The Jordan B. Peterson Podcast - 463. Heaven, the Matrix, Dark Matter, and Aliens | Dr. David Kipping
Episode Date: July 11, 2024Dr. Jordan Peterson sits down with the director of the Cool Worlds Lab at Columbia University, Dr. David Kipping. They discuss the likelihood of finding life elsewhere in the universe, what it means t...o be a Type I civilization, why Mars is our best chance at interplanetary expansion, the comparative rarity of a solar system like ours, and science fiction concepts, such as the Dyson sphere, which may one day become a reality. David Kipping is an associate professor of astronomy and director of the Cool Worlds Lab at Columbia University in New York City. He has published over a hundred peer reviewed research articles, spanning the fields of exoplanet and exomoon detection, astrostatistics, astrobiology, and technosignatures. He is also an active communicator of science through his popular YouTube channel Cool Worlds. This episode was recorded on June 28, 2024  - Links - For David Kipping On X https://x.com/david_kipping?ref_src=twsrc%5Egoogle%7Ctwcamp%5Eserp%7Ctwgr%5Eauthor Cool Worlds on YouTube https://www.youtube.com/@CoolWorldsLab
Transcript
Discussion (0)
Hello, everybody. I'm talking today with Dr. David Kipping, a scientist, an associate professor
of astronomy and director of the K the Cool Worlds Lab at Columbia, recently
tenured.
He's published already over a hundred peer-reviewed articles, research articles, and is an active
communicator regarding scientific matters on YouTube.
Cool Worlds, YouTube channel.
What did we talk about?
We talked about, well, the position of man and woman in the universe.
Are we alone?
We talked about the means by which the exoplanets that could harbor alien life have been discovered
and assessed and what those planets look like.
We talked about the potential progression of civilizations at different technological levels
and how that might be detected in the cosmological space.
We talked about Dyson spheres and the utilization
of the energy that a sun produces
for moving the technological enterprise forward.
We talked about the Big Bang and some of the challenges
that have been posed to the axioms and theories of modern cosmology in the light of the development of the James Watt telescope.
And we talked about the pursuit of astrophysics as a with the big question, I suppose.
I know that you study the possibility of life elsewhere in the universe, and so I suppose
the big question that goes along with that is, are we alone in the universe?
That's a question that so many scientists have very assertive answers to.
They feel very confident they know what they answer to, and typically the response is,
well, of course, there must be. There's sort of two ways of
answering that whether you're talking about simple life, microbial life or
whether you're going all the way to intelligent civilizations comparable to
our own or even far more sophisticated but on both fronts the most
intellectually honest answer that I can offer you is I don't know and I think we
have to be comfortable
owning that possibility at the moment.
If you're going to say I don't know,
you have to concede that it may be possible
that we are alone, but it's also quite possible
that we're not.
Our job as scientists is not to pre-guess
what the answer is, but rather to do the experiment,
collect the data, and then to analyze it
and determine the most likely outcome.
But I do have a lot of trepidation about how overly zealous and confident some
of my colleagues are on this topic, because I'm just so aware of the danger of experimenters'
bias, which of course in psychology is a very common issue as well with many experiments
that have been done, where you think you know what the answer to an experiment is, you can
consciously or subconsciously influence the outcome of how you conduct that experiment, how you interpret it.
So I just say let's try to be forcibly agnostic.
I hope the answer is yes.
I hope there's someone out there.
But I think it does us a disservice to our objectivity when we say, of course, there
must be.
Well, it seems to me that part of the problem is that all the answers to the question seem preposterous, right?
Yes, there's life elsewhere. Okay, well then the first question perhaps that comes up there is where?
And then what, and if there isn't, well that seems completely preposterous because that's so it seems so utterly unlikely given the vast magnitude of the
of the universe that we would somehow be alone and the meaning of that seems so incomprehensible that
I can understand why scientists particularly would be loathe to accept that. It implies a very
peculiar kind of uniqueness to Earth. And then I suppose the third problem is, well, are there other civilizations?
Well, the only species that's ever managed a civilization even on Earth is human beings.
And that's only really occurred in the last few hundred thousand years.
So even in a place where we know there's life, the probability of an advanced technological civilization that can sustain itself seems,
well, it's happened once. Once isn't very many times. I know that human civilization
has emerged in different places, but really only after the last Ice Age and only in a
few places that communicated very rapidly. So So further thoughts on any of that?
Yeah, I mean, you kind of remind me of Arthur C. Clark's
famous quote about this, that there's two possibilities
and both of them are equally terrifying,
that either we are alone or surrounded.
And I think you're right on the money in terms of
the cognitive dissonance that both of those seem to imply.
I think there are ways out.
If the universe is teeming with
microbial simple life, then I think we could probably be okay with that
scenario in terms of compatibility with the observations. We look out at
these exoplanets and as impressive as our instrumentation is with especially
the James Webb Space Telescope, even that facility is not capable of detecting
biosignatures, life on another planet,
unless we're extremely fortuitous
with the types of signatures that they present.
It's very unlikely that even
JDU-ST would be able to detect biosignatures.
We're probably looking at the next generation
of telescopes to make that experiment.
Therefore, the fact that nobody has made a headline yet saying,
microbes discovered on Proxima Centauri B
or choose your favorite exoplanet is not surprising.
So we can perhaps be comfortable with the idea
that the universe is compatible
with being full of simple life,
but then that raises the question,
that means therefore the simple life does not go on
very often to at least form galactic empires, right?
Something like you see in like Star Wars or Star Trek,
where you have these federations spanning the galaxy.
Right. Well, I read a mathematical analysis years ago
in Scientific American about, from a scientist who had been
arguing strenuously against the existence of advanced
civilizations, because he calculated that even a space-faring
civilization that had reasonably but not absurdly fast interstellar craft
could populate an entire galaxy over the span
of something approximating a million
or a couple of million years.
And given that the universe is 14 billion years old,
perhaps that's 14,000 such time spans.
And yet, well, where the hell are the aliens? And so, you know,
that's that that was an interesting argument as far as I was concerned. I'd never seen
it formulated like that from a kind of quasi arithmetic perspective.
That's known as Hart's fact A. So there's this idea of the Fermi paradox that I'm sure
you've heard of. Many of your viewers have probably heard of this idea of, you know,
if everybody's out there, why don't we see them? We should see evidence for them. But kind of the
stronger version of Fermi paradox is not so much about radio signals or ships flying through space,
but it really is the aspect of colonization, that if there really is a galactic empire that has some
will to span themselves across multiple planets, which remember is essentially what we're trying
to do.
I mean, Elon Musk often talks about this.
He says that he feels almost an obligation
to try and continue the flame of consciousness
as he describes it.
And that's why he wants to go multi-planetary,
to go to Mars and to build a colony there.
It's perfectly natural that any species
that's interested in self-perpetuation
would see the obvious benefits of trying to
expand to other colonies, to other planets, and eventually even to other
stars. Because let's face it, even if you're all in the solar system, it can
only take a nearby supernovae or gamma ray burst to completely extinguish your
life in this solar system. So there's an obvious need that I think it's hard to
argue why, at least at a common rate, you'd expect a survival instinct
to encourage civilizations to want to do this. And yet, there is the problem, because as far as
we can tell, that has not happened. We do not see stars which have been engineered. We do not see
galactic-spanning empires or Dyson spheres littering the sky. So it appears, as far as we can tell,
that if there are others out there, they're certainly not at a rate where they dominate the galaxy. If they are, they're very rare
and maybe they're around one or two handful of stars, a sprinkling of stars if you like,
but they certainly don't dominate. And that's perplexing because you would think a survival
instinct would be to go out and get as many as you could. Well it's also perplexing in that if such civilizations are possible then, and they've
done it at all, then why aren't they everywhere?
I mean is it just the fact that by some strange fluke of time and space that we're either
the first ones to even vaguely attempt this or that it's somehow set up so that
this is equally improbable,
that no advanced civilization that exists
has managed to get to that point.
It just doesn't seem that,
especially given that we seem in some ways,
as you pointed out, to be on the verge of that.
Yeah, it's very complex.
I think-
Mysteries everywhere.
One of the strangest things, I think one of the things we have a lot of resistance to
is the idea of any kind of suggestion that we might be special.
I think astronomers and cosmologists have a real aversion to that idea
and it's kind of built into this idea called the cosmological principle.
