Lex Fridman Podcast - #433 – Sara Walker: Physics of Life, Time, Complexity, and Aliens
Episode Date: June 13, 2024Sara Walker is an astrobiologist and theoretical physicist. She is the author of a new book titled "Life as No One Knows It: The Physics of Life's Emergence". Please support this podcast by checking o...ut our sponsors: - Notion: https://notion.com/lex - Motific: https://motific.ai - Shopify: https://shopify.com/lex to get $1 per month trial - BetterHelp: https://betterhelp.com/lex to get 10% off - AG1: https://drinkag1.com/lex to get 1 month supply of fish oil Transcript: https://lexfridman.com/sara-walker-3-transcript EPISODE LINKS: Sara's Book - Life as No One Knows It: https://amzn.to/3wVmOe1 Sara's X: https://x.com/Sara_Imari Sara's Instagram: https://instagram.com/alien_matter 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 (10:40) - Definition of life (31:18) - Time and space (42:00) - Technosphere (46:25) - Theory of everything (55:06) - Origin of life (1:16:44) - Assembly theory (1:32:58) - Aliens (1:44:48) - Great Perceptual Filter (1:48:45) - Fashion (1:52:47) - Beauty (1:59:08) - Language (2:05:50) - Computation (2:15:37) - Consciousness (2:24:28) - Artificial life (2:48:21) - Free will (2:55:05) - Why anything exists
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The following is a conversation with Sarah Walker,
her third time on this podcast.
She is an astrobiologist and theoretical physicist
interested in the origin of life
and in discovering alien life on other worlds.
She has written an amazing new upcoming book
titled Life as No One Knows It,
The Physics of Life's Emergence.
This book is coming out on August 6th, so please go pre-order it now.
It will blow your mind.
And now a quick few second mention of each sponsor.
Check them out in the description.
It's the best way to support this podcast.
We got Notion for Notes, Motific for LLM Deploy Shopify for ecommerce, BetterHelp for mental health,
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slash contact.
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but I scrolled past it, and I regret it.
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that actually works, but I wish there was a way
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And now, dear friends, here's Sarah Walker.
You open the book, Life as No One Knows It, The Physics of Life's Emergence,
with a distinction between the materialists
and the vitalists.
So what's the difference?
Can you maybe define the two?
I think the question there is about whether life
can be described in terms of matter and physical things,
or whether there is some other feature that's
not physical that actually animates living things.
So for a long time, people maybe have called that a soul.
It's been really hard to pin down what that is.
So I think the vitalist idea is really that it's kind of a dualistic interpretation,
that there's sort of the material properties
but there's something else that animates life
that is there when you're alive
and it's not there when you're dead.
And materialists kind of don't think that there's anything
really special about the matter of life
and the material substrates that life is made out of.
So they disagree on some really fundamental points.
Is there a gray area between the two?
Like maybe all there is is matter, but there's so much we don't know
that it might as well be magic that like whatever that magic that the vital is see.
Meaning like there's just so much mystery that it's really unfair
to say that it's boring and understood and as simple
as quote unquote physics.
Yeah, I think the entire universe is just a giant mystery.
I guess that's what motivates me as a scientist.
And so oftentimes when I look at open problems like the nature of life or consciousness or
what is intelligence or are there souls or whatever question that we have
that we feel like we aren't even on the tip of answering yet, I think, you know, we
have a lot more work to do to really understand the answers to these questions.
So it's not magic, it's just the unknown.
And I think a lot of the history of humans coming to understand the world around us has
been taking ideas that we once thought
were magic or supernatural and really understanding them
in a much deeper way that we learn what those things are
and they still have an air of mystery
even when we understand them.
There's no sort of bottom to our understanding.
So do you think the vitalists have a point
that they're more eager and able
to notice the magic of life?
I think that no tradition, vitalists included,
is ever fully wrong about the nature
of the things that they're describing.
So a lot of times when I look at different ways
that people have described things across human history,
across different cultures,
there's always a seed of truth in them.
And I think it's really important to try to look for those
because if there are narratives
that humans have been telling ourselves
for thousands of years, for thousands of generations,
there must be some truth to them.
We've been learning about reality for a really long time
and we recognize the patterns that
reality presents us.
We don't always understand what those patterns are.
And so I think it's really important to pay attention to that.
So I don't think the vitalists were actually wrong.
And a lot of what I talk about in the book, but also I think about a lot just professionally,
is the nature of our definitions of what's material and how science has come
to invent the concept of matter and that some of those things actually really are inventions
that happened in a particular time in a particular technology that could learn about certain
patterns and help us understand them and that there are some patterns we still don't understand. And if we knew how to measure those things
or we knew how to describe them in a more rigorous way,
we would realize that the material world matter
has more properties than we thought that it did.
And one of those might be associated
with the thing that we call life.
