Find out about the Weak Force on today's podcast with Daniel and Jorge.
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Hey, hey, you have strong opinions about naming things, don't you.
Well, I just don't like kid when things are named in a very confusing way, or where the name actually confuses you instead of making things clear.
All right, Well, then I have a bit of a personal question. How did you pick the names of your.
Kids, not through physics, for sure, that's definitely.
There's not one called strange, one called charm.
They're both strange and charming, for sure.
That's a linear superposition. There is physics there.
They are definitely quantum and delep a lot.
For sure.
Our son was named my wife had a dream, and that's actually came up with a name for our son. She just came up with the name and a dream. And my daughter is named after a Jane Austen character.
Wow. All right, so both inspired by mental realms outside of the physical world.
I am more handmade cartoonists and the creator of PhD comics.
I'm Daniel. I'm a particle physicist, and I'm a connoisseur of all jokes physics y strong electric and even weak.
Ones and banana forces of course.
That's right, and of course the mysterious banana field that feels the universe and is mostly concentrated around Jorge's head.
And together we are co authors on books and other projects. But this is our podcast, Daniel and Jorge Explain the Universe, a production of iHeart Radio, in.
Which we take you on a tour of all the weird crazy amazing stuff in the universe and try to explain it to you. So you go away going, wow, that's kind of cool. I never understood that before.
Yeah, all the strong and amazing things and even the weak but significant things in the universe that maybe every once you know about.
That's right. It's a forceful exposition of all the fascinating things about the universe.
Oh man, now you're just forcing it.
I think that's right. Well, you know my joke, force is pretty weak. But forces themselves are sort of a weird thing. It's like, forces are something that physicists you've even had a hard time grappling with over the centuries.
Well, something that's really intuitive. I think you know, as a little kid, even as a baby, you sort of get the idea of a force, right, Thanks pushing you, thanks pulling you, gravity pushing you down.
Yeah, but I think your intuition is misleading. I think most people think of a force as something as a push, right, something that's touching you. Somebody comes up to you, pushes you over, you fall over, you move your role or whatever. So I think most people think of forces as touching. The really weird thing about forces is when they can act without touching, right, when they can, Like when you see a magnet levitating, it seems almost like magic, right, because it's this these two things are acting on each other without actually touching each other.
Yeah, it's weird. And so today we'll be talking about one particular force out of all the forces out there in the universe, one that is maybe not the strongest one, but that led to some amazing discoveries.
Right, that's right. It's not the most powerful force, but it did give us some amazing hints into the way the universe works. So it's weekly powered, but plays a strong role in the sort of overarching drama that is physics.
Yep, it's a force that's inside everyone, right, It's inside of me, inside of you, inside of everyone listening to this podcast.
That's right. It's everywhere in the universe, and it plays an important role in how we live and how we dine and how we power ourselves.
So to be on the podcast, we'll be talking about the weak Force week fours.
Are you just trying to add some drama to it because it needs some panache?
Yeah, it was a little anti climatic to say.
The week Well, I thought you might go with weak nuclear force because nuclear gives it some sort of like edge of mysteriousness.
Right, the weak quantum nano, n the weak black hole. Let's just give the multiple hybernated.
Names the weak Truehehi, Montes Yang force are exactly. That would be a lot more fun. No, the weak force is really amazing, it's fascinating.
Yeah, it's one of the four fundamental forces in nature. Right, there's only four of them. Yeah, well, spoiler alert, turns out there's three. You eliminated one like Pluto just got de declassified.
No. No, that's the goal of physics, right, is to not have four forces. We don't want to say, hey, here's how the universe works. There are four totally weird, separate rules about things, how things can push and pull on each other. We we think, we hope, we want to explain the universe in terms of one force. So the story of physics so far is look around you see all the weird thing that's happening in the universe, and try to describe them all in terms of the smallest number of things, the smallest number of forces. So, yeah, the goal is to sort of take things off the list and describe everything in terms of just one thing.
So you're saying, there used to be only four forces in the universe, but then phasics killed one of them and or marry two of them, and now there are only three fundamental forces in the universe.
Yeah, well, the drama is even more because we suspect that in the first few moments after the Big Bang there was just one force, really, but then as the universe cooled, we think they broke up into all these different forces. And what we're trying to do now is sort of run that backwards and understand, like, can we bring these things together? Can we understand these things in terms of one big picture? How do we bring marry these things back together? You know, it's like a universal divorce early on, and we're trying to bring the couples back together and show them how they can work together.
