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One thing that I really love about physics is that sometimes the laws of physics don't just work, they're actually pretty great.

One thing that I really love about physics is that sometimes the laws of physics don't just work, they're actually pretty great.

What do you mean physics can be pretty You know? I thought physics and science was like a hard hitting objective thing, you know, human endeavor.

What do you mean physics can be pretty You know? I thought physics and science was like a hard hitting objective thing, you know, human endeavor.

Absolutely, we got big tasks. We want to understand the universe and makes sense of it. But sometimes we come up with an idea, something that just looks beautiful, something which is has an innate elegance to it.

Absolutely, we got big tasks. We want to understand the universe and makes sense of it. But sometimes we come up with an idea, something that just looks beautiful, something which is has an innate elegance to it.

You mean, like you'd see a theory walking down the road and you'd be like, oh, man, that that theory hasn't going on.

You mean, like you'd see a theory walking down the road and you'd be like, oh, man, that that theory hasn't going on.

Yeah, there's some sexy curves in that theory.

Yeah, there's some sexy curves in that theory.

You mean like graphs though, right, like that.

You mean like graphs though, right, like that.

That kind of curves, right, that graph has a nice curve too, look at those peaks. And one of the most controversial theories of all time, one of the ones that gets people up in arms, is also one that's probably survived because it's so beautiful and elegant.

That kind of curves, right, that graph has a nice curve too, look at those peaks. And one of the most controversial theories of all time, one of the ones that gets people up in arms, is also one that's probably survived because it's so beautiful and elegant.

Is it the theory of attraction?

Is it the theory of attraction?

No, it's a theory that was once described as a piece of twenty first century physics that had fallen by accident into the twentieth century.

No, it's a theory that was once described as a piece of twenty first century physics that had fallen by accident into the twentieth century.

So it's a future.

So it's a future.

Babe, future babe exactly.

Babe, future babe exactly.

Hi. I'm Jorge.

Hi. I'm Jorge.

I'm a cartoonist, and I'm Daniel. I'm a particle physicist.

I'm a cartoonist, and I'm Daniel. I'm a particle physicist.

And we are the authors of the book We Have No Idea.

And we are the authors of the book We Have No Idea.

Which talks about all the things we don't know about the universe and how we might hope to one day understand them.

Which talks about all the things we don't know about the universe and how we might hope to one day understand them.

Yeah, So welcome to our podcast Daniel and Jorge explain the Universe, in.

Yeah, So welcome to our podcast Daniel and Jorge explain the Universe, in.

Which we take everything and anything in the universe and try to explain it to you in a way that makes sense and hopefully makes you laugh to be.

Which we take everything and anything in the universe and try to explain it to you in a way that makes sense and hopefully makes you laugh to be.

On the program. We're going to talk about string theory.

On the program. We're going to talk about string theory.

That's right, string theory. And this is a question that we've been getting from listeners. We ask people please send in your requests for topics, and maybe more than fifty percent of the request work. Can you explain string theory? What is string theory? Talk about string.

That's right, string theory. And this is a question that we've been getting from listeners. We ask people please send in your requests for topics, and maybe more than fifty percent of the request work. Can you explain string theory? What is string theory? Talk about string.

Theory more than fifty percent, Yeah.

Theory more than fifty percent, Yeah.

And it's fascinating, it's because string theory really is a part of the sort of cultural zeitgeist. It's like an idea that people know exists, even if they don't understand it.

And it's fascinating, it's because string theory really is a part of the sort of cultural zeitgeist. It's like an idea that people know exists, even if they don't understand it.

But it's a big part of that show, The Big Bang Theory, right, Like the people in that show they supposedly study string theory.

But it's a big part of that show, The Big Bang Theory, right, Like the people in that show they supposedly study string theory.

I don't know. I don't watch that.

I don't know. I don't watch that.

Show me neither, but that's what I've been told.

Show me neither, but that's what I've been told.

Your cultural advice expert has told you, yeah, that this is a cultural relevant thing. Well, yeah, it's it's something people have heard about. Well have you heard about string theory before you started spending your time talking to physicists.

Your cultural advice expert has told you, yeah, that this is a cultural relevant thing. Well, yeah, it's it's something people have heard about. Well have you heard about string theory before you started spending your time talking to physicists.

Oh, yeah, I'd heard about it. You know, it's one of these things that you hear a lot about. It's these like crazy theory about the universe, but it's really and you know, you hear certain things about it, like, oh, everything is made out of strings, but you don't really kind of know what it is and what does it mean for things to be strings.

Oh, yeah, I'd heard about it. You know, it's one of these things that you hear a lot about. It's these like crazy theory about the universe, but it's really and you know, you hear certain things about it, like, oh, everything is made out of strings, but you don't really kind of know what it is and what does it mean for things to be strings.

You're a very visual person. What image do you get in your head if I tell you everything is made out of strings? Do you get like a universe an idea of like a universe where everything is crocheted out of yarn? Or how does it work in your head?

You're a very visual person. What image do you get in your head if I tell you everything is made out of strings? Do you get like a universe an idea of like a universe where everything is crocheted out of yarn? Or how does it work in your head?

I would just ask what are those strings made out of?

I would just ask what are those strings made out of?

Right? Right? Of course, so you are a physicist at Hard, right, because every question just leads to the next question.

Right? Right? Of course, so you are a physicist at Hard, right, because every question just leads to the next question.

That's right, Yeah, beautiful physicists at hard supermodel on the outside.

That's right, Yeah, beautiful physicists at hard supermodel on the outside.

No comment, But I thought it was an interesting question to tackle because it's something everybody's heard about, but very few people actually understand. I think that's why people wanted us to talk about it. Say that, can you make this not just something we've heard this phrase, but something where we can know what it means and get some insight into why people are spending their time doing it? Damn.

No comment, But I thought it was an interesting question to tackle because it's something everybody's heard about, but very few people actually understand. I think that's why people wanted us to talk about it. Say that, can you make this not just something we've heard this phrase, but something where we can know what it means and get some insight into why people are spending their time doing it? Damn.

So, as usual, we went out into the street and ask, do you know what string theory is?

So, as usual, we went out into the street and ask, do you know what string theory is?

Yeah, So before you hear these answers, think for a moment, could you define string theory? Do you know what it is and why it's persisted for so long? Here's what people who I asked had to say.

