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Jonathan Gorard: Quantum Gravity & Wolfram Physics Project
March 29, 2024
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The Economist covers math, physics, philosophy, and AI in a manner that shows how different countries perceive developments and how they impact markets. They recently published a piece on China's new neutrino detector. They cover extending life via mitochondrial transplants, creating an entirely new field of medicine. But it's also not just science they analyze.
Culture, they analyze finance, economics, business, international affairs across every region. I'm particularly liking their new insider feature. It was just launched this month. It gives you, it gives me, a front row access to The Economist's internal editorial debates.
Where senior editors argue through the news with world leaders and policy makers in twice weekly long format shows. Basically an extremely high quality podcast. Whether it's scientific innovation or shifting global politics, The Economist provides comprehensive coverage beyond headlines. As a toe listener, you get a special discount. Head over to economist.com slash TOE to subscribe. That's economist.com slash TOE for your discount.
Think Verizon, the best 5G network is expensive? Think again. Bring in your AT&T or T-Mobile bill to a Verizon store today and we'll give you a better deal. Now what to do with your unwanted bills? Ever seen an origami version of the Miami Bull?
Jokes aside, Verizon has the most ways to save on phones and plans where you can get a single line with everything you need. So bring in your bill to your local Miami Verizon store today and we'll give you a better deal.
In a sense we know that black holes or in the Big Bang or something that's probably an abstraction that loses usefulness and eventually will be superseded by something more foundational. Our universe seems to be neither maximally simple nor is it kind of maximally complicated. There's some regularity but it's not completely logically trivial. It's not like every little particle follows its own set of laws but it's also not like we can just reduce everything to one logical tautology.
Jonathan Gerard is a researcher in mathematical physics at Princeton University and in my opinion is the starkness and the brains behind the rigor at the Wolframs physics project. Today's conversation is quite detailed as we go into the meticulous technicalities as if this were a conversation between two friends behind closed doors. In this discussion we elucidate the core principles and claims of the Wolframs physics project. We distinguish them from the surrounding hype. Specifically we explore potential connections between category theory
And quantum gravity, we also delve into refining truth and representations, the pros and the perils of peer review. And furthermore, we highlight the differences between Jonathan and Stephen Wolfram, particularly in the context of computational and consciousness related aspects.
You should also know that there are three interviews with Stephen Wolfram on this channel. Each is linked in the description. In it, we detail the Wolfram's physics project with Stephen Wolfram himself and why he thinks it's a potential candidate for a theory of everything. My name is Kurt Jaimungal. For those of you who are unfamiliar, this is a channel called Theories of Everything, where we explore theories of everything in the physics sense, using my background in mathematical physics.
from the University of Toronto, but as well as explore other large grand questions. What is consciousness? Where does it come from? What is reality? What defines truth? What is free will? And do we have it? Of course, increasingly, we've been exploring artificial intelligence and its potential relationship to the fundamental laws.
Also, the string theory video that Jonathan mentions is called the iceberg of string theory, and I recommend you check it out. It took approximately two months of writing, four months of editing with four editors, four rewrites, 14 shoots, and there are seven layers. It's the most effort that's gone into any single theories of everything video. It's a rabbit hole of the math of string theory geared toward the graduate level. There's nothing else like it.
If that sounds interesting to you, then check out the channel or hit subscribe to get notified. Enjoy this episode with Jonathan Gerard. So Jonathan, what is the Wolframs physics project and what's your role in it? That's a really good question, Kurt. So I guess there are various people involved and I think you'll get slightly different answers or perhaps very different answers depending on who you ask. I'm
I think when we first launched the physics project back in April 2020, we lent hard on this billing of it's a project to find the fundamental theory of physics. That was not really how I viewed it at the time, and it's become even less how I view it over time. Interesting.
I'm saying this as a prelude to clarify that what you're about to hear is my own perspective on it, and it will probably differ quite a lot from the perspective given by some other members of the project. Essentially, my view is that the Wolfram Physics Project is an attempt to answer a counterfactual history question.
Back in the 17th century, Newton, Leibniz, and a little bit earlier people like Descartes, Galileo, they kind of set the stage for modern theoretical kind of mathematical physics and more broadly for our kind of modern conception of how the exact sciences work.
And so essentially the idea was rather than just describing phenomena in these kind of philosophical terms, you could actually construct kind of robust quantitative models of what natural systems do. And that was enabled by a particular piece of mathematical technology or a particular piece of cognitive technology, which was calculus, which later became
you know, mathematical analysis and the basis of differential geometry and all the kind of machinery of modern mathematical physics. So, you know, Newton Leibniz, you know, building off earlier work by people like Archimedes and so on, kind of, you know, they built up this formalism of calculus that sort of enabled modern physics. And
Arguably that choice of formalism that that choice to base physical models on you know essentially analytic calculus based mathematical formalisms has had an impact on our physical intuition right so you know it involves thinking about things in terms of smooth analytic functions in terms of continuously varying kind of gradients of quantities.
It necessitates us formalizing notions like space and time in terms of smooth manifolds or real numbers. It involves thinking about things like energy and momenta as being continuously varying quantities. And those are, of course, extremely good idealizations of what's really happening. But I think there's always a danger whenever you have a model like that, that you start to believe in the ontological validity of the model. And so for a lot of physicists, I feel like
It's kind of seeped in and percolated our intuition to the extent that we actually think that space is a, you know, smooth Romani and manifold. We think the energy is a kind of real valued function rather than these just being idealizations of some potentially quite different, you know, underlying reality.
Okay, now, fast forward about 300 years, and you have people like Alan Turing and Alonzo Church and Kurt Gödel in the early 20th century building up the beginnings of what became theoretical computer science, right, as a kind of as an as an offshoot of mathematical logic, there were people interested in the question of, you know, what is mathematics? What is mathematical proof? You know, what are mathematical theorems? And that kind of necessitated them building this really quite different mathematical formalism, which initially had different
Manifestations at your turing machines lambda calculus you know general recursive functions etc which then gradually got unified thanks to things like the church turing thesis but so that so now you so in a way.
Again, at least the way I like to think about it is the sort of stuff that Newton and Leibniz and people were doing in the 1600s, with analysis, that gave you a systematic way of understanding and exploring continuous mathematical structures. What Turing and Church and Gödel and people did in the early 20th century with computability theory gave one a systematic way of understanding discrete mathematical structures, the kinds of things that could be represented by simple computations and simple programs.
I'm now by that point is a calculate this is the sort of calculus based approaches had had a three hundred year head starts in terms of the exact sciences it took a little while before people started thinking actually you know maybe we could use these formalisms from computer theory to construct models of natural phenomena to construct you know scientific models and models for things like fundamental physics.
I'm but of course that necessitates being a quite radical departure and how we think about physical laws right that you suddenly have to deviate from thinking about space is some smooth continuous structure and start thinking about it in terms of some discrete combinatorial structure like a kind of network or a graph. I'm in a sense that you moving away from thinking about dynamics in terms of continuous partial differential equations and thinking about it in terms of kind of discrete time step updates like say that the kinds that you can represent using network rewriting rules.
And so you know a lot of this is to train in the in the traditional mathematical formulas and find this quite counterintuitive because i say it you know that was those ideas for mathematical analysis of seat so far into our intuition that we think that's actually how the universe works rather than just thinking of it as being a model and so.
The way, the slightly poetic way that I like to think about what the physics project is doing is we're trying to address this kind of counterfactual history question of what would have happened if, you know, Turing was born 300 years before Newton, not the other way around. In other words, if we had, if discrete mathematical approaches based on computability theory had a 300 year head start in the foundation to a natural science over continuous mathematical structures based on analysis. That's my kind of zoomed out picture of what it is that we're trying to do. Aha.
So there's a lot more that can be said about that of course and i'm sure we'll discuss more of it later but that's at least my kind of that's my. My big picture summary of what i think the physics projects is about it's about trying to reconstruct the foundations of physics not in terms of you know.
Larenzian manifolds and continuous space-times, but in terms of things like graphs, hypergraphs, hypergraphy writing, causal networks, and the kinds of discrete structures that could be represented in a very explicit, computable way. There are some nice connections there, by the way, to things like the constructivist foundations of mathematics that arose in the 20th century as well, and we'll likely talk about that later too.
In terms of my own role within it, Stephen Wolfram, who I know has appeared on TUI a number of times, has been by far the single most energetic evangelist of these ideas for a very long time. He wrote back in 2002 this book, A New Kind of Science, in which he first postulated the beginnings of these ideas about maybe it's useful to think of fundamental physics in terms of network automata and things like that.
And, you know, had some initial hints towards, okay, here's how we might be able to get general relativity, you know, beginnings of quantum mechanics, those kinds of things out of those out of those systems.
Um, but then the, you know, those ideas basically lay dormant for a long time. I mean, NKS had, you know, I had this kind of maelstrom of, of, of attention for, for a couple of years. And then mostly, at least physicists mostly ignored it as kind of at least my impression. Um, where, you know, I, as a teenager, you know, I, I read NKS and, um, I, like many people found certain aspects of the way the book is written a little bit off putting, but I thought that there were many, many core ideas in it that that were really, really quite, quite foundationally important.
and one of them was this idea about fundamental physics and so you know for a while i kind of advocated like we should be doing you know we should be trying to build physics on these kind of computable models if only just to see what happens right just to see you know where that leads us.
Sorry, just a moment. You said that you would be working on these prior to going to the Wolfram School, the summer school.
yes yeah exactly so i went to this i went to the wolfram summer school in 2017 as a consequence of my interest in these models so i'd already been doing a little bit of my own kind of work on this the stuff trying
In large parts, in a sense, to rediscover what Stephen had already done. He had these big claims in NKS about being able to derive Einstein equations and things from these graphic writing models. But the details were never included in the book and I tried to ask Stephen about them and he kind of said, oh, I can't really remember how I did that now. And so I spent quite a lot of time trying to reconstruct that and that eventually ended up, that was the thing that
The results to me, you know, attending the summer school and then and then being kind of pulled into Stephen's orbit. And is it your understanding that Stephen actually did have a proof? He just wasn't able to recall it like format or just was too small of a space to publish or that he thinks he was able to prove it. But the tools weren't available at the time. And you think back like maybe he had a sketch, but it wasn't. Well, it's Leonardo's sketch versus the Mona Lisa.
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Right, right. I think the Leonardo sketch versus the Mona Lisa analogy is probably the right one. My suspicion, based on what I know of the history of that book and also based on what I know of Stephen's personality, is that Stephen had proved it to his own satisfaction, but probably not to the satisfaction of anyone else, right? Interesting. I think many of us are like this, right? If you encounter some problem or some phenomenon you don't really understand,
And you go when you try and understand how it works you try and prove some results about it and eventually you convince yourself that it can be done or that you convince yourself that there is an explanation you don't necessarily tie together all the details to the point where you could actually publish it and make it understandable to other people but kind of to your own intellectual satisfaction it's like oh yeah now i i'm at least convinced that that can work my impression is that that's basically that's essentially where the kind of
Physics project formalism ended up in two thousand two that steven thought about it for a while had some research assistance look at and eventually they kind of convinced themselves yes. It would be possible to derive an equations from these kind of formalisms but i highly from what i've seen of the material was put together and so i don't think anyone actually trace that proof you know with complete mathematical position eventually in two thousand nineteen steven myself and max piss can of we decided.
various reasons that it was kind of the right time for us to do this project in a serious way. Stephen had some new ideas about how we could simplify the formalism a little bit. I'd made some recent progress in kind of understanding the mathematical underpinnings of it. Max had just finished writing some really quite nicely optimized kind of low level C++ code for enumerating these hypergraph systems really efficiently. And so we decided like, okay, if we're not going to do it now, it's never going to happen. And so that was then the beginnings of the physics project.
And so now i'm i'm less i guess less actively involved in the you know in the project as a kind of branding entity but i you know i'm still kind of actively working on the formalism and still trying to push ahead in various mathematical directions trying to kind of concreted by the foundations of what we're doing and make connections to you know to existing areas of mathematical physics.
I see, I see. So I also noticed a similar problem as yourself across society. So across history, that people entwine this prevalent application with some ontological status. So what I mean by that is you'll have a tool which is ubiquitous and usefulness. And then you start to think that there's some reality synonymous with that. So another example would be an ancient poet who would see the power of poetry and think that what lies at the fundament is narrative pieces.
Or a mystic who sees consciousness everywhere almost by definition and then believes consciousness must lie at the root of reality. And some people, Max Tegmark would be an example of this, find that math is so powerful, it must be what reality is. So it's also not clear to me whether computation is another such fashionable instance of a tool being so powerful that we mistake its effectiveness with its substantiveness.
And I understand that Stephen may think differently. I understand that you may think differently. So please explain. That's a fantastic point. I suspect.
From at least from what you said, I think I think our views may be quite similar on this, that I'm reminded of this meme that circulated on Twitter a little while ago about, you know, people saying, you know, immediately after the invention of kind of writing systems and narrative structure, everyone goes, ah, yes, the universe, you know, the cosmos must be a book, right? And then, you know, immediately after the invention of mathematics, ah, yes, the cosmos must be made of mathematics. And then it's, you know, immediately after the invention of the computer, ah, yes, the converse, the cosmos must be a computer.
It's a folly that we've fallen into throughout all of human history. My feeling about this is always that we build models using the kind of ambient technology of our time. And when I say technology, I don't just mean nuts and bolts technology, I also mean kind of thinking technology. There are kind of ambient ideas and processes that we have access to.
And we use those as a kind of raw substrate for making models of the world. So, you know, it's unsurprising that when people like Descartes and Newton built models of the cosmos, you know, of the solar system and so on, they describe them in terms of clockwork by analogies to clockwork mechanisms. Right. And, you know, Descartes even sort of more or less directly wrote that he thought that the solar system was a piece of clockwork.
When he actually thought that in the logical sense of whether it was just a kind of poetic metaphor i don't completely know but you know it's sort of obvious that would happen right because you know that the the fifteenth century sixteenth century that was sort of the height of of clockwork technology in an ambient society. And so you know we live right now and it's arguably the zenith of kind of computational technology and so again it's completely unsurprising that we build models of the cosmos.
Base largely on computer based largely or partly on computational ideas. Yeah, I agree. I think it would be a folly. And I think you're right. This is maybe one area where perhaps Stephen and I differ slightly on in our kind of philosophical conception. I personally feel like it's folly to say therefore, you know, the universe must be a computer, right? Or that, you know, that, that, um, yeah, my feeling about it is the strongest we can say is that
You know modeling the universe as a turing machine is a useful scientific model and it's a useful thinking tool by which to reason through kind of various problems and i think it's. Yeah i would be uncomfortable. Endowing it with any greater ontological significance than that.
That being said, of course, there are also lots of examples where people have made the opposite mistake. The classic example is, say, Hendrik Lorentz, who basically invented the whole formalism of special relativity, but he said, oh, no, no, this is just a mathematical trick. He discovered the right form of time dilation and length contraction, but he said, this is just some coordinate change. It doesn't have any physical effect. It's just a formalism.
And then really the contribution of Einstein was to say, no, it's not just a formalism. This is an actual physical effect. And here's how we might be able to measure it. And so, yeah, you, I'm just trying to, I'm trying to indicate that there's, you have to thread a delicate needle there. Yeah. So you mentioned Turing and there's another approach called constructor theory, which generalizes Turing machines or universal Turing machines to universal constructors.
So called universal constructors. So I'd like you to explain what those are to the degree that you have studied it and then its relationship to what you work on at the Wolframs physics project. And by the way, string theory, loop quantum gravity, they have these succinct names, but WPP doesn't have a graspable, apprehensible name, at least not to me to be able to echo that. So is there one that you all use internally to refer to it?
Okay, so on that, yeah, I'm not a fan of the naming of the Wolfram physics project or indeed even the Wolfram model.
Which is a slightly more succinct version. In a lot of what I've written, I describe it and I use the term hypergraph dynamics or sometimes hypergraphy writing dynamics. OK, because I think that's a that's a more descriptive title for what it really is. But no, I agree. I think I think as a branding exercise, there's still there's still more work that needs to be done. So for the sake of us speaking more quickly, we'll say the HD model. So in this HD model, what is its relationship to what was the category? No, it wasn't category.
It was constructed construct, right? Okay. So what is the HD models relationship to constructor theory? Although that's, that's an interesting Freudian slip because I think basically the relationship is category theory, right? So, um, yeah, okay. So, so I mean, with the, with the proviso that, you know, again, I, I know that you've had Chiara Moleto on, on, on TOE before, right? So I, I'm, I'm certainly not an expert on constructor theory. I've read some of Chiara's and David Deutsch's, um, uh, papers on these, on these topics, but, um,
Sorry i as you say i can give an explanation to the extent that i understand it.
rather than describing physical laws in terms of kind of you know equations of motion right so in the traditional conception of physics we would say you know you've got some initial state of a system you have some equations of motion that describe the dynamics of how it evolves and then you you know it evolves down to some final state uh the idea with constructed theory is you say rather than formulating stuff in terms of equations of motion you formulate things in terms of what classes of transformations are and are not permitted so uh
And I think one of the classic examples that I think Deutsch uses in one of his early papers, and I know that Chiara has done additional work on, is the second law of thermodynamics, and indeed the first law of thermodynamics, right? So thermodynamic laws are not really expressible in terms of equations of motion, or at least not in a very direct way. They're really saying quite global statements about what classes of physical transformations are and are not possible, right? They're saying you cannot build a perpetual motion machine of the first kind or the second kind or whatever, right? That there is no valid
Procedure that takes you from this class of initial states to this class of final states that you know reduce global entropy or that you know create free energy or whatever right and that's a really quite different way of conceptualizing the laws of physics.
So constructive theory, as I understand it, is a way of applying that to physics as a whole, to saying we formalize physical laws not in terms of initial states and equations of motion, but in terms of initial substrates, final substrates, and constructions, which are these general processes that I guess one can think of as being like generalizations of catalysts. It's really a grand generalization of the theory of catalysis in chemistry. You're describing
This enables this process to happen, which allows this class of transformations between these classes of substrates or something. Now, inadvertently, you brought up this question of category theory or this concept of category theory. I have to be a little bit careful with what I say here because I know that the few people I know who work in constructive theory say that what they're doing is not really category theory.
I would argue has some quite in terms of the philosophical conception of it it has some quite remarkable similarities so. To pivot momentarily to talk about the duality between set theory and category theories as foundations for mathematics so with you know.
Since the late 19th century, early 20th century, it's been the kind of vogue to build mathematical foundations based on set theory, based on things like Zemileo Frankel set theory or Hilbert Bernays Gödel set theory and other things, where your fundamental object is a set, some collection of stuff, which then you can apply various operations to, and the idea is you build mathematical structures out of sets. Now, set theory is a very
Is a is a model of mathematics that. Depends very heavily on internal structure right so for instance in the in the standard axioms of set theory you have things like the axiom of extensionality that essentially says two sets are equivalent if they have two sets are identical if they have the same elements. What involves you saying you know identifying sets based on looking inside them and seeing what's inside.
But there's another way that you can think about mathematical structure which is you say, i'm not going to i'm not i'm not gonna allow myself to look inside this object i'm gonna treat it some atomic thing. And instead i'm going to give it an identity based on how it relates to all other objects of the same type. So what transformations can i so you know to give a concrete example right suppose i've got some some topological space.
Um, so one of the kind of set theoretic view is okay. That topological space is a set of points. It's a collection of points that have a topology defined on them. The kind of more category theoretic view would be to say, uh, actually that topological space is defined as the collection of continuous transformations that can be applied to it. So that space can be continuously deformed into some class of other spaces. And that class of other spaces that it can be deformed into is what identifies the space you started from.
And so that's a so and you can define that without ever having to talk about points or you know what was inside it right in fact there's a whole generalization of topology called pointless topology or locale theory which is all about doing topology without an a priori notion of points. So in a way it necessitates this conceptual shift from a an internal structure view to a kind of process theoretic view.
Um, and so that was a viewpoint that was really advocated by the pioneers of, of, of Kaspi theory, um, as Samuel Allenberg and Saunders McLean, uh, and also some other people who were working in topology, like Jean-Pierre Serre and Alexander Grotendieck and others. Um, there was a kind of radically different way to conceptualize the foundations of mathematics. Sorry to interrupt. Just as a point for the audience, you mentioned the word duality between sets and categories. Now, do you mean that in a literal sense or just morally there's a duality?
Because category theorists make a huge fuss that what they're dealing with aren't always like small categories are sets but or can be thought of as sets but not categories as such. Right okay yeah and i shouldn't have said i mean yes no the short answer is no i don't mean duality in any formal sense and in particular it's a dangerous word to use around category theorists because it means something very precise it means that
uh... dual concepts of ones that are that are equivalent up to reversal of the direction of morphisms. I certainly don't mean that. I meant duality in the sense that so there is a precise sense in which set theory and category theory are equivalently valid foundations for mathematics and that precise sense is
I mean we can go deep in the weeds if you want it's that's you know we'll see where the conversation goes but the basic idea is there's a there's a fee as a branch of category theory called elementary topos theory. Which is all about using category theory is a foundation for logic and mathematics and the idea there is so in from a category theoretic perspective sets.
Are just they just form one particular category there is a category called set which is objects are sets and whose transformation is morphisms are set valued functions. And then you might say well you know why is that so important like what's what's so great about set that we build all mathematics on that it's just one random category in the space of possible categories elementary topos theory is all about asking what are the essential properties of set.
that make it a quote unquote good place to do mathematics and and can we abstract those out and figure out some much more general class of mathematical structures some jet some more general class of categories within which internal to which we can build mathematical structures and uh and that gives us the idea of an elementary topos i'm saying elementary because there's a slightly different idea called a growth and deep topos that's related but not quite equivalent and whatever so um but generally when logicians say topos they mean elementary topos
So yeah, there's a particular kind of category which has these technical conditions that it has all finite limits and it possesses a sub-object classifier or equivalently a power object. But basically what it means is that it has the minimal algebraic structure that sets have, that you can do analogs of things like set intersections, set unions, that you can take power sets, you can do subsets. And it
It kind of detects for you a much larger class of mathematical structures, these elementary top hosses, which have those same features. And so then the argument goes, well, therefore you can build mathematics internal to any of those top hosses, and the mathematical structures that you get out are in some deep sense isomorphic to the ones that you would have got if you built mathematics based on set.
Yes, and now the relationship between constructor theory and HD, which is the hypergraph dynamics or Wolfram's physics project for people who are just tuning in.
Right right so yes the the the excursion to talk about category theory is in a sense the my reason for bringing that up is because i think that that same conceptual shift that i was describing where you go from thinking about internal structure to thinking about kind of process theories that's been applied to many other areas it's been applied say in quantum mechanics right so where there's
In the traditional conception, you'd say quantum states are fundamental and you have Hilbert spaces that are spaces of quantum states and then you have operators that transform those Hilbert spaces, but they're somehow secondary. Then there's this rather different, and that's the Von Neumann Dirac picture.
Then there's this rather different formalization of the foundations of quantum mechanics that's due to Samson Abramsky and Bob Kocher, which is categorical quantum mechanics, where the idea is you say actually the spaces of states, those are secondary and what really matters are quantum processes. What matters are the transformations from one space of states to another. And you describe quantum mechanics purely in terms of the algebra of those processes. So,
And there are many other examples of that. I mean, you know, things like functional programming versus imperative programming or lambda calculus versus Turing machines in a sense that these are all instances of, you know, thinking about things in terms of processes and functions rather than in terms of states and sets. I view constructor theory as being the kind of processes and functions version of physics, whereas traditional mathematical physics is the kind of sets and structures version of physics.
I'm in a sense the the the hypergraph dynamics view slash willful model. Yes, you have you want to describe it and is one that nicely synthesizes both cases because in the hypergraph dynamics case you have both
The internal structure that you have an actual hypergraph and you can look inside it and you can talk about vertices and nodes and things like that, vertices and edges and so on. But you also have a kind of process algebra because you have this multi-way system where I apply lots of different transformations to the hypergraph and I don't just get a single transformation path, I get this whole tree or directed acyclic graph of different transformation paths.
And so then i have so in the sense you can imagine defining an algebra and we've done this in other in another work where you know you have a kind of a rule for how you compose different edges in the in the multi-way system both sequentially and in parallel.
And you get this nice algebraic structure that happens to have a category theoretic interpretation. And so in a way, the pure hypergraph view, that's a kind of set theory structural view. The pure multi-way system view, that's a kind of pure process theory category theoretic view. And then one of the kind of really interesting ideas that comes out of thinking about physics in those terms is the general relativity and quantum mechanics emerge from those two limiting cases.
Right, so in a sense, if you neglect all considerations of the multiway system and you just care about the internal structure of the hypergraph and the causal graph, and you define a kind of discrete differential geometric theory over those, what you get in some appropriate limit is general relativity for some cases.
On the other hand, if you neglect all considerations of the internal structure of the hypergraph and you care only about the process algebra of the multi-way system, what you get is categorical quantum mechanics. You get a symmetric monoidal category that has the same algebraic structure as the category of finite dimensional Herbert spaces in quantum mechanics. And so, in a sense, the
Traditional physics, which is very structural, gives you one limit, gives you the general relativistic limit. The kind of more constructive theoretic view, which is more process theoretic, more category oriented, gives you another limit, gives you the quantum mechanics limit. Yeah, and do you need a daggersymmetric monoidal category or is the symmetric monoidal enough?
You do need it to be dagger symmetric. That's a very important point. So I'm going to assume not all of your followers and listeners are card carrying category theorists. So just as a very quick summary of what Kurt means by dagger symmetric. So actually, maybe we should say what we mean by symmetric monoidal. So if you have a category, if you just think of it as some collection of simple processes, like in the multi-way system cases, just individual rewrites of a hypergraph.
Then you can compose those things together sequentially, you can apply rewrite one then rewrite two and you get some result. There's also a case where you can do that in any category. There are also cases where you can apply them in parallel, you can do rewrite one and rewrite two simultaneously and in a multi-way system that's always going to be possible. And then you get what's called a monoidal category or actually a symmetric monoidal category if it doesn't matter which way around you compose them.
And that kind of generalizes the tensor product structure in quantum mechanics. And then you can also have what's called a dagger structure. And so the dagger structure is a thing that generalizes the Hermitian adjoint operation in quantum mechanics, the thing that gives you time reversal.
So in that case, then you have some operation that you can take a rewrite and you can reverse it. And for the hypergraphy writing rules, there's a guarantee that you can always do that. There's yet another level of structure, which is what's called a compact closed structure, which means that you can essentially do the analog of taking duels of spaces. So for those of you who know about quantum mechanics, that's the generalization of exchanging bras for kets and vice versa.
I'm and again you can do that for in the case of hyper graphs there's a natural duality operation because you can you can it for any hyper graph you can construct a dual hyper graph whose vertex set is the hyper edge set of the old set of the old hyper graph and use hyper edge set.
Is the incident structure of those hyper edges in the in the new case and that's a that gives you a duality that satisfies the axioms of compact closure. So you so and yeah in a sense the the the key idea behind categorical quantum mechanics is that if you have one of these daggers structures you have a compact closed structure you have a symmetric monoidal structure and they're all compatible then what you've got is again by analogy to topos theory some mathematical structure which is
You know in which you can build a theory that is isomorphic to quantum mechanics and that's what we have. Yeah, that's what that's what we have in the case of multi-way systems. So when we spoke approximately three years ago, I believe we had a zoom meeting. It could have been a phone call. I recall that you were saying that you were working maybe the year prior on something where
Your operators, your measurements don't have to be self-adjoint. And the reason was self-adjointness is there because we want real eigenvalues. And that just means for people who are listening, you want to measure something that's real, not imaginary. What is an imaginary tick that usually comes down to ticks or not ticks and the measurement device. But then I recall you said that you were working on constructing quantum mechanics with observables that weren't
So self-adjointness is required. Sorry, self-adjointness implies real eigenvalues, but there were other ways of getting real eigenvalues that aren't self-adjoint. I don't know if I misunderstood what you said or if I'm recapitulating incorrectly, but please spell out that research if this rings the bell to you. So your memory is far better than mine. So that's that sounds like a very accurate summary of something I would have said, but I actually have no memory of saying it. So but yes, no, it's
Yes, so and to be clear, that's by no means my idea. So there's there's a field called PT symmetric quantum mechanics and sometimes known as non Hermitian quantum mechanics, which have various developers. Carl Bender is one of them. I think there's a guy called Jonathan Brody. Oh, hey, Brody. I can't remember Carl Bender. So I just spoke to him about a couple of months ago, coincidentally.
Oh, well, you should have asked him this question. Yes. So Bender and Brody and others. Dohey Brody. I don't know why there's another person. Maybe Jonathan Keating is involved somehow. But anyway, so it's been a little while since I thought about this, as you can tell. But so, yes.
There's a generalization of standard unitary Hermitian quantum mechanics. As Kurt mentioned, in the standard mathematical formulas of quantum mechanics, your measurements seem to be Hermitian. When you take the adjoint of the operator, you get the same result. And your evolution operators seem to be unitary, so that when you take the adjoint, you get the time reversal of the result.
I'm in a sense that's the key difference between evolution and measurement in standard for some and we know that if you're. Operate your hamiltonian is commission.
Add the thing that is in the equation that's a mission operator then the solution to the equation that gives you the military evolution that gives you a solution operator sorry is guaranteed to be unitary and also the values of the measurement operator which is which is cut said in a sense the those your measurement outcomes those are guaranteed to be to be real.
That's a sufficient condition hermiticity but it's not a necessary one so that you can have non permission measurement operators that still give you real eigenvalues. And where you don't get a unitary evolution operator. In the algebraic sense but you get what is often called physical unitarity.
Unitarity means a bunch of things. Algebraically, as I say, it means that when you apply the adjoint operator, you get the time reversal. Therefore, if you take a unitary evolution operator and it's adjoint, you get the identity matrix or the identity operator. So as soon as you have non-hermitian Hamiltonians,
Ceases to be true and also you end up with probabilities so in in the interpretation where your quantum amplitudes are really kind of related to probabilities right where you take the you know you take the absolute value of the amplitude squared and that gives you the probability now as soon as you have non unitary evolution operators your probability amplitudes are not your probabilities are not guaranteed to sum to one so that looks on the surface like it's completely sort of you know hopeless um but
Actually, you can still get real measurement outcomes. The interpretation of the norm squareds of the amplitudes as being probabilities, that's simply an interpretation. It's not mandated by the formalism. And what people like Bender and Brody showed was that you could still have a consistent theory where you have parity time symmetry. So you still have a time symmetric theory of quantum mechanics. It's still invariant under parity
Transmissions and it's still possible even when you apply one of these non unitary evolution operators to to to some initial state it's still always possible to reconstruct what the initial state was from the final state i mean that's really what time symmetry means and so.
It was widely believe i think for a long time that if you didn't have amplitude is normal squared some to one then you wouldn't be able to do that and what bender brody shows no you can you have to be you still have restrictions but just weaker than the restrictions we thought existed. I was probably bringing that up because at the time.
Okay, two reasons. One was, it turns out there are these nice connections, which I was a little bit obsessed with a few years back, between PT-symmetric quantum mechanics and the Riemann hypothesis. So a colleague of mine, a former colleague of mine from Wolfram Research, Paul Abbot, was the person who actually told me about this. And so the idea there is there's this thing called the
Okay, let me get this right. So there's a thing, there's a thing called the Hilbert-Pollier conjecture, which is the conjecture that we have, which I think is reasonably well known. I would like at least some people, people in our kind of area have often heard about. Yeah, which is the idea that somehow the non-trivial zeros of the Riemann zeta function should be related to the, to the, to the eigen spectrum of some manifestly self adjoint operator.
um, and so it's somehow a connection between the analytic number theory of, of, you know, the zeta function and the kind of foundation, the operator theoretic foundations of quantum mechanics. And then, uh, there's the thing called the Berry Keating Hamiltonian. Uh, so Mike Berry and Jonathan Keating constructed, uh, a case of what they conjectured to be a Hilbert polio type, um, a type Hamiltonian. So, so in other words, a Hamiltonian where if you could prove that it was manifestly self adjoint, um, it would be equivalent to proving the Riemann hypothesis.
The problem is that Hamiltonian is actually not, it's not self adjoint, it's not Hermitian in the traditional sense, but it is Hermitian in this PT symmetric sense. So it's not algebraically Hermitian, it's not equal to its own adjoint, but it's still a valid Hamiltonian for parity time symmetric quantum mechanics.
I'm and so by trying to think about the hypothesis in terms of quantum formalism you end up being kind of inevitably drawn into thinking about non commission foundations and these kind of symmetric formulations that's how i. Let's learn about this nice expect i was talking about the time party because i was just interested in that connection.
It turns out that the the spectrum of these operators are related not just to the receipt to the reman zeta function but also to what's called the hovitz zeta function and and and several other uh objects in analytic number theory but also at the time this is turned out to be false but at the time i thought that the version of quantum mechanics that we would end up with from these multi-way systems would be a pt symmetric
Formalism for quantum mechanics not standard quantum mechanics as it turns out Actually, there's a way you can do it where you get standard quantum mechanics complete with proper hermeticity and unitarity So you don't really need to worry about that But at the time I was quite nervous that we weren't gonna get that but we were gonna get some weird non Hermitian version of quantum mechanics We'd have to worry about that. Do you end up getting both or just one? So there is a construction where you can get I mean like
What i want to stress is that there's no you know there's no canonical if you just give it a multi-way system and you said derive quantum mechanics right there's no canonical way to do that okay the the approach that we ended up taking was to show that as i say that there's this algebraic structure that has this dagger symmetric compact closed monoidal category feature and therefore you can get standard quantum mechanics because standard quantum mechanics is what's developed kind of internal to that category.
So just as an aside, a pedagogical aside for the people who aren't mathematicians or physicists, they hear terms like closed, compact, symmetric, monoidal, dagger, unitary, adjoint,
And they're wondering, why are we using these words to describe physical processes? And the reason is because the mathematicians got there first. So physicists are trying to describe something and then they see that there's some tools invented by other people, goes by other names, and then they end up applying in the physical situations. But when the physicist gets there first, they're often intuitive names, momentum, spin up, spin down. It's actually, it makes more sense.
So just in case people are wondering, this terminology is needlessly complex. Well, it can be to the outsider, but as you become familiar with them, you just realize historically, if you want to communicate to mathematicians and vice versa, then just use whatever terms were invented first.
I would say there's the opposite problem as well. There are cases where physicists discovered concepts first that have been subsumed into mathematics and the physical names don't really make any sense in the mathematical context. There are things like physicists, because of general relativity, were really the first people to seriously think about and formalize notions like torsion in differential manifolds and concepts like metric affine connections. The standard connection that you define on a manifold with torsion
Is the spin connection so named because it was originally used in these metric affine theories where you have a spin tensor that describes the spin of particles but so now that you know that there are these ideas in algebraic and differential geometry called spin connections and spin holonomies and I'm nothing to do with spin nothing but I just you know it's just been you know it's the it's the relic of the kind of physical origins of the subject there are several cases of that too yeah I haven't announced this and I'm not sure if I'll end up doing this I've been writing a script for myself
On words that I dislike in physics and math, sometimes they'll say something like, what's the callback? What is it called? The callback, callback, libeler, callback, wibler diversions. Okay. If you just say that it doesn't mean anything, you have to know what it's defined as. So calling something the earth movers distance is much more intuitive.
And then I have this whole list of words that I say, okay, it's so foolish to call it this. Why don't you just call it by its descriptive name? And then I suggest some descriptive names and there's another class of foolish names to myself. Torsion is one of them, but it's not because it's a bad name. It's because it's used in different senses on an elliptic curve. There's Torsion, but it has nothing to do with the Torsion in differential geometry, which as far as I can tell, maybe you can tell me the difference here that in cohomology,
There's torsion, where if you are using the field of the integers, and then you go to the reals, if they're not equivalent, then you say it has torsion. Yes, yes. Same as the differential geometric torsion, as far as I can tell.
I think that's true, yeah. So I think that confusion has arisen because it's one of these examples of like, you know, independent evolution. So there was a notion of torsion that appeared in group theory, but then because of that got subsumed into, as you say, things like homology theory and cohomology theory. So in group theory, a group is defined as being torsion if it's
If it has only finite generators, generates a finite order, so the generators of a group, the things that you multiply, you exponentiate to get all elements of the group, if there are
If the group is generated only by generators of finite order, then you say it's a torsion group and you can talk about torsion subgroups or you could talk about the torsion part of group. And so, yeah, it appears a lot in the theory of elliptic curves, because, you know, there are things like the the model of a theorem that are talking about, you know, when you when you take rational points on elliptic curves, you can ask about how large is the torsion part, how large is the non torsion part. And there are things like butchers, winners and dire conjecture that are all about relating those ideas.
But then yeah then quite independently there was a notion of torsion that appeared in differential geometry that as you know is that you know it's just essentially it's a measure of you know i have points x and y how much how different is the distance from x to y and the difference from y to x and and the name there comes from the fact that in the classical kind of gaussian theory of of geometry of surfaces uh it's it's really it's the concept that gives you the torsion of of a curve right that you know how much the curve is twisting
Yeah, as far as I know, those two names are unrelated. And as you say, there are these awkward areas like homology theory where it's partly about spaces and about groups. And so it's kind of unclear which one you're talking about. This is a great point to linger on here, particularly about torsion, because I have a video that is controversially titled that gravity is not curvature.
For some context, here's the String Theory iceberg video that's being referenced, where I talk about gravity is not curvature. The link is in the description. If you listen to this podcast, you'll hear me say often that it's not so clear gravity is merely the curvature of spacetime. Yes, you heard that right. You can formulate the exact predictions of general relativity, but with a model of zero curvature with torsion, non-zero torsion, that's Einstein Cartan,
You can also assume that there's no curvature and there's no torsion, but there is something called non-metricity. That's something called symmetric teleparallel gravity. Something else I like to explore are higher spin gravitons. That is controversially titled that gravity is not curvature. It's just the saying that there are alternative formulations with torsion or non-metricity. For people who don't know, general relativity is formulated as
Gravity is curvature of space time, but you can get equivalent predictions. If you don't think of curvature, you can think of zero curvature, but the presence of so-called torsion or zero curvature and zero torsion, but the presence of so-called non-matricity. Okay. These are seen as equivalent formulations, but I'm wondering if the Wolfram's physics project or the hyper graph dynamical approach actually identifies one of them as being more canonical.
So, unfortunately, I think, at least based on stuff that I've done, I think the answer is no. And also, I think it actually makes the problem worse. I mean, if you're so if you are, if you're concerned by the fact that there's this kind of there's this apparent arbitrary freedom of do you choose to fix the contortion tensor or the non-matricity tensor or the curvature tensor or whatever. Thinking about things in terms of hypergraphs, you actually get yet another free free parameter, which is dimension.
So in a hypergraph setting, again, I know you've had Stephen on here before, and I know that he's covered a lot of these ideas, so I'll just very briefly summarize. So hypergraphs have no a priori notion of dimension. They have no a priori notion of curvature. You can calculate those things subject to certain assumptions where you say, I'm going to look at, I take a node and I look at all nodes adjacent to it and all nodes adjacent to those nodes and so on. I grow out some ball and I ask, what is the scaling factor of that ball as a function of radius?
I can take logarithmic differences, that gives me the exponent. That exponent is like a Hausdorff dimension. Then I can ask, what's the correction? Is that giving me some leading order term in the expansion? What are the correction terms? Those correction terms give me projections of the Riemann tensor. And that's just using the analogy to kind of classical differential geometry. But the point is that to get the curvature terms, as we do in, say, the derivation of general relativity, you have to assume that the hypergraph is kind of uniform dimensional.
Right. Even to be able to take that Taylor expansion, you have to assume that the dimension is uniform. So then an obvious question is what happens if you relax that assumption?
