Into the Impossible With Brian Keating - He Used Quantum Entanglement to Explain Where the Aliens Are [Ep. 490]
Episode Date: May 4, 2025Consensus is the AI powered results engine I use every day in my research. Visit https://bit.ly/ConsensusApp and sign up for one year for *FREE* with code KEATING25 just for listeners of The INTO THE ...IMPOSSIBLE Podcast! What if the best person to solve the mystery of alien communication isn't a SETI researcher or a radio astronomer, but instead a theoretical physicist trained in the deepest notions of physical law, symmetries, and quantum field theory? Well, today, I’m joined by Latham Boyle, a renowned theoretical physicist exploring the fundamental symmetries of the universe and developing new ideas to understand how the universe began. But his research goes beyond that—he’s also tackling one of the greatest mysteries of all time: the Fermi Paradox. After explaining everything we need to know about symmetries, Latham shares his bold theory of a mirror universe, where the cosmos is symmetric across the Big Bang, and how that could explain the strange silence from the stars. We explore how this radical idea might reshape our understanding of dark matter, the origin of the universe, and why advanced civilizations might be using quantum signals we’re simply not equipped to detect. What if we’re not alone, just looking in the wrong way? — Key Takeaways: 00:00 Intro 02:29 Explaining symmetries and CPT symmetry 05:07 Theoretical framework and observational evidence 09:49 Symmetry violations 12:56 Possible alternative explanation of the early universe 40:55 Quantum entanglement and the Fermi Paradox 51:14 Technology of biological material? 56:29 Outro — Additional resources: ➡️ Follow me on your fav platforms: ✖️ Twitter: https://twitter.com/DrBrianKeating 🔔 YouTube: https://www.youtube.com/DrBrianKeating?sub_confirmation=1 📝 Join my mailing list: https://briankeating.com/list ✍️ Check out my blog: https://briankeating.com/cosmic-musings/ 🎙️ Follow my podcast: https://briankeating.com/podcast — Into the Impossible with Brian Keating is a podcast dedicated to all those who want to explore the universe within and beyond the known. Make sure to follow/subscribe so you never miss an episode! Learn more about your ad choices. Visit megaphone.fm/adchoices
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What if the best person to solve the mystery of alien communication isn't a setty researcher, a radio astronomer, or even an actor, an actress?
But instead, as a theoretical physicist trained in the deepest,
notions of physical law, symmetries, and quantum field theory.
Well, today I'm speaking with an expert Latham Boyle, whose day job is to explore the fundamental
symmetries of the universe and perhaps develop new ideas to understand how the universe began
and how it would relate to the groundbreaking data that new experiments like the Simon's Observatory and others are coming up with.
But he has even more to his research repertoire than just that.
Perhaps the answer to one of the greatest paradoxes of all time, the firm
The universe teams with life, where are the aliens?
I think you're going to love the deep dive that we go into and solving perhaps the physics
of communicating with aliens and solving the Fermi paradox once and for all.
So, Latham, thank you so much for joining us today from Edinburgh.
Oh, well, thanks so much for having me.
It's a pleasure to speak with you.
Like I said, I've wanted to have you on for quite some time.
We had your colleague Neil Turak on for his second appearance just recently.
I do want to get to that topic of the Fermi paradox and your unique kind of solution to it,
which resonates with a completely different part of my brain than any of the resolutions that I've heard before.
But as I said, before we get to that later on in the interview, I really want to understand what drives you working on these deep mathematical mysteries and uncovering and maybe predicting new structures that ties all your research together.
It seems like you have a thread that goes through it.
And it's asking these big questions.
How did you get here?
How did you get to this kind of unique position where you could be as conversion talking about
mirror universes as the Fermi paradox. I don't really think of myself as an expert on the Fermi
paradox. There's a lot of people who are much more expert on it. I just realized one thing that hadn't been
pointed out about it that seemed important to me. I just, I guess I've worked on the things that
struck me as the most fascinating. And I find that if I work on what I'm most interested in,
that I'm much more productive. And if I try to work on what someone else is interested in, I'm
incredibly unproductive. I just end up wandering around to whatever. I think that's the best I can tell you.
I don't know exactly why the particular topics I'm interested in have grabbed me.
Let's talk about this, the mirror universe.
And first of all, let's define some terms for the audience that might not be as familiar with your research.
What are symmetries?
And in particular, what is the importance of CPT symmetry and its violations?
Well, symmetry in general refers to any change that you can do to anything that leaves it the same.
So the most famous example is mirror symmetry, where if you reflect something in a
mirror and it looks the same. Another example would be if you have a cube, all the different ways
you can rotate the cube that, you know, if you rotate it by 90 degrees about any axis,
connecting two opposite faces, that'll carry the cube into itself. But the laws of physics have a lot
of symmetries. That seems to be the most basic principle we know. That's emerged over centuries of
research as kind of the organizing principle for how the laws, as we best understand,
them can be described. They are the laws that have such and such symmetries in which the constituent
fields and particles transform in such and such a way under those symmetries. In particular,
CPT symmetry is believed to be an exact symmetry of the laws of nature, and it's the symmetry where
you reflect a process in a mirror, and then run it backward in time, and then also replace every
particle by its antiparticle. And if you do any of those three things by itself, it's not a
symmetry of the laws of nature. But if you do all three of them together, it is. And that's believed
to be a symmetry of the law of nature. It's believed to relate any microscopic process to another
related microscopic process that has the same amplitude, people say. The amplitude is the
quantum mechanical quantity that you calculate from quantum mechanics and then you square it to
at the probability of that process happening. But the universe as a whole, if you just look at the
portion of the universe after the Big Bang, doesn't naively seem to have that symmetry. It seems that
there's a particular going one direction in time away from the Big Bang, where the universe
expands and cools, is very different than the other direction in time where it gets hotter and you
go back toward the Big Bang. So that was one of the things that led us to this alternative picture
that we've been getting more and more excited about over the past few years is developing a
picture of the cosmos in which it actually does respect CPT symmetry and then trying to understand
what a model like that can explain about the observed cosmos and what it can predict for future
experiments. With Neil, was there sort of an exact moment when you both realized the math was
pointing you to somewhere, someone would say pretty radical? I don't think there was. I think there
have been a lot of steps along the way. Theory really didn't fall into place all at once, and really
it still hasn't completely fallen into place. There's still a lot of stuff we don't understand.
