Sean Carroll's Mindscape: Science, Society, Philosophy, Culture, Arts, and Ideas - 268 | Matt Strassler on Relativity, Fields, and the Language of Reality
Episode Date: March 4, 2024In the 1860s, James Clerk Maxwell argued that light was a wave of electric and magnetic fields. But it took over four decades for physicists to put together the theory of special relativity, which cor...rectly describes the symmetries underlying Maxwell's theory. The delay came in part from the difficulty in accepting that light was a wave, but not a wave in any underlying "aether." Today our most basic view of fundamental physics is found in quantum field theory, which posits that everything around us is a quantum version of a relativistic wave. I talk with physicist Matt Strassler about how we go from these interesting-but-intimidating concepts to the everyday world of tables, chairs, and ourselves. Blog post with transcript: https://www.preposterousuniverse.com/podcast/2024/03/04/267-matt-strassler-on-relativity-fields-and-the-language-of-reality/ Support Mindscape on Patreon. Matt Strassler received his Ph.D. in physics from Stanford University. He is currently a writer and a visiting researcher in physics at Harvard University. His research has ranged over a number of topics in theoretical high-energy physics, from the phenomenology of dark matter and the Higgs boson to dualities in gauge theory and string theory. He blogs at Of Particular Significance, and his new book is Waves in an Impossible Sea: How Everyday Life Emerges from the Cosmic Ocean. Web site Google Scholar publications
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Hey everyone, it's Cal Penn.
I'm inviting you to join the best-sounding book club you've ever heard with my podcast, Earsay,
the Audible and I-Heart Audio Book Club.
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audiobook club on the IHeart Radio app or wherever you get your podcasts. Hello everyone. Welcome to
the Mindscape podcast. I'm your host, Sean Carroll. One thing we do a lot here on Mindscape,
or for that matter, I do in my life, otherwise even off the podcast, is to try to explain
difficult concepts in physics to a broad audience, right? Whether it's quantum mechanics,
quantum field theory, relativity, cosmology, what have you, taking these ideas that have been developed by lots of smart people over many years and bringing them to a broader audience, which I think is very important and is absolutely doable if you put the effort into it.
But many people try to do this.
We're not the only ones who try to do this.
And there are a couple of patterns which are kind of bad that many physicists or scientists more broadly fall into when they're trying to explain their concept.
to a broader audience. One is, just from the fact that scientists, physicists, but also other
kinds of scientists or other kinds of academics, for that matter, are typically professors,
they are college professors, and they've developed a pretty good set of techniques for
teaching students who are going to major in that area, right? So physics professors, as part of
their job, will teach young undergraduates and then up to graduate students how to be a physicist. So
they know what steps they have to go through. They've taken the courses themselves, they've taught the
course, or they read the textbook or whatever. There's a set of ideas you have to march through. And one
failure mode, I would say, for reaching out to the public is people try to take that way of teaching
physics, the way that we teach our undergraduates, and just water it down, right? Teach exactly the same
stuff, exactly the same concepts in the same order, but try to remove some of the equations or something
like that. And that's not always the right way to reach a different kind of audience. I've come across
this, of course, in my recent attempts to write the biggest ideas in the universe, where I'm trying
to reach a broad audience with equations, but without any prior exposure to those equations or
those ideas, it's even harder if you're trying to explain without any equations at all. It's really
weird when you just take the usual steps that you would go through in an undergraduate physics
education and demathify them and expect people to understand. Another failure mode is that
sometimes we do search for analogies, stories, metaphors, allegories, pictures, ways of getting
across the basic idea without going into the equations. And it's a little bit easy to forget
that people take these analogies seriously, maybe more seriously than they should, right? When a
physicist presents an analogy for a deep physical concept, they know which aspects of the
analogy actually apply and which do not apply to this situation. And the poor person listening
doesn't know that. So they just take the analogy at face value. So because of these failure modes,
there's an enormous value to be placed on actually stepping back, thinking deeply about the
ideas we want to convey, forgetting about how we teach our undergraduates, to really think
how we should just talk to people who are not going to become physicists down the line,
but I want to understand the ideas. And today's guest, Matt Strassler, is really,
really good at exactly that. Matt is an accomplished physicist, someone I've known for a long time,
but he's put an enormous amount of work. I can vouch for this. I've been talking to Matt for years
about this book that is about to come out called Waves in an Impossible Sea,
how everyday life emerges from the cosmic ocean.
And the cheap way of saying what the book is about is it's about quantum field theory and modern physics.
But the real charm of the book is that he really takes seriously the challenge of talking about these ideas in a way that is as honest and true to the material as possible without just watering down the usual years-long physics.
curriculum, or relying on analogies that give you some good ideas and some bad ideas at the same time.
So it's a novel take on trying to understand these ideas. And we're going to go from basic ideas like
relativity and quantum field theory to maybe some fun research level things, because Matt's a very
good explainer of these things. So it's physics. It's the kind of stuff we talk about all the time,
but maybe with a slightly fresh take on it. So let's go.
Matt Strassler, welcome to the Mindscape Podcast.
Thank you, Sean. It's a pleasure to be here.
So you know, like I do, that a bit over a decade ago, we discovered the Higgs boson.
And I wrote a whole book about the Higgs boson.
I remember this famous story.
And apparently there was a competition, you know, it was inspired by some British government official who didn't understand the Higgs boson.
And so the physicist said, you know, who could come up with the best metaphor?
for what it is. And they came up with this metaphor of people of different levels of fame,
walking through a party. I would start by asking you, like, what was that metaphor? Is it any good,
or does it do more harm than good? Well, the image that was brought to mind by the winner of this
competition has some, you know, it has some general merit to it and that it gives a sense of perhaps
what things might be like in that a person who is totally unknown can just make their way through
the party. Nobody pays any attention. They just have to sort of shove their way through the people
are in their way and that's all there is to it. So that would be your experience in mine.
But if Margaret Thatcher walks into the room, suddenly everybody wants to talk to her. And so she
makes it in a meter or so and then she finds herself stopped. And then she tries to go another few
another few meters and she stopped again.
And so it just takes her a very long time.
She's slowed down by all the people in the room.
And so the image that this particular metaphor is trying to convey is that the Higgs field
is like this substance that fills the room.
And those things that interact with that substance are slowed down and that has to do
with why they have mass.
And is that good?
Well, no.
It's pretty bad, actually.
And again, this is not to criticize the inventors of this metaphor, because they were supposed
to come up with something that fits in a paragraph.
And the fact of the matter is that some aspects of the universe don't fit in a paragraph,
and this is one of them.
But what's unfortunate about this particular metaphor is not merely that,
it doesn't really capture the essence of what's going on, but it actually flies in the face
of an even more important principle of nature.
And that is the relationship between mass and motion.
And if, as this metaphor suggests, you get the idea that, oh, mass has to do with slowing
things down, with obstruction, with obstructing motion.
then your conception of the world ends up back in the Middle Ages.
And you really don't want to end up there.
I mean, they were smart people, but they were very confused.
And we would prefer to avoid that confusion.
Now, what am I talking about here?
What is going wrong with this metaphor is that it contradicts the principle of relativity,
which if you even don't know much physics, you've never taken a class on it, you've never heard much about it,
Violating the principle of relativity sounds like a pretty bad idea, and it is.
And the reason it's such an important principle is that it explains many of the fundamentally
counterintuitive aspects of the basics of being in this world.
For example, why it is that we're all, you know, I'm sitting down, you're sitting down,
both of us feel like we're not going anywhere.
But of course, we are.
The earth is spinning.
The earth is going around the sun.
The sun is going around the galaxy.
And the speeds involved are enormous.
I mean, the earth and sun are going around the galaxy at 150 miles per second.
Now, why don't we feel that?
And why, if the earth has so much mass and this metaphor were right,
why isn't it slowing down?