And the answer is, well, you get a theory that is equivalent to general relativity in the kind of observational sense. But now you can have fixed curvature, fixed contortion, fixed non-metricity, but you also have, you just have variable dimension. And so, you know, the point is that in the, in the expansion for that volume element, the dimension gives you an exponential, it gives you the kind of leading order of exponential term.
The reach scale up coverage gives you a quadratic correction to that and then you have low your higher order corrections. So because of the answer because of this very basic mathematical fact that if you if you're if you're really far if you're zoomed in really far. It's very hard to distinguish an exponential curve from a quadratic curve right you can have to zoom out and see it very globally before you can really tell the difference between the two. And so what that translates to is if you if you're looking only at the microstructure of space time.
There's no way for you to systematically distinguish between a small change in dimension and a very large change in curvature. So if you had a region of space time that was kind of rather than being four dimensional was, you know, 4.001 dimensional, but we were to kind of measure it as though it were four dimensional, it would manifest to us as a curvature change. Yes, it would be indistinguishably observational change. So
So let's go back to category theory for just a moment. When I was speaking to Wolfram about that, Stephen Wolfram, he said that he's not a fan of category theory because he believes it circumvents computational irreducibility.
I said, why? He said, well, because you go from A to B. Yes. Then you can go from B to C, but then you also have an arrow that goes directly from A to C. But when I was thinking about it, that's only the case if you think that each mapping takes a time step. But when I look at category theory, I don't see it as any time step. At least I don't. I see it as just this timeless creation. So please tell me your thoughts. Hear that sound.
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Go to shopify.com slash theories now to grow your business, no matter what stage you're in shopify.com slash theories. Right. Okay. Well, so, uh, I'm, I'm in the fortunate position of having written quite a long paper on exactly this problem. Okay. Um, so, uh, there's a paper that I wrote back in 2022 called a functorial perspective on multi-computational irreducibility.
I'm which is all about the exactly this idea that that's yes or as you say category theory. As it's ordinarily conceived is a is just a kind of algebraic theory that has no notion of there's no there's nothing computational about it right there's no notion of time step there's no there's no statement made about you know what's the competition complexity of any given of any given more for some.
Um, but then an obvious question is, well, okay, is there a version of category theory which does care about those things, the kind of resource limited version or some version where individual morphisms are kind of tagged with computational complexity information? And it turns out the answer is yes. And it has some very nice connections to, uh, not just categorical quantum mechanics, but also things like functorial quantum field theory. Um, but also it gives you a new, it's, I think Steven is
Wrong in that statement that it doesn't care about competition or disability because actually it gives you a very clean way of thinking about competition or disability. So what i mean by that is so i'm gonna use your ability to reduce ability this idea that you know there's some computations that you can't short cut in some fundamental sense.
as far as i know i was the first person to actually give a formal definition of that in a paper back in 2018 or something sorry a formal definition of computational irreducibility of computational irreducibility nothing nothing very profound but just you know essentially you know you say i i've got some turing machine that maps me from this state to that state does there exist a turing machine of the same signature that gets me to the same output state with with fewer applications of the transition function
Sorry, I don't mean to cut you off. So please just remember where you are. Okay.
Because it's my understanding that wolfram said the rule thirty something like that maybe you would recall it more vividly because it's in his book rule thirty is computationally irreducible i've always wondered how do you prove that now i imagine that he proved it or maybe it's one of those wolfram proof so proof to himself but in order for him to prove it even to himself he would have had to have a definition of it.
Right. Okay. So there's an important point that, so rule 30 is not proved to be computationally irreducible. And in fact, there's a prize. So if you go to, I think it's rule30prize.org. I'm ostensibly on the prize committee. This is a prize that Wolfram put out back in 2018. There's actually three prizes, none of which have been claimed. Each one is $10,000. And one of which is prove that rule 30 is computationally irreducible.
I'm and so yeah it's on proven and in fact there's really only one up to. Some of the equivalence is really only one of the elementary cellular automata in nks that's been proven to be computationally reducible in any realistic sense and that's rule one ten.
and that was proved by showing that it's capable of doing universal computation that it's that it's capable of that it's it's a Turing complete rule and so intuitively you can kind of say well if it's Turing complete then you know questions about termination are going to be undecidable and therefore it has to be irreducible but it's a kind of slightly hand wavy thing okay but yeah so so yeah in a way
It's an interesting question. Can you prove that something is computationally irreducible without proving that it's universal? And of course, as you say, for that, you would need a formal definition of irreducibility. Okay, and now going back to your paper on functoriality and computational irreducibility.
you were able to formalize this yes so sorry yes so so um what i was saying was yes so there was this existing formal definition of computational reusability but i then realized that if you think about it from a category theoretic standpoint there's actually a much nicer definition a much less kind of ad hoc definition
Which is as follows. So imagine a version of category theory where your morphisms, as I say, are tagged with computational complexity information. So each morphism has a little integer associated to it. So, you know, you fix some model of computation, you fix Turing machines, and you say, each morphism, I'm going to tag with an integer that tells me how many operations was needed to compute this object from that object. In other words, how many applications of the of the partial transition of the transition function of the Turing machine do I need to apply? So
Now if I compose two of those morphisms together, I get some composite, and that composite is also going to have some computational complexity information. And that computational complexity information is going to satisfy some version of the triangle inequality. So if it takes some number of steps to go from x to y and some number of steps to go from y to z, I can't go from x to z in fewer computational steps that it would have taken to go from x to y or from y to z.
Um, so it's going to, it's going to at least satisfy the axioms of something like a measure, something like a metric space. There's some kind of triangle inequality there. Um, but then you could, you could consider the case where the complexities are just additive, right? Where, you know, to get from X to Z, you have to, it takes the same number of steps as it takes to go from X to Y plus the number of steps it takes to go from Y to Z. And that's precisely the case where the computation is irreducible, right? Cause it's saying you can't shortcut the process of going from X to Z.
Which then means you could define the reducibility, the case of computational reducibility as being the case where this algebra is sub at where the algebra of complexities is sub additive under the operation of morphism composition. And there's a way that you can formulate this as so you take your initial category.
You take a category whose objects are essentially integers and discrete intervals between integers, and then you have a functor that maps each object in one category to an object in another, each morphism in one to a morphism of the other. And then the composition operation in the second category is just discrete unions of these intervals.
And then you can ask whether the essentially whether the cardinality of those intervals is discreetly additive or discreetly sub additive under morphism composition and that gives you a way of formalizing computational disability and the really lovely thing about that is that not only can you then measure irreducibility and reducibility in terms of defamation of this functor.
But it also generalizes to the case of multi-way systems, you can formalize notions of multi-computational ability, but by essentially just equipping these categories with a with a monoidal structure with a tensor product structure. So my understanding of computational irreducibility is either that a system has it or it doesn't, but it sounds like you're able to formulate an index so that this system is more irreducible than another, like you can actually give a degree to it.
Exactly, exactly. So yeah, so there's a kind of there's a limit case where it's it's exactly additive. And anything that's less than that, you know, where the complexities are exactly additive, that's kind of maximally irreducible. But anything less than that is sort of partially reducible, but not necessarily fully reducible. Now, are there any interesting cases of something that is completely reducible, like has zero on the index of computational irreducibility? Is there anything interesting? Even trivial is interesting, actually. Um,
Yes, I mean. Well, OK, so any any computation that doesn't change your data structure, that's just, you know, just a repetition of the of the OK, so forget about the identity operation is going to have that property. I don't. I'm not sure I can necessarily prove this. I don't think there are any examples other than that. I think any example other than that must have at least some minimal amount of irreducibility.
But yes, I mean, this this also gets into into a bigger question that I actually relates to some things I'm working on at the moment, which is exactly how you equivalence objects in this in this kind of perspective, right? Because even to say it's a trivial case, right, where I'm just applying this, I'm applying some identity operation, I'm getting the same object, you have to have some way of saying that it is the same object. And that's actually I mean, that sounds like a
Simple thing but in it's actually quite a philosophically thorny issue right because you know in a very simple case you could say well okay so first thing to say is
Everything we're talking about at the moment, this is all internal to this category, which in the paper I call comp, this category whose objects are in a sense elementary data structures and whose morphisms are, the morphisms that generate, that freely generate this category are elementary computations. And so the collection of all morphisms that you get from compositions are essentially the class of all possible programs.
So within this category, when two objects are equivalent, and therefore when two programs are equivalent, is a fairly non-trivial thing, right? So you can imagine having a data structure where nothing substantively changes, but you've just got like a time step or something that goes up every time you apply an operation. So it just increments from one, two, three, four. So in that case, you're never going to have equivalences every time you apply an operation. Even if the operation morally does nothing, it's going to be a different object. So even that would show up as being somehow irreducible.
But there are also less trivial cases of that, like with hypergraphs, right? So with hypergraphs, you have to determine equivalence, you have to have some notion of hypergraph isomorphism, and that's a complicated thing to even to define, let alone to formalize algorithmically. And so you quickly realize that these notions, you can't really separate these notions of reducibility and irreducibility from these notions of equivalencing.
And somehow it's all deeply related to what data structures do you kind of define as being equivalent or equivalent up to natural isomorphism or whatever. And that's really quite a difficult problem that relates to definitions of things like observers in these physical systems, right? If you have someone who is embedded in one of these data structures, what do they see as equivalent? Which might be very different to what a kind of God's eye perspective views as being equivalent from the outside.
So are there close time like curves in wolframs physics project sorry HD project. That's what it that's how it's known right now so yeah that's a really good question right because you know.
In a way it's very easy to say no because we can just we can do that trick that i just you know you just tag everything with a with a time step number and then of course you know you even if the hyper graph is the same the time step is different so you there's no equivalence and you don't in the multi-way system or the causal graph you never see a cycle. But that's somehow cheating right you know and what we can't win when people ask about ctc's.
What they care about is not this very nerdy criterion of, oh, do you actually get exactly equivalent data structures? What they care about is nerdy. Criterions seems to define this entire conversation up until this point. Well, yes, I suppose, you know, you take two people with math backgrounds and get them to discuss stuff. Yeah, exactly. That's going to happen. Right. But yeah, so yeah, what they care about people who care about time travel. Right.
What one cares about is yeah exactly is time travel and and and causality violations and things which which don't necessarily care about your equivalency or care about them and care about it in a slightly different way. Yeah I mean so. My short answer is I don't know because I think I think we can't. My personal feeling is we are not yet at this level of maturity where we can even pose that question precisely for the following reason right so even.
Defining a notion of causality is complicated. So in most of what we've done in that project in derivation, derivations of things like the Einstein equations and so on, we've used what on the surface appears like a very natural definition of causality for hypergraph rewriting. So you have two
Rewrites you know each one is gonna ingest some number of hyper edges it's gonna output some other number of hyper edges those hyper edges have some identifier. And then you can ask okay did this future event ingest edges that were produced in the output of this past event. And so if it did then the future event couldn't have happened unless the past event had previously happened and so we say that it calls the related so the the somehow the if the output set of one has a non-trivial intersection with the input set of another. We say that they're closely related that's a.
Seems like a perfectly sensible definition, except it requires, it has exactly the problem we've been discussing, right? It requires having an identifier for each of the hyper edges. You need to be able to say this hyper edge that this event ingested is the same as this hyper edge that the other event output. But if they're just hyper edges, they're just structural data, there's no canonical choice of universal identifier of UUID. And so what that means is you can have these degenerate trivial cases where, for instance, you have an event that
Adjust the hyper edge changes its uid but doesn't he change anything structurally the graph is still the same nothing is actually changed interestingly but the identifier is different but now any event in the future that uses that edge. Is going to is going to register as being closely related to this other event that didn't do anything right i have a bunch of these spurious causal relations so it's clear that definition of causality isn't quite right.
What's really needed is some definition of causality that isn't subject to this problem, but it's very unclear what that is. I've worked a little bit on trying to formalize that by recursively identifying hyperedges based on their complete causal history. The identifiers are not chosen arbitrarily as random integers or something, but instead each hyperedged encodes in a slightly blockchaining way
A directed a cyclic graph representation of its complete causal history and so then to high bridges are treated as the same if and only if they have the same history of causal relationships in the writing system. And that's somewhat better but again is quite complicated reason about and say it's kind of it's all deeply related to this question of what.
Data structures do you ultimately treat as being equivalent, which is really an observer dependent thing. It depends on the computational sophistication of the person or entity who is trying to decode what the system is doing. It's not the kind of inherent problem property of the system itself. So what do you make of observer theory, which is a recent large blog post by Stephen and a theory, an outlook. So what do you make of it? Yeah, so observer theory really has
It's a rebranding of this thing that's been a feature of the physics project since before we started it, right? So this idea that, yes, exactly, that you cannot sort of consider a computational system independent of the observer that is interpreting its results. And somehow both the computational sophistication of the observer and the computational sophistication of the system have to be factored into that description somehow.
So in a way it's a very natural idea which is which is really the prelude to this work we did on kind of quantum foundations and other things in the context of physics project. I like to think of it as a kind of natural extension of a bunch of stuff that happened in 20th century physics right because of course this is not how those things it's not how these things were viewed at the time but both general relativity and quantum mechanics can in some sense be thought of as being
A lot of traditional scientific models made this assumption that the observer was infinitely far removed from the system they were observing, that they were these kind of omnipotent entities, they didn't have any influence over the systems, they weren't constrained by the same laws. But if you then say, okay, well, maybe the observer has some limitations, maybe they can't travel faster than light, what does that imply?
Well in some if you follow the right chain of logicals action what that implies is general covariance and therefore general relativity that you know as soon as you have a service you can travel faster than light and they don't necessarily agree on the ordering of space like separate events and suddenly you get general relativity.
Equivalently, if you have observers who are constrained by the same physical laws of the systems that they're observing, then what that means is, if you try and measure some property of a system, what happens when you measure it? Well, you have to have some interaction with it, you have to kind of poke it somehow, and the poke that you receive back is going to be equal in magnitude to the poke that you gave to the system.
And so anytime you try and measure some quantity, there's a minimum amount that you have to disturb it. And again, if you kind of follow that chain of reasoning to its logical conclusion, you get at least the kind of Heisenberg picture of quantum mechanics. So in a way, both general relativity and quantum mechanics are, as I say, ways of becoming more realistic about what observers are capable of and ways of coming to terms with the fact that observers are constrained by the same physical laws as the systems that they observe. So observer theory
which i mean i don't i don't think it's yet a theory so i'm not sure it's yes no i'm not i'm sure i i i'm hugely fond of the terminology but uh i mean it's it's a it's a yeah it's a conceptual idea um is really just the kind of computational instantiation of that and you know so my field okay you mentioned before this very interesting thing about geometry that that somehow you know you you have this freedom of
Do you choose to very curvature do you choose to very torsion do you choose to very non-metricity. My feeling is that there's a similar free parameter that exists in our scientific models with regards to the role of the observer. And this is again maybe a point of philosophical departure from between me and Stephen is so.
You have these kind of, you can imagine these two extreme cases, right? You can imagine the case where all you care about is the computation that the system is doing. So you're just building up some, some structure from, from, you know, from, from bottom up rules. Um, and so the observer, so to speak, is just some trivial object that's seeing the data structure and all of the kind of computational burden is being shouldered by the system itself. Um, and, uh, you know, that's kind of, that's the way that the physics project is often presented, right? You just have a hypergraph and it's doing its thing and we kind of, we, we, we perform analysis on it.
And that's one extreme. There's another extreme where you could say, well, maybe the system itself is trivial. You know, the computation is doing is essentially trivial. And all of the sophistication is all the kind of computational burden is shouldered by the observer. So the case of that would be what Stephen refers to as the rule yard, which is really just this, what I was describing earlier, this kind of category of, you know, all possible elementary data structures and all possible computations. And so in that picture,
That's an object that minimizes algorithmic complexity. It minimizes Kolmogorov complexity. The set of all possible computations has the same algorithmic complexity as the set of no computations.
I'm just purely for information reasons and so in that case the actual computation that generates it is trivial. It's trivial to specify but in order to get a particular computational path or in order to restrict down to a particular multi-way system you have to have an observer some generalized observer who is making equivalences between different parts and the sophistication of that observer can be arbitrarily high and so
You have these two extreme cases one one case where the observer is trivial all the computation is being done by the system another case where the system is trivial all the computations being done by the observer. And my argument is these two cases i mean there's no observational way of distinguishing between them and in fact there's the whole interstitial space in the middle where you have some of the burden being sold by the system some of the burden by the observer.
And these are not really things that we can observationally distinguish. And so in a sense, it's a genuinely free parameter in how we construct our models. And I would even go so far as to say that I think in some sense, this argument that occurred in early European philosophy between the kind of empiricists and the rationalists, right, between people like, you know, Locke and Hume on the kind of empiricist side and people like, you know, Descartes and Bishop Barclay and so on, and on the rationalist side.
That's really the kind of this is really the modern version of that same argument right the empiricist saying we need to get the observer out of the picture as much as possible and just describe the systems the rational is saying no no you know what matters is the internal representation of the world and you know the external reality is somehow some secondary emergent phenomenon.
I'm confused so the difference between observation and perception. Because even would say that look because you're an observer of the kind that you are you. Then derive general relativity or have that as a property or quantum mechanics. But then firstly we all don't perceive the same.
And then we also don't perceive quantum mechanics nor general relativity. In fact, in many ways we perceive the earth as being flat and we don't perceive any of the other colors outside of the spectrum of visible light. So it's a painstaking process to then say, well, what are the laws of physics? We have to somehow derive that test that. And then the question is, well, does a cat perceive the same laws? Well, a cat doesn't perceive perceive. This is what I mean. We don't perceive the same. The cat doesn't perceive the same, but presumably
It's on the same field. We're playing on the same field. The cat is playing on the same field of general relativity and quantum mechanics as we are. So sure, our perceptions are different, but then would Wolfram say that our observations are the same, like delineate for me, an observation and a perception. Yeah, that's, that's a really important distinction, right? Because, um, and it goes back to some, some really kind of foundational ideas and in early philosophy of science and, you know, people like
Thomas koon and others who kind of use stress the idea and car popper who stress the idea of theory ladenness of observation right that so. The basic i think in the in the way that you're using those terms i think it's an important distinction right the perceptions are kind of much closer to the just the qualia that we perceive for the quality of the experience and the observations are some kind of interpretation that we give to them.
And so the important point, I think the point that people like Coon and Papa were making with the relatedness is that, you know, we, in a sense, we perceive nothing as it quote really is right? Like any time we, any time we make a scientific observation, we're not perceiving the phenomenon where it's filtered through many, many layers of observation and, and, and, and, and, um,
interpretation and analysis right so you know when we say that we have we have observed we have detected this particle in this particle accelerator what does that actually mean right well it means that i don't know that there was some there was some cluster of photons in this detector that were produced by some Cherenkov radiation which would then you know spot which would then stimulated some photovoltaic cells on the scintillator and you know there are maybe a hundred layers of of models and theories and and and you know
You know additional bits of interpretation. In between whatever was going on in that particle accelerator and the bits of photosensitive cells that was stimulated in the scientists eyes as they looked at the screen and and and so this thing and so if you actually try and trace out. How many levels of abstraction are there between the quote unquote perceptions and the quote unquote scientific observations it's huge right and it only takes one of those to be wrong or you know not or tweaks a little bit.
And suddenly the model you have of the world which is still just as consistent with your own perceptions is completely different right so yeah i think it's important that's an important thing to bear in mind it's. It's a thing in a sense which annoys me a little bit. With regards to some criticisms of.
You know experimental validation because i think people tend to get that's an area where people kind of get confused in terms of that distinction the people say you know it annoys you just a bit only a bit uh well i may maybe i don't have to deal with it as much as you do well no i don't do what i just mean i'm curious if it annoys you more than that or if you're just being polite well i mean it maybe would annoy me if i had if if if i was being confronted with it all the time but you know when when you see occasional
When you see people saying that the multiverse is fundamentally unobservable, that seems to me to make this exactly the mistake that you're characterizing. It's not perceivable, sure, but then most things that we care about in science aren't perceivable. I think David Deutsch has this nice example that no one has ever seen a dinosaur, no one ever will see a dinosaur, will never get a dinosaur in a lab.
If you restrict science to only be about things that we can directly sort of perceive or test in the bar or something then you can make statements about dinosaurs you can make statements about the composition distribution of fossils but you know that's not very interesting release it's you know if you only care about the properties of certain rocks you would be a geologist not a paleontologist. I'm the point is that when we look at the composition and distribution of fossils.
That perceptual data is consistent with a model of the world that logically implies the existence of dinosaurs. And that's really what we mean when we say we have evidence of dinosaurs. So, you know, not that I'm to be clear, not that I'm particularly defending the multiverse view or anything like that. But, you know, there's there's a really important distinction between, yes, the multiverse is not perceivable, which is true. And it's not possible on the basis of perceptions that we can have
To validate a model of the world that is logically consistent with the existence of a multiverse, which is a very different, it's a very different statement and a much more reasonable statement. And yet, you know, in the, in the popular discourse about these things, those are things that often get confused. So, so yeah, it, it annoys me when I see it and, uh, uh, you know, maybe would annoy me more if I saw it more often. Speaking of points of annoyance, what are your thoughts on the state of publishing? So what's your stance on peer review and where
Academic publishing is headed even its current state. Yeah, so, um,
I had the slightly depressing experience recently, I'm not sure whether you've done this, of going to Google Scholar and searching in inverted commas as an AI language model or some other similar thing, and just seeing the sheer volume of papers that have passed so-called peer review in so-called prestigious journals that are just obviously not human written, with no indication of that fact.
And there are obviously plenty of examples, you know, the, the, the, the, the, um, uh, if you go to the Sokol affair and, and, and, you know, other things where, where, you know, this process that on the surface sounds like a very reasonable idea. This, you know, the, the idea that, you know, you, you claim some new result, you get people who know the field to kind of say, yes, that's a reasonable result or no, this is not quite right. Um, that's a perfectly reasonable model. It's just not what peer review actually is in practice. Um, and yeah, it's, it's important to remember as well that.
In a sense the the the modern system of scientific publishing and the modern system of academia was not really designed right like no one sat down and said this is how we should do science just kinda happened right this model of scientific journals and peer review and editors and so on that's.
You can trace that back to a direct extension of the you know these early proto journals like the transactions of the of the of the world society. Which if you go back and look at them were very different to modern scientific jobs right it's always kind of entertaining when you go and read. You know submissions to the transactions of the world society that were made by robert hoek and robert boil and isaac newton and so on because they basically read like blog posts.
They're actually very very informal that you know that they know you have these guys they just going they say you know i did this i did that i you know i mix this chemical with this i saw this thing and then you know my cat knocks my you know not my experiment over and whatever and it's very conversations very discusses.
And yes it was reviewed but you know the review process was much less formalized than it is and you know i'm not saying that something like that could work today i mean science is much more sort of industrialized and so on you could you could you need some kind of more systematic way of processing the volume of scientific literature that's being produced but still.
It's pretty evident that there was never any person who said this is a good model for scientific research and dissemination. This is how it should be done. It just kind of it naturally evolved from a system that really wasn't set up to accommodate what it's become. Another important thing to remember is that the notion of scientific publishing and the notion of peer review
Served a particular served a pair of purposes, which in the modern world have essentially become distinct. So it used to be that the journal publishers served two roles. They were there for quality control because of peer review, and they were there for dissemination because they actually printed physical scripts that got sent to libraries and things in the modern era with things like archive and sci-archive and bio archive and generally, you know, preprint servers and, you know, people able to host papers on their website dissemination. That's which was always the expensive part of journal publishing.
We don't need that anymore, right? We've got that covered. So peer reviews for quality control. So, yeah, exactly. So the real role for journals now is quality control, in my opinion. And the issue with that is that's incredibly cheap because, you know, I review papers as does every other academic and we do it for free. We do it because it's kind of public service and whatever. And it's an important thing to do. So we don't get paid. The people writing the papers don't get paid.
The journals shouldn't need to spend lots of money to print physical copies so really general publication should be not quite free but basically incredibly cheap and it's not right and the reason is because you have these journals who are essentially kind of holding on to this very outmoded model where they're pushing the dissemination part at I would argue at the expense of the quality control part.
And so that's why i've been a great advocate there are these new kinds of journals that are coming out there's one called discrete analysis and a few others that are the so called archive overlay journals which i think are fantastic idea.
Where the idea is we say the content itself is going to be hosted on the archive preprint service. So we don't need to care about dissemination. So that's all incredibly cheap. We just literally post a link to an archive paper. And so all we're going to do is worry about the quality control. And then once you start to think about that, and once you're not bound to having physical copies that have to go to printers and things, you can actually do peer review in a very different and I would argue much more productive way. You can have things like open public, you can have open post publication peer review.
Where rather than pre-publication, the manuscript gets sent to some anonymous reviewers and then they spend six months deliberating and they get the result back and no one ever, no one ever sees it. You can have something where someone posts a pre-print on archive. It goes on an open review site and then anyone in that area or anyone outside the area can come in and say, I don't understand this or this doesn't make sense or this is a great paper or whatever. And then you can kind of up vote down vote. You can say, Oh yeah, I agree with your criticism and et cetera. And the whole thing can be open and de-anonymized.
And it would have to be anonymized by the person who's publishing who's posting it up there because otherwise if people see that Ed Witten posted something more eyes will go toward that but you can also if you're in the field you can discern sometimes who's publishing what. Yeah absolutely and and and and certainly in math and physics in these places where and computer science in places where you know.
In those fields, it's been standard for many decades now, for several decades, that everyone posts their work on archive, right? And they post their work on typically before or possibly simultaneously with submitting their work to a journal. So if you get even if you even have the job, I mean, because of that physics journals, you know, journals like Jay hair or classical quantum gravity, et cetera, they don't even try and anonymize their manuscripts because they know if they anonymized it, you could just Google the first sentence and go find the archive paper and see you posted it. So, yes, I think
So about the journals inflated prices, outside of an oligarchy or collusion, what's keeping it high?
I'm reticent to claim that it's a collusion. A lot of it is tied into the promotion structure in academia. A lot of it is tied into
If you want to get a permanent job in academia if you want to advance up that that ladder you need to get you know there's this general view that you need to get published in the fancy journals and then that means that the journals that are generally perceived by university administrators as being the fancy ones know that they can charge essentially arbitrarily high prices and people will pay them because they kind of because you know their livelihoods depend on yes yes um it's a sort it's a really quite sorted
situation when you think about it. I saw a talk recently by someone who's going into the academic world saying that some of the applications for professorship or postdocship that the second question after what is your name is how many citations do you have and then people try to game this because you can publish something that is just worthy of publication and do that many times rather than produce something that you feel like it's of high quality but will get less citations than if you were to split that up and then you just flood the market.
Yeah, absolutely. And, you know, there are these metrics, there is author level metrics like the H index and so on, which, you know, which measure, you know, so H index equals N means that you have N papers that have been cited at least N times. And that gets used actually quite frequently in hiring committees and tenure committees and things like that. And yeah, it's incredibly easy to game, right? It's this classic Goodhart's law example where, you know,
As soon as you know that you're being measured on that criterion, you can then say, oh, I'm going to just cite myself in all, you know, every future paper I'm going to write, I'm going to cite myself in all previous ones. And then I can very easily get some kind of N squared dependence on my H index. And then I can get my friends to cite me too. And I can, as you say, rather than, you know, rather than investing a year to write this one really good polished definitive paper on this subject,
I'm going to write 10 like salami sliced mini in a minimum publishable unit thing. Yeah, right. That's a great way of saying it.
Right. And yeah, and all of that happens, right? And it requires, I know, I'm guilty of some of that, too, you know, not because I want to be but because, you know, I need to, you know, I live in the academic system, that's kind of how one has to operate to a certain extent, if you're competing with other people who are doing that, it's awful, right? And I don't, I don't want to be in that situation. And, you know, I, yeah, if obviously, if given the choice, I always try to be someone who, yeah, if I'm going to invest the time to write a paper on something, I want to write
In as much as possible, the definitive paper on that thing and have it clean and polished and something that I'm proud of. But yeah, it's I think it's my impression at least is that it's becoming increasingly hard for that to be a viable career strategy. Yeah. What's fortunate in your case is that you were employed by Wolfram for some time. And so you were able to work on the ideas that were interesting to you and not have to concern yourself. Maybe I'm incorrect, but at least from my perspective, you didn't have to concern yourself with incremental publications on ideas that aren't innovative in order for you to build the
credit to your name, but maybe I'm incorrect. Well, I mean, there was certainly an element of that, right? So during the time I was employed at Wolfram, I also was, I mean, initially I was a graduate student, very early stages, I was an undergraduate, then I was a graduate student, and then I was a kind of junior academic. So I still had some academic position during that time. And for that reason,
It wasn't something I could completely ignore, right? Because, you know, that would have been kind of irresponsible from a career standpoint. But yes, in a way, it did take the pressure off because it meant that it meant that I had a kind of more or less guaranteed funding source for at least part of my research. And I wasn't having to repeatedly kind of beg, you know, government funding agencies for more money and things and show them long lists of papers. It was also useful in a different way, which is that it meant that the stuff I was doing got
Much more exposure than it would have done otherwise. I mean, you know, we wouldn't have met, you know, if it hadn't been for Stephen and the kind of the additional, both the additional cache and the additional, uh, flack that is associated with, uh, you know, with having his name attached to the project. And so, yeah, I know in a way it meant that there was four, you know, for my level in the, in the academic hierarchy, my work ended up being significantly overexposed and yeah, that was good in a way. It was bad in another way. Why would it be bad?
Well, it meant that, okay, so one negative aspect of it, which has not been hugely problematic but is, you know,
Stephen has a certain reputation, right? And that reputation is positive in many ways and negative in many other ways. And by, you know, if you are billed as, you know, you are the person what you are the other person or one of the other people working on the Wolfram physics project, you get, there's a, there's a sense in which you're elevated by association and you get tainted by association and people assume that, you know,
Yeah, people assume that many of the negative characteristics associated with, you know, I don't know, not giving appropriate credits to prior sources or having slightly inflated ego issues, et cetera, right? Many of those things kind of get projected on you, rightly or wrongly, but yeah, by virtue of association. Yeah. Or that you're supporting that. So maybe you don't have those qualities. Okay. Right, right. And it's a difficult thing to, I mean, in a way,
It helps because it meant that a lot of the criticism of the project got leveled at Stephen, not the rest of us, right? Yes. So in a way it was useful. But yeah, but in other senses, you know, it was a yeah, it's a delicate balance. So how do you see academics engagement with the ideas from the Wolfram physics project? Yeah, it's been mixed, very mixed. So on the kind of traditional fundamental physics people
It's mostly been, you know, ignored, right? So like, if you look at your average string theorist, many of them will have, you talk to them, many of them will have heard of the project and will say, oh, that's that weird, kooky thing that that guy did. And we don't really know anything about it, right? That's at least that's the general response that I've seen. They'll say they scrolled through the blog post, but then didn't find anything readily applicable to their field. And so they're just waiting for it to produce results. That's the general state, right? Exactly.
Yes, and I've certainly had conversations with people who are not quite so polite.
There's that crowd. There are some people in the quantum gravity community who have actually taken some interest and have started, you know, have cited our work and have used it and it's been incorporated in other things. So causal set theory is one example of a that's again a slightly unconventional branch to quantum gravity that's really quite formalistically similar in a way. Causal sets are really just, you know, they're partially ordered sets. They're really the same as causal graphs in some sense. And so there's a
Precise sense in which you can say that the you know that the hypergraphic writing formalism is just giving you a dynamics for causal set theory which calls us that there does not possess a priori because it's essentially a kinematic theory and so in those communities it's but there's been it's been somewhat more receptive there's been again there are in areas this is essentially unsurprising right so.
In areas where there is formalistic similarity, like say, loop quantum gravity, where there's some similarity in the setup of things like spin networks and spin foams, there's been some interest in these kind of topological quantum field theory models or topological quantum computing models, where again, there's this interest in this intersection between, you know, combinatorial structure, topology, etc. and fundamental physics, there's been some interest. An area where we've got a lot of interest is in applied category theory. So, you know, people who, I would say that's been
At least in terms of the stuff that i've worked on that's been by far our kind of most warm reception are people working on categorical quantum mechanics and particularly these kind of diagrammatic graph rewriting approaches to quantum mechanics like zx calculus and so on. We've had some very very productive interactions with that with that crowd and also with people not directly on the physics side but interested in the formalism for other reasons so there are people like.
The algebraic graph you're writing crowd, many of whom are in areas like Paris and Scotland. Again, you know, have been very interested in what we've been doing, not necessarily again, not necessarily for physics reasons, but because they're interested in the algebraic structure of how we're setting things up, or they're interested in how the formulas can be applied to other things like chemical reaction networks or, or, you know, distributed computing and that kind of stuff. You're currently at Princeton, correct? Right. Okay. So what do you do day to day?
Uh, so mostly I work on computational physics. Um, so I work on, uh, you know, developing, uh, yeah, developing algorithms and things for, for, for understanding physical phenomena through computational means, uh, which is, you know, more or less a direct extension of, uh, you know, of the stuff that I was doing at Wolfram research, but, um, yeah, I'm, I'm in a sense having been associated with the physics project and with Wolfram research for some time. I'm.
I now consider in part my role to be trying to get some of those ideas more deeply embedded in sort of traditional scientific and academic circles. And, you know, not so much tied to, yeah, as you were putting it earlier, you know, Stephen's own personal research dollars and that kind of thing. How do you feel when the popular press almost invariably ascribes all, if not the majority of the credit of the Wolfram physics project to Wolfram himself? Yeah, it's difficult, right? So,
As I say, in a way, there is a positive aspect to that, which is that it means that you're shielded from direct criticism. Right, right. Less likely to be blamed. But no, I mean, yeah, it's emotionally difficult, right? I think, I don't know, maybe not for everyone, but certainly for me, I find it quite psychologically tough if, you know,
If there's an idea that I've had that I'm reasonably proud of or, you know, result that I've proved that I'm reasonably proud of, et cetera, it's not the best feeling to see, you know, headlines and Twitter threads and whatever, where it's all being ascribed to one person. And in my small way, I try to push back against that. But sorry, gone. I love Wolfram. I love Stephen. But so this goes without saying he doesn't do many favors in that regard. So when someone gives him the accolades,
It's rare that I'll see him say, oh, and by the way, that result was from Jonathan Gerrard. Right, right. And again, I guess, you know, we're all guilty of that to a certain extent. I mean, I'm acutely aware that in the course of this conversation, I haven't mentioned, for instance, Manognar Namaduri, who is the person who I kind of did a lot of this work on categorical quantum mechanics with, right, and who deserves, you know, again, a reasonable fraction of the credit for that insight. So, you know, I'm guilty of this too. And I guess everyone is to an extent. Steven,
Maybe more than many people, but but you know, I it's yeah, it's it's it's, you know, that's a feature of this personality that I can't claim to have been ignorant of. Sure, sure. So he has another claim, which is that he solved the second law of thermodynamics. And from my reading of it, I wasn't able to see what the problem was with the second law and how it was solved, other than you say you derive it from statistical mechanics, which was there before.
I must be missing something because I don't imagine Stephen would make that claim without there being something more to it. So please enlighten me. Yeah. Okay. So, uh, I think as with many of these things, um, that, that blog post about the, or that series of three blog posts about the second law, I think was, um, there was interesting, you know, just like with NKS, right? I think there was, there was a lot of interesting stuff there, uh, that they got figured out.
It wasn't quite as grandiose as i think steven made it out to be but you know again that's you know that's part that's that's the responsibility of any scientist right is to slightly inflate the significance of what they're doing but so my reading of it is as follows that uh so there's a there's a kind of standard textbook popular science type way that entropy increase gets explained right which is you know you say uh
If you define entropy as being the number of microstates consistent with a given macrostate or the logarithm of that, which is Boltzmann's equation, then the fact that entropy has to increase is kind of obvious in some sense because the number of ordered states, the number of ordered microstates or the number of microstates consistent with an ordered macrostate is always going to be smaller than the number of microstates consistent with a disordered macrostate.
And so if you're just a godically sampling in your space of states, you're going to tend towards ones which are less orderly and not towards ones that are more orderly. And that argument or that explanation seems convincing for a few seconds until you really start to think about it and you realize that it can't possibly make sense. And one reason, I mean a very foundational reason why it can't possibly make sense is because that explanation is time symmetric, right? So if
If it's the case that you're ergotically sampling your space of possible states, and yes, the less ordered ones are always going to be more numerous than the more ordered ones, then yes, it's true that evolving forwards in time, you're going to tend towards the less ordered ones. But it's also true that if you're evolving backwards in time, you would tend towards the less ordered ones. But of course, that's not what we observe in thermodynamic systems. So that explanation can't be right or at the very least can't be the complete answer.
I think the conceptual problem is a real one. I think it is true that we really don't fully understand the second law of thermodynamics from a statistical mechanical point of view.
When you as soon as you start trying to apply it to more general kinds of systems the problems become worse i mean there's a there's a famous example that you know was brought up by by Penrose of you know what you know what happens when you try and apply the second law of thermodynamics to the early universe and again you get to you seeming get these two contradictory answers that so you know as the universe evolves forwards if we believe the second law things should be getting you know as we as we get further and further away from the initial singularity things should be entropy should be getting higher and higher
And yet when you look back close to the initial singularity and you look at the cosmic microwave background and so on, it looks very, very smooth. It looks basically Maxwellian, like a Boltzmann distribution. It looks more or less like a maximum entropy state.
So we have this bizarre situation where, as you move away from the big bang, entropy gets higher, but as you go towards the big bang, entropy gets higher. So something must be wrong. And, you know, Penrose has these, uh, has these arguments about conformal cyclic cosmology and how, you know, the, the, the role of gravitational fields is essentially to decrease global entropy and all that kind of stuff. But that's all, you know, again, fairly speculative. And I would say at some deep level, that's still a story we don't really understand. So that I think is the problem that's being solved. And, uh,
that that series of blog posts proposes and again this is not really that i mean even hear that sound
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Go to shopify.com slash theories now to grow your business no matter what stage you're in shopify.com slash theories. Even in NKS, there were indications of this idea. But yeah, I mean, the basic idea is that you can explain the time asymmetry in terms of computational irreducibility explain where you say, okay, so even if you have a system whose dynamics are exactly reversible,
In practice, because of computational irreducibility effects, the system can become pragmatically arbitrarily hard to reverse, and that you can think about it essentially as being a kind of a cryptanalysis problem, right? So in a sense, the dynamics of a computationally irreducible system are progressively encrypting certain microscopic details of the initial condition, so that in practice, even if it is in principle possible to reverse from a computability standpoint,
If you try and think about the computational complexity of that operation, it's equivalent to solving some arbitrarily difficult crypt analysis problem to work out, okay, where exactly was that molecule at time t equals zero? And and that goes some way towards explaining this time asymmetry problem. I don't think it's a complete explanation. I think there's I think there's a yet deeper mystery there. But I do think it's an interesting collection of ideas. Yeah. So that's observer dependent. So it would be difficult for you. Sorry, not.
Difficult for anyone, but difficult for an observer, but for the system itself. Yes. Would there still be that issue of having to decrypt for the system itself? Well, no, I would argue not because it's a very important point, right? That these notions are all observer dependent because in a sense, the Boltzmann equation
Requires the existence of a macro of a macro state, right? So, um, and the macro state is a, is an observer. It's a synthetic kind of observer theoretic idea, right? It's like, you know, you've got a bunch of molecules bouncing around in a box. Um, and so they have some micro state details, but then you want to describe that box in terms of gas kinematics. You want to describe it in terms of a density and a pressure and a temperature and whatever. So those give you your macro states, but
The you know the the choice to aggregate this particular collection of micro states and say these are all consistent with a ideal gas with this you know temperature in this idea index whatever that's an observer dependent thing and so yeah and that's another point that again i don't think it's completely original but i think has not been adequately stressed until these blog posts which is that different definitions of an observer will yield different definitions of entropy different choices of coarse grainings yield different choice different definitions of entropy
And therefore, you know, in that sense, it's kind of unsurprising that, you know, as Von Neumann and Claude Shannon and people kind of pointed out that, you know, the term entropy is so poorly understood and that there are so many different definitions of it. There's entropy in quantum mechanics, there's entropy in thermodynamics, there's entropy in stat mech, there's entropy in information theory, and they're all
Similar similar vibes but the formally different and you can have situations where one entry measure is increasing one entry measures decreasing and that becomes much more easy to understand when you realize that they are all measures of entropy relative to different formalizations of what it means to be an observer. And yes with regards to the to the decryption thing. Yes i would say.
