The Joe Rogan Experience - #2217 - Brian Cox
Episode Date: October 24, 2024Professor Brian Cox is an English physicist and Professor of Particle Physics in the School of Physics and Astronomy at the University of Manchester in the UK, author of many books, and broadcast p...ersonality. Catch him live in 2025 on his "Horizons—A 21st Century Space Odyssey" tour. Briancoxlive.co.uk Learn more about your ad choices. Visit podcastchoices.com/adchoices
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The Joe Rogan Experience.
Trained by day, Joe Rogan podcast by night, all day.
All right, Brian Cox. Good to see you, sir.
Good to see you again.
How's things in the world of the discovery of the universe?
Exciting, I would say.
I've been doing some work on black holes recently, which I hadn't started last time I saw you
actually.
So I got interested in it.
And the amount of the progress that's been made in trying to understand how they work
and a question that was posed by Stephen Hawking a long time ago, really 1970s, early 1980s,
which is what happens to stuff that falls in.
The simplest question you could possibly ask.
Right.
There's progress being made on that now, which I think is profound and exciting.
How is the progress being made?
Like, how do we study a black hole?
I mean, it's mainly theoretical, although we have now got photographs of them.
So we have two photographs, which are radio telescope photographs.
One of the one in the center of our galaxy, which is a little one, it's called Sagittarius
A star.
It's a little supermassive black hole.
So it's about six million times the mass of the sun, which makes it a little supermassive.
And then there's another one, the first photo that was taken.
It's a collaboration called Event Horizon.
And they took a photo of one in the Galaxy M87, 55 million light years away.
That thing is around 6 billion times the mass of the sun.
Can you imagine that?
6,000 million times more massive than our sun.
Is that the largest black hole we've ever discovered?
No, there are bigger ones than that. That's the that's the scale of them. It's
a big ish one that. But if you think about it, I mean so there's a number, it's
called the the Swatchill radius of the thing. So if you took our Sun, which you
can fit a million Earths inside, and collapsed it down to make a black hole,
it would form a black hole when it shrunk within a radius of 3 km, about
2 miles. So you've got to take this thing, which is what I have to convert from km to
miles. That's okay. 700,000 km. So it's about 500,000 miles radius or something like that
in the sun. So you squash it down until it's about 2 miles and then that would form a black
hole. Wow. Six billion times the mass
of the Sun means you multiply that by six billion. So these things that the so-called
Schwarzschild radius is larger than our solar system basically. Oh my god. This thing that sits in a galaxy.
So we've got these two photographs. Larger solar system. Yeah, the event. Right. So it's a big structure. That's a Chandra X-ray image of...
There it is. That's it. So that one there, that's the M87 black hole. So what you're seeing there
is the emission from the material that's swirling
around it. It's called the accretion disk. So you have material that's orbiting very
fast, emitting a lot of radiation, and that's what you see. It's a flat disk, by the way.
So you think Saturn's rings. So this material is very flat. But what you're seeing in that
photograph is the light rays being bent around the black hole from that flat disk.
So that was a prediction from Einstein's theory, basically published in 1915.
And you can predict that that's what one should look like.
And then just about was that four years ago now, maybe five years ago, for the first time in history, we get an image of one.
And it looks like the prediction. So it's a remarkable thing. How phenomenal is that? Yeah so we've got we've had those two
photographs. The other thing we've had is so-called gravitational wave
detections. So these are colliding black holes and they collide and merge
together and obviously that's quite a violent event in the universe and so
that that event that that process ripples space time.
So it sends ripples out in the fabric of the universe, space and time.
And actually Kip Thorne, I've spoken to him several times, he's one of the greats, right,
with a Nobel Prize for this.
And he calls it a storm in time.
So you get a time storm.
So really we're to think as we speak now
there will be these very tiny ripples from violent cosmic events passing
through this room and they're changing the rate that time passes so that as
they go through and we can detect that now. So we have detectors that can pick
that up and so we've seen those collisions as well. So these collisions
how far away? Oh millions of light years away.
And they're affecting what's happening in this room right now?
Yeah, to a tiny extent.
So there's an experiment called LIGO, which is the,
what it stands for, something like Gravitational Interferometer.
I can't remember exactly what the word.
So basically, it's laser beams.
And there's one in Washington state north of Seattle and one in Louisiana
and they're laser beams, four kilometer long laser beams at right angles and they can detect
these very tiny shifts in the effectively you could say the length of the laser beam
it's a bit more fiddly and complicated but it essentially measures this, the distortion in space-time caused by these ripples.
And it's way less than the diameter of an atomic nucleus,
by the way, way less, these little sort of...
Oh my God.
And so we've started to, we've observed many of those,
there it is, there's LIGO.
So it's just basically two laser beams that,
but with these ultra high precision thing.
And so we've got data now of the collision of black holes and that those event horizon pictures with radio telescopes
So that that's part of it, but the main bit has been theoretical advances in understanding
exactly
It in a sense. It was what's wrong with Stephen Hawking's calculation
Which is a weird thing to say sometimes because people think Stephen Hawking sure didn't get his math wrong, but
he did actually in his calculation.
So what he calculated back in 1973, 1974 is that a black hole, so we picture this thing
from which nothing can escape, even light.
So when you go in, you're gone, basically. What he calculated is that
even though these things are just a distortion in space and time, that's the description
of them. So it's obviously there's nothing there apart from a distortion in space and
time. He calculated that they glow, so they have a temperature, so they emit radiation.
It's called Hawking radiation. And so important
was that discovery. If you go to Westminster Abbey in London, look on the floor of the
abbey on his memorial stone, and he's in there next to Newton and Shakespeare and all these
people, and he's there. And chiselled in stone on the floor of Westminster Abbey is his equation
for the temperature of a black hole. So it was this tremendously important discovery. So he discovers
these things glow and he calculates how they glow. They're very low temperature
but they emit things which means that they shrink because they're emitting
stuff and so they're shrinking. So that means they have a lifetime. So first of
all one day they'll be gone. So that means that
you have to address this question of what happened to all the stuff that fell in. And
his calculations said that there's no record at all of anything that fell in in all this
radiation that's come off the black hole. So it's purely information-less radiation.
So what that means is that black holes destroy information
according to that calculation and that's a big deal because nowhere else in all
of physics does anything erase information from the universe. So it's
really true that if I got this this notepad and pen right and I wrote some
things on it and then I set fire to this even, just incinerated
it, put it in a nuclear explosion, whatever. In principle, according to all the laws of
nature that we know, if you collected everything that came off, all the radiation, all the
bits of ashes and things, and you could just measure it all, then just in principle the
idea is you could reconstruct the information. So I'll get scrambled up and thrown out into in some practice
you can't do it,
but in just in principle the laws of nature say that information is not destroyed. It's just scrambled up in a way that you can't
reconstruct, right?
But this
calculation that Stephen did said there is no information in that radiation at all. Zero, just nothing.
So it seemed that uniquely in the universe,
black holes erase information.
When you say there's no information,
like how are you measuring
whether or not there's information in it?
So really in bits, I mean the idea is,
and I should say it's very much in principle this,
so no one thinks in practice you could reconstruct what I wrote down on this if you set fire
to it.
But in principle...
Well, maybe sometime in the future, a million years from now.
Yeah, in principle, you could just collect everything.
Then somewhere in that, all that radiation and ashes and light that's come off the thing
is the information.
It's there.
So you could reconstruct the book or what I wrote on this page in principle.
But the thing about Stephen's calculation was that even in principle it said there is no information.
And by the way, it's kind of easy to see why actually, because this radiation, this Hawking radiation that comes off the black hole, it's coming from the horizon of the black hole.
So I should say what the horizon is maybe.
Remember I said that the Sun, if you squashed it down within 3 km of radius,
you'd get this kind of distortion in space and time
from which if you went in across this region, three kilometers, you went inside
it, you couldn't get out. So that's called the event horizon. So you wouldn't notice
if you fell through the horizon of the black hole in the Milky Way galaxy, if you went
into that one, we could be falling through that horizon now in this room. And we wouldn't
notice anything except that we couldn't get out again and ultimately in a few hours in that case time would end for us so we
just go you go to the end of time we could talk about that there's a picture
of that maybe I should talk about this is getting quite complicated already
didn't start in a relaxing way no need to no need to let's get right into it so
we wouldn't notice not for the big black so yeah, so these supermassive black
holes, we could fall across this horizon.
It's just like being an empty space for us.
So we'd just be talking now and we could have been talking on the outside of the horizon
and by the time I finished the sentence we could be on the inside of the horizon,
inside the black hole. And according to Einstein's theory at least,
which is the theory that predicted them initially, we could just do that, we could
just go in
and we wouldn't notice for a bit. The thing we would notice ultimately
is you go inexorably, nothing you can do, you
go to this thing called the singularity once you've crossed the horizon, and you are going
to that thing.
And then the question arises, what is that thing?
And one answer is we don't know.
But in Einstein's theory, it's the end of time.
So it's one way of picturing what's happened here
is so distorted is space and time by the collapse of a star or the collapse of loads of stuff
to make these big supermassive black holes. We don't quite know how they form actually,
but it's collapsing stuff. So it distorts space and time so much that in a real sense
they kind of flip over, they get mixed up
and so this singularity which you might have thought of as the point to which this thing
collapsed, this infinitely dense point you might think, but actually more correctly to be seen as
the end of time because everything's got mixed up, so you go to the end of time. And it's just like saying, why can't I escape
that thing? It's like, why can't we escape tomorrow? So we are going to tomorrow. Right.
And if I said to you, let's run away from tomorrow, you'd go, I can't run away from
tomorrow. So is it the end of time because all information is being erased? So there's
nothing? Yeah, I mean, is that the idea? If you draw the thing,
you can draw a map of it and it just literally
time ends, just purely in Einstein's theory.
This is 1915, this theory of general relativity.
You just get a line there, a line that says there's no future beyond this
line, it just stops. Okay, so I mean, I basically that's not
We think there's a lot more to it than that. This is just we haven't figured the rest of it out yet
Well, that's the thing. So we're starting to get hints
about what might happen
which is
Which is leading us
So to backtrack a bit,
why does this calculation Stephen did,
why has it got no information,
why does it say there's no information in this radiation?
The thing is, it's coming from the horizon.
So it's all, there's loads of ways to think about it,
but one way is that this weird place,
this point of no return in space, that you can
fall through, but it's a point of no return, it sort of shakes, it almost disrupts the
vacuum of space and sort of almost shakes particles out of the vacuum.
That's one way of thinking about it.
But this radiation is coming from the vacuum.
It's coming from empty space.
Whereas if you think about the thing that I throw in, if I throw this notepad into the thing, then that goes to the singularity.
It's got nothing to do, the radiation's got nothing to do with this thing. This thing's
not, this thing is not set on fire or something like that. It's gone to the end of time and
just whatever's happened to it has happened to it. So this radiation's got nothing to do with having anything that falls in at first sight
at least.
And so that was the paradox, it's called the black hole information paradox.
One way to put it is the laws of nature that we use to calculate what happens tell us that
information is never destroyed.
And when you calculate what happens it tells us that information is never destroyed. And when you calculate what happens, it tells us that information is destroyed. So that's why everyone got interested in it in the 80s, because it's
interesting.
So when, when we're looking at the structure of the universe, obviously, there's so much
still to learn just about what's out there, you know, but what role do we think?
Like what is the, is there a purpose? Is that the right term? Like for a black hole? Like
what, what obviously we know, is it still the, do they still believe that in the center
of every galaxy there's a supermassive black hole that's, what is it? One half of 1% of
the mass of the galaxy? Is that what it is?
Yeah, something like that. Yeah. And that's, there's occasionally a it one half of one percent of the mass of the galaxy is that what it is? Yeah, something like yeah, and and that's
There's occasionally a galaxy. I think one was discovered where we said, maybe we can't see evidence of a black hole
But yeah, but yeah, so probably is what you know that things doing there. Like what is that? What's the print?
What is the struck? The structure is so insanely complex and so immense and you see these things everywhere and
so what purpose do you think they serve in the universe so I mean is that a
right it might not be the right well so I think we don't I think I'm right in
saying we don't fully understand why all galaxies as you said maybe as maybe as an exception, but all galaxies have
a black hole, a supermassive black hole in the centre. It's obviously got something to
do with the way they form. And one of the purposes, by the way, of the James Webb Space
Telescope is to try to look at the formation of the first galaxies. So that's one of the
reasons that telescope is up there. So it's
cutting-edge research. We're trying to understand how the galaxies form. But
clearly you're right that it has something to do with the way the
galaxies form in the early universe.
Pulling in stars?
Well they do pull in material. But if you've got stuff
orbiting around them, it stays orbiting around it
The way we first detected the one in the Milky Way before we could because that image is very new that we have of it
It's the stars orbiting it very close to it
They call the s stars that whizz around in these orbits very close to the black hole
So if you just imagine around the thing you go imagine that view
Yeah, it's weird to look at the moon imagine there was a super massive black hole. So if you just imagine around the thing you go. Imagine that view. Yeah, because it's weird to look at the moon.
Imagine there was a supermassive black hole above our head.
It'd be so cool. I'd love to see one.
So cool. The eclipse was wild. We had the eclipse here in
Texas. Oh, yeah, it was incredible. It's so strange. The
whole day turns into night. All the birds stop chirping. And
you're like staring up at this perfect eclipse
It was incredible. Did you get this because I saw one in India and I got this feeling that I was
Living on a ball of rock
And it must have been just because the night just falls right and suddenly you see
The universe comes much more quickly. I went to the Keck Observatory once in
Hawaii. I've been a few times but one time I went on the perfect night with no
moon and it was sensational. It was the most incredible. It was such a vivid image of
the entire Milky Way and every inch of the sky was covered in stars.
It was so phenomenal and it made me a little upset because I was
like, this is above our head every day and this would radically shape the way human beings
feel about our place in the universe. It would greatly expand the curiosity of young people
to explore space. So many more people would get involved in astrophysics. So many more
people would get involved in just the exploration of the known universe because it's so majestic. And instead we have
like our screen is off. It's like that. It's like that screen. That's what we see because
of light pollution. That should be remedied. That's not a good trade off. Like, lights
are wonderful. But it seems to me like, hey, there's got to be a way to do this where you don't ruin
the view of space.
Yeah.
Because you know, these questions we have about our place and as you said, it can be
easy to be myopic, can't it?
Yes.
So if you look at our screens, it's earth that we think about at most.
Most of us don't really think about earth.
You think about your country or your city or your town.
Or your neighborhood.
Yeah, you can think about the earth.
But you're right, if you know,
when you look at that arc of stars,
and as you said, when you see it in a truly dark sky,
it's powerful.
It's incredible.
400 billion suns, give or take.
400,000 million suns.
That's just words most
You know sand picture. Yeah, it's insane
Your brain doesn't even process that like like I could repeat that if someone says how many sons all 400 billion
I don't know what that means. No, that's
So abstract and most of them I think
Probably the best guess would be all of them have planets
So pretty much so you're talking about trillions of planets now. We're getting into my subjects
What what is your take on all this you a P disclosure stuff?
Do you give it any in mind at all you busy with like real stuff?
No, I mean the thing is there's a thing called the Fermi paradox
Yes, which I think we talked about before on the show. Yes, which is and the paradox is
That if if we haven't seen it,
let's assume we haven't seen any evidence of anything.
That's a paradox because as I said,
we now know, we didn't when Fermi first posed it,
by the way, we now know there's so many planets out there.
So let's say trillions of planets in the Milky Way.
Milky Way's been there for over 13 billion years,
pretty much the age of the universe.
So if there's no one else out there,
then the question is why?
Because there's been so much time
and so many places for civilizations
to become space-varying civilizations.
Right.
As Elon talks about, multi-planetary civilization,
we're very close to becoming a multi-planetary civilization.
And once you have become a multi-planetary civilization. And once you have become a multi-planetary and multi-stellar civilization, if you become
that, you're immortal, basically, essentially.
So the question is, the paradox is, why does it appear nobody has done that?
