Sean Carroll's Mindscape: Science, Society, Philosophy, Culture, Arts, and Ideas - 271 | Claudia de Rham on Modifying General Relativity
Episode Date: April 1, 2024Einstein's theory of general relativity has been our best understanding of gravity for over a century, withstanding a variety of experimental challenges of ever-increasing precision. But we have to be... open to the possibility that general relativity -- even at the classical level, aside from any questions of quantum gravity -- isn't the right theory of gravity. Such speculation is motivated by cosmology, where we have a good model of the universe but one with a number of loose ends. Claudia de Rham has been a leader in exploring how gravity could be modified in cosmologically interesting ways, and we discuss the current state of the art as well as future prospects. Blog post with transcript: https://www.preposterousuniverse.com/podcast/2024/04/01/271-claudia-de-rham-on-modifying-general-relativity/ Support Mindscape on Patreon. Claudia de Rham received her Ph.D. in physics from the University of Cambridge. She is currently a professor of physics and deputy department head at Imperial College, London. She is a Simons Foundation Investigator, winner of the Blavatnik Award, and a member of the American Academy of Arts and Sciences. Her new book is The Beauty of Falling: A Life in Pursuit of Gravity. Imperial College web page Wikipedia Publications at Inspire
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Hello, everyone, and welcome to the Mindscape podcast.
I'm your host, Sean Carroll.
There's a talk that I sometimes give.
I've been giving for last year and a half.
I'm sure you can find versions of it online.
It's related to volume one, the biggest ideas in the universe, where I go through classical mechanics, space time, all the way up to general relativity, Einstein's theory of gravity.
So in the talk, I have the high aspiration of in one hour explaining to you Einstein's equation in all of its specific real glory.
The real equation, R mu nu nu nu, minus one half RG, mu nu, munu, equals 8xg, T mu nu nu nu, not just e equals mc squared.
That's easy enough.
Everyone can understand that. And one of the themes of this talk that I give is the equations are smarter than we are. This is why I think it's worth the effort in a book like the biggest idea series of talking about the equations. Not that it's the only way to talk about physics, etc. Just because I have some equations in my recent book doesn't mean that I'm suddenly looking down upon people who don't have equations in their books. I think that all different levels, all different approaches are interesting and important.
but one of those interesting ones is the equation-based one.
And the reason why is because, as I said,
the equations seem to capture more than we put into them.
I mean, Einstein was a smart guy,
but his equation implied things that had never occurred to Einstein himself,
from the expansion of the universe to gravitational waves to black holes, right?
They were right there implied in solutions of the equations,
but Einstein himself didn't come up with these ideas.
And so it's therefore kind of interesting to imagine changing a theory like general relativity.
Einstein had this wonderful theory of gravity that has done better than we ever had any right to expect.
Not only does it explain things like the deflection of light and the procession of the perihelion of Mercury,
it also works for all these very, very far-flung regions of the cosmos
where we had no direct empirical evidence about when Einstein was doing his stuff.
Having said all that, of course, we don't think that Einstein's theory is the final answer.
General relativity, as we know, doesn't play well with quantum mechanics.
You can approximate, you can get a pretty good theory of quantum gravity
if you're just in weak fields, like here in the solar system and whatever.
But when it comes to the interior of black holes or the beginning of the universe,
quantum mechanics is going to be important.
That's what leads people to explore ideas like string theory,
where gravity is part of a bigger picture,
and maybe the whole bigger picture holds together.
But if you talk to people who do quantum field theory,
they will say the expectation is that general relativity will work well,
on long length scales, right? In field theory, we have a connection between large distances and
low energies, and basically you should expect your field theory to break down at high energies,
short distances, but there's no general reason to expect it to break down at long distances
or low energies. Here, though, we have a special situation with gravity because we have the whole
universe. There is a very, very explicit case where there's a very explicit case where there's a
the long-distance, low-energy behavior of the theory is of special interest.
Let's just put it that way.
And also, it kind of fits and makes sense.
We have good theories to explain the cosmological observations that we have,
but there are some lingering puzzles, most obviously,
the cosmological constant and the acceleration of the universe.
So despite the fact that Einstein's theory is so good,
his equations are so smart, and it's been so successful at fitting all the data,
it is still worth thinking about ways to modify or change Einstein's general relativity,
both at short scales and high distances and at long distances and low energy scales.
That's what we're talking about today in the podcast.
Claudia de Ram is a theoretical physicist who also has a new book out called The Beauty of Falling,
a Life in Pursuit of Gravity.
But we theoretical physicists know her as the world's expert in what we call
massive gravity.
So you know that gravity, once you have a little bit of quantum mechanics in the game,
implies the existence of graviton particles, and they can be analyzed using the usual tools
of particle physics and quantum field theory, and they're mass list.
The graviton has zero mass, just like the photon does.
What if you imagine giving graviton's a little tiny mass?
Is that good?
Is it bad?
Does it make your life easier?
Does it make it harder?
what we'll find out in the episode is that, in fact, it's actually super difficult to do that in any coherent way because there's just so many constraints, so many rules you have to play by in quantum field theory.
But Claudia and her collaborators have figured out a way to do it, and these days they are applying their ideas to cosmology to see if maybe we can do even better than Einstein did himself.
It's an ambitious kind of thing, but that's why theoretical physicists get paid the big bucks.
So let's go.
Claudia DeRam, welcome to the Mindscape Podcast.
Thank you. Hi.
So you, of course, do all of these fancy things with gravity and field theory and things like that that that we will get into.
But they're all starting with general relativity.
And let's imagine that the typical podcast listener has heard of general relativity, but doesn't exactly know the details.
In fact, coincidentally, recently on social media, people were arguing about whether or not gravity is a force.
So why don't you tell us how you think of, how you conceptualize what general relativity is trying to tell us?
Yeah, it's amazing because there's a big emphasis in saying that according to Einstein's theory of general relativity,
gravity is unlike the other phenomenon and it's not a force.
And I guess I like to differ a little bit.
And I'm not going to say anything controversial there.
So far, maybe for the first five minutes, it's going to be quite standard.
But still, we can very much think of gravity as.
a force, I would say, like electromagnetism or the weak force or the other fundamental forces of nature.
But it's true that what we typically experience as gravitational attraction, let's say,
it's better understood as being the representation, the manifestation, I would say, of the
curvature of space time we live in. And so in this sense, it's much more an embedding in where we
are with in mind the fact that if we if we are living on that space time, if a planet is living
on that space time, it has an effect on the curvature of space time. And in turn, this curvature
of space time is dictating to us how we should evolve and move in that space time. I think what is
quite remarkable about gravity, let me say really about gravity and at the core of everything, and
perhaps what is really, really exciting about gravity is that it's entirely, it's really completely
equivalent to everybody. He has this equivalent principle, which tells you that it will affect
everything, everyone in exactly the same way. So the gravitational pull attraction on different
masses, no matter what the masses are, and you can have something as light as, as light itself,
if you want to, and it will still have a gravitational effect on them.
And so from this equivalence principle, it became clear to Einstein that it had to be something
a bit more fundamental than just you have masses which are sort of the chart with respect
to gravity and they get affected in this way.
It had to be much more internal in some sense, much more related to intrinsically the evolution
in space and time and this.
understanding that it's not just something outside that will act on different masses in different
ways, on different charges, on different ways is very much, much more internal and related to
the motion in space and time, and therefore related to curvature or how we affect curvature
around the space time around ourselves and how this space time curvature affect us in return.
So I think that is the standard picture that gravity from that perspective is much more of an embedding, is much more omnipresent than your typical forces.
But you still have a force deep down.
There is still a force in gravity.
And we have observed it.
We don't experience it in every day.
When we think of us falling down, whether I'm going to drop my pen or maybe we have the apple falling on Newton's head.