Life could be a material property
and still have a lot of the features
that the vitalists thought were mysterious.
So we may still expand our understanding
what is incorporated in the category of matter
that will eventually incorporate such magical things
that the vitalists have noticed like life.
Yeah, so I think about,
I always like to use examples from physics,
so I'll probably do that to like, like it do that. It's just my go-to place.
But in the history of gravitational physics, for example, in the history of motion, when
Aristotle came up with his theories of motion, he did it by the material properties he thought
things had.
So there was a concept of things falling to Earth because they were solid-like and things
raising to the heavens because they were solid-like and things raising
to the heavens because they were air-like
and things moving around the planet
because they were celestial-like.
But then we came to realize that thousands of years later
and after the invention of many technologies
that allowed us to actually measure time
in a mechanistic way and track planetary motion,
and we could roll balls down
and climb planes and track that progress,
we realized that if we just talked about mass
and acceleration, we could unify all motion in the universe
in a really simple description.
So we didn't really have to worry about the fact
that my cup is heavy and the air is light,
like the same laws describe them,
if we have the right material properties
to talk about what those
laws are actually interacting with. And so I think the issue with life is we don't know how to think
about information in a material way. And so we haven't been able to build a unified description
of what life is or the kind of things that evolution builds because we haven't really invented
the right material concept yet.
So when talking about motion, the laws of physics
appear to be the same everywhere in the universe.
You think the same is true for other kinds of matter
that we might eventually include life in?
I think life obeys universal principles.
I think there is some deep underlying explanatory framework
that will tell us about the nature of life in the universe
and will allow us to identify life
that we can't yet recognize because it's too different.
You write about the paradox of defining life.
Why does it seem to be so easy
and so complicated at the same time?
All the sort of classic definitions people want to use
just don't work.
They don't work in all cases.
So Carl Sagan had this wonderful essay
on definitions of life where I think he talks about
aliens coming from another planet.
If they saw Earth, they might think that cars were the dominant life form because there's so many of them on our planet. And
like humans are inside them and you might want to exclude machines. But any definition,
you know, like classic biology textbook definitions would also include them. And so, you know,
he wanted to draw a boundary between these kinds of things by trying to exclude them,
but they were naturally included by
the definitions people want to give.
And in fact, what he ended up pointing out is that all of the definitions of life that
we have, whether it's life is a self-reproducing system or life eats to survive or life requires
compartments, whatever it is, there's always a counter example that challenges that definition.
This is why viruses are so hard or why fire is so hard.
And so we've had a really hard time trying to pin down
from a definitional perspective exactly what life is.
Yeah, you actually bring up the zombie and fungus.
I enjoyed looking at this thing.
As an example of one of the challenges,
you mentioned viruses, but this is a parasite.
Look at that.
Did you see this in the jungle?
Infects ants.
Actually, one of the interesting things about the jungle,
that everything is ephemeral,
like everything eats everything really quickly.
So if an organism dies, that organism disappears.
Is it? Yeah.
It's a machine that doesn't have,
I wanted to say it doesn't have a memory or a history,
which is interesting,
given your work on history in defining a living being.
The jungle forgets very quickly.
It wants to erase the fact that you existed very quickly.
Yeah, but it can't erase it, it's just restructuring it.
And I think the other thing that is really, you know, vivid to me about this example that you existed very quickly. Yeah, but it can't erase it, it's just restructuring it. And I think the other thing that is really vivid to me
about this example that you're giving
is how much death is necessary for life.
So I worry a bit about notions of immortality
and whether immortality is a good thing or not.
So I have sort of a broad conception
that life is the only thing the universe generates
that actually has even the potential to be immortal. But that's as like this sort of
process that you're describing where life is about memory and historical contingency
and construction of new possibilities. But when you look at any instance of life, especially
one as dynamic as what you're describing, it's a constant birth and death process. But that birth and death process is like the way
that the universe can explore what possibilities can exist
and not everything, not every possible human
or every possible ant or every possible zombie ant
or every possible tree will ever live.
So it's an incredibly dynamic and creative place
because of all that death.
So does this thing, this is a parasite that needs the ant.
So is this a living thing or is this not a living thing?
So this is, it just pierces the ant.
I mean, it.
Right.
And I've seen a lot of this, by the way,
organisms working together in the jungle,
like ants protecting a delicious piece of fruit.
So they need the fruit, but if you touch that fruit,
they're going to, the forces emerge.
They're fighting you, they're defending that food
to the death.
It's just nature seems to find mutual benefits, right?
Yeah, it does.
I think the thing that's perplexing for me
about these kind of examples is, you know,
effectively the ant's dead, but it's staying alive now
because it's piloted by this fungus.
And so that gets back to this, you know,
thing that we were talking about a few minutes ago
about how the boundary of life is really hard to define.
So, you know, anytime that you wanna draw a boundary
around something and you say,
this feature is the thing that makes this alive or this thing is alive on its own,
there's not ever really a clear boundary.
