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Revision as of 04:00, 14 March 2020

Description

Roger Penrose is arguably the most important living descendant of Albert Einstein’s school of geometric physics. In this episode of The Portal, we avoid the usual questions put to Roger about quantum foundations and quantum consciousness. Instead we go back to ask about the current status of his thinking on what would have been called “Unified Field Theory” before it fell out of fashion a couple of generations ago. In particular, Roger is the dean of one of the only rival schools of thought to have survived the “String Theory wars” of the 1980s-2000s. We discuss his view of this Twistor Theory and its prospects for unification. Instead of spoon feeding the audience, however, the material is presented as it might occur between colleagues in neighboring fields so that the Portal audience might glimpse something closer to scientific communication rather than made for TV performance pedagogy. We hope you enjoy our conversation with Prof. Penrose.

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Participants

Housekeeping

WEIN - Hello, this is Eric. 2 pieces of housekeeping:

  1. On Bret and Heather (we will resume that thread when they return from the jungle)
  2. On today’s guest. Eric mentions;

1:00 = Roger is famous for being one of the greatest Geometric Physicists now living and perhaps the best descendent of Albert Einstein currently still working in Theoretical Physics in this particular line of thought. Also, he is an example of what the UK does well.

(Don’t Panic!)

1:30 = …if you start to feel as though you are being left behind by one line of thinking, what we do in general is wait to see if a different line of thinking opens up… …this is normal.

2:30 = welcome Roger

3:00 = WEIN - “I know you as one of the most important people at the nexus of Geometry and Physics”

Lyrics from the Leonard Cohen song, “The Future” (“You don’t know me from the wind, you never will, you never did, but I’m the little jew who wrote the bible”)

Book: The Road to Reality, by Roger Penrose (this appears to be easily accessible online as a pdf)

4:00 = WEIN - “Where are we in the history of coming to understand what this place is in which we find ourselves? What we are made of? And what we know about our own context?”

PEN - “I now feel I should re-write part of it (the Road to Reality) because since I wrote it things have changed in one important way” *

<<<Did he say what the one way it had changed was?

PEN - “A lot has not changed - the thing that has changed… …is to do with Cosmology.”

PEN - I have a proposal… which is new since I wrote that book

[NOTE: I’m not sure if he ever gets back to saying what this proposal is. It looks like it might be “Conformal Cyclic Cosmology”, see eg; Physics World, ibid, his own book, Cycles of Time]

6:00 =

Penrose brief biography.

Penrose;

PEN - “I’d encountered a friend of my brothers, Dennis Sciama.” * (see also the note below)

<<<This name took some finding

Sciama gave lectures on Cosmology and talked about steady state theories in which the Universe expands but doesn’t change because it’s continually ‘replenished’ by the creation of new matter.

Penrose’s older brother, Oliver Penrose who was studying Statistical Mechanics was the precocious one (of the two brothers).

Penrose had also been listening to talks byFred Hoyle who suggested that when the matter in the accelerating expansion reaches the speed of light it disappears.

Penrose didn’t think that was quite right and started drawing pictures with Light Cones and thought they would gradually fade, but not disappear.

8:00 = Talking to his brother in the Kingswood Restaurant, Cambridge *, Roger expressed his doubts and was referred to Dennis.

[NOTE: I tried to find a link for this restaurant, which appears to no longer exist, and came across this really interesting paper by Professor Penrose and George Ellis, which is a kind of “scientific eulogy”* for Dennis Sciama, in which the same anecdote is recalled, amongst others: https://royalsocietypublishing.org/doi/pdf/10.1098/rsbm.2009.0023 (pdf) ]

<<<There’s probably a better term for this, right?

<<<When I search for ‘“the kingswood restaurant” cambridge’ I don’t turn up anything that seems relevant and when I add the word “remember” to that search I start to turn up links to Sir Roger himself.Possibly it was called by a different name. Also possible that no trace of it has made it onto the internet other than his telling.

Dennis Sciama was impressed! Later, when Roger came up, he took him under his wing.

Penrose’s supervisor was Hodge - W.V.D Hodge

But later he threw Roger out and Todd became his supervisor - J.A Todd *

<<<The links I’ve added to Hodge and Todd both seem right but I’m not personally familiar

Ad Break

9:00 = advert for a watches. Masculinity, something, something….

10:00 = advert for lamps. Mention of the Matrimandir (looks nice, might buy a lamp)

Dennis Sciama

File:Image 2.png
image alt text

(Dennis Sciama)

11:00 = Dennis wanted Roger to be a Cosmologist

Dennis had a knack of making sure people met each other. In one case it was Stephen Hawking

Dennis was the last (at the time the only) graduate student of Paul Dirac.

Book: The Strangest Man: The Hidden Life of Paul Dirac, Mystic of the Atom by Graham Farmelo

PEN - Dirac was hard to get to know.