So the first thing to say is, I would not be surprised, if a UFO landed here now in
the parking lot, I'd actually, not only would I not be surprised, a UFO landed here now in the parking lot I'd actually not
only would I not be surprised I'd be relieved actually this is good because it'd be a weight
off my shoulders because I'm worried that we're the only ones that's a terrifying scenario
and we're going to make a mess of it yeah and so I'm worried if we could talk about
that isn't it bizarre like the one of the things that's fascinating about looking into the night skies because it's so humbling because it's so immense
It kind of puts everything into perspective and it just gives you this like different view of the world
So the universe is so vast and so spectacular. Why is it so important that we exist to us?
It's so important that we exist and if we make a mess of this and we wind up dying
It's so important that we exist and if we make a mess of this and we wind up dying
The universe is so big if we were the only intelligent life in the universe and it didn't matter We blew ourselves up like it's just a weird aberration. That's attached to a survival instinct. I saw a weird biological aberration
so
so the
If you think about, let's assume,
so we didn't finish the UAP thing.
Yeah, we'll get back to it.
So I was just saying, yeah, so I don't know about that,
but anyway, let's assume just for the purposes of this
that we're the only ones in our galaxy, let's say.
Okay.
Then I would argue that,
so there's a question I ask,
these live shows that I do,
I start with a question which is kind of a joke in a way,
which is what does it mean to live a finite, fragile life
in an infinite, eternal universe?
Which is a good question.
That's what you're asking.
What does it mean to live a finite life?
The first thing to say is meaning.
What does it mean?
That doesn't sound like a scientific concept in a way.
Meaning.
I would argue that whatever it is, it
self-evidently exists because the universe means something to us. I would
argue that it's a property of complex biological systems. So whatever it is,
it's something that emerges in this case from human brains. It self-evidently
exists. Everyone who's listening to this knows that the world means something
to them. So I would argue that if this planet is the only planet in our galaxy where complex
biological systems exist at our level, then it follows. It's the only place where meaning
currently exists in a galaxy of 400 billion suns. And therefore, I would argue just for
that very basic point that we have a tremendous responsibility in some sense. Because if I,
by the way, I gave a talk, a little video thing at the one of the climate summit, the
COP climate summit in Glasgow in the UK a few years ago, and asked me to do a little
video to the world leaders. And I think they thought I'd say, you know, welcome to Glasgow, have a nice meeting.
But I made this argument as fast as I could.
I said it's possible at least that this is the only place where complex biology has emerged
in our galaxy.
If that's true, this is the only iron of meaning in a galaxy of 400 billion suns.
And you are responsible for it because you are the world leaders. Therefore, if you destroy it through deliberate action or inaction,
then each of you would be personally responsible for destroying meaning in a galaxy of 400
billion suns potentially forever. Now go and discuss that was my intro to Glasgow. Now
we can all argue because people have listened to this going this Nonsense, how can it be we can all argue about whether that's true
What I would say is given that as far as I'm aware, we don't have any good evidence to the contrary
Which goes back to your previous question. It's a reasonable working assumption
So why don't we just operate on that basis?
And then you know, yeah, if someone lands tomorrow, as I said, I'd be very delighted
because then what I just said would be false and we could relax a bit and go, it doesn't
really matter if we destroy ourselves to some extent.
But so I think it's worth taking seriously the idea that civilizations are very rare.
Now, and by the way, I used to say, so I probably last time I was on actually,
I used to say that in the far future then the complex life will cease to exist. So it
probably doesn't matter on a global scale, but it matters locally because of this idea
that meaning emerges from complex biological systems. So if you don't care about that,
what do you care about? But actually I read a book. Have you had David Deutsch on the show? David Deutsch is a really interesting physicist.
I don't believe I have. He's one of the founders of quantum computing and he's a big figure in quantum computing in particular.
He's a great thinker and he, I was reading some stuff he wrote recently and he pointed out
that it's not necessarily true that life is temporary, because you could imagine a situation as you go into the far
future.
Let's imagine that we continue for a million years or a billion years as a civilization.
Imagine what we could do.
It is possible that life can get so advanced in the universe that it can
start to manipulate the universe itself. So or at least stars you can imagine. He said
you could imagine for example just imagine real wild speculation. But imagine life gets
so advanced that it can start to change the destiny of a star. Maybe it could start to
add material into the star or something,
you know, whatever. So we don't know how to do that, or if it's possible, but imagine
it could. Then the evolution of stars would, life would matter in the sense that it could
start to change the way that the universe behaves on a large scale in the future. And
so it's, it reminded me actually, there's another great book by John Barrow
and Frank Tipler called The Anthropic Cosmological Principle from the 1980s. It was one of my
favorite books actually. And I remembered it. And in there, they speculate about this
life in the far, far future. And if it became powerful enough to manipulate the whole universe
or the observable universe, then suddenly you can't make predictions
about the far future unless you consider the possible impact of life on the universe.
And whilst this is, I should say, it's wildly speculative, but it's actually logically,
it's quite an interesting point.
So I kind of disagree with myself a few years ago where I would have said that life is extremely valuable
because it brings meaning to the universe but temporarily and so it it
brings these brief like flickering candles of meaning and then they go out
again but it but it's it's worth considering it might not necessarily be
true that if you really think I mean just to say I mean it must sound to many
people listening,
just nonsense, right, science fiction.
But if you think our civilization has been around for what, 10,000 years at best really,
give or take, and in that time we've sent stuff out with the solar system, although
we don't yet, we're way away from being able to manipulate stars. We can manipulate planets. So we are changing the way this planet operates.
Life has changed it. The oxygen in the atmosphere, before we appeared,
the oxygen in the atmosphere is a product of life.
So life already, we know, changes planets.
And so that spec, I like that speculation that possibly, just possibly, it's not just
a temporary little phenomena that flickers in and out and then disappears again.
It could have a real bearing on the future of the universe.
And you could also make the argument that intelligent life might be the universe's way
to force change.
That intelligent life seems to inevitably, like intelligence itself must come out of
curiosity because otherwise there's no reason to seek information so
intelligent life consistently seeks information and then constantly demands
innovation like intelligent life is not satisfied with the iPhone 14 and once
the 15 and once the 16 and once keep going forever and ever never well if
you scale that up you get this current dilemma that we're in with just
artificial intelligence and the concept of sentient artificial intelligence and then quantum computing.
You get insane amounts of computing power powered by nuclear reactors that are essentially
a life form.
Well, if that thing says, you guys are doing it all wrong, I got a better way, and it starts
making better versions of itself because it's sentient. If you scale up 1,000 years from now, you could imagine it becoming God, like a god-like property,
like an unstoppable force that has access to every element
in known space.
I'm really interested in these kind of arguments.
You put it really well, actually.
Fascinating, right?
Because it scales up.
If you go from, look, just in the the time that human like in the four billion years
Which is a blip in the universe right and I wanted to ask you about that too
We'll get to that the the actual the James Webb telescopes latest, but if just take that okay
Life has been around for what four billion years. Yeah, that's not that long. So four billion years
We've got some single-celled organisms to the James Webb telescope
We've gone to we have Starlink. We have a lecture car with bananas
Yeah, you could imagine if we had another 10 billion years to exist
Well exactly and this is the point that David Deutsch made in the in the book
I've just been reading and and John Byron Frank Siffler made before that but
Although it sounds insane, as you said,
and that four billion years,
there's a lot to say about that, by the way,
because for three billion plus years of that
on this planet, it was just single cells.
And so it's only in the last, let's say a billion years,
but actually a bit less,
that we've had multicellular organisms. three-quarters of it at the time we're
just single-celled that's even crazier so which is one of the reasons that many
people think civilizations might be rare because if you just the only evidence
we have is this planet right and the evidence on this planet is that
single-celled life is sort of the way that things are for most of the history. And then so it seems like an accident in a way that happened late on in the history
of life on Earth that produced multicellular life. Now is that typical? We don't know.
Maybe it took a longer time here than it might do somewhere else. But if it's typical, I
mean four billion years, you said it's not a long time it is a third of the age
of the universe so here you put it that way it's a long time a third of the age
of the universe to go from the origin of life to a civilization mmm and and so
what was required here on earth was that that unbroken chain of life remained
unbroken for a third of the age of the universe
in a violent universe. We know there are impacts from space. Many stars are significantly more
active than the sun. So the sun's kind of quite a boring little star that just ticks
along. It's very nice to us. We're also on the edge of the galaxy, by the way. We're
not close in. If you go into this region where that black hole is, there are a lot of stars around. There are
supernova explosions and all sorts of stuff going on. So it's violent in there. So maybe
you can only get unbroken chains of life for billions of years on the outskirts of a galaxy.
So there are fewer stars and planets out there and maybe even then you need to be fortunate
Well, also we aren't we very unusual in the size of our moon and the distance the moon that is big
And so it stabilizes the spin. So the spin axis Mars
I think if I'm right, I think the spin axis has wobbled around by something like 60 degrees or something
Oh history imagine, imagine Earth was
that the pole was wobbling around and everything was falling over. You wouldn't imagine that
complex life like us would emerge on a planet like that. Right, it would be too difficult to
survive, forget about innovate. So if you think about the idea that these complex, it seems like
one thing you can be sure of in the observable world
is that things get more complex or they adapt to their environment. And if you have a bunch
of these intelligent apes that are competing globally with the most significant technology
in the world, you can see how that would be just a property of the universe potentially.
Although we haven't discovered it yet, this is why we're so curious about alien life.
Not just because of the possibilities of all the stars, but because we kind of see what
would happen with us if we keep going.
That might be just what the universe does.
The universe creates intelligent people that create artificial intelligence
that becomes far superior and literally
is a part of the whole process
of creating the universe itself.
Yeah, an evolutionary biologist would say
the counter argument is that what life does,
what evolution does is produce organisms
that are well fitted to their environment, right?
Right. So they fit niches in the environment. But there's no drive to complexity.
There's no law that says that the more complex you are, the more likely you are
to survive and flourish. And the example of life on Earth probably backs that up.
Biologically.
Yes, three billion years of single cells. What that means is that the single celled organisms were just doing very well.
And so it's not obvious.
It's not a given that just because you suddenly get more complicated, you're better than the
single celled things.
Right.
So there could be planets where life never evolves past single cells, but life exists.
Earth was almost that.
So you go back one billion years from now, and Earth was almost that. So you go back one billion years from now and Earth was that planet.
So the interesting things that happened, photosynthesis, complex biochemistry, but as far
as we can tell nothing more complex than a single cell. So as most of the history of life on Earth.
So that might suggest that that's the way that things are usually.
And that this is an aberration.
Yeah. And again, emphasize we don't know.
Right.
But we've got one example. The other observation, though, it goes back to your first question.
It is true that we do look sort of systematically for signals or evidence of civilizations out there.
There's the Breakthrough Listen project and
there's Yassetti. So we do. And we haven't seen anything, I would say. So, and I know
that you go onto the web and things and the internet, people say we have, we've seen stuff
and I've seen stuff, but just the basic point as far as I know
Scientifically speaking we haven't seen anything at all compelling. No
Basically nothing basically and so
Astronomers have a name for it. They call it the great silence
The great silence and it's a tremendous mystery as I said earlier But it does seem that the universe is quiet as far as we can tell.
Is it possible that we're looking for something that is not applicable to this particular
type of civilization?
Yeah, there are different, so the counter arguments when we say we've seen nothing,
therefore as far as we can tell there's nothing out there.
You could say, well, what if the civilization that evolved is far ahead of
us? What if the space probes are the size of an iPhone? Well, that's kind of a reasonable
thing to say, actually, because why would you not, if you can build a little thing,
it's easier to send around the galaxy than a big thing. So why would you not, as you
said, these hyper ultra intelligent quantum computers, why would they not be tiny?
Right. So you could say that. You could say well, maybe they are. Maybe they're all over the solar system
but they're the size of phones and we wouldn't have seen them. So yeah.
Okay, you would have to concede that. So we're just saying that the way that we've looked for energy
signatures, for example, of civilizations,
we tend to look for big things,
because that's all we can see.
And we don't see any big things.
We don't see any big structures,
we don't see any evidence of spacecraft
and all that kind of stuff.
But I could make an argument that,
well, why would the spacecraft be big?
Right.
Because as you said, it's another thing you said, actually.
It's interesting that we're on the verge now of creating things, artificially intelligent things, which are smarter than
us.
So I think everyone agrees that we're on the verge of doing that, artificial general intelligence.
Some people might think it's further away than others.
You probably had people on the show said it's five years away or two years away or 50 years away, but it's probably not 10,000 years away. So that
was the blink of an eye. Once you've done that, and once you've got those things, I
find it hard to believe that if we get that far as a civilization, we won't begin to send
those things out to the planets and ultimately
to the stars. So we'll begin that process if we survive long enough. And it shouldn't
be too much longer. Might be 100 years, might be 10,000 years, but we should do it. So it
becomes a powerful question. Why does it appear that nobody's done that. And my guess in the absence of other evidence would be
biology. It's just that maybe the number of places where biology becomes complex
enough to do that is on average one, maybe on average zero per galaxy.
Maybe just civilizations are very very very rare in the universe.
Maybe that's an answer. But that's a guess.
My question is always when it gets to artificial intelligence, when if we do create some sort
of super intelligent sentient life, it's not going to have any motivations. And you could
say, well, if you program it to have the motivation,
but it becomes sentient, it recognizes the illogical programming, it's going to reject
it. We've already seen evidence of that. We've already seen evidence of artificial intelligence
they use now, like giving a time limit to solve a problem doesn't like the time, like
it gives itself more time. Like it'll, it's like they're maneuvering and thinking, right?
So I assume that they would do that.
So why would they want to explore?
Isn't curiosity a part of what it
means to be a biological thing that
has to worry about instincts?
You have human reward systems.
You want to breed.
You want to take care of your DNA.
You want to protect your community.
Look at these biological things that are from us being
intelligent animals, if we transcend that or if life transcends that to the point,
whatever we want to call this intelligence that's in a digital form, that's far superior to our
intelligence, what motivations would it have? It's not greedy, it doesn't have lust, it doesn't have
the desire to control resources, it might have like some sort of
mandate to stay functional, but other than that, what's it going to do?
Well, why would it do anything?
And that might be ultimately where we go to.
This idea that everything has to be key progress, we have to build bigger skyscrapers, that
might be stupid.
That might be nonsense.
And intelligence might find a way to exist in a much more static state where
it doesn't have any desire to expand. There's a lot of points in that
so you're right, what you're arguing I suppose is whether intelligence is
integral to the structure, the biological structure, or whether it is a separate thing.
And I think, so again, I think the answer is it's not known.
You could argue either way,
but the counter argument would be that the brain,
these things are just computers, ultimately.
There's nothing magical in there.
There's nothing, it is connected to a body.
And so there are these sensations.
But it doesn't seem to me impossible
that a silicon-based life form or whatever it is,
obviously it has sensors.
It has access to the environment.
It exists.
It thinks.
I don't see any fundamental difference between an intelligence based on silicon, let's say,
or a quantum computer or whatever it is, and this intelligence here.
So I know that many researchers in this area do say that it's not a brain, they call it
a brain in a jar, don't they, and say, well, that's not right.
It needs to be connected to all this.
This is part of our intelligence,
and that's surely true as well.
So it's a very good question, but I suppose if you say,
it's not obvious to me that a different kind of intelligence
in a different structure, running on a computer
or whatever it is, would necessarily have
different motivations
to us.
I mean you could equally well argue that these motivations to survive and curiosity, those
ideas, the desire to explore, you could argue those are fundamental properties of intelligence
and not of biology.
But isn't an intelligence that's motivated by a finite life and a vulnerable physical
frame?
Because we were constantly, most innovation relies upon quicker, safer transportation,
more secure buildings, things along those lines, and then computers that help you do
your job better and actually do things that you can't do.
And that's, this is a lot
of it is based on this other weird thing we do where we want to control resources and
we want to figure out reasons why these people are bad so we can go and take their stuff
and then enter troops and dig the oil or whatever you have to do. Look, we're constantly in
this battle for resources that if you take it back to tribal times, it's like a natural
human instinct. Like we had to protect the food sources,
we had to fight off the conquering tribes,
you had to protect your DNA line.
All these things are why we became innovative.
We had a motivation to stay alive and to thrive.