Yeah, So before you hear these answers, think for a moment, could you define string theory? Do you know what it is and why it's persisted for so long? Here's what people who I asked had to say.

No, I have no idea what that is. No, I do not I've heard of it. My only way of Big bang theory?

No, I have no idea what that is. No, I do not I've heard of it. My only way of Big bang theory?

Okay, awesome, I don't know. I'm sorry.

Okay, awesome, I don't know. I'm sorry.

Trying to measure the connectedness of Adams and sub atomic particles, I believe.

Trying to measure the connectedness of Adams and sub atomic particles, I believe.

Okay, it's something that Sheldon worked on big bank theory.

Okay, it's something that Sheldon worked on big bank theory.

Yes, okay. So first of all, it's kind of interesting because you normally you go out into your university campus to ask people, but this time you went somewhere different.

Yes, okay. So first of all, it's kind of interesting because you normally you go out into your university campus to ask people, but this time you went somewhere different.

Yeah, that's right. You see, Irvine was closed for a holiday, so instead I went to the mall here at Irvine, the Spectrum, and I asked a bunch of random strangers questions about science. And again I was struck by how many people were willing to answer my questions. I thought people would say, who are you? Go away security security? Right?

Yeah, that's right. You see, Irvine was closed for a holiday, so instead I went to the mall here at Irvine, the Spectrum, and I asked a bunch of random strangers questions about science. And again I was struck by how many people were willing to answer my questions. I thought people would say, who are you? Go away security security? Right?

Maybe they sense a certain beauty about you, Daniel, You're like, who is this beautiful as the specimen of a person?

Maybe they sense a certain beauty about you, Daniel, You're like, who is this beautiful as the specimen of a person?

No?

No?

Who is it? I said? Apparently I just don't look very threatening, you know, I look like I could get knocked over with just a passing breeze or something. Uh huh. So everybody was willing to engage, which was awesome, and people had some pretty fun ideas, and everybody had heard of it. Nobody had said huh what, And your other speculation was correct. Some people had heard of string theory specifically, because of the Big Bang theory. So thank you Big Bang Theory. You've mined all this juice from nerd culture and you have actually communicated something to the public. So congratulations. Nobody understands what string theory is, but they do understand that it is a theory.

Who is it? I said? Apparently I just don't look very threatening, you know, I look like I could get knocked over with just a passing breeze or something. Uh huh. So everybody was willing to engage, which was awesome, and people had some pretty fun ideas, and everybody had heard of it. Nobody had said huh what, And your other speculation was correct. Some people had heard of string theory specifically, because of the Big Bang theory. So thank you Big Bang Theory. You've mined all this juice from nerd culture and you have actually communicated something to the public. So congratulations. Nobody understands what string theory is, but they do understand that it is a theory.

Well, I think that show doesn't even try to explain it, right, They almost use it for the opposite effect, Like, let's depict our character as this impenetrable, unrelatable genius that speaks gobblygoog, So we'll just haven't talk about string theory that nobody and nobody's going to understand that.

Well, I think that show doesn't even try to explain it, right, They almost use it for the opposite effect, Like, let's depict our character as this impenetrable, unrelatable genius that speaks gobblygoog, So we'll just haven't talk about string theory that nobody and nobody's going to understand that.

So it's like, so you're saying string theory represents the impenetrability of physics. I think it's more important to explain these things to people rather than just toss these words around and try to intimidate people.

So it's like, so you're saying string theory represents the impenetrability of physics. I think it's more important to explain these things to people rather than just toss these words around and try to intimidate people.

So yeah, I think that's what I mean. It's like they use it to intimidate people about physics.

So yeah, I think that's what I mean. It's like they use it to intimidate people about physics.

Yeah, when physics is nothing but warm and cuddly and just wants to explain the universe to you. Man, there's nothing intimidating about physics, right, It's about revealing secrets and giving understanding and inside and appreciating beauty. And that's the thing about string theory is it doesn't just potentially explain a lot of things. It also offers some elegance, some gorgeousness, like a peak into what nature is doing underneath. Because you know, you can have ugly theories and you can have elegant theories. You know, you might ask the difference, like how what is the difference? Yeah, I can ask you the same question about art, right, Like I look at a Kandinsky and I say, hey, that's beautiful, and somebody else says, whatever, I could do that in an afternoon. It's garbage. It's subjective, right, you can't. It's like the whole question of what is beauty something that's very difficult to nail down, right, So you shouldn't judge of painting by the same metric used to judge of physics theory. And you know, two physicists can disagree about what theory is pretty and what theory is ugly. So it's it's totally subjective. It's not an objective like.

Yeah, when physics is nothing but warm and cuddly and just wants to explain the universe to you. Man, there's nothing intimidating about physics, right, It's about revealing secrets and giving understanding and inside and appreciating beauty. And that's the thing about string theory is it doesn't just potentially explain a lot of things. It also offers some elegance, some gorgeousness, like a peak into what nature is doing underneath. Because you know, you can have ugly theories and you can have elegant theories. You know, you might ask the difference, like how what is the difference? Yeah, I can ask you the same question about art, right, Like I look at a Kandinsky and I say, hey, that's beautiful, and somebody else says, whatever, I could do that in an afternoon. It's garbage. It's subjective, right, you can't. It's like the whole question of what is beauty something that's very difficult to nail down, right, So you shouldn't judge of painting by the same metric used to judge of physics theory. And you know, two physicists can disagree about what theory is pretty and what theory is ugly. So it's it's totally subjective. It's not an objective like.

A fetish, like a you know, I like this kind of theory, I like that kind of theory.

A fetish, like a you know, I like this kind of theory, I like that kind of theory.

Yeah, I like you know, I like theories with handcuffs in them instead of strings. Right, my handcuff theory of the universe. That's where that's where you're going.

Yeah, I like you know, I like theories with handcuffs in them instead of strings. Right, my handcuff theory of the universe. That's where that's where you're going.

Theories or you know. Okay, So let's break it down for people. What is string theory?

Theories or you know. Okay, So let's break it down for people. What is string theory?

Right? So string theory is basically is the idea that the smallest elements of matter, the things that things are made out of, are not points, not particles, but instead they're lines, their strings, strings of what strings of basic universes stuff?

