Daniel and Kelly’s Extraordinary Universe - Listener Questions 32: Particles, particles, particles!
Episode Date: October 4, 2022Daniel and Jorge answer questions from listeners like you, all about the particles around us.See omnystudio.com/listener for privacy information....
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December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
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Just a chaotic, chaotic scene.
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My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam. Maybe her boyfriend's just looking for extra credit.
Well, Dakota, luckily, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend's been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other, but I just want or gone.
Hold up. Isn't that against school policy? That seems inappropriate.
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Why are TSA rules so confusing?
You got a hood of you. I take it all.
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Why are you screaming it?
I can't expect what to do.
Now, if the rule was the same, go off on me.
I deserve it.
You know, lock him up.
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for lunch. Oh, well, that's not hard. I always have cereal, but which kind of cereal, though?
Something made out of protons, neutrons, and electrons maybe? Oh, close. I had a new cereal called
neutrinoes. No, I'm just kidding. Let's just regular atom-based cereal. How did you know? Well,
you know, you gave me a massive hint telling me it was a heavy lunch. Right, right. And only things with
protons, neutrons, and electrons have mass? That's right. Maybe you should try something lighter.
like a photon-based meal.
Mmm, it sounds like a brilliant and delicious idea.
Good for my diet.
Hi, I'm Jorge. I'm a cartoonist and the co-author of Frequently Asked Questions about the universe.
Hi, I'm Daniel.
I'm a particle physicist and a professor at UC.
at UC Irvine and I'm pretty glad that I can't eat photons. Well, how do you know? Have you tried? Have you
tasted them? Have you shown a flashlight down your throat? I think they do that at the doctors all the
time. So I think you have eaten photons. Yeah, well, but if I lay down in the sun for a nap, for example,
I still sometimes wake up hungry. Maybe you shouldn't put on sunblock. The no photon diet.
But, I mean, do you nap with your mouth open, though? Have you tried that? I've not tried
napping with my mouth open, but I was imagining that maybe humans would evolve to
photosynthesize so we could just like absorb photons as we go walk around or lay in the
sun. Oh, wow, that's pretty cool. Yeah, we could all be green with envy and photosynthesis.
It'd be pretty hard to go on a diet though. I guess you'd have to like walk around with an
umbrella. You could sell a diet sunblock, I guess. Yeah, or a parasol would be like a new fashion
accessory for the super thin. Stay thin and pale. Welcome to our podcast, Daniel and Jorge,
Explain the Universe, a production of iHeartRadio.
In which we don't eat photons, but we do gobble up all of the information provided to us by the particles in the universe.
We are made of particles. Everything around us is made of particles.
And in their incredible dance, they convey to us everything that is happening out there.
They tell us about the fundamental nature of the universe at the smallest scales.
And they come together to describe the sweeping motions of enormous galaxies and the dance of galactic clusters.
as they get pulled apart by dark energy.
Everything around us is made of particles
and all of our understanding of it
is stored in particles in our brain.
Yeah, because it is a tasty and brilliant universe
full of amazing things to discover,
full of information,
beaming down to us from the light of stars
and planets and nebulas out there in the cosmos,
ready for us to digest and absorb all of those amazing knowledge nutrients
from the universe.
And the most amazing thing about the particles
that make up your brain,
is that they are curious about all the other particles.
These particles want to understand those particles.
And that bubbles up in the form of questions,
questions that we ask about the nature of the universe around us,
questions we ask ourselves, questions we ask our friends,
questions we whisper to ourselves quietly at night when we stare up at the stars,
and questions we send to podcast hosts.
Yeah, the world is full of questions.
Everyone has questions.
It's kind of an inherent part of being human.
and in this podcast we like to answer some of those questions most of the time at least we like to ask them we don't always answer them i guess
we answer them as best as we can some of these things are tough explaining concepts in an understandable way which are often just described mathematically can be a real challenge but we knew our best to boil it down to the essential ideas
i guess saying i don't know is also an answer so technically we do answer every question yeah we have no idea is a valid answer to it not just a good book absolutely and sometimes
Sometimes when I'm posed with an especially difficult conceptual question, like, can you make me understand why X, Y, Z happens?
I'll walk the hallways here at UCI and I'll ask the theorist, why do you think this happens?
Why do you think that happens?
Do you have an intuitive understanding of this?
And often I'll get very different ideas and sometimes conflicting accounts for why things happen, which just tells you that even the experts don't always deeply understand the Y.
Right, right, because the X and the Z are easier or what?
Because sometimes the ABCs are easier than the X, Y, Zs.
Well, they do come first, I guess.
But it's not just the scientists and the physicists of the world that ask questions.
Everybody asks questions.
Everyone looks up at the stars, at the sky, the things around them,
and they wonder what's going on.
How does it all work?
They do.
And especially our listeners, our curious folks.
We hope that you are listening to the podcast
because you wonder about the nature of the universe
and because you want to understand it.
You want to do more than just hear,
an explanation, you want those pieces to fit together in your mind in a way that you can manipulate
it, that you can rotate it and probe it from different angles and make sure that it sort of hangs
together. And when it doesn't, we encourage you to write to us so we could help you fill in those
gaps. And so today on the podcast, we'll be tackling. Listener questions. Number 32. Oh, my goodness,
we've done 32 of these listener question episodes. Oh, we have. We get lots and lots of listener
questions. Many of them come to our email address to questions at Daniel and Jorge.com and we
answer all of them. So if you have a question, please don't be shy. But sometimes we get a
question which I think will be really fun to talk about or is quite tricky. It requires me to do
a little bit of background research. And for those, we ask people to send in some audio so we can
talk about it on the podcast. Interesting. And so if this is our 32nd listener questions episode and we do
about three questions and episode, that means we're close to like a hundred questions.
Oh, yeah.
I mean, one of you, anyone sending their question in now
could be the 100 listener question we answer on the podcast.
Wow, are we going to give away a prize?
Yes, a possible answer.
I think we should at least shower them in digital confetti or something.
Send them a gif or an emoji with some confetti.
Yeah, instead of a gift, you just got a gif.
There you go.
Leave out the tea.
They get a gif or a jif.
We do love answering questions from listeners.
And today we have some pretty interesting questions in that they're all about particles and kind of about mass, it seems.
Were you feeling in a kind of particle mood?
Or do you think these questions just all came in at the same time?
No, these questions are not sorted by when they arrive.
I try to group them together so the concepts are a little bit related.
So we do a batch about black holes and a batch about particles and a batch about how physics might kill you.
So we can dive a little bit deeper into the topic.
All right.
Well, today we have three particularly particles.
questions, some of them about virtual particles, about particles that may or may not exist,
and also about what kind of particle light is.
And so our first question comes from Carter, who wants to know about all the other particles
in existence?
Hi, this is Carter, and my question for you is, why do particles other than the electron, the electron
neutrino and the up and down quarks exist if we only need those four particles to build up
the world around us.
Awesome question.
Thank you, Carter.
It's amazing to me that you have a question like that.
Absolutely.
Carter is 12 years old and he's already at the forefront of particle physics asking questions
we don't know the answers to.
Yeah, I think when I was 12, I was mostly just wondering what I was going to have for lunch
that day.