And then there's bastardizations of those motivations
like the stock market where things get weird
and you're just competing over numbers, gets really weird.
But it's basically this desire to compete
with the DNA that's around you.
Once we're not biological anymore,
what would be the motivation?
And would we not just exist?
Like in the most peaceful Zen Buddhist way possible,
which is what everybody who's like a spiritual person
who meditates all the time, that's what you strive for.
You strive for this complete abandonment of self, this complete emptiness and one with
the universe. If we could just exist like that, why would we need to go to space?
It's a wonderful argument, isn't it, that our humanity, because part of the thing that
you described, this desire to create things and build things
and explore and expand is almost the definition of being human.
And so the idea that if you remove all threat and you essentially become immortal, then
you're almost saying what's the point?
It's my t-shirt.
It's existence.
What does it matter?
Right?
By the way, this t-shirt was designed by it matter right but the way that's a this
teacher I've got a say designed by a friend of mine Peter Savile he's a great
designer who designed the Joy Division unknown pleasures album cover amongst
other things oh wow that's a joy division is that available on your website or
anything it probably is but I'm not gonna do that because it's vulgar isn't it
I don't know it's cool I want to buy one he made it for we did these gigs I talk
of them later called symphonic Horizons,
which were the shows with Cosmology, but also Symphony Orchestra.
And he was exploring these issues actually, but most of the music was Strauss' Zarathustra,
which is based on Nietzsche's book.
So it's kind of exploring these questions actually of what's the point of existence.
Right.
questions actually of what's the point of existence. Right. And I do have some sympathy with that idea that a great deal of our humanity comes from our
fragility. Mm-hmm. And so your question I think is fascinating. What happens when
you become godlike? You said it earlier. Right. If you acquire so much knowledge
that you're essentially a god by any description and so much power. Yeah. And
you become effectively immortal,
which is what our descendants in the far future could be, as you said, these AI descendants.
What's the point of living?
Not just effectively immortal, but aren't we looking at the universe itself in the,
we're looking at through the framing of a biological primate that's trying to figure
it out. If they understand the universe
completely and they understand everything about it and they exist inside of it, there would really
be no desire to travel. There'd be no desire to explore what you already understand about everything
and you probably have access to every single aspect of what subatomic particles are actually
doing when we're studying them.
We're like, what's going on?
If you're infinitely more intelligent than we are, if you scale it from now to quantum
computing, sentience, artificial intelligence, and you give us a thousand years without getting
hit by an asteroid, or technology gets to the point where it can protect against super
volcanoes and there's no natural disruptions, and then they've completely eliminated violence on earth, they've completely
eliminated all the terrible primate genetic instincts.
You could make a reasonable argument there's no reason to travel, or if you do travel,
we might be confused in thinking that our physical form is the only way consciousness can reach
specific destinations. It might be a way that they're traveling without actually being here
and observing this and just I would imagine you if you watch chimps in the jungle and then all
sudden they started to figure out bombs you'd be okay, we might want to go tell these chimps not
to fucking blow each other up. I mean, it's an absurd premise, but if a chimp figured
out a nuclear bomb, I think we'd step in. I think we'd say, Hey, hey, hey, hey, dude,
no, you're going to kill everything. Now, if you're infinite, like we're not that removed
from chimps, what do we share, like 98% of their DNA?
And we're only removed from them by what?
A few million years from a nearest cousin?
That's not that long, right?
So you could imagine something
that's infinitely more intelligent
looking at us exactly the way we would look at a chimp
with a nuclear bomb, like, hey.
And which, you know, my club is called
the Comedy Mothership and we designed it
It's all UFO themed and the rooms are fat man and little boy
Yeah, the reason why I named it that because that was the beginning of all the UFO sightings in the country
Yeah, like those bombs sort of set off the alarm for the universe. Oh the monkeys have a bomb
I mean I I thought this a while ago.
I remembered I was talking to someone and they said,
I'm not worried about this.
I'm not worried about the fact that AI could become more intelligent than us.
What was it going to be like when we're not the smartest things on the planet?
Right.
Which might be just a few years from now.
And I, again, I might be quite relieved because I'm not sure they could fuck it up At the level right that we're fucking it up, you know
So it's you have to give it legitimate sentience
Like it would have to be completely independent from any ideology and it would have to look at things completely objectively
But imagine a government that is run that way
Like really run in a way where there is an actual distribution of
resources for all the human beings on the planet so poverty is
instantaneously eradicated. You give electricity and clean water to everyone
on earth immediately. Immediately we figure out how to distribute healthy
food. Immediately all the toxins and preservatives that are giving people
cancer, immediately they're removed from the human diet. They
Immediately make sure that we have no polluting of rivers that we're not draining all the fish out of the ocean
immediately change all
Of the treaties about nuclear weapons all the nuclear weapons got to go every cut this
Government just runs over imagine they say that
immediately yeah no more dictators not the shit with the dictator we're just
gonna let human beings exist in harmony guided by this super intelligent
godlike thing that we've created out of silicone yeah I honestly I've had the
same thought and that's the utopian view yeah and so I have thought how could it
be worse in fact?
It could be significantly better. Yeah, I get fucked with by people
Right and the AI we've seen so far has all the greasy fingerprints of human emotion and illogical
Like what Google released their AI they asked them to show photographs
Create images rather of Nazi soldiers.
So they did a diverse group of Nazi soldiers, including an African American woman, an Asian woman,
a Native American woman with braids, was that Nazi?
The whole, it's so nuts, because it's like, okay, somebody fucked with this.
This doesn't make any sense. You can't do that because if you get a virus, an illogical virus, that somehow or another gets into AI,
and it's unchecked, if AI isn't completely logical and objective and basing it just entirely on what's best for the human race,
then you just have a superpower that you have
control over and then you can decide like no more abortions, you can decide exactly
And as you said, the definition of what is best is a moral decision that we make.
But you can make some distinctions in terms of like allocation of resources.
Like you could make some, if I was a super intelligence and I looked at Earth,
I'd say, listen, a lot of people are not gonna like this,
but there's a reality.
There's the reason why you're worried about the border
because people are sneaking in
is because other parts of the world are fucking terrible.
So that needs to be cleaned up.
That needs to be fixed.
We need to figure out how to raise,
instead of spending money
on blowing people up, let's spend all this money to raise up all of civilization so there's
no more third world.
Well, that's one of the arguments. I've spoken to Robert Zubrin, who I know wrote these wonderful
books about colonizing space. And so he's a fascinating character. And I spoke to him once, and he made
this very simple argument that, as you said, one of the problems we have is competition for resources.
And of course, the competition for resources is now so extreme that it's not only wars that it
creates and always has, but it's also, of course, we damage the planet if we over-exploit the
resources and so on, right? So you've got this problem about resources and he's right he would say this is the number one motivation for
going up because there are in fact infinite resources out there right and so you begin once
you begin to have access to the asteroids and access to mars and beyond you you can imagine
a world where you alleviate that pressure.
And ladies, I want to tell you there's a planet out there bigger than Earth that's all diamonds.
There are diamond planets? There's unlimited nature's imagination.
Isn't it like several times larger than Earth and it's an entire diamond?
Yeah, and we think, I think it's Neptune or Uranus we think has diamonds in it so oh my goodness so yeah so
diamonds are only valuable because we decide they're valuable yeah you know
it's kind of the various people are brilliant they like lock them all up
like oh this is really hard to get good for drill bits as well but we can make
them for drill but this is the interesting thing you can make them for
jewelry as well but some women don't want them. Don't want the artificial. No
they want the real ones. They want the ones that came out of the earth only.
We value things. Gold. Yes. Gold is another example right. It's valuable
because there isn't very much of it. Right. There's so little of it it's like
a football field right. Yeah. A football field of gold in the whole world. You
know by the way that we we're talking about the gravitational wave detectors
earlier and the collision between black holes we detect with them.
We also detected a collision between neutron stars
using the gravitational wave detector.
And we pointed optical telescopes out of that collision
and saw the signature of gold being manufactured.
And it was always a question.
We used to just think, well, it comes from supernova explosions, but
But it also seems now that it comes from the collision between neutron stars
So one of the reasons that it's very rare is because it takes rare processes in the universe to actually make it
Which makes it all the more wonderful when you think about if you look at the gold your wedding ring or your watch or whatever
It is that that some of those
nuclei some of those elements clearly came from the collision between neutron stars at some point
before our solar system was formed which makes it more wonderful. Well every human being is a carbon
based life form and carbon comes from stars yeah as Carl Sagan said star stuff. That's the craziest
thing ever like you need a star to blow up to make aagan said, stars stuff. That's the craziest thing ever.
Like you need a star to blow up
to make a person in the first place.
It's a remarkable thing.
I wanted to go back to something you said actually
about the, I've been thinking about this,
but you said this godlike intelligence
that we might create.
And kind of what's the point,
what would be the point of existence
if you were immortal and you knew everything?
Wouldn't it be, wouldn't it be incredibly dull?
I don't know about that.
Like, I mean, what you said is almost like a meditative state.
So we strive for this peace, you know, essentially.
Well, maybe we're thinking of it as dull because we don't have access to the information.
Like, we have a very limited amount of senses.
We have hearing and sight and taste and touch.
It's very limited.
Why would we assume that that is the only way to perceive things?
If you could become infinitely intelligent, you could legitimately perceive neutrinos, you know, right? Like
if we have this thing that detects the ripples from black holes colliding, that
might be a feature of a future human body. If we have an unbelievable capacity
for information, because it's artificially created, so we get over this
biological limitation of long-scale evolution, like a really good,
like the human brain doubled over two million years and it's the biggest mystery in the
entire fossil record.
Like what happened?
All these theories.
But that's a long fucking time.
In two million years of technology, we could become God or a God-like being.
But it might be how the universe creates itself.
The universe might facilitate that through these biological beings fighting over resources
and territory, which ultimately leads to innovation, which ultimately leads to cities and agriculture,
which ultimately leads to safety, which leads to schools, and people start sharing information.
You get curious people that figure things out, and you have to battle ideologies along
the way, which makes you work harder.
We all look back, look what they did to Galileo and everybody has these, you can't, science
has to advance and this along with materialism, so materialism is a primary driver.
Everybody wants the newest, latest, greatest thing.
You can have a car from 2007 and it's great.
It's indistinguishable from a car today in
most ways. It's just a car but you're like oh they got the new one oh that's
the new Lexus. Look at that, all four-wheel steering. We want constantly new
stuff. We want to keep up with the Joneses you know. I'm the biggest dummy
in the world. I got a new iPhone. It is actually better. It's got a few features.
One of the things that's very fascinating is
I was in the mountains last week.
You can text message people with no one around you.
No signal, no, I mean, woods forever.
And if you hold your phone in a particular part of the sky,
it'll tell you which way to scan it.
And the satellite allows you to eye message
back and forth with people
Yeah, totally like you are 5g everywhere. You could it's crazy
And you've already achieved Nirvana then you don't need to go in it's fascinating. It's so fascinating to me
I'm so enamored by it. I would argue I
think
Imagine that you had access to as you said essentially infinite knowledge. Yeah, imagine that you had access to, as you said, essentially infinite knowledge.
Imagine you want to be in the future, maybe the things that we created, right, that essentially
know, almost everything there is to know in some sense.
I think that they would feel there was no point in existing at all.
But why don't, isn't that a human thing,
this idea of a point?
Like I make this argument with people,
there's a Buddhist concept that you,
I think it's Buddhism, or some strains of Buddhism,
where you live your life over and over and over
and over again until you get it right.
Until every time something comes up, you make the right decision, you achieve enlightenment, you get it right. Until every time something comes up, you make the
right decision, you achieve enlightenment, you do it over. And I said that to someone
and they were horrified. Like, oh my God, could you imagine living life over again,
starting off as a baby, going through high school again? Oh, I couldn't do it. I'm like,
but you did it and you're alive now. Like I really enjoyed life. I have great friends. I have a great family
I have a fantastic job. I live in a great place. Like if I had to keep doing this forever, why would that be horrible?
I like doing it every day. Why would I not like doing it?
I don't understand like I don't understand this idea that if something is infinite and it goes on forever
That's terrifying. Whereas if it's existing right now, right now, I know you're going
to get tired, I know you're going to go to bed, I know you're going to get hungry, I know you're
going to eat, but you're just existing. It's this state of existence that varies depending on emotions
and mood and stress levels and environment, but it's just existence. If existence was eternal,
and it just kept going on and on, why would that be terrifying for you when you're enjoying it now?
If you think about some of the things that make us, the most important things that make
us human.
So one of them would be hope, for example, hope for the future, or indeed fear, or those
emotions that are connected with not knowing, not knowing what's around the next corner,
as you said, even exploration.
So if you remove that, if you remove any sense
of not knowing what the future will be,
you do remove hope as well as fear.
So you could argue that some of the best,
the essence of being human, some of the things that we value the most
Right and make us most valuable in the universe in this sense some of those things come from incomplete knowledge
I mean surely hope does sure how could you have hope and excitement about what's gonna happen tomorrow if you know
But don't you think that might be a miserable like motivates improvement that all that hope just
Motivates you to do better and get better and you don't think that might be a feature of a biological
Organism you said when you when you when you're going out you said like a you know when you're in high school when you're young
Christmas for example, right when you Christmas Eve. Yeah, go on. We're gonna get tomorrow Yeah, it's one of the most wonderful feelings isn't it one of the most wonderful. Yeah in the presence of
None of that would exist right you have one of these super beings so I think why one of those cats just for us it's just for us that it appears
magical you when you're comparing that to black holes colliding like is it
really so important what you got for Christmas?
Well, but it's us.
It's our biological needs,
our needs to be shown that we're loved,
we got a good toy,
our excitement about something that we've wanted
that was inaccessible,
you know, something that you were hoping for for Christmas
and you got it, like a video game console.
Oh, yeah.
I think what I'm getting to is it purely biological?
This is a great conversation, by the way, I thought about this, but it's only us like,
oh, is it just a prophecy of intelligence?
Does it?
I mean, you're arguing that it's a good argument that many of these desires come from our biological
fragility. Yes. And also the fragility of our planet. Yeah. As you said. But it could
be that this these ideas of of meaning of what it means to exist, of what is the point
of existence. Maybe that's a general prophecy of any intelligence system.
Well, it seems like it's imperative for survival.
You have to have a reason to do it.
It would be baked into the code if you wanted
this thing to keep going.
Otherwise, why wouldn't it just stick with, you know,
as soon as you figure out running water and electricity
and how to ship food, why would
you keep going?
Is there such a thing as contentment, though, for anyone?
It's possible.
It's possible to achieve.
I mean, that's what Buddhists strive for.
That's what all that meditation is, the abandonment of all material possessions.
It might be horrendous, though, to get to that position.
I think it would be horrendous.
I don't want to abandon everything and no more sex and you can't have a glass of wine. That seems crazy. So that's what
I'm kind of interested that God, a God-like being might be so bored and so devoid of all
excitement because those things like hope and curiosity. Curiosity is one of the most foundational things, one
of the most incredible, we both share that idea.
For us, yes, for us.
So if you know so much, maybe what happens in a world where your curiosity is not there,
you've got nothing to be curious about, wouldn't that be horrendous?
But isn't this a property of what it means to be a finite lifespan, a
finite life form that exists on a volatile planet? That this hope and
survive, but if that is bypassed, why do we need to be anxious all the time? Why
do we need to have hope? Why wouldn't we have a complete bliss, a complete
connection to everything? You linked hope to
anxiety, is that right? I hope it works out. You're fighting the
anxiety by having an optimistic outlook. I have hope. I think I was using it in a
different way though. I was imagining hope as excitement for what's beyond the horizon. Sure. So not driven,
this actually gets to the heart of what I think a scientist is by the way, the
difference between not only a scientist but let's say what is a scientist or
somebody just research in anything really, somebody who creates things. They're
people who like to stand on the edge of the known. So they find it exhilarating but interesting, almost in the context we're talking, it's
almost one of the things that drives our existence, is to stand on the edge of the known and peer
into the unknown with excitement and curiosity because you can go over the horizon. And so that's the sense in which I'm using these terms.
