Lex Fridman Podcast - #214 – Jed Buchwald: Isaac Newton and the Philosophy of Science
Episode Date: August 28, 2021Jed Buchwald is a historian and philosopher of science at Caltech. Please support this podcast by checking out our sponsors: - GiveWell: https://www.givewell.org/ and use code LEX to get donation matc...hed up to $1k - Theragun: https://therabody.com/lex to get 30 day trial - LMNT: https://drinkLMNT.com/lex to get free sample pack - Fundrise: https://fundrise.com/lex - BetterHelp: https://betterhelp.com/lex to get 10% off EPISODE LINKS: Jed's Caltech page: https://bit.ly/38eLLRF Jed's Books: https://amzn.to/2WoxGPi PODCAST INFO: Podcast website: https://lexfridman.com/podcast Apple Podcasts: https://apple.co/2lwqZIr Spotify: https://spoti.fi/2nEwCF8 RSS: https://lexfridman.com/feed/podcast/ YouTube Full Episodes: https://youtube.com/lexfridman YouTube Clips: https://youtube.com/lexclips SUPPORT & CONNECT: - Check out the sponsors above, it's the best way to support this podcast - Support on Patreon: https://www.patreon.com/lexfridman - Twitter: https://twitter.com/lexfridman - Instagram: https://www.instagram.com/lexfridman - LinkedIn: https://www.linkedin.com/in/lexfridman - Facebook: https://www.facebook.com/lexfridman - Medium: https://medium.com/@lexfridman OUTLINE: Here's the timestamps for the episode. On some podcast players you should be able to click the timestamp to jump to that time. (00:00) - Introduction (06:34) - How does science progress? (22:48) - Theory of Everything (34:40) - Consciousness (38:15) - Most Beautiful Moments in Science (46:00) - Isaac Newton (1:12:13) - Competition in Science (1:22:47) - Newton's Career (1:35:58) - Importance of Data (1:42:17) - Alchemy (1:46:31) - Newton and Religion (1:49:44) - Showing Newton the future (1:54:28) - Newton and Einstein
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The following is a conversation with Jed Buckwald, a professor of history and a philosopher of science at Caltech.
Interested, especially in the development of scientific concepts and the instruments used to create and explore new effects and ideas in science.
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realized by hosting a podcast. Speaking of which, this is the Lex Friedman
podcast and here is my conversation with Jed Buckwald. The science progress via paradigm shifts and revolutions as philosopher Thomas Koon said
or does it progress gradually?
What do you think? Well, I got into this field because I was Tom Coon's research
assistant 50 years ago, 52 years ago.
He pulled me into it out of physics instead.
So I know his work pretty well.
And in the years when I was an MIT running an institute,
he was then in the philosophy department
used to come over all the time
to the talks we held and so on. So what would I say about that? He of course developed his ideas a
lot over the years. The thing that he's famous for, the structure of scientific revolutions,
came out in 62. And as you just just said it offered an
Outline for what he called a paradigmatic structure namely the notion that
You have to look at what scientists do is forming a community of
Investigators and that they're trying to solve various puzzles as he would put it that crop up
figuring out how this works, how that works,
and so on. And of course, they don't do it out of the blue. They do it within a certain framework.
The framework can be pretty vague. He called it a paradigm. And his notion was that eventually,
they run into troubles, or what he called anomalies, that kind of cracks things. Somebody knew comes along with a different way of doing it,
et cetera. Do I think things work that way? No, not really.
Tom and I used to have lengthy discussions about that over the years.
I do think there is a common structure
that formulates both theoretical and experimental practices.
Historians nowadays have science like to refer to scientific work as what science is
practice.
It's almost craftsmen like.
They can usually adapt in various ways.
I can give you all kinds of examples of that. I once wrote a book
on the origins of wave theory of light, and that is one of the paradigmatic examples
that Tom used, only it didn't work that way, exactly, because he thought that what happened
was that the wave theory ran into trouble with a certain phenomenon which it
couldn't crack. Well it turned out that in fact historically that phenomenon was
actually not relevant later on to the wave theory and when the wave theory came
in the alternative to it which hadailed, which was Newton's views,
light as particles, that it seemed couldn't explain what the wave theory could explain.
Again, not true.
Not true.
Much more complex than that.
The wave theory offered the opportunity to deploy novel experimental and mathematical structures
which gave younger scientists, mathematicians and others,
the opportunity to effect, manufacture, make new sorts of devices.
It's not that the alternative couldn't sort of explain
these things, but it never was able to generate them
day-novo as novelties. In other words, if you think of it as something explain these things, but it never was able to generate them day
novo as novelties. In other words, if you think of it as
something scientists want to progress in the sense of finding
new stuff to solve, then I think what often happens is is that
it's not so much that the prevailing view can't crack
something as that it doesn't give you the opportunity to do new stuff.
When you say new stuff, are we referring to experimental science here or new stuff in this space of new theories?
Could be both. Could be both actually. So how does that mean maybe elaborate a little bit on the story of the wave view? Sure.
The prevailing view of light, at least in France, where the wave theory really first took
off, although it had been introduced in England by Thomas Young. The prevailing theory dates back
to Newton that light is a stream of particles, and that refraction and reflection involve sort of
repulsive and attractive forces that deflect and bend the paths of these particles. Newton was not able
successfully to deal with the phenomenon of what happens when light goes past a knife's
edge or a sharp edge, what we now call diffraction. He had cooked up something about it that no
mathematical structure could be applied.
Thomas Young first, but really this guy named Augustant Fernel in France, deployed in Fernel's
case rather advanced calculus forms of mathematics which enabled computations to be done and observations to be melded with these computations in a way that you
could not do or see how to do with Newton. Did that mean that the Newtonian explanation of what
goes on in diffraction fails? Not really. You can actually make it work, but you can't generate anything new out of it, whereas using the mathematics
of wave optics in respect to a particular phenomenon called polarization, which ironically
was discovered by partisans of Newton's way of doing things, you were able to generate devices, which reflect light in crystals, do various things, that
the Newtonian way could accommodate only after the fact.
They couldn't generate it from the beginning.
And so if you want to be somebody who is working a novel vein, which increasingly becomes the case with people who become what
we now call physicists in the 1820s, 30s and 40s, in particular, then that's the direction
you're going to go.
But there were holdouts until the 1850s.
I want to try to elaborate on the nature of the disagreement you have with Thomas Kuhn.
So do you still believe in paradigm shifts? Do you still see that there is ideas that really have a transformational effect on science?
You just the nature of the disagreement has to do with how those paradigm shifts come to be?
How they come to be and how they change. I certainly think they exist. How strong they may be at any given time
is maybe not quite as powerful as Tom thought in general, although towards the end of his life,
he was beginning to develop different modifications of his original way of thinking. But I don't think that the changes happen quite so neatly, if you will, in
reaction to novel experimental observations.
They can much more complex than that.
In terms of meat-ness, how much of science progresses by individual, long geniuses and how much by the messy collaboration of
competing and cooperating humans. I don't think you can cut that with a knife to
say it's this percent to that percent. It's almost always the case that there are one or two,
or maybe three individuals who are sort of central to what goes on when things begin to shift.
Are they inevitably and solely responsible for what then begins to happen in a major way, I think
not. It depends. You can go very far back with this, even into antiquity to see what goes
on. The major locus we always talk about from the beginning is if you're talking about Galileo's
work on motion, for example, were there ways of accommodating it that others could adapt
to without buying into the whole scheme?
Yes.
Did it eventually evolve and start convincing people because you could also do other things
with it that you couldn't
otherwise do.
Also yes, let me give you an example.
The great French mathematician philosopher Descartes, who was a mechanical philosopher,
he believed the world was matter in motion, he never thought much of what Galileo had
done in respect to motion because he thought, well,
it bested some sort of approximative scheme or something like that.
But one of his initial, I wouldn't call him a disciple, but follower, who then broke with
him in a number of ways, was a man named Christian Huygens, who was, along with Newton, one of
the two greatest scientists of the 17th century, Huygens'
is older than Newton, and Huygens nicely deployed Galilean relationships in respect to
motion to develop all sorts of things, including the first pendulum-governed clock.
And even figured out how to build one, which which is keeps perfect time, except it didn't work,
but he had the mathematical structure for it. How well known is for you? Oh, very well known.
Should I be, should I know him well? Yes, you should. Interesting. You should definitely know him.
No, no, no, no, no, no. Can we, can we define should here? Oh, yeah. Because I don't. Right.
should here because I don't. Right. So so this should like a yeah, can you define should
should mean this. If you had taken up to a second ear physics course, as you should, you would have heard his name because one of the fundamental principles and optics is called Huygens principle.
Okay.
Yeah, so I have, and I have a herd his name.
