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Theories of Everything with Curt Jaimungal

Emily Adlam: The "All At Once" Universe Shatters Our View of Time

April 11, 2025 1:23:25 undefined

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[1:06] The dogma I worry about is that we should think about physics in terms of time evolution, this picture where you start at the beginning and evolve forwards in time. That's a very intuitive way of thinking about physics, but it is very clearly not a good fit for what we are seeing. There's really good evidence coming from lots of different parts of physics that we shouldn't be thinking about time in those terms.
[1:27] Imagine a completed Sudoku puzzle. The rules don't dictate that you start in one corner and then work systematically across the grid. Instead, they just constrain what patterns are valid for the entire puzzle. Professor Emily Adlam of Chapman University suggests that the fundamental laws of physics work similarly. You don't evolve the universe step by step from past to future. Instead, there are these constraints.
[1:49] something that selects valid patterns across all of space-time simultaneously. This quote-unquote all at once perspective helps explain paradoxical quantum phenomena like delayed choice experiments and Bell nonlocality. It also comports with Einstein's relativity where the distinction between past and future depends on the observer's reference frame. If correct, this paradigm shift would transform our understanding of causality of observers and of the nature of physical law itself.
[2:18] What's the largest unsolved problem in physics today that you're interested in?
[2:23] Well, this is not a very original answer, but I think the measurement problem of quantum mechanics for me still really stands out as an important unsolved problem. And not just because it's sort of intellectually interesting, but because it seems to me that it's closely linked to a variety of concrete problems that we're working on in modern physics. So in particular, I think in the context of work on quantum gravity, a lot of the issues we're really sort of struggling with are ultimately to do with the nature of observers, the nature of observation,
[2:51] So for example, solving the problem of time is all about trying to understand how to put the observers into their theories in the way that reproduces the kinds of observations we expect to see. And so that makes me think that perhaps there's an issue here where we never really came to grips with how to think about observers in the context of ordinary quantum mechanics. And that's really holding us back from making us progress on further physics. So I think that problem to me demands a solution, not just for intellectual curiosity, but also to be able to make real progress.
[3:22] What's the definition of observer? Is it the same as measuring device or what counts as a measurement?
[3:27] Well, that's exactly the problem. We don't know clearly how to define observers in concrete physical terms. We have, of course, an intuitive notion of what an observer is, and we know what we expect observers to see, but it's still very unclear how to properly model observers within quantum mechanics. All the interpretations of quantum mechanics say something different about how you should represent observers, and that has important knock-on effects for how you're going to think about observers in the context of further physics like quantum gravity.
[3:58] How does the problem of observers or defining what observers are have anything to do with quantum gravity? So, I mean, one of the big problems we encounter in the formulation of quantum gravity is known as the problem of time, which refers to the fact that if you impose a sort of canonical quantization on gravity, the result is that time evolution seems to vanish. You end up with this sort of strange timeless model. And so then one obvious problem you have is try to try to understand
[4:26] So why don't you tell us how you make sense of observers then?
[4:53] Unfortunately, I don't have a complete answer to this question. I think one thing that we can see clearly from both general relativity and quantum gravity
[5:04] is that making sense of observers is probably going to require understanding them in sort of relational terms, understanding observations as things that happen in some sense relative to observers rather than being things that are out there in the world by themselves. So that seems like an important insight, which I think is also relevant for standard quantum mechanics, but certainly it's an ongoing project to understand exactly how to make that work in a coherent way.
[5:31] We're going to get to the relational interpretation of quantum mechanics and your work with Carla Rovelli. But prior to that, I want to know what the heck is a Sudoku universe? Yes. So the Sudoku universe is a way of thinking about time and laws.
[5:46] in the context of modern physics. So there's this perhaps quite traditional way of thinking about physics where we imagine it as something like a computer as Ken Wharton puts it. So we think of an initial state being put in and then the universe just evolves the initial state forwards in time and produces the course of history. And that's, I think, the intuitively natural way to think about physics that many people still use.
[6:09] But there's I think really good evidence coming from lots of different parts of physics that we shouldn't be thinking about time in those terms. We should instead be thinking about the laws of Natia as applying all at once to the whole of history. So in that sense that they're like the rules of a game of Sudoku. The rules of Sudoku don't tell you to start at the left and then move towards the right. What they do is constrain the whole grid and tell you whether an entire solution is valid or invalid. So the thought is that the laws of Natia perhaps work like that.
[6:38] Is that the same as saying that there's some imposition of consistency?
[6:55] I don't know how to derive the actual laws that we observe from purely consistency conditions. It would be neat if that could be done, but it seems like there might be some constraints going beyond just consistency conditions to sort of impose the specific types of laws that we actually see. You had a 2018 paper called Spooky Action at a Temporal Distance, which is a great title by the way.
[7:19] You mentioned something becoming a dogma in physics. I'm quoting you a dogma and something like there's an assumption which is actively limiting progress in quantum foundation. So what is it? And those are strong words. So I'd like you to justify your usage of that language. Yes. So the dogma I was worrying about there was this idea that we should think about physics in terms of time evolution. This picture where you start at the beginning and evolve forwards in time.
[7:48] As I say that's a very intuitive way of thinking about physics but it is I think very clearly not a good fit for what we are seeing in modern physics and yet nonetheless many people I think are still drawn to try to think about things in those terms. So for example in quantum foundations it's very common to be quite focused on trying to give causal accounts of things to understand at
[8:11] Either in classical terms or to move to a sort of quantum notion of causation where you can tell the story about one thing causing another thing causing another thing and that I think is is not a good use of our efforts because there are clear indications that that's not really the structure that physics actually has and so trying to force it into a causal structure is not likely to be a good way of understanding it. In the philosophical literature, there's dispute as to what is causation. Do you have a personal account of causation?
[8:42] When I say personal, I mean one that you favor. Yes. So definitely the Council of Causation, I favor other ones, which suggests that causation needs to be understood as essentially as a macroscopic phenomenon. So causation, I think, clearly has something to do with thermodynamics and the thermodynamic arrow in terms of entropy. It's also, I think, clearly related to perspective, the perspective of macroscopic observers like us and what we can and can't achieve.
[9:09] It's related to interventions and telling a story about what observers like us can achieve by intervening on certain types of variables. So all of those things make it seem very macroscopic in nature, which means that for me it's incorrect to think of causation as being something that inheres in the microscopic world. Certainly there are, I think, important kinds of structure
[9:34] So I'd like to talk about non-locality as well, specifically temporal non-locality and in temporal is time and earlier you mentioned the problem of time and then here we're talking about the arrow of time or the thermodynamic arrow of time.
[9:59] It sounds to people who know some physics that, oh, there's a problem of time. Is that the problem of the arrow of time? Is the problem of time different than the arrow of time problem? And does the second law solve it? All of these get entwined in their minds. So why don't you distinguish those? What is the problem of time? What is the arrow of time and what it has to do with the second law? Yes. So the arrow of time usually refers to the fact that in the world, as we experience it, there are all these temporal asymmetries, you know,
[10:29] glasses break and don't usually recompose themselves, all of these kinds of obvious asymmetries that characterize our lives. And the problem of the arrow of time is that the underlying physics mostly seems to be time symmetric. So in that sense, it's not obvious where all of these asymmetries could come from. You seem to have to impose them by just deciding by fiat that the initial state of the universe is some special kind of state which can explain those asymmetries. But for many people, that's not super satisfying.
[10:59] The problem of time and quantum gravity is a distinct issue. It refers to the fact that within a specific technical formalism for quantizing gravity, when you perform that quantization, you find that time evolution ends up being what's called a gauge transformation, which means that it's not physically real. It's just kind of giving two different descriptions of the same thing. So it looks like time evolution in the ordinary sense is not present at all.
[11:25] So that leads to a problem of trying to understand, you know, where do our experiences come from? Why do we have the experiences that feel like they are temporal in nature? So they are separate problems, but I think it's very likely they are linked. I think certainly the story about why we have experiences which are temporal in nature
[11:44] Most have something to do with thermodynamics and the fact that we live in this very asymmetric regime. So there's still work to be done to flesh out the connections between these things, but certainly I think they're not completely independent. So some people explain the arrow of time with coarse graining. I think Stephen Wolfram does this and in coarse graining is
[12:07] Yes. So in that paper, this is sort of an exploratory paper.
[12:25] necessarily committed to the view that reductionism is false, but I'm interested in whether that is maybe one way to try to resolve some of the problems that we encounter in quantum field theory. So one of the problems is a sort of fine tuning issue where we find that in certain kinds of cases, it seems that the values of two distinct fundamental constants must be very carefully adjusted to fit each other in order to produce the observed value of the constant at a higher scale.
[12:54] and sort of the observation I was making here was that if you say things are the other way around, if you say that the higher level constant is fundamental and the smaller scale constants are in fact derived from it, that gives you a very natural explanation for why they're fine-tuned in this way because they are in fact fixed by the actual value of the higher level constant. So the thought there was just that perhaps changing our way of thinking such that
[13:21] some cases smaller scale things are explained by larger scale things rather than vice versa might be a way of understanding some of those phenomena. It was important to look at the renormalization transformations because renormalization is the transformation we use in quantum field theory to move between different scales and so the question I was looking at there was trying to understand
[13:44] Given the mathematical structure of the renormalization translations, is it possible to that things could be reversed in direction and that the higher scale things could define the lower scale things and not vice versa? We normally wouldn't think that's possible in sort of more ordinary physics because we think there's a sort of many to one mapping where many microscopic possibilities get mapped to one macroscopic possibility. So the macroscopic possibility can't determine what's going on in the microscopic scales.
[14:10] Even at fixed points?
[14:32] Because fixed points do involve scenarios where many solutions get mapped to one solution. But the thing about fixed points is that they can occur both at very small scales and at larger scales. So it's not obvious to me that invoking fixed points particularly favors one direction of explanation since they occur at both levels.
[14:52] Let me see if I can phrase this in the language for mathematicians and correct me if I'm incorrect. The renormalization group is a set of tools to determine how parameters change with different scales, whether it's energy scales or length scales or what have you. Now, it's less of a group in the algebraic sense and more a set of tools. But if it was to be something like a group, it would be a monoid because not every element is invertible.
[15:16] However, most of the elements are invertible and this would mean that you don't privilege some scales being more fundamental in the same way that in an affine group you don't have a privileged origin.
[15:28] That's right. Yeah. So we, I mean, we have various approximations we use to do renormalization and many of those are not invertible. But there are good reasons to think that the real underlying transformations should be invertible. And if that's the case, then outside of six points, you can go from small scales to large scales, or you can go from large scales to small scales. It's kind of the same from the point of view of the underlying math. And so there's no sort of obvious sense in which the physics is telling you the small things must explain the big things and not vice versa.
[15:59] Hmm. Let me see if I can make another analogy. So let's imagine there's a bird in the sky and you take a snapshot of that bird and then you say, okay, it's position is here and it's velocity is here. So or it's momentum. And then you could say, okay, where is it going to be? And then you can plan out it or you can predict its trajectory. And then you say, well, look, what we got here is an initial position and velocity. But why did you call this initial? Like you could actually from another point,
[16:29] make the trajectory go backward. And so you have the whole trajectory. So what is the initial point? Why is one point being privileged? Yeah, I mean, I think that's a great analogy, because I would say much the same about time, time evolution as well, that there is no particular reason to privilege one point. Certainly, the physics doesn't tell you you have to do that. And yeah, I think the same is true, at least for many applications of renormalization transformation, the physics doesn't seem to be telling you that
[16:59] The smallest, most fundamental scales must actually be privileged in that sense. So let's get to non-locality. There's a large hubbub about non-locality and Bell's theorem and also realism. Yeah. Well, what is non-locality? Yeah. So in the context of quantum mechanics, non-locality is the phenomenon that quantum mechanics exhibits correlations which seem to be too strong to be explained by any local model.
[17:28] Normally when we see correlations at a distance, we would expect to explain them by some common cause in the past. They both came from the same source or something like that. But Bell's theorem demonstrates that the types of correlations we see in quantum mechanics can't be explained that way. It seems as though there's some kind of direct influence between events happening at a distance that can't be explained in this sort of common cause way. Now, there's two different types of non-locality.
[17:56] Spatial and temporal. And you have many papers, many talks as well on temporal nonlocality. So please distinguish the two. Yeah, so perhaps the, I guess the traditional way of thinking about nonlocality in quantum mechanics is to imagine it as a spatial form of nonlocality. So that involves a situation in which
[18:17] Perhaps Alice performs a measurement in one location and as soon as she does that the wave function collapses everywhere in the world and that sort of conveys information across to Bob wherever he is and that has an impact on the results of his subsequent measurement. So that non-locality is spatial because the effect of what Alice does is just transferred to the whole global state everywhere at the same time.
[18:43] Whereas temporal nonlocality suggests that nonlocality doesn't necessarily have to be conveyed immediately in terms of the current state of the world, you can potentially think of nonlocality as kind of hopping across time as well. So Alice performs her measurement at some time and at some other place and at some later time, Bob performs a measurement and there's just a direct relationship. There's some kind of constraint requiring that Bob's outcome
[19:12] Does spatial nonlocality imply temporal or vice versa?
[19:29] Yes, so I think combining spatial non-locality with relativistic constraints makes it very compelling to think that there should be temporal non-locality. That's because if you take a frame of reference within a relativistic setting where you have a spatially non-local effect, something Ellis does influences something that happens over here, you're allowed within relativity to make a change of reference frame to get another equally valid reference frame.
[19:57] And in that reference frame, those events are not going to be at the same time anymore. The event, Bob's event over here is going to be either in the future or the past of Alice's observation. So it looks like by making that transformation, you have turned your spatial nonlocality into temporal nonlocality. So that in that sense, if you sort of, if you believe what relativity tells us about the close connections between space and time, it seems very hard to maintain that nonlocality is always spatial and never temporal.
[20:25] So then why is it that physicists, if I understood one of your papers correctly, why is it that physicists focus on the spatial nonlocality when if you're in the relativistic setting and both are on quote-unquote equal footing, a term I don't like for various reasons, I'll put a link to a video on why I don't like equal footing, but regardless, why is it that physicists tend to focus on the spatial nonlocality compared to the temporal one? Yeah, well I think one main reason for this is because quantum mechanics historically and
[20:55] still usually today is formulated as a time evolution theory. So the natural way to think about quantum mechanics in its standard formulation is to sort of formulate it in terms of global states which carry all the information forwards in time. So from that point of view if you're trying to model locality in that picture perhaps the sort of natural thing to do is have a global collapse of the wave function that takes place everywhere and so to have a spatial non-locality.
[21:25] If you are formulating quantum mechanics in a different way as a non-time evolution theory, then temporal nonlocality becomes much more sort of natural and compelling, but that's not the traditional way in which we have formulated quantum mechanics. Is the future influencing the past an example of temporal nonlocality?
[21:46] Yes, so it could be. It depends, I think, how you think about the way in which the future influences the past. If, for example, your model of the future influencing the past involves some kind of backwards evolving state that goes back and carries the information backwards in time, you might end up with a picture where there is a backwards influence but it is sort of locally mediated by a backwards
[22:11] Evolving states, on the other hand, if your model of the way in which the future influences the past is some kind of all at once style model where there's just a sort of global constraint relating these two things to each other. In that case, it is going to look much more like temporal nonlocality because there doesn't need to be a sort of literal state that goes back and carries the information.
