Cosmic Queries – The Complex Universe with Sean Carroll

I love our stable of cosmologists. This time Sean Carroll. Yes, Sean Carroll. Well, love him. Awesome. Because he's brilliant and we don't have to help out his explanations. Yeah. Is it better than anything we come up with? Yeah, and every time he's on, as well as Brian Cox or Jan 11 or Blue or any of them, I realize I don't know Jack. Nothing. Coming up. Welcome to Star Talk. Your place in the universe where science and pop culture collide. Star Talk begins right now. This is Star Talk. Cosmic Queries edition, Neil the Grass Tyson. You're a personal astrophysicist. We got here, of course, Lord Chuck Knies. Hey, what's happening? You're locked and loaded there with the question. I'm locked and loaded because we got queries, man. They're not just queries about anything to anyone. No. They're queries on cosmology to one of our cosmologists about town. Yes. One of our fave interviews. We got Sean Carroll on the line. Sean, how you doing, man? Hey, how's it going? Lord Chuck, I didn't know you got a promotion. Yeah. If you try hard, like he does, you might get one too. Yeah, I mean, no kings, but lords are okay. The occasional lord. There you go. That's right. No, I'm down with the no kings, but I'm still Lord nice. And so let's catch people up on your trajectory through life. You spent a lot of your professional career at Caltech over in Pasadena. And now you joined us back on the East Coast and Baltimore at the Johns Hopkins University. And I've got you as the homeward professor of natural philosophy. That's right. There aren't that many of those. I'm basically the only one. So it's nice. Right. This is a very retro title. It is. Okay. I think Newton had a title of natural philosophy. Right. Before the word physics was a thing. Yeah. Yeah. Favorite people out there because not only do you bring science to the public, which is something we care deeply about here at Start Talk, but you have the, for me, the best combination of astrophysics, fluency, right physics fluency, right? And philosophy fluency. Right. You put all that together and there's no boring conversation you will ever have ever true. But we're going to try to change that to. I'm going to take this as a challenge. Yeah. I don't think I can do it. So Sean, you had a couple of books recently. I mean, you're always out there, you know, talking physics smack with an interested public. You have two in a row here, space time and motion. You know, that's, that's, you know, what's left after that. Right. That's a lot. Yeah. That's pretty much everything, right? But no, not for Sean Garry. Right. You could quanta and fields. Oh, wow. Look at that. Now it is everything. Yeah. Space time, emotion, and then quanta and fields. What's left? What's left will be volume three, which is complexity and emergence. That's what I'm nearly done with writing right now. So it's a whole three part series called the biggest ideas in the universe. Yeah. That's definitely what that is for sure. For sure. You know, fields is a thing, right? That if I didn't study physics, I'd still think they were kind of imaginary. Go back to Faraday, right? Who says, well, there's magnetism there, but there's a field. What can I see it? No. But the, like the iron filings can see it. But I can't. Right. OK. But if you take away the iron filings, is it still there? Yeah. And so just, just to, what did it take to get everybody comfortable with the idea of a field? There's a great question because it wasn't easy. It took a while. You know, Isaac Newton worried about the fact that he didn't know about the concept of fields. He said that there was a gravitational force between the sun and the earth. And it depends on the distance, you know, the inverse square law, the bigger the distance, the less the force. But he didn't know how it got there. How does the earth know where the sun is, how far away it is, how massive it is. And he said, you know, this is over my pay grade. I'm going to leave this for future generations to decide, which is not the kind of thing that Isaac Newton said very often. So it wasn't until the 1800s. So he knew something was up. He knew something was up. He needed further explanation. Yeah. Action at a distance. You know, Einstein famously said spooky action at a distance for quantum mechanics. But even in Newton's time, there was this weird thing. What is it that takes the gravitational force and moves it from the sun to the earth, et cetera? Can vice versa. Yeah. In some way, there was an answer there from Laplace, Pierre Simone Laplace. But it wasn't until Faraday, like you said, that he starts moving magnets and watching electrical currents pop up in a wire next to it, like not there, not touching it, right? Like through empty space, something happened. And the great thing about Faraday was he was an absolutely genius, intuitive physicist. He was not the math expert that you sometimes need to be. So Maxwell, James Clark Maxwell, came along with a huge admirer of Faraday and basically made it all mathematically respectable and said, yeah, there's these things called the electric field and the magnetic field and they fill all of space. And you can't see them. But we can predict what they're going to do and they're super duper important for explaining everything. I think Faraday, if memory serves, none of his published papers does an equation of any kind appear. That's possible. I didn't know quite that fact, Lloyd, but it's absolutely in keeping. He was thinking about, in fact, it wasn't even fields that he primarily focused on. He imagined lines of force. So out of an electron, there's an electric field, we would say now, but he thought they were literally lines of force filling all of space. And Maxwell's first papers were about trying to make mathematical sense of lines of force. And he eventually said, nah, it's better to think of fields with little vectors, so like little arrows at every point. And then the lines are sort of moving in the direction of the arrows. And that will happen in the 19th century. All happened in the 19th century. And the great thing was, if you think of the number of different apparent phenomena in the world that we now think of as electricity and magnetism in action, right? Heat, light, radio waves, x-rays, the magnets, all this stuff, like very, very different things, all explained in just two fields, talking to each other, electricity and magnetism. That's amazing. That's completely crazy. And I was just thinking, I go through this sort of existential moment, maybe once a month. I'm sitting there and I press a button on my smartphone, and it changes the channel on my TV. Right. And then I press another button, it starts my car, right? Which is three miles away. And I'm thinking, this is magic. Yeah, basically. Yeah, and this is why writing books is good, because you write a book and you say, you point your remote control, your TV, and a radio wave comes out and turns it on. And you get many emails saying, that's an infrared wave, not a radio wave. You don't know what you're talking about. But