WEIN - Dirac would be neck and neck with Einstein for greatest 20th Century Physicist.

Eric imputes that Dirac’s hair was not as good as Einstein’s.

PEN - Dirac was the one who put QM in order

Taste and Beauty

File:Image 3.gif
image alt text

The Hopf Fibration (source,gif)

WEIN - “you have wielded taste and beauty as a weapon your entire life, your drawings are among the most compelling”

13:00 = “Our friend Joe Rogan” *

File:Image 4.png
image alt text

Joe Rogan * is a prominent Podcaster and Cage-fighting Commentator

<<<Roger Penrose and Eric Weinstein are friends with the guy who does the commentary for the cage fighting. It’s quite a time to be alive.

<<<If you have ever been on Joe Rogan’s Podcast and now have your own podcast, you are contractually obliged to mention his name at least every 2.5 episodes

WEIN - The hopf fibration is the only non-trivial principal bundle that can be visually seen

WEIN - since the world seems to be about principal bundles, it’s a bit odd that the general public doesn’t know that stuff of which we are.

PEN - The “Hopf fibration”, or the “Clifford Parallels” was instrumental in the subject of Twistor Theory.

14:00 = Penrose’s diagram

There were three versions. The third version is in The Road to Reality. He thinks the second version is probably the best.

(I think they are talking about the diagram of the Hopf Fibration ?? as seen at the link above )

I think this is the one from “The Road to Reality”, which would make it Version 3: * **

please correct this if you know betterimage alt text

There’s also this diagram, which I found at a blog here: http://arkadiusz-jadczyk.eu/blog/tag/penrose/

File:Image 6.png
image alt text

And there’s this diagram, which I found at this link ( http://users.ox.ac.uk/~tweb/00001/ ) which is an HTML presentation of “On the Origins of Twistor Theory” - Roger Penrose, 1987

File:Image 7.png
image alt text

[NOTE: these latter two might be Versions 1 and 2? Or later reproductions.]

Penrose thinks Version 2 was the best.

WEIN - Dirac famously brought in these bizarre objects called Spinors, which are a prerequisite to getting to Twistors.

Dirac’s Spinors

File:Image 8.png
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Paul Dirac

15:00 = Dirac gave a course (2 courses) of lectures on Quantum Mechanics

Course 1 - Basic Quantum Mechanics

Course 2 - Quantum Field Theory but also Spinors

In the second course (when Penrose took the course) Dirac deviated from his normal course of lectures to give two or three lectures on Two Component Spinors. (Spinors)

WEIN - For the lay audience… If we think of all of matter as waves, the question is "what medium are they waves in? And the medium would be a medium of Spinors, which is not something that’s easy for people to understand.

Denis recommended to Roger a book by Corson (presumably this one: Introduction to Tensors, Spinors, and Relativistic Wave-Equations, 1953 by E.M. Corson *

The book was reviewed by Abdus Salam in 1955 (https://www.nature.com/articles/175831b0 )

<<<Dr Corson doesn’t seem to have a Wikipedia page which is a shame, considering some of the people who do

Roger found the book incomprehensible.

But then he took Dirac’s (2nd) course.

Dirac talked about Two Component Spinors and this was exactly what Roger needed.

Other people said that Dirac’s course was just like his book but Roger hadn’t read the book.

(I assume this one? Dirac - Principles of Quantum Mechanics)

18:00 = WEIN - "do you think Dirac understood (Spinors)?…

Mention of Mathematicians:

WEIN - let me throw out a dangerous idea. I don’t think any of us understand them (Spinors) .

WEIN - Dirac understood what could be said about Spinors

20:00 = PEN - "usually one talks about the Dirac Spinors, which are the 4 spinors, but they split into these 2 and 2 (WEIN - in even dimensions) Yes, that’s right.

File:Image 9.png
image alt text

Sir Roger Penrose’s favourite film is 2001: A Space Odyssey

Geometric Interpretation of Spinors

Roger describes the way he thinks of spinors geometrically.

“I had this picture of a flag. You have the flag-pole, goes along the light-cone (WEIN - that’s the vector-like piece of it) and then you have an extra piece of data which is this flag plane. You get a pretty good geometrical understanding. The one little catch is that if you rotate it through 360 degrees, so you might think just to where it started, it’s not the same as before, it’s changed its sign.”

File:Image 10.png
image alt text

Taken from Introduction to Spinors - Andrew M Steane 2013 (pdf)

WEIN: Klein Bottle:

Interlude: Klein Bottles

Get your Klein Bottle today from our friends at Acme Klein Bottles

Here’s a good video about Klein Bottles

(the presenter is Clifford Stoll, Astronomer and proprietor of Acme Klein Bottles )

Here is another, related video, also from Numberphile, about the Topology of a Twisted Torus

<<<NB: This is a link to the actual pattern so that you can make your very own Origami Klein bottle.