[22:33] Right. In your work, as I was going through it, you differentiate between dynamical retro causality. So influences propagating backward in time, step by step. And then this all at once and this term all at once will come up over and over. And I believe it's an all at once temporal retro causality. But would it be called retro causality at that time? At that point, if it's all, I guess that's a pun. Would it be called retro causality if it's happening all at once? Yeah. Why is it retro causality?
[23:00] Yeah, well I use retro causality in this connection just to sort of
[23:07] In a loose way to relate what's going on here to sort of more traditional discussions of retro causality. I think strictly speaking, what's going on there is not retro causality because I think there's no cause causality in fundamental physics. So, you know, neither the forwards nor the backwards direction is truly causal. But, but certainly if you, if you try to look at this from a more macroscopic point of view and you sort of write down a causal model in which a person intervenes on something,
[23:34] So when you're thinking about all at once, are you also thinking about boundary conditions? So the ordinary way that physics is thought about is that you have your boundary conditions plus the laws and you then evolve forward. So please define what all at once is.
[24:01] Yes, so all at once refers to this sort of Sudoku universe style idea where the laws of nature apply to the whole of history all at once. So the one possible type of all at once model is a model in which you fix the initial and the final conditions and then you ask the laws to determine what happens in between.
[24:21] I mean, that's quite a common type of problem that we see even in fairly standard physics. But it's also not the only kind of possibility. When I talk about all at once or constraint based laws, I usually talk about the laws of native fixing, determining the whole history at once.
[24:39] So in that sense, often it will be the case that you can fix any state anywhere on the history and that will be sufficient to fix the rest. So it could be the initial state, could be the final state, could be one or more states in between. In that sense, in that kind of picture, no particular point of time has to be specially privileged. It's just the history as a whole which is selected by the laws. When speaking about these histories, it reminds me of the transaction interpretation. Have you done any work on the
[25:07] on the transaction interpretation or do you have any thoughts on it? I think the transactional interpretation is certainly interesting. I'm interested in these kinds of retro-causal models. I guess I would like to see more emphasis from the transactional interpretation on moving away from specific experimental situations to a more general picture where I can understand
[25:35] how the experimental situations and the observers in particular are supposed to arise from something more fundamental than that. In some cases, the transactional interpretation seems to me overly focused on a set up where we already have instruments and the observers are kind of already given.
[25:54] Tim Maudlin had a challenge to the transactional interpretation about how there's some contradiction in simple backward causal stories. What is Tim Maudlin's objection or challenge and what does the all at once model do to resolve it? Maudlin's concern was that if you imagine an experiment in which
[26:18] We take some sort of preliminary measurement in the middle of the experiment and then we use that to determine part of the final conditions, the final measurement we're going to make. That looks inconsistent with the most naive version of the transactional interpretation because the transactional interpretation is supposed to take the initial and final conditions and determine what happens in between, so you can make that become contradictory.
[26:42] So there are more sophisticated versions of the transactional interpretation which avoid this issue but I think all of them ultimately avoid this issue by moving away from the sort of naive story where there's a literal transaction taking place in some sort of temporal process and more towards an all-at-once style picture where the whole thing is kind of atemporal and has to be thought of as being determined
[27:07] We started this conversation with talking about the largest problem that irks you and it was the measurement problem and now we're talking about the all at once model. Did the measurement problem lead you to this all at once quantum framework or
[27:37] I think they are separate in that the indications that the all at once model is correct come partly from quantum mechanics but also from other parts of physics, from relativity and quantum gravity and so on.
[28:01] And I think just adopting an all at once style model does not by itself solve the measurement problem because the measurement problem is to a large extent about how to model observers. Just saying we're going to tell an all at once story doesn't answer the question of how to model observers. So I do think that it seems clear to me that the right solution to the measurement problem is going to be some all at once style solution, but there are a number of different possibilities within that. And so I think it's still for me open, which is the right way to do that.
[28:32] Do you find cubism or other observer centric interpretations to be unsatisfactory? I find them incoherent. My worry about them is that if you're really serious about your observer centricity, that is going to lead you inevitably to a picture in which every observer
[28:50] kind of has their own reality and they're not able to communicate with each other. That I think is incompatible with the practice of science. Science is a very social activity. The sort of objectivity of science rests on the fact that we have all these different scientists doing observations and then sharing them. So I don't think it's, it's reasonable to interpret quantum mechanics in any way, which ultimately says we can't actually communicate with different observers.
[29:15] I am however interested in sort of more moderate observer centric views which allow that observers play an important role or that perspectives in general play an important role but which nonetheless make provision for sort of connections between perspectives to happen. Such as relational quantum?
[29:33] Relational quantum mechanics in its standard formulation does have the problem that I've just described because it does imply that it is impossible in an absolute sense to ever know anything about what's going on in anyone else's perspective. But the work that I did with Carla Rovelli recently was about thinking about how could you alter relational quantum mechanics to overcome this issue and so we did suggest
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[32:04] How is it that you think about probabilities?
[32:24] There are different interpretations of probability. Forget about quantum mechanics. There are different interpretations of what a probability is. So in metaphysics and in science, how do you think about probability? Yeah, I think the interpretation of probability is a very hard problem. I think I'm not wholly satisfied with any of the approaches that we have available to us. The frequentist approaches are useful in many cases, but have pretty significant philosophical problems.
[32:54] for us accounting for certain kinds of edge cases. Subjective Bayesianism I think just just doesn't do justice to the fact that certain probabilities do seem to be out there in the world and not just in our minds. The sort of disposition list accounts are quite mysterious and also very hard to reconcile with all-at-one style physics. There are a couple of recent approaches that I'm very interested in. There's a view called nomic frequentism due to someone called John Roberts which suggests that
[33:24] probabilities should be understood as in terms of laws which require that frequencies should look a certain way and there's some really nice work on this recently by Eddie Chin and John Barrett looking at the ways in which you could potentially expand on that and think about probabilities as sort of constraints on relative frequencies. So while that work is still ongoing I think that's a really interesting direction and probably the most promising approach from my point of view.
[33:53] What do you mean? What does Eddie 10 saying that probability should look a certain way? What does that mean? So this is working within sort of all at once style constraint based view of laws. And the observation is that if you allow that laws are global constraints, which apply to the whole of history, then you can formulate a probabilistic law as saying something like the relative frequency of occurrences of some outcome across all
[34:18] all instances of this type of measurement across all of history must have some value or must fall in some range. So you can think of the laws or probabilities as directly constraining the relative frequencies that actually occur. So that's somewhat similar in spirit to the frequentist approaches but I think avoids some of the more serious problems for frequentism because it's not just saying that probabilities are whatever the frequencies should happen to be, it really is saying that
[34:45] Add the laws constrain the frequencies and require them to have certain values. So how does your approach compare with silly Goldstein's approach? Yes, so the approach that Eddie Chen and jelly Goldstein have worked on in terms of laws is I think a very similar in spirit to mine and indeed alien. I are working on a project sort of examining some of those similarities. But perhaps one one difference is that
[35:15] One difference is that they are inclined to think of those all at once constraints as a sort of fundamental primitive, whereas I perhaps prefer to think of them as being a form of modal structure in accordance with a sort of generally structurally realist approach to physics and to laws. But I don't think those views are necessarily incompatible with each other. They're more sort of a difference of emphasis. What's a modal structure? What does that mean?
[35:43] So modal is a word that philosophers use to refer to facts about what is possible and impossible. So modal structure
[35:54] Perhaps the most well known example of modal structure is causal structure. So that's one form that modal structure can take. Because I don't think causation is fundamental. I don't think that that can be the most general type of modal structure. But I do think the world has some other kind of structure, which is in some way similar to causal structure, but perhaps more general than that. And so that's where I would sort of expect those all at once constraints to live.
[36:23] Model structures, so model comes from philosophy. It's not a term you hear in theoretical physics. Now it is when you start to study the foundations of physics or the foundations of quantum mechanics, but I'm curious how philosophical tools such as modalism or analyzing determinism or realism has guided your research. Yes, I think there's a sort of useful back and forth to be had here. I think that modern theoretical physics has
[36:51] important lessons for a variety of traditional philosophical discussions. This discussion about lawhood is a great example. Both me and Eddie and Shelley are inspired by noting that traditional philosophical accounts of lawhood don't seem to do a very good job of accommodating the kinds of laws we see in modern physics.
[37:11] I think there's a useful sort of flow of information backwards as well, because using these philosophical tools and doing the work to analyze, okay, so what are laws now? How can we understand the types of laws we're seeing in modern physics? That's a useful way of clarifying our thought about what's going on in theoretical physics.
[37:30] at understanding what are useful directions for future research and sort of understanding how we can connect those developments back up to the kinds of things we're concerned with in philosophy and in everyday life.
[37:45] Do you encounter the attitude from physicists that, hey, physics, experimental physics, theoretical physics, it doesn't need anything from philosophy. Philosophy hasn't contributed anything to science in the past 100 years, other than maybe Popper. And before that, it was a while and you can't just count Aristotle. That was thousands of years ago. So do you encounter that attitude?
[38:06] I think there's a wide spectrum of attitudes within physics. I mean, I certainly have encountered people with that attitude, but I've also encountered many physicists who love philosophy and are very interested in it and are very keen to talk to philosophers. So while their attitude does exist, I think it's also plenty of goodwill and interest in both communities to talk to each other and make progress. What would be the counterpoint to someone who's saying that philosophy hasn't contributed directly to physics in the past?
[38:36] The most obvious example I would say is Bell's theorem in the discussion around nonlocality.
[38:45] Bell's theorem was very much regarded as not mainstream physics when it was formulated, and Bell was a physicist, but other people involved in the discussion of non-locality and pushing this forward, like Schimone, were not physicists, they were primarily philosophers, and certainly I think this topic probably got more of a foothold within philosophy before it moved back into mainstream physics.
[39:08] But now it's certainly recognized as mainstream physics, you know, the Nobel Prize was awarded for it recently. So I think that's an example of a case where topics that were considered sort of foundational and conceptual were worked on within philosophy for a while, but ultimately became recognized as part of mainstream physics. So what got you interested in philosophy? Did you start in physics or did you start in philosophy?
[39:35] My undergrad was in both physics and philosophy. I've always been very interested in physics and in science, but my questions have always been more on the side of what is considered to be
[39:51] foundational physics or philosophy of physics. I think it was a toss up for a long time, whether I was going to be a physicist working on the foundations of physics or a philosopher. My PhD is actually in physics, not philosophy. But in the end, I think perhaps the kind of work I want to do feels like it lives more happily within philosophy. So that's why I ended up here. And what does foundations mean? So when someone says they study the foundations of something,
[40:19] Yes, so I mean generally that means something to do with interested in the sort of more basic conceptual questions and looking at the sort of underlying structures and perhaps understanding why the theory is the way it is or understanding sort of basic principles of the theory. Sort of a contrast to you know more applied approaches so if you study the foundations of quantum mechanics you're not
[40:43] I'm going to be primarily working on how to build new quantum technologies. You're going to be thinking about the structure of the theory and what it all means. And perhaps those results will eventually go on to be useful in quantum technologies. They often do, but if you're working in foundations, that's not your sort of primary focus. So what I enjoy about your work is that much like Jacob Barndes, you emphasize clarity of concepts and principles as a guide to progress.
[41:11] You actually co-authored a paper last year, if I'm not mistaken, with Sabine Hassenfelder and Tim Palmer, both of whom have been on the podcast before. So I'll put a link to that on screen and in the description. The paper is called something like a taxonomy of physics for quantum theory or beyond quantum theory. It's something that everyone should read if they're interested in physics. And if you follow this podcast, you can follow that paper. So there are different concepts that are explained there with precision.
[41:40] I've heard beables, local beables be described as ontological entities. And I believe you said it's something like the input value on a C model that's assigned to a compact region of space time. And you explained what a C model is. I think it's a calculation model, if I'm not mistaken. So anyhow, what led you to write that paper? Yeah, this paper arose out of a conference on retro causality and super determinism. Retro causality and super determinism are two approaches that people have often
[42:09] try to use in order to avoid the conclusion that quantum mechanics might be non-local. So this conference was kind of discussing those possibilities and can you get rid of non-locality using one of these methods. I think what we discovered is that there were a variety of different ways in which people were using the words retrocausality and super determinism and there was a sort of a problem where people were talking past each other because they were just using these words in different ways. So the goal of this paper was to sort of provide a clarifying story which would help explain
[42:39] What's going on with these terms and perhaps can we have a sort of community-wide consensus about how to use these words so we can have discussions more clearly? When people hear temporal non-locality, how is that different than time travel? Yes, so time travel is much like retro.
[43:02] Causality could be temporarily local or temporarily non-local. If your vision of time travel involves people literally moving backwards in time.
[43:12] Does any of this have to do with free will?
[43:43] Certainly if you look at the all at once style of model that does seem like it has some implications for free will because some people have thought that something that's important to free will is the idea that the future is genuinely open that in this moment as I am acting there is no fact of the matter about what my action is going to be
[44:10] And it's in an all at once style model, that way of thinking about free will is not available to you. The whole of the universe exists at once. I'm acting now, but there is already some fact from the atemporal point of view about what my action is going to be. So I don't think that means we have to say there is no such thing as free will in that context, but certainly we're going to have to be a bit more careful about how we analyze free will and what that means. Hmm.
[44:37] So, this doesn't depend on determinism, it's just saying that there's something that's globally fixed? Yeah, so even if you have a probabilistic model in the all at once context, what that's going to look like is either it's going to be some kind of frequency constraint, as Eddie Chen has suggested, or perhaps it's going to be, you know,
[44:58] I remember
[45:21] Oh, gosh, I forgot who it was. Someone was saying it could be the Calvinists. Maybe it was a religion or maybe it was an actual philosopher was saying that if you have trajectories in space time, just because they exist and you can view it from a God's eye point of view, a temporally, it doesn't mean that those trajectories cause the movement. Those trajectories are the movement. Sorry, are the are the trajectory. So an agent can still be causal. There's nothing about the trajectories.
[45:49] Causing, like the laws don't cause. So can you please distinguish between the determination of an agent and causal origination of an agent? Yeah, I mean, so because I think that causation is not fundamental in any case, I think that understanding how the history comes about is not going to involve any kind of causal story. That's going to be
[46:15] and some some more general kind of modal constraint perhaps that selects the history i mean causation is something that appears in a much higher level of description and probably is only going to be relevant in the kinds of regimes where you have agents taking actions so i think it's perfectly possible to say to say you know
[46:33] In some sort of fundamental sense, the history was already there and was selected in an all at once way. But nonetheless, the agent is the cause of their action because causation is only suitable in that kind of regime of description anyway. And so it is still true insofar as there is such a thing as causation. It's still true that the agent is causing their actions. Right. What do you disagree most with, Carla Raveleon? I disagree most with.