So when we look out around the universe, this patch of the universe is not
any different from any other patch of the universe. That's kind of foundational to how we understand the nature around us. And so it is a
problem then, it would seem incongruous to this principle if we admit that perhaps we are the first
or we are the only one or maybe the Earth is the only planet in the whole galaxy which is capable
maybe not of microbial life but getting all the way to this point. And yet at the same time, so this is called the Copernican principle sometimes as well, the
mediocracy principle, but what flies in the face of that argument, and I hear that argument all the
time by many optimists, let's say, for life in the universe, what flies in the face of that is what's
known as the weak anthropic principle. And this is an idea that Brandon Carter wrote about in the
1970s, and he was thinking about
cosmology as well, and things like the fine tuning of constants of the universe, the speed
of light, the mass of the electron, these all seem to also be kind of finely tuned such
that life is possible in this universe.
And if you change any of those numbers, then we really shouldn't be here to talk about
it.
But of course, an obvious answer to that is that maybe there are many, many universes out there,
and it just so happens that we live in the one
which is tuned just right for life,
because of course it couldn't be any other way.
How we can't live elsewhere.
So this really goes down to why the planet might be special.
I've never, okay, a couple of things there.
I've never really understood the tuning argument,
because it seems to me that if you're a Darwinian, you've already taken care of that problem. It isn't so much that the universe
is tuned, it's that we're adapted to the constants that are in place. Now, I suppose you could argue
that without those particular constants, our form of life wouldn't be possible, but I don't think
that actually shifts the problem with the argument. So, because we have our form of life and we can't conceptualize, or at least not very accurately,
what any other form of life might take.
Now, I know that people have made the case that there's something particularly special about carbon
insofar as it's, because of its ability to combine in ways that make very complex molecules probable
and even likely.
But I still, the fine tuning argument always seems to me
to put the cart before the horse.
It's like, well, you adapt to the constants
that present themselves.
So of course it appears in retrospect
that everything's being finely tuned.
And I don't see, like I'm inclined towards, what would you say, deistic belief in some
fundamental way, but I don't think the fine tuning argument is very good argument for
the existence of the specialness, let's say, of the human psyche.
So I don't know, maybe I've just got that wrong.
Yeah, I think if I can just respond to that, I think there's an interesting aspect is the, it almost
gets into the philosophical a little bit, is the experience of the observer themselves. So we are,
you know, a primate and we have our brains in our head and we have these two eyes and we,
our version of experience is really defined by the bodies we inhabit and the planet we live on.
It may very well be that there is plenty of quote unquote intelligent life,
or if you want to call that out there,
that is just so radically different that
its experience is not really comparable to our own.
So you could imagine a fungus that lives on
a planet and it totally inhabits it,
and it's basically a giant neural network
that's on that planet and its version of
experience will be completely atypical to that of ours.
So when we use this argument of, well, with the Weak Antartic Principle, we experience this version of experience would be completely atypical to that of ours. And so when we use this argument
of, you know, well, with the Weekend Topic Principle, we experience this sort of version of events and
everything has to be sort of tuned such that that's the case, there may be power-all paths. And so when
we talk about this Rare Earth and we talk about Weekend Topic Principle, it's really a funnel to
this particular type of experience that we enjoy. And it's perfectly possible there are completely alternates,
but then that's not perhaps so satisfying because if there is
a planet covered in fungus,
we're not going to have a communication with that thing.
So it doesn't really scratch the itch.
I think when we talk about
the search for extraterrestrial intelligence,
we really do hope, maybe naively,
to actually engage in a conversation or communication or
an interaction of some meaningful sense
where we can understand one another's minds and that in my
opinion is probably too aspirational. I don't think that's very likely to occur.
Well again you look you look at the earthly situation because you would assume that that's the simplest place to look for first. And we can communicate to some degree with mammals
that are psychophysiologically similar to us.
I suppose the biggest gap we've managed to bridge
might be with octopi, right?
Because I've seen, and I don't know how accurate
these accounts are, but I've seen some documentary
evidence, let's say, of people establishing something
akin to at least a
relationship of curiosity with octopi.
And they're very exploratory, and they have
the kind of tentacles that are sufficiently
close to hands that you could imagine a kind of
parallel mucking about with things, intelligence,
that characterizes octopi because they can
manipulate so well.
But that's about it on Earth and that includes cetaceans.
I mean, we've been trying to communicate with whales and dolphins, porpoises and so forth for 60 years,
really with some degree of intensity.
And it isn't obvious that that's gone very far.
Whales are sufficiently different from us
so that even if we could talk,
it's not clear what we would talk about.
That was what E.O. Wilson's arguments about ants.
I think if we could talk to ants,
we'd have nothing to say to each other.
Because they, yeah, well, the funding,
that's a consequence of that
psychophysiological embedding that you described.
We don't really understand, I think,
when we think of our consciousness as like a free-floating entity, how grounded in our hands, for example, our
consciousness really is. Yeah, I agree. And even between different cultures of humanity,
it can sometimes be extremely difficult to have conversations and understand one another's mindset.
So I totally agree. It puts me in... Even with your wife.
mindset. So I totally agree. It puts me in... Even with your wife.
Sometimes that does happen as well. So I think it's perfectly possible that I'm willing to let go of this idea of the fatherly figure. It's almost like a stand-in for a god. The fatherly figure
alien comes down and teaches us the error of our ways, provides all this advanced technology,
and shepherds us to becoming more sophisticated and mature. I think that's a complete fiction. I think if there is other
life out there, it's likely vastly more different than we can possibly imagine. But that doesn't
make it scientifically not interesting. It's still extremely, perhaps even more scientifically
interesting to investigate it because we already know about this experience. So I think learning
about these other possible forms of life could be
extremely rewarding, but I really don't have a bet in the game as to whether that's even possible. As I said before, I do try to
remain forcibly agnostic that I'm actually okay with the idea of just lots of empty worlds out there.
Yeah, you mentioned the mediocrity principle essentially and that earlier if I got that right and that seems to me to be a
Doherty principle essentially, and that earlier, if I got that right, and that seems to me to be
a reasonable variant of Occam's razor, right?
There's no reason to assume a priori
that this corner of the universe is any different
from the rest of the universe,
then you would assume any given handful of sand
differs from all the sand on a given beach.
And so, but having said that, and I do think that's a good scientific starting point,
we are definitely stuck with the problem that here we are and we are conscious
and we seem to be rather unique in that regard.
And so that does challenge that assumption of, what did you describe it as?
I think it was the assumption of mediocrity.
Yeah, or Copernican principle.
That scientists start with. Yeah.
Yeah. So I think an obvious counter example to the mediocrity principle,
and I often say this when I teach my students about this idea, is a case where it breaks down
is in the solar system thinking about say oxygen atmospheres. So before we had studied any of the
planets in the solar system, we would live on a planet with an oxygen atmosphere and say,
hey, you know, we must assume that everywhere is typical,
and we cannot assume we are special,
and therefore oxygen atmospheres must be very, very common
on all of the other planets in the solar system.
And then lo and behold, not a single moon or planet
in the solar system out of, you know,
over 100 of those things has an oxygen-rich atmosphere.
Now, it's not all liquid water or, you know, plate plate, you can go on, there's a list of things.
And so it's not maybe surprising that that is the case because of course we could not
live on Pluto if it lacks an oxygen atmosphere.
We have to necessarily live on the rare instantiation where oxygen is because that's a prerequisite
at least for mammalian life. So I think this mediocrity principle, it's okay
to use it in cases where your existence is not predicated upon that statement. So if
I was to say the solar system has a Neptune, as far as we know, Neptune has no bearing
whatsoever on the probability of life developing on the earth. So by the Copernican principle,
many of the solar systems should have Neptune's. And you would be right. In fact, Neptune's are
the most common type of planet in the universe, and Jupiter's too are very common. So it'd be
perfectly reasonable to apply it in those instances. It'd be very dangerous to apply it to, say,
our large moon, because our large moon may, may not, we're still trying to figure this out,
have some influences to the development of life on this planet. Similarly, oxygen certainly does, liquid water certainly does.
So we can't take those properties, I would say, and generalize them because we're only
here because those things are here.
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Yeah, yeah. So I guess the question there is how many of the prerequisites for the complex life that has emerged on earth are the function of features that are just as uncommon in some
sense as life. And that is a very interesting exception to that rule of homogeneity, let's
say, because it is even from a statistical, from a very basic statistical perspective, it is odd given
that principle that the Earth would be the only planet that has oxygen on it.
I know that's also a function of life.
So that's a very difficult puzzle to work through intellectually because I can certainly
understand why the presumption of homogeneity is a useful presumption. It works in many cases.