they're all different manifestations of electromagnetism. And so, no, no, wait, my cellphone is not in the front. But the remote control is. Yeah, that's for sure. Yeah, exactly. Like, who knows these things? I can't keep track of these things. I'm just a theoretical physicist. It's funny. While you guys are talking, I'm sitting here with my iPad, and I'm taking my finger and moving the screen up and down to this, is worried above your right. And it's exactly the same thing. Like, that's, isn't that the electromagnetic field on my finger? Basically, everything is the electromagnetic field. The other than gravity, it's all electromagnetism all the way down. We live it. We just live it. There's a hugely important philosophy of science lesson here, because like Neil said, you can't see the electric field or the magnetic field. But they're clearly everywhere. Like, we have equations that describe them exactly and make predictions and fit all the data. Therefore, we accept that they are there. You don't need to see them with your eyes to have evidence that they're part of reality. I do a whole stand-up bit about that. I try to beat that into chuck every time. When I say the universe is under no obligation to make sense to you. Which, believe it or not, I can accept. You must make sense to me, because I am the center of all things. So, Shaw, what's this latest paper we have you published here, a co-authored, what Hawking radiation looks like as you fall into a black hole? Was that something that needed to be addressed? It's something that I've worried about for decades. And honestly, here's the question. There's two things that we think are true about a black hole. One is, if you're standing very far away, and you look at the black hole, Stephen Hawking says black holes give off radiation. Not that much radiation admittedly, especially for a big black hole, but he, again, has an equation that predicts exactly how much you should see. The second thing is, we have this feeling, no one's ever done it, but we have this belief that if you fall into a black hole, you see nothing special when you cross the boundary. You've been across the event horizon, right? It just looks like ordinary empty space everywhere. But these two statements seem a little bit contradictory, because if I'm standing far away, and I see radiation coming out, and then I just fall in, right? I just, I stopped my rocket ship or whatever, and let myself fall in. You know, Neil, that you should see that radiation get blue-shifted. It should look brighter and brighter and more and more energetic. So why does it turn off when you hit the event horizon? What actually happens? What is it that you see? And it turns out this is 100% implicit in all the equations that we have, but took a lot of work to actually pull it out. And the answer in a very short, slightly oversimplified form is, there is high-intensity radiation when you're crossing the event horizon, but you're moving so fast that you don't have time to observe it. So it looks to you like there's nothing there. What? Yes. Oh. I mean, in a Heisenberg uncertainty principle way, you don't have time to observe it. Yeah, exactly right. And by the way, before I forget, I got to give huge credit to Chris Shalou, my co-author on this. Your co-author, yes. He was a grad student at Harvard who just graduated, did all the heavy lifting on this and other projects, and he was fantastic. So he got the right answer after other people's got it wrong. Graduates students, they have to have an exception to the slave amendment in the Constitution for graduate students. Right. So you know, are they only three-fifths of a person? No. Three-fifths of a scientist. Yeah. Three-fifths of a scientist. Is that what they are? No. If graduate students did the heavy lifting, right, there it is. But see, that's the whole, Shalou's in the Bahamas and his graduate students do it. And that's the way it's supposed to be. So I'm already did his work. Okay. That's the whole idea. I would have loved to do the heavy lifting, but for his sake, I needed to let him have that experience. You know how it is. Of course. Yes. I mean, listen, Leonardo da Vinci, when he painted, he had artisans that worked under him. Yeah. He painted a work. And then you come in and you sign in there. No, but I will tell you this, that in physics and astronomy, in our journals, it is not our tradition to put our degrees after our name, the way it is in the social sciences. And why is that? Well, I made up a reason why that's good, but I don't know if it had different origins. And Sean, you might have some insight here. If you didn't otherwise know the people, you have no idea who a senior, who is junior, because any brilliant idea can come out of anybody. Gotcha. Even your students. Right. And so there's no reason to segregate who's got title and who doesn't, because a brilliant idea is a brilliant idea, no matter the package, and a stupid idea. It's a stupid idea. No matter who comes up with it. Yeah. I like that. I like that system. It's very egalitarian. Yeah. I like that. Hi. I'm Ernie Carducci from Columbus, Ohio. I'm here with my son Ernie, because we listen to Star Talk every night and support Star Talk on Patreon. This is Star Talk with Neil DeGrasse Tyson. Sean, one other thing before we get to our Patreon questions, something that's fascinated me for decades ever since I could think about this question. And that's the arrow of time. Some of my earliest books in middle school are all about time and how it passes. And why do we know time is going forward rather than backwards? And you have some emergent thinking on that? I absolutely do. This is something that was hugely important for me in my career. The arrow of time is just the fact that the past and future are different from each other. Like I can have photographs of the past. I cannot have photographs that are truly representing what happens in the future. AI's got your future. Lord Chuck can do it, but I can't. So why is this true? An Aristotle wouldn't even have had the question. There are different things. Why is an elephant not an orange? What are you even asking? But once Isaac Newton comes along with his theory of physics, suddenly the distinction between the past and future disappears. These equations don't treat the past and future differently. It turns out long story short that it's a cosmology question. The early universe, 14 billion years ago, near the Big Bang, was in a very special organized state and it's becoming more disorganized and higher entropy, as we say ever since then, that's where the arrow of time comes from. But okay, why was the early universe like that? And that we don't know. So I wrote a paper about this 20 years ago and I'm revisiting that now to try to improve upon it. We still don't know, but I do think we're making progress in that direction. Well, I hope so after 20 years. That's not very long that it's been the universe. Yeah, I was going to say, excuse me, I'm both universe on me. It's a fourth of your life, it's a fifth of your life. The universal weight. We know