[47:01] I think we still have an ongoing debate about whether it's necessary to change relational quantum mechanics in the way that we suggested. So we proposed a postulate that you can add to the theory which makes it possible for observers to communicate with each other in an absolute sense and for their perspectives to become aligned in an absolute sense.
[47:21] I think that doesn't solve the kinds of epistemic worries I have about the role of social inquiry in science, so I think the absolute story is necessary, but this is an ongoing debate.
[47:49] Now many derivations in physics rely on integration by parts and then they have this argument that and the boundary terms are zero and because of that we get so-and-so. Are there times when these surface terms are ordinarily said to vanish but because of your work on all at once you believe that to be an unreasonable assumption? Oh gosh, that's an interesting question. I actually have not thought about that. Seems very possible but I would have to think more about the technical details before I could say one way or another.
[48:18] What is self-location? So self-location refers to scenarios in which you are uncertain about your location within the universe. So you might be uncertain where you are or when you are, or if you're in a multiverse, you might be uncertain about which universe within the multiverse you are currently located in. So it's those kinds of questions pertaining to a location within a universe. And there's something between pure and superficial, if I'm not mistaken.
[48:48] What are those? When we talk about self-locating uncertainty in philosophy or in physics, I think there are two importantly different classes of self-locating uncertainty that we should distinguish between.
[49:03] So what I call pure self-locating uncertainty refers to cases where you are uncertain about what location you are out of a possible class of locations which are all located within the same world. So for example, Adam Elger's case falls into that that
[49:21] That's a case in which Dr. Evil or a person who believes himself to be Dr. Evil receives a credible message telling him that a subject of the identical duplicate has been made of Dr. Evil and placed somewhere. So in that case, he's now uncertain whether he is in fact the real Dr. Evil or the duplicate, but most of those people exist within one in the same world. So that is pure self locating uncertainty.
[49:44] By contrast, superficially suffocating uncertainty refers to the case where you're uncertain about your location, but the possible locations you could be in belong to different possible worlds. So for example, suppose you wake up and you haven't looked at the clock yet, so you don't know what time it is, you're uncertain about your location and time. But of course, in every possible world, there's exactly one time at which you actually wake up.
[50:07] Is this related to the sleeping beauty paradox?
[50:22] Yes, so the sleeping beauty paradox in fact involves a mixture of pure and superficially self-locating uncertainty. So I think the correct way to analyze that is to appeal to your scientific theory to determine the superficially self-locating credences and then to assign the pure credences any way you want. So the outcome is that the correct solution is the double half a solution.
[50:48] The Sleeping Beauty Paradox refers to a scenario in which
[51:00] I'm
[51:23] What credences should you assign to the outcome of the coin toss? Should you assign and do the credences change if you're woken up and then told what day it is?
[51:41] various different approaches have been taken to try to decide what the correct assignation of probabilities is. Most philosophers, I think, are of the view that when you learn something about what day it is, you ought to change your credences. My view is that
[52:01] because the coin flip issue is a superficially self-locating issue whereas the issues about when you are located are pure, the outcome is that the further information shouldn't actually change any of your assignations of credences because the right way to assign credences in these situations is always to assign the superficial self-location credences first and then having done that
[52:26] Now was there something about when you when they say you get woken up twice that after you get woken up once you take something to forget that you woke up once? Yes, you are not going to know that you've woken up at once or twice. Now what does any of this have to do with physical law?
[52:57] Yeah, so self-location is important to physical law, particularly in the context of physical theories that deal with multiverses.
[53:07] So in particular, the cosmological multiverse and the many worlds interpretation of quantum mechanics has a multiverse. And in both of these multiverses, in order to make certain kinds of predictions, it's necessary that you assign some credences over locations within the multiverse. You have to assign probabilities to which universe you might be within this multiverse. And so all of those approaches to making predictions in a multiverse
[53:34] a kind of predicated on the assumption that there is in fact some objectively right or uniquely correct way to assign your self-locating credences over parts of the multiverse. And so therefore they are necessarily predicated on the claim that there are unique ways to assign pure self-locating credences. There's a right way to do it and there's a wrong way to do it.
[53:55] So I think that's wrong. I think that for superficially self-location credences, there are right ways to assign them because those credences can just be inherited from a scientific theory. But in the pure case, there is nothing whatsoever which could compel you or constrain you to assign your credences in any particular way. So any assignation of credences is fine. And therefore, you're not going to be able to get meaningful predictions out of any theory which involves this kind of multiverse reasoning.
[54:21] So if I'm right about that, that's a serious problem both for the cosmological multiverse and for the many worlds interpretation of quantum mechanics because it seems to say that we can't make meaningful predictions in that context and we therefore can't obtain any sensible evidence for scientific theories in that context because there's nothing to sort of predict and then see if it comes true.
[54:42] I'm sure you've spoken to Sean Carroll about this. So have you and what has he said or what do you think he would say? I have not spoken to Sean Carroll about this. I know that Carroll has a view of the multiverse which
[55:03] The Everettian Multiverse in particular, which is based on the idea that certain constraints on self-locating credences can help tell you how to assign probabilities in the Everettian case. I do think this view says that approach is wrong. There are no rational constraints on self-locating credences in the Everettian scenario and so any model which takes that as a starting point I think cannot be right.
[55:33] I believe in 1907, if I'm not mistaken, Einstein had his happiest thought about free fall and weightlessness. Have you had a happiest thought? I think one moment I'd pick out is,
[55:58] There's a theorem in quantum foundations called the PBR theorem. The PBR theorem is about the reality of the quantum state. It attempts to prove that if in order to reproduce all of the predictions of quantum mechanics it must be the case that the quantum state is a real object of thing which travels through time conveying information from one time to another and I think
[56:22] Thinking about this theorem, one thing that struck me was that the whole theorem was predicated on the assumption of what I would call temporal locality. It's predicated on the assumption that if a measurement result depends on earlier preparation, there must be something which travels between them carrying that information from one point to another. So that I think was the origin of most of my work on temporal non-locality was that the observation that there's this
[56:49] Do you have any thoughts about eternalism versus presentism and can you please briefly define those terms?
[57:03] Yeah, so presentism is a philosophical view which says that in some sense only the present is real, the past and the future are not currently real. Eternalism says that the whole of history is real at once, there's no sort of privileged present moment, it's all there. As you might expect, given my views on all at once physics, I'm definitely more
[57:30] More on the eternalist side, I think it's very hard to make presentism work in a way that is compatible with with relativity because, you know, relativity denies that there exists a global present. So it's kind of unclear what the present even is in that picture. And people have have, you know,
[57:47] made attempts to sort of reformulate presentism in relativistic ways. But you know, I think all of them feel a bit ad hoc and not very compelling to me. So certainly, in the context of what we know about physics now, eternalism seems to me much more viable.
[58:04] Hi everyone, hope you're enjoying today's episode. If you're hungry for deeper dives into physics, AI, consciousness, philosophy, along with my personal reflections, you'll find it all on my sub stack. Subscribers get first access to new episodes, new posts as well, behind the scenes insights, and the chance to be a part of a thriving community of like-minded pilgrimers.
[58:25] By joining you'll directly be supporting my work and helping keep these conversations at the cutting edge so click the link on screen here hit subscribe and let's keep pushing the boundaries of knowledge together thank you and enjoy the show just so you know if you're listening it's c u r t j a i m u n g a l dot org kurt jaimungal dot org we talked about cubism transactional many worlds
[58:50] What other interpretation of quantum mechanics have we not talked about that you feel fails significantly? And why does it fail? Well, the obvious ones are the sort of primitive ontology approaches, so that the Bohmian approach and the spontaneous collapse approach. You know, I wouldn't say these approaches fail. What I'd say is that at present, we don't know how to reproduce the whole of quantum field theory in these kinds of approaches.
[59:19] And there are reasons to think we may never be able to do that, or that it's very difficult to do that in the context of this particular kind of view. So never say never, but right now I'm not sure the prospects for expanding those to cover all of quantum theory look very good. And until we can show that that can be done, that's a sort of compelling reason to be worried about those approaches.
[59:45] 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?
[59:57] 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. Rankings based on root metric true score report dated 1-H-2025. Your results may vary. Must provide a post-patients room mobile bill dated within the past 45 days. Bill must be in the same name as the person who made the deal. Additional terms apply. So what's on your mind these days research wise? Research wise, so I have been thinking about
[60:25] One thing I've been thinking about is a problem in relational quantum mechanics. So there's this worry, relational quantum mechanics is committed to the view that all physical systems can in some sense count as observers, they can have quantum states defined relative to them. There's a worry brought up by Kasselab-Brookner that
[60:45] It doesn't make sense to say something like a qubit is an observer because there's no way to get a well-defined basis in which a qubit could make an observation, so you just couldn't get a well-defined
[60:57] observed value out of interaction involving a qubit. So I think he's right about that as an objection. I think the way to resolve this is to appreciate that the description of the world relative to a qubit is not going to be a full quantum hill of its face. It's not going to be as complicated as that because a qubit just doesn't have the right enough physical resources to define that kind of relative description.
[61:21] So I've been trying to think about what would be a sensible way of formulating what the world does look like relative to a qubit and thus of sort of understanding what the range of observations that something like a qubit could make might look like. Do you then generalize a quantum system to a process matrix? Why don't you define what a process matrix is? Great, yes. So process matrices are a tool developed within quantum foundations recently to study
[61:50] Causal processes more general than those we would encounter in our ordinary space time. So the idea here is that we'll start with a set of laboratories in which agents can do various actions and we'll write down a description of the way in which these laboratories are related to each other.
[62:06] But we will not require that these laboratories have any sort of specific space time location. And so we won't require that their relationships are constrained by the causal structure of ordinary space time. The only constraint we'll put on them is that it has to be logically consistent. So they have to be related to each other in ways that won't produce logical contradictions. So what we can do then is end up with a description of a class of possible causal processes, which is much more general than what we would normally encounter in the world.
[62:35] And that is potentially going to give us an idea of what kinds of processes might perhaps be possible, for example, in certain regimes of quantum gravity where space time in the ordinary sense, it breaks down or is perhaps not present. The process matrix is another way of formulating or thinking about quantum mechanics or or what or thinking about the wave function or density matrices.
[62:56] Yes, so I mean process matrices are quantum innate here but they are much more general than ordinary quantum mechanics because in ordinary quantum mechanics we would tell a story in which you start with a state and just evolve forwards and produce everything in a well-defined temporal order.
[63:11] Do you derive the Born Rule or do you have to assume it? Do you have to postulate it somehow? In the process matrix formalism,
[63:41] It's not clear that the born rule is even used. I think certainly understanding where the born rule fits into that picture is an ongoing project that hasn't yet been fully resolved. But with that said, you can also formulate an equivalent of
[64:01] What's Humean supervenience and what is its relation to asymmetric dependence?
[64:30] Human supervenience is the idea that the world is just a distribution of categorical properties over space-time. It's just, you know, one thing and another thing and another thing. There's no deeper structural connections. And so everything else, including things like the laws of nature and the facts about causation, have to, in some sense, depend on or supervene on
[64:54] In your model, what's at the ground? What do you take as your ontological commitments?
[65:22] That way I formulate that in the past is, you know, we start from some space of possible courses of history, you know, which might be an ensemble of, you know, human mosaics composed of distributions of facts across space-time. And then we have constraints which determine possible, determine which elements of that set are allowed by the laws of nature. And then
[65:50] some element of that set is going to be selected and made actual. So we have a sort of space of possibilities, the constraints narrow down the possibilities and then one constraint is somehow selected. I think there's more work to be done here on understanding what the space of possibilities look like and how that space of possibilities is related to the constraints and to the properties that we see in our everyday lives, but that's the general picture that you have possibilities narrowed down and then one is going to be selected.
[66:20] So space time would emerge from possibilities plus constraints? Yeah, I think the story that we should tell about space time here is certainly still a work in progress. You know, in my previous work on the subject, I've just kind of taken space time as given and imagined, you know, let's select the constraints are just going to tell you how things are distributed across space time. But certainly that, I think, can't be the right final answer because, you know, modern physics and particularly quantum gravity
[66:49] What would it be that selects the specific dimensionality and signature, like 3 plus 1?
[67:15] Yes, that's a great question. Ultimately, I think at least some aspects of the way space-time is have got to come from consistency constraints. So, for example, using the process matrix formalism, for example, you can see that there's going to be a need, if you want to have consistency, there's usually going to be a need for things to occur in some well-defined order.
[67:36] add a well-defined order stops that stops processes from looping back on themselves and producing contradictions and so i think from those kinds of consistency constraints you can get already the idea that there's got to be some kind of something like a temporal dimension which is different from the spatial dimensions and i also think you can get
[67:56] the idea that it needs to have a sort of a relativistic space-time structure from the observation that if you have superluminal signaling, for example, you can use that to create a loop which goes around and which could then also be used to create logical contradictions. So consistency is also going to give you something like the light cone structure of space-time. Interesting. I don't know yet how to get exactly three dimensions out of that.
[68:21] It would be great if there are a way to get that as a consistency condition as well. I'm not sure what that would look like, but, you know, I certainly I think many aspects of space time structure can can be understood in that sort of basic way as consistency conditions. Do you imagine that you'll be able to derive any of the fundamental constants from global laws, or is there still like, let's say alpha or G or is there still going to be some residual contingency leaving room for why these structures?
[68:51] Yeah, that's a great question. So ADHN has written before about this idea called strong determinism, which is the idea that maybe the laws of nature are so strong that they actually dictate the whole course of history uniquely and there's only one possibility. That's in some ways an old idea. Leibniz hoped for something like that as well. It doesn't seem obvious to me how to get there from the laws that we currently know.
[69:18] And I'm skeptical that we could possibly know all of the constraints, even if there do exist a set of constraints that strong. But in principle, I think that it's certainly possible that there are constraint-based laws that we perhaps haven't arrived at yet and might be able to arrive at one day, which would give an explanation of some of those things. Do you imagine there would be specific correlations between seemingly unrelated physical parameters?
[69:48] Certainly it's very, very possible. I mean, it's a bit hard to speculate because we don't have much of a sense of what that would look like. But certainly if we could give explanations for relationships between the values of things, that would be a very, I think, compelling piece of evidence that this right way of thinking is right. So it's certainly something to look for.
[70:09] Are you more interested in the philosophy of physics specifically or more broadly into the philosophy of science? What about metaphysics? What about ethics? Yes, I do focus largely on the philosophy of physics because my training is in physics. But I think many of the questions we are talking about in the philosophy of physics have really interesting implications for more general questions in the philosophy of science.
[70:35] So these questions about the nature of lawhood, for example, and I think once you move to an all at once style account of laws, that's going to have implications for a lot of other traditional philosophical questions about things like causation, explanation, determinism and so on, free will.
[70:53] So although my focus comes from physics, a lot of that expands more generally into philosophy of science and also metaphysics because these questions about lawhood, causation, explanation do also link to metaphysics. Ethics, I'm very interested in ethics. I've never worked on it professionally though. Cool. Do you have any advice for young upcoming researchers in the field of physics and philosophy?
