fact that space and time sort of work together in the ways that give relativity.
That's an emergent fact.
That's not something that's built into the underlying model.
In quantum mechanics, I think a similar wrong term was taken.
So in quantum mechanics, one of the things that one does one will formulate quantum mechanics,
in terms of wave functions in the Schrodinger equation,
or a whole variety of other versions of that formalism,
what one's doing is one's saying,
there are these quantum amplitudes.
They're these things that we will be able to represent
kind of the quantum world in terms of.
And quantum amplitudes are complex numbers.
They have a magnitude, the overall, you know,
complex numbers can be represented,
and you can sort of plot them in two dimensions,
and they have a distance from the origin and an angle from the origin.
So the magnitude and the phase.
In quantum mechanics, one packages together the magnitude and the phase.
In our models, they come from completely different places.
The magnitude comes from the counting of the number of paths in this multi-way system.
The phase is basically the position in branch hill space.
There's a bunch of mathematics we have not yet worked out,
and that's quite difficult, I would say.
but what seems to be the case is that what's happening is in quantum mechanics, you are, well, okay, so I should say another thing.
In space time, one of the key things that happens is that the presence of energy momentum or mass deflects shortest paths.
So, as you know very well, there are geodesic paths, shortest paths in space time.
And, you know, when you just are dealing with everything on a plane, for example,
the shortest path between two points is a straight line.
If you distort that plane, the shortest path between two points won't be a straight line anymore.
And the kind of original idea of generativity was the structure of space-time is being distorted by the presence of mass.
And that distortion is causing shortest paths to no longer be straight lines.
Shortest paths are deflected and that's the deflection associated with the force of gravity.
And that was kind of, that's kind of the basic idea of general relativity.
And so what happens in our models is, well, you can have shortest paths, same kind of deal.
In this graph, you can just say, what's the shortest path on the graph going through edges of the graph?
How do you get from this place to that place going through the smallest number of edges on the graph?
So now you can say, well, the next question is, what's energy momentum?
This is something really surprised me, actually.
I thought it was going to be very difficult to understand what energy momentum is.
Turns out it's not.
Turns out energy momentum is essentially just the energy momentum.
amount, the density of activity in the network. So we've got all this network is being
rewritten in all these different ways. We can represent that slightly more formally by a causal
graph that says there are these little rewrite events. And every rewrite event can
is producing output that will be the input to subsequent rewrite events. And we can make
this graph that represents the sort of causal connections between these things. And energy
is simply if we look at, well, we have to define in relativity,
As you well know, we're talking about space-like hyperservices, these things.
So events can be related in a time-like way in the sense that one event is followed by another event in a sequence in time.
But there are also events that can be space-like separated where those events can happen simultaneously in time.
If you're time-like separated, you better not be space-like separated because one event follows from another event.
and they couldn't be simultaneous.
But there are events that are sort of orthogonal
to the time-like directions,
are space-like directions.
There are many different choices of space-like directions.
That's what gives the reference frames in relativity and so on.
But in any case, if you look at these space-like hyperservices,
energy in our models is simply the flux of these causal edges
through space-like hyperservices.
Momentum is flux through time-like hyperservices.
Okay, so then you can derive the processionable.
presence of the existence of gravity. And you can derive the fact that there is, when there is
this density of activity in the network, it deflects shortest paths than the network. That's a pretty
neat thing that you can give an intuitive definition, intuitive explanation when gravity happens.
Right. Yeah. So actually, to give another one of these intuitive things, so time dilation is a
phenomenon of special artivity, that, you know, things that are going fast, things that are
moving a lot, time seems to go slower for them. Well, in our models, you can kind of see why
that happens, because what is time? Time is this inexorable process of executing computations.