There you go.
No, but I don't remember.
But you don't remember.
So, I mean, there's a very different thing between names attached to principles and laws
and so on that you sometimes let go of, you just remember the equations of the principles
themselves and the equations of the principles themselves,
and the personalities of science.
And there's certain personalities, certain human beings that stand out.
And that's why there is a sense to which the lone inventor, the lone scientist,
is the way I personally, I mean, I think a lot of people think about the history of science,
is these lone geniuses.
Without them, the sense is, if you remove Newton from the picture, if you remove Galileo
from the picture, then science would, there's almost a feeling like it would just have stopped
there.
Or at the very least, there's a feeling like it would take much longer to develop the things
that were developed.
Is that a silly way to look at the history?
That's not entirely incorrect, I suppose.
I find it difficult to believe that had Galileo not existed that eventually someone like
Huygens, for instance, given the context of the time, what was floating around in the belief structure
concerning the nature of the world and so on, the developments in mathematics and whatnot,
that sooner or later whether it would have been exactly the same or not, I cannot say,
but would things have evolved? Yes.
If we look at the long arc of history of science from from back when we were in the caves, trying to knock two rocks together,
or maybe make a basic tool to a long time from now many centuries from now when human
civilization finally destroys itself. If you look at that history and imagine
your historian at the end like with the fire of the apocalypse coming upon us and
you look back at this time in the 21st century, how far long are we on that arc? Do you sense? Have we invented
and discovered everything that's to be discovered? Or are we at like below 1%?
Well, you're going to get a lot of absurd questions today. I apologize. It's a Lugubrius picture,
you're painting there. I don't even know what the word, Lou Gubrius is, but I love it.
The Gubrius.
Well, let me try and separate the question
of whether we're all going to die in an apocalypse
in several hundred years or not,
from the question of where science may be sitting.
Take that as an assumption.
Okay.
I find that hard to say. And I find it hard to say because in the deepest sense of the term, as it's usually deployed by philosophers
of science today, I'm not fundamentally a realist. That is to say, I think our access to the inner
workings of nature is inevitably mediated by what we can do with the materials and factors
around us. We can probe things in various ways. Does that mean that I don't think that the
you know the standard model and quantum electrodynamics is in Crop Course not. I
wouldn't even dream of saying such a thing. It can do a lot
especially when it comes to figuring out what's happening in very large expensive
particle accelerators.
And applying results in cosmology and so on as well.
Do I think that we have inevitably probed the depths of reality through this?
I do not agree with Stephen Weinberg who thinks we have about such things.
Do I, on the other hand, think that the way in which science has been moving for the last
hundred years, physics, in particular, is what I have in mind, will continue on the same
course in that sense.
I don't, because we're not going to be building bigger and bigger and more and more expensive
machines to rip apart particles in various ways. In which case, what are physicists going to do? They'll turn their attention to other aspects. There are all sorts of things we've never explained
about the material world. We don't have theories that go beyond a certain point for all sorts of things.
We can't, can we, for example, start with the standard model and work our way up all
the way to chemical transformations? You can make an argument about it and you can justify
things, but that's in chemistry, that's not the way people work. They work with much higher
level quantum mechanical
relationships and so on. So this notion of the deep theory to explain everything is a long
standing belief, which goes back pretty far, although I think it only takes its fullest form
far, although I think it only takes its fullest form sometime in towards the end of the 19th century.
So maybe we just speak to that.
You're referring to a hope, a dream, a reality of coming up with a theory of everything
that explains everything.
So there's a very specific thing that that currently means in physics, as the unification
of the laws of physics.
But I'm sure in antiquity, or before it meant maybe something else,
or was it always about physics?
Does that mean, I think, as you've kind of implied,
in physics, there's a sense once you get to the theory of everything,
you've understood everything.
But there's a very deep sense in which you've actually understood
not very much at all. You've understood at that particular level how things work, but you don't
understand how the abstractions and type of abstractions form all the way to the chemistry,
to the human mind, and the human societies, and all those kinds of things. So maybe you can
speak to the theory of everything in its history and comment on what does that
even mean, the theory of everything?
Well, I don't think you can go back that far with something like that, maybe at best to
the 17th century.
If you go back all the way in antiquity, there are, of course, discussions about the nature
of the world. But first of all, you have to recognize that the manipulative
character of physics and chemistry, the probing of, let me put it this way, we assume and
have assumed for a long time, I'll come back to when in a moment,
that if I take a little device,
which is really complicatedly made,
out of all kinds of things,
and I put a piece of some material in it,
and I monkey around with it
and do all kinds of unnatural things to it,
things that wouldn't happen naturally,
and I find out how
it behaves and whatnot. And then I try and make an argument about how that really applies,
even in the natural world, without any artificial structures and so on. That's not a belief
that was widely held by pretty much anyone until sometime, maybe in the 1500s. And when it was first held,
it was held by people we now call alchemists. So alchemists was the early days of the theory
of everything, of a dream of by probing nature in artificial,
reconstructed ways, we can find out what's going on deep down there.
So that was that's distinct from science being an observing thing,
where you observe nature and you study nature.
You're talking about probing,
like messing with nature to understand it.
Indeed I am, and but that of course is the very essence of experimental science. You have
to, you have to manipulate nature to find out things about it, And then you have to convince others that you haven't so manipulated it,
that what you've done is to produce what amounts to fake, artificial behavior that doesn't really
hold purely naturally. So where are we today in your sense to jump around a little bit with a theory of everything. Maybe a quick kind of
sense you have about the journey in the world of physics that we're taking towards the theory of
everything. Well, I'm of course not a practicing physicist. I mean, I was trained in physics,
at Princeton a long time ago. Until Thomas Kuhn stole you away.
More or less, I was taking graduate courses.
In those days in general relativity, I was an undergraduate, but I moved up and then I
took a course with him.
Well, you made the mistake of being compelled by charismatic philosophers.
And never looked back.
I suppose so in a way. And from one I understand talking especially to my friends
at Caltech, like Kip Thorn and others, the divine and work with in the universe that we inhabit are perhaps quite unique
to this particular universe as it formed at the Big Bang.
The question is how deep does it go? If you are very mathematically inclined, the prevailing notion for several decades now has been what's called string theory.
But that has not been able to figure a way to generate probative experimental evidence, although it's pretty good apparently at accommodating things.
And then the question is, you know, what's before the big bang?
Or actually the word before doesn't mean anything given the nature of time, but why do we
have the laws that prevail in our universe. Well, there is a notion that those laws prevail
in our universe because if they didn't, we wouldn't be here.
That's a bit of a cyclical, but nevertheless a compelling definition. And there's all kinds
of things like the, it seems like the unification of those laws could be discovered by looking inside of a black hole because you get both the general relativity and the quantum mechanics quantum field theory in there
Experimentally, of course, there's a lot of interesting ideas. We can't really look close to the big bang can look that far back
This in Caltech and MIT will like go look in a gravitational ways
and Caltech and MIT will lie go, look in a gravitational ways,
perhaps allows us to march backwards and so on.
Yeah, it's really exciting space.
And there's, of course, the theory of everything,
like with a lot of things in science,
captivates the dreams of those who are,
perhaps completely outside of science.
It's the dream of discovering the key to how the, you know,
the nature of how everything works.
And that feels, that feels deeply human.
That's perhaps the thing, the basic elements of what makes up a scientist in the end is
that curiosity, that longing to understand.
Let me ask you mentioned a disagreement with Weinberg on the reality.
Could you elaborate a little bit?
Well, obviously I don't disagree with Steve Weinberg on physics itself.
I wouldn't know enough to even begin to do that.
And clearly, you know, he's one of the founders of the standard model and so on, and it works
to a level of accuracy
that no physical theory has ever worked at before.
I suppose the question in my mind is something
that in one way could go back to the philosopher
Immanuel Kant in the 18th century.
Namely, can we really ever convince ourselves that we have come to grips
with something that is not in itself noble to us by our senses or even accept in the most remote way through the complex instruments that we make as to what it is that underlies everything.
Can we corral it with mathematics and experimental structures?
Yes. Do I think that a particular way of corraling nature will inevitably play itself out. I don't know. It always has. I'll put it to you
that way. So the basic question is, can we know reality? Is that the the the the con question is that the Weinberg question?
We humans okay with our brains right can we
Comprehend reality Sounds like a very trippy question because a lot of it rests on definitions of no and comprehend and reality but
Get to the bottom of it
But like it's it's turtles on top of turtles can we get to the bottom of it. It's turtles on top of turtles.
Can we get to the bottom turtle?