Right? So string theory is basically is the idea that the smallest elements of matter, the things that things are made out of, are not points, not particles, but instead they're lines, their strings, strings of what strings of basic universes stuff?

Right, So, like the electron is not like a little ball. We know, it's like a quantum object, which is like a point point with some kind of probability. But you're saying if you zoom in even more, maybe you would see a little squiggle there.

Right, So, like the electron is not like a little ball. We know, it's like a quantum object, which is like a point point with some kind of probability. But you're saying if you zoom in even more, maybe you would see a little squiggle there.

Yeah, And there's sort of two ideas there. One is what is the most basic element? And the second is is there a most basic element? So this assumes that there is a most basic element. You know that you look at something next to you, pick up in the nearest object you have, you know, maybe it's an apple, maybe it's a platypus, maybe it's a you know, I don't know what, and think about what it's made out. If it's made of molecules, right, tear those apart, you get atoms. Tear those atoms apart, you get protons and neutrons, electrons, tear those apart, you get quarks. Right, and you could keep going and eventually you get to smaller and smaller particles. Right. The question is do you ever get to the smallest particle? Right? That's one question? Is there a smallest thing? And we covered that in a whole podcast, but here we're just going to assume that there is. Right, at some point you get down the most basic thing where you're not allowed to ask what it's made out of because it's made out of the most basic universe stuff.

Yeah, And there's sort of two ideas there. One is what is the most basic element? And the second is is there a most basic element? So this assumes that there is a most basic element. You know that you look at something next to you, pick up in the nearest object you have, you know, maybe it's an apple, maybe it's a platypus, maybe it's a you know, I don't know what, and think about what it's made out. If it's made of molecules, right, tear those apart, you get atoms. Tear those atoms apart, you get protons and neutrons, electrons, tear those apart, you get quarks. Right, and you could keep going and eventually you get to smaller and smaller particles. Right. The question is do you ever get to the smallest particle? Right? That's one question? Is there a smallest thing? And we covered that in a whole podcast, but here we're just going to assume that there is. Right, at some point you get down the most basic thing where you're not allowed to ask what it's made out of because it's made out of the most basic universe stuff.

It's like the one circle on a lego set. It's like you can get any smaller.

It's like the one circle on a lego set. It's like you can get any smaller.

Than that, Right, it's the unit exactly, And that you might feel like that, well, that's frustrating. Why can't I ask what it's made out of? You know? But it's also not frustrating because it would be the answer. I mean, if you actually got there and you said, look, everything in the universe is made out of this one basic thing. That's a deep insight. Right, that's what we're going for. That's the day we wish for that we peel back a layer of reality and see, ah, everything is made out of this thing, because then you can ask why this thing? What does that mean? Oh? I see?

Than that, Right, it's the unit exactly, And that you might feel like that, well, that's frustrating. Why can't I ask what it's made out of? You know? But it's also not frustrating because it would be the answer. I mean, if you actually got there and you said, look, everything in the universe is made out of this one basic thing. That's a deep insight. Right, that's what we're going for. That's the day we wish for that we peel back a layer of reality and see, ah, everything is made out of this thing, because then you can ask why this thing? What does that mean? Oh? I see?

So string theory is saying that everything electrons. Course, eventually, if you break them down, you'll get to this one type of string.

So string theory is saying that everything electrons. Course, eventually, if you break them down, you'll get to this one type of string.

That's right. We think of things being made of particles. We think of them as tiny dots right in space. But string theory says they're not dots, they're lines, okay, And there are these loops and wiggles instead of being dots. And then everything is made out of these strings. And you might ask, well, how can you get different kinds of particles, for example, out of one kind of string? Right? And the idea there is that this strings can vibrate, The strings can wiggle, right, the reverberations in the string just like you know a rubber band or a string.

That's right. We think of things being made of particles. We think of them as tiny dots right in space. But string theory says they're not dots, they're lines, okay, And there are these loops and wiggles instead of being dots. And then everything is made out of these strings. And you might ask, well, how can you get different kinds of particles, for example, out of one kind of string? Right? And the idea there is that this strings can vibrate, The strings can wiggle, right, the reverberations in the string just like you know a rubber band or a string.

Is it like an actual vibration like it goes up and down? Or is it just like the different shapes you can make with a string.

Is it like an actual vibration like it goes up and down? Or is it just like the different shapes you can make with a string.

Oh I see, No, it's actual motion of the string. Yeah, And so it's diff different vibrational modes. Yes, So they get excited and they can get to this state or that state. As the string vibrates in different ways, it makes different particles. So some tiny particle calling it said an electron, for example, is actually a string vibrating this way, and quark is a string vibrating the other way, and a nutrino is a string vibrating a third way. So the same thing with different vibrations can appear as different particles.

Oh I see, No, it's actual motion of the string. Yeah, And so it's diff different vibrational modes. Yes, So they get excited and they can get to this state or that state. As the string vibrates in different ways, it makes different particles. So some tiny particle calling it said an electron, for example, is actually a string vibrating this way, and quark is a string vibrating the other way, and a nutrino is a string vibrating a third way. So the same thing with different vibrations can appear as different particles.

Oh okay, So it's not like different strings and a guitar. That's not what we're talking about. We're talking about one string. It's like a one string guitar, and just the different ways in which it can vibrate that gives rise to all the different stuff we see in the universe exactly.

Oh okay, So it's not like different strings and a guitar. That's not what we're talking about. We're talking about one string. It's like a one string guitar, and just the different ways in which it can vibrate that gives rise to all the different stuff we see in the universe exactly.

And like a guitar, can pluck the string differently and you can get different notes, right, you can based on how fast it's vibrating, and you know where you put your finger in the end, you can get different notes out of the same string. And it's key here that it's one string, right, it's a single string. Because we're trying to explain everything in the universe in terms of one object. So we're trying to explain how you get all this complexity in terms of one thing. And that's the answer from string theory, is that the string has different modes to it. The string can do different things, right, And you know, you might think that that's sort of weird, Like I expect stuff, if it's all made of the same thing, to be the same thing, right, Like if everything is made of the same stuff, why is this red and that blue? And this tastes delicious and this tastes terrible, right, right? And it comes from the way it's vibrating. It's kind of like maybe light. You know, light is just made out of one thing, photons, but depending on the frequency, then it's different colors. Yeah, exactly. And the way things move and vibrate it can totally affect the way we perceive them. You know, think about for example, water, Right, water is made out of water molecules. So is ice, and so is steam. Right, they're made out of the same thing, but we feel them, we experience them very differently because of the way they're moving. Right. Steam and liquid water have the water particles moving more than in ice, right, And so it's the motion of those particles that generates the macroscopic qualities that we use to define it. So the things we used to define the electron, and things we used to define a quark actually come just from the vibrations of these strings again according to this theory.