[71:20] I think my biggest piece of advice would be to work on the things that you love and are interested in. I think there can be a pressure to work on something that is currently one of the hot topics or that is getting lots of attention in the field at the time. But ultimately, I think what's most rewarding and what will be successful in the long run is for you to pursue the things that you care about and
[71:43] What's some topic that's underappreciated that you think should be more appreciated? So I'll give you an example of something that's a hot topic right now, black holes.
[72:09] Supermassive black holes and time travel or time dilation, etc. And those are said ad nauseum in these popular science circles. So what's something else that you think people should be paying more attention to?
[72:21] I'm on a bit of a crusade to get people to pay more attention to the epistemology of the measurement problem. I think when we talk about the measurement problem it often gets framed in terms of ontology, in terms of we need to know what is really there and what is really happening. Whereas for me I think the measurement problem is really important precisely because it ties to questions about how could we possibly know the things we are supposed to know, how can we make sense of
[72:49] the empirical confirmation associated with quantum mechanics. And I think that a number of very popular interpretations of quantum mechanics have really big problems answering those kinds of questions. So particularly the many worlds interpretation and the observer relative interpretations have really bad epistemic problems and I think do not do a good job of answering these epistemic issues. So I really like to see our discussions of the measurement problem focus more on these questions of
[73:15] Can you repeat these epistemological questions that you think people or physicists or foundational physicists should be thinking about? Yeah, I mean the fundamental question is that when we're thinking about
[73:40] how to interpret quantum mechanics it is I think essential that our interpretation tells a consistent story about how we could have come to know about the theory. So for example I think the many worlds interpretation has a real problem with this because the many worlds interpretation has difficulty giving meaning to assignations of probability to measurement outcomes
[74:03] And in particular, it seems hard in the many worlds context to justify the claim that you should expect to see high probability outcomes. But if you can't expect to see high probability outcomes, then you can't use the outcomes you have observed as evidence for the theory because you have no idea whether the outcome is one that's assigned a high or a low probability by the theory. So you can't like connect it back up to the structure of the theory you're trying to find out about.
[74:27] What's a lesson, Emily, that you wish you had learned earlier, that if you could tell your younger self, it would be beneficial?
[75:03] i think probably as many people would tell their younger selves i would i would counsel patients that you know it takes this kind of thing research definitely takes time and work and
[75:15] You will fail many times and many things will not go anywhere. And I think you need to, you have to be persistent and hang on and have faith that, you know, in the long run, I think you're going to come to interesting results and people will eventually come to be interested in what you're doing. And it does come eventually. It just takes time. It doesn't happen immediately.
[75:37] So was there a time maybe a year, three years, four years where people weren't interested in your work and that frustrated you or made you downcast? I think for some time I was worried that the kind of work I was doing was not
[75:56] was not going to be mainstream enough for me to be able to make a career in the field. I actually left academia for a few years and worked outside of it because I was pessimistic about whether I could do the kind of work I wanted to do and be in the field. But eventually some of the things I was doing
[76:16] I did get positive feedback on and that I think was enough to encourage me to come back and keep working on this stuff. And I, you know, I don't regret that. I think that was the right decision. But yeah, I think, you know, looking back, perhaps if I'd if I'd understood the need for patients that could have been avoided. Tell me about that. So you left academia for a while and then were you still publishing while you were outside? Yeah, I did.
[76:42] I did in my PhD, I mostly published on pure physics topics. After finishing, I left academia, but continued to think about particularly more philosophical topics and to publish and to write on those things. And eventually, I think came to the realization that clearly this is what I should be doing professionally. And so then then sort of wanted to switch, switch from the more physics side into the more philosophy side. How did you get back in?
[77:11] Yeah, it wasn't straightforward, especially because I was looking for philosophy positions and had physics qualifications. But the people at the University of Western Ontario were very helpful and encouraging and found a way to bring me there and allow me to do a postdoc there. That was a very productive time, really fantastic. And so that was my route back into the field.
[77:35] Well, it's fantastic speaking with you. Thank you so much for spending your time with me. Yeah, it's really fun. Thank you. Yes. I've received several messages, emails and comments from professors saying that they recommend theories of everything to their students. And that's fantastic. If you're a professor or lecturer and there's a particular standout episode that your students can benefit from, please do share. And as always, feel free to contact me.
[77:59] new update started a sub stack writings on there are currently about language and ill-defined concepts as well as some other mathematical details
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      "text": " 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."
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      "text": " I'm particularly liking their new insider feature was just launched this month it gives you gives me a front row access to the economist internal editorial debates where senior editors argue through the news with world leaders and policy makers and 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."
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      "text": " 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."
    },
    {
      "end_time": 85.111,
      "index": 3,
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      "text": " The dogma I worry about is that we should think about physics in terms of time evolution, this picture where you start at the beginning and evolve forwards in time. That's a very intuitive way of thinking about physics, but it is very clearly not a good fit for what we are seeing. There's really good evidence coming from lots of different parts of physics that we shouldn't be thinking about time in those terms."
    },
    {
      "end_time": 109.923,
      "index": 4,
      "start_time": 87.176,
      "text": " Imagine a completed Sudoku puzzle. The rules don't dictate that you start in one corner and then work systematically across the grid. Instead, they just constrain what patterns are valid for the entire puzzle. Professor Emily Adlam of Chapman University suggests that the fundamental laws of physics work similarly. You don't evolve the universe step by step from past to future. Instead, there are these constraints."
    },
    {
      "end_time": 136.852,
      "index": 5,
      "start_time": 109.923,
      "text": " something that selects valid patterns across all of space-time simultaneously. This quote-unquote all at once perspective helps explain paradoxical quantum phenomena like delayed choice experiments and Bell nonlocality. It also comports with Einstein's relativity where the distinction between past and future depends on the observer's reference frame. If correct, this paradigm shift would transform our understanding of causality of observers and of the nature of physical law itself."
    },
    {
      "end_time": 142.295,
      "index": 6,
      "start_time": 138.66,
      "text": " What's the largest unsolved problem in physics today that you're interested in?"
    },
    {
      "end_time": 171.084,
      "index": 7,
      "start_time": 143.592,
      "text": " Well, this is not a very original answer, but I think the measurement problem of quantum mechanics for me still really stands out as an important unsolved problem. And not just because it's sort of intellectually interesting, but because it seems to me that it's closely linked to a variety of concrete problems that we're working on in modern physics. So in particular, I think in the context of work on quantum gravity, a lot of the issues we're really sort of struggling with are ultimately to do with the nature of observers, the nature of observation,"
    },
    {
      "end_time": 201.22,
      "index": 8,
      "start_time": 171.476,
      "text": " So for example, solving the problem of time is all about trying to understand how to put the observers into their theories in the way that reproduces the kinds of observations we expect to see. And so that makes me think that perhaps there's an issue here where we never really came to grips with how to think about observers in the context of ordinary quantum mechanics. And that's really holding us back from making us progress on further physics. So I think that problem to me demands a solution, not just for intellectual curiosity, but also to be able to make real progress."
    },
    {
      "end_time": 207.278,
      "index": 9,
      "start_time": 202.688,
      "text": " What's the definition of observer? Is it the same as measuring device or what counts as a measurement?"
    },
    {
      "end_time": 237.312,
      "index": 10,
      "start_time": 207.91,
      "text": " Well, that's exactly the problem. We don't know clearly how to define observers in concrete physical terms. We have, of course, an intuitive notion of what an observer is, and we know what we expect observers to see, but it's still very unclear how to properly model observers within quantum mechanics. All the interpretations of quantum mechanics say something different about how you should represent observers, and that has important knock-on effects for how you're going to think about observers in the context of further physics like quantum gravity."
    },
    {
      "end_time": 266.34,
      "index": 11,
      "start_time": 238.968,
      "text": " How does the problem of observers or defining what observers are have anything to do with quantum gravity? So, I mean, one of the big problems we encounter in the formulation of quantum gravity is known as the problem of time, which refers to the fact that if you impose a sort of canonical quantization on gravity, the result is that time evolution seems to vanish. You end up with this sort of strange timeless model. And so then one obvious problem you have is try to try to understand"
    },
    {
      "end_time": 291.527,
      "index": 12,
      "start_time": 266.766,
      "text": " So why don't you tell us how you make sense of observers then?"
    },
    {
      "end_time": 304.087,
      "index": 13,
      "start_time": 293.148,
      "text": " Unfortunately, I don't have a complete answer to this question. I think one thing that we can see clearly from both general relativity and quantum gravity"
    },
    {
      "end_time": 329.855,
      "index": 14,
      "start_time": 304.411,
      "text": " is that making sense of observers is probably going to require understanding them in sort of relational terms, understanding observations as things that happen in some sense relative to observers rather than being things that are out there in the world by themselves. So that seems like an important insight, which I think is also relevant for standard quantum mechanics, but certainly it's an ongoing project to understand exactly how to make that work in a coherent way."
    },
    {
      "end_time": 346.442,
      "index": 15,
      "start_time": 331.561,
      "text": " We're going to get to the relational interpretation of quantum mechanics and your work with Carla Rovelli. But prior to that, I want to know what the heck is a Sudoku universe? Yes. So the Sudoku universe is a way of thinking about time and laws."
    },
    {
      "end_time": 369.275,
      "index": 16,
      "start_time": 346.732,
      "text": " in the context of modern physics. So there's this perhaps quite traditional way of thinking about physics where we imagine it as something like a computer as Ken Wharton puts it. So we think of an initial state being put in and then the universe just evolves the initial state forwards in time and produces the course of history. And that's, I think, the intuitively natural way to think about physics that many people still use."
    },
    {
      "end_time": 398.37,
      "index": 17,
      "start_time": 369.718,
      "text": " But there's I think really good evidence coming from lots of different parts of physics that we shouldn't be thinking about time in those terms. We should instead be thinking about the laws of Natia as applying all at once to the whole of history. So in that sense that they're like the rules of a game of Sudoku. The rules of Sudoku don't tell you to start at the left and then move towards the right. What they do is constrain the whole grid and tell you whether an entire solution is valid or invalid. So the thought is that the laws of Natia perhaps work like that."
    },
    {
      "end_time": 414.65,
      "index": 18,
      "start_time": 398.37,
      "text": " Is that the same as saying that there's some imposition of consistency?"
    },
    {
      "end_time": 439.104,
      "index": 19,
      "start_time": 415.316,
      "text": " I don't know how to derive the actual laws that we observe from purely consistency conditions. It would be neat if that could be done, but it seems like there might be some constraints going beyond just consistency conditions to sort of impose the specific types of laws that we actually see. You had a 2018 paper called Spooky Action at a Temporal Distance, which is a great title by the way."
    },
    {
      "end_time": 468.148,
      "index": 20,
      "start_time": 439.787,
      "text": " You mentioned something becoming a dogma in physics. I'm quoting you a dogma and something like there's an assumption which is actively limiting progress in quantum foundation. So what is it? And those are strong words. So I'd like you to justify your usage of that language. Yes. So the dogma I was worrying about there was this idea that we should think about physics in terms of time evolution. This picture where you start at the beginning and evolve forwards in time."
    },
    {
      "end_time": 491.8,
      "index": 21,
      "start_time": 468.933,
      "text": " As I say that's a very intuitive way of thinking about physics but it is I think very clearly not a good fit for what we are seeing in modern physics and yet nonetheless many people I think are still drawn to try to think about things in those terms. So for example in quantum foundations it's very common to be quite focused on trying to give causal accounts of things to understand at"
    },
    {
      "end_time": 521.442,
      "index": 22,
      "start_time": 491.8,
      "text": " Either in classical terms or to move to a sort of quantum notion of causation where you can tell the story about one thing causing another thing causing another thing and that I think is is not a good use of our efforts because there are clear indications that that's not really the structure that physics actually has and so trying to force it into a causal structure is not likely to be a good way of understanding it. In the philosophical literature, there's dispute as to what is causation. Do you have a personal account of causation?"
    },
    {
      "end_time": 549.189,
      "index": 23,
      "start_time": 522.005,
      "text": " When I say personal, I mean one that you favor. Yes. So definitely the Council of Causation, I favor other ones, which suggests that causation needs to be understood as essentially as a macroscopic phenomenon. So causation, I think, clearly has something to do with thermodynamics and the thermodynamic arrow in terms of entropy. It's also, I think, clearly related to perspective, the perspective of macroscopic observers like us and what we can and can't achieve."
    },
    {
      "end_time": 574.77,
      "index": 24,
      "start_time": 549.65,
      "text": " It's related to interventions and telling a story about what observers like us can achieve by intervening on certain types of variables. So all of those things make it seem very macroscopic in nature, which means that for me it's incorrect to think of causation as being something that inheres in the microscopic world. Certainly there are, I think, important kinds of structure"
    },
    {
      "end_time": 598.916,
      "index": 25,
      "start_time": 574.94,
      "text": " So I'd like to talk about non-locality as well, specifically temporal non-locality and in temporal is time and earlier you mentioned the problem of time and then here we're talking about the arrow of time or the thermodynamic arrow of time."
    },
    {
      "end_time": 629.019,
      "index": 26,
      "start_time": 599.275,
      "text": " It sounds to people who know some physics that, oh, there's a problem of time. Is that the problem of the arrow of time? Is the problem of time different than the arrow of time problem? And does the second law solve it? All of these get entwined in their minds. So why don't you distinguish those? What is the problem of time? What is the arrow of time and what it has to do with the second law? Yes. So the arrow of time usually refers to the fact that in the world, as we experience it, there are all these temporal asymmetries, you know,"
    },
    {
      "end_time": 658.882,
      "index": 27,
      "start_time": 629.599,
      "text": " glasses break and don't usually recompose themselves, all of these kinds of obvious asymmetries that characterize our lives. And the problem of the arrow of time is that the underlying physics mostly seems to be time symmetric. So in that sense, it's not obvious where all of these asymmetries could come from. You seem to have to impose them by just deciding by fiat that the initial state of the universe is some special kind of state which can explain those asymmetries. But for many people, that's not super satisfying."
    },
    {
      "end_time": 684.582,
      "index": 28,
      "start_time": 659.616,
      "text": " The problem of time and quantum gravity is a distinct issue. It refers to the fact that within a specific technical formalism for quantizing gravity, when you perform that quantization, you find that time evolution ends up being what's called a gauge transformation, which means that it's not physically real. It's just kind of giving two different descriptions of the same thing. So it looks like time evolution in the ordinary sense is not present at all."
    },
    {
      "end_time": 704.531,
      "index": 29,
      "start_time": 685.077,
      "text": " So that leads to a problem of trying to understand, you know, where do our experiences come from? Why do we have the experiences that feel like they are temporal in nature? So they are separate problems, but I think it's very likely they are linked. I think certainly the story about why we have experiences which are temporal in nature"
    },
    {
      "end_time": 726.084,
      "index": 30,
      "start_time": 704.889,
      "text": " Most have something to do with thermodynamics and the fact that we live in this very asymmetric regime. So there's still work to be done to flesh out the connections between these things, but certainly I think they're not completely independent. So some people explain the arrow of time with coarse graining. I think Stephen Wolfram does this and in coarse graining is"
    },
    {
      "end_time": 744.684,
      "index": 31,
      "start_time": 727.056,
      "text": " Yes. So in that paper, this is sort of an exploratory paper."