Right?
this picture of Margaret Thatcher having a lot of mass because she's being slowed down by the
crowd, well, I mean, the Earth has a lot more mass than she does. Why isn't the Higgs field
slowing her, slowing the earth down? And, well, the answer is that the metaphor doesn't work.
And you therefore have to try to find a way back to the principle of relativity to start the
process of explaining what the Higgs field really does. And so that's why the book I've recently
written starts at that place. I do like the fact that you can date the origin of the metaphor so
precisely just by the fact that it was Margaret Thatcher, who they picked as the famous person
who would have trouble walking through the party. Yes, and you can imagine that today it would be
Elon Musk, but he would certainly have trouble. But he's very wealthy, but his mass is not
that big. Well, this is what I like about your book, because of course quantum field theory,
is a mutual interest of ours,
and I think that we both agree that it would be nice
if everyone in the world understood quantum field theory
a little bit better than they do.
If I were to explain it,
I would probably start with quantum mechanics
and then say, okay, what if you do fields to it?
And you take a very different approach,
really starting with relativity and space time and mass
and how those things work.
So tell us what relativity is.
It didn't come from Einstein originally.
It did not.
And indeed, Einstein in a way, saved it more than created it, as we understand it today.
And the person who was perhaps most responsible, although clearly there were other people who were thinking about it, historically was Galileo.
In the 1630s, Galileo wrote a famous passage into one of his texts, in which he explained that if you're on a boat and you're in,
the boat. So the air, the wind isn't blowing in your hair. You're just inside in one of the rooms.
And the boat is moving really steadily. It's not a wavy day. It's just, the boat is just smoothly
moving through the water. You will have no idea that the boat is in motion. You will not be able to
tell how fast it's going or which direction it's going. And he gives lots of examples of things that
you could do to try to check it. You might think that, well, if I, if I drop something and the boat is
moving, then as I drop it, it will move towards the back of the boat. But that's not true.
Maybe you might think the flies in the room will be all pushed to the back of the room,
but that's not true. And when you think it through, he argued, you realize that there's
nothing, absolutely nothing you can do, which would show that you are in motion, as long as that motion
is steady. And he infers from this that the laws of nature.
do not depend in any way on whether you are moving if that motion is steady.
And when you think about it, that's the thin end of the wedge on the question of why you and I
don't feel our motion. And so we go from a situation where even in 1600, 50 years after
Copernicus, really great thinkers like Tycho Brahe, Kepler's boss, could write things down saying
that it's just not possible that the earth is spinning and moving around the sun. That makes no
sense. We would feel it. A heavy body like the earth shouldn't be moving. To the modern day
where we realize that the earth, in fact, is flying through the heavens at extraordinary speed
and doing all sorts of gyrations, and yet we are completely unaware of it here on Earth.
And the explanation for that is Galileo's realization about how motion is a relative
thing. There is no such thing as absolute motion. You can't say in this universe whether you are
moving or not. You can only say how fast you're moving relative to another object.
You and I had a longer than it should have been conversation once about whether the earth
goes around the sun. Or the sun around the earth. Well, or is it up to you because you can
choose coordinate systems? Did you ever personally come down to the right answer in your mind there?
I did. And this is a wonderful question, although it's a question fundamentally about Einstein's
general notion of reality. I know, skipping ahead, but that's okay. It's just a podcast. It's all right.
But I'll give you the short answer. Of course, I wrote about this extensively on my blog,
because I thought, this is such an interesting question. And here you, there are professors at
significant universities who actually argue that, no, you really can't say whether the earth
goes around the sun or vice versa. And the reason that's a mistake, I believe, is that it's not just
about two objects one orbiting the other. You really are asking the question, is the Earth orbiting the
sun subject to gravity? In other words, it's not just a matter about what its path is, but why its path is
the way it is. And you can easily tell that the Earth is going around the sun in sun's gravity and not the
other way around, by simply looking at Kepler's third law of mechanics, which tells you
that the planets have a rule by which their orbital times are related to their orbital distances
from the sun. And the Earth satisfies Kepler's law for the sun, whereas the Earth also has
a Kepler's like law. The moon satisfies it. The space station satisfies it. But the sun
does not. And so in a way, it's as simple as that. Now, you can go into more detail and talk about
the fact that orbits are an entire class of motions and not just the Earth's motion alone
and come up with all sorts of ways of saying this in more technical detail. But in the end, fundamentally,
it's not true that the Sun goes around the Earth gravitationally. And that's really what's at stake here.
The Earth goes around the Sun gravitationally and not the other way around.
Yeah, and so I am one of the people who would disagree with you about this. But of course,
it's interesting precisely because you and I 100% agree on the physics, right? It's just a matter
of how to match up the words in the English language to the physics that we understand.
And that's going to be a theme throughout your book and your attempts to discuss relativity
and quantum mechanics and so forth. Yeah, I mean, I think, you know, just in the sense there's
an even larger issue, which is the fact that scientists could have
on the physics and disagree on the way to talk about the physics, even, you know, colleagues like
you and you and I, is a clear problem for a person who is not an expert, trying to understand
what scientists do know and what scientists are still disagreeing about. And so I think, you know,
for both you and I and for other people who spend a lot of time trying to convey how science
works, the important thing to do is be very clear about what it is we know and about why it
is we are explaining it in the way that we are. So that a non-expert could read what I write
about it and could read what you write about it and come away with the correct impression.
Namely, we're not disagreeing about the math. We're disagreeing about the way to look at the
But that's not in the end what physics is.
Physics is about prediction based on mathematics.
And the fact that you want to talk about it in a different way does not make it a contradiction.
It simply makes it a different perspective on the same thing.
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shows up as we go, but I don't want to leave Gallo behind entirely because I've, I've, I've
made the case most clearly in my book, The Big Picture, to me, the specific idea that motion
just continues on by itself, right? That the natural state of things is for things to keep moving
at a constant velocity. If you want to promote that to conservation of momentum or something like
that, you can. But to me, that is maybe the single biggest realization in the history of science.
because it removes the need for explaining why things are moving, right?
In the Middle Ages point of view, it was weird when things were moving, and you needed a force or a mover to do it,
and post-Galileo and his other predecessors, like Yvesena who set this up, now we can just think of the universe as kind of a mechanism following patterns.
That's right, and there's a very close tie between the...
the law of inertia or whatever, what comes up in physics class as Newton's first law of motion,
although he wasn't the first person to write it down by any means, and Galileo's principle,
that these two are in some sense two sides of the same coin, because what Galileo says is you can't
tell the difference between steady motion and no motion. And so if you believe that if you are stationary,
you will remain stationary unless something does something to you, then it must also be true that
if you're in steady motion, you will remain in steady motion until somebody does something to you.
So they are very closely tied together, these notions.
Did either Galileo or Newton say those words that you just said make that argument?
That's a great question.
I don't know the history enough to know of a precise point at which either one might have said that.
It's something I should maybe look into.
It's an interesting question.
But I don't, you know, of course, the way we learn history is we learn the history of the great thinkers.
But there are always smaller personalities who have certain insights and write certain things down.
And so to trace that back and find out, you know, which one or which set of people first have these insights would be a real challenge for even for a historian of science since we're talking several hundred years ago.
But it's probably known to the experts in that field.
So we're already coming up across something, even at this pretty easy to understand
level of what Galileo was talking about, but something that's nevertheless pretty non-intuitive,
right? The idea that there is no universal standard of rest. There is no way to just say,
here is the speed of something full stop. This is going to be something we've got to continue
to fight against all the way up through modern physics, right? Absolutely. It goes, I mean,
it's a fascinating thing that we teach physics to college students. And this is almost the first
thing we teach them. And in the classes that, in the class where I was taught, and in the classes
where I've been expected to teach, the idea is you teach Newton's first law, maybe in the first
week or maybe in the second week, and then you move on without grappling with the fact that
this is a remarkably counterintuitive notion. We never see this.
experience this in ordinary life. Anything that we want to move, we typically have to, you know,
keep it moving. Cars need engines, planes need engines. We have to keep pushing, you know,
walking tires us out. We can't just sort of glide down a highway without doing anything.