And why it would not work in the case of Earth is a great mystery. Hey, I've got a question for you
that I've always wondered about. You know, I see people looking for life on Mars, analyzing rocks
from Mars, for example, or meteorites. And I think this, to me, thinking biologically, this just seems utterly preposterous to me, because I don't
think life is the sort of thing, like on a given planet, where it would be somewhere
hidden and hard to find.
I mean, if you look at Earth, I don't know how far down we've gone into the Earth's core
to continue to check for microorganisms, but I read not so long ago that there's more biomass in the Earth's crust
than there is on the surface.
I mean, life seems to be one of those things
that if it's anywhere, it's everywhere.
Yeah, yeah, and so, I mean, is the argument
that Mars underwent a cataclysm at some point,
hypothetically, that was so overwhelming
that it destroyed all
life but maybe there's some signs of it sequestered somewhere.
Like, what's the rationale for the search?
Yeah, I think that's exactly one very plausible scenario.
We certainly do know that Mars has undergone significant changes.
We see evidence of liquid water once flowing on the surface.
In the past, there's many geological features that we see that strongly indicate, almost unambiguously, that liquid water must have been there at significant
levels. It's just unclear for how long. So it may have been like flash floods that just
kind of appeared briefly, or it may have been a sustained body of water. This obviously
is not the case any longer, and thus we can surmise from this that something has happened
to Mars over time. It's probably lost its magnetic field over time that has probably decayed, that has led to the sputtering of the atmosphere. It's probably lost its magnetic field over time, that has probably decayed,
that has led to the sputtering of the atmosphere.
It's probably lost its atmosphere over time,
has much thinner atmosphere than it once did.
So I think we can imagine,
this is almost like looking ahead to the Earth's future.
When we make projections about the biosphere of our own planet,
most of those projections actually predict that
the biosphere will gradually decline.
Actually, probably it's already slowly in decline at this point.
The Sun is gradually warming up and producing more luminosity, that is putting greater,
greater pressure, if you like, on the Earth's biosphere until we hit this point where it
becomes harder and harder for life to keep up with the amount of insulation we're receiving.
And so most of these predictions predict that after about a billion years into the future,
Earth's biosphere will essentially collapse and the only things left would be living in
extreme conditions such as very cold caves that have been protected from that intense
scorching heat.
You might have some subterranean life as you allude to deep in the mantle or deep in the
crust.
And so we can imagine pockets of life surviving that are the relics of a once rich biosphere.
And that's possible, it still raises the problem why we don't see fossils and we
don't see any evidence of fossils on the surface. So whatever was on Mars, if you
are an optimist that it had life, it certainly was nothing like the kind of
extent that we had here on the earth. And having said that, it is another
possibility is that life could transfer between them. So it's also, this is the idea of panspermia.
Perhaps there is life on the earth,
which is being knocked off on asteroids,
it's clinging on, maybe a tardigrade
is like clinging onto a little asteroid or something.
And it can actually survive the vacuum of space,
these things.
We don't know if it could survive an impact.
Like mushroom spores.
Right, yes.
They could just propagate across the solar system.
Mars would be one of the places that, I mean,
it's surely the most hospitable place after the earth.
And so you would imagine if anywhere is going to be
a place where extremophiles,
which are highly adapted for extreme conditions
here on the earth, they might have a chance of surviving
in some of the remnant pockets of habitability
left on Mars at this point.
Right, okay, okay, So that's the rationale.
So now, have you also been interested in the issue of,
this is a strange kind of science fiction-like issue.
I've seen descriptions in the pop scientific culture online,
I suppose, of the notion of different civilizational types. So is that a notion that you've toyed with to any degree?
Yeah, this is probably the Kardashev scaling you're thinking of. So this was a Nikolai
Kardashev was a Russian Soviet Union physicist, I think in the 60s or 70s, and
he wanted to try and come up with a way of classifying different potential
civilizations out there.
And he argued that the most reasonable way to do this, and many people would disagree
with him, I think, but he argued the most reasonable way would be energy, energy usage.
And so he calculated that a type one civilization, as he defined it, would be one that uses all
of the radiation that hits the planet.
So imagine you cover the whole Earth in solar panels,
and there are 100 percent efficient solar panels,
and the energy you collect equals the energy you use.
So that would be a type 1 civilization.
Now, in practice, you couldn't do it with solar panels, of course.
You have nowhere to live,
so you'd probably have structures in space to make this really work.
But it's the energy usage which really matters.
Going to a type 2 is the energy of a star, and a type 3 is the energy of an entire galaxy. So there is interest, I think the reason
why we like this is that if it's purely in terms of energy, we think we have a pretty good grasp
on thermodynamics and we think it's fairly immutable that any civilization must operate within the
rules of thermodynamics. And so this places some fairly firm observational limits on how often this happens.
If there really were civilizations out there
that were harvesting all the energy from their star,
using it for work, so imagine like your laptop running,
it produces still waste heat.
And if you actually collected all the waste heat
that it radiates, it would be equal to the amount of power
that goes in, has to be an energy balance,
conservation of energy one, the laws of thermodynamics.
So we can look at these across the sky and see if there are stars which are essentially
invisible in visible light because all that radiation is being absorbed, but radiating
in the kind of waste heat band passes, which would be like infrared heat signatures.
And we've been looking for those.
Actually, a few weeks ago, there was a couple of seven candidates that were announced by a group. They were scanning the sky, looking
for objects which had these anomalous infrared excesses. They're very interesting. However,
another group soon after showed that three of these seven candidates happened to co-align
with known radio sources, which they surmised were most likely background galaxies or things very far away that were covered in dust. We know that galaxies
do often get covered in dust and that can produce a similar type of signature
to that which they see. And so they argued that three of the seven are
definitely false positives and in fact when you run the numbers it's perfectly
possible the other four are too. We haven't seen the galaxies yet. But
the density of these objects, given the number of stars they looked at,
looked consistent with them all being false positives.
So we don't have any compelling evidence for those objects,
but it is nice that it's an observational test we can do.
One of my colleagues, Jason Wright, led a survey out of Penn State
where they surveyed 100,000 nearby galaxies
to see if the entire galaxy had been converted this way.
And so this is looking for what we call the Kardashev type 3 civilizations.
And they found that basically there was no strong candidates. And so this is really intriguing.
We look around and we don't see nearby galaxies after 100,000 of them do not appear. It's very
rare that they appear to have been converted in this way. And similarly for many stars, about 100,000 nearby stars have been surveyed similar to this. So
it's very curious. It means that if civilizations do develop, they probably don't ever reach this
Kardashev type two or type three. Maybe they go to the virtual world. Maybe the idea of just
developing with physical structures to add in for an item doesn't make sense.
And eventually we all, you know, go into the metaverse, whatever it is, and just
decide to live in a virtual world rather than the physical world.
Yes, well, in some ways that would be a more straightforward thing to do,
obviously, because we're already doing that and it's definitely less resource intense.
So what got you interested in your line of research?
And you have about a hundred papers.
So why don't you outline first the full range of your research or at least the bulk of your
research so that we can flesh out all the domains that we might discuss.
And then I'd like to know what it was that sparked your interest in what you're pursuing.
Sure.
Yeah, thank you.
So I work on many different things.
My main area of research is exoplanets.
So these are planets orbiting other stars, which we've been talking about thus far.
And that has always been a fascinating topic to me just because it was fairly new.
Only in the last 30 years have we been able to make this reach should be able to actually detect these things for the first time
However in doing you know for me when you look for exoplanets certainly when I started looking for exoplanets
I would be immediately interested in the possibility of life and intelligent life if we've been talking about and many of my colleagues
We kind of giggle and laugh about that
It's still still carries what we call the giggle factor, the field of SETI,
Search for Extraterrestrial Intelligence, SETI.
And still many of my colleagues kind of dismiss that as kind of a frivolous activity.
But for me, it's always been obvious that if we're going to look for stars,
which could have planets, and then we're going to look for planets that could have,
you know, Earth-like conditions, then surely the end
point of this entire intellectual exercise is to ask the question whether they have life
on them.
I don't understand what we're doing if we're not going to eventually shoot at that question.
So I was never shy of addressing that.
And so a lot of my research has broadened out into questions of astrobiology, technosignatures,
which is kind of a modern rebranding of SETI, ways to look for technology in the universe,
such as the Dyson spheres that we've spoken about.
And increasingly, I've been interested in statistics
and the application of statistics
to these types of problems,
where, as we've already pointed out,
you're very data-starved.
We don't have a catalog of habitats out there,
at least known habitats.
We don't have a catalog of civilizations
discovered thus far.