But I guess maybe the starting point was that I think we had both come to the view that the
dominant theory of the early universe, the inflationary picture, I guess we both have had the gut
feeling that it probably was not correct. According to that picture, if you look
back toward the Big Bang, well, when we look back toward the Big Bang, we see that as we look
further back, as we look back close to the bang, as far back as we can look, we see that the
universe becomes dominated by radiation, by a plasma of hot particles and photons. But according to
the inflationary picture, if you look even further back, that radiation-dominated era would
end, and there would be an earlier period, the inflationary period. But because we began to suspect
the inflationary period didn't exist. We began to think about, well, what if the radiation
dominated period just extended all the way back to the Big Bang? And when you do that, that solution
to Einstein's equations for gravity just naturally extends through the Big Bang and is symmetric
around the Big Bang. And so it has this property. It can be extended through the Big Bang. And then once
you do that, you find it can be symmetrically flipped, reflected through the Big Bang. So
that the portion after the Big Bang gets swapped with the portion before the Big Bang.
One's first inclination is to say, oh, maybe that's just a mathematical artifact
and to not really pay attention to it.
But, you know, historically, it's usually not a good idea to do that.
Time and again, if the laws of physics tell you something,
the best laws you know at the time seem to, you know, have a solution with such and such
a striking property. You know, it's usually a good idea to at least take it seriously and see where,
or at least see where taking it seriously leads. And so I think that was kind of the start, is that we began to
think about, oh, what if we did take that seriously? What if it's not just an artifact? What if it's a real
hint? And then, yeah, that led to the us to realize, wait a minute, actually, if you do that,
if you just, then to be consistent, there should be a reflecting boundary condition at the Big Bang,
which is like, if you look at an ordinary mirror, the reason you see an image of yourself on the
other side of the mirror is that the electromagnetic fields, the silver atoms on the mirror conduct
electricity and they force the electromagnetic fields at the mirror at the surface of the mirror
to satisfy a special property called a reflecting boundary condition and it makes it look like
there's another copy of you on the other side of the mirror. We realized if the universe really is
symmetric about the bang is that as the solution I just mentioned seems to suggest, then the
fields there should satisfy a reflecting boundary condition. But then we were just struck, wait a
minute. Actually, a reflecting boundary condition is exactly what the observed primordial perturbations do
satisfy. You have worked on cosmic microwave background experiments. You've done these great
experiments that measure in detail the properties of the primordial perturbations by measuring this
snapshot that the universe took of itself, 370,000 years after the Big Bang. That's cosmic microwave
background. The most famous thing about that snapshot is that if you plot power spectrum, you see
this beautiful ringing curve with peaks and troughs. And if you just ask, why is there that ringing
spectrum? Why does it make that kind of sinusoidal pattern and why are the peaks and troughs
precisely where they are? Well, there's a usual way that's described in inflation. In inflation,
it's described by saying that there was a period of inflation and cosmological perturbations
got dragged outside the horizon and froze, that's what set their initial conditions.
And then because they all froze together, then once they started oscillating, they all
oscillated in sync with one another. And that's what created the ringing pattern in the CMB.
Another way to say it is just that if there was no inflationary period and you just
follow the radiation dominated epic all the way back to the bang, the exact same thing
is just amounts to the statement that those perturbations satisfy a reflecting boundary condition
at the Big Bang. That's what synchronized in exactly the way that we see. Those two starting
observations were the thing that really got us excited, really thinking like, wait a minute,
there might be a simpler explanation for what's going on, and we should think more about it.
And yeah, when I, you know, talk to Neil about this, I said, you guys in Edinburgh right now
should be more conversion than almost anyone in the universe.
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First about the importance of symmetry breaking, because, of course,
Peter Higgs, the late great Peter Higg.
Isn't it true, though, that most of the interesting, you know, facts about our universe owe their existence to symmetry violations?
I mean, if there were equal amounts of matter and antimatter, this would be a tough conversation to have.
So how do you reconcile that, you know, kind of the existence of theoretical physicists with a perfect symmetry?
Or is there perhaps a hint that maybe even sacrosanct, you know, principles like CPT might get violated at a critical condition, say, near the origin of our universe?
Well, on the one hand, you know, if you can really summarize the progress in theoretical physics over the past few hundred years in one word, it really would be symmetry, that there are these fundamental governing symmetries that seem to essentially define what the laws of nature are.
And in a sense, learning the laws of physics has essentially amounted to learning from the observations what the right symmetries are.
what are the actual symmetries governing the fundamental laws in our universe?
Then, yeah, there's the symmetries in the laws of nature,
and then there is the actual state of the universe, which is not necessarily as symmetric.
That's the first distinction I would draw,
is that these symmetries, gauge symmetries that define the standard model,
SU3 times SU2 times U1 is gauge group of the standard model.
That could very well be exact.
I suspect that is an exact symmetry.
Well, who knows.
But anyway, as far as we know, that's exact.
And the basic symmetry of Einstein's theory of gravity is a symmetry called diphomorphism invariance,
basically the symmetry to choose different frames of reference,
different observers at different places in the space time can all choose different frames of reference.
And that could very well be exact also.
Then the state of the universe itself can violate those symmetries.
But there, again, it's a very fascinating interplay because if you look back,
in the early universe, the state of the early universe was vastly more symmetric than it is today.