which direction time moves because certain phenomena we would never see in reverse. Like some famous ones that you drop a blob of ink in water, the ink will disperse. You never see that happen in reverse. Right. If you're just eavesdropping on a scene and no one told you which way time was pointing, just by phenomena that occur, you should be able to know. You should be able to figure it out. Like you never see an orange fall up from the ground back onto a branch. Right. But these are, you're picking good examples, but what lets admit, you're picking the easy examples. We understand those examples, but I can make a choice about what to do right now. Like I could make a choice right now. This is the most boring podcast ever. I'm going to storm off and not do it. You won't be the first. But I can't make a choice now, not to have come on the podcast in the first place. I can't make a choice that affects the past. Oh, look at that. Oh, good. That's right there at the boundary of physics and philosophy. Both the physicists and the philosophers need to think about this. And again, we have good ideas, but there's still work to be done. Wow. Well, now you got me thinking about the multiple timelines and parallel universes and every single, like if we are on a, call it a trajectory, every choice that we make, all those other possible trajectories from this point of decision still continue forward just without me. So what the hell is happening there? Not sure if I'm quite on board with your explanation there of what's going on. Well, no, what I'm saying is I'm being way too literal, so what I'm saying is the possibilities of all those trajectories. What are the many world's hypothesis? Is that what that is? That's what you're trying to say about that. Well, it's pretty close. I mean, many worlds is like really down to earth and an equation base. Because the Schrodinger equation of quantum mechanics tells you what set of things happen in the future and which don't. And it's not because you're making a decision that creates a difference between one world and another. It's because of entanglement in the underlying quantum structure of reality. But we do have reason to believe that there are other copies of the universe where things turned out a little bit different. And you can all, if you have an iPhone, you can download an app called Universe Splitter. And I'm a big salesman for this app here. I don't get any commission or anything, but I think everyone should get it because when you're torn between two decisions, should I take this job or should I just continue living a life of leisure, you can ask the phone. And it will plug in these two options. And it will send a photon down a beam splitter that has a 50-50 chance of saying, you should take the job or you should just stay sitting around. And then there'll be, if you do it, if you obey the instructions, you know there will be a world in which you did the other thing. That brings me to my question. Oh, you got a question before we start before we have a strong and specifically, did you pay your flight all those a month? I'm a OU. I'm funding another world he did. In another world. I made it. That's funny. All right, so on. This is specifically for you, okay? I had this question. All right, it's your question. It's my question. First of all, you have to be familiar with this experiment. In the double slit delay choice, quantum eraser experiment, okay? I know you can worry about that one. Yeah. No, I really am, so on. I'm dead serious. I told Neil, this is keeping me up at night. Sean, that's a thing. It's a thing. Yeah, it's a thing, right? It's a double slit delay choice quantum eraser experiment. Okay, I'd never heard of this. Okay, go. Okay. And maybe it's all, I don't know. Maybe I read about it and I'm just like, this is crazy. It may be his BS. I don't know. Give it to me. All right. So it appears that the photons know they're being measured. Like they actually know. All right. So the signal photons and the idler photons show a constructive wave interference pattern when they're not measured by a detector. But there's four detectors and they can't know because of the way the detectors are set up because the photons are split and some go on not to be measured and some go on to be measured. Okay. Now, here's the deal. There is no wave interference pattern when they are measured. So this makes it look like they know when they're being observed. I can understand the whole explanation of entanglement. I don't know why. I should say I can accept it. I don't know why it's easy for me to accept that, but I can just accept it. What I can't know or understand is a particle knowing that it's being watched. So are there any hypotheses that would explain why this thing would know? All right. So that's just that your query there sounds like you just need the double slit experiment. No, I'm still distracted by the rest of what it's called. No, this is beyond the double slit experiment because well, maybe I'll just show on it. Just show on it. I can explain it. But I'm probably not going to do explain it as eloquently as so on. The way the experiment is set up. It's a, yeah, the double slit experiment is of course a famous thought experiment originally. They wrote down what it should do long before they ever did it to illustrate the magic of quantum mechanics. You have a single electron going through two slits. It's detected somewhere on the other side. And it's just a dot. You can't figure out that much from the dot, but you do that many, many, many times. What you see is an interference pattern. It's like a wave went through the two slits and waves go up and down depending on how far away they are from the target. And so a wave going through one slit can interfere with the wave going through the other slit. And that's what you see in the distribution of dots on the detector screen. So the miracle occurs when you observe which slit the electron goes through, right? Because in the Copenhagen usual way of thinking about quantum mechanics, when you observe the electron, you collapse its wave function. It's no longer going through both slits. You saw it go through one or the other. And magically the interference pattern goes away because indeed you changed the electron dramatically by observing which one it goes through. So that's all standard stuff everyone, you know, and their mom learns that in kindergarten when they're learning about quantum mechanics. The delayed choice quantum eraser experiment is a hilariously convoluted elaboration of that which makes people feel bad for no good reason at all. Thank God. I actually wrote a blog post about it called the notorious delayed choice quantum eraser where I make fun of people who are trying to make you lose sleep because of this. Well, they got to me. They got it. Yeah, we're all victims here, I think. So the way that that works is rather than just observe whether the electron goes through the left slit or the right slit, what do you mean by observe? You mean like maybe you with your eyeball or with some measuring apparatus have detected