This video is about slicing up toroids. The presenter is Carlo H. Séquin. Later in the podcast, Roger talks about the Clifford Parallels dividing up space in a similar way. This helped me to visualise that.

<<<One of his sculptures is not far from where I live. May have to make a visit.

It also introduced me to Keizo Ushio who makes amazing toroidal sculptures, like this one *

File:Image 11.png
image alt text

(source)

Here is an interview with Keizo Ushio.

In this video he can be heard speaking in English.

And here is a limerick about Klein bottles.

A mathematician named Klein

Thought the Moebius band was divine

Said he: "If you glue

The edges of two

You’ll get a weird bottle like mine."

(source) *

There are some more interesting (if somewhat amateur) visualisations in this Youtube video, from which I learned:

<<<Also relevant:

A mathematician confided

That the Moebius band is one-sided

And you’ll get quite a laugh

If you cut one in half

’Cause it stays in one piece when divided.

The Square Root of the Klein Bottle (Weyl’s Cones)

21:00 = WEIN - The Klein bottle has (in certain sense that can be made precise) a square-root that is a torus.

[Note: googling for “the square root of the Klein Bottle” didn’t get me far but searching for “double cover” I got useful things like this question on math Stackexchange, where someone has drawn this:

File:Image 12.png
image alt text

And the top respondent says “Most topologists would be happy just drawing the diagram you’ve drawn” (to prove that there is a two-sheeted covering of the Klein bottle by the Torus)

Reading that answer and then this one: https://math.stackexchange.com/questions/140439/torus-as-double-cover-of-the-klein-bottle gave me a pretty good idea of what’s going on.]

WEIN - It’s really the square-root of the rotations that has this double effect (but we say it linguistically in a way that makes it impossible for anyone to understand)

PEN - I understood that a spinor was the square root of a vector and I couldn’t make head of tail of it. When I went to Dirac’s course it did make sense.

Dirac gave a demonstration due to Hermann Weyl of rolling one cone on another

Here is a google-books link to Penrose describing the same model in the Hermann Weyl Centenary Lectures.

This site also has a description of the model (http://www.weylmann.com/2010archive.shtml - you need to search for the word “cone” to find the right article) and lots of other information about Weyl himself. It includes this diagram to illustrate the model:

File:Image 13.png
image alt text

The author of the site is William O. Straub and he has written other papers about Spinors, including eg; Weyl Spinors and Dirac’s Electron Equation.

This video on Youtube is a visualisation of rolling one coin around another.

22:00 =

PEN - You imagine increasing the semi-angle of the cone until it becomes almost flat. And then what’s the other one? It’s just a little wobble.

This demonstrates

WEIN - with a pulley system

In the place where you can see this most easily, it’s slightly confusing.

23:50 = WEIN - “we have to use the visual cortex we’re handed and then we have to trick it into imagining worlds beyond where we’ve seen.”

Ad Break

24:00 = advert for supplements.

25:00 = advert for online courses

26:00 =

Dirac’s Scissors

Dirac’s scissors, aka the Plate Trick, (related to?) the Belt Trick

Air on a Dirac String: https://www.youtube.com/watch?v=CYBqIRM8GiY

Fermions have a spin which is half an odd number. They have this curious property that rotate them and they get back to minus themselves. And it’s crucial for matter.

Without this, we wouldn’t have anything.

Bosons are the opposite. They’d rather like to be in the same state. For the Fermions it’s completely the opposite.

The Spin Statistics Theorem - "if things have a spin of a

When we want to treat these objects quantum mechanically, we have two

PEN - well, you’ve got these two types of matter.

Fermions

Bosons

34:00 = Phlogiston

[NOTE: Phlogiston was the supposed substance that inhered in bodies capable of combustion

Apropos of nothing much, I have always loved this quote about writing:

“The real writer is one who really writes. Talent is an invention like phlogiston after the fact of fire. Work is its own cure. You have to like it better than being loved.”

]

Maxwell’s Equations

35: 00 = “Maxwell’s Equations completely changed our way of looking at the world”

Faraday had a lot of the influential ideas.

Faraday had clues that there were connections to light, but he didn’t have the equations.

File:Image 14.png
image alt text

Charles Darwin

Book: Darwin - ON THE VARIOUS CONTRIVANCES BY WHICH BRITISH AND FOREIGN ORCHIDS ARE FERTILISED BY INSECTS, AND ON THE GOOD EFFECTS OF INTERCROSSING. BY CHARLES DARWIN, M.A., F.R.S., &c. WITH ILLUSTRATIONS.

(full text as HTML)

In which Eric claims Darwin reveals that he did not understand his own theories.