I mean, today it's this very inhomogeneous place where there's some places where it's very
dense and a lot of interesting stuff is going on like here on Earth. And then there's other places
deep and avoid where there's almost no matter. It's almost pure vacuum and nothing's going on.
But then if you follow it back to early times, the state of the universe got very symmetric,
very homogeneous and isotropic, almost perfectly so. But then there was, like you say,
there were these tiny little deviations from that perfect homogeneity and isotropy, tiny little
perturbations, which ultimately were responsible for everything interesting that happened. I mean,
they grew into galaxies and planets and ultimately, you know, led to, you know, at least in our neck
of the woods, things coming to life and, you know, everything interesting. So somehow the interplay of
those two things, I think is not very well understood, but it's what it's all about. I agree with you.
You mentioned life forms, and we have to get to the Fermi paradox to answer the question if there are
other life forms, and if so, why are they concealing themselves so effectively? We'll get to that,
but I do want to go through some of the, you're gracious enough to prepare some slides for advanced layperson
level, and I think it would be good to kind of go into those to kind of, I like to avoid, you know,
too much overproduction, but to understand what a CPT symmetric mirror universe concept.
really would imply and why we might want to find such a universe or look for it, at least
in the context of, as you mentioned, the experiments like our Simon's Observatory.
So why don't we share your screen now?
I'll try to introduce the basic idea and why we've begun to take it more and more seriously
as a possible alternative explanation of the early universe.
My subtitle here, what is the simplicity of the early universe trying to tell us?
So let me give you the gist.
So here's a cartoon picture of the expanding universe where time,
Tau, the conformal time, Tau runs up the slide.
The cartoon shows a picture of the universe that's like an inverted lampshade or a cone with its tip cut off with a kind of small circle at the bottom, the very small early universe, expanding as we go up the slide to a large circle at the top, the big universe we live in today.
We're sort of standing at the top. We're living on that big circle at the top.
And we look back with our telescopes toward the tip of the cone, but we can't see all the way back.
The universe becomes opaque.
If we try to look too far back, the universe becomes too dense and it becomes opaque.
So we can't see all the way back to the bang, but we can see very close.
We can see rather directly to a few hundred thousand years after the bang, the cosmic microve background that you and your colleagues have been measuring better more and more beautifully over the years.
And then more indirectly based on, but still with quite good certainty, we infer or see in quotes back to a
fraction of a second after the bang. And in either case, what we see is very striking for its
simplicity. In summary, the simple fact that's been observed is that the closer back you look to
the Big Bang, things get simpler and simpler in all ways that we've thought to check. So that
includes, first of all, if you look at the background universe, it's almost perfectly symmetric,
homogeneous, isotropic, and spatially flat.
So homogeneous just means, so if we took a snapshot of the universe,
a fraction of a second after the bang,
if you moved from one point to another in the snapshot,
the conditions are virtually identical from one point to another,
same temperature, same density.
And isotropic means if you looked one direction in the snapshot
and then turned and faced in a different direction,
things again would look identical to you in either direction.
And then also the geometry of the snapshot,
shot is flat, just like flat three-dimensional space. The four-dimensional universe is curved
because of Einstein's equations, but the three-dimensional slice of the universe, well, it could
have been curved, but it's observed to not be. Observationally, we know that it's almost
perfectly flat. So much for the background, but then if you zoom in, it's like if you looked at
the earth from very far away, if you see a picture of the earth taken by a satellite,
a far away in the solar system, it looks like an almost perfectly round, smooth marble.
but as you get closer to it, you see that there's tiny, you know, you begin to see, oh, there's
actually peaks and troughs, mountains and valleys, bumps on the sphere. And it's like that in the early
universe, too. It's almost perfectly symmetrical. But if you look closely enough, there's tiny
perturbations in the temperature and density as you move from one place to another. Those are of order
10 to the minus five, in order a few parts in 100,000. Very, very tiny. But they, too, turn out to be as simple
as possible. They're as simple as they can be, again, in every way that people have thought to check.
In particular, I've given three more properties here that they are found to satisfy. They're purely
scalar perturbations, meaning it's purely perturbations in the temperature and density from place to place.
There's no evidence for any vorticity or primordial gravitational waves in the early universe,
which are the other two types of perturbations that could have been there.
Then we should say, yeah, I mean, there could be evidence.
So far there's no evidence for anything but purely scalar density perturbations. That's a good point. Yeah,
the same goes for all of these things. The second point is that so far they seem to be their correlations,
the statistical correlations between the perturbations at one point and another seem to be described
by purely Gaussian, nearly scale invariant correlation functions. No evidence for any violation of
Gaussianity or of a pure power law in the correlation functions. And then finally, as I mentioned,
And the third way in which they're special is that the phases are all perfectly in sync with one another.
And indeed, they're synchronized exactly in such a way that as you follow them, if you think of any of the perturbations, as you follow the universe forward in time, they oscillate in time.
But if you follow it backward in time, all of the perturbations in the universe, if you imagine splitting them, we call it Fourier decomposition.
If you imagine splitting this field of random perturbations into each separate wavelength of perturbation
and following each wavelength separately, each wavelength is oscillating in time,
but if you follow it back, they're all simultaneously reaching their maximum of their oscillation
right as you get back to the Big Bangs.
Physicists will recognize that as a reflecting boundary condition.
That's called a Neumon boundary condition that they satisfy and that's responsible for the
oscillating pattern we observe in the CMB, like I mentioned before. That was one of our early
motivations for taking seriously this picture that the Big Bang is a mirror. What is the usual story
in early universe cosmology? So the hint is that the closer back you look to the Big Bang,
the simpler things get. That's the sort of fundamental clue that we're given. And the goal,
the central topic in early universe cosmology, is to understand that hint. What is it trying to tell
us? According to the conventional picture, the idea is the following.