it. You just entangle it a little bit like you entangle it with one little particle, okay? Then unlike if you personally had observed it, you could imagine unentangling it. You could imagine not letting it get the interference pattern destroyed or you could imagine having it be destroyed. And you can make that decision after the electrons been detected. That's the slightly spooky part, right? That's the spooky part, right? If you were the kind of person who spoke a language of the electron goes through one slit or the other slit and it's making a decision, then what Chuck says, like it sounds like the electrons decision was affected by what I did after it was detected. Oh my God, how could that be? But if you just talk the language of a wave going through and becoming entangled and taking quantum mechanics seriously, all of this is 100% what is predicted. By the Schrodinger equation of quantum mechanics without anything knowing anything, anything making any choices or anything going backward in time. Okay. So there. So there you have it. It's hard to explain, but I encourage people to Google notorious delayed choice quantum eraser and they will find my blog post and they will hear it all. And this is literally the chapter I wrote for my book, Something Deeply Hidden, which is all about quantum mechanics. And I read the chapter and said, this is too much. Like they don't need this. This is too complicated and specific. So I just made it a blog post instead. Excellent. And what do we find that blog post? On my blog, preposterousuniverse.com slash blog. But again, if you just Google, late choice quantum eraser with the word notorious in front, my blog post will come up first. I promise you. Proposterous universe. Proposterous universe. That's preposterous. Exactly. All right. Well, that was good, man. All right. You got your zero dollars worth of that one. Yeah, that one zero dollars worth of that one. It's an idiot. It's an idiot. It's a perfect example of rather than trying to demystify quantum mechanics. Sometimes people try to mystify it. They try to make it sound even more confusing than it is. Even more confusing. Quantum mechanics really is confusing. You don't need to make it sound more confusing than it is. That's what this is. That's what I, and you're absolutely right. Well, that's cool, man. I'm, well, I appreciate that. Okay. Here we go. This is from our buddy, Kevin the sommelier. And he says, if dark matter were a wine varietal, would we be at the, I know it exists, but I can't quite describe it stage or the, I swear I taste something, but everyone thinks I'm making it upstage. That's funny. One or more grounded note for the holidays. Gaza promise. Gaza. Gaza. Gaza. Gaza. Like, Gaza. No, G-A-J. It's Italian. Okay. Gaza promise, which is a beautiful, super-tusk and will pair incredibly well with any roast that you were planning. Oh. And you're familiar with this. Gaza promise. It's expensive, but it's good. Okay. All right. And you say that like, Chuck, you can't afford it. That's what Jesus said. That's what I was here. That's all I heard. You were like, Gaza. Yeah, Chuck, you can add afford it. Okay. So maybe one day I'll pour it for you at my house. In the meantime, keep dreaming. But the yellowtail is good, Chuck. Don't worry. You'll do it. You're too much Chuck. It's too much Chuck. Come down. So in that question, I guess he's trying to, using his wine expertise, trying to probe what's really going on with the dark, the matter, dark energy or both. No, he said a dark matter. Just dark matter. Yeah. Yeah. Yeah. Yeah. Yeah. Yeah. Yeah. Yeah. Yeah. And doesn't have to be a particle. Ooh, that's a tough one. You made it tough. I had an easy question. You threw me a softball there. See, this is what I do, man. You just saw what I did with that stupid delay double slit thing. I can't help it. And Neil, we just did this earlier. We were together earlier before you got on. And he was just like, Chuck, you overthink everything. Just calm down, bro. Look, you know, back in my day, when Neil and I were young, it was perfectly okay to think it maybe dark matter didn't exist. In other words, there were absolutely things going on in galaxies and clusters of galaxies, things like that that looked like dark matter. Looks like there's more matter in a galaxy than we could attribute a count for just by counting the stars and the gas and the dust. But maybe there was something weird going on with gravity, you know, maybe Isaac Newton and Albert Einstein didn't have the last word. We've long since passed that phase of the development of cosmology. I think a lot of people haven't caught up because we've learned so much more from the leftover radiation, from the big bang, the cosmic microwave background, from gravitational lensing with clusters of galaxies, from the growth of structure of galaxies and clusters and things like that. Dark matter exists. It's really there in some form or another. Now, maybe gravity is also modified. That's perfectly okay. But yeah, there's something called dark matter. Is it a particle? Well, we got to admit. We don't know what it is. The range of possibilities goes from some tiny fraction of the mass of an electron to the mass of the moon or something like that. There's a very, very large range of possible masses the dark matter could have. If it's a particle, could it be something beyond a particle? It always could be like anything is possible. But boy, it really acts like particle like. We know a lot about where the dark matter is, how much of it there is, how fast it is, how fast it's moving. It looks exactly like some massive, slowly moving particle that was sort of still stationary in the early universe and started moving ever since then. So it's our job to go actually find it, then we'll know. So two small points. I, I, whenever given the occasion, I don't describe it as dark matter because we don't know it's matter. But it is definitely dark gravity. That's what it is, right? Because we're tracking gravity at every turn that we say we're measuring the dark matter. So I think that's the most honest way to describe it. Because Sean, you've seen this. There, there, there, there, clickbait. There's a news article that says, you know, scientists may be wrong about dark matter. Of course, it might not be matter. It might not be matter. Yeah. But we can't be wrong about dark gravity because we don't know what it is, right? I'm just trying to distinguish that. No, I think that's a, that's a perfectly good and fair distinction. But I think that I would just be more conclusive about what we do know, you know, like I said. And you've sounded very good there. You've sounded really good. In the 80s, what, what we were discovering was there's more gravity at the edges of galaxies than there is that you would predict from the stars, etc. inside. So okay, maybe gravity is different. But nowadays we see gravity where there is no ordinary matter to cause it. So it's not just that the strength of gravity is different, but it's just pointing at something which we're not seeing. So that's dark matter. You