Just Another Really Good Episode with Brian Greene
56:35 Share

Learning a new language in school was always difficult. So many distractions in a classroom and learning from a textbook, well, things just didn't pop. And Rosetta Stone, though, is the most trusted language learning program. It is available on desktop or can be used as an app on your phone or tablet, which is perfect if you're always on the go. Trusted expert for 30 years with millions of users and 25 languages offered.

Rosetta Stone immerses you in many ways with its intuitive process. You can pick up any language naturally, first with words, then phrases, then sentences. And if you're travelling abroad, it's new languages and new cultures.

But you can, with a tool like Rosetta Stone's Lifetime Membership, break down those communication barriers and immerse yourself more deeply in a new culture. Don't put off learning that language. There's no better time than right now to get started. For a very limited time, StarTalk Radio listeners can get Rosetta Stone's Lifetime Membership for 50% off today.

Visit rosettastone.com slash StarTalk. That's rosettastone.com slash StarTalk.

Apartments.com, the nation's online rental marketplace, is the perfect place to find your place. And they have the right tools to help you along the way. Imagine you could take a virtual 3D tour. How cool is that? And then you can search for the specific amenities that suit you. Plus, you can tuck away your favorite listings and they'll be there waiting for you all in one place. Apartments.com has over 1 million

million available units for rent and they are the most pet friendly rental listings on the internet. What are you waiting for? Go to apartments.com now to find your perfect place.

Chuck, have you recovered from this conversation with Brian Greene? I'm surprised that I can even speak to you right now, to be honest. You look like you blew a couple of gaskets in there. It's more than a gasket. This was mind-blowing, beyond mind-blowing. It was like blood coming out of your eye sockets. Your brain said, I can't handle this. Well, when you and Brian get going, man, I've got to tell you, it's tough to keep up. I don't know. All right.

Welcome to StarTalk. Your place in the universe where science and pop culture collide. StarTalk begins right now. This is StarTalk.

Neil deGrasse Tyson, you're a personal astrophysicist. I got Chuck Nice with me. Chuck, baby. What's up, Neil? All right. All right. You know what you're going to talk about today? I do not. The only way to talk about physics is to talk about physics with Brian Greene in the house. That is true. Thank you. You got to, you know, you can't. It's empty unless you have Brian Greene in the conversation. Absolutely. And he's just up the street.

up at Columbia. You're a dual professor, professor of physics and professor of mathematics. That's right. Wow. You get paid twice for that. But I go to no faculty meetings. I'm always saying I'm in the other department. That's pretty cool. I'm sorry, I can't. I'm math today. So you're...

author of several books, Until the End of Time. Was that your more recent one? That's my most recent, yes. And that came out how long ago? 2020, right at the pandemic. What a moment to have a book called Until the End of Time, right? And the one I think most people know, if they know you at all, The Elegant Universe.

There's another one, The Fabric of the Cosmos. Yeah, absolutely. That's the next one. Hidden reality. Yeah, that's about multiple universes. Right. Man, so he's all up in it. I believe the fabric of the universe is a tweed. A tweed? A satin weave. A satin weave. So welcome back to the show. Thank you. This is like your...

more than a three-peat, I think, at this point. Yeah. Oh, God. And you're involved in a lot of things. You're writing the book. Other than being a professor, you're writing the books. And are we in the 15th year of your...

You're a World Science Festival? How many years have you been doing this? That's right. We started 2008. So if you just subtract, it's even a little bit more. But the pandemic changed things a little bit. Pandemic, yeah. Yeah, we're coming up to probably the 15th live event. Congratulations on that. Although it's a little audacious to hold it in New York and call it the World Science Festival. But we don't only have it in New York. We also have it in Australia.

And we've had events in Amsterdam, in Moscow. I got nothing. In Italy, in Spain. I know. I try to. And by the way, New York is the world. Let's be honest. I mean, for anybody out there listening, I'm sorry. You go to Paris, you find Parisians. You go to England, you find the Brits. But you come to New York, you find everybody. Audacious would have been like the...

Cosmic Science Festival. Yeah, you know, then you would have had a point. Well, congratulations on bringing it to the world. Thank you. Or taking it to the world. And what I enjoyed most about the several that I've attended is the effort to bring the arts into it in a meaningful way. There are many artists who I would later learn or not learn

rare, who are inspired by science and the universe and discoveries. And they will compose dance and music. And you have a mixture of these sessions. We do. We do. I mean, the goal is to have science feel connected to everything that

matters to us. And of course, culture is a big part of that. Culture and arts matter to everybody. In fact, now with AI, we're doing a program on the arts in the age of artificial intelligence. So how is AI changing how artists approach their work and how scientists think about art? We'll be more unemployed artists. Yeah, well. But it's funny, people say that. It's not paid.

They just won't be made. Yeah, but whenever new technology comes along, like the camera, people are like, okay, now you don't need artists anymore because anyone can just click. But there are artists who use the camera to create things that mere mortals can't. And there are painters who actually take a picture and then they actually paint the picture as opposed to having someone sit for a portrait. But that wasn't the biggest thing. The biggest force operating was you no longer needed the artist to

to portray reality because of course the camera captured that so that's freedom up freed the artist that's right to put to portray impression reality exactly it's not what the scene looks like it's what the scene it feels like the interpretation that matters it's huge i mean that's what is the magic in so much expression right it's what we do with it as opposed to just literally depicting what's out there so

There are many people who project that AI is going to create a new kind of art just the way the camera does. Just the way the camera does. It has to shake out. I think AI just accelerates creativity. It doesn't replace it because what happens is you have associations that are being made at a level that you as a human being would maybe eventually over a course of years you might make those associations but the computer can do it

almost instantaneously. And then you take that and you say, hmm, what does that mean to me? Okay, so it pushes you along. Pushes you along. Yeah, but the flip side of that is if you have a computer creating so much, there's a lot of

you know, that you have to separate out. So true. Yeah. There's chaff even when people do it. No, it's true. Yeah. You're born and raised in New York City. Yeah, right across the street from where we are sitting right now. You went to Stuyvesant High School, which is a selective high school that specialized in science in the way the Bronx High School of Science specializes. In fact, they're rivals. That's right. They're like intellectual rivals. Why do you think that we've wrestled each other now and then? I always lose them. You would not like a book if it's...