And we have things which are even bigger, like the orbit of the planets around the stars.
Those are all gravitational phenomenon.
And it's perhaps not exactly what we think as the gravitational force per se.
But there is still a gravitational force.
Something maybe before we get there is how one way I like to think about it is if we imagine,
try to think of what does gravity feel like?
You can wonder, what does the question even mean?
What does gravity feel like?
And I don't know.
You don't know.
No one knows because gravity is not something we can feel at a given point.
We can't.
I can tell you you can't as a human being feel gravity.
It's impossible.
It's impossible for us because it affects every single cell in a body,
every single molecule, every single atom, every single fundamental particle in your body are affected in exactly the same way through this gravitational way we experience the curvature of space-time around ourselves.
So there's no stretching of any cells apart.
There's no e-drum cells which are being pushed apart.
There's no chemical reaction in our tongues.
There's no light coming in our eyes.
There's no pressure on our skin.
we can't feel gravity.
We can't feel gravity in the same way that we could say we can some sense feel or see light or electromagnetism.
It's quite different because every single fundamental particle in a body experiences gravity in exactly the same way.
So they can't be distinguishing it in any possible way.
So that is the typical sense in which gravity affect us.
And there's no feeling in that sense.
Okay, but once you get to my age, it certainly feels like you can feel gravity.
Yeah, I can feel the gravity of time.
I can definitely feel that.
Yeah, and I can feel the gravity of space as well when I propagate myself.
Yeah, there you go.
And I can feel the gravity of my mass as well, sometimes.
So I can feel a lot of things related to gravity.
But the fundamental effect of gravity, actually, it's something which you're not going to be able to experience at an age given one point.
And already, if you think of the notion of, okay, gravity manifests itself through curvature, curvature of space time,
that very notion of curvature already requires connecting between different points, requires comparing what happens at a given point and then comparing at another point.
if you think of you sitting here on Earth, okay, we are, both of us, we're on different places on the planet.
But myself, I feel around myself is pretty flat and probably you feel the same thing for you.
And it's only if we started trying to wave at each other or trying to look at each other or try to look.
We both start looking at the stars and comparing what we see.
Then if we were very clever and if we would be able to see that,
what we observe is different.
So we do comparison between you and me,
and we see that what is different.
And from there, we should be able to determine
that actually the surface of the earth is curved
because we're not seeing the sky in the same way.
So a perspective of the sky is rotated with respect to one another.
And so there is a curvature on the surface of which we live.
And we can infer the notion of curvature.
So the reason I'm saying that is already the notion of curvature,
experiencing curvature,
And then in some sense, experiencing gravity does really require comparing between different points, communicating between different points.
There's not such a thing as gravity.
There's not such a thing as curvature really locally.
It always requires some comparison.
It's relative.
So the name relativity kind of makes sense in this case.
Yes.
That's right.
That's right.
Exactly.
It's general relativity.
So relative.
It's general.
It's general relative.
Actually, the name does really make sense.
It's interesting.
Now, still, I would beg to say that there is a force in gravity
in a very similar way that there is an electromagnetic force.
And also in just the same way that fundamentally,
electromagnetism is a quantum phenomenon,
and all of the fundamental forces are quantum phenomenon.
I would say that gravity also is a,
a quantum phenomenon. And we do understand very, very well how to describe this up to some given
extent at the quantum level to describe gravity as a force, as a quantum force up to a given level.
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Hey everyone, it's Cal Penn. I'm the host of Earsay, the Audible and IHeart Audio Book Club.
This week on the podcast, I am sitting down with Ray Porter, the narrow.
narrator of Andy Weir's audiobook Project Hail Mary,
massive sci-fi adventure about survival and science,
and what happens when you wake up alone very far from Earth?
I really had to make a decision because I caught myself getting that frog in my throat
and starting to get teary as I'm narrating some of these sections.
And it's like, okay, yo, yeah, yo, is this indulgent?
And I really thought about it.
I was like, no, at this point, it would kind of be betraying the trust
the author and the listener have in telling this story if I don't go through it. But there's places
in this book that deeply emotionally affected me and I left it on the mic. That's great.
Because it served the story. People will say like, oh my God, I cried at the end. It's like,
yeah, dude, me too. Listen to Earsay, the Audible and IHeart Audio Book Club on the IHeart Radio
app or wherever you get your podcasts. Let's get into this because that's a provocative statement
that you just made.
And I think that one that I agree with,
but it does require some unpacking
for people who might have simply heard
that we don't know what quantum gravity is, right?
And you're not someone who is taking sides
about string theory or loop quantum gravity
or anything like that,
but you are kind of thinking about quantum mechanics
and gravity together.
So how is that possible?
Yes, yes.
Yes.
So first, maybe I should say why I think gravity is a force
and how I want to put it in the same footing as the other phenomenon and fundamental forces of nature.
And I think maybe it'll be simpler to think of why what I'm saying is not at all controversial.
I think string theorists and quantum gravity people and also people that do find challenging to quantized gravity,
we would still find what I'm saying, not at all controversial.
So we have absurd gravitational waves.
We have, and I think there's little debate now that gravitational waves are real phenomenon in nature.
they correspond to a distortion of space and time around what we call a quadrupole.
So you should really think of comparing not only two points,
but really along two directions to see gravitational waves.
But this distortion of space time is really waves of gravity,
gravitational waves propagating through space time.
This is very similar than light, actually.
Light are waves of electromagnetic nature.
the electromagnetic waves, there fluctuation in the electromagnetic field propagating at the speed of light through space time.
And if you think of the same thing for gravity, the fluctuation of a gravitational field,
so of what corresponds to the space time, through space and time themselves, there are gravitational waves,
and we have observed them.
And it is through this squeezing and pulling and pushing and squeezing, tearing us,
apart a little bit. If we were close to a black hole, we would feel that much, much more.
But since we're quite far away from there, it's very, very subtle. But this strain of gravitational
waves that they have between different bodies on different directions, they are fundamentally
the force of gravity, just like there is an electromagnetic force. And so if we think of it like
that, it's very similar than electromagnetism, and it is very similar than the
force, for instance, or the strong force to some extent.
Although the strong force has some complications which are really due to the strong force itself.
And this is why, you know, when we have, for those of us who have seen pictures of the gravitational
wave observatories like LIGO and Virgo and so forth, there's two long tubes at right
angles to each other, right? Because they're testing, that squeezing that you just talked about,
that quadrupole is exactly that you're squeezed in one direction and stretched in the perpendicular.
particular direction.
That's right.
That's one.
That's right.
That's right.
That would be, if we were able to experience that in that body ourselves, that would be us feeling
gravity.
Yeah.
But we need such extraordinary experiments to feel that on such big scales that is quite unlikely.
We're going to feel that in our body.
And if we do, probably that's the last thing we feel because we're probably falling into
to black hole merging into one another or something like that.
So it'll be a quick feel.
But yes, we can't think of it just like, now this is good,
because we see the gravitational force is sort of a quadrupole phenomenon,
a quadrupole force.
We have this two long tube at right angle to one another.
We need to compare those two directions to experience it.
And the electromagnetic force is, we just need a dipole,
if we want to. We can,
for instance, experience it through the
variation of two
electrons
accelerated respect to one another.
They would lead to the propagation of
light, the propagation of
an electromagnetic field. And similarly,
they would receive the electromagnetic field
and that would affect them. We can measure it
like that. But in some
sense, then it's very similar.
The fundamental properties of one,
it's a dipole, the other one is a quadrupole.
the subtleties are a little bit different and that has a big impact for some of the effects.
But at a quite fundamental level, there are just two forces, one which we think of it as a dipole,
the other one as a quadrupole.
Maybe if I put that more in terms of quantum field theory, because I want to go there.
That's what we're going.
Yeah.
More group theory.