You're trying to bring the band back together. Basically, it's Liketles broke up and you know, we enjoyed their individual work.
But come on, guys, yeah, that's a great analogy. Wouldn't you like to just describe the Beatles instead of having to describe all four members of the Beatles? Right, That's exactly what we're trying to do. We're trying to show you that, you know, the drums are not interesting on their own, They're just part of a larger harmony, right. They make much more sense when you understand them in terms of the guitar parts and the vocals which come together to make this amazing, beautiful music. Right.
Yeah, the physics of the Beatles. That will be the next exactly.
So today we're going to show you how Paul and John were actually the same person.
Spoiler alert, they were the same person.
That's right. And Ringo's an alien. Everybody knows Ringo's an alien, right, all right.
So the weak nuclear force, and so it's not the most popular force. You know, most people know electromagnetism and gravity. Right, it is part of the forces, isn't it.
Yeah, maybe it is. Maybe it's the Ringo forces. It's sort of overlooked and you know, dismissed, but in the end fundamentally important to making things work. It's just like Ringo, he kept going the harmony together exactly. Without the beeds together, you wouldn't have a good song, that's right. Who ever heard a good pop song without it, without without a drum.
Line, without Ringo? All right, So we were wondering it is kind of the lesser known maybe of the forces. And so we were wondering how many people out there knew what the weak force was.
Yeah, and this is one of the times when I really had no idea what to expect. Had everybody heard of the weak force and they were going to spout off some interesting physics about it, or was there going to get a bunch of blank stares? So I was pretty curious.
And so as usual, Daniel went out into the street and as random strangers if they knew what the weak force was. And so before you listen to these answers, think a little bit yourself. If someone approached you on the street and wearing sandals and supporting a beard, if they asked you randomly what the weak force.
Was, You're giving away my disguise. Man, I'm gonna have to wear a completely different disguise when they'll throw them off. They be like, you can't be Daniel, I can I can't see your toes.
So if you were asked this question, you would you know the answer to it. Here's what people had to say.
Yeah, has it kind of governs radioactive to k most particle stuff?
I guess I'm not heard of the weak nuclear force.
Have you heard of the strong nuclear force, the medium nuclear force, not the super weak nuclear force? I made most of those clear force not as well, I've heard of them.
I'm not sure.
No, I'm not heard of that. No, the MRI measures in nuclear force.
And then you can no, I don't know.
That's good. That's one of the four main types of forces in physics.
Not just in physics, in the universe, right in the universe.
Sure, it's kind of it's a kind of part to a strong nuclear force.
Why do we have it? What is important or what does it do?
Has something to do with how atoms are held together? I don't know exactly, all right, So not a lot of yeses.
I got a lot of blank looks on this one, that's for sure.
Well some people most people say no, they'd never heard of it. But somebody actually said that it's related to the radioactive radiactivity radioactive decay.
Yeah, exactly, And somebody even understood that it was like connected to particle physics experiments we do in Geneva. So a hundred bonus points to that, because.
Was it your office made another physics professor.
That was me with disguising my own voices, asking myself with question spoiler Earler.
They're all you always every episode.
I'm just amazing at impressions right now. You know what one of my career goals is, please speaking of which is you ever read The Onion. They have this fantastic people in the Street section where they ask people ridiculous questions and every week they have the same four pictures and they just give them made up names and jobs, you know, bone crusher or like, you know, keyboard tester or something. My career, your goal is to get My face is used in the Onion as one of those people on the street saying something dumb. But I've actually written to the Onions several times volunteering, but never heard back.
Please use my picture.
Exactly, please make fun of me every week.
Do they write back or they just ignored it?
No?
No, Unlike other Internet celebrities, they did not respond to my cold call.
Well keep trying, Daniel, there's always hope, all right, I will so, yeah, somebody. Most people didn't know what it was, and so did that surprise you. I mean, it's not something that is usually covered in you know, high school physics.
Even it didn't surprise me because it is a bit esoteric. And also it's not something people experience. You know, people experience gravity, they all know what it is. They have to understand it, they have an intuitive sense of it. People experience electricity, right, We've all been shocked by static electricity. People experience magnets, right. But people don't interact with the weak nuclear force very much. You don't really see its consequences directly. You can't tell the difference between it and something else the way you can tell the difference between gravity and magnetism. Right.
Yeah, Well, there's very a couple of things about it. First of all, it's a force, and second it's weak.