Aharonov, Escher, Bohm

This bizarre effect of passing an electron around an insulated wire

The gentleman mentioned is Yakir Aharonov *

They are talking about the Aharonov–Bohm effect *

<<<or possibly the related Al’tshuler-Aronov-Spivak effect? Where ‘Aranov’ is a different person? I’m pretty sure it’s the aharanov-Bohm effect

We learned that if you have an insulated solenoid, the phase of the electron beam going in a circle around it would be shifted despite the fact that the electromagnetic field could be treated as zero because the electromagnetic potential, this precursor, had been shown to carry the actual content… it turned out that geometric object was more important

38:00 = MC ESCHER - Ascending and Descending (The Penrose Stairs)

File:Image 15.png
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Ascending and Descending - M.C. Escher

39:00 = PEN - anecdote about visiting Amsterdam. Mentions Shaun Wyile *

this is a guess, please check I have the right person

41:00 = “I played around with this and whittled it down to the triangle which people refer to as a ‘tribar’.” NB: He’s being modest and we actually call it a Penrose Triangle. (Penrose Triangle on Wolfram)

I’m pretty sure this is the paper: impossible objects a special type of visual illusion - L.S. Penrose and R. Penrose *

<<<NB: Wiley want $7 to rent this 62 year old paper for 48 hours (!) or $42 (!!) to buy it as a PDF. It is on SciHub and is 3 pages long. If you had to buy Penrose’s (paperback) book (tRtR) for the same per-page price, it would cost $14,000 a copy

Escher gave Penrose a print and it is in the Ashmolean Museum

<<<I can’t read this article: https://www.thetimes.co.uk/article/roger-penrose-on-his-friend-mc-escher-the-genius-that-galleries-ignored-90nhp8gsd0l because it’s behind a paywall, but the google link-summary says “… and he chose Fish and Scales, now on loan to the Ashmolean in Oxford”

(I think) the print was Fishes and Scales *

File:Image 16.png
image alt text

43:00 =

Eric Explains General Relativity

You have to begin with 4 degrees of freedom

Then you put rulers and protractors into it

That rise is

Those don’t fit together

The degree of “Escher-ness”

You throw one of them away, called the Weyl

That’s a long causal chain, but it is an accurate

Cohomology

It also illustrates co-homology.

What can you use Twistor-theory for? You can use it to solve Maxwell’s equations.

the movie inception

But that effect is the soul of the Aharanov-Bohm effect

Oscar Reutersvärd

We’ve mistold our stories

You were quite close to Michael Atiyah

His partner was Isadore Singer

They came up with the Atiyah-Singer Index Theorem which governs worlds in which there are no time dimensions but only space dimensions, or only time dimensions but no space

PEN - they could be just equations

Soap films look like elliptic equations

PEN - Atiyah-Singer is extremely general

WEIN - it tells you that… some high dimension… topological knotedness tells you something about the kinds of waves that can dance on that space.

53:00 =

Is The Real World Complex?

How to make Twistor-theory work in curved spaces

I ran into a problem that had to do with complex geometry.

Complex Geometry:

The analysis is particularly fascinating.

When you talk about real numbers, you can draw a function.

Smooth? Continuous? Curvature? How many degrees of smoothness? 1,2,3,4 or infinite?

Then we learn about complex. Do it all again using complex numbers and suddenly you find that if it’s smooth, everything comes with it.

WEIN - mathematicians quite often view the case of complex numbers as the natural case.

WEIN - You (Penrose) have been instrumental in making the case

…and then I learned about Quantum Mechanics. Yeah - there they are!

Suddenly these numbers are right there at the base of the subject

Minkowskian Geometry

57:00 = One of the ways of explaining what Twistor theory is

You are taking space-time and replacing it

You can ‘pull it upstairs’ to this Twistor space

Has this complex-number baked into it.

PEN - these things come together and take many years, sometimes, before they come together.

I was struck by the fact that

According to Einstein, special relativity, objects get flattened

It was these two-component spinors

If you think about the sky

Think of vector which is something that has a magnitude and also a direction to it.

You have particular vectors that you call ‘null’ - these are the ones along the light cone.

1:00 = in Minkowskian Geometry

1:01 = Minkowski showed

One event, say, and the light from that event reaches… a position in space time.

An event, or a point, in space-time

Imagine a particle moving between two points.

Minkowski realised that special-relativity is best described by this Minkowskian geometry.

Your idea was…

PEN - it took years but the initial idea isn’t so hard to understand.

If you look up in the sky, what are you seeing?

The world-line of that photon is ‘tilted over’

Suppose the photon is emitted at one event and received at another event.

That time measure is

Suppose you travel to a planet that is 8 light years away

Less than the time that someone on Earth would think it took you to get there.

And if you actually travel the speed of light, that time would be zero.

You’re not travelling at the speed of light, because you can’t get to the speed of light.

Even people who do this day and night choose never to work in some world.

If you go back and look at when Einstein introduced his relativity.

In that innocent decision to break off one degree of freedom and treat it different.