One is what I would call a spin one.
and then the other one is a spin two.
And that is just a technicality at this level related to how they behave under rotations.
Really under rotational space time.
But if you don't want to think of rotational space times are what we call Lawrence environment.
So we can rotate space, but we can also sort of rotate time.
And that's also related to this relative notion of special relativity.
If you're moving with respect to one another, then not only your space is.
affected, but your time is also affected. And so you have rotational space time. And so a photon,
which is the particle propagating or mediating the electromagnetic force from a quantum field
theory perspective, there's a quantum of this electromagnetic field, which is a photon. And that is
from a particle point of view, we can think of it as a particle which has spin one. So it rotate
in a particular way under Lawrence transformation and the Lawrence rotations.
You can think of it a little bit like an apple with a stern on top.
And you need a full rotation to see it again.
And a graviton would be then by analogy, if I make the exact same analogy,
a graviton would be the same thing as a photon, it's a fundamental particle,
but for gravity.
So it would be the particle responsible.
for the gravitational mediation.
And you can think of the gravitational waves
that we have observed.
They are a classical phenomenon,
but they're not made of a completely continuum
of waves.
Really fundamentally, there's a quantum of this wave,
which we call a graviton.
The gravitational waves we have observed,
they have a lot, really a lot of those gravitons,
about 10 to the 40, 40, 44 gravitons.
So just picking one of them would be quite challenging.
But if in principle we could make an experiment as precise as possible, more precise than what would be valid by Heisenberg uncertainty in principle, then in principle we could think of detecting one graviton.
But that maybe for later, for another story.
Well, I'm sure that there's going to be some people who are listening and they've been told that we'll never detect gravitons.
So how do you know that they're real?
but you're talking as if you think that gravitons are pretty well established.
Yes, so there's multiple reasons for that, but for one thing is that, first of all, let me just say there's no problem thinking about a graviton.
Maybe let me just say that what I'm saying so far is not at all controversial.
It's not that I have come up with a new theory of quantum gravity that I'm trying to unveil and to sell to everybody.
What I'm saying is very uncontroversial, and we're dealing with quantum gravity on a daily basis,
Everything, if you look on the back of my blackboard, is related to gravity and is related to quantum field theory.
And there's no problem thinking about a graviton, thinking about quantum gravity within a given regime.
In our everyday life, that's absolutely possible.
And if you think at sufficiently low curvature, sufficiently low energy scales, then you can quantize gravity in a, if you want to say,
in a perturbative ways.
So what we do, actually, we think of flat space time,
and we think of gravitational waves leaving on flat space time,
and those gravitational waves, they have a quantum of them,
which is the graviton.
And from that perspective, there's no issue whatsoever.
That's absolutely fine.
Really, what becomes problematic is if you try to think of this quantum
and of the quantum nature of gravity,
when you're reaching very high energy scales or very high curvature scales or very short distances,
that close to the Planck scale, the Planck Energy Scale, for instance.
So if I were performing a particle collision at energy scales, which is way beyond what is currently at CERN.
So at CERN, we are TV energy scale, roughly speaking, so 10 to the 12 electron volt.
but if I was going to 10 to the 19 giga electron volts,
so 10 to the 27 electron volt,
so that's 25 orders of magnitude, no, sorry, 15 orders, 15, thank you.
15 orders of magnitude more than CERN than the large hydraulic collider,
15 orders of magnitude, that's a lot.
If I were at 15 orders of magnitude larger than that,
then when I start colliding particles, I would expect to produce black holes,
but also I would expect that it's going to be quite difficult to predict what the outcome is precisely
because it requires me understanding the quantum nature of gravity at those scales
and that maybe some of my colleagues know what it is, maybe it's string theory,
maybe it's quantum gravity, quantum gravity, maybe it's causal set,
maybe it's loads of different things.
I don't know.
Actually, I really don't know.
I'm quite agnostic about that.
I'm happy to believe whatever they may think.
considered different perspective, but I don't know for sure. So far, I don't think we know for sure.
What we know is that we, we don't have yet a fully complete theory of everything at those scales.
And so we don't have a fully complete theory of quantum gravity at those very high energy scales,
if we were to imagine a very high energetic process of colliding any particles.
So if you were to collide any particle, even if you wanted to think of it as electrons or protons,
and you were colliding them, even if you're not colliding gravitons per se,
you can't prevent them from interacting with gravity.
This is the beauty of the equivalence principle,
that everything connects with gravity.
It's the beauty of it, but it's also a curse,
so you can't shield gravity from play along.
It will come in, it will come into play, whether you want it or not.
And on our everyday life, when we do particle collisions at the LHC, I guess that's my everyday life.
That's not really my everyday life, but in what we do.
The gravitational effect is quite small and we don't need to worry too much about it.
But if we were to go to much higher energy, we can't prevent but worrying about it.
It will come in for sure and it will have a dramatic effect on the outcome.
So dramatic, I don't know what happens.
I just want to make sure that we all get it.
So you're admitting that we don't know what happens at the plank scale.
Like we don't know what the fundamental theory of quantum gravity is deep down.
But nevertheless, we can do quantum gravity in the sense of thinking of gravitons in a regime we're perfectly safe.
And that's kind of the game that you want to play.
You want to think about ways to understand and even modify our theory of gravitons in various cases.
Exactly. Absolutely. Exactly.
And the other thing to just drive home, because it's really important, and almost never gets explained, this dipole versus quadrupole thing is related to the spin of the particles, as you said.
Exactly. An electron in an electromagnetic wave jiggles up and down. That's a dipole. That's spin one. The graviton squeezes and then stretches, which is a different thing, and that spin two. And all that's going to matter for what we're about to say.
That's right, that's right, that's all.
So if we're just explaining like that, it looks like it's very similar.
But when we're trying to implement that in a fully-fledged theory, then it makes a big difference.
I can say, let me just say something technical just now, which may seem a bit technical and innocent.
Let me just say nonetheless, because this is interesting.
If you take this spin one, for instance, of electromagnetic force, it means that it.
if I'm starting having some collisions, I take particles and I collide them with each other.
Let me take electrons, for instance, and I collide them with each other.
And then I'm trying to see, they will exchange photons because they can.
They will exchange photons.
And the probability of a given outcome will typically grow for some of the effect of that.
If I'm trying to pick up a particular effect of that, will grow in energy like the spin of the particles.
So if I have the photon, it will grow like spin one.
So it will go actually like twice the spin.
So like energy squared.
We'll go in like energy squared.
But if I take another, I can take the same thing.
And in prayer you could also exchange graviton in that process.
And that would be quite a weak interactions because everything interacts quite weak with gravity to start with.
but the probability of the outcome will sort of grow like the energy for that process
the energy comes to the power twice the spin.
So that's to the power four.
And that increases, to start with it's not very much.
It's very weak at very low energy, like the energies we're probing nowadays.
But because it grows faster in energy, it comes to a point where this is really the process
that dominates and it starts really growing too fast.
for us to make sense of it when it gets close to the plank scale.
And so this is where the difference in spin becomes really important.
And if we wanted to think of something, particles of higher spin, even higher than spin two,
higher than a graviton, then we know that we wouldn't be able to fully make sense of them by
themselves.
We need to have, we need to mediate them to mitigate them in different ways.
So gravity, the spin two is the last thing we can see.
sort of try to make sense to some extent.
And then that's it.
Anything higher speed than that,
if it is a fundamental particle,
then it just goes a bit too crazy.
If it is a fundamental particle.
Right.
And this is actually a wonderful thing.
I'm glad that you mentioned that technical point,
because it opens the window a little bit
into how real physicists spend their time thinking about things.
You know,
like I think that I get a lot of emails.
I don't know if you do.
you have a book coming out.
Claudia has a book coming out called The Beauty of Falling.
So your number of emails is going to increase once the book comes out.