And these kind of examples are really good at showing that because it's like the thing that you would have thought is the living organism is now dead,
except that it has another living organism that's piloting it. So the two of them together are alive in some sense, but they're now in this kind of weird symbiotic
relationship that's taking this ant to its death.
So what do you do with that in terms of when you try to define life?
I think we have to get rid of the notion of an individual as being relevant. And this
is really difficult because a lot of the ways that we think about life,
like the fundamental unit of life is the cell, individuals are alive,
but we don't think about how gray that distinction is.
So, for example, you might consider, you know,
self-reproduction to be the most defining feature of life.
A lot of people do actually, like one of these standard different definitions
that a lot of people may feel like to use in astrobiology
is life is a self-sustaining chemical system
capable of Darwinian evolution,
which I was once quoted as agreeing with,
and I was really offended
because I hate that definition.
I think it's terrible.
And I think it's terrible that people use it.
I think like every word in that definition
is actually wrong as a descriptor of life.
Life is a self-sustaining chemical system capable
of Darwinian evolution.
Why is that?
That seems like a pretty good definition.
Yeah, I know.
If you wanna make me angry, you can pretend I said that.
Oh, and believed it.
So self-sustaining chemical system, Darwinian evolution.
What is self-sustaining?
What's so frustrating?
I mean, which aspect is frustrating to you?
But it's also those very interesting words.
Yeah, they're all interesting words.
And you know, together they sound really smart
and they sound like they box in what life is,
but you can use any of the words individually
and you can come up with counter examples
that don't fulfill that property.
The self-sustaining one is really interesting,
thinking about humans, right? Like we're not self-sustaining one is really interesting, thinking about humans, right?
Like we're not self-sustaining, we're dependent on societies.
And so, you know, I find it paradoxical that, you know,
it might be that societies,
because they're self-sustaining units,
are now more alive than individuals are.
And that could be the case,
but I still think we have some property
associated with life.
I mean, that's the thing that we're trying to describe. So that one's quite hard. And in general, you
know, no organism is really self-sustaining. They always require an environment. So being
self-sustaining is coupled in some sense to the world around you. We don't live in a
vacuum. So that part's already challenging. And then you can go to chemical system.
I don't think that's good either.
I think there's a confusion because life emerges
in chemistry, that life is chemical.
I don't think life is chemical.
I think life emerges in chemistry because chemistry
is the first thing the universe builds
where it cannot exhaust all the possibilities
because the combinatorial space of chemistry is too large.
Well, but is it possible to have a life that is not a chemical system?
Yes.
Well, there's a guy I know named Lee Cronin has been on a podcast a couple of times who
just got really pissed off listening to this.
I know, I was like, what a coincidence.
He probably just got really pissed off hearing that.
For people who somehow don't know, he's a chemist.
Yeah, but he would agree with that statement. Would he?
I don't think he would.
I don't think he would.
He would broaden the definition of chemistry
until it would include everything.
Oh, sure.
Okay, so you're-
Or maybe, I don't know.
But wait, but you said that universe,
that's the first thing it creates is chemistry.
Where the, very precisely,
it's not the first thing it creates, obviously,
like it has to make atoms first,
but it's the first thing.
Like if you think about, you think about the universe originated,
atoms were made in Big Bang nuclear synthesis,
and then later in stars, and then planets formed,
and planets become engines of chemistry.
They start exploring what kind of chemistry is possible,
and the combinatorial space of chemistry is so large that even on every planet in the
entire universe, you will never express every possible molecule. I like this example actually
that Lee gave me, which is to think about taxol. It has a molecular weight of about
853. It's got a lot of atoms, but it's not astronomically large. And if you tried to make one molecule with that molecular formula in every three-dimensional
shape you could make with that molecular formula, it would fill 1.5 universes in volume.
So with one unique molecule.
That's just one molecule.
So chemical space is huge.
And I think it's really important to recognize that
because if you wanna ask a question
of why does life emerge in chemistry,
well, life emerges in chemistry
because life is the physics of how the universe selects
what gets to exist.
And those things get created
along historically contingent pathways and memory
and all the other stuff that we can talk about.
But the universe has to actually make
historically contingent choices in chemistry
because it can't exhaust all possible molecules.
What kind of things can you create
that's outside the combinatorial space of chemistry?
That's what I'm trying to understand.
Oh, if it's not chemicals.
So I think some of the things that have evolved
on our biosphere, I would call as much alive as
chemistry as a cell
But they seem much more abstract. So for example, I think language is alive. I think
Or at least life. I
Think memes are I think you're saying language is life. Yeah, language is alive. Oh boy. I'm gonna have to explore that one
Language is life. Yes.
Language is alive.
Oh boy, I'm going to have to explore that one.
Life maybe not alive, but I actually don't know where I stand exactly on that.