The Twistor Theory Cult

1:06 = “at that time, mathematicians and physicists were barely talking to each other”

Roman Jackiw - “when we talked to the geometers, we started to learn new things”

Jakiw is interviewed here at aip *

Schwarzchild Singularity - what we’d now call a ‘horizon’

<<<I haven’t found the direct quote, if you can find it, add a link

1:10 = you were sort of seen as running a cult

Twistor Newsletter

1:11 = PEN - “let me describe the basics of (Twistor Theory)”

Twistor Theory

Let me think of it the other way round, that is my past light cone

Imagine this cone stretching out into the past

Those stars in the sky look like points.

WEIN - imagine the world is transparent?

PEN - no, let’s go out into space

An astronaut whizzing by looks up.

Thanks to aberration, these will not be in quite the same place

It’s distorted, but it’s distorted conformally

If I see a circle, the astronaut will also see a circle

The thing about that transformation - something I knew about

You think about the Riemann Sphere

image alt textimage alt text

The Reimann Sphere and a Candy (or Toffee) Apple

The Riemann sphere folds all this up.

If you had a caramel coating around an apple (a Candy Apple) and at the point where the stick goes into that apple.

And it (the Riemann Sphere) has this property that it’s conformal.

The transformation is ‘analytic’ or ‘holomorphic’

WEIN - the analog of smooth for real numbers

Those transformations which send the sphere to the sphere are exactly those in Relativity.

The mapping from their sky to my sky is exactly this

And you get these two-component spinors

People find this puzzling. I find it puzzling!

The boundary of the thing will remain a circle.

Raoul Bott

Bott periodicity

Low-dimensional coincidences

Spinors grow exponentially whereas vectors grow linearly.

The Lorentz group.

The rotations of space and time

When you do it (relativity) in the two spinor form.

Complex one-dimensional space.

Each complex number carries the information of two real numbers

The complex line

The language is intended to make things hostile to the newbie *

<<<Is it really intended for that purpose? Is it “the DISC”?

An object with the smallest spin you can have. Spin 1/2

Chirality

(I think this is what’s called the Right-hand Screw Rule)

The complex numbers come in to describe these possible directions of spin.

These rather abstract numbers and the concrete directions in space.

The World is Given Only Once

1:22 = WEIN - “do you wed yourself to the world that’s given”

“the world is given only once”, attributed to Ernst Mach

“Do you wish to have a more general theory?”

What I see you having done is to work with mathematics that are particularising themselves to the world we live in.

1:23 = “You’re getting married to the world while other people are dating it, trying to keep their options open”

String Theory: People talk about (high) dimensions and, sure, we’ve got mathematics to describe that.

PEN - I’m looking for a way to describe the world that’s very particualar to the world we see

10 is two more than 8 and in 8 you have triality.

WEIN - “They (string theorists) never grow up to playing with reality”

PEN - I’m looking for a route that works specifically for the dimensionality we have

WEIN - If there weren’t a beautiful mathematics to catch you. You’re stage diving at a punk concert…

… the political economy of science means fewer people are willing to make strong predictions.

A dying breed of people who are prepared to go down with the ship for the privelege of commanding it.

Yours has been one of the most important, idiosyncratic programmes.

It is at least a deep insight into how to transform one problem into another to allow solutionis that wouldn’t have been easily gleaned in the original formulation.

WEIN - “do you believe Twistors are a more fundamental description of the world?”

PEN - “I do, yes. I don’t usually say that out loud”

WEIN - “I think that’s fucking great”

1:27 = one of the aims of mathematics is being more and more general

Atiyah-Singer Theorem

Deformation Complexes: 1st term - symmetries, 2nd - fields/waves, 3rd - equations

Cut it off at that point and have an elliptic complex

In dimension 4 we glean, something bizarre, that there are infinite ways to do calculus in 4 dimensional space and only one way to do it in every other dimension.

WEIN - Maybe differentiable structures are part of Physics

PEN - it’s quite possible

A Brief Critique of Particle Physics

If you have two Lie groups that act transitively on the same sphere in usual position, then either their intersection acts transitively on that sphere or the dimension of that sphere is 15. And I believe the intersection of the groups looks like the electro-strong group.

PEN - “I’ve never been someone who studied particle physics closely”

Pulled out of nowhere just by talking about sphere-transitive group actions.

Particle Physics?

We may be a long way from understanding what’s going on there.

WEIN - I didn’t know that

WEIN - I think we’re almost at the end

PEN - Understanding why the groups are the groups that we see.

1:30 = let me ask you a couple of questions

People like:

Unifying symmetries that remain very odd because they’re so attractive and powerful.

<<<This guy seems to have a very wide variety of interests. I double checked I have the right person and it seems right but please change it if you know differently.

The prettiest of them being spin-10, which physicists insist on calling SO 10 for reasons that escape me.

PEN - “Is this the one that doesn’t exist?”

Spin-5 (lives inside spin-10) was disproven

WEIN - Glashow and Georgi “rushed to commit ritual suicide far too quickly”

PEN - from the outside, I’m not convinced that…

Somehow (particle physics) has not got to the point… I’m hoping that Twistor theory might have something to say about it but the area that needs to be explored hasn’t been explored"

Particles in Twistor Theory

PEN - there was a question about how we treat massive particles in Twistor theory.