if it didn't have equations in it. That's true. This is weird. Yeah, that has changed, I should say. So you've read a novel. That's right now and then. That meant you thought more deeply about math than you thought about words. Yeah, but the one change I would make to that statement was, it was when it came to books for a science class. If the book was chock full of words,

I feel like, oh no, there's a lot of interpretation that's going to go into this particular science class. But it was chock full of equations. I was like, nah, this is rigorous. This is going to be specific. And it's going to be something that I can nail because I don't have to interpret. I can just really engage with the equation. Wow. So in a history class or a literature class, you...

you would have been in tears for the task required of you. - Well, again, it was mostly just for science. But you're absolutely right. There is a different mindset that you bring to a history class or an English class, which I did not have a full appreciation for when I was younger. That's absolutely true. And as I got older, and especially there's a moment when I graduated college and I said to myself,

I think I just got a technical education as opposed to learning about the world and life and humanity. And I went into kind of a tailspin for a little while because I was like, what did I do?

And that really then changed it all for me. And words have become vital to the way I engage with the world. You think? I mean, given his four best-selling books, words matter. That'll do it. If you want to talk to other people who are not physicists. And if you want to really get the essence of what someone's about as opposed to quantifying some quality of abstract or objective reality. Okay. Yeah. All right. I think that's a...

That's an enlightened posture. Yeah, I've gotten there. It took me a while. So, what I want to do is follow up. There was a question to our Cosmic Queries that I didn't have an answer to. Oh, no. Here we go. Okay. And I said, you know, I don't know. We're going to have to get Brian Greene in here. We've got to get the big guns in here. All right. If I remember the question, it was, what happens if a quark...

falls into a black hole. You have a quark pair. Yes. And we've only ever found them in quark pairs. Yeah. Okay. And in a normal lab, if you take them and pull them apart, the strength, the force that wants to bring them together grows.

Which sounds weird when you're used to gravity and other things where distance makes something weaker. But they're like really creepy identical twins. Like you ever meet identical twins that are like super creepy? Where they sort of talk together? Where they kind of talk together? And walk together? They got their own language. Yeah, yeah, yeah. Okay. Right. So, but it's kind of like a rubber band.

Yeah. As you stretch the rhombus band, the force is greater. Yeah, the gluonic force between them. The gluonic force. It's held together by gluons. Okay, so now as I pull it apart, there will be a point where it snaps.

As I understand my nuclear physics, it snaps with the exact amount of energy you put in so that out of that energy creates two other quarks. Yeah. So now I have four quarks. Quark-anti-quark pairs. Pairs. Thank you. Okay. Pairs. Okay. So now. So you want to see what happens. Now you send a pair of quarks down the black hole.

it gets split, we make two other quarks. Yeah. Thank you. That was very good. And you keep doing this, and they... So wouldn't the quarks eat the entire gravitational field of the black hole? Yeah. And then you wouldn't have a black hole left, you just have a ball of quarks. You have to realize, number one, that we still don't know the under...

the physics of the singularity of a black hole well enough. Why else did I invite you into this office now? So, well, I wish one day, one day I pray that I'll sit here and tell you what happens at the singularity of a black hole. Bring the person who knows next time. But here's the thing. There is nobody on planet Earth who knows the answer, unfortunately, yet. Okay. When we follow the mathematics to the actual singularity of a black hole... Using...

Einstein general relativity. Using Einstein general relativity and even some of the modifications that have come from more recent thinking, we're still not there yet to truly understand what happens. And I should say there are ideas. There are ideas of things, I don't know if you've heard of them, called fuzz balls, where there isn't actually a singularity and the black hole is actually a more fuzzy collection of matter. So there are ideas that people put forward. That makes your math come out okay. Makes the math come out okay, but we're not sure if it's right. When they say black holes are where

the singularity at the center of a black hole is where God is dividing by zero. Yeah, that's a Stephen Hawking quip or something. Did he say that? I think it is, you know. Do you remember why if you divide by zero, it blows up? Well, it's not going to work out. Right. And it's actually, in a sense, it's literal because if you calculate what's known as a scalar curvature, which is a

that characterizes how warped a region of space is. Okay. It does go to infinity as you go to the center of a black hole, just like when you divide by zero, it goes to infinity. In fact, it goes to infinity as the sixth power of your distance. So we know very well how badly behaved the center of a black hole is. So it goes to infinity fast. It goes to infinity fast. That's crazy. Yeah. And so if you ask what really happens if something is just being crushed at the center of a black hole,

We can't really answer yet. So is it possible that as a quark-antiquark pair goes, that the tidal forces will create additional quark-antiquark pairs? Sure. And then you'd have the proliferation of quarks. Making me some sounds. So there may be a cloud and there may be some sort of cloud that forms just before it hits. Ultimately, we believe it hits the singularity, whatever that means, because we don't really know what the singularity is yet. If it's a fuzzball, you can have a fuzzball or quarks.

Possibly. Or the fuzzball may have a slightly different impact on the cork-anti-cork pair. Maybe before... Influence. Influence on it, yeah. Impact. Yeah, that's right, exactly. So it's a really good question, but it will have to fully await a full understanding of what truly happened at the center. Okay, so me not being able to answer it wasn't...

Just my personal ignorance, it's a total ignorance of all humans on Earth. Yeah, and there are... So I don't feel so bad about it. And I should say there are many, many questions like that that we're still struggling with. Like, we believe that when any information falls into a black hole, we believe that information does not get destroyed. But for a while, Stephen Hawking thought, no, any information ultimately hits the singularity and leaves our universe. He changed his mind later in life, which just goes to show... Was that his famous bet with...

Yes, that's right. So they bet, I think, an encyclopedia, you know, the source of information that we humans have created. So there... Kip Thorne was one of the executive producers on Interstellar. Interstellar, right. And he sort of spearheaded the effort, among others, but he was the

exponent to build the laser interferometry gravitational wave observatory like oh the detected colliding black holes and he won the nobel prize for that so he's he's significant in our field and i have at least a few books by him on my shelves and uh he was clearly on a level of geekdom where he bets encyclopedias yeah but in terms of his book he wrote in an

encyclopedic book on gravity and black holes, which is about 1,200 pages just filled with equations. Therefore, I loved it when I was a kid. The Misner-Thorne Wheeler. Yes. I have two copies of that in my office. Two copies? Yes. Do you want to cross-reference or something? One of those is mine, and the other one belonged to my wife.