That's right. It's really really weak, like compared to electromagnetism and the strong nuclear force. It just is not very effective. And one way to understand that is to think about how particles interact, right, Like when you touch something or when you bounce against something, that's all done with particles. That's particles pushing against each other or interacting with each other.
I mean, like the particles in my finger are interacting with the particles in the table, and so they're pushing against each other.
That's right, And that's mostly using electromagnetism because it has to do with the bonds and the electrons holding the atoms tightly together and making this like you know, chain link fence of atoms that your finger can't pass through. But there are other particles, right, And that's because all the particles in your finger and all the particles in the table feel electromagnetism, right, But there are particles that don't feel electromagnetism, like this mysterious particle called the neutrino. Right, the neutrino doesn't feel electromagnetism, and it doesn't feel a strong force, and it has almost no mass or it hardly feels any gravity. The only way it interacts is through the weak force, and so it's a good lens for figuring out like how weak is the weak force.
Yeah, we had a whole podcast episode about neutrinos and we sort of talked about how, you know, the forces are sort of like social media channels. You know, there's Twitter, there's Facebook, there's Instagram that you can interact with people, but some people don't use some of the don't use Instagram, where they only use Twitter, or they only they or they use all three.
And neutrinos are like that. They only subscribe to this one very lightly used social media channel, and so they hardly interact.
It's the friends through of social media channel.
The original And so that's why neutrino can pass right through you, and a neutrino can pass right through the Earth right. We do these experiments where we look at neutrinos from the Sun and we use the entire Earth as an instrument to try to get the neutrinos to interact, but most of them fly right through the entire Earth without interacting. And if you had to say, like how thick a wall would I have to build to block neutrinos, Well, neutrinos can fly through a light year of lead and have a fifty percent chance I'm getting through. So I mean it's it's hard to even fathom, like how big a wall you would have to build to effectively block neutrinos. And the reason is that the weak force is so weak that every time the neutrino nears something, it rolls a dye and the dye has to come up just right for it to interact. Most of the time it just ignores it.
Oh wait, so all right, so we're getting into what is the weak force, and you're saying that it is super weak, and you're saying that it's weak, not because it's just the weak force, but it's it's just less likely to interact with you.
That's exactly what weak means, right, that it has a smaller chance to interact. Right that you shoot these two things against each other and they will less often have an interaction.
But when they do interact, the force that you actually feel is also weak or not.
Oh, I see what you mean. No, the magnitude of the force is not effect that, it's how often it happens. Oh, it's how likely it is to happen when it intrino interacts with the nucleus. For example, it bounces off and goes in the other direction. It's not like just slightly deflected. It's just that it doesn't happen very often. It passes right through most of the nuclei without doing anything, just ignores them latin out there.
But in terms of magnitude, like when it does interact, it is as strong as the other forces.
Yeah, that's a really good question. I've never really thought about it that way. It's just a question of whether it interacts. The strength of the force really determines whether it's interacting. And so, for example, you know, the strong force is really really strong. There's a lot of energy in that interaction, and so it's going to interact with everything else that feels it. Electromagnetism is a powerful force, and that means that it's going to interact almost all the time, and so you get lots of particles contributing. But if you're like going to measure it per particle, I think, I think it's just another way of saying the same thing. I think. You know, the strength of the force between them is another way of saying how likely are they too interact or not the other fast in anything about the weak force, Another reason to think about why it's weak is that it doesn't interact over a very long range, like electromagnetism. Two electrons that are like one thousand miles away from each other, they can feel each other, they feel each other's electric fields, right that electromagnetism extends infinitely far. The weak force, another way to think about why it's weak is that it only interacts with things very very near it, right, Like you have to be really close to that neutrino to interact with it.
Is that true? Like two electrons, even if there are millions of light years apart, they'll still feel each other.
Absolutely, you feel the electric field from electrons in Alpha Centauri or the Andromeda Galaxy or halfway across the universe. Absolutely?
Is that why I feel like I'm being pulled apart?
No, that's like maybe the only scientific action between astronomy and astrology, Like are you affected by the movements of the planets fields? Maybe, but it's really negligible. And I also remember that it's time delayed. You know, if you if there are electrons in Alpha Centauri and somebody wiggles them, you don't see those wiggles until the information comes here, which takes you know, which travels at the speed of lights, so it takes a long time.
But you're saying the weak neugar force doesn't have that long range, like at some point two particles that feel it don't affect each other with the weak force.