I've been thinking about that a little bit more lately, but mathematics too.
It's interesting because people think that math has this platonic reality that exists
outside of our universe, and I think it's a feature of our biosphere and it's telling us
something about the structure of ourselves. And I find that really interesting because when you
would sort of internalize all of these things that we noticed about the world and you start asking,
well, what do these look like if I was, you know, something outside of myself observing
these systems that we're all embedded in, what would that structure look like?
And I think we look really different
than the way that we talk about
what we look like to each other.
What do you think a living organism in math is?
Is it one axiomatic system or is it individual theorems?
Or is it individual steps of-
I think it's the fact that it's open-ended in some sense.
It's another open-ended combinatorial space and the recursive properties
of it allow creativity to happen, which is what you see with the revolution in the last century
with Gödel's theorem and Turing. There's clear places where mathematics notices holes in the
universe.
It seems like you're sneaking up on a different definition of life.
Open-ended, large combinatorial space, room for creativity.
Definitely not chemical.
I mean, chemistry is one substrate.
It's restricted to chemical.
What about the third thing,
which I think will be the hardest because you probably like it the most
is evolution or selection.
Well, specifically it's Darwinian evolution.
And I think Darwinian evolution is a problem,
but the reason that that definition is a problem
is not because evolution is in the definition,
but because the implication is that,
you know, that most people would wanna make
is that an individual is
alive. And the evolutionary process, at least the Darwinian evolutionary process, most evolutionary
processes, they don't happen at the level of individuals, they happen at the level of
populations. So again, you would be saying something like what we saw with the self-sustaining
definition, which is that populations are alive, but individuals aren't, because populations evolve and individuals don't.
And obviously like maybe you're alive
because your gut microbiome is evolving,
but Lex as an entity right now
is not evolving by canonical theories of evolution.
In assembly theory, which is attempting to explain life,
evolution is a much broader thing.
So an individual organism can evolve
under assembly theory?
Yes, you're constructing yourself all the time.
Assembly theory is about construction
and how the universe selects for things to exist.
What if you were to formulate everything
like a population is a living organism?
That's fine too.
But this again gets back to,
so I think what all of the,
like we can nitpick at definitions.
I don't think it's like incredibly helpful to do it,
but the reason for me-
It's fun.
Yeah, it is fun.
It is really fun.
And actually I do think it's useful in the sense
that when you see the ways that they all break down,
you either have to keep forcing in your like sort of
conception of life you want to have,
or you have to say all these definitions are breaking down for a reason, maybe I should adopt a more expansive
definition that encompasses all the things that I think are life.
And so for me, I think life is the process of how information structures matter over
time and space.
And an example of life is what emerges on a planet and yields an open-ended
cascade of generation of structure and increasing complexity. And this is the thing that life is.
And any individual is just a particular instance of these lineages that are structured across time.
And so we focus so much on these individuals
that are these short temporal moments
in this larger causal structure
that actually is the life on our planet.
And I think that's why these definitions break down
because they're not general enough,
they're not universal enough, they're not deep enough,
they're not abstract enough
to actually capture that regularity.
Because we're focused on those,
that little ephemeral thing that we call human life.
Aristotle focusing on, you know,
heavy things falling because they're earth-like
and, you know, things floating because they're air-like.
It's the wrong thing to focus on.
So what exactly are we missing by focusing on
at such a short span of time?
I think we're missing most of what we are.
So one of the issues, I've been thinking about this
all like really viscerally lately,
it's weird when you do theoretical physics
because I think it like literally changes
the structure of your brain.
And you see the world differently,
especially when you're trying to build new abstractions.
Do you think it's possible if you're a theoretical physicist
like it's easy to fall off the cliff
and go descend into madness? I mean, I think you're always on physicist, like it's easy to fall off the cliff and go descend into madness?
I mean, I think you're always on the edge of it,
but I think what is amazing about being a scientist
and trying to do things rigorously is it keeps your sanity.
So I think if I wasn't a theoretical physicist,
I would be probably not sane.
But what it forces you to do is hold the fire,
like you have to hold yourself to the fire of like,
these abstractions in my mind
have to really correspond to reality.
And I have to really test that all the time.
And so I love building new abstractions
and I love going to those like incredibly creative,
you know, spaces that people don't see
as part of the way that we understand the world now.
But ultimately, I have to make sure
that whatever I'm pulling from that space
is something that's really usable
and really relates to the world outside of me.
That's what science is.
So we were talking about what we're missing
when we look at a small stretch of time
and a small stretch of space.
Yeah, so the issue is we evolve perception
to see reality a certain way, right?
So for us, space is really important
and time feels fleeting.
And I had a really wonderful mentor, Paul Davies,
most of my career, and Paul's amazing
because he gives these little seed thought experiments
all the time, like something he used to ask me all the time when I was a postdoc,
this is kind of a random tangent,
but was how much of the universe could be converted into technology?