There's an aspect of it that is fundamental, that is purely a feature of the system. Even if you don't have any model of the observer and you're just looking directly at the data structures, you can have the situation where the forward computation is much more easy or much more difficult than the reverse computation. And obviously those kind of one-way functions, those get used in things like cryptography, right? And the existence of those is quite well studied in cryptanalysis. So those certainly exist and those can give you some form of time asymmetry.
but arguably the version of time asymmetry that's relevant for physics is the observer dependent one. It's the one where you say actually, you know, in this particular, for this particular aggregation of micro states and this particular interpretation of that aggregation as this macro state, this is the computational complexity of the reversal operation. And that is an observer dependent thing. You mentioned Penrose and I want to get to some of your arguments. I don't know if you still have them, but I recall from a few years ago, you mentioned that you have some issues with Penrose is non computational mind.
argument. So I want to get to that, but I want to say something in defense of Stephen, that people don't realize what it's like when you're not in academia to one, get your ideas taken seriously by academia. And then also what it's like in terms of funding. So people will say that, yeah, sure. Stephen is rather montate or self triumphant, but you have to be that to the public because that's your
funding source. Whereas for the academics, they are that to the grant agencies, to the people they're asking for money, you have to big yourself up. It's just that you don't get to see that. Yeah, I know. I absolutely agree. Great, great. Now for Penrose, please outline what are your issues with I think it's the Penrose Lucas argument, although I don't know if Penrose and Lucas I know Lucas had an argument is called the Penrose Lucas argument. I don't know their historical relationship.
Right, right. And yeah, there's an original argument that's purely using kind of mathematical logic and Turing machines and things. And then there's the Penrose-Hameroff mechanism, right, which is the proposed biochemical mechanism by which there exists this non-computability in the brain. Yeah, I mean, so, okay, there's an... Okay, how to phrase this.
There's an element of this which I'm quite sympathetic to which goes back actually to the one of the very first things we discussed right which is the distinction between you know what is model versus what is reality Turing machines are a model. Yes. And so if you say well the mind is not a Turing machine.
I mean if that's the if that's your only statement then i agree right but then nothing you know like the universe isn't a turing machine in that sense right and the question is is it useful to model the mind is a turing machine or is it used to model the universe as a turing machine and there i think the answers emphatically yes. And you know okay are you going to be able to model everything well not necessarily so again.
To that extent, I do have some sympathy with the Penrose-Lucas argument that I'm open to the possibility that there may be aspects of cognition that are not amenable to analysis in terms of Turing machines and lambda calculus and that kind of thing. I just don't think that the particular examples that Penrose gives, for instance, in his book, Emperor's New Mind, are especially convincing examples. I mean, he has this argument that mathematics
The process of apprehending mathematical truth must be a non-computable process because we know from Gödel's theorems that
For any given formal system, if it's consistent, then there must be statements that are independent of that system, where both the statement and its negation are consistent with the underlying axioms. Gödel's original argument proved that for piano arithmetic, for the standard axiom system for arithmetic, and later on it was discovered it works for any axiom system that's at least as strong as piano arithmetic.
And so Penrose's argument, I mean, I'm caricaturing a bit and it's a little unfair, but, you know, the basic argument is, well, we can obviously see that arithmetic is consistent. So when we construct this girdle sentence that says this statement is unprovable, we can see that it has to be true. And yet, you know, within the formal axioms of arithmetic, as they are computable, it cannot be decided in finite time that that statement is true.
And okay so most of that is correct but the part where you say well we we as we as human observers can clearly see that that statement is true well that presupposes that we are able to you know we are able to know the consistency of integer arithmetic which we have strong reason to believe is consistent but.
Goodell's second incompleteness theorem says that, well, we can't know that formally either. So in a sense, he's he's presupposing the conclusion. He's already presupposing that we can know the truth value of an independent proposition, namely the consistency of Piano arithmetic in order to prove that we can know the truth value of another independent proposition, namely this good sentence. And so for me, it just feels extremely circular. So it doesn't. Sorry, can you not use like what if he didn't say that it's irrefutable?
Rather that probably so far it seems like piano arithmetic is consistent and if it was to explode it'd be so odd that it hasn't exploded already and we've explored it quite extensively every day we increase our credence and the consistency of it can you not use an argument like that.
He absolutely could and that and that would be correct but then the problem with that is there's nothing in that argument that a computer could not replicate right a machine could also make that same argument you could also write computer program that says okay i'm gonna test loads of propositions in piano arithmetic and and see whether i find a you know an inconsistency and the more propositions i test uh you know the the less likely it is that the piano arithmetic is inconsistent so i can construct
This is machine speaking here i can construct some kind of basic argument that says you know i'm this level of confident that this proposition is true so yes human beings can can can do that kind of basic reasoning but then so can machine and so that the crux of the pen rose argument is openers lucas argument is that.
You know there is there is this additional non-computable step where the human somehow knows not assumes but just knows that piano arithmetic is consistent and from that deduces that he has to be true and I I don't see how you can justify that without essentially presupposing the conclusion. So what's the difference between intuitionist logic and constructivist logic. Okay that's a fantastic question so and and cycles back to the stuff we were talking about the beginning with regards to like constructivist foundations for physics right so
I would say, so constructivism is really a kind of broad, okay, the simple answer is intuitionistic logic is a special case of constructivist logic. So constructivism is a broad philosophical movement where the idea is, so okay, for the people who don't know the history of this, so in the aftermath of Gödel's incompleteness theorems and Tarski's undefinability theorem and Turing's proof of the undecidability of the halting problem and all these limited results in mathematical logic that happened in the early 20th century,
People started saying, okay, well, how can we trust that anything is true in mathematics, right? So if, if we always have to make some unprovable assumption about the consistency of our axiom system, how can we ever be confident of anything beyond just the kind of heuristic Bayesian argument that we made before? Um, and so then, uh, various people like, especially a guy called Brower and later, you know, in his lazy years, David Hilbert, um, cotton on the idea that, okay, what you could do is you could say, well, um, if we,
Strengthen our criterion for mathematical proof. If we say that when you reason about a mathematical object, it's not enough just to reason about it abstractly. You actually have to give an algorithm, a finite deterministic procedure that constructs that object before your statements can even make sense. That's a much stronger condition and it immediately rules out certain forms of mathematical proof. So for instance, a proof by contradiction, it would not be allowed in such a paradigm because if you prove a statement, okay,
So obviously, suppose I want to convince you that this equation has a solution. So one way I could convince you is to make a proof by contradiction. I could say, assume it doesn't have a solution and then derive some piece of nonsense. My assumption had to be wrong. But you can prove existence without construction. Right, right. But that only works if I assume that the axiom system I was using to prove that is consistent and that the inference rules I was using to derive that contradiction were actually sound.
If they weren't, if it was an inconsistent system or the inference rules would not sound, then I could derive a contradiction even from a statement that was true, and so it would be invalid. And of course we know from Gödel's theorems and from Turing's work that we cannot for any non-trivial formal system know conclusively that the system is consistent or that the inference rules are sound.
i'm whereas instead if i try and convince you by saying look here's a program here's an actual algorithm that constructs a solution for you and you can just go and check whether it solves the equation somehow that's much more convincing you don't have to assume anything except that maybe the validity of the model of computation but you can check that too right so there's no you're placing a much lower kind of um
Epistemological burden on the underlying axioms of mathematics you can use those to guide you in how you search for things but ultimately the ultimate criteria and the ultimate test for truth is can you define a mathematical deterministic algorithm that actually witnesses the structure that you're talking about.
And so this was intended to be a kind of almost a get out clause, you know, from these limited of results to say this is a way that we can kind of bypass many of these, not all of them, of course, but many of these issues. Now, it's a very, very significant limitation because it immediately means that there are very large classes of mathematical structures that you just can't talk about at all. You know, the structures where you can't avoid undecidability and independence.
But rather astonishingly, there are large parts of mathematics, including areas like analysis, which you maybe wouldn't have thought would be amenable to constructivism, where many of the most interesting results, you know, the Heine-Barrell theorem or whatever, right, you can actually prove using purely constructivist means. So that's really what constructivism is about. Then intuitionism, which is a particular flavor of constructivism that's due to Brouwer.
What once you decided that you want to work in construction is mathematical foundations and then you still have the problem of what am i what my underlying rules going to be what what how do i actually impose those constraints in a systematic way. And so intuition is just one approach to doing where you say okay. I want to outlaw non constructive proofs like proof by contradiction how do i do that.
Well, uh, one, you know, what's the one thing that should be outlawed is any use of double negation. So the, the, the axiom of double negation that not, not X is equivalent to X. I shouldn't be able to do that because that allows me to do non-constructive proofs. And it turns out that if you're going to outlaw that you also out need to outlaw what's called the law of excluded middle, the statement that a or not a is true for any proposition that you, you, you, you, sorry, you need to outlawed or is equivalent to outlawing that. Uh, it's equivalent to it was here. So, so, so one, one necessitates the other.
And and then you know in the kind of logical foundations that's what you need to do and then that implies certain things like that say the axiom of choice in set theory read the statement that if you have a collection of if you have some collection of non empty sets.
Is that the root of the word intuitionism? Like is it actually meant to say that this is more intuitively the case?
These were meant to be the minimum rules that somehow, yeah, I mean, in a way, yes, these are meant to be kind of the minimum conditions that that matched human mathematical intuition. Yeah, I don't know. I know there's a whole history of, like I mentioned, I want to do a whole video on my gripes with names. So it could be something philosophical about content intuition. I have no clue. But do intuitionists not have a concept of infinity? Because you mentioned Heine-Barrell. And so it's not embedded in that the
Right, right. If you say you can do analysis, I don't understand how that can be done. Yeah, okay. This is a really important point. So
I mentioned that intuition is just one flavor of constructivism and there are many others and there are ones that are more or less strict. So there's a stricter version of constructivism called finiteism, which is exactly that where you say, not only am I going to be constructivist, but my algorithms have to terminate in finite time.
If you're an intuitionist and you're not and you don't subscribe to the kind of finite is my day you might say well i can write down an algorithm that solves this there is a deterministic procedure but it may not necessarily terminate in finite time so you know i mean the the you know an example that would be the integers right so with the integers.
I can write down an algorithm which provably constructs the complete set of integers. That algorithm doesn't terminate. If I were to run it on a finite machine it wouldn't terminate. But any given integer can eventually be derived by just repeatedly applying that procedure.
I'm so you could so there is actually a way subject this kind of weaker version of intuition ism there is a way you can reason about infinite mathematical structures but if you then say oh no i'm not gonna allow myself to do that i want all of all my you know all the deterministic procedures that i write down.
I like it. I don't believe in it, but I like it. Well, again, it's it's it's this question of what do you mean by belief, right? I mean, if if
If mathematics is intended to be a kind of tool set for modeling certain processes of thought, then, you know, there are there are certain kinds of problems where I think it's useful to take a finite or ultra finite mindset. Yeah, I agree. If you if you're a mathematical Platonist, which I'm not, then you might say, Okay, well, I believe that the mathematical universe is much larger than, you know, in some logical sense than the universe that's conceived by ultra finiteists. But
What do you believe to be the primary difficulty between combining general relativity and quantum mechanics?
Right. So that's been formulated in many ways. I mean, so I'm going to having having just sort of slightly slated Penrose for his for his consciousness views. Let me let me let me try and write that wrong a little bit by saying I think Penrose has a really, really nice argument for why even just at a conceptual level, quantum mechanics and general relativity are incompatible, which is the following that that if you take the two of the most foundational principles,
In a sense delineate how quantum mechanics is different from classical mechanics and how general relativity is different from classical mechanics. Those would be the superposition principle in quantum mechanics, the principle that if you have a system that can be in this eigenstate or this eigenstate it can also be in some complex linear combination of them.
And on the side of the equations of general relativity it's the principle of equivalence rates the principle that accelerating reference frames and gravitational reference frames are really the same or to translate that into slightly more mathematical terms that you can that anything that appears on the left hand side of the field equations in the Einstein tensor you can move as a negative contribution to the right hand side in the stress energy sensor. So. Penrose has this really nice argument for why those two principles are logically inconsistent and the argument goes like this that so
Suppose that you've got something like a Schrodinger-Capps type experiment where you've got a robotic arm that contains a mass at the end that's producing a gravitational field and it's connected up to radioactive nucleus that has some probability of decaying. So that arm can be in one of two positions. It can be position A, position B, and the position that it's in depends on the quantum state of that nucleus. So now, just naively, what you appear to have done is created a superposition of two different gravitational field configurations.
Okay, so if you do that, you can write down the wave function that corresponds to that superposition and everything looks just fine. So far, there's no problem. But then if you believe the equivalence principle, then you should get the same wave function if you then do the same calculation in an accelerating frame. So if you take that whole desktop apparatus and rather than doing it here on the Earth, you do it in a spaceship that's accelerating at 9.81 mps² and you have exactly the same experimental setup with the same robotic arm,
You should get the same way function. What if you calculate it which you can it's just a standard calculation in a realistic quantum mechanics you get almost the same answer. The two way functions differ by a face factor. Which normally wouldn't be too much of a problem normally you know if they don't buy a face back to you say that they're somehow the same quantum system yes but the face factor depends on time to the power for. And because.
Of some slightly technical reasons that have to do with the fact that quadratics have two solutions, if you have a phase factor depends on time to the power four, that's telling you that the wave function you've written down corresponds to a superposition of two different vacuum states.
And one of the core axioms of quantum mechanics is that you can't superpose two different vacuum states for the very simple reason that the vacuum state is the kind of zero point from which you measure energies, you know, using your Hamiltonian. So if you have a superposition of two different vacuum states, there's no longer a uniquely defined Hamiltonian. There's no longer a defined energy because there's no, there's no rule for how you superpose those vacua.
So it is inherently illegal in quantum mechanics to produce the super positions so somehow by by just assuming that you could superpose gravitational fields you've been able to use the equivalent principle to violate the the superposition principle off. Equivalently vice versa. There's a more mathematical way of seeing the same thing which is to say that okay so.
At a very basic level, quantum mechanics is linear and has to be linear by the Schrodinger equation. The Schrodinger equation has to be linear because of the superposition principle. So if I have two solutions to the Schrodinger equation, then a complex linear combination of those states with appropriate normalization has to also be a valid solution to the Schrodinger equation. General relativity is nonlinear and has to be nonlinear because, in a sense, if you take the Einstein field equations and you linearize them, you linearize the gravitational interaction,
Then what you get is a version of general relativity that doesn't possess gravitational self-energy. So in other words, the reason why general relativity is a nonlinear theory is because in Newtonian gravity, if I have a mass, that mass produces a gravitational potential. But the gravitational potential doesn't produce a gravitational potential.
But in general relativity because of the mass energy equivalence, I have a massive producer gravitational potential, but that gravitational potential has some energy associated to it. So it also produces a gravitational field and that produced another gravitational field and so on. So there's actually a whole infinite sort of sets of these smaller gravitational fields that are being produced. So this is often summarized as the by the slogan that gravity gravitates.
And that appears as a nonlinear contribution to the Einstein field equations, these off diagonal terms that appear in the Einstein tensor. And so it has to be nonlinear because if you were to take two solutions to the Einstein equations, two metrics and just try and add them together, you quite clearly wouldn't get a third solution to the Einstein equations in general, because what you've done is you've added the gravitational potentials, which is really what the metric tensors are indicating. But you haven't incorporated all these additional nonlinear contributions
So the basic problem is that you can't superpose gravitational fields, right? And that's really what the Penrose argument is kind of indicating, that if I try and take two metric tensors and just add them in a way that's consistent with the Schrodinger equation, I'll violate the Einstein field equations. And if I try and take two solutions to the Einstein field equations and combine them in a nonlinear way that's compatible with general relativity, I'll violate the linearity of the Schrodinger equation.
Does the conceptual difficulty still persist in the quantizing linearized general relativity?
So my understanding is that you can certainly get further with quantizing linear. So if you just linearize your gravitational interaction, you can not only evolve quantum fields on top of a curved space-time described in terms of linearized gravity, which you can do for Einstein gravity,
But you can also describe the back reaction of the quantum fields onto the metric tensor. I actually don't know how much further than that you can go. I suspect, but what I do know is that it's definitely a lot easier. You can make much more rapid progress with quantizing gravity if you assume linearizations than if you don't. I think there are still some problems that persist, but I think they're nowhere near as difficult. So how is it that higher category theory overcomes this? That's a great question.
I don't know but there's a very tempting kind of hypothesis. I mentioned towards the beginning that there are these category theoretic models for quantum mechanics and I even mentioned briefly that there are these models for quantum field theory as well. And the way that that works is, so we talked at the start about these dagisymmetric compact closed monoidal categories,
Which are the kind of the basic mathematical set up for categorical quantum mechanics the problem with that though is that every time you apply one of these morphisms every time you apply one of these time evolution operators you are essentially.
picking out a preferred direction of time right you are assuming you've got you know if you imagine each of your quantum state each of your space of states is a space of states on a particular space like hypersurface when you once you construct a unitary evolution operator that's a solution to the shredding equation you are selecting a preferred direction of time which is of course not relativistic that's not covariant.
So to go from the non-relativistic version of quantum mechanics to a version that's compatible, at least with Lorentz symmetry, you need to have some systematic way of transforming one time direction to another. Well, if you think about it in the category theoretics perspective, through the category theoretic lens, there's a systematic way to do that, which is through higher categories. So if you consider categories which have
You know, objects and morphisms, you can also consider two categories that have two morphisms between those morphisms that allow you to transform morphisms to each other, not just objects to each other. And so if you take the two category version of the one category picture of categorical quantum mechanics, you can allow the two categories to correspond to gauge transformations between your evolution operators. So you're transforming the direction of time in a way that's consistent with, say, with the generators of the Lorentz group.
And so what you get in some appropriate special case is what's called a functorial quantum field theory. So Baez and Dolan constructed this axiomatization of functorial and particularly topological quantum field theories based on what's called a T.S. Segal axiomatization that used these two categories and indeed even higher categories as a way of formalizing this notion of gauge transformations, of being able to transform between time directions.
Okay so that's a nice piece of mathematics and in my opinion is one of the more promising avenues towards constructing a kind of mathematically rigorous foundation for quantum field theory.
What does it have to do with quantum gravity? Well, this is where it necessarily becomes very speculative. But so there's an idea that goes back to Alexander Grothendieck, who I mentioned, amazing algebraic geometry from the early 20th century, who really developed a whole bunch of these ideas from applied in higher category theory while he was sort of living as a basically a hermit in the Pyrenees, I think. But so Grothendieck made this hypothesis that's now called Grothendieck's hypothesis or the homotopy hypothesis.
Which goes as follows, okay, let me motivate it like this so. If I have a topological space, you know it has some collection of points and it has paths that connect those points. But I can also have.
Pause the connect the pause and those are called homotopies right so i can continuously deform one path into another i can use that. Information to tell me stuff about the topology of the space so you know you can use that the homotopy information to tell you about the technology right you can find that there's a. If you're in a donut you can see that there's a hole there because if you have a loop. I don't path loops around that hole you can't continue you can't continuously track the contract to a point without encountering some discontinuity.
Um, so, uh, those homotopies you can formalize as, you know, kind of higher order paths between paths. So in the language of category theory, you could say my initial topological space is a one category that has points and, you know, paths between the objects and morphisms. My, the, the first homotopy type is the two category I construct from that where the two morphisms homotopies between those paths. But then I can also consider homotopies between homotopies and so on. So I can construct this whole hierarchy of, of, of higher categories and higher homotopy types.
And the somehow we know that.
from various results in high-category theory that that the that the information all the information that you care about up to we come out to be equivalent about not just the space you started from but all of the intermediate spaces that were in a hierarchy all of that information is somehow contained in the algebraic structure of that infinity category.
The infinity category determines up to we come out of the equivalence everything that's that comes in the hierarchy below it and that's why kind of infinity category theory is so different to even just normal finite higher category theory infinity categories somehow contain far more information there's actually is a specific type of infinity of infinity category called an infinity group or eight because of the you know because the paths are invertible right um and growth and decrease one of the
Really one of the first people who encouraged topologists to stop thinking about fundamental groups and start thinking about fundamental group points without, you know, without needing to define distinguished base points and things like that. But the homotopy hypothesis is this really deep statement that kind of goes in the other direction where, so we know that starting from a space and doing this, you know, hierarchical construction, you build up to this infinity category that tells you, you know, up to weak homotopy equivalents, all the topological information about that space and all of its homotopy types.
I'm. Grosvenor then said well maybe that's really the definition of a topological space that infinity categories are just spaces infinity group points are spaces. Or at least they define the structure of a space and all of it homotopy types up to become must be equivalent to converse direction.
It's not proven, it's not even precisely formulated, but it's a very interesting idea that I think is largely believed to be correct. It aligns well with our intuitions for how algebraic topology should work.
Attempting speculation about the relationship between that and physics. So going back to the quantum field theory picture for a moment. So suppose you don't just stop at two categories or indeed three categories. You keep going, right? You keep adding these higher gauge transformations. So not just gauge transformations that deform time direction to time direction, but higher gauge transformations that deform gauge transformation to gauge transformation. You build up a higher homotopy type that way. What happens when you get to the infinity category limit?
Well, so what you end up with is something that has the structure of a topological space so you starting from something that's completely non spatial you've ended up with a topological space. And so. In the spirit of these kind of emergent space time views you know like er equals EPR and so on.
One hypothesis that's quite tempting to make is maybe that infinity category defines the structure of our space time. The topology and geometry of space time emerges in that infinity category limit that i take by just adding higher and higher gate transformation starting from categorical quantum mechanics. And so if that's true which.
Again to be clear we have no idea whether that's true or not, but if that were true, then the coherence conditions, the conditions that define how the infinity category relates to all of the lower categories in that hierarchy, those coherence conditions would essentially be an algebraic parameterization for possible quantum gravity models.
And so that would be a very, if that ended up being correct, that would be a really nice way to kind of conceptualize and formalize the essential problem of quantum gravity that we're really trying to nail down the coherence conditions that relate that infinity category to all the all the higher categories in that hierarchy. Now, what would it be like to study the topology? So there's something called the stone duality, I'm sure you're aware of, which relates topology to syntax. So
I've never heard of someone studying stone duality at the infinity categorical level at the topology that's induced from that category. What does that look like? Yeah, that's that's a really interesting question. So yes, the way that stone duality works is so if you have a
I mean, there's, again, as with many of these things, there's a nice categorical interpretation in terms of Boolean topos and things. But the basic idea is that if you have a Boolean algebra, you know, a kind of minimal algebraic axiomatization for logic, there's a way that you can formalize that in terms of this mathematical structure of a lattice, right, and specifically an orthomodular lattice, I think. I may be getting that wrong. I think it's an orthomodular lattice. But so
In which essentially every point in that lattice is a is a proposition and then you have these meat operations in these joint operations that become equivalent to your and an or operation logic. And the reason that significant is because those same class of lattices also appear in topology because there are specific spaces called stone spaces that are essentially the so okay sorry let me let me.
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Say that less confusingly. So if you take a topological space and you look at it, it doesn't like topological spaces. No. OK, let's let's let's try that again. OK, sorry, that's been kept in that part.
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If you take a topological space, then you can look at its open set structure. So if you take the collection of all open sets, you can look at, in particular, you can look at the open set containment structure. You can look at, you know, which open sets are included in which others. And when you do that, you again get the structure and also modular lattice, because you know that the lattice operations are essentially defined by the inclusion relations between the open sets.
So you could ask what are the particular topological spaces that you get if you look for topological spaces whose open set lattices are the lattices that you get from looking at Boolean Algebras.
And those are the stone spaces of the topological spatial interpretation of logic in some sense and in a way you can say topos theory is really about trying to generalize that that idea right it's another way to think about it that so. Every elementary topos has an internal logic.
And also every elementary topos has some kind of spatial interpretation because the axioms of elementary topos theory, this finite limit axiom and this existence of power objects or sub-object classifiers is really the analogue of, is really some generalisation of the axioms of point set topology, right? Because, you know, the topos theoretic analogue of saying that your open sets have to be closed, you know, the collection of open sets has to be closed under arbitrary unions and finite intersections and so on.
I'm so topos have special interpretations and they also have an internal logic. I'm so there's a particular kind of topos called boolean topos whose internal logic is boolean algebra and who special interpretation is there for a stone space but actually you can make that you can do the same construction for any elementary topos that you like.
I'm and so then really what you're asking is working when you go to higher topos theory if we take the higher category which turns every day that that infinity category that you get from the growth and deconstruction is no admits a topos structure. So then you could ask what is the internal logic to that and what is its relationship to its space reality. And what you end up with is the spatial structure of an infinity homotopy type in homotopy type theory.
So in homotopy type theory, this is another kind of logic interpretation of, uh, of, uh, you know, of, of higher categories where my apologies. Sorry. Crying somewhat. Hang on. Um, okay.
Yes, yes, it's getting slightly more restricted in my motions now. But if you imagine taking a proof system and you say, OK, so now I'm going to interpret every point, every proposition in that proof system as being a point in some space and every proof as being a part. Yes. Right. So a proof just connects two propositions together.
Then so i can prove one proposition for another i could prove that two propositions are equivalent i can also prove that two proofs are equivalent right i can take two parts and i can continuously deform them but that proof exists in the next homotopy type right because that's interpreted topologically as a homotopy between those between those parts.
And so you can do exactly the same construction and so that in the infinity category limit what you get is a is a logic which allows not just for proofs of propositions but proofs of equivalence between proofs and proofs of equivalence between those proofs and so on right so that would be the kind of that's the internal logic of one of those higher top losses it's a it's a it's a it's a logic that allows for proofs of equivalence between proofs up to arbitrarily high order interesting so
In theories of truth there's one called Tarski's theory of truth where your truth can only speak about the level that's beneath it and then right and this is one of the ways of getting around the liars paradox is that you say well it's truth level one and then you're speaking about a truth level two or falsity level two etc and then the criticism is well what happens Tarski when you go all the way up to infinity and I don't think he had an answer but it's sounding like there can be a metaphor here for some answer
yes i mean potentially it's not something i've thought about a huge amount but it's certainly the case that in these in these kind of higher order logic constructions there are things that happen at the infinity level that don't happen at any finite level and it's conceivable that yes you you might be able to say you might be able to do a kind of tasky thing of evading the light or you may be able to do some kind of right i mean i think the same thing happens with quine's paradox right or where you have um you know you you try and how you you try and construct uh um
You know lie paradox type scenarios without self reference where you say you know i do know that the next sentence is false the previous sentence is true or something yes but then. The logical structure of those things changes when you as soon as you go from having a finite cycle of those things to having an infinite cycle the logical structure changes and i think the same is true of things like the task you theory of truth.
And yeah, it may be that there's some nice interpretation of that in terms of what happens as you build up the, you know, to these to these progressively higher or small posses in homotopy type theory. I don't know. I mean that it's but it's a it's an interesting speculation. What would be your preferred interpretation of truth? So from a logic standpoint, I'm quite taken with the kind of with the definition of semantic truth that exists in things like task is undefined ability theorem, which is the idea that
You say a proposition is true if you can incorporate it into your formal system without changing its consistency properties, right? So if you have formal system S and you have proposition T, T is true if and only if S plus T is, you know, if and only if con S plus T is the same as con S.
And that's a fairly neat idea that I think I mean it's used a lot in logic and it's quite useful for formalizing certain concepts of mathematical truth and particularly for distinguishing these kind of concepts of like completeness versus soundness versus decidability, which often get confused. Those become a lot easier to understand in my experience if you start to think of truth in those terms. Yeah, great. John, that's a formal definition of truth. It works for formal statements, but what about colloquial informal ones?
No i agree it's extremely full but i was what i was about to say that i think it also aligns quite well with some. Basic intuition we have for how truth works when we when we reason about things informally right so if we have some model of the world right and that's like a formal system some informal system right and when we take if you take on board some new piece of information.
Generally speaking, the way that humans seem to work is, if we can incorporate that new piece of information without fundamentally changing the consistency properties of our model of the world, we are much more likely to believe that statement is true than if it necessitates some radical reimagining of the consistency properties of our internal representation. And so I think informally,
There's a version of that same definition of truth that has a bit of slack, right? Where you say, okay, a proposition could be provisionally true, but how likely I am to accept it as true depends on how radically I have to reformulate my foundations of reality in order to incorporate it in a consistent way. I see. Well, John, I don't know what subject we haven't touched on. This is a fascinating conversation. Thank you, man.
No, this was fantastic. As you say, I'm really, you know, it's, it's, uh, it's been a long time coming, but I'm really glad we had this opportunity to chat. And, uh, and yeah, I really look forward to staying in touch. I've become, I have to confess when you first reached out, I hadn't heard of you, but in part because you reached out and in part for, because, you know, of the, of the explosion of your channel, I've been following a lot of what you've been doing subsequently. And I think, um, no, I think TOE is, is, is a really fantastic resource. And the,
Yeah, your particular niche is one that desperately needs to be filled, and I think you're doing a fantastic job of filling it. What would you say that niche is? And I ask just because it's always interesting for me to hear. Well, I have an idea as to what TOW is or what TOW is doing, what theories of everything the project is. It doesn't always correspond with what other people think of it. Right. So the reason I really like your channel and the reason I like witnessing these conversations and to some extent participating in them as well,
Is the following reason right you it feels to me like you got these two extremes out there right that there are these. Really quite vacuous kind of popular science popularization or philosophy popularization youtube channels and documentary series and things where you often have a host to you know.
Goes very far to kind of play up the fact that they're ignorant of what's being discussed and they don't really have any strong opinions and it's just you know they just go and ask some brain boxes for what they think and then it gets assembled in some nice documentary package that's kind of one extreme. Then you have the other extreme of you know you take some.
This is just some philosopher who's been working on their own pet theory for thirty years and they go make some you know some some long youtube video about it just advocating that and shouting down all the competition and being very kind of bigoted and dogmatic or whatever.
What you are managing to do but you know because you are an extremely intelligent and well read person with your background in math and physics and who has been very wide interest outside of that you know more so than any other youtuber in youtube i've encountered actually makes an effort to really understand. You know the stuff that talking about the stuff that the guests are talking about that's even just in itself that would be incredibly valuable but then what i think what i think that allows you to do is.
Do something to do something that's somehow a really nice synthesis of the best aspects of those two approaches, whilst avoiding them more unpleasant aspects, which is to be someone to be the kind of interested, educated, motivated interlocutor who is, you know, not completely inert, like in the, in the, in the kind of the sort of popular science documentary case, but also not, you know, dogmatically pushing and saying, ah, you know, you're completely wrong to be thinking about loop quantum gravity or something, but just saying,
Oh but how does this connect to that or is it possible you could rethink you could think of things in this in this you know being that kind of Socratic dialogue partner.
In a way that I think you are almost uniquely placed because of your skill set and your, your personality to, to, you know, that's a role you're almost uniquely placed to play in that space. Um, I've never really seen that work in, uh, in any context outside of your channel. Um, and as I think that's something really quite special, man, that's the hugest compliment and I appreciate that. Thank you so much. I think you've captured. Well, I don't know if I'm the bigot in that, but I'll interpret that as me not being a bigot just to sleep at night. No, no, no, exactly. I mean,
I think you handle the balance really well as someone who clearly has ideas and has opinions and has views, as you have every right to as someone who's thought about this as much as anyone else. But you're not trying to shout down opposition, you're not trying to force some viewer down someone's throat. As far as I can tell, you are actually
You know in completely good faith just trying to explore with genuine intellectual curiosity the space of ideas and you know and present new perspectives and point in directions that people may not have previously thought of in a way that I think a lot of people say that they're trying to do. I very rarely seen anyone actually you know.
And people might be able to simulate that for a while, but, you know, after a while that, you know, the, the, the mask kind of slips and you see, Oh, really? They're kind of pushing this viewpoint or whatever. And, you know, so part of that is that I don't have that incentive structure of having to produce and get citations in order for me to live. Because if I was, then I would have to specialize much earlier and I wouldn't be able to survey as much before I specialize. So currently I'm still in the surveying mode. Like again, it's before I go down and eat.
So I'm lucky in that regard and I had man like, holy moly, super cool. So I have many questions from the audience, by the way. I mean, just, just informally on the following up on that. I mean, I think the, in many ways, I think the string theory landscape video is the, is the perfect embodiment of that, of that sort of side of you, right? That it's the fact that I don't know any other person really who could have done something like that, because it requires both
You come across quite critical of string theory, right? No string theorist would have made that video. But also no one whose paycheck depends on them investigating loop quantum gravity would have invested the time to understand string theory at the level that you had to understand it in order to make the video. And so it's like, I don't know who else would have filled that niche.
Yeah, that was a fun project. I find it's just it's so terribly in vogue to say I dislike string theory, but then simultaneously to feel like you're voicing a controversial opinion. And I wanted to understand string theory before us. And I, by the way, I love string theory, right? I think it may be describing elements of reality correctly. And that may be why it has I misspoke, by the way, when I said in the video that it has no predictions, it had mathematical predictions, maybe still does.
And this is something Richard Borchards emailed me because he said that's something I would correct in the video. It has mathematical predictions. It doesn't have physical ones. But anyhow, I think that's why it may prove so fruitful mathematically. And it also, I mean, like parts of it have physical predictions that are but they just happen to not strictly depend on the string theoretic interpretation. Right. So there are condensed matter predictions of ADS CFT that have been quite experimentally validated. Right. It's just that
Yes if he came from string theory but it doesn't strictly depend on the right exactly exactly. Okay so one of the questions from the audience is has john ever done psychedelics. Yes so i have tried psychedelics and actually i consider it. I don't want to come across as too much of a kind of drug pusher but i i i consider it's one of the most important things i've ever done.
I don't do it regularly because i'm afraid of the effect that has on the brain and things like that so i had a list of things i wanted to try and i tried each of them once i'm very glad that i did and the main takeaway was the stuff we were talking about before about. You know this kind of this.
The computation that a system is doing and as the computation of the observer is doing and you know the track so you know really what you've got is that you know you've got these two computations and you've got a third computation that is sort of the encoding function the thing that maps a concrete state of the system to an abstract state in the in the internal representation of the observer and really all three of those things are kind of free parameters. And you know i've been thinking about that kind of stuff
Not in those terms precisely, but in some form for a long time, you know, from when I was a teenager onwards, and kind of in this very kind of nerdy intellectual way, thinking about, oh, yes, you know, surely, my model of reality, if my model of reality changes even slightly, then you know, the interpretations of the perceptions and qualia that I experienced is going to be radically different. But it doesn't matter how much you intellectualize that idea. It's very, very different if you just like subjectively experience it, right. And that's in a sense,
Driving home the fact that if you make what is in the grand scheme of things, an absolutely trivial modification to your brain chemistry, your modes of decomposing and understanding the world completely just dissolve as happens with things like LSD. Um, actually experiencing that from a firsthand perspective is really, really important. It kind of convinced me. I don't want to, again, I don't want to seem too, okay.
It would be too strong to say ultimately convinced me of the validity of that way of thinking about things, but it definitely is something that occurs to me when I when I'm kind of. When I'm worried that I'm overplaying this observer dependence of phenomena line, I kind of think, well, no, actually, if you if you modify even just very slightly neurotransmitter balances in the brain, the internal perception of reality changes, you know, it's kind of really, really radically. Yes. OK, well, here's
A physics question, what would happen if an object wider than a wormhole throat flies into the wormhole? Does the wormhole widen? Does the object cork the wormhole? Does it deform the object? If it deforms at how? What about if the object flies at an even faster speed? So 0.9 speed of light. Okay, interesting question. So I mean, wormholes
Obviously are not known to be physical. They are valid solutions to the Einstein equations. Einstein rows and bridges and extended Schwarzschild solutions are valid solutions, but the Einstein equations are incredibly permissive and they permit many, many more solutions than things that we believe to be physical. So if you just take the Einstein field equations on face value. So, okay, one thing to remember is that when an object is falling into the wormhole, it's not like it has to fit
Into the throat so to speak right the object is because if you imagine the topology of what's going on you've got you know you've got this two sheets sort of hyperboloid almost right and the wormhole throat that's connecting them but any object you throw in is localized to one of the sheets so it's it's traveling on that sheet and follows the world lines on that sheet it's not like it's kind of it's not like it's some plug that's trying to go through the throat in you know through the space in the middle.
I'm so it may well be that the that the world lines coming this will happen to the title defamation to the object will will be kind of will be stretched in the in the radio direction compressed in the angular directions as it gets pulled in just do the gravitational tidal effects but the fact that it's that the object is quite a bit bigger than the wormhole throat doesn't matter me it's just it it's just.
Would you kindly ask him how would he tie science and spirituality together?
I think one always has to be a bit careful with that, right? I mean, so I'm certainly not, in the sense that I don't want to take either of the two extreme positions of saying, oh, you know, science validates the existence of an immortal soul or something, which I don't believe. But nor do I want to say, oh, science invalidates whatever the, you know, the numinous dimension. I think it's, you know, they're largely agnostic to one another.
I do think there are some things, okay, so actually it comes back to the stuff we were talking about at the beginning in a way about the kind of the language that we use and the models that we use for constructing reality, right? Do you actually believe that the universe is a computer? Do you actually believe that the solar system is made of clockwork or something? And again, the answer is no, right? My view is that these are just models we use based on the ambient technology of our time.
I kind of have a similar feeling about a lot of theology and a lot of spirituality, right? That it's so if you go, if you go and read writings by people like, I know, John Duns Scotus or, you know, medieval scholastic theologians, the questions they're grappling with are really the same questions that I'm interested in, you know, so like, okay, for take a concrete example, right? So I realized I'm talking about religion here, not necessarily spirituality, tie it together. But so you could ask the question. So
Our universe is neither, it seems to be neither completely trivial, it's neither kind of maximally simple, nor is it kind of maximally complicated. So there's some regularity, but it's not completely logically trivial. It's not like every little particle follows its own set of laws, but it's also not like we can just reduce everything to one, as far as you can tell, we can just reduce everything to one logical tautology. So
As far as I can tell, the first people to really discuss that question in a systematic way, at least from European theology and philosophy, I'm more ignorant of other traditions, were the scholastic theologians, were people like Don Scotus who asked, you know, why did God create a world which is neither maximally simple nor maximally complex effectively? And Don Scotus' answer is a perfectly reasonable answer, right? Which is because God created the world that way because that world is the most interesting.
And if we were to focus on if i want to formulate that question in modern terminology i would formulate in terms of complexity right i would say why why is the universe why is the algorithmic complexity of the universe neither zero nor infinity why is it some finite value.
And the answer, as far as you can tell, is essentially because of because of information theory, because we learned from Shannon that the kind of the most interesting or the highest information density, you know, the most interesting signal is one that is neither completely noisy maximum information nor completely simple, but somewhere in the middle. So really, Don Scotus hits upon a really foundational idea in modern algorithmic information theory. He didn't formulate it in those terms because, you know,
You didn't know what complexity was no way of that ambient thinking technology didn't exist. So he formulated the answer in terms of the ambient thinking technology of the time which was god in the bible and all that kind of stuff.