The conventional picture is, okay, it's true that things get simpler and simpler as you go backward in time all the way back to a fraction of a second.
As far back as we can see, things get simpler and simpler.
But if, according to the standard story, if you could see even further back, you would discover that trend was an illusion.
That if you could see back even further, you would see that even earlier there was a big mess, a very inhomogeneous, messy universe with,
maybe giant fluctuations in the curvature and temperature and density from place to place,
a very chaotic beginning.
And according to that view, the goal of the theory of the early universe is to explain how that
messy initial state got transformed into the pristine symmetric simple state that we actually can see.
And so the idea of inflation is basically that there was a period in between those two,
in between the mess and the simplicity,
that there was a period of very rapid exponential stretching of the universe.
And effectively, that stretching has the result
that when we look back, our past light cone,
the portion of the universe that we can see using our telescopes,
effectively gets zoomed in on such a tiny piece of the mess
that we can't see how messy it is.
We end up just seeing a tiny little speck of the initial mess.
messiness that has been stretched out so much that we can't see what a mess it was part of. It looks
like the simple state we see. That's the usual story. But, you know, Neil and I were interested in
taking, you know, seeing if we could take the observations more at face value. You know, as far back as we
can see, it looks like the further back you look, the closer to the Big Bang you look, the simpler
things get. Maybe the universe is just trying to tell us that that's what's going on. For some reason,
as you follow things back to the bang, things get extremely simple in the way that we observe.
And, you know, yeah, maybe what we should do is just try to take that observation at face value and see where it leads.
As I mentioned, so if you do that, then, well, we know what the solution of Einstein's equations looks like in the very simple early phase that we can see.
And if you just take it seriously, then it has this property that you can analytically explain.
extend it, it has a very particularly simple structure where the full metric of space time,
the shape of the space times is very simple. It's just flat space, but times an overall scale
factor or conformal factor that stretches the universe with time and does it in a particularly
simple way. It's just proportional to the conformal time tau itself. And so unlike most
singularities in general relativity, so if you follow this solution back, you know, you eventually
get to the tip of the cone, the place where the conformal factor, the scale factor, touches zero.
So that's an example of a singularity.
Most singularities in Einstein's theory of gravity are a mess.
You can't analytically extend the space time through them.
But this one is very special in that regard, because the singularity is purely a momentary
vanishing of the conformal factor in.
front of the metric. And because the vanishing has this very special property, it's just a simple
zero, just proportional to one power of the time. It's unambiguous how to extend this. And it's just
you just let the time extend to negative values. You don't cut it off when tau equals zero.
And if you do that, you find that the space time extends to this double cone picture, like two ice cream
cones touching at their point. And when you do that, you notice that the new extended space time,
has a new symmetry under tau goes to minus tau, basically taking the two cones and swapping them with
one another, or if you think of it as an hourglass, flipping over the hourglass. More correctly,
the proper thing is to the real symmetry involved here is the one that I mentioned before. It's a
version of CPT symmetry that I described earlier. So let's try to take this seriously. As I say,
the fact that there's this extension of the solution describing our universe in the past that has this
reflection symmetry. Again, one perspective is that it's just a mathematical artifact and doesn't have
anything to do with reality. Maybe that's the case, but let's try to take it seriously and see
where it leads. And the interesting thing is that if you do take it seriously, it ends up
giving new explanations for a bunch of things that we see about the universe that we hadn't
previously thought of as being explained in this way. This is a figure that I've stolen from
Stuckelberg's great 1930s paper where he invented the idea that an antiparticle is just a particle
traveling back in time, which is very connected to this idea of CPD.
You might think of there as being a sense in which these two halves of the universe are a bit
like a universe, anti-universe pair forming out of the Big Bang, in analogy to how in Stuckelberg's
picture a particle, anti-particle pair can nucleate at a given moment in time.
Is that only in a black hole or is that general?
That's general, that's general, yeah.
Tuckleberg's picture where particles can nucleate.
For example, this happens in a strong electromagnetic field.
You can have this swinger pear production
where a particle antiparticle nucleates out of the vacuum like this.
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So I want to give a couple examples of facts about the universe
that are explained if you take this reflection symmetry seriously,
this sort of temporal reflection symmetry about the bang seriously.
But to do that, it's helpful to use Roger Penrose's trick
where instead of the two ice cream cone picture of spacetime, we switch, we kind of blow up the
singularity, expand the tip of the ice cream cone into a dashed circle in this picture so that it becomes
like a straight cylinder. And so now the part of the cylinder above the sort of dashed circle equator
is again the part of the universe after the Big Bang and the part below the equator, below the belt,
is the part before the Big Bang. And so now in this picture, this is called these sort of diagrams,
these Penrose diagrams are meant to show, they show more clearly what the causal structure of the
space time is, in particular near the edges of the space time, the boundaries and near the singularities.
And so what we see in this picture is that the Big Bang is a kind of spatial surface.
At that surface, if we want to take the reflection symmetry seriously, there should be a reflecting
boundary condition like at a mirror, but unlike a normal mirror where the direction perpendicular to
the mirror is a spatial direction. This is a kind of exotic mirror where the direction
perpendicular to the mirror is the time direction. But other than that, it's mathematically
very similar. As I mentioned, a first thing that one finds, if one takes seriously that
the fields should satisfy reflecting boundary conditions at this mirror, at the Big Bang,
is that the scalar perturbations are synchronized in exactly the way we see in the cosmic
microwave background, okay, that it exists.
explains this famous ringing pattern that's observed and that's so where the theory and the data
agrees so beautifully. It also kills any vorticity. It turns out the reflecting boundary condition
is incompatible with primordial vorticity or vector perturbations, which is good because
they're not observed. And it's also incompatible with any singular perturbations, including
the kind of primordial tensor perturbations or gravitational wave perturbations that would diverge,
would blow up near the Big Bang and make it look very anisotropic in contrast to what we see. So
it's also not compatible with an anisotropic Big Bang, which is, again, good, because that matches
what we see. We see a very isotropic Big Bang. What I wanted to tell you now is about how this same
mirror idea provides a very elegant explanation, we think, for what the dark matter is. So the universe
appears to be full of dark matter.