That's right. The range of the force is really tiny. It's like the diameter of a proton, right, So these particles have to be really close together. It's just another way of thinking about whether these two things will interact. I think about it sort of like, you know, imagine you're throwing two baseballs at each other, right, They're less likely to interact than if you're throwing two basketballs at each other, or two with some really enormous ball, some like enormous yoga bounce a yoga ball at each other, right, And so the size this is what we call cross section in physics, because the cross section of those balls tells you how likely they are to hit each other. Balls with a really small cross section, like if you're throwing, you know, pebbles at each other, it's much harder for them to hit. And so the range of this force tells you basically the cross section of their interaction. And so the weak force is a really small range, which makes it less likely to interact. When they interact that you know, they still bounce off each other like anything else, just less likely to happen.
So what happens when you get further away? Does it the force just drops off? Or you know, like I've heard that at some point the weak force doesn't travel far because the particles decay or they don't last far far out enough.
Yeah, that's a really fascinating way to think about it. Yeah, the weak force, it just is negligible beyond a certain distance, like you know, it's basically zero. And another way to answer the question why is the weak force week, I mean one way to say, as well, it just has a number associated with it, and that number is smaller than the number associated with electromagnet or the strong force. And then of course you can ask why. But one way to explain that is to think about in terms of the particles that transmit these forces. Right, we think about like the photon. The photon is the thing that transmits electromagnetism.
Right.
What do we mean by that, Well, we have this sort of picture that like two electrons coming near each other, one of them can shoot off a photon to hit the other electron and push it away, and that's like how electrons repel via a photon. And we use that same sort of picture for all the forces. Actually, but the particles that are associated with the weak force, they are not massless like the photon.
Is.
The reason electromagnetism extends so far is because the photon is massless. It zooms away at the speed of light and it doesn't decay. Right, Photons can go forever. But the weak force has these really heavy particles. They're really really heavy, and so they don't go very far before they basically decay.
It's like if I was trying to hit you with a bowling ball, my range would be limited.
Yeah, Or if you, like, you know, had taped a bunch of stuff together very loosely and then tried to throw it at me and it exploded in midair before it got to me.
Like throwing a sandball at some point in might.
Exactly a sandball exactly. It's like throwing a sandball. You know, you're not really gonna get hit by the full force of the sandball unless you're really close. And that's that's fascinating. It's like these particles, these particles that mediate the weak force bosons, why are they so heavy in the and the photon is is massless. That's like one of the deep questions in physics over the last few decades.
And that's why the photon can go to infinity because it's massless and it just keeps going right exactly.
That's why electromagtism is powerful, and that's why its range is infinite, and the weak force is very weak because the things that carry it are very fat and slow. You know. It's like, you know, if you wanted to send letters ups drivers are super super fast and driving Lamborghinis, right, and instead you sent it via I don't know us mail and they're driving, you know, a big, heavy, slow bus or something. Your letters is not going to get there as fast or might not even get there. So the thing that carries the messages, the information of the weak force, is big and.
Hazy, weak, and that's what makes it the force blame the messenger.
And the fascinating thing is that that's really only irrelevant sort of late in the universe. That's relevant when every when there isn't a whole lot of energy, because the mass these particles makes a difference when everything doesn't have a lot of energy. But if everything was really hot and dense and zooming around, then it wouldn't really matter what the mass of these particles was, Right, they have a little bit of mass or not they had a lot of energy, wouldn't make any difference. And that's why we think back in the beginning of the universe, electromagnetism and the weak force had the same strength.
Because everything we're just closer together and interacting the same way.
Yeah, and those particles, the ones that carry the weak force, just had enough energy to get further. The fact that they had mass didn't really matter because they had so much energy it was negligible.
All right, So that's the weak fours. Now we know it's a force, and we know why it's a weak and so let's get into what's interesting about the week fours. Why is it weak, what's weird about it? Why do we have it? And how did it help us discover the Higgs boson. But first, let's take a quick break.
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All right, hey, Daniel, do you think the weak force knows that it's called the weak force? You know?
I think my agents have been working for quite a while to get a name change. Yeah, I think it needs a pr overhaul for sure.
What should be called? Would you like to be called Doctor Week or Daniel Week or I don't think anyone?
Master of the Week force expertness still worked out for John Week.
That franchise change then.
Exactly. Well, you know, what would you have called the weak Force?
Well, I don't know anything about it. Much about it.
You should listen to this podcast to explain it to you. It's really good.
Well, all I know is that it's weak and that it's a force. But you know, is there what do we know about it that might give it some identity? Like what's special about it?