I don't want to be someone who sits here and says oh look at those people they were talking about you know god and whatever and when they so ignorant because i don't want people to look at you know yes i see what you're saying but i don't want people to look at my work in a thousand years and say oh look he thought the universe was a computer how silly he was right i don't think the universe is a computer i think it's a useful model just as they thought god was a useful model.
And, um, which it was, and maybe to an extent still is. Uh, so that's kind of my general view about sort of theology and spirituality is that I think there, you know, there are some classes of questions where it's useful to think about things in terms of Turing machines or, you know, fiber bundles or whatever it is. And there are some classes of questions where it is useful to couch them in terms of the soul or, you know, an immortal spirit or God or whatever.
And you can do those things without believing in the ontological reality of any of them as indeed i don't but that doesn't make them not useful. Now can you actually distinguish those two if you're a pragmatist cuz my understanding if you like william james the utility of it is tied to the truth of it. Yeah i mean that that's it's a tricky one that's something i okay. Being completely honest i don't know it's something i've gone back and forth on over the years right because in a way so yes you might say.
Okay do i believe in god or do i believe in the soul in some ontological sense and the answer is no but.
If that's your definition of exist or that's your definition of belief then i also don't believe in electrons right i don't believe in space time you know i think all of these things are just models right like do i think that you know space time is a useful mathematical abstraction but in a sense we know that you know in black holes or in the big bang or something that's probably an abstraction that uses use that loses usefulness and eventually will be superseded by something more foundational.
So do i believe in space time in an ontological sense no do i believe in particles in an ontological sense no so interesting whereas you might say okay well therefore i have that means probably that my definition of the word exist is not very useful right i should i should loosen that definition a bit and be a bit more permissive so then you might take the william james view of okay well. You could say i believe in space i believe that space time exists in as much as.
I think it's a useful model for a large class of natural phenomena. Again, it's a bit like the dinosaur thing we were talking about earlier. You could say, well, you know, I don't believe that space and doesn't exist in an ontological sense, but it's kind of consistent with a model of reality that does have good experimental validation or observational validation. But then if you, if that's your criterion, then I kind of have to admit that, okay, well, in that sense, maybe I do believe in a soul, right? Because there are, you know, so for instance, you know, I don't,
I don't believe that there's any hardline distinction between the computations that are going on inside the brain and the computations that are going on inside lumps of rock or something. And really the distinction is, it comes back to the point you were making earlier about
What laws of physics would a cat formulate? So in a sense, okay, yes, maybe they exist in the same objective reality, whatever that means. But whatever their internal model of the world is, it's going to be quite different from mine because cats have not just different brain structure, but they have a different kind of social order, their culture is different, et cetera. Just like my internal representation of the world would be different to different humans who was raised in a completely different environment with a different education system, et cetera.
I'm into this it's not like some abrupt discontinuity there's a kind of smooth gradient of how culturally similar are these two objects are these two entities and how that for how much overlap is there in the internal representation of the world so you know that i have. More overlap with you that i do with a cat but i have more overlap with a cat i do with a rock and so on right but there's no there's no hard line distinction between any of those things at least in my view right.
So in a way you could say, well, therefore I'm some kind of panpsychist or, you know, like I believe that there's, or I'm an animist, right? I believe that there's kind of mind or spirit and everything. And again, I think that's not a comp, you know, it's not personally how I choose to formulate it. I choose to formulate it in terms of computation theory, but it's not a completely ridiculous way of translating that view. And, you know, these kind of druidic animistic religions, you know, a lot of what they're saying, if interpreted in those terms is perfectly reasonable.
Um, so, so, yeah, it's just a very verbose way of saying, no, I don't have any particularly good way of distinguishing between the two. And so in a sense, I have to choose either between being ultra pragmatist and basically saying, I don't believe in anything or being ultra permissive and saying, yeah, I basically believe in everything, which seem like equally useless filters. Well, another commonality between us is that the way that you characterized the scholastics, I believe, and their
Ideas of God and then being inspired and realizing that that's similar, not the same, of course, but similar to ideas of computation now, or at least how they were describing it. And that's one of the reasons why on this channel, I interviewed such a wide range of people. It's because I work extremely diligently to understand the theories and to be rigorous. But I also feel like much of the innovations will come from the fringes, but then be verified by the center.
In other words, the fringes are more creative, but they're not as strict. The center is much more stringent, but then it has too fine of a sieve. Right, right. It's like those simulated annealing algorithms that you get in combinatorial optimization, where you're trying to find some local minimum of a function. So you set the parameter really high initially, so you're kind of exploring all over the place, but being very, very erratic. And then gradually, over time, you have to lower the temperature parameter.
There's something in that about as a model of creativity that at the beginning you have to be kind of crazy and irrational and whatever and then gradually you have to drop that temperature and kind of become a bit more strict and precise and slowly start to nail things down. Now the Santa Fe Institute has an interesting, I don't know if it's a slogan, but it's the way that they operate, which is you have to be solitary and even loopy inane.
And then go back to people to then be verified and actually have some wall to push against you because otherwise you're just floating in the air. Sorry, since I since I was to continue being complimentary to you and the channel. I mean, that's that's another thing which I think is
Is very rare which you do extremely well which is to actually take seriously. I think it's something which i think a lot of people say that they want to do or would like to think that they want to do but a lot of people seem to be i'm bad at this to write i tried but i think i fail where if you want if you.
If you're presented with some really crazy, very speculative idea, and it's hard to kind of make head or tail of what the person is talking about, you know, for a lot of people, it's the kind of instinctive reaction to say is complete nonsense, like, don't waste my time. And, you know, certainly a lot of the mainstream physics community has that opinion and to an extent has to have that, you know, view, because if you, you know, one of the, one of the things you learn, if you start writing papers about fundamental physics is you get a huge amount of sort of unsolicited correspondence from people trying to tell you their theory of the universe, right?
I'm but you know it's always it's also important to be mindful of stories like the story of ramanujan right like writing to g. h. hardy and people you know who must have seen like an absolute not case actually was this kind of era defining genius and you know you have to be careful not to set the filter to strict and i think what we know one thing i think you do extremely well is is really to kind of.
I think the, I think the expression in the post-wraps community is, you know, steel man. These, these kinds of arguments is to say, you know, if you're, if you're presented with some idea that seems on the surface, completely nuts, let's try and adopt the most charitable possible interpretation of what's happening. Like how might we be able to make this make sense? And yeah, it's something I try to do with ideas and physics and theology and other things, but I think you certainly do it far better than anyone else I've encountered. Is this related to why you follow the Pope on Twitter?
No, it's not. That is a completely yes. Okay, well, well spotted. Because so all right. The backstory to that is so that Twitter account was made when I was like 15 years old. And I didn't use it. I think I sent sort of two or three weird tweets as a teenager and then let it die. Okay, I didn't even realize it was still around.
And then when the physics project got announced, which was really the first bit of serious media attention I ever received, right. And I was having interviews and magazines and other things. And I got a message from the director of public relations at Wolfram research saying, they found your Twitter account and it's got like some, you know, it's got 2000 followers. I can't remember what it was. People who started following this Twitter account was like, I don't have a Twitter account. And then I, and then I figured out, oh, they found this Twitter account that I made when I was 15 and, and never deleted and forgot existed. Now.
when i was fifteen years old for some reason i thought it was funny so this is some betrayal of my sense of humor so i i i tweeted kind of weird nerdy math stuff and whatever and in my teenage sense of humor i thought it'd be funny if i only followed two people uh the pope and this person called fern britain who is a sort of daytime television star in in the uk and i i i don't know why i thought that was so humorous but i thought it
i thought it was entertaining and then i think fun britain left twitter or something and so so when i when i went back to this twitter account the only account i followed was the pope and then i thought okay well forget i'll just leave it and then i since then have followed a few other people but he's still there somehow okay so it's just a relic you can't bear to get rid of him like some people can't bear to delete some deceased person from their phone like it's for posterity what's the reason why do you still have it
Yeah, it's partly posterity. It's and it's partly because there is still a part of me that for whatever reason thinks it's kind of funny that I that I follow a bunch, basically a bunch of scientists and like, you know, science popularized Christopher Hitchens and then the Pope. Yeah. Yeah. And then the Pope. Yeah. OK. So speaking about other people's theories, this question is, does Jonathan see any connections between the really at Eric Weinstein's geometric unity and Chris Langan's CTMU, which is also known as the cognitive theoretic model of the universe?
So on a very surface level, I guess I see some connections, I have to confess. So I'm not, I don't know really anything about either geometric unity or CTMU. I've encountered both people have told me things about both. I've been able to find very little formal material about CTMU at all. And the little I know says, okay, yeah, it probably does have some similarity with, you know, this general thing we were talking about earlier of, you know, having a model of reality that places mind at the center.
And that kind of takes seriously the role that the observers model of the universe plays in, you know, in constructing an internal representation. I think that's. That's certainly a commonality, but I'm kind of I'm nervous to comment beyond that, because I really don't understand it well enough with geometric unity. Yeah, I don't really know what I mean. Even if I were to understand it technically, which I don't, my issue would still be a kind of conceptual one, which is I think it's kind of insufficiently
Radical, right? I mean, it's like, it's really the idea is, you know, use, you know, use the existing methods from gauge theory to figure out, you know, if we have a Lorentzian manifold with, you know, with a chosen orientation and chosen spin structure, here is the kind of here is the kind of canonical gauge theory that we get, you know, defined over that structure.
And the claim is that gauge theory unifies gravitation and the three other gauge forces. Like I say, I certainly wasn't convinced that that's formally true just by reading the paper, which even if it were true, I would find it a little bit disappointing if it turned out that the key thing that was needed for radical advance in physics just turned out to be a bigger gauge group. That would be a little bit anticlimactic.
Now we've talked about the pros of computational models and you even rebutted, at least from your point of view, Penrose's refutation of computations. But this question is about what are the limitations or drawbacks for using computational models minus complexity and irreducibility? Like that's just a practical issue.
Right so sure but even conceptually there may be issues right so i am i and again this is kind of what i mean when i say i'm not dogmatically trying to assert that the universe is a turing machine or something then maybe. Physical phenomena that are fundamentally non computable as you know penrose and other people believe you know it so it but i don't think we know that yet and certainly the parts of physics that we kind of know to be true we know are computable.
And so computation is therefore, you know, again, going back to the pragmatist point, computation is therefore at least a very useful model for thinking about a lot of physics, whether it's useful for thinking about everything, who knows, probably not right. But yeah, I mean, there are open questions like so, for instance, it might be the case that so we know we have known since since Turing's first paper on on computable numbers, that most real numbers are non computable.
Uh so if you have you know if the universe turned out to be fundamentally based on continuous mathematical structures and based on real numbers then uh you know at its foundational level it would be a non-computable structure um but then you still have this open question of well you still got this issue of the observer you could imagine the situation where you have a continuous universe that's based on non-computable mathematics
But all experiments that you can in principle perform within that universe would yield computable values of the observables.
And in that case, and in fact, you know, again, there are papers by people like David Deutsch, who've, you know, argued similar things, right, that, you know, that, you know, within, for instance, within quantum mechanics, you have, you know, arbitrary complex numbers appearing in the amplitudes. And so, you know, most of those are going to be non-computable. But eventually you project those onto a discrete collection of eigenstates, and those are computable.
So in the end it doesn't matter that it's the underlying model was based on computer mathematics because the part of it that you can actually interface with an observer still has computer outcomes. Which means that there is still going to be an effective model that's consistent with observation that is nevertheless computer.
In a sense, I don't think we know that yet. I don't think we know whether it's even possible to set up, if the universe were non-computable, would it be possible to set up experiments that are effectively able to excavate or exploit that non-computability to do practical hypercomputation or something? Wait, sorry, is David Deutsch suggesting that quantum mechanics only has point spectrums and that there are no continuous spectrums?
I'm sorry. Let me let me not malign. Let me not malign. That's specifically in the context of, you know, quantum information theory and finite dimensional space is right. So, you know, even if you have only a finite eigen basis, so all your all your measurements are computable, you know, the eigenstates are discrete sets. But the amplitudes are still non-computable, right, in general. OK, I have a nettling point that I want to bring up that I hear mathematicians and physicists say, but I don't think it's quite true.
So when they're talking about discrete models, they'll say discrete versus continuous, but it should technically be discrete versus continuum, because you can have two graphs which are discrete, and you can have continuous maps between them, because you just need the pre image to be open. And it's not a continuum, but it's continuous. Right. I hear that all the time. And I'm like, why does no one say that? But I just want to know, am I understanding something incorrectly?
No, I think you're not understanding something incorrectly. I think you're, you're, you're thinking about this more deeply than most mathematicians do, which is, which is perhaps a positive sign. I mean, so yes. Um, the distinction between what is discrete and what is continuum is actually not very well defined. Right. So, um, let me give you a concrete example. So, uh, and this is actually something that comes from a method of proof in logic called forcing, uh, it was developed by Paul Cohen. Right. Right. So, and one of the key
Ideas in forcing is this idea called a forcing P name, which I'm slightly technical idea, but basically what it allows you to do is to talk about the cardinality of a set from a different set theoretic universe from a different domain of discourse. The significance of that is so okay, what do we mean when we say that something is discrete?
Well, what we mean is that it can be bijected with the natural numbers, right? That it's countable. It consists of a countable collection of data. And when we say that something is continuous, I mean, modular considerations of the continuum hypothesis and something, basically what we mean is that it's uncountable, that you can't biject it with the natural numbers. But, you know, what is a bijection? Well, a bijection is a function. And what is a function? Well, set theoretically a function is just a set, right? It's a set of ordered pairs that map, you know, inputs to outputs.
So if you have control over your set theoretic universe, you can control not just what sets you can build, but also what functions you could build. So you can have the situation where you have a set that is countable from one larger set theoretic universe in the sense that it's the function that bijects that set with the naturals exists in that universe. But if you restrict to a smaller one, that function can no longer be constructed. So internal to that set,
That you know the internal to that universe that set is no longer countable it's no longer it's effectively gone from being discrete to being continuous the set itself is the same it's just that you've made the function that bijected it with the naturals non-constructive yes if you like to an observer to a generalized mathematical observer internal to that universe it looks like it's continuous.
And again, there are versions of this idea that occur throughout topos theory. PT Johnston, one of the pioneers of topos theory, did a lot of work on these topos theoretic models of the continuum, where you can have a very similar phenomenon, where you can have some mathematical structure that looks discrete.
From a larger super topos but if you take some appropriate sub topos you exclude you make non-constructible the functions that essentially witness it as being discrete and so internal to that it becomes a continuous structure and so you can actually do things like locale theory and pointless topology in a manner that is fundamentally agnostic as to whether the spaces you're dealing with are actually discrete or continuous so
Yeah, even the question of whether something is discrete or continuous is in a sense observer dependent is dependent on, you know, what what what functions you can and cannot construct or compute within your particular model of mathematics. So what I was saying is that continuity and continuousness is the same to me. But what is continuous is not the same as a continuum for continuum. I would just say it's a spectrum with the real numbers, say,
But continuous is just a function has the property of that is continuous. That can be there even when there's discrete phenomenon. Yes, exactly. And in fact, you know, that I mean, that's related to the fact that a you know, you can have accountable space that's not discrete, right? I mean, so it's a discreteness in topology means that, you know, you that only the, you know, that has essentially the only the points themselves have, you know, represent open sets.
Then it is so in a sense it's it's kind of the it's the I forget whether it's the courses for the finest possible topology one of the two it's the it's the dual to the box topology um but of the trivial topology um but you can have but you can perfectly well have countable topological spaces that are not discrete and you can have you know discrete topological spaces that are not countable so yeah somehow these yeah it's again it's this problem of uh sorry is this further complicated with uh lowenheim skull and theorem which
In one way says, if you have something that's countable, you have a model where it's uncountable and of every cardinality and vice versa. Right, right. Yes. It's certainly right. I mean, so the downward lo and heimskolen theorem is used in the, in the forcing construction that I mentioned earlier. I see. Okay. All of which, all of which is to illustrate exactly the point that I think you're making, which is the, so, you know, there's the notion of continuity of, you know, pre images of open sets are open that comes from analysis and topology. Um, but that's not the same as the notion of continuum in the sense of.
I don't know what subject we haven't touched on.
I'm glad you enjoyed this episode with Jonathan Gerrard. If you'd like more episodes that are similar to it, again, Wolfram was interviewed himself three times on Theories of Everything. It's on screen right now. I recommend you check it out.
Also the string theory video that Jonathan mentions is called the iceberg of string theory and I recommend you check it out. It took approximately two months of writing, four months of editing with four editors, four rewrites, 14 shoots and there are seven layers. It's the most effort that's gone into any single theories of everything video. It's a rabbit hole of the math of string theory geared toward the graduate level. There's nothing else like it.
Thank you for watching. Thank you for listening. There's now a website, curtjymungle.org, and that has a mailing list. The reason being that large platforms like YouTube, like Patreon, they can disable you for whatever reason, whenever they like.
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"text": " In a sense we know that black holes or in the Big Bang or something that's probably an abstraction that loses usefulness and eventually will be superseded by something more foundational. Our universe seems to be neither maximally simple nor is it kind of maximally complicated. There's some regularity but it's not completely logically trivial. It's not like every little particle follows its own set of laws but it's also not like we can just reduce everything to one logical tautology."
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"text": " Jonathan Gerard is a researcher in mathematical physics at Princeton University and in my opinion is the starkness and the brains behind the rigor at the Wolframs physics project. Today's conversation is quite detailed as we go into the meticulous technicalities as if this were a conversation between two friends behind closed doors. In this discussion we elucidate the core principles and claims of the Wolframs physics project. We distinguish them from the surrounding hype. Specifically we explore potential connections between category theory"
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"text": " You should also know that there are three interviews with Stephen Wolfram on this channel. Each is linked in the description. In it, we detail the Wolfram's physics project with Stephen Wolfram himself and why he thinks it's a potential candidate for a theory of everything. My name is Kurt Jaimungal. For those of you who are unfamiliar, this is a channel called Theories of Everything, where we explore theories of everything in the physics sense, using my background in mathematical physics."
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"text": " from the University of Toronto, but as well as explore other large grand questions. What is consciousness? Where does it come from? What is reality? What defines truth? What is free will? And do we have it? Of course, increasingly, we've been exploring artificial intelligence and its potential relationship to the fundamental laws."
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"text": " Also, the string theory video that Jonathan mentions is called the iceberg of string theory, and I recommend you check it out. It took approximately two months of writing, four months of editing with four editors, four rewrites, 14 shoots, and there are seven layers. It's the most effort that's gone into any single theories of everything video. It's a rabbit hole of the math of string theory geared toward the graduate level. There's nothing else like it."
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"text": " If that sounds interesting to you, then check out the channel or hit subscribe to get notified. Enjoy this episode with Jonathan Gerard. So Jonathan, what is the Wolframs physics project and what's your role in it? That's a really good question, Kurt. So I guess there are various people involved and I think you'll get slightly different answers or perhaps very different answers depending on who you ask. I'm"
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"text": " I think when we first launched the physics project back in April 2020, we lent hard on this billing of it's a project to find the fundamental theory of physics. That was not really how I viewed it at the time, and it's become even less how I view it over time. Interesting."
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"text": " I'm saying this as a prelude to clarify that what you're about to hear is my own perspective on it, and it will probably differ quite a lot from the perspective given by some other members of the project. Essentially, my view is that the Wolfram Physics Project is an attempt to answer a counterfactual history question."
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"text": " Back in the 17th century, Newton, Leibniz, and a little bit earlier people like Descartes, Galileo, they kind of set the stage for modern theoretical kind of mathematical physics and more broadly for our kind of modern conception of how the exact sciences work."
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"text": " And so essentially the idea was rather than just describing phenomena in these kind of philosophical terms, you could actually construct kind of robust quantitative models of what natural systems do. And that was enabled by a particular piece of mathematical technology or a particular piece of cognitive technology, which was calculus, which later became"
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"text": " you know, mathematical analysis and the basis of differential geometry and all the kind of machinery of modern mathematical physics. So, you know, Newton Leibniz, you know, building off earlier work by people like Archimedes and so on, kind of, you know, they built up this formalism of calculus that sort of enabled modern physics. And"
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"text": " Arguably that choice of formalism that that choice to base physical models on you know essentially analytic calculus based mathematical formalisms has had an impact on our physical intuition right so you know it involves thinking about things in terms of smooth analytic functions in terms of continuously varying kind of gradients of quantities."
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"text": " It necessitates us formalizing notions like space and time in terms of smooth manifolds or real numbers. It involves thinking about things like energy and momenta as being continuously varying quantities. And those are, of course, extremely good idealizations of what's really happening. But I think there's always a danger whenever you have a model like that, that you start to believe in the ontological validity of the model. And so for a lot of physicists, I feel like"
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"text": " It's kind of seeped in and percolated our intuition to the extent that we actually think that space is a, you know, smooth Romani and manifold. We think the energy is a kind of real valued function rather than these just being idealizations of some potentially quite different, you know, underlying reality."
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"text": " Okay, now, fast forward about 300 years, and you have people like Alan Turing and Alonzo Church and Kurt Gödel in the early 20th century building up the beginnings of what became theoretical computer science, right, as a kind of as an as an offshoot of mathematical logic, there were people interested in the question of, you know, what is mathematics? What is mathematical proof? You know, what are mathematical theorems? And that kind of necessitated them building this really quite different mathematical formalism, which initially had different"
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"text": " Manifestations at your turing machines lambda calculus you know general recursive functions etc which then gradually got unified thanks to things like the church turing thesis but so that so now you so in a way."
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"text": " Again, at least the way I like to think about it is the sort of stuff that Newton and Leibniz and people were doing in the 1600s, with analysis, that gave you a systematic way of understanding and exploring continuous mathematical structures. What Turing and Church and Gödel and people did in the early 20th century with computability theory gave one a systematic way of understanding discrete mathematical structures, the kinds of things that could be represented by simple computations and simple programs."
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"text": " I'm now by that point is a calculate this is the sort of calculus based approaches had had a three hundred year head starts in terms of the exact sciences it took a little while before people started thinking actually you know maybe we could use these formalisms from computer theory to construct models of natural phenomena to construct you know scientific models and models for things like fundamental physics."
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"text": " I'm but of course that necessitates being a quite radical departure and how we think about physical laws right that you suddenly have to deviate from thinking about space is some smooth continuous structure and start thinking about it in terms of some discrete combinatorial structure like a kind of network or a graph. I'm in a sense that you moving away from thinking about dynamics in terms of continuous partial differential equations and thinking about it in terms of kind of discrete time step updates like say that the kinds that you can represent using network rewriting rules."
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"text": " And so you know a lot of this is to train in the in the traditional mathematical formulas and find this quite counterintuitive because i say it you know that was those ideas for mathematical analysis of seat so far into our intuition that we think that's actually how the universe works rather than just thinking of it as being a model and so."
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"text": " The way, the slightly poetic way that I like to think about what the physics project is doing is we're trying to address this kind of counterfactual history question of what would have happened if, you know, Turing was born 300 years before Newton, not the other way around. In other words, if we had, if discrete mathematical approaches based on computability theory had a 300 year head start in the foundation to a natural science over continuous mathematical structures based on analysis. That's my kind of zoomed out picture of what it is that we're trying to do. Aha."
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"text": " So there's a lot more that can be said about that of course and i'm sure we'll discuss more of it later but that's at least my kind of that's my. My big picture summary of what i think the physics projects is about it's about trying to reconstruct the foundations of physics not in terms of you know."
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"text": " Larenzian manifolds and continuous space-times, but in terms of things like graphs, hypergraphs, hypergraphy writing, causal networks, and the kinds of discrete structures that could be represented in a very explicit, computable way. There are some nice connections there, by the way, to things like the constructivist foundations of mathematics that arose in the 20th century as well, and we'll likely talk about that later too."
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"text": " In terms of my own role within it, Stephen Wolfram, who I know has appeared on TUI a number of times, has been by far the single most energetic evangelist of these ideas for a very long time. He wrote back in 2002 this book, A New Kind of Science, in which he first postulated the beginnings of these ideas about maybe it's useful to think of fundamental physics in terms of network automata and things like that."
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"text": " And, you know, had some initial hints towards, okay, here's how we might be able to get general relativity, you know, beginnings of quantum mechanics, those kinds of things out of those out of those systems."
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"text": " Um, but then the, you know, those ideas basically lay dormant for a long time. I mean, NKS had, you know, I had this kind of maelstrom of, of, of attention for, for a couple of years. And then mostly, at least physicists mostly ignored it as kind of at least my impression. Um, where, you know, I, as a teenager, you know, I, I read NKS and, um, I, like many people found certain aspects of the way the book is written a little bit off putting, but I thought that there were many, many core ideas in it that that were really, really quite, quite foundationally important."
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"text": " and one of them was this idea about fundamental physics and so you know for a while i kind of advocated like we should be doing you know we should be trying to build physics on these kind of computable models if only just to see what happens right just to see you know where that leads us."
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"text": " Sorry, just a moment. You said that you would be working on these prior to going to the Wolfram School, the summer school."
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"text": " yes yeah exactly so i went to this i went to the wolfram summer school in 2017 as a consequence of my interest in these models so i'd already been doing a little bit of my own kind of work on this the stuff trying"
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"text": " In large parts, in a sense, to rediscover what Stephen had already done. He had these big claims in NKS about being able to derive Einstein equations and things from these graphic writing models. But the details were never included in the book and I tried to ask Stephen about them and he kind of said, oh, I can't really remember how I did that now. And so I spent quite a lot of time trying to reconstruct that and that eventually ended up, that was the thing that"
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"text": " The results to me, you know, attending the summer school and then and then being kind of pulled into Stephen's orbit. And is it your understanding that Stephen actually did have a proof? He just wasn't able to recall it like format or just was too small of a space to publish or that he thinks he was able to prove it. But the tools weren't available at the time. And you think back like maybe he had a sketch, but it wasn't. Well, it's Leonardo's sketch versus the Mona Lisa."
},
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"text": " Hi, I'm here to pick up my son Milo. There's no Milo here. Who picked up my son from school? Streaming only on Peacock. I'm gonna need the name of everyone that could have a connection. You don't understand. It was just the five of us. So this was all planned? What are you gonna do? I will do whatever it takes to get my son back. I honestly didn't see this coming. These nice people killing each other. All Her Fault, a new series streaming now only on Peacock."
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"text": " Right, right. I think the Leonardo sketch versus the Mona Lisa analogy is probably the right one. My suspicion, based on what I know of the history of that book and also based on what I know of Stephen's personality, is that Stephen had proved it to his own satisfaction, but probably not to the satisfaction of anyone else, right? Interesting. I think many of us are like this, right? If you encounter some problem or some phenomenon you don't really understand,"
},
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"end_time": 870.179,
"index": 39,
"start_time": 845.265,
"text": " And you go when you try and understand how it works you try and prove some results about it and eventually you convince yourself that it can be done or that you convince yourself that there is an explanation you don't necessarily tie together all the details to the point where you could actually publish it and make it understandable to other people but kind of to your own intellectual satisfaction it's like oh yeah now i i'm at least convinced that that can work my impression is that that's basically that's essentially where the kind of"
},
{
"end_time": 895.23,
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"start_time": 870.179,
"text": " Physics project formalism ended up in two thousand two that steven thought about it for a while had some research assistance look at and eventually they kind of convinced themselves yes. It would be possible to derive an equations from these kind of formalisms but i highly from what i've seen of the material was put together and so i don't think anyone actually trace that proof you know with complete mathematical position eventually in two thousand nineteen steven myself and max piss can of we decided."
},
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"end_time": 924.548,
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"start_time": 895.52,
"text": " various reasons that it was kind of the right time for us to do this project in a serious way. Stephen had some new ideas about how we could simplify the formalism a little bit. I'd made some recent progress in kind of understanding the mathematical underpinnings of it. Max had just finished writing some really quite nicely optimized kind of low level C++ code for enumerating these hypergraph systems really efficiently. And so we decided like, okay, if we're not going to do it now, it's never going to happen. And so that was then the beginnings of the physics project."
},
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"text": " And so now i'm i'm less i guess less actively involved in the you know in the project as a kind of branding entity but i you know i'm still kind of actively working on the formalism and still trying to push ahead in various mathematical directions trying to kind of concreted by the foundations of what we're doing and make connections to you know to existing areas of mathematical physics."
},
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"text": " I see, I see. So I also noticed a similar problem as yourself across society. So across history, that people entwine this prevalent application with some ontological status. So what I mean by that is you'll have a tool which is ubiquitous and usefulness. And then you start to think that there's some reality synonymous with that. So another example would be an ancient poet who would see the power of poetry and think that what lies at the fundament is narrative pieces."
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"end_time": 1001.937,
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"start_time": 976.647,
"text": " Or a mystic who sees consciousness everywhere almost by definition and then believes consciousness must lie at the root of reality. And some people, Max Tegmark would be an example of this, find that math is so powerful, it must be what reality is. So it's also not clear to me whether computation is another such fashionable instance of a tool being so powerful that we mistake its effectiveness with its substantiveness."
},
{
"end_time": 1011.596,
"index": 45,
"start_time": 1002.363,
"text": " And I understand that Stephen may think differently. I understand that you may think differently. So please explain. That's a fantastic point. I suspect."
},
{
"end_time": 1036.647,
"index": 46,
"start_time": 1011.783,
"text": " From at least from what you said, I think I think our views may be quite similar on this, that I'm reminded of this meme that circulated on Twitter a little while ago about, you know, people saying, you know, immediately after the invention of kind of writing systems and narrative structure, everyone goes, ah, yes, the universe, you know, the cosmos must be a book, right? And then, you know, immediately after the invention of mathematics, ah, yes, the cosmos must be made of mathematics. And then it's, you know, immediately after the invention of the computer, ah, yes, the converse, the cosmos must be a computer."
},
{
"end_time": 1065.367,
"index": 47,
"start_time": 1037.073,
"text": " It's a folly that we've fallen into throughout all of human history. My feeling about this is always that we build models using the kind of ambient technology of our time. And when I say technology, I don't just mean nuts and bolts technology, I also mean kind of thinking technology. There are kind of ambient ideas and processes that we have access to."
},
{
"end_time": 1086.732,
"index": 48,
"start_time": 1065.367,
"text": " And we use those as a kind of raw substrate for making models of the world. So, you know, it's unsurprising that when people like Descartes and Newton built models of the cosmos, you know, of the solar system and so on, they describe them in terms of clockwork by analogies to clockwork mechanisms. Right. And, you know, Descartes even sort of more or less directly wrote that he thought that the solar system was a piece of clockwork."
},
{
"end_time": 1109.224,
"index": 49,
"start_time": 1086.732,
"text": " When he actually thought that in the logical sense of whether it was just a kind of poetic metaphor i don't completely know but you know it's sort of obvious that would happen right because you know that the the fifteenth century sixteenth century that was sort of the height of of clockwork technology in an ambient society. And so you know we live right now and it's arguably the zenith of kind of computational technology and so again it's completely unsurprising that we build models of the cosmos."
},
{
"end_time": 1136.288,
"index": 50,
"start_time": 1109.718,
"text": " Base largely on computer based largely or partly on computational ideas. Yeah, I agree. I think it would be a folly. And I think you're right. This is maybe one area where perhaps Stephen and I differ slightly on in our kind of philosophical conception. I personally feel like it's folly to say therefore, you know, the universe must be a computer, right? Or that, you know, that, that, um, yeah, my feeling about it is the strongest we can say is that"
},
{
"end_time": 1153.302,
"index": 51,
"start_time": 1136.544,
"text": " You know modeling the universe as a turing machine is a useful scientific model and it's a useful thinking tool by which to reason through kind of various problems and i think it's. Yeah i would be uncomfortable. Endowing it with any greater ontological significance than that."
},
{
"end_time": 1178.268,
"index": 52,
"start_time": 1153.814,
"text": " That being said, of course, there are also lots of examples where people have made the opposite mistake. The classic example is, say, Hendrik Lorentz, who basically invented the whole formalism of special relativity, but he said, oh, no, no, this is just a mathematical trick. He discovered the right form of time dilation and length contraction, but he said, this is just some coordinate change. It doesn't have any physical effect. It's just a formalism."
},
{
"end_time": 1204.07,
"index": 53,
"start_time": 1178.268,
"text": " And then really the contribution of Einstein was to say, no, it's not just a formalism. This is an actual physical effect. And here's how we might be able to measure it. And so, yeah, you, I'm just trying to, I'm trying to indicate that there's, you have to thread a delicate needle there. Yeah. So you mentioned Turing and there's another approach called constructor theory, which generalizes Turing machines or universal Turing machines to universal constructors."
},
{
"end_time": 1228.575,
"index": 54,
"start_time": 1204.326,
"text": " So called universal constructors. So I'd like you to explain what those are to the degree that you have studied it and then its relationship to what you work on at the Wolframs physics project. And by the way, string theory, loop quantum gravity, they have these succinct names, but WPP doesn't have a graspable, apprehensible name, at least not to me to be able to echo that. So is there one that you all use internally to refer to it?"
},
{
"end_time": 1239.275,
"index": 55,
"start_time": 1230.435,
"text": " Okay, so on that, yeah, I'm not a fan of the naming of the Wolfram physics project or indeed even the Wolfram model."
},
{
"end_time": 1267.637,
"index": 56,
"start_time": 1240.094,
"text": " Which is a slightly more succinct version. In a lot of what I've written, I describe it and I use the term hypergraph dynamics or sometimes hypergraphy writing dynamics. OK, because I think that's a that's a more descriptive title for what it really is. But no, I agree. I think I think as a branding exercise, there's still there's still more work that needs to be done. So for the sake of us speaking more quickly, we'll say the HD model. So in this HD model, what is its relationship to what was the category? No, it wasn't category."
},
{
"end_time": 1295.077,
"index": 57,
"start_time": 1267.961,
"text": " It was constructed construct, right? Okay. So what is the HD models relationship to constructor theory? Although that's, that's an interesting Freudian slip because I think basically the relationship is category theory, right? So, um, yeah, okay. So, so I mean, with the, with the proviso that, you know, again, I, I know that you've had Chiara Moleto on, on, on TOE before, right? So I, I'm, I'm certainly not an expert on constructor theory. I've read some of Chiara's and David Deutsch's, um, uh, papers on these, on these topics, but, um,"
},
{
"end_time": 1304.104,
"index": 58,
"start_time": 1295.384,
"text": " Sorry i as you say i can give an explanation to the extent that i understand it."
},
{
"end_time": 1331.049,
"index": 59,
"start_time": 1304.855,
"text": " rather than describing physical laws in terms of kind of you know equations of motion right so in the traditional conception of physics we would say you know you've got some initial state of a system you have some equations of motion that describe the dynamics of how it evolves and then you you know it evolves down to some final state uh the idea with constructed theory is you say rather than formulating stuff in terms of equations of motion you formulate things in terms of what classes of transformations are and are not permitted so uh"
},
{
"end_time": 1360.435,
"index": 60,
"start_time": 1331.305,
"text": " And I think one of the classic examples that I think Deutsch uses in one of his early papers, and I know that Chiara has done additional work on, is the second law of thermodynamics, and indeed the first law of thermodynamics, right? So thermodynamic laws are not really expressible in terms of equations of motion, or at least not in a very direct way. They're really saying quite global statements about what classes of physical transformations are and are not possible, right? They're saying you cannot build a perpetual motion machine of the first kind or the second kind or whatever, right? That there is no valid"
},
{
"end_time": 1372.159,
"index": 61,
"start_time": 1360.435,
"text": " Procedure that takes you from this class of initial states to this class of final states that you know reduce global entropy or that you know create free energy or whatever right and that's a really quite different way of conceptualizing the laws of physics."
},
{
"end_time": 1400.708,
"index": 62,
"start_time": 1372.705,
"text": " So constructive theory, as I understand it, is a way of applying that to physics as a whole, to saying we formalize physical laws not in terms of initial states and equations of motion, but in terms of initial substrates, final substrates, and constructions, which are these general processes that I guess one can think of as being like generalizations of catalysts. It's really a grand generalization of the theory of catalysis in chemistry. You're describing"
},
{
"end_time": 1425.145,
"index": 63,
"start_time": 1401.834,
"text": " This enables this process to happen, which allows this class of transformations between these classes of substrates or something. Now, inadvertently, you brought up this question of category theory or this concept of category theory. I have to be a little bit careful with what I say here because I know that the few people I know who work in constructive theory say that what they're doing is not really category theory."
},
{
"end_time": 1444.565,
"index": 64,
"start_time": 1425.589,
"text": " I would argue has some quite in terms of the philosophical conception of it it has some quite remarkable similarities so. To pivot momentarily to talk about the duality between set theory and category theories as foundations for mathematics so with you know."
},
{
"end_time": 1472.193,
"index": 65,
"start_time": 1445.111,
"text": " Since the late 19th century, early 20th century, it's been the kind of vogue to build mathematical foundations based on set theory, based on things like Zemileo Frankel set theory or Hilbert Bernays Gödel set theory and other things, where your fundamental object is a set, some collection of stuff, which then you can apply various operations to, and the idea is you build mathematical structures out of sets. Now, set theory is a very"
},
{
"end_time": 1494.377,
"index": 66,
"start_time": 1472.995,
"text": " Is a is a model of mathematics that. Depends very heavily on internal structure right so for instance in the in the standard axioms of set theory you have things like the axiom of extensionality that essentially says two sets are equivalent if they have two sets are identical if they have the same elements. What involves you saying you know identifying sets based on looking inside them and seeing what's inside."
},
{
"end_time": 1517.637,
"index": 67,
"start_time": 1494.838,
"text": " But there's another way that you can think about mathematical structure which is you say, i'm not going to i'm not i'm not gonna allow myself to look inside this object i'm gonna treat it some atomic thing. And instead i'm going to give it an identity based on how it relates to all other objects of the same type. So what transformations can i so you know to give a concrete example right suppose i've got some some topological space."
},
{
"end_time": 1546.749,
"index": 68,
"start_time": 1518.37,
"text": " Um, so one of the kind of set theoretic view is okay. That topological space is a set of points. It's a collection of points that have a topology defined on them. The kind of more category theoretic view would be to say, uh, actually that topological space is defined as the collection of continuous transformations that can be applied to it. So that space can be continuously deformed into some class of other spaces. And that class of other spaces that it can be deformed into is what identifies the space you started from."
},
{
"end_time": 1570.299,
"index": 69,
"start_time": 1547.329,
"text": " And so that's a so and you can define that without ever having to talk about points or you know what was inside it right in fact there's a whole generalization of topology called pointless topology or locale theory which is all about doing topology without an a priori notion of points. So in a way it necessitates this conceptual shift from a an internal structure view to a kind of process theoretic view."
},
{
"end_time": 1598.166,
"index": 70,
"start_time": 1571.152,
"text": " Um, and so that was a viewpoint that was really advocated by the pioneers of, of, of Kaspi theory, um, as Samuel Allenberg and Saunders McLean, uh, and also some other people who were working in topology, like Jean-Pierre Serre and Alexander Grotendieck and others. Um, there was a kind of radically different way to conceptualize the foundations of mathematics. Sorry to interrupt. Just as a point for the audience, you mentioned the word duality between sets and categories. Now, do you mean that in a literal sense or just morally there's a duality?"
},
{
"end_time": 1625.145,
"index": 71,
"start_time": 1598.166,
"text": " Because category theorists make a huge fuss that what they're dealing with aren't always like small categories are sets but or can be thought of as sets but not categories as such. Right okay yeah and i shouldn't have said i mean yes no the short answer is no i don't mean duality in any formal sense and in particular it's a dangerous word to use around category theorists because it means something very precise it means that"
},
{
"end_time": 1648.575,
"index": 72,
"start_time": 1625.572,
"text": " uh... dual concepts of ones that are that are equivalent up to reversal of the direction of morphisms. I certainly don't mean that. I meant duality in the sense that so there is a precise sense in which set theory and category theory are equivalently valid foundations for mathematics and that precise sense is"
},
{
"end_time": 1670.452,
"index": 73,
"start_time": 1649.36,
"text": " I mean we can go deep in the weeds if you want it's that's you know we'll see where the conversation goes but the basic idea is there's a there's a fee as a branch of category theory called elementary topos theory. Which is all about using category theory is a foundation for logic and mathematics and the idea there is so in from a category theoretic perspective sets."