And they're proposing a new theory.
And they say, well, what if gravity is time?
And, you know, that is not how physicists think.
They're thinking about all of these constraints from the behavior of scattering processes
as a function of energy and the spins of the fields and things like that.
And there's a whole bunch of ideas you've got to keep around at all times when you're even imagining different approaches.
That's right. That's right. That's right. Yeah, I mean, you and me and many of our colleagues have thought a lot about gravity and also if we can challenge it and if we can think of something else.
And one thing is we really need to understand general relativity and how it connects with all the observation and all the beauty, all the fundamental physics beyond it.
and how it connects also with quantum field theory.
We need to understand all of this to a huge level
to then make an indent into how we can think of it,
challenge it slightly differently
because it is working so remarkably well.
It's annoying.
Yes, yeah.
We really need to have all of this under track
before we can try to understand how to challenge it slightly.
But yes, indeed, we're thinking of it very much
in terms of, I think, the symmetries and the energy skills and how they relate to one another
and how things transform and how we can push them to the limits is very important.
We can't just start over from scratch and think of a different concept.
Hey, everyone, it's Cal Penn.
I'm the host of Earsay, the Audible and I Heart Audio Book Club.
This week on the podcast, I am sitting down with Ray Porter, the narrator of Andy Weir's
audiobook Project Hail Mary, massive sci-fi adventure about survival and science. And what happens
when you wake up alone very far from Earth? I really had to make a decision because I caught myself
getting that frog in my throat and starting to get teary as I'm narrating some of these sections.
And it's like, okay, yo, yeah, yeah, yo, is this indulgent? And I really thought about it. I was like,
no, at this point, it would kind of be betraying the trust the author and the listener have
in telling this story if I don't go through it.
But there's places in this book that deeply emotionally affected me,
and I left it on the mic.
That's great.
Because it served the story.
People will say like, oh my God, I cried at the end.
It's like, yeah, dude, me too.
Listen to Earsay, the Audible and Iheart audiobook club on the Iheart radio app or wherever
you get your podcasts.
And the other thing that you mentioned, again, I'm sort of repeating things you said
because they're so important, but these spins.
that particles have are quite constrained, right?
We have mostly, most of the universe around us
looks like spin one-half particles like electrons and quarks
or spin-one particles like photons and gluons.
There's the Higgs boson, which is spin zero,
the graviton, which is spin two.
That's it.
Those are the only options that we can imagine others.
We've never found a fundamental particle
with any spin other than that.
That's right.
That's fine.
That's fine.
And the spin-2 nature of the graviton comes from general relativity, right?
Like Einstein didn't think of it that way, but the modern particle physicist will think of it that way.
Exactly, yes.
So it's there in Einstein-the-R general relativity, whether he didn't build general activity in thinking,
aha, let me think about we have the photon, so let me think of a spin-2 now and built general activity.
But nowadays, we actually, that's very much the way I think about it, very much down to Earth and say, okay, we have these different possibilities of particles.
And so if I have a spin half, if I have a spin zero, if I have a spin one, if I have a spin two, and if I start to understand how to make sense of a theory of massless spin two, so a particle which mass, internal mass is inertial mass, I should say,
say is zero, like the photon, which is a particle of spin one, which inertial mass is zero,
I would be, and this now there are theorems done, for instance, by fine mine, by desert,
by all sorts of amazing physicists in the past century that show that the only consistent
theory that I can have within some given assumptions about how they couple and things like
that, and the symmetry level, is general relativity. That's the only thing we can
can have. So we're really able to build
Einstein-theory general activity from the grounds up.
And I think that that's quite beautiful because
we typically are taught or we hear about
anstand-theory general relativity as relying on some pillars,
Einstein's pillars of general activity requiring some of some things.
For instance, we often hear about special relativity
as being requiring that nothing propagates faster than the speed of light.
the speed of light being this fundamental thing.
And nowadays, I would say we almost think of it the other way around.
We can very much think of the fundamental particles and the fundamental symmetries.
And a lot of those things come out of that, that nothing can travel faster than light
because of the symmetry that we are relying on ourselves.
And we need to have general relativity, which is the theory of mass less spin two,
which encodes a metric that describes how space and time.
are evolving all around us, this is the only possibility. It's not because it's beautiful,
it's because it's the only thing that makes sense. It's also beautiful, but you're right.
It is. It is. Yes. Yeah. Okay, so you want to take this beautiful structure. Einstein came up
with this theory. As you said, something that I just think is a remarkable fact that if Einstein
hadn't come up with it, but we knew that there was gravity someday much later, people might have
started thinking about spin two particles and invented general relativity, which is a wonderful idea.
So you want to mess it up. I don't understand. So we have this beautiful. Well, I don't know if I
if there's one thing, you know, that's one of the things. If there's one thing I learned about
all of the things I've done is how, as you say, how beautiful or how fundamental and how
challenging is to challenge general activity. So if anything, I don't really want to challenge
it per se. But first to understand how fundamentalities. And
and how much it is the only possibility that we can ever think about.
We need to think a little bit beyond the box.
And then we understand how challenging it would be,
what you would mean to have something ever so slightly different than general activity.
So then we can compare it with it when we have observations.
We can understand what you would mean.
Because if the only game in town is general activity, we can take it for granted.
But if we have no reference, and it's all.
relative, right? So if we have no reference, then I don't know, I don't know what you say.
So yeah, let me give you some elements of what makes me a bit uncomfortable for some of the
aspect that we think about. So of course, I spent now maybe half an hour telling you how there's
absolutely no problem with quantum gravity. We know how to deal with that. But we do know that
they will come a point where we need another theory than general relativity.
We know general relativity is not the theory of everything that we know for sure.
So we know there's going to be new layers of physics.
I'm not going to tell you what they are because I don't know,
because that's a very, very challenging question.
But I'm telling you that because already in our way of thinking as physicists nowadays,
we don't really ever think of this is the theory of everything
and there's nothing else to be learned.
And this is a theory which is applicable
at absolutely every energy scales possible.
Already in telling you that we understand
Einstein's theoretical relativity,
we can treat it as a quantum field theory
up to a given energy scale,
in those statements, we make it clear
that the description we do of the world around us,
the way we describe nature around us,
adapts depending on precisely what we're interested in
and the type of energy scales we're interested in in particular
or the type of curvature scales we're interested in.
And we do that every day, for instance,
if I want to understand how fluid dynamics works to a good approximation,
I don't really need to look at the particle descriptions
of the electrons and the protons inside the atoms and the molecules of water.
I don't need to do that.
I can have a much more effective description of what's going on.
Sure.
And then I can dive deeper into the underlying fundamental physics that goes on.
So in the way we describe the world around us,
we're trying to understand what it is we're interested in,
and then we have a particular description,
which is relevant for those skills.
And so we know that within energy scales we're dealing with here,
for instance, in the solar system, for instance, in the galaxy,
we can treat general relativity as an effective quantum field theory, and that works really well.
But we also know that if I wanted to understand what's happening very close to the singularity of a black hole,
then I would need to have something else.
If I wanted to do a particle collision at energy scales, which are of the order of the Planck scale,
I would need to have something else.
If I wanted to look at what happens at the very beginning of the universe,
very close to the big bang, I would need to understand what is the underlying structure
of quantum theory of gravity.
But now I'm going to ask myself the question,
is general relativity really a good description?
We know it's a good description for the skills we're interested in.
We know it's not such a good description for too high energy scales.
And how about very low energy scales?
What do I mean by that?
Maybe that's a bit harder to appreciate.
So let me just say there's a duality,
or not a duality, but in physics,
we always have this notion of high energy corresponds to small distance and low energy corresponds to long distances.
I don't know how familiar you think this will be too.
I think that you just said it and I think that's good.
We can get it.