And that's because friction and other forms of drag are ubiquitous in a world on the earth.
And so we grow up in an environment and we have an intuition that motion requires activity.
But it's only by understanding that motion does not require activity that we can understand astronomy,
that we can understand why the Earth does what it does and the moon does what it does.
And so, again, this is why astronomy was so counterintuitive and took so many hundreds, thousands of years to understand.
So, so, yes, this is a profoundly counterintuitive notion.
And we don't fundamentally know why it should be true, why it has to be true.
We just have experimental evidence that makes it seem that it appears that it's true throughout the universe.
And yet, and this is in some sense where we get into the really interesting aspects of modern physics, it almost broke down.
It was on the verge of breaking down when people tried to understand what light is.
And we're going to get to that.
Okay, good.
Yeah.
No, that's, it is, it's always a back and forth, right?
Like one generation's precious principle that we can't violate is another one's, you know, antiquated relic that we have to overcome.
Absolutely.
And speaking of which, you know, a topic that you go into great detail in the book, you've mentioned
Newton's first law, then there's, which says that we're going to go in straight lines if you don't
act on us with a force. But the second law, that's where Newton really made his money, right?
That's F equals M.A. That's what made modern physics possible. And there's all three of those
symbols, F and M and A, are kind of interesting. But let's talk about M. What is that parameter that
appears in Newton's law? Was he the first to talk about that? Where did it come from?
Well, in a way, it has a long complex history like most concepts, but the original confusion about what we now call mass is its conflation with the concept of weight.
And before Newton, people assumed these two concepts were essentially the same, as far as I understand.
And Newton was the first to realize, no, you have to separate them.
And to talk about it in modern language rather than try to confuse ourselves with the way people
used to think about it, mass is a property that tells you how hard it is to change in object's
motion.
Now, again, this is in contrast to that Higgs metaphor and Margaret Thatcher that we started with,
which suggests that mass is about how quickly things slow down.
It's quite the reverse.
Things will continue in a straight line unless you do something to them.
and mass is how hard it is to change something's direction or slow something down or speed it up.
And so that is an aspect of an object which reflects not its motion, but in some sense it's stubbornness
that prevents change in motion.
Now, what is weight?
Weight is how heavy an object is, literally, how hard it is to hold an object up against the pull of gravity.
And on Earth, these two things are completely connected to each other.
The more mass an object has, the more weight it has.
And so it was natural for people living on Earth and never having gone anywhere else
and never really having thought that hard about anyplace else to imagine these were the same thing.
But Newton's key recognition was this couldn't be true if there was some way to understand
the moon's motion in terms of gravity or the planets in terms of gravity. It had to be that weight
for something that's far enough away would be smaller, even though its mass remained the same.
So the moon has an enormous mass, but its weight, that is to say, the degree to which it is
pulled by the Earth's gravity is much smaller than you would imagine if you thought mass and weight
were the same thing. So, and, you know, we, we carry.
this conflation of mass and weight with us wherever we go. That's why we're always interested in,
you know, watching our weight and keeping our weight under control. Whereas in fact, if you just
wanted to lose weight, you could go to the moon. But I don't think your body shape would change at all.
So one should keep in mind that one really wants to lose his mass. And I'm kind of surprised that
physics teachers don't sort of teach this right at the beginning of the section on gravity.
But it seems an obvious point to make that we conflate these two ideas, but we're, we conflate these two
ideas, but to understand modern physics, even to understand Newtonian physics, you have to first
pull these ideas apart.
And what's interesting about that is that you need to bring in gravity into the discussion.
And I think that, you know, from the Ask Me Anything questions I get for the podcast, etc,
I think that this is a very natural confusion that people have.
Like, is mass somehow intrinsically linked to the idea of gravity, or is it something
separate?
And the answer is implicit in what you said, but let's make it explicit.
Well, it's even, it is, but it's a little subtle too, which is that when we get to Einstein,
we're even going to have to keep track of the fact that what you mean by mass is ambiguous if you're not careful.
Yeah. But at the time of Newton, the idea was that mass has to do with motion, as we just described,
has to do with preventing changes or getting in the way of changes of motion.
But it also, for some reason that Newton did not understand, has to do with gravity.
in that the force between two objects involves the multiplying their two masses together.
And the more mass things have, the more gravity they inflict on other things.
What we know today is that the chain of logic linking those different types of,
those different aspects of mass, is more complicated.
And that, in fact, gravity comes from energy and momentum,
and not directly from what we would call rest mass, which is the type of mass that affects motion
in the simplest sense.
And also, most importantly, the type of mass called rest mass is what appears in Einstein's
most famous formula, E equals MC squared, interpreted as saying that the mass of an object
that's at rest, that's stationary, has to do with the amount of energy that's inside it.
So what Einstein does, he says, well, look, mass, at least rest mass, the mass of a stationary object, comes from its energy.
And separately, gravity is an effect that comes from energy.
So when you put those two things together, in simple situations, you get Newton's notion that gravity comes from mass,
because gravity comes from energy and mass is a form of energy.
But when you pull them apart, you get the much more varied and much richer notion of what gravity can do that you know better than I in the context of general relativity and Einstein's theory of gravity.
And speaking of Einstein's theory of gravity, he was led to his insights in part because of the principle of equivalence, which people give credit to Einstein for.
But Newton noticed a version of the principle of equivalence, right?
Sure, in the sense that all objects, already, just from the start, all objects fall to the earth at the same rate.
In a way, even Galileo knew this, and Newton in a way gave it an explanation because he noted that the acceleration of an object is related to the force on it divided by its mass.
And in gravity, the force on it is proportional to its mass.
And so in the acceleration, the mass cancels out.
There's a mass in the numerator.
There's a mass in the denominator.
So acceleration is the same for all objects falling on the earth.
And so that means that if I take a little paperclip and I take a heavy book and I drop them at the same time, they land at the same time.
And if you haven't ever seen this yourself, try it.
It's amazing how many people sort of know this but have never actually tried to drop something really light and something really heavy,
making sure that that very light thing isn't affected by air resistance.
And in that case, you'll really see it's as though it looks like magic.
And it is, in a way, a sort of magic, because it's what leads to Einstein's conception that gravity could be an aspect of the geometry of space and time rather than some just generalized force. It has some very special properties.
Well, I think that's why Newton maybe didn't explain it as completely as Einstein did, right? I mean, yes, Newton noticed that the parameter mass that appears in his second law,
and the parameter mass that appears in the law of gravity are the same parameter. But why are they
the same parameter was a little bit unclear? And that was kind of mysterious. I'm not sure
that Einstein does completely explain it. He accounts for it. It is a true fact in general relativity.
But if someone just sat back and said, did it have to be that way? I'm not even sure what the
right answer is. Well, that's a really good question, because in a way, there is an explanation that
comes out of quantum field theory, if you accept that gravity comes from a gravitational field
that is associated with what a particle physicist would call a particle of spin two.
And what's interesting about that is in Einstein's theory, yes, there is an association of
gravity with a field with certain properties such that it's particle.
have spin two. And then it does follow from mathematical consistency that you must be able to
interpret space and time in terms of, interpret gravity in terms of the geometry of space and time.
But one thing that's often forgotten, although again, people like you know this very well,
is that there was a competing theory of gravity at that time by a fellow named Nordstrom.
And in Nordstrom's theory, instead of spin two, there was a spin zero. There was a spin zero.
object, and it was a perfectly good theory.
But it would not have had, in retrospect, the mathematics would not have required it to have
the properties that Einstein wanted it to have.
Whereas with a spin-two field, you are sort of forced into it by the math.
That's not something Einstein knew at the time.
That was something that was learned later.
So in a way, Einstein got lucky.
He had some principles.
they led to a particular theory, it turns out that there weren't many options beyond the one he came up with
that would be mathematically consistent. But at the time, like any good theorist, he had some principles he was working with,
and it led him to an answer, but it wasn't obvious that it was the correct answer. That depended on experiment.