If you were thinking about long-term futures and stuff like that.
It's like a weird thought experiment,
but there's a lot of deep things there.
I do think a lot about the fact that we're really limited in
our interactions with reality by the particular architectures that we evolved and so we're not seeing everything and
in fact our technology tells us this all the time because it allows us to see the
world in new ways by basically allowing us to perceive the world in ways that we
couldn't otherwise. And so what I'm getting at with this is I think that
living objects are actually huge.
Like, they're some of the biggest structures in the universe,
but they are not big in space, they are big in time.
And we actually can't resolve that feature,
we don't interact with it on a regular basis,
so we see them as these fleeting things
that have this really short temporal clock time
without seeing how large they are.
When I'm saying time here, I really like the way
that people could picture it is in terms
of causal structure.
So if you think about the history of the universe
to get to you and you imagine that that entire history
is you, that is the picture I have in my mind
when I look at every living thing.
So you have a tweet for everything.
You tweeted.
Doesn't everyone?
You have a lot of poetic, profound tweets.
Sometimes they're puzzles
that take a long time to figure out.
Well, you know what the trick is?
The reason they're hard to write
is because it's compressing a very deep idea
into a short amount of space.
And I really like doing that intellectual exercise
because I find it productive for me.
Yeah, it's a very interesting kind of compression algorithm.
Yeah, I like language.
I think it's really fun to play with.
Yeah, I wonder if AI can decompress it.
That'd be interesting.
I think I would like to try this,
but I think I use language in certain ways
that are non-canonical and I do it very purposefully.
And it would be interesting to me
how AI would interpret it.
Yeah, your tweets would be a good touring test
for super intelligence.
Anyway, you tweeted that things only look emergent
because we can't see time.
So if we could see time, what would the world look like?
You're saying you'll be able to see everything So if we could see time, what would the world look like?
You're saying you'll be able to see everything
that an object has been, every step of the way
that led to this current moment,
and all the interactions that required
to make that evolution happen.
You would see this gigantic tale.
The universe is far larger in time than it is in space.
Yeah.
And this planet is one of the biggest things
in the universe.
Also the more complexity, the bigger the object.
Yeah, technosphere, I think the modern technosphere
is the largest object in time in the universe that we know about.
And when you say technosphere, what do you mean?
I mean the global integration of life
and technology on this planet.
So all the technological things we've created?
Mm-hmm, but I don't think of them as separate.
They're like very integrated with the structure
that generated them.
So you can almost imagine it,
like time is constantly bifurcating and it's generating new structures
and these new structures are, you know,
locally constructing the future.
And so things like you and I are very close together in time
because we didn't diverge like very early
in the history of the universe, it's very recent.
And I think this is one of the reasons
that we can understand each other so well
and we can communicate effectively.
And I might have some sense of what it feels like to be you,
but other organisms bifurcated from us in time earlier,
this is just the concept of phylogeny, right?
But if you take that deeper and you really think about that
as the structure of the physics that generates life and you take that deeper and you really think about that as the structure of the physics
that generates life and you take that very seriously, all of that causation is still
bundled up in the objects we observe today.
So you and I are close in this temporal structure, but we're also,
we're so close because we're really big
and we only are very different
and sort of like the most recent moments
in the time that's like embedded in us.
It's hard to use words to visualize what's in minds.
I have such a hard time with this sometimes.
I'm like, I like, I actually was thinking in the way
over here, I was like, I like, you know, you have pictures in your brain
and then they're hard to put into words.
But I realized, I always say I have a visual,
but it's not actually I have a visual,
it's I have a feeling.
Because oftentimes I cannot actually draw a picture
in my mind for the things that I say,
but sometimes they go through a picture
before they get to words.
But I like experimenting with words because I think they help paint pictures.
Yeah. It's again,
some kind of compressed feeling that you can query to get a,
a sense of the bigger visualization that you have in mind.
It's just a really nice compression,
but I think the idea of this object that in it
contains all the information about the history
of identity that you see now, just trying to visualize that is pretty cool.
Yeah.
It's, I mean, obviously the mind breaks down quickly as you step seconds and minutes back in time.
Yeah, for sure.
I guess it's just a gigantic object
that we're supposed to be thinking about.
Yeah, I think so.
And I think this is one of the reasons
that we have such an ability to abstract as humans
because we are so gigantic that the space
that we can go back into is really large.
So the more abstract you're going,
the deeper you're going in that space.
But in that sense, aren't we fundamentally all connected?
Yes, and this is why the definition of life
cannot be the individual.
It has to be these lineages,
because they're all connected, they're interwoven,
and they're exchanging parts all the time.
Yeah, so maybe there's certain aspects of those lineages
that can be lifelike, they can be characteristics,
they can be measured, like with the Sunbeam theory,
that have more or less life.