And like a guitar, can pluck the string differently and you can get different notes, right, you can based on how fast it's vibrating, and you know where you put your finger in the end, you can get different notes out of the same string. And it's key here that it's one string, right, it's a single string. Because we're trying to explain everything in the universe in terms of one object. So we're trying to explain how you get all this complexity in terms of one thing. And that's the answer from string theory, is that the string has different modes to it. The string can do different things, right, And you know, you might think that that's sort of weird, Like I expect stuff, if it's all made of the same thing, to be the same thing, right, Like if everything is made of the same stuff, why is this red and that blue? And this tastes delicious and this tastes terrible, right, right? And it comes from the way it's vibrating. It's kind of like maybe light. You know, light is just made out of one thing, photons, but depending on the frequency, then it's different colors. Yeah, exactly. And the way things move and vibrate it can totally affect the way we perceive them. You know, think about for example, water, Right, water is made out of water molecules. So is ice, and so is steam. Right, they're made out of the same thing, but we feel them, we experience them very differently because of the way they're moving. Right. Steam and liquid water have the water particles moving more than in ice, right, And so it's the motion of those particles that generates the macroscopic qualities that we use to define it. So the things we used to define the electron, and things we used to define a quark actually come just from the vibrations of these strings again according to this theory.

Okay, so then, but then my question is still what are these strings made? Is it just like made out of universe?

Okay, so then, but then my question is still what are these strings made? Is it just like made out of universe?

I told you, Jorge, you're not less to ask once we get down to the lowest level, no more questions.

I told you, Jorge, you're not less to ask once we get down to the lowest level, no more questions.

No, but do you know what I mean? Like is it like a like a physical string or just like a mathematical string? Do you know what I mean?

No, but do you know what I mean? Like is it like a like a physical string or just like a mathematical string? Do you know what I mean?

Like? Is now ooh, prepare for a philosophical detour here, like.

Like? Is now ooh, prepare for a philosophical detour here, like.

What's actually vibrating like universe stuff?

What's actually vibrating like universe stuff?

Yeah? Yeah, well, because I still look in the end, all physics theories are just models. Right, you can ask the question is is really happening or is this just a mathematical model in my head? I use to do calculations and predict the results of experiments. Okay, boom. That is a big philosophical question, right, and there's no way to answer that. So we think of these things as models in our head reflect reality. Okay, you know the top quark, does it exist or not? Or is it just a calculation model in my head? We could you know, smoke banana peels and talk about that for a long time without making any progress.

Yeah? Yeah, well, because I still look in the end, all physics theories are just models. Right, you can ask the question is is really happening or is this just a mathematical model in my head? I use to do calculations and predict the results of experiments. Okay, boom. That is a big philosophical question, right, and there's no way to answer that. So we think of these things as models in our head reflect reality. Okay, you know the top quark, does it exist or not? Or is it just a calculation model in my head? We could you know, smoke banana peels and talk about that for a long time without making any progress.

So this model is just asking me to imagine that the most fundamental thing in the universe are these little strings. They can vibrate in different ways. But then these strings can move around.

So this model is just asking me to imagine that the most fundamental thing in the universe are these little strings. They can vibrate in different ways. But then these strings can move around.

And they can't be cut into pieces. Right, you can't get anything smaller than a string. It's the most basic unit.

And they can't be cut into pieces. Right, you can't get anything smaller than a string. It's the most basic unit.

Oh, like, there's something about the stuff of the universe that is just you can't vibrate or do things shorter than these little strings.

Oh, like, there's something about the stuff of the universe that is just you can't vibrate or do things shorter than these little strings.

Yeah, exactly. Well I think about it from the other direction. You know, how do you make a universe? Well, you start with a huge pile of tiny strings, and then the way those strings interact it gives you all sorts of interesting structure. But that's what you start art from, right, that's the universe's initial condition is like a huge pile of strings.

Yeah, exactly. Well I think about it from the other direction. You know, how do you make a universe? Well, you start with a huge pile of tiny strings, and then the way those strings interact it gives you all sorts of interesting structure. But that's what you start art from, right, that's the universe's initial condition is like a huge pile of strings.

And these strings can move around space.

And these strings can move around space.

Yeah, they move and they interact with each other, right, and that's where all the interesting stuff.

Yeah, they move and they interact with each other, right, and that's where all the interesting stuff.

But are these related to like quantum fields? How does that relate quantum fields?

But are these related to like quantum fields? How does that relate quantum fields?

Yeah? So everything we'd be built out of these strings, including all the particles and all the forces, and that's actually why string theory is so popular because string theory, we think, can explain some of the mysteries of quantum fields and some of the mysteries of how to bring gravity into the fold and describe it in terms of a quantum field. So the short answer to your question is, all the quantum fields arise from these string interactions. Mmmm.

Yeah? So everything we'd be built out of these strings, including all the particles and all the forces, and that's actually why string theory is so popular because string theory, we think, can explain some of the mysteries of quantum fields and some of the mysteries of how to bring gravity into the fold and describe it in terms of a quantum field. So the short answer to your question is, all the quantum fields arise from these string interactions. Mmmm.

All these fields, all these particles just come from this one string guitar being plugged at different frequencies.

All these fields, all these particles just come from this one string guitar being plugged at different frequencies.

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All right, so that's a crazy concept to ask people to digest. But let's assume that that's the theory. Who came up with this and why do we think it's a good theory about the universe?

All right, so that's a crazy concept to ask people to digest. But let's assume that that's the theory. Who came up with this and why do we think it's a good theory about the universe?

Yes, so string theories had a lot of people contribute to it. It's sort of an old theory that started out trying to explain something else and then was tossed aside when it didn't work, and then was later picked up again and reused to as a theory of everything. And this sort of idea of string theory is to take a different approach to solving this question of what is the universe made out of? As an experimentalist, my approach is take something concrete, break it into pieces, get smaller and smaller and smaller. You know, as you discover new stuff, you're revealing secrets of the universe, and just keep going until you get to the smallest bit, sort of via top down approach. Right, this idea is different. This is sort of a bottom up They say, let's just start at the very bottom. Let's go to the most basic element and try to explain the universe from the start. You know, if a hypothesize the universes made of strings, can we put them together in a way that explains the universe and describe everything we see around us.