He has a PhD in mathematical physics. Wow, that's so cool. And we met in relativity class. Really? Taught by John Wheeler. What? Really? Yes! You took relativity from Wheeler? Yes, I did. That is amazing. Wow. Nice. Yeah, so John Wheeler is one of the authors of this Misner, Thorne, and Wheeler. Yeah. And Misner taught physics at University of Maryland. Charles Misner. Charles Misner, yeah. Yeah, yeah. Okay, so...

I would think of it as a quark catastrophe that would happen in the center of the black hole. The trouble with quarks, they're like triples. By the way, there's a previous, if we're physics geeking out here, there's a previous time, was it 100 years, 110 years ago? There's something called the ultraviolet catastrophe. Do you remember that? I remember it. Well, I wasn't there, but I've learned about it. Yeah, this is the start of quantum physics. Yeah, it had to predate 1900. It predated...

Max Planck. Oh, okay. Because there was an equation that would show how much energy would come from glowing objects. Okay. And how much energy of a certain wavelength of light and then another wavelength. And so there'd be the spectrum of what it gives you. Okay. And if you follow that equation to higher and higher energies, it blows up.

and was called the ultraviolet catastrophe. Now, we knew that's not happening in the actual universe, but we had no theoretical understanding of why the actual universe was not doing what our equation said. So we knew something was missing. Okay. And Max Planck comes along, finished the story. Yes, and Max Planck comes along, and he suggests an idea that he never fully believed. This is interesting. He suggests that maybe the energy only comes in packets, right?

of certain quantized sizes. And therefore, your calculation of the amount of energy was biased by assuming that energy could come in arbitrarily large or small amounts. If you assume it only comes in packets of a minimum size, then the total energy inside that cavity is finite. It actually converges and drops off. And it agrees with experiments. Right. But the weird thing is... And he got an equation. The equation is like...

holy shit, this would come out of someone's head to make this happen. It's got an exponential, and an exponential has interesting properties where it goes up and then it comes down again if it's a negative exponent. I mean, there's a fun math in there. Exactly. And was it just a fitting function, or did he actually have deep physics insight? He had a model in mind.

He really quantized the energy. He broke it up into little bits and redid the calculation, and that's what came out. But then later on, he never fully believed that energy in light, in photons, as we now call it, did come in little packets.

Right. He said, sure, the math seems to describe it. But. But I'm not willing to go to that next step of ascribing a full reality to it. And so it's really Einstein who came along and came up with the idea of photons, more particularly with the photoelectric effect. And that's how he wins the Nobel Prize. Many people think he won the prize for special relativity or general relativity. No. My boy Kusha could have had eight Nobel Prizes. His Nobel Prizes are for what he's least famous for.

Right. Yeah. That's just impactful. That's straight up. But it's a problem that's still there. Exactly. People winning Nobel Prizes for discovering things that he predicted.

So if you add everything he predicted to the Nobel Prize count, plus what everything, if they gave out Nobel Prizes for everything you did, I give him eight Nobel Prizes. What would you give him? Well, certainly gravitational waves. That's right. Although again, he didn't fully believe it, but it comes right out of his 1916 and 1918 paper. I'm saying if you give him a Nobel Prize for everything people discovered based on his stuff. Well then, it's kind of everything. I think.

- Your purse was on the Nobel Prize receiving line, and nope, you're taken. - It's like that Bugs Bunny, first base, Bugs Bunny, second base, Bugs Bunny, third base, yeah, every Nobel Prize is Albert Einstein. - That's the answer right there. And so of course, since if energy is quantized, thus,

is born the branch of physics called quantum mechanics. Quantum mechanics. Wow. And that probably has had the greatest impact on life as we know it. And that was the year 1900. Yeah. Well, 1905 is when Einstein writes his paper on the idea of photons. But Max Planck, you're right, was 1900. Max Planck was clean 1900, starting a new century. Yeah. Before they even had calculators. Oh, was that? Really? Was it that far back? Yeah.

Discover so many ways for the whole family to play with the Nintendo Switch system. With an awesome roster of games like Super Mario Bros. Wonder, Nintendo Switch Sports, and The Legend of Zelda Tears of the Kingdom, there's something for everyone.

Nintendo Switch also has three different play modes, from handheld mode to tabletop mode to TV mode, so you can play at home or on the go. Turn anytime into playtime with Nintendo Switch. Games rated E to E10+. Games and systems sold separately.

Whether you're a family vacation traveler, business tripper, or long weekend adventurer, Choice Hotels has a stay for any you. And that's good, because there are a lot of me's. Choice Hotels has over 7,400 locations and 22 brands, including Comfort Hotels, Radisson Hotels, and Cambria Hotels.

Get the best value for your money when you book with Choice Hotels. Cambria Hotels feature locally inspired hotel bars with specialty cocktails and downtown locations in the center of it all. Hey, that's me. Radisson Hotels have flexible workspaces to get the most of your business travel and on-site restaurants.

That's me too. And at Comfort Hotels, you'll enjoy free hot breakfast with fresh waffles, great pools for the entire family, and spacious rooms. Hey, that's me too. I guess I'm just going to have to stay at all of them. Choice Hotels has a stay for any you. Book direct at choicehotels.com, where travel comes true.

Cam found out that group chats between different phones aren't private. Or encrypted. Or encrypted, thank you. We only text in code. Yes, which I created. I created a code. Yes. Which can be a little annoying. Wait, was that your attempt at the code? You already forgot the code, didn't you? I should have written it down. The place to safely send messages between different devices. WhatsApp. Message privately with everyone.

Hi, I'm Ernie Carducci from Columbus, Ohio. I'm here with my son Ernie because we listen to StarTalk every night and support StarTalk on Patreon. This is StarTalk with Neil deGrasse Tyson. We're old enough to remember when the United States lost the most powerful collider in the world.

the superconducting supercollider. Yeah. Which they already, there was money allocated, they started digging a hole. It was a 200 mile circumference. There was something huge. And superconducting, it was going to use superconducting magnets. Wow. Which had very powerful magnetic fields. And because that was coming of age at the time, it was going to push the frontier.