I think that the idea of thinking of gravity is arising from a spin-two particle is a really fun and important one, and we should talk about it again, but we have to eat our vegetables a little bit first and work our way up.
So let's just remind ourselves what happened to the poor principle of relativity. I mean, Galileo put it out there. Newton had a theory that embodied it, but then something happened with electricity and magnetism, and the world was never the same.
Yes, in a way, I mean, we could certainly talk about electricity and magnetism in their details,
but in a way the problem is even deeper, which is that, which is the simple observation that light somehow makes it across the universe.
Light can travel a very long distance, and it doesn't lose its oomph.
It clearly maintains its color, its frequency as it goes.
somehow, you know, it has this property that somehow it can travel through the universe itself. And
if you think light is just a bunch of particles, as Newton did, that might not be so surprising.
If the universe is mostly empty and you're sending bullets through it, well, the bullets will
just keep going, according to Newton's first law. Yeah. Nothing there to stop them or slow them down.
But there was a debate for two centuries as to whether light was a wave or made of particles. And
Then around 1800, there was definitive evidence from interference effects that, no, light is really a wave.
And now we hit a puzzle, a very serious puzzle.
Because, you know, sound waves are waves in air.
They don't go through the universe.
Why not?
Because there's no air there.
A sound wave is a vibration of the air.
If there's no air, there's no sound waves.
Same idea if you go to the beach, right?
the ocean waves come to the beach, and they stop. They don't keep going because there's no
war. So if light waves can go through the universe, there must be something out there.
There must be a thing you would naturally think that is vibrating in which the waves are a vibration.
So what is this thing? And why doesn't it slow the earth down?
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like the value of the family,
the importance of the job,
and that the 99% of the people
of more of 50
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So we hit a puzzle.
Don't keep a saying here, Matt.
Tell us what the answer is.
Well, I mean, at a certain level, we don't entirely know the answer.
What Einstein did was point out that, well, let me back up one step.
Sure.
The point that seems obvious is even if you're confused about what this stuff is, you should be able
to measure whether you're moving through it or not. For example, if you're in a boat, you can easily tell if you're
moving through the water or not. If you turn off your engine, if you're moving through the water,
you will very quickly slow down. And although Galileo says you can't measure whether you're
moving in a steady motion, if you're slowing down, you certainly feel that. So, same thing for a plane
that's flying through the air.
If it were stationary, it would be doing one thing.
And if it's flying through the air without an engine, it's going to slow down and so forth.
So you can tell whether you are in motion and how you are in motion with respect to ordinary
substances.
So the basic idea was we ought to be able to tell if we're moving through this magical substance,
which was called the Luminiferous Ether, a name, which has got lovely resonances to it.
It's a great name compared to a lot of other dumb names physicists came up with.
Such a shame.
Too bad it doesn't exist.
I know.
maybe it is. We'll come back to that. But in any case, the idea was, all right, there should be
some measurement we can make that can tell us something about this substance in which light is a wave.
And in the 1880s, the right technology came along. And that was invented by Albert Michelson,
who, along with Edmund Morley, built a machine, a device that could very accurately measure the speed
light in different directions. And if you think about it, if you're moving through the water
and you're looking at ocean waves, ocean waves that are going in the same direction that you're going
will seem relative to your boat to move more slowly than ocean waves going the other direction.
And so it was a similar idea that Michelson had in mind that you should be able to tell
that light moves at different speeds relative to this medium depending on how fast the earth is going
through the medium. And of course, the earth goes in different directions every, you know, as it goes
around the sun. So if you measure this a few times a year, you measure this in different direction,
you should be able to tell a difference. And famously, Michelson and Morley saw no difference at all.
The speed of light seemed to be the same from all directions at all times.
And that seems to be in contradiction with the idea that there's a substance in which light
is a wave. Now, this is where we come back to Galileo. Because if it had been true,
that Michelson's experiment had worked. If it were possible to tell how fast the Earth were moving
through this luminiferous ether, then it would not be true that all types of steady motion
are the same. There would be experiments that you could do, even in a closed room, even under the deck
of a ship, as Galileo suggested. It would be experiments you could do. You could do Michael's
experiment and tell how fast you are moving through the ether.
But since the ether apparently is everywhere in space, after all, light goes through
the universe from all directions and from many places, then you would conclude that Galileo's
idea, although it might apply to some things, is not fundamentally correct.
And so, Michelson's experiment had it shown a difference in the speeds of light from different
directions would have been the death knell for Galileo's relativity. So now came a brief period of
25 years where people tried to explain what does Michelson's experiment mean? Why can't we detect
this thing? And there were various ideas which we don't have to go into, but all of them would
still have violated Galileo's relativity. And then Einstein pointed out, as a 26-year-old student,
that actually, if you insist that Galileo's relativity is correct,
and you relinquish your notions of space and time as you always thought they worked,
you can write down math that can both explain why light travels as a wave,
a particular a wave of the electromagnetic fields,
and yet can travel from your perspective at the same speed from all directions,
independently of how you are moving or the object that's emitting the light is moving.
And that was an extraordinary thing to point out.
That's obviously one of the great ideas in scientific history because it put, but it showed
the only way to reconcile light's amazing ability to travel the universe is to give up your
notions how space and time work.
It seems like a big ask, but it paid off.
It's a huge ask.
And needless to say, people were curious, interested, but very skeptical.
But in the end, it doesn't matter what people think.
It matters what experiment says.
Experiments said these ideas are correct.
You make the case very nicely that Einstein's insight here really wasn't the word
relativity in any sense at all.
Relativity was already there.
And then there was this experimental idea that.
the speed of light was constant to everyone. He figured out how to reconcile those two amazing facts
that sound innocuous together, but kind of have tension between them. Yeah, that's right. Einstein's
theory of relativity is not the invention of the idea of relativity. It is a revision of the idea of
relativity as Galileo had it, because Galileo didn't worry about time. Gallo just worried about how
things move, but he assumed time is just time. Sure. And Einstein is now already
even before general relativity, starting to make us wonder how we should think about time and what
it means if everybody who's moving around has a different clock than the notion of simultaneity
and the notion of synchronized clocks, it's all starting to come at risk. And general relativity
tears it all apart. Well, I got a question recently. Why don't people consider special relativity
as one of the great triumphs of unification of physics
because it unified space and time together.
And my result, my answer was like, what do you mean?
I always talk about it that way.
That's exactly what it was.
And many other unifications came with it.
This is where we can now finally talk about
E equals MC squared
and how mass and energy are related to each other.
Even in some sense,
the unification of electricity and magnetism,
which I think fairly can be attributed to Maxwell,
there is a way in which that unification becomes not only true but necessary once you have Einstein's
understanding of how it works. You simply can't talk about one without the other because what is
electric from one person's point of view can be part electric, part magnetic from another person's
point of view, and that's deeply integrated into the math of the theory.
And we're left with a picture where, I mean, eventually Einstein events general relativity.
We don't need to go into great details about that.
But it leaves us hanging a little bit with this issue of whether space or space time, if you want, is a medium by itself, right?
It's not the ether.
We can't measure our velocity with respect to it, but it's something.
It has a geometry, et cetera.
How are we supposed to think about space and space time?
Well, I think that remains one of the great questions of modern physics today, in the sense that, as you, as you, as you,
just to say what you said, but in a slightly different way,
there is a fundamental tension that still remains conceptually.
It's not a tension in the mathematics,
but it's tension in how we think about it.
In that we know today that, thanks to Einstein,
that space and time somehow thought of together,
they're kind of like a fabric in that they can stretch
in the expanding universe, that's what's happening,
They can warp.
That's what gives us gravity.
They can ripple.
That's what gives us gravitational waves,
which are the subject of a Nobel Prize just in the last few years.
And yet, this fact that we can't measure this substance, whatever it is,
we can't measure whether we're moving through it or not, because that would violate Galileo's principle.
