Theories of Everything with Curt Jaimungal - Roger Penrose: Why The Big Bang Was Not The Beginning
Episode Date: November 3, 2025Nobel laureate Sir Roger Penrose dismantles standard cosmology, arguing the Big Bang wasn't the beginning and quantum mechanics is fundamentally wrong. He then connects a real, gravitational wave func...tion collapse to the non-computational nature of consciousness and why today's AI can't truly understand. Sponsors: - Get 50% off Claude Pro, including access to Claude Code, at https://claude.ai/theoriesofeverything - As a listener of TOE you can get a special 20% off discount to The Economist and all it has to offer! Visit https://www.economist.com/toe Join My New Substack (Personal Writings): https://curtjaimungal.substack.com Listen on Spotify: https://open.spotify.com/show/4gL14b92xAErofYQA7bU4e Timestamps: - 00:00 - The Big Bang Wasn't The Beginning - 02:14 - Conformal Cyclic Cosmology (CCC) - 09:12 - The Collapse Problem - 14:31 - A Feeling of Elation - 24:32 - Gödel and Understanding - 37:32 - Gravitational Collapse - 50:05 - Critique of Modern AI - 57:12 - Black Hole Information "Paradox" - 1:04:15 - Wheeler, Wigner, & Witten - 1:15:04 - Richard Feynman in Poland - 1:20:25 - Libet's Timing of Consciousness - 1:32:49 - Three Worlds, Three Mysteries - 1:44:14 - Why Quantum Mechanics Is Wrong Links mentioned: - Stuart Hameroff [TOE]: https://youtu.be/0_bQwdJir1o - Classical Theory [Paper]: https://arxiv.org/pdf/hep-th/9409195 - Rebecca Goldstein [TOE]: https://youtu.be/VkL3BcKEB6Y - The Emperor’s New Mind [Book]: https://www.amazon.ca/Emperors-New-Mind-Concerning-Computers/dp/0192861980 - Fashion, Faith, and Fantasy in the New Physics of the Universe [Book]: https://www.amazon.ca/Fashion-Faith-Fantasy-Physics-Universe/dp/0691178534 - Perturbative Gauge Theory as a String Theory in Twistor Space [Paper]: https://arxiv.org/pdf/hep-th/0312171 - What Is Life? [Book]: https://www.amazon.ca/What-Life-Matter-Autobiographical-Sketches/dp/1107604664 - Michael Levin [TOE]: https://youtu.be/Exdz2HKP7u0 - Why I Don’t Buy the Simulation Hypothesis (Nor Materialism) [TOE]: https://youtu.be/3_lBPMc6JRY - Consciousness and Quantum Mechanics [Book]: https://www.amazon.ca/Consciousness-Quantum-Mechanics-Shan-Gao/dp/0197501664 - Ivette Fuentes [TOE]: https://youtu.be/cUj2TcZSlZc Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
My idea is a crazy idea, and I admit it's a crazy idea.
But you need something crazy because the conventional ideas don't work.
And I think people just sort of go with the crowd.
I'm just not persuaded by going with the crowd.
It doesn't make sense.
I don't believe a word of it.
The Big Bang was not the beginning.
The same as quantum mechanics.
No, there's a huge thing missing.
It's extremely accurate.
You could say it's incomplete.
Schrodinger and Einstein were much more polite.
They said, well, quantum mechanics is inconclusive.
Complete.
Svala suggests, oh, there's a little detail.
Oh, change the sun in here.
I don't mean that.
It's a big thing that's missing.
Standard cosmology says the Big Bang was the beginning.
Penrose says that's dead wrong.
His conformal cyclic cosmology makes each Big Bang the conformal continuation of a previous
Eon's remote future.
Why?
Because mass becomes irrelevant.
Twice, in fact, for different reasons.
At the Big Bang, there's extreme temperature, and in the remote future, there's only massless
photons and scaling of Dirac particles.
No mass means no scale.
So conformal geometry.
This lets the remote future match a stretched-out Big Bang.
And this explains why our origin is smooth while black holes are tumultuous.
Penrose argues inflation doesn't explain this, but his model does.
He further insists that quantum mechanics is wrong, not
just incomplete. On this channel, I interview researchers on theories of reality with rigor and
depth, and I've been blessed to speak to Roger Penrose four times, once for the Institute
for Arts and Ideas, once in a two-hour podcast last year in Oxford's Math Institute, today
for another two-hour session that you're about to see, and soon again on this channel in a couple
weeks with his collaborator, Professor Yvette Fuentes, on a groundbreaking new unannounced experiment.
So subscribe for that.
Enjoy this episode with Sir Roger Penrose.
Professor, what is something that most physicists believe that you think is completely wrong?
Well, there are several things in nature.
I think probably the most blatant one is the cosmology.
model I have. You see, most people who
normal cosmologists these days
believe that the universe began
with the Big Bang, and there was an
early phase called inflation. And this
phase was supposed to have smoothed the universe out. I never
believed that. It doesn't make sense. Because why does it work
in one direction and not in the other direction?
I mean, you get crazy singularities in black holes,
which are not automatically smoothed out by time-reversed inflation.
It doesn't, it's, it's, okay, most cosmologists believe in inflation.
I don't believe a word of it.
But this is just part of the story.
You see, the story which I have is that the Big Bang was not the beginning,
that the universe goes through cycles,
the cycles
start with
each one
starts with
its own
big bang
terminates
with a
remote future
you see
this is the
thing you
have to
understand
is that
the scheme
at both
ends
the conformal
structure
on space
time is
the relevant
thing
conformal structure
to get an
idea
it's useful
to think
of these
Escher
pictures
with
infinity
see angels
and devils
and
they crowd out along this circle boundary which represents infinity.
And this is a conformal representation.
Now, the same thing applies, I claim, to the universe as a whole.
And our remote future is a situation.
You see, I'm arguing that there are two times, if you like,
one, at each of these times mass becomes irrelevant.
One of them is at the Big Bang.
mass becomes irrelevant because the temperature gets so high that the particles move around so fast
that the mass contribution becomes trivial.
I mean, the main contribution is the kinetic motion, and the actual rest mass of the particles
becomes less and less important, the closer you get to the big bang as you go earlier.
So that's a situation in which mass becomes irrelevant at the beginning.
and another place where mass becomes irrelevant
for a quite different reason
is in the very remote future
and then I weren't going to the reason in detail
that's sort of shifted for my early arguments
but the massive particles
the mass term scales in such a way
that it becomes irrelevant in the remote future
certainly Dirac particles
and the direct particles will be the main particles
apart from photons
Photons are already massless.
The other particles mainly will be direct particles, electrons, positrons,
maybe protons, but maybe they decay.
Doesn't matter which.
There's still direct particles.
And they will, if you write them in the right way,
you can see that they scale out,
and so they become effectively massless in the remote future.
And so those two ends, the mass disappears.
Now, when you don't have any mass, you don't have any scale.
The geometry is really what I call conformal geometry.
Well, it's not what I call it.
It is conformal geometry.
And the conformal geometry means, well, like those azure pictures, you preserve angles.
The angles are clearly defined and make sense and are affected by getting close to the edge of the picture, whereas the sizes are changed.
So conformal geometry is the geometry of angles, if you like.
In space time, it's the geometry of the light cones.
So you have the null cones, I should say.
The null cone gives you nine out of ten components of the metric.
The tenth component really is the scaling of the whole thing,
and that is given by the mass.
The scaling of the mass comes from the two most famous formulae of 20th century physics,
One of them is E equals MC squared, and the other is E equals H-new, H-F, if you like, due to Plank.
So the Einstein, E-H-E-X-M-C-squared, and the Max Planck, E equals H-F, or H-new.
Put the two together, and that tells you that frequency and mass are equivalent.
you see the energy is
one energy is the other
so frequency and mass are equivalent
so that mass is what gives you the scale
so it determines a frequency
you see if you don't have any mass
you don't have the notion of frequency
then you don't have scale
so you have conformal geometry
and the two places you don't have mass
I argue is in the remote future
because the Dirac particles
is all that's left and they scale away
and the Big Bang
where you have energy so great
that the mass becomes irrelevant
so for quite different reasons
but then the argument is
that then a remote future
from a conformal perspective
is very like stretched out Big Bang
and the reason for this perspective
is that
the Big Bang
is extraordinarily special
in the sense
that the gravitational degrees of freedom
are not activated
and for some reason.
And this isn't explained by inflation.
It's not explained by any conventional cosmology.
However, it is explained
if you say that the Big Bang
is a conformal continuation of the remote future
because you find that the scale,
the gravitational degrees of freedom scale away.
It's a little bit of a subtle question
because gravity has two different scalings.
One of them goes away and the other one stays with you
and enables gravitational signals to get through from one side to the other.
But anyway, that's a scheme which I think there's a lot of evidence for,
but people pay very little attention to it.
And certainly it's not a...
I mean, the majority view is to have a big bang in inflation and all that stuff.
So that's perhaps the main example, where I hold a different view from most people.
Another place where I hold a different view, I think, has to do with the collapse of the weight function,
which I believe is a very important phenomenon, which, well, you see, there's no common view on that one, I think, you see.