Yes, so string theories had a lot of people contribute to it. It's sort of an old theory that started out trying to explain something else and then was tossed aside when it didn't work, and then was later picked up again and reused to as a theory of everything. And this sort of idea of string theory is to take a different approach to solving this question of what is the universe made out of? As an experimentalist, my approach is take something concrete, break it into pieces, get smaller and smaller and smaller. You know, as you discover new stuff, you're revealing secrets of the universe, and just keep going until you get to the smallest bit, sort of via top down approach. Right, this idea is different. This is sort of a bottom up They say, let's just start at the very bottom. Let's go to the most basic element and try to explain the universe from the start. You know, if a hypothesize the universes made of strings, can we put them together in a way that explains the universe and describe everything we see around us.

But I guess, how did someone even think of using strings? How do you make a lot of things out of one thing? And a little string that vibrates different ways is one way to get a lot of things out of one simple thing? Is that kind of the origins of it?

But I guess, how did someone even think of using strings? How do you make a lot of things out of one thing? And a little string that vibrates different ways is one way to get a lot of things out of one simple thing? Is that kind of the origins of it?

Yeah, exactly, you should imagine. Physicists are basically random, terrible idea generators, okay, and most of those just don't work. So at some point somebody is like fed up with thinking about the universe in terms of particles, and they're like, well, what if they're not you know, what if they're not dots? Let's just try it with lines. Does that work? You know? And basically every idea that you can imagine, somebody has tried to make that work as a theory of everything and usually given up after about two seconds because the theory of everything based out of little puppies or whatever doesn't work. It's very hard to make that put together.

Yeah, exactly, you should imagine. Physicists are basically random, terrible idea generators, okay, and most of those just don't work. So at some point somebody is like fed up with thinking about the universe in terms of particles, and they're like, well, what if they're not you know, what if they're not dots? Let's just try it with lines. Does that work? You know? And basically every idea that you can imagine, somebody has tried to make that work as a theory of everything and usually given up after about two seconds because the theory of everything based out of little puppies or whatever doesn't work. It's very hard to make that put together.

But like they said, what if there's just one particle that makes up everything, how would you explain how this one particle can turn into other things? And so that's kind of difficult maybe, but a string, you can imagine it vibrating or moving in different ways to give rise to different particles.

But like they said, what if there's just one particle that makes up everything, how would you explain how this one particle can turn into other things? And so that's kind of difficult maybe, but a string, you can imagine it vibrating or moving in different ways to give rise to different particles.

Right, yeah, exactly. And people were playing with it and they're like, what can we do with this? And they tried, Like I said, they try to use it to solve other problems. Specifically, they try to understand the strong nuclear force using strings, and it didn't work. And then later somebody else said, huh, I heard about this idea of strings. I wonder if I can use that to solve this other problem, which is why can't we get gravity to play well with the other forces. You know, if you want to understand the way the universe works, you have to try to explain everything in terms of one theory, right, to bring it all together into a single explanation.

Right, yeah, exactly. And people were playing with it and they're like, what can we do with this? And they tried, Like I said, they try to use it to solve other problems. Specifically, they try to understand the strong nuclear force using strings, and it didn't work. And then later somebody else said, huh, I heard about this idea of strings. I wonder if I can use that to solve this other problem, which is why can't we get gravity to play well with the other forces. You know, if you want to understand the way the universe works, you have to try to explain everything in terms of one theory, right, to bring it all together into a single explanation.

Because that's a big problem right now in physics. Right, it's like marrying quantum physics with gravity.

Because that's a big problem right now in physics. Right, it's like marrying quantum physics with gravity.

That's right, It's a marriage we've been trying to arrange forever, but to participants just do not want to person do not want to play along, exactly.

That's right, It's a marriage we've been trying to arrange forever, but to participants just do not want to person do not want to play along, exactly.

They don't like pressure.

They don't like pressure.

Yes, so we have these sort of two towering achievements of physics. On one hand, quantum mechanics, right, a revelation about one hundred years old. That tells us that the universe is very different from the way we thought it was. That there's uncertainties, that there's fuzziness, a limited amount of knowledge we can actually obtain about the universe. And it's most specifically that the universe is quantized. It's broken up into discrete little chunks. Right. And on the other hand, we have gravity and general relativity, which is an incredibly successful theory that describes the motion of planets around stars and black holes and all sorts of crazy stuff and time dilation in the way space and time are connected, all this incredible stuff. But it assumes the universe is not quantum mechanical, right. It assumes that that energy can be subdivided into arbitrarily small bits, and that you can have an infinite number of locations and an infinite amount of information. Right. And so the two theories are not consistent, and most of the time they're talking about different stuff, so they don't overlap. Sometimes, like when you're talking about a black hole, then the two give you very different stories.

Yes, so we have these sort of two towering achievements of physics. On one hand, quantum mechanics, right, a revelation about one hundred years old. That tells us that the universe is very different from the way we thought it was. That there's uncertainties, that there's fuzziness, a limited amount of knowledge we can actually obtain about the universe. And it's most specifically that the universe is quantized. It's broken up into discrete little chunks. Right. And on the other hand, we have gravity and general relativity, which is an incredibly successful theory that describes the motion of planets around stars and black holes and all sorts of crazy stuff and time dilation in the way space and time are connected, all this incredible stuff. But it assumes the universe is not quantum mechanical, right. It assumes that that energy can be subdivided into arbitrarily small bits, and that you can have an infinite number of locations and an infinite amount of information. Right. And so the two theories are not consistent, and most of the time they're talking about different stuff, so they don't overlap. Sometimes, like when you're talking about a black hole, then the two give you very different stories.

Okay, so how is string theory able to marry gravity and quantum mechanics?

Okay, so how is string theory able to marry gravity and quantum mechanics?