Yeah.
So to say it again, space is sort of a thing.
It does stuff.
but we are not able to measure whether we are moving through it.
And more generally, we're not able to measure its presence or it's, we can see some of the things it does,
and yet we can't see kind of what it is.
We can't grab hold of it or bottle it.
It's not like a substance the way water is a substance or like any other substance we're used to.
And so this conflict between a substance-like thing which acts like it's there
and this thing which sometimes acts like it's nothingness, that fundamental.
conflict is a deep conceptual conflict for our brains, the math is okay with it, but it's such a
deep problem that it might even make you wonder whether space is real. Good. Go ahead.
And physicists do really wonder about this. I mean, this is an active area of research. There are
various reasons for that, which are kind of another discussion. But certainly we live in a universe
whose basic fundamental properties are very strange, strange enough that we should certainly worry
that maybe there's another level of understanding behind them that we have yet to encounter.
I'm really glad that you put it that way, because it's very honest.
You know, you weren't trying to claim more certainty than we have, which some people will
sometimes try to do.
And also, you know, I personally, at the research level, am increasingly sympathetic to notions
where this lack of a rest frame, right, what we call Lorenzen variance in the technical
lingo, is only an approximation, that in fact, you know, it comes out in the wash,
at long wavelengths, low energies, things like that, like many other things do, but maybe
it's actually not a fundamental feature of the universe. I'm not wedded to that idea,
but I think it's absolutely on the table as a possibility and a very exciting one,
both theoretically and experimentally. Yeah, I mean, I think, you know, we, we, I, I think, I
I've written this book as though we're sure about Galileo's principle of relativity.
But of course, there are no principles about which we are sure.
They're always subject to experimental verification at more and more precise levels as our technology improves.
And it's always possible that something we have held as almost certainly true for hundreds of years may fall apart at some point, just as Newton's Law of Gravity did after more than 200 years.
So we have to be humble about what we do and don't understand.
But there is also the possibility that even the notion of space is an approximation to something far stranger.
And those people who think about quantum gravity along certain modern lines face that because we have found equations, not necessarily the equations that describe our universe, but we have found equations in which space is.
is an epithenomenon, an emergent concept.
And the basic thing you start with is just a very large collection of objects that don't
have any notion of space at all.
So, you know, there's a lot that we know.
We know there's a lot we don't know.
And any particular way of looking at the world that we have now has to be viewed as a
progress report, a very successful progress report at the moment, but one which has plenty
of holes in it that could turn out to be quite large in the end.
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When getting to the 50,
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Good, but this question of the realness of space, the thinginess of space, I don't know if you know,
do you know about the Clark Leibniz correspondence?
Have you heard these words before?
Yes.
You and I have spoken about this, and I recall it.
Clark, you read about them in my book, because you were a reader.
And Leibniz and Newton arguing for Clark, yes.
Is space relational or substantival?
Is it a thing, or is it just a collection of relations?
And we still don't know.
Like, in Einstein's world, it was a substance, but maybe we're post-Einstein now.
Another fact to keep in the back of our minds when we're contemplating that question is that space isn't really empty or it's not featureless anyway because it's filled with all these fields like the electromagnetic field.
So you do a great job in your book talking about what a field is, the idea of the fundamentals of fields, which is very bizarre to people, right?
Like they always want to know what the fields are made of.
And I got to say, like, no, no, no.
The things are made of fields, not the other way around.
Right. And, you know, part of the problem about, part of the problem with talking about fields and what they are is that fundamentally we don't know. It's always harder to explain something you don't really understand. We understand what fields do with remarkable precision in many cases. We have math that describes what they will do in all sorts of circumstances. We can predict all sorts of wonderful details. But just because you can predict what something does doesn't mean you really understand fundamentally what it is.
is. And an analogy I like to use that I think is reflective of the right way to think about fields
is that if you think about the atmosphere, just think about the air of the earth, it has all
sorts of features that you can measure. It has pressure, it has temperature, it has wind,
wind meaning how fast it's flowing in a particular location. And these things, pressure, temperature,
wind, humidity, these are properties of the air that you can measure anywhere.
There's some machine you can use for measuring the wind speed and direction, et cetera, et cetera.
But imagine that you didn't know what air was.
And all you had was these measuring devices.
You could measure this thing, which you call pressure, but you don't have the conception
that it is literally the pressure of a gas.
You just call it P.
And you measure this thing called T.
It's temperature, but you don't know that.
And something called W, which is wind, but you don't know that.
So you have these things you can measure.
And you can figure out equations which describe how they work.
And you can even predict the weather if you're clever enough to figure out the right equations.
Because the equations stand on their own.
They tell you how these things you can measure change over time and how they relate to each other.
But if you don't know what error is or even necessarily that it exists, then you don't know what pressure, how to think about pressure.
You don't know what property of error it's referring to.
And since you don't even know what error is, you can't even sort of talk about what property it might be.
And this may be our situation with the fields of the universe, where the vast majority of the fields, with one interesting exception, that I'll come back to, they seem to be properties of the universe, the way pressure is a property of error.
That might be the right way to think about them.
but we have no idea which properties and we have no idea what the substance of the universe is.
And the one interesting exception is gravity, which is ironic because in many ways, gravity is the one we understand the least from the point of view of quantum physics.
But in the case of gravity, the gravitational field is telling you about the property of space, which we call curvature, the degree to which it's warped.
So it is possible that the electromagnetic field is telling us some property of space and time that is not obvious,
some sort of hidden property that we have yet to learn.
In string theory, for example, that's a common situation, not to put, not to say anything pro or con against string theory,
but it is an example of a context in which the luminiferous ether does exist.
exist. It's a part of space time. And so it may be that this notion that space and time are a substance
that has many properties and those properties are the fields of nature, that may be a perspective,
which is at least useful and maybe even somewhat fundamental. But we still have to deal with the
fact that space is very strange because you can't measure your motion with respect to it. So if it's like
a material, it's not like anything we've ever seen. I just want to be sure.
Because the audience has different levels of understanding here, if we put aside for the moment
our desires to be super-duper careful and clear and correct, what is a field?
A field is something that is found.
Well, let me back up one step.
A cosmic field, the field of the cosmos, is something that can be measured anywhere in the universe.
It's some sort of property which has to be.
the feature that if you change it in one place, it has effects in other places in the future.
In some sense, that's the most important aspect of what a field is. It's something which is everywhere,
and it's not just randomly everywhere. It has this feature that it's somehow what you do
at point A affects later what happens at point B and vice versa. So in the context of air as an
analogy. The fields of air are found everywhere in the air. And if you change the wind in one place,
it's going to cause the wind to change somewhere else. And in fact, that's what weather prediction is
all about. It's about saying, okay, I know what the fields of air are today. I know what the pressure
and the temperature and the wind are right now. Can I predict in the future what they will be?
and the fact that the future depends in such detail on the past, and not just on the past at my current location,
but on the past at all locations nearby.
And the further back in time I go for my predictions, the more of these fields I need to know and further, further distances.
This is what's characteristic of a field.
So if you think about weather prediction and about the properties of the air and how they affect each other,
and now you extend that to properties of the universe,
now you're thinking about fields, I think, in a sensible way.
Okay, that's very good.
And if we were to add quantum mechanics to the mix, there's this wonderful fact that,
and we don't need to talk about many worlds or measurement problem, that's okay, that's a different podcast.
But we should talk about the fact that when you quantize a field, when you take fields and put them into your quantum mechanical brain, out pop particles.
I don't know if you want to just take that for granted right now, or do you have a favorite way of thinking about that remark?
Well, I think it's useful maybe to step back a moment. Obviously, the purpose of, I should say something about the reason why the book that I've just written is called Waves in an Impossible Sea. We've just been talking about the sea, that's the universe, and we've been talking about why it's impossible because it has these very strange features that it both seems to be there and seems not to be there, depending on what question you ask.
But then there are the waves.