With the cosmology, there is a common view that the Big Bang was the beginning, and for some
reason, trying to be argued that inflation was the reason, but it doesn't really work,
that the uniformity of the Big Bang, which distinguishes it from the incredible complication
that you expect for singularities in black holes, I mean, they're utterly different
in nature, so you need some explanation for that.
And the other element has to do with the collapse of the wave function.
But there isn't really a common view, I think, that is held by most physicists.
I'm not sure what most physicists think.
They usually sweep the problem under the carpet, I think, as far as I can make out,
without recognizing isn't a serious problem.
So two of the other problems that inflation solves,
one is flatness that you mentioned,
but two of the other ones are the uniformity of the CMB,
so the horizon problem.
Well, the fact that you don't have gravitational degrees of freedom.
I mean, people don't sort of recognize that very well.
I don't know what, you see, I found it very puzzling
because the expectation inside black holes,
of course we don't know what goes on inside black holes,
but the expectation from independent calculations
from a Russian group,
Bolinsky-Liftschitz and Kalatnikov and Charlie Mizner in Princeton,
and they have pictures of the complicated situation that you get
as you get close to the singularity, and it's very complicated.
You find curvatures go wild in different directions, and one direction takes over,
and then another one, and it's very complicated.
Nothing like the Big Bang.
I don't think people think about the problem, really.
It's not that they have a different view from me.
They have a different view, but they actually don't face up to the real problem.
They have this belief somehow that inflation solves the problem,
which is, in my view, completely wrong.
Where does that belief come from?
The fact that you have, you don't have this kind of singularity.
in a big bang.
And so the belief has to come from somewhere.
And so the inflationary point of view seems to be,
that's all they can think of, I suppose.
I don't know.
I mean, it's very commonly believed inflation is part of a standard cosmology.
I was speaking to, it was either Leonard Suskin or Nusser,
Neil deGrasse Tyson, and I was asking one of those two, I believe is one of those two,
what is it that you disagree with your colleagues about? And then he thought and said,
if I disagreed strongly with my colleagues about it, then I probably shouldn't be thinking it
because something that they believe in the wisdom of the crowds, they believe that they're the
ones that are most likely incorrect if everyone else believe something different. How is it that
you can maintain this level of, maybe belief is not the correct,
conviction and credence in your own ideas, despite being criticized by colleagues. How do you
psychologically deal with that? Just that the arguments are wrong. I mean, I don't see any good
arguments against my point of view. I mean, the thing about the cosmology is that it's a crazy
idea. My idea is a crazy idea, and I admit it's a crazy idea. But you need something crazy.
because the conventional ideas don't work.
And I think people just sort of go with the crowd.
I'm just not persuaded by going with the crowd.
It doesn't seem to me...
I mean, there are lots of things I don't know anything about.
And then I say, I'll trust the crowd because I haven't got any views of my own.
I would say particle physics is a good example.
I don't have any particular views of my own,
so I'm quite prepared to believe what the most people think about,
Particle physics is probably on the whole correct.
I don't know.
I don't have an opposing view on that.
So...
Have you always been like that?
I don't think my own views have been worked out enough
to have a strong opposing view to what other people might think.
I mean, it goes back, I suppose, to the singularity theorem I proved,
which eventually got a Nobel Prize
which was the...
I heard about that.
You see, that was a...
It was at a time when people were very puzzled
because of the quasars
and they found these very bright objects,
very distant objects,
and people weren't even quite sure
how far away they were.
They weren't sure that the redshift
you saw was actually a cosmological
redshift, or might it be some gravitational red shift or something like that.
There was a lot of puzzlement about it.
So it was at a time when there was a lot of confusion, I think, about what was going on.
And I became interested in this, but without holding a particular view of my own.
And I did learn about the Oppenheimer-Snyder collapse picture of a collapse.
collapsing cloud of dust, in fact it was, and this reached a singularity at the end.
And this was well known to people, but nobody trusted it for the very good reason that this
assumes exact spherical symmetry, so that you might think that if it's not symmetrical,
it would get more and more complicated as it collapses, and then it might swirl around and
I'm swishing out again. So I think that was the common view at the time, that although
Oppenheimer Snyder was well known, it didn't seem to represent reality in people's view,
which was a reasonable point of view, I think. And I didn't know what the answer was.
There had been a paper at the time written by Lifshitz and Kalantikov, two Russians, and they
seem to have proved that in the general case you would not get singularities.
And I looked at the paper, I didn't sort of go into it very hard, I thought the techniques
they were using were not likely to be trustworthy. I didn't see the mistake in the paper.
There was a serious error in the paper, which was later found by Balinski, I think, who corrected
the mistake and joined the other group.
and the later paper came to the opposite conclusion
that singularities were generic,
but they did come about like that.
But that was not the view at the time.
The view at the time was that Lifshitz and Kalatnikov
had shown that singularities didn't occur in general,
and therefore the Oppenheimer-Snyder collapsed
and you'd have swirl around
and maybe it would come a swishing out again.
I began to worry about this problem,
and I wasn't sure I believed Liftsjian Kalatnikov.
I didn't take them very seriously
probably not for a very good reason
that's mainly I hadn't looked at the paper
thoroughly enough
I certainly did not see the error in the paper
that was seen by Balinski
later on I think
however
I did think about whether
this was likely to be correct
or not and came to the view
that probably
singularities were generic
and I'm not quite sure why I think
that came to that view
I had been thinking about related problems
and I'd probably
vaguely formed that view
but I didn't have an argument for it
and I told this story many times
but I was Ivor Robinson
who was a very good talker
and he
wrote his papers by talking
and somebody else would co-authored them
with him
he would never write them himself
but anyway he was a
He talked very elegantly, and he was talking to me.
I was on my way to my job at Birkbeck College,
and I remember we were walking along the street,
and then there was a side street.
We had to cross the road,
and as we crossed the road, the conversation stopped,
and when he was got to the other side of the road,
his conversation started again.
And then when he left,
I was left with a strange feeling of elation.
Why do I feel elated?
I thought, I can't think.
So I began to think all the things that happened to me.
What happened for breakfast?
No, no, no, nothing to do with that.
Walk in the woods to get to the bus stop.
No, no, that can't have been it.
The bus trip, no, there on the same.
Blah, blah, blah, blah.
And then it thought, oh, it was when we crossed the road.
I had an idea.
That was it.
And so I reconstructed what that idea was,
which I think was, I've never quite got this straight,
but I'm pretty sure it was the idea of a trapped surface.
You have to have some criterion
which is a generic criterion,
so it doesn't assume that you have symmetry or anything like that.
It just tells you that the collapse had gone to irreversible place,
and this with you have a surface, and you look at the boundary of the future.
Well, you look at the future region of that thing,
and it has converging lines on it,
and I knew enough about some of these things to show that this would lead you to a contradiction.
And then there must be something wrong.
And that singularities were generic.
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And that singularities were generic. And then I gave a talk about this.
the thinking about this
yes that's right
I gave a talk about this
at King's College London
and the movie
according to the movie
Stephen Hawking was there
being inspired
and sparks coming out of his head
or something
he wasn't there
but it's not quite so bad
as that
because I did give a repeat talk
it was a King's College London
I gave this talk
I gave a repeat talk
in Cambridge
she Dennis Sharma
had heard about my talk
and asked me to give another talk in Cambridge.
So I gave a repeat, and Stephen Hawking was present at that talk.
And I talked to him afterwards,
mainly it was the talk afterwards, which I had to him,
and George Ellis, and I think Brandon Carter,
at least for some of this discussion,
in which I described the details of the proof that I had.
and this
Stephen then picked up on some of these ideas
and generalised them to
so apply to the Big Bang and things like that
and then we
later on we collaborated on a paper
which was very general arguments
curiously enough it didn't quite include my original
theorem so the original theorem was not
a corollary of what we did in that more general paper.
I don't think, no, because we had a different condition
on the energy condition, was stronger.
We were talking off-air about
what is it that you're most misunderstood about?
I would think the consciousness thing, probably.
The trouble is that,
It's a murky subject, and probably I'm not sure I should have got into it at all.
It's a good question.
I think I'm glad I did, but it came about mainly from talks.
You see, this was one of the three courses I went, which were nothing to do when I was a graduate student in Cambridge,
and I went to three courses that were nothing to do with my subject.
One was by Herman Bondi on general relativity, one was by Paul Dirac,
quantum mechanics, big influence on me clearly, and the third one was by a man called
Steen on mathematical logic. And I learned about the Gödel theorems, and I found it absolutely
stunning, because I had sort of vaguely heard that girdle theorem showed that there were things
in mathematics you couldn't prove. I didn't like the idea very much, but then when I heard
what it actually said, I found this stunning. Because what it says, you make a sentence, and this
sentence says, you have to, it's clever to make it do it, but you make this sentence say, in effect,
I am not provable by those rules, and that's what it says. So you say, well, maybe it's false.
And if it's false, it is provable by the rules, and therefore it's true and not provable by the rules.
Amazing. So how do you make it do that?
Well, that's the trick, of course.
But what I found remarkable is that how do you know it's true?
You know it's true not because of the rules that you're using,
because you believe that those rules only give you truths.
And what's the point of using these rules as methods of proof if you don't trust the rules?
Why is it proof anyway?
Why is it something which you believe to be true?
only because you trust the rules.
But if you trust the rules,
then you can prove this other statement,
which is based on your belief
that the rules only give you truths,
but you can't obtain that using the rules.