Motion is you get to recreate yourself at a different place in space. That phenomenon of motion,
the fact that you're recreating yourself at a different place in space, that takes computational
effort. So you know, have this trade-off. What are you going to spend your
computational effort on. You're going to spend your computational effort on moving in space,
or are you going to use it on progressing in time? And so when you're moving in space,
you're using up your computation on motion, so you don't have as much left over to progress in
time. So that means you effectively, time goes slower for you. And that's what time dilation
comes from. And the math works out, and that's really how it works. And it's really quite, to me,
it's really amazing that you can give what is essentially a mechanistic explanation of what seemed
to be a purely kind of the math happens to work out that way kind of phenomenon.
But okay, so that's how this works in physical space.
In branchial space, there's a similar phenomenon.
You have these GD6, these shortest paths, things travel on shortest paths, but now energy
momentum also deflects shortest paths in branchial space.
And then what's the consequence of that?
Well, there's this, there's something is, is, is, is, is, is, is, is, is, is, is, is, is
moving where you are in branchial space.
The fundamental law of quantum mechanics, one way to state it is the Feynman path integral.
The Feynman path integral says you have this thing that is what's called the action, kind of this
relativistically invariant version of energy, and that the presence of action, um, and that the presence of
action, effectively energy momentum, is the thing that changes the phase of your description
of the quantum system.
So in other words, the presence of energy momentum is making this change.
So in our models, the presence of energy momentum is deflecting GAD6.
It's moving things, but it's moving things not in physical space, but in branchial space.
So now the question is, what is motion in branchial space?
Well, motion in branchial space appears to be change of quantum phase.
And so what's happening is the phenomenon that is general relativity,
that is deflection due to gravity in physical space,
that same phenomenon, the deflection in branchial space is a change of quantum phase,
and that change of quantum phase is what the path integral says should happen in quantum mechanics.
So in other words, what one's saying is quantum mechanics is the same phenomenon
as gravity and general relativity,
what is general relativity in physical space
is quantum mechanics and branchial space.
They're the same thing.
Does that imply it's a symplectic, geometrical,
that bronchial space is also symplectic space?
In other words, that's manifold.
It's essentially an abstract manifold
on which these things can take place,
or am I misinterpreting that?
So it's a little complicated,
because momentum is this flux of causal edges,
through time-like hyperservices.
And so when you look at a commutation relation
that's about this flux of causal edges
as compared to position,
I don't know the answer.
It's quite possible that it's not mathematically trivial
to figure that out.
An interesting question about these commutators
and anti-commutators
is the presence of, you know,
there are two very different kinds of particles,
bosons and fermions,
things like photons where you can cram as many photons as you want into something
they really like to hang out together which is why lasers work or electrons
but they really don't like to hang out together you can only get one electron in a given state
and that's why matter doesn't collapse and things like this and that's that's some and so
this distinction between fermions and bosons is the distinction between
commutators and anti-commutators and quantum mechanics and it looks like there is
in these multi-way graphs, it looks like, we don't know exactly how this works, but it looks like
there is a relationship between kind of the structure of these multi-way graphs and whether
when you have a branch in the multi-way graph, it immediately recombines or not, that that's related
to the presence of that, the branching and recombining is a commutator being equal to zero.
And so it seems like bosons are that case and fermions are the case where things sort of tree out and don't recombine.
How that relates to the symplectic structure in phase space.
Let me think about that for a second.
We should come back to...
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But maybe in a separate conversation at a later time, because I think it's imperative for me as an experimental physicist.
You know, I'd be shirking my duties. If I didn't ask about some kind of,
consequences that my colleagues potentially can investigate, you know, not on your behalf,
but on our behalf, right? Because these could be pointing in new directions, newer interpretations,
but also new physical observables. So we talked a lot about black bodies. We talked a lot about
the second law. We talked about term. So I studied the CMB, the most perfect black body
known to exist in the universe. There are aspects of it that can be used to synchronize clocks or
to synchronize coordinate systems within our local frame of motion, which is causing.
by our dark matter driven, at least in some conceptions, motion towards the Virgo supercluster.