And the reason to talk about waves is that fundamentally, the things we call elementary
particles, electrons, quarks, photons, they are in the language of quantum field theory
more wave-like than particle-like.
And to understand what that means requires dealing with the fact that there's a history
to the notion that electrons are both particles and waves.
That's a trope that comes out of the 1920s and 30s,
but it's one that got modified over the decades
and in ways that aren't always made explicit.
It's a mess.
And the word particle and the word field are, again, misleading
in how we use them compared to how they're used in daily English.
And so one has to really take a moment.
to just parse all that.
So with that preamble, let me start.
So when we talk about particle in ordinary English, we always mean something like a
grain of sand or a dust particle.
Something that's like a little ball, maybe irregular shaped, but you can, you know,
it's this little thing that moves around on some path.
Yeah.
And when people first discovered electrons, that's what they thought they were.
So they called them particles.
And when it turned out that's not what they were, they still called them particles.
So we often face this problem in science and science communication that things are named before they are understood.
And very rarely are they renamed once it becomes clear what's actually going on.
Very true.
That's a problem.
So there's that problem.
We have to first take the word particle and understand that we're not going to be
use it the way our English conception of particle is used in ordinary language. And then wave is a
problem too. When we say light is a wave, we do not mean that light is like a wave breaking at the
beach. At the beach, we mean, you know, here comes a big wave. What we mean is here is a high point
in the water separated from the next high point by a low point behind it and a low point in front.
whereas when we talk about sound waves coming from a musical instrument or from somebody's voice
or we talk about light waves coming from a light bulb, we're talking about a long sequence of high and
low points, a long sequence of wave crests and wave troughs, which we often call in ordinary
English, if we were at the beach, we would call it a wave set or a series of waves.
So what we mean by wave singular in physics may have many crests.
and troughs, which is not the way we would talk about things at the beach.
Good.
So that's important because when we say light is made from particles,
I don't want you to think about the individual particles as being individual crests in a wave train.
That's the wrong picture.
Okay, I won't.
So now, how do we understand that we are made from waves?
This is a very strange thing, again, to, to, it's such a strange thing that took people a long time to make sense of it, because we from ordinary life have a lot of intuition about waves.
And we have all seen houses made of bricks and made from stones and made from concrete.
But you have never seen a house made from sound waves.
You've never seen a house made from earthquake waves.
Waves are not things that we think of as objects from which you can make.
structured objects that will stay together and stay organized for, you know, centuries.
And so the idea that we and, you know, the walls and the table and so forth are made from
waves, where requires already some sort of conceptual leap. And the conceptual leap is that,
and again, it's due to Einstein, although not in a single step, is that even the ways of light,
which are definitely waves in the sense that there are crests and troughs,
these things have a frequency and a wavelength, just like sound waves do.
Nevertheless, they are made from, well, we call them particles.
Let's not call them particles.
Let's just say they're made from things.
We'll call them photons.
And now let's figure out what they are.
And so the way I like to talk about this that I think is useful is that we have
many examples of objects that we know are kind of granular or particulate, but not in the sense
that they're made from particles per se. So, yes, if you go to a beach, it looks continuous,
but if you look closely, there's all sorts of sand grains that make it up. In that case,
the objects are really particles of sand. But, you know, if you take a giant pile of spaghetti,
dried spaghetti before you cook it, well, if you look at it from far enough away, it just look
like a giant pile. But if you go in there and dig around, you realize, you know, there's
lots of individual strands of spaghetti there.
Or if you take a giant stack of paper,
you've never seen one before,
it may not be obvious to you whether it's continuous or discrete,
whether it's, whether, you know, what it's made of.
But if you start taking it apart, you will very quickly realize
it's made from sheets of paper.
And so when we look at a laser beam,
it is not obvious to us that it isn't a continuous thing.
And then, in fact, it's made from individual strands.
in a sense. The way a rope is made from individual strands of twine, it's not that it's made
literally from particle-like objects, but it can be disassembled into individual pieces.
And those pieces of a light wave, again, they're not individual crests and troughs.
Each one of them is a series of crests and troughs. And we call those things photons.
So photons are waves, but they are particulate.
They cannot be divided into smaller pieces, and they are the things out of which more dramatic waves, like those in a laser beam, are constructed.
And this is far from obvious, just as it would not be obvious to a person seeing a rope for the first time, that you could disassemble the rope into individual strands.
And that's why people before the 20th century didn't have, it wasn't obvious to people before the 20th century that this was true.
You needed the technology, and you also needed the right set of experiments to give you a clue that this is something that might be the case.
And this is a specifically quantum mechanical aspect of light.
Maxwell's equations did a perfectly good job of talking about light waves in a classical way,
and this photon language only becomes relevant once quantum mechanics comes on the scene.
In a way, you can say it's the definition of the first aspect of quantum physics.
The statement that light is made from photons is a more general statement that there are large
classes of waves in our universe, and in particular, all of the waves of the elementary fields of the
universe are made from these individual pieces, which are called, generally, quanta.
That's where the word quantum initially comes from historically.
Is Einstein trying to suggest that light is made from these individual strands or packets
or whatever you want to call them?
And it was only 15 to 20 years later that people gave these bits of light the name photon
and even five years after that, that they realized that there was an analogy between photons
and electrons.
That electrons were not actually these dot-like points.
particles, the ones we draw in the cartoon of atoms, but they're more like photons. They have
wave-like properties. They are particulate waves, rather than being particles in the English sense.
And so this is really the language of quantum field theory that comes out of the 1950s,
and it's different from the language of the quantum mechanics physicists of the 1920s and 30s,
whose famous statements such as an electron is both a wave and a particle, or sometimes it's a wave
and sometimes it's a particle, that's a language which Niels Bohr popularized, but it was left in
the historical dust as far as the math.
Yeah.
And yet, it maintained a life of its own in the culture.
So most people who teach quantum physics still use this language when they teach quantum mechanics
to juniors in college. And it certainly has survived in most of the popular science books.
So that causes a lot of confusion. And that's one of the reasons why in my book I spent a whole
chapter trying to make this really clear that we don't think about an electron as a dot.
And in fact, you can't understand its most critical properties, such as the fact that it has mass
if you think of it as a dot.
Because if it's really a dot,
and it's really true that E equals MC squared,
and therefore the mass of the electron has something to do
with the energy that it carries with it,
when it's stationary,
well, why would a stationary dot have energy?
Especially if it's really a point-like object in some sense,
where would that energy be?
But when you understand an electron,
even an electron that is stationary
is a wave-like object
and like the wave on a guitar string,
it is vibrating and is sitting in place.
It's not going anywhere,
but nevertheless there is vibration associated with it.
Then you understand, ah,
there's energy associated with the vibration.
And that's where the mass comes from.
And if you thought of an electron as a dot just sitting there,
instead of thinking of it as a wave that's vibrating,
you have no way into this idea.
And that's why it's so important
that in quantum field theory,
we do not think about electrons as dots,
and we do have an understanding
of what their mass is associated with.
Not to mention the fact that,
at least at face value,
a dot-like electron would collapse to be a black hole.
Well, there is that problem, too,
but I think it's useful to understand
that this particular problem
is independent of gravity.
Sure.
And would be there even in the absence of gravity.
So while it's certainly true that point-like objects without some sort of wave-like structure
have all sorts of conceptual issues associated with them, there's an independent sort of conceptual
problem, which is that if you carry this notion of a dot-like electron with you too far,
even if you take bore seriously that some of the time it's like a particle and some of the time it's like a wave,
You've lost the fact that its wave-like property, the fact that it's a vibrating object is essential in its existence.
And its basic properties, such as its mass, simply are not explicable if you somehow try to make that point-like object work in your head.
It doesn't work.
And we see this in these fundamental properties of electrons and all the other elementary particles, too.
For the listeners who have followed us this far into the podcast, we're allowed to get a little more technical and wild here.
So I'm going to fearlessly ask you about the difference between electron fields and photon fields.