But they're all just fingertips of a much bigger object.
I think life is very high dimensional.
And in fact, I think you can be alive in some dimensions
and not in others.
Like if you could project all the causation that's in you,
in some features of you, very little causation is required,
very little history, and in some features a lot is.
So it's quite difficult to take this really high-dimensional,
very deep structure and project it into things
that we really can understand and say,
this is the one thing that we're seeing,
because it's not one thing.
It's funny we're talking about this now,
and I'm slowly starting to realize,
one of the things I saw when I took ayahuasca,
afterwards actually, so the actual ceremony
is four or five hours, but afterwards you're still riding
whatever the thing that you're riding,
and I got a chance to afterwards hang out with some friends
and just shoot the shit in the forest.
And I get to see their faces.
And what was happening with their faces and their hair
is I would get this interesting effect.
First of all, everything was beautiful
and I just had so much love for everybody.
But I could see their past selves behind them.
It was this effect where, I guess it's a blurring effect
of where if I move like this,
the faces that were just there are still there
and it would just float like this these
Behind them which will create this incredible effect, but it's also another way to think about that is I'm visualizing a
Little bit of that object of the thing they wore just a few seconds ago. Yeah, it's a cool little effect
That's very cool. And now it's like giving it a bit more profundity
To the effect that was just beautiful aesthetically And now it's like giving it a bit more profundity
to the effect that was just beautiful aesthetically,
but it's also beautiful from a physics perspective
because that is a past self.
I get a little glimpse at the past selves that they were,
but then you take that to its natural conclusion,
not just a few seconds ago,
but just to the beginning of the universe.
And you can probably get to that.
Billions of years, yeah.
Get down that lineage.
It's crazy that there's billions of years inside all of us.
All of us.
Yeah.
And then we connect, obviously.
Yeah.
Not too long ago.
Yeah.
You mentioned just the technosphere,
and you also wrote that the most alive thing
on this planet is our technosphere.
Why is the technology we create a kind of life form?
Why are you seeing it as life?
Because it's creative, but with us, obviously,
not independently of us, and also because
of this lineage view of life, and I think about life
often as a planetary scale phenomena,
because that's sort of the natural boundary for all
of this causation that's bundled in every object
in our biosphere.
And so for me, it's just sort of the current boundary
of how far life on our planet has pushed into the things
that our universe can generate.
And so it's the furthest thing, it's the biggest thing.
And I think a lot about the nature of life
across different scales.
And so, you know, we have cells inside of us that are alive
and we feel like we're alive,
but we don't often think about the societies
that we're embedded in as alive
or a global scale organization of us and our technology on the in as alive or a global scale organization
of us and our technology on the planet as alive.
But I think if you have this deeper view
into the nature of life, which I think is necessary also
to solve the origin of life,
then you have to include those things.
All of them.
So you have to simultaneously think about life
at every single scale, the planetary
and the bacteria level.
Yeah, this is the hard thing about solving
the problem of life, I think, is how many things
you have to integrate into building a sort of a
unified picture of this thing that we wanna call life.
And a lot of our theories of physics are built on
building deep regularities that explain
a really broad class of phenomenon. I think we haven't really traditionally thought about life
that way. But I think to get at some of these hardest questions, like looking for life on other
planets or the origin of life, you really have to think about it that way. And so most of like,
my professional work is just trying to understand like every single thing on this planet
That might be an example of life, which is pretty much everything and then trying to figure out like what's the deeper structure underlying that?
Yeah, shorting or wrote the living matter while not alluding the laws of physics is established up to date is likely to involve other laws of physics
Here there are two unknown so to him to involve other laws of physics hitherto unknown.
So to him.
I love that quote.
There was a sense that at the bottom of this
are new laws of physics that could explain
this thing that we call life.
Yeah, Schrodinger really tried to do
what physicists try to do, which is explain things.
And his attempt was to try to explain life
in terms of non-equilibrium physics
because he thought that was the best description
that we could generate at the time.
And so he did come up with something really insightful,
which was to predict the structure of DNA
as an aperiodic crystal.
And that was for a very precise reason that, you know, that was the only kind of physical
structure that could encode enough information to actually specify a cell.
We knew some things about genes, but not about DNA and its actual structure when he proposed
that.
But in the book, he tried to explain life as kind of going against entropy.
And so some people talked about it as like Schrodinger's paradox, how can life persist
when the second law of thermodynamics is there. But in open systems that's not so problematic.
And really the question is, why can life generate so much order? And we don't have a physics to
describe that. And it's interesting, you know,
generations of physicists have thought about this problem.
Oftentimes it's like when people are retiring,
they're like, oh, now I can work on life.
Or they're like more senior in their career
and they've worked on other more traditional problems.
And there's still a lot of impetus in the physics community
to think that non-equilibrium physics will explain life.
But I think that's not the right approach.