Well, maybe I can put it to you this way in a way that I often begin discussions in
a class on the history of science and so on, and say, I'm looking
at you. Yes. You are, in fact, a figment of my imagination. You have a messed up imagination,
yes. Well, what do I mean by that? If I were a dragonfly looking at you, whatever my nervous system would form by way of a perceptual
structure would clearly be utterly different from what my brain and perceptual system altogether is forming when I look at you. Who's right? Is
it me or the dragonfly? Well, the dragonfly is certainly very impressive. So I don't know, but yes, it's the observer matters.
Well, how does what is that supposed to tell us about objective reality?
Well, I think it means that it's very difficult to get beyond the constructs that our perceptual system is leading us to when we make apparatus and devices and so on,
we're still making things the results of which or the outputs of which we process perceptually in
various ways. And an analogy I like to use with the students sometimes is this. All right, they all have their laptops open in front of them, of course.
Okay.
And I've sent them something to read.
And I say, okay, click on it and open it up.
So PDF opens up.
I said, what are you looking at?
And I said, well, I'm looking at, you know, the paper that you sent me.
I said, no, you're not.
What you're looking at is a stream of light coming off LEDs or LCDs, coming off a screen.
And I said, what happens when you use your mouse and move that fake piece of paper on the
screen around?
What are you doing?
You're not moving a piece of paper around, are you?
You're moving a construct around, a construct that's being processed so that our perceptual system can interact with it in the way we interact with
pieces of paper. Yes, but it's not real
So are there things outside of the reach of science?
Can you maybe as an example talk about
consciousness, masking for a friend, trying to figure this thing out?
Well, boy, I mean, I read a fair bit about that, but I certainly don't, can't really say much about it.
can't really say much about it. I'm a materialist in the deepest sense of the term. I don't think there is anything out there except material structures which interact in various ways. Do I think, for example,
that this bottle of water is conscious, no, I do not.
Although, how would I know? I can't talk to it. Yeah.
But so what do it's a hypothesis? Yeah.
It's an opinion, an educated opinion that may be very wrong.
Well, I know that you're conscious because I can interact directly with you.
But am I? Well, unless you're a figment in my imagination, of course,
or or I'm a robot that's able to generate the illusion of consciousness effectively enough to facilitate a good conversation because we humans do want to pretend that we're talking
to other conscious beings because that's how we respect them.
If it's not conscious, we don't respect them.
We're not going to talk to robots.
That's true.
Of course, we generalize from our own inner sense, which is the kind of thing Descartes said from the beginning. We generalize from that. But I do think that
consciousness must be something, whatever it is, that occurs as a result of some particular
organizational structure of material elements. Does materialism mean that it's all within the
reach of science? My sense would be that especially as neuroscience progresses
more and more, and at Caltech we just built a a home neuroscience arena and so on.
And as more knowledge is gained about the ways in which animals, when they behave, what
patterns show up at various parts of the brain and nervous system, and perhaps extending
it to humans eventually as well, we'll get more of a handle on what brain activity is
associated with experiences that we have as humans. Can we move from the brain activity to the
experiences in terms of our person. No, you can't.
Perception is perception.
That's the hypothesis once again.
Maybe the,
maybe consciousness is just one of the laws of physics
that's yet to be discovered.
Maybe it permeates all matter.
Maybe it's,
maybe it's as simple as trying to plug it in and plug into the ability
to generate and control that kind of law of physics that would crack open, or we would
understand that the bottle water is in fact conscious, just much less conscious than us
humans. And then we would be able to then generate beings that are more conscious.
Well, that will be unfortunate. I'd have to stop drinking the water after that.
Every time you take a sip, there's a little bit of a suffering going on.
What do you use the most interesting, beautiful moments in the history of science?
What stands out? And then we can pull at that thread.
Right.
Well, I like to think of events that have a major impact and involve both beautiful conceptual
mathematical, if we're talking physical structures, work, and are associated as well with probing
experimental situations.
So
Among my favorites is one of the most famous which was the young Isaac Newton's
work with the colors produced when you pass sunlight through a prism
And why do I like that?
It's not profoundly mathematical in one sense.
It doesn't need it initially.
It needs the following, though, which begins to show you, I think, a little bit about
what gets involved when you've got a smart individual who's trying to monkey around with
stuff and finds new things about it.
First, let me say that the notion, the prevailing notion going back to antiquity
was that colors are produced in a sense by modifying or tinting white light,
that they're modifications of white light.
In other words, the colors are not in the sunlight in any way. Okay. Now, what Newton did,
following experiments done by Descartes before him, who came to very different conclusions, he took
a prism. You might ask, where do you get prisms in the, you know, 16 questions. County fares. They
were very popular. They were pretty crude with bubbles in them and
everything, but they produced colors. So you could buy them at county fairs and things very popular.
So they were modifying the white light to create colors. They were creating colors from it, well-known.
And what he did was the following. He was by this time, even though he's very young,
But he did was the following. He was by this time, even though he's very young, a very good mathematician.
And he could use the then-known laws for how light behaves when it goes through glass
to calculate what should happen if you took light from the sun, past it from a hole,
through a little hole, then hit the prism, goes out of the prism,
goes strikes a wall along distance away and makes a splash of light.
Never mind the colors for a moment.
Makes a splash of light there. He was very smart.
First of all, he abstracts from the colors themselves, even though that's what everybody's
paying attention to initially. Because what he knows is this, he knows that if you take this prism and you turn it to
a certain particular angle, that he knew what it should be because he could calculate
things.
Very few other people in Europe at the time could calculate things like he could.
That if you turn the prism to that particular angle, then the sun, which is of course a circle,
when its light passes through this little hole and then into the prism, on the far distant wall,
should still make a circle. But it doesn't. It makes a very long image. And this led him to a very different conception of light, indicating that there are different types of light in the sunlight.
Now, to go beyond that, what's particularly interesting, I think, is the following.
When he published this paper, which got him into a controversy,
he really didn't describe it all what he did.
He just gave you some numbers. Now, I just told you that you have to set this prism at a certain angle.
Right? You would think, because we do have his notes and so on. You would think that he took
some kind of complicated measuring device to set the prism he didn't. He held it in his hand. That's all. And he twiddled it around. And
what was he doing? It turns out that when you twiddled the prism around at the
point where you should get a circle from a circle, it also is the place where
the image does not move very fast.
So if you want to get close to there, you just twiddle it.
This is manipulative experimentation, taking advantage through his mathematical knowledge
of the inherent inaccuracies that label, let you come to exact conclusions
regardless of the built-in
problematics of measurement. He's the only one I know of doing anything like that at the time. I'm yeah.
Well, even still there's very few people that are able to have to calculate as well as he did to be a theoretician
and an experimentalist like in the same moment.
It's true, although until the, really, the well into the 20th century, maybe the beginning of the 20th century really, most of the most significant experimental
results produced in the 1800s, which laid the foundations for light, electricity,
electrodynamics, and so on, even hydrodynamics and whatnot, were also produced by people who were both excellent calculators, very talented mathematicians,
and good with their hands experimentally.
And that led to the 21st century in Rico for me that one of the last people that was
able to do that, both of those things very well,
and that he built a little device called an atomic bomb
that has some positive as negatives.
But in many projects.
Well, right, of course that actually did involve
some pretty large-scale elaborate equipment to.
While holding a lot of prison in your hands,
the same thing. Right, no.
What's the controversy that you didn't
gotten into with that paper when he published it? Well, I, in a number of ways,
it's a complicated story. There was a very talented character known as a mechanic.
Mechanic means somebody who was a craftsman who could build and make really good stuff.
And he was very talented. His name was Robert Hook. And he was the guy who at the weekly meetings
of the Royal Society in London, and Newton's not in London, you know, he's a Cambridge,
a young guy. He would demonstrate new things, and he was very clever. And he had written a book, in fact, called the micrographia, which by the way,
he used a microscope to make the first depictions of things like a fly's eye, the structure of,
you know, it had a big influence. And in there, he also talked about light. And so he had a different
view of light. And when he read what Newton was wrote, he had a double reaction. On the one hand, he said,
anything in there that is correct, I already know. And anything that I didn't already know is
probably not right anyway. I got a little bit of love. He goes, okay, can you, can we just step
back? Can you say who was Isaac Newton?
What are the things he contributed to this world in the space of ideas?
Wow.
Who was he?
He was born in 1642 and near the small town of Grantham in England. In fact, the house he was born in,
and that his mother died in, is still there and can be visited. His father died before
he was born, and his mother eventually remarried a man named Reverend Smith, whom Newton did not like
at all, because Reverend Smith took his mother away to live with him a few miles away, leaving
Newton to be brought up more or less by his grandmother over there.
And he had huge resentment about that, his whole life.
I think that gives you a little inkling that,
a little bit of trauma and childhood,
maybe a complicated father-son relationship
can be useful to create a good scientist.