I think when I was 12, I was watching the movie Stand By Me over and over every single day
for a summer.
Oh.
I mean the one where they find a dead body?
Yeah.
I don't know why.
watch that every single day for a summer. But I remember there was a summer where I watched that
in the morning and then I wrote computer programs in the afternoon. Unlike that was my summer.
Wow. Sounds like you got a lot of sunlight or at least light from your monitor.
Exactly. But Carter apparently is thinking about the nature of the universe and how it comes together
and why there are weird particles out there. Yeah, because as he said, we only sort of need a certain
number of particles to make things around us, like everything we can see and touch and
stand on and look up at the sky at, it's pretty much made out of only three particles, right?
I mean, he mentioned the fourth, but most of the things are made out of three particles.
Yeah, he's right, that the things that we are made out of technically are just three particles.
But as we'll talk about, the other particles do play a role in determining the nature of our
universe.
It would be quite different if those particles didn't exist.
All right.
Well, maybe let's review things a little bit.
So why is it that everything that we're made out of is only made out of three particles?
So everything that we are made out of is made of atoms, right?
If you zoom in really, really far, you'll see that your hand and the table next to you
and the llama that maybe you wrote to work on this morning are all made out of molecules,
which are built out of atoms from the periodic table.
Everything around us, right?
All the kinds of matter that you're familiar with are made out of atoms.
This excludes, of course, dark matter, which is some other weird kind of stuff that's part of the
universe, but we don't understand it all.
So all this sort of familiar kind of matter, the kind of stuff you can see and taste and eat is made out of atoms.
And those atoms are made out of electrons. And then in the nucleus, there are protons and neutrons.
Inside the protons and neutrons are made out of two different kinds of quarks.
Two ups and a down make a proton. Two downs and an up make a neutron.
So out of up quarks, down quarks, and electrons, you can build basically any atom.
and from that you can build any chemical
and from that you can build anything.
And the thing that's incredible to me
is that it's not just that all the stuff around us
is made out of these three particles.
It's also made out of these three particles
in the same relative abundances.
Like a kilogram of lava
and a kilogram of kitten
have the same number of each kinds
of these particles inside of them.
It's just the arrangements
that are different between them.
Interesting. Yeah, it's amazing
that you can reduce
the almost seemingly infinite variety of stuff in the universe into three things.
And like you said, it's amazing.
It's just all about the arrangement.
Although I think you said it's all kind of the same proportion.
Is that really true?
Like a cloud of hydrogen doesn't have the same number or proportion of particles as like lava, does it?
It almost does.
Hydrogen, of course, mostly has just protons in it, though there are forms of hydrogen that
also have a neutron.
And most atoms have an equal balance between protons and neutrons.
So most of the stuff out there in the universe has the same number of protons.
and neutrons in it, and that means the same number of upcorks and down corks inside.
You're right that most of the universe is hydrogen, which means that most of it are protons,
which means that there are more upcorks out there than down quarks.
The stuff that we made out of the stuff that we interact with is mostly not hydrogen.
I mean, I don't know if you're having hydrogen for lunch, for example,
but if you're having things made out of more complicated atoms,
then mostly it's an equal number of protons and neutrons,
which means an equal number of upcorks and down quarks.
I do have a lot of gas right now, but I don't think it's high.
But that's interesting, I hadn't thought about it before, that there are maybe more up quarks in the universe than down quarks.
Yes, there definitely are because the universe is mostly hydrogen out there.
Like it started out as mostly hydrogen and it's still mostly hydrogen, even though stars have been working furiously to make heavier elements in their cores.
And it's been billions and billions of years, they really only made a little bit of a dent.
So most of the matter out there in the universe, the visible matter of our kind is hydrogen.
You know, just as a caveat, remember that there's five times as much dark matter as any kind of atomic matter out there in the universe.
So anytime we're talking about this, we're only talking about the fraction of atomic matter in the universe.
And that's all made out of atoms by definition.
Right, because we are talking about matter particles, right?
There are other particles besides matter particles.
That's right.
And so the up quark, the down quark, and the electron, these are particles we call fermions.
They're spin one-half particles.
But as you say, there are other particles out there in the universe, and there's a different kind of particle.
They're particles we call force particles.
These are bosons.
For example, what holds the proton together?
It has three corks inside of it.
They're tied together by gluons.
So gluons are inside the proton, and they're just as much part of the proton as the corks are.
They're just sort of like less long-lived.
There's a huge swarm of gluons inside the proton.
In fact, most of the mass of the proton is not the corks.
it's the gluons. So it's like you have these three very light corks held together by incredibly
massive ocean of gluons, but each individual glue on doesn't last very long. Right, right.
It's kind of like when my kids make a craft, it's like it's mostly hot glue, a mess of hot glue
with some, you know, popsicles, sticks holding the glue together. Yeah. So most of the energy
inside the proton, which is what contributes to its mass, is due to the gluons. So, you know,
know, can you say that the proton is made partially of gluons?
Yes, you can, but you can't like point to a glue on and say, this is the gluon inside the proton,
because they're constantly just getting passed back and forth between the corks.
Whereas the corks, you can say, here's an upcork, I see where it is, it's this same upcork.
It's been part of the proton for a long time.
It's a stable state.
Right, right.
So we're all made out of up and down corks and electrons.
And you're saying that we also sort of need the particles that glue things together and then keep them together.
But I wonder if Carter's question was more about the other matter particles that have mass but that don't form the things that we're made out of.
You know, things like the top quark and the extra quarks and the other neutrinos and the extra electrons, right?
Yeah, so just to complete the story of the force particles, there's not just the gluons, of course, there are photons inside of us.
There are Higgs bosons that give mass to the particles.
There are weak bosons like the W and the Z.
All these things are playing part of this dance of how those matter particles.
are fitting together. But you're right, there are other matter particles. And I think these are probably
the ones that he was referring to because it's not just the electron. The electron has a heavy cousin
called the muon and has an even heavier cousin called the tau. And that's true of all of these
fermions. The upcork has two heavy cousins, the charm and the top. The down cork has two heavy cousins,
the strange and the bottom. And you know, a fundamental question, which is I think basically
is what Carter was asking is, why do these exist? Why are they there?
Why isn't there just a single generation?
Or why, if we have other particles, are they not totally different?
Why are they so similar, basically tweaked copies of this first generation?
The short answer to that is the title of our great book, which is we have no idea sort of why it is that way.
We can't say the universe has to be this way.
What we can say is that if the universe wasn't this way, it would look very different.
That is, we would notice if you, like, deleted them from nature.
Right.
Well, it's kind of interesting that he would ask or that,
anyone would ask that question, right?
I mean, we know these sort of heavy cousin versions of the electron and the quarks exist
because they can be made in a particle collider, for example, right?
That's how we know they technically exist, even though you don't see them around very much.
Yeah, so by exist, we mean they're part of the laws of the universe, not necessarily that
there are any in existence at any moment.
Right, and so they can exist.
And so the question, I guess, is like, why is it that they can exist if we don't see them
around us very much, right?
Because everything we know that the things are made out of around us are just the basic electron and up and down quarks.
Why can these other heavier particles exist?
Yeah.
And there's lots of really fascinating angles there.