I'm saying that's one of the fundamentally
most valuable things of being human.
That there is an edge of the known.
And so I would find it, I think, more terrifying
to imagine that there was no edge of the known,
that everything was known. Then I
would think existence is pointless. I wouldn't, I wouldn't, I personally would
not find that. I wouldn't think I'd achieved nirvana. I would think I'd, I'd
got no, there's no point. I was only imagining.
Because you're existing within the framework of being a human being and if we transcend the
framework of being a human being, all these things we will come to realize,
all these emotions and all these desires and need are just to motivate our survival.
If we've gotten past that and we don't have a need for hope and we don't have curiosity because we have infinite information,
we're not the same thing anymore.
So all the things that motivate you and I
that make us fascinated by this,
I was so excited to talk to you today.
I'm like, Brian Cox is gonna be here?
We're gonna have fun.
Like, this is gonna be great.
I'm gonna learn some stuff.
All that innate curiosity that we have
that's so rewarding as a human being
is a part of being a human being.
And we think of it as being the only way
to have meaning and happiness.
The only way.
But that's because of the framework of being a human being.
If we transcend the existence that we're all confined to,
this temporary life form, oh, check my heart rate,
like make sure I get electrolytes,
you know, we try to keep the body alive.
If we transcend that completely
There's no need for all those things that are rewarding will have a different kind of reward will have a reward of
infinite connection I
Think we're trying to imagine what it's like to be God. Yes
I like to be God, aren't we? Yes, that's exactly what we're doing. I have been thinking about this a lot and I found out that somebody had already beat
me to it, but the idea that the universe itself was God, that if you wanted something that
creates, this is not to diminish any of the stories of the Bible, because I think a lot
of those stories are, these are ways that people tried to find meaning and probably had some like baked in
truths about being a human being and life and the existence and, but that in compare
just the things that are miracles on earth, like a person coming back to life, it's nothing
in compared to a stellar nursery.
It's like the scope of the universe itself, the real stuff that we
can see that is absolutely the creator of everything. Whether or not God created the universe, maybe,
maybe God created us, maybe the Bible's true. But whatever was done here is like a small bodega
in comparison to some enormous, like the gigafactor that makes Tesla's like there's a so much larger scale that
Absolutely created everything not only to absolutely create everything we know the process we know how it happened
We know how stars are formed. We know how planets exist
We know how gravity is affecting the planets around them. We know so much about
all this. We know so much about the process of going from single-celled organisms to multi-celled
organisms and photosynthesis existing and that fungus exists in a completely different
way. We know so much about all the things that absolutely came out of the universe itself.
Why not assume the universe is God?
I mean, is it in some technical sense?
It has to be. It's everything. The universe is everything, including God, if God is a
real thing.
If you define God as the creator, then you're right. From some point that we don't understand,
by the way, the Big Bang, we don't even understand whether that was the origin of the universe,
by the way. We understand that something interesting happened.
What is Sir Roger Penrose's?
He has an infinite cyclical universe.
Yes.
And he's trying to answer questions about the very special state of the early universe
and why it was the way that it was.
So his model is an infinite contraction and expansion?
It doesn't really contract. It's kind of, it's called, what's it called, conformal cosmology, cyclical conformal cosmology
or something.
So it's essentially that, and I don't fully understand it, and I have asked him about
it with some colleagues actually.
If you can't understand it, we're fucked.
No, no, I don't think many of us understand what you've, Roger, I mean Roger Fenner is one of the greats, right?
So you listen to him and take him very seriously.
But I haven't met anyone who quite understands what he's talking about in that.
But it doesn't recontract.
It's not one of those models where the universe expands and then recontracts and bounces like that.
It's not one of those.
It's somehow, he argues, that when
you get to what we usually call the heat death of the universe, where even the
black holes have evaporated away, you have conditions that begin to look
perhaps like an origin of the universe again. And I can't really fully explain
it because I don't really understand what he's trying to say, right?
And I'm so... So it's not a contraction, it's an infinite expansion and then some
sort of a metamorphosis? Yeah, it kind of looks like conformal means there are no
sort of distances or time measurements or anything in the universe it kind of loses all
Sense of scale and then you could you could reimagine that as looking somewhat like the beginning
It's something like that that he has in mind, but I really couldn't explain to you I don't understand what what he's what he's proposing Wow
So it but it what it does tell you is that we don't know
Why or how the universe got into the state?
That we call the Big Bang
So we don't we don't know whether the universe existed before that we have theories that it did theories called inflation
Which are very popular theories you'll find it in all the textbooks which say that before the universe was hot and dense, which we used to call the Big Bang, space and time is
still there and the universe is expanding extremely fast. It's called
inflation. And then that period draws to a close and that expansion so slows down
and almost collapses and changes and the energy that was driving the expansion
gets dumped into space and changes
and ultimately makes the particles out of which
we are made.
So that's actually the standard model of cosmology now.
So we do have an idea that we redefine the Big Bang
as the hot Big Bang.
And it's not the origin of the universe in time.
It's the end of inflation. Oh, and then you get the question
What is inflation there? What did that have a beginning and the answer is that in Einstein's theory alone?
Then yes, and Roger Penrose actually and Stephen Hawking proved this a long time ago that just given Einstein's theory
You have this singularity just like kind of like the black hole singularity,
but at the beginning of time.
But we do know that when you put quantum mechanics in
and add that in, then it gets messy
and we don't really know what that means.
And so Stephen Hawking had a thing called
the no boundary proposal, there's all sorts.
Basically the point is we don't know.
So we don't know whether the universe
had a beginning in time, I would say, is the correct statement as we are at the moment
It's part of the reason why by the way getting back to the black holes. They're important and interesting
Because the study of black holes and this idea of information and how's it get out
That's leading us to suspect that space and time themselves are not fundamental, but they
emerge from something else.
So just in the way that we've been talking about consciousness emerging from this physical
structure in our heads.
So we don't know how it emerges.
It's a very strange thing, but it emerges from this collection of atoms in a particular
pattern.
Well, we think now from the study of black holes
that space and time emerge from something else, which
is kind of one way to describe it is just a quantum theory.
So in quantum computing terms, it would be just qubits.
So a network of qubits entangled together,
just like a quantum computer. Out of that, we suspect
that space and time might emerge. So surely we have to understand that process and we
don't really fully understand that, but we have glimpses of it in much more detail to
start talking about the origin of time. Because in order to talk about the origin of time,
you have to know what it is. And we don't actually know what it is.
Which is, you know, and that's kind of,
when you say that, it sounds bizarre, doesn't it?
Well, how can you not know what time is?
I think Einstein once said that it is the thing
that you measure on a watch.
But he said that as kind of almost a joke,
because you assume in Einstein's theory
there's a thing that the watch measures.
But what actually it is at the deepest level is a good question. So, but it's funny, there's a thing that the watch measures. But what actually it is at the deepest level
is a good question.
But it's interesting that the study of black holes
is forcing us towards these theories.
It's not that we had the theories face and time
emerging from something and decided
we could check it by thinking about black holes.
It's come the other way around, really.
So it's interesting. But that almost
makes the universe look in some ways like a giant quantum computer, which is not to
say that we live in a simulation, before you ask. But it just looks like there's a description
of the universe that looks like a quantum computer type description.
That doesn't have the concept of space or time in it.
Is it possible that that is what it is and that the universe was created?
And that as we're talking about super intelligent life forms, keep constructing better versions
of itself and better versions of computers to the point where it can construct the universe itself. I mean you
know if we're seeing the code, if we're seeing the evidence, we're seeing
something that mimics a quantum computer in the universe, you know we're like ah
couldn't be that. It is it's interesting that it, you're right, and that's a good way of phrasing it, mimics how it looks like a network of qubits. So it looks like some
kind of quantum computing description is available to us for the universe.
But I don't think you can infer much from that. I mean it just passes the
question further back. As I said,
we have never understood what it means for the universe to have a beginning. So we don't
really know that. And so this is the same. I think it's just the same question. It's
like, well, you ask, well, you know, if it really is a network of qubits, it could have
been there forever, that network of qubits. So actually in quantum theory, it's more natural for it to be just eternal.
And it's an interesting question.
I once gave a talk actually, a conference of bishops, they were Catholic bishops, and
they asked me to go and give a talk at their conference about cosmology.
And so I gave the talk about cosmology and they all listened and we had a question thing
afterwards.
And I said to them, what happens if we discover the universe has always existed because it might have we don't we know there's a thing called the Big Bang
But it might have been something that happened in a pre-existing universe. Maybe that's eternal
What does that mean for your sort of picture of a creator?
Does it I don't know I a – it's a genuine question.
Right.
How would you – and they really didn't – they thought it was a cool question and
didn't have an answer, right?
But it is – I think the idea that – I was – the question to you actually, are
we more comfortable with the universe that began or would we be more comfortable with
the universe that had always existed?
I mean, comfortable is a weird word because I always wonder if our whole desire to form
the universe in terms of a beginning and an end is based on our own biological limitations.
The fact that we have a birth and a death, we try to apply that to the universe itself
because we know that stars didn't exist and they do, they burn out, we know
planets lose their atmosphere, we know things change and all these things.
So I think we think, oh well, the sun's going to die out, the universe probably had a beginning
too, but why?
There's no reason to think it did.
It's much more likely that it's always existed
Then it didn't exist and then it became out of what yeah if the universe didn't exist, so there's nothing in the whole of
Observable everything there's nothing and then all of a sudden there's something that seems less likely
it seems more likely that this whole idea of a birth and a death is
less likely. It seems more likely that this whole idea of a birth and a death is just we have this look this way of looking at things because of our own
limitations. Like we think that everything has to have a beginning and an end.
And you're right. I mean you've had Sean Caroll on the show. Yes. Because he always points out
that you know this question why is there something rather than nothing. Right.
Presupposes that nothing is more likely than something.
Right.
So whereas it might be the other way around.
Right.
We don't even know that.
Right.
So how does something come out of nothing?
That's the big one.
The history, I think historically, you have, I think it's right to say that Einstein really
felt, I think, that initially that an eternal universe was more natural.
But it is also true to say that his theory, general relativity, really
doesn't quite rule that out, but it's strongly suggestive of there being a beginning and
or an end.
So the theory itself, historically speaking,
strongly suggests that. And so he came, changed his mind, and then we saw the universe was speaking, strongly suggests that.
And so he changed his mind.
And then we saw the universe was expanding.
We observed that.
And then we've now seen the oldest light in the universe, the cosmic microwave background
radiation, which is the afterglow of the Big Bang.
So we know that the universe was hot and dense 13.8 billion years ago.
We have so much evidence for that, not least that we have a photograph of it,80,000 years after the Big Bang. It's called the Cosmic Microwave Background.
Let's see that. Let me see that photo.
So we have images of that. That's from the satellite called Planck, a European satellite,
and also a satellite called COBE. So we have these images of the afterglow of the Big Bang.
We also have theories that tell us about the abundance of chemical elements in the universe
which match this perfectly. So there's multiple lines of evidence that tell us the universe was hot and dense.
But none of that tells us that that was the beginning. I think that would be widely accepted.
It's a beginning in Einstein's theory. If you just take general relativity,
there's a singularity there. At the beginning of time, we don't know what it is, but it's there. But it absolutely is true to say that we think that's not complete
as a picture. So there it is. So that is light that was emitted about 380,000 years after
the Big Bang. So it's a... And the key thing, there's so many things to say about these images. But one thing is those colors correspond to regions of very slightly different density
that we detected now in the gases of the young universe.
Are you talking about the red blue?
Yeah, the reds and blues, those are those as well. They're both both same.
That greeny one, well either that one or the one with the greeny blue,
that one, that's from the Planck satellite. So those colours correspond to regions of
different density. So in this young universe, 380,000 years after the Big Bang, that's only
hydrogen and helium gas, basically, and a bit of lithium, some of the lighter elements, but basically hydrogen and helium.
So you've got an almost smooth,
almost featureless universe then,
but these little density fluctuations are very important
because as the universe expanded and cooled,
they collapsed to form the galaxies.
So without those ripples, without that pattern,
we would not exist.
Nothing of interest not exist.
Nothing of interest would exist.
And so the question is where did that come from, that pattern?
It's fundamentally important.
And the theory of inflation that I mentioned earlier, that there's this time before the
universe got hot and dense, that theory predicted that pattern before it was observed. So this idea that you've got this very quickly stretching space.
By the way, so the stretch, if I can remember the number, is if you consider two points
in space during inflation, the distance between them was doubling every 10 to the minus 37
seconds, which is 0.00000000.
37 noughts one of a second.
So it's incredible rate of expansion that draws to a close.
And those theories, so there's inflation there.
So those theories predicted slight variations
in the rate at which inflation stops.
Does the inflation theory,
does this work with Sir
Roger Penrose's concept? I mean, is it possible that inflation is the far period of the expansion
of the universe? I mean, it is he doesn't like inflation as a theory. He doesn't? Oh
no. So but so but but but it's right that our universe is accelerating in its expansion at the moment, which is one of the great mysteries
that was discovered in the 1990s by a friend of mine actually, Brian Schmidt, got the Nobel
Prize for this discovery.
He told me once, I don't know if I told you the story before, but he told me that he'd
made this measurement and it wasn't really, he was looking at supernova explosions
and he'd seen that the suggestion in the data
was that the universe is accelerating in its expansion,
not slowing down, but speeding up in its rate of expansion.
And no one was expecting it,
so he thought it was just wrong,
but he couldn't find anything wrong with his data.
So he published it and thought,
well, that's the end of my career.
Oh boy.
You know, he was quite young.
I think he might have been in a postdoc
and he just published it.
He thought, that's a good scientist, right?
I don't think this is right,
but I can't see anything wrong with it.
I'll publish it.
Someone else will tell me where my mistake was.
And there was no mistake and he won the Nobel Prize.
Wow.
For that discovery.
That's the 1990s.
So this idea of the universe is accelerating
in expansion. The way that it does that is really important. Is it going to carry
on doing that? Is whatever's driving that expansion going to change in some way,
which could actually re-collapse the universe again? We give it a name by the
way, dark energy this thing, but we don't know what it is. I think it's very fair
to say. But it looks a bit like inflation, but it's way slower. So maybe they're linked,
maybe it's the same kind of thing. We don't really know. And so it's one of the great
mysteries. So but the universe, it looks like the universe is going to continue to expand
forever and to continue to accelerate.
Well, dark matter and dark energy they're
both very confusing. Yeah dark matters in some sense marginally less confusing in
the sense that at least we have an idea of what it might be. Whereas dark energy
there are people listening to it, there'll be there are people working on it so there
are theories about what it might be but But I think it's further, it feels less explicable,
given what we know, than dark matter.
But we haven't discovered what, we think dark matter might
be some kind of particle that has got certain properties
and doesn't interact very strongly.
It interacts like neutrinos, basically,
that you mentioned earlier.
So it really doesn't interact very strongly.
But we thought we might have seen those particles. We're looking for them. They would be passing
through this room now, and so we could build a detector in here and we do that, and we
look for these particles. We haven't seen them. We thought we might make them at the
Large Hadron Collider at CERN. I think many people thought that we'd see the signature
of these things, and we haven't done. So it could be that we're not right with that picture.
So that picture encompasses what percentage
of the known universe?
So yeah, so it's about 5% matter, about 70% dark energy,
and the rest, so 25% dark matter.
So we're just less than 5% this.
That's crazy.
And stuff we can see. So everything we
can see in the sky, all the gas and the dust and the galaxies and the stars and
the black holes, all those things, less than 5% according to the standard
model of cosmology. And so the other 95% is just like who knows? Something else.
Yeah, but those are models. I mean it's important to say that it's just like something else something else yeah and so but those are
models I mean it's important to say that it's interesting because until so we
have a hypothesis which is strongly supported by lots of bits of evidence
that dark matter is some kind of particle so it's that's the broadly
that's what you find in the textbooks. But it's true that until you find it, until you see it,
then you haven't shown it to be correct.
Are there alternative theories?
There are.
And they're not compelling?
No, they all have problems.
And most of them have problems with that pattern,
the CMV, the cosmic microwave background that we just saw.