Traditionally, people have considered particles beyond the standard model when they try to explain
the dark matter.
They talk about supersymmetric partners of the standard model particles, or they talk about axions.
Many different particles have been considered.
A crucial question is whether anything in the standard model can be the dark matter.
Do we really need something beyond the standard model?
Well, first we have to clarify what we mean by the standard model.
So the original version of the standard model back in the 60s and 70s would have meant the particles in this figure that I'm displaying.
In particular, there's six types of corks, an up quark, charm cork, top quark, down quark, strange cork, bottom cork.
And there's three types of charged leptons, electron, muon, and tau.
And three types of uncharged leptons, the electron neutrino, the muon neutrino and the tau neutrino.
And then there's the force-carrying particles, the gluon, the photon, the weak bosons, W and Z, and the Higgs particle.
What I want to mention is that in this original version of the theory, all of the particles, every come in left-right pairs.
Every particle really comes in two variants, a left-handed variant and a right-handed variant, except for the neutrinos on the bottom line.
In the original version of the standard model, the electron neutrino, the muon neutrino, and the tau neutrino
were all thought to be just left-handed particles. But in the late 1990s, the supercomioconda experiment,
observed that neutrinos have mass and that they oscillate into one another. Well, the fact that
neutrinos have mass, the simplest explanation for that, certainly the simplest re-normalizable explanation
for it, is that actually the neutrinos are just like all the other particles in the standard model. They
have a right-handed partner too. They're just, the right-handed partner tends to be hard to detect,
because the right-handed neutrinos, because of the pattern, the mathematical pattern in the standard
model, we know that the right-handed neutrinos don't couple to any of the gauge forces. So they don't
feel the weak force, the strong force, or the electromagnetic force. It's natural that they're
harder to detect than the rest of the particles in the standard model. And so it's natural that they
were discovered later. And indeed, we still haven't directly detected the right-handed neutrinos.
but, as I say, indirectly, they seem to give the most plausible explanation and the simplest
renormalizable explanation for why the neutrinos are observed to have mass and oscillate.
If you go back to that earlier version of the standard model with no right-handed neutrinos,
there's just no dark matter candidate left in that theory anymore.
But if you now turn to the standard model with right-handed neutrinos,
there's exactly one dark matter candidate in the theory.
Okay, so when I say dark matter candidate, the two basic requirements you have to be to be a dark matter candidate is that, well, you have to be stable. You have to live for at least the age of the universe because the dark matter does that. So you can't just be decaying in the early universe. You have to hang around for a long time. And secondly, you can't have been detected yet except through your gravitational interaction. So you can't be one of the particles on this chart where we already detect you by some other non-gravitational means. And there's only one particle left on the chart, which
has those two properties.
Namely, one of the three right-handed neutrinos could still be the dark matter.
That's the last remaining possible candidate in this list.
Now, the reason that it is not, you might say, well, why isn't that just the obvious candidate?
Why isn't that the one everybody always talks about and why do they even bother considering
particles beyond the standard model?
I think the main reason is that it turns out that the same property of the neutrino that
makes it stable, turns out that in order to be stable, it's saying that,
certain parameters in the standard model are zero. There's a certain symmetry that sets those
parameters to zero. Nothing new beyond the standard model, but it's essentially equivalent to the
statement that the dark matter neutrino is stable. That's equivalent to the statement that certain
parameters in the standard model are zero. But those same parameters, when you set them to zero,
it's saying that that particle, that dark matter neutrino is completely decoupled from the
rest of the standard model. It only talks to gravity. It doesn't talk at all to the
rest of the particles in the standard model. So that's good from the standpoint of being dark matter.
It means it's very dark. It only talks to gravity. So it's good news on the one hand that just
the requirement that it be stable automatically enforces that it's ultra dark. But you might say
the bad news would be, well, you still have to somehow produce enough of it in the early universe
to explain why we see the universe full of it today. The universe today has a certain measured
density of dark matter that it's full of, and you have to somehow have made that in the early
universe. And if this particle isn't talking to anything but gravity, you might wonder, well,
how did it get produced in the first place? This mirror idea, the idea that the Big Bang is a mirror,
provides a very neat explanation for that, which is that in a curved space time, the vacuum state
of a particle becomes ambiguous. Ordinarily, you know, in the room here or, you know, in your office,
You don't really need to think about the curvature of space time.
You can treat physics as if you're working in flat space.
And in flat space, in Minkowski space time, there's a unique vacuum state that respects all the symmetries of Minkowski space time.
We don't normally think of the vacuum, the zero particle state, as being ambiguous.
But in curve space, it's a fact that's in your face that if you're in a curve space like the expanding universe,
different observers at different points in the space time will disagree about what the zero particle state is.
And if the universe is in one state, which one observer calls the zero particle state,
a different observer at a different point in time, say, or a different state of motion could disagree and say,
no, no, that state actually is full of particles. According to my particle detector, there's particles present.
So that happens in cosmology. And in a general cosmological space time, in a general expanding universe,
there isn't really a preferred choice for the vacuum state.
You don't really know which one to choose.
But the interesting thing is that when you consider this extended picture
where the universe is reflection symmetric about the Big Bang,
that extra symmetry does provide enough symmetry to select a preferred vacuum state.
So there's a vacuum state for these neutrinos that respects the reflection symmetry around the bang.
But that is different than the vacuum state that a late-time observer like you or I would define.
Our notion of zero particles differs from that, from the one defined by that reflection symmetric vacuum state.