In fact, it wouldn't be much good if you did use the rules,
because you have to know that the rules only give you truth
in an order to trust the conclusion.
So you have to understand why the rules only give you truth.
So then I'm going to think,
What does understanding mean?
What are you doing?
Well, it seemed to me, whatever it is, it seems to involve consciousness.
I mean, the very term understanding, you wouldn't really say an entity understand something
unless it's aware of it.
That's normal usage of the language.
So to understand something, you have to be aware of it.
So for some reason, the awareness of things gives you something beyond what you could achieve.
achieve you with computers.
So that is a view
which I held then
and still hold
which is more relevant than ever
now of course because people talk about
AI which is
already a misnomer as far as I'm
concerned. It's not artificial intelligence
it may be artificial
cleverness or something
but it doesn't involve any understanding
you're just following the rules
and the argument that
I had convinced myself, learning from Mr. Steen about the mathematical logic,
was to say that the understanding of why the rules work
is something which is not a computational thing.
What is it if it's not computational?
Well, it's something to do with consciousness.
Now, you see, I don't know anything about what I...
I wrote my book, The Emperor's New Mind,
to try and express this point of view.
And I learned a bit of neurophysiology,
thinking that if I learned enough neurophysiology,
I would find out somewhere what it is that maybe...
You see, I formed the view...
Yes, I have to backtrack a little bit.
I formed the view thinking of all the laws of physics.
You see, I'm a physicalist.
So I believe whatever is going on in our heads is following the laws of physics.
But what are the laws of physics?
Well, the laws of physics, Newtonian mechanics does pretty well.
But then you have to go further than that.
You have to have Maxwell's equations.
You have to talk about special relativity, a general relativity,
and quantum mechanics.
But all these things, although there's a little bit of,
what do I call it
an
incompleteness in the argument.
You see, all these theories
depend on the continuum
and it might
there could be a catch there
that something is not
based on the continuum.
But the continuum seems to be
how you can approximate
and you can approximate
the continuum
and calculate very accurately.
Even with that
time there weren't good calculations on general relativity, but I realized that it was still a
computational problem. And nowadays, people do great things with calculators on computing what
happens with black holes spiraling into each other and things like that, which is pretty
impressive. So sure, that's things you could put on a computer. General relativity, as well as
Newtonian mechanics, Maxwell's equations, all these things you can put on a computer. Quantum
mechanics, well, the Schrodinger equation, that's you put that on the computer, maybe lots
of variables you have to worry about and so on and so forth, but still, it's still a same
sort of thing. How about the collapse of the wave function? Well, that seemed to be the gap
that maybe is where one needs a gap in this whole discussion, and that's the only gap that I
know of. It could be there's something else, of course, that we don't know in physics, but
but that seems to be an important gap
and collapse of the wave function.
You see, many people,
including Vigna,
you see, I remember talking to Vigna
when I was in Princeton,
and I remember had dinner with him
and discussing this question with him
because one of the views attributed to Vigna
was that it's the conscious being
observing the quantum system
which collapses the wave function.
So it requires consciousness
to make the collapse work.
I talked to him a bit,
and he was not so dogmatic
as people tend to think about this.
He said that was a view
that he played with
and thought it was a possibility.
I didn't think it was at all likely
for all sorts of reasons.
Seems to me that think
I had this argument
about a distant planet, which is an earth-like planet,
and the weather on that planet, there's no life.
It just never got started.
And there's no butterfly to flap its wings
and cause the weather to do this or that.
It's just a quantum mixture of all the different weathers
it can possibly have.
And there's no conscious observer to look at it,
so it's just a quantum superposition
of all these different alternatives.
So the space probe which travels out
takes a photograph of all this
superposition of all these different weathers
and when it gets back to Earth
or close to Earth it sends a signal
to the Earth and says this is the photograph
I've just taken and somebody sitting
and looking at a screen
sees this superposition of
weathers. First time a conscious being has seen it
suddenly it becomes one weather
doesn't make any sense
so that's not what I believe
it's not that consciousness
causes the collapse of the wave function
my view is almost the opposite
it's that whatever consciousness is
it depends on the collapse of the wave function
that there is the only thing
which I could see which was not
obviously computable
okay the way we do it
is we just introduce a randomness
but that I would argue is an approximation
that there is something going
on, which is not just explained by randomness, but it doesn't, I don't have a solution to that
question, but it did sort of, it was my entry into the consciousness discussion. And I mean, I wrote
my book, The Emperor's New Mind, to try and explain this point of view, I had no answer. I remember
getting to the end, thinking I would learn about the Hodgkin-Huxley nerve transmissions, and I would
learned enough about that to see what the answer might be, no, I didn't. So I just sort of tapered off
at the end with something I didn't really believe, and that was the end of a book. But later on,
I learned from Stuart Hammeroff about microtubules, which I thought were much more likely.
Something in microtubules could easily be more likely. But the subject is not something.
It involves biology.
I don't understand about biology.
I can't remember the names that people keep using,
and they talk about different chemicals, processes,
and it's all beyond me.
Right.
So it's not something that I feel I could develop thinking in.
So that's, I mean, I did have lots of discussions with people,
but the discussion sort of went off in different directions
and not anything which I could really contribute to.
I think there's
interesting aspects
about the collapse of the wave function
which most of which I didn't know at the time
but thinking about later
there's something extremely puzzling
about how it works with regard to time
and this puzzlement
could easily have relevance to
conscious perception
and things like this
So I think there's a story there
There's a story there which is worth exploring
But it's not really an area
Which I don't
I can never remember the names
That people talk of the chemicals
Which are involved and so on
And it's not a kind of thing I can do
So I'm happy for other people
To follow these lines up
Except I don't think they've got very close as yet
I don't know
It's quite possible
that this is not my idea because I can't really contribute.
But one thing I would worry about is you have the cerebrum
and the cerebellum underneath.
The cerebellum is organized much more in the way
that if you're a computer scientist, you would organize it.
The left-hand part controls the left hand,
all the left side of the body,
the right-hand part to the right-hand side of the body.
There's none of this crazy crossing over and all that stuff
that the cerebrum is involved with.
It's much more organized like a computer.
It's completely unconscious.
It is like a computer, maybe.
But the thing that impressed me a little bit
about what Stuart Hammeroff was doing later on
is that he considers that this main relevant structures
in the brain have to do with things called pyramidal cells.
and that's the first time I've heard about certain types of cell
which are not found in the cerebellum.
Everything else you see is the same kinds of cells and so on and so what.
But these cells and occupy a particular location in the brain
and Stuart seems to think that they are very important with regard to consciousness.
I can't make any comment there because it's not my area.
But I do find that particular
a suggestion as quite plausible.
That's all I can say.
Now, if you're a physicalist
and you believe that the collapse of the wave function
somehow produces consciousness,
then I don't see that as inconsistent
with a computer being conscious,
because a computer is a physical system after all.
Well, no, it would have to be harnessed,
and you'd have to make use of it in some way.
You see, it's, it's, I mean, it's physical,
in the sense that the collapse of the wave function is part of physics.
It's not to do with an observer looking at it, as I was saying earlier.
It has to do with the system getting too big in some sense.
And that's another line of thinking, which I've developed, to some extent, independently.
I had an argument which I put forward, around about the turn of the century,
I can't remember exactly when
and it came up
this argument produced a lifetime
for a superposition
so if you have a body
take this cup
forget about the coffee in it
take this cup
and imagine it's in superposition
of being here and here
well I can tell you
that that will have a lifetime
of becoming one or the other
and what is that lifetime
well I work out
if I take two copies of the cup
right on top of each other
I move one of them away from the other,
I ask how much energy that would cost me
if I consider only gravity
to the gravitational force between the particles.
As I move this away, it's tiny,
but still huge in another respect,
that energy is a fundamental uncertainty
whose reciprocal gives you the lifetime.
So the lifetime for this cup would be absolutely instantaneous.
If it's a molecule, maybe not.
Maybe it take a long time.
If it's a big enough molecule, maybe the collapse would happen quite quickly.
Depends how big it is.
But that calculation tells you the lifetime.
I should say that that lifetime was independently discovered,
independently about two years before me by Diyoshi.
So that you can call it the Diochi Lifetime.
I sometimes call it that.
However, his scheme is in a way different from mine,
and there was, you still have an argument for a lifetime,
but it has other implications in his scheme which have been refuted.
There was an experiment done a few years ago,
you know, about three or four years ago, I can't remember now,
in a mountain, because his point of view would predict
that the collapsing is happening all the time,
and this gives you an effect.
effective heating. And so
the system would gradually
heat up. There would be a
slight spontaneous
heating. And that
heating is measured not to take
place. So
some people say this disproves the
Penrose theory. But it's not
the Penrose theory. Because
my scheme
does not involve the heating.
It would be a nuisance because I think it would
cause real problems with
cosmology. You have neutron stars
probably would already be heating up spontaneously in a way that they don't, so I don't believe
that. But in order to avoid the heating problem, you have to have something else, which is very
curious. And this curious thing depends on certain things being retrocausal, as though the
cause goes back into the past. But you can only make sense of this if you have
what I call
two kinds of reality.
One is classical reality
and the other is quantum reality.
And classical reality,
well the cup here has classical reality.