My analysis, if you read the report, well, there were cost overruns and we have too many other priorities here. So we're going to zero the budget for this superconducting supercollider. And you read the report and say, well, we have other priorities. Plus, this is going to be built in Texas. And if we're going to build the space station, which is based in Houston, Texas is already getting a chunk of change. You know when all this happened? Like between 1989 and 1992, when the debates and then they...

Zeroed the budget. What else was happening over those years? Let me think. Oh my gosh. Peace broke out in Europe. No longer do we need the physicists to protect us from the evil, godless communists. That's what I think was the subtext of that story. Damn you, Harmony. Because no other particle accelerator was ever canceled for any reason that was designed, conceived, and built in the 20th century. Yeah.

So if you grant me one conspiracy theory, grant me that. But then you think they kept the space station because that was the place where the new battles might be waged? Possibly. So what we're looking at right now, when you think about it? Yeah, with the Space Force and everything else. So that's where I am on that. But I say this only to note that once that got canceled, the center of mass of particle physics went across the pond to Europe.

And then CERN, the European Center for Nuclear Research. Somewhere in there, yeah. It's a French acronym when the words are in the French order or something. That's it. It goes there. And I think our lawmakers don't really understand that if we don't do the physics, someone else can and will.

We don't own all access to future discoveries of science. And so now Europe does it. And so they went ahead, built a large hadron collider, and they successfully found the Higgs boson, the big holy grail. July 4th, 2012.

Look at that. Was it July 4th? That's sticking it to us. Wow, that really was. And you know they really found it on like June 28th. You know they found it on June 28th and they were like, guys, we're going to sit on this for a few days. Yeah. But there are a lot of Americans involved in the large- Yes, of course. That's true. But just to say, but yes, exactly right. Yeah. Even Peter Higgs, is he American? Peter Higgs was...

Scottish, I would think. I think it was from Edinburgh. Although I think he was Edinburgh, but I don't think he was Scottish. Maybe he was English. I don't 100% know. But yeah, he predicted its existence and then it was discovered and at the announcement...

Saw tears welling in this man's eyes who'd been waiting decades for this idea that at first nobody believed. Right. Ultimately was accepted theoretically, but it was proven experimentally finally in 2012. And what is the Higgs boson? Exactly. Of the particle categories, one of them is bosons. Right. Okay? And bosons are force mitigating particles. Okay. Okay? So...

And when we think of a force action at a distance, there's a way to think about that in terms of the particle that in the category of particles is a boson. One of the bosons is this Higgs boson, which has what properties? Was I right? Yes, very good. Thank you. We said I was very good. Can I answer? Thank you, Brian. Thank you, Brian. Please. It's what endows other particles, even itself actually, with mass.

Interesting. Now, where does that come from? Well, just to take Neil's idea, it starts with the idea of a field. That's how you get rid of this idea of action at a distance. You imagine that space is filled with stuff. You don't invent the fields? Uh...

I really don't. Michael Faraday. Oh, really? Well, that makes sense. He was the first. Yeah. What a leap that is. Yeah, it is. It's an insane leap. Right. Take it for granted there's nothing there. Yeah. You're looking at nothing. You're seeing nothing. And yet you're positing that there is something there. And that's an amazing thing. But he was talking electric and magnetic field. Right. What Higgs is talking about is a new field called the Higgs field.

field, which he didn't call it that, but that's what we call it. So it's this field that fills space and as particles that otherwise would be massless, as they try to go through space, they have to burrow through the Higgs field. And that creates a kind of drag force on them

which is what imparts the mass that they have. Okay. And that's the field. Now, what's the particle? Well, if you have this field, in principle, if you hit it hard enough, like hitting the surface of water, you can cause little particles of the field to spray out. And that's what the Large Hadron Collider did. It slammed proton against proton

and that way jostled the Higgs field and caused a little droplet of it to break free, and that's the Higgs particle. And then we got the, oh my God, so you're seeing an actual piece of the field. Yes. Oh my God. So the Higgs field-

generated via E equals MC squared, its own particle of its own DNA. That's right. Or you can say it's a quanta, to go back to the other language, it's a quanta of the Higgs field, like the photon is the quanta of the electromagnetic field. All right, that's amazing. That's some stuff. Okay, now I get it. So it's not the particle that you're actually seeing. It's not the particle that is imbued with mass itself.

It is the thing on which the particle is traveling the field, the medium itself. Boom, it kind of splashes apart for a quick second, and then that itself becomes a particle and has mass. Holy...

Wait, wait. So. That's amazing. That is amazing. Chuck just blew a gas can. Oh my God, that's crazy. Dude, that is insane. Call the doctors. This is the first time I've actually really understood. Call the doctors. Because.

Oh my God, that's so freaking crazy. Oh my God. A week later, he's there in bed still. Eyes this big. That is fantastic. So my favorite analog to this is when I explain the Higgs field to people, I say it's like a...

a Hollywood party. Okay? So there are people in the party. Right. All right? And the bar is at the back of the wall. Okay. Okay? And if no one knows you and you walk into this party... Okay, that's my experience. You have near zero...

resistance to movement through that party. True. So you have a very low, if not zero, party mass. Exactly. Okay? Because you have no... You get into the bar right away. Right, you get in the bar right away. So your inertia, it knows no resistance there. Exactly. Whereas if Beyonce walks in, everybody will crowd around her. She can only make very small steps towards the bar. Right. She has a very high party mass.

Is that fair? That's awesome. That's the party field. The party field. And then if you slap all those party goers, you can slap off one of them. That's the party particle. Somebody from the beehive. Somebody from the beehive. Yeah. Party particle. Oh my God, was that Beyonce? Oh, there it is. All right. So I have learned, not from you, and I'm disappointed because I thought you would have told me the whole story. Yes. I come to you for these frontier conversations that...

The Higgs mass that a particle would have is only for free particles.

If a particle is in an atom, it's not getting its mass from the Higgs field. I have told you this in the past, though. I absolutely have. I don't think he... But you're absolutely right. You're absolutely right. So if I'm a fat proton in a nucleus, I'm not getting my mass from the Higgs field. No, and that's why it's a really misleading notion that many people have. They think that all...