said a moment ago that we might one day need to modify gravity, but that's not what we need to do to explain dark matter. It is not sufficient to explain dark matter. We need extra stuff out there. And just to be super duper clear, because again, much like the notorious delayed choice quantum eraser experiments, sometimes people like to make things harder to understand, rather than easier to understand, there are people who have theories of modified gravity, where they've changed Einstein's theory of gravity and they say, I can explain away the dark matter. But when you look at their theory of gravity, in addition to changing gravity, they've also put new sources of gravity in there, which are just dark matter. Right. They break the universe in the process. Right. Okay. Kevin Kudos for the creative posing of the question. This is Rachel Ambrose and Rachel says, Hey, Rachel here from Austin, Texas. I'm a big fan of Sean and his Mindscape podcast. Thank you, Rachel. I've been thinking. Product placement. Rachel says, I've been thinking about the spinning universe hypothesis, which says the entire universe may be rotating very slowly as a whole. This was hypothesized to help resolve the Hubble tension, but I was thinking if it's true, could this also help us explain dark energy as a kind of centrifugal force or centrifugal depending upon how you want to say it? Yeah. Look, I'll be super honest. And my honest answer is I don't know. That sounds like a research program. Rachel should write a paper about this and submit it to the physical review. I doubt it. It was the slightly longer answer because if the universe is rotating, then that tends to break the isotropy of the universe. Okay. Got to bless you for that. I'm going to fill you in. Isotropy just means things look the same in every direction. Okay. Statistically the same. Statistically the same. I think that's right. That's right. There's not like a big hot spot in one side of the universe and cold spot. On the other side, it's more or less the same average everywhere with little fluctuations around it. And we have that right now. That's exactly what we have. Yes. And so once you start messing with that, can you mess with it like just a little bit and maybe no one has noticed yet? Sure. You absolutely always can. But it's hard to do that. And the theory that we have for dark energy with Einstein's cosmological constant just does a really good job at fitting the data in a sort of a simple direct blatant kind of I. Here I go kind of way. So I'm absolutely open to creative new things like the rotation of the universe. But where would that come from? I'm not sure. And what other effects would it have on observable quantities? I'm also not sure. So that sounds like a work. Okay. Very cool. Plus I think we still need verification that net angular momentum is manifest everywhere. I think it was just one pocket of the universe where they made this measurement. And so you would need to do more of the universe to reveal this. Right. If it's really true. So it was just, it was the, it's which way spiral galaxies are rotating. Right. If there's a net rotation in one direction over here, that says there's something going on in the whole universe. Gotcha. These outskies wouldn't know about each other necessarily. Because something is that they would be responding to the same thing. Exactly. Correct. Correct. Okay. Anyway, there's just just to so people know that you got to be careful about these things. There was one study that had the brilliant idea. It was a while back. So we didn't have, you know, the computers weren't there. They had volunteers. There was like citizen science. They said, here are some pictures of spiral galaxies. You go through them. You citizen scientists and tell us. Are they counterclockwise spirals or are they clockwise spirals? Okay. And you would expect it to be 50, 50, but it was like 70, 30. Like there were a lot more clockwise spirals than counterclockwise spirals. And the astronomers were like, oh my God, what is going on? And someone had the brilliant idea. Okay. Let's give the same galaxies to the same people. But let's take the mirror image of them. Let's flip them. Ah, what a smart idea. And guess what? Still 70% clockwise galaxies. It was people were seeing things. People are not an objective. Get people out of the equation. Yeah. Yeah, there you go. So you just got to be careful about all these things. Sean Browning says, hello, this is Sean Browning from Hood River, Oregon. In a previous episode, Neil stated that if you were to fall into a black hole, that would see the future in of the universe unfold or you would see the future of the universe unfold. Behind you. Right. Yeah. If that's true, then what would happen if the black hole finished evaporating before the universe ended? So I think that the details matter here. You know, there's a way that we have a thinking about black holes that is sort of idealized. Like I wrote a textbook on general relativity and you can learn about black holes in there. But the real world black holes are messy and they're made of stuff and things like that. So I don't actually think it's true that you see an enormous amount of the past of the universe in a real black hole. In a real black hole, you would, as you know, get spaghettified and die very quickly. Right. So if you're in a real evaporating black hole, you would first get spaghettified and then you would be released as a stream of black body radiation. And none of you is experiencing anything here. So I think that you don't need to worry. You would see more maybe than you would if you were outside the black hole. But there's no parent paradox that you're going to see the whole thing. Got you. Okay. You're a very literal son. What is, if your time is slowing down as you near the black hole, then the time for the rest of the universe is speeding up. Right. So you're normal and the rest of the universe is speeding up. So I think that's the foundation of this question. That is. However long it takes you to fall into the black hole, will the universe or vice versa? Will one of them live out their days before the other one finishes what it's doing? I think you should always think about, I mean, what I would like is that everyone in the world thought about spacetime diagrams and light cones. You know, your past light cone, which is the set of all things that can send light signals to you without moving fast from the speed of light. It never covers the whole universe. It never sees the future. It never sees things that are further away from you than the speed of light can get. That's true whether you're inside a black hole or not. So there's some quantitative question about how much you see, but there's no worry you're seeing things that didn't happen yet before the black hole evaporated. Wow. That's a bummer. That's a bummer. You're the one falling into a black hole. There's other bummers you have to worry about. Let me tell you this is true. This is not your biggest bummer. It's not the biggest bummer. All right. This is Shadow Dominic and he