},
{
"end_time": 1693.404,
"index": 74,
"start_time": 1670.862,
"text": " Are just they just form one particular category there is a category called set which is objects are sets and whose transformation is morphisms are set valued functions. And then you might say well you know why is that so important like what's what's so great about set that we build all mathematics on that it's just one random category in the space of possible categories elementary topos theory is all about asking what are the essential properties of set."
},
{
"end_time": 1722.295,
"index": 75,
"start_time": 1693.899,
"text": " that make it a quote unquote good place to do mathematics and and can we abstract those out and figure out some much more general class of mathematical structures some jet some more general class of categories within which internal to which we can build mathematical structures and uh and that gives us the idea of an elementary topos i'm saying elementary because there's a slightly different idea called a growth and deep topos that's related but not quite equivalent and whatever so um but generally when logicians say topos they mean elementary topos"
},
{
"end_time": 1744.019,
"index": 76,
"start_time": 1723.063,
"text": " So yeah, there's a particular kind of category which has these technical conditions that it has all finite limits and it possesses a sub-object classifier or equivalently a power object. But basically what it means is that it has the minimal algebraic structure that sets have, that you can do analogs of things like set intersections, set unions, that you can take power sets, you can do subsets. And it"
},
{
"end_time": 1769.838,
"index": 77,
"start_time": 1744.565,
"text": " It kind of detects for you a much larger class of mathematical structures, these elementary top hosses, which have those same features. And so then the argument goes, well, therefore you can build mathematics internal to any of those top hosses, and the mathematical structures that you get out are in some deep sense isomorphic to the ones that you would have got if you built mathematics based on set."
},
{
"end_time": 1799.787,
"index": 78,
"start_time": 1770.435,
"text": " Yes, and now the relationship between constructor theory and HD, which is the hypergraph dynamics or Wolfram's physics project for people who are just tuning in."
},
{
"end_time": 1820.333,
"index": 79,
"start_time": 1800.794,
"text": " Right right so yes the the the excursion to talk about category theory is in a sense the my reason for bringing that up is because i think that that same conceptual shift that i was describing where you go from thinking about internal structure to thinking about kind of process theories that's been applied to many other areas it's been applied say in quantum mechanics right so where there's"
},
{
"end_time": 1834.872,
"index": 80,
"start_time": 1820.64,
"text": " In the traditional conception, you'd say quantum states are fundamental and you have Hilbert spaces that are spaces of quantum states and then you have operators that transform those Hilbert spaces, but they're somehow secondary. Then there's this rather different, and that's the Von Neumann Dirac picture."
},
{
"end_time": 1857.858,
"index": 81,
"start_time": 1835.111,
"text": " Then there's this rather different formalization of the foundations of quantum mechanics that's due to Samson Abramsky and Bob Kocher, which is categorical quantum mechanics, where the idea is you say actually the spaces of states, those are secondary and what really matters are quantum processes. What matters are the transformations from one space of states to another. And you describe quantum mechanics purely in terms of the algebra of those processes. So,"
},
{
"end_time": 1883.114,
"index": 82,
"start_time": 1858.439,
"text": " And there are many other examples of that. I mean, you know, things like functional programming versus imperative programming or lambda calculus versus Turing machines in a sense that these are all instances of, you know, thinking about things in terms of processes and functions rather than in terms of states and sets. I view constructor theory as being the kind of processes and functions version of physics, whereas traditional mathematical physics is the kind of sets and structures version of physics."
},
{
"end_time": 1897.295,
"index": 83,
"start_time": 1883.78,
"text": " I'm in a sense the the the hypergraph dynamics view slash willful model. Yes, you have you want to describe it and is one that nicely synthesizes both cases because in the hypergraph dynamics case you have both"
},
{
"end_time": 1921.459,
"index": 84,
"start_time": 1897.807,
"text": " The internal structure that you have an actual hypergraph and you can look inside it and you can talk about vertices and nodes and things like that, vertices and edges and so on. But you also have a kind of process algebra because you have this multi-way system where I apply lots of different transformations to the hypergraph and I don't just get a single transformation path, I get this whole tree or directed acyclic graph of different transformation paths."
},
{
"end_time": 1935.452,
"index": 85,
"start_time": 1921.459,
"text": " And so then i have so in the sense you can imagine defining an algebra and we've done this in other in another work where you know you have a kind of a rule for how you compose different edges in the in the multi-way system both sequentially and in parallel."
},
{
"end_time": 1962.944,
"index": 86,
"start_time": 1935.981,
"text": " And you get this nice algebraic structure that happens to have a category theoretic interpretation. And so in a way, the pure hypergraph view, that's a kind of set theory structural view. The pure multi-way system view, that's a kind of pure process theory category theoretic view. And then one of the kind of really interesting ideas that comes out of thinking about physics in those terms is the general relativity and quantum mechanics emerge from those two limiting cases."
},
{
"end_time": 1982.193,
"index": 87,
"start_time": 1963.78,
"text": " Right, so in a sense, if you neglect all considerations of the multiway system and you just care about the internal structure of the hypergraph and the causal graph, and you define a kind of discrete differential geometric theory over those, what you get in some appropriate limit is general relativity for some cases."
},
{
"end_time": 2001.049,
"index": 88,
"start_time": 1982.5,
"text": " On the other hand, if you neglect all considerations of the internal structure of the hypergraph and you care only about the process algebra of the multi-way system, what you get is categorical quantum mechanics. You get a symmetric monoidal category that has the same algebraic structure as the category of finite dimensional Herbert spaces in quantum mechanics. And so, in a sense, the"
},
{
"end_time": 2020.043,
"index": 89,
"start_time": 2001.63,
"text": " Traditional physics, which is very structural, gives you one limit, gives you the general relativistic limit. The kind of more constructive theoretic view, which is more process theoretic, more category oriented, gives you another limit, gives you the quantum mechanics limit. Yeah, and do you need a daggersymmetric monoidal category or is the symmetric monoidal enough?"
},
{
"end_time": 2048.217,
"index": 90,
"start_time": 2020.879,
"text": " You do need it to be dagger symmetric. That's a very important point. So I'm going to assume not all of your followers and listeners are card carrying category theorists. So just as a very quick summary of what Kurt means by dagger symmetric. So actually, maybe we should say what we mean by symmetric monoidal. So if you have a category, if you just think of it as some collection of simple processes, like in the multi-way system cases, just individual rewrites of a hypergraph."
},
{
"end_time": 2071.8,
"index": 91,
"start_time": 2048.797,
"text": " Then you can compose those things together sequentially, you can apply rewrite one then rewrite two and you get some result. There's also a case where you can do that in any category. There are also cases where you can apply them in parallel, you can do rewrite one and rewrite two simultaneously and in a multi-way system that's always going to be possible. And then you get what's called a monoidal category or actually a symmetric monoidal category if it doesn't matter which way around you compose them."
},
{
"end_time": 2086.203,
"index": 92,
"start_time": 2072.398,
"text": " And that kind of generalizes the tensor product structure in quantum mechanics. And then you can also have what's called a dagger structure. And so the dagger structure is a thing that generalizes the Hermitian adjoint operation in quantum mechanics, the thing that gives you time reversal."
},
{
"end_time": 2114.804,
"index": 93,
"start_time": 2086.681,
"text": " So in that case, then you have some operation that you can take a rewrite and you can reverse it. And for the hypergraphy writing rules, there's a guarantee that you can always do that. There's yet another level of structure, which is what's called a compact closed structure, which means that you can essentially do the analog of taking duels of spaces. So for those of you who know about quantum mechanics, that's the generalization of exchanging bras for kets and vice versa."
},
{
"end_time": 2129.087,
"index": 94,
"start_time": 2114.804,
"text": " I'm and again you can do that for in the case of hyper graphs there's a natural duality operation because you can you can it for any hyper graph you can construct a dual hyper graph whose vertex set is the hyper edge set of the old set of the old hyper graph and use hyper edge set."
},
{
"end_time": 2154.36,
"index": 95,
"start_time": 2129.292,
"text": " Is the incident structure of those hyper edges in the in the new case and that's a that gives you a duality that satisfies the axioms of compact closure. So you so and yeah in a sense the the the key idea behind categorical quantum mechanics is that if you have one of these daggers structures you have a compact closed structure you have a symmetric monoidal structure and they're all compatible then what you've got is again by analogy to topos theory some mathematical structure which is"
},
{
"end_time": 2175.657,
"index": 96,
"start_time": 2154.94,
"text": " You know in which you can build a theory that is isomorphic to quantum mechanics and that's what we have. Yeah, that's what that's what we have in the case of multi-way systems. So when we spoke approximately three years ago, I believe we had a zoom meeting. It could have been a phone call. I recall that you were saying that you were working maybe the year prior on something where"
},
{
"end_time": 2201.766,
"index": 97,
"start_time": 2176.391,
"text": " Your operators, your measurements don't have to be self-adjoint. And the reason was self-adjointness is there because we want real eigenvalues. And that just means for people who are listening, you want to measure something that's real, not imaginary. What is an imaginary tick that usually comes down to ticks or not ticks and the measurement device. But then I recall you said that you were working on constructing quantum mechanics with observables that weren't"
},
{
"end_time": 2231.101,
"index": 98,
"start_time": 2202.722,
"text": " So self-adjointness is required. Sorry, self-adjointness implies real eigenvalues, but there were other ways of getting real eigenvalues that aren't self-adjoint. I don't know if I misunderstood what you said or if I'm recapitulating incorrectly, but please spell out that research if this rings the bell to you. So your memory is far better than mine. So that's that sounds like a very accurate summary of something I would have said, but I actually have no memory of saying it. So but yes, no, it's"
},
{
"end_time": 2256.544,
"index": 99,
"start_time": 2231.493,
"text": " Yes, so and to be clear, that's by no means my idea. So there's there's a field called PT symmetric quantum mechanics and sometimes known as non Hermitian quantum mechanics, which have various developers. Carl Bender is one of them. I think there's a guy called Jonathan Brody. Oh, hey, Brody. I can't remember Carl Bender. So I just spoke to him about a couple of months ago, coincidentally."
},
{
"end_time": 2274.497,
"index": 100,
"start_time": 2257.159,
"text": " Oh, well, you should have asked him this question. Yes. So Bender and Brody and others. Dohey Brody. I don't know why there's another person. Maybe Jonathan Keating is involved somehow. But anyway, so it's been a little while since I thought about this, as you can tell. But so, yes."
},
{
"end_time": 2300.401,
"index": 101,
"start_time": 2274.497,
"text": " There's a generalization of standard unitary Hermitian quantum mechanics. As Kurt mentioned, in the standard mathematical formulas of quantum mechanics, your measurements seem to be Hermitian. When you take the adjoint of the operator, you get the same result. And your evolution operators seem to be unitary, so that when you take the adjoint, you get the time reversal of the result."
},
{
"end_time": 2314.445,
"index": 102,
"start_time": 2301.084,
"text": " I'm in a sense that's the key difference between evolution and measurement in standard for some and we know that if you're. Operate your hamiltonian is commission."
},
{
"end_time": 2333.2,
"index": 103,
"start_time": 2314.753,
"text": " Add the thing that is in the equation that's a mission operator then the solution to the equation that gives you the military evolution that gives you a solution operator sorry is guaranteed to be unitary and also the values of the measurement operator which is which is cut said in a sense the those your measurement outcomes those are guaranteed to be to be real."
},
{
"end_time": 2353.302,
"index": 104,
"start_time": 2333.2,
"text": " That's a sufficient condition hermiticity but it's not a necessary one so that you can have non permission measurement operators that still give you real eigenvalues. And where you don't get a unitary evolution operator. In the algebraic sense but you get what is often called physical unitarity."
},
{
"end_time": 2371.92,
"index": 105,
"start_time": 2353.814,
"text": " Unitarity means a bunch of things. Algebraically, as I say, it means that when you apply the adjoint operator, you get the time reversal. Therefore, if you take a unitary evolution operator and it's adjoint, you get the identity matrix or the identity operator. So as soon as you have non-hermitian Hamiltonians,"
},
{
"end_time": 2401.288,
"index": 106,
"start_time": 2372.193,
"text": " Ceases to be true and also you end up with probabilities so in in the interpretation where your quantum amplitudes are really kind of related to probabilities right where you take the you know you take the absolute value of the amplitude squared and that gives you the probability now as soon as you have non unitary evolution operators your probability amplitudes are not your probabilities are not guaranteed to sum to one so that looks on the surface like it's completely sort of you know hopeless um but"
},
{
"end_time": 2424.974,
"index": 107,
"start_time": 2401.8,
"text": " Actually, you can still get real measurement outcomes. The interpretation of the norm squareds of the amplitudes as being probabilities, that's simply an interpretation. It's not mandated by the formalism. And what people like Bender and Brody showed was that you could still have a consistent theory where you have parity time symmetry. So you still have a time symmetric theory of quantum mechanics. It's still invariant under parity"
},
{
"end_time": 2440.947,
"index": 108,
"start_time": 2424.974,
"text": " Transmissions and it's still possible even when you apply one of these non unitary evolution operators to to to some initial state it's still always possible to reconstruct what the initial state was from the final state i mean that's really what time symmetry means and so."
},
{
"end_time": 2460.606,
"index": 109,
"start_time": 2440.947,
"text": " It was widely believe i think for a long time that if you didn't have amplitude is normal squared some to one then you wouldn't be able to do that and what bender brody shows no you can you have to be you still have restrictions but just weaker than the restrictions we thought existed. I was probably bringing that up because at the time."
},
{
"end_time": 2483.524,
"index": 110,
"start_time": 2461.049,
"text": " Okay, two reasons. One was, it turns out there are these nice connections, which I was a little bit obsessed with a few years back, between PT-symmetric quantum mechanics and the Riemann hypothesis. So a colleague of mine, a former colleague of mine from Wolfram Research, Paul Abbot, was the person who actually told me about this. And so the idea there is there's this thing called the"
},
{
"end_time": 2510.998,
"index": 111,
"start_time": 2484.36,
"text": " Okay, let me get this right. So there's a thing, there's a thing called the Hilbert-Pollier conjecture, which is the conjecture that we have, which I think is reasonably well known. I would like at least some people, people in our kind of area have often heard about. Yeah, which is the idea that somehow the non-trivial zeros of the Riemann zeta function should be related to the, to the, to the eigen spectrum of some manifestly self adjoint operator."
},
{
"end_time": 2540.503,
"index": 112,
"start_time": 2511.92,
"text": " um, and so it's somehow a connection between the analytic number theory of, of, you know, the zeta function and the kind of foundation, the operator theoretic foundations of quantum mechanics. And then, uh, there's the thing called the Berry Keating Hamiltonian. Uh, so Mike Berry and Jonathan Keating constructed, uh, a case of what they conjectured to be a Hilbert polio type, um, a type Hamiltonian. So, so in other words, a Hamiltonian where if you could prove that it was manifestly self adjoint, um, it would be equivalent to proving the Riemann hypothesis."
},
{
"end_time": 2560.589,
"index": 113,
"start_time": 2540.811,
"text": " The problem is that Hamiltonian is actually not, it's not self adjoint, it's not Hermitian in the traditional sense, but it is Hermitian in this PT symmetric sense. So it's not algebraically Hermitian, it's not equal to its own adjoint, but it's still a valid Hamiltonian for parity time symmetric quantum mechanics."
},
{
"end_time": 2580.282,
"index": 114,
"start_time": 2560.589,
"text": " I'm and so by trying to think about the hypothesis in terms of quantum formalism you end up being kind of inevitably drawn into thinking about non commission foundations and these kind of symmetric formulations that's how i. Let's learn about this nice expect i was talking about the time party because i was just interested in that connection."
},
{
"end_time": 2602.21,
"index": 115,
"start_time": 2580.282,
"text": " It turns out that the the spectrum of these operators are related not just to the receipt to the reman zeta function but also to what's called the hovitz zeta function and and and several other uh objects in analytic number theory but also at the time this is turned out to be false but at the time i thought that the version of quantum mechanics that we would end up with from these multi-way systems would be a pt symmetric"
},
{
"end_time": 2629.394,
"index": 116,
"start_time": 2602.671,
"text": " Formalism for quantum mechanics not standard quantum mechanics as it turns out Actually, there's a way you can do it where you get standard quantum mechanics complete with proper hermeticity and unitarity So you don't really need to worry about that But at the time I was quite nervous that we weren't gonna get that but we were gonna get some weird non Hermitian version of quantum mechanics We'd have to worry about that. Do you end up getting both or just one? So there is a construction where you can get I mean like"
},
{
"end_time": 2654.292,
"index": 117,
"start_time": 2630.077,
"text": " What i want to stress is that there's no you know there's no canonical if you just give it a multi-way system and you said derive quantum mechanics right there's no canonical way to do that okay the the approach that we ended up taking was to show that as i say that there's this algebraic structure that has this dagger symmetric compact closed monoidal category feature and therefore you can get standard quantum mechanics because standard quantum mechanics is what's developed kind of internal to that category."
},
{
"end_time": 2683.507,
"index": 118,
"start_time": 2654.497,
"text": " So just as an aside, a pedagogical aside for the people who aren't mathematicians or physicists, they hear terms like closed, compact, symmetric, monoidal, dagger, unitary, adjoint,"
},
{
"end_time": 2707.09,
"index": 119,
"start_time": 2683.882,
"text": " And they're wondering, why are we using these words to describe physical processes? And the reason is because the mathematicians got there first. So physicists are trying to describe something and then they see that there's some tools invented by other people, goes by other names, and then they end up applying in the physical situations. But when the physicist gets there first, they're often intuitive names, momentum, spin up, spin down. It's actually, it makes more sense."
},
{
"end_time": 2722.346,
"index": 120,
"start_time": 2707.295,
"text": " So just in case people are wondering, this terminology is needlessly complex. Well, it can be to the outsider, but as you become familiar with them, you just realize historically, if you want to communicate to mathematicians and vice versa, then just use whatever terms were invented first."
},
{
"end_time": 2750.845,
"index": 121,
"start_time": 2722.346,
"text": " I would say there's the opposite problem as well. There are cases where physicists discovered concepts first that have been subsumed into mathematics and the physical names don't really make any sense in the mathematical context. There are things like physicists, because of general relativity, were really the first people to seriously think about and formalize notions like torsion in differential manifolds and concepts like metric affine connections. The standard connection that you define on a manifold with torsion"
},
{
"end_time": 2779.326,
"index": 122,
"start_time": 2750.845,
"text": " Is the spin connection so named because it was originally used in these metric affine theories where you have a spin tensor that describes the spin of particles but so now that you know that there are these ideas in algebraic and differential geometry called spin connections and spin holonomies and I'm nothing to do with spin nothing but I just you know it's just been you know it's the it's the relic of the kind of physical origins of the subject there are several cases of that too yeah I haven't announced this and I'm not sure if I'll end up doing this I've been writing a script for myself"
},
{
"end_time": 2801.22,
"index": 123,
"start_time": 2779.701,
"text": " On words that I dislike in physics and math, sometimes they'll say something like, what's the callback? What is it called? The callback, callback, libeler, callback, wibler diversions. Okay. If you just say that it doesn't mean anything, you have to know what it's defined as. So calling something the earth movers distance is much more intuitive."
},
{
"end_time": 2831.323,
"index": 124,
"start_time": 2801.749,
"text": " And then I have this whole list of words that I say, okay, it's so foolish to call it this. Why don't you just call it by its descriptive name? And then I suggest some descriptive names and there's another class of foolish names to myself. Torsion is one of them, but it's not because it's a bad name. It's because it's used in different senses on an elliptic curve. There's Torsion, but it has nothing to do with the Torsion in differential geometry, which as far as I can tell, maybe you can tell me the difference here that in cohomology,"
},
{
"end_time": 2845.299,
"index": 125,
"start_time": 2831.715,
"text": " There's torsion, where if you are using the field of the integers, and then you go to the reals, if they're not equivalent, then you say it has torsion. Yes, yes. Same as the differential geometric torsion, as far as I can tell."
},
{
"end_time": 2867.671,
"index": 126,
"start_time": 2846.186,
"text": " I think that's true, yeah. So I think that confusion has arisen because it's one of these examples of like, you know, independent evolution. So there was a notion of torsion that appeared in group theory, but then because of that got subsumed into, as you say, things like homology theory and cohomology theory. So in group theory, a group is defined as being torsion if it's"
},
{
"end_time": 2881.254,
"index": 127,
"start_time": 2868.319,
"text": " If it has only finite generators, generates a finite order, so the generators of a group, the things that you multiply, you exponentiate to get all elements of the group, if there are"
},
{
"end_time": 2909.275,
"index": 128,
"start_time": 2881.971,
"text": " If the group is generated only by generators of finite order, then you say it's a torsion group and you can talk about torsion subgroups or you could talk about the torsion part of group. And so, yeah, it appears a lot in the theory of elliptic curves, because, you know, there are things like the the model of a theorem that are talking about, you know, when you when you take rational points on elliptic curves, you can ask about how large is the torsion part, how large is the non torsion part. And there are things like butchers, winners and dire conjecture that are all about relating those ideas."
},
{
"end_time": 2935.247,
"index": 129,
"start_time": 2909.633,
"text": " But then yeah then quite independently there was a notion of torsion that appeared in differential geometry that as you know is that you know it's just essentially it's a measure of you know i have points x and y how much how different is the distance from x to y and the difference from y to x and and the name there comes from the fact that in the classical kind of gaussian theory of of geometry of surfaces uh it's it's really it's the concept that gives you the torsion of of a curve right that you know how much the curve is twisting"
},
{
"end_time": 2956.408,
"index": 130,
"start_time": 2935.623,
"text": " Yeah, as far as I know, those two names are unrelated. And as you say, there are these awkward areas like homology theory where it's partly about spaces and about groups. And so it's kind of unclear which one you're talking about. This is a great point to linger on here, particularly about torsion, because I have a video that is controversially titled that gravity is not curvature."
},
{
"end_time": 2980.009,
"index": 131,
"start_time": 2956.92,
"text": " For some context, here's the String Theory iceberg video that's being referenced, where I talk about gravity is not curvature. The link is in the description. If you listen to this podcast, you'll hear me say often that it's not so clear gravity is merely the curvature of spacetime. Yes, you heard that right. You can formulate the exact predictions of general relativity, but with a model of zero curvature with torsion, non-zero torsion, that's Einstein Cartan,"
},
{
"end_time": 3002.125,
"index": 132,
"start_time": 2980.009,
"text": " You can also assume that there's no curvature and there's no torsion, but there is something called non-metricity. That's something called symmetric teleparallel gravity. Something else I like to explore are higher spin gravitons. That is controversially titled that gravity is not curvature. It's just the saying that there are alternative formulations with torsion or non-metricity. For people who don't know, general relativity is formulated as"
},
{
"end_time": 3030.247,
"index": 133,
"start_time": 3002.671,
"text": " Gravity is curvature of space time, but you can get equivalent predictions. If you don't think of curvature, you can think of zero curvature, but the presence of so-called torsion or zero curvature and zero torsion, but the presence of so-called non-matricity. Okay. These are seen as equivalent formulations, but I'm wondering if the Wolfram's physics project or the hyper graph dynamical approach actually identifies one of them as being more canonical."
},
{
"end_time": 3061.101,
"index": 134,
"start_time": 3032.159,
"text": " So, unfortunately, I think, at least based on stuff that I've done, I think the answer is no. And also, I think it actually makes the problem worse. I mean, if you're so if you are, if you're concerned by the fact that there's this kind of there's this apparent arbitrary freedom of do you choose to fix the contortion tensor or the non-matricity tensor or the curvature tensor or whatever. Thinking about things in terms of hypergraphs, you actually get yet another free free parameter, which is dimension."
},
{
"end_time": 3091.357,
"index": 135,
"start_time": 3061.8,
"text": " So in a hypergraph setting, again, I know you've had Stephen on here before, and I know that he's covered a lot of these ideas, so I'll just very briefly summarize. So hypergraphs have no a priori notion of dimension. They have no a priori notion of curvature. You can calculate those things subject to certain assumptions where you say, I'm going to look at, I take a node and I look at all nodes adjacent to it and all nodes adjacent to those nodes and so on. I grow out some ball and I ask, what is the scaling factor of that ball as a function of radius?"
},
{
"end_time": 3117.807,
"index": 136,
"start_time": 3091.664,
"text": " I can take logarithmic differences, that gives me the exponent. That exponent is like a Hausdorff dimension. Then I can ask, what's the correction? Is that giving me some leading order term in the expansion? What are the correction terms? Those correction terms give me projections of the Riemann tensor. And that's just using the analogy to kind of classical differential geometry. But the point is that to get the curvature terms, as we do in, say, the derivation of general relativity, you have to assume that the hypergraph is kind of uniform dimensional."
},
{
"end_time": 3127.073,
"index": 137,
"start_time": 3118.063,
"text": " Right. Even to be able to take that Taylor expansion, you have to assume that the dimension is uniform. So then an obvious question is what happens if you relax that assumption?"
},
{
"end_time": 3152.056,
"index": 138,
"start_time": 3127.432,
"text": " And the answer is, well, you get a theory that is equivalent to general relativity in the kind of observational sense. But now you can have fixed curvature, fixed contortion, fixed non-metricity, but you also have, you just have variable dimension. And so, you know, the point is that in the, in the expansion for that volume element, the dimension gives you an exponential, it gives you the kind of leading order of exponential term."
},
{
"end_time": 3178.66,
"index": 139,
"start_time": 3152.056,
"text": " The reach scale up coverage gives you a quadratic correction to that and then you have low your higher order corrections. So because of the answer because of this very basic mathematical fact that if you if you're if you're really far if you're zoomed in really far. It's very hard to distinguish an exponential curve from a quadratic curve right you can have to zoom out and see it very globally before you can really tell the difference between the two. And so what that translates to is if you if you're looking only at the microstructure of space time."
},
{
"end_time": 3203.336,
"index": 140,
"start_time": 3179.036,
"text": " There's no way for you to systematically distinguish between a small change in dimension and a very large change in curvature. So if you had a region of space time that was kind of rather than being four dimensional was, you know, 4.001 dimensional, but we were to kind of measure it as though it were four dimensional, it would manifest to us as a curvature change. Yes, it would be indistinguishably observational change. So"
},
{
"end_time": 3231.869,
"index": 141,
"start_time": 3204.155,
"text": " So let's go back to category theory for just a moment. When I was speaking to Wolfram about that, Stephen Wolfram, he said that he's not a fan of category theory because he believes it circumvents computational irreducibility."
},
{
"end_time": 3256.63,
"index": 142,
"start_time": 3232.193,
"text": " I said, why? He said, well, because you go from A to B. Yes. Then you can go from B to C, but then you also have an arrow that goes directly from A to C. But when I was thinking about it, that's only the case if you think that each mapping takes a time step. But when I look at category theory, I don't see it as any time step. At least I don't. I see it as just this timeless creation. So please tell me your thoughts. Hear that sound."
},
{
"end_time": 3283.609,
"index": 143,
"start_time": 3257.5,
"text": " That's the sweet sound of success with Shopify. Shopify is the all-encompassing commerce platform that's with you from the first flicker of an idea to the moment you realize you're running a global enterprise. Whether it's handcrafted jewelry or high-tech gadgets, Shopify supports you at every point of sale, both online and in person. They streamline the process with the Internet's best converting checkout, making it 36% more effective than other leading platforms."
},
{
"end_time": 3309.718,
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"start_time": 3283.609,
"text": " There's also something called Shopify Magic, your AI-powered assistant that's like an all-star team member working tirelessly behind the scenes. What I find fascinating about Shopify is how it scales with your ambition. No matter how big you want to grow, Shopify gives you everything you need to take control and take your business to the next level. Join the ranks of businesses in 175 countries that have made Shopify the backbone"
},
{
"end_time": 3335.486,
"index": 145,
"start_time": 3309.718,
"text": " of their commerce. Shopify, by the way, powers 10% of all e-commerce in the United States, including huge names like Allbirds, Rothy's, and Brooklyn. If you ever need help, their award-winning support is like having a mentor that's just a click away. Now, are you ready to start your own success story? Sign up for a $1 per month trial period at shopify.com slash theories, all lowercase."
},
{
"end_time": 3360.964,
"index": 146,
"start_time": 3335.486,
"text": " Go to shopify.com slash theories now to grow your business, no matter what stage you're in shopify.com slash theories. Right. Okay. Well, so, uh, I'm, I'm in the fortunate position of having written quite a long paper on exactly this problem. Okay. Um, so, uh, there's a paper that I wrote back in 2022 called a functorial perspective on multi-computational irreducibility."
},
{
"end_time": 3381.493,
"index": 147,
"start_time": 3361.305,
"text": " I'm which is all about the exactly this idea that that's yes or as you say category theory. As it's ordinarily conceived is a is just a kind of algebraic theory that has no notion of there's no there's nothing computational about it right there's no notion of time step there's no there's no statement made about you know what's the competition complexity of any given of any given more for some."
},
{
"end_time": 3407.79,
"index": 148,
"start_time": 3382.227,
"text": " Um, but then an obvious question is, well, okay, is there a version of category theory which does care about those things, the kind of resource limited version or some version where individual morphisms are kind of tagged with computational complexity information? And it turns out the answer is yes. And it has some very nice connections to, uh, not just categorical quantum mechanics, but also things like functorial quantum field theory. Um, but also it gives you a new, it's, I think Steven is"
},
{
"end_time": 3423.899,
"index": 149,
"start_time": 3408.302,
"text": " Wrong in that statement that it doesn't care about competition or disability because actually it gives you a very clean way of thinking about competition or disability. So what i mean by that is so i'm gonna use your ability to reduce ability this idea that you know there's some computations that you can't short cut in some fundamental sense."
},
{
"end_time": 3448.814,
"index": 150,
"start_time": 3424.104,
"text": " as far as i know i was the first person to actually give a formal definition of that in a paper back in 2018 or something sorry a formal definition of computational irreducibility of computational irreducibility nothing nothing very profound but just you know essentially you know you say i i've got some turing machine that maps me from this state to that state does there exist a turing machine of the same signature that gets me to the same output state with with fewer applications of the transition function"
},
{
"end_time": 3462.312,
"index": 151,
"start_time": 3448.814,
"text": " Sorry, I don't mean to cut you off. So please just remember where you are. Okay."
},
{
"end_time": 3483.677,
"index": 152,
"start_time": 3462.449,
"text": " Because it's my understanding that wolfram said the rule thirty something like that maybe you would recall it more vividly because it's in his book rule thirty is computationally irreducible i've always wondered how do you prove that now i imagine that he proved it or maybe it's one of those wolfram proof so proof to himself but in order for him to prove it even to himself he would have had to have a definition of it."
},
{
"end_time": 3512.005,
"index": 153,
"start_time": 3485.93,
"text": " Right. Okay. So there's an important point that, so rule 30 is not proved to be computationally irreducible. And in fact, there's a prize. So if you go to, I think it's rule30prize.org. I'm ostensibly on the prize committee. This is a prize that Wolfram put out back in 2018. There's actually three prizes, none of which have been claimed. Each one is $10,000. And one of which is prove that rule 30 is computationally irreducible."
},
{
"end_time": 3528.951,
"index": 154,
"start_time": 3512.568,
"text": " I'm and so yeah it's on proven and in fact there's really only one up to. Some of the equivalence is really only one of the elementary cellular automata in nks that's been proven to be computationally reducible in any realistic sense and that's rule one ten."
},
{
"end_time": 3551.152,
"index": 155,
"start_time": 3529.701,
"text": " and that was proved by showing that it's capable of doing universal computation that it's that it's capable of that it's it's a Turing complete rule and so intuitively you can kind of say well if it's Turing complete then you know questions about termination are going to be undecidable and therefore it has to be irreducible but it's a kind of slightly hand wavy thing okay but yeah so so yeah in a way"
},
{
"end_time": 3567.585,
"index": 156,
"start_time": 3551.8,
"text": " It's an interesting question. Can you prove that something is computationally irreducible without proving that it's universal? And of course, as you say, for that, you would need a formal definition of irreducibility. Okay, and now going back to your paper on functoriality and computational irreducibility."
},
{
"end_time": 3583.473,
"index": 157,
"start_time": 3568.08,
"text": " you were able to formalize this yes so sorry yes so so um what i was saying was yes so there was this existing formal definition of computational reusability but i then realized that if you think about it from a category theoretic standpoint there's actually a much nicer definition a much less kind of ad hoc definition"
},
{
"end_time": 3611.391,
"index": 158,
"start_time": 3583.831,
"text": " Which is as follows. So imagine a version of category theory where your morphisms, as I say, are tagged with computational complexity information. So each morphism has a little integer associated to it. So, you know, you fix some model of computation, you fix Turing machines, and you say, each morphism, I'm going to tag with an integer that tells me how many operations was needed to compute this object from that object. In other words, how many applications of the of the partial transition of the transition function of the Turing machine do I need to apply? So"
},
{
"end_time": 3636.34,
"index": 159,
"start_time": 3611.817,
"text": " Now if I compose two of those morphisms together, I get some composite, and that composite is also going to have some computational complexity information. And that computational complexity information is going to satisfy some version of the triangle inequality. So if it takes some number of steps to go from x to y and some number of steps to go from y to z, I can't go from x to z in fewer computational steps that it would have taken to go from x to y or from y to z."
},
{
"end_time": 3663.882,
"index": 160,
"start_time": 3636.971,
"text": " Um, so it's going to, it's going to at least satisfy the axioms of something like a measure, something like a metric space. There's some kind of triangle inequality there. Um, but then you could, you could consider the case where the complexities are just additive, right? Where, you know, to get from X to Z, you have to, it takes the same number of steps as it takes to go from X to Y plus the number of steps it takes to go from Y to Z. And that's precisely the case where the computation is irreducible, right? Cause it's saying you can't shortcut the process of going from X to Z."
},
{
"end_time": 3681.698,
"index": 161,
"start_time": 3664.343,
"text": " Which then means you could define the reducibility, the case of computational reducibility as being the case where this algebra is sub at where the algebra of complexities is sub additive under the operation of morphism composition. And there's a way that you can formulate this as so you take your initial category."
},
{
"end_time": 3703.387,
"index": 162,
"start_time": 3681.698,
"text": " You take a category whose objects are essentially integers and discrete intervals between integers, and then you have a functor that maps each object in one category to an object in another, each morphism in one to a morphism of the other. And then the composition operation in the second category is just discrete unions of these intervals."
},
{
"end_time": 3722.363,
"index": 163,
"start_time": 3703.387,
"text": " And then you can ask whether the essentially whether the cardinality of those intervals is discreetly additive or discreetly sub additive under morphism composition and that gives you a way of formalizing computational disability and the really lovely thing about that is that not only can you then measure irreducibility and reducibility in terms of defamation of this functor."
},
{
"end_time": 3746.357,
"index": 164,
"start_time": 3722.363,
"text": " But it also generalizes to the case of multi-way systems, you can formalize notions of multi-computational ability, but by essentially just equipping these categories with a with a monoidal structure with a tensor product structure. So my understanding of computational irreducibility is either that a system has it or it doesn't, but it sounds like you're able to formulate an index so that this system is more irreducible than another, like you can actually give a degree to it."
},
{
"end_time": 3774.735,
"index": 165,
"start_time": 3747.108,
"text": " Exactly, exactly. So yeah, so there's a kind of there's a limit case where it's it's exactly additive. And anything that's less than that, you know, where the complexities are exactly additive, that's kind of maximally irreducible. But anything less than that is sort of partially reducible, but not necessarily fully reducible. Now, are there any interesting cases of something that is completely reducible, like has zero on the index of computational irreducibility? Is there anything interesting? Even trivial is interesting, actually. Um,"
},
{
"end_time": 3802.346,
"index": 166,
"start_time": 3776.408,
"text": " Yes, I mean. Well, OK, so any any computation that doesn't change your data structure, that's just, you know, just a repetition of the of the OK, so forget about the identity operation is going to have that property. I don't. I'm not sure I can necessarily prove this. I don't think there are any examples other than that. I think any example other than that must have at least some minimal amount of irreducibility."
},
{
"end_time": 3830.009,
"index": 167,
"start_time": 3803.899,
"text": " But yes, I mean, this this also gets into into a bigger question that I actually relates to some things I'm working on at the moment, which is exactly how you equivalence objects in this in this kind of perspective, right? Because even to say it's a trivial case, right, where I'm just applying this, I'm applying some identity operation, I'm getting the same object, you have to have some way of saying that it is the same object. And that's actually I mean, that sounds like a"
},
{
"end_time": 3840.094,
"index": 168,
"start_time": 3830.469,
"text": " Simple thing but in it's actually quite a philosophically thorny issue right because you know in a very simple case you could say well okay so first thing to say is"
},
{
"end_time": 3861.596,
"index": 169,
"start_time": 3841.305,
"text": " Everything we're talking about at the moment, this is all internal to this category, which in the paper I call comp, this category whose objects are in a sense elementary data structures and whose morphisms are, the morphisms that generate, that freely generate this category are elementary computations. And so the collection of all morphisms that you get from compositions are essentially the class of all possible programs."
},
{
"end_time": 3889.804,
"index": 170,
"start_time": 3862.056,
"text": " So within this category, when two objects are equivalent, and therefore when two programs are equivalent, is a fairly non-trivial thing, right? So you can imagine having a data structure where nothing substantively changes, but you've just got like a time step or something that goes up every time you apply an operation. So it just increments from one, two, three, four. So in that case, you're never going to have equivalences every time you apply an operation. Even if the operation morally does nothing, it's going to be a different object. So even that would show up as being somehow irreducible."
},
{
"end_time": 3916.254,
"index": 171,
"start_time": 3890.128,
"text": " But there are also less trivial cases of that, like with hypergraphs, right? So with hypergraphs, you have to determine equivalence, you have to have some notion of hypergraph isomorphism, and that's a complicated thing to even to define, let alone to formalize algorithmically. And so you quickly realize that these notions, you can't really separate these notions of reducibility and irreducibility from these notions of equivalencing."
},
{
"end_time": 3943.439,
"index": 172,
"start_time": 3916.681,
"text": " And somehow it's all deeply related to what data structures do you kind of define as being equivalent or equivalent up to natural isomorphism or whatever. And that's really quite a difficult problem that relates to definitions of things like observers in these physical systems, right? If you have someone who is embedded in one of these data structures, what do they see as equivalent? Which might be very different to what a kind of God's eye perspective views as being equivalent from the outside."
},
{
"end_time": 3958.592,
"index": 173,
"start_time": 3944.002,
"text": " So are there close time like curves in wolframs physics project sorry HD project. That's what it that's how it's known right now so yeah that's a really good question right because you know."
},
{
"end_time": 3980.333,
"index": 174,
"start_time": 3959.445,
"text": " In a way it's very easy to say no because we can just we can do that trick that i just you know you just tag everything with a with a time step number and then of course you know you even if the hyper graph is the same the time step is different so you there's no equivalence and you don't in the multi-way system or the causal graph you never see a cycle. But that's somehow cheating right you know and what we can't win when people ask about ctc's."
},
{
"end_time": 4006.681,
"index": 175,
"start_time": 3980.828,
"text": " What they care about is not this very nerdy criterion of, oh, do you actually get exactly equivalent data structures? What they care about is nerdy. Criterions seems to define this entire conversation up until this point. Well, yes, I suppose, you know, you take two people with math backgrounds and get them to discuss stuff. Yeah, exactly. That's going to happen. Right. But yeah, so yeah, what they care about people who care about time travel. Right."