One is like if there are these heavier particles, why do we only see the lighter ones?
Why are the lighter ones the only ones that seem to be around?
And the answer to that is that nature doesn't like heavy stuff.
It tends to spread out the energy.
So the heavy ones are short-lived.
They tend to decay into the lighter.
ones. So if you made a bunch of all the different kind of particles, including the heavy ones and the
light ones, the heavy ones would very quickly just turn into the lighter ones. Like the top cork doesn't
last for very long and last for like 10 to the minus 23 seconds before it turns into a bottom cork. And then
the bottom cork decays into a strange cork, which decays then into a down cork, for example. And so these
things just don't last very long. That's why they are not around. But the deeper question, which I think
you're asking is like, why can they exist at all? Why are they on the menu? And why three
generations and why not two and why not four? Right. I think that's the deeper question you're
asking. Yeah. Well, I think they're both deep questions, right? Like, why can they exist? Yes,
first of all. And also, why is it that right now we only see one kind? I mean, those are two big
questions, right? Well, the answer to why can they exist is really just a flat out we don't know.
We don't know if the universe has to be this way. To answer the question, why can they
You have to think, like, what kind of answer would be satisfactory.
And one kind of answer would be to say, this is the only way the universe could exist.
Like, it mathematically would be inconsistent or it just wouldn't make sense or it doesn't hang together.
There's no other way for it to be than to have three generations.
We don't think that's true right now.
Like, we could imagine a universe without those things.
It would still have laws of physics which functioned well and would make sense.
It would just be quite different.
Like, it would look very different from our universe.
But that doesn't mean that it couldn't exist.
And maybe out there somewhere in the multiverse, it does.
There are universes with one generation or seven generations or seven thousand generations.
The short answer is this is just a number, three, and we don't know why three and why not one.
It's not something in the equations of math of the universe that maybe tell you why they have to exist, like it to make things click or something?
Not right now.
If right now it's just descriptive.
You know, we don't understand it.
sort of the way, like, we used to not understand why there were so many atoms.
Like, why isn't there just hydrogen?
Why are these other weird atoms also out there, these other elements?
Now, we do understand it.
We understand that those things emerge from how smaller pieces come together and create
these other opportunities.
So it's possible that these other generations are like that, that they're all made out
of some smaller bits that electrons and quarks are not the smallest things in the universe.
There are even smaller things, squiggles or squaggles or whatever.
and the way that squiggles and squiggles come together make all these various options.
We don't know that that's true.
Right now, we're just in the descriptive phase.
We see these particles.
We catalog them.
We describe their interactions.
We don't know whether they emerge from something deeper, which determines this structure we see.
Right.
And the other question is, why do we only see the lighter particles now?
Because I think we've talked about this before that, like, maybe in the early universe,
there were the conditions for the heavier particles to exist.
So back then, it was common to have those larger, heavier particles.
But just right now, you don't see them.
Yeah, the short answer is that the universe is cold and old.
So back when the universe was young and hot,
then there was enough energy density to create these particles all the time.
They still decayed.
These particles are very short-lived, the heavy ones.
They turn into the lighter particles as just the natural way of the universe.
Energy density spreads out, right?
Second law of thermodynamics.
But back then, there was enough energy to constantly just be creating them out of the vacuum.
So the universe was a hot soup of all of these particles.
And there was so much energy that didn't really matter which ones had mass and which ones didn't,
because there was much more energy around than any of the mass of these particles.
So they were all very, very fast-moving particles.
But as the universe cooled down, it basically wasn't capable of making these particles on its own anymore,
and all the heavy ones decayed into the lighter ones,
and then it's just capable of keeping the lighter ones around from making those.
And now the universe is very cold and very old.
And so the only way you can make these heavy particles now is to artificially recreate
those conditions by, for example, slamming two protons together to create a dot of very high
energy density. And that's exactly how we discover that these particles still can exist in our
universe, even though they don't very often naturally. Right. And so that's kind of the answer
for why we don't see them around anymore, right? Is that they die, right? And they've all died
out, basically, right? Like maybe the early universe had a bunch of them, but they're like,
you know, I'm done. I'm out. Yeah. Well, it's just not hot enough to make those anymore.
more. And you know, there are conditions naturally that will create them. Like when protons
hit the upper atmosphere at very, very high energy, cosmic rays from space, they also create
these particles. So it's not just a large Hadron Collider capable of making these conditions. It
does occur naturally. But when they do, they decay away very, very quickly. So you don't find like
a pile of top quarks lying around or you can dig into the earth to find them. And it's fascinating
that some of these things are stable and some of them are not, right? Like we don't have the
conditions to make iron, for example, here on Earth. But iron is,
stable. Once you've made it in the heart of a star, you can take it out of that and bury it in a
planet and it'll sit there for billions of years. Top quarks are not like that. They're not stable.
So you make them in the early universe, you can't then just find hunks of top quark lying around.
All right. Well, then I guess maybe to extend Carter's question, then like if the universe
couldn't make these heavier particles besides the electron up and down corks, if it was maybe
impossible or if they didn't exist, would the universe notice? Would it be any different
than it is right now?
Yeah, you might wonder, like, would the only difference be for particle physicists
creating these collisions at the Large Hadron Collider?
Would anybody else notice?
Would the universe be any different?
Well, apparently we don't sort of need them to have the world around us right now,
because they don't exist right now, right?
You don't see a lot of them around, so why do we need them?
I guess it's probably Carter's question.
Yeah, so we actually do need them.
They do play a role.
Like, there's not enough energy to make them actually exist,
but virtual versions of themselves can exist.
they can like participate in interactions, even if they can't ever exist on their own.
And that's important because they do end up playing a role.
For example, the Higgs boson itself has a bunch of mass.
And that mass comes from interacting with not just the particles that do exist,
but all the particles that can possibly exist.
So if those other particles, the top cork and the bottom quark weren't on the menu,
the Higgs boson would have a very different mass and it would behave differently.
right so that would change how everything operated well not just the higgs but basically every other
particle would weigh the same or have a different mass yeah it would change how the higgs field is
balanced and so that would change the mass of all of the particles and so it's a very sort of
delicate rube goldberg machine you know it all sort of hangs together in this very complex way
it also would affect how the universe had evolved from the very early stages you know we think
that in the very beginning of the universe matter and antimatter were made in the same proportions
Now, of course, it's almost all matter.
We don't understand very well why that is, but the hints we have suggest that it has to do with these other weird particles like strange quarks and bottom quarks, that they don't have symmetries, that there's a difference between particles made of strange quarks and anti-strange quarks, for example, that the universe prefers for those to decay into matter rather than antimatter.
It's not something we've totally solved, but we think these other generations play a big role in that.
So if they weren't around, then there might just be a perfect balance between matter and anti-matter,
which would have all just annihilated into photons, and the universe would just be light.
There would be no matter left over.
Wow.
Sounds like either way, we just all weigh a little less.
We'd all be brighter, too.
Well, all right.
Well, I think that answers Carter's question.
Why do particles other than the electron neutrina up and down quirk is this?
We don't know.
But definitely the universe would be a lot different.