What is special about it? It's pretty weird. It can do some things that other forces can't do. It's sort of like messes with your mind. A lot of the things that we thought we knew about the universe, that we assumed we're fundamentally true about the universe. The weak Force just sort of breaks those rules and shrugs and moves on. And so it's a great window into like what is the sort of the limitation? What can forces do in the universe. It turns out they can do a lot of things that we thought were impossible.
And that's what the weak force can do.
Yeah, that's what the weak force can do. For example, the weak force can change quark flavors. We had a whole podcast episode abou quark flavors. And for those of you thinking what what's a quark and how does it have flavors? We're not talking about European yogurt snacks, though there are flavors snacks called quark. We're talking about fundamental particles.
Yeah, and so this, the weak force can change the flavor of a quark.
Yeah, exactly. Electromagnetism can't do that, right, you have a charm cork. It can't give off a photon and then become an upquark. That doesn't happen, right, But if the charm interacts using the weak force, it can give off one of the particles that it transmits, and it can become for example, a down cork or a strange cork can become an upcark, right, or top cork can become a bottom cork or a down cork. Right, And so it can actually change these flavors, and other other forces are not allowed to do that.
Well, and that's kind of a big deal because if I change all the flavors in the quarts inside of your atoms, you'd be in trouble, right.
Oh, I think I'd be even tastier.
You'd be charming and strange, but or more charming and more strange.
Yeah. Well, you know, you think of its sort of like a ladder. There's the lowest energy ones, the lowest mass ones. Those are the upcork and the down cork, and if you have the heavier quarks, then that they tend to decay down the ladder. Things in the universe tend to be the lowest energy state, the lowest mass particles. So if you have the heavier particles like the top, then it uses the weak force to sort of step down that ladder down to the up and the down and I and you and every banana you've ever eaten are made up of just upcorks and down quarks and of course electrons. But it also changes. It can change those upquarks and down corks back into each other, and that's actually what we call radioactive beta decay. That's how you change, for example, a neutron into a proton is by changing is by going back and forth between upquarks and down quarks, because that's the difference between neutrons and protons. It's just one up versus one down.
So it's weird because it can really mess with the identity of matter, right Like, if if all my quarks change identities, I would probably blow up, right, I wouldn't be able to stay together, right Like, if all my protons turn into neutrons, you know, goodbye wore.
Yeah, well, protons don't turn into neutrons, right, Protons are stable, which is a whole other fascinating thing, like can protons live for the whole life of the universe or do they eventually decay? Currently we think that protons live for like zillions of years, but neutrons don't. Neutrons will eventually turn into protons, and that's fascinating. And that's what the that's what the weak nuclear force does, and only the weak force can do that.
Okay, that's weird, So maybe I would call it the weird force.
I don't know. Ooh, we the flavor flavor seems a little. The tasty force, you know, the particles that it uses are also weird. Like we said, the electromagnetism has the photon, right, and that's how we transmits information. And the weak force is more complicated. It has three particles that transmit its forces. It has this particle we call the z boson, and then it has the W plus and the W minus, and we call them plus and minus because those particles themselves have electric charge. So it's like the particles of one force feel the forces of another force.
Huh. So the bloody mind cat affect the weak force using a magnet, is kind of what you're saying.
Yeah, exactly. Or the particles that transmit the weak force can shoot off photons, right, they interact with each other using electromagnetism. Yeah, oh weird. And that was a big clue. We'll talk about that later, that there's a deep, deep connection between the weak force and electromagnetism.
It's kind of like it'd be cool, like if, for example, you can affect gravity using electromagnetism, right, that would be crazy. Then you could.
Yeah, right exactly, if you could like make a magnet which turned off gravity or something, that would be cool. And you know, we hope one day in the far future to have a unified understanding of all the forces. Take gravity turn it into a quantum mechanical theory, which we haven't done yet and have no clue how to do, and then somehow unify it with the other forces and show that they're all just part of the same larger force. In that case, then maybe you could do what you just said, is use one part of the force to balance another part of the force and affect it. So, yeah, I think you just invented an anti gravity machine right here on the right.
I should get one one half of a Nobel prize then.
Or.
Let's go with one five hundred million, so real.
That's probably the chances that I will get one.
I think that's probably accurate.
Yeah, all right, so well let's get into Now we know what it is, we know what's kind of weird.
Wait, but wait, there's more the more, there's even a weird thing about that.
I thought it was weak, but there's more.