says, hello. He's named Shadow Dominic. Yeah. All right. He says, hi, this is Dominic from Madison, Wisconsin. If you could instantly know the answer to one currently unsolved physics problem, no strings attached, was that a pun? No. You're staying with me. Yeah. Was that a pun? What are you doing, bro? As which one would you pick and why? I mean, the cheating answer is, yes, tell me the theory of everything. That's it. Then I could like work out everything else from that. Let me, let me double up behind you. What gives you the confidence that a theory of everything even exists? Because the universe exists. No, no, no. I'm not accepting that. No, don't tell me. No, no. So you should accept the universe, Neil. No. It could be that quantum physics and general relativity in this universe never come together and there's nothing that would ever bring them together. That's just how the universe is. We're invoking a philosophical bias beauty to even assert that there is one theory of everything. Nope, that's not true. Oh, tell me. Oh, the universe exists. There is something that happens, right? We don't know the best way of summarizing what happens. The best way of summarizing what happens in the universe might just be to literally list everything that happens. That would be a terribly uninformative theory of the world. We think we do much better than that. I'm not saying that the theory of everything is simple or elegant or fits on an napkin or a t-shirt or anything like that. But there is some full and complete description of the universe. The fact that you said it could be a very long account of everything that happens. But if it's everything that happens and then everything that happens. And if everything that happens. Yeah, okay. So that could be just a really messy, ugly, not philosophically beautiful theory of everything. Because this is a page in the book for everything that happens. Right. Right. Because I'm very much in agreement with the philosophy that we should not be going around telling the universe how to behave. We can't decide ahead of time what the universe is like. It's absolutely possible that the ultimate explanations are not that simple. I actually don't believe that. I think the ultimate explanation probably will be really, really simple. But I don't know. Yeah. What if you can't access that information? Like it is non-accessible on this plane of existence. But the answer is there. Or you're saying are we just too stupid as humans? That's another way to ask your questions. Yeah, get to this. You think that we have sufficient intellect to even get there? Yes. Oh, that's interesting. I love it him some hubs and pomeosapiens there. I mean, again, we don't know. But what I would like to do is just think about how far we've already come. 100 years ago, we had just finished getting quantum mechanics. We didn't know about the expansion of the universe. We certainly didn't know about quantum fields and the standard model and all these things. And we didn't know about other galaxies yet. In 1926. Holy moly. Yeah. Of course, it's possible we'll never get there. But the rate at which we've been learning things, and this is just the past 100 years. Think about the past 1000 years and 10,000 years from now? We're going to know a lot. If we're here. Yeah. If we are here. One of the hypotheses that I thought was intriguing was that as we measure the limits of whatever the limits are of what we're measuring, we might reach a cut off like in a Truman show, an example where he goes to the horizon, but the horizon is a painted sky. So we look at the energy levels of gamma rays or we find a cut off that would have no natural explanation other than that somebody programmed this and they had to put in a limit because they couldn't put infinity into their software. Yeah. Yeah. I think that's, it's fascinating to imagine at a slightly more detailed, careful level, what are the ways that we could become convinced that we're not ever going to find a simple theory of everything? That's another way to think about it. Yeah. And things like that are maybe we get evidence that we live in a simulation or that the laws of physics are different from place to place in time to time. And so even if we get them figured out here, we won't know them some other way. But again, what's amazing to me is how rock solid and reliable the laws of physics are, like we're able to extrapolate them way past the environments in which we invent them and they still work. I just got to put one example on the table, which is Big Bang nucleosynthesis. This is my favorite example of exactly this. You know, a bunch of scientists, mostly in the 20th century, figured out the rules of nuclear physics, the rules of gravity, the rules of cosmology, and they realized the universe is 14 billion years old and they extrapolate these rules back to when the universe was one minute old. And they make a prediction for how much hydrogen and helium they should be and they got it right. Like what in the world? That's the impressive thing to me. Like we can figure this stuff out. Fantastic. Oh, that is well, that's that's that's very encouraging. And there's another example I got from Rich Gott, George Gamma, makes a prediction based on this early nucleosynthesis of the universe that there should be a residual temperature of the universe. And that would be the temperature pretty much, not pretty much, that would be temperature everywhere, everywhere. So, so he, so think of the level of extrapolation this required. And he said the temperature would be 10 degrees. Okay. So then we finally measure it. It's three degrees. Wow. Okay. So you can say it was an idiot. He really scrapped the bed. The standards were lower back then, Chuck, it was a very different day. But Rich Gott said that's like predicting that a 10th foot flying saucer would land on the lawn of the White House. But it was a three foot flying saucer. Yeah. That's pretty wide. Oh my gosh, it's a flying saucer. I'm like, right, yeah. No, that's super impressive. Yeah. All right. Okay. So you, you helped me talk me off the ledge there. You know, every now and then I just wake up skeptical that we're going to ever figure anything out. And what we have figured out, I need to be more impressed with that. Keeps a good patient. Yeah, I know. Like it'll take some time. Thank you. So one, what else you have? All right. This is Shota. I'll say Ziziguri. Ziziguri. I'm betting that it's so not right, but go on. Easy for you to say. All right. Shota Ziziguri. Anyway, hello, this is Shota from Georgia. What a name like that. Anyway. Maybe it's Soviet Georgia. I mean, Georgia, it's not Soviet anymore. It's not Soviet anymore, but yeah, I know what you're saying. They say, or Shota says, regarding the many worlds interpretation, is it simply a mathematical framework we use to describe quantum behavior and apparent wave function collapse? Or do you think it represents an actual physical process in which the universe truly branches into separate, real worlds? How real are these other worlds? That's the many worlds. Yeah, it's a great