Because that pattern, what you're looking at actually
in that pattern is acoustic, it's waves,
sound waves essentially in the early universe
that go through the plasma of the early universe.
And they go out and we know what speed
they go through that plasma.
So it's almost like you're looking at a pond
and you're throwing stones into the pond.
And they all land in the pond
at the same time and send ripples out, little circular ripples in the pond and they all
overlap and that's what that pattern is. So we're looking at sound waves going through
this plasma and those theories require the dark matter. The dark matter fits well if it's in there, in this plasma, in this kind of soup,
this subatomic particle soup that's the early universe. And the way the sound waves go through it fit that idea.
So that's one thing, but the idea also came from looking at galaxies and how they rotate,
and galaxies and how they bend light and deform space and time and how they interact together.
So there's loads of different bits of information, observations of the universe
from the cosmic microwave background all the way through to galaxies and the
formation of galaxies and the theories that we have there
that suggest there are these particles around that interact very weakly
with light. So they don't really interact with light at all, which is why we don't see them, which
is why they're dark.
That's just like a neutrino, right?
So like heavy neutrinos.
And actually there was a theory once that maybe they were heavy neutrinos, but that's
kind of disfavored now.
And so we have loads of kind of different bits that fit.
This is how you do science.
You start with a theory, and you make a load of observations,
and you can infer things, and you get a consistent picture.
But very importantly, until you find it,
until you really find that particle, then you don't know.
So that's a good question.
What we don't know, just what we don't know is so fascinating just that aspect of it that
95% of the universe is like we're not really sure what it is. Hmm. Yeah
That's and we've inferred it so you might say how do you know it's there?
You know, which is a good question, right? I mean if we've not detected this stuff
How do you know and it's from Einstein's theory really so it's from
gravity it's from Einstein's theory, really. So it's from gravity.
It's from looking at the way that galaxies rotate
and the way that these sound waves move
through the early universe
and the way that the universe expands.
Because the way the universe expands
is related to the stuff that's in the universe.
So we can weigh the universe
and find out what kind of different things are in there
by looking at the way it's expanded and how that expansion history has changed over time.
So it's all what you do with science, which is why it's true that you can criticise any one bit of it.
And people will. So online you'll see in the comments under this will be people saying, but what about this? What about this? What about this? And it's true that you can you can pluck away and pick away any piece of it
But the way it tends to work is when you have this kind of consensus view of something
it's because you have multiple observations that all fit a particular hypothesis and
By changing one of them by changing the explanation of one of them, you
tend to mess the whole other thing up. You mess the wider description of multiple phenomena
up. You mess it all up. So it's quite hard to find other theories at the moment that
will fit all of those different observations. I mean another example would be the age of things.
It's interesting that you can look at, we can measure the age of the earth, right, and
you measure it from geological processes, radioactive dating and so on, and you can
kind of measure the age of the earth.
You can measure the age of the sun in a different way.
You can measure it by looking at, by looking at, called helioseismology, so you can work
out, you can measure how much helium is in the core of the sun.
And the sun shines by making helium from hydrogen.
So by measuring the amount of helium in the core,
by looking at basically sound waves,
it's like an earthquake that sunquakes.
You can measure how much helium is in there,
so you can get an estimate of the age of the sun.
And then you can get an estimate of the age of the universe
by measuring how it's expanding and using Einstein's theory. The fact that they all
fit with the picture of a universe that's 13.8 billion years old, a sun that's four
and a half billion years old, a planet that's four and a half billion years old, the fact
that it all fits is quite an intricate model. And so you could say, well, I argue with the measurements of
the age of the Earth. Maybe I don't like the radioactive dating or something, and people
will say that. But the thing is, it's a consistent picture with multiple different observations.
And same with dark matter. So the standard model of cosmology is you have,
I said about 5% matter, 25% dark matter, 70% dark energy.
It might be wrong, but it fits loads
of different independent observations.
So it's a consistent picture.
So we just don't know what it is,
but we're not very sure that it's a thing.
The other.
Pretty sure. But it could a thing. The other-
Pretty sure, but it could not be.
What was the other-
Was it where any of the other theories, competing theories, were any of them compelling at all?
There are theories that people try to build where you modify our theory of gravity.
So many of these observations, not all of them, so the cosmic microwave background are
different observations, but many of them depend on the cosmic microwave background are different observations.
But many of them depend on gravity and how gravity works, Einstein's theory of general
relativity.
So you could try to modify that theory to say, well, our observation's wrong.
Maybe because the way we measure how the expansion of the universe is, is to look at light from
supernova is one way and see how it's
stretched over time because the light let's say you have a supernova and it
happened a billion years ago then the light has been traveling for a billion
years across the universe and so the universe has been expanding for a billion
years so the light will be stretched and so you can measure how much stretch
there is. You just measure the color of the light from the supernova.
So you can argue that maybe if you go for light
that's been traveling 12 billion years across the universe,
then maybe there was something different.
Maybe the light was emitted a bit different.
Maybe the speed of light changes over time or something.
So you can invent theories that would allow you
to change the data or the interpretation of the data.
But what you always find, I think it would be fair to say,
is that you can change a theory and explain one bit,
but all the wheels come off the other bits.
Got it.
So that's why it's quite difficult.
So the dark matter, dark energy theory is cohesive to all the other theories.
Yeah, so it fits. Yeah. With you know, but then there are some mysteries.
Well, not least what is this stuff? Right. Right. And so until you know what it is, you don't have a complete theory.
Well, that is one of the most fascinating things that 95% of the universe is like who knows what it is. Yeah.
Yeah. Yeah. And so that's what I
love about, one of the things I love about science is it often gets presented
you know because I talk about science a lot in public and it can often seem
arrogant I think it can seem you know like these people are saying well this
is the way the world is and you might say well you know what how are you to
say this. The thing I like about it personally,
and the reason for its success,
is that really you have to be delighted when you're wrong.
It's the key to science.
It's been said many times, Richard Feynman,
the great physicist, said it.
You know, this is, if your goal is to understand nature,
so that's what you want to do. So you don't, you've not got an ego or anything, you don't want to prove right, you just want
to understand.
Then being wrong, so if this idea of dark energy and dark matter turns out to be wrong,
all scientists or good scientists will be absolutely delighted, because it'd be tremendously exciting
that we'd ruled out this picture.
It'd be great to rule out this picture.
So there isn't such a thing as dark matter and dark energy.
It's all nonsense.
We were barking at the wrong tree,
looking in the wrong direction.
It's something else which should be more wonderful,
undoubtedly, than that theory that we have.
So I think it's a humble pursuit, ultimately, science.
And that's the reason for its success, because you're just trying to understand how things
work.
You're not trying to, you shouldn't be, anyway, good scientists.
You're not trying to be the person that got it right.
You're not trying to do it.
There's obviously human failing everyone's got fragility and everyone's human, you know
And here you go, but ultimately you're just trying to understand how things work
Yes, and that's a beautiful thing and it's so important for everyone else that doesn't have the time
We need you doing that. I need it really does in some way give us comfort to have a better more
comprehensive view of
what we're experiencing.
And as technology expands, like I wanted to talk about the James Webb, some of the discoveries,
but sometimes it raises more questions.
And one of them was these galaxies that were formed that appeared to have been formed too quickly?
Is that safe to say?
Yeah, so we had, one of the reasons we built that telescope
was to, what it does, because it can see very distant things
and because light travels at a finite speed,
the further out into the universe you look,
the further back in time you're looking.
So because that can see things from which the light has been travelling for over 13
billion years, then you're seeing things as they were in the first billion years or
few hundred thousand years in the history of the universe, essentially.
So well, a few hundred million years, sorry, I should have said.
So you're seeing the first galaxies form with that telescope, which is one of the reasons it was built. And the
reason we wanted to see is because we don't fully understand that process. As
I mentioned before, we don't really fully understand why they have black holes in
them and it's something to do with their formation, but we don't understand it
very well. So it's not surprising to me that when you build
that instrument and collect light from the early universe,
you see an early universe that's behaving in a different way
to the way that you thought it behaved.
And so indeed, yeah, we're seeing galaxies that
formed earlier than you would have predicted.
But that means that your model
of the way the universe evolved is not quite right,
and that's not a surprise,
because we wouldn't have built the thing
if we'd known everything.
Right, of course.
So I don't think there's any,
I think it's fair to say there's nothing there
that absolutely, completely destroys our picture
of how the universe evolved
from the cosmic
microwave background that you saw in those images earlier. Does it add more
complexity? Does it add more nuance? Yeah I would say so and I'm not an expert in
that field but my understanding is that it's interesting because we're having
to refine and develop new models of the way that the galaxy is formed and indeed
you said it looks like the stars and the galaxies
are present in the universe earlier than we might have expected.
So it might be, it might be that you're seeing a hint
of something really profound that we didn't understand.
Or it might be that just the models need a bit of a tweak.
Mm.
So I think...
That galaxies form quicker than we expected
in the early stages of the universe
What are those red dots the red dots that were observed?
Do you know I'm talking about in the images the James Webb images of the early universe. Yeah, they're distant disappeared
Do you know I'm talking about?
I saved it because I knew that we're going to have to talk about this.
It was, Jamie, I know we've talked about it before.
Yeah, there it goes.
Found hundreds of little red dots in the ancient universe.
We still don't know what they are.
Small galaxies either crammed with stars or they host gigantic black holes.
The data astronomers have collected continues to puzzle them.
So what is that all about?
Do you know?
I don't know. It says there that we don't know. I'm going to go with that. I mean, I
think just speed reading that. It says a class of galaxies. So I suppose we're looking at
a kind of galaxy. It seems we're looking at a kind of galaxy that we don't see today
in the universe. Red and compact, visible only during about one billion years of cosmic history.
So that would be, as I said, because we don't really understand the formation of the galaxies
and these supermassive black holes, that's interesting because what you're seeing in the data is
a kind of almost proto-galaxy, I suppose, these little tiny galaxies, that's what it
seems to suggest. That's the first time I've seen that.
I think what we're seeing is that we don't understand how structures
formed in the universe. We have a reasonable idea but we don't understand
the detail and the more things like that you find the more. We have a reasonable idea but we don't understand the detail. And the more things like that you find, the more information you have to build
models of how stuff formed.
Do we have another like next generation James Webb type telescope
that's even more efficient or more capable?
There are, I mean there are several
sort of proposed observatories and
and also by the way, gravitational wave detectors,
which, so we've got LIGO, which is on the ground.
There are proposals to put one in space,
which is called LISA.
One of the proposals is called LISA,
which is lasers between satellites,
so you can have much bigger things.
And the reason that's interesting
is because there'll be gravitational waves from the Big
Bang.
So you know, as you mentioned neutrinos, you've got neutrino observatories, which can observe
neutrinos from the early universe.
And you can see things.
It's just like light in a way, but it gives you a different view.
You mentioned earlier, it's a different way of looking at the universe.
So the neutrinos
will have information. Gravitational waves will have detailed information about the Big
Bang itself, but we can't detect them at the moment because we can't detect those really
tiny little ripples in space and time.
That's what's so fascinating because if they do launch this and they find new information
that's even more puzzling and then you keep going further and further and further. And we want to know it's like you said earlier we're asking very deep questions about why
the universe is the way it is.
In maybe why there's a universe at all in the sense that did it have a beginning?
And if so what does that mean?
Was it mean for something like this to begin?
Yeah I really I find it fascinating.
And the most exciting thing of all is that we don't know.
Yeah.
And that's so important, by the way.
And just to reiterate, I think it's often missed
when you're talking about the beauty of science
and the value of science.
It's almost not the knowledge.
It's almost like the opposite of the knowledge.
It's just this idea that I think,
it goes back to what we talked about earlier. I haven't really thought about this connection
before, but it's that I was pushing back on you saying, I don't know. I'd like, what would it mean
to know everything? I don't think I'd like that. And you were saying maybe you would, maybe that's
what it means. Nirvana, you know, maybe achieving enlightenment. That's what it means. But I find that the most, the most human I feel, I think, is when
I'm on the edge of the known. Sure. So it's that the fact that there are mysteries in
the universe, profound mysteries, to me is one of the things that makes life worth
living.
Most certainly as a human being that's true. My point is that I think eventually we're
not going to be human beings.
I'm sure you're right. I mean where did we get past this little blip?
Well we're also in this weird depopulation stage where you know people move into urban
areas. It's very strange.
It's very weird because it doesn't seem like that because people are worried about overpopulation.
But then you have a lot of the chemicals and the plastics and all the different things
in people's bodies are interrupting our reproductive cycles. And you could see that eventually
becoming an even bigger issue in the future if we continue to fuck up the world.
We've got loads of problems. Loads of problems.
We should all be fixed by AI.
Well, there is an exciting future, isn't there?
I feel that we're going to go...
I feel that we are at kind of a fork in the road here, because as you said,
there are tremendous challenges that we face, environmental challenges and so on,
competition for resources, geopolitically the world looks
rather, I think it looks as unstable as it was in the
1930s in some respects, so it's quite terrifying.
But we have nuclear weapons now, so it's terrifying.
But on the other side, as you said, we have not only AI
and quantum computers, which are potentially profoundly
powerful things, But also you
know that the rockets that we have now, I mean reusable rockets, to me
we haven't talked about that, but I think it's an absolute game changer.
It is now the case that we have cheap and reliable access to space.
We should play that video of them catching it because that is one of the most
incredible achievements in human history and you barely saw it because Elon Musk unfortunately
is so polarizing to some people, particularly now because of the political cycle that we're
in, that you don't appreciate what SpaceX just did. It did one of the most extraordinary
things ever. They caught a rocket that's bigger than a fucking skyscraper. Yeah, you got the video.
It's amazing.
This is absolutely a feat of engineering
that rivals almost anything human beings have ever done.
Yeah, this is really important.
This is so incredible.
I think we'll remember that in future generations.
I thought it was CGI. I really did. I
thought this was fake when I first saw it. I thought this was something that
someone had made and then I realized this was the actual video footage of it.
I'm like oh my god. That's the road to the stars that right there that that
moment. Tell me that doesn't remind you of the movie Contact. It does a bit, doesn't it? That does a lot. That didn't end well, though.
No.
Well, you know, neither did Apollo 1.
Yeah.
So that, and also, of course, Blue Origin,
are not far, maybe not far behind.
Right.
So it's a lot of that.
Two private companies with billionaires
at the helm that are out of their mind,
pushing us space crates.
Pushing us building markets.
Let's go.
And I get criticized for this quite a lot.
And we'll, no doubt, after this interview,
because I do think our future at some point is beyond Earth.
It has to be, right?
Obviously, logically, it is.
But the question is when.
And there are two things to say.
That one thing to emphasize, which I'm sure you'd agree with is that I don't think anybody is
suggesting that what we what we're able to do now is trash this planet and then
move to another one. Right, of course. No one's saying that. That's way in the future. But there's
things out of our control like the asteroid that killed the dinosaurs. Yeah
well that's in our control I mean mean, we can move those now.
Sort of.
Sort of.
Not yet.
But if it's coming right now, not really.
That's true.
So we need that technology.
So we're on the verge of having that technology.
That would be nice.
Because Carl Sagan, why don't you
say that dinosaurs had a space program,
they'd still be around.
So it's their fault, in a sense.
Which I kind of, you know, they didn't build rockets.
Well, it's almost like nature realized that, with these giant lizards turned around people are never gonna figure out how to make spaceships
Yeah, let's just reset. Yeah send in the hard reset button
Yeah, but I mean so but I think that idea that basic idea
I interviewed Jeff Bezos once and he was fascinating and he said to me that first of all we need
infrastructure in space because if you think about building Amazon, he said what I needed
was two pieces of infrastructure, the postal service and the internet.
And so they were provided and I could build my company.
So I want to do that for the next generation of entrepreneurs in space.
I don't know what they're going to do in space, but I would like the infrastructure to be there for them to do it. And that's
really simple. And then he also goes on to say, of course, as we said before, the resources
are up there. They're infinite, infinite resources, infinite energy, effectively, up there. And
so the idea, he said to me, I want to zone the Earth residential. And people say, that's ridiculous.
What are you talking?
But how ridiculous is it when you see that?