And if they didn't exist, we probably wouldn't be around to ask.
this question. That's right, but maybe one day we will peer inside the electron and the quark
and we will understand why they exist and why their cousins exist. So future generations
of podcast listeners might be asking questions about why those little squiggles and squaggles.
Yeah, and it could be Carter. He could become a particle physicist.
Do it, Carter. His parents are going, no, what have you done? I bet they prefer a particle physicist
to a cartoonist. Some cartoonists are pretty rich. I don't know any of them, but I hear some of
are pretty rich.
Yeah, we'll have Mac Groening on the podcast.
All right, well, awesome question.
Thank you, Carter.
So let's get to some of our other questions
about particles from listeners.
But first, let's take a quick break.
December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage,
kids gripping their new Christmas toys,
then at 6,000.
33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and order, criminal justice system is back.
In season two, we're turning our focus to a threat that hides in plain sight.
That's harder to predict and even harder to stop.
Listen to the new season of Law and Order Criminal Justice System
on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam. Maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on.
the okay story time podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out
with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other,
but I just want her gone.
Now hold up, isn't that against school policy?
That sounds totally inappropriate.
Well, according to this person,
this is her boyfriend's former professor
and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person
to believe him because he now wants them both to meet.
So, do we find out if this person's boyfriend really cheated with his professor or not?
To hear the explosive finale, listen to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
I had this, like, overwhelming sensation that I had to call her right then.
And I just hit call, said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation.
And I just wanted to call on and let her know there's a lot of people battling some of the very same things you're battling.
And there is help out there.
The Good Stuff podcast, season two, takes a deep look into One Tribe Foundation, a non-profit fighting suicide in the veteran community.
September is National Suicide Prevention Month, so join host Jacob and Ashley Schick as they bring you to the front lines of One Tribe's mission.
I was married to a combat army veteran, and he actually took his own life to suicide.
One Tribe saved my life twice.
There's a lot of love that flows through this place, and it's sincere.
Now it's a personal mission.
Don't have to go to any more funerals, you know.
I got blown up on a React mission.
I ended up having amputation below the knee of my right leg
and a traumatic brain injury
because I landed on my head.
Welcome to Season 2 of the Good Stuff.
Listen to the Good Stuff podcast
on the IHeart Radio app, Apple Podcasts,
or wherever you get your podcast.
Hola, it's HoneyGerman,
and my podcast, Grasias Come Again, is back.
This season, we're going even deeper
into the world of music and entertainment
with raw and honest conversations
with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We've got some of the biggest actors, musicians, content creators, and culture shifters
sharing their real stories of failure and success.
You were destined to be a start.
We talk all about what's viral and trending with a little bit of chisement, a lot of laughs,
and those amazing Vibras you've come to expect.
And of course, we'll explore deeper topics dealing with identity,
struggles, and all the issues affecting our Latin community.
You feel like you get a little whitewash because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
But the whole pretending and cold, you know, it takes a toll on you.
Listen to the new season of Grasas Has Come Again as part of My Cultura Podcast Network
on the IHart Radio app, Apple Podcast, or wherever you get your podcast.
All right, we're answering listener questions, and today's theme is particles and mass and little tiny things in the universe.
We're drilling down to the core questions about the universe, like how do you pronounce Matt Groening's name anyway?
Groening, graining, I've never understood.
And so our next question comes from Ricky from New Zealand.
Hey, guys, my name is Ricky.
I'm from New Zealand.
I've been listening to the podcast for a few months, and I'm really enjoying it, so thanks heaps for that.
I have a question about light.
I was wondering how it would have affected the growth of the universe
and how it would affect our everyday life now
if light had any form of mass to it.
Cool.
Thank you.
Great question.
Thank you, Ricky.
I think his question is,
how would the universe be different if light had mass?
Mm-hmm.
And I guess specifically, like, how would it have developed differently?
And how would it be different for us today if it had mass?
Yeah, so this is a super fun question.
And it led me down a little rabbit hole of reading, thinking about why is it any way that the photon has no mass?
And do we actually know that the photon has no mass?
What?
Okay, first of all, most people think the photon or light has no mass.
That's right.
And in our current theory, it has no mass.
Like the standard model of particle physics assigns it to be exactly zero mass.
But that's the theoretical description, right?
You can also go out in the universe and you can ask, well, can we measure the mass of light?
And we do experiments to tell us whether light has any mass.
And you know, experiments are always a little bit fuzzy.
There's always statistical fluctuations or a limit to your sensitivity.
And so a really fun question to ask is like, well, how do we know that light has no mass?
Interesting.
Nobody's tried to weigh it, I guess.
But isn't it impossible for light to have mass?
Like, then it can't go as fast as the speed of light, right?
Then you would have to change the name of the speed of light.
Yeah, that's right.
If light had mass, then it wouldn't.
act the way we describe it. You know, all the properties we talk about for light, that it moves
at the maximum speed of the universe, that it can't have a rest frame, all of these things require
it to not have mass. That doesn't mean that it doesn't have mass, right? That's just like our
description of the universe has light with zero mass in it. And you can also ask the question,
like, does our description of the universe require light to have zero mass? Could you have a universe
where light does have mass? Is it necessary? As we were talking about earlier, for light to
have no mass or why does our universe give mass no light?
But I thought in our theories that if something had mass and if it was going at the speed of
light, it would need infinite energy.
That's right.
So if light has mass, then it wouldn't be moving at the maximum speed of the universe,
what we're currently calling the speed of light.
But you can devise theories of the universe where light does have mass and then doesn't move
at that maximum speed.
Oh, we could have a universe where there was.
was a maximum speed, but light wouldn't move at that speed.
Exactly.
Like you can just give mass to light and the universe would still work?
Yeah. In fact, we don't even really know why our universe doesn't give any mass to light.
You know, the mass of the other particles like the W and the Z, these come from the Higgs boson.
But the W and the Z are really very, very similar to the photon.
And in the very early universe, they all had no mass.
And then the Higgs field settled into its weird value and it gave mass to the W and to the W and
the Z and zero to the photon. You might ask like, why zero? Well, the answer is we don't know.
It's sort of unexplained. It could have given some mass to the photon, but it didn't.
And if it had, then our universe would be a little bit different. We don't know why the Higgs boson
gives the photon zero mass. It doesn't have to. It's like a parameter. And we seem to be at or very
near zero for the photon's mass, but it could have been different.
Is it that the Higgs field just ignores the photon?
Like it just doesn't interact with it?
Or it does interact.
It just assigns a value of zero mass to it.
It definitely interacts with it.
You know, the photon is part of the electro-week theory
where you combine electromagnetism where the photon operates
and the weak force where you have the Ws and the Zs.
So in the early universe, the photon, the two Ws and the Zs,
they're like a gang of four.
They're all very related.
They're part of this larger group.
And the Higgs comes along and he picks three of them out
and says, you guys all get a mass, and photon, you get none.
And you're saying, like, we don't actually know if light has zero math,
like nobody has ever measured it?
Or I guess we've never measured that something can go faster than light.
Would that tell us that light has mass?
Like, if we ever measure something going faster than light,
maybe that means that the maximum of the universe is higher than the speed of light,
and light maybe has some mass.
Exactly.
We have definitely tried to measure the mass of light,
and every experiment is consistent with light having no mass.