Right, it's weak, but it's got a long backstory, right. It's one of these superhero characters with like a really deep interesting connection. It was affected in its childhood and it's carrying all that back.
Like Widow not a lot of superpowers, but you're like, what is going.
On with her? Oh? You mean blackwed are the superhero now the the actual spider. Yeah exactly. She she looks good in leather and she can really kick.
Yeah, but she has all the mysterious of Russian spy backstory.
Yeah exactly. She's intimidating now. The one of the weirdest things. But the weak fours is that it breaks what we thought was a fundamental symmetry in the universe, and that is that we think that it shouldn't make a difference sort of how you draw your X, Y and Z axes. Like, if you have to draw, you draw an X axis and a Y axis. You put them in ninety degrees with each other, right, then you're gonna draw Z axis. You want to put it in ninety degrees. But then there's a question do you draw it like sort of up above the X Y axis or down below right? And the difference is what we call handedness. Is it a left handed system or a right handed system. It's really just arbitrary, and so because most of us are right handed, we tend to draw those things the way you would have the first three fingers on your right hand point, so we call them right handed coordinates.
It's kind of related to mirrors, right, like you think that physics should work the same on one side of the mirror or in the reflection of the.
Mirror, exactly, because if you take a right handed coordinate system and you look in the mirror, then it looks left handed. And so for a long time people thought, well, that's just a thing we made up. It's just like human it's not fundamental or physical. Right, And so they said, well, physics shouldn't matter. The physics shouldn't depend on whether things are right handed or left handed. So they made this assumption. They said, well, we assume that any experiment you do, if you watch the experiment in the mirror, you should also be able to do that mirror experiment, right, that the laws of physics should work the same here as they do in the mirror. Right. So, like you do some experiment you watch in the mirror, should you should be able to do that same experiment or our laws of physics should still govern what's happening in the mirror.
Right, But you're saying the weak force totally doesn't care.
Yeah, And this is one of the great stories of physics, is that nobody checked for a long long time, like they checked the electromagnetism. Yep, it's true. They checked the strong force, Yep, it's true. And they thought, well, this is just so fundamental and obvious, like we don't need to check it. You know. It's like, you know, do you check that the sun doesn't like come out in the middle of the night. No, they don't get up in the middle of the night and check if the sun is sneaking around, right, You just you checked it at sunset, You check it at sunrise, and you assume what else is happening? Right, So people thought, well, the weak force is really hard to test, so we'll just assume that it also respects the symmetry called parody. And then in the fifties some theorists realized nobody's actually ever checked this, so maybe somebody should. And this is great story about a physicist at Columbia. She was planning to go on vacation with her husband for Christmas, and she said, you know what, I can't go on vacation and it can't relax without knowing the answer to this deep question.
Sounds like a physicist exactly.
So her husband went on vacation by himself and she stayed back and she did these experiments where she demonstrated. She asked the question would the weak force look the same in the mirror, And she set up this really complicated but very clever experiment, and it's difficult to describe it with the audio. So I encourage everybody to check out or hey, your video on this experiment, which you can find by googling. But the short version, we.
Remember you made it with the Derek Muller of veritassium. If you look up.
Yeah, it's a great video. It's a great video. It's called due particles respect time symmetry? Or do particles go backwards in time? In that video, you can see that the weak force doesn't work the same in the mirror. In fact, in the mirror works exactly the opposite. So not only does it not like respect this basic symmetry we assume was a true thing about the universe, it violates it almost one hundred percent.
So it's weak, but it's like the rebel force.
Yeah, which means that like our universe is, you know, has a handedness. It's not like it could have been this or could have been that. It is one way, right, And anytime you see a kind of thing like that in physics, where it's like an arbitrary choice between two things. You expect it to be balanced or even or symmetric, and then it's not. That's a clue that tells you something happened when the universe was being cooked up, that it went this way and not that way. Yeah, what is that? Yeah?
It makes you realize that the universe maybe doesn't have laws, or the laws you thought real to universe are not always true exactly.
It makes you wonder is there a deeper understanding in which it had to be this way? Right? Is it just arbitrary and random and we live in a multiverse and it's one of a bajillion and there's no reason for it. I don't like that idea. I think it's a clue that there's something deeper going on. There's another way to think about the way the universe works that requires it to be this this thing that's weird to us. And those are the moments of insight. That's when when your intuition is confronted by reality and you realize, ooh, here's a clue that reality is quite different from my intuition. Those are learning moments, right.