But I guess the only thing to say is that that idea is so ingrained in physicists that they almost forget which one they're talking about.
Short distance just is high energy.
long distance is low energy. They mean the same thing. Yeah. Yeah. Yeah. And I think of it, if you want,
if you think of it as a wave, if I have a wave with a very long wavelength with a very long
spread, then it's actually a very low frequency towards the red if you want. And so that has a low
energy. And then vice versa. It's very peaked. It has a very short wavelength. Then it's very high
frequency and I would say it's high energy. Again, here I'm mixing all sorts of different units
and notion and we just exchange them. It's very hard to think about which one we're thinking
at any given time. In fact, people call them the infrared and the ultraviolet, right?
For long distances and short distances. Exactly. Exactly. Yeah. It's the notion of color and
wavelengths and frequency and energy and curvature. It's all mixed into one pack.
And you're suggesting that even though we don't claim, you don't
don't claim, I don't claim to understand gravity in the ultraviolet, the short-distance high-energy regime,
maybe there's room to learn something about the long-distance infrared regime.
That's right. Exactly. So I want to think of gravity in the, let me say, IR, infrared,
and by that, color of gravity, it's a funny concept, but what I mean by that is very, very long
distances. So what do I mean by very long distances? Imagine the longest possible distance,
as you can imagine, and that is the scale of the observable universe today.
So I don't know if the universe is infinite in size or finite.
That's also a very complicated question.
Maybe we'll never know.
I think most people maybe would believe it's infinite,
or maybe it was infinite equation, or maybe it was, I don't know.
Truly don't know, yeah.
No, we don't know. I don't think we know.
I think it'll be hard to really claim for sure.
But we have a finite size observable universe, which means we can only see up to a given distance
because the universe is expanding.
That means that the structure of space and time is stretching.
And so the further away you look, the fastest objects seem to be moving away from you.
And if you look far enough, then the objects will really, it's a structure of space time between us.
but it would look as if the objects are moving away from us faster than light.
And so that that would mean that if you look too far away,
you can't see the objects anymore because it's moving faster than light.
It doesn't mean that information is propagating faster than light.
There's no information propagating there.
It's just the structure of space between different objects,
between different galaxies, if you want in the universe,
is stretching so fast that if you're looking very far away,
then it seems like it's going faster than light.
So because of that, and also if you want,
because of the fact that the universe has a finite life, lifetime,
there's only a finite science for our observable universe.
We can't see further than that.
And so that's the longest possible distances that I can picture in my head.
I can think of distances longer than that,
but then they'll never be observable.
They never really make sense nowadays.
Maybe if we wait, I don't know.
that will depend on the future of our universe.
I don't know.
So let me think of gravity on those very, very large distance scales.
And it's very likely that it is, if I think of gravity,
if I think of the structures based on those very, very large distances,
it is well described by Einstein theory of general activity.
But who am I to know?
I don't know, because I have no other experiments done at those scales.
I have no way to compare.
The only thing I can do is think of it.
But it's not like I can do another experiment in the lab measuring these big distances.
The behavior of gravity on those big distances, or if we want the behavior of gravity on very, very low curvature scales, very low, it's almost so low, it's flat almost, it's not quite, but it's very, very low.
It's something we have never measured before.
We can't compare and say, okay, it is well described by.
Unstand Theoretional Activity because we don't know.
So this is just the premises.
It doesn't mean that it's wrong, but that's just the premises of where we stand.
I don't think anything I'm saying so far is controversial.
Something else I'm going to say which is not controversial is that we do observe that the expansion,
the universe is expanding, but not only it is expanding, this expansion is accelerating.
And that led to the 2013 Nobel Prize, I think it was, for.
for the, sorry, the 2011.
It was earlier, yeah, yeah.
I think it's for 2011, right?
Yeah, 2011.
2013 was discovery of the Higgs.
Former Mindscape guest Adam Reese was one of the winners of the Nobel Prize.
Yes, exactly.
For the discovery, I don't know the exact citations,
but it's something like the redshift of supernovae.
Yeah, but it's really the acceleration of the universe, obviously, yes.
Yeah, yeah.
So we do see that the universe is expanding, but that expansion is also accelerating.
So maybe most of you have heard some things along those lines.
And then also the fact that we may have some notion of what could lead to this accelerated expansion,
but it's not entirely clear.
And for lack of a better name, we can say it's dark energy.
There's some sort of dark energy out there.
I just really, I might say anything, any other word I want.
I can call it glibibulka, I can call it whatever I want.
I don't know what it is.
It's just a placeholder.
And we can think of it as a fluid with negative pressure.
We often, we sometimes say it's a negative, it's a, what is, anti-gravity fluid.
And I think that's not quite right because it's actually very gravity.
It plays with gravity.
I never use those words, right.
Yeah, it's not a top.
all counter gravity in any way, really acts with gravity,
and it acts with gravity in its favor.
There's nothing anti about it.
But it's a fluid which we can describe with positive energy density,
but negative pressure.
And that's this negative pressure that would lead to the accelerated expansion of the universe.
So that's fine.
That's an effective description of what's going on.
But this effective description is not really explaining what is happening,
is not telling us where this dark energy is coming from.
However, this is where I think the quantum nature of the world we're living is important.
We also know that every particle that we know of, let's say the electron, the Higgs, the top quark and everything,
they are fundamentally quantum objects.
That is not controversial.
I think all of those particles we know, they're quantum objects, their quantum field.
and they have, they lead to quantum fluctuations in the vacuum.
They sort of have a soul, wherever you are.
You can be in a galaxy, you can be in a cluster of galaxy,
you can be near a black hole,
or you can be near in the middle of a cosmic void
in an completely empty region of the universe
with nothing, absolutely nothing around you
for millions of light years around you.
And yet you have this constant bubbling up out of nothing
of fundamental particles that come in and out of existence for a little instant and then
disappear.
There are virtual particles.
To detect them, really, you should have, you should make something else.
But we can see the effect of this constant bubbling of vacuum particles in other effects,
like at the LHC, like at CERN.
This virtual effect is present, not necessarily directly from the vacuum, but it is something
we have very strong reasons to believe has some.
level of reality that is not just a mathematical artifact, it's actually something real.
And so this soul, if you want, quantum soul of all the particles that we know,
we would expect them to lead to an energy density in the vacuum.
And this energy density locally is quite small, but it's everywhere.
It's absolutely everywhere in the universe.
It doesn't care about the local environment.
It will be everywhere in the universe.
and so integrate it out, it leads to a huge contribution in the universe.
It would really dominate the whole energy content of the universe by many, many, many orders of magnitude.
And this contribution, because it is constant everywhere in the universe, everywhere in space, everywhere in time,
we can call it a cosmological constant.
And actually, that is a term that Einstein had introduced himself from very early on in his Einstein's theory,
which he then retracted,
but it's probably one of the most eureka moment he had.
To introduce this cosmological constant,
it can lead to an accelerated expansion of the universe.
So in some sense, so far,
things seem to fit in together
that we have the quantum fields of all the particles that we know
lead to some vacuum energy that looks like a cosmological constant
that can lead to an accelerated expansion of the universe,
which is precisely what we are.
observe, and so this seems all consistent. The only thing is that the level of the contribution
of vacuum energy to this cosmological constant is too big by at least 56 orders of magnitude,
if I just consider the particles that I do know for sure do exist in nature, like the Higgs,
like the electron, just by themselves, they lead to a huge level of vacuum energy, and therefore
I would say to a cosmological constant, which is way too big to.
to be consistent with the observations of the current accelerated expansion of the universe.
We would have expected, actually, that the universe would be accelerating far, far, far, faster.
So this is really where the issue lies.
And some of you may have heard of this discrepancy of 120 orders of magnitude.
this is really if you consider that you have contribution
that would come in all the way up to the Planck scale
and that I'm going to remain agnostic about
because I have no reason to believe for or against.