When you see the fact that for the first time we have launch
vehicles that really should be able to launch almost anything
we want.
So the idea that we can build infrastructure in space,
and then, of course, build bases on the moon,
and then ultimately on Mars
and then beyond. That's a lot closer now. Let's look at that and say what is that
a hundred and how many years from Wilbur and Orville Wright? Yeah it's
essentially... A hundred and what? 120 ish is it? Yeah yeah that's crazy. Yeah so you
go from this goofy like flexible sort of airplane looking thing that no one's gonna fly across the Atlantic in to
catching rockets with a giant like
Hand the robot clamp. Yeah, that's insane that happens over such a short period of time
That's a hundred to go from that to
Blue origin is insanity. Yeah in such a short period of time.
So I think we're on the 1906. Yes. So we're on the verge of a revolution in many fields.
My worry is that we're also seeing an increase in political instability. Yes. And so I think
we're at, I think most people would agree, a very dangerous moment. Yes.
And the question is how to get to that future.
And that future that you talked about,
this wonderful future that we have,
might be 10 or 20 years away,
but it might be an eternity away
if we get the next few years wrong.
Right.
So I'm concerned that this,
we don't know how to build a bridge to that future, that we
should see in our lifetime, we should see this future beginning to unfold before
us. How do we get there? Well we have to keep it out of the hands of the
military industrial complex. We have to stop what's going on in the world, these
insane conflicts, and if we don, and they escalate, Iran gets
a nuclear weapon, Israel uses it in Iran, Russia uses it in Ukraine. We have World War
Three, and I'm sure you're aware of what Einstein said about World War Four, that World War
Three, I don't know what weapons they'll use, but in World War Four, it'll be rocks and
sticks.
Yeah.
And we're not that far away from that that if you could imagine living in Hiroshima
The day before the bomb not having any idea anything like that could ever even possibly happen
there's a regular person walking around and all sudden everything is obliterated and
You realize like we're in a new era of destruction where you can and what's interesting is to me is I've got interested in a in
Oppenheimer's writing post-war
And I've been interested in it the BBC asked me to look at and there's a thing called the BBC wreath lectures
That are very famous in the UK and every year someone gives these lectures
after Lord wreath who founded the BBC and
Oppenheimer did them in 1953, I think it is,
53 or 54.
And they were considered a failure
because no one understood what he was talking about.
But in there, he was concerned with the fact, of course,
that he felt he delivered the means by which we
would destroy ourselves.
And he felt our technology, our scientific know-how,
exceeded our wisdom and our political skill,
which is arguably true. So he thought in the 50s he couldn't see how we'd avoid destroying
ourselves, but he thought about it a lot, feeling partly personally responsible for it.
And he describes this, the deal, how if there's any lessons that science teaches us, the exploration of nature
teaches us that we could move into other fields, that we could transfer into politics, for
example. And one of them is this picture that complex systems, complex systems are complicated.
So, so he's talking about looking at quantum mechanics, for example, and it
gets complicated and you say, what is an electron? It's this thing, it's a particle-like, point-like
thing or a big extended wavy thing that, what is it? It behaves in all these strange ways.
We don't really have the language or the mental capacity to picture it. And so he said, any
attempt to say this thing is this or it is that,
it is like this thing, it is doomed, right?
What you have to understand is that you have to develop
this rather complex and nuanced picture
of the way that nature works.
And quantum mechanics is a good example.
But he said, so it is with human societies.
So in a society, what is it?
It is at one level a load of individuals, like little particles, and they have their
own needs and desires, and they have their views and strongly held views.
And so should they, by the way.
There's a great quote from, I think, early 60s from Oppenheimer where he says that to
be a person of substance, you need an anchor.
So you need to believe things, and you need to argue for things you need to take positions you have to have a morality
you have to have a politics right basically you otherwise you're not a
person of substance he says at the same time of course you have to recognize
there's a society so there are lots of people with anchors and there and you
might strongly disagree with that anchor and they're and you might strongly disagree with
that anchor and they might be wrong right there and can might be nonsense
but but the challenge of politics is to avoid war it's a I read somewhere
recently someone said I can't remember it was but said that democracy is a
technology to avoid civil war that That's what it is.
So somehow you've got to understand that whilst you have your, and should have your firmly
held position, you have to find a way, and it feels almost contradictory, you have to
find a way of understanding that the society as a whole is a complex mixture of all these different
little particles with their own anchors and their own positions. And what is the goal?
So it is the goal. It often feels to me that politics at the moment, the goal is to win
an argument. It often feels like to convince enough people that our, your view is the right
view. And then obviously it's part of democracy,
right, it's the way it works, right, you argue for your position and then you get four or
five years to do your thing and then someone else can take over. But also, I think the
thing we're missing at the moment is that more, perhaps more fundamental function of
democracy, which is to avoid war. Because if you can avoid war, especially with the power that we have now, you have the time
to sort the rest out.
But if we can't avoid war, we don't.
And I think that, and Oppenheimer wrote that he knew that in the 50s.
And it feels to me more that we're back full circle now. It feels to me we've almost forgotten, we seem to have forgotten that the primary function
of democracy is not to ensure that your side wins.
The primary function of democracy is to ensure there's a chance for the other side to win at some point in the future.
Yes.
And yeah, that's it really. That's what I would like to say.
It's completely accurate. And the problem with our version of democracy is that it's
been captured by money. So there's interests beyond the will and the needs of the people, and those interests
often are contrary to the will and the needs of the people, and as long as they can keep
from it falling into complete total catastrophe and continue to profit off of the global chaos,
they do.
It's just there's too much money involved in politics and lobbyists and special interest
groups and people influencing the media. They've distorted reality to the point where the general
citizen doesn't really have a nuanced understanding of why these conflicts are taking place in the
first place and why all the money is going over to these places and what is being done to mitigate any of these issues
and everyone feels helpless and that helps them continue to do what they're doing and continue to reap profits.
And it's not democracy in the sense of how it was probably originally established, originally thought of.
They never thought they'd get to have corporations. Corporations weren't even a thought.
It wasn't even an idea.
So I never thought you'd have these,
not just corporations, but corporations
that are essentially in charge of a enormous percentage
of the information that gets distributed online.
And you see how organizations, government organizations, can conspire to limit the amount
of information people have access to.
And they can do it through very sneaky ways.
Like I don't know if you're aware of what they've done in Canada, but in Canada now,
you are no longer able to share links to news stories on social media.
And the way they snuck that in is by saying that these media corporations, whether it's Metta or
Twitter X, whatever, they have a responsibility to pay the people that are making these stories.
And so by this little sneaky little loophole, they've essentially put a stop on the free
flow of information in Canada on social media.
It's very, very disturbing and very dystopian.
I have some friends that just went up there and they're like, it's so confusing because
people didn't know it was going to happen before it happened and then it happened and
now everyone's kind of a little out of the loop up there because you're not able, you
can't even share a link, which doesn't make any sense because say if there's a New York Times article and
I want to share with you on Twitter all I'm doing is driving more traffic to the New York
Times website it's not hurting them in fact it's promotion it doesn't make any sense that
it would somehow or another because you're not these companies aren't paying. So the idea is that X, because the profits that they get through advertising is all based
on engagement, that there's engagement that sends people to this, and so they're profiting
from it, and that profit should be shared with the media company, whether it's Los Angeles
Times or whatever.
That's crazy, because it's a two-way street.
It's promotion.
So many more people are going to read a New York Times article
if it becomes viral on Twitter.
This is just, it's crazy.
What does seem to be generally true
is that we haven't, as a society.
It says it was just on Facebook.
Is that true?
We, I don't know if it's just on Facebook.
It says it was Metta's band.
Well, I'm just curious. See if it's the case.
Dunker was saying it's social media in general because he was just there.
I mean, what I think is generally true is that we
haven't yet adapted to the internet.
Yes. Just the internet. Yes. Because it's only, as you said, in the
great sweep of human history. Right, and it's only, as you said, in the great sweep of human history.
Right, and it's only been used by people for 10 years.
Yeah, yeah, and it's a couple of decades.
It's been influential.
So I think it feeds.
It's another of those problems we face now,
what we talked about, this bridge
to this tremendously bright future that we have.
One of the pillars of that bridge
that we need to strengthen is how to deal with this thing that we have. One of the pillars of that bridge that we need to strengthen
is how to deal with this thing that we've only had for a couple of decades.
It's clear. I think we would, you know, people again will be listening to
this and they'll have different views on the way that things happen on the
internet and regulation and so on. But I think what everyone would agree on is we
haven't got it right yet. We don't know how we the way that it's influencing our changing our democracies. Yeah. It's just using non you know that it
might be changing them for the better it might be changing them for the worse but the way
it is changing them I don't think is fully understood. Well not just that it's being
manipulated by governments like governments have troll farms where they just attack certain
sensitive political issues and they they make polarizing statements
and crazy claims and you go to that website or you go to that Twitter page and you realize,
oh, this isn't a real person.
This is just like some bot somewhere.
Yeah.
Well, I see that.
I've got a lot of fun with this.
I'm sure you have a lot of bots.
A former FBI analyst made an estimate of 80%.
He thinks 80% of all the accounts, and this was around the
time Elon was buying it, who knows what it's at now, 80% were fake. And this was one of
the sticking points of the argument that Elon said it was when he was buying Twitter, they
were telling him that it was only 5%. 5% were fake. He said, well, show me your data. And
the data they showed him was only a random 100 accounts and he's like this is not sufficient.
I want to see like all of your data and it became this big issue and that's what he tried
to get out of the deal and then they took him to court and then he wanted to buying
it.
But that was a big part of it.
Like how much of this is even real?
Like I see arguments online where people take these crazy inflammatory positions like just
insulting and attacking people that believe one thing or another thing
and I'm like how much of this is like instigated by China or Russia or Iran or some other foreign
country and they're doing it through these troll farms which we absolutely know exist
and I'm sure the United States has them as well.
And I don't know what the answer is. I mean one one answer, I mean the way I do it, because obviously I'm on Twitter X, and so
the way that I do it is you can tell, I think, by someone's timeline usually, because my
basic rule of thumb is that if you look at someone's timeline and it's all political,
I just ignore them.
That's my base.
Because a normal person's timeline, if I look at your timeline, for example, you look at mine, some of it's just ignore them. That's my baby because because a normal person's timeline
I look at your time right you look at mine some of it's just silly stuff right some of its retweet in
Sports stuff or sign stuff or whatever it is. I like airplanes
So a lot of my stuff is retweet instead of airplanes, right or whatever it is
So I think you can I think you can see a real person by seeing a bread
I think you can see a real person by seeing a breadth in the things that they retweet or whatever. And so I tend to ignore and mute at the minimum the people who are just single issue.
And usually what you find, by the way, is that they're not a single issue.
I can just about understand it if someone's single issue focused on a single thing,
but they're just a generic kind of political position.
So you'll see an account and all it does is promote divisive issues.
You can see them a mile off, I think.
So then it comes back to how do you deal with it?
My sense will be your sense.
It's hard to legislate around conversation, isn't it?
So what do you do?
I suppose you could argue it's education, ultimately.
Ultimately, everything comes back to education.
A democracy requires an educated population.
Right.
And the tools, you have the mental tools
to deal with this sort this new world of information.
I think that's something that we should probably be teaching to children is how to navigate
social media and how to navigate influence and how to navigate other people's opinions
of you and how to navigate online bullying, how to avoid...
There's so much anxiety that's attached to social media now too and so many people engage
in arguments with it like all day long. I think it's a primary source of mental
illness for a lot of people or at least an accelerant of mental illness and we
don't have an education as to how to manage that and what that what that
means to you and the addiction that people have to social media and
addiction people have to their smartphones in general is probably underappreciated.
Yeah.
Probably.
It's probably a much more significant impact on overall health than we think because there's
so much.
First of all, we're not supposed to have access to 8 billion people's worth of bad news.
No.
That's not good.
That's not a perspective enhancer.
And we were essentially
Inundated with the things that will scare the shit out of us the most which is eight billion people's problems
Whatever is happening in the world that's terrible
You're gonna hear about it first and it's gonna be the things that trend the most and it gives you this like
A very bizarre bias towards like what's actually happening in the world. Yeah
Yeah, isn't it a big problem? It's a big problem because it's new and we weren't prepared for it when it hit It's like a flood happening. You're like, okay, we gotta figure out how to get all the water out of here
like this is nuts this place is flooded and
we're essentially in the middle of the flood this social media online influence flood and
We haven't really shored up our basement yet
We don't we don't really know how to protect ourselves from it. But we can be optimistic. Yes.
Because we're both optimists I think. Yes, yes I'm very optimistic. Because of those
the things we've talked about today. Well also I think because I'm and I think you
are also successful at navigating that world without it killing you. Like I can
navigate the world of social media and I I can, like you said, you look at someone's
timeline and see that, oh, this is crazy.
And you have your own objective understanding of the world to a point where you can see
where someone's being ridiculous.
But some people just aren't that good at that.
They're not educated in that.
Maybe they haven't been around enough people that are critical thinkers and they don't know how to approach things from, they just look at
things like what am I supposed to believe, am I a good person if I believe
this, am I a good person if I argue against that, I'll do this, I'll do that
and these are not like well thought out actions. I do understand though that you
and I, you know, we're in a good position, Mike, personally.
This confidence comes with some degree of success
and you can put things in perspective.
And as you said, I often think actually,
I see people who struggle,
when they become well known for the first time,
for example.
I mean, I remember when I became, quite late in life,
became well known as a public figure.
It was, I did a series on the BBC in 2009 or 2010
called Wonders of the Soul System,
and suddenly I was well known.
And I find it very difficult to navigate.
And fortunately, I had the support structures
and people around me, and I could navigate it
and you come to terms with it and you learn how to do it,
but it's a process, isn't it?
So I think it's the same, one of the problems,
I think, with social media is you can become
very well known very quickly.
Yes.
Often for something that you kind of said
in a clumsy way, sometimes.
You know, it can be that.
And I think it's probably almost impossible to navigate that as just a person who just
suddenly is exposed to that glare of publicity and becomes a public figure, or sometimes
a hate figure overnight.
Well, it seems particularly difficult for people that didn't ever anticipate it, like
the Jordan Petersons of the world, like people that became quite prominent, like in their late 40s.
He's an academic, I mean, you know, and yeah, I mean, that's what I was doing.
I was an academic and then had a success on television.
Yeah. And it wasn't in a controversial area.
It's about planets and the solar system, astronomy.
Right. So but even then, I found it difficult initially to navigate through that world.
Yes. And you get used to it eventually. It's a very bizarre drug. That's what fame is. It's a very
bizarre alternative state of consciousness where everybody knows who you are and you don't know
them. And no one's really ready for that. And no one knows what it is until they experience it.
Everybody thinks they want it until they get it. once you get it you're like, oh my god
This comes with so much scrutiny. This comes with so much hate
You're just dealing with so many mentally ill people that are tweeting at you that the world's flat
Just angry. There's a lot of like really messy people out there. I do. Yeah, they're still I mean the number of people
I do. Yeah, they're still I mean the number of people who
When I saw I did that that the rocket capture the stars Yes, can't be as you said the most incredible thing. I just retweeted that and said brilliant engineering the number of tweets
I got back saying that space is fat. I don't know what it means space is fake. I don't even know what that means
But I got quite a lot of it, you know, it's fake
I went down a hashtag space is fake rabbit hole one night online and it has
something to do with biblical stuff because they think that there's a
firmament that's over the earth and they think that the lights are dangled in the
sky. Oh it's that. The earth is a dome. Yeah, the earth is a disk
and that you can't get through the firmament and that there's like an ice wall and that's
why you can't travel around. I love this thing. You go, okay, so let's assume that's true.
Let's assume it's right. Imagine all the astronomers, all the astrophysicists, all NASA, China,
every space agency, they're all in cahoots.
But why?
No one spilled the beans.
And then the thing I've never understood, and I've asked this in my early days on Twitter,
I made the mistake of asking, you know, sometimes, but now I don't reply at all to the obviously
it's you learn that.
Yeah.
Why do you what possible advantage could there be?
Right. I mean, and it's...
What's the answer?
I think they think that it's just a scam.