So my question for you is, are there observables? Are there distortions, say, there are common
spectral distortions to a black body that are, I wouldn't say easy to observe? I mean, it's not exactly
what I do, but the technology has been there for some time to measure very minute, parts per million,
parts per hundredth of a million distortions to black bodies. Are there kind of quarries that you can
set me and my colleagues off on to look for that would lead to an interpretation or perhaps
a measurement of some fundamental link scale of computational.
We think so.
We don't yet know.
I mean, this is one of the challenges is you have a fundamental theory and you have to build
up from that to something you can actually point a telescope there and see it.
I mean, you know, cautionary tale from general relativity that you probably know well is, you know,
that one of the predictions of general relativity is that the bending of light around.
the sun will be twice as great as it was in the Newtonian theory.
In 1916, so the theory was proposed in 1915 in December of 1915, in 1916 there was a total eclipse,
was visible from Crimea, and there was an expedition that went to go and observe
whether light was bent more around the sun than it would have otherwise been at that time.
Well, at that point, Einstein had calculated it wrong.
So he had a prediction, and these guys went to go and measure the prediction.
And they almost measured it except the US-centered World War I.
And these American physicists with all their equipment were told by the Russians, I guess, at that time, no, you know, this is off limits.
Go away.
They imprisoned them.
Yeah, that's right.
So the experiment didn't get done.
Then your friend Eddington in 1919 went to South Africa, read the experiment.
I suspect he cooked the books on that experiment, but that's a different issue.
And by that time, Einstein had corrected the calculation of the bending of light around the sun,
and Eddington claimed to have observed exactly that phenomenon.
So, you know, it is a difficult thing to go from the fundamental physics to an experimental prediction.
I've seen this.
I used to do particle physics where one could in the late 1970s, which is a very golden age for particle physics.
And I saw this multiple times of, you know, for example, one of my experiences in as a young physicist,
when I was 17 years old, actually,
was I worked out in QCD,
theory of quarks and gluons,
how many charm particles should be produced
in proton-proton collisions.
So I had this calculation.
I said, the number should be this.
Okay, there was an experiment
that said, no, it's not that.
The number is 10 times small,
is less than 10 times smaller than that.
And it's like, what's going on?
I don't know what to do.
So I published this paper,
but I said, this is the calculation from QCD,
and then half the paper is, but the experiment says it isn't true, here's why it might be wrong,
even though QCD really said that's how it should work.
Well, it turns out the experiment was wrong.
That was the last time I didn't visit an experiment who's, you know, after that time, I always
made it a principle.
I'm going to go visit the experiment, going to ask all kinds of questions.
I'm going to, you know, it was one of these experiments where they're looking for something
where they didn't find anything, and that's always suspicious because, you know,
when you find nothing, it's kind of you don't really know that you were looking to trying to detect it correctly.
But so, you know, with that cautionary statements, what kinds of things might one look for?
Yeah.
Well, I think the, you know, I think dimension fluctuations are a big thing.
I think that there are a bunch of effects, actually.
It was just my young colleague, Jonathan Gorard, was just at a,
gravitational wave background conference and I think he and some other people
there cooked up a whole bunch of things that are possible effects that you could
look for the challenge in all of these is just doing the physics that goes
between this very small length scale so for example one really cool
effect would be gravitational lensing around the dimension fluctuation so in
ordinary gravitational lensing you know you're you're looking at some galaxy or
something and the light is being bent by the presence of mass.
In this case, we expect that the light will be bent by the presence of a dimension fluctuation.
If the universe isn't exactly three-dimensional, then the kind of the, you know, if you even
have the electric field from a point charge, usually just streams out in all directions and
has an inverse square law kind of fall off.
if you're not in three dimensions, it's not an inverse square law. And there's an effective
kind of refractive index type thing that seems to happen when you go through a dimension
fluctuation. So the coolest experiment, which I don't think is going to work out this way,
but it would be super cool if it did, is that we don't know how this works yet. We don't know
what actually happens to a bundle of photons that go through a dimension fluctuation.
But, you know, in a very fanciful way, one could imagine they're shattered into some kind of
a fractal distribution in the imaging plane.