All mass comes from the Higgs field. It is just the fundamental particles. And here's the thing. If you were to go up into your particle data book, which I know you have a few copies lying around in here. Yes, it's particle data. It's very good. If you look up the masses of the quarks, the up quark and the down quark that make up a proton, up, up, and a down, add up their masses. He said that quickly. Up, up, and a down. The nucleons have three quarks in them all bound together.

making up the proton and the neutron, but they're different combinations of three quarks. This is good. Tell them.

So quarks have charges, fractional charges. Yes. So watch this. Okay. So proton has a charge of plus one. All right. How do you get that from three quarks? Yeah. How do you do that? So give me. You got to have a two-thirds and a two-thirds and a minus one-third. Two-thirds, two-thirds, minus one-third. So two-thirds plus two-thirds is one and a third. And then a minus charge to bring it down to one. Now, neutrons have charged quarks inside of them, but they don't have any charge. So how do you get them? How do you get them? Let's hear it.

Oh, it must be...

Up two-thirds, down one-third, down one-third. Yeah, so if you have an up and then a down, and a down-down, then you got a two-thirds, minus one-third, minus one-third. Minus one-third. Now- Cancelling out, and so it's a neutral thing. Even though what's inside of it has charges. Right, but here's the thing. The point I want to make, though, is if you add up the masses of those quarks, they're much less than the mass of the proton. So what's going on here? They make up the proton, and yet the proton's much heavier than its ingredients. Right. Answer is, there's another contribution to the mass, which has nothing to do with the Higgs field.

which is the thing we were talking about before, the energy in the glue holding the quarks together. Oh, the gluonic force. There's energy holding them together equals MC squared. There's mass associated with that energy. And most of the mass of the proton is coming from the glue that's holding the quarks together. That's insane. So let's take a neutron, which has a half-life in minutes, like 15 minutes, if memory serves. And after that amount of time,

Half the neutrons will have decayed into a proton. Let's say if it's a regular proton and then an electron. An electron. And an antineutrino. And an antineutrino. If you add up the masses of those, don't you recover the mass of the proton? As long as you've taken kinetic energy into account and all this too. Because they fly away. They fly away. But yes, but yes. So the energy budget is all there. It's all there.

Okay. Look at that. So everything is conserved. Yeah. All the time. And in fact, the way the neutrino was predicted was from looking at these particle decays and finding that the energy budget was not adding up.

And so the idea was maybe there's an invisible particle that's carrying away some additional energy. Was this Enrico Fermi? Yes. So what I like about this is he's like, look, folks, I can't explain this. Let's make some shit up. Yes. But geniuses make up shit that's right. That is a quote. That's a bumper sticker right there. That's it. I'm getting a T-shirt. I'm getting a T-shirt. I'm getting a T-shirt.

That's awesome. That's great. That's what Carl Sagan was famous for saying. They laughed at Einstein. They laughed at, you know, all these people with these great ideas. And he said, they also laughed at Bozo the Clown. Just because people laugh doesn't mean they're going to be wrong. He makes it up, and then everyone starts looking for it. And it's this highly elusive particle that has no charge whatsoever.

Because we knew all the charges had already balanced in the lab. It's got no charge, but it's carrying away energy. And no one has detected it. And he was Italian, right? So neutrino is like little neutral. Little neutral. Little neutral one, I think. Oh, that may be right. Little neutral one. Yeah, right. And so that's the only thing that allows me to, okay.

I'm not going to get in your way. When people say dark matter, it's some elusive particle that we can't detect. Right. That's accounting for the extra gravity. And it's a particle we haven't found the particle yet. And I'm thinking that's intellectually lazy, but it's no different than the neutrino. So that's why I cut it some slack, more slack than I otherwise would. Now, we still need to find it. If it's a particle we haven't found. Yeah, right. So are you a betting man? Is it a particle or is it something else? Uh...

Look, I'm relatively conservative when it comes to these things, so I think that it's likely to be a particle. Just because we've been down that road before. We've been down that road before. It fits in so well to our theoretical framework. It doesn't require... Do you have a slot for a dark matter particle?

Well, the amazing thing is, and here's where you're going to come back at me and say this should undercut my confidence. When you look at a theory called supersymmetry that I've spent a long time working on. Okay. Within this theory, which goes beyond what we know about particle physics for reasons that are well motivated. Because that's ordinary symmetry. That's right. It takes the symmetries that we have and it takes them one step further and it's the only step further that you could possibly go. So of course nature must make use of this final symmetry principle.

Why else would it exist? That's the thinking that we've had. - Let me back up for a minute. So as I was learning particle physics, I was intrigued to recognize that you have your electron, you have your photon, you have your neutrino, and these other sort of basic particles. And they exist in our world that we live, we experience. If you up the energy knob, other particles manifest.

There's a version of the electron that manifests only in these higher energy levels, and it's called the muon. Right. Okay? And so there's a whole layer of particles sitting above the ones that are in our world. Right. So there's three of these layers. And tell me the three electrons. You got the electron, the muon, and the tau. Right.

The tau. Yeah. Okay. And there's an electron neutrino. There's a muon neutrino. There's a tau neutrino. So now I have three layers here, and you have access to them in your particle accelerators because it takes a lot of energy, and you can get there. Yeah. Okay. Now what does supersymmetry do with this package? Supersymmetry says that... This package is... Beautiful and confirmed. And tell me the three force...

We have a photon. You got the photon, then you got the gluons, and you have W and Z bosons, or the weak nuclear force. Okay. And those are the three forces. Discovered by Bozo. Right. Bozo. Actually, Bose. Bose is an Indian physicist. Yes, absolutely. And then for the quarks, you got the up and the down that we spoke about. You got the charm, the strange. You got the top and the bottom. Right. So again, they come in three pairs of two. Okay. Super symmetry says take all of those particles and double them.

another shadow version of all of those particles. It's a shadow governed. For the electron. We are the puppets. This is the deep state. This is the deep state. They are the puppet masters. The quantum deep state. Wait, wait, wait. So I didn't know this. The entire set of particles would have a counterpart in this supersymmetric place. So for the electron, you have the supersymmetric electron.