I can say, hello cup.
What is your shape?
And it says, I've got more or less a circle up there
and I have this particular curve there
and actually symmetric apart from the handle
and so on, you see.
That's classical reality.
I can ask it what its shape is.
Quantum reality is best.
are described by, say, the spin of an electron. The spin of electron, the spin state could be
in any direction in space, but it's the superposition, quantum superposition, only two directions.
If you want to ask it, you say, you, see, Einstein had a criterion. See, I think people
were worrying about whether the quantum state was real or not. When I say real, I don't mean real
in the mathematical sense
as opposed to complex
because it's complex numbers.
But I mean real, is it physically real?
And Einstein had the following criteria.
He says, if you have a state
that you can perform a measurement
on the state such that it gives you the answer,
yes, you've got the right answer,
yes with certainty, that gives it a reality
without disturbing the system.
That's right.
You can make a measurement without the serving a system to say, are you like a spin, half particle, say.
Is your spin in that direction?
And if you've got it right, it will say yes with certainty.
That's Einstein's criterion for the reality.
I'm slightly changing the terminology.
That is, in my mind, the criterion for quantum reality.
You can't say hello particle which way are you spinning.
you can say that, but it won't tell you.
It looks at you blankness, blankly, and says, I don't answer questions like that.
Suggests the direction, you see.
Then you can suggest the direction.
If you've got it right, it will say yes, you got it right.
If you've got it wrong, it may say yes, it may say no, with various probabilities, depending
on where, if you've got it completely wrong, opposite right, it will say no with certainty.
so Einstein's criterion is satisfied
but you can't ask the particle which way it's spinning
that's quantum reality
so you have to distinguish between the quantum and classical realities
and the quantum reality has very curious causal behavior
it looks as though it goes into the past
and things like that
so you have to be very careful about it
that it doesn't give you a causal anomaly
somehow you could predict the past or something
kind of retradict.
So it doesn't do that because it's only quantum reality.
But it's a curious kind of situation,
which I have written about,
but not probably sufficiently detailed.
And I'm thinking about writing a paper,
which would explain this more complex,
completely. It's actually in my book,
fashion, faith, and fantasy.
So it's in the book, but perhaps it needs a little bit more.
Sharpening up.
Yeah.
Do you see this quantum and classical reality as completely distinct?
Because most of the time people think of the classical world
as the limit of large N or large amounts of quantum systems.
I mean, you can have a quantum system which has a huge spin,
and that's been still quantum reality.
It's not going to give you a classical answer,
just because the spin is large.
So the fact that your state involves many degrees of freedom,
what do you mean by large, you see?
Does it mean lots of degrees of freedom are included,
in which case I don't think that's the answer?
The answer has to do more with mass displacement,
and then, yeah, it depends on the moving the glass and so on.
So the classical reality, it's not a fully worked out scheme.
I don't know the answer to most of these questions.
But all I would say is that I think this criterion for collapse
for a body in two locations is a fairly clear-cut.
formula, I said the D or she timescale for collapse.
But it's not just because the system is big in the sense of having many degrees of freedom.
Depends what one means by big, I suppose.
Big in the sense of mass displacement, yes, that probably is true.
But then you see, that's...
Let me put it like this.
it depends on combining with general relativity.
Now, often people say,
what is the major problem of physics
that we don't know about?
And they say quantum gravity, you see?
Now, I say that's the wrong way around.
Sure, that may be a big problem
and maybe some people have some answer to it,
but what good will it do you?
I tell you what happens inside a black hole,
that doesn't do you much good anyway.
way, because black holes are, you see the outside of them, you don't see what's going on
inside. If quantum gravity is playing its role right in the middle, and maybe it does,
doesn't help me very much. However, the other way around is a huge problem, well, a huge issue
to be resolved. And what I say is the gravitization of quantum mechanics. And the collapse of the
wave function is what I'm really talking about, because you see I'm saying the collapse of the
wave function is a gravitational effect. It depends on bringing ideas from generality. See, to be more
specific, the criterion that I come to here comes from the principle of equivalence, principle of
equivalence, which says that gravitational field is equivalent to an acceleration. Look, it goes back
to Galileo.
Galileo is very clear on that point.
If you drop a big rock and a little rock
from the leaning tower of Pisa,
I mean, I'm not sure you ever did that,
but the theoretical discussion,
if you got rid of the atmosphere,
sure, if you drop a feather,
it hovers away, but then that's air resistance.
He knew all about that.
So it was, sure,
if you could get rid of the air,
big rock and the feather,
as people have done,
on the moon or something.
It was showing that Galileo was right
by dropping a feather and a rock on the moon.
Quite a nice demonstration,
because you can't expect anything else.
But what it means is that locally,
you can get rid of the gravitational field.
But now you combine that with quantum mechanics,
and it's not quite so simple.
And you find that you have to monkey about
with the wave function
in a way which looks as though it's just a little technicality.
But when you think about it in a more broad context,
you see it's not just a technicality.
It tells you there's something funny going on
when you try to combine the basic principle
behind general relativity with quantum mechanics.
And it tells you, in my view,
that you have to have collapse of the wave function.
And that collapse, timescale, is the same as Diochi.
That was you, the mass displacement.
You do that calculation, which I did.
Tried to move the cup away from itself.
How much energy is that in terms of gravity alone?
And that energy gives you a lifetime.
And that lifetime is physically there.
So this cup, it would be instantaneous, it behaves classically.
Have you played around with modern LLMs, like ChatGPT or Claude?
The only thing I ever did was there was some primitive version of this, some mechanical woman.
What was her name? I can't remember. She was a robot.
Oh.
And I did talk to her, and I thought she was incredibly stupid.
Okay.
I mean, you have to keep to the subject.
I think I said behind
I think behind you there was a cat
or something which is not looking very happy or something
I don't know I remember sure
she had the foggiest idea what I was talking about
there were only just a certain number of sentences
it could respond to
and I felt very
I thought it was very stupid
because it said at one point
that this mechanical woman
somebody had come and talked to her
and the mechanical woman said
we're going to try something different now
we'll try meditating
so they sat there
not saying anything at all
neither the person
nor the robot was saying
anything at all I thought this is a big cheat
oh dear
I'm sure it's a lot better than that now
much more convincing
well the reason I ask
is that with the modern LLMs
like Gemini or Claude or chat GPT.
You can ask it to explain Gertil's Incompleteness theorem to you,
the first one, or the second one,
but let's just say the first one.
And then it will, and then you could ask it to prove it,
and it will, and you could even show it your own version of the proof
with some small, subtle error,
and it will say that's an incorrect proof,
why, because of this and that,
and it will get it correct.
So does that at all chip away at...
No, no, I don't think so.
I don't find that all that impressive.
I suppose whether you can talk.
I mean, people call it the Turing Test,
and they say it's past the Turing test.
But then that really depends on who's doing the Turing testing.
You have to have somebody who really knows what they're talking about.
Just an ordinary person talking without just talking ordinary about
what happened to the millic came to work in the morning
or something. I don't know. I don't know. I've not been involved with these things recently.
I find it scary in the sense that really because people believe it's conscious
and probably it will do things. But then there are examples that, I suppose this is a well-known
example, that Helen was telling me this example. What was it? And I have to think of the right word.
It's a word with raspberry, I think it was.
Oh, right, right, yes.
How many hours are there in raspberry?
Strawberry.
Strawberry, was it?
Strawberry.
How many hours in strawberry?
And it said two.
And then the person would say, well, let's count them out.
And you say, oh, one, there's a S-T-R, there's one, and then double R there.
How many hours in strawberry?
Two.
Didn't we say just three of them?
It's two.
That's not intelligence.
I mean, it's taking a sort of average of goodness knows what.
I mean, data, conversations, and somehow averaging it out.
I don't know.
I find it worrying because it's clearly not intelligent,
but it could be sort of persuasive enough to people
that they think it is.
I guess there are even people
who have girlfriends and boyfriends
which are simply AI systems
which is a bit worrying, I'm afraid.
I don't know, I've never had
not like this crazy
electronic woman
which I talked to before, which is
incredibly stupid.
I'm sure they're a lot better than that.
And they can probably
fool you for a while.
I mean, most conversations you speak to somebody
and they're fairly automatic.
They don't really involve the person you're speaking to being aware at all.
But you could probably fool people quite not too hard.
I don't think probably you could fool somebody as an expert
on testing these things.
What is intelligence to you?
I don't know.
All I know is that whatever it is, it does involve awareness.
So I would say that whatever intelligence is.
It's a mental state somehow.
Well, it doesn't.
Yeah, there's something going on, sure, which has to do with consciousness.
And don't ask me what it is because I don't know.
All I'm saying is that I don't think it's a consequence of the laws of physics that we currently know.
but then
the main laws that we don't know
have to do with how
the gravitization of...
See, I'd say it's the other way around.
People say quantum gravity is the big mystery.
Well, maybe it's a good mystery,
but that's not the main mystery.
The main mystery is the gravitization
of quantum mechanics.
The quantum mechanics
has a huge hole in it.
It's the collapse of the wave function.
and nuts of people hold all sorts of different views about that,
or they don't think about it.
They say, well, you shouldn't stop thinking about that.
But it doesn't make the answer there.
There's an answer.
The wave function spontaneously collapses.