And then the thing that would be spectacular,
which I think is very fanciful so far,
is we'd be able to say, use the space telescope,
you look at this thing,
you've got this thing that looks like noise,
you make this transform on it,
and you've got a picture of a galaxy.
If that happened, we really know we're seeing dimension fluctuations.
I don't think it's going to be as simple as that.
I think that the likelihood is, in terms of CMB,
I think the potential is relic dimension fluctuations from the early universe, and the question is,
what are their signatures?
And in our models, there's no inflation story.
The reason that different parts of the universe are in causal contact is because the universe was
originally infinite dimensional, but causal contact is trivial, because the different parts
of the graph, everything is connected to everything.
So then what happens?
So there are no doubt predictions about.
Actually, that brings up something very concrete, Stephen, because if we on the Simon's Observatory or our competitors and Bicep and others, if we detect a primordial gas of gravitational waves resulting from primordial curvature perturbations and fluctuations in the inflaton, that would seem to falsify this, at least the notion that as I understand it, of the infinite dimensional space.
space cleaving into a finite number of dimensions. So it's virtue of what you're saying because
it's falsifiable in the Paparian sense, is it not? The calculation of what the gravitational wave
spectrum is from, you know, our models is a difficult thing. I mean, it hasn't yet been done. We don't
know how to do that yet. But there's no inflaton. There's nothing to fluctuate. There's no
multiverse, right? In your model. No, that's right. But there will be, there will absolutely be
relic gravitational waves from the beginning of the universe.
Right, but their spectrum would be probably very different from what inflation would predict.
In other words, I'm looking for ways...
In fact, there's a big, messy story.
I mean, inflation has a thousand, well, not a thousand, but at least 20 parameters that
you can tweak.
We don't have those parameters.
So whatever we predict, we're stuck with predicting that.
We don't know what that prediction is.
I would encourage you.
I would encourage you at great haste, Stephen, because this is something that over a billion
is being planned devoted to in the field of cosmic micro-ray background, so-called B-mode experiments
that are not only looking for the presence of these primordial gravitational ways, but eventually
their power spectrum, if indeed they exist. Now, if we discover them and, you know, in other words,
it's a crisp test. It's a decisive test to use Popper's language. But Stephen, I have to go
put some kids to bed in about 10 minutes, but I have a billion more questions to ask you.
I'd love it if you would beg your forbearance to have a part two at some, a part four at some time.
But I do have some questions from the audience that they're dying to ask you.
Go for it.
Yes, please.
So, okay, these will be maybe yes or no or a quick short answer so we can get to his money.
I'm really bad at short answers.
I apologize.
I haven't noticed, I never noticed.
Okay.
So you mentioned, according to my listener, Shadari,
Stephen mentioned that he had realized ADS-CFT is related to do with something to do with bronchial space.
Can you give any details or implications about it?
So what happens is that,
And again, the details are not fully known yet, but this is not a yes-no question.
Okay.
In the simplest way of thinking about it, every branch in the multi-way graph has a complete universe, has a complete state of the universe.
But that's a very inefficient way to think about it.
Rather, those states of the universe, most aspects of them are the same.
It's only a small part that's different.
So you end up with this thing we call multi-way causal graph that relates to the universe.
the different events that happen at different places in physical space
and on different branches in this multi-way graph.
And you've got this multi-way causal graph that contains information
both on the relationship between events at different places in space
and the events at different places in branch-hill space.
It's the fact that there is a single object
that contains information about both branchial space,
which is related to quantum mechanics,
and physical space that's related to general relativity.
that's what knits those two things together.
And so the ADF-CFT correspondence is almost certainly two different projections of this multi-way causal graph.
A projection in the branchial direction giving you the CFT part,
a projection in the spatial direction giving you the ADS part.
And again, there's a bunch of people have been working on this.
And it's, you know, that seems to be what's going on.
That's the intuition about what's going on.
There's this ER equals EPR kind of conjecture that comes out of ADSCFT,
which it looks like we can reproduce in our models.
But there are many details to be filled in.