Twistor theory describes massless things.

Massless things have a privileged treatment.

PEN - There is a way of describing the Maxwell equations …which comes directly out of Twistor theory.

If you want to talk about massive particles, the way it seems to lead you is

A massive particle has a momentum vector which is time-like, so it points within the cone.

One way you can describe a time-like one is to think of two null ones. So you think of a zig-zag, so it’s got a zig and a zag and that’s one convenient way of doing it.

Or you might have one that’s made of three: zig, zag, zog - something like that.

You can get at the time-like line, it can be built from primitives.

You get these groups in Twistor theory and they look like the particle physics groups.

You get SU-2 and SU-3

SU-2 is ubiquitous and does not impress Eric.

but SU-3, representing the strong force, can be gauged to give QCD (genuine gauge theory)

Weak isospin.

Gauging doesn’t really work for SU-2

It’s not the full group and so on and there’s something wrong with it

1:34 - this is all guessing

The idea is you could develop a particle physics using many Twistors.

We have a problem in the standard model. We have an origin story with two gods.

The God of Einstein and the other god of SU-2 x SU-3.

The other gives us the quantum numbers.

This has no connection to the space and time data.

PEN - “they must be tied up at some stage but we haven’t got to that”

The idea was to do it via twistors.

When people discovered Charm this suddenly didn’t fit.

By charm you mean the addition of entirely separate versions of the familiar family of matter.

The addition of genera

1:36 = PEN - “I think we should go back to that”

Twistor Theory starts off as a theory about flat space-time

WEIN - “that’s what bothers me”

Origins of Twistor Theory

1:37 = PEN - “… the question is where did twistor theory come from”

WEIN - The Riemann Sphere of a with the Riemann Sphere of b

The world we see is Real numbers but the dynamics is controlled by the complex numbers.

Space-time has 4 dimensions.

Wanted to add another one because I wanted to incorporate an idea that was

Think of a Riemann sphere again

Complex numbers on one side and again on the other.

Rather than splitting everything into fourier components

Space-time is 4 dimensional and if you try to complexify it, you get 8 dimensions

1:39 = PEN - Anecdote about the day the JFK was shot and the day after when they visited San Antonio.

He travelled back with István Ozsváth * who didn’t speak much and started to think about

these constructions of Ivor Robinson * (in Dallas) which were solutions to the Maxwell equations that had these curious twists in them. I’d understood these things and realised that they were described by the Hopf map or the Clifford Parallels:

<<<I think? This was another hard one to look for.

<<<Please correct any links that you think are wrong?

Hopf fibration/Clifford parallels: https://en.wikipedia.org/wiki/Hopf_fibration

Robinson Congruences

You can think of a three dimensional sphere in four dimensions and you have these circles which fill the whole space, no two intersect and every two link. Beautiful configuration. This was the thing that geometrically described the solutions Ivor had found.

Think of a light ray and then think of all the light rays that meet that one and that family of light rays, you could have solutions of Maxwell’s equations that point along those rays.

It pushes the light ray into the complex.

You don’t see the light ray anymore.

You describe it by this family.

As I called them later, Robinson Congruences.

Six-dimensional family.

And one dimension, they can twist one way or the other.

WEIN - and that had three complex dimensions

PEN - it was a complex-projected three-space.

You have a 5-dimensional space that divides this 6-dimensional space into two.

1:44 - Isadore Singer took the work of Jim Simons and Frank Yang and on the trip to Oxford said “oh my god, this is the quaternionic rather than the complex hopf fibration”. He realised the self-dual equations were going to be a revolution.

1:45 = 4 complex dimensions means 8 real dimensions.

The Wu Yang Dictionary

WEIN - I am not a devotee of String Theory, nor of Loop Quantum Gravity

1:47 = if you look at curvature.

The Wu Yang dictionary. A geometer who becomes the most successful hedge fund manager in human history (Wu) meets a physicsist (Yang) *

<<<I’m confused about who the hedge fund manager is ? When I look up the two scientists I can’t see any mention of a hedge fund. Have I mis-identified one of them?

Steenrod’s fibre bundles (Norman Steenrod)

Charles Ehresmann, Ehresmannconnections, vector potentials and what have you

Geometric quantisation revolution

Heisenberg’s uncertainty relations come out of curvature

The pre-quantum line bundle

The key point is that what we’d previously treated as the annoyance of the HUP now became the beauty… the underlying quantum theory is now geometric.

Michael Atiyah

This weird grab bag that is called QFT - regimes where the number of particles changes, you need QFT, you can’t do it in QM.

QFT would have been discovered by topologists and geometers.

These are three separate revolutions. With people noones ever heard of. *

This thing, which is as gorgeous as anyting I’ve ever seen

What the F? Am I wildly off?