    },
    {
      "end_time": 774.428,
      "index": 32,
      "start_time": 745.589,
      "text": " necessarily committed to the view that reductionism is false, but I'm interested in whether that is maybe one way to try to resolve some of the problems that we encounter in quantum field theory. So one of the problems is a sort of fine tuning issue where we find that in certain kinds of cases, it seems that the values of two distinct fundamental constants must be very carefully adjusted to fit each other in order to produce the observed value of the constant at a higher scale."
    },
    {
      "end_time": 801.459,
      "index": 33,
      "start_time": 774.957,
      "text": " and sort of the observation I was making here was that if you say things are the other way around, if you say that the higher level constant is fundamental and the smaller scale constants are in fact derived from it, that gives you a very natural explanation for why they're fine-tuned in this way because they are in fact fixed by the actual value of the higher level constant. So the thought there was just that perhaps changing our way of thinking such that"
    },
    {
      "end_time": 823.695,
      "index": 34,
      "start_time": 801.664,
      "text": " some cases smaller scale things are explained by larger scale things rather than vice versa might be a way of understanding some of those phenomena. It was important to look at the renormalization transformations because renormalization is the transformation we use in quantum field theory to move between different scales and so the question I was looking at there was trying to understand"
    },
    {
      "end_time": 850.469,
      "index": 35,
      "start_time": 824.548,
      "text": " Given the mathematical structure of the renormalization translations, is it possible to that things could be reversed in direction and that the higher scale things could define the lower scale things and not vice versa? We normally wouldn't think that's possible in sort of more ordinary physics because we think there's a sort of many to one mapping where many microscopic possibilities get mapped to one macroscopic possibility. So the macroscopic possibility can't determine what's going on in the microscopic scales."
    },
    {
      "end_time": 871.749,
      "index": 36,
      "start_time": 850.845,
      "text": " Even at fixed points?"
    },
    {
      "end_time": 890.538,
      "index": 37,
      "start_time": 872.022,
      "text": " Because fixed points do involve scenarios where many solutions get mapped to one solution. But the thing about fixed points is that they can occur both at very small scales and at larger scales. So it's not obvious to me that invoking fixed points particularly favors one direction of explanation since they occur at both levels."
    },
    {
      "end_time": 916.51,
      "index": 38,
      "start_time": 892.193,
      "text": " Let me see if I can phrase this in the language for mathematicians and correct me if I'm incorrect. The renormalization group is a set of tools to determine how parameters change with different scales, whether it's energy scales or length scales or what have you. Now, it's less of a group in the algebraic sense and more a set of tools. But if it was to be something like a group, it would be a monoid because not every element is invertible."
    },
    {
      "end_time": 927.585,
      "index": 39,
      "start_time": 916.988,
      "text": " However, most of the elements are invertible and this would mean that you don't privilege some scales being more fundamental in the same way that in an affine group you don't have a privileged origin."
    },
    {
      "end_time": 957.602,
      "index": 40,
      "start_time": 928.217,
      "text": " That's right. Yeah. So we, I mean, we have various approximations we use to do renormalization and many of those are not invertible. But there are good reasons to think that the real underlying transformations should be invertible. And if that's the case, then outside of six points, you can go from small scales to large scales, or you can go from large scales to small scales. It's kind of the same from the point of view of the underlying math. And so there's no sort of obvious sense in which the physics is telling you the small things must explain the big things and not vice versa."
    },
    {
      "end_time": 988.763,
      "index": 41,
      "start_time": 959.377,
      "text": " Hmm. Let me see if I can make another analogy. So let's imagine there's a bird in the sky and you take a snapshot of that bird and then you say, okay, it's position is here and it's velocity is here. So or it's momentum. And then you could say, okay, where is it going to be? And then you can plan out it or you can predict its trajectory. And then you say, well, look, what we got here is an initial position and velocity. But why did you call this initial? Like you could actually from another point,"
    },
    {
      "end_time": 1018.951,
      "index": 42,
      "start_time": 989.855,
      "text": " make the trajectory go backward. And so you have the whole trajectory. So what is the initial point? Why is one point being privileged? Yeah, I mean, I think that's a great analogy, because I would say much the same about time, time evolution as well, that there is no particular reason to privilege one point. Certainly, the physics doesn't tell you you have to do that. And yeah, I think the same is true, at least for many applications of renormalization transformation, the physics doesn't seem to be telling you that"
    },
    {
      "end_time": 1048.524,
      "index": 43,
      "start_time": 1019.514,
      "text": " The smallest, most fundamental scales must actually be privileged in that sense. So let's get to non-locality. There's a large hubbub about non-locality and Bell's theorem and also realism. Yeah. Well, what is non-locality? Yeah. So in the context of quantum mechanics, non-locality is the phenomenon that quantum mechanics exhibits correlations which seem to be too strong to be explained by any local model."
    },
    {
      "end_time": 1076.22,
      "index": 44,
      "start_time": 1048.677,
      "text": " Normally when we see correlations at a distance, we would expect to explain them by some common cause in the past. They both came from the same source or something like that. But Bell's theorem demonstrates that the types of correlations we see in quantum mechanics can't be explained that way. It seems as though there's some kind of direct influence between events happening at a distance that can't be explained in this sort of common cause way. Now, there's two different types of non-locality."
    },
    {
      "end_time": 1096.817,
      "index": 45,
      "start_time": 1076.869,
      "text": " Spatial and temporal. And you have many papers, many talks as well on temporal nonlocality. So please distinguish the two. Yeah, so perhaps the, I guess the traditional way of thinking about nonlocality in quantum mechanics is to imagine it as a spatial form of nonlocality. So that involves a situation in which"
    },
    {
      "end_time": 1121.715,
      "index": 46,
      "start_time": 1097.261,
      "text": " Perhaps Alice performs a measurement in one location and as soon as she does that the wave function collapses everywhere in the world and that sort of conveys information across to Bob wherever he is and that has an impact on the results of his subsequent measurement. So that non-locality is spatial because the effect of what Alice does is just transferred to the whole global state everywhere at the same time."
    },
    {
      "end_time": 1152.227,
      "index": 47,
      "start_time": 1123.695,
      "text": " Whereas temporal nonlocality suggests that nonlocality doesn't necessarily have to be conveyed immediately in terms of the current state of the world, you can potentially think of nonlocality as kind of hopping across time as well. So Alice performs her measurement at some time and at some other place and at some later time, Bob performs a measurement and there's just a direct relationship. There's some kind of constraint requiring that Bob's outcome"
    },
    {
      "end_time": 1168.37,
      "index": 48,
      "start_time": 1152.483,
      "text": " Does spatial nonlocality imply temporal or vice versa?"
    },
    {
      "end_time": 1197.193,
      "index": 49,
      "start_time": 1169.838,
      "text": " Yes, so I think combining spatial non-locality with relativistic constraints makes it very compelling to think that there should be temporal non-locality. That's because if you take a frame of reference within a relativistic setting where you have a spatially non-local effect, something Ellis does influences something that happens over here, you're allowed within relativity to make a change of reference frame to get another equally valid reference frame."
    },
    {
      "end_time": 1224.241,
      "index": 50,
      "start_time": 1197.193,
      "text": " And in that reference frame, those events are not going to be at the same time anymore. The event, Bob's event over here is going to be either in the future or the past of Alice's observation. So it looks like by making that transformation, you have turned your spatial nonlocality into temporal nonlocality. So that in that sense, if you sort of, if you believe what relativity tells us about the close connections between space and time, it seems very hard to maintain that nonlocality is always spatial and never temporal."
    },
    {
      "end_time": 1255.333,
      "index": 51,
      "start_time": 1225.367,
      "text": " So then why is it that physicists, if I understood one of your papers correctly, why is it that physicists focus on the spatial nonlocality when if you're in the relativistic setting and both are on quote-unquote equal footing, a term I don't like for various reasons, I'll put a link to a video on why I don't like equal footing, but regardless, why is it that physicists tend to focus on the spatial nonlocality compared to the temporal one? Yeah, well I think one main reason for this is because quantum mechanics historically and"
    },
    {
      "end_time": 1284.36,
      "index": 52,
      "start_time": 1255.64,
      "text": " still usually today is formulated as a time evolution theory. So the natural way to think about quantum mechanics in its standard formulation is to sort of formulate it in terms of global states which carry all the information forwards in time. So from that point of view if you're trying to model locality in that picture perhaps the sort of natural thing to do is have a global collapse of the wave function that takes place everywhere and so to have a spatial non-locality."
    },
    {
      "end_time": 1305.418,
      "index": 53,
      "start_time": 1285.725,
      "text": " If you are formulating quantum mechanics in a different way as a non-time evolution theory, then temporal nonlocality becomes much more sort of natural and compelling, but that's not the traditional way in which we have formulated quantum mechanics. Is the future influencing the past an example of temporal nonlocality?"
    },
    {
      "end_time": 1330.623,
      "index": 54,
      "start_time": 1306.442,
      "text": " Yes, so it could be. It depends, I think, how you think about the way in which the future influences the past. If, for example, your model of the future influencing the past involves some kind of backwards evolving state that goes back and carries the information backwards in time, you might end up with a picture where there is a backwards influence but it is sort of locally mediated by a backwards"
    },
    {
      "end_time": 1351.544,
      "index": 55,
      "start_time": 1331.152,
      "text": " Evolving states, on the other hand, if your model of the way in which the future influences the past is some kind of all at once style model where there's just a sort of global constraint relating these two things to each other. In that case, it is going to look much more like temporal nonlocality because there doesn't need to be a sort of literal state that goes back and carries the information."
    },
    {
      "end_time": 1380.213,
      "index": 56,
      "start_time": 1353.234,
      "text": " Right. In your work, as I was going through it, you differentiate between dynamical retro causality. So influences propagating backward in time, step by step. And then this all at once and this term all at once will come up over and over. And I believe it's an all at once temporal retro causality. But would it be called retro causality at that time? At that point, if it's all, I guess that's a pun. Would it be called retro causality if it's happening all at once? Yeah. Why is it retro causality?"
    },
    {
      "end_time": 1386.152,
      "index": 57,
      "start_time": 1380.862,
      "text": " Yeah, well I use retro causality in this connection just to sort of"
    },
    {
      "end_time": 1413.712,
      "index": 58,
      "start_time": 1387.056,
      "text": " In a loose way to relate what's going on here to sort of more traditional discussions of retro causality. I think strictly speaking, what's going on there is not retro causality because I think there's no cause causality in fundamental physics. So, you know, neither the forwards nor the backwards direction is truly causal. But, but certainly if you, if you try to look at this from a more macroscopic point of view and you sort of write down a causal model in which a person intervenes on something,"
    },
    {
      "end_time": 1440.879,
      "index": 59,
      "start_time": 1414.104,
      "text": " So when you're thinking about all at once, are you also thinking about boundary conditions? So the ordinary way that physics is thought about is that you have your boundary conditions plus the laws and you then evolve forward. So please define what all at once is."
    },
    {
      "end_time": 1461.084,
      "index": 60,
      "start_time": 1441.954,
      "text": " Yes, so all at once refers to this sort of Sudoku universe style idea where the laws of nature apply to the whole of history all at once. So the one possible type of all at once model is a model in which you fix the initial and the final conditions and then you ask the laws to determine what happens in between."
    },
    {
      "end_time": 1479.224,
      "index": 61,
      "start_time": 1461.647,
      "text": " I mean, that's quite a common type of problem that we see even in fairly standard physics. But it's also not the only kind of possibility. When I talk about all at once or constraint based laws, I usually talk about the laws of native fixing, determining the whole history at once."
    },
    {
      "end_time": 1507.568,
      "index": 62,
      "start_time": 1479.599,
      "text": " So in that sense, often it will be the case that you can fix any state anywhere on the history and that will be sufficient to fix the rest. So it could be the initial state, could be the final state, could be one or more states in between. In that sense, in that kind of picture, no particular point of time has to be specially privileged. It's just the history as a whole which is selected by the laws. When speaking about these histories, it reminds me of the transaction interpretation. Have you done any work on the"
    },
    {
      "end_time": 1535.282,
      "index": 63,
      "start_time": 1507.892,
      "text": " on the transaction interpretation or do you have any thoughts on it? I think the transactional interpretation is certainly interesting. I'm interested in these kinds of retro-causal models. I guess I would like to see more emphasis from the transactional interpretation on moving away from specific experimental situations to a more general picture where I can understand"
    },
    {
      "end_time": 1551.288,
      "index": 64,
      "start_time": 1535.623,
      "text": " how the experimental situations and the observers in particular are supposed to arise from something more fundamental than that. In some cases, the transactional interpretation seems to me overly focused on a set up where we already have instruments and the observers are kind of already given."
    },
    {
      "end_time": 1577.858,
      "index": 65,
      "start_time": 1554.241,
      "text": " Tim Maudlin had a challenge to the transactional interpretation about how there's some contradiction in simple backward causal stories. What is Tim Maudlin's objection or challenge and what does the all at once model do to resolve it? Maudlin's concern was that if you imagine an experiment in which"
    },
    {
      "end_time": 1601.937,
      "index": 66,
      "start_time": 1578.114,
      "text": " We take some sort of preliminary measurement in the middle of the experiment and then we use that to determine part of the final conditions, the final measurement we're going to make. That looks inconsistent with the most naive version of the transactional interpretation because the transactional interpretation is supposed to take the initial and final conditions and determine what happens in between, so you can make that become contradictory."
    },
    {
      "end_time": 1627.125,
      "index": 67,
      "start_time": 1602.073,
      "text": " So there are more sophisticated versions of the transactional interpretation which avoid this issue but I think all of them ultimately avoid this issue by moving away from the sort of naive story where there's a literal transaction taking place in some sort of temporal process and more towards an all-at-once style picture where the whole thing is kind of atemporal and has to be thought of as being determined"
    },
    {
      "end_time": 1657.312,
      "index": 68,
      "start_time": 1627.773,
      "text": " We started this conversation with talking about the largest problem that irks you and it was the measurement problem and now we're talking about the all at once model. Did the measurement problem lead you to this all at once quantum framework or"
    },
    {
      "end_time": 1680.794,
      "index": 69,
      "start_time": 1657.944,
      "text": " I think they are separate in that the indications that the all at once model is correct come partly from quantum mechanics but also from other parts of physics, from relativity and quantum gravity and so on."
    },
    {
      "end_time": 1710.265,
      "index": 70,
      "start_time": 1681.015,
      "text": " And I think just adopting an all at once style model does not by itself solve the measurement problem because the measurement problem is to a large extent about how to model observers. Just saying we're going to tell an all at once story doesn't answer the question of how to model observers. So I do think that it seems clear to me that the right solution to the measurement problem is going to be some all at once style solution, but there are a number of different possibilities within that. And so I think it's still for me open, which is the right way to do that."
    },
    {
      "end_time": 1729.77,
      "index": 71,
      "start_time": 1712.637,
      "text": " Do you find cubism or other observer centric interpretations to be unsatisfactory? I find them incoherent. My worry about them is that if you're really serious about your observer centricity, that is going to lead you inevitably to a picture in which every observer"
    },
    {
      "end_time": 1755.23,
      "index": 72,
      "start_time": 1730.06,
      "text": " kind of has their own reality and they're not able to communicate with each other. That I think is incompatible with the practice of science. Science is a very social activity. The sort of objectivity of science rests on the fact that we have all these different scientists doing observations and then sharing them. So I don't think it's, it's reasonable to interpret quantum mechanics in any way, which ultimately says we can't actually communicate with different observers."