I mean, this is, you know, what's happened with these models basically is there's a big burst of activity in physics 100 years ago.
Lots of things got figured out.
There's a certain paradigm that existed in mathematical physics at that time.
We kind of have a new paradigm, and there's a lot of new stuff that will be figured out.
but it's complicated, and it's going to take, you know, it's going to take the work of lots of people
and some time to know all these consequences. But we, you know, kind of with the way we see it is,
it looks like we really, you know, we know how the machine code works. Now we kind of have to
see what the consequences of that are. Hey, guys, I'm so sorry to interrupt this amazing deep dive
with my friend Stephen Wolfram, but I know that you're going to want to catch this special offer
that I make. Once a month, I select a winner of one of
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And by joining my mailing, let's you get the freshest space news and access to my guest.
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So do it now before you forget.
Go to briancating.com slash list if you're not already subscribed and join the mailing list.
And every Monday, you'll get the most magical message to live.
straight to your inbox. Okay, now back to the episode. So this is a question I'm going to kind of
pervert it to my purposes, but someone named G. Tycro, maybe asked the question of your
thoughts on the future of science in the age of LLMs. And I want to augment that, Stephen,
with my host prerogative by stating a fact that you're probably aware of. Do you recall
what Einstein's happiest thought was that gave him palpitations, Stephen? Do you remember
what Einstein said. The fact that the universe is understandable to us is remarkable. I mean,
not that one. I'll give you a hint. There's old Albert. Okay. Here's Albert. He's in free fall.
He's in free fall. Okay. So an observer in free fall experiences no gravitational force.
I want to use that as a springboard to ask you about AI. And it's potential as a scientist to do
scientific, for us as scientists, but to generate new scientific ideas. And the way I like to say it is,
can a computer have a happiest thought like Albert? And can it do science the way he did without a
body, without the sensation of what it means to free fall, perhaps in a visceral sense? Are you
optimistic that there'll be an AI Galileo or A.E. Einstein? To what extent are you optimistic or
pessimistic about scientists, scientific breakers coming from AIs and L.L. Well, this is a complicated story.
The basic thing is, in the computational universe of all possible computations, there's lots of stuff that goes on.
Only some tiny sliver of it is stuff that we humans care about.
There's only some tiny sliver of it that we even have sensory apparatus to detect.
And so we've pulled out these things that we care about,
that are the aspects of the universe, the natural laws that we want to talk about in the universe.
there's a lot more besides.
So the challenge is not to go out and find natural laws.
It's kind of like in mathematics.
We can go out and generate theorems.
I wrote this whole book about the physicalization of metamathematics.
About, you know, us humans, we've written down about three or four million theorems
in the history of mathematics.
But there's an infinite number of possible theorems.
You can just go out and generate them.
You can have a computer go generate all these theorems.
The issue is which of these theorems are we humans going to care about?
And this question of sort of what is there to discover, there's a big piece to that, which is there are all these prongs we can kind of pursue.
There are all these directions we can pursue.
Which ones are ones that sort of merge with the narratives that we humans care about?
So this question about what does it mean for, you know, I've spent a large part of my life trying to formalize the world in computational terms.
and that's what our computational language, well, from language that, you know, millions of people use every day is all about.
It's about kind of, you know, we had these different kinds of formalization.
We used human language to formalize things.
We could say, you know, the concept of a rock rather than individually pointing at every rock.
We have logic that kind of, you know, sort of gives us the structure of arguments, independent of individual arguments.
We have mathematics.
It gives us a type of formalization.
Computation is, I think, a much more powerful type of form.
that is the defining kind of paradigmatic idea of our century, actually.
And I think that the kind of, that's kind of the big, the big thing is can you represent
the world computationally?
And then the question of in which direction do you want to go, this, this thing you can
represent computationally has lots of directions, lots of richness.
The question of which way you want to go is really a much more human question.
This is a long story.
I mean, I've talked about, written about a lot, these kinds of issues.
I think this is a, you know, bottom line sort of, you know, in a sense, people would have said a lot of the things I built in my life as sort of AI doing science.