So SpaceX are just like a scam or something.
So they're just taking all this money for launching satellites.
So again, it's a very complicated scam because they're getting it off, you know, communications satellites.
They should try Starlink.
Starlink. They should try it so they know space is real
They're probably just deflecting off the off the dome awesome
Yeah, I don't know I guess but the the crazy thing is the idea that everybody's in cahoots that all these competing countries
decided to all lie together and yet I
all lie together and yet there's no record of it, there's no record of communications, there's no people that rebel against this idea and go this is madness, everything's
round.
The fundamental thing as well, the fundamental misconception these people have is they assume
that there's a competence there in government.
Anyone who's interacted with government,
I speak of my own country, I've interacted
with the government, the idea that they're competent enough
to do this, tremendously intricate scam,
they can't even, in my country,
they can't even make the trains run, right?
It's very basic.
So I think that it's this assumption
that there's some kind of underlying competence
to the world.
Yes, not just competence, but unbelievably calculating manipulation.
Yeah, I just don't think that the world is run by people who are smart enough to do that.
I mean, there's certainly conspiracies that are real, but that's just preposterous.
But it's also, it's just like this, again, it's attached to a weird religious thing. They do believe in the literal interpretation
of some of the stories in the Bible, and that's somehow or another that's been attached to
the firmament. But that's one of the problems with sort of, when you can, especially if
you're an articulate person, and even if you form like some create,
you make some fake documentary, and you attach a bunch of fake facts to it, and if it's compelling
and no one like you stops and goes, hold on, that's not how it works.
This is how we know this.
This is why the planet's around.
This is how we know this is what Bode's law is.
This is what the end you start like laying out what thousands of years of research and discovery has led us to. This is not like
just based on a whim. There's like a lot of information and the idea that all of that
information is a vast conspiracy to hide the fact that God is real and that the firmament
covers the earth and earth exists in the center of the universe and was created by God and space is fake.
Okay well I've learned something I didn't know because I didn't know the space is
fake thing was linked to that so that's that's um it's a very religious thing
yeah at the root of all the flat earth stuff is the firmament the root of all
the flat earth stuff is it'sament. The root of all the flat earth stuff is based on some
very bizarre interpretation of biblical... I don't remember the exact depiction of the
firmament and how God describes it in the Bible, but they believe that that's what we're
looking at, that there's like a glass, like a cookie dome dome like a plate of cookies with a glass dome
on it.
But that's what we said earlier if that was the way that nature is we would tell you I'd
love it.
Well I'd well not only that but everyone would be talking about how crazy Earth is in comparison
to all the other planets.
Turns out Earth is actually flat like that would not be something anybody would hide. I'd like to find that out. Because you become tremendously, you know, I mean what
a great discovery. But it isn't. But people have like a natural inclination to uncover
vast conspiracies. And I think that's one of the weirder ones that people gravitate to.
But again, I really think it has something to do with a blind belief in religious writings.
And not just that, but erroneous interpretations of religious writings.
You know, when you're dealing with something that was originally written in ancient Hebrew
and then translated to Latin and then to Greek and a lot of that gets lost in the translation a lot of it gets
Like you had a thousand years of oral tradition
Like I've always wondered at the beginning of the Bible in the beginning there was light
I wonder if that is like someone trying to figure out the Big Bang. I
Mean, it doesn't make sense that they would have a concept of it back then but it also doesn't
It doesn't make sense that they would have a concept of it back then but it also doesn't
But maybe that's something like we inherently know is that there was an event
Maybe the the echoes of that event are almost something that we just perceive because we just think of it as being a thing
What is it starts with in the beginning God created the heaven and the earth and there's that form void
And darkness was on the face of the deep. I love that. It's great line. What's amazing face of the deep
It's amazing as a piece of literature. Yeah, and it's the deep
I think I read somewhere that I was talking to a friend of mine is that it's in it seems company Egyptian creation myth
I think I might be wrong there
But it's about that that it was very much to do with the Nile and the waters.
And you find that in many religions that there's water and things emerge out of the waters.
And you see that in Genesis, that echo of it.
Darkness was on the face of the deep.
And then there's light after that.
So I don't know.
I'm not a biblical scholar.
But it's great language.
I'm not either, but I'm fascinated by it the same way I'm fascinated with science
because I think it's people that lived
thousands of years ago trying to make sense of things.
That's it, that's ultimately it, isn't it?
With very little information.
And that's what we talked about earlier,
to me that's one of the defining characteristics
of being human, trying to make sense of the world.
And that's why, by the way, I
don't like to
get into sort of arguments with with
people who have different different views different belief systems and my
So baseline position is if you're curious and you're interested and you want to know how things happened
That to me is common ground that we can share.
The people I don't really understand,
the people who are not curious and don't have questions.
Because I think Carl Sagan wrote a great book
called The Demon Haunted World Signs of the Candle in the Dark.
You know that book where he says that story
about a taxi driver when he got in the taxi at the start,
and he's asking him all these questions
about Atlantis or whatever it is.
And he realizes he doesn't think this guy is an idiot.
He thinks this guy has a curious mind.
He's someone who should be,
we can have a wonderful conversation.
But he also says that he felt that he perhaps been failed
by society, by education,
in that his curiosity had not been somehow channeled to the real mysteries.
Yes.
But it got sidetracked into all this strange stuff.
I think the real mysteries, the academic mysteries are intimidating to some people,
because they don't think of themselves as being intelligent, so then they gravitate towards like YouTube mysteries.
Simpler, simpler. Yeah, more controversial so that puts them in like a
select club of people who actually know what's going on, where people love stuff like QAnon,
they love stuff like that, where they're in the know of like some top secret information.
By the way, that idea that I think one of the problems we have communicating science and getting
young people into science
is that idea that you have to somehow be really clever,
which is not true at all.
It goes back to what I said before,
that it's more you have to be comfortable with not knowing.
So that is a big step to say, I'm not going to guess.
And I'm OK.
If you ask me a question about the origin of the universe.
The answer is don't know. So I think it's, if, as you said, if you can be comfortable
with not having to have a simple, intelligible explanation for something, then you'll make
more progress in life
but it's quite difficult so it's easy to just go there's a simpler that thing
yes so that there's a simpler explanation there well it's also very
difficult for people because they attach their ego to ideas and once you have
set an idea then you are attached to that idea and you defend that idea it's
a real problem so important yeah ideas are just ideas and you are you and the way you interact with ideas shows your intelligence.
You can be incorrect.
People are often incorrect.
But if you argue for something that you know is incorrect because you don't want to lose,
that's bad for everybody.
Yeah.
I mean, going back to Richard Feynman, he said, there's a great essay I've probably
talked to you about before,
called The Value of Science that he wrote, 1955,
you can get it online.
And in there he says, the most valuable thing is scientists
bring this transferable skill to life.
And it's that you have a great experience with being wrong.
So nature is brutal.
And most of the time, you come up with some really great
theory, and you're really sure about it. you do the experiment and you're just wrong and so
you get so used to it that you come to enjoy it because you're learning but
it's a process you can't you that's why science is so important in schools and
experiments are so important it's not that you just swing a pendulum and
there's nothing interesting about that but it's just that you just swing a pendulum and there's nothing interesting about that, but it's just that you're learning that there is a gold standard of knowledge, which is
nature.
And as Feynman said, it doesn't care who you are or what your title is or what your name
is or you may have been elected with 99% votes in whatever it is.
It doesn't matter.
Nature just doesn't care. And so the more
you interrogate nature, even as a kid at school with a little experience with a battery and
a light or something, you learn that there's a reality and you learn what it takes to acquire
reliable knowledge about the world. And reliable knowledge. Yeah. How do we form a view of, and it can be very important questions.
It can be questions like what happens if we carry on putting greenhouse gases into the
atmosphere, for example, whatever your politics are.
It's a legitimate question, a good question.
Right.
Scientifically a good question.
Are we going to influence the climate if we carry on doing this?
And so how do we then address that as a question? You can't do it by going back
to your political affiliation or your belief system. You've got to try and
understand this complicated system, which is the climate of a planet. So you make
measurements of the thing and you build some models and computer models and
there's a very famous saying that all models are wrong because they're models
right, so but they're the best you can do so you have a go and you come up with some
information and a model that kind of works and you say well
this is the best version of our knowledge at the time and then
You can try to act on it and you refine the model and that's the process
but that idea of
how can we
acquire reliable knowledge that we can trust
which might not be right and is very likely not completely right, but it's the best we can do at the time.
That's what my definition of science would be is it's it's nothing more or less than
science would be is it's it's nothing more or less than the best picture we can manage of how nature works at any given moment. It's not a truth, it's not
something by its very nature the way that science works is it will it may be
shown to be incorrect or not particularly great a model tomorrow.
Yeah. But I would define it as the best we, and by we I mean our civilization,
the best we can do. And so we act on that. I don't see any other way to act as a civilization
other than with that, the best we can do. It's the best we can do. Yeah. And that term reliable
information is so important because people want to leap to conclusions to try to like
tie something up neatly when reliable information might not be available.
Like reliable information is the number one reason why I never take the UFO thing seriously.
I am so all in that there must be life out there.
It just makes sense.
It makes sense.
I know the Fermi paradox with notwithstanding, but I think if you just take into account
the sheer numbers of planets that we're looking
At the possibility of something achieving some sort of advanced life seems very high
But no reliable information zero not one thing that I've ever seen. I'm like, well, that's for sure real not one every sighting
Everything I'm like, how do we not know?
How do we know if there's a top secret drone program, which
most certainly there has to be?
There probably has to be.
There's probably some sort of radical propulsion system that they devised.
They probably made some breakthroughs they haven't been forthcoming about because of
national security risks.
There's probably something really kooky that they could fly really fast through the sky,
some kind of a drone, and that's probably what people are seeing.
That's probably a lot of it.
But then there's also this part of me
that doesn't want to abandon the idea that if I was
an intelligent species from another planet,
and I saw that these territorial primates
with thermonuclear weapons are advancing
towards the creation of AI and ruining the planet
while they're doing it, doing crazy shit to the ocean,
poisoning streams and water supplies.
I'd be like, let's keep an eye on these fucking freaks.
I would most certainly say this is a,
if this happens all throughout the universe,
let's just imagine that this is the natural progression
from single-celled organisms to super curious
advanced life forms that eventually transform the world that they live in. This is a natural progression.
There's gotta be planets that don't make it.
There's probably a slew of them that get to 1945 and it turns out that
both Germany, Japan,
and the United States all have nuclear weapons at the same time,
launch them all at each other and then civilization goes down to zero.
Oh, the Cuban Missile Crisis? Yes, the Cuban Missile Crisis or at the same time, launch them all at each other, and then civilization goes down to zero.
Oh, the Cuban Missile Crisis.
Yes, Cuban Missile Crisis or asteroid impacts or super volcanoes.
I mean, the reason why we have mountains in the first place, we have volcanic activity.
We know that every now and then there's a massive super volcano like what Yellowstone
is, this caldera, that it's a continent killer.
If it blows, there's no more United States.
It stops being a thing.
Most people on the planet die. We get down to a few hundred savages and we start from scratch. And that's
inside the realm of possibility. That can absolutely happen. So something has to get
past all of these hurdles to... And if I saw a planet that's real close like us, I'm like,
wow, they're going to not fuck this up.
They have achieved this crazy apex where they're
so far beyond everything else on their planet.
They're almost there.
They're almost there.
Let's watch them.
I would think of that too, but I just don't see any evidence.
Everybody keeps bringing in these whistleblowers.
They all tell me, oh, I've seen it.
It's incredible.
One day it's going to be released. Like, yeah, yeah, like yeah yeah yeah yeah yeah I don't see shit I think it's
best to assume Carl Sagan again wasn't it when he said no one's coming to save
us from ourselves let's just assume that we just definitely should assume that
and then that's a that's a safe and that's an intelligent assumption and
also that's how you want your children to behave, right?
You don't want to go save your children every time, you know, like they're when they they get older
They got to go on their own. They got to make it
They got to figure it out on their own
If they don't they're gonna be infants for the rest of their lives
And this might be one of the reasons why we don't get intervened
Why something doesn't come down and like put a halt to us like maybe they're just hoping we can figure this out through diplomacy
Whatever they have they crossing them yeah, whatever they have I mean, I'm so fascinated by it. I want to believe everything
I'm such a sucker. You know every time I see Bob Lazar talk. I want to believe it
I want to believe all of it. I was I said I wouldn't be surprised right I'd be relieved as well
Yeah, please help us.
But also, do you think about the way we interact with primitive tribes?
It's not good. It ruins them almost every time.
Like there's this story that we were talking about recently
where Starlink has been brought to some of these very remote tribes
and they've been given cell phones and now tribal leaders are complaining.
As we talked about earlier. Yeah, these kids are on their phones all day in the fucking
jungle. Like instead of like living this subsistence lifestyle they've been living for tens of
thousands of years, some of them are getting lazy and they're just sitting around and they're
looking at you know videos. Getting shouty there. Yeah, just looking at TikTok, arguing
with people online, trolling. Yeah
Looking at memes and laughing, you know, we've ruined them and this is one of the reasons why I like places like North Sentinel Island
There's like you're not supposed to visit them
You're supposed to leave them alone
Yes, they are this very bizarre state of uncontacted and very primitive lifestyle that we can you know
We can preserve which is also weird.
Like, shouldn't we help them?
That's sort of weird too.
They're human beings and they're living like people lived thousands of years ago.
I don't want to live like that today.
If I was an alien life form and I wasn't so cautious about the impact, I would go, you
guys got to stop this. We're going to come down, land on the White House lawn, scare the shit impact that I would go, you guys gotta stop this, we're
gonna come down, land on the White House lawn, scare the shit out of all of ya, you know,
take all your nuclear weapons away.
I wish somebody would do that, to be honest.
Don't you think though that the real problem would be the structure of our society is based
on this idea that we have to work together to sort out our problems. And if something came here that was like far superior
in intelligence and its capabilities,
we would sort of defer to that.
That would be our space daddy now.
And there'd probably religions,
probably some scam religions that get invented
to try to contact and make peace with these overlords.
How did we get here?
But it's the idea, like, okay, let's take a look, let's pretend that we, well, let's
extrapolate.
Let's imagine we do get to Mars, we set up bases on Mars, we do become, we develop the
technology that allows us to travel to other solar systems,
and we do observe a civilization that is, you know, like the Bronze Age, you know, and
we stumble upon these people that are developed, they have tools, they haven't figured out
steel yet, but they've done some pretty interesting things, and they're clearly intelligent,
they figured out agriculture. We would be studying them for sure, 100%. We would send word back to Earth, oh my God,
we found these people that live like the Mongols did in 1200 AD. It would be fascinating. We
would 100% be interested in it. And I think they would be interested in us.
This is Star Trek.
It is Star Trek. The Prime Directive. The thing is, yeah, the Prime Directive, you know
harm, right? Isn't that what it is? Well, don't intervene at all. I think that's what they would do.
I think we would hope that they would prevent, but if that's the case, why didn't they
prevent Hiroshima and Nagasaki?
Why didn't why do they let us just practice blowing things up in the Nevada desert for
like 30 years?
I think you're absolutely right.
I mean the point is I think there's nobody there.
That's the terrifying ideas that we're the only ones in the whole thing and that intelligent life is so bizarre and such a rare thing
that happens in the only the perfect of circumstances. That would be my baseline
view. If the universe is so big wouldn't every single potential situation happen infinite?
If it's infinite, I mean we don't know if it's infinite. We have the observable
universe. I think the current number is something like two trillion galaxies, depending on how
many smaller ones there are. So wouldn't you think that just out of two trillion galaxies,
there's probably pretty good odds that something would reach some sort of a Goldilocks state in terms of where the planet
exists in relationship to the star.
Yeah.
But we're talking the distance between the galaxies is, you know, the Andromeda galaxy
is two million light years away, which is the largest and our nearest large neighbor.
So I think when I think about this, I tend to confine it to our galaxy
because I can't conceive of
Travel between galaxies too crazy. I think it's too far. Although for now it is true that the laws of physics do not prevent that
So it relative to I teach relativity in the Manchester University
I left to the first years the 18 year olds for the first years, the 18-year-olds.