Could be, although this case, it would be right,
the, you know, absent father, non-father relationships,
to speak.
He was known as a kid, a little that we do know for
being very clever about flying kites and there are stories about him putting candles and putting
flying kites and scaring the living devil out of people at night by doing that and things like that, making things. Most of the physicists and natural
philosophers I've dealt with actually as children were very fond of making and playing with
things. I can't think of one I know of who wasn't actually, they're very good with their hands and whatnot. He was his mother wanted him to take over the manner. It was a
kind of farming manner. They were the class of what are known as yeomans. There are stories that he
wasn't very good at that. One day one of the stories is he's sitting out in the field and the cows come home without him and he doesn't
know what's going on.
Anyway, add relatives and he manages to get to Cambridge, sent to Cambridge because he's
known to be smart.
He's read books that he got from local dignitaries and some relatives and he goes there as what's
known as a subsisor.
What does that mean?
Well, it's not too pleasant. Basically, a subsisor was a student
who had to clean the bedpans of the richer kids.
Okay.
Right?
That didn't last too long.
He makes his way and he becomes absorbed
in some of the new ways of thinking
that are being talked about
on the parts of Descartes and others as well.
There's also the traditional curriculum
which he follows and we have his notes.
We have his student notebooks and so on.
We can see gradually this young man's mind
focusing and coming to grips with deeper questions
of the nature of the world and perception even,
and how we know things,
and also probing and learning mathematical structures
to such an extent that he builds on some of the investigations
that had been done in the period before him
to create the foundations of a way of investigating processes that happen
and change continuously instead of by leaps and bounds and so on, forming the foundation
of what we now call the calculus.
Yeah.
So, can you maybe just paint a little bit of a picture?
You've already started of what were the things that bothered him the most that
stood out to him the most about the traditional curriculum, about the way people saw the world.
You mentioned discrete versus continuous.
Is there something where he began thinking in a revolutionary way?
It's because it's fascinating. Most of us go to college, Cambridge or otherwise,
and we just kind of take what we hear as gospel, not gospel, but as facts. You don't begin to
sort of see how can I expand on this aggressively or how can I challenge everything that I hear like rigorously,
mathematically through the, I mean, I don't even know how rigorous the mathematics was at
that point.
I'm sure it was geometry and so on.
No calculus, huh?
There are elements of what turned into the calculus that predate Newton, but how much,
how much rigor was there how much
Well rigor no and then of course no scientific method
Not really I mean somewhat the
I mean appreciation of data
Ah, that is a separate question from a question of method
Appreciation of data is a significant question as to what you do with data. There's lots of things
you're asking. I apologize. So let's backtrack in the first question. Was there something that
was bothering him? He especially thought he could contribute a work on. Well, of course,
we can't go back and talk to him, but we do have these student notebooks. There's two of them.
One's called the philosophical
questions, and the other is called the waste book. The philosophical questions has discussions
of the nature of reality and various issues concerning it, and the waste book has things
that have to do with motion in various ways. What happens in collisions and things of that
sort. And it's a complicated story.
But what's among the things that I think are interesting is
he took notes in the philosophical questions on stuff that was
traditionally given to you in the curriculums going back
several hundred years, namely on what scholars refer to as scholastic or neoscholastic ways
of thinking about the world dating back to the reformulation of Aristotle in the Middle
Ages by Thomas Aquinas in the church.
This is a totally different way of thinking about things, which actually connects to something
we were saying a moment ago. For instance, so I'm wearing a blue shirt.
And I will sometimes ask students, where is the blue?
And they'll usually say, what's in your shirt?
And then some of them get clear and they say, well, no, you know,
light is striking. It photons are re-emitted.
They strike the back of your retina, and et cetera, et cetera.
And I said, yes,
you what that means is that the blue is actually an artifact of our perceptual system considered
as the percept of blue. It's not out there, it's in here. Right? That's not how things were thought about well into the 16th century. The general notion
dating back even to Aristotelian antiquity and formalized by the 12th century at the Paris
Oxford and elsewhere is that qualities are there in the world. They're not in us.
We have senses, and our senses can be wrong.
You know, you could go blind, things like that.
But if they're working properly,
you get the actual qualities of the world.
Now, that break, which is occurring towards
the end of the 16th century and is most visible in
Descartes, is the break between conceiving that the qualities of the world are
very different from the qualities that we perceive. That in fact, the qualities of
the world consist almost entirely in shapes of various kinds and maybe hard particles or whatever,
but not colors, not sounds, not smells, not softness and hardness.
They're not in the world.
They're in us.
That break Newton is picking up as he reads day card. He's going to disagree with a lot in day card, but that break he is
Among other things picking up very strongly and that underlies a lot of the way he works later on when he becomes skeptical of the evidence provided by the senses
Yeah, that's that's, I don't know,
the way you're describing it's so powerful,
it just makes me realize how libering that is
as a scientist, as somebody who's trying
to understand reality that our senses is just,
our senses are not to be trusted.
That reality is to be investigated through tools that are beyond our senses.
Yes.
Or that improve our senses.
That improve our senses in some ways.
That's pretty powerful.
I mean, that is for a human being, that's like Einstein level.
For human being to realize, I can't trust my own senses
at that time.
That's pretty trippy.
It's coming in, it's coming in,
and I think it arises probably,
a fair number of decades before that, perhaps in part
with all chemical experimentation and manipulations that you have to go through elaborate structures
to produce things and ways you think about it.
But let me give you an example that, you know, I think you might find interesting because
it's from, it involves that guy named
Hook that Newton had an argument with.
And he had lots of arguments with Hook, although Hook was a very clever guy and gave him some
things that stimulated him later.
Anyway, Hook, who was argumentative, and he really was convinced that the only way to gain real knowledge of nature is through
carefully constructed devices.
And he was an expert mechanic, if you will, at building such things.
Now there was a, there was a rather wealthy man in Danzig by the name of Hevelius, Latinized name. He was a brewer
in town, and he had become fascinated with the telescope. This is 30 years or so, 20 or 30 years
after the telescope had moved out and become more common. And he built a large observatory on the top of his brewery,
actually, and working with his wife, they used these very elaborately constructed
grass and metal instruments to make observations of positions of the stars. And he published a
whole new catalog of where the stars are.
And he claimed it was incredibly accurate. He claimed it was so accurate that nothing
had ever come close to it. Hook reads this, and he says, wait a minute. You didn't use
a telescope here of any kind, because what's the point, unless you do something to the telescope
or you see your dots with stars, you just
use your eyes.
Your eyes can't be that good.
It's impossible.
So what did Hook do to prove this?
He said what you should have done is you should have put a little device in the telescope
that lets you measure distances between these dots.
You didn't do that because you didn't.
There's no way you could have been that good.
At two successive meetings of the Royal Society, he holds the members out into the courtyard
and he takes a card and he makes successive black and white stripes on the card and he
paces the card up on a wall and he takes them take some one by one, he says, now, move back looking
at it, presumably with one eye, until you can't tell the black ones from the white stripes.
He says, that I can then measure the distance, I can see the angles, I can give a number
then for what is the best possible, what we would call perceptual acuity of human vision?
And it turned out he thought to be something like ten or more times worse than this guy
Havailius had claimed. So obviously he says Hokehavailius.
Well, years ago, I calculated Havailius' numbers and so on using modern tables from NASA and so on,
and they are even more accurate than Haveles claimed. And worse than that,
the Royal Society sent a young astronomer named Halley over to Donzig to work with him,
and Halley writes back, and he says, I couldn't believe it. But I could, he taught me how to do it and I could get just as good as he, how is it possible? Well, here
and this shows you something very interesting about experiments, perception and everything
else. Hook was right, but he was also wrong. He was wrong for the right reasons and he
was right for the wrong reasons. and what do I mean by that?
What he actually found was the number for what we now call 2020 vision. He was right
You can't tell except a few people much better than that. Yeah, but he was observing the wrong thing. Yes
What Havailius was observing was a bright dot, a star moving past a pointer.
Our eyes are rather similar to frog's eyes.
You know, I'm sure you've heard the story.
If I hold a dead fly on a string in front of a frog and don't move it, the frog pays no attention.
As soon as I move the fly, the frog immediately tongue latch out because the visual system
of the frog responds to motion, so does ours, and our acuity for distinguishing motion
from static five or more times better. Yeah, that's fascinating.
Damn.
And of course, I mean, maybe you can comment on their understanding
of the human perceptual system of the town was probably really terrible.
Like, yeah.