So, according to us, if the universe is really in the reflection symmetric state, and in particular, if this dark matter neutrino is really in the reflection symmetric state, then we will observe a flux, a non-zero flux of these particles.
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Emerging from the Big Bang into the late universe where we live and how much emerges, how much dark matter you get depends on what the mass of that.
dark matter particle is. And so in particular, from this standpoint, there's a very natural
explanation for why these dark matter neutrinos are produced in the early universe. And moreover,
according to this perspective, when a cosmologist like yourself measures the density of dark matter
in the universe today, they are essentially measuring one of the last remaining unmeasured parameters
in the standard model, the mass of this neutrino. They're measuring it to be a particular number,
4.8 times 10 to the 8,
GEV, a very specific number.
This is very closely analogous to Hawking's picture
of how a radiation is emitted by a black hole.
Hawking famously discovered that black holes emit hawking radiation.
There are the idea is that the black hole is in one state,
but a different observer defines a different vacuum state.
So it looks to them like particles are being radiated by the hole.
Similarly, we're saying the universe is in one state,
the CPT symmetric state,
We, a late-time observer, far from the bang, are in a different state, and so it looks to us
like these dark matter neutrinos are emerging from the bang.
As I mentioned, this leads to several predictions.
One is that the dark matter is 4.8 times 10 to the H-EV.
Another is that the dark matter is cold.
That's a testable prediction.
So far, it's consistent with the data, but cosmologists who observe galaxies are constantly
testing to see whether the predictions of the cold dark matter model are correct.
A third prediction is that if this dark matter neutrino is stable, the last,
lightest neutrino has to be exactly massless. And actually this observation was just confirmed
by the DESE experiment earlier last week. This is a telescope that just released its second year data
and has essentially, is now in conflict with anything except the lightest possible value for the
light neutrinos. It's ruled out the inverted hierarchy, I think is the technical. All that
oscillation experiments measure, particle physics experiments measure, is the differences between the
neutrino masses. So they measure these two differences, but there's two possibilities. One is called
the normal hierarchy where the masses kind of look like this, two light ones and a heavy one,
and then there's the inverted hierarchy where there's two heavy ones and a light one. But in either
case, there's an overall unmeasured parameter, which is how far the lightest neutrino is from
zero. So we're predicting that the lightest neutrino is down at zero. So first of all, like you say,
they have not only forced the lightest neutrino down to zero, they've also ruled out the inverted
hierarchy where the two of them are heavy and the other one is light. But also for the normal
hierarchy, they've essentially ruled out any non-zero value where they've put a very tight
constraint. The constraints have really pushed the bottom neutrino essentially down to zero because,
in fact, much more than I had expected, because in fact, so much so that if you, there's this funny
result that if you let the neutrino mass go negative, they actually prefer a negative value for the
lightest neutrino mass. So actually any positive value is really quite disfavored at the moment.
So and then there's other future experiments that could test this, but those are
neutrinalist elevated k experiments that are further away. I'll give one more example of a thing
that is explained by this picture, which is that, so I mentioned three properties of the early
universe that it's homogeneous, isotropic, and spatially flat. Properties that are traditionally
supposed to be explained by inflation, but we give an alternative explanation. What's the basic idea?
Well, what we did was we calculated this gravitational entropy of the universe, and in short,
we found that it favors universes that are homogeneous, isotropic, and spatially flat.
So in other words, we're saying that the reason that the universe was homogeneous isotropic and
spatially flat is basically the same reason that the air in the room, you're
in is spread homogeneously and isotropically through the room. That is the state of highest entropy.
So very briefly, we solved for the first time, we found the exact solution of the Friedman equation
where for a general universe with radiation, matter, vacuum energy, and curvature. So that's basically
all the components that we know are there. And then normally people also include inflation,
which makes it impossible to find the general solution. But if you don't have inflation,
if you don't include it.
It turns out you can solve this equation exactly.
It's given by elliptic function.
It's this kind of beautiful function,
but it lives on the surface of what mathematicians would call an elliptic curve
or what, to put it in terms Homer Simpson would prefer,
on the surface of a donut.
And all the solutions have this property that the direction around the donut here
is actually the imaginary time direction.
So this is the real time direction as you go around the hole in the donut.
Or if you go through the hole in the donut,
That's going around a circle in the imaginary time direction.
This property that the solutions turn out to be periodic in the imaginary time direction,
that's exactly the same thing that Gibbons and Hawking discovered in the 70s about black hole solutions
and that famously allowed them to calculate the entropy of black hole solutions.
Well, you can just do exactly the same trick here now.
You can use exactly their same argument to calculate the entropy of these cosmological solutions.
So we do that.
And then you can just ask, okay, which cosmological solutions have the highest entree?
And it turns out that they're the ones that are almost perfectly spatially flat, like the universe we observe.
And now if you include perturbations, density perturbations, gravitational wave perturbations,
if you allow deviations from a perfectly homogeneous isotropic universe,
well, in general, they could take the entropy up or down.
But if you only allow perturbations that satisfy this reflecting boundary condition at the big bang,
perturbations that are symmetric under reflection about the Big Bang, then those turn out to all
cost entropy. So in other words, it's saying that the highest entropy universes, the ones that are the
most probable from a statistical standpoint, are exactly like the homogeneous isotropic, spatially
flat universe as we observe. So taken altogether, it seems to us to give a very elegant way to understand
a lot of the things we see about our universe. Starting from this one very simple principle,
reflection symmetry about the Big Bang,
and so they're derived into sort of very principled way,
but without having to add new particles beyond the standard model,
without having to make up new laws of physics
to explain these things or invoke new epics
that we don't actually observe.
We've gotten more and more excited about it for that reason.
It's a hallmark of what your brand of theoretical physics
and Niels as well is known for,
which is creativity, originality,
but also grounding in hard truth, hard data,
in facts and what we know now,
and the pace of the data coming in,
will no doubt accelerate with, you know, further results.