I don't know.
We haven't seen particles beyond the Higgs
or beyond of mass larger than the top quarks.
So I'm not going to claim anything about that.
But from what we know, we know there's a Higgs field
with a given mass.
And already that mass leads to a contribution.
to the vacuum energy, which is way too fast to be consistent with a current observation,
any observation.
That is not, I mean, everybody would tell from the beginning that it would otherwise have
been way too fast.
So this is a problem.
So this is, I think the community would agree that it is probably one of the biggest
problem we have.
The biggest discrepancy, at the very least, of the whole history of physics, of science,
of everything.
It's a huge discrepancy.
It's a huge paradox in some sense
that we have this theory of general activity
on one side that works so well
and everything seems to be fitting in
perfectly together,
even the fact that a cosmological constant
will lead to the accelerated expansion
of the universe,
which we do observe that.
And on the other hand,
we have quantum field theory,
which has been working
in remarkable precision
for the particles that we know,
and all of the sea of virtual particles.
We go within so deep layers of those loops of fundamental particles to do calculations,
to look at predictions of what will happen at CERN and other particle accelerators,
and that works so well, really, really incredibly well to such a high precision.
And so we have those two descriptions of nature, which are not at all contradictory.
I would say in everyday life, we can really put gravity in the quantum world together,
and there's not at all any contradiction.
But the real contradiction is coming into the effect of the vacuum energy,
of those fundamental particles into gravity, into the curvature of space time,
and into how fast you would want it to make the universe expansion accelerate.
This is the real contradiction.
And that's the motivation for messing with gravity at long-distance is in the internet.
That's right.
So all of this is my excuse for now.
You're excuse.
I think you have a very, very good motivation there.
And so there could be many different ways to mess with gravity.
I've even done this.
I've played this game myself.
But what you want to say, if I'm vastly oversimplifying,
is that that starting point when we were talking about particles and spins,
and you say that the graviton, like the photon, is a massless particle.
It moves at the speed of light.
you want to say maybe it doesn't.
That's right. I want to say all of this is a big paradox because I'm assuming that the
graviton is a massless particle that moves at the speed of light and that has an infinite range.
That means that I really need to include all of the vacuum energy throughout the whole universe,
throughout the whole past of the universe.
And that has an effect on the universe which is way too big.
But maybe this is because we're actually just.
starting to probe the fact that gravity itself has a finite range, has a finite range
maybe in space, but what's even more relevant is that it has a finite range in time.
So it's sort of a little bit lazy, just a tiny little bit lazy.
After 14 billion years, I think you can forgive it if you want to say, okay, enough with this
vacuum energy.
I've been carrying it along.
Maybe it's been much longer than that.
We don't know.
Maybe the universe is even older than that.
and has been carrying this vacuum energy
and taking it very seriously for such a long time
and maybe not saying,
okay, enough, I'm a bit tired out.
I'm not going to let it affect me as much as Einstein wants it to be.
Let me just relax a little bit.
And slowly the effect of this huge vacuum energy
could not be so important on the curvature of space time.
After some time, after billions and billions of years,
the effect could be weakened out a little bit.
And so these are just words.
But to make that concrete,
if we think of gravity as being the propagation of a spin-two particle,
and I don't really want to mess up with that
because we have observed gravitational ways
because there's so many fundamental aspects
that really rely on this,
I don't want to mess up with that too much.
the one thing I can think of investigating,
which Appriot doesn't seem like completely crazy,
is to wonder whether this particle could have a mass, actually.
And this is not completely crazy because we do know, actually,
from the Higgs mechanism, that fundamental particle that carry a mass,
sorry, that carry a force can have a mass.
That is the case of the W and the Z boson.
They are actually spin one particles.
They carry a mass and they carry a force, which is the weak force.
And maybe we're not all very familiar with the weak force.
It's not something I think.
Well, I do spend my day thinking about my one or not thinking in my everyday life.
Because it's a weak force.
And the reason it's weak is because it's been propagated by very massive particles.
The W and the Z bosom, they are very massive particles.
And so this is just to give you a little bit more intuitively how the Higgs mechanism that can give a mass to fundamental particles, for instance, to the W and the Z boson, are related to the fact that it weakens some of the forces.
It weakens the force mediated by this particle, in this case, the weak force.
And you can think of that because if you have a massive object, this is an analogy.
is not exactly like that.
If you have a massive object,
then by massive, I mean, alas, inertia,
then it will be harder to drag it along.
So it's not going to be,
if you give it a kick,
it may not want to go along until the end of time.
You may want to stop at some time.
This is an analogy.
That's just an analogy.
Okay.
Metz-Strasler will be very upset with us
because he doesn't like those analogies
and he was just on, but that's okay.
I think it does convey exactly what you're trying to get to, yeah.
So this is just an analogy to say that effectively if I want to weaken out gravity,
but I still want to think of it at the particle level and I still want to think of it as a spin-two particle,
then one of the things I can start thinking about is to give it an inertial mass.
So rather than being a massless spin-two particle as in Einstein theory of general relativity,
it can be perhaps a massive particle, as in massive gravity.
And massive gravity doesn't mean that gravity is genomic.
It just means that the particle that propagates it is massive.
It has an inertial mass.
So that is the idea behind what we're trying to do.
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Hey, everyone. It's Cal Penn.
I'm the host of Earsay, the Audible and I Heart Audio Book Club.
This week on the podcast, I am sitting down with Ray Porter,
the narrator of Andy Weir's audiobook Project Hail Mary,
massive sci-fi adventure about survival and science,
and what happens when you wake up alone very far from Earth?
I really had to make a decision because I caught myself getting that frog in my throat
and starting to get teary as I'm narrating some of these sections,
and it's like, okay, yo, yeah, yo, is this indulgent?
And I really thought about it.
I was like, no, at this point it would kind of be betraying the trust,
the author and the list.
have in telling this story if I don't go through it. But there's places in this book that
deeply emotionally affected me and I left it on the mic. That's great. Because it served the story.
People will say like, oh my God, I cried at the end. It's like, yeah, dude, me too.
Listen to Eursay, the Audible and IHeart Audio Book Club on the IHeart Radio app or wherever you get
your podcasts. But as we said before, you know, the particle physicists out there, the
quantum field theorists such as yourself have to struggle with a million constraints that nature
puts on you. So is it easy to imagine, oh, let's give the graviton a small mass, or do you have
to work very hard at this? So you're leading the question. I know the answer to this one, yes.
Yeah, if it was easy, I wouldn't be there to talk about it. It would have been done on day one.
I think thinking of this type of things,
thinking about at the very least what it means to give a mass to a spin-to particle,
that is something that is not, I mean, motivated as something which is quite natural.
And so people naturally have tried it very early on.
Fierce and Pauly have tried it already in 1939.
So now it's almost 100 years ago.
But it's important.
That's Wolfgang Pauly, the same guy behind the exclusion.
principle. He tried to give the graviton a mass. Yes, they tried that very, very early on,
because it's such a natural thing to do. Really, it's not, it's not extravagant if you think of it
like that. It's very much from the particle physics point of view. You can try that. And if the
mass is sufficiently small, it should be identical to general activities. So let's try it and
see how big the mass can be. That's a very natural question. It's a very innocent question.
It's a very phenomenological question in some sense.
So let's try that.
And already then, already,
Wolfgang Pauley and Marcus Fiatts tried that in 1939.
And one thing they realized was that if you think of the,
if you think of gravity as being propagated by spin-to-particle,
it has in the manifestation of the waves of this field,
if you think of gravitational waves, for instance,
He has different polarizations, just like the polarization of light.
Light has two polarizations, and if you had polarized sunglasses, you filter out one polarization
and just see the other one.
And the same thing happens for gravitational waves.