Like I've recently been working with just almost as a fun side thing,
with vision scientists and peripheral vision, it's
a beautiful complex mess that whole thing. We still don't understand all the weird ways
that human perception works, and they were probably terrible at it. They probably didn't
even have any conception of peripheral vision or the fovee or, I mean, basically anything. They had some, I mean, because actually it was Newton himself who probed a lot of this, for instance,
Newton, the young Newton, trying to work his way around what's going on with colors,
wanted to try and distinguish colors that occur through natural processes out there,
and colors that are a result of our eyes not operating
right. So you know what he did, the famous thing. He took a stick, and he stuck that stick under his
lower eyelid and pushed up on his eyeball. And what that did would produce colored circles at
diametrically opposite positions of the stick in the eyeball
and he moved it around to see how they moved, trying to distinguish.
Legit.
Right?
I always have to tell my students, don't do this, but.
Or do it if you want to be great and remembered by human history.
That there's a lot of equivalent to sticking a stick into your eye in modern day that
May pay off in the end
Okay
As a small aside is the Newton and the Apple story true. No
Was it a different fruit?
As a colleague of mine named Simon Schaffer in England once said on an over program that we were both on
The role of fruit in the history of science has been vastly exaggerated
Okay, so was there any immune to the zoom out moments of epiphany?
to the zoom out moments of epiphany. Is there something to moments of epiphany? Or again, this is the paradigm shift versus the gradualism. There is a shift. It's a much more complex one than that.
As it happens, a colleague of mine and I are writing a paper right now on one of the aspects of these things
based on the work that many of our colleagues have done over the last 30 and 40 years.
Let me try and see if I could put it to you this way.
Newton until the early 1670s and probably really until a fair time after that. First of all, was not very interested
in questions of motion. He was working actually in all chemical relationships or what is called
by historians' chemistry, a kind of early modern chemical structure. Colleagues of ours at Indiana have even reproduced the amalgams that, anyway, his way of thinking
about motion involved a certain set of relationships which was not conducive to any application that would yield
computationally direct results
for things like planetary motions,
which he wasn't terribly interested in anyway.
He enters a correspondence
with his original nemesis, Robert Hook.
And Hook says, well, have you ever thought about,
and then Hook tells him a certain way
You might think about it. And when Newton hears that
He recognizes that there is a way to inject time that would enable him to solve certain problems
It's not that he that there was anything he thought before that was contrary to that way of thinking. It's just that that particular
technical insight was not something that for a lot of reasons that are complex had never occurred
to him at all. And that sent him a different way of thinking. But to answer your question about
the Apple business, which is always about you know know gravity and the moon and all of that being, no.
The reason there is that the idea that what goes on here in the neighborhood of the Earth
and what goes on at the moon, let us say, remind the Sun and the planet, can be due to a direct relationship between the Earth, let's say, and the Moon, is contrary to fundamental beliefs held by many of the mechanical philosophers, as they're called at the time, in which everything has to involve at least a sequence of direct contacts. Has to be something between here and there.
Yes.
That's involved.
And Hook, probably not thinking terribly deeply about it based on what he said, along
with others, like the architect and mathematician Christopher Ran, hearken back to the notion
that, well, maybe there is a kind of magnetic
relationship between the moon and maybe the planets and the earth and gravity and so
on, vague, but establishing a direct connection, somehow, however it's happening, forget
about it.
Newton wouldn't have cared about that if that's all they said, but it was when a hook
mentioned this different way of thinking about the motion, a way he could certainly have thought of, because it does not contradict
anything.
Newton is a brilliant mathematician, and he could see that you could suddenly start to do things
with that.
That you otherwise wouldn't, and this led eventually to another controversy with Hook, in which Hook said, well, after Newton published his great print, Kippie,
I gave him how to do this.
And then Newton of course got ticked off about that and said, well, listen to this,
I did everything, and because he had a pick of you and little idea,
he thinks he can take credit for it.
Okay.
So his ability to play with his ideas mathematically is what solidified the initial intuition
that you could have was at the first time he was born the idea that you have action at a distance
that you can have forces without contact, which is another revolutionary idea. I would say that in the sense of dealing with the mechanics of force-like effects considered
to act at some distance, it is novel with both hook and Newton at the time.
The notion that two things might interact at a distance with one another without direct contact that goes back to antiquity
Only there would thought of more as a sympathetic reaction, you know to a magnet and and a piece of iron they have a kind of mutual sympathy
for one another
Like like what love what are we talking actually, they do sometimes talk like that.
But that is love, that I met.
I see now, I talk like that all the time.
I think love is somehow in consciousness,
there are forces of physics that you have to be discovered.
Okay. Now, there's the other side of things, which is calculus,
that you begin to talk about. Newton brought a lot of things to this world. things, which is calculus, that you begin to talk about,
so Newton brought a lot of things to this world.
One of them is calculus.
What is calculus?
And what was Newton's role in bringing it to life?
What was it like?
What was the story of bringing calculus to this world?
Well, since the publication, starting many decades ago by Tom Whiteside, who is now
deceased of Newton's mathematical papers, we know a lot about how he was pushing things
and how he was developing things.
It's a complex question to say what calculus is, calculus is the set of mathematical techniques that enable you
to investigate what we now call functions, mathematical functions, which are continuous
that is, that are not formed out of discrete sets like the counting numbers, for instance.
Newton, there were already procedures
for solving problems involving such things
as finding areas to under curves and tangents to curves
by using geometrical structures,
but only for certain limited types of curves,
if you will.
Newton, as a young man, we know this is what happened, is looking at a formula which involves
an expansion in separate terms, polynomial terms, as we say, for certain
functions.
I know I want to get complicated here about this, and he realizes it could be generalized,
and he tries the generalization, and that leads him to an expansion formula called the binomial theorem. That enables him to move ahead with
a notion that if I take something that has a certain value, and I add a little bit to
it, and I use this binomial theorem and expand things out, I can begin to do new things.
And the new things that he begins to do leads him to a recognition that the
calculations of areas and the calculations of tangents to curves are reciprocal
to one another and the procedures that he develops is a particular form of the
calculus in which he considers small increments and then continuous flows and changes
of curves and so on.
We have relics of it.
In physics today, the notation in which you put a dot over a variable indicating the rate
of change of the variable, that's Newton's original type of notation.
The dot, yeah, the dot notation. Possibly independently of Newton, because he didn't publish this thing,
although he became quite well known as quite a brilliant young man in part because people heard about his work
and so on. When another young man by the name of Gottfried Leibniz visited London and he heard
about these things, it is said that he independently develops his form of the calculus, which is actually the form we use today,
both in notation and perhaps in certain fundamental ways of thinking.
It has remained a controversial point as to where exactly and how much independently Leibniz did it.
Leibniz of Fissionados think and continue to maintain. He did it completely independently.
Newton, when he became president of the Royal Society, put together a group to go on the attack,
saying, no, you must have taken everything. We don't know.
But I will tell you this,
about 25 or so years ago, a scholar who's a professor at Indiana now named Domainico Melley,
got his hands on a Leibniz manuscript called the Ten Taman, which was Leibniz's attempt
to produce an alternative to Newton's mechanics. And it comes to some conclusions that you have
in the Newton's mechanics.
Well, he published that, but Mellie got the manuscript, and what Mellie found out was that
Leibniz reverse engineered the principia and cooked it backwards so that he could get the results he wanted.
Now, that was for the mechanics. So that means his mind allows for that kind of thing.
Some people, you're breaking some news today.
You're starting some people.
Some people think so.
I think most historians of mathematics do not agree with that.
A friend of mine, rather well-known physicist,
unfortunately, died a couple years ago in a Mike Nowanberg
at UC Santa Cruz, had some evidence along those lines.
Didn't pass mustard with many of my
friends who were historians of math. In fact, I had it with a historian of math, a technical
journal, and we were unable to publish it in there because we couldn't get it through
any of our colleagues. But I am, I remain suspicious.
What is it about those tense relationships and that kind of drama? Einstein doesn't appear to have much of that drama.
Nobody claimed, I haven't heard claims that they've, perhaps because it's such crazy ideas. Have any of his major inventions, major ideas, being those that are basically, I came up with it
first or independently. There's not as far as I'm aware, and I mean, people talk about
general relativity, especially in those terms, but with Newton, that was the case. I mean,
is that just the natural augur of how science works? Is there's going to be personalities that I'm not saying this about lens, but maybe I
am that there's people who steal ideas for the, you know, because of ego, because of all
those kinds of things.
I don't think it's all that common, frankly.
The Newton hook, Leibniz, Contra Thompson, and so on. Well, you know, you're at the
beginnings of a lot of things there, and so on. These are difficult and complex times as well.
These are times in which science as an activity pursued by other than, let us say,
other than let us say interested aristocrats is becoming something somewhat different. It's not a professional community of investigators in the same way.