So we are trying to make inferences about our uniqueness, of habitats out there, at least known habitats. We don't have a catalog of civilizations discovered thus far.
So we are trying to make inferences about our uniqueness,
which to me is one of the most interesting
and fundamental questions we can ask,
is how special or common are we out there in the universe?
And we are trying to make inferences
based off very little data, a paucity of data.
And to me, that's always just been intellectually
very stimulating to try and work on that fringe of where you know
So little but there's actually still some information that there is still something there
There's information about the timing of when Earth developed when life developed on the earth
There's information about the future of our planet. We know that from the evolution of the Sun
There's information about the fact we don't see galactic empires
And so my job is to try to sort of piece this puzzle together
and not give necessarily definitive answer,
but at least limit the options down to what is the landscape
of what's possible.
Okay, so you mentioned that it's been about 30 years
that we've had the technological capacity
to even detect exoplanets.
And so do you want to talk a little bit about
what that technology consists of when we started
to discover these planets and then also how in the world do you in fact discover them?
Yeah, it's a long enterprise we've been trying to do.
Ever since 1855, there's actually the first paper published trying to make the first claim
of an exoplanet.
It's a lovely story of Captain William S. Jacob.
He was at Madras Observatory in India and he was trying to use a technique back then called astrometry,
which is essentially, we still tried to do it,
but it's looking at wobbling stars.
That's what we mean by astrometry. Stars and measuring
their positions very carefully.
He was inspired by the detection of
many binary star systems this way,
especially by Friedrich Bessel, a German astronomer.
However, this method never really bore fruit
until really only the last few years, so we've been able to make reliably detect However, this method never really bore fruit until really only the
last few years, so we've been able to make reliably detections using this
method. So the first method which gave us success was Pulsar
timing, which was kind of ignored. This happened in the early 1990s.
I think 1990 was the first ever claim of this method. It was largely ignored
because pulsars are so strange. They are neutron stars, so these are stars
which aren't quite massive enough to collapse into a black hole when they die, but not too
far off. So they're kind of the predecessor. If you actually spooned a bit more mass onto
them, you could probably tip them over the edge into becoming a black hole. And these
things produce these very powerful magnetic jets out of their North and South pole. And
as they spin, it's like a lighthouse spinning, and they spin extremely fast, like as fast as a blender basically, like a milli- you know,
once per millisecond they can spin. And we can use these as clocks, like the clock, a cosmic clock
of the universe. And so if there's a planet orbiting it, it disturbs that clock gravitationally,
and we can detect its presence indirectly. So the first planets were found that way.
However, no Nobel Prize was given to that. You might think since that was the first ever discovery, it's Alexander Wolfscan
at Penn State, a very incredible discovery. It was largely ignored and
still is often overlooked in the scientific community. And it wasn't until
we discovered planets around quote-unquote normal stars, which really
means stars similar to our Sun, which are not neutron stars. These are stars in
their main part of their life, their main sequence lifetime,
as we would say. And the discovery there was through, again, a wobbling method, but through a
speed wobbling method rather than a position method. So if a planet is tugging on a star and
making it move, yes, its position changes, but also its speed relative to us is changing. So when
it's coming towards us, it'll be in blue shifted. When it's coming away from us, red shifted is the classic analogy. It's an ambulance going past you on this on the sidewalk.
It's siren will kind of appear higher pitch as it's driving towards you and sound lower pitch as
it's moving away. And we can use that same change in pitch to discover exoplanets. So in 1995,
Michel Mayor and Didier Kellogg's made the first discovery of 51 Pegasi B, the first real bonafide exoplanet
around a normal star.
And that was actually where the Nobel Prize was awarded to, I think, two or three years
ago.
But still, I think, recently, many colleagues in the pulsar world have been saying, hold
on, like, what about us?
Like we were five years before you, and we, you know, why are we ignoring these planets?
Why does the existence of a planet,
why does that alter the shift of the light?
I don't, I'm missing something.
Yes, it's a gravitational effect.
So the planet, really we often think of the planet
orbiting a star and the star just kind of sits there
inertly, static, but that's not true.
Really, it's not that the Earth orbits the sun,
the Earth and the Sun orbit one another.
And so the Sun is therefore moving in inertial space, sometimes a little bit towards us in response to the Earth's gravitational field.
So it's this influence that we can look for.
Right. They both rotate around their center of mass, don't they? The center of the mass of the system. Is that how that works? But the center of the mass of the Sun and Earth is so
it's so weighted towards the Sun that the center of the mass is still inside
the Sun, if I remember correctly. Yeah, far, far inside. Even for Jupiter, it's far
inside the Sun. And in fact, the speed difference as caused by the Earth is
the Sun moving by about eight centimeters every second. That's the speed.
So that's literally less than I think the speed that a snail will crawl.
And that is the speed that we are able to detect at this level.
We are getting to the point where we can now detect centimeters level per second speed
changes in stars.
So it's a remarkable feat.
That's for sure.
That's for sure.
So you can detect movement of stars, distant stars that are literally moving at a snail's
pace because of the effects of their planets.
That is really something.
Well, I guess light is a very accurate measurement tool.
Yeah.
But I have to say, even when these planets were discovered in 95, the Nobel Prize was
only awarded recently for probably a decade or so.
People didn't even believe those planets and there was still a lot of
skepticism about them.
And it was only when we started to discover what we called transits that
largely everyone got on board and said, okay, these planets are real.
There was a lot of concern that these changes in light that we were seeing
might not be due to a planet, but instead could be due to something
happening on the surface of the star.
So maybe there's a weird sunspot or star spot, maybe there's a strange flaring activity or pulsation
that is mimicking this signature. Since it is an indirect method, it is always possible that was
the case. So there were still skeptics and it wasn't until we started seeing planets eclipse
in front of their star, and we call those transits, and they happened coincidentally with when the
wobbling method predicted they
should happen that everyone kind of said, okay, this is wrapped up.
Like there can be no question now that these are real planets.
And when did that happen?
That was around 2000.
So it was Dave Charbonneau and Henry independently discovered two, it was the same system actually,
but independently measured two transits of the same planet.
And that was around 2000.
And ever since then, the whole field has been
largely focused on this.
We now have over 5,000 exoplanets discovered,
primarily using that method.
So it's been far the most successful technique.
Okay, now you mentioned earlier that the most common
form of exoplanet is Neptune-like.
So would you describe for us what a
Neptune-like planet is precisely and then also what proportion of the
discovered planets have been Neptune-like and why that's the most
common planet? Yeah, well let me even correct myself a little bit and say it's
actually even like a mini Neptune is the most common type of planet. So it appears
that you know the Earth is, well let's just say the Earth is the size of the Earth and the Neptune is four times that size. And in between
that around two to three Earth radii, we find many, many, many exoplanets. So we call these
mini-Neptunes. But honestly, that might be a misnomer. We're not really sure what they
are. Maybe many of them are just mega-Earths or super-Earths rather than mini-Neptunes.
So a big question in the field is actually trying to figure out what these things are.
They may even be a completely different type of object, like an ocean world.
We call those Hycian worlds, and that's been hypothesized as well.
So there could be big balls of water in space.
So we're still trying to figure out what these are.
We do know that they're extremely common, and it kind of raises the question actually,
because they are so common, why doesn't the solar system have one?
That is kind of an oddity.
In fact, there are many qualities of the solar system which betray the trends that we see
in exoplanets.
So for example, a Jupiter seems, you know, fairly, and you might expect to be a common
outcome because we have basically two Jupiters in the solar system with Saturn and Jupiter
being the same size as each other. But when you look at exoplanets, they're quite rare. Only 10% of stars have
Jupiter-like planets around them. So this immediately is interesting when we look at
the solar system in different ways and different dimensions, it does appear that it has lots
of unusual properties. We also see many exoplanets which are highly eccentric, they're almost
like comets going around their star,
and they're on these greatly elliptical orbits.
We see many hot Jupiters, these are Jupiter-sized planets
which are very, very close to the star.
And we also see lots of compact multis, as we call them.
A compact multi is essentially six or seven
small rocky planets or sub-Neptunes,
which are very, very close to the star
in nice compact circular circular orbits but all squeezed
into within say the orbit of Mercury around the Sun.
We see many of these types of systems as well.
You can have almost like a honey-eye shrunk,
the kids version of the solar system,
and that appears to be a common outcome.
We're still really making a headwind of
what do we do with all these systems?
How do we understand the uniqueness of the solar system? And clearly there's lots of strange things
going on with what we see out there.