Right, So that is exactly the right question, how does string theory allow us to bring together quantum mechanics and gravity. Well to understand that, you really have to understand why we failed without string theory. And the problem is that when you bring together quantum mechanics and gravity, you get lots of infinities. Right A theory doesn't work when it can't predict the results of experiments. So if you ask a theory what happens when I smash two particles together, it should give you a reasonable answer. If the answer is infinity, or you know, nothing will happen or something, then it doesn't make any sense. It has to get physical answers, and infinity is not a physical answer. The problem is when you try to bring gravity into quantum mechanics, you get lots of these infinities. And the infinities come because of the point particles, because you're trying to treat these objects as if they're just dots in space, and that leads to lots of craziness. You know, how do you have mass in a tiny little dot in space that has infinite density? Right now, we have lots of other theories that do play well with quantum mechanics. Electromagnetism, for example, very happily married with quantum mechanics. And the reason that works is that we have tricks to hide those infinities. We can bundle up those infinities that pop up from the point particles in various other ways mathematical tricks. Those tricks don't work for gravity because gravity is very different from the other forces. The strength of the force grows with the energy of the object, right, So in this case, when an object has more and more energy, it feels more and more gravity, right, because gravity is proportional as the amount of energy in an object. So the typical tricks we use to hide those infinities under the rug that works for quantum electrodynamics doesn't work for gravity when we try to do quantum gravity. So how does string theory to solve that problem? Simple? It just says there are no points. It says, at the smallest scale, you don't have to worry about dealing with gravity tiny points because there are none. Because that it's smallest scale. The universe is not made of points but strings, and so it's a nice way to sort of circumvent that problem. And that's why string theory can bring together quantum mechanics and gravity so nicely and that got people excited, and that's where the beauty was. People were like, wow, and it's beautiful. There's like these strings floating around and you get these membranes, and it seemed really cool to people.

Right, So that is exactly the right question, how does string theory allow us to bring together quantum mechanics and gravity. Well to understand that, you really have to understand why we failed without string theory. And the problem is that when you bring together quantum mechanics and gravity, you get lots of infinities. Right A theory doesn't work when it can't predict the results of experiments. So if you ask a theory what happens when I smash two particles together, it should give you a reasonable answer. If the answer is infinity, or you know, nothing will happen or something, then it doesn't make any sense. It has to get physical answers, and infinity is not a physical answer. The problem is when you try to bring gravity into quantum mechanics, you get lots of these infinities. And the infinities come because of the point particles, because you're trying to treat these objects as if they're just dots in space, and that leads to lots of craziness. You know, how do you have mass in a tiny little dot in space that has infinite density? Right now, we have lots of other theories that do play well with quantum mechanics. Electromagnetism, for example, very happily married with quantum mechanics. And the reason that works is that we have tricks to hide those infinities. We can bundle up those infinities that pop up from the point particles in various other ways mathematical tricks. Those tricks don't work for gravity because gravity is very different from the other forces. The strength of the force grows with the energy of the object, right, So in this case, when an object has more and more energy, it feels more and more gravity, right, because gravity is proportional as the amount of energy in an object. So the typical tricks we use to hide those infinities under the rug that works for quantum electrodynamics doesn't work for gravity when we try to do quantum gravity. So how does string theory to solve that problem? Simple? It just says there are no points. It says, at the smallest scale, you don't have to worry about dealing with gravity tiny points because there are none. Because that it's smallest scale. The universe is not made of points but strings, and so it's a nice way to sort of circumvent that problem. And that's why string theory can bring together quantum mechanics and gravity so nicely and that got people excited, and that's where the beauty was. People were like, wow, and it's beautiful. There's like these strings floating around and you get these membranes, and it seemed really cool to people.

So you said something interesting, which was it? People thought that string theory was beautiful and elegant. So can you try to explain like why people thought that, Like is it simple or is it just it's so open ended or it just seems to be working or it doesn't fall into the ugliness of other theories.

So you said something interesting, which was it? People thought that string theory was beautiful and elegant. So can you try to explain like why people thought that, Like is it simple or is it just it's so open ended or it just seems to be working or it doesn't fall into the ugliness of other theories.

I think people just have fun working with it, you know. I think it's I think it stimulates people's imaginations can have fun, and physicists can have fun. Yeah, And you know, when you do string theory, you write down these diagrams and instead of these diagrams being lines with Swiggs, the diagrams are like loops and they have sheets and to connect them, you know, membranes, and you get to think about these high dimensional surfaces and people have a lot of fun with them, and it's been so invigorating for physicists. That's actually led to a lot of good results just in mathematics, Like mathematicians have learned about things from the things the physicists have done while exploring its string theory. Wow, and so it's stimulated the whole field of mathematics. And you know, mathematics is about the beauty and interconnectedness of numbers. They don't care if it actually describes anything in the real world, right, it's about these abstract ideas and how they come together. And one of the lead physicists who works on string theory is name is Ed Witten. He won what's basically the Nobel Prize for math, which is the field metal, which is even harder to win than the Nobel Prize because they only give it every two years. And he's a physicist, and he won the top prize in mathematics for advances in string theory, which tells you that there's a huge amount of mathematical machinery that's been invented here. And these folks they love it like it's fascination for them. It's a there's a deep pleasure in manipulating these equations and in thinking about it.

I think people just have fun working with it, you know. I think it's I think it stimulates people's imaginations can have fun, and physicists can have fun. Yeah, And you know, when you do string theory, you write down these diagrams and instead of these diagrams being lines with Swiggs, the diagrams are like loops and they have sheets and to connect them, you know, membranes, and you get to think about these high dimensional surfaces and people have a lot of fun with them, and it's been so invigorating for physicists. That's actually led to a lot of good results just in mathematics, Like mathematicians have learned about things from the things the physicists have done while exploring its string theory. Wow, and so it's stimulated the whole field of mathematics. And you know, mathematics is about the beauty and interconnectedness of numbers. They don't care if it actually describes anything in the real world, right, it's about these abstract ideas and how they come together. And one of the lead physicists who works on string theory is name is Ed Witten. He won what's basically the Nobel Prize for math, which is the field metal, which is even harder to win than the Nobel Prize because they only give it every two years. And he's a physicist, and he won the top prize in mathematics for advances in string theory, which tells you that there's a huge amount of mathematical machinery that's been invented here. And these folks they love it like it's fascination for them. It's a there's a deep pleasure in manipulating these equations and in thinking about it.