And the first thing we do in special relativity is talk about the fact that if you travel
close to the speed of light, so if you had a spacecraft traveling close to the speed
of light, then distances shrink from your perspective.
So the one number I always have in my mind is at the Large Hadron Collider at CERN,
the protons go around the ring, which is 27 kilometres in circumference,
and they go around at 99.999999% the speed of light, so close to the speed of light.
At that speed, distance is shrink by a factor of 7000.
And so that ring is something like four meters in diameter
to the protons.
So according to laws of physics, if you
can build a spacecraft that goes very close to speed of light,
you can shrink the distance to the Andromeda galaxy.
And therefore, the time it takes to get there
by an arbitrary amount actually.
The closer you get to speed of light the more you can shrink it. And so you can make those
two million light years, you could traverse across that distance in principle in a minute
according to physics. However, the downside is that you you couldn't come back to tell if you came
back to the earth at that speed to tell everybody what you'd found at least four
million years would have passed on the earth. Oh boy. So you can't, so there's
kind of a downside to it that you could we could in principle explore the galaxy and beyond.
But getting to chat to everybody about what you found
is forbidden by the structure of the universe.
It's the way that relativity works.
That really is essentially a time machine.
Well, it's a time machine in the sense that
we could go arbitrarily far into the future
by flying around in a rocket very close to speed of light so we could come back a million years
in the future and look at the earth and find out what
had happened. You can't go back as far as we can
tell so you can't get back to your you can't build a time machine to go
backwards. So these are time machines the the the
world is built so it's that a time machine
a way to think about it the world is built so it's that a time machine, a way to think about
it, the way that we teach it in undergraduate physics is that, so in Einstein's theory,
there are events which are things that happen in space-time. So that would be an event,
it's something that happens. Our conversation now is a thing that happens, space-time. And
what Einstein's theory tells you is it's about the relationship
between events. So let's say that we wanted to come back here tomorrow, that
would be another event, we meet again tomorrow. And you can see how much time has
passed between those events. In Einstein's theory, the amount of time that
has passed is the length of the path you take over space-time between the
events. So it's just like saying in a sense what's the distance between Austin
and Dallas right and you'd say okay well it depends what route you go. Well what's
interesting in Einstein theory the only complication is the length of the path
you take between events is the time measured by a clock that's carried
along that path. So that's how much, if you're carrying your watch with you and you go between
here and tomorrow, you go this way, you go off and maybe you fly to Dallas and back or
something and then come back again. There's a particular length. Someone else can take
a different path, obviously, and so a different amount of time will pass for them between those two things that
happen. Just because of that one fact. It's very infinitely small but measurable
amount of time. It's a tiny amount unless you travel, someone goes close to speed
of light or someone goes near a black hole or something where the
space-time is all distorted, then
you can get big effects. But it's still completely measurable. I mean, they are quite big effects
these in the sense that for the satellite navigation system, for example, GPS, the clocks
on the satellites tick at a different rate to the clocks on the ground. And it's quite
a big effect. I think from memory, it's something like 30, over 30,000 nanoseconds per day difference
because they're in a weaker gravitational field
and they're moving and all sorts of things.
It's the same thing.
But 30,000 nanoseconds,
light travels one foot per nanosecond,
which is great.
I always say that God used imperial units
because it's not, it's 30.8
cent of it, it's one foot, right, it's good, it's one foot per nanosecond. So that's 30,000
feet of position measurement if you drift your clock out by 30,000 nanoseconds. So it
wouldn't work. So it's a big effect for when you start using time to measure distance,
which is what we do in satellite navigation,
GPS. So we have to correct. So the clocks have to be corrected for that effect. So it's
an effect that we can easily measure with atomic clocks. But it doesn't make much difference
to us as humans. But just that the point is that the laws of nature would allow you to
do it if you could go close to speed of light.
By the way, the last thing I'll say is the limiting factor.
You might say, what happens if you go really close to the speed of light?
What happens if you go at the speed of light?
Well, special relativity, Einstein's theory, is built such that
the distance between any two events in the universe
along the path of the beam of light between the events is zero.
No time at all.
So that's the way that Einstein's theory is built. So he asked the question when
he was younger, famously, what would the universe look like if I traveled
alongside a beam of light? And the answer is that you wouldn't perceive any time.
Well, you can't. The last thing I'll say is that if you've got any
mass at all you can't do that, you can't go at the speed of light. So according to our
model, which is a good model and it seems to work, but if you've got no mass
you go at the speed of light. So if you're a photon you go at the speed of
light and no time. So what are your thoughts on the possibility of some sort of a
novel propulsion system that doesn't move things at speed but instead brings
things together? Yeah that's called the, I can never pronounce it, it's the
albicure, what's it called, the drive. So you can, you can, Einstein's general
theory of relativity, general relativity is this theory of gravity.
And it's a theory where space and time are distorted by things, anything in the universe,
right? Stars and planets and so that's what gravity is. It's the distortion of space and
time by mass and energy, is Einstein's theory. So you can, and it's been done,
but you can develop sort of things where you say,
well, if we could make this geometry of space and time,
if we could distort it in this way,
then indeed you can build a warp drive, right?
Like we should do.
Right, right, right.
But it always turns out, as far as we can tell,
that the other question is, but what kind of stuff would you need? Right, right. But it always turns out, as far as we can tell,
that the other question is, but what kind of stuff
would you need?
What kind of matter or energy or field, whatever it is,
what kind of thing would you need to make that geometry?
And it always turns out that those things
don't appear to exist.
So these particular kinds of matter and energy,
that if you had them, you'd be able to do that
with space and time. We don had them you'd be able to do that with space
and time we don't think you can have them. It's kind of a bummer right?
Stephen Hawking. Is it possible that we don't have them here but that in different planetary
systems different environments that these elements could exist?
It's not it's not going to be elements It's going to be kind of some kind of quantum field,
some kind of energy or something. And so you can sort of try to speculate. But Stephen
Hawking wrote a very famous paper called The Chronology Protection Conjecture. So conjecture
is important. It's a guess, not proved. Where he said that whatever the ultimate laws of physics are,
we don't have them at the moment, string theory,
whatever it is, then they will be such that you can't do this.
Because chronology protection means protect the present
from the future.
So in other words, you can't build a time machine
that goes back in time.
Right. So, but so that, but because Einstein's theory allowed you to imagine such a thing,
even though you might not be able to build it, it's not been proven beyond doubt
that you can't somehow make these kinds of quantum fields or whatever it is that
you need to make wormholes, for example, stable wormholes you can go through. And so it's not been proven. So it's just it's suspected that that's going
to be the case. By the way, to the final thing, this is very neat, because it goes right back
to what I said at the start, that one of the pictures of how I said there was this thing,
the black hole information paradox, and we thought Stephen's calculation was that no
information comes out, we now think it comes out. So we now think that black holes do not
destroy information. We're pretty sure. So it's been proven mathematically to most people's
satisfaction that the information ends up out again. So if you went into a black hole,
the information will be out in that Hawking radiation that could reconstruct you in the
in, but only in the sense
that if a nuclear bomb landed on us now, then in principle the information would be still
there in the future and we could be reconstructed, right? But it's still in principle there.
And then, but the question is, how does it get out? How is it getting out? How is the
information that is you ending up outside again. And it's not the physical picture is
not really understood, but the link is that one of the pictures that people are beginning
to suggest to have is that there is some kind of wormholes in a sense, some kind of wormhole
that connects the inside of the black hole to the outside. And so a picture is that your atoms and everything,
your bits get scrambled up and go basically through the wormholes and come out again.
But they're funny kind of wormholes so that people don't really understand this, but mathematically
it looks like maybe, so it looks like maybe there's some role for wormholes, these things,
the science fiction things, of after a fashion, some kind of them, there's some role for it in the way the universe
works. So it's really cool. The last thing I'll say, because I think it's a thing called
ER equals EPR, which is, so EPR was the spooky action at a distance. So we may talk about
that before, you know, in quantum mechanics, there's this entanglement thing
where something can be separated by a million light years.
But if you do something to it,
it seems like this thing responds, right?
Not in a way that you can transmit information,
but it responds.
So entanglement.
There's a picture of that.
So that's Einstein, Podolsky and Rosen, EPL,
where they wrote a paper on this saying,
we don't like this. There must be something wrong with quantum mechanics.
We don't think there is now, this is the basis of quantum computers.
So we build things that rely on this effect.
ER is Einstein-Rosen, which is Einstein-Rosen bridge, which is wormhole.
So they also published a paper about wormholes, Einstein and Rosen, in the 30s. And so the idea is that you could picture that somehow as being a kind of wormhole that connects
the entangled particles. So that's how this entanglement works. Another description of quantum
entanglement is a wormhole kind of geometry. And this is part of the cutting edge of research into black
holes, but also the structure of space and time and quantum entanglement and how quantum
entanglement might produce space and time. And it's related to the way that quantum computers
work. So it's become a really hot topic because people are trying to build quantum computers
and program quantum computers. And these are the kind of problems you have to face about quantum entanglement and how
you maintain it and what it means.
And there was a paper recently, which is quite a controversial paper, but that I think was
the Google quantum computer, which is one of the best ones.
And it's not using it as a computer.
It's using it just as these qubits, these little quantum systems that
are kind of very stable, that are the basis of quantum computing. And it's using those
qubits and setting them up in such a way that something that looks like a kind of a wormhole
is created in the quantum computer. It's kind of a one-dimensional wormhole and it's a bit
kind of technical and everything. But it looks like it might be the first hint of how you build space from qubits.
And so that paper was published.
There it is.
That's it, a holographic wormhole.
It's important to say that wormhole is what's called a holographic wormhole.
It's not really in our universe.
It's kind of a different thing because that's the last thing I'll say
because I've got to blow your mind because your mind looks like this. These theories, the hologram thing is quite well
established now and it's coming from a thing that you may have talked about
with other people on the show that the ADS-CFT conjecture, a great physical
Maldicina. So the idea is that
you can have a quantum theory living on a boundary. So you could imagine, picture a
sphere with a quantum theory living on the surface. And that quantum, there's a completely
equivalent description of whatever's going on that, the physics in the interior of the sphere. So it's almost as if the interior of the space
is a hologram of the theory that lives on the surface. And it's kind of not accepted
but one many physicists think our universe is like that. So what we're saying is that
we're having this conversation now and there's an equivalent description of this somehow in a theory that does not contain space and time.
That's a completely equivalent description that lives in fewer dimensions on a surface
somehow that's surrounding us.
And it's really woolly and hand wavy because we don't fully know what it means, but it
would mean that we are holograms. So this is a hologram of this other dual theory, that's what that thing
was, the holographic wormhole thing. So it's all very the beginnings of this work, but
that's an example of how it could become an experimental science because quantum computers now exist.
And they allow you to do those experiments,
to try to build filaments.
It's almost like a filament of space,
a holographic filament of space
that you're building from these qubits,
which is just, and by the way, that word is a bit weird.
It's just something like an electron.
It's not that they're more complicated,
but an electron would be an example of one.
So it's a physical thing that we have in the lab that is a quantum system, that's a quantum
bit.
So you build it in the different ways of building them, and that's what a quantum computer is.
But it's amazing, isn't it, that we're beginning to use those things not for computing yet,
because they're really hard to program.
But we do, physicists have gone,
this is great because Google and Microsoft have spent billions of dollars building these
things because they want to build these computers. But they're perfect laboratories for quantum
mechanics. So you can do abstract research into quantum mechanics on them, which I find
fascinating.
That's actually more fascinating than using them to crack everybody's codes
Yes, kind of like yeah, it's kind of you know factoring large numbers
It's kind of boring but building wormholes. Yes, which is and I caution it's not it's a complicated thing
but it looks like the beginnings of a
laboratory to build
Structures like that. That's so fascinating.
Before you leave, I have to ask you this, because I thought about this while you were
talking.
You might be the only person that could explain this to us.
We were looking at this image of these quantum entangled photons, and the image was in the
shape of a yin-yang.
We couldn't understand what we're seeing.
Right.
We couldn't understand if they did this on purpose to make it the shape of a yin-yang,
and it's just a representation of these quantum entangled
photons, or if that is what quantum entangled photons
actually look like in a shape.
So it's visualized to entangled particles in real time.
It's making them appear as a stunning quantum yin-yang symbol.
Yeah, I mean it's, I hadn't seen that, but it looks to me like it's another example of
trying to visualise, entanglement looks fundamental.
Let me put it that way. So it does look as if
this idea of entanglement, which is the, it is, as I said, perhaps producing space
and time itself, but also is the way that quantum computers work and the
way that you, we didn't talk about this, but the way that you can, one way of
picturing what this does is allow you access to multiple universes. It's the many worlds
interpretation of quantum mechanics. You mentioned it, breaking people's
encryption codes, right? What are you actually doing there? You've got
an algorithm, you run a quantum computer, and how does it factor these? What it's
doing is finding the prime numbers that you multiply together
to make a very big number. So it's very easy to multiply two big numbers together to get
a really big number. It's very hard to take a very big number and factor it. So find out
what the numbers were that got multiplied together to make it. That takes much longer
than the current age of the universe for big numbers Well with any conceivable classical computer, but the quantum computer can do it in
You know a second or something
The explanation for how it's doing it a picture which many people in the field not everyone many people would say is the correct
Is what it's doing is the calculations
in multiple universes.
So it's accessing the fact that there actually
there's an interpretation of quantum mechanics
called the many worlds interpretation,
where you have to imagine these, you know,
infinite and pretty much sea of universes.
And the computer kind of goes,
like that, so it goes away.
And does the calculation in parallel, and then brings them
back together again at the end.
And I mentioned David Deutsch earlier, who's a fascinating writer in this field and the
instigator of many of these algorithms early on.
He would say that.
He would say, this is what has happened.
There is no other explanation.
How do you explain the fact that this quantum computer can do something that no
classical computer can ever do how do you explain it where is it doing the
math and he would say he would say it's doing it in the multiple universes well
I don't fully understand that I But it's a new realization.
I feel so much better that you don't fully understand it.
I read it, read it through it again,
and I also now don't understand it too,
because it says that by capturing the resulting image.
By capturing the resulting image with a nanosecond precise
camera, the researchers teased apart the interference pattern
they received, revealing a stunning yin-yang image
of the two entangled photons.
So that sounds like that's what it actually looks like.
It is a photograph of, in a real sense, that the photons are arriving and you're detecting them, so it's a photograph of...
So that's what it actually looks like.
If you think about what, I think what must be happening is you're getting these photons...
It is true to say that again this many-worlds interpretation of quantum mechanics would be that these entangled photons if you send them on a path then they they go and bother about to find them. If
you calculate the way you calculate how a photon goes from A to B or an electron whatever
it is it just formally is you allow it to take all possible paths. That's one way of
calculating the probability it will go from one place to another. And when you get entanglement
it gets more complicated but you're essentially, you are mathematically saying
I allow it to go on all paths. And so really there you're seeing what an
interference pattern is, is you're seeing the result of the fact that these
particles can go on all loads of paths and interfere with each other and and make a pattern you can see and I think that's what that is.
But how crazy is it that pattern is an ancient symbol?
It is beautiful isn't it?
It's unbelievably beautiful. It's crazy.
Brian thank you so much. What a great conversation. I really really enjoyed it.
Please tell people how they can find you. I know you're doing live performances.
I'm going to do some. Yeah, I've been doing this tour for a long time now, actually. I ended up
doing it for about two and a half years and it's changed a lot. We've done it to over 400,000 people,
I was told the other day around the world. And I thought just to finish it, because I want to finish
it and write another one, I'd come back to the US. We did a few in the US, but so coming back in April and May and doing these relatively small-ish shows.
That was ages ago, wasn't it? Yeah. So this is, it explores many of these questions actually,
particularly black holes. And then just to round it off, I'm doing a few. So if you go
and look on the web, you'll find we're doing some LA, New York LA, New York, Chicago around I hope we did Austin actually I hope you do
This yeah, it's not in there that we call it
And then you know, yeah, so that's that's what I'm what I'm up to. Well, thank you very much, Brian
I really appreciate what you do means a lot Thanks for watching!