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So, so one of the findings appears to be that solar systems of the type that we inhabit aren't particularly what? The
solar system is not particularly emblematic of the typical solar system
that has been discovered. So that's another bit of evidence for some kind of
odd exceptionalism.
Yeah, we're not the template. I mean even just the Sun is not the
template. Only 10% of stars look like the Sun and And of those, very few are as quiet as our sun.
Our sun's actually remarkably stable.
It doesn't flare too often.
It doesn't have many sunspots.
Most other suns we look at are far more active than our sun,
so that's interesting.
As I said, we have a Jupiter.
We have two Jupiters.
That appears to be unusual.
We have this rich dynamical system of eight planets,
as far as we can tell.
I think the record holder is of seven planets around one system that we've ever discovered.
So there are many aspects about the solar system which could be quite special.
But I wouldn't go as far as to say it's completely unique because, of course, instrumentation
is finite.
We cannot detect exact clones of, say, Mars.
Mars is just too small.
It would be invisible to our current technologies. So as we're getting better and better we are able to get
more insight into the true uniqueness of the solar system. But it's certainly not
a typical outcome. I think we could say that with some confidence at this point.
Okay. Okay. Now you mentioned a couple of things I wanted to return to. The idea to
begin with that there was something suspicious or even frivolous,
let's say, about the search for life on exoplanets.
And I was wondering what your opinion on the matter, this matter is.
You talked about the projection that science fiction oriented people, let's say, might have of something approximating a religious belief in
a sky alien who descends to the earth to save us.
And that was an unbelievably common trope in the 1970s.
I mean, I read a lot of science fiction in the 1970s
and that was extraordinarily.
In fact, the Grok that Musk's AI is named after
is a remnant of that kind of thinking, right?
Because Grok was the mode of apprehension used by,
I think, Valentine Smith in Stranger in a Strange Land,
Robert Heinlein's book, and it was basically a sky savior
who was humanoid that came from Mars.
I didn't know that, okay.
Oh yes, that's very,
see, well, that's why I wanted to bring this up
because there is a religious impulse that's lurking
behind the technological enterprise that's associated,
let's say with the fantasizing about life and other planets.
And you see this pop up everywhere.
So for example, the Superman, the DC Comics character,
Superman is another good example of that.
And you write because Superman has sky parents
and he's essentially a technological God
who ends up on earth.
And you see the same thing replicated with,
well, the Marvel universe in many ways with Thor and Loki.
I know they're drawing from Norse mythology, obviously there,
but the idea still lurks there.
And I'm wondering if it's that subversion,
like a juvenile, it's a juvenile subversion
of the religious instinct that drives these fantasies
of extra planetary salvation at the hands of aliens,
or perhaps destruction for that matter.
So I'm wondering if you have any thoughts
about whether that might be part of the reason
why such concern was regarded for such a long time
as less than serious or even frivolous.
Yeah, there's a rich history of theology
intermixing with a search for alien life.
If you even go back to the first speculations
about alien life, this, I think you're talking about,
Cassini, he believed there was life on the moon.
And so they were imagining kind of angels flying around
and there's these depictions of, you know,
with wings flying around in these caves.
So they kind of imagined these angelic beings
living on the moon.
That's why we should one day try and visit there.
Similarly, when you look about speculations
about life on Mars, Percival Lowell was an astronomer, kind of really an amateur astronomer, he kind of was an industrialist
first in the 19th century and then sort of committed to getting into astronomy and purchased
the Lowell Observatory in Arizona as a huge donation from his wealth. But he was passionate
about the idea of looking for life on Mars. And he really believed, as many do at the
time, that they would be fairly human-like. And so many of the depictions were even not
just human-like, but even expecting them to speak English and interact with radio technology
and things like this.
Well, it would be English.
Yes. It's very much like that Star Trek trope of everyone just happens to look just like
us. And there was really no, almost imagination.
It's kind of strange to get your head around.
Why did they, it's puzzling to me.
Why did, why was there assumption that all these beings
would look just like human beings?
I think it is an intermingling of the theological
with the material, let's say.
I mean, obviously there is an overlap
between the idea of heaven and the idea of space.
And heaven has been imagined as populated by beings forever.
And that's a mystery.
That's a very deep mystery in and of itself.
It seems relatively obvious to me that the heaven
of the mythological imagination is not the same
heaven as the material heaven that's above us. And I suppose part of the evidence for that would be that the material heaven
that's above us doesn't seem to be populated by
devils, let's say angels or gods.
But there is that strange strain of human metaphysical speculation that does posit a parallel universe of a sort or
multiple parallel universes where alien beings exist. And you know there's some very strange
things about that too and one of the strangest things I know of is the fact that if you give
human subjects DMT, which is the fundamental psychoactive chemical component
of ayahuasca, people reliably report being shot out of their bodies and encountering
alien beings. And that's so common that the main person who did this research, who was
a very down-to-earth psychophysiologist, I think got so discombobulated
by the consistency of these reports and the insistence
by the people who had the experience that that was real,
that he ceased investigating the DMT phenomena.
So I don't know what to make of all that, obviously,
and I don't think anyone else does too,
but it is interesting to see the overlap
between the imagination that projects deities
into a mythological heaven
and the actual domain of heaven above us.
Yeah.
Yeah, I think there's a lot we can learn
from theologians interacting with them.
I've been to SETI conferences
and theologians are actually now starting to participate in those meetings and
there's a lot to learn about.
It's almost like a search not only for life out there but a search for who we are. What we look for
says a lot about who we are rather. I mean if we're looking for
a species which are engaging in nuclear war, because that
produces such a loud signature, that is almost more of a reflection of our own inner fears
than it is of a serious discussion of what an advanced civilization would do.
And so I think this connection has always been there.
Well, you saw this in the latest mythological extravaganza, sort of planet-wide mythological
extravaganza, which was planet wide mythological extravaganza,
which was the explosion of the Marvel universe.
I mean, the Chitauri who come from outer space,
they're basically apocalyptic end of time demons, right?
But it is conflated with actual space
in a very interesting manner.
And so, and it does say something very deep
about our fears about, well, the end of the world and of salvation and of the notion that
both the end of the world and salvation will come from, what would you say, come from above,
come from below, come from outside, something like that.
Yeah, I do, this, this doomist mentality certainly has been with us for a
long time in Seti. Obviously, when Seti seriously got going in the 60s and 70s,
the specter of the Cold War was looming over and it was, it was really baked into
the, the origins of Seti was thinking about the fear of destruction and
annihilation. And I think there's a certain sense to that these days as well
that has been re-raising its head for various reasons and I've often said, you know, even if you're a pessimist about intelligent life in the universe
Now right there might be nobody out in the galaxy right now
you'd have to be a much more of a pessimist to believe that it never ever happens in the
Billions even trillions of years future that our galaxy still has ahead of it.
And so if we are serious about making it our goal to have contact with another intelligent civilization,
we should perhaps concede that it might not be a two-way conversation, but we can have a one-way conversation into the future.
That we could leave a relic, we could leave a monument as our ancestors did with the pyramids
and many of the monuments stonehenge, they left us messages from the past that transcend
their own existence.
And if we are feeling maybe pessimistic that we will never expand to this galactic empire,
there is still hope of being remembered.
If that's all we, you know, maybe there's, I think that's a fundamental component of our human desires
is to not be forgotten, to have some thread of our strain of existence
not be completely futile and gets remembered by the galaxy,
then I think we should seriously commit to building a monument,
maybe on the Moon, the Moon is an obvious place to do it,
because it just, it's unaffected by weather or geological activity, it could last for
billions and billions of years, we could build something or a spacecraft that goes out with
messages that just has a tomb of information about who we are, what we believed in, our arts,
our sciences, and I think that would be a really beautiful endeavor to try and unify people beyond what we believe in or maybe don't believe in
and also to
Have honestly some hope that the universe will not forget us and maybe it's a small thread of a chance that anyone will ever discover it
But it's better than than just giving up on the idea of detection altogether
I think that's probably our most likely window of getting detection. I
Think I read a science fiction story when I was about 13 of some advanced human civilization turning the moon into a gigantic Coca-Cola ad, like a billboard.
So we could do that, but I don't think that's exactly what you're thinking about.
Not quite that.
So let...
No, not quite that.
That would be, well, that seems to be something
that would approximate a form of sacralage.
Well, definitely, definitely.
It wouldn't cost that much to spray paint the surface, let's say.
So, hey, I'm kind of curious.
You referred to something else, too.
You talked about Dyson spheres.
And I know a little bit about Dyson,
and he was quite the character,
to put it mildly.