And it doesn't seem to be
whether a conscious being is there or not.
That's something else.
So my argument is that it's not the conscious being
which collapses the wave function.
it's the collapse of the wave function
which creates the consciousness
but however that how it does it
is a very very subtle far off
we're not close
I don't think we're close
would that mean that black holes are conscious
no
don't see why
just because they're big
no
don't see why they're content
there's no collapse of the wave function
involved in the black hole
far as I know
I mean, maybe to make one, you're going to do a bit of that on the wig.
But the black hole is a very classical object.
It depends on general relativity.
I see no reason to regard that as being conscious now.
I could be wrong.
Do you see the black hole information paradox as a problem?
No.
I don't see it's a paradox either.
No, it's stupid.
Oh, dear.
You see, people say,
they don't like information to be destroyed, that's why.
And black holes seem to swallow information,
and so they like to think it comes back again with hawking evaporation.
I have no reasons to see why it should come back again.
I don't see why it shouldn't be destroyed.
Well, as I can see, it probably is destroyed in singularities.
that I don't
it's putting
something we believe about
classical physics onto
I don't know
I don't see why it needs to be
I don't regard it as a paradox
you see there's two strands to this
you see people say oh well it's a paradox
and you resolve the paradox by hawking evaporation
and this means that the information comes back again
when the black hole evaporates.
I don't think so.
It's completely different information which comes out.
It's not even information.
The word information, unfortunately, I think, carries too many.
It carries a certain implication that there's something,
it means something, I guess.
Right.
I mean, it doesn't mean it.
I mean, the evaporation of a black hole doesn't mean anything.
It's just temperature as far as I can make out.
Is this something that you disagreed with hawking about?
Probably, yes.
But I did disagree with him a few things, yes.
I can't remember.
I remember the last conversation I had with him,
he didn't even talk.
No, he was going to, he was very ill.
I mean, he gave a talk, actually,
he gave the first of these so-called Penrose lectures
that we have here in Oxford.
It was a good talk, actually.
I thought he was not bad at all.
And he did refer to the gravitational horizon size,
the black hole horizon increase.
which he hadn't given me any credit for previously,
but he did in this talk.
Now, that was a rather disturbing.
I can see how it came about.
You see, I had a conversation with Stephen
where I described to him
the black hole area increase,
classical phenomenon.
And I was, I said,
the night in Cambridge.
This was talk I had in some lecture room.
I described this idea to him.
And then in the morning, he phoned me up.
Well, I was still in bed, I think.
And he phoned me up.
And he said that this idea, he had a new way of looking at it.
If you could say a pair of black holes, if they collide,
then you can get an inequality on how big they are and so on from the area.
and the area
combined area
of the two holes
and the final area
gives the limit
on some inequality
and I said
oh that's a wonderful idea
I hadn't thought of that
where how do you know
where the horizon is
when they're separated
he said oh well
they've got to be close
very close to them
and I said oh yes
I see
and then he wrote about this
you see without any
giving me any credit
which did irk me
a little bit
it really should have been
a joint paper, which he did admit afterwards that idea came from me, but I hadn't thought
of using it in that way. So it was certainly that was him. Yes. But the earlier part of seeing
the area business was something I told him, which he sort of grabbed himself and then only
but in the talk he gave in Oxford, he was more generous and he did explain the idea came from
me.
He wasn't curious.
Sorry, I, no, it's really different.
It was awkward with him in many ways.
Of course, he did have terrible problem.
I mean, what do you do?
And I sometimes travel with him into a conference in Europe.
And I'd come back with him on the plane,
and I remember one occasion when somebody who was driving us to the airport
took a wrong turning, oh, dear, that was terrible.
And he finally got us to the airport almost, much too late.
And I remember racing, pushing him down one ramp and up another one,
finally get into the plane, and the door was about to close.
Finally, I think they were waiting.
They knew that we were coming, and they waited enough time for us to get there.
But that was a narrows creak.
You said it was awkward with him at the end?
Yes.
I would say so.
Well, it was difficult to talk to him.
Well, for good reason.
No, it's very hard to talk to him.
And he would tend to lay down the law a bit about what was...
I did try and talk to him about my cosmology at one point.
And I'm not sure he understood it probably.
Because he'd asked me some question about it, which...
I may be my fault. I didn't explain it very well. I don't know.
But he had a different idea, you see, the House or Hawking view, which I didn't believe at all.
And still don't believe.
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It gives the wrong...
I don't think what it is, first of all. It's something about the closing off the Big Bang
with making it.
you have to do a signature change,
so you're making it positive, definite.
And I never like signatures changes anyway.
It seemed to me they were.
The whole idea was wrong.
But the idea was if you're doing quantum gravity,
you can do that kind of stuff.
But I didn't think that's,
I couldn't trust anything that anybody did in quantum gravity.
I don't think it could explain why the Big Bang was so special.
I don't think it gave in a proper explanation.
Did you ever disagree with Wheeler on the nature of information?
I don't remember talking to him about it, but I probably did disagree with him.
I don't remember.
Yes, he did talk about information being the most important thing or something, yeah.
I never took it seriously.
See, I'm not quite sure what information is when people talk about it.
It didn't make sense for me.
It was, oh, my relation was really
was a bit peculiar in many ways.
Okay, let's hear it.
Well, it was Dennis' idea.
You see, I, Dennis said,
you must go to America.
He thought that I needed to,
I needed to understand
what was going on in quantum gravity,
I guess, and things like that.
And there was, I got a NATO fellowship
for two years,
which was to go to Princeton.
And that was it in the advice of Dennis Sharma.
So I put in for it and managed to get it, I got it.
And so I went to Princeton.
It was meant to be for two years.
I stayed about a year and a half at Princeton.
Then I went to Syracuse because a lot of good people were going to Syracuse.
And that was useful.
More useful in a way than Princeton, I think.
Princeton was a bit sort of narrow in its viewpoint I guess
well it was very Wheeler driven
Wheeler had some very definite ideas
about how to do quantum gravity and things like that
and I didn't think they were going to get you anywhere
I think I didn't think
doing quantum gravity
is going to get you anywhere
it's really
I don't think I held the sphere
at that time
but that's the other way around
how the gravity affects
quantum mechanics
but that was not
I wasn't plugging that at the time
that came much later
I think
yes I don't remember much about that
Ah
You mentioned Vigner
Yes
You mentioned that he wasn't as staunch
About his own interpretation
That people at least ascribe to him
Yes
I think that's true yes
No I was more reasonable
What did he believe then
I think he just said it didn't know
But he did think that was one possibility
It was the
collapse of the wave function
came about through, I mean, he was worrying about the problem, which I must say, a lot of people
didn't, but he had a genuine view. I mean, one possibility was that it was the conscious being
looking at the system, reducing its state. I remember having a lunch with him, which I had
discussed these things with him quite a bit. But I found him not so dogmatic about that
particular perspective, as one might have thought. I think he just thought it was a
possibility, which he quite liked, I think. You mentioned you have an Edinburgh story
about Ed Witten. Oh, yes. Yes, there was a conference in Edinburgh. In Edinburgh, as you may
know, is divided into two. It looks as though there used to be a river. It looks as though there used to be a river.
that's dried up now.
I don't know if there's a trickle in the middle or not.
But the one side was where the hotel was where we were staying.
And the other side was where the conference was.
And so you had to go along this narrow bridge to go to the other side.
And I was not very early in my bit late getting up in the morning to go to this talk.
And whenever I would get up, I would see Ed Witton waiting for me.
you wanted to talk to me.
So, okay, so we did walk
and he asked me this question,
which was worrying him.
He was worrying
that the cosmological constant
should be negative
because his
picture of string,
all that stuff,
required.
It's fine that I know
they still do, I'm not sure,
a negative cosmological constant.
And I said,
no.
the evidence is strong
this is positive
you're not going to get away
with it being negative
and he was very upset
because he wanted me
to give him the freedom
to have a negative
cosmological fountain
he wanted you to give him the freedom
I think he wanted me
to be more open-minded about it
I was just taking the evidence for it
but I don't
it's not much of a story
It's just that he was waiting, waiting, didn't mind being a little late for the lecture if he could try and persuade me to have a negative cosmological constant, which I wasn't prepared to do. I just thought the evidence was pretty strong. I mean, there's a second, there's an earlier part to that story, which is not written. The earlier part of the story was to do with an American cosmologist, an interesting fellow.
I forgot this.
Oh, I should know who are you, yes, sorry.
But he was visiting England.
And I think we were going into dinner at one of my college.
And as we were going in, it was in the early days when the redshift,
which suggested that there was a positive cosmological constant come along.
And I didn't like it, you see.
At that time, I thought it should be zero.
from some idea to do with Swissor theory
and I wanted to try and had a solution
to what I called the Googly problem
and the solution depended on it being null
infinity being null
so I had zero cosmological constant
and that was my idea
and I remember going into dinner
and I said surely this
red shift
for these dust could be dust
as some people were saying
and he said no no that doesn't work
it's not just that
it fits so well
with all sorts of things
and they've come together so well
if you have a positive
cosmological constant
so I changed my mind
I said okay
we've had to get used to the idea
I'm glad I did
because the whole idea of CCC
depends on the cosmological constant
being positive
absolutely you've got to have a space like infinity
I knew it meant
space like infinity
I mean, that's the work I'd done previously.