Oh, usually it's the other way around, Like usually you guys have to come over the theory and convince mathematicians that this is something fundamental. Yeah, here it seems to be coming from the other way. It's like, here's something that even mathematicians think might be fundamental about the universe.

Oh, usually it's the other way around, Like usually you guys have to come over the theory and convince mathematicians that this is something fundamental. Yeah, here it seems to be coming from the other way. It's like, here's something that even mathematicians think might be fundamental about the universe.

Well, I don't know if mathematicians think it's fundamental about the universe. They just think it helps solve interesting problems. They're like, ooh, this is a cool tool. It can solve some problems in math, or it gives us a new way to think about mathematical problems. You know, and anytime you get a new tool, it's fascinating. And you imagine, for example, you're an artist and somebody invents a new musical instrument and you're like, ooh cool, what can I use this for? I can invent a new kind of music. I can I have a new kind of rhythm or a new kind of song. Or in the same way, you create a new physics theory, a new basic object get to play with. It's exciting. It gives you things to play with and ideas to try.

Well, I don't know if mathematicians think it's fundamental about the universe. They just think it helps solve interesting problems. They're like, ooh, this is a cool tool. It can solve some problems in math, or it gives us a new way to think about mathematical problems. You know, and anytime you get a new tool, it's fascinating. And you imagine, for example, you're an artist and somebody invents a new musical instrument and you're like, ooh cool, what can I use this for? I can invent a new kind of music. I can I have a new kind of rhythm or a new kind of song. Or in the same way, you create a new physics theory, a new basic object get to play with. It's exciting. It gives you things to play with and ideas to try.

And so like physicists said, hey, look, I have a one string guitar, and theses were.

And so like physicists said, hey, look, I have a one string guitar, and theses were.

Like, whoa, I can play the whole universe and that thing. But you know, string theory has a lot of people who love it and adherents, and a lot of people in departments who are working on it. But there are also a lot of people who don't like string theory. It's got sort of a backlash as well. Any part you know you've made it as a physics theory when you have haters, right.

Like, whoa, I can play the whole universe and that thing. But you know, string theory has a lot of people who love it and adherents, and a lot of people in departments who are working on it. But there are also a lot of people who don't like string theory. It's got sort of a backlash as well. Any part you know you've made it as a physics theory when you have haters, right.

Oh, physics haters. All right, let's get into it, But first, let's take a quick break.

Oh, physics haters. All right, let's get into it, But first, let's take a quick break.

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There are children, friends, and families walking, riding on passing the roads every day. Remember they're real people with loved ones who need them to get home safely. Protect our cyclists and pedestrians because they're people too.

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California from the California Office of Traffic Safety and Caltrans.

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All right, So, string theory has its haters, people who don't think it's all that or who think it might be wrong, or maybe it's not all that beautiful. So what are some of the arguments against string theory.

All right, So, string theory has its haters, people who don't think it's all that or who think it might be wrong, or maybe it's not all that beautiful. So what are some of the arguments against string theory.

Yeah, so I would say there's really two categories of attacks people make against string theory. One is there are just too many of them, and the other is that we can't test it.

Yeah, so I would say there's really two categories of attacks people make against string theory. One is there are just too many of them, and the other is that we can't test it.

Too many string theories.

Too many string theories.

Too many string theories.

Too many string theories.

It's not a singular concept, you know, string theory. It's actually string theories. I'm trilogy a string theories.

It's not a singular concept, you know, string theory. It's actually string theories. I'm trilogy a string theories.

String theory, there are a lot of There are a lot of these things. There's lots of ways that you can put it together, lots of different ways you can shape the string, and lots of ways you can have them interact with each other. And you know, we were saying earlier, you'd like a simple theory. You'd like to make your choices for how you build the theory not be arbitrary, but before by the mathematical construction. You know, like why is there a three here? It's the only way that it works. So we have a theory where there are lots of ways it could work. Then you have a question like which way do we choose? And that's the problem with string theory. There's lots of ways to build one.

String theory, there are a lot of There are a lot of these things. There's lots of ways that you can put it together, lots of different ways you can shape the string, and lots of ways you can have them interact with each other. And you know, we were saying earlier, you'd like a simple theory. You'd like to make your choices for how you build the theory not be arbitrary, but before by the mathematical construction. You know, like why is there a three here? It's the only way that it works. So we have a theory where there are lots of ways it could work. Then you have a question like which way do we choose? And that's the problem with string theory. There's lots of ways to build one.

They all have the same basic idea, right, which is that the universe is made out of little strings and everything comes out of the way vibrates. But you're saying, there's a lot of options after that basic concept, like how do how do these strings yeah interact?

They all have the same basic idea, right, which is that the universe is made out of little strings and everything comes out of the way vibrates. But you're saying, there's a lot of options after that basic concept, like how do how do these strings yeah interact?

Or what do they sound like or exactly? And the reason is that you can't make string theory work in four dimensions. Right, Our universe that we experience has four dimensions, is three dimensions emotion x, y, z, and then one dimension of time. So we live in four dimensions. But strings, for they get them, to get them to have these mathematical properties that we want to unify quantum mechanics and gravity, they have to operate in more dimensions for the math to works, like.

Or what do they sound like or exactly? And the reason is that you can't make string theory work in four dimensions. Right, Our universe that we experience has four dimensions, is three dimensions emotion x, y, z, and then one dimension of time. So we live in four dimensions. But strings, for they get them, to get them to have these mathematical properties that we want to unify quantum mechanics and gravity, they have to operate in more dimensions for the math to works, like.

The dimension in which they're vibrating kind of thing, and then our four are just the ones where it's moving around it.

The dimension in which they're vibrating kind of thing, and then our four are just the ones where it's moving around it.

In some theories, yes, they vibrate in those other dimensions, and that changes how we see them in these dimensions. But there's a lot of different kinds of string theory, and so that's not a general statement. And some of them are eleven dimensional theories and some of them are twenty six dimensional theories. Right, And so the idea is these strings are vibrating in these other dimensions, but we don't see those other dimensions, like I don't I can't move in twenty six dimensions. How can you say that your theory, which has twenty six dimensions explains my four dimensional universe. So to answer that, to solve that problem, they have to roll up those other dimensions and tuck them away and make them small.