A lot of the great physicists are, you know, you tend to think of great physicists, if
you don't know much about them, as very, very serious, and they're like ordinary people,
except extremely brilliant and very serious.
But if you look into the lives of great physicists,
they're, well, to call them odd is barely scraping the surface.
They can be colorful.
And so, an odd in the best way.
Yeah.
Well, that's for sure.
So, and Dyson was definitely one of those characters.
And so, do you want to talk about the Dyson Sphere
and let everybody know what it is?
Yeah.
In case they want to build one?
Sure.
Yeah.
Dyson had many wonderful ideas. I've built upon a few of his ideas myself
in my own research. But the Dyson Sphere's idea was kind of the manifestation of this
Kardashev Type II civilization. How would one harvest all of the energy from a star
and use it to do something useful with it? And so the Dyson sphere is essentially trying to construct some giant shell around a star.
Now, a lot of people imagine a solid structure
that it would be a solid sphere,
a spheroid put around a star.
But that's actually not what Dyson had in mind
because he immediately realized that was not stable.
For instance, if you take a solid sphere
and you give it just the slightest nudge from the outside,
it would fall into the star. So it's metastable immediately.
Unless it's perfectly balanced, one slight particle of dust would nudge it into the star, basically.
It also has extreme strains in terms of the tensile strength that would be required,
that basically no material could possibly hold this thing together.
So there's immediate problems to something in that naive version of a Dyson
sphere. And so maybe a better way to think about it is a Dyson swarm or a collection of small
objects which almost form like a quasi shell but they're not physically connected. And so these
all they all orbit around the star and in fact they'd have actually different orbital periods
depending on where they're located at which, and what latitude they are in this shell. And so this object would be
essentially trying to collect all the energy from the star and use it for
what we don't know. One might imagine extreme computation. I mean an
interesting question is what does a super advanced civilization even
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because there's an infinite number of math problems until, you know, because
there's always an infinite number of math problems to solve, and maybe that's what
they're using all their energy for.
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My brother-in-law, Jim Keller, is a very famous and able designer of computer chips,
perhaps foremost in the world on that front. And he and I have had some very interesting
conversations in that regard. And one of the things that he's rather comically pointed out to me
in the last 10 years is that the earth's crust
happens to be made up of elements that are very similar
to precisely what you need to build a computer chip.
And so he could envision in his wilder fantasies,
which can be quite wild,
that all of the earth's crust is transformed
into computer chips.
And with all of the computational technology
that that would entail.
And you could certainly imagine a technological civilization
going in that direction, because in some ways
that's clearly the direction that we're going.
Like there seems to be no upper bound.
It's a weird thing too, you know,
I was thinking about time in this regard.
You know, we think that the time that we inhabit is finite, but time is very fractional.
And computers can obviously do many trillions of calculations in a given second.
And if you keep adding computers, then that's more computations per second.
And it doesn't seem, the upper limit to that's obviously defined by something like energy and material availability,
and that's all, not to the fractionation of time.
And so you could imagine the civilization,
well, you can't,
because we have no idea what would happen with,
we can't even keep track of our computational power now.
Can't imagine what a civilization would be like
that had something approximating
unbounded
computational power at its fingertips.
Yeah, I mean, there's always a bound.
There must be some bound, even if that bound is unimaginably high compared to our own capabilities
by just the amount of physical matter there is in the system.
So a Dyson sphere actually isn't just the crust of the Earth.
It would actually be comparable to the entire mass of Jupiter being deconstructed.
And even though Jupiter is not mostly silicon, which is what you want for building ships,
you can imagine using fusion to combine it into the elements that you need.
So this is obviously extremely advanced for talking about the capabilities of doing something
like this.
But yeah, the real limits of computation are essentially how much mass and energy is there
in the entire galaxy. And so, you know, Neil Blomkamp, he's the director who made the
District 9 movies. He gave a wonderful TED Talk that I found very influential, you can probably
find it online, about what he thinks the most likely form of life is. And he talks about the
idea of basically computation spreading across the universe and the universe waking up at this instance. So as soon as you have
these ships which can start moving, it doesn't have to be very fast, as we said earlier,
like probably comparable to even the speed of our current spacecraft is sufficient to
colonize the entire galaxy in a much smaller fraction in its own lifetime, like a hundred
or fifty times less than its current age,
you could actually spread out and just imagine like
a 3D printer with an AI on it,
and it just lands on a planet and it just starts going
around converting all of the matter it interacts with
with more versions of itself, almost like a virus.
Essentially, it's going around converting the entire galaxy.
All dumb matter becomes smart matter.
And that's his primary goal.
It's not very obvious what it would do with all this computation, as I said.
It's hard to imagine.
Well, you know what we do?
Well, what we do with it, weirdly enough, so you know, you might ask what is driving
the demand for advanced computational devices now?
Because most people have enough power in their laptop, so they can pretty... the laptop in
many ways exceeds their ability to use it already.
Now, that's not true in every regard, but then so then you might say, well, what's driving
the demand for enhanced computation?
And the answer to that, at least part of the answer to that, is the desire to ever more accurately simulate realities such that games can be played
with those simulations. And like that sounds trivial in a way that you'd use computation
to play games, but that's only trivial if you think games are trivial, and they're not trivial. They're forms of... Look, there's a very deep biological idea in relationship to thought,
that the reason that we think is so that our thoughts can die instead of us.
Right? And so, material evolution is a very slow process, and the price you pay to evolve
materially is that your material form dies
if you are sufficiently in error.
But if you virtualize that so that your thoughts are now avatars of yourself, you can have
your foolish avatars expire and you can continue.
And so it's a very useful way of experimenting.
It's certainly what children are doing, for example, when they're playing games.
And we don't know the limits to that. And I don't think it's mere fluke that a tremendous
amount of the market for high-end computational devices is the market to drive simulation
so that we can play fictional games. And so maybe advanced civilizations do, in fact,
take off into the fictional game space because it's in some ways an infinite domain of potential
experimentation.
Now, you know, that's way beyond the limits of my capacity to imagine in some fundamental
sense, but that's the trend at the moment among human users.
And so it's not an unreasonable extrapolation.
It would resolve the Fermi paradox.
I mean, it's a natural answer that everybody just
eventually transcends the physical world and disappears into the virtual one. This would
naturally explain why we're doing anything. You know, we're speaking of Dyson earlier, Freeman
Dyson had another interesting point about this idea of the virtual world. He was so far ahead of his
time. He was thinking about, you know, simulation theory way before and people were trending about
it with the Elon Musk statements and things like this this and he had a really interesting idea he asked
you know how could you live forever truly live forever and he suggested that
in a simulation you could do this so if you imagine you go far far into the
future it's thought the universe will eventually arrive at this what we call
the heat death where entropy takes over and essentially the amount you know all the stars burn out and there's very very
little energy left in the universe intrinsically until there's actually
almost nothing and so he imagines that you could simulate yourselves but you
could adjust the speed of the simulation so that one day for you one full day
actually takes in the real world maybe a thousand years to simulate so you're
essentially moving you know almost in slow motion in your simulation. And then
once, you know, you've used up the energy that's available, then you slow it down
ever more and ever more and ever more. And as long as you keep slowing it down,
you can actually live forever. It's a strange idea. So it's called Dyson's
eternal intelligence. And even though the universe asymptotically approaches zero energy
You can just equally asymptotically slow down your simulation such that you live forever
So it's kind of like Zeno's paradox of like the arrow never quite catching up with a runner
And so it's a kind of a beautiful genius idea that he had that there is a potential of living forever
Didn't Dyson also suggest that at some level
information was conserved?
I mean, I know he went way the hell out
into the metaphysical realms in his writings.
And I read a fair bit of Dyson, I don't know,
a long time ago, so I could barely remember it.
But he had some concept that was essentially theological
where what what all the
information that constituted the universe was somehow conserved.
That was part of, wasn't that part of singularity theory?
I'm reaching way back.
I don't know about Dyson's writing to this, but it's certainly the idea of
information conservation is actually thought to be almost an axiom of quantum
mechanics. So it really is thought that in quantum mechanics...
This was definitely Dyson.
Yeah. This kind of gets into the idea of like what we call the black hole information paradox.
When information falls in, it's seemingly destroyed and this violates this curious feature
that we think quantum mechanics demands that everything should be really not so much information
conserved but reversible. If I, you know, burn a book and all the particles of ash fall around onto the ground and into the air, in principle I
should be able to recollect up all those particles, put them back together and
reconstruct the pages and the words on those pages. And black holes seemingly
violate that. So that has been a puzzle.