I knew it meant that, but I didn't want it previously.
I tend to visit him sometimes in Princeton.
So I went to visit him at one point and I had some ideas about
Twister theory I wanted to talk to him about or something I can't remember.
Him being Ed Whitten?
Ed Whitten, yes, yes.
No, I wanted to talk about him.
It was useful to talk to him.
He had interesting ideas.
And so I started to talk.
to me. He said he started to describe something,
blah, blah, blah, blah. And I
said, that looks like Twister theory.
And he said, yes, it is.
He was using twister theories to try and do
calculations in quantum gravity or something.
And so at the end of that, I said, that sounds
very interesting. Now, he
said to me, I'm thinking of writing
a very short paper and a short note
paper on this. Would you, would be prepared to look
at it? So I said, yes, sure.
I waited two months, and then this 100-page paper came.
And that 100-page paper, it was 99 pages, I think, but you know.
And I gave it to work some of my colleagues and students.
And then they went discussing this paper,
which was bringing Twister theory in connection with gravitational calculations.
And it sort of started off a whole line of thinking.
in my group.
And then we had Ed Witton
and we invited him over
and I think he
had a combined discussion
with all these ideas.
I'm not sure it was a good idea
actually the whole thing
because people had
got carried off
in a particular direction.
I mean it was probably close
to when I retired anyway
so it didn't matter too much
to what went on.
although I kept up my contact with these people.
I think I had a view that it probably was carrying people not quite in,
it was an interesting, interesting to see how the string ideas that he were having,
did relate to Trister ideas.
But on the other hand, later on, I think I thought it was not a good idea.
Why not?
And also, do you mind explaining the idea, the semblance that you recall?
I'm not sure I can remember it, though.
It was trying to bring, I think, string theory ideas into connection with Twister theory ideas.
And it was a kind of set people thinking off and along new directions, which was interesting.
Sure.
But the thing is, I'm not so convinced about string theory myself.
I think, I can't remember the details of it because I think I was not really in full.
You see, it's a time when I'd retired, I think, and so I was not really, didn't have a group of people who were doing research with me.
And they went off on their own and developed certain.
ideas. I probably shouldn't comment too much because I don't think I understand it well enough.
What about Richard Feynman? I know you've told several Feynman stories. Oh, I've got several of
them, yeah. There are about six Feynman stories, so I'm not sure. Is there one that you haven't
told much, or at all, even? I have to think there probably is one, yes. I don't know,
because I usually tell them all, don't I?
Tommy Gold's one.
You see, I first met Feynman
at a conference
which was being held in Poland,
but north of Warsaw.
And it was just at a time
when the sort of cold war
was starting to thaw a little bit.
And they had people from both sides
of the iron curtains
it then was
until there was
some Russians
there too
and Poland
already was
on the other side
of the Iron Curtain
so I remember
I had
the thing is that
my then wife
was very keen
on getting a Volkswagen
which we bought
we picked it up
in Walsberg
where they
made the cars
and we picked
it up fresh
from the
place where they make them
I think we must have left our old one with them
I can't remember the story exactly
I think that was right it was a new car
and I remember driving through
checkpoint Charlie and all that sort of thing
it was all behind the iron curtain
you see at that time
but there was a bit of a thaw
and at this conference
Feynman was there
and I actually talked to him a little bit
about some ideas I had
about doing zig-zog
sort of integrals using zigzags
for the
working out the electron field or something
and he seemed to be quite interested in what I was saying
but I don't know
how much of an impression that made
but what I do know
is that
at the end of the conference
there were
a group of people were going to a
hotel in northern Poland
were at the mountainous area apparently
and it was a question of
enjoying the mountain
scenery and going
to this hotel.
But this involved a bus
trip to the hotel
and you had to get a
complete ticket with the bus
and the hotel and then the bus coming back
and since I had a car
I didn't want the bus
so I wanted to go to the hotel
and so we tried to find out
where the hotel was, and the people refused.
They wouldn't tell us.
No, we don't tell you.
And I complained to Feynman about this.
They're not going to tell us about it.
So he said, I'll find out for you.
So anyway, so the day came, we were just about to drive off somewhere.
I didn't quite know where at this point.
Feynman came up to us and handed a little piece of paper.
Open a little piece of a name of a hotel.
I don't know how he'd found out.
Because they were absolutely adamant not to tell us.
And the reason they weren't telling it, it wasn't anything to do with the iron curtain and all that.
Well, it was in the sense.
But the reason was they were charging everybody twice as much as the official price.
Ah.
And so we got the ordinary price when we went up there.
But people who paid for the tour, they paid twice as much.
And that was the reason.
And then we drove back and I think we did.
to come back through the hard curtain or whatever it was called.
But that was the first encountering with Feynman,
which wasn't much of a story, really.
I think the main,
there was a beautiful set of photographs
people took of this conference, people.
And one of the most magnificent of these is Feynman.
Picture of Feynman and Dirac.
and those Feynman sort of with his hands like this somehow
trying to explain something
and this direct sort of leaning back
rather than sort of reserved
yes and it's a wonderful picture
yes it captures their personalities
absolutely yes that's right
yeah
have you ever met Schrodinger
I very much regretted
never met in meeting Schrodinger
because I used to go quite frequently
to the place where Shrewd
went in Ireland.
You see, he had an appointment in Ireland
at the Institute for Advanced Studies.
And I quite frequently went there,
but unfortunately after Schrodinger left.
The closest I got to Schrodinger
was his daughter.
One of his daughters, I think,
had a conversation with her, and I met her.
And I had two copies of Schrodinger's book
what is life or something.
And so she had two copies, and so was she constrained copies,
my copy with his signature on this or something.
I can't remember.
No, I never actually met Schrodinger.
The one with my signature and hers,
I had Schrodinger's daughter's signature.
So I met his daughter.
But that was a regret of mine,
because I sort of could have met Tronier.
I would like to have met him very much.
because I thought he was a fascinating character.
And he wrote, I mean, I was a great fan of his writings.
Because Schroding was somebody who wrote popular books, or semi-popular, you might say.
Yes.
And very good ones.
And I think I had all his books.
Did that inspire you to write your own books?
I think it did.
Probably, yes.
I think it was an influence, yes.
Sort of think if Schroding can do it, well, maybe I can.
I don't know.
Tell me about the writing of Emperor's New Mind.
Did you already have those ideas worked out prior to you starting the book?
Well, I knew why I wanted to write it,
but what I didn't know was how the brain could be making use of what I think it needed, you see.
and so I learned a bit about neurophysiology
and there is a whole section in the book about neurophysiology
and I thought a fascinating subject
but I learned about the Hodgkin-Huxley nerve transmission
and I said there's no hope
you can't preserve coherence that way
doesn't answer my problems
so when I got to the end of my book
I hoped that I would have an answer to see
where in the brain there could be something which could
employ the collapse of the wave function
and I didn't
I was left a blank to me
I couldn't see anywhere
so I ended up with something very
weak that I didn't bleed in really
something about crystals
which is in the book which
my excuse for
leading it off but it was not
no no it kind of petered out at the end
although there was a
description of the experiments
due to Benjamin Libbet
which I thought fascinating.
I suppose, I think they're not legal to do now
because they should be repeated.
There were experiments which had to do
with the timing of conscious experience.
The readiness potential and free will
telling someone to decide when to make a movement?
I think there are two different things, you see.
This was, yes, that may have been part of it.
It wasn't so much that, it was the sensory aspect.
you see there was a patient who had an operation on the brain for some other reason
and permission was given for the for limit i guess to perform experiments on this person
which probably would not be legal he's not so people tell me which is a shame because of
fascinating experiments i do describe them in in roughly in my book the empty mind at the end
and the thing is that there's an electrode which touches the finger and the sensation of that
and then there's another electrode in that part of the brain which has to do with the sensation
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It's all to do with the timing, and there's a clock.
which is a fast-moving clock,
and the patient has to try and say
when he or she feels this.
And if you touch the finger,
then it's almost instantaneous, apparently.
If you touch the part of the brain
to do with the sensory that,
it takes a little while
in the sense of half a second.
That took quite a long time.
Before that part gets,
maybe it was a quarter of a second.
I can't, you know, half, I think it was half a second.
Not quite a long time in a sense.
And then there are things about if you touch the finger first
and then the brain, then the brain since it says, yes,
the finger one seems to be instantaneous.
The one on the brain takes half a second before it's felt.
Before the patient registers feeling it, which is curious,
already curious.
But if you touch the finger
and then a quarter of a second later
do the brain stimulation,
then the brain stimulation is felt,
but the finger stimulation is unfelt.
How can you unfeel something
which you should already have felt?
So there's something strange
about the temporal
exactly when things are felt and so on.
And this ties in with other things too.
Yes.
which it seems for example
if you're playing a sport or something
which I used to play ping pong a lot
not to a huge skill but I played it
and the
I would
see I think even now the current view is
that the conscious
it takes a while for consciousness
maybe half a second
Now, I think that's ridiculous
because if I wanted to decide whether to hit the ball
that way or that way, I see where I think the opponent is
and maybe it do it that way, you see.
That's much less than half a second.
Then they say, oh, no, it's all unconscious.
No, I was deciding to do this.
Right.
He said, no, it can't be.