So, you know, this is sort of a theoretical exercise.
The best description of the universe that we see around us is one where light has no mass.
Don't be confused about that.
We're not saying the light might have mass or we think it does have mass.
We're just saying there's not necessarily any a priori reason for it to not have mass,
but it's the best description of what we see out there.
So we can do a bunch of experiments to try to measure the mass of light.
And if light had a lot of mass, it would be obvious, right?
It would look very different.
Things would travel faster than it, right?
The most sensitive experiment, the best way to see if light has even a tiny little bit of mass is to look at the sun's magnetic field and how the solar wind moves through it.
Because remember, photons are part of the electromagnetic field.
And so if light had even a little bit of mass, it would change how electromagnetic fields propagate through the universe.
It would be a little bit weaker if light had a little bit of mass.
So the sun's magnetic field is like the biggest electromagnetic effect in our neighborhood.
And so it's the most sensitive test.
So by looking at the sun's magnetic field,
we can tell that light, if it has any mass,
it's an incredibly small value.
I see.
I think you're saying that according to the theories,
light could have mass,
but according to our measurements,
we think light has no mass.
Exactly.
There's a parameter in the theory
that could give mass to light.
We set that parameter to zero
because that's the value
that's most consistent with all of the experiments,
all of our descriptions of the universe.
as we see it today are consistent with light having zero mass.
All right.
Well, now let's get to Ricky's question,
how would the universe be different if light had mass?
So the universe would look pretty different,
but it depends on how much mass light had.
You know, if light had a lot of mass,
then everything would be very, very different
because it would make the electromagnetic force quite different.
You know, the electromagnetic force is very powerful.
It's much more powerful than the weak force.
But that's because the photon has no mass,
and the weak bosons do have mass.
Wait, how does having mass make the force weaker?
Well, you know, there's a connection between these forces and the particles, right?
So the electromagnetic force comes from the photon.
The photon is the thing that does the job of the electromagnetic force.
And so if the photon was massive, it couldn't do his job as well.
It would move more slowly.
It would cost more energy to make it, this kind of stuff.
Just like the way the weak force does because the particles that transmit the weak force,
the W and the Z particles, they're also heavy.
Right.
like when you get two magnets together
or like what keeps your atoms together
in your body is the electromagnetic force
and so it's the photon
is sort of like the transmitter of that force
right? And so I guess
if that transmitter had mass
it would just be sluggish right
or it would sort of disappear
it more easily. Yeah it would be like shorter
range. You know it wouldn't have as
far an impact like the weak force right
now is basically like the electromagnetic force
but with heavy photons.
Right. So what would happen if the photon
had mass, electromagnetism would be a lot more like the weak force.
It would be much weaker.
It would have shorter range.
It's like instead of email communications between people right now, we would be back
to like stone tablets, kind of, right?
Like the way that things communicate had a lot of mass to them.
You know, society wouldn't function as quickly, right?
Yeah, it would be very different.
And also, light wouldn't be as long lived, right?
If light had mass, it could decay into other particles, right?
Now we're very privileged because a photon created billions of years ago and super far away
can travel through the universe basically forever until it hits something.
Like maybe it hits the James Webb Space Telescope and we get to see a really old, distant
galaxy.
That's because that photon is stable.
It's because the photon is massless.
If the photon had mass, then along the way it could like turn into other stuff.
It could decay into lighter particles depending on how much mass it had.
And so the universe wouldn't be as visible.
Like if I sent you a stone tablet email, it might break along the way
or most likely will break along the way, right?
Almost certainly, yeah.
Zs and Ws created by distinct galaxies don't get here.
They turn into other stuff and fizzle out.
And so we don't see them.
We see photons from those galaxies because they're massless, because they're stable,
so they can fly forever.
All right, I'll cancel my new startup idea, stone mill.
It's probably very secure, though, right?
Do you encrypt it?
Is it in cuneiform?
And I think probably doesn't rock.
All right.
So then if light has mass, then the electromagnetic force would be a lot weaker, shorter range.
How would that affect the universe?
Well, first of all, you could do really fun experiments in that case because you could, like, catch up to photons.
You could be in their reference frame.
You could have photons that are at rest.
You could, like, have a pile of photons.
You know, we don't know what a photon looks like right now.
A photon, you only see it.
it hits your eye. A photon passing by you, you can't see, right? You can't ever catch up to a
photon. But if photons had mass, then they could be at rest. And so you could like hang out
with a photon. So that would be pretty different, you know, for nerds like us who are curious
about what particles are like, that would be quite different. Well, although, can we, do we know
what an electron looks like? What does an electron look like? What does an electron look like? You know,
whatever it does to a photon that bounces off of it. So yeah, you have to probe these things with
something. So what would you probe light with? More light? You could probe it with electrons. You
could use a scanning electron microscope to look at photons at rest. Interesting. All right. So we could
maybe get a closer look at light if it was moving slower because it had mass. How else would
think to be different? What Ricky was also asking about how it would affect the evolution of the
universe. You know, we know that very early on in the universe, there was this plasma of all sorts
of crazy goop. There were photons. There were particles. There was dark matter. And all that was sort of
oscillating back and forth and sloshing in and out and made all of these acoustic ripples.
And the rate of those ripples and how things were sloshing back and forth depend on the
fraction of dark matter and normal matter and photons. And so that would all be different if
photons had mass because it would affect the gravity of that situation. And so it would affect
how those things are sloshing. And that sloshing is very important because it ends up controlling
where the dark matter pooled together, which turns out to influence how galaxies form. So the whole
structure of the universe could be very different if you tweak those initial ingredients even a
little bit.
Well, how would the structure be different?
Like, would we be more dark matterish or would mass, would we have black holes earlier?
You know, what would be different about how it looks?
So part of this sloshing has to do with dark matter pulling things in and then photons
pushing things back out.
That's why we get these like ripples, these oscillations.
And so photons aren't as powerful if they have mass, if they contribute,
to pulling things in rather than pushing things out, then things would oscillate differently.
And those oscillations are what caused sort of the pattern of galaxies that we see today.
And so we'd have galaxies at like different distances from each other right now because those
oscillations are what caused galaxies to form like here and not there.
And so the overall large scale structure of the galaxies would definitely be different.
You might also get different size pools of dark matter, which would make different size
galaxies, but I'd have to like run a bunch of really complicated simulations to know for sure.
I see. Like maybe the universe would be good cluster together more or maybe it might be sparser
or something like that. It's all a very, very delicate recipe, you know, sort of like a souffle.
You change the ingredients a very small amount and it can come out quite different. Yeah, that's why I don't
like baking or cooking. Too stressful. Well, I'm glad you weren't in charge of baking the universe.
Yeah, you don't want me in charge of baking anything.
much less everything, everything.
But I guess, you know, being selfish, how would it affect me if light had mass, right?
Because I think the electromagnetic force really basically controls everything about me, right?
Like, it's not just magnets and light, it's also like chemical bonds and why even the electron
sticks to the nucleus of an atom and why atoms stick together at all.
It's all because of photons, right?
Yeah, and the electromagnetic force.