So let, okay, okay, so let me ask you about that because, so let's take that
particular example where you burn,
okay, now imagine that you burn the book thoroughly enough
so the ashes have been reduced to something approximately
molecular size or maybe even atomic size.
Now you want to reverse that.
Doesn't the fact that there's quantum uncertainty
at the level of the atom imply that true reversibility
is impossible because the information is blurred at the quantum level?
It's certainly in practice completely, you know, impossible to do this.
There's no way that in the real world you could ever manifest this.
I think the fundamental best way to think about it with these analogies
maybe not quite right is the idea of a reversibility. So when you look at the equations of quantum
mechanics like the Schrodinger equation or something or the wave function equations,
they really don't have a care about which direction time goes in. So you should be able to point in
either direction and end up. So if I know an initial state, I should
be able to propagate it forward to a final state.
And yes, there's uncertainty.
So the wave function can expand and the probability space
can change.
But I should always be able to do that in both directions.
And so the fundamental problem of the wave function
with a black hole is that it seems to basically reach
an endpoint where it's just terminated
and it cuts off this reversibility
aspect.
So, this has been a big problem and people have been wondering about it.
And I think most people work on this believe that somehow the information must get out
of the black hole.
We're still trying to put the one possible candidate is probably through Hawking radiation.
So, this radiation which happens that Stephen Hawking predicted on the outskirts of these black holes, it's a very pitiful amountking radiation. So this radiation which happens, that Stephen Hawking predicted, on the outskirts of these black holes,
it's a very pitiful amount of radiation,
but perhaps that is carrying away some information
about what fell into the black hole.
And thus, if you did fall into a black hole,
in principle, you could be reconstructed
from this Hawking radiation.
So that's the current hope,
because otherwise we have to seriously rethink
quantum mechanics.
How does the...
So that Hawking radiation, if I remember correctly, it emerges at the event horizon, right?
Right at the event horizon.
And so some particle, an antiparticle falls in and a particle flies off.
It's something like that emerging out of...
Those are virtual particles.
How in the world are they supposed to propagate information?
That's a good question.
I mean, the problem with this is that
in order to propagate information
about what's inside the black hole,
that requires essentially an entanglement,
what we call a quantum entanglement with states inside.
So somehow this particle,
which has just been created on the event horizon,
it probably had, let's say, an antiparticle pair,
which was created just inside the event horizon.
Now, because they're created as a pair,
they should be entangled with each other.
An entanglement, unlike people, is strictly monogamous.
There's no way you can have an entanglement that
can suddenly become re-entangled with something else
at the same time as being entangled to this particle.
So once it's entangled with each other,
these two particles, it somehow now has to be entangled to something else at the same time as being entangled to this particle. So once it's entangled with each other, these two particles, it somehow now has to be entangled
to something else.
This is where, this is where physicists are really getting stuck.
And we just, we're really struggling with this problem right now.
Right.
I see, I see.
So does that imply that the antimatter particle that falls into the black hole is affected
by what's in there in such a way that the entangled particle
that's escaped contains that information.
That's the idea?
If I got that right?
Yeah.
I think people are wrestling with tweaking the rules of entanglement to try and somehow
allow for an entanglement to be maintained with whatever fell inside the black hole.
And perhaps the stuff that falls in can in a way be
thought of as the antiparticle of the Hawking radiation which came out and that we are and
there may be two aspects of the same thing rather than discrete processes. So these I have to say
this is not my field of expertise but I find it a totally fascinating topic and I've made videos
about it in the past but it is really... So that means that not only does the black hole evaporate
because of the Hawking radiation in principle,
but the information from the black hole escapes as well.
That's okay, that's wild. I didn't know that.
That's very interesting.
So what's on the horizon for your field, do you think?
One of the things I wanted to ask you, for example,
is that I know this isn't your specialty,
but any light you could shed on it would be appreciated.
I've heard that the new telescopes,
which can see farther into space
than anything we've managed before
and farther back into time, therefore,
have put some wobbles in the,
what was almost universal acceptance
of the theory of the Big Bang.
And so can you clue us in a little bit about at least
what's going on in astrophysics with regards to that
debate? Sure.
So we have this telescope that was launched two years ago,
the James Webb Space Telescope,
the most powerful instrument we have right now
for peering back into the far reaches of the universe and thus therefore into the past. Because of
course something that's very far away from us, it takes a long time for that light to travel.
And so essentially the light we are seeing from some of these objects is over 13 billion years
old. And thus we are seeing the universe in its first few hundred million years. When we're looking at the universe at this very ancient primordial phase, we are surprised to see rich structures like
fairly mature looking galaxies. They're still nothing as mature as what we have like the
Milky Way, but surprisingly mature given the epoch we are looking at in our data and suddenly
for large black holes as well. We're seeing black holes more massive than we would expect in the center of some of those
galaxies.
So, the puzzle has been how do you build this stuff fast enough?
Obviously, you could argue that maybe you need to totally rip up the textbook and say,
you know, all of our cosmological models are wrong and including the Big Bang, we need
to change everything. I don't think most astronomers are quite ready to rip up the textbook.
I think there are other ways to explain what we are seeing without going quite so drastically.
Speaking with my colleagues about this, we had a wonderful colloquium and I was speaking to the
some of my colleagues about making sense of this. And there was one of the interesting things I took away from that was
the models of star formation that we apply are calibrated to the local universe,
and they may not be actually applicable to this earliest epoch.
So when we see these galaxies,
these ancient galaxies, we are basically saying there are too many stars.
It built stars and too much stuff faster than it should have done,
based off the rates at which we think stars can form., based off the rates at which we think stars can form.
But really, the rates at which we think stars can form is
calibrated to what we see around us now,
which is not necessarily representative of the conditions,
well, certainly cannot be,
representative of the conditions of the early universe.
In fact, when they've gone back and revised those models and
they've updated them to account for the much stronger star formation and more intense densities that they naturally have
in these early epochs, it actually does predict these galaxies and most of the galaxies we
see.
So, in fact, we could have predicted many of these galaxies had we just been maybe a
little bit more thoughtful about what we put into the physics of those models in the first
place.
But it did make, of course, a spectacular headline to claim that the Big Bang model
was wrong.
I don't want to totally dismiss it, but there are still challenges, but I don't think it's
quite as dramatic as has been portrayed.
I see.
I see.
So part of the problem there too was the extension of that principle of homogeneity or uniformity
in the temporal domain when it wasn't
appropriate as you said if the conditions while the conditions are
obviously different soon after the Big Bang clearly and the so then the
question would be well how consequential are those differences and your argument
is the magnitude of those differences was conservatively underestimated.
And that's cast some of the theory into disrepute,
but that doesn't mean that, at least in your estimation,
that the baby has to be thrown out with the bath bomb.
Yeah, I think if you throw out all of, you know, the Big Bang model,
which really, when we say the Big Bang model,
we don't really just mean the Big Bang.
What we call is lambda CDM, which means lambda is dark energy,
CDM stands for cold dark matter.
And this, you can think of lambda CDM
as essentially the standard model of astronomy.
In the same way that there's a standard model
of particle physics that includes
the basic fundamental particles,
we have a standard model of astronomy and cosmology.
And so this model has been extraordinarily successful
as indeed has the standard model in particle physics.
It explains such a wide span of observations
that were you to throw it out,
it would be extremely difficult to understand
how it could coincidentally explain such a vast array
of diverse phenomena so exquisitely.
So I think we're not, you know, astronomers do like it,
physicists like it when we get to rip things up,
but given the extraordinary success of the model and this, you know, one interesting puzzle,
I don't think we're quite ready to throw in the towel at the first punch. You know,
we're willing to fight back a little bit. I think it was Arthur C. Clarke, possibly.
I might be wrong about this. No, it was Carl Sagan, who said that extraordinary claims
require extraordinary evidence.
And so, well, the proper response to that is that you always modify your theory no more
dramatically than is minimally necessary, right?
It's just otherwise, that's true even psychologically.
You know, if you don't, every time you're upset
with your wife, you don't think that now divorce
is in the offing, right?
That's just not the solution to the problem.
So, okay, so maybe we can close with this if you don't mind.
It's, and this is a very complex question
for a closing question, but so be it.
I don't understand at all the theories that purport
to include dark matter and dark energy.
And they've always seemed to me, and this I'm sure
is a reflection of my ignorance, as post-hoc rationalizations
for the failure of a theory.
Sort of like the cosmological constant.
But like I said, I'm nowhere near informed enough
to make that judgment.
But can you explain, you talked a little bit about
the standard cosmological theory, can you explain
how the notions of dark matter and dark energy
have been incorporated into that and why?