It must be, it's an illusion.
You're not really conscious doing it.
So that's, I don't know if it's the current view now or not,
but it had been.
The current view is, no, no.
All these things you think you're doing consciously are really unconscious.
I thought that's ridiculous.
I mean, if you're a piano playing, you see,
and they might touch a note.
I mean, a piece may be very, you know, lots and lots and lots of notes
going within a half a second and to decide whether to hit this note
maybe you're slightly more delicately than before.
That's a conscious decision.
No, not doesn't, you can't have time to do that.
It must be unconscious.
But you see, it's probably...
The timing of these things is not a straightforward issue.
When you think something, I don't know.
But you see, if it's to do...
I can't make any definite statement.
All I think is that there's some monkey business going on.
Okay.
When I say monkey business, it's some subtlety,
which you can't explain using classical physics.
Somehow I knew you were going to say monkey business.
I think.
It's either that or poppycock.
Poppycock.
I didn't think that one applied in this case.
Yes, it's, it's, when monkey business tends to me there's something going on there.
It's not just random.
I just spoke to a neuroscientist name,
Aaron Sugar, who's reinterpreted the livid experiments. And he said that we've been making a
mistake, seeing that there's this potential that comes on approximately half a second to one second
prior to us deciding to make some action. You can't go from that to infer that, okay, the decision
must have been unconscious, therefore we didn't actually decide it, because he was saying, well,
there's a correlation, but the correlation doesn't imply causation. And then in his model, he gives
an analogy. He says, if I put on some measuring devices on you that measure your health across the
season, they will show a small dip prior to you getting the flu. Does that mean that small dip
caused you to get the flu? Well, some other people get a lower dip as well, but then don't get the
flu. So there's this line of reasoning that he goes through and says that he can get this
reaction time for consciousness down to actual reaction time, which is 50 milliseconds or so,
which is much more in alignment to you
consciously deciding to swing the ping pong ball
rather than what people told you before,
which is, no, you think you decided it,
but you just unconsciously decided it,
and then some post-hawk rationalization told you,
I decided it.
His view is slightly complicated.
Well, I'd be interested to see what it is.
Yeah.
See, my view is it's probably not explicable by classical physics.
that there is something
you see there is something retro
causal nothing to do
with this at all
so I usually don't bring this
sort of thing into my arguments at all
it's not necessary
too speculative
it's bringing in consciousness
which I prefer not to
hear this here
you see I think that's a whole story
which
I've dabbled in
that's true
but it's not something
which I could probably
seriously contribute to
because it requires
understanding too much biology
and things like that
which I
Zach
I sometimes say
you know
the
sorry I shouldn't be confusing
all my stories
originally I was supposed to be a doctor
both my parents were medical
and they had decided
that I was the one who was going
that was before my sister grew up
actually did become a doctor and married one
so they got two for the price of one
but they were very disappointed
when I went and did mathematics instead
but that's all sort of
irrelevant to the story
except that
it's just as well I didn't do that
because I would never have understood
I would never remember the different
medications that people were supposed to have
I've got them confused because I wouldn't remember the different names.
That's all I'm trying to say.
Because when it comes to things like biology, it's really not my area.
Because it involves different kinds of chemical compounds and what on earth they're doing
and which kinds is which and what name is attached to which one.
And no, I can't do that kind of thing.
So I don't want to.
all I'm trying to say is the consciousness issue
if you're really going to get into what
involved in say human consciousness
there's a lot of biology involved in that
and there has to be
because that's what we're all,
we are biological systems
so it's not going to
it's not my area
I'm not my area
I was speaking to Dr. Michael Levin
who's a biologist
a developmental biologist
Oh, yeah.
He wanted to know, well, what he's doing is extending platonic space
to include biological systems and minds as well.
He had a question for you.
He wanted to know if you thought platonic space has its own dynamics,
or if it's just eternal and static.
So that was one question.
No, I can do that one.
It's eternal and static.
I mean, there's no temporal.
time doesn't come into it.
It's just mathematics.
And mathematical truth
isn't temporal thing.
It's true.
I mean, it doesn't involve time.
Nothing to do with it.
I mean, you can talk about physics,
and of course that involves time.
His second question was,
do you think this platonic space
includes more than just mathematics?
Well, I'm using
it depends what you mean by platonic space I suppose
I'm not sure I understand the question
you see the Platonism I refer to
in the sense of mathematics
having its existence
independent of us
independent of mathematicians
it's
to do mathematics is a bit more like
archaeology than you might think.
There's the platonic world out there
and you're digging your way at it and you
find some beautiful result
which is sitting there waiting to be
discovered or doesn't care whether you discover it
or not. That's not its concern.
So the mathematical world
is there.
It's not created by us trying to do
mathematics.
That's the only sense.
But when you say giving something else
of proletonic existence, that sort of
and we don't know quite what that means.
means. What was the thing?
Okay, let me read the question for the audience as well.
You've said you're a platonist about mathematics.
Does the mathematical realm exist independently of physical reality?
Is the Mandelbrot set out there, even if the universe didn't exist?
And do the contents of platonic space have dynamics of their own?
You've answered that already.
What's the best way to think about the interaction between platonic objects,
which presumably don't have time,
and physical objects, or processes, which operate in time.
Well, I've usually, I have this sort of triangular picture,
which I like to draw as an impossible object.
And these are what I call the three worlds and the three mysteries.
I mean, I used to talk about this, I haven't done it much recently.
And the worlds are the platonic mathematical world
and the physical world and the mental world.
world. Yes, and then they see, but then the connections are the three mysteries. So I'm calling them
mysteries, you see. One of the mysteries is the physical world and how that depends on mathematics,
which seems to be a very close connection. But not every thing in the mathematics. The way I draw it
is only a little bit of the mathematical world seems to be governing. See, there is a
sort of view that people have, oh, this is such a beautiful piece of mathematics. It must have
relevance to the physical world. Not at all. There's no reason why it should. There's a lot of
very beautiful mathematics going on, which as far as we can see has no connection with physics
at all. Of course, it might have some distant physical theory that comes about, but I don't
see any reason why it should have. This comes out particularly with things when they talk about
higher dimensional theories, you see, like in string theory and all that. They like
they like to use these different dimensions of space and so on.
I don't see any reason for that at all
just because you've got a mathematical theory
which can exist in higher dimensions,
no reason why physics should follow it.
And then you see, again, there's a next mystery
which is that only part of the physical world
seems to have consciousness.
So that's a mystery too.
and then I say, well, most of conscious activity
is not thinking about mathematics.
Even you're the mathematician.
You like to have your lunch, too, and you like to have your cappuccino.
Exactly.
So it's not just mathematics,
and I don't know how much most mathematicians think about mathematics,
but certainly it's not all the time with me,
only a small amount of the time,
especially when I get older.
I can't, you know, it's hard enough for me to think about it.
I know you called yourself a physicalist, which is a monist,
which means there's only one kind of substance and it's just a physical substance.
The way that I read your work is at least a dualist.
It could be a trialist because of this.
So there's the physical realm, the mental realm, and then the platonic realm.
And it's not clear to me that the platonic realm is dependent on the physical or vice versa.
It seems like they're distinct.
So at least there would be a dualism.
It seems like we can make this triality, this triangle into a rectangle,
because the physical itself splits into quantum and classical.
Okay.
I'm not sure you see how distinct they are.
It's a useful...
Yeah.
Okay.
When you said quantum mechanics,
You see, I'm not saying that's a separate world, because it's all the same world.
But these are notions of reality, which I find useful to think.
I'm not sure whether I tie that in with the philosophy so much.
I think it's both physics.
They're both physics, you see.
The quantum reality and the classical reality.
Whether they are even separate, or whether there's the only, maybe you have some continuum,
read between the two and so on.
It's just a useful way of...
Of thinking about quantum theories,
relationship to classical mechanics,
or the measurement problem.
It's more thinking about.
I'm saying it's probably a temporary position to hold.
Probably.
See, I worry about that a bit.
I mean, just say quantum reality and classical.
Maybe there's a whole different,
maybe a continuum of possibility.
I'm not wanting to, I'm not trying to be dogmatic about that.
I just think it's a useful way to think about certain things.
See, particularly, one thing I wish I'd put in,
you see, the article which I discuss these ideas most completely
is in a book, edited by Shan Gao on consciousness and quantum mechanics.
or something. It's just a collection of articles, and I have an article in that book. I think it's
Oxford University Press. And I have an article in that book where I describe this quantum
reality and classical reality. But one thing I rather regret it is not putting in something
which I could have done
because I have a nice picture of it
which is with E.P.R.
Einstein Podolsky-R.
you know what I mean by that?
So you see Alice and Bob
are presented,
there's a spin-zero particle
and it splits into two spin- halves.
Alice and Bob each have a sealed box
where they're not allowed to see this
and they go a long way off
from light years away maybe.
At a certain point, Alice opens her box
and okay it's a spin half particle
so she has to choose a direction
and say okay are you spinning this way
yes or no
and it says
nope you got me wrong
it's the other way
so it fixes her spin as the opposite
now bobs must therefore be the opposite
of Alice's but when
well you see people worry about this
and John Bell used to argue about these things
all that that my view
to make it relatively significantly invariant
you have to go along the past light cone.