    },
    {
      "end_time": 1773.063,
      "index": 73,
      "start_time": 1755.981,
      "text": " I am however interested in sort of more moderate observer centric views which allow that observers play an important role or that perspectives in general play an important role but which nonetheless make provision for sort of connections between perspectives to happen. Such as relational quantum?"
    },
    {
      "end_time": 1799.787,
      "index": 74,
      "start_time": 1773.695,
      "text": " Relational quantum mechanics in its standard formulation does have the problem that I've just described because it does imply that it is impossible in an absolute sense to ever know anything about what's going on in anyone else's perspective. But the work that I did with Carla Rovelli recently was about thinking about how could you alter relational quantum mechanics to overcome this issue and so we did suggest"
    },
    {
      "end_time": 1809.957,
      "index": 75,
      "start_time": 1800.145,
      "text": " Just a moment. Don't go anywhere. Hey, I see you inching away."
    },
    {
      "end_time": 1833.677,
      "index": 76,
      "start_time": 1810.418,
      "text": " Don't be like the economy, instead read the economist. I thought all the economist was was something that CEOs read to stay up to date on world trends. And that's true, but that's not only true. What I found more than useful for myself personally is their coverage of math, physics, philosophy, and AI, especially how something is perceived by other countries and how it may impact markets."
    },
    {
      "end_time": 1857.705,
      "index": 77,
      "start_time": 1833.677,
      "text": " For instance the economist had an interview with some of the people behind deep seek the week deep seek was launched no one else had that another example is the economist has this fantastic article on the recent dark energy data which surpasses even scientific americans coverage in my opinion they also have the charts of everything like the chart version of this channel it's something which is a pleasure to scroll through and learn from."
    },
    {
      "end_time": 1875.538,
      "index": 78,
      "start_time": 1857.705,
      "text": " Links to all of these will be in the description of course. Now the economist commitment to rigorous journalism means that you get a clear picture of the world's most significant developments. I am personally interested in the more scientific ones like this one on extending life via mitochondrial transplants which creates actually a new field of medicine."
    },
    {
      "end_time": 1899.94,
      "index": 79,
      "start_time": 1875.538,
      "text": " Something that would make michael levin proud the economist also covers culture finance and economics business international affairs britain europe the middle east africa china asia americas and of course the u.s.a. whether it's the latest in scientific innovation or the shifting landscape of global politics the economist provides comprehensive coverage and it goes far beyond just headlines."
    },
    {
      "end_time": 1924.548,
      "index": 80,
      "start_time": 1899.94,
      "text": " Look, if you're passionate about expanding your knowledge and gaining a new understanding, a deeper one of the forces that shape our world, then I highly recommend subscribing to The Economist. I subscribe to them and it's an investment into my, into your intellectual growth. It's one that you won't regret. As a listener of this podcast, you'll get a special 20% off discount. Now you can enjoy The Economist and all it has to offer."
    },
    {
      "end_time": 1944.343,
      "index": 81,
      "start_time": 1924.787,
      "text": " How is it that you think about probabilities?"
    },
    {
      "end_time": 1974.616,
      "index": 82,
      "start_time": 1944.718,
      "text": " There are different interpretations of probability. Forget about quantum mechanics. There are different interpretations of what a probability is. So in metaphysics and in science, how do you think about probability? Yeah, I think the interpretation of probability is a very hard problem. I think I'm not wholly satisfied with any of the approaches that we have available to us. The frequentist approaches are useful in many cases, but have pretty significant philosophical problems."
    },
    {
      "end_time": 2003.746,
      "index": 83,
      "start_time": 1974.787,
      "text": " for us accounting for certain kinds of edge cases. Subjective Bayesianism I think just just doesn't do justice to the fact that certain probabilities do seem to be out there in the world and not just in our minds. The sort of disposition list accounts are quite mysterious and also very hard to reconcile with all-at-one style physics. There are a couple of recent approaches that I'm very interested in. There's a view called nomic frequentism due to someone called John Roberts which suggests that"
    },
    {
      "end_time": 2032.807,
      "index": 84,
      "start_time": 2004.087,
      "text": " probabilities should be understood as in terms of laws which require that frequencies should look a certain way and there's some really nice work on this recently by Eddie Chin and John Barrett looking at the ways in which you could potentially expand on that and think about probabilities as sort of constraints on relative frequencies. So while that work is still ongoing I think that's a really interesting direction and probably the most promising approach from my point of view."
    },
    {
      "end_time": 2057.5,
      "index": 85,
      "start_time": 2033.575,
      "text": " What do you mean? What does Eddie 10 saying that probability should look a certain way? What does that mean? So this is working within sort of all at once style constraint based view of laws. And the observation is that if you allow that laws are global constraints, which apply to the whole of history, then you can formulate a probabilistic law as saying something like the relative frequency of occurrences of some outcome across all"
    },
    {
      "end_time": 2085.691,
      "index": 86,
      "start_time": 2058.183,
      "text": " all instances of this type of measurement across all of history must have some value or must fall in some range. So you can think of the laws or probabilities as directly constraining the relative frequencies that actually occur. So that's somewhat similar in spirit to the frequentist approaches but I think avoids some of the more serious problems for frequentism because it's not just saying that probabilities are whatever the frequencies should happen to be, it really is saying that"
    },
    {
      "end_time": 2114.565,
      "index": 87,
      "start_time": 2085.691,
      "text": " Add the laws constrain the frequencies and require them to have certain values. So how does your approach compare with silly Goldstein's approach? Yes, so the approach that Eddie Chen and jelly Goldstein have worked on in terms of laws is I think a very similar in spirit to mine and indeed alien. I are working on a project sort of examining some of those similarities. But perhaps one one difference is that"
    },
    {
      "end_time": 2142.483,
      "index": 88,
      "start_time": 2115.469,
      "text": " One difference is that they are inclined to think of those all at once constraints as a sort of fundamental primitive, whereas I perhaps prefer to think of them as being a form of modal structure in accordance with a sort of generally structurally realist approach to physics and to laws. But I don't think those views are necessarily incompatible with each other. They're more sort of a difference of emphasis. What's a modal structure? What does that mean?"
    },
    {
      "end_time": 2154.258,
      "index": 89,
      "start_time": 2143.695,
      "text": " So modal is a word that philosophers use to refer to facts about what is possible and impossible. So modal structure"
    },
    {
      "end_time": 2180.776,
      "index": 90,
      "start_time": 2154.804,
      "text": " Perhaps the most well known example of modal structure is causal structure. So that's one form that modal structure can take. Because I don't think causation is fundamental. I don't think that that can be the most general type of modal structure. But I do think the world has some other kind of structure, which is in some way similar to causal structure, but perhaps more general than that. And so that's where I would sort of expect those all at once constraints to live."
    },
    {
      "end_time": 2211.596,
      "index": 91,
      "start_time": 2183.336,
      "text": " Model structures, so model comes from philosophy. It's not a term you hear in theoretical physics. Now it is when you start to study the foundations of physics or the foundations of quantum mechanics, but I'm curious how philosophical tools such as modalism or analyzing determinism or realism has guided your research. Yes, I think there's a sort of useful back and forth to be had here. I think that modern theoretical physics has"
    },
    {
      "end_time": 2230.913,
      "index": 92,
      "start_time": 2211.852,
      "text": " important lessons for a variety of traditional philosophical discussions. This discussion about lawhood is a great example. Both me and Eddie and Shelley are inspired by noting that traditional philosophical accounts of lawhood don't seem to do a very good job of accommodating the kinds of laws we see in modern physics."
    },
    {
      "end_time": 2249.684,
      "index": 93,
      "start_time": 2231.391,
      "text": " I think there's a useful sort of flow of information backwards as well, because using these philosophical tools and doing the work to analyze, okay, so what are laws now? How can we understand the types of laws we're seeing in modern physics? That's a useful way of clarifying our thought about what's going on in theoretical physics."
    },
    {
      "end_time": 2262.602,
      "index": 94,
      "start_time": 2250.06,
      "text": " at understanding what are useful directions for future research and sort of understanding how we can connect those developments back up to the kinds of things we're concerned with in philosophy and in everyday life."
    },
    {
      "end_time": 2285.759,
      "index": 95,
      "start_time": 2265.077,
      "text": " Do you encounter the attitude from physicists that, hey, physics, experimental physics, theoretical physics, it doesn't need anything from philosophy. Philosophy hasn't contributed anything to science in the past 100 years, other than maybe Popper. And before that, it was a while and you can't just count Aristotle. That was thousands of years ago. So do you encounter that attitude?"
    },
    {
      "end_time": 2315.401,
      "index": 96,
      "start_time": 2286.169,
      "text": " I think there's a wide spectrum of attitudes within physics. I mean, I certainly have encountered people with that attitude, but I've also encountered many physicists who love philosophy and are very interested in it and are very keen to talk to philosophers. So while their attitude does exist, I think it's also plenty of goodwill and interest in both communities to talk to each other and make progress. What would be the counterpoint to someone who's saying that philosophy hasn't contributed directly to physics in the past?"
    },
    {
      "end_time": 2325.196,
      "index": 97,
      "start_time": 2316.203,
      "text": " The most obvious example I would say is Bell's theorem in the discussion around nonlocality."
    },
    {
      "end_time": 2348.063,
      "index": 98,
      "start_time": 2325.538,
      "text": " Bell's theorem was very much regarded as not mainstream physics when it was formulated, and Bell was a physicist, but other people involved in the discussion of non-locality and pushing this forward, like Schimone, were not physicists, they were primarily philosophers, and certainly I think this topic probably got more of a foothold within philosophy before it moved back into mainstream physics."
    },
    {
      "end_time": 2374.514,
      "index": 99,
      "start_time": 2348.422,
      "text": " But now it's certainly recognized as mainstream physics, you know, the Nobel Prize was awarded for it recently. So I think that's an example of a case where topics that were considered sort of foundational and conceptual were worked on within philosophy for a while, but ultimately became recognized as part of mainstream physics. So what got you interested in philosophy? Did you start in physics or did you start in philosophy?"
    },
    {
      "end_time": 2390.35,
      "index": 100,
      "start_time": 2375.555,
      "text": " My undergrad was in both physics and philosophy. I've always been very interested in physics and in science, but my questions have always been more on the side of what is considered to be"
    },
    {
      "end_time": 2417.892,
      "index": 101,
      "start_time": 2391.203,
      "text": " foundational physics or philosophy of physics. I think it was a toss up for a long time, whether I was going to be a physicist working on the foundations of physics or a philosopher. My PhD is actually in physics, not philosophy. But in the end, I think perhaps the kind of work I want to do feels like it lives more happily within philosophy. So that's why I ended up here. And what does foundations mean? So when someone says they study the foundations of something,"
    },
    {
      "end_time": 2443.285,
      "index": 102,
      "start_time": 2419.155,
      "text": " Yes, so I mean generally that means something to do with interested in the sort of more basic conceptual questions and looking at the sort of underlying structures and perhaps understanding why the theory is the way it is or understanding sort of basic principles of the theory. Sort of a contrast to you know more applied approaches so if you study the foundations of quantum mechanics you're not"
    },
    {
      "end_time": 2471.118,
      "index": 103,
      "start_time": 2443.899,
      "text": " I'm going to be primarily working on how to build new quantum technologies. You're going to be thinking about the structure of the theory and what it all means. And perhaps those results will eventually go on to be useful in quantum technologies. They often do, but if you're working in foundations, that's not your sort of primary focus. So what I enjoy about your work is that much like Jacob Barndes, you emphasize clarity of concepts and principles as a guide to progress."
    },
    {
      "end_time": 2500.35,
      "index": 104,
      "start_time": 2471.578,
      "text": " You actually co-authored a paper last year, if I'm not mistaken, with Sabine Hassenfelder and Tim Palmer, both of whom have been on the podcast before. So I'll put a link to that on screen and in the description. The paper is called something like a taxonomy of physics for quantum theory or beyond quantum theory. It's something that everyone should read if they're interested in physics. And if you follow this podcast, you can follow that paper. So there are different concepts that are explained there with precision."
    },
    {
      "end_time": 2529.343,
      "index": 105,
      "start_time": 2500.879,
      "text": " I've heard beables, local beables be described as ontological entities. And I believe you said it's something like the input value on a C model that's assigned to a compact region of space time. And you explained what a C model is. I think it's a calculation model, if I'm not mistaken. So anyhow, what led you to write that paper? Yeah, this paper arose out of a conference on retro causality and super determinism. Retro causality and super determinism are two approaches that people have often"
    },
    {
      "end_time": 2559.667,
      "index": 106,
      "start_time": 2529.753,
      "text": " try to use in order to avoid the conclusion that quantum mechanics might be non-local. So this conference was kind of discussing those possibilities and can you get rid of non-locality using one of these methods. I think what we discovered is that there were a variety of different ways in which people were using the words retrocausality and super determinism and there was a sort of a problem where people were talking past each other because they were just using these words in different ways. So the goal of this paper was to sort of provide a clarifying story which would help explain"
    },
    {
      "end_time": 2581.8,
      "index": 107,
      "start_time": 2559.94,
      "text": " What's going on with these terms and perhaps can we have a sort of community-wide consensus about how to use these words so we can have discussions more clearly? When people hear temporal non-locality, how is that different than time travel? Yes, so time travel is much like retro."
    },
    {
      "end_time": 2591.476,
      "index": 108,
      "start_time": 2582.108,
      "text": " Causality could be temporarily local or temporarily non-local. If your vision of time travel involves people literally moving backwards in time."
    },
    {
      "end_time": 2621.305,
      "index": 109,
      "start_time": 2592.125,
      "text": " Does any of this have to do with free will?"
    },
    {
      "end_time": 2649.701,
      "index": 110,
      "start_time": 2623.677,
      "text": " Certainly if you look at the all at once style of model that does seem like it has some implications for free will because some people have thought that something that's important to free will is the idea that the future is genuinely open that in this moment as I am acting there is no fact of the matter about what my action is going to be"
    },
    {
      "end_time": 2676.834,
      "index": 111,
      "start_time": 2650.23,
      "text": " And it's in an all at once style model, that way of thinking about free will is not available to you. The whole of the universe exists at once. I'm acting now, but there is already some fact from the atemporal point of view about what my action is going to be. So I don't think that means we have to say there is no such thing as free will in that context, but certainly we're going to have to be a bit more careful about how we analyze free will and what that means. Hmm."