For the quarks, you have squarks. For neutrinos, you have neutrinos. People just making shit up. You run out of names after a while. But here's the thing. This is all mathematically motivated by a completely compelling rationale. So this is not pulled out of thin air. We have our universe three ways, a three-layer cake. And there's a whole other cake. Where does that live?

with us, but we believe they're more massive, which is why we wanted to build the superconducting super collider to try to find them. Now we've looked for these at the Large Hadron. If they're more massive, why aren't they right here in front of our faces? They typically have short lifetimes, so they'll decay into lighter particles.

but the lightest of the supersymmetric particles would not decay, and therefore it should be all around us. Tell them why the lightest one would not decay. If it's the lightest one, when it decays, the decay products have to be lighter than it. Okay. And so if it's the lightest one, subject to a certain conservation law. It's no place for it to go. It's no place for it to go. It's the same reason why you can have an energy field of any kind and decays

you will not make particles out of that unless the energy available is higher than the E equals MC squared of two electrons. Right. Because it has to make them in pairs.

Okay. To keep the charge conserved. Because it's plus and a minus. Right. And so an electron is the lightest physical particle. Right. So nothing's happening. Lightest charged particle. That's why it's not happening around us right now. Yeah, it's the lightest charged particle. So it has to talk to the electromagnetic field. There it is. That's why light coming from lights

is not just making particles. It doesn't have enough energy. Right. If it did? If X-rays start to come out of there, X-rays, high-energy X-rays, you can pop electrons into existence. Because they're stepping down, so they leave something. The energy of the field is big enough to create the electron and anti-electron, and so it will pair-produce them. In fact, That's so wild. electron microscopes are enabled by X-rays,

creating them, and the wavelength of X-rays is so tiny that you can see tiny detail. It's tinier than the detail. You can't have resolution higher than the wavelength of light that you can use to see it. Right. Now, back to dark matter, just to finish this point. This is a whole massive other layer cake, and you're telling me that is the mass of the dark matter. Well, the lightest supersymmetric particle would be stable.

should be around us. That's what everyone's looking for. So maybe it's filling space. Right. And here's the beautiful thing. This will blow your mind. This will blow your mind. This will blow your mind. When you do the calculation of how much of this light is supersymmetric particle should be left over since the Big Bang, it exactly matches what you need to be the dark matter. It comes in the right abundance.

And yet we've not found it. And it may be the wrong answer. So sometimes things that just seem so deeply compelling are wrong, but we don't know yet. Wow. So do you know enough in the theory of these particles to predict how you should detect it? Yes. Now they can vary which is the lightest supersymmetric particle on the flavor of the supersymmetric theory you're looking at. But

But in any given version, yes, you know exactly how the particle interacts. Okay, so now you have everybody's favorite flavor, the theorists, come out with their competing models. But still, they got to have one of these particles. Okay, so now I'm an experimentalist. And it's how many tests for this one? I don't find it. Let me test for that one. I don't find it. So it's not looking good. Yeah, I agree. Okay. I agree. Okay. Wow. I agree. But yeah, when I was a student, it was...

It was almost a foregone conclusion that you just had to look for it. You'd find it. This is a dark matter because supersymmetry also solves other problems. The so-called hierarchy problem that's of the dark matter problem is a beautiful idea that seems perhaps not to be right now. It's not fully ruled out yet, but that may be where we're going. Who's the one that said the great tragedy in science, a beautiful theory.

Slain by some facts. Somebody said I forgot. I think that's exactly what it may be. Whether you're a family vacation traveler, business tripper, or long weekend adventurer, Choice Hotels has a stay for any you. And that's good because there are a lot of me's. Choice Hotels has over 7,400 locations and 22 brands, including Comfort Hotels, Radisson Hotels, and Cambria Hotels.

Get the best value for your money when you book with Choice Hotels. Cambria Hotels feature locally inspired hotel bars with specialty cocktails and downtown locations in the center of it all. Hey, that's me. Radisson Hotels have flexible workspaces to get the most of your business travel and on-site restaurants.

That's me too. And at Comfort Hotels, you'll enjoy free hot breakfast with fresh waffles, great pools for the entire family, and spacious rooms. Hey, that's me too. I guess I'm just going to have to stay at all of them. Choice Hotels has a stay for any you. Book direct at choicehotels.com, where travel comes true.

Hear that? That's what cooked when you order juicy beef sounds like. The steaming hug of two slices of melted cheese, the crunch of tangy pickles and sliced onions, all topped with a toasted sesame seed bun. That's the sound of a McDonald's quarter pounder with cheese. First Beef at participating U.S. McDonald's. Excludes Alaska, Hawaii, and U.S. territories.

Earning your degree online doesn't mean you have to go about it alone. At Capella University, we're here to support you when you're ready. From enrollment counselors who get to know you and your goals, to academic coaches who can help you form a plan to stay on track. We care about your success and are dedicated to helping you pursue your goals.

Going back to school is a big step, but having support at every step of your academic journey can make a big difference. Imagine your future differently at capella.edu. I have not been the same since we had lunch months ago. And you explained to me, and I've said it here, that there are ideas percolating that the fabric of space-time might be woven together.

by wormholes that connect the virtual particle pairs that come in and out of existence. And that if they're connected by wormholes, rather than just some field, then the wormhole is an actual structural texture of the universe. Yeah. In fact, the other way... I'm sorry. First of all...

I need some weed to even deal with this. Because if I'm trying to figure out what you just said, because it's so freaking, I mean, it really is just crazy. Wait, wait, let's back up. The vacuum of space is not a vacuum because quantum physics requires what?

There's all sorts of uncertainty, and that uncertainty means that there's fluctuations, and therefore there are particle-antiparticle pairs. There's energy fluctuations. There's field fluctuations. Right. It's a roiling mess out there in empty space. So there's no nothing. There is no such thing as nothing. That violates uncertainty. There's truly nothing. Right. There's truly nothing. We couldn't have uncertainty. So the uncertainty gives us the fact that we do have uncertainty.

virtual particles. Yes. We know that they popped in and out of existence. What you're trying to tell me. I think it's not that we know they're there. No one denies it because it's completely consistent. Well, the Casimir force where you actually put two metal plates in otherwise empty space, they should simply sit there. They're drawn together. And our best explanation is it's the virtual pairs of particles. It's a fluctuating film. I did.