It's also a period in which procedures and rules are practiced or being developed
to avoid attacking one another directly and pulling out a sword to cut off the other guy's head if he disagrees with you.
And so on. So there's a very different period. Controversies happen, people get angry. I can think of a number of others, including in the development of optics in the 19th century and so on. And it can get hot under the collar.
Sometimes one character who's worked in area,
extensively, whether they've come up with something terribly novel or not,
and somebody else kind of moves in and does completely different novel things.
The first guy gets upset about it because he sort of muscled into what I thought was my area.
Yeah. And you find that sort of stuff.
But do you have examples of cases where it worked out well, like that competition is good for the progress of science?
Yeah, I'd almost always as good in that sense.
Just painful for the individuals involved. And B, it doesn't have to be nasty, although sometimes it is.
So on the space, like for the example of optics, could you comment on that one?
Well, yeah, sure. Let me, there's several, but I could give you,
all right, so I'll give you this example that probably is the most pertinent.
example that probably is the most pertinent. The first polytechnic school, like MIT or Caltech, was actually founded in France during the French Revolution. It exists today. It's the
I call polytechnique. Two people who were there were two young men in the 90s, 1790s, named on the one hand François
Aragot and the other Jean-Baptiste B.O. They both lived a long time, well into the 1850s.
Aragot became a major administrator of science, and B.O. career started to peter out after about the late teens. Now, they are sent on an expedition,
which was one of the expeditions involving measuring things to start the metric system.
That's a lot more to that story. Anyway, they come back. Arrogo gets separated. He's captured
He come back, Arrogot gets separated. He's captured by pirates, actually.
Wounds up in Tangier, escapes, is captured again.
Everybody thinks he's dead.
He gets back to Paris and so on.
He's greeted as a hero.
And what not in the meantime, Bio has pretty much published some of the stuff that he's
done.
And Aragoh doesn't get much credit for it.
And Aragoh starts to get very angry.
And B.O. is known for this kind of thing.
So Aragoh, anyway,
B.O. starts investigating a new phenomenon on an optics,
involving something called polarization.
Any rights, all kinds of stuff on it.
Arago looks into this and decides to write some things as well.
And actually, B.O. gets mostly interested in it when he finds out that Arago is doing
stuff.
Now, B.O. is actually the better scientist in a lot of ways.
But Arago is furious about this.
So furious that he actually demands and forces
the leader of French science Laplace,
the Marquette de Laplace,
and cohorts to write a note in the published journal saying,
oh, excuse us, actually, Arragó, etc., etc., blah blah.
So Aragó continues to just hold this antipathy and fear of bio. So what happens? 1815. Napoleon
is finished at Waterloo. A young Frenchman by the name of Augustant Frinnell was in the army,
is going back to his home on the north coast of France in Normandy, passes through Paris.
Arago is friends with Frinnell's uncle, who is the head of the Ico Coldeboz are at the time?
Anyway, Frenel is already interested in certain things in light.
He talks to Arago.
Arago tells him a few things.
Frenel goes home.
And Frenel is a brilliant experimenter.
He observes things, and he's a very good mathematician.
Calculates things.
He writes something up. He sent it to Arago.
Arago looks at it.
And Arago says to himself, I can use this to get back at B.O.
He brings Frenel to Paris, sets him up in a room at the observatory where
Arago is for Frenel to continue his work paper after paper comes out.
Undercutting everything B.O. had done. What is it about jealousy and just envy that could be an engine of
creativity and productivity versus like an Einstein where it seems like not. I
don't know which one is better.
I guess it depends on the personality,
both the use flingens and science.
Well, in this particular story,
it's maybe even more interesting
because Fresnel himself, the young guy,
he knew what Arago was doing with him and he didn't like it.
He didn't wanna get with, he wrote his brothers
and I don't wanna get an argument with B.
I just want to do my stuff.
Arrogo is using him, but it's because Arrogo kept pushing him
to go into certain areas that stuff kept coming out.
Yeah.
Yeah.
Ego is beautiful.
OK, back to Newton.
There's a bunch of things I want to ask, but sort of, let's say, since we're on the
ligaments and the topic of drama, let me ask another drama question. Why was Newton a complicated man?
Ah,
we're breaking news today. This is like, uh,
a bright white was complicated. It's like,
This is like a bright white was complicated. It's like, and his brain structure was different.
I don't know why he had a complicated young life, as we've said.
He had always been very self-contained and solitary.
He had acquaintances and friends, and when he moved to London eventually, he had quite a career,
a career, for instance, that
led him when he was famous by then the 1690s.
He moves to London.
He becomes first warden of the mint.
The mint is what produces coins.
And coinage was a complicated thing because there was counterfeiting going on.
And he becomes master of the mint to the extent. And a guy at MIT wrote
a book about this a little bit. We wrote something on it too. I forget his name was Levin.
That Newton sent investigators out to catch these guys and sent at least one of them a famous
one named Challenger to the gallows. So he was, and one of the reasons he probably was
so particularly angry at Challenger was Challenger
had apparently said some nasty things about Newton
in front of Parliament at some point.
Fair enough.
Yeah, it was apparently not a good idea.
Well, he had a bit of a temper,
so you didn't have a bit of a temper.
Oh, clearly.
Okay. Clearly. Okay, clearly.
But he, he even, as a young man at Cambridge, though he doesn't come from wealth, he attracts
people who recognize his smarts. There's a young fellow named Humphrey Newton,
shared his rooms. You know, these students always shared rooms with one another, became his kind of a manuances to write down
what Newton was doing and so on.
And there were others over time who he befriended
in various ways and so on.
He was solitary.
Yeah, as far as we know, no relationships with either women or men in anything
other than a formal way. The only those get in the way relationships.
Right. Well, I mean, he was, he was, I don't know if he was close to his mother. I mean,
she passed away. Everything left him. He went to be with her after she died. He was close to his niece
Catherine Barton who basically came to run his household
When he moved to London and so on and she married a man named conduit who became one of the
people who controlled Newton's legacy
became one of the people who controlled Newton's legacy later on and so on. So he and you can even see the house that the townhouse, the Newton lived in in those days, still there.
So there's the story of Newton coming up with quite a few ideas during a pandemic.
We're on the outskirts of a pandemic ourselves. Right. And a lot of people use that
example as motivation for everybody while they're in lockdown to get stuff done. So what's that
about? Can you tell the story of that? Well, I can. Let me first say that, of course, we've been
teaching over Zoom lately. There's no Zoom back then. Yeah, there was no zoom back then. All
though, it wouldn't have made much difference because the story was Newton was so
complicated in his lectures that at one point, the Humphrey Newton actually said
that he might as well have just been lecturing to the walls because nobody was
there. Yeah, to listen to it. So what difference? But also not a great teacher, huh?
I if you look at his optical notes, if that's what he's reading from.
Oh, boy.
Okay.
No.
So what can you say about that whole journey through the pandemic that results in so much
innovation, sort of a mod of time?
Well, I mean, there's two times that he goes home. Would he have been able to do it
and do do it if he'd stayed in Cambridge? I think he would have. I don't think it really.
Although I do like to tell my advanced students when I electron the history of physics to the
physics and chemistry students, especially we've been doing it over Zoom the last year,
when we get to Newton and so on, because these kids are, you know, 21, 22,
I like to say, well, you know, when Newton was your age
and he had to go home during an epidemic,
do you know what he produced?
So can you actually summarize this
for people who don't know how old was Newton
and what did he produce?
Well, Newton goes up to Cambridge, as it said,
when he's 18 years old, in the 1660.
And the so-called miraculous year, the Anus Mirabili's, where you get the development
in the calculus and in optical discoveries, especially, is 1666.
Right?
So he's what, 24 years old at the time. But judging from his the notebooks
that I mentioned, he's already before that come to an awful lot of developments over the
previous couple of years. It doesn't have much to do with the fact that he twice went
home. It is true that the optical experiments that we talked of a while ago with the light on the wall moving up and down were done at home.
In fact, you can visit the very room he did it in to this day.
Yeah, it's very cool.
And if you look through the window in that room, there is an apple tree out there in the garden.
So you might be wrong about this.
You're lying to me. Maybe there's an apple vault after all. Well, it's not the same apple tree,
but it's cuttings. They don't last that long, but it's 400 years ago. Oh, not this.
Wow, I continue with the dumbest questions. Okay. So you're saying that perhaps going home was not...
It may have given him an opportunity to work things through.
And after all, he did make use of that room.
And he could do things like put a shade over the window, move things around,
cut holes in it and do stuff.
Probably in his rooms at Cambridge, he may be not, although when he stated Cambridge,
subsequently, became a fellow, and then the first, actually the second Lucaisian professor there,
he was actually really the first one because Isaac Barrow, who was the mathematician,
professor of optics, recognized Newton's genius, gave up
what would have been his position,
because he recognized,
not Newton may not have learned too much from him,
although they did interact.