    },
    {
      "end_time": 2697.244,
      "index": 112,
      "start_time": 2677.278,
      "text": " So, this doesn't depend on determinism, it's just saying that there's something that's globally fixed? Yeah, so even if you have a probabilistic model in the all at once context, what that's going to look like is either it's going to be some kind of frequency constraint, as Eddie Chen has suggested, or perhaps it's going to be, you know,"
    },
    {
      "end_time": 2720.896,
      "index": 113,
      "start_time": 2698.063,
      "text": " I remember"
    },
    {
      "end_time": 2749.343,
      "index": 114,
      "start_time": 2721.357,
      "text": " Oh, gosh, I forgot who it was. Someone was saying it could be the Calvinists. Maybe it was a religion or maybe it was an actual philosopher was saying that if you have trajectories in space time, just because they exist and you can view it from a God's eye point of view, a temporally, it doesn't mean that those trajectories cause the movement. Those trajectories are the movement. Sorry, are the are the trajectory. So an agent can still be causal. There's nothing about the trajectories."
    },
    {
      "end_time": 2775.896,
      "index": 115,
      "start_time": 2749.906,
      "text": " Causing, like the laws don't cause. So can you please distinguish between the determination of an agent and causal origination of an agent? Yeah, I mean, so because I think that causation is not fundamental in any case, I think that understanding how the history comes about is not going to involve any kind of causal story. That's going to be"
    },
    {
      "end_time": 2793.797,
      "index": 116,
      "start_time": 2775.896,
      "text": " and some some more general kind of modal constraint perhaps that selects the history i mean causation is something that appears in a much higher level of description and probably is only going to be relevant in the kinds of regimes where you have agents taking actions so i think it's perfectly possible to say to say you know"
    },
    {
      "end_time": 2820.299,
      "index": 117,
      "start_time": 2793.797,
      "text": " In some sort of fundamental sense, the history was already there and was selected in an all at once way. But nonetheless, the agent is the cause of their action because causation is only suitable in that kind of regime of description anyway. And so it is still true insofar as there is such a thing as causation. It's still true that the agent is causing their actions. Right. What do you disagree most with, Carla Raveleon? I disagree most with."
    },
    {
      "end_time": 2841.527,
      "index": 118,
      "start_time": 2821.51,
      "text": " I think we still have an ongoing debate about whether it's necessary to change relational quantum mechanics in the way that we suggested. So we proposed a postulate that you can add to the theory which makes it possible for observers to communicate with each other in an absolute sense and for their perspectives to become aligned in an absolute sense."
    },
    {
      "end_time": 2868.592,
      "index": 119,
      "start_time": 2841.527,
      "text": " I think that doesn't solve the kinds of epistemic worries I have about the role of social inquiry in science, so I think the absolute story is necessary, but this is an ongoing debate."
    },
    {
      "end_time": 2898.387,
      "index": 120,
      "start_time": 2869.275,
      "text": " Now many derivations in physics rely on integration by parts and then they have this argument that and the boundary terms are zero and because of that we get so-and-so. Are there times when these surface terms are ordinarily said to vanish but because of your work on all at once you believe that to be an unreasonable assumption? Oh gosh, that's an interesting question. I actually have not thought about that. Seems very possible but I would have to think more about the technical details before I could say one way or another."
    },
    {
      "end_time": 2928.217,
      "index": 121,
      "start_time": 2898.677,
      "text": " What is self-location? So self-location refers to scenarios in which you are uncertain about your location within the universe. So you might be uncertain where you are or when you are, or if you're in a multiverse, you might be uncertain about which universe within the multiverse you are currently located in. So it's those kinds of questions pertaining to a location within a universe. And there's something between pure and superficial, if I'm not mistaken."
    },
    {
      "end_time": 2943.217,
      "index": 122,
      "start_time": 2928.695,
      "text": " What are those? When we talk about self-locating uncertainty in philosophy or in physics, I think there are two importantly different classes of self-locating uncertainty that we should distinguish between."
    },
    {
      "end_time": 2961.544,
      "index": 123,
      "start_time": 2943.575,
      "text": " So what I call pure self-locating uncertainty refers to cases where you are uncertain about what location you are out of a possible class of locations which are all located within the same world. So for example, Adam Elger's case falls into that that"
    },
    {
      "end_time": 2983.831,
      "index": 124,
      "start_time": 2961.544,
      "text": " That's a case in which Dr. Evil or a person who believes himself to be Dr. Evil receives a credible message telling him that a subject of the identical duplicate has been made of Dr. Evil and placed somewhere. So in that case, he's now uncertain whether he is in fact the real Dr. Evil or the duplicate, but most of those people exist within one in the same world. So that is pure self locating uncertainty."
    },
    {
      "end_time": 3007.773,
      "index": 125,
      "start_time": 2984.633,
      "text": " By contrast, superficially suffocating uncertainty refers to the case where you're uncertain about your location, but the possible locations you could be in belong to different possible worlds. So for example, suppose you wake up and you haven't looked at the clock yet, so you don't know what time it is, you're uncertain about your location and time. But of course, in every possible world, there's exactly one time at which you actually wake up."
    },
    {
      "end_time": 3022.005,
      "index": 126,
      "start_time": 3007.773,
      "text": " Is this related to the sleeping beauty paradox?"
    },
    {
      "end_time": 3047.688,
      "index": 127,
      "start_time": 3022.944,
      "text": " Yes, so the sleeping beauty paradox in fact involves a mixture of pure and superficially self-locating uncertainty. So I think the correct way to analyze that is to appeal to your scientific theory to determine the superficially self-locating credences and then to assign the pure credences any way you want. So the outcome is that the correct solution is the double half a solution."
    },
    {
      "end_time": 3060.265,
      "index": 128,
      "start_time": 3048.558,
      "text": " The Sleeping Beauty Paradox refers to a scenario in which"
    },
    {
      "end_time": 3083.012,
      "index": 129,
      "start_time": 3060.623,
      "text": " I'm"
    },
    {
      "end_time": 3101.34,
      "index": 130,
      "start_time": 3083.302,
      "text": " What credences should you assign to the outcome of the coin toss? Should you assign and do the credences change if you're woken up and then told what day it is?"
    },
    {
      "end_time": 3121.288,
      "index": 131,
      "start_time": 3101.664,
      "text": " various different approaches have been taken to try to decide what the correct assignation of probabilities is. Most philosophers, I think, are of the view that when you learn something about what day it is, you ought to change your credences. My view is that"
    },
    {
      "end_time": 3146.783,
      "index": 132,
      "start_time": 3121.288,
      "text": " because the coin flip issue is a superficially self-locating issue whereas the issues about when you are located are pure, the outcome is that the further information shouldn't actually change any of your assignations of credences because the right way to assign credences in these situations is always to assign the superficial self-location credences first and then having done that"
    },
    {
      "end_time": 3175.896,
      "index": 133,
      "start_time": 3146.783,
      "text": " Now was there something about when you when they say you get woken up twice that after you get woken up once you take something to forget that you woke up once? Yes, you are not going to know that you've woken up at once or twice. Now what does any of this have to do with physical law?"
    },
    {
      "end_time": 3187.329,
      "index": 134,
      "start_time": 3177.108,
      "text": " Yeah, so self-location is important to physical law, particularly in the context of physical theories that deal with multiverses."
    },
    {
      "end_time": 3214.258,
      "index": 135,
      "start_time": 3187.756,
      "text": " So in particular, the cosmological multiverse and the many worlds interpretation of quantum mechanics has a multiverse. And in both of these multiverses, in order to make certain kinds of predictions, it's necessary that you assign some credences over locations within the multiverse. You have to assign probabilities to which universe you might be within this multiverse. And so all of those approaches to making predictions in a multiverse"
    },
    {
      "end_time": 3234.889,
      "index": 136,
      "start_time": 3214.445,
      "text": " a kind of predicated on the assumption that there is in fact some objectively right or uniquely correct way to assign your self-locating credences over parts of the multiverse. And so therefore they are necessarily predicated on the claim that there are unique ways to assign pure self-locating credences. There's a right way to do it and there's a wrong way to do it."
    },
    {
      "end_time": 3261.374,
      "index": 137,
      "start_time": 3235.333,
      "text": " So I think that's wrong. I think that for superficially self-location credences, there are right ways to assign them because those credences can just be inherited from a scientific theory. But in the pure case, there is nothing whatsoever which could compel you or constrain you to assign your credences in any particular way. So any assignation of credences is fine. And therefore, you're not going to be able to get meaningful predictions out of any theory which involves this kind of multiverse reasoning."
    },
    {
      "end_time": 3280.776,
      "index": 138,
      "start_time": 3261.374,
      "text": " So if I'm right about that, that's a serious problem both for the cosmological multiverse and for the many worlds interpretation of quantum mechanics because it seems to say that we can't make meaningful predictions in that context and we therefore can't obtain any sensible evidence for scientific theories in that context because there's nothing to sort of predict and then see if it comes true."
    },
    {
      "end_time": 3302.722,
      "index": 139,
      "start_time": 3282.671,
      "text": " I'm sure you've spoken to Sean Carroll about this. So have you and what has he said or what do you think he would say? I have not spoken to Sean Carroll about this. I know that Carroll has a view of the multiverse which"
    },
    {
      "end_time": 3329.701,
      "index": 140,
      "start_time": 3303.063,
      "text": " The Everettian Multiverse in particular, which is based on the idea that certain constraints on self-locating credences can help tell you how to assign probabilities in the Everettian case. I do think this view says that approach is wrong. There are no rational constraints on self-locating credences in the Everettian scenario and so any model which takes that as a starting point I think cannot be right."
    },
    {
      "end_time": 3357.79,
      "index": 141,
      "start_time": 3333.217,
      "text": " I believe in 1907, if I'm not mistaken, Einstein had his happiest thought about free fall and weightlessness. Have you had a happiest thought? I think one moment I'd pick out is,"
    },
    {
      "end_time": 3382.227,
      "index": 142,
      "start_time": 3358.285,
      "text": " There's a theorem in quantum foundations called the PBR theorem. The PBR theorem is about the reality of the quantum state. It attempts to prove that if in order to reproduce all of the predictions of quantum mechanics it must be the case that the quantum state is a real object of thing which travels through time conveying information from one time to another and I think"
    },
    {
      "end_time": 3409.377,
      "index": 143,
      "start_time": 3382.773,
      "text": " Thinking about this theorem, one thing that struck me was that the whole theorem was predicated on the assumption of what I would call temporal locality. It's predicated on the assumption that if a measurement result depends on earlier preparation, there must be something which travels between them carrying that information from one point to another. So that I think was the origin of most of my work on temporal non-locality was that the observation that there's this"
    },
    {
      "end_time": 3422.295,
      "index": 144,
      "start_time": 3409.821,
      "text": " Do you have any thoughts about eternalism versus presentism and can you please briefly define those terms?"
    },
    {
      "end_time": 3449.224,
      "index": 145,
      "start_time": 3423.439,
      "text": " Yeah, so presentism is a philosophical view which says that in some sense only the present is real, the past and the future are not currently real. Eternalism says that the whole of history is real at once, there's no sort of privileged present moment, it's all there. As you might expect, given my views on all at once physics, I'm definitely more"
    },
    {
      "end_time": 3467.346,
      "index": 146,
      "start_time": 3450.538,
      "text": " More on the eternalist side, I think it's very hard to make presentism work in a way that is compatible with with relativity because, you know, relativity denies that there exists a global present. So it's kind of unclear what the present even is in that picture. And people have have, you know,"
    },
    {
      "end_time": 3483.029,
      "index": 147,
      "start_time": 3467.824,
      "text": " made attempts to sort of reformulate presentism in relativistic ways. But you know, I think all of them feel a bit ad hoc and not very compelling to me. So certainly, in the context of what we know about physics now, eternalism seems to me much more viable."
    },
    {
      "end_time": 3505.486,
      "index": 148,
      "start_time": 3484.65,
      "text": " Hi everyone, hope you're enjoying today's episode. If you're hungry for deeper dives into physics, AI, consciousness, philosophy, along with my personal reflections, you'll find it all on my sub stack. Subscribers get first access to new episodes, new posts as well, behind the scenes insights, and the chance to be a part of a thriving community of like-minded pilgrimers."
    },
    {
      "end_time": 3530.435,
      "index": 149,
      "start_time": 3505.486,
      "text": " By joining you'll directly be supporting my work and helping keep these conversations at the cutting edge so click the link on screen here hit subscribe and let's keep pushing the boundaries of knowledge together thank you and enjoy the show just so you know if you're listening it's c u r t j a i m u n g a l dot org kurt jaimungal dot org we talked about cubism transactional many worlds"
    },
    {
      "end_time": 3559.445,
      "index": 150,
      "start_time": 3530.93,
      "text": " What other interpretation of quantum mechanics have we not talked about that you feel fails significantly? And why does it fail? Well, the obvious ones are the sort of primitive ontology approaches, so that the Bohmian approach and the spontaneous collapse approach. You know, I wouldn't say these approaches fail. What I'd say is that at present, we don't know how to reproduce the whole of quantum field theory in these kinds of approaches."
    },
    {
      "end_time": 3583.865,
      "index": 151,
      "start_time": 3559.821,
      "text": " And there are reasons to think we may never be able to do that, or that it's very difficult to do that in the context of this particular kind of view. So never say never, but right now I'm not sure the prospects for expanding those to cover all of quantum theory look very good. And until we can show that that can be done, that's a sort of compelling reason to be worried about those approaches."
    },
    {
      "end_time": 3597.176,
      "index": 152,
      "start_time": 3585.23,
      "text": " 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?"
    },
    {
      "end_time": 3624.531,
      "index": 153,
      "start_time": 3597.637,
      "text": " 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. Rankings based on root metric true score report dated 1-H-2025. Your results may vary. Must provide a post-patients room mobile bill dated within the past 45 days. Bill must be in the same name as the person who made the deal. Additional terms apply. So what's on your mind these days research wise? Research wise, so I have been thinking about"
    },
    {
      "end_time": 3645.265,
      "index": 154,
      "start_time": 3625.811,
      "text": " One thing I've been thinking about is a problem in relational quantum mechanics. So there's this worry, relational quantum mechanics is committed to the view that all physical systems can in some sense count as observers, they can have quantum states defined relative to them. There's a worry brought up by Kasselab-Brookner that"
    },
    {
      "end_time": 3656.63,
      "index": 155,
      "start_time": 3645.555,
      "text": " It doesn't make sense to say something like a qubit is an observer because there's no way to get a well-defined basis in which a qubit could make an observation, so you just couldn't get a well-defined"
    },
    {
      "end_time": 3681.408,
      "index": 156,
      "start_time": 3657.227,
      "text": " observed value out of interaction involving a qubit. So I think he's right about that as an objection. I think the way to resolve this is to appreciate that the description of the world relative to a qubit is not going to be a full quantum hill of its face. It's not going to be as complicated as that because a qubit just doesn't have the right enough physical resources to define that kind of relative description."
    },
    {
      "end_time": 3710.538,
      "index": 157,
      "start_time": 3681.408,
      "text": " So I've been trying to think about what would be a sensible way of formulating what the world does look like relative to a qubit and thus of sort of understanding what the range of observations that something like a qubit could make might look like. Do you then generalize a quantum system to a process matrix? Why don't you define what a process matrix is? Great, yes. So process matrices are a tool developed within quantum foundations recently to study"
    },
    {
      "end_time": 3726.084,
      "index": 158,
      "start_time": 3710.623,
      "text": " Causal processes more general than those we would encounter in our ordinary space time. So the idea here is that we'll start with a set of laboratories in which agents can do various actions and we'll write down a description of the way in which these laboratories are related to each other."