I feel like I have fallen into a Star Trek nightmare. Watch, watch. So you take two exactly parallel plates. Okay. Okay? And evacuate what's in between. In between them. That makes sense. The best vacuum you can muster. Right. Then you slowly move them together. Right. There is a point within which a whole other force kicks in. That's right. And it's not the gravitational force. It's not.

It's not a electromagnetic force. Rather, it's a force that comes from the Casimir field, which is basically... That got a Nobel Prize? The Casimir? Well, 1948 is when it was discovered. It got one of my books. But it should have. You just gave it one. I just gave it one. Yeah, it definitely deserved one. That's insane. But it's an imbalance between the fluctuations of uncertainty within the place and the fluctuations of uncertainty outside of the place. And it's that imbalance...

Creates a force and puts them together. Yeah. Okay. Okay. So that's how we get the particles in the vacuum of space. Okay, so now...

So now, what compels you to say wormhole rather than just a field? Well, because it really comes from the idea of quantum entanglement. What we find is that entanglement, which normally we think of as particle pairs, but now we're finding that the vacuum of space may be stitched together by the threads of quantum entanglement itself.

So deep down within the substrate of reality, it may all be stitched together by quantum entanglement. And then other work shows us that quantum entanglement connecting two particles is just like a wormhole going from one to the other. Because what happens in one happens to the other instantly. Yes. And that means they're touching each other in that instant. They're connected in some weird way.

And entanglement is one language, but we believe wormholes may be the general relativistic version of that quantum language. So it's like a little quantum net holding the whole universe together. Yes, exactly right. Because we find mathematically, if we cut the threads of quantum entanglement, which we can do mathematically, space falls apart. It discretizes into little tiny pieces and then just disappears.

I gotta go. I gotta go. No, Chuck. I need you to the end of this. Chuck, don't leave me. Don't leave me, Chuck. Oh my God. Oh my God. Dude, that's insane. It's not just that there's a field there. It's the fact that they were quantum entangled that makes the wormhole model...

Compelling. Yeah, but I would say you don't even need the particle pairs. It's as if the entanglement is entangling regions of space. So space itself has a fundamental substrate woven by these threads of quantum connection.

Now, look, it's mathematical, but it comes out of our cutting edge ideas. It all makes sense. It just makes sense. He said he's not pulling it out of his ass. Right. Okay, he's saying the math gave it to him. The math works. And he started out saying, my boy loves the math. So now, last thing. Yeah. Explain why you need more than four dimensions for your string theory universe. Well, it's a very concrete explanation. When we look at the equations of string theory, there's a consistency equation.

where something must equal zero or the math doesn't work. That something is a product of two things. One term is really complicated, it's never zero. The other term is the number of dimensions minus 10. The only way to get it to be equal to zero is for D to be equal to 10.

That's it. I am not joking. This is where the constraint of extra dimensions comes from in string theory. The math is forcing our hands. Forces your hand. And then you say, well, let me take this math here. One thing you could say is, well, if it's not D equals four, three space in one time, throw the theory away. Others of us will say, hey, let's keep going.

Consider the possibility. Don't sell the universe short. Yeah, exactly. So why should these three dimensions of space be the only ones? Right. We only are aware of them because they're big enough that we can be directly aware of them with these really faulty sensors that we have. Right. If it's only your senses that limit that awareness. Yeah.

Why not, in principle, can we build something that can gain access to these higher dimensions? Yeah, so there are experiments on the table. Some have been carried out, but more precise ones may be done where you study Newton's law of gravity. Why does Newton's law go like one over R squared? Why do we teach our kids GMM over R squared? It's a geometric sphere in three dimensions.

dimensions of space. Yes. Look at that sphere in four or five or six dimensions and the two in Newton's law won't be a two. No. It'll be a bigger number. The fall off will be differently. Right.

And so look at the gravitational force on very small distances. Look for a deviation from the one over R squared that Isaac Newton told us about in the late 16th century. Okay, because that's only in our dimensional measurement of it. Yes. Okay, because I'd asked you again over that same lunch. Yeah. Why did we have lunch? I forgot. We were just catching up. We were just catching up. You know, it's my annual fix, my annual Brian Greene infusion. It was, could dark matter...

be ordinary matter with ordinary gravity in a parallel universe.

Because for reasons I don't understand the math of, the field theory equations of, you were telling me that electromagnetic energy cannot escape our space-time, but gravity can. In a certain model called the brain universe, where our universe... B-R-A-N-E. B-R-A-N-E. It comes out of... As a membrane. Yeah, it's a membrane. So our universe is like a four-dimensional membrane floating in a higher-dimensional universe that might have other membranes. Okay.

Higher dimensional membrane. Yes, and those other membranes like parallel to us like two slices of bread and a big loaf of bread. I like it. So one slice of bread is some other membranical universe. Ours is this one, but it's one multiverse. Okay, and so gravity could leak out of one into the other. Or it could just be the, yeah, that's right. So the gravitational pull, yeah. That's what I'm getting. So if the other universe has six times

Nobody, see this is where you corrected me. Because I was thinking, because we have six times as much force of gravity operating in the universe as matter and energy can account for it.

Okay. It's a factor of six. Right. So I'm saying, why isn't it just a parallel universe that has six times the mass and it's leakage into our universe? And we're trying to feel the elephant, trying to figure out what it is, but it's just regular matter in another universe whose gravity leaked. But then you said, if it's in another membrane, it's going to be dropping off faster than one over R squared. Yeah. Like one over R cubed. There's some higher dimension. Yeah.

And if that's the case, it has to be way more than six times. You could imagine rigging it so that it would have the right amount. Yes. And people have studied this, and it's hard to make these theories work in detail. And be all self-consistent. But in principle, it's an idea that's absolutely worthy of investigating because that's one way to make it invisible. Just put it in another membrane. Just stick it somewhere else. Yeah, exactly. And then we can still calculate with it. It's not a problem. Right. Yeah. That's crazy. Man. Oh, man.

All right. I don't know what to believe about anything. Nothing is real. Nothing is real, man. Dark energy. I'm curious about this because it was a natural arithmetic error.

of Einstein's equations. It's like an integration constant, as I understood it. You're talking about the cosmological constant? The cosmological constant in his equations that enabled Lemaitre to calculate that the universe is either expanding or... But the universe is not static. And so there's a term there. And if you've had calculus, you might remember there's a constant of integration. Often it's just zero and you can ignore it.