Yeah, chemistry is basically just the dance of electrons and photons, right?
as those charges make atoms stable, and then those atoms form together to make molecules
and all sorts of chemistry of life.
And so you're really changing the very basic rules of those structures.
You know, it's like you're taking away some of the crucial Lego pieces for building things,
and you're replacing them with something else, something much, much weaker.
And so it might be that, you know, you just can't get atoms as stable.
The energy levels of atoms would definitely be different, which would lead to totally different
chemistry.
And it might also be interesting.
It might also be delicious.
but it would definitely be unrecognizable from our world.
Well, I think maybe a cool question to ask is,
what if I had a switch in front of me that had like the mass of the photon
and I just said, hey.
Don't touch it. Don't touch it.
Yeah, that's what I mean.
Like, what if suddenly we had the world we have right now,
but all of a sudden the photon had mass,
but we all just kind of like dissolve, explode, you know, turn too much?
What do you think?
I think we were probably just sort of like drift off into a gas.
You know, I think that a lot of our bodily consistency depends on all these bonds holding themselves together.
And those bonds suddenly get weaker by a significant amount.
And yeah, you basically just like sublimate into a gas.
You mean like in the Avengers Infinity War?
Like we just all turned to ash?
Yes.
Whoa.
And maybe that's how Thanos did it.
Yeah, maybe that's how he did it.
Yeah, that's how he did it.
Oh, man, Thanos.
You knew he was a particle physicist, right?
He had that evil gleam in his eye.
That's right.
That's how it works.
You snap your fingers and you can change the, you know, that's what physics gives you the power to do.
Yeah.
And so we think that our photons probably have zero mass.
If they do have mass, it's something smaller than 10 to the 26th of the mass of the electron, right?
So it's a very, very, very small value.
But we can't actually say for sure it's zero.
And the theory would allow for it to be non-zero.
Interesting.
But I guess if it did have a little bit of mass, everything might be okay because we're still here.
Yeah, you could have like almost zero, very, very close to zero, like 0.0 and then 100 zeros and then a 1, and the universe wouldn't be very different.
We wouldn't be able to tell the difference.
All right.
Well, I think that answers Ricky's question.
The universe would be pretty different depending on how much mass the photon would have in this scenario.
It had a lot of mass.
This would be super duper different and not the same.
But maybe if it has a little bit of mass, it would still be okay.
And we would still be here.
And so, Ricky, please don't build a device that gives photons in the universe mass.
Or if you do, don't press the button.
That's right.
Don't put on the infinity gauntlet.
Leave it where it is.
Or at least take out the physics stone, because that's the one that causes all the trouble.
All right.
Well, let's get to our last question about virtual particles.
But first, let's take another quick break.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of.
of enemy emerged, and it was here to stay. Terrorism.
Law and Order Criminal Justice System is back. In season two, we're turning our focus
to a threat that hides in plain sight. That's harder to predict and even harder to stop.
Listen to the new season of Law and Order Criminal Justice System on the IHeart Radio app,
Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Well, wait a minute, Sam, maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now, he's insisting we get to know each other, but I just want her gone.
Now, hold up. Isn't that against school policy? That sounds totally inappropriate.
Well, according to this person, this is her boyfriend's former professor, and they're the same age.
And it's even more likely that they're cheating.
He insists there's nothing between them.
I mean, do you believe him?
Well, he's certainly trying to get this person to believe him
because he now wants them both to meet.
So, do we find out if this person's boyfriend really cheated with his professor or not?
To hear the explosive finale, listen to the OK Storytime podcast on the Iheart Radio app,
Apple Podcasts, or wherever you get your podcast.
Our Iheart Radio Music Festival, presented by Capital One, is coming back to Las Vegas.
Vegas.
September 19th and 20th.
On your feet!
Streaming live only on Hulu.
Ladies and gentlemen, Brian Adams, Ed Shearrett, Fade, Chlorilla, Jelly Roll,
John Fogarty, Lil Wayne, LL Cool J, Mariah, Mariah Carey, Maroon 5, Sammy Hagar, Tate McCray,
the Offspring, Tim McRaw, tickets are on sale now at AXS.com.
Get your tickets today, AXS.com.
Hola, it's HoneyGerman, and my podcast, Grasasas Come Again, is back.
This season, we're going even deeper into the world of music and entertainment.
With raw and honest conversations with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't audition in like over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We've got some of the biggest actors, musicians, content creators, and culture shifters,
sharing their real stories of failure and success.
You were destined to be a start.
We talk all about what's viral and trending with a little bit of chisement,
a lot of laughs and those amazing vibras you've come to expect.
And of course, we'll explore deeper topics
dealing with identity, struggles,
and all the issues affecting our Latin community.
You feel like you get a little whitewash
because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
But the whole pretending and code, you know, it takes a toll on you.
Listen to the new season of Grasasasas Come Again
as part of my Cultura podcast network
on the IHartRadio app, Apple Podcast,
or wherever you get your podcast.
All right, we're taking listener questions about particles in this episode.
And our last question comes from Anthony, who is a question about virtual particle.
Hello, Daniel and Jorge.
Ever since I heard your episode on virtual particles, recorded back in 2020,
I've had a question in the back of my mind.
From your explanations on the subject, I've understood that virtual particles,
particles are ephemeral, they don't last long, and that their mass may fluctuate. But that still
means that at any given point in time, there must be myriad virtual particles in the universe.
Someone must have surely estimated their combined mass. What does it add up to? Does the mass of all
the virtual particles in the universe get counted as ordinary matter? And if not, could it account
for the elusive dark matter or some portion thereof? Thank you.
All right. Awesome question from Anthony about virtual
particles and possibly as an explanation of dark matter.
Do you think he's cracked the big mystery?
No.
Oh, you can have been a little gentler there.
Sometimes you just got to give a clear and crisp answer.
See?
Oh, man.
No, I don't think that dark matter is made out of virtual particles.
Well, I'm still rooting for you, Anthony.
Don't worry.
We'll try to make it work here on the podcast.
You know, you got to understand how often people write to me and say,
oh, by the way, I don't really understand.
ABC and could that be the dark matter?
It's basically like the end of almost every question we get.
Really? Well, maybe one of them might be true one day.
Yeah, they might. Absolutely. Isn't that possible?
Absolutely. And I encourage people to keep thinking about it because someday somebody will
figure it out. Hey, Daniel, I don't understand pink hamsters. Could that be the cause of
dark matter in the universe?
No.
Oh, man. You're like the Simon Cowell here of physics today.
Harsh, harsh, harsh. Hey, people want answers.
Yeah.
All right, so the question was about virtual particles and whether maybe physicists have forgotten to take into account their mass and their effect in the universe.
So step us through here.
What is a virtual particle first of all?
So a virtual particle is shocker sort of badly named.
It's not really a particle in the way that we are thinking about particles.
You know, what is a particle?
A particle is like a wiggle in a field.
So the electron, for example, is a wiggle in the electron field.
is a field for every particle that's out there,
the electron field, the upcork field,
the downcork field, the electromagnetic field.
All these things are fields.
And they can wiggle in this interesting,
a particular way, we have like a little packet of energy,
which is self-sustaining and moves through the field.
The way you can take, for example, a rope,
and you can tweak it so that you have like a standing wave
which moves down the rope, right?