question. So the way I like to think about it is we have an equation, the Schrodinger equation. You can read about it in my book, Quanta and Fields, by the way. And the equation makes predictions for what's going to happen. And the simplest reading of the prediction is that the universe branches into these many copies slightly changed because in one, the electron is spinning clockwise and the other is counterclockwise, but otherwise the universe is the same. And we live in one of those possibilities. We don't see the other ones, and it seems to fit the data. So then you say, OK, what about all those other possibilities that we take them seriously as real? And the answer is, if you take our possibility as real, then you have two choices. Number one, either you take the other possibilities is also real. You know, you treat them equal. They're all there in the equation. I'm going to take them seriously. Or you tell me why I shouldn't treat the other ones as real. And there's a long history of people trying to come up with reasons why the other worlds aren't there. The following worlds, theories of quantum mechanics, as Ted Bunn has called them. It turns out to be hard. It turns out to be awkward and doesn't fit in well with modern physics. You can try to do it. It's a free country. You know, go nuts. Like, invent all the theories of quantum mechanics you want. Or you can just say, yeah, they're there. I don't care. They don't bother me. They don't take up the resources we have in our world or anything. It's not grabbing a beer in the middle of the night for me. That's right. You know what I mean? And just correct me from wrong. When we think of what's called the Copenhagen interpretation, that's the many world-type offices, correct? No, that's the opposite. The opposite. So describe the opposite. Copenhagen is the one that was invented by Bohr and Heisenberg back in the day. And Bohr is the only one who's Danish in that pair. Yes. That is correct. So why does he get the name? What does his hometown get the name of the idea? He was slightly older than everybody else. And he founded the Institute for Theoretical Physics in Copenhagen where all this work was done. So he had the money. Heisenberg was a postdoc at this time. Bohr was a famous physicist. So Copenhagen puts in the laws of physics the notion of measurement. It says that when you make a measurement of something, a dramatic effect occurs where the wave function, the describes the system completely changes. The real hard core of Copenhagen philosophy is that there is no such thing as what the system is doing before you measure it. The whole of reality consists of nothing but measurement outcomes. That's what Copenhagen actually says. Okay. I remember learning that, but I didn't connect it with the Copenhagen interpretation. If we were to divide into camps, that's my camp. It took me a while to grow a custom. Let me restate what you just said. It doesn't even make sense to talk about it unless there's a measurement of it. To talk about a state of a system unless you can measure it. And then the measurement is the reality of what things are. Is that, is that, is that, did I oversimplify that? No, that's actually quite good. I'm all about, like, the universe doesn't care about you and your measurements. The universe is just out there. And I'm just going to believe in it. Why not? The universe is impersonal and the word measurement should not appear in the fundamental laws of physics. Wow, that's cool. I like that. I like that. All right. This is Rory L who says, hello, Dr. Tyson, Lorde Nice, Dr. Carol, Rory from Colorado here. The happy recipient of a gift subscription. Wow. Somebody gave him a Patreon gift subscription. Hey, guess what? You guys can do that too. Give a gift subscription to somebody else by my year of Patreon. And by the, that's a cheap ass subscription. It really is. But you can make somebody really happy for not so much money. Right. Okay. Dr. Carol, which science discipline do you rely upon the most when studying a possible multiverse or is it a combination? Thanks. And throw philosophy in there as well as a, as a branch of thought. Why not? Yes. So, what questions are you referring to? Like, is it mostly a philosophical question or is it mostly a physics question? Or is it mostly quantum physics or, or relativity physics? How about that? Add that in there. Sure. There's also, right. Different parts of physics are also very relevant here. But this is exactly why I chose to title myself a professor of natural philosophy because I don't think that there's a boundary or a dividing line between the philosophy of it all and the physics of it all. You are never going to invent quantum mechanics by sitting around in your armchair, thinking about how the universe would be, right? You needed experiments that gave you, giving you data that you couldn't otherwise account for. And that's what led us to quantum mechanics. But then quantum mechanics leads us to this idea of many worlds happening every time you make a quantum measurement. And philosophy becomes super important for accounting for that, for understanding that. The physicists bless their hearts, have done a terrible job. Most of them just live in denial and don't even want to think about this. And it's kind of an embarrassment, but the philosophers have at least taken up the challenge. I don't think that we're done yet. I don't think we have a perfect understanding of everything. That's good. That's good for me, full employment for me and my graduate students. We still have things left to do. But I think you need them all. There's no one answer there. It's everyone from the South knows. If you say, bless this heart, the next thing isn't going to be a nasty insult. Well, yeah. And the South blesses heart means F you. They just, they got it down to a science. The most polite F you possible. Bless us heart. Bless us heart. This is John Mayer. He says, hi, I'm John from San Diego. And listen, every episode I listen to, it's my jam. Thank you. Dear Dr. Tyson and Dr. Carol. Can we can we can we advertise that? Start talk. It's my jam. He says. All right. He says Dr. Tyson, Dr. Carol and the energetic Lord and I's please help me understand how a photon traveling between stars experiences no time yet also has a wavelength pattern and changes over space and time. Is the wavelength a function of the photon or is it a display function of the space time medium within which it is traveling within or is it even something else? Oh, that a great question. People love this question. I get this question. It's and they don't like the answer, which is that photons don't experience things. They're just single particles. Electrons don't experience things either. I think that we get in trouble because we are complicated creatures, right, with senses and memories and things like that. And so we have a feeling for what it is like for time to pass. And that wouldn't apply if we were moving at the speed of light because then no time would pass. But when we talk about the wavelength of a photon or its path through the