I don't think ultimately the solution
to what life is is there,
and I don't really think entropy has much to do with it
unless it's entirely reformulated.
Well, because you have to explain how interesting order,
how complexity emerges from the soup.
Yes, from randomness.
From randomness.
Physics currently can't do that.
No, physics hardly even acknowledges that the universe is random at its base. Yes, from randomness. From randomness. Physics currently can't do that.
No.
Physics hardly even acknowledges that the universe is random at its base.
We like to think we live in a deterministic universe and everything's deterministic,
but I think that's probably an artifact of the way that we've written down laws of physics
since Newton invented modern physics and his conception of motion and gravity,
which he formulated laws that had initial conditions
and fixed dynamical laws.
And that's become the standard canon of how
people think the universe works and how
we need to describe any physical system
is with an initial condition and a law of motion.
And I think that's not
actually the way the universe really works. I think it's a good approximation for the kind
of systems that physicists have studied so far. And I think it will radically fail in the long
term at describing reality at its more basal levels. I'm not saying there's a base. I don't
think that reality has a ground. And I don't think there's a base, I don't think that reality has a ground.
And I don't think there's a theory of everything.
But I think there are better theories
and I think there are more explanatory theories
and I think we can get to something that explains
much more than the current laws of physics do.
When you say theory of everything,
you mean like everything, everything.
Yeah, you know, like in physics right now,
it's really popular to talk about theories of everything.
So string theory is supposed to be a theory of everything
because it unifies quantum mechanics and gravity.
And people have their different pet theories of everything.
And the challenge with a theory of everything,
I really love this quote from David Krakauer,
which is a theory of everything is a theory of everything
except those things that theorize.
Oh, you mean removing the observer from the thing.
Yeah, but it's also weird because if a theory
of everything explained everything,
it should also explain the theory.
So the theory has to be recursive.
And none of our theories of physics are recursive.
So it's a weird concept.
Yeah, but it's very difficult to integrate
the observer into a theory.
I don't think so.
I think you can build a theory acknowledging
that you're an observer inside the universe.
But doesn't it become recursive in that way?
And that's, you're saying it's possible to make a theory
that's okay with that?
I think so.
I mean, I don't think, there's always gonna be
the paradox of another meta level you could build
on the meta level, right?
So like if you assume this is your universe
and you're the observer outside of it,
you have some meta description of that universe,
but then you need a meta description
of you describing that universe, right?
So, you know, this is one of the biggest challenges
that we face being observers inside our universe
and also, you know, why the paradoxes
and the foundations of mathematics
and any place that we try to have observers in the system
or a system describing itself show up.
But I think it is possible to build a physics
that builds in those things intrinsically
without having them be paradoxical
or have holes in the descriptions.
And so one place I think about this quite a lot,
which I think can give you sort of a more concrete example, is the nature of what we call fundamental.
So we typically define fundamental right now in terms of the smallest indivisible units of matter.
So again, you have to have a definition of what you think material is and matter is.
But right now, what's fundamental or elementary particles?
And we think they're fundamental
because we can't break them apart further.
And obviously we have theories like string theory
that if they're right, would replace the current description
of what's the most fundamental thing in our universe
by replacing it with something smaller.
But we can't get to those theories
because we're technologically limited.
And so if you look at this from a historical perspective
and you think about explanations changing
as physical systems like us learn more about the reality
in which they live, we once considered atoms
to be the most fundamental thing.
And it literally comes from the word indivisible.
And then we realized atoms had substructure because we built better technology which allowed us to
quote-unquote see the world better and resolve smaller features of it and then
we built even better technology which allowed us to see even smaller
structure and get down to the standard model particles and we think that there
might be structure below that but we can't get there yet with our technology. So what's fundamental, the way we talk about it
in current physics is not actually fundamental.
It's the boundaries of what we can observe in our universe,
what we can see with our technology.
And so if you wanna build a theory that's about us
and about what's inside the universe that we can observe, about what's inside the universe
that we can observe, not what's at the boundary of it.
You need to talk about objects that are in the universe
that you can actually break apart to smaller things.
So I think the things that are fundamental
are actually the constructed objects.
They're the ones that really exist
and you really understand their properties
because you know how the universe constructed them
because you can actually take them apart.
You can understand the intrinsic laws that built them.
But the things at the boundary are just at the boundary.
They're evolving with us and we'll learn more about that structure as we go along.
But really if we want to talk about what's fundamental inside our universe, we have to
talk about all these things that are traditionally considered emergent, but really just structures
in time that have causal histories that constructed them
and are really actually what our universe is about.
So we should focus on the construction methodology
as the fundamental thing.
Do you think there's a bottom to the smallest possible thing
that makes up the universe?
I don't see one.
And it'll take way too long.
It'll take longer to find that than it will
to understand the mechanism that created life.
I think so, yeah.