So particles are these sort of special oscillations of these fields
in a way that lets them like move through the field.
So that's what a particle is.
I see.
There's sort of like a wiggle that doesn't just dissipate in a quantum field in the universe.
Do we know why some wiggles stay around and some wiggles don't?
So we have this whole episode recently about what is a particle and it gets kind of philosophical.
And so some folks think that particles are just these wiggles in fields.
And the ones we define to be particles are the ones that do stay around, right?
They have this capacity for the energy to slide around in this particular.
way. So the way the energy moves through these fields is governed by the wave equation, just
like with any other kind of wave, right, like in the water or on a string. There's this mathematical
equation that tells you what are the possible solutions. And there are some solutions to
those equations that are self-sustaining, you know, that where the energy just flows in this
particular way, so it maintains itself. It doesn't spread out. Right. I'm thinking maybe like the, if you
think about a field, a quantum field as like a big sheet that you have, maybe.
And if you have it out there in the wind and kind of holding it up, the wind will make it kind of ripple all over the place.
But every once in a while you might see like a little like a bump in that sheet that kind of forms and then can move it across the sheet.
That's kind of what a particle is, right?
And so any situation where you have a self-sustaining wave that moves across and sort of keeps its coherence, that's what you call a particle.
And if it does that, then it has special properties.
like you can talk about it having a certain mass because it has motion and you can describe the motion, you know, in terms of like a force having been applied and getting acceleration. And so there's a concept of mass of this particle has all sorts of properties that we tend to attribute to the kind of stuff we find familiar. You know, things around us have mass. So these ripples and these fields have these properties like they have a specific mass, which is related to their energy, et cetera, et cetera, all the things we tend to think of as particles. So that's what a particle is. A virtual part
is something different.
A virtual particle is like a different kind of wiggle in this field.
It's one that's not self-sustaining.
It's usually caused by the presence of other particles.
So for example, an electron is a self-sustaining wiggle in the electron field,
but it creates wiggles in the electromagnetic field, right?
Because electrons have charge.
That's what it means to have charge,
is that you create wiggles in the electromagnetic field.
So an electron whizzing around the universe is making ripples in the elliptic
ripples in the electromagnetic fields around us, which means, in some sense, it's making virtual
particles in that field, which we call virtual photons. So virtual particles are like non-self-sustaining
ripples in a field, mostly caused by the presence of other particles. Wait, what? Okay, first
of all, you were saying that an electron can cause a ripple in the photon field that is not a
photon. But it does create photons, right? Like the presence of an electron talking to maybe
another electron does create ripples in the electromagnetic field, which we call photons. But you're saying
it can also make ripples that are not photons. It can make ripples that are real photons. Like an
electron can radiate a photon, which can hit your eyeball and you can see it. It's a real
photon. Propagates to the universe with what we think is zero mass and follows all those rules.
electrons can also create all sorts of other ripples in the electromagnetic field,
you know, just sort of like sloshy, messy ripples that don't coalesce to be a self-sustaining packet,
and we call all those ripples virtual particles.
It would have been better if we'd given them a different name
because they really are sort of a different category of thing,
but some people think of them as all part of a larger spectrum of phenomenon.
So they call these real particles versus virtual particles.
I see.
And I guess the big difference is that virtual particles don't last.
or something, right?
They're not sort of cohesive packages
like the regular particles.
They are ripples in the quantum fields,
but maybe there are sort of like
messy ripples,
like just a little, tiny, random fluctuations.
Yeah, they don't last.
They dissipate.
They tend to spread out.
And if the source of them disappears,
then they disappear.
But doesn't it take energy to make them?
It does take energy, absolutely.
And so the source of them is putting
some energy from its field
into the target field.
So, for example, electrons do give up energy
into virtual photons, right?
And those virtual photons capture some of that energy, right?
But then they turn into other stuff.
Those virtual photons turn into other fields.
Sort of just sloshes through the universe.
It's not in a coherent self-sustaining packet.
Wait, what?
So then an electron flying through the universe will eventually slow down?
Well, for an electron to transmit any energy into the photon field,
it has to decelerate or accelerate.
So it has to change its energy.
So it would slow down.
But an electron just flying constant velocity doesn't slow down
and doesn't create any virtual photons.
Only when it accelerates does it create any real or virtual photons.
That's when it changes the electromagnetic field.
Flying with constant velocity doesn't change any of the fields.
But I guess maybe the takeaway, instead of talking about these specific,
is that a virtual particle is just like a random wiggle in the quantum fields, right?
But it's a little bit different than maybe, I wonder if Anthony is maybe thinking
of maybe a different kind of virtual particle.
Like they say that when particles sort of exist, there's also like other particles popping
in and out around it, right?
Isn't that something they also call virtual particles?
Like when you calculate the mass of a particle,
you have to calculate all of the possible particles
that may be popping in and out of existence around it too.
Yeah, yeah.
And so you could ignore virtual particles completely
and you could say, look, it's just particles
and there are fields.
And instead of thinking about virtual particles,
you just think about the fields.
Like when the electron moves through the universe,
it's interacting with the photon field.
And don't try to call those things particles.
Just think about them as fields.
And so what you were just talking about is how particles interact with the fields that are around them.
Like we were saying earlier, the fact that the top quark can exist changes how Higgs bosons move to the universe because they talk to virtual top quarks.
Or another way to say that is that they interact with the top cork field that is out there in the universe, even if there are no real top quarks existing in the universe.
So every bit of space is filled with these quantum fields.
And those fields, the top quark field, the field is there, even if there are no top quarks in it, right?
And so the electron field is there, even if there are no electrons in it.
So the universe is filled with these fields, which you could also call virtual particles, right?
You could think of these fields is just like a swarm of very low energy virtual particles.
It's sort of mathematically equivalent, whether you think about them in terms of the fields or a sum over lots and lots of virtual particles.
Okay, but I think maybe the takeaway is that we have quantum fields out there.
and they do wiggle, maybe, and sometimes not in super permanent particle ways.
They do sort of wiggle, which maybe have energy in their wiggles.
And so I think maybe Anthony is asking, like, you know, there are all these fields out there.
They're wiggling and have energy.
Doesn't that maybe add mass to the universe?
Because energy in a field is sort of like having mass in the universe, isn't it?
Like, what's the relationship between these wiggles and do they actually have mass?
It's a great question.
Right. And so you can think about empty space and what's going on there and there are these fields, which you can all think about as like particles. Now, do virtual particles have mass? You know, particles themselves have a specific mass because of the way they move through the universe. Virtual particles don't really have a well-defined mass. But do they have mass? If you want to think about them in terms of the particle framework, then they can have mass and those masses can be any value. You know, you can have virtual photons that have a huge amount of mass. You can have virtual top quarks with a very tiny.
amount of mass, but those only really exist in our calculations. Virtual particles are not
things you can ever see or observe. They're only like the way other particles talk to each
other, which I think is why it's maybe more natural to think about them instead in just in terms
of fields. They're just really the way the two particles talk to each other. But technically,
mathematically, these particles do have mass, but you can never observe these particles. You can
ever interact with them. You only interact with real particles, not with virtual particles.