But this question about, you know, do you just say, okay, AI, I want to detect features of the cosmic microwave background, you know, tell me what,
experiment I should build, tell me what, those are things where if you define your objectives
carefully enough, then there is a chance that you can search for solutions to, you know, I've
got this engineering problem, I want to have this particular strut that, you know, is organized
in this way and is, you know, minimum weight or whatever else. And, you know, you can absolutely
imagine computationally kind of searching the set of possibilities and finding the one that works.
I think there's much more to say about this.
I mean, there's some, and actually I'm currently doing some experiments
that have to do with the question of just what can things like LLMs predict.
They do a good job of predicting sort of what you might say in an essay
to follow what is typical of what has been said in the essays on a few billion web pages.
And the question would be in the natural world, to what extent can an LLM predict
things that happen in the natural world.
There's no reason they should be able to.
For example, an LLM trained on human natural language,
I don't think it's going to do it.
We actually just, in fact, I probably get right after this
to see the results of one of those experiments.
We've been training some LLMs, LLM-like technology,
to make predictions of idealized natural systems
and trying to understand to what extent to my guess
about what's going to happen.
And this is a very dangerous thing in doing science, because I have a guess about what's going to happen.
But I've been doing science long enough to know that one of the most important things is not to take your guesses that seriously.
Because the chips are going to fall as they fall, and you have to be ready for that.
And it's a mistake.
You know, scientists make this mistake all the time.
You have a hypothesis and you just keep doing things until you verify that hypothesis.
And, you know, you have to not do that.
So, but I'm going to tell you what I think is going to happen, and then I'll go look at my computer, it will have not happened.
So that's, um, but that's the humility.
Yeah, right.
No, it's an important feature of, you know, I think it's, it's critical if you actually want to get the science right.
I mean, it's kind of, you know, but I think the, what I think is going to happen is that it's going to be possible to predict things that when we as humans look at them, we say, oh yeah, I know how that's going to continue.
As soon as you're hitting kind of computational reducibility, and as soon as you can't tell as a human what's going to happen, the AI is going to fail as well.
We'll see.
If we're chatting again in another episode, you can ask me about that again, and I'll tell you what the answer was.
I would love that.
And just to reiterate how grateful I am for your time and staying up late, and I want you to get to look at those experiments, and I've got to put some little experiments to bed.
but we got through about two of the 11 pages of notes and questions that I had.
So I'll beg your forbearance in the new year, perhaps, to do a part four because there's,
there's so much deep interest in what you're doing.
And, you know, from a venal self-interested perspective, too, I want to know what, you know,
possible ways to prospect in the CMB sky and in the underground particle accelerators and so
forth that my colleagues and I can do to get a deeper, a deeper glimpse into the nature of
reality.
I want that to.
The problem is we're building a bridge from two sides, right?
We have an underlying theory.
You have experimental equipment that can measure things.
And now it's a question of, we've got to, you know, in the end, we've got to, in the end,
there's a lot of physics work of building that bridge.
And, you know, I think that's where we're kind of just trying to get that started.
And, you know, I might grill you for information about the details of, you'll know that we're getting close when I'm grilling you for information about your detectors and exactly what they can detect and so on.
But we're not yet there. I'm not yet ready for that.
No, I'm more than happy to oblige, and I have brilliant students that can assist.
But, yeah, I've been thinking about we need sort of a rosetta stone, you know, to transmit between the language of mathematics, the WolframAlpha language.
and the physics project, the theoretical space.
We need to map that to the hardcore observer space
because that's what I love to do.
And there's nothing more fun than making a decisive measurement.
So Stephen Wilfrum, Dr. Stephen Wilford,
thank you so much for sharing your time.
I hope the experiments that you're running tonight
will bring you great joy,
but also allow you to get some sleep whenever it is
that you turn in for the evening.
Thank you so much, Stephen.
Have a great rest of your year,
and I'll be in touch early next year
and we'll hopefully do another part.
Good.
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