We just saw great results from Desi, as you mentioned, and from Act,
and soon we'll have Assignment's Observatory data as well.
Nathan, now I need to take a turn because this is the part I flagged at the very beginning of the show
and, in part, you know, what my audience is clamoring to learn more about.
And that's that you, Lathen Boyle, high-energy particle physicist,
recently published, you know, in a cosmic scale of paper on the Fermi paradox,
which, you know, I was thinking it's kind of like, you know,
Roger Penrose dropping a rap battle mixtape or something like that.
And so I'd like to know more about what drove you to this.
And what in principle, I think we should start off with kind of the cornerstone of the paper,
which involves quantum entanglement.
So first of all, if you could explain that.
And second of all, there are a lot of, you know, contentions by people that have been on
the show many times, that quantum entanglement is beautiful.
It's interesting.
But, you know, fundamentally, it can't be used to transmit information.
So tell us, what is the Fermi paradox solution?
you're proposing and why should the audience members be interested in a resolution to the Fermi
Paradox in this way?
A topic that's often discussed is whether when you have two particles that are entangled
in quantum mechanics, whether measuring one particle can instantaneously send information to the other,
whether entanglement can be used to instantaneously communicate information.
And just to be clear, the answer is no, so I'm not saying anything unusual about that.
But it's also known that entanglement can be used to send quantum messages.
In particular, the most famous process is something called quantum teleportation.
That's been tested in the lab.
So I got interested in this question of whether one could send quantum signals over interstellar
distances.
People have, like you say, worked for a long time on the possibility.
It was realized back in 1959 that one could already with human technology send classical messages over interstellar distances using radio waves and then shortly after people realized you could do it with lasers.
And so that ignited the search for classical setty, the classical search for extraterrestrial intelligence.
But subsequently people discovered that classical communications and classical communication theory was just a special case of a more.
more general type of communication one can do, which in many respects lets you do things that you
just cannot do with classical communication called quantum communication. I got interested in this
question of whether quantum communication over interstellar distances was possible. And actually,
there was a great pioneering paper a few years ago by Arjun Barera here at the University
of Edinburgh. He showed that quantum coherence could be maintained over interstellar.
stellar distances so that if you send signals at the right frequency, you can send
cubits and have them retain their quantum coherence without decohering their information,
losing their information to the environment as they travel from Alpha Centauri to us.
But what I did in this new paper was I asked what it would take for a,
you see, maintaining quantum coherence isn't enough to send a quantum signal.
The real question is whether an interstellar quantum channel can have non-zeroing.
quantum capacity. The quantum capacity is a number that measures how well a communication
channel can carry a quantum signal. And if it's zero, it means you can't send, you can't
exchange quantum messages over that channel. So maintaining quantum coherence is a necessary
condition for the quantum capacity to be non-zero, but it's not a sufficient condition.
That's what I did. I calculated for the first time, what is the quantum capacity of an interstellar channel.
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consensus premium when you sign up by August 30th 2025. Now back to the episode. The results just
struck me as interesting. So on the one hand, basically in short, you know, one striking thing is that the laws of
nature and the properties of the universe, namely the cosmic microwave background, and the properties of the
Milky Way galaxy, are interstellar medium in the Milky Way galaxy, they all conspire to make it possible
to build an interstellar quantum channel with non-zero quantum capacity. So that's the first,
that's the first important thing. But there are certain requirements in order for it to be satisfied. You have
operate at certain frequencies, but also it turns out to require enormous telescopes, and so
bigger than we have built so far. So humanity has just not crossed the threshold to be in the
game of quantum communication yet. That's the bad news, is that we really can't be one end of a quantum
signaling channel with quantum capacity Q greater than zero at the moment. But it seemed to
point to an interesting possibility, which is that, you know, it turns out that the same condition on a,
So there's a lower bound on the size of your telescope in order for you to be one end of an interstellar channel with Q greater than zero.
But it turns out that lower bound is exactly the same.
First of all, the same lower bound applies to the sender.
So it applies to the alien in Alpha Centauri that wants to send us a quantum message.
But it also means that if they do have a telescope large enough to send a quantum signal to us,
then it's also large enough to see that we don't have such a telescope.
And so they wouldn't send it.
An important part of the story here is that quantum communication with Q greater than zero is very different than classical communication.
In classical communication, you can send out your classical signal, your classical radio wave signal, for example.
You can send it out in all directions, and almost all of the photons will get lost into space.
No one will detect them.
On some distant star, they might just detect a tiny fraction of the photons you sent out.
and still be perfectly able to read your quantum message.
They can still, it's perfectly possible to send the classical capacity
will be non-zero in that case.
They can receive your classical message,
even if they only receive a tiny smidgen of your photons.
But quantum communication is very different.
You really have to receive, we would have to receive more than half
of the transmitted Q bits, quantum bits, in the message
in order to have a channel with Q greater than zero.
that's because if you could do it with any less than a half,
that would violate the so-called no-cloning theorem of quantum mechanics
or the no-Zerox principle.
You can't Xerox a quantum state.
And that prohibits a channel with Q greater than zero
if you receive fewer than half of the photons.
But so it means that if it is the case,
that if there are intelligence civilizations in our galaxy,
if they're communicating quantumly with one another,
it means by necessity they have to do that in a very directed way.
They have to be basically sending their signals
so that they travel essentially from the sender's telescope to the receiver's telescope.
Essentially, they're not spilling photons all over the place.
They have to be sending them in a very directed way just to get a non-zero quantum capacity.
If they can see that we do not have a telescope capable of receiving that message,
they wouldn't send it to us, and we would be none the wiser
because they would be sending signals around that we couldn't see.