And you have like five minutes.
Just kidding, take your time.
Yeah, it's a huge topic and it's something I totally understand. There is a lot of skepticism
about the reality of dark matter and dark energy because it is so porous, it's so immaterial
that of course it's hard to accept it if you can't hold it in your hand and you can't see it
how do we know this thing is really there? It is quite frankly an invention to explain some of the
observations that we see but you know physics is not opposed to doing that and we've done that for
a long time we've invented many extra terms we know we've invented extra terms we have Newtonian
understanding of gravity and Einstein looked at the orbit
of Mercury and said that doesn't fit in.
It doesn't agree with Newtonian physics.
We need to add some extra stuff to make this work.
And so we, you know, physics has always been iterative and we've always added more complexity
to our model.
So in that sense, we shouldn't be opposed to it fundamentally because of what it's doing. The evidence for dark matter is quite strong and diverse at this point,
but I don't think we have completely concluded that it is absolutely real.
There are still many interesting clues that there could be alternatives to dark matter,
such as actually modifying again what Einstein did
another level and changing things because it's modified theory of gravity. So that's possible. The evidence for dark matter,
the classic piece of evidence that we first collected was Vera Rubin. She was
an astronomer in the in the 70s I believe and she noted that many galaxies
appear to be rotating so fast that by the centrifugal force they should fly
apart. If you add up how much mass they have with the stars, the stuff you can see, they're
spinning so fast there's just no way they should really be bound.
They should be spewing out into space.
So she argued there could be some extra additional matter there that simply we cannot see.
And I kind of like this idea personally because why should we arrogantly assume that we can see everything?
That's always kind of bothering me. Like the assumption that everything we see
should, everything that we can see with our own visible eyes is,
is the entire state of the universe.
That obviously seems to be a very naive perspective to have.
If just because you can't see it, therefore it doesn't exist. Well,
therefore you wouldn't have air, right?
You wouldn't believe in the presence of air, all kinds of things,
if you've operated into this mentality. So this, this neatly explains the galaxies. And also, you wouldn't have air, right? You wouldn't believe in the presence of air, all kinds of things if you operated into this mentality.
So this neatly explains the galaxies.
And also, we have many other evidences now,
for example, another example is weak lensing.
So when we look at very distant, bright sources,
like galaxies, like James Greb is looking at,
and we look at their light,
it should travel in a straight line, of course,
but we notice that it doesn't.
And these galaxies appear slightly warped and distorted.
Like looking, if you go to a fun house
and you have these curved mirrors,
they get distorted into strange shapes.
And we see this.
We call this weak lensing.
It's a very mild effect to these galaxies,
but it is detectable.
And so we know there must be some invisible fluff
between us and these distant galaxies that is somehow
distorting their images consistently.
And in fact, you can notice in one patch of the sky,
all the galaxies are twisted in the same way,
and then it gradually changes to
a slightly different perturbation.
So you can even map out the density of
this dark matter if you believe it is dark matter between.
This explanation neatly explains many things.
Another example is tidal streams.
When you look at the outskirts of the galaxy,
you see these clusters of stars,
which should be all bound together as one ball,
but instead they're being spaghettified, spaghettification,
like when you fall into a black hole through the intense gravity.
So we can use the amount of spaghettification we see of
these clusters to measure
the strength of gravity that they are feeling.
And that's the get a vacation factor also matches the predictions of dark matter.
So we've met this just three examples, but we have many, many examples now of, of, of,
I think, I think you guys should have hired a poet to come up with a better word than
spaghetti.
Yeah, we normally call them title streams, but spaghetti vacation always kind of catches
for some reason, it got into the public consciousness.
And so that's the way I use that term.
But I agree, it's not perhaps the easiest term to wrap your head around.
Well, I suppose it's no worse really than the Big Bang as a poetic representation.
Well, it is a joke, but I mean, it is a joke.
It is, and it's actually quite funny to call it the Big Bang, but you know, it's definitely engineer nerd humor funny.
Yeah, yeah. I mean, we give these things terrible names. That's true.
And dark energy?
Yeah, dark energy is much more mysterious.
We have far less evidence for this than dark matter, at least far less diversity of evidence for it.
For dark matter, we have many independent sources of
information that suggest the same kind of thing.
We would still like to detect the particle,
and maybe we'll one day do this,
but probably not, to be honest.
Most of our detectors seem to keep falling short,
and whatever dark matter is,
it's probably just way beyond our energy reaches right now.
Dark energy, we only really have one driving force of evidence for it,
and that's the expansion of the universe.
So when we look at the universe, we know it's expanding, of course,
we can see things moving away from us,
that's what Edwin Hubble discovered in the 1930s, I believe.
But now it's even worse than that because we see the,
there was actually a Nobel Prize given for this,
because we see that the universe is not only expanding, but it's accelerating worse than that because we see the, it was actually a Nobel Prize given for this, because we see that the universe is not only expanding,
but it's accelerating in that expansion.
So that's just very puzzling.
Well, that's a mystery already.
Right, that's for sure.
This is the cosmological constant
that Einstein had in his equations,
and he put it in there to try and keep,
he knew that gravity should collapse the universe down,
so he added in a term to keep it static.
And now we, you know, he called it his biggest mistake
when he put it in.
He really regretted this fictional term.
But now we actually think that not only is that
cosmological constant really genuinely there,
but it's even higher than what he imagined it to be.
It's not only keeping the universe stable,
it's actually causing it to fly apart ever faster.
Well, the fact that it's accelerating, that really is incomprehensible.
You could see why that would call for the hypothesis of an entirely new kind of energy,
because that's just preposterous.
It's preposterous.
It's preposterous.
We have no way to understand it.
One idea is that it could be due to quantum fluctuations, vacuum fluctuations.
If you look at empty space, you see particles popping in and out of existence due to quantum
uncertainty and that happens all the time.
But it's one of the biggest embarrassments in physics that when you calculate the rate
of dark energy that predicts, you know, the universe wouldn't even really be here, quite
frankly, if that rate was maintained.
So somehow this theory must be wrong at some level, this energy must be being leaked out
in other places, yet when we look at dark energy, it's clearly far, far less.
So we don't even have a real good causal explanation.
It's really kind of an embarrassment, quite frankly, at this point, to understand what's
going on.
So why is there, I hate to delve into this, but I'm going to anyways, because I'd like to know, these particles and antiparticles
that hypothetically pop up in the vacuum of space,
why is that not energy neutral?
Why does that produce an excess,
this hypothetical excess of energy that's calculated
by the quantum investigators that you described?
Because my understanding was that these particles
pop up and then disappear and that's an energy neutral phenomena.
It's not because they produce a photon.
Obviously that's wrong.
If I produce an electron and positron, so positron is the anti-electron, they pop into existence.
Yeah.
And then when they recombine, that produces a photon. So that photon is now, is this vacuum energy
and that is now, you know,
there's nothing to annihilate a photon.
You can't annihilate a photon.
So it's just free to go through the universe.
So this is the-
Where does it come from, that photon?
It's essentially borrowed energy.
It's what it is, yeah.
So it's extremely strange implication of quantum mechanics.
And if it bothers you, it should bother you.
And Neal's Bohr famously said that anyone who's not
disturbed by the consequences of quantum theory
has not understood it because it's so baffling.
Well, it sounds a lot like,
it sounds a lot like let there be light to me.
You know, that's a, seriously,
that's a very strange thing.
The universe shines intrinsically.
Yeah, right, right, right, right.
Isn't that something?
Okay, well, that's a good place to end, I would say.
You know, that's a nice poetic ending, much more so than Spaghettification or the Big Bang, let's say.
So, all right. So thank you very much for walking us through that. That was fascinating.
It's nice to talk to a so-called hard scientist, although I think you astrophysicists and physicists are the strangest of hard scientists by a large
margin. So there's plenty of metaphysics in physics and that's quite fun. And so much appreciated.
For everybody watching and listening, thank you very much for your time and attention. I'm going
to continue this discussion with Dr. David Kipping on the daily wire side of things. And I think we'll
delve there a little bit more into the psychological. I'd like to find out how Dr. Kipping came to his interest in astrophysics and how his career
developed. And so it's always interesting to me as a psychologist to find out how people's calling,
the calling that made them who they are, made itself manifest. So that's what we'll talk about
on the daily wire side. So consider joining us there. And to the film crew here in Toronto today,
thank you very much.
And to the film crew there, you're in New York City,
near Columbia.
And yeah, thank you to them as well.
And good talking to you, sir.
Thank you for having me, Joran. Real pleasure.