And so Newton was the first Lucaisian professor, really,
the one that Stephen Hawking held, till he died.
And we know that the rooms that he had there at Cambridge subsequently,
those rooms are still there. He built an all-chemical furnace outside. He did all sorts of stuff in those rooms.
And don't forget you didn't have to do too much as a Lucaisian professor. Every so often you
had to go give these lectures, whether anybody was there or not,
and deposit the notes for the future, which is how we have all those things.
Oh, there were stored and now we have them. And now we know just how terrible the teaching
Newton was.
Yeah, but we know how brilliant these notes are. In fact, the second volume of Newton's of the notes really on the
great book that he published the optics, which he published in 1704, that has just been
finished with full annotations and analysis by the greatest analyst of Newton's optics, Alan Shapiro,
who retired a few years ago at the University of Minnesota and been working on Newton's optics
ever since I knew him and before and I've known him since 1976. Is there something you could say
broadly about either that work on optics or princope yourself as something that I've never actually looked at as a piece of work, is it powerful
in itself or is it just an important moment in history in terms of the amount of inventions
there within, a amount of ideas there within, or is it a really powerful work in itself? Well, it is a powerful work in itself.
You can see this guy coming to grips with and pushing through and working his way around,
complicated and difficult issues melding experimental situations, which nobody had worked with
before, even discovering new things,
trying to figure out ways of putting this together with mathematical structures, succeeding
and failing at the same time.
And we can see him doing that.
I mean, what is contained within Prinkipia?
I don't even know.
In terms of the scope of the work.
All right.
Is it the entirety of the body of work of New York?
No, no, no, no.
The Principia Mathematica is a catalyst.
Well, he, all right.
So the Principia is divided into three books.
Excellent.
Book one contains his version of the laws of motion and the application of those laws to figure out
when a body moves in certain curves and is forced to move in those curves by forces directed
to certain fixed points, what is the nature of the mathematical formula for those forces? That's
all that book 1 is about, and it contains not the kind
of version of the calculus that uses algebra of the sort that I was trying to explain before,
but is done in terms of ratios between geometric line segments when one of the line segments goes very, very small.
It's called a kind of limiting procedure, which is calculus, but it's a geometrically structured,
although it's clearly got algebraic elements in it as well.
And that makes the Principia's mathematical structure rather hard for people who aren't
studying it today to go back to. Book
2 contains his work on what we now call hydrostatics and a little bit about hydrodynamics, a
fuller development of the concept of pressure, which is a complicated concept. And book three applies what he did in book one to the solar system.
And it is successful partially, because the only way that you can exactly solve, the only types of problems you can exactly solve
in terms of the interactions of two particles
governed by gravitational force between them
is for only two bodies.
If there's more than two, let's say it's A, B, and C,
A, X, and B, B, X, and C, C, X, and A,
you cannot solve it exactly. You have to develop techniques. The
fullest sets of techniques are really only developed about 30 or 40 years after Newton's
death by French mathematicians like Laplace. Newton tried to apply his structure to the sun, earth, moon, because the moon's motion is very complicated.
The moon, for instance, exactly repeats its observable position among the stars only every 19 years.
That is, if you look up where the moon is among the stars at certain times, and it changes,
it's complicated. That's, when the stars, at certain times, and it's complicated.
That's by the way, that was discovered,
that was discovered by the Babylonians.
That fact in 19 years.
That was a few years ago, yes.
And then you have the little piece of data
and how do you make sense of it?
What do you mean that, that is data,
and it's complicated.
And it's complicated.
So Newton actually kind of reverse engineered a technique
that had been developed by a man named Horrocks
using certain laws of Kepler's to try and get around this
thing in Newton, then sort of my understanding,
I've never studied this, has reversed it
and fit it together with his forced calculations
by way of an approximation.
and fit it together with his force calculations by way of an approximation.
And I was able to construct a model
to make some predictions.
It fit things backwards pretty well.
Okay, where does data fit into this?
We kind of earlier in the discussion,
mention data as part of the scientific method.
How important was data to Newton?
So like you mentioned Prism and playing with it and looking at stuff and then coming up
with calculations and so on.
What is data fit into any of his ideas?
All right, well, let me say two things.
First, one, we rarely use the phrase scientific method anymore, because there is no one easily
describable such method.
And I mean, humans have been playing around with the world and learning how to repetitively do things
and make things happen ever since, you know, humans became humans.
Do you have a preferred definition of the scientific method? What are the various?
No, I don't. I prefer to talk about the considered manipulation of artificial structures to produce results that can be worked together with schemes to
construct other devices and make predictions, if you will, about the way such things will
work.
So ultimately it's about producing other devices.
It's like leads you down the, I think so, principally.
I mean, you may have data, if you will, like astronomical data obtained otherwise and so on,
but yes, and, but, but, but number two here's this question
of data, what is data in that sense?
See, when we talk about data today,
we have a kind of complex notion,
which reverts to even issues of statistics and measurement
procedures and so on.
So let me put it to you this way.
So let's say I had a ruler in front of me.
Go on.
And it's marked off in little black marks separated by,'s say distances called a millimeter.
Now I make a mark on this piece of paper here. So I made a nice black mark.
Right? Nice black mark. And I ask you I want you to measure that and tell me how long it is.
You're going to take the ruler, you're going to put it next to it, and you're going to put it next to it and you're going to look and it's not going to sit even
if you put one end as close as you can on one black mark, the other end probably isn't
going to be exactly on a black mark.
Well, you'll say it's closer to this or that.
You'll write down a number and I say, okay, take the ruler away a minute.
I take this away, come back in five minutes, put the piece of paper down, do it again. You're going to probably come up with a different number. And you're
going to do that a lot of times. And then if I tell you, I want you to give me your best
estimate of what the actual length of that thing is, what are you going to do? You're going
to average all of these numbers? Why?
Statistics. Well, yes. Statistics.
There's lots of ways of going around it,
but the average is the best estimate on the basis of what's called the central limit theorem.
A statistical theorem. We were talking about things that were not really developed until the 1750s,
60s, and 70s. Newton died in 1727. The intuition perhaps was there. Not really. I'll tell you what
people did, including Newton, although Newton is partially the one exception. We talked a while
ago about this guy, Chris Chen Hoyens. He measured lots lots of things and he was a good mechanic himself.
He and his brother, ground lenses. Hoygens, I told you, developed the first pendulum mechanism,
pendulum driven clock with a mechanism and so on. Also a spring watch where he got into
a controversy with hook over that, by the way. Well, some of these mechanics and the controversy.
Well we also have Huygens' notes.
They're preserved at the Adlyden University in Holland.
He's Dutch for his work in optics, which was extensive.
We don't have time to go into that except the following.
Number of years ago, I went through those things because in this optical theory that he had, there are four numbers
that you've got to be able to get good numbers on to be able to predict other things.
So what would we do today? What in fact was done at the end of the 18th century when somebody went
back to this? You do what you just, I told you to do with the ruler.
You make a lot of measurements and average results.
We have Huygons' notes.
He did make a lot of measurements.
One after the other, after the other.
But when he came to use the numbers for calculations, and indeed when he published things at the
end of his life, he gives you one
number, and it's not the average of any of them. It's just one of them. Which one was it? The one
that he thought he got so good at working by practice that he put down the one he was most confident in.
That was the general procedure at the time.
You wouldn't publish a paper in which you wrote down six numbers and said,
well, I measured this six times, let me put them together.
None of them is really, they would have said, the right number,
but I'll put them together and give you a good number. No, you would have
been thought of that, you know, you don't know what you're doing. Yeah. By the way, there's
just an inkling of value to that approach. Just an inkling. We sometimes use statistics
as like a thing that like, oh, that's all is all the problems. We'll just do a lot of it
and we'll take the average or whatever it is. There's as many excellent books on mathematics have highlighted
the flaws in our approach to certain sciences that rely heavily on statistics.
Okay, let me ask you again for a friend about this alchemy thing. You know, it'd be nice to create gold, but it also seems to come into
play quite a bit throughout the history of science, perhaps in positive ways in terms
of its impact. Can you say something to the history of alchemy?
A little bit. And its impact. Sure. It used to be thought, two things. One, that alchemy, which dates certainly back to the Islamic period,
in Islam, you're talking, you know, picked up strikingly in the 16th century,
1500s and thereabouts, was a sort of mystical procedure involving all sorts of strange notions
and so on. And that's not entirely untrue, but it is substantially untrue. And that all chemists were engaged in what was known as chrysal poia. That
is looking for ways to transform invaluable materials
into valuable ones. But in the process of doing so or attempting to do so, they learned how to create complex amalgams of various kinds.