In some theories, yes, they vibrate in those other dimensions, and that changes how we see them in these dimensions. But there's a lot of different kinds of string theory, and so that's not a general statement. And some of them are eleven dimensional theories and some of them are twenty six dimensional theories. Right, And so the idea is these strings are vibrating in these other dimensions, but we don't see those other dimensions, like I don't I can't move in twenty six dimensions. How can you say that your theory, which has twenty six dimensions explains my four dimensional universe. So to answer that, to solve that problem, they have to roll up those other dimensions and tuck them away and make them small.

Make them like hidden, kind of like too small to be experience in our everyday lives.

Make them like hidden, kind of like too small to be experience in our everyday lives.

Yeah, which is why you don't see them or experience them or see them in physics experiments. And there's lots of different ways to do that, because twenty six dimensions is a lot of freedom, and so you can organize that in lots of different ways, and there's you can make choices, and you have to make choices. How do you take this twenty six dimensional theory boil it down to four dimensions? Turns out there's like ten to the five hundred different ways to organize that, which is a lot of different.

Yeah, which is why you don't see them or experience them or see them in physics experiments. And there's lots of different ways to do that, because twenty six dimensions is a lot of freedom, and so you can organize that in lots of different ways, and there's you can make choices, and you have to make choices. How do you take this twenty six dimensional theory boil it down to four dimensions? Turns out there's like ten to the five hundred different ways to organize that, which is a lot of different.

Choices, different flavors of string theory, or different choices you can make.

Choices, different flavors of string theory, or different choices you can make.

Yeah, different flavors. You went to the ice cream shop for string theory, and they have ten to the five hundred different flavors. And if you want a sample of each one, you're not even going to order. You're gonna be full before you leave. I mean ten to the five hundred. Think about what that number is, right for scale, there's like ten to the ninety particles in the universe.

Yeah, different flavors. You went to the ice cream shop for string theory, and they have ten to the five hundred different flavors. And if you want a sample of each one, you're not even going to order. You're gonna be full before you leave. I mean ten to the five hundred. Think about what that number is, right for scale, there's like ten to the ninety particles in the universe.

Right, So is the problem in string theories that all of these string theories would work. Is that kind of the problem.

Right, So is the problem in string theories that all of these string theories would work. Is that kind of the problem.

Yes, yeah, And that gets into the second criticism, which is, you know, can we test string theory. We can only see the universe down to a certain scale so far. I mean, we use large the large Hadron collider, we smash particles together. We get down to distances of like ten to the minus twenty meters, right, really really small distances. So all the string theories, that ten of the five hundred string theories, they all can explain things that happen that we've seen so far, all of them right. To distinguish between them, we'd need to look much deeper.

Yes, yeah, And that gets into the second criticism, which is, you know, can we test string theory. We can only see the universe down to a certain scale so far. I mean, we use large the large Hadron collider, we smash particles together. We get down to distances of like ten to the minus twenty meters, right, really really small distances. So all the string theories, that ten of the five hundred string theories, they all can explain things that happen that we've seen so far, all of them right. To distinguish between them, we'd need to look much deeper.

Oh, I see, mathematically there's a whole bunch of possible ones, but experimentally we can't test which one is right exactly.

Oh, I see, mathematically there's a whole bunch of possible ones, but experimentally we can't test which one is right exactly.

And that's the problem because strings, if they exist, we think they're about ten to the minus thirty five meters in size, which is super duper tiny. And maybe you're thinking, I don't know, we can see down to ten to the minus twenty meters. How much smaller is ten to the minus thirty five They're basically right.

And that's the problem because strings, if they exist, we think they're about ten to the minus thirty five meters in size, which is super duper tiny. And maybe you're thinking, I don't know, we can see down to ten to the minus twenty meters. How much smaller is ten to the minus thirty five They're basically right.

It's just tiny.

It's just tiny.

It's much much smaller. It's ten to the fifteen times smaller. Right, And to give you a sense of scale, like the Solar system is about ten to the fifteen meters across. It's a big difference, you know, if you could see only Solar system sized stuff or if you could see like one meter sized stuff. So strings are really really tiny, which is why we're not anywhere close to seeing them.

It's much much smaller. It's ten to the fifteen times smaller. Right, And to give you a sense of scale, like the Solar system is about ten to the fifteen meters across. It's a big difference, you know, if you could see only Solar system sized stuff or if you could see like one meter sized stuff. So strings are really really tiny, which is why we're not anywhere close to seeing them.

Doesn't the theory have also ways in which it kind of builds up to our world?

Doesn't the theory have also ways in which it kind of builds up to our world?

It does, but you can't distinguish between those theories. They all predict the same thing, and they're also competing theories. You know, there's a theory of quantum loops, you know, not strings, but loops, right, that also explains quantum gravity. And we can't distinguish between the various string theories and this theory of quantum loops because we can't see small enough yet, right, And so it's a criticism of this whole bottom up approach. Right, Yeah, cool, you started at the bottom, but you haven't built up far enough for us to test your theory. Is this just mathematical masturbation or you're actually doing something useful? Right? So sometimes people argue, like, okay, string theory is nice, but it's not physics. It's math because it can't be tested.

It does, but you can't distinguish between those theories. They all predict the same thing, and they're also competing theories. You know, there's a theory of quantum loops, you know, not strings, but loops, right, that also explains quantum gravity. And we can't distinguish between the various string theories and this theory of quantum loops because we can't see small enough yet, right, And so it's a criticism of this whole bottom up approach. Right, Yeah, cool, you started at the bottom, but you haven't built up far enough for us to test your theory. Is this just mathematical masturbation or you're actually doing something useful? Right? So sometimes people argue, like, okay, string theory is nice, but it's not physics. It's math because it can't be tested.

But but then that's what they need to do. They need to build up their math to sort of our scale in our world. But you're saying that's really difficult.

But but then that's what they need to do. They need to build up their math to sort of our scale in our world. But you're saying that's really difficult.

Absolutely, it's difficult because they've got a long ways to go. They have to go from ten to the minus thirty five meters up to ten to the minus twenty meters. It's a tall mountain to climb, and they've been working on it for twenty years. And you know, like with any theory that had fanfare and excitement around it twenty years ago, they're gonna be people who say, oh, you failed if you haven't succeeded yet, right, and so people are just sort of impatient. Are we ever going to get there? Is string theory ever going to provide something we can actually test or these guys just going to be twiddling around on chalkboards for the next two hundred years.