Right.
We have our fermions and our bosons, and they're fundamentally different kinds of fields, and that contributes to why conceptually we tend to think of matter and,
and light as two different kinds of things.
Right, and of course you and I have, well, the word matter is another one of those words that
is really problematic.
I'm just throwing it out just because I know you'll get a rise out of you.
Yeah, you went there, the target was right on.
But let's just talk about atoms and light.
And there is this, as you said, this remark.
feature of our world that is not to be taken for granted. You have to work out in mathematics
of quantum fields to show that there's only two types of fields, or rather you can divide
all of the fields that could possibly be part of our cosmos into two classes. One of those classes
is called bosonic fields, the other class is called fermionic fields, the particles, that is to say,
these waves that are the minimal waves that you can have in the electromagnetic field that we call
photons, they are bosons, then there is an electron field, not to be confused with the electric
field, there is an electron field that is fermionic, and its minimal waves are what we call electrons.
And all of the different elementary particles of nature can be understood. Each one is a wave
of a particular field, and each field has to be either bosonic or fermionic, and each particle
has to either be a boson or a fermion.
Now, what's the key difference?
The key difference, we already learned some of it in undergraduate chemistry.
Electrons cannot do the same thing at the same time.
No two electrons can do identical things.
This is known as the Powley Exclusion Principle, and it was discovered as people tried to understand
the properties of atoms back in the 1920s.
And the whole structure of atoms would be completely different if electrons were bosons.
Because bosons don't have an exclusion principle.
In fact, they are perfectly happy to do exactly the same thing.
And that's why lasers can be made out of photons.
So you couldn't make atoms like ours if electrons were bosons instead of fermions.
And you couldn't make lasers out of light if light was made from fermions.
So these are very obvious differences, but the degree to which they affect our macroscopic experience
is a little less obvious.
And so one of the remarkable things is that if electrons were bosons, not only would atomic
structure be very different.
But if you tried now to pile a large number of atoms together, instead of forming
crystals or blocky structures that you could make tables and microphones and people out of,
they would just sort of collapse in on themselves.
And so the very basics of the macroscopic world depend on the fact that electrons are fermions.
But they also depend on something else because the powerly exclusion principle would not
apply if electrons weren't literally identical.
and why are electrons literally identical?
Well, that is one of the key predictions of quantum field theory.
If electrons were just dots, we would have no idea why they are identical.
But they are waves in a field, and it's the same field, right?
There's just one electron field.
And the minimal wave in an electron field is an electron, and it doesn't matter where you make it,
It doesn't matter when you make it.
It doesn't matter how long it's been around for.
It remains a minimal wave of the electron field.
And so any two electrons, they're the same type of thing.
They are literally identical.
And because of that, the Powell Exclusion principle can apply to them.
And because of that, our world can have macroscopic objects in it that don't collapse.
And it's really important and fascinating to me in the context of quantum field theory
that you have your electrons, you have your electromagnetic field,
but there's not an infinite variety of possible kinds of fields, right?
There's kind of a tiny handful, and essentially almost all the ones that we think are possible
are there between gravity and Higgs and electromagnetism and other force fields and electrons and so forth.
Like, it's a really limited set to draw from.
Well, this is an interesting, an interesting feature of the, of the discourse.
that physicists on the theoretical side and mathematical physicists have made about how quantum field
theory can work. When you go into a subject which has some mathematical content like physics,
you could wonder whether the world that you see is just one example of possible worlds.
Maybe there's an enormous number and you're living in just one for some reason. Or you can
maybe there's only one possible world that's consistent with quantum field theory or with
quantum field theory and gravity together. And we live in it because there's simply no other type of
world that you could have. And the reality turns out to be somewhere in between. It's remarkable
how many mathematical constraints there are. When you try to combine quantum physics
and special relativity, that is say, pre-gravity.
And then when you try to combine it with gravity as well, you find that the mathematics
is somewhat rigid.
You can't do anything you want.
You can only do a relatively limited set of things.
It's still a very big set, but it's a lot smaller than you might have thought.
And on your point that there's a limited set of types of fields, that's true with a caveat,
which is that this assumes that the fields have particles either whose mass is zero or that come from,
their masses come from a limited set of possibilities. Once you allow there to be, once you allow
for particles that have, that get their mass any old way, you have a wider set of possibilities.
But experimentally, we find that all of the particles that we know of so far, with one exception,
either don't have any, their particles either don't have any mass, like the photon, or if they do
have mass, like the electron, they get it in a very special way. And that's from this strange substance
called the Higgs field that we started our discussion with. So it is true that once you know
experimentally that there are some limits to the types of fields we find in nature, then you find
that the possibilities are very limited indeed. And so it's some mix of theory and experimentally.
that tell us that we're in this strangely, or maybe not strangely, limited situation.
Well, let's close the circle here by getting the Higgs boson right, because I think that,
as we discussed with, you know, people with the best of intentions, physicists try to explain things,
and they smooth over some rough edges, and they say, the Higgs field is responsible for mass.
And I get very well-intentioned members of the general public saying, well, mass creates
gravity. So without gravity, would there be no Higgs field, or is the Higgs responsible for gravity or
something like that? Hopefully, everyone who's been following along with what you've said so far
knows why that's not right, but let's help them out a little bit. Well, indeed, it's a natural
confusion to have if you think that the Higgs field is responsible for mass. But that is not
correct. In fact, the Higgs field is not responsible for most of your mass, and mine. Because
protons and neutrons, which are the majority of the mass in an...
atom do not get their mass from the Higgs field.
So we can dispense with that idea.
The Higgs field is responsible for the mass of certain elementary particles, but it's not
responsible for the mass of protons and neutrons.
And the story of where they get their mass from, okay, I'm afraid that we'll have to leave
that for the book.
Yeah.
But we don't have time for that right now.
But now there's the question, okay, so electrons do get their mass from the Higgs field,
so do up quarks and down quarks.
And so most of the elementary particles that we're made from do get their masses.
from the Higgs field, even if the more complicated objects, the protons and neutrons, and therefore
the atoms, do not. So simply because of that, it's clear that the Higgs field and gravity
can't be directly linked because protons and neutrons have lots of gravity, but they're not really
getting much mass from the Higgs field. And there are other reasons which we could discuss,
but let's leave the aside for now. So they are independent ideas. And now the question comes,
well, all right, so we started with this Margaret Thatcher in a room analogy where the Higgs field is like a crowd that slows people down as they try to move through it and the more well-known they are, the harder they have.
Okay.
Well, what's wrong with that is partly that it is in conflict with the principle of relativity, and that's pretty bad.
But in a way, the broader way in which it's wrong is that it suggests that the Higgs field has to do with most.
and that it affects the properties of the motion of objects directly.
But that's not how it works.
And we have to go back a moment and remember that what electrons are.
Electrons are waves in the electron field.
And the Higgs field does not, in some direct sense, give mass to electrons.
It does not provide the energy that an electron carries.
that gives it mass. What it actually does is it changes the properties of the electron field.
The Higgs field affects other fields. That's the real direct connection. And the way in which it affects
the electron field changes the way that the electron field vibrates. And since electrons are
vibrations in the electron field, that changes the properties of electron.
Yes. So it's that more indirect route that is the way that the Higgs field does its thing. And so
really the fundamental story is not how does the, sorry, how does the Higgs field affect elementary
particles? It's really, how does the Higgs field affect the fields whose waves are elementary
particles? And so it's the interactions between fields, the Higgs field and other fields, that is at the
fundamental heart of how the Higgs field is able to affect the world in such a dramatic way.
And just to add one side comment to that, again, to just make sure it's all clear,
the big news in 2012 was the discovery of the Higgs boson, a type of particle.
The type of particle is itself a ripple, a minimal wave in something.
What is it a ripple in?
It's a ripple in the Higgs field.
So the discovery of the Higgs particle was really not the big story.
It was the means to an end.