Yeah, No, definitely, I have a lot more respect. Now for the week furs. I mean, it's so weird and breaks all these laws. I feel like you just upgraded it from Ringo to George Harrison, you know what I mean?
Like, there you go. So now we should be called the well respected ya.
Yesh, there you go, well respected, well liked. Interesting.
They should speak with a stuffy British accent.
Well, let's get into now whether we even need the weak force or why is it important? But first let's take a quick break.
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All right, let's get into why we need the week Force? Do we even need it? Like, well, there's two questions, I think practically, So practically, first of all, what would happen if we didn't have the week Force? We still be here? And the second why is it important to physics?
Yeah, so that's a fun hypothetical question, like if you deleted a lot of physics, what would happen? Right, Well, obviously everything would be different, you know. Yeah, Well, you wouldn't have radioactive decay, right for example, you wouldn't have beta decay. And the week force is important to making things happen in the center of suns and the structure of the atom is partially controlled by the weak force, and so so everything would be there.
So if we took it out, if we eliminated Ringo Star from the Beatles, what would happen to my atoms? Like would I just dissolve, would I explode? Would I feel just a little heavier? Or what would happen?
Well, it depends. Are you talking about starting from the beginning of the universe never having the week force or having the current universe and then just turning it off.
Let's do the second one first, So flip the switch, the week four just quit goes away. What happens.
My first caveat is it's impossible. It doesn't make any sense for reasons we'll talk about it in a minute. Because it turns out the weak force is just entangled with everything else and you can't get rid of it right the way. You can't just fire your drummer, and the universe wouldn't make any sense if you did that. But say you just turn that off. Somehow, somehow you're able to get to the control panel of the universe and turn off the weak force. What would happen. I don't think you would feel it immediately. I think we would never interact with neutrinos again, right, Neutrinos would just become invisible, becoming decoupled. No, no to interact with them. But yeah, no big lassoever really feel nutrinos. It'd be harder to run nuclear reactors, and fission wouldn't work the same way, so we'd have to re engineer all that. But again, you know, not everybody's a big fan of nuclear power. The structure of the atom would be a little bit different, right, I mean, it certainly plays a role in how the nucleus is held together and how it gets broken up. So that's a good deep question. I'm not sure the answer of how it changes structure of the atom, But mostly I think you could just totally ignore it eutrinos that were already mostly ignoring.
All right, So then what's the other answer that if we started off the universe without the weak force, would we end up in the same spot.
Yeah, that's a great question. I think I have to deflect that question because I don't think the universe makes any sense without the weak force. And the reason is that it turns out the weak force is not its own thing. It's not like a completely separate thing that we're like right now, we don't understand any connection between gravity and electromagnetism. They seem like totally different phenomena with no relationship. Turns out the weak force is not its own thing. It's actually part of electromagnetism, or said more correctly, the weak force and electromagnetism are part of one larger force.
I've heard that before, that the weak force and the electromagnetic force are actually just one What does that mean? They're actually the same particles, but they behave differently, or they're all like different flavors of the same particles. What does that mean?
It means that they're all different parts of the same thing. There are like different sides of the same coin. And I think a more intuitive analogy to help you get there is to think about electricity and magnetism. Like one hundred and fifty years ago, people thought electricity, oh, that's the thing with that zaps you. Magnetism, that's the thing that lets magnets fly or magnets work right, And they thought they were totally separate. And it wasn't until Maxwell wrote down Maxwell's equations and he realized, hold on a second, the laws that government electricity and the laws that governed magnetism are basically the same thing when you write them down mathematically. And you know, magnets can create currents and currents can create magnets. So it turns out that there's just one force electromagnetism, and we had artificially separated into two. We were just categorizing the different parts of it separately and had recognized that it makes much more sense when they're connected. So we said, okay, let's just call this one force electromagnetism.
Right, So it's like the same force. It just sometimes acts to create currents inside of wires and some times it acts to repel magnets apart, but it's the same thing.
You're just one guy. Sometimes you're happy, sometimes you're grumpy, right, Like, are you a different person when you're grumpy? I mean, some people might say so, but I know deep down you're really the same person, And so it makes much more sense to say, oh, this is different sides of somebody's personality. This is two different aspects of the same.
Thing sometimes like different feelings of it or different behaviors of it.
Yeah, exactly. And what we've discovered is that the photon and the W and the z bosons are all just parts of one force that we called the electroweak force. And you notice what happened there is that we merged electricity and magnetism into electromagnetism. Then we added the weak force, and like magnetism just kind of got squeezed out. It should have been called the like electromagnetic weak force or something like magnetic force or magneti weak force right through electricity.