But when we were in graduate school, I'm a little older than you, when we were in graduate school, we always recognized, we paid homage to that constant, but said, let's assume it's zero. If this term existed, it would mean there was a force operating in the universe opposite that of gravity. Depending on the sign of the cosmological constant, but yes.

Because it could have either sign. Okay, it would either work with gravity or against it. Exactly. But if we had a static universe, it would be something just holding up the universe against the collapse of gravity. Which is why Einstein thought of it. And we didn't have any reason to think it. So it could be zero. But we always had to go through that portal. We say, here it is. We set it to zero and move on. Then it gets discovered. Dark energy gets discovered in 1998. It gets the Nobel Prize. Using quantum physics...

which has done so well by us, perhaps the most successful theory ever about anything, fails in its attempt to predict the amount of dark energy in the universe. Yeah. And it fails badly.

by a factor- - What's up with that, Brian? - Of a Google. - Wow, by a factor of- - Bigger than a Google. 10 to like, it's like 10 to 123 or something. - Google is 10 to the 100th? - Yeah. - It gets the wrong answer by the biggest amount

ever in a mismatch between theory and observation. Where are we with the dark energy theorists? - Well, look, what this is showing us is that quantum mechanics is incredibly successful when you apply it to the electromagnetic force, to the weak nuclear force, to the strong nuclear force. But we've long known that when you apply it to gravity, something goes wrong, something changes. This is the motivation for string theory. And this is the motivation for trying to go beyond conventional approaches.

And so you're absolutely right. This is the clearest signal that something is wrong. Now here's, I think our best guess- - But that's not something's wrong. That's actually a good thing. - Well, it's an opportunity. - Opportunity, that's the way. - Yeah, it's a huge opportunity. - Yeah, the press always says, "Oh, scientists are angry or this." No, we're delighted. If something breaks, oh my gosh, it's a new thing. - Exactly. - That's right. And so I would say my guess where we're going is, and many of my colleagues agree with me, that you can't quantize gravity.

The way you had to quantize Faraday and Maxwell's electromagnetism or the way I had to quantize the weak or strong nuclear forces. It may be that gravity and quantum mechanics are already so intimately connected that it's a completely different mindset when you approach them. You don't take the rules of quantum mechanics and slap them onto gravity. That gets you the wrong answer. That's the wrong approach.

In fact, this idea of entanglement and wormholes suggests that gravity and quantum mechanics are already in there. They're already there. That makes sense. They already have the shotgun wedding. Exactly. So you just need to understand that melding better. And when you do, perhaps you'll be able to do a calculation of the cosmological constant and get the right answer. Right. Now, another answer might be maybe the cosmological constant is not a constant.

Right? There's recent data. They're working on that now. Maybe it's changing over time. And so you don't actually calculate the number. You just need to understand the dynamical process. However...

doesn't the math in general relativity require that it be constant? No. That's how it came out of the integral. There can be a constant, but it doesn't have to be the only contribution that looks like that constant. And the other contribution can change over time. What do you say there? It can be a constant, but it doesn't have to look like, and then... No, it's not the only contribution to that term. So you can have a field.

that slowly varies over time. And that field may dominate. So that field is meta to that equation. Yes. Look at that. It is meta to that equation. Oh my gosh. Absolutely. So Einstein did not talk about that field. No, he didn't. No, he wasn't there yet. And you're right. And he did talk about the constant because you're right. It's just an integration constant. It's an integration constant. It's right there. It's a constant. It's a constant. Right. So if in fact it needs to modify because that's how they reconcile this tension in the age of the universe. Yes. Because the age of the universe, there's,

In my day, we didn't know it by a factor of two. Now people are, there's a 10% difference. So it's more than 6,000 years. Is what you're saying. Yes, that's exactly what I'm saying. Yes, yes, yes. When Noah's flood took place. So to relieve the tension, as we describe it, this was a 10%, some single digit percent.

of the age of the universe. Actually, not uncertainty. These two methods have very small, tight uncertainties that do not overlap. That's why everyone is freaking out. And as I learned recently, you can resolve that by allowing...

the cosmological constant to vary in some way, but that's a meta variation on top of Einstein. Yes, this Hubble tension that people are struggling with today is exactly something that also may point toward a dynamical value. So we'll see. But yes, the true test of a version of gravity that you fully understand with quantum mechanics included would be a calculation of the cosmological constant and get a number. Are you and your people smart enough to get that?

get this figured out? I don't think so. And that's how you're... Good answer. Because you know I've dragged you over the cold about that. We have come full circle. Because I've told him, I said, look, you know, Einstein came up with general relativity in 10 years by himself. You strength theorists, dozens of you have been working on this for decades. Either...

You're all wrong or you're all just too stupid to figure it out. And it's probably a combination. Love you, man. Brian, thanks for coming back to StarTalk. Always good, Chuck. So great. Chuck, we'll find you in the hospital. Bless you, Will. I'm completely fried right now. I'm fried. Just to take us out, let me remind us all, we are in my office at the Hayden Planetarium of the American Museum of Natural History. The Cosmic Crib. The Cosmic Crib.

And after this conversation we just had, I delight in realizing and celebrating the fact that just a few pounds of organic matter inside of our heads can not only contemplate, but figure out how the universe works. And yes, we still have a long way to go. And we don't even know how long a way to go remains in front of us. But

The distance we've come thus far gives us everything that we call civilization. And it's the power of mind over the mysteries of the universe. And that is a product of the eternal curiosity expressed by our species, beginning in childhood, continuing, for some, into adulthood. We call them scientists, those who never lost that childhood curiosity. Brian Greene, of course, among them. So...

I'd like to just give a shout out to our species for all it has wondered as we looked up at night, all that we have discovered, and all that we have yet to figure out. That is a cosmic perspective. I'm Neil deGrasse Tyson, your personal astrophysicist. Keep looking up.

Earning your degree online doesn't mean you have to go about it alone. At Capella University, we're here to support you when you're ready. From enrollment counselors who get to know you and your goals, to academic coaches who can help you form a plan to stay on track. We care about your success and are dedicated to helping you pursue your goals.

Going back to school is a big step, but having support at every step of your academic journey can make a big difference. Imagine your future differently at capella.edu.