universe, we're not talking about its inner experience. We're not talking about its first person point of view. We're talking about what it looks like to us. The photon passes us by. It has a wavelength. It has a path. So it's all about us. It's all about us. And that case, it's all about us. Well, even better, it's all relative, as Einstein would have said, relative from what the observer sees to the photon real. Relative to the observer. Yeah. And it's also about the math because that's the thing that people, that the photon is a particle, but the math is why it doesn't experience time. It has no mass and is traveling at the speed of light. So there is no time. There just isn't. That's right. It travels through a path in space time that takes it no time from its point of view. Right. Okay. However, if you look at muons, a muon knows when to decay. Ooh, that's right. So it must have an internal clock for you to just say a particle, and you even mention electrons, doesn't care about time. I'm a decaying particle. I do care about time. Ooh. So there. Ooh. That was going to stop anthropomorphizing elementary particles. Yeah. Muon say, you ready to go? You ready to jump out of this one? Let's go together. Hold hands. That's great. That's great. Yeah. There is time that the extent of a muon's path through the universe does include a passage of time. As a muon as an elementary particle, has no hopes or desires. Sorry. Poor muon. I've had one last question. All right. This is Ben Grund or Groond. He says, hello smart people. Ben from Novi, Michigan. I think Sean helped me understand entropy best in his books and lectures. Charles Liu made an interesting comment recently that time can be measured by entropy. Ooh. I was wondering, is entropy creating time in some strange way? Thanks for all the blown gaskets. Brangaskets. Brangaskets. Brangaskets. Exactly. Let me add some extra punctuation in that question. If entropy goes up with the passage of time, allowing us to deduce the arrow of time by seeing systems left to themselves as we watch entropy rise within them. Could it be that entropy goes up no matter what the universe is doing, even if it were recalapsing, or is the entropy intricately connected to an expanding universe so that even if we, so even if we recalapsed, the entropy would continue to go up. As far as we know, there's no connection between whether entropy goes up and down and whether the universe is expanding or contracting. You could have it anyway. There's an empirical fact about our universe that entropy was low when the universe was relatively tiny and has been going ever since. But if it started collapsing, we expect that entropy would still be going up toward the future. But, and that's part of the actual answer to the question, which is that you have to distinguish between time and the arrow of time. One could exist without an arrow, and the fact that entropy provides time with an arrow doesn't mean that it explains or accounts for time itself. Like here in this room where I am, if I take my coffee mug and I let it go, it falls to the ground. It falls down. It doesn't fall up. There's an arrow of space here in the room. There's a clear distinction between up and down. But it's because the earth is beneath my feet. It's not because the earth is creating space. The earth is just distinguishing between two different directions in space up and down. That's what entropy does for the universe. I like that. That's great. That was really good, man. But wait, but if we recalapt in the whole universe and then occupies a small volume, isn't that necessarily a lower entropy universe? Nope. What? What? No, don't leave me hang it. We have to end now. I can't leave me hanging like with a nope. We got to go. All right. Bye everyone. He was like a Tegan easy. Bye. Have a beautiful time. We learned from statistical mechanics where you have this blob of gas and you just let it go and then it will expand and its entropy will go up because there's more places the particles can occupy. And it's not contained within a volume. If the universe is shrinking, the whole universe is in a smaller and smaller and smaller volume. How could you tell me that that universe can also have an increase in entropy? Do you think eggs are going to start unscramble just because the universe starts shrinking? Yes. Please don't think that you'll digastize them. Okay. No, that makes sense. All right. Yeah. The eggs are broken. They're in the Bain Marie and that's it. Okay. We'll open them up. All right. Just in case there's anyone who really wants it out there, I mean, Neil's given a very good reason to think that entropy should go down and the secret to, you know, for a little bit more technicality because it's the end of the podcast, we should care about phase space, not space. That is to say, we should think about both the positions of particles and also their velocities. So the positions of particles are indeed going to get squeezed together if the universe collapses. But the velocities are going to spread all out and do crazy things and increase the entropy of the whole configuration. And in fact, it's going to look wildly in homogeneous with black holes and empty regions and it's going to look nothing like our early universe looked. Wow. Man, you're good. I'm old. I've done this before, not my first rodeo. I'm not going to tell you. So it's called quantum and fields that was 2024? That was 2024 and the one I'm supposed to be finishing up right now is called complexity and emergence, 2026. Nice. Nice. Look at that. And after that, that's the trinity of the universe. You're done. Yeah. You go to Bahamas. I figure like the trilogy format worked well for JR or Tokyo and it should work well for me too. So I'm waiting for the adaptation. And then you escape to middle earth and all as well. We find you online with the preposterous universe. That's right. And a lot of my work these days talking out there is in the podcast format with the Minescape podcast. Yeah. Minescape. And how often do you drop those? Every single week. Wow. It's very nice. Very nice. Very nice. And at least some of your fans came through us to get back to you again. Absolutely. I can. You were delighted by that. Podcast pros. Yeah. Well Sean, delighted to see you again. Next time I'm in Baltimore, I'll give you a call. I was there actually a few months ago. I just forgot to call you. Ah. Don't. It's going in your permanent record. He's like, you know, you don't really have to tell me that. That's true. You know, that's how you can keep yourself. You know what I mean? Yeah. Yeah. 100% next time we're on the podcast, he's going to be saying, yeah, I went back to Baltimore again. I forgot. Yeah. Strange. I forget every single time. Sean, delighted to see you once again. All right. All right. Good stuff. This has been Star Talk, Cosm Aquaries. Yet another cosmology edition. I love these. No end people's curiosity. Chuck, you doing good? Always a pleasure. All right. This is so much fun. All right. Neil deGrasse Tyson, you're a personal astrophysicist. Until next time, keep looking out.