The discovery of the Higgs particle proved that there must be a Higgs field because particles
are just manifestations of ripples of fields.
And so the discovery of the Higgs field, that was the big deal.
The Higgs particle doesn't give mass to anything.
It doesn't affect anything.
Despite the name God particle that's been given to it, it has essentially no role in the
universe at all.
And if you make a Higgs particle, it's gone.
in a tiny fraction of a second.
But the Higgs field, that's another matter.
It's present everywhere in the universe, just like the electromagnetic field.
But it has an additional feature that has allowed it to change the properties of other fields
and thereby the properties of elementary particles on which our lives fundamentally depend.
I'm fond of pointing out that we're, we shouldn't call it the God particle anymore because now
we have evidence that it exists.
Oh, I love that.
It goes over separately with different audiences, depending on who.
you're talking to, but that was very helpful, good. And I think that we can, you know,
actually wind things up with, this leads us directly to, you know, okay, mass, gravity, etc.
You brought up the fact that one way of thinking about gravity is through the gravitational field,
which at the quantum field theory level looks like a spin-two particle, the graviton. And I know that
this is a lot of, this is definitely an area where people struggle trying to understand what we
physicists are saying, because on the one hand, we're saying gravity is not a force, right? Einstein
seemed to imply that gravity is a feature of space time, not a force. On the other hand, it's a particle,
just like the photon is a particle, which makes it seem kind of force-like. And on the, well, I mean,
there's many hands we can go down here, but we don't understand gravity at the quantum level.
is that an obstacle to talking about things like gravitons?
Gravitons have never been detected.
Should we really be sure that they're there?
I'm just going to dump all these questions in your lap
and give you 30 seconds to close it out.
You get more than 30 seconds, don't worry.
But however long it takes.
Well, I think the way to understand what we know
and don't know about gravity
and what we suspect about how it works
is really to make sure that your understanding
of electromagnetism and the focal.
is complete because the analogies are almost exact.
Yeah.
The notion that the electric force has to do with the exchange of photons, this is another
phrase that's common in the world of science communication.
I hate it because I think it really fundamentally miscommunicates what particles are.
And what we learn in first-year physics class is that electric forces are associated with the electric field is still just as true as it was before people invented quantum mechanics.
The electric field does generate the effect that we call electric force.
And to try to talk about it in terms of photons moving back and forth is kind of a math trick and not fundamental from my perspective to the actual physics.
photons, as we said, are the basic elements out of which a light wave is constructed.
Now, we can import these ideas to gravity, that gravity is caused by the gravitational field,
which itself, in this case, we have some idea of what it might be.
It reflects the curvature.
It's the property of space time, which we call curvature.
And waves in the gravitational field, we call gravitational waves.
just as a laser beam is a very bright wave of light.
The gravitational waves that were recently measured,
they are very bright,
even though they are extraordinarily difficult to measure,
and they're very dim by human standards.
They're extraordinarily bright by quantum standards.
And if you could make a sufficiently dim gravitational wave,
you would discover that it's made from individual gravitons,
just as if you take a sufficiently,
if you take a laser and make it sufficiently dim,
you'll discover that it's made from photons.
Now, that is still conjecture, but that is the analogy that we make, and we believe it's likely true.
Unfortunately, to test it experimentally is far beyond current technology.
But as far as the math goes, that math analogy works just fine.
The problems of quantum gravity do not arise with that analogy.
They arise when you try to make sense of the more quantum properties of spacetime itself.
And so that's sort of a more sophisticated application of quantum physics.
There's no problem with imagining gravitons.
They can be put into the equations.
They can be calculated.
One can even calculate things that they do, like scatter off of objects.
And so we have reason to think that gravitons may exist, but it's always possible that
our understanding of gravity is wrong and that some aspect of it will break down even before
we get to the quantum level. And if that's the case, then the story will be more complicated.
That's for experiment to decide. I would still argue, maybe disagree, but I would still argue
that there's essentially zero credence we should put on gravitons not existing. Maybe they're not
fundamental, but even in the wind, there's sound waves and we can quantize them to get phonons, right?
I mean, there's going to be something that is the quantum of the gravitational field,
whether it's fundamental or not.
Well, this is an interesting physics point that I am not 100% sure my own understanding
is as good as it should be.
It's kind of one of those things which I looked into at some point.
It's certainly true that sound waves in a piece of metal are made out of phonons in the same way
that light waves are made from photons.
But it is, I think, not the case that there are phonons in air.
Oh.
I think this is true.
This is something where, you know, I might be embarrassing myself here.
The point is that when the amplitude gets sufficiently low and you're starting to tell
whether you're trying to tell whether the sound wave is really something you could pull
apart, the whole structure of the material starts to be.
become important.
Sure.
And so your ability to describe it as a collective sort of wave breaks down before you get to
the quantum effects.
So I think it is possible that something similar is true for gravity and that we will have
to change the way we talk about it before we really get to individual quanta.
And that if you try to get to individual quanta, you would discover that there's something
wrong about the way you're thinking of space and time. Now, again, I don't say this with 100%
confidence because I haven't actually worked through the math and tried to understand this in detail.
I do remember reading something of this sort. And so I think both you and I have some reading
to do to settle this issue. That's always true. And that's very helpful because that's a point I
hadn't thought about, so that's useful. But maybe tell me if I'm oversimplifying, but for the people
out there who are still trying to get straight on whether gravity is a force or not, I would say
you know, there's a language that says,
gravity's not a force, it's the curvature of space time.
There's another language that says,
gravity is a force,
follows the inverse square law, like Isaac Newton said.
There's a third language that says,
gravity can be thought of as a manifestation
of a bunch of spin-two particles grouped up into some condensate.
And all of these languages are correct.
They're mutually incompatible.
You had to choose one at one time,
but they all describe the same underlying phenomenon
on in slightly different linguistic choices?
Well, this is, I think, this reflects a very important aspect of physics and mathematics
that I view as one of the really important conceptual points that is poorly understood
outside of the experts, but even the experts forget about it.
They know it.
And the first time we physicists learn that there's not going to be one unique language for talking about anything is when we're learning Newtonian physics.
Yeah.
Because we first learn everything that everybody learns in first year of physics, which is that there are forces and there's accelerations and that's the way you should describe things.
And then we learn three entirely different ways of saying the same thing.
Lagrangians, Hamiltonians, Hamilton-Jacquesquie theory, each one of these is a different way of talking about Newton's laws.
And you can prove mathematically that all the predictions that you will get from these different ways of saying the same thing are identical.
Which means that there are multiple conceptual languages based on multiple ways of writing down the same math,
which have exactly the same experimental consequences and cannot be distinguished by an experiment.
So, you know, how should we think about this?
I mean, math can be written in different ways.
Adding a positive number to a negative number can be thought of a subtraction.
Subtracting a positive number from a positive number.
So is it addition or is it subtraction?
Well, you know, that's kind of a, you know, clearly you could do it either way.
And if you wanted to base your world on addition and negative numbers, you could view the world
that way.
And if you wanted to think about, no, all numbers are positive, but I can do addition to subtraction,
that would be a different way to do it.
And there's nothing wrong with either one.
But it might change the way you talk.
So the different languages which you described for talking about general relativity, there are different ways
of writing the math or viewing the math that have exactly the same consequences.
And so a professional will use any and all of them whenever a particular one is convenient,
we'll use that one. If it makes the calculations simpler, we'll use it. And what we learn
is that we should not be too wedded to a particular conceptual viewpoint. We simply can't be.
We can't decide on the basis of experiment which one of these viewpoints is correct, nor should we try.
The math is what we use to make predictions.
The language in which we talk about the math or the version of the math that we use,
as long as they're literally identical in all predictions,
they are simply equivalent and common ways.
Just like you can describe a table using English or French or German,
it doesn't make it any less a table.
I think that's a wonderful lesson to wrap up with.
So Matt Strasser, thanks so much for being on the Mindscape Podcast.
Thank you very much, Sean.
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