Whatchromagnetic is how I would have maybe called it. So you're saying then that electrons and the the W and the z bosons, they're all those are different, but they're also of carriers of the same force.
Yeah, there's one larger, more complex force. So we call it electroweek and it has four carriers, the photon, the two ws, and the z and has four carriers to it.
Does the weak force have like charge, you know how we talked about electromaticism has charge and the strong force has color color.
Right, and the weak force has its own thing. It's called weak hypercharge, which is like a contradictory branding a great name, I know, super awesome, not that awesome charge. It's kind of confusing. It has weak hypercharge, and then together the combined electroweak force has something called weak isospin, which has nothing to do with spin. So it's a big mess, and it comes from a historical naming accident.
Really, the main lesson is just that they can be described by sort of the same what is it terms in the equations of the universe kind.
Of yeah, exactly they have. The mathematics is very similar. And in fact, when people were looking at that, they noticed, like, these things are so similar, But why does the photon have no mass and these other particles have a lot of mass? Right, Like, that's why electricity and magnetism seem so different from the rest of the force, because this one particle, the photon, has no mass, but the other ones have a lot of mass. So that was a big puzzle like fifty years ago, and that's the puzzle that inspired Higgs himself to think up the Higgs boson. He said, well, maybe there's this other particle out there, this other field and it's interacting with these bosons and it's giving them mass, and it came up with a really clever mathematical way to make that happen, to give mass to just these particles and not to the photon.
So I think the conclusion of all it is then, is that the weak fours. It's there. It's kind of like the conjoined twin of electromagnetism.
Right.
It's not its own thing, that's.
Right, Yeah, exactly, And.
It's not very consequential in the universe, meaning that you can take it away, but we wouldn't instantly feel it. But it's sort of necessary, right, It's part of the universe, and in fact, it kind of gave us a lot of clues about the universe, including the Higgs boson.
That's right. And you can sort of blame it on the Higgs, right. The Higgs is the reason that the W and Z have so much mass, and that's why it's so weak. So if it wasn't for the Higgs holding it down, the weak force would have had a much different career.
Arc Maybe we should call it the I hate the Higgs force exactly mental state than the weak force.
Yeah, but there's like, you know, many Nobel prizes have been won along the route to understanding this, Understanding that electricity and magnetism are together with the weak force, understanding the Higgs mechanism, all this stuff. These are a lot of really important ideas. All of really complex mathematical machinery was developed just to understand this. And it's really beautiful when you learn that, because it shows you how the structure of these theories really are deeply mathematical. Now, how much mathematics really reveals the way the.
Universe works, all right, ending on a note of beauty, that's pretty cool.
Yeah, And so for those of you interested in learning more about it, or encourage you to get a little bit into the group theory because it connects for you the symmetry of these things with the idea of particles carrying these forces and why it has to be that way. It's really deep and fascinating and we should dive into on another podcast episode.
All right. Thanks for joining us. I hope you enjoyed that. We'll see you next time.
Thanks for tuning in. I hope it wasn't a weak episode.
I hope that had a forceful impact on you.
If you still have a question after listening to all these explanations. Please drop us a line. We'd love to hear from you. You can find us at Facebook, Twitter, and Instagram at Daniel and Jorge That's one Word, or email us at Feedback at Danielandhorge dot com. Thanks for listening. Remember that Daniel and Jorge Explain the Universe is a production of iHeartRadio. For more podcasts from iHeartRadio, visit the iHeartRadio app, Apple Podcasts, or wherever you listen to your favorite shows. When you pop a piece of cheese into your mouth, you're probably not thinking about the environmental impact. But the people in the dairy industry are. That's why they're working hard every day to find new ways to reduce waste, conserve natural resources, and drive down greenhouse gas emissions. House US dairy tackling greenhouse gases. Many farms use anaerobic digestors to turn the methane from manure into renewable energy that can power farms, towns, and electric cars. Visit you as dairy dot COM's Last Sustainability to learn more.
As a United Explorer Card member, you can earn fifty thousand bonus miles plus look forward to extraordinary travel rewards, including a free checked bag, two times the miles on United purchases and two times the miles on dining and at hotels. Become an explorer and seek out unforgettable places while enjoying rewards everywhere you travel. Cards issued by JP Morgan Chase Bank NA member FDIC subject to credit approval offer subject to change terms apply.
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To strengthen yours.
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