But I guess we were calling virtual particles the wiggles in these fields, right?
So the universe has fields, there are random non-particle wiggles in them.
And so maybe Anthony is wondering, like, do these random wiggles have mass?
And could that mass maybe account for dark matter?
These random wiggles do have energy, right?
And all the fields that are out there in the universe have energy because quantum fields can never be at zero.
That's why we talk sometimes about virtual particles popping out of the vacuum because there isn't really zero energy vacuum out there.
there's energy out there.
But mostly it's potential energy.
These fields have non-zero potential energy.
And potential energy actually has the opposite effect of mass.
Potential energy can create a repulsive force in the universe.
It contributes, for example, potentially to the dark energy of the universe.
So Anthony's on to something.
He's just maybe picked the wrong dark concept here.
Is that what you're saying?
Yeah.
And we know the universe is accelerating.
And one way to describe that acceleration is to say maybe the universe is filled.
with a bunch of potential energy that's causing that because in general relativity, if your space is
filled with a field with potential energy, that can cause repulsion. It might explain inflation in the
early universe. It might explain dark energy. Problem is that if we look out into the universe and
measure the potential energy of all the fields we think are out there, it doesn't explain the dark
energy that we see. So we have accounted for the potential energy of the fields that we see, but it doesn't
explain the acceleration. It's off by a factor of like 10 to the 100. I see. A little bit off.
A little bit off. But what about Anthony's question here where he asked, what is the combined mass
of virtual particles in the universe? I would say that doesn't really have a solid answer,
you know, because the virtual particles don't really have a well-defined mass. So it really could
be anything at any moment. Oh, interesting. But in a particular spot maybe, you know, a virtual
particle could have any mass, but maybe he's wondering if overall in the universe as an average,
if you take the average of all virtual particles everywhere, or at least in like a giant space
the size of the galaxy, is that also fluctuating? Or do you think it has some sort of like standing
mass to that average, you know, ripples and wiggles in the field?
The way I think about it is that that's just the potential energy of those fields.
Sometimes that potential energy gets momentarily converted into virtual particles, but it's really
just another way of thinking about the field as having potential energy, is having capacity
to interact with the stuff around it. So I don't really think of that as having like real
actual mass. But you just say that virtual particles are sort of created and popped into
existence. But those virtual particles don't have mass? Well, they don't have mass in the same
way that real particles do. Like what does mass mean? It means how particles propagate through the
universe. And virtual particles don't propagate through the universe the same way real ones do. Also,
Remember, now we're talking about, like, the mass from particles.
We don't even understand how gravity works when it comes to particles.
So if you're talking about, like, the gravitational impact of individual quantum particles,
that's a question for quantum gravity anyway.
All right.
Well, then I guess how would you summarize his question, the answer to his question?
Like, do virtual particles have mass and can they add up to something?
Or, I mean, I feel like your answer is very kind of theoretical and seems to be dependent on how you look at things in the universe.
What would be a more direct answer for Anthony?
I think maybe the crispest answer is no.
No, that virtual particles don't have mass?
No, the virtual particles aren't the dark matter.
They're not contributing to the mass of the universe.
I think the clearest way to think about it is that virtual particles are not particles
the way you are thinking about tiny little bits of stuff.
Instead, just think about them as fields filling the universe.
There are these quantum fields out there capable of doing stuff.
And they are affecting the overall flow and shape of the universe,
but in the opposite way of mass,
we think they're probably contributing to the expansion of the universe
rather than pulling stuff together.
I see.
Okay, I think maybe then what you're saying is that virtual particles
maybe even have, not only do they not have mass
in the same way that particles do,
but maybe they have kind of negative matter
or they contribute negative mass to the universe.
As maybe you can tell,
I'm not a fan of the picture of virtual particles.
I prefer to think about fields as a way to interact between particles
rather than virtual particles.
But mathematically, they are,
equivalent, but I think they raise a whole bunch of questions that you can't really answer because
particles is sort of the wrong word to describe them. I see. So we'll just tell Anthony to
rephrase this question in terms of quantum fields. And maybe you'll be in a better mood to
answer this one. Quantum fields don't contribute to the dark matter, Anthony. We think they might
contribute to dark energy, but we don't really understand by how much. But it is interesting. I mean,
I can see how Anthony could have reached that conclusion, right? Like, you'd
learn about one thing and then you learn about something else. And you're like, oh, wow,
that makes sense to me if they're related. I wonder if they are, right? Like, it's all right
to wonder these things, right? Oh, absolutely. And sometimes two big mysteries are the answers to
each other, right? Like, why does this happen over there? Why does that happen over there? Oh,
it turns out you were thinking about these things as disconnected, but they're actually two parts
of the same coin. So I absolutely encourage people to think about how part of one mystery might be
the answer to another. That's right. And also don't insult this is by asking if maybe they
miss something. I think that's one lesson we've learned today. No, I don't feel insulted at all.
And I love all of the questions. And I encourage people to think broadly and write every
question they have. Please send us your questions to questions at Danielanhorpe.com.
Great. Well, those are our three questions about particle physics. And Daniel, as a particle
physicist, must be pretty exciting to have people ask you questions about the field you're studying.
It's super fun. I love thinking about this stuff. And I love that other folks, not just particle,
physicists are interested in these questions. You know, it's easy to look up at the night sky and think
about astronomy and ask questions about stars and galaxies. But it's also possible to look just down
at your hand and the ground below your feet and all the matter that's around us and wonder like
what makes that up. What are the rules of it? That's what got me into particle physics. And I think
that's pretty accessible. Yeah. And it's pretty amazing to think that, you know, we have this
intuitive view of our or intuitive sense of the universe as being these kind of, you know,
giant pool table with biller balls bouncing around.
But as you drill down into these small sizes,
there's all kinds of weird things happening.
Absolutely.
And sometimes we understand that only in terms
of the mathematical description, which amazingly
works so well and predicts the results of our experiments,
we don't always have a deep intuitive understanding of it.
And that's because things of the smallest level
really are very different from our intuition.
To build an intuitive understanding usually
means explaining the unknown in terms of the known.
But here the unknown is so radically different than the known that it's really hard sometimes
to describe it in terms of familiar concepts.
So if you hear me struggling and you hear Jorge persisting and asking the same question
until we get an answer that you guys can understand,
that's because sometimes it's just hard to translate these ideas from mathematics to intuition.
Right, right.
We need to spend a summer in front of a computer coding so that we can beam the math rate into our listeners.
Paint that picture and our brain.
I've had many moments in science where I said, I don't understand this, but I'm just going to follow the math because the math works.
It'll give me a prediction. It gives me the answer I need. I don't really intuitively understand it.
Daniel, the math is telling me that you send me a check for $100,000.
And sometimes being asked to explain it intuitively, to teach it in a class or to talk about in the podcast, forces me to think about it again and dive deeper for an intuitive explanation, which helps me understand it better.
Cool. Well, thank you to all the people who send us questions.
We love to answer them here on the podcast
and we hope that all of you out there
enjoyed us talking about these questions
and maybe or maybe not answering them.
Certainly doing our best.
We hope you enjoyed that.
Thanks for joining us.
See you next time.
Thanks for listening.
And remember that Daniel and Jorge
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