    },
    {
      "end_time": 3755.196,
      "index": 159,
      "start_time": 3726.596,
      "text": " But we will not require that these laboratories have any sort of specific space time location. And so we won't require that their relationships are constrained by the causal structure of ordinary space time. The only constraint we'll put on them is that it has to be logically consistent. So they have to be related to each other in ways that won't produce logical contradictions. So what we can do then is end up with a description of a class of possible causal processes, which is much more general than what we would normally encounter in the world."
    },
    {
      "end_time": 3776.169,
      "index": 160,
      "start_time": 3755.469,
      "text": " And that is potentially going to give us an idea of what kinds of processes might perhaps be possible, for example, in certain regimes of quantum gravity where space time in the ordinary sense, it breaks down or is perhaps not present. The process matrix is another way of formulating or thinking about quantum mechanics or or what or thinking about the wave function or density matrices."
    },
    {
      "end_time": 3791.92,
      "index": 161,
      "start_time": 3776.613,
      "text": " Yes, so I mean process matrices are quantum innate here but they are much more general than ordinary quantum mechanics because in ordinary quantum mechanics we would tell a story in which you start with a state and just evolve forwards and produce everything in a well-defined temporal order."
    },
    {
      "end_time": 3821.288,
      "index": 162,
      "start_time": 3791.92,
      "text": " Do you derive the Born Rule or do you have to assume it? Do you have to postulate it somehow? In the process matrix formalism,"
    },
    {
      "end_time": 3841.63,
      "index": 163,
      "start_time": 3821.698,
      "text": " It's not clear that the born rule is even used. I think certainly understanding where the born rule fits into that picture is an ongoing project that hasn't yet been fully resolved. But with that said, you can also formulate an equivalent of"
    },
    {
      "end_time": 3868.131,
      "index": 164,
      "start_time": 3841.92,
      "text": " What's Humean supervenience and what is its relation to asymmetric dependence?"
    },
    {
      "end_time": 3894.087,
      "index": 165,
      "start_time": 3870.128,
      "text": " Human supervenience is the idea that the world is just a distribution of categorical properties over space-time. It's just, you know, one thing and another thing and another thing. There's no deeper structural connections. And so everything else, including things like the laws of nature and the facts about causation, have to, in some sense, depend on or supervene on"
    },
    {
      "end_time": 3922.363,
      "index": 166,
      "start_time": 3894.087,
      "text": " In your model, what's at the ground? What do you take as your ontological commitments?"
    },
    {
      "end_time": 3949.189,
      "index": 167,
      "start_time": 3922.875,
      "text": " That way I formulate that in the past is, you know, we start from some space of possible courses of history, you know, which might be an ensemble of, you know, human mosaics composed of distributions of facts across space-time. And then we have constraints which determine possible, determine which elements of that set are allowed by the laws of nature. And then"
    },
    {
      "end_time": 3978.422,
      "index": 168,
      "start_time": 3950.009,
      "text": " some element of that set is going to be selected and made actual. So we have a sort of space of possibilities, the constraints narrow down the possibilities and then one constraint is somehow selected. I think there's more work to be done here on understanding what the space of possibilities look like and how that space of possibilities is related to the constraints and to the properties that we see in our everyday lives, but that's the general picture that you have possibilities narrowed down and then one is going to be selected."
    },
    {
      "end_time": 4008.916,
      "index": 169,
      "start_time": 3980.162,
      "text": " So space time would emerge from possibilities plus constraints? Yeah, I think the story that we should tell about space time here is certainly still a work in progress. You know, in my previous work on the subject, I've just kind of taken space time as given and imagined, you know, let's select the constraints are just going to tell you how things are distributed across space time. But certainly that, I think, can't be the right final answer because, you know, modern physics and particularly quantum gravity"
    },
    {
      "end_time": 4032.363,
      "index": 170,
      "start_time": 4009.497,
      "text": " What would it be that selects the specific dimensionality and signature, like 3 plus 1?"
    },
    {
      "end_time": 4056.954,
      "index": 171,
      "start_time": 4035.06,
      "text": " Yes, that's a great question. Ultimately, I think at least some aspects of the way space-time is have got to come from consistency constraints. So, for example, using the process matrix formalism, for example, you can see that there's going to be a need, if you want to have consistency, there's usually going to be a need for things to occur in some well-defined order."
    },
    {
      "end_time": 4076.084,
      "index": 172,
      "start_time": 4056.954,
      "text": " add a well-defined order stops that stops processes from looping back on themselves and producing contradictions and so i think from those kinds of consistency constraints you can get already the idea that there's got to be some kind of something like a temporal dimension which is different from the spatial dimensions and i also think you can get"
    },
    {
      "end_time": 4101.305,
      "index": 173,
      "start_time": 4076.084,
      "text": " the idea that it needs to have a sort of a relativistic space-time structure from the observation that if you have superluminal signaling, for example, you can use that to create a loop which goes around and which could then also be used to create logical contradictions. So consistency is also going to give you something like the light cone structure of space-time. Interesting. I don't know yet how to get exactly three dimensions out of that."
    },
    {
      "end_time": 4130.469,
      "index": 174,
      "start_time": 4101.766,
      "text": " It would be great if there are a way to get that as a consistency condition as well. I'm not sure what that would look like, but, you know, I certainly I think many aspects of space time structure can can be understood in that sort of basic way as consistency conditions. Do you imagine that you'll be able to derive any of the fundamental constants from global laws, or is there still like, let's say alpha or G or is there still going to be some residual contingency leaving room for why these structures?"
    },
    {
      "end_time": 4157.346,
      "index": 175,
      "start_time": 4131.425,
      "text": " Yeah, that's a great question. So ADHN has written before about this idea called strong determinism, which is the idea that maybe the laws of nature are so strong that they actually dictate the whole course of history uniquely and there's only one possibility. That's in some ways an old idea. Leibniz hoped for something like that as well. It doesn't seem obvious to me how to get there from the laws that we currently know."
    },
    {
      "end_time": 4186.135,
      "index": 176,
      "start_time": 4158.626,
      "text": " And I'm skeptical that we could possibly know all of the constraints, even if there do exist a set of constraints that strong. But in principle, I think that it's certainly possible that there are constraint-based laws that we perhaps haven't arrived at yet and might be able to arrive at one day, which would give an explanation of some of those things. Do you imagine there would be specific correlations between seemingly unrelated physical parameters?"
    },
    {
      "end_time": 4209.121,
      "index": 177,
      "start_time": 4188.456,
      "text": " Certainly it's very, very possible. I mean, it's a bit hard to speculate because we don't have much of a sense of what that would look like. But certainly if we could give explanations for relationships between the values of things, that would be a very, I think, compelling piece of evidence that this right way of thinking is right. So it's certainly something to look for."
    },
    {
      "end_time": 4235.486,
      "index": 178,
      "start_time": 4209.957,
      "text": " Are you more interested in the philosophy of physics specifically or more broadly into the philosophy of science? What about metaphysics? What about ethics? Yes, I do focus largely on the philosophy of physics because my training is in physics. But I think many of the questions we are talking about in the philosophy of physics have really interesting implications for more general questions in the philosophy of science."
    },
    {
      "end_time": 4253.524,
      "index": 179,
      "start_time": 4235.862,
      "text": " So these questions about the nature of lawhood, for example, and I think once you move to an all at once style account of laws, that's going to have implications for a lot of other traditional philosophical questions about things like causation, explanation, determinism and so on, free will."
    },
    {
      "end_time": 4279.855,
      "index": 180,
      "start_time": 4253.524,
      "text": " So although my focus comes from physics, a lot of that expands more generally into philosophy of science and also metaphysics because these questions about lawhood, causation, explanation do also link to metaphysics. Ethics, I'm very interested in ethics. I've never worked on it professionally though. Cool. Do you have any advice for young upcoming researchers in the field of physics and philosophy?"
    },
    {
      "end_time": 4303.251,
      "index": 181,
      "start_time": 4280.947,
      "text": " I think my biggest piece of advice would be to work on the things that you love and are interested in. I think there can be a pressure to work on something that is currently one of the hot topics or that is getting lots of attention in the field at the time. But ultimately, I think what's most rewarding and what will be successful in the long run is for you to pursue the things that you care about and"
    },
    {
      "end_time": 4329.019,
      "index": 182,
      "start_time": 4303.575,
      "text": " What's some topic that's underappreciated that you think should be more appreciated? So I'll give you an example of something that's a hot topic right now, black holes."
    },
    {
      "end_time": 4340.691,
      "index": 183,
      "start_time": 4329.411,
      "text": " Supermassive black holes and time travel or time dilation, etc. And those are said ad nauseum in these popular science circles. So what's something else that you think people should be paying more attention to?"
    },
    {
      "end_time": 4369.94,
      "index": 184,
      "start_time": 4341.169,
      "text": " I'm on a bit of a crusade to get people to pay more attention to the epistemology of the measurement problem. I think when we talk about the measurement problem it often gets framed in terms of ontology, in terms of we need to know what is really there and what is really happening. Whereas for me I think the measurement problem is really important precisely because it ties to questions about how could we possibly know the things we are supposed to know, how can we make sense of"
    },
    {
      "end_time": 4395.418,
      "index": 185,
      "start_time": 4369.94,
      "text": " the empirical confirmation associated with quantum mechanics. And I think that a number of very popular interpretations of quantum mechanics have really big problems answering those kinds of questions. So particularly the many worlds interpretation and the observer relative interpretations have really bad epistemic problems and I think do not do a good job of answering these epistemic issues. So I really like to see our discussions of the measurement problem focus more on these questions of"
    },
    {
      "end_time": 4419.855,
      "index": 186,
      "start_time": 4395.418,
      "text": " Can you repeat these epistemological questions that you think people or physicists or foundational physicists should be thinking about? Yeah, I mean the fundamental question is that when we're thinking about"
    },
    {
      "end_time": 4443.097,
      "index": 187,
      "start_time": 4420.742,
      "text": " how to interpret quantum mechanics it is I think essential that our interpretation tells a consistent story about how we could have come to know about the theory. So for example I think the many worlds interpretation has a real problem with this because the many worlds interpretation has difficulty giving meaning to assignations of probability to measurement outcomes"
    },
    {
      "end_time": 4467.654,
      "index": 188,
      "start_time": 4443.097,
      "text": " And in particular, it seems hard in the many worlds context to justify the claim that you should expect to see high probability outcomes. But if you can't expect to see high probability outcomes, then you can't use the outcomes you have observed as evidence for the theory because you have no idea whether the outcome is one that's assigned a high or a low probability by the theory. So you can't like connect it back up to the structure of the theory you're trying to find out about."
    },
    {
      "end_time": 4491.186,
      "index": 189,
      "start_time": 4467.654,
      "text": " What's a lesson, Emily, that you wish you had learned earlier, that if you could tell your younger self, it would be beneficial?"
    },
    {
      "end_time": 4515.435,
      "index": 190,
      "start_time": 4503.097,
      "text": " i think probably as many people would tell their younger selves i would i would counsel patients that you know it takes this kind of thing research definitely takes time and work and"
    },
    {
      "end_time": 4536.186,
      "index": 191,
      "start_time": 4515.862,
      "text": " You will fail many times and many things will not go anywhere. And I think you need to, you have to be persistent and hang on and have faith that, you know, in the long run, I think you're going to come to interesting results and people will eventually come to be interested in what you're doing. And it does come eventually. It just takes time. It doesn't happen immediately."
    },
    {
      "end_time": 4554.394,
      "index": 192,
      "start_time": 4537.09,
      "text": " So was there a time maybe a year, three years, four years where people weren't interested in your work and that frustrated you or made you downcast? I think for some time I was worried that the kind of work I was doing was not"
    },
    {
      "end_time": 4575.503,
      "index": 193,
      "start_time": 4556.049,
      "text": " was not going to be mainstream enough for me to be able to make a career in the field. I actually left academia for a few years and worked outside of it because I was pessimistic about whether I could do the kind of work I wanted to do and be in the field. But eventually some of the things I was doing"
    },
    {
      "end_time": 4601.578,
      "index": 194,
      "start_time": 4576.152,
      "text": " I did get positive feedback on and that I think was enough to encourage me to come back and keep working on this stuff. And I, you know, I don't regret that. I think that was the right decision. But yeah, I think, you know, looking back, perhaps if I'd if I'd understood the need for patients that could have been avoided. Tell me about that. So you left academia for a while and then were you still publishing while you were outside? Yeah, I did."
    },
    {
      "end_time": 4629.684,
      "index": 195,
      "start_time": 4602.415,
      "text": " I did in my PhD, I mostly published on pure physics topics. After finishing, I left academia, but continued to think about particularly more philosophical topics and to publish and to write on those things. And eventually, I think came to the realization that clearly this is what I should be doing professionally. And so then then sort of wanted to switch, switch from the more physics side into the more philosophy side. How did you get back in?"
    },
    {
      "end_time": 4654.309,
      "index": 196,
      "start_time": 4631.186,
      "text": " Yeah, it wasn't straightforward, especially because I was looking for philosophy positions and had physics qualifications. But the people at the University of Western Ontario were very helpful and encouraging and found a way to bring me there and allow me to do a postdoc there. That was a very productive time, really fantastic. And so that was my route back into the field."
    },
    {
      "end_time": 4678.797,
      "index": 197,
      "start_time": 4655.009,
      "text": " Well, it's fantastic speaking with you. Thank you so much for spending your time with me. Yeah, it's really fun. Thank you. Yes. I've received several messages, emails and comments from professors saying that they recommend theories of everything to their students. And that's fantastic. If you're a professor or lecturer and there's a particular standout episode that your students can benefit from, please do share. And as always, feel free to contact me."
    },
    {
      "end_time": 4687.432,
      "index": 198,
      "start_time": 4679.241,
      "text": " new update started a sub stack writings on there are currently about language and ill-defined concepts as well as some other mathematical details"
    },
    {
      "end_time": 4715.828,
      "index": 199,
      "start_time": 4687.654,
      "text": " Much more being written there. This is content that isn't anywhere else. It's not on theories of everything. It's not on Patreon. Also, full transcripts will be placed there at some point in the future. Several people ask me, hey, Kurt, you've spoken to so many people in the fields of theoretical physics, philosophy and consciousness. What are your thoughts? While I remain impartial in interviews, this substack is a way to peer into my present deliberations on these topics. Also,"
    },
    {
      "end_time": 4743.148,
      "index": 200,
      "start_time": 4715.998,
      "text": " Thank you to our partner, The Economist. Firstly, thank you for watching. Thank you for listening. 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. Plus, it helps out Kurt directly, aka me. I also found out last year that external links count plenty toward the algorithm."
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    },
    {
      "end_time": 4789.155,
      "index": 202,
      "start_time": 4769.189,
      "text": " I also read in the comments"
    },
    {
      "end_time": 4812.602,
      "index": 203,
      "start_time": 4789.155,
      "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."
    },
    {
      "end_time": 4819.189,
      "index": 204,
      "start_time": 4812.602,
      "text": " Every dollar helps far more than you think either way your viewership is generosity enough. Thank you so much"
    }
  ]
}

No transcript available.