So you go along the past light cone backwards in time
to earlier time, if you like,
and that his particle is now flipped
to be the opposite of what Alice measures.
Now that's sort of retrocausal.
Now, isn't that going to land you an all sorts of paradoxes?
No, because it's quantum reality.
If Bob could say hello particle,
which way are you spinning, yeah, you'd be in trouble.
But all Bob can do is to decide on his direction
and then say, hello, particle,
do you happen to be spinning this way or the other way?
Says, you got me right this time.
It doesn't tell him that to spin,
he can't, the very fact
that it's quantum reality
means he can't ascertain what the spin state is.
He can only confirm it.
if he has reason to believe that it might be so-and-so
you can test whether that's right or not
this is the Einstein criterion
but the Einstein criterion is only quantum reality
it doesn't tell you you can't ask the system
hello system what's your state
it looks blankly at you and say I don't ask
questions like that suggest the direction
and you need that point of view to make sense of it
and I like to put the whole picture, you see, of Alice and Bob
in the different regions where the state is so-and-so,
and it's so consistent over the whole picture.
I find that quite surprising,
that the actual quantum reality of all over the whole picture
is completely consistent.
I'm slightly regretting not having put this picture into my article,
but maybe that'll be a new article.
I think I should, you see,
I'm supposed to write up my Basil Highley lecture.
And, oh, I was just reminded.
Somebody said, oh, when are you going to produce your article which on this?
And I said, well, oh, I'm supposed to do that?
And he said, well, Olivia, give you a little bit more time, thanks.
So I have to write this article.
And maybe I can put this in, you see.
I think I mentioned it in the actual lecture,
showing Alice and Bob and all that stuff.
And you can have a nice picture showing where the quantum.
reality is all over the whole picture, and it's completely consistent. But it has a
funny kind of causality relationship. It's not the ordinary way of propagating within the
light cone. It's sort of without the past light cone, which is very strange.
Now, I'd like to end on how you view the state of current theoretical physics, fundamental physics.
when I ask this to people
they tend to split into two camps
one that says there are some
problems and then they split into some
camps as to what the cause of that
problem is. Maybe they'll say
well the cause is that
experiments are just too expensive to run
to probe even deeper than
we need. The problem is that
quantum mechanics is too successful and it would
be great if there was something that was
disagreeing with the standard
model. It's not funny how people see how
successful. Well you see there all
times of experiments where you don't
perturb them.
It's way below the
Deoshi level, you see.
So these experiments
and it works extraordinarily well.
Sure it does. But you don't
move much mass.
There's a
huge story there.
If you're asking me, am I one of these people
who are nearly there, just as funny
details, are not one of those
people. And one of the people
that said, no, there's a big theory
behind him behind that, that we just don't know at all.
If that's what you want to know.
I want to know if you've noticed a difference
over the past few decades as to how
fundamental physics is researched.
So, for instance, as I was mentioning,
there are two camps, one that thinks it's gone awry
for some reason and one that thinks, no, it's broadly on track
and it's operating as usual.
We're just dealing with extremely difficult problems.
What do you see?
I mean, it's probably the same.
It's the quantum this year, if you like.
Because it works so well when you don't move much mass around,
people get sort of convinced that it's the full answer.
And I don't think that's right at all.
No, there's a huge thing missing.
Is that why in our first conversation,
you mentioned quantum mechanics is wrong,
or quantum theory is wrong,
and then, of course, the objection.
is, well, it's extremely accurate.
You could say it's incomplete.
That's not the same as it being wrong.
So is that what you mean that, look, sure, quantum mechanics is extremely correct.
I like to be ruder about it, you see.
See, Schrodinger and Einstein were much more polite.
They said, well, quantum mechanics is incomplete.
Okay, you can say that.
I like to be more brutal and say it's actually wrong.
But, I mean, that's fine.
We're not really disagreeing.
It's just terminology.
I'm saying that it's a big thing that's missing.
Incomplete, swather suggests, oh, there's a little detail.
Oh, change the sign here.
Oh, that's it.
I don't mean that.
I mean that the broad framework needs overhauling.
And in the limit of not much mass displacement, it's quantum mechanics.
Sure.
If you have mass displacements, it goes wrong very rapidly.
You know, so people say, what about the plank scale, you see?
Well, what is the plank mass?
The plank mass is a flea's eye, more or less.
Yes.
If you put a fleas eye in two places at once,
maybe with a flea is looking that way, that way at the same time,
does it collapse the wave function?
Yes, because a flea's eye is a plank mass,
and it collapses in the plank time.
What is the plank time?
10 to the minus 30 seconds or something.
Ridiculously small time.
So it would be flees-eye as classical
because the collapse time is so tiny.
In experiments, sure, I'm not an expert on experiments,
but the experiments which have been done,
which convince,
show you quantum mechanics
is right, there's no, practically no mass displacement involves in these experiments.
Of course you get the right out. I mean, I'm going to, of course. It's amazing. I'm not saying
course, really. Quantum mechanics isn't an amazing revolution. There's no question about that.
I do agree with that. But if you're considering displacing masses, it gives you the wrong
answer. A tiny fraction of a second.
It's saying that because certain things work so well,
tells you the theory is right.
No, it doesn't.
Because all these experiments are in a regime
where you hardly move a mass around at all.
Is there any piece of advice that you consistently give your students?
No, because I don't have any students.
Or you students?
Anyway, I only taught mathematics, you see.
You see, I was always in mathematics departments.
I taught mathematics.
I occasionally taught, I did teach quantum mechanics, that's true.
And I would waste a lot of time.
I'd realize what a fool I was.
The whole first two lectures I wasted
because I was all on this stuffed philosophy of it
and why wave function collapses or something
and I shouldn't have been wasting my time on that
because I had a race at a great speed
to try and catch up with a syllabus.
If you want to teach the course,
you have to teach what's in the course.
Not trying to explain whether things.
But then people obviously worry about it.
And there is this feeling somehow
that big systems,
because it's too much trouble
to make the quantum state of a big system.
Or else you're like the philosophy,
The philosophers used to be in Oxford.
I don't think they're like that now,
where you go into the many worlds picture.
So all these different alternatives coexist somehow.
And the reality of the situation is a huge mass
of all the different things that might happen.
And somehow a conscious being threads its way through this
and huge entangled mass of things.
So that's one resolution, if you call it a resolution.
which used to be keen on the philosophers and others.
I'm not sure whether it's true anymore
because the person, there's a funny story there.
David Wallace, I think that's his name, yes.
But he's gone to Princeton.
I remember going to a very small conference about six people
and we used to discussing these issues.
And David Wallace is one of the people.
And then the thing will finish.
And I thought, well, I'm glad this is all.
over and then I just go home and David Wallace said we're all right if I'd walk with you
said yeah that's all right so I'd chat with it for a while I think I hope we'll get to a corner
where he goes to us off and we go a different way and I can relax a bit no no he turns the same way
he's sweet no this way no he turns the same way this way oh well we're going to the same
flat complex comes in the same doors me go up same floor he's just down the corridor
He doesn't live there anymore now
because he's gone to Pritzburg
It was funny
The chances against that
Must be quite large
Have you ever spoken to Douglas Hofstetter
About your theory of consciousness
And girdles?
Okay, I'll tell you my Hofstetter story
I was going to have lunch with him
Which I did
But before lunch
There was an occasion
where we could discuss things with him.
And I read his book, and I knew his point of view,
and I thought he'd come to the wrong conclusion,
and I had decided I was going to paint him into a corner.
You see, so I started painting him into this corner,
and the corner I was going to paint him into
is that certain integers are conscious.
Right.
And I had only got, you know,
He hardly got into the corner.
He simply leapt into the corner.
What, you mean to the sound?
And is it a conscious?
Yeah.
That was my Hofstetter.
Sorry.
I think we had quite a nice lunch afterwards, but I just find it so extraordinary.
I mean, quite consistent, because that was the view that he was driving for.
But it seemed to me an absurdity.
But he didn't think it was an absurdity.
He just thought, well, yes, something to just happen to be conscious, that's all.
Okay.
Well, you can think that as you like.
Professor, I've had such a great time speaking with you.
Okay.
Thank you for spending two hours with me.
Oh, goodness.
I hope I'm not wasting the time.
Yvette should have been here.
Yes, Yvette just came through the door,
and just for the people who are wondering what this is about.
Yvette Fuentes is now coming
and we're going to do another podcast
jointly on
Yvette. She's by herself first, is that right?
No, she's going to be with you, but we're going to take a break.
So there's three podcasts.
There's this one with Roger's solo.
There's one with Yvette and Roger.
And then there's one with Yvette solo.
That's what I was expecting, yes.
Oh, she's doing an experiment,
which is testing this idea about the state reduction,
which is a very important experiment for some of concern.
We're going to talk all about quantum gravity and collapse models with Yvette in a few minutes.
Okay, thank you.
No, it's always been great fun.
Thank you.
Yes.
I hope you enjoyed that interview with Sir Roger Penrose.
There's another interview with, said Sir Roger Penrose coming up in a couple weeks.
In that interview, we discussed a sensitive experiment.
It's in the pre-publishing phases currently, that experiment, or at least the results of it.
And so once it's officially published, then I have the go ahead to launch it.
subscribe for that. Now, it takes a huge amount of time to prepare for interviews like this. I study
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