Quillam Theory?

1:51 = if you find the way through this you will really find the key.

That’s picked up a beautiful area of mathematics and turned it into physics.

I think there are things that are hiding in there.

What do you make of the fact that we now have three separate geometries?

  1. Reimannian Geometry - Parent of General Relativity
  2. Ehresmannian Geometry - Parent of the Maxwell Theory, also strong/weak force
  3. And then you’ve got this other geometric theory which is the geometric quantum.

Simons and Yang find … has gauge theory

Because Einstein takes curvature and uses something called

The opportunity to use gauge theory is lost.

He did this amazing thing by developing relativity.

He died before Quarks

There are huge, beautiful things in Mathematics and they do have a role.

The way the world works depends on deep mathematics.

They can be generalising ideas and revealing all sorts

The proportion of these that has relevance to Physics is very small

I’m sure that we will find other things, but the temptation is that there are so many directions

Once we had people who had a lot of different ideas.

Almost every new idea is dead on arrival unless you specifically keep it from predicting things that we don’t see.

A Brief Critique of String Theory

A class of “naughty boys” who get to make all sorts of claims…*

1:57 = “twistor theory is, at a minimum, an incredible valuable tool”

However, it’s also somewhat tolerated within the system

It’s a minority point of view but it’s allowed to play a parallel game to the String community.

String Theory is the smartest community out there - smarter than the relativists, smarter than the geometers, very clever and very insufferable.

The problem with that community is that they’ve accomplished a great deal that isn’t of a stringy nature.

Instead of quantising geometry, it backfired and they had the geometry geometrise the quantum. That’s the main legacy of these people.

They took off for Paris and landed in Tokyo. Very impressive as a feat but not what they intended to do.

I think I agree with that.

The influence I

Supersymmetry

What do you think about the legacy of something like Supersymmetry?

When I (Penrose) first heard of it

You needed complex analysis.

I visited (Bruno) Zumino

Deep supersymmetric model (the [model])

2:00 = Dirac had written this paper using two spinors - all the different spins with 2 spinors, clearer, etc.

Realised you could write it in

2:02 = Feynamn said these two things are proportional

Bell-Robinson Tensor

Bianci Identities written in 2-spinors

The higher the spin, the more indices

The Torsion Tensor

“We don’t really understand the things that we are given for free”

Re-deduces the Bianci identities

“I worry that we never really grounded these fields”

The torsion tensor.

Never shows up in any meaningful way anywhere.

2:04 PEN: I don’t use it.

what we have learned is of a very frightening nature.

Einsteins equations come from the simplest possible thing that could be optimised.

The Lagrangian.

Dirac and the Bianci Identities

Dirac’s third equation is the equation for matter which generates all of something called K-theory, which is absolutely fundamental.

2:06 PEN: I wanted to finish a story

At one point Dirac was a fellow at the same college.

I said to him “would he have opportunity to talk to me about it”

I wrote down this wave equation that represents the Bianci equations

He asked where it came from and he said “what are the Bianci identities”

He simply re-discovered them himself, he didn’t know they were called the Bianci identities.

In vacuum, say, and you take the Weil curvature which is all that’s left of the Riemann curvature and you write that in spinors and it’s a spinor with four indices completely symmetrical and then when you write the derivative, it’s the derivative acting on those four things and one contraction - the derivative two indices and you contract one of those - and that’s your equation. That vanishes, that’s the equation. Same as the Maxwell equations, same as the neutrino if you have one index and no mass, and it’s the way I think about these things.

Did you read his 1963 article in

Against naive application of the scientific method.

He says Schrodinger would not have been led into error if he had not been pressed into agreement with experiment.

Secretly he was talking about himself.

Dirac trying to give us a gift from mount Olympus

Give yourself more room to play, to imagine and to be wrong.

2:10 PEN - Dirac didn’t like to be wrong. He was very worried about saying things that were wrong and so would say nothing.

The Future of Analytic Geometry

WEIN - Let me ask you a hard question… …you’re going to be in your 90’s soon

There’s a failure to pass torches. Who would you be pointing to?

PEN - A Human Being? …I don’t think I’m going to take you up on that one… …it’s proably someone I don’t know.

WEIN - Do you worry that the Oxford School of geometric physics won’t continue?

PEN - I suppose I do a bit.

WEIN - the UK tolerates and encourages personal idiosyncrasies.

You’re asking me a bigger thing than… yeah

Penrose Tiles

Have you been to the courtyard of the Simons Centre for Geometry and Physics

They have a wall there - the so called iconic wall

They’re in a place that can be visited with a key and I always think about, in a fantastic world, unlocking that wall and seeing if it’s a gateway to something else.

2:15 = We all worry that we won’t get to see the end

What if I don’t get to see the end? Does that animates you?