They used very elaborate apparatus, glass,
olemics in which they would use heat
to produce chemical decomposition.
They would write down and observe these compositions.
And many of the so-called really strange looking chemical formulas and statements where they'll
say something like, I can't produce it, but it'll be the soul of Mars will combine with
the this, et cetera, et cetera.
These, it has been shown are almost all actual formulas for how to engage in the production
of complex amalgams and what to do.
And by the time of Newton, Newton was reading the works of a fellow by the name of Starkey
who was actually, it came from Harvard shortly before, in which things had progressed, if you will,
to the point where the procedure turns into what historians call chrysopoieta, which
basically runs into the notion of thinking that these things are made out of particles.
This is the mechanical philosophy.
Can we engage in processes, chemical processes,
to rearrange these things, which is not so stupid after all.
I mean, we do it, except we happen to do it in reactors,
not in chemical processes, unless, of course,
it had happened that cold fusion had worked, which it didn't.
Not yet.
Well, right. But so that's the way worked, which it didn't. Well, right.
But so that's the way they're thinking about these things.
There's a kind of mix.
And Newton engages extensively in those sorts of manipulations.
In fact, more in that than almost anything else,
except for his optical investigations.
If you look through the latter parts of the 1670s,
the last 5, 6, 7 years or so of that, there's more on that than there is on anything else.
He's not working on mechanics.
He's pretty much gone pretty far in optics.
He'll turn back to optics later on.
So optics in alchemy, so what you're saying is Isaac Newton liked shiny things.
Well actually if you go online and look at what Bill Newman, the professor of Indiana,
at Bloomington, Indiana has produced, you'll find the very shiny thing called the star
regulus, which Newton describes as having produced according to a particular way, which Newman figured out and was able to do it. And it's very shiny. There you go.
Proves the theorem. Can I ask you about God, religion, and its role in Newton's life?
Was there helpful, constructive or destructive influences of religion in his work and in his life.
Well, there you begin to touch on a complex question.
The role that God played would be an interesting question to answer, should one go and be able
to speak with this invisible character who doesn't exist.
But putting that aside for the moment.
Yeah, we don't like to talk about others while they're not here.
Right.
Newton is a deeply religious man, not unusually so, of course, for the assignment.
And clearly his upbringing and perhaps his early experiences have exacerbated that in a number
of ways that he takes a lot of things personally and he finds perhaps solace in thinking about
a sort of governing abstract rulemaking, exacting deity. I think there is little question that his
conviction that you can figure things out has a fair bit to do with his profound belief that this rulemaker doesn't do things arbitrarily.
Newton does not think that miracles have happened since maybe the time of Christ, if then, and
not in the same way.
He was, for instance, an anti-Trinitarian.
He did not hold that Christ had a divine being, but was rather endowed
with certain powers by the rulemaker and whatnot.
And he did not think that some of the tales of the Old Testament with various miracles
and so on occurred in anything like that way.
Some may have some may not have,
like everybody else.
Of course, he did think the creation had happened
about 6,000 years ago.
Wait, really?
Oh, yeah, sure.
Well, biblical chronology can give you a little bit
about that.
That's little controversial, but sure.
Interesting.
Wow.
The deity created the universe 6,000 years ago. And that didn't interfere
with his playing around with the Sun and the Moon and the universe. Oh no, because he's figuring out
he's he's watching the brilliant construction that this perfect entity did 6,000 years ago.
This perfect entity did 6000 years ago.
Yeah, has produced. Plus or minus, a few years.
Well, if you go with Bishop Osher,
it's 4,000, 4 BCE.
Wanna be precise about it.
We always, this is a serious problem.
We always wanna be precise.
Okay, let me ask another ridiculous question.
If Newton were to travel forward in time and
visit with Einstein and have a discussion about space time and general relativity, that
conception of time, that conception of gravity, what do you think that discussion will go like?
Put that way, I think Newton would sit there and shock and say,
I have no idea what you're talking about.
If on the other hand, there's a time machine, you go back and bring a
somewhat younger Newton, not a man, my age, say, I mean, he lived a
long time, you know, into his mid 80s, but take him when he's
in his 40s, let's say, bring him forward and don't immediately introduce him to Einstein.
Let's take him for a ride on a railroad, let him experience the railroad.
Oh, that's right.
Take him around and show him a sparking machine. He knows about sparks. Sending off sparks.
Show him wires. Have him touch the wires and get a little shock. Show him a clicking
telegraph machine of the kind. Then let him hear the clicks in a telephone receiver and so on.
Do that for a couple of months.
Let him get accustomed to things.
Then take him into, not Einstein yet, let's say we're taking him into the 1890s.
Einstein is a young man.
We take him into some of the laboratories.
We show him some of the equipment, the devices, not the
most elaborate ones. We show him certain things. We educate him bit by bit.
No, the optics, maybe focus on that. Certainly. You begin to show him things. He's
a brilliant human being. I think bit by bit, he would begin to see what's going on. But if you just dumped him in front
of Einstein, he'd sit there as eyes would glaze over.
I mean, it's almost a question of how big of a leap, how many leaps I've been taken
in science that go from Newton to Einstein. We sometimes in a compressed version of history think that not much. Oh, that's totally wrong. A lot,
huge amounts in multi-ferious ways involving fundamental conceptions, mathematical structures,
the evolution of novel experimentation and devices, the organization, everything, everything.
I mean, to a point where I wonder, even if Newton was like, he said 40, but even like 30, so he's very,
like, if you would be able to catch up with a conception of everything, I wonder as a scientist how much you load in from age five about this world
in order to be able to conceive of the world of ideas that push that science forward. I mean,
you mentioned the railroad and all those kinds of things. That we might that might be fundamental
to our ability to invent even when it doesn't directly obviously seem relevant.
Well, yes. I mean, the railroad, the steam engine, the watt engine, etc. I mean, that was really
the watt engine, you know, was developed pretty, although what new Joseph Black, a chemist, scientist, so on, did stuff
on heat, was developed pretty much independently of the developing thoughts about heat at the
time.
But what it's not independent of is the evolution of practice in the manufacture and construction of devices which can do things in extraordinarily
novel ways and the premium being gradually placed on calculating how you can make the more
efficient.
That is of a piece with a way of thinking about the world in which you're controlling things
and working it. It's something that, you know,
humans have been doing for a long time, but in this more concerted and structured way, I think you
really don't find it in the fullest sense until well into the 1500s and really not fully until the
well into the 1500s and really not fully until the 17th century later on.
So Newton had this year of miracles.
I wonder if I could ask you briefly about Einstein and his year of miracles. I've been reading, I'm rereading, revisiting the brilliance of the papers that Einstein published in the year 1905,
one of which one on the Nobel Prize, the photoelectric effect, but also Brianion motion,
special theory of relativity, and of course the old E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E. E Is there, does that make sense to you that these two figures had such productive years
that there's this moment of genius?
Maybe if we zoom out, I mean, my work is very much an artificial intelligence, sort of
wondering about the nature of intelligence, like how did we, how did evolution on earth produce genius that could come
up with so much in so little time?
To me that gives me hope that one person can change the world in such a small amount of
time.
Well, of course, there are precedents for in both Newton's and Einstein's cases for elements of what we're finding there
is, you know, and so on.
Well, I have no idea.
You know, I'm sure you must have read.
It was kind of a famous story that after Einstein died, he donated his brain and they sliced
it up to see if they could find something unusual there, nothing unusual visibly in there.
So I have...
Clearly, there are people who, for various reasons,
maybe both intrinsic and extrinsic in the sense of experience and so on,
are capable of coming up with these extraordinary results.
Many years ago, when I was a student, friend of mine came in and said, did you read about?
Did you read this?
I forget what?
Anyway, there was a story in the paper.
It was about, I think it was a young woman who was, she couldn't speak. and she was somewhere on the autism spectrum. She could not read
other people's affect in any way. But she could sit down at a piano and having heard it once and then run variations on the most complex pianistic works of Chopin and others.
Right now how?
Some aspect of our mind is able to tune in and some aspect of reality and become a master of it.
And every once in a while that means reality and become a master of it. And every once
in a while, that means coming up with breakthrough ideas and physics.
Yeah, how the heck does that happen? Who knows?
Yeah, I'd like to say thank you so much for spending your valuable time with me today.
I was really fascinated conversation. I've learned so much about Isaac Newton, who is one of
the most fascinating figures in human history. So thank you so much for talking to me. A pleasure and joy to very much
Thanks for listening to this conversation with Jed Buckwald to support this podcast
Please check out our sponsors in the description and now let me leave you some words from Thomas Coon a
philosopher of science
The answers you get depend on the questions you ask.
Thank you.