},
{
"end_time": 4036.391,
"index": 176,
"start_time": 4007.261,
"text": " What one cares about is yeah exactly is time travel and and and causality violations and things which which don't necessarily care about your equivalency or care about them and care about it in a slightly different way. Yeah I mean so. My short answer is I don't know because I think I think we can't. My personal feeling is we are not yet at this level of maturity where we can even pose that question precisely for the following reason right so even."
},
{
"end_time": 4055.179,
"index": 177,
"start_time": 4036.766,
"text": " Defining a notion of causality is complicated. So in most of what we've done in that project in derivation, derivations of things like the Einstein equations and so on, we've used what on the surface appears like a very natural definition of causality for hypergraph rewriting. So you have two"
},
{
"end_time": 4082.602,
"index": 178,
"start_time": 4055.179,
"text": " Rewrites you know each one is gonna ingest some number of hyper edges it's gonna output some other number of hyper edges those hyper edges have some identifier. And then you can ask okay did this future event ingest edges that were produced in the output of this past event. And so if it did then the future event couldn't have happened unless the past event had previously happened and so we say that it calls the related so the the somehow the if the output set of one has a non-trivial intersection with the input set of another. We say that they're closely related that's a."
},
{
"end_time": 4112.261,
"index": 179,
"start_time": 4083.2,
"text": " Seems like a perfectly sensible definition, except it requires, it has exactly the problem we've been discussing, right? It requires having an identifier for each of the hyper edges. You need to be able to say this hyper edge that this event ingested is the same as this hyper edge that the other event output. But if they're just hyper edges, they're just structural data, there's no canonical choice of universal identifier of UUID. And so what that means is you can have these degenerate trivial cases where, for instance, you have an event that"
},
{
"end_time": 4135.435,
"index": 180,
"start_time": 4112.756,
"text": " Adjust the hyper edge changes its uid but doesn't he change anything structurally the graph is still the same nothing is actually changed interestingly but the identifier is different but now any event in the future that uses that edge. Is going to is going to register as being closely related to this other event that didn't do anything right i have a bunch of these spurious causal relations so it's clear that definition of causality isn't quite right."
},
{
"end_time": 4160.708,
"index": 181,
"start_time": 4136.118,
"text": " What's really needed is some definition of causality that isn't subject to this problem, but it's very unclear what that is. I've worked a little bit on trying to formalize that by recursively identifying hyperedges based on their complete causal history. The identifiers are not chosen arbitrarily as random integers or something, but instead each hyperedged encodes in a slightly blockchaining way"
},
{
"end_time": 4179.138,
"index": 182,
"start_time": 4161.015,
"text": " A directed a cyclic graph representation of its complete causal history and so then to high bridges are treated as the same if and only if they have the same history of causal relationships in the writing system. And that's somewhat better but again is quite complicated reason about and say it's kind of it's all deeply related to this question of what."
},
{
"end_time": 4208.575,
"index": 183,
"start_time": 4179.445,
"text": " Data structures do you ultimately treat as being equivalent, which is really an observer dependent thing. It depends on the computational sophistication of the person or entity who is trying to decode what the system is doing. It's not the kind of inherent problem property of the system itself. So what do you make of observer theory, which is a recent large blog post by Stephen and a theory, an outlook. So what do you make of it? Yeah, so observer theory really has"
},
{
"end_time": 4235.145,
"index": 184,
"start_time": 4209.155,
"text": " It's a rebranding of this thing that's been a feature of the physics project since before we started it, right? So this idea that, yes, exactly, that you cannot sort of consider a computational system independent of the observer that is interpreting its results. And somehow both the computational sophistication of the observer and the computational sophistication of the system have to be factored into that description somehow."
},
{
"end_time": 4262.688,
"index": 185,
"start_time": 4235.708,
"text": " So in a way it's a very natural idea which is which is really the prelude to this work we did on kind of quantum foundations and other things in the context of physics project. I like to think of it as a kind of natural extension of a bunch of stuff that happened in 20th century physics right because of course this is not how those things it's not how these things were viewed at the time but both general relativity and quantum mechanics can in some sense be thought of as being"
},
{
"end_time": 4292.381,
"index": 186,
"start_time": 4263.302,
"text": " A lot of traditional scientific models made this assumption that the observer was infinitely far removed from the system they were observing, that they were these kind of omnipotent entities, they didn't have any influence over the systems, they weren't constrained by the same laws. But if you then say, okay, well, maybe the observer has some limitations, maybe they can't travel faster than light, what does that imply?"
},
{
"end_time": 4307.585,
"index": 187,
"start_time": 4292.381,
"text": " Well in some if you follow the right chain of logicals action what that implies is general covariance and therefore general relativity that you know as soon as you have a service you can travel faster than light and they don't necessarily agree on the ordering of space like separate events and suddenly you get general relativity."
},
{
"end_time": 4328.404,
"index": 188,
"start_time": 4308.046,
"text": " Equivalently, if you have observers who are constrained by the same physical laws of the systems that they're observing, then what that means is, if you try and measure some property of a system, what happens when you measure it? Well, you have to have some interaction with it, you have to kind of poke it somehow, and the poke that you receive back is going to be equal in magnitude to the poke that you gave to the system."
},
{
"end_time": 4357.773,
"index": 189,
"start_time": 4328.404,
"text": " And so anytime you try and measure some quantity, there's a minimum amount that you have to disturb it. And again, if you kind of follow that chain of reasoning to its logical conclusion, you get at least the kind of Heisenberg picture of quantum mechanics. So in a way, both general relativity and quantum mechanics are, as I say, ways of becoming more realistic about what observers are capable of and ways of coming to terms with the fact that observers are constrained by the same physical laws as the systems that they observe. So observer theory"
},
{
"end_time": 4385.845,
"index": 190,
"start_time": 4358.251,
"text": " which i mean i don't i don't think it's yet a theory so i'm not sure it's yes no i'm not i'm sure i i i'm hugely fond of the terminology but uh i mean it's it's a it's a yeah it's a conceptual idea um is really just the kind of computational instantiation of that and you know so my field okay you mentioned before this very interesting thing about geometry that that somehow you know you you have this freedom of"
},
{
"end_time": 4405.23,
"index": 191,
"start_time": 4386.476,
"text": " Do you choose to very curvature do you choose to very torsion do you choose to very non-metricity. My feeling is that there's a similar free parameter that exists in our scientific models with regards to the role of the observer. And this is again maybe a point of philosophical departure from between me and Stephen is so."
},
{
"end_time": 4435.572,
"index": 192,
"start_time": 4405.64,
"text": " You have these kind of, you can imagine these two extreme cases, right? You can imagine the case where all you care about is the computation that the system is doing. So you're just building up some, some structure from, from, you know, from, from bottom up rules. Um, and so the observer, so to speak, is just some trivial object that's seeing the data structure and all of the kind of computational burden is being shouldered by the system itself. Um, and, uh, you know, that's kind of, that's the way that the physics project is often presented, right? You just have a hypergraph and it's doing its thing and we kind of, we, we, we perform analysis on it."
},
{
"end_time": 4463.114,
"index": 193,
"start_time": 4435.981,
"text": " And that's one extreme. There's another extreme where you could say, well, maybe the system itself is trivial. You know, the computation is doing is essentially trivial. And all of the sophistication is all the kind of computational burden is shouldered by the observer. So the case of that would be what Stephen refers to as the rule yard, which is really just this, what I was describing earlier, this kind of category of, you know, all possible elementary data structures and all possible computations. And so in that picture,"
},
{
"end_time": 4477.244,
"index": 194,
"start_time": 4463.78,
"text": " That's an object that minimizes algorithmic complexity. It minimizes Kolmogorov complexity. The set of all possible computations has the same algorithmic complexity as the set of no computations."
},
{
"end_time": 4503.183,
"index": 195,
"start_time": 4477.466,
"text": " I'm just purely for information reasons and so in that case the actual computation that generates it is trivial. It's trivial to specify but in order to get a particular computational path or in order to restrict down to a particular multi-way system you have to have an observer some generalized observer who is making equivalences between different parts and the sophistication of that observer can be arbitrarily high and so"
},
{
"end_time": 4524.053,
"index": 196,
"start_time": 4503.677,
"text": " You have these two extreme cases one one case where the observer is trivial all the computation is being done by the system another case where the system is trivial all the computations being done by the observer. And my argument is these two cases i mean there's no observational way of distinguishing between them and in fact there's the whole interstitial space in the middle where you have some of the burden being sold by the system some of the burden by the observer."
},
{
"end_time": 4554.48,
"index": 197,
"start_time": 4524.65,
"text": " And these are not really things that we can observationally distinguish. And so in a sense, it's a genuinely free parameter in how we construct our models. And I would even go so far as to say that I think in some sense, this argument that occurred in early European philosophy between the kind of empiricists and the rationalists, right, between people like, you know, Locke and Hume on the kind of empiricist side and people like, you know, Descartes and Bishop Barclay and so on, and on the rationalist side."
},
{
"end_time": 4572.193,
"index": 198,
"start_time": 4554.889,
"text": " That's really the kind of this is really the modern version of that same argument right the empiricist saying we need to get the observer out of the picture as much as possible and just describe the systems the rational is saying no no you know what matters is the internal representation of the world and you know the external reality is somehow some secondary emergent phenomenon."
},
{
"end_time": 4600.401,
"index": 199,
"start_time": 4572.193,
"text": " I'm confused so the difference between observation and perception. Because even would say that look because you're an observer of the kind that you are you. Then derive general relativity or have that as a property or quantum mechanics. But then firstly we all don't perceive the same."
},
{
"end_time": 4629.838,
"index": 200,
"start_time": 4600.742,
"text": " And then we also don't perceive quantum mechanics nor general relativity. In fact, in many ways we perceive the earth as being flat and we don't perceive any of the other colors outside of the spectrum of visible light. So it's a painstaking process to then say, well, what are the laws of physics? We have to somehow derive that test that. And then the question is, well, does a cat perceive the same laws? Well, a cat doesn't perceive perceive. This is what I mean. We don't perceive the same. The cat doesn't perceive the same, but presumably"
},
{
"end_time": 4658.319,
"index": 201,
"start_time": 4630.503,
"text": " It's on the same field. We're playing on the same field. The cat is playing on the same field of general relativity and quantum mechanics as we are. So sure, our perceptions are different, but then would Wolfram say that our observations are the same, like delineate for me, an observation and a perception. Yeah, that's, that's a really important distinction, right? Because, um, and it goes back to some, some really kind of foundational ideas and in early philosophy of science and, you know, people like"
},
{
"end_time": 4679.65,
"index": 202,
"start_time": 4658.729,
"text": " Thomas koon and others who kind of use stress the idea and car popper who stress the idea of theory ladenness of observation right that so. The basic i think in the in the way that you're using those terms i think it's an important distinction right the perceptions are kind of much closer to the just the qualia that we perceive for the quality of the experience and the observations are some kind of interpretation that we give to them."
},
{
"end_time": 4702.09,
"index": 203,
"start_time": 4680.538,
"text": " And so the important point, I think the point that people like Coon and Papa were making with the relatedness is that, you know, we, in a sense, we perceive nothing as it quote really is right? Like any time we, any time we make a scientific observation, we're not perceiving the phenomenon where it's filtered through many, many layers of observation and, and, and, and, and, um,"
},
{
"end_time": 4729.701,
"index": 204,
"start_time": 4702.415,
"text": " interpretation and analysis right so you know when we say that we have we have observed we have detected this particle in this particle accelerator what does that actually mean right well it means that i don't know that there was some there was some cluster of photons in this detector that were produced by some Cherenkov radiation which would then you know spot which would then stimulated some photovoltaic cells on the scintillator and you know there are maybe a hundred layers of of models and theories and and and you know"
},
{
"end_time": 4758.114,
"index": 205,
"start_time": 4729.701,
"text": " You know additional bits of interpretation. In between whatever was going on in that particle accelerator and the bits of photosensitive cells that was stimulated in the scientists eyes as they looked at the screen and and and so this thing and so if you actually try and trace out. How many levels of abstraction are there between the quote unquote perceptions and the quote unquote scientific observations it's huge right and it only takes one of those to be wrong or you know not or tweaks a little bit."
},
{
"end_time": 4778.37,
"index": 206,
"start_time": 4758.507,
"text": " And suddenly the model you have of the world which is still just as consistent with your own perceptions is completely different right so yeah i think it's important that's an important thing to bear in mind it's. It's a thing in a sense which annoys me a little bit. With regards to some criticisms of."
},
{
"end_time": 4808.234,
"index": 207,
"start_time": 4778.797,
"text": " You know experimental validation because i think people tend to get that's an area where people kind of get confused in terms of that distinction the people say you know it annoys you just a bit only a bit uh well i may maybe i don't have to deal with it as much as you do well no i don't do what i just mean i'm curious if it annoys you more than that or if you're just being polite well i mean it maybe would annoy me if i had if if if i was being confronted with it all the time but you know when when you see occasional"
},
{
"end_time": 4834.65,
"index": 208,
"start_time": 4809.411,
"text": " When you see people saying that the multiverse is fundamentally unobservable, that seems to me to make this exactly the mistake that you're characterizing. It's not perceivable, sure, but then most things that we care about in science aren't perceivable. I think David Deutsch has this nice example that no one has ever seen a dinosaur, no one ever will see a dinosaur, will never get a dinosaur in a lab."
},
{
"end_time": 4856.408,
"index": 209,
"start_time": 4834.65,
"text": " If you restrict science to only be about things that we can directly sort of perceive or test in the bar or something then you can make statements about dinosaurs you can make statements about the composition distribution of fossils but you know that's not very interesting release it's you know if you only care about the properties of certain rocks you would be a geologist not a paleontologist. I'm the point is that when we look at the composition and distribution of fossils."
},
{
"end_time": 4884.531,
"index": 210,
"start_time": 4857.056,
"text": " That perceptual data is consistent with a model of the world that logically implies the existence of dinosaurs. And that's really what we mean when we say we have evidence of dinosaurs. So, you know, not that I'm to be clear, not that I'm particularly defending the multiverse view or anything like that. But, you know, there's there's a really important distinction between, yes, the multiverse is not perceivable, which is true. And it's not possible on the basis of perceptions that we can have"
},
{
"end_time": 4913.712,
"index": 211,
"start_time": 4885.077,
"text": " To validate a model of the world that is logically consistent with the existence of a multiverse, which is a very different, it's a very different statement and a much more reasonable statement. And yet, you know, in the, in the popular discourse about these things, those are things that often get confused. So, so yeah, it, it annoys me when I see it and, uh, uh, you know, maybe would annoy me more if I saw it more often. Speaking of points of annoyance, what are your thoughts on the state of publishing? So what's your stance on peer review and where"
},
{
"end_time": 4920.418,
"index": 212,
"start_time": 4914.309,
"text": " Academic publishing is headed even its current state. Yeah, so, um,"
},
{
"end_time": 4944.599,
"index": 213,
"start_time": 4921.647,
"text": " I had the slightly depressing experience recently, I'm not sure whether you've done this, of going to Google Scholar and searching in inverted commas as an AI language model or some other similar thing, and just seeing the sheer volume of papers that have passed so-called peer review in so-called prestigious journals that are just obviously not human written, with no indication of that fact."
},
{
"end_time": 4974.377,
"index": 214,
"start_time": 4944.599,
"text": " And there are obviously plenty of examples, you know, the, the, the, the, the, um, uh, if you go to the Sokol affair and, and, and, you know, other things where, where, you know, this process that on the surface sounds like a very reasonable idea. This, you know, the, the idea that, you know, you, you claim some new result, you get people who know the field to kind of say, yes, that's a reasonable result or no, this is not quite right. Um, that's a perfectly reasonable model. It's just not what peer review actually is in practice. Um, and yeah, it's, it's important to remember as well that."
},
{
"end_time": 4990.811,
"index": 215,
"start_time": 4975.981,
"text": " In a sense the the the modern system of scientific publishing and the modern system of academia was not really designed right like no one sat down and said this is how we should do science just kinda happened right this model of scientific journals and peer review and editors and so on that's."
},
{
"end_time": 5013.882,
"index": 216,
"start_time": 4991.288,
"text": " You can trace that back to a direct extension of the you know these early proto journals like the transactions of the of the of the world society. Which if you go back and look at them were very different to modern scientific jobs right it's always kind of entertaining when you go and read. You know submissions to the transactions of the world society that were made by robert hoek and robert boil and isaac newton and so on because they basically read like blog posts."
},
{
"end_time": 5030.657,
"index": 217,
"start_time": 5013.882,
"text": " They're actually very very informal that you know that they know you have these guys they just going they say you know i did this i did that i you know i mix this chemical with this i saw this thing and then you know my cat knocks my you know not my experiment over and whatever and it's very conversations very discusses."
},
{
"end_time": 5049.309,
"index": 218,
"start_time": 5031.34,
"text": " And yes it was reviewed but you know the review process was much less formalized than it is and you know i'm not saying that something like that could work today i mean science is much more sort of industrialized and so on you could you could you need some kind of more systematic way of processing the volume of scientific literature that's being produced but still."
},
{
"end_time": 5070.64,
"index": 219,
"start_time": 5050.213,
"text": " It's pretty evident that there was never any person who said this is a good model for scientific research and dissemination. This is how it should be done. It just kind of it naturally evolved from a system that really wasn't set up to accommodate what it's become. Another important thing to remember is that the notion of scientific publishing and the notion of peer review"
},
{
"end_time": 5101.63,
"index": 220,
"start_time": 5072.398,
"text": " Served a particular served a pair of purposes, which in the modern world have essentially become distinct. So it used to be that the journal publishers served two roles. They were there for quality control because of peer review, and they were there for dissemination because they actually printed physical scripts that got sent to libraries and things in the modern era with things like archive and sci-archive and bio archive and generally, you know, preprint servers and, you know, people able to host papers on their website dissemination. That's which was always the expensive part of journal publishing."
},
{
"end_time": 5130.247,
"index": 221,
"start_time": 5102.005,
"text": " We don't need that anymore, right? We've got that covered. So peer reviews for quality control. So, yeah, exactly. So the real role for journals now is quality control, in my opinion. And the issue with that is that's incredibly cheap because, you know, I review papers as does every other academic and we do it for free. We do it because it's kind of public service and whatever. And it's an important thing to do. So we don't get paid. The people writing the papers don't get paid."
},
{
"end_time": 5151.749,
"index": 222,
"start_time": 5130.896,
"text": " The journals shouldn't need to spend lots of money to print physical copies so really general publication should be not quite free but basically incredibly cheap and it's not right and the reason is because you have these journals who are essentially kind of holding on to this very outmoded model where they're pushing the dissemination part at I would argue at the expense of the quality control part."
},
{
"end_time": 5165.418,
"index": 223,
"start_time": 5151.749,
"text": " And so that's why i've been a great advocate there are these new kinds of journals that are coming out there's one called discrete analysis and a few others that are the so called archive overlay journals which i think are fantastic idea."
},
{
"end_time": 5192.568,
"index": 224,
"start_time": 5166.032,
"text": " Where the idea is we say the content itself is going to be hosted on the archive preprint service. So we don't need to care about dissemination. So that's all incredibly cheap. We just literally post a link to an archive paper. And so all we're going to do is worry about the quality control. And then once you start to think about that, and once you're not bound to having physical copies that have to go to printers and things, you can actually do peer review in a very different and I would argue much more productive way. You can have things like open public, you can have open post publication peer review."
},
{
"end_time": 5220.418,
"index": 225,
"start_time": 5193.183,
"text": " Where rather than pre-publication, the manuscript gets sent to some anonymous reviewers and then they spend six months deliberating and they get the result back and no one ever, no one ever sees it. You can have something where someone posts a pre-print on archive. It goes on an open review site and then anyone in that area or anyone outside the area can come in and say, I don't understand this or this doesn't make sense or this is a great paper or whatever. And then you can kind of up vote down vote. You can say, Oh yeah, I agree with your criticism and et cetera. And the whole thing can be open and de-anonymized."
},
{
"end_time": 5241.049,
"index": 226,
"start_time": 5220.725,
"text": " And it would have to be anonymized by the person who's publishing who's posting it up there because otherwise if people see that Ed Witten posted something more eyes will go toward that but you can also if you're in the field you can discern sometimes who's publishing what. Yeah absolutely and and and and certainly in math and physics in these places where and computer science in places where you know."
},
{
"end_time": 5270.128,
"index": 227,
"start_time": 5241.425,
"text": " In those fields, it's been standard for many decades now, for several decades, that everyone posts their work on archive, right? And they post their work on typically before or possibly simultaneously with submitting their work to a journal. So if you get even if you even have the job, I mean, because of that physics journals, you know, journals like Jay hair or classical quantum gravity, et cetera, they don't even try and anonymize their manuscripts because they know if they anonymized it, you could just Google the first sentence and go find the archive paper and see you posted it. So, yes, I think"
},
{
"end_time": 5299.838,
"index": 228,
"start_time": 5270.35,
"text": " So about the journals inflated prices, outside of an oligarchy or collusion, what's keeping it high?"
},
{
"end_time": 5317.278,
"index": 229,
"start_time": 5300.06,
"text": " I'm reticent to claim that it's a collusion. A lot of it is tied into the promotion structure in academia. A lot of it is tied into"
},
{
"end_time": 5341.749,
"index": 230,
"start_time": 5318.08,
"text": " If you want to get a permanent job in academia if you want to advance up that that ladder you need to get you know there's this general view that you need to get published in the fancy journals and then that means that the journals that are generally perceived by university administrators as being the fancy ones know that they can charge essentially arbitrarily high prices and people will pay them because they kind of because you know their livelihoods depend on yes yes um it's a sort it's a really quite sorted"
},
{
"end_time": 5370.691,
"index": 231,
"start_time": 5342.329,
"text": " situation when you think about it. I saw a talk recently by someone who's going into the academic world saying that some of the applications for professorship or postdocship that the second question after what is your name is how many citations do you have and then people try to game this because you can publish something that is just worthy of publication and do that many times rather than produce something that you feel like it's of high quality but will get less citations than if you were to split that up and then you just flood the market."
},
{
"end_time": 5392.005,
"index": 232,
"start_time": 5371.613,
"text": " Yeah, absolutely. And, you know, there are these metrics, there is author level metrics like the H index and so on, which, you know, which measure, you know, so H index equals N means that you have N papers that have been cited at least N times. And that gets used actually quite frequently in hiring committees and tenure committees and things like that. And yeah, it's incredibly easy to game, right? It's this classic Goodhart's law example where, you know,"
},
{
"end_time": 5415.794,
"index": 233,
"start_time": 5392.432,
"text": " As soon as you know that you're being measured on that criterion, you can then say, oh, I'm going to just cite myself in all, you know, every future paper I'm going to write, I'm going to cite myself in all previous ones. And then I can very easily get some kind of N squared dependence on my H index. And then I can get my friends to cite me too. And I can, as you say, rather than, you know, rather than investing a year to write this one really good polished definitive paper on this subject,"
},
{
"end_time": 5422.927,
"index": 234,
"start_time": 5415.794,
"text": " I'm going to write 10 like salami sliced mini in a minimum publishable unit thing. Yeah, right. That's a great way of saying it."
},
{
"end_time": 5451.101,
"index": 235,
"start_time": 5423.592,
"text": " Right. And yeah, and all of that happens, right? And it requires, I know, I'm guilty of some of that, too, you know, not because I want to be but because, you know, I need to, you know, I live in the academic system, that's kind of how one has to operate to a certain extent, if you're competing with other people who are doing that, it's awful, right? And I don't, I don't want to be in that situation. And, you know, I, yeah, if obviously, if given the choice, I always try to be someone who, yeah, if I'm going to invest the time to write a paper on something, I want to write"
},
{
"end_time": 5481.203,
"index": 236,
"start_time": 5451.544,
"text": " In as much as possible, the definitive paper on that thing and have it clean and polished and something that I'm proud of. But yeah, it's I think it's my impression at least is that it's becoming increasingly hard for that to be a viable career strategy. Yeah. What's fortunate in your case is that you were employed by Wolfram for some time. And so you were able to work on the ideas that were interesting to you and not have to concern yourself. Maybe I'm incorrect, but at least from my perspective, you didn't have to concern yourself with incremental publications on ideas that aren't innovative in order for you to build the"
},
{
"end_time": 5505.623,
"index": 237,
"start_time": 5481.971,
"text": " credit to your name, but maybe I'm incorrect. Well, I mean, there was certainly an element of that, right? So during the time I was employed at Wolfram, I also was, I mean, initially I was a graduate student, very early stages, I was an undergraduate, then I was a graduate student, and then I was a kind of junior academic. So I still had some academic position during that time. And for that reason,"
},
{
"end_time": 5531.852,
"index": 238,
"start_time": 5506.084,
"text": " It wasn't something I could completely ignore, right? Because, you know, that would have been kind of irresponsible from a career standpoint. But yes, in a way, it did take the pressure off because it meant that it meant that I had a kind of more or less guaranteed funding source for at least part of my research. And I wasn't having to repeatedly kind of beg, you know, government funding agencies for more money and things and show them long lists of papers. It was also useful in a different way, which is that it meant that the stuff I was doing got"
},
{
"end_time": 5561.015,
"index": 239,
"start_time": 5532.193,
"text": " Much more exposure than it would have done otherwise. I mean, you know, we wouldn't have met, you know, if it hadn't been for Stephen and the kind of the additional, both the additional cache and the additional, uh, flack that is associated with, uh, you know, with having his name attached to the project. And so, yeah, I know in a way it meant that there was four, you know, for my level in the, in the academic hierarchy, my work ended up being significantly overexposed and yeah, that was good in a way. It was bad in another way. Why would it be bad?"
},
{
"end_time": 5572.551,
"index": 240,
"start_time": 5562.398,
"text": " Well, it meant that, okay, so one negative aspect of it, which has not been hugely problematic but is, you know,"
},
{
"end_time": 5593.114,
"index": 241,
"start_time": 5572.875,
"text": " Stephen has a certain reputation, right? And that reputation is positive in many ways and negative in many other ways. And by, you know, if you are billed as, you know, you are the person what you are the other person or one of the other people working on the Wolfram physics project, you get, there's a, there's a sense in which you're elevated by association and you get tainted by association and people assume that, you know,"
},
{
"end_time": 5620.401,
"index": 242,
"start_time": 5593.968,
"text": " Yeah, people assume that many of the negative characteristics associated with, you know, I don't know, not giving appropriate credits to prior sources or having slightly inflated ego issues, et cetera, right? Many of those things kind of get projected on you, rightly or wrongly, but yeah, by virtue of association. Yeah. Or that you're supporting that. So maybe you don't have those qualities. Okay. Right, right. And it's a difficult thing to, I mean, in a way,"
},
{
"end_time": 5646.51,
"index": 243,
"start_time": 5621.032,
"text": " It helps because it meant that a lot of the criticism of the project got leveled at Stephen, not the rest of us, right? Yes. So in a way it was useful. But yeah, but in other senses, you know, it was a yeah, it's a delicate balance. So how do you see academics engagement with the ideas from the Wolfram physics project? Yeah, it's been mixed, very mixed. So on the kind of traditional fundamental physics people"
},
{
"end_time": 5671.8,
"index": 244,
"start_time": 5646.869,
"text": " It's mostly been, you know, ignored, right? So like, if you look at your average string theorist, many of them will have, you talk to them, many of them will have heard of the project and will say, oh, that's that weird, kooky thing that that guy did. And we don't really know anything about it, right? That's at least that's the general response that I've seen. They'll say they scrolled through the blog post, but then didn't find anything readily applicable to their field. And so they're just waiting for it to produce results. That's the general state, right? Exactly."
},
{
"end_time": 5690.776,
"index": 245,
"start_time": 5672.585,
"text": " Yes, and I've certainly had conversations with people who are not quite so polite."
},
{
"end_time": 5718.353,
"index": 246,
"start_time": 5691.237,
"text": " There's that crowd. There are some people in the quantum gravity community who have actually taken some interest and have started, you know, have cited our work and have used it and it's been incorporated in other things. So causal set theory is one example of a that's again a slightly unconventional branch to quantum gravity that's really quite formalistically similar in a way. Causal sets are really just, you know, they're partially ordered sets. They're really the same as causal graphs in some sense. And so there's a"
},
{
"end_time": 5738.08,
"index": 247,
"start_time": 5718.592,
"text": " Precise sense in which you can say that the you know that the hypergraphic writing formalism is just giving you a dynamics for causal set theory which calls us that there does not possess a priori because it's essentially a kinematic theory and so in those communities it's but there's been it's been somewhat more receptive there's been again there are in areas this is essentially unsurprising right so."
},
{
"end_time": 5767.159,
"index": 248,
"start_time": 5738.712,
"text": " In areas where there is formalistic similarity, like say, loop quantum gravity, where there's some similarity in the setup of things like spin networks and spin foams, there's been some interest in these kind of topological quantum field theory models or topological quantum computing models, where again, there's this interest in this intersection between, you know, combinatorial structure, topology, etc. and fundamental physics, there's been some interest. An area where we've got a lot of interest is in applied category theory. So, you know, people who, I would say that's been"
},
{
"end_time": 5791.647,
"index": 249,
"start_time": 5768.66,
"text": " At least in terms of the stuff that i've worked on that's been by far our kind of most warm reception are people working on categorical quantum mechanics and particularly these kind of diagrammatic graph rewriting approaches to quantum mechanics like zx calculus and so on. We've had some very very productive interactions with that with that crowd and also with people not directly on the physics side but interested in the formalism for other reasons so there are people like."
},
{
"end_time": 5819.36,
"index": 250,
"start_time": 5792.142,
"text": " The algebraic graph you're writing crowd, many of whom are in areas like Paris and Scotland. Again, you know, have been very interested in what we've been doing, not necessarily again, not necessarily for physics reasons, but because they're interested in the algebraic structure of how we're setting things up, or they're interested in how the formulas can be applied to other things like chemical reaction networks or, or, you know, distributed computing and that kind of stuff. You're currently at Princeton, correct? Right. Okay. So what do you do day to day?"
},
{
"end_time": 5846.63,
"index": 251,
"start_time": 5820.52,
"text": " Uh, so mostly I work on computational physics. Um, so I work on, uh, you know, developing, uh, yeah, developing algorithms and things for, for, for understanding physical phenomena through computational means, uh, which is, you know, more or less a direct extension of, uh, you know, of the stuff that I was doing at Wolfram research, but, um, yeah, I'm, I'm in a sense having been associated with the physics project and with Wolfram research for some time. I'm."
},
{
"end_time": 5876.903,
"index": 252,
"start_time": 5847.125,
"text": " I now consider in part my role to be trying to get some of those ideas more deeply embedded in sort of traditional scientific and academic circles. And, you know, not so much tied to, yeah, as you were putting it earlier, you know, Stephen's own personal research dollars and that kind of thing. How do you feel when the popular press almost invariably ascribes all, if not the majority of the credit of the Wolfram physics project to Wolfram himself? Yeah, it's difficult, right? So,"
},
{
"end_time": 5902.398,
"index": 253,
"start_time": 5877.517,
"text": " As I say, in a way, there is a positive aspect to that, which is that it means that you're shielded from direct criticism. Right, right. Less likely to be blamed. But no, I mean, yeah, it's emotionally difficult, right? I think, I don't know, maybe not for everyone, but certainly for me, I find it quite psychologically tough if, you know,"
},
{
"end_time": 5933.166,
"index": 254,
"start_time": 5903.78,
"text": " If there's an idea that I've had that I'm reasonably proud of or, you know, result that I've proved that I'm reasonably proud of, et cetera, it's not the best feeling to see, you know, headlines and Twitter threads and whatever, where it's all being ascribed to one person. And in my small way, I try to push back against that. But sorry, gone. I love Wolfram. I love Stephen. But so this goes without saying he doesn't do many favors in that regard. So when someone gives him the accolades,"
},
{
"end_time": 5963.831,
"index": 255,
"start_time": 5933.968,
"text": " It's rare that I'll see him say, oh, and by the way, that result was from Jonathan Gerrard. Right, right. And again, I guess, you know, we're all guilty of that to a certain extent. I mean, I'm acutely aware that in the course of this conversation, I haven't mentioned, for instance, Manognar Namaduri, who is the person who I kind of did a lot of this work on categorical quantum mechanics with, right, and who deserves, you know, again, a reasonable fraction of the credit for that insight. So, you know, I'm guilty of this too. And I guess everyone is to an extent. Steven,"
},
{
"end_time": 5994.087,
"index": 256,
"start_time": 5965.026,
"text": " Maybe more than many people, but but you know, I it's yeah, it's it's it's, you know, that's a feature of this personality that I can't claim to have been ignorant of. Sure, sure. So he has another claim, which is that he solved the second law of thermodynamics. And from my reading of it, I wasn't able to see what the problem was with the second law and how it was solved, other than you say you derive it from statistical mechanics, which was there before."
},
{
"end_time": 6022.073,
"index": 257,
"start_time": 5994.377,
"text": " I must be missing something because I don't imagine Stephen would make that claim without there being something more to it. So please enlighten me. Yeah. Okay. So, uh, I think as with many of these things, um, that, that blog post about the, or that series of three blog posts about the second law, I think was, um, there was interesting, you know, just like with NKS, right? I think there was, there was a lot of interesting stuff there, uh, that they got figured out."
},
{
"end_time": 6045.776,
"index": 258,
"start_time": 6022.551,
"text": " It wasn't quite as grandiose as i think steven made it out to be but you know again that's you know that's part that's that's the responsibility of any scientist right is to slightly inflate the significance of what they're doing but so my reading of it is as follows that uh so there's a there's a kind of standard textbook popular science type way that entropy increase gets explained right which is you know you say uh"
},
{
"end_time": 6071.596,
"index": 259,
"start_time": 6046.169,
"text": " If you define entropy as being the number of microstates consistent with a given macrostate or the logarithm of that, which is Boltzmann's equation, then the fact that entropy has to increase is kind of obvious in some sense because the number of ordered states, the number of ordered microstates or the number of microstates consistent with an ordered macrostate is always going to be smaller than the number of microstates consistent with a disordered macrostate."
},
{
"end_time": 6099.206,
"index": 260,
"start_time": 6071.596,
"text": " And so if you're just a godically sampling in your space of states, you're going to tend towards ones which are less orderly and not towards ones that are more orderly. And that argument or that explanation seems convincing for a few seconds until you really start to think about it and you realize that it can't possibly make sense. And one reason, I mean a very foundational reason why it can't possibly make sense is because that explanation is time symmetric, right? So if"
},
{
"end_time": 6125.862,
"index": 261,
"start_time": 6099.65,
"text": " If it's the case that you're ergotically sampling your space of possible states, and yes, the less ordered ones are always going to be more numerous than the more ordered ones, then yes, it's true that evolving forwards in time, you're going to tend towards the less ordered ones. But it's also true that if you're evolving backwards in time, you would tend towards the less ordered ones. But of course, that's not what we observe in thermodynamic systems. So that explanation can't be right or at the very least can't be the complete answer."
},
{
"end_time": 6139.121,
"index": 262,
"start_time": 6126.544,
"text": " I think the conceptual problem is a real one. I think it is true that we really don't fully understand the second law of thermodynamics from a statistical mechanical point of view."
},
{
"end_time": 6168.336,
"index": 263,
"start_time": 6140.247,
"text": " When you as soon as you start trying to apply it to more general kinds of systems the problems become worse i mean there's a there's a famous example that you know was brought up by by Penrose of you know what you know what happens when you try and apply the second law of thermodynamics to the early universe and again you get to you seeming get these two contradictory answers that so you know as the universe evolves forwards if we believe the second law things should be getting you know as we as we get further and further away from the initial singularity things should be entropy should be getting higher and higher"
},
{
"end_time": 6182.995,
"index": 264,
"start_time": 6168.933,
"text": " And yet when you look back close to the initial singularity and you look at the cosmic microwave background and so on, it looks very, very smooth. It looks basically Maxwellian, like a Boltzmann distribution. It looks more or less like a maximum entropy state."
},
{
"end_time": 6211.169,
"index": 265,
"start_time": 6183.319,
"text": " So we have this bizarre situation where, as you move away from the big bang, entropy gets higher, but as you go towards the big bang, entropy gets higher. So something must be wrong. And, you know, Penrose has these, uh, has these arguments about conformal cyclic cosmology and how, you know, the, the, the role of gravitational fields is essentially to decrease global entropy and all that kind of stuff. But that's all, you know, again, fairly speculative. And I would say at some deep level, that's still a story we don't really understand. So that I think is the problem that's being solved. And, uh,"
},
{
"end_time": 6219.036,
"index": 266,
"start_time": 6211.834,
"text": " that that series of blog posts proposes and again this is not really that i mean even hear that sound"
},
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"end_time": 6246.067,
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"start_time": 6219.991,
"text": " That's the sweet sound of success with Shopify. Shopify is the all-encompassing commerce platform that's with you from the first flicker of an idea to the moment you realize you're running a global enterprise. Whether it's handcrafted jewelry or high-tech gadgets, Shopify supports you at every point of sale, both online and in person. They streamline the process with the Internet's best converting checkout, making it 36% more effective than other leading platforms."
},
{
"end_time": 6272.176,
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"start_time": 6246.067,
"text": " There's also something called Shopify Magic, your AI-powered assistant that's like an all-star team member working tirelessly behind the scenes. What I find fascinating about Shopify is how it scales with your ambition. No matter how big you want to grow, Shopify gives you everything you need to take control and take your business to the next level. Join the ranks of businesses in 175 countries that have made Shopify the backbone."
},
{
"end_time": 6297.961,
"index": 269,
"start_time": 6272.176,
"text": " of their commerce. Shopify, by the way, powers 10% of all e-commerce in the United States, including huge names like Allbirds, Rothy's, and Brooklyn. If you ever need help, their award-winning support is like having a mentor that's just a click away. Now, are you ready to start your own success story? Sign up for a $1 per month trial period at shopify.com slash theories, all lowercase."
},
{
"end_time": 6326.203,
"index": 270,
"start_time": 6297.961,
"text": " Go to shopify.com slash theories now to grow your business no matter what stage you're in shopify.com slash theories. Even in NKS, there were indications of this idea. But yeah, I mean, the basic idea is that you can explain the time asymmetry in terms of computational irreducibility explain where you say, okay, so even if you have a system whose dynamics are exactly reversible,"
},
{
"end_time": 6350.811,
"index": 271,
"start_time": 6326.852,
"text": " In practice, because of computational irreducibility effects, the system can become pragmatically arbitrarily hard to reverse, and that you can think about it essentially as being a kind of a cryptanalysis problem, right? So in a sense, the dynamics of a computationally irreducible system are progressively encrypting certain microscopic details of the initial condition, so that in practice, even if it is in principle possible to reverse from a computability standpoint,"
},
{
"end_time": 6377.551,
"index": 272,
"start_time": 6351.271,
"text": " If you try and think about the computational complexity of that operation, it's equivalent to solving some arbitrarily difficult crypt analysis problem to work out, okay, where exactly was that molecule at time t equals zero? And and that goes some way towards explaining this time asymmetry problem. I don't think it's a complete explanation. I think there's I think there's a yet deeper mystery there. But I do think it's an interesting collection of ideas. Yeah. So that's observer dependent. So it would be difficult for you. Sorry, not."