Now, do I believe that this is the real explanation for why we don't see,
evidence of large-scale intelligent life elsewhere in the galaxy? I really have no idea. I guess if I was
going to bet I maybe might bet against this. It sounds a little bit like science fiction to me,
but it just struck me as very interesting that the laws of physics essentially, you know,
imply that first of all, there is this more advanced type of communication, much more powerful
type of communication one can do, that already, you know, a hundred years into our technological
civilization, we're already kind of trying to progress, you know, we're already have discovered it
and are beginning to progress ourselves to try to learn to use it, to try to learn to use quantum
communication in various ways ourselves on Earth. So on the one hand, there's this more powerful
communication option available. And on the other hand, because of the laws of physics, because of the
laws of quantum mechanics, basically, if you did imagine that they were, that they were advanced
civilizations communicating quantumly, that seems sufficient to explain why we,
don't see any sign of that. I don't know. It just seemed like an interesting enough conclusion that it seemed worth pointing out. I just noticed no one had
calculated the capacity of one of these interstellar channels. And so, yeah, I guess nobody had really noticed this.
The question that I get mostly is, you know, these objects that people claim to see defy the laws of physics. And I mean, you're one of the top physicists alive today.
What do you make of these sightings and claims and so forth of technology of biological material? Do you believe that? I mean, that would be the ultimate evidence that the Fermi parrot,
It's not a paradox, right? They're here. So what do you make of these sightings and even claims of
physical artifacts from either craft or biological specimens? So there are a lot of these claims where
really the evidence is not available for scientific scrutiny or people are asking you to take
their word for it. For those claims, I personally don't believe them until there's evidence that's
kind of available for scientific scrutiny. There's the other type of claim, which is the sort of claim that has been
made by Avi Loeb, one thing that definitely has been detected are, you know, like
Umuamua, are objects from outside the solar system that have been detected. And then there's a
question of whether those may be of technological origin. That seems like a very interesting
question, which in principle can be investigated scientifically, maybe not with Umuamua, because it's
too far away now, but with other objects like that. So that's in a totally different category. I mean,
there's not strong evidence that anything like that is of extraterrestrial origin. If further
investigation of that sort of thing showed that it was, well, that would be very exciting and great.
I mean, I wouldn't, again, I personally, based on no information, I kind of wouldn't bet much money
on that turning out to be the case, but who knows? And also, yeah, I mean, so he, I think,
speaking of, I think that Avi also has meteorites that he's recovered from the ocean floor,
that also, I think he thinks are of extra solar, you know, came from outside the solar system.
That sort of thing, yeah, I think that sort of investigation is very interesting. And if, again,
And I really don't know whether it'll turn up any what it'll turn up, but that's in a completely different category.
And speaking of meteorites, I always like to mention that for my guests like Latham, but in the academic community, I give out these meteorites to anybody with a dot edu email address.
But unlike Latham, they have to live in the United States.
So to get those, you go to Brian Keating.com slash edu if you do live in the U.S.
But if you don't have an E.D.U. email address or you don't live in the U.S. and you do have one, go to Brian Keating.com.
slash list and you'll sign up and we'll have a lot of kind of debriefing from this episode,
which has been so much fun for me and I know for the audience as well, Aetham.
But as we wrap up, you know, we started off talking about fundamental symmetries and how
a particle physicist got into all these disparate kind of interesting intellectual terrains and
landscapes.
But I guess, you know, when I think about how we've journeyed today from, you know,
discussion of CPP symmetry to then, you know, a mirror universe wrapping up with a return to
this question that I posed at the top about how a particle physicist could get interested in
solutions to one of the most vexing conundra of all time, the Fermi paradox. So let me ask you
this final question. If both of your major threads that we talked about today, at least CPT
symmetry and the mirror universe and interstellar communication quantum signaling as a solution to
the Fermi paradox or an approach to it, if both of those turned out to be right, what kind of
the universe would we really be living in? And what would it say about humanity's place within it?
I find it very, you know, fascinating, I think like everyone must, that like we discussed before,
things somehow the, somehow the universe began as this very symmetrical soup with just tiny perturbations.
And then they grew over time into galaxies and planets and at some point came awake and came alive and then ultimately
became conscious and began, began, you know, developing explanations and understanding of the universe.
It just seems like a very fascinating but puzzling question how that happened in the first place.
You know, that maybe the modern take on the Fermi paradox from a cosmologist standpoint would be that
the evolution of, you know, our scientific understanding. At one point, we started off thinking that we
were at the center of the universe and then, but then kind of generally speaking, the Copernican principle has
held true that, you know, we discovered that no, we were actually not at the center of the
solar system. We were just one of a bunch of planets orbiting around the sun, and then solar system
was not the only solar system. It was one of maybe 100 million solar, 100 billion solar systems
in the Milky Way maybe, and then the Milky Way itself wasn't the only galaxy. It was just one of
many, like similar galaxies spread throughout, you know, 100 billion of those in the observable
universe and who knows how many more beyond. And so that whole trend has been to say that we're not really
in a special place in the universe that we're in a kind of typical place or a place that's
reproduced many times over. And, you know, so it would be a big reversal of that trend if it
turned out that we were somehow the only planet with life in the galaxy or in the observable
universe or something like that. I haven't the faintest idea whether it is or not. I don't,
everyone seems to have a strong opinion about whether that's true or not. I personally, I just
feel completely perplexed about whether it's true or not.
Latham has been a wonderful conversation. We'll have to do it again. I'll be in Edinburgh this summer. Maybe we'll do one in person.
Okay. That sounds great. And I'll bring you a meteorite. I'll bring you a meteorite. I was going to ask, the way you phrased it, I think what you meant was that you can't request a meteorite if you're outside the United States.
You could request it. I just can't ship it. Yeah. We will definitely get a meteorite. I'll bring you a meteorite and maybe even some more swag.
Latham Boyle, thank you so much for joining us late in the evening or later in the evening for you than it is for me.
There's so much more left to cover.
I can't wait to our part two.
Thanks.
Likewise.
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