I don't think we're going to have polarized sunglasses for gravitational waves very soon,
but you can think of the polarizations of gravitational waves as well.
And gravitational waves have two polarizations.
The fact that the same number as light is just an accident.
of four dimensions, in high dimensions, it would be different, but so bad.
Those two polarizations, as you mentioned, when we think of the gravitation where observatory,
they have these two tubes at a 90-degree angle.
We can think of one polarization will fluctuate in one particular way, and then the other
one it will cross 90 degrees from that.
I don't know if people are familiar with the plus and cross polarizations.
I think 45 degrees, right?
Yeah, sorry.
Absolutely, 45 degrees.
Yeah.
So a plus sign and an X, 45 degrees apart.
That's right.
That's right.
Exactly.
Sorry.
So those are the two polarization of gravitational waves according to an
theory of general relativity.
But if the particle that mediates gravity had a mass, if it was a massive graviton,
you could actually have additional polarization.
And some of those polarization wouldn't be just transverse to the line of propagation of the gravitational waves.
They would also be along the line of propagation.
Some of them would be longitudinal propagations.
So if you think, for instance, of sand waves, sand waves, they are very, well, there are waves.
They're not fundamental particle.
They're not fundamental waves.
But they're still waves.
Those are much more longitudinal waves.
their compression of the air along the line of propagation.
So those are longitudinal waves, and that's how we hear.
That's how we, they have very familiar waves.
So in principle, if you consider a slide modification of gravity,
and if you add a small mass to the graviton,
you could have those additional polarizations,
these are additional channel of propagation,
additional channel of communications of gravitation,
waves.
And what's quite interesting is that it doesn't, in principle, it doesn't matter how small
the mass is.
It could be extremely small.
It could be smaller than anything you could ever measure.
But conceptually, it doesn't make a difference on whether it is zero, exactly zero,
and those polarization are not allowed to be there.
There's a symmetry reason.
The underlying symmetries that Einstein relied on, which tells you those extra polarization
are absolutely forbidden.
and if the mass is infinitesimal,
so just tiny, tiny bit there, or if it's large,
but as soon as you have the possibility of a non-zero mass,
then you open up the possibility of these additional polarizations,
additional channel of communication.
So the, let me call it a force.
I'm going to provoke people,
let me call it the force of gravity would then have new ways
of communicating between any two things,
I need two objects in the universe.
And that changes in principle things dramatically, absolutely dramatically.
One thing I should say, though, is that that already seems like a problem, a problem from observations, but it gets worse.
That may be a problem in the sense that maybe if you're unlucky or even if you're lucky,
this doesn't, it may not be, the observables may not be the same as what you would have expected from general activity.
That's one thing.
But the more problematic in that is that gravitational waves are not just innocent waves.
They actually fluctuation in space and time.
So when they propagate, they do affect the flow of space for the standard gravitational waves.
But if you have additional polarization, they can also start messing up with the flow of time.
And there is this connection between time and energy.
and if you start messing up with that,
you end up with some polarization which have negative energy.
We call them ghost.
And so some of this longitudinal mode,
they're actually ghostly.
They are modes which have negative energy.
It costs them a negative amount of energy to get produced,
which means they will get produced,
whether you want it or not.
They will be there.
And not only they'll be there,
they will enjoy being as big,
as large as possible,
and dominating the whole world
and destroying the whole world,
and destroying the whole structure of reality along with it.
Yeah, I wrote a paper about that once.
I think that people are a little bit,
is once again a constraint that you have to worry about, right?
Like you invent a new theory, you think it's all fine,
but then you realize it causes instant doom for everything in the universe,
which is bad.
That's right. That's one. That's one.
And so Fiatz and Pauley in 1939 knew that.
They already knew that.
And at the time, they were just looking at a theory
at what we call the linear level.
So the first effect around flat space time,
they didn't even think too much about doing something
which is fully gravitational
and looking, for instance, at the curvature in the solar system
or anything like that.
Let's just think of the simplest thing we can think of,
just gravitational waves living on flat space time.
And already there, they realized there was this huge problem
related to the negative energy of some of the modes,
what we call ghost.
and they already had to work very hard to make sure there wasn't any such pathology occurring around that very simple case.
I just want to let everyone know.
You said it, but it went by very quickly.
Particle physicists called these negative energy particles ghosts, which is very funny.
That's right.
That's what.
That's wrong.
And so it sounds like I'm just making up things.
There's even little doodles of ghosts in your book.
I know.
Yeah, this is actually the correct scientific terminology.
Believe it or not, they are called ghosts.
That's the way we call them.
They are different, let me just say, they are different from other type of instabilities
you may have heard of, like tachyonic instabilities.
Tachyonic instabilities, you can argue, for instance, the Higgs in its past,
you underwent a period of unstable phase where its potential got to change
and the potential was unstable for a little bit
until the Higgs found a new vacuum,
a new grand state.
Takion can exist,
and maybe they're not very comfortable with for a given time,
but we know how to deal with them.
They're okay.
Ghost are really negative kinetic energy phenomenon,
and that is beyond uncomfortable.
It's simply unviable.
Okay, so,
why do we still need to keep talking? Why can't we just say it didn't work? We failed.
Okay, so this is where it becomes interesting. At the linear level, as described by Fierce and Polly,
they could make it work, actually. They could make it work. But quickly, not quickly, actually,
in the 70s, it was realized that that wasn't good enough because the world is not just flat space time
with small ripples living on top of us. We are there. We have curvature.
around us.
And perhaps even more so, you could have the other polarizations of gravity coming in into
massive gravity, and we haven't observed them yet.
So what is going on?
And what was realized is that it wasn't sufficient just to do the analysis in the way
that Fierts and Pauli did it, which was what I'll call a linear theory, a perturbative theory.
It had to be a fully-fledged nonlinear theory of massive gravity to make sense, something
completely non-linear.
Einstein theory of general relativity is a fully-fledged full theory.
Okay, we don't know the full quantum theory of gravity,
but it's an effective quantum phenomenon,
and it's a very non-linear phenomenon,
and we can describe some very non-trivial phenomenon,
like black holes, and like the evolution of the universe,
and like the solar system,
and very, very non-trivial systems in there.
And so in order to pass any tests,
we need to be able to do the same thing for massive gravity,
and so we need to do it to,
to think of a theory of massive gravity at the non-linear level, fully-fledged non-linear level.
And this is where the complication came because it seemed very, well, it seemed, let me just say it,
it seemed impossible at the time to make it work.
And not only impossible, but people came up with all sorts of argument in showing how this
would never be the case.
There was what we call no-go theorems that are really, as the name is said, as it states,
It's a theorem that tells you there's no way.
No go.
Impossible.
There's no go.
And there wasn't just one no go theorems.
There was at least six no go theorems in different ways.
We're showing in that language, in that language, in this way, in this formulation, it's impossible.
So stop talking about it.
Let's move on.
And so I never, it's not like I came in and say, okay, I'm going to, I'm going to want to challenge everybody and make everybody hate me.
It wasn't like that.
actually, with Gregory Gabarazzi, independently, but actually at the same time, we were working
on models with extra dimensions, and in the way gravity leaks into the extra dimension, it did
look like from the four-dimensional point of view as a theory of massive gravity.
And in that case, we saw that the problem is that people were talking about didn't manifest
themselves. They didn't manifest themselves in higher dimensions because it was actually gravity
in higher dimensions. But they didn't manifest themselves in four dimensions either. And I was sure
we were making a mistake. So we spent ages and ages just going back and forth and trying to
understand. And of course, he was relying on extra dimensions, but all of that formalism
could actually be captured just from a point of view of four dimensions. And all of the
arguments was claimed until then should have applied and the no-go should have been preventing
us to define the result that we were finding. So that seemed very controversial. Well, that seemed
very unlikely. And the most likely reason was that we made a mistake. So we spent ages,
but really ages going back and trying to see where we made a mistake until we realized that
there was actually no mistake in what we've done. It's just that all of the no-go's theorems
you have a no-go, but there's always some level of assumptions that go beyond it, underlying it, I should say.