},
{
"end_time": 6399.07,
"index": 273,
"start_time": 6377.978,
"text": " Difficult for anyone, but difficult for an observer, but for the system itself. Yes. Would there still be that issue of having to decrypt for the system itself? Well, no, I would argue not because it's a very important point, right? That these notions are all observer dependent because in a sense, the Boltzmann equation"
},
{
"end_time": 6424.343,
"index": 274,
"start_time": 6399.36,
"text": " Requires the existence of a macro of a macro state, right? So, um, and the macro state is a, is an observer. It's a synthetic kind of observer theoretic idea, right? It's like, you know, you've got a bunch of molecules bouncing around in a box. Um, and so they have some micro state details, but then you want to describe that box in terms of gas kinematics. You want to describe it in terms of a density and a pressure and a temperature and whatever. So those give you your macro states, but"
},
{
"end_time": 6452.892,
"index": 275,
"start_time": 6424.65,
"text": " The you know the the choice to aggregate this particular collection of micro states and say these are all consistent with a ideal gas with this you know temperature in this idea index whatever that's an observer dependent thing and so yeah and that's another point that again i don't think it's completely original but i think has not been adequately stressed until these blog posts which is that different definitions of an observer will yield different definitions of entropy different choices of coarse grainings yield different choice different definitions of entropy"
},
{
"end_time": 6472.841,
"index": 276,
"start_time": 6453.131,
"text": " And therefore, you know, in that sense, it's kind of unsurprising that, you know, as Von Neumann and Claude Shannon and people kind of pointed out that, you know, the term entropy is so poorly understood and that there are so many different definitions of it. There's entropy in quantum mechanics, there's entropy in thermodynamics, there's entropy in stat mech, there's entropy in information theory, and they're all"
},
{
"end_time": 6495.759,
"index": 277,
"start_time": 6473.609,
"text": " Similar similar vibes but the formally different and you can have situations where one entry measure is increasing one entry measures decreasing and that becomes much more easy to understand when you realize that they are all measures of entropy relative to different formalizations of what it means to be an observer. And yes with regards to the to the decryption thing. Yes i would say."
},
{
"end_time": 6525.589,
"index": 278,
"start_time": 6496.34,
"text": " There's an aspect of it that is fundamental, that is purely a feature of the system. Even if you don't have any model of the observer and you're just looking directly at the data structures, you can have the situation where the forward computation is much more easy or much more difficult than the reverse computation. And obviously those kind of one-way functions, those get used in things like cryptography, right? And the existence of those is quite well studied in cryptanalysis. So those certainly exist and those can give you some form of time asymmetry."
},
{
"end_time": 6555.196,
"index": 279,
"start_time": 6526.101,
"text": " but arguably the version of time asymmetry that's relevant for physics is the observer dependent one. It's the one where you say actually, you know, in this particular, for this particular aggregation of micro states and this particular interpretation of that aggregation as this macro state, this is the computational complexity of the reversal operation. And that is an observer dependent thing. You mentioned Penrose and I want to get to some of your arguments. I don't know if you still have them, but I recall from a few years ago, you mentioned that you have some issues with Penrose is non computational mind."
},
{
"end_time": 6577.654,
"index": 280,
"start_time": 6555.691,
"text": " argument. So I want to get to that, but I want to say something in defense of Stephen, that people don't realize what it's like when you're not in academia to one, get your ideas taken seriously by academia. And then also what it's like in terms of funding. So people will say that, yeah, sure. Stephen is rather montate or self triumphant, but you have to be that to the public because that's your"
},
{
"end_time": 6603.012,
"index": 281,
"start_time": 6578.063,
"text": " funding source. Whereas for the academics, they are that to the grant agencies, to the people they're asking for money, you have to big yourself up. It's just that you don't get to see that. Yeah, I know. I absolutely agree. Great, great. Now for Penrose, please outline what are your issues with I think it's the Penrose Lucas argument, although I don't know if Penrose and Lucas I know Lucas had an argument is called the Penrose Lucas argument. I don't know their historical relationship."
},
{
"end_time": 6625.247,
"index": 282,
"start_time": 6604.36,
"text": " Right, right. And yeah, there's an original argument that's purely using kind of mathematical logic and Turing machines and things. And then there's the Penrose-Hameroff mechanism, right, which is the proposed biochemical mechanism by which there exists this non-computability in the brain. Yeah, I mean, so, okay, there's an... Okay, how to phrase this."
},
{
"end_time": 6640.964,
"index": 283,
"start_time": 6625.435,
"text": " There's an element of this which I'm quite sympathetic to which goes back actually to the one of the very first things we discussed right which is the distinction between you know what is model versus what is reality Turing machines are a model. Yes. And so if you say well the mind is not a Turing machine."
},
{
"end_time": 6662.756,
"index": 284,
"start_time": 6641.8,
"text": " I mean if that's the if that's your only statement then i agree right but then nothing you know like the universe isn't a turing machine in that sense right and the question is is it useful to model the mind is a turing machine or is it used to model the universe as a turing machine and there i think the answers emphatically yes. And you know okay are you going to be able to model everything well not necessarily so again."
},
{
"end_time": 6690.23,
"index": 285,
"start_time": 6663.217,
"text": " To that extent, I do have some sympathy with the Penrose-Lucas argument that I'm open to the possibility that there may be aspects of cognition that are not amenable to analysis in terms of Turing machines and lambda calculus and that kind of thing. I just don't think that the particular examples that Penrose gives, for instance, in his book, Emperor's New Mind, are especially convincing examples. I mean, he has this argument that mathematics"
},
{
"end_time": 6698.985,
"index": 286,
"start_time": 6690.555,
"text": " The process of apprehending mathematical truth must be a non-computable process because we know from Gödel's theorems that"
},
{
"end_time": 6724.514,
"index": 287,
"start_time": 6699.65,
"text": " For any given formal system, if it's consistent, then there must be statements that are independent of that system, where both the statement and its negation are consistent with the underlying axioms. Gödel's original argument proved that for piano arithmetic, for the standard axiom system for arithmetic, and later on it was discovered it works for any axiom system that's at least as strong as piano arithmetic."
},
{
"end_time": 6751.732,
"index": 288,
"start_time": 6724.753,
"text": " And so Penrose's argument, I mean, I'm caricaturing a bit and it's a little unfair, but, you know, the basic argument is, well, we can obviously see that arithmetic is consistent. So when we construct this girdle sentence that says this statement is unprovable, we can see that it has to be true. And yet, you know, within the formal axioms of arithmetic, as they are computable, it cannot be decided in finite time that that statement is true."
},
{
"end_time": 6768.951,
"index": 289,
"start_time": 6752.381,
"text": " And okay so most of that is correct but the part where you say well we we as we as human observers can clearly see that that statement is true well that presupposes that we are able to you know we are able to know the consistency of integer arithmetic which we have strong reason to believe is consistent but."
},
{
"end_time": 6797.176,
"index": 290,
"start_time": 6769.411,
"text": " Goodell's second incompleteness theorem says that, well, we can't know that formally either. So in a sense, he's he's presupposing the conclusion. He's already presupposing that we can know the truth value of an independent proposition, namely the consistency of Piano arithmetic in order to prove that we can know the truth value of another independent proposition, namely this good sentence. And so for me, it just feels extremely circular. So it doesn't. Sorry, can you not use like what if he didn't say that it's irrefutable?"
},
{
"end_time": 6815.367,
"index": 291,
"start_time": 6797.432,
"text": " Rather that probably so far it seems like piano arithmetic is consistent and if it was to explode it'd be so odd that it hasn't exploded already and we've explored it quite extensively every day we increase our credence and the consistency of it can you not use an argument like that."
},
{
"end_time": 6840.64,
"index": 292,
"start_time": 6816.203,
"text": " He absolutely could and that and that would be correct but then the problem with that is there's nothing in that argument that a computer could not replicate right a machine could also make that same argument you could also write computer program that says okay i'm gonna test loads of propositions in piano arithmetic and and see whether i find a you know an inconsistency and the more propositions i test uh you know the the less likely it is that the piano arithmetic is inconsistent so i can construct"
},
{
"end_time": 6859.053,
"index": 293,
"start_time": 6840.64,
"text": " This is machine speaking here i can construct some kind of basic argument that says you know i'm this level of confident that this proposition is true so yes human beings can can can do that kind of basic reasoning but then so can machine and so that the crux of the pen rose argument is openers lucas argument is that."
},
{
"end_time": 6888.251,
"index": 294,
"start_time": 6859.053,
"text": " You know there is there is this additional non-computable step where the human somehow knows not assumes but just knows that piano arithmetic is consistent and from that deduces that he has to be true and I I don't see how you can justify that without essentially presupposing the conclusion. So what's the difference between intuitionist logic and constructivist logic. Okay that's a fantastic question so and and cycles back to the stuff we were talking about the beginning with regards to like constructivist foundations for physics right so"
},
{
"end_time": 6916.544,
"index": 295,
"start_time": 6888.541,
"text": " I would say, so constructivism is really a kind of broad, okay, the simple answer is intuitionistic logic is a special case of constructivist logic. So constructivism is a broad philosophical movement where the idea is, so okay, for the people who don't know the history of this, so in the aftermath of Gödel's incompleteness theorems and Tarski's undefinability theorem and Turing's proof of the undecidability of the halting problem and all these limited results in mathematical logic that happened in the early 20th century,"
},
{
"end_time": 6945.589,
"index": 296,
"start_time": 6917.159,
"text": " People started saying, okay, well, how can we trust that anything is true in mathematics, right? So if, if we always have to make some unprovable assumption about the consistency of our axiom system, how can we ever be confident of anything beyond just the kind of heuristic Bayesian argument that we made before? Um, and so then, uh, various people like, especially a guy called Brower and later, you know, in his lazy years, David Hilbert, um, cotton on the idea that, okay, what you could do is you could say, well, um, if we,"
},
{
"end_time": 6974.497,
"index": 297,
"start_time": 6945.896,
"text": " Strengthen our criterion for mathematical proof. If we say that when you reason about a mathematical object, it's not enough just to reason about it abstractly. You actually have to give an algorithm, a finite deterministic procedure that constructs that object before your statements can even make sense. That's a much stronger condition and it immediately rules out certain forms of mathematical proof. So for instance, a proof by contradiction, it would not be allowed in such a paradigm because if you prove a statement, okay,"
},
{
"end_time": 7003.404,
"index": 298,
"start_time": 6975.145,
"text": " So obviously, suppose I want to convince you that this equation has a solution. So one way I could convince you is to make a proof by contradiction. I could say, assume it doesn't have a solution and then derive some piece of nonsense. My assumption had to be wrong. But you can prove existence without construction. Right, right. But that only works if I assume that the axiom system I was using to prove that is consistent and that the inference rules I was using to derive that contradiction were actually sound."
},
{
"end_time": 7023.592,
"index": 299,
"start_time": 7003.763,
"text": " If they weren't, if it was an inconsistent system or the inference rules would not sound, then I could derive a contradiction even from a statement that was true, and so it would be invalid. And of course we know from Gödel's theorems and from Turing's work that we cannot for any non-trivial formal system know conclusively that the system is consistent or that the inference rules are sound."
},
{
"end_time": 7047.381,
"index": 300,
"start_time": 7024.104,
"text": " i'm whereas instead if i try and convince you by saying look here's a program here's an actual algorithm that constructs a solution for you and you can just go and check whether it solves the equation somehow that's much more convincing you don't have to assume anything except that maybe the validity of the model of computation but you can check that too right so there's no you're placing a much lower kind of um"
},
{
"end_time": 7065.486,
"index": 301,
"start_time": 7047.773,
"text": " Epistemological burden on the underlying axioms of mathematics you can use those to guide you in how you search for things but ultimately the ultimate criteria and the ultimate test for truth is can you define a mathematical deterministic algorithm that actually witnesses the structure that you're talking about."
},
{
"end_time": 7088.695,
"index": 302,
"start_time": 7066.323,
"text": " And so this was intended to be a kind of almost a get out clause, you know, from these limited of results to say this is a way that we can kind of bypass many of these, not all of them, of course, but many of these issues. Now, it's a very, very significant limitation because it immediately means that there are very large classes of mathematical structures that you just can't talk about at all. You know, the structures where you can't avoid undecidability and independence."
},
{
"end_time": 7114.189,
"index": 303,
"start_time": 7088.695,
"text": " But rather astonishingly, there are large parts of mathematics, including areas like analysis, which you maybe wouldn't have thought would be amenable to constructivism, where many of the most interesting results, you know, the Heine-Barrell theorem or whatever, right, you can actually prove using purely constructivist means. So that's really what constructivism is about. Then intuitionism, which is a particular flavor of constructivism that's due to Brouwer."
},
{
"end_time": 7137.449,
"index": 304,
"start_time": 7115.538,
"text": " What once you decided that you want to work in construction is mathematical foundations and then you still have the problem of what am i what my underlying rules going to be what what how do i actually impose those constraints in a systematic way. And so intuition is just one approach to doing where you say okay. I want to outlaw non constructive proofs like proof by contradiction how do i do that."
},
{
"end_time": 7166.203,
"index": 305,
"start_time": 7138.234,
"text": " Well, uh, one, you know, what's the one thing that should be outlawed is any use of double negation. So the, the, the axiom of double negation that not, not X is equivalent to X. I shouldn't be able to do that because that allows me to do non-constructive proofs. And it turns out that if you're going to outlaw that you also out need to outlaw what's called the law of excluded middle, the statement that a or not a is true for any proposition that you, you, you, you, sorry, you need to outlawed or is equivalent to outlawing that. Uh, it's equivalent to it was here. So, so, so one, one necessitates the other."
},
{
"end_time": 7182.125,
"index": 306,
"start_time": 7166.647,
"text": " And and then you know in the kind of logical foundations that's what you need to do and then that implies certain things like that say the axiom of choice in set theory read the statement that if you have a collection of if you have some collection of non empty sets."
},
{
"end_time": 7211.954,
"index": 307,
"start_time": 7182.125,
"text": " Is that the root of the word intuitionism? Like is it actually meant to say that this is more intuitively the case?"
},
{
"end_time": 7242.449,
"index": 308,
"start_time": 7212.79,
"text": " These were meant to be the minimum rules that somehow, yeah, I mean, in a way, yes, these are meant to be kind of the minimum conditions that that matched human mathematical intuition. Yeah, I don't know. I know there's a whole history of, like I mentioned, I want to do a whole video on my gripes with names. So it could be something philosophical about content intuition. I have no clue. But do intuitionists not have a concept of infinity? Because you mentioned Heine-Barrell. And so it's not embedded in that the"
},
{
"end_time": 7251.442,
"index": 309,
"start_time": 7242.875,
"text": " Right, right. If you say you can do analysis, I don't understand how that can be done. Yeah, okay. This is a really important point. So"
},
{
"end_time": 7274.667,
"index": 310,
"start_time": 7252.09,
"text": " I mentioned that intuition is just one flavor of constructivism and there are many others and there are ones that are more or less strict. So there's a stricter version of constructivism called finiteism, which is exactly that where you say, not only am I going to be constructivist, but my algorithms have to terminate in finite time."
},
{
"end_time": 7293.234,
"index": 311,
"start_time": 7274.974,
"text": " If you're an intuitionist and you're not and you don't subscribe to the kind of finite is my day you might say well i can write down an algorithm that solves this there is a deterministic procedure but it may not necessarily terminate in finite time so you know i mean the the you know an example that would be the integers right so with the integers."
},
{
"end_time": 7308.49,
"index": 312,
"start_time": 7293.951,
"text": " I can write down an algorithm which provably constructs the complete set of integers. That algorithm doesn't terminate. If I were to run it on a finite machine it wouldn't terminate. But any given integer can eventually be derived by just repeatedly applying that procedure."
},
{
"end_time": 7326.135,
"index": 313,
"start_time": 7308.916,
"text": " I'm so you could so there is actually a way subject this kind of weaker version of intuition ism there is a way you can reason about infinite mathematical structures but if you then say oh no i'm not gonna allow myself to do that i want all of all my you know all the deterministic procedures that i write down."
},
{
"end_time": 7355.043,
"index": 314,
"start_time": 7326.578,
"text": " I like it. I don't believe in it, but I like it. Well, again, it's it's it's this question of what do you mean by belief, right? I mean, if if"
},
{
"end_time": 7381.852,
"index": 315,
"start_time": 7356.22,
"text": " If mathematics is intended to be a kind of tool set for modeling certain processes of thought, then, you know, there are there are certain kinds of problems where I think it's useful to take a finite or ultra finite mindset. Yeah, I agree. If you if you're a mathematical Platonist, which I'm not, then you might say, Okay, well, I believe that the mathematical universe is much larger than, you know, in some logical sense than the universe that's conceived by ultra finiteists. But"
},
{
"end_time": 7401.698,
"index": 316,
"start_time": 7382.346,
"text": " What do you believe to be the primary difficulty between combining general relativity and quantum mechanics?"
},
{
"end_time": 7431.869,
"index": 317,
"start_time": 7403.473,
"text": " Right. So that's been formulated in many ways. I mean, so I'm going to having having just sort of slightly slated Penrose for his for his consciousness views. Let me let me let me try and write that wrong a little bit by saying I think Penrose has a really, really nice argument for why even just at a conceptual level, quantum mechanics and general relativity are incompatible, which is the following that that if you take the two of the most foundational principles,"
},
{
"end_time": 7452.944,
"index": 318,
"start_time": 7432.278,
"text": " In a sense delineate how quantum mechanics is different from classical mechanics and how general relativity is different from classical mechanics. Those would be the superposition principle in quantum mechanics, the principle that if you have a system that can be in this eigenstate or this eigenstate it can also be in some complex linear combination of them."
},
{
"end_time": 7482.756,
"index": 319,
"start_time": 7453.148,
"text": " And on the side of the equations of general relativity it's the principle of equivalence rates the principle that accelerating reference frames and gravitational reference frames are really the same or to translate that into slightly more mathematical terms that you can that anything that appears on the left hand side of the field equations in the Einstein tensor you can move as a negative contribution to the right hand side in the stress energy sensor. So. Penrose has this really nice argument for why those two principles are logically inconsistent and the argument goes like this that so"
},
{
"end_time": 7512.363,
"index": 320,
"start_time": 7483.643,
"text": " Suppose that you've got something like a Schrodinger-Capps type experiment where you've got a robotic arm that contains a mass at the end that's producing a gravitational field and it's connected up to radioactive nucleus that has some probability of decaying. So that arm can be in one of two positions. It can be position A, position B, and the position that it's in depends on the quantum state of that nucleus. So now, just naively, what you appear to have done is created a superposition of two different gravitational field configurations."
},
{
"end_time": 7542.329,
"index": 321,
"start_time": 7513.183,
"text": " Okay, so if you do that, you can write down the wave function that corresponds to that superposition and everything looks just fine. So far, there's no problem. But then if you believe the equivalence principle, then you should get the same wave function if you then do the same calculation in an accelerating frame. So if you take that whole desktop apparatus and rather than doing it here on the Earth, you do it in a spaceship that's accelerating at 9.81 mps² and you have exactly the same experimental setup with the same robotic arm,"
},
{
"end_time": 7567.056,
"index": 322,
"start_time": 7542.329,
"text": " You should get the same way function. What if you calculate it which you can it's just a standard calculation in a realistic quantum mechanics you get almost the same answer. The two way functions differ by a face factor. Which normally wouldn't be too much of a problem normally you know if they don't buy a face back to you say that they're somehow the same quantum system yes but the face factor depends on time to the power for. And because."
},
{
"end_time": 7578.78,
"index": 323,
"start_time": 7567.415,
"text": " Of some slightly technical reasons that have to do with the fact that quadratics have two solutions, if you have a phase factor depends on time to the power four, that's telling you that the wave function you've written down corresponds to a superposition of two different vacuum states."
},
{
"end_time": 7600.776,
"index": 324,
"start_time": 7579.599,
"text": " And one of the core axioms of quantum mechanics is that you can't superpose two different vacuum states for the very simple reason that the vacuum state is the kind of zero point from which you measure energies, you know, using your Hamiltonian. So if you have a superposition of two different vacuum states, there's no longer a uniquely defined Hamiltonian. There's no longer a defined energy because there's no, there's no rule for how you superpose those vacua."
},
{
"end_time": 7620.35,
"index": 325,
"start_time": 7600.776,
"text": " So it is inherently illegal in quantum mechanics to produce the super positions so somehow by by just assuming that you could superpose gravitational fields you've been able to use the equivalent principle to violate the the superposition principle off. Equivalently vice versa. There's a more mathematical way of seeing the same thing which is to say that okay so."
},
{
"end_time": 7649.991,
"index": 326,
"start_time": 7620.913,
"text": " At a very basic level, quantum mechanics is linear and has to be linear by the Schrodinger equation. The Schrodinger equation has to be linear because of the superposition principle. So if I have two solutions to the Schrodinger equation, then a complex linear combination of those states with appropriate normalization has to also be a valid solution to the Schrodinger equation. General relativity is nonlinear and has to be nonlinear because, in a sense, if you take the Einstein field equations and you linearize them, you linearize the gravitational interaction,"
},
{
"end_time": 7670.486,
"index": 327,
"start_time": 7650.538,
"text": " Then what you get is a version of general relativity that doesn't possess gravitational self-energy. So in other words, the reason why general relativity is a nonlinear theory is because in Newtonian gravity, if I have a mass, that mass produces a gravitational potential. But the gravitational potential doesn't produce a gravitational potential."
},
{
"end_time": 7691.63,
"index": 328,
"start_time": 7670.794,
"text": " But in general relativity because of the mass energy equivalence, I have a massive producer gravitational potential, but that gravitational potential has some energy associated to it. So it also produces a gravitational field and that produced another gravitational field and so on. So there's actually a whole infinite sort of sets of these smaller gravitational fields that are being produced. So this is often summarized as the by the slogan that gravity gravitates."
},
{
"end_time": 7719.377,
"index": 329,
"start_time": 7692.278,
"text": " And that appears as a nonlinear contribution to the Einstein field equations, these off diagonal terms that appear in the Einstein tensor. And so it has to be nonlinear because if you were to take two solutions to the Einstein equations, two metrics and just try and add them together, you quite clearly wouldn't get a third solution to the Einstein equations in general, because what you've done is you've added the gravitational potentials, which is really what the metric tensors are indicating. But you haven't incorporated all these additional nonlinear contributions"
},
{
"end_time": 7747.039,
"index": 330,
"start_time": 7720.009,
"text": " So the basic problem is that you can't superpose gravitational fields, right? And that's really what the Penrose argument is kind of indicating, that if I try and take two metric tensors and just add them in a way that's consistent with the Schrodinger equation, I'll violate the Einstein field equations. And if I try and take two solutions to the Einstein field equations and combine them in a nonlinear way that's compatible with general relativity, I'll violate the linearity of the Schrodinger equation."
},
{
"end_time": 7766.544,
"index": 331,
"start_time": 7747.329,
"text": " Does the conceptual difficulty still persist in the quantizing linearized general relativity?"
},
{
"end_time": 7788.114,
"index": 332,
"start_time": 7768.217,
"text": " So my understanding is that you can certainly get further with quantizing linear. So if you just linearize your gravitational interaction, you can not only evolve quantum fields on top of a curved space-time described in terms of linearized gravity, which you can do for Einstein gravity,"
},
{
"end_time": 7817.944,
"index": 333,
"start_time": 7788.114,
"text": " But you can also describe the back reaction of the quantum fields onto the metric tensor. I actually don't know how much further than that you can go. I suspect, but what I do know is that it's definitely a lot easier. You can make much more rapid progress with quantizing gravity if you assume linearizations than if you don't. I think there are still some problems that persist, but I think they're nowhere near as difficult. So how is it that higher category theory overcomes this? That's a great question."
},
{
"end_time": 7840.026,
"index": 334,
"start_time": 7818.49,
"text": " I don't know but there's a very tempting kind of hypothesis. I mentioned towards the beginning that there are these category theoretic models for quantum mechanics and I even mentioned briefly that there are these models for quantum field theory as well. And the way that that works is, so we talked at the start about these dagisymmetric compact closed monoidal categories,"
},
{
"end_time": 7852.585,
"index": 335,
"start_time": 7840.794,
"text": " Which are the kind of the basic mathematical set up for categorical quantum mechanics the problem with that though is that every time you apply one of these morphisms every time you apply one of these time evolution operators you are essentially."
},
{
"end_time": 7873.439,
"index": 336,
"start_time": 7853.166,
"text": " picking out a preferred direction of time right you are assuming you've got you know if you imagine each of your quantum state each of your space of states is a space of states on a particular space like hypersurface when you once you construct a unitary evolution operator that's a solution to the shredding equation you are selecting a preferred direction of time which is of course not relativistic that's not covariant."
},
{
"end_time": 7896.459,
"index": 337,
"start_time": 7874.036,
"text": " So to go from the non-relativistic version of quantum mechanics to a version that's compatible, at least with Lorentz symmetry, you need to have some systematic way of transforming one time direction to another. Well, if you think about it in the category theoretics perspective, through the category theoretic lens, there's a systematic way to do that, which is through higher categories. So if you consider categories which have"
},
{
"end_time": 7924.258,
"index": 338,
"start_time": 7896.766,
"text": " You know, objects and morphisms, you can also consider two categories that have two morphisms between those morphisms that allow you to transform morphisms to each other, not just objects to each other. And so if you take the two category version of the one category picture of categorical quantum mechanics, you can allow the two categories to correspond to gauge transformations between your evolution operators. So you're transforming the direction of time in a way that's consistent with, say, with the generators of the Lorentz group."
},
{
"end_time": 7949.531,
"index": 339,
"start_time": 7924.838,
"text": " And so what you get in some appropriate special case is what's called a functorial quantum field theory. So Baez and Dolan constructed this axiomatization of functorial and particularly topological quantum field theories based on what's called a T.S. Segal axiomatization that used these two categories and indeed even higher categories as a way of formalizing this notion of gauge transformations, of being able to transform between time directions."
},
{
"end_time": 7962.875,
"index": 340,
"start_time": 7950.52,
"text": " Okay so that's a nice piece of mathematics and in my opinion is one of the more promising avenues towards constructing a kind of mathematically rigorous foundation for quantum field theory."
},
{
"end_time": 7991.493,
"index": 341,
"start_time": 7963.268,
"text": " What does it have to do with quantum gravity? Well, this is where it necessarily becomes very speculative. But so there's an idea that goes back to Alexander Grothendieck, who I mentioned, amazing algebraic geometry from the early 20th century, who really developed a whole bunch of these ideas from applied in higher category theory while he was sort of living as a basically a hermit in the Pyrenees, I think. But so Grothendieck made this hypothesis that's now called Grothendieck's hypothesis or the homotopy hypothesis."
},
{
"end_time": 8005.179,
"index": 342,
"start_time": 7992.449,
"text": " Which goes as follows, okay, let me motivate it like this so. If I have a topological space, you know it has some collection of points and it has paths that connect those points. But I can also have."
},
{
"end_time": 8030.555,
"index": 343,
"start_time": 8005.538,
"text": " Pause the connect the pause and those are called homotopies right so i can continuously deform one path into another i can use that. Information to tell me stuff about the topology of the space so you know you can use that the homotopy information to tell you about the technology right you can find that there's a. If you're in a donut you can see that there's a hole there because if you have a loop. I don't path loops around that hole you can't continue you can't continuously track the contract to a point without encountering some discontinuity."
},
{
"end_time": 8059.667,
"index": 344,
"start_time": 8030.981,
"text": " Um, so, uh, those homotopies you can formalize as, you know, kind of higher order paths between paths. So in the language of category theory, you could say my initial topological space is a one category that has points and, you know, paths between the objects and morphisms. My, the, the first homotopy type is the two category I construct from that where the two morphisms homotopies between those paths. But then I can also consider homotopies between homotopies and so on. So I can construct this whole hierarchy of, of, of higher categories and higher homotopy types."
},
{
"end_time": 8073.933,
"index": 345,
"start_time": 8060.145,
"text": " And the somehow we know that."
},
{
"end_time": 8091.613,
"index": 346,
"start_time": 8074.343,
"text": " from various results in high-category theory that that the that the information all the information that you care about up to we come out to be equivalent about not just the space you started from but all of the intermediate spaces that were in a hierarchy all of that information is somehow contained in the algebraic structure of that infinity category."
},
{
"end_time": 8114.275,
"index": 347,
"start_time": 8091.886,
"text": " The infinity category determines up to we come out of the equivalence everything that's that comes in the hierarchy below it and that's why kind of infinity category theory is so different to even just normal finite higher category theory infinity categories somehow contain far more information there's actually is a specific type of infinity of infinity category called an infinity group or eight because of the you know because the paths are invertible right um and growth and decrease one of the"
},
{
"end_time": 8144.616,
"index": 348,
"start_time": 8114.65,
"text": " Really one of the first people who encouraged topologists to stop thinking about fundamental groups and start thinking about fundamental group points without, you know, without needing to define distinguished base points and things like that. But the homotopy hypothesis is this really deep statement that kind of goes in the other direction where, so we know that starting from a space and doing this, you know, hierarchical construction, you build up to this infinity category that tells you, you know, up to weak homotopy equivalents, all the topological information about that space and all of its homotopy types."
},
{
"end_time": 8162.039,
"index": 349,
"start_time": 8145.043,
"text": " I'm. Grosvenor then said well maybe that's really the definition of a topological space that infinity categories are just spaces infinity group points are spaces. Or at least they define the structure of a space and all of it homotopy types up to become must be equivalent to converse direction."
},
{
"end_time": 8178.951,
"index": 350,
"start_time": 8162.688,
"text": " It's not proven, it's not even precisely formulated, but it's a very interesting idea that I think is largely believed to be correct. It aligns well with our intuitions for how algebraic topology should work."
},
{
"end_time": 8205.913,
"index": 351,
"start_time": 8179.377,
"text": " Attempting speculation about the relationship between that and physics. So going back to the quantum field theory picture for a moment. So suppose you don't just stop at two categories or indeed three categories. You keep going, right? You keep adding these higher gauge transformations. So not just gauge transformations that deform time direction to time direction, but higher gauge transformations that deform gauge transformation to gauge transformation. You build up a higher homotopy type that way. What happens when you get to the infinity category limit?"
},
{
"end_time": 8224.241,
"index": 352,
"start_time": 8206.544,
"text": " Well, so what you end up with is something that has the structure of a topological space so you starting from something that's completely non spatial you've ended up with a topological space. And so. In the spirit of these kind of emergent space time views you know like er equals EPR and so on."
},
{
"end_time": 8243.712,
"index": 353,
"start_time": 8224.616,
"text": " One hypothesis that's quite tempting to make is maybe that infinity category defines the structure of our space time. The topology and geometry of space time emerges in that infinity category limit that i take by just adding higher and higher gate transformation starting from categorical quantum mechanics. And so if that's true which."
},
{
"end_time": 8261.869,
"index": 354,
"start_time": 8244.224,
"text": " Again to be clear we have no idea whether that's true or not, but if that were true, then the coherence conditions, the conditions that define how the infinity category relates to all of the lower categories in that hierarchy, those coherence conditions would essentially be an algebraic parameterization for possible quantum gravity models."
},
{
"end_time": 8287.875,
"index": 355,
"start_time": 8262.142,
"text": " And so that would be a very, if that ended up being correct, that would be a really nice way to kind of conceptualize and formalize the essential problem of quantum gravity that we're really trying to nail down the coherence conditions that relate that infinity category to all the all the higher categories in that hierarchy. Now, what would it be like to study the topology? So there's something called the stone duality, I'm sure you're aware of, which relates topology to syntax. So"
},
{
"end_time": 8306.408,
"index": 356,
"start_time": 8288.114,
"text": " I've never heard of someone studying stone duality at the infinity categorical level at the topology that's induced from that category. What does that look like? Yeah, that's that's a really interesting question. So yes, the way that stone duality works is so if you have a"
},
{
"end_time": 8331.561,
"index": 357,
"start_time": 8306.715,
"text": " I mean, there's, again, as with many of these things, there's a nice categorical interpretation in terms of Boolean topos and things. But the basic idea is that if you have a Boolean algebra, you know, a kind of minimal algebraic axiomatization for logic, there's a way that you can formalize that in terms of this mathematical structure of a lattice, right, and specifically an orthomodular lattice, I think. I may be getting that wrong. I think it's an orthomodular lattice. But so"
},
{
"end_time": 8354.838,
"index": 358,
"start_time": 8332.363,
"text": " In which essentially every point in that lattice is a is a proposition and then you have these meat operations in these joint operations that become equivalent to your and an or operation logic. And the reason that significant is because those same class of lattices also appear in topology because there are specific spaces called stone spaces that are essentially the so okay sorry let me let me."
},
{
"end_time": 8383.558,
"index": 359,
"start_time": 8355.384,
"text": " Hear that sound? That's the sweet sound of success with Shopify. Shopify is the all-encompassing commerce platform that's with you from the first flicker of an idea to the moment you realize you're running a global enterprise. Whether it's handcrafted jewelry or high-tech gadgets, Shopify supports you at every point of sale, both online and in person. They streamline the process with the internet's best converting checkout, making it 36% more effective than other leading platforms."
},
{
"end_time": 8409.565,
"index": 360,
"start_time": 8383.558,
"text": " There's also something called Shopify Magic, your AI-powered assistant that's like an all-star team member working tirelessly behind the scenes. What I find fascinating about Shopify is how it scales with your ambition. No matter how big you want to grow, Shopify gives you everything you need to take control and take your business to the next level. Join the ranks of businesses in 175 countries that have made Shopify the backbone"
},
{
"end_time": 8432.91,
"index": 361,
"start_time": 8409.565,
"text": " of their commerce. Shopify, by the way, powers 10% of all e-commerce in the United States, including huge names like Allbirds, Rothy's, and Brooklyn. If you ever need help, their award-winning support is like having a mentor that's just a click away. Now, are you ready to start your own success story? Sign up for a $1 per month trial period at Shopify.com"
},
{
"end_time": 8460.879,
"index": 362,
"start_time": 8432.91,
"text": " Say that less confusingly. So if you take a topological space and you look at it, it doesn't like topological spaces. No. OK, let's let's let's try that again. OK, sorry, that's been kept in that part."
},
{
"end_time": 8489.121,
"index": 363,
"start_time": 8461.596,
"text": " So wait, wait, is it angry at you? No, it was angry at someone. There's a gate just outside, which which sometimes opens and closes. And this is my fiance's dachshund, who is very, very territorial. And he was up until now sleeping very soundly and has just woken up. And so we may get some interruptions. Well, congratulations on the engagement. Thank you. Thank you. Yes, anyway. So what was I saying? Yes. OK."
},
{
"end_time": 8511.254,
"index": 364,
"start_time": 8489.514,
"text": " If you take a topological space, then you can look at its open set structure. So if you take the collection of all open sets, you can look at, in particular, you can look at the open set containment structure. You can look at, you know, which open sets are included in which others. And when you do that, you again get the structure and also modular lattice, because you know that the lattice operations are essentially defined by the inclusion relations between the open sets."
},
{
"end_time": 8528.37,
"index": 365,
"start_time": 8512.056,
"text": " So you could ask what are the particular topological spaces that you get if you look for topological spaces whose open set lattices are the lattices that you get from looking at Boolean Algebras."
},
{
"end_time": 8546.425,
"index": 366,
"start_time": 8528.643,
"text": " And those are the stone spaces of the topological spatial interpretation of logic in some sense and in a way you can say topos theory is really about trying to generalize that that idea right it's another way to think about it that so. Every elementary topos has an internal logic."
},
{
"end_time": 8575.23,
"index": 367,
"start_time": 8546.971,
"text": " And also every elementary topos has some kind of spatial interpretation because the axioms of elementary topos theory, this finite limit axiom and this existence of power objects or sub-object classifiers is really the analogue of, is really some generalisation of the axioms of point set topology, right? Because, you know, the topos theoretic analogue of saying that your open sets have to be closed, you know, the collection of open sets has to be closed under arbitrary unions and finite intersections and so on."
},
{
"end_time": 8593.831,
"index": 368,
"start_time": 8576.135,
"text": " I'm so topos have special interpretations and they also have an internal logic. I'm so there's a particular kind of topos called boolean topos whose internal logic is boolean algebra and who special interpretation is there for a stone space but actually you can make that you can do the same construction for any elementary topos that you like."
},
{
"end_time": 8617.79,
"index": 369,
"start_time": 8594.309,
"text": " I'm and so then really what you're asking is working when you go to higher topos theory if we take the higher category which turns every day that that infinity category that you get from the growth and deconstruction is no admits a topos structure. So then you could ask what is the internal logic to that and what is its relationship to its space reality. And what you end up with is the spatial structure of an infinity homotopy type in homotopy type theory."
},
{
"end_time": 8632.858,
"index": 370,
"start_time": 8618.609,
"text": " So in homotopy type theory, this is another kind of logic interpretation of, uh, of, uh, you know, of, of higher categories where my apologies. Sorry. Crying somewhat. Hang on. Um, okay."
},
{
"end_time": 8650.162,
"index": 371,
"start_time": 8633.183,
"text": " Yes, yes, it's getting slightly more restricted in my motions now. But if you imagine taking a proof system and you say, OK, so now I'm going to interpret every point, every proposition in that proof system as being a point in some space and every proof as being a part. Yes. Right. So a proof just connects two propositions together."
},
{
"end_time": 8666.869,
"index": 372,
"start_time": 8650.572,
"text": " Then so i can prove one proposition for another i could prove that two propositions are equivalent i can also prove that two proofs are equivalent right i can take two parts and i can continuously deform them but that proof exists in the next homotopy type right because that's interpreted topologically as a homotopy between those between those parts."
},
{
"end_time": 8692.585,
"index": 373,
"start_time": 8666.869,
"text": " And so you can do exactly the same construction and so that in the infinity category limit what you get is a is a logic which allows not just for proofs of propositions but proofs of equivalence between proofs and proofs of equivalence between those proofs and so on right so that would be the kind of that's the internal logic of one of those higher top losses it's a it's a it's a it's a logic that allows for proofs of equivalence between proofs up to arbitrarily high order interesting so"
},
{
"end_time": 8721.527,
"index": 374,
"start_time": 8693.148,
"text": " In theories of truth there's one called Tarski's theory of truth where your truth can only speak about the level that's beneath it and then right and this is one of the ways of getting around the liars paradox is that you say well it's truth level one and then you're speaking about a truth level two or falsity level two etc and then the criticism is well what happens Tarski when you go all the way up to infinity and I don't think he had an answer but it's sounding like there can be a metaphor here for some answer"
},
{
"end_time": 8753.353,
"index": 375,
"start_time": 8724.923,
"text": " yes i mean potentially it's not something i've thought about a huge amount but it's certainly the case that in these in these kind of higher order logic constructions there are things that happen at the infinity level that don't happen at any finite level and it's conceivable that yes you you might be able to say you might be able to do a kind of tasky thing of evading the light or you may be able to do some kind of right i mean i think the same thing happens with quine's paradox right or where you have um you know you you try and how you you try and construct uh um"
},
{
"end_time": 8773.695,
"index": 376,
"start_time": 8754.087,
"text": " You know lie paradox type scenarios without self reference where you say you know i do know that the next sentence is false the previous sentence is true or something yes but then. The logical structure of those things changes when you as soon as you go from having a finite cycle of those things to having an infinite cycle the logical structure changes and i think the same is true of things like the task you theory of truth."
},
{
"end_time": 8802.756,
"index": 377,
"start_time": 8773.695,
"text": " And yeah, it may be that there's some nice interpretation of that in terms of what happens as you build up the, you know, to these to these progressively higher or small posses in homotopy type theory. I don't know. I mean that it's but it's a it's an interesting speculation. What would be your preferred interpretation of truth? So from a logic standpoint, I'm quite taken with the kind of with the definition of semantic truth that exists in things like task is undefined ability theorem, which is the idea that"
},
{
"end_time": 8821.852,
"index": 378,
"start_time": 8803.148,
"text": " You say a proposition is true if you can incorporate it into your formal system without changing its consistency properties, right? So if you have formal system S and you have proposition T, T is true if and only if S plus T is, you know, if and only if con S plus T is the same as con S."