There’s a huge amount of chance involved in these things. It’s all a gamble. *

TO see a real end is too remote

<<<Imagine how he must have seen the fellow-minds of his generation die, decade by decade

The Googly Problem

On the other hand we didn’t really discuss twistor theory - it’s been stuck and now it’s got unstuck.

The main theory

Construct solutions of the Einstein equations or the Ricci-flat which were completely

as long as they were anti-self dual

Why do we want complex solutions anyway?

Once I thought that the complex solutions were wavefunctions

I called in the non-linear graviton, which got stuck with the googly problem.

A googly is a ball bowled in the game of Cricket.

The ball bounces and to make it spin left-handed requires a special action but when you throw a googly, you use the same action which spins the ball left to instead spin it right.

I struggled and struggled and came up with all sorts of wild ideas and I found one that worked but it required a Cosmological Constant.

I was talking to

“That’s not the point, there are so many things that work better if you put this Cosmological Constant in”

It enables you to have a construction that enables you to solve the problem.

You talk about this algebra

Instead of patching

A point made clear to me by Michael Atiyah

This enables you to find a general solution of the Einstein equations.

But this is Lorentzian and not positive definite.

And that’s not the thing I’m good at doing

WEIN - sounds like you need a collaborator?

WEIN - stay away from that consciousness stuff

WEIN - stick with what you’ve done in Physics and try ot push that ball forwards.

WEIN - people are hungry to hear what it sounds like

PEN - as important as the details if not more.

2:22 = Thank You Very Much

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Resources

Clifford parallels
Ascending and Descending, by M. C. Escher. Lithograph, 1960.

Notes

There were three versions. The third version is in The Road to Reality. He thinks the second version is probably the best.

MC ESCHER - Ascending and Descending (The Penrose Stairs)

Experimental Markup for player

Denis just wanted to get me interested

200px-Sciama2.jpg

do working in cosmology this was it

I never he wanted me to change my

subject I learned an awful lot from

Dennis about physics because Dennis sort

of knew everything and everybody and he

had a real knack of getting if he

thought two people should meet each

other he got made sure they did meet

each other in one case it was Stephen

Hawking but Dennis was actually yeah

when you mentioned Dirac Dennis was

actually the last graduate with at the

time he was the only graduate student of

directs is that right yes then this was

Dirac was famously sort of difficult I

think that you know in recent years this

book came out of grammar mail of the

strangest man that puts directs

bizarreness he was difficult to get to

know but there's a bit of an irony here

I mean certainly he was hard for

physicists and so on to get to know him

now there were two people and actually

maybe I could just say one thing to our

listeners yes

in my estimation if not yours Dirac

would be neck-and-neck with Einstein for

the greatest of 20th century physicists

I think I wouldn't be far off that that

description for some reason his press

wasn't nearly as good maybe because of

his hair I don't know well he didn't

talk much this is one of the problems no

I agree I think he was I mean you think

about all we quantum mechanics people

who developed that amazing subject and

Dirac was really the one who put put it

all in order and so on well is is is and

this gets to a very odd issue which is

that you have wielded taste and beauty

as a weapon your entire life your

drawings are among the most compelling I

remember the first time what are one of

the things I've done using our friend

Joe Rogan's program is to push out

discussion of the hopf fibration because

it's an it's the only non-trivial

principal bundle that can be visual

scene and since the world seems to be

about principle bundles it's a bit odd

that the general population doesn't know

that stuff of which we are yes well they

the hopf fibration or the Clifford

parallels was instrumental in the

subject of Trista theory well but the

first time I ever saw a diagram it was

somebody reproducing a diagram they had

seen of yours and so the way in which

you have used art and sketches yeah it

was drawn by hand largely I mean they

were adding some circles involved which

I use a compass for but basically I

draped my hand there were two versions

of it the first one was more I sort of

thread you die first one was had more

circles in it and I thought I draw

there's more simply in the second

version but actually I had three

versions the third version is in the

road to reality but I'm not sure it's

best I think the second version perhaps

is the best so so Dirac getting back to

it had this elegance of mind yeah it was

unrelenting yes and he famously brought

in these bizarre objects with which some

of us are obsessed others of us don't

understand the obsession called spinners

which is sort of her a prerequisite to

getting to twister theory which you've

popularized well I I went to the UC

Dirac gave a course of lectures in

quantum mechanics and the first course

was sort of basic quantum mechanics and

the second course was on quantum field

theory but also spinners and there's an

interesting story about that which I

don't know the answer to in the second

course he deviated from his normal

course of lectures now I understood when

I talked to Graham family who wrote this

biography of Dirac I understood from

grand family that when I described that

the

deviated from his normal course to give

two or three lectures on two component

spinners which for me were absolutely

what I needed you see I'd learned from

my work on algebraic geometry we changed

that by trying to understand tensor

systems as abstract systems and things

which you can't represent in terms of

compare should just say that in terms of

these two components spin as you're

talking about for the lay audience all

of the matter that they think about