And maybe one of the most common assumption, it wasn't just that, but one of the most common assumption was that, at least to start with in the 70s, wasn't to chart all the possibilities, because this is really very hard to do every possible case.
So what one can do to start with is you look at a given region.
You look at the way things are in a given situation.
And from there, you extrapolate, assuming things are never going to look too different
if you charted the whole allowed region of possibilities.
But that's sometimes also a bit circular because you'll never know if something different can happen
if you haven't actually gone further and looked for other things.
So that was one of the reasons was some of the no-go theorems that were developed.
There weren't exactly no-go theorems for all possibilities.
There were no-go-therms for the simplest models,
and then that was extrapolating to lots of models thinking,
surely there's nothing else to think about, but actually that wasn't quite the case.
But the upshot is that you now think that you have a way to give the graviton a really tiny mess.
That's right. That's right. That's right.
So with that, that really pushed us to understand much more what was going on with these no-goes
and then to come up with a fully-fledged four-dimensional, not relying on extra-dimensional,
four-dimensional theory of massive gravity, which evades all of those problems related to these ghosts,
to these instabilities.
And so where the graviton could in principle have a mass, have an inertial mass.
So it comes with lots of possible signatures.
It comes with lots of features which are also in themselves quite uncomfortable.
which we need to deal with.
It's not a perfect theory by any stretch of imagination.
But no one would expect that.
And if it was too comfortable, if it was too close to GR,
it wouldn't play any role either.
We want to have it something quite different.
We want it to, the way it interacts with the rest of the world,
has to be slightly different, particularly for cosmology.
That is a good feature in some sense.
If we can allow ourselves a simple cosmological constant
and something which has a lot of symmetry,
not to affect space time in the same way as he would do in GR.
It makes it much more complicated.
That's exactly what I want to get to,
because I know that we're going to run out of time here very soon.
Tell me how we would ever know the difference between your theory
and Albert Einstein's theory.
I won't even remark on the chutzpah of trying to compare.
But what is the observation or experiment we could do?
Okay, so very good.
So there's different things that can happen.
thing is with gravity being general activity or massive gravity is that they are fully fleshed
theories. So it's not like you can just have one observation. There's a multitude of observations,
just like general activity has black holes in the solar system and the cosmology and the bending
of light, all of those things. And all of those things have to be consistent with one another.
And the same thing has to be true for massive gravity. So there are lots of different things that
can, that should happen, that can happen.
And some of them will be observable.
Some of them will not.
One of the simplest thing to think about, if we go back to gravitational waves, is in the
way they propagate.
So in the way we build the theory of massive gravity, it is such that when gravitational
ways I emitted, for instance, from black hole mergers, they are still very like those
of general activity.
So you're not going to produce many of the other polarizations.
Okay.
But you're still going to produce the same ones as in general
activity. However, if gravitational waves are massive, then those at low frequency will be more affected
by the mass and will start propagating at a slightly lower speed than those at a higher frequency
that travel close to the speed of light. So the gravitational waves that have been observed by
LIGO so far, they're relatively high frequency compared to the mass of the graviton so far.
And so even though we have strong reason to believe that within the realm of what
we have observed all the frequency travel at the same speed roughly.
So there's no distortion of the signal.
And that speed, more or the less, is very close to that of speed of light.
We have observed that from the neutron star merger,
that they travel very close to the speed of light in one part to the 10 to the 15.
So this doesn't put yet a very strong constraint on the graviton mass.
It puts a constraint on the graviton mass that it has to be smaller than roughly 10 to the minus
22 electron volt or so.
So just for comparison,
what we have in mind is a gravitan mass, which is of the order, again, I'm going to have different units.
I grab it on mass, which is of the order of the Hubble parameter today, so 10 to the minus 32, 33 electron volt,
because that's the size in distance, that's the size of the observable universe today.
The Hubble parameter today, roughly, people would see, we know that in terms of kilometers per second per megaparsecs,
but I'd like to think of it in terms of electron volt.
Yes, me do.
the herbal parmeter today is roughly 10 to the minus 32 electron volts.
So we want to gravite on mass,
which is roughly of that order of magnitude.
And the current constraints from LIGO and from Newton star mergers,
multi-messinger are roughly 10 to the minus 22 electron volts.
So we're still within a 10 orders of magnitude margin.
That's good.
That's fine.
But as we go and observe gravitational waves,
which are much lower frequency,
then we can hope to put better constraint on the gravitational mass.
And maybe if one day we were able to observe gravitational waves
with a wavelength as long as the whole observable universe today,
then we could actually tell whether gravity is massive or not,
that that would be one way.
So for instance, if we were able to observe primordial gravitational waves,
gravitational waves that have been emitted at the very beginning of the universe,
and propagating throughout the age of the universe to us,
and they would have an imprint, for instance,
on the cosmic microwave background, on the CMB,
through B-mode polarizations.
So if you were able to observe B-mode polarizations,
and you were really sure that they came from primordial gravitational waves
and nothing else,
and if you were able to observe the power spectrum of these B-mode polarizations,
then you should be able to say whether it's consistent,
with general activity or whether it's consistent with massive gravity.
For massive gravity, at low frequency, you would have a plateau as opposed to a production
of gravitational waves because the mass would inhibit the production of the gravitational waves
unlike in massive gravity.
So that's a possible way.
Yeah.
So it does seem very testable, very constrainable.
Is it, do you get a benefit from giving the graviton a mess?
Did you actually explain why the cosmological constant is small?
That is the hope, right?
That is the hope.
So I can do a back-of-the-envelop calculation.
This is not me, but that's the origin motivation,
which would take two lines based on linearized gravity.
And I say, yes, if I come in myself,
I can think of gravity, the effect of a cosmological constant on gravity
would be tuned down after a while,
and therefore I can explain observation.
In reality, to make that work in the real cosmological setup is extremely challenging.
And it is extremely challenging mainly because the typical cosmological solutions that we have,
the way we construct them in general activity, that doesn't work anymore for massive gravity.
That is a huge challenge.
I would say it's perhaps people who disagree.
I would say, actually, this is a good sign.
It's a sign that it's not working quite the way you would have expected in general activity.
You didn't want it to work in the same way as in general activity.
We don't want it to have a simple relation between the cosmological constant
and having homogeneous and isotropic universe with a huge acceleration
because then you won't do anything.
So you want this correspondence to change a little bit.
But that's also the gift and the curse.
Okay, it has changed.
that has happened.
But into what, I don't know.
And I really don't know.
And what I can tell you is that it's extremely challenging.
And probably the fact that it's so challenging would tell us that we can't do it at the
end of the day.
But I don't know.
Well, but you've already explained how there were literally theorems that convinced people
that this whole thing couldn't work.
And we found loopholes in the theorems.
So that motivates us when we have such a big puzzle like the vacuum.
energy like the cosmological history more generally, let's explore the different alternatives.
Exactly, exactly.
That's exactly the way we think about it.
And I would say with that in mind, I would say we are in a much better position now because
rather than having an answer that we weren't even allowed to question before, now we have
a question that I can't answer for you.
But I think that's much better.
Well, that's good.
And I hope that we at least help some people be more convinced that gravitation.
are real things and we don't know all their polarizations,
but we're learning a lot more about them.
That's what.
That's all.
So, Cloudy, Duran.
Thanks so much.
Lots of things to do.
Lots of things to do.
Never a dull moment around here.
So thanks so much for being on the Mindscape podcast.
Thank you very much.
Pleasure.
Thanks a lot.