},
{
"end_time": 8847.961,
"index": 379,
"start_time": 8821.852,
"text": " And that's a fairly neat idea that I think I mean it's used a lot in logic and it's quite useful for formalizing certain concepts of mathematical truth and particularly for distinguishing these kind of concepts of like completeness versus soundness versus decidability, which often get confused. Those become a lot easier to understand in my experience if you start to think of truth in those terms. Yeah, great. John, that's a formal definition of truth. It works for formal statements, but what about colloquial informal ones?"
},
{
"end_time": 8869.77,
"index": 380,
"start_time": 8848.456,
"text": " No i agree it's extremely full but i was what i was about to say that i think it also aligns quite well with some. Basic intuition we have for how truth works when we when we reason about things informally right so if we have some model of the world right and that's like a formal system some informal system right and when we take if you take on board some new piece of information."
},
{
"end_time": 8891.203,
"index": 381,
"start_time": 8870.35,
"text": " Generally speaking, the way that humans seem to work is, if we can incorporate that new piece of information without fundamentally changing the consistency properties of our model of the world, we are much more likely to believe that statement is true than if it necessitates some radical reimagining of the consistency properties of our internal representation. And so I think informally,"
},
{
"end_time": 8918.2,
"index": 382,
"start_time": 8891.92,
"text": " There's a version of that same definition of truth that has a bit of slack, right? Where you say, okay, a proposition could be provisionally true, but how likely I am to accept it as true depends on how radically I have to reformulate my foundations of reality in order to incorporate it in a consistent way. I see. Well, John, I don't know what subject we haven't touched on. This is a fascinating conversation. Thank you, man."
},
{
"end_time": 8945.538,
"index": 383,
"start_time": 8919.138,
"text": " No, this was fantastic. As you say, I'm really, you know, it's, it's, uh, it's been a long time coming, but I'm really glad we had this opportunity to chat. And, uh, and yeah, I really look forward to staying in touch. I've become, I have to confess when you first reached out, I hadn't heard of you, but in part because you reached out and in part for, because, you know, of the, of the explosion of your channel, I've been following a lot of what you've been doing subsequently. And I think, um, no, I think TOE is, is, is a really fantastic resource. And the,"
},
{
"end_time": 8976.032,
"index": 384,
"start_time": 8947.022,
"text": " Yeah, your particular niche is one that desperately needs to be filled, and I think you're doing a fantastic job of filling it. What would you say that niche is? And I ask just because it's always interesting for me to hear. Well, I have an idea as to what TOW is or what TOW is doing, what theories of everything the project is. It doesn't always correspond with what other people think of it. Right. So the reason I really like your channel and the reason I like witnessing these conversations and to some extent participating in them as well,"
},
{
"end_time": 8992.671,
"index": 385,
"start_time": 8976.596,
"text": " Is the following reason right you it feels to me like you got these two extremes out there right that there are these. Really quite vacuous kind of popular science popularization or philosophy popularization youtube channels and documentary series and things where you often have a host to you know."
},
{
"end_time": 9011.476,
"index": 386,
"start_time": 8992.671,
"text": " Goes very far to kind of play up the fact that they're ignorant of what's being discussed and they don't really have any strong opinions and it's just you know they just go and ask some brain boxes for what they think and then it gets assembled in some nice documentary package that's kind of one extreme. Then you have the other extreme of you know you take some."
},
{
"end_time": 9027.585,
"index": 387,
"start_time": 9011.971,
"text": " This is just some philosopher who's been working on their own pet theory for thirty years and they go make some you know some some long youtube video about it just advocating that and shouting down all the competition and being very kind of bigoted and dogmatic or whatever."
},
{
"end_time": 9056.988,
"index": 388,
"start_time": 9027.585,
"text": " What you are managing to do but you know because you are an extremely intelligent and well read person with your background in math and physics and who has been very wide interest outside of that you know more so than any other youtuber in youtube i've encountered actually makes an effort to really understand. You know the stuff that talking about the stuff that the guests are talking about that's even just in itself that would be incredibly valuable but then what i think what i think that allows you to do is."
},
{
"end_time": 9086.391,
"index": 389,
"start_time": 9057.602,
"text": " Do something to do something that's somehow a really nice synthesis of the best aspects of those two approaches, whilst avoiding them more unpleasant aspects, which is to be someone to be the kind of interested, educated, motivated interlocutor who is, you know, not completely inert, like in the, in the, in the kind of the sort of popular science documentary case, but also not, you know, dogmatically pushing and saying, ah, you know, you're completely wrong to be thinking about loop quantum gravity or something, but just saying,"
},
{
"end_time": 9095.026,
"index": 390,
"start_time": 9087.261,
"text": " Oh but how does this connect to that or is it possible you could rethink you could think of things in this in this you know being that kind of Socratic dialogue partner."
},
{
"end_time": 9125.009,
"index": 391,
"start_time": 9095.503,
"text": " In a way that I think you are almost uniquely placed because of your skill set and your, your personality to, to, you know, that's a role you're almost uniquely placed to play in that space. Um, I've never really seen that work in, uh, in any context outside of your channel. Um, and as I think that's something really quite special, man, that's the hugest compliment and I appreciate that. Thank you so much. I think you've captured. Well, I don't know if I'm the bigot in that, but I'll interpret that as me not being a bigot just to sleep at night. No, no, no, exactly. I mean,"
},
{
"end_time": 9146.886,
"index": 392,
"start_time": 9125.879,
"text": " I think you handle the balance really well as someone who clearly has ideas and has opinions and has views, as you have every right to as someone who's thought about this as much as anyone else. But you're not trying to shout down opposition, you're not trying to force some viewer down someone's throat. As far as I can tell, you are actually"
},
{
"end_time": 9167.022,
"index": 393,
"start_time": 9147.671,
"text": " You know in completely good faith just trying to explore with genuine intellectual curiosity the space of ideas and you know and present new perspectives and point in directions that people may not have previously thought of in a way that I think a lot of people say that they're trying to do. I very rarely seen anyone actually you know."
},
{
"end_time": 9195.623,
"index": 394,
"start_time": 9168.677,
"text": " And people might be able to simulate that for a while, but, you know, after a while that, you know, the, the, the mask kind of slips and you see, Oh, really? They're kind of pushing this viewpoint or whatever. And, you know, so part of that is that I don't have that incentive structure of having to produce and get citations in order for me to live. Because if I was, then I would have to specialize much earlier and I wouldn't be able to survey as much before I specialize. So currently I'm still in the surveying mode. Like again, it's before I go down and eat."
},
{
"end_time": 9220.657,
"index": 395,
"start_time": 9196.288,
"text": " So I'm lucky in that regard and I had man like, holy moly, super cool. So I have many questions from the audience, by the way. I mean, just, just informally on the following up on that. I mean, I think the, in many ways, I think the string theory landscape video is the, is the perfect embodiment of that, of that sort of side of you, right? That it's the fact that I don't know any other person really who could have done something like that, because it requires both"
},
{
"end_time": 9243.268,
"index": 396,
"start_time": 9221.288,
"text": " You come across quite critical of string theory, right? No string theorist would have made that video. But also no one whose paycheck depends on them investigating loop quantum gravity would have invested the time to understand string theory at the level that you had to understand it in order to make the video. And so it's like, I don't know who else would have filled that niche."
},
{
"end_time": 9272.142,
"index": 397,
"start_time": 9243.831,
"text": " Yeah, that was a fun project. I find it's just it's so terribly in vogue to say I dislike string theory, but then simultaneously to feel like you're voicing a controversial opinion. And I wanted to understand string theory before us. And I, by the way, I love string theory, right? I think it may be describing elements of reality correctly. And that may be why it has I misspoke, by the way, when I said in the video that it has no predictions, it had mathematical predictions, maybe still does."
},
{
"end_time": 9302.79,
"index": 398,
"start_time": 9272.841,
"text": " And this is something Richard Borchards emailed me because he said that's something I would correct in the video. It has mathematical predictions. It doesn't have physical ones. But anyhow, I think that's why it may prove so fruitful mathematically. And it also, I mean, like parts of it have physical predictions that are but they just happen to not strictly depend on the string theoretic interpretation. Right. So there are condensed matter predictions of ADS CFT that have been quite experimentally validated. Right. It's just that"
},
{
"end_time": 9326.869,
"index": 399,
"start_time": 9303.046,
"text": " Yes if he came from string theory but it doesn't strictly depend on the right exactly exactly. Okay so one of the questions from the audience is has john ever done psychedelics. Yes so i have tried psychedelics and actually i consider it. I don't want to come across as too much of a kind of drug pusher but i i i consider it's one of the most important things i've ever done."
},
{
"end_time": 9346.357,
"index": 400,
"start_time": 9327.415,
"text": " I don't do it regularly because i'm afraid of the effect that has on the brain and things like that so i had a list of things i wanted to try and i tried each of them once i'm very glad that i did and the main takeaway was the stuff we were talking about before about. You know this kind of this."
},
{
"end_time": 9371.749,
"index": 401,
"start_time": 9347.022,
"text": " The computation that a system is doing and as the computation of the observer is doing and you know the track so you know really what you've got is that you know you've got these two computations and you've got a third computation that is sort of the encoding function the thing that maps a concrete state of the system to an abstract state in the in the internal representation of the observer and really all three of those things are kind of free parameters. And you know i've been thinking about that kind of stuff"
},
{
"end_time": 9402.022,
"index": 402,
"start_time": 9372.193,
"text": " Not in those terms precisely, but in some form for a long time, you know, from when I was a teenager onwards, and kind of in this very kind of nerdy intellectual way, thinking about, oh, yes, you know, surely, my model of reality, if my model of reality changes even slightly, then you know, the interpretations of the perceptions and qualia that I experienced is going to be radically different. But it doesn't matter how much you intellectualize that idea. It's very, very different if you just like subjectively experience it, right. And that's in a sense,"
},
{
"end_time": 9429.599,
"index": 403,
"start_time": 9402.978,
"text": " Driving home the fact that if you make what is in the grand scheme of things, an absolutely trivial modification to your brain chemistry, your modes of decomposing and understanding the world completely just dissolve as happens with things like LSD. Um, actually experiencing that from a firsthand perspective is really, really important. It kind of convinced me. I don't want to, again, I don't want to seem too, okay."
},
{
"end_time": 9458.012,
"index": 404,
"start_time": 9430.213,
"text": " It would be too strong to say ultimately convinced me of the validity of that way of thinking about things, but it definitely is something that occurs to me when I when I'm kind of. When I'm worried that I'm overplaying this observer dependence of phenomena line, I kind of think, well, no, actually, if you if you modify even just very slightly neurotransmitter balances in the brain, the internal perception of reality changes, you know, it's kind of really, really radically. Yes. OK, well, here's"
},
{
"end_time": 9481.834,
"index": 405,
"start_time": 9458.507,
"text": " A physics question, what would happen if an object wider than a wormhole throat flies into the wormhole? Does the wormhole widen? Does the object cork the wormhole? Does it deform the object? If it deforms at how? What about if the object flies at an even faster speed? So 0.9 speed of light. Okay, interesting question. So I mean, wormholes"
},
{
"end_time": 9509.224,
"index": 406,
"start_time": 9482.432,
"text": " Obviously are not known to be physical. They are valid solutions to the Einstein equations. Einstein rows and bridges and extended Schwarzschild solutions are valid solutions, but the Einstein equations are incredibly permissive and they permit many, many more solutions than things that we believe to be physical. So if you just take the Einstein field equations on face value. So, okay, one thing to remember is that when an object is falling into the wormhole, it's not like it has to fit"
},
{
"end_time": 9533.097,
"index": 407,
"start_time": 9509.582,
"text": " Into the throat so to speak right the object is because if you imagine the topology of what's going on you've got you know you've got this two sheets sort of hyperboloid almost right and the wormhole throat that's connecting them but any object you throw in is localized to one of the sheets so it's it's traveling on that sheet and follows the world lines on that sheet it's not like it's kind of it's not like it's some plug that's trying to go through the throat in you know through the space in the middle."
},
{
"end_time": 9555.657,
"index": 408,
"start_time": 9533.677,
"text": " I'm so it may well be that the that the world lines coming this will happen to the title defamation to the object will will be kind of will be stretched in the in the radio direction compressed in the angular directions as it gets pulled in just do the gravitational tidal effects but the fact that it's that the object is quite a bit bigger than the wormhole throat doesn't matter me it's just it it's just."
},
{
"end_time": 9577.688,
"index": 409,
"start_time": 9556.425,
"text": " Would you kindly ask him how would he tie science and spirituality together?"
},
{
"end_time": 9602.807,
"index": 410,
"start_time": 9578.473,
"text": " I think one always has to be a bit careful with that, right? I mean, so I'm certainly not, in the sense that I don't want to take either of the two extreme positions of saying, oh, you know, science validates the existence of an immortal soul or something, which I don't believe. But nor do I want to say, oh, science invalidates whatever the, you know, the numinous dimension. I think it's, you know, they're largely agnostic to one another."
},
{
"end_time": 9632.244,
"index": 411,
"start_time": 9603.695,
"text": " I do think there are some things, okay, so actually it comes back to the stuff we were talking about at the beginning in a way about the kind of the language that we use and the models that we use for constructing reality, right? Do you actually believe that the universe is a computer? Do you actually believe that the solar system is made of clockwork or something? And again, the answer is no, right? My view is that these are just models we use based on the ambient technology of our time."
},
{
"end_time": 9662.585,
"index": 412,
"start_time": 9632.773,
"text": " I kind of have a similar feeling about a lot of theology and a lot of spirituality, right? That it's so if you go, if you go and read writings by people like, I know, John Duns Scotus or, you know, medieval scholastic theologians, the questions they're grappling with are really the same questions that I'm interested in, you know, so like, okay, for take a concrete example, right? So I realized I'm talking about religion here, not necessarily spirituality, tie it together. But so you could ask the question. So"
},
{
"end_time": 9688.507,
"index": 413,
"start_time": 9663.063,
"text": " Our universe is neither, it seems to be neither completely trivial, it's neither kind of maximally simple, nor is it kind of maximally complicated. So there's some regularity, but it's not completely logically trivial. It's not like every little particle follows its own set of laws, but it's also not like we can just reduce everything to one, as far as you can tell, we can just reduce everything to one logical tautology. So"
},
{
"end_time": 9718.029,
"index": 414,
"start_time": 9689.394,
"text": " As far as I can tell, the first people to really discuss that question in a systematic way, at least from European theology and philosophy, I'm more ignorant of other traditions, were the scholastic theologians, were people like Don Scotus who asked, you know, why did God create a world which is neither maximally simple nor maximally complex effectively? And Don Scotus' answer is a perfectly reasonable answer, right? Which is because God created the world that way because that world is the most interesting."
},
{
"end_time": 9734.104,
"index": 415,
"start_time": 9718.422,
"text": " And if we were to focus on if i want to formulate that question in modern terminology i would formulate in terms of complexity right i would say why why is the universe why is the algorithmic complexity of the universe neither zero nor infinity why is it some finite value."
},
{
"end_time": 9761.186,
"index": 416,
"start_time": 9734.445,
"text": " And the answer, as far as you can tell, is essentially because of because of information theory, because we learned from Shannon that the kind of the most interesting or the highest information density, you know, the most interesting signal is one that is neither completely noisy maximum information nor completely simple, but somewhere in the middle. So really, Don Scotus hits upon a really foundational idea in modern algorithmic information theory. He didn't formulate it in those terms because, you know,"
},
{
"end_time": 9775.299,
"index": 417,
"start_time": 9761.596,
"text": " You didn't know what complexity was no way of that ambient thinking technology didn't exist. So he formulated the answer in terms of the ambient thinking technology of the time which was god in the bible and all that kind of stuff."
},
{
"end_time": 9795.691,
"index": 418,
"start_time": 9775.811,
"text": " I don't want to be someone who sits here and says oh look at those people they were talking about you know god and whatever and when they so ignorant because i don't want people to look at you know yes i see what you're saying but i don't want people to look at my work in a thousand years and say oh look he thought the universe was a computer how silly he was right i don't think the universe is a computer i think it's a useful model just as they thought god was a useful model."
},
{
"end_time": 9819.172,
"index": 419,
"start_time": 9796.101,
"text": " And, um, which it was, and maybe to an extent still is. Uh, so that's kind of my general view about sort of theology and spirituality is that I think there, you know, there are some classes of questions where it's useful to think about things in terms of Turing machines or, you know, fiber bundles or whatever it is. And there are some classes of questions where it is useful to couch them in terms of the soul or, you know, an immortal spirit or God or whatever."
},
{
"end_time": 9846.903,
"index": 420,
"start_time": 9819.172,
"text": " And you can do those things without believing in the ontological reality of any of them as indeed i don't but that doesn't make them not useful. Now can you actually distinguish those two if you're a pragmatist cuz my understanding if you like william james the utility of it is tied to the truth of it. Yeah i mean that that's it's a tricky one that's something i okay. Being completely honest i don't know it's something i've gone back and forth on over the years right because in a way so yes you might say."
},
{
"end_time": 9854.189,
"index": 421,
"start_time": 9847.261,
"text": " Okay do i believe in god or do i believe in the soul in some ontological sense and the answer is no but."
},
{
"end_time": 9879.087,
"index": 422,
"start_time": 9854.957,
"text": " If that's your definition of exist or that's your definition of belief then i also don't believe in electrons right i don't believe in space time you know i think all of these things are just models right like do i think that you know space time is a useful mathematical abstraction but in a sense we know that you know in black holes or in the big bang or something that's probably an abstraction that uses use that loses usefulness and eventually will be superseded by something more foundational."
},
{
"end_time": 9904.616,
"index": 423,
"start_time": 9879.087,
"text": " So do i believe in space time in an ontological sense no do i believe in particles in an ontological sense no so interesting whereas you might say okay well therefore i have that means probably that my definition of the word exist is not very useful right i should i should loosen that definition a bit and be a bit more permissive so then you might take the william james view of okay well. You could say i believe in space i believe that space time exists in as much as."
},
{
"end_time": 9933.251,
"index": 424,
"start_time": 9905.094,
"text": " I think it's a useful model for a large class of natural phenomena. Again, it's a bit like the dinosaur thing we were talking about earlier. You could say, well, you know, I don't believe that space and doesn't exist in an ontological sense, but it's kind of consistent with a model of reality that does have good experimental validation or observational validation. But then if you, if that's your criterion, then I kind of have to admit that, okay, well, in that sense, maybe I do believe in a soul, right? Because there are, you know, so for instance, you know, I don't,"
},
{
"end_time": 9951.391,
"index": 425,
"start_time": 9935.52,
"text": " I don't believe that there's any hardline distinction between the computations that are going on inside the brain and the computations that are going on inside lumps of rock or something. And really the distinction is, it comes back to the point you were making earlier about"
},
{
"end_time": 9979.48,
"index": 426,
"start_time": 9951.869,
"text": " What laws of physics would a cat formulate? So in a sense, okay, yes, maybe they exist in the same objective reality, whatever that means. But whatever their internal model of the world is, it's going to be quite different from mine because cats have not just different brain structure, but they have a different kind of social order, their culture is different, et cetera. Just like my internal representation of the world would be different to different humans who was raised in a completely different environment with a different education system, et cetera."
},
{
"end_time": 10004.667,
"index": 427,
"start_time": 9979.48,
"text": " I'm into this it's not like some abrupt discontinuity there's a kind of smooth gradient of how culturally similar are these two objects are these two entities and how that for how much overlap is there in the internal representation of the world so you know that i have. More overlap with you that i do with a cat but i have more overlap with a cat i do with a rock and so on right but there's no there's no hard line distinction between any of those things at least in my view right."
},
{
"end_time": 10033.131,
"index": 428,
"start_time": 10005.128,
"text": " So in a way you could say, well, therefore I'm some kind of panpsychist or, you know, like I believe that there's, or I'm an animist, right? I believe that there's kind of mind or spirit and everything. And again, I think that's not a comp, you know, it's not personally how I choose to formulate it. I choose to formulate it in terms of computation theory, but it's not a completely ridiculous way of translating that view. And, you know, these kind of druidic animistic religions, you know, a lot of what they're saying, if interpreted in those terms is perfectly reasonable."
},
{
"end_time": 10060.93,
"index": 429,
"start_time": 10033.473,
"text": " Um, so, so, yeah, it's just a very verbose way of saying, no, I don't have any particularly good way of distinguishing between the two. And so in a sense, I have to choose either between being ultra pragmatist and basically saying, I don't believe in anything or being ultra permissive and saying, yeah, I basically believe in everything, which seem like equally useless filters. Well, another commonality between us is that the way that you characterized the scholastics, I believe, and their"
},
{
"end_time": 10089.565,
"index": 430,
"start_time": 10061.561,
"text": " Ideas of God and then being inspired and realizing that that's similar, not the same, of course, but similar to ideas of computation now, or at least how they were describing it. And that's one of the reasons why on this channel, I interviewed such a wide range of people. It's because I work extremely diligently to understand the theories and to be rigorous. But I also feel like much of the innovations will come from the fringes, but then be verified by the center."
},
{
"end_time": 10120.094,
"index": 431,
"start_time": 10090.282,
"text": " In other words, the fringes are more creative, but they're not as strict. The center is much more stringent, but then it has too fine of a sieve. Right, right. It's like those simulated annealing algorithms that you get in combinatorial optimization, where you're trying to find some local minimum of a function. So you set the parameter really high initially, so you're kind of exploring all over the place, but being very, very erratic. And then gradually, over time, you have to lower the temperature parameter."
},
{
"end_time": 10143.37,
"index": 432,
"start_time": 10120.486,
"text": " There's something in that about as a model of creativity that at the beginning you have to be kind of crazy and irrational and whatever and then gradually you have to drop that temperature and kind of become a bit more strict and precise and slowly start to nail things down. Now the Santa Fe Institute has an interesting, I don't know if it's a slogan, but it's the way that they operate, which is you have to be solitary and even loopy inane."
},
{
"end_time": 10158.66,
"index": 433,
"start_time": 10143.865,
"text": " And then go back to people to then be verified and actually have some wall to push against you because otherwise you're just floating in the air. Sorry, since I since I was to continue being complimentary to you and the channel. I mean, that's that's another thing which I think is"
},
{
"end_time": 10174.804,
"index": 434,
"start_time": 10158.968,
"text": " Is very rare which you do extremely well which is to actually take seriously. I think it's something which i think a lot of people say that they want to do or would like to think that they want to do but a lot of people seem to be i'm bad at this to write i tried but i think i fail where if you want if you."
},
{
"end_time": 10205.367,
"index": 435,
"start_time": 10176.015,
"text": " If you're presented with some really crazy, very speculative idea, and it's hard to kind of make head or tail of what the person is talking about, you know, for a lot of people, it's the kind of instinctive reaction to say is complete nonsense, like, don't waste my time. And, you know, certainly a lot of the mainstream physics community has that opinion and to an extent has to have that, you know, view, because if you, you know, one of the, one of the things you learn, if you start writing papers about fundamental physics is you get a huge amount of sort of unsolicited correspondence from people trying to tell you their theory of the universe, right?"
},
{
"end_time": 10228.148,
"index": 436,
"start_time": 10205.862,
"text": " I'm but you know it's always it's also important to be mindful of stories like the story of ramanujan right like writing to g. h. hardy and people you know who must have seen like an absolute not case actually was this kind of era defining genius and you know you have to be careful not to set the filter to strict and i think what we know one thing i think you do extremely well is is really to kind of."
},
{
"end_time": 10255.026,
"index": 437,
"start_time": 10229.326,
"text": " I think the, I think the expression in the post-wraps community is, you know, steel man. These, these kinds of arguments is to say, you know, if you're, if you're presented with some idea that seems on the surface, completely nuts, let's try and adopt the most charitable possible interpretation of what's happening. Like how might we be able to make this make sense? And yeah, it's something I try to do with ideas and physics and theology and other things, but I think you certainly do it far better than anyone else I've encountered. Is this related to why you follow the Pope on Twitter?"
},
{
"end_time": 10281.408,
"index": 438,
"start_time": 10256.852,
"text": " No, it's not. That is a completely yes. Okay, well, well spotted. Because so all right. The backstory to that is so that Twitter account was made when I was like 15 years old. And I didn't use it. I think I sent sort of two or three weird tweets as a teenager and then let it die. Okay, I didn't even realize it was still around."
},
{
"end_time": 10311.8,
"index": 439,
"start_time": 10281.886,
"text": " And then when the physics project got announced, which was really the first bit of serious media attention I ever received, right. And I was having interviews and magazines and other things. And I got a message from the director of public relations at Wolfram research saying, they found your Twitter account and it's got like some, you know, it's got 2000 followers. I can't remember what it was. People who started following this Twitter account was like, I don't have a Twitter account. And then I, and then I figured out, oh, they found this Twitter account that I made when I was 15 and, and never deleted and forgot existed. Now."
},
{
"end_time": 10340.657,
"index": 440,
"start_time": 10312.346,
"text": " when i was fifteen years old for some reason i thought it was funny so this is some betrayal of my sense of humor so i i i tweeted kind of weird nerdy math stuff and whatever and in my teenage sense of humor i thought it'd be funny if i only followed two people uh the pope and this person called fern britain who is a sort of daytime television star in in the uk and i i i don't know why i thought that was so humorous but i thought it"
},
{
"end_time": 10365.657,
"index": 441,
"start_time": 10341.084,
"text": " i thought it was entertaining and then i think fun britain left twitter or something and so so when i when i went back to this twitter account the only account i followed was the pope and then i thought okay well forget i'll just leave it and then i since then have followed a few other people but he's still there somehow okay so it's just a relic you can't bear to get rid of him like some people can't bear to delete some deceased person from their phone like it's for posterity what's the reason why do you still have it"
},
{
"end_time": 10396.271,
"index": 442,
"start_time": 10366.271,
"text": " Yeah, it's partly posterity. It's and it's partly because there is still a part of me that for whatever reason thinks it's kind of funny that I that I follow a bunch, basically a bunch of scientists and like, you know, science popularized Christopher Hitchens and then the Pope. Yeah. Yeah. And then the Pope. Yeah. OK. So speaking about other people's theories, this question is, does Jonathan see any connections between the really at Eric Weinstein's geometric unity and Chris Langan's CTMU, which is also known as the cognitive theoretic model of the universe?"
},
{
"end_time": 10425.009,
"index": 443,
"start_time": 10397.09,
"text": " So on a very surface level, I guess I see some connections, I have to confess. So I'm not, I don't know really anything about either geometric unity or CTMU. I've encountered both people have told me things about both. I've been able to find very little formal material about CTMU at all. And the little I know says, okay, yeah, it probably does have some similarity with, you know, this general thing we were talking about earlier of, you know, having a model of reality that places mind at the center."
},
{
"end_time": 10455.503,
"index": 444,
"start_time": 10425.674,
"text": " And that kind of takes seriously the role that the observers model of the universe plays in, you know, in constructing an internal representation. I think that's. That's certainly a commonality, but I'm kind of I'm nervous to comment beyond that, because I really don't understand it well enough with geometric unity. Yeah, I don't really know what I mean. Even if I were to understand it technically, which I don't, my issue would still be a kind of conceptual one, which is I think it's kind of insufficiently"
},
{
"end_time": 10478.695,
"index": 445,
"start_time": 10455.896,
"text": " Radical, right? I mean, it's like, it's really the idea is, you know, use, you know, use the existing methods from gauge theory to figure out, you know, if we have a Lorentzian manifold with, you know, with a chosen orientation and chosen spin structure, here is the kind of here is the kind of canonical gauge theory that we get, you know, defined over that structure."
},
{
"end_time": 10508.029,
"index": 446,
"start_time": 10479.343,
"text": " And the claim is that gauge theory unifies gravitation and the three other gauge forces. Like I say, I certainly wasn't convinced that that's formally true just by reading the paper, which even if it were true, I would find it a little bit disappointing if it turned out that the key thing that was needed for radical advance in physics just turned out to be a bigger gauge group. That would be a little bit anticlimactic."
},
{
"end_time": 10528.541,
"index": 447,
"start_time": 10509.104,
"text": " Now we've talked about the pros of computational models and you even rebutted, at least from your point of view, Penrose's refutation of computations. But this question is about what are the limitations or drawbacks for using computational models minus complexity and irreducibility? Like that's just a practical issue."
},
{
"end_time": 10554.36,
"index": 448,
"start_time": 10529.821,
"text": " Right so sure but even conceptually there may be issues right so i am i and again this is kind of what i mean when i say i'm not dogmatically trying to assert that the universe is a turing machine or something then maybe. Physical phenomena that are fundamentally non computable as you know penrose and other people believe you know it so it but i don't think we know that yet and certainly the parts of physics that we kind of know to be true we know are computable."
},
{
"end_time": 10582.176,
"index": 449,
"start_time": 10554.684,
"text": " And so computation is therefore, you know, again, going back to the pragmatist point, computation is therefore at least a very useful model for thinking about a lot of physics, whether it's useful for thinking about everything, who knows, probably not right. But yeah, I mean, there are open questions like so, for instance, it might be the case that so we know we have known since since Turing's first paper on on computable numbers, that most real numbers are non computable."
},
{
"end_time": 10605.247,
"index": 450,
"start_time": 10582.927,
"text": " Uh so if you have you know if the universe turned out to be fundamentally based on continuous mathematical structures and based on real numbers then uh you know at its foundational level it would be a non-computable structure um but then you still have this open question of well you still got this issue of the observer you could imagine the situation where you have a continuous universe that's based on non-computable mathematics"
},
{
"end_time": 10613.37,
"index": 451,
"start_time": 10605.503,
"text": " But all experiments that you can in principle perform within that universe would yield computable values of the observables."
},
{
"end_time": 10636.903,
"index": 452,
"start_time": 10614.292,
"text": " And in that case, and in fact, you know, again, there are papers by people like David Deutsch, who've, you know, argued similar things, right, that, you know, that, you know, within, for instance, within quantum mechanics, you have, you know, arbitrary complex numbers appearing in the amplitudes. And so, you know, most of those are going to be non-computable. But eventually you project those onto a discrete collection of eigenstates, and those are computable."
},
{
"end_time": 10654.206,
"index": 453,
"start_time": 10637.295,
"text": " So in the end it doesn't matter that it's the underlying model was based on computer mathematics because the part of it that you can actually interface with an observer still has computer outcomes. Which means that there is still going to be an effective model that's consistent with observation that is nevertheless computer."
},
{
"end_time": 10677.227,
"index": 454,
"start_time": 10654.514,
"text": " In a sense, I don't think we know that yet. I don't think we know whether it's even possible to set up, if the universe were non-computable, would it be possible to set up experiments that are effectively able to excavate or exploit that non-computability to do practical hypercomputation or something? Wait, sorry, is David Deutsch suggesting that quantum mechanics only has point spectrums and that there are no continuous spectrums?"
},
{
"end_time": 10707.432,
"index": 455,
"start_time": 10677.961,
"text": " I'm sorry. Let me let me not malign. Let me not malign. That's specifically in the context of, you know, quantum information theory and finite dimensional space is right. So, you know, even if you have only a finite eigen basis, so all your all your measurements are computable, you know, the eigenstates are discrete sets. But the amplitudes are still non-computable, right, in general. OK, I have a nettling point that I want to bring up that I hear mathematicians and physicists say, but I don't think it's quite true."
},
{
"end_time": 10731.749,
"index": 456,
"start_time": 10707.654,
"text": " So when they're talking about discrete models, they'll say discrete versus continuous, but it should technically be discrete versus continuum, because you can have two graphs which are discrete, and you can have continuous maps between them, because you just need the pre image to be open. And it's not a continuum, but it's continuous. Right. I hear that all the time. And I'm like, why does no one say that? But I just want to know, am I understanding something incorrectly?"
},
{
"end_time": 10759.309,
"index": 457,
"start_time": 10732.995,
"text": " No, I think you're not understanding something incorrectly. I think you're, you're, you're thinking about this more deeply than most mathematicians do, which is, which is perhaps a positive sign. I mean, so yes. Um, the distinction between what is discrete and what is continuum is actually not very well defined. Right. So, um, let me give you a concrete example. So, uh, and this is actually something that comes from a method of proof in logic called forcing, uh, it was developed by Paul Cohen. Right. Right. So, and one of the key"
},
{
"end_time": 10777.602,
"index": 458,
"start_time": 10759.633,
"text": " Ideas in forcing is this idea called a forcing P name, which I'm slightly technical idea, but basically what it allows you to do is to talk about the cardinality of a set from a different set theoretic universe from a different domain of discourse. The significance of that is so okay, what do we mean when we say that something is discrete?"
},
{
"end_time": 10805.811,
"index": 459,
"start_time": 10778.012,
"text": " Well, what we mean is that it can be bijected with the natural numbers, right? That it's countable. It consists of a countable collection of data. And when we say that something is continuous, I mean, modular considerations of the continuum hypothesis and something, basically what we mean is that it's uncountable, that you can't biject it with the natural numbers. But, you know, what is a bijection? Well, a bijection is a function. And what is a function? Well, set theoretically a function is just a set, right? It's a set of ordered pairs that map, you know, inputs to outputs."
},
{
"end_time": 10833.336,
"index": 460,
"start_time": 10806.442,
"text": " So if you have control over your set theoretic universe, you can control not just what sets you can build, but also what functions you could build. So you can have the situation where you have a set that is countable from one larger set theoretic universe in the sense that it's the function that bijects that set with the naturals exists in that universe. But if you restrict to a smaller one, that function can no longer be constructed. So internal to that set,"
},
{
"end_time": 10853.763,
"index": 461,
"start_time": 10833.592,
"text": " That you know the internal to that universe that set is no longer countable it's no longer it's effectively gone from being discrete to being continuous the set itself is the same it's just that you've made the function that bijected it with the naturals non-constructive yes if you like to an observer to a generalized mathematical observer internal to that universe it looks like it's continuous."
},
{
"end_time": 10873.882,
"index": 462,
"start_time": 10854.531,
"text": " And again, there are versions of this idea that occur throughout topos theory. PT Johnston, one of the pioneers of topos theory, did a lot of work on these topos theoretic models of the continuum, where you can have a very similar phenomenon, where you can have some mathematical structure that looks discrete."
},
{
"end_time": 10900.247,
"index": 463,
"start_time": 10873.882,
"text": " From a larger super topos but if you take some appropriate sub topos you exclude you make non-constructible the functions that essentially witness it as being discrete and so internal to that it becomes a continuous structure and so you can actually do things like locale theory and pointless topology in a manner that is fundamentally agnostic as to whether the spaces you're dealing with are actually discrete or continuous so"
},
{
"end_time": 10926.049,
"index": 464,
"start_time": 10900.486,
"text": " Yeah, even the question of whether something is discrete or continuous is in a sense observer dependent is dependent on, you know, what what what functions you can and cannot construct or compute within your particular model of mathematics. So what I was saying is that continuity and continuousness is the same to me. But what is continuous is not the same as a continuum for continuum. I would just say it's a spectrum with the real numbers, say,"
},
{
"end_time": 10949.462,
"index": 465,
"start_time": 10926.271,
"text": " But continuous is just a function has the property of that is continuous. That can be there even when there's discrete phenomenon. Yes, exactly. And in fact, you know, that I mean, that's related to the fact that a you know, you can have accountable space that's not discrete, right? I mean, so it's a discreteness in topology means that, you know, you that only the, you know, that has essentially the only the points themselves have, you know, represent open sets."
},
{
"end_time": 10977.91,
"index": 466,
"start_time": 10950.606,
"text": " Then it is so in a sense it's it's kind of the it's the I forget whether it's the courses for the finest possible topology one of the two it's the it's the dual to the box topology um but of the trivial topology um but you can have but you can perfectly well have countable topological spaces that are not discrete and you can have you know discrete topological spaces that are not countable so yeah somehow these yeah it's again it's this problem of uh sorry is this further complicated with uh lowenheim skull and theorem which"
},
{
"end_time": 11007.09,
"index": 467,
"start_time": 10978.131,
"text": " In one way says, if you have something that's countable, you have a model where it's uncountable and of every cardinality and vice versa. Right, right. Yes. It's certainly right. I mean, so the downward lo and heimskolen theorem is used in the, in the forcing construction that I mentioned earlier. I see. Okay. All of which, all of which is to illustrate exactly the point that I think you're making, which is the, so, you know, there's the notion of continuity of, you know, pre images of open sets are open that comes from analysis and topology. Um, but that's not the same as the notion of continuum in the sense of."
},
{
"end_time": 11025.964,
"index": 468,
"start_time": 11007.09,
"text": " I don't know what subject we haven't touched on."
},
{
"end_time": 11052.79,
"index": 469,
"start_time": 11026.817,
"text": " I'm glad you enjoyed this episode with Jonathan Gerrard. If you'd like more episodes that are similar to it, again, Wolfram was interviewed himself three times on Theories of Everything. It's on screen right now. I recommend you check it out."
},
{
"end_time": 11078.422,
"index": 470,
"start_time": 11052.978,
"text": " Also the string theory video that Jonathan mentions is called the iceberg of string theory and I recommend you check it out. It took approximately two months of writing, four months of editing with four editors, four rewrites, 14 shoots and there are seven layers. It's the most effort that's gone into any single theories of everything video. It's a rabbit hole of the math of string theory geared toward the graduate level. There's nothing else like it."
},
{
"end_time": 11093.285,
"index": 471,
"start_time": 11079.121,
"text": " Thank you for watching. Thank you for listening. There's now a website, curtjymungle.org, and that has a mailing list. The reason being that large platforms like YouTube, like Patreon, they can disable you for whatever reason, whenever they like."
},
{
"end_time": 11119.701,
"index": 472,
"start_time": 11093.507,
"text": " That's just part of the terms of service. Now, a direct mailing list ensures that I have an untrammeled communication with you. Plus, soon I'll be releasing a one-page PDF of my top 10 toes. It's not as Quentin Tarantino as it sounds like. Secondly, if you haven't subscribed or clicked that like button, now is the time to do so. Why? Because each subscribe, each like helps YouTube push this content to more people like yourself"
},
{
"end_time": 11138.217,
"index": 473,
"start_time": 11119.701,
"text": " Plus, it helps out Kurt directly, aka me. I also found out last year that external links count plenty toward the algorithm, which means that whenever you share on Twitter, say on Facebook or even on Reddit, etc., it shows YouTube, hey, people are talking about this content outside of YouTube, which in turn"
},
{
"end_time": 11166.459,
"index": 474,
"start_time": 11138.422,
"text": " Greatly aids the distribution on YouTube. Thirdly, there's a remarkably active Discord and subreddit for theories of everything where people explicate toes, they disagree respectfully about theories and build as a community our own toe. Links to both are in the description. Fourthly, you should know this podcast is on iTunes. It's on Spotify. It's on all of the audio platforms. All you have to do is type in theories of everything and you'll find it. Personally, I gained from rewatching lectures and podcasts."
},
{
"end_time": 11186.425,
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"text": " I also read in the comments"
},
{
"end_time": 11212.654,
"index": 476,
"start_time": 11186.425,
"text": " and donating with whatever you like. There's also PayPal. There's also crypto. There's also just joining on YouTube. Again, keep in mind it's support from the sponsors and you that allow me to work on toe full time. You also get early access to ad free episodes, whether it's audio or video. It's audio in the case of Patreon video in the case of YouTube. For instance, this episode that you're listening to right now was released a few days earlier. Every dollar helps far more than you think."
},
{
"end_time": 11216.459,
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"text": " Either way, your viewership is generosity enough. Thank you so much."
},
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"index": 478,
"start_time": 11229.667,
"text": " This holiday, discover meaningful gifts for everyone on your list at K. Not sure where to start? Our jewelry experts are here to help you find or create the perfect gift, in-store or online. Book your appointment today and unwrap love this season, only at K."
}
]
}No transcript available.