I think for me, the frontier in modern physics,
where the new physics lies,
is not in high energy particle physics,
it's not in quantum gravity,
it's not in any of these sort of traditionally sold,
this is gonna be the newest, deepest insight we have
into the nature of reality.
It is going to be in studying the problems of life
and intelligence and the things that are sort of
also our current existential crises as a civilization
or a culture that's going through an existential trauma
of inventing technologies that we don't understand right now.
The existential trauma and the terror we feel
that that technology might somehow destroy us,
us meaning living, intelligently living organisms.
Right.
And yet we don't understand what that even means.
Well, humans have always been afraid
of our technologies though, right?
So it's kind of a fascinating thing
that every time we invent something we don't understand,
it takes us a little while to catch up with it.
I think also in part, humans kind of love being afraid.
Yeah, we love being traumatized.
It's weird.
We wanna learn more,
and then when we learn more it traumatizes us.
Yeah.
You know, I never thought about it this before,
but I think this is one of the reasons I love what I do
is because it traumatizes me all the time.
That sounds really bad.
But what I mean is like,
I love the shock of realizing
that coming to understand something
in a way that you never understood it before.
I think it seems to me, when I see a lot of the ways
other people react to new ideas,
that they don't feel that way intrinsically.
But for me, that's why I do what I do.
I love that feeling.
But you're also working on a topic
where it's fundamentally ego destroying.
Because you're talking about like life.
It's humbling to think that we're not,
the individual human is not special.
Yeah.
And you're like very viscerally exploring that.
Yeah, I'm trying to embody that.
Because I think you have to live the physics to understand it but there's a great quote about Einstein I don't know
if this is true or not that he once said that he could feel like the beam in his
belly and I think but I think like you gotta think about it though right like
you're if you're a really deep thinker and you're really thinking about reality
that deeply and you are part of the reality that you're trying to describe,
like you feel it, you really feel it.
That's what I was saying about
you're always like walking along the cliff.
If you fall off, you're falling into madness.
Yes, it's a constant, constant descent in the madness.
The fascinating thing about physicists and madness
is that you don't know if you've fallen off the cliff.
Yeah, you know you don't know. That's the cool thing about that.
I rely on other people to tell me.
Actually, this is very funny,
because I have these conversations with my students often.
They're worried about going crazy.
I have to reassure them that one of the reasons
they'll stay sane is by trying to work on concrete problems.
Going crazy or waking up, I don't know which one it is. So what do you think is the origin of life on Earth?
And how can we talk about it in a productive way?
The origin of life is like this boundary
that the universe can only cross
if a structure that emerges can reinforce its own existence,
which is self-reproduction, autocatalysis,
things people traditionally talk about. But it has to be a structure that can be a structure that emerges can reinforce its own existence,
which is self-reproduction, autocatalysis,
things people traditionally talk about,
but it has to be able to maintain its own existence
against this sort of randomness that happens in chemistry
and this randomness that happens in the quantum world.
And like, it's in some sense,
the emergence of like a deterministic structure that says,
you know, I'm gonna exist and I'm gonna keep going.
But pinning that down is really hard.
We have ways of thinking about it in assembly theory that I think are pretty
rigorous.
And one of the things I'm really excited about is trying to actually quantify in
an assembly theoretic way when the origin of life happens.
But the basic process I have in mind is like a system that
has no causal contingency, no constraints of objects basically constraining the existence
of other objects or allowing the existence of other objects. And so that sounds very
abstract but like you can just think of like a chemical reaction can't happen if there's
not a catalyst, for example, or a baby can't be born if there wasn't a parent. So there's a lot of causal
contingency that's necessary for certain things to happen. So you think about this sort of unconstrained
random system, there's nothing that reinforces the existence of other things. So the sort of
resources just get washed out
in all of these different structures and none of them exist again or they just, you know,
they're not very complicated if they're in high abundance. And some random events
allow some things to start reinforcing the existence of a small subset of objects. And
if they can do that, you know,
like just molecules basically recognizing each other
and being able to catalyze certain reactions,
there's this kind of transition point that happens
where unless you get a self-reinforcing structure,
something that can maintain its own existence,
it actually can't cross this boundary to make any objects in high abundance
without having this sort of past history that it's carrying with us and maintaining the existence of that past history.
And that boundary point where objects can't exist unless they have the selection and history in them is what we call the original life. And pretty much everything beyond that boundary is holding on for dear life to all of the
causation and causal structure that's basically put it there.
And it's carving its way through this possibility space into generating more and more structure.
And that's when you get the open ended cascade of evolution.
But that boundary point is really hard to cross. And then what happens when you cross that boundary point and the way objects come
into existence is also like really fascinating dynamics because
You know like as things become more complex the assembly index increases. I can explain all these things
Sorry, you can tell me what you want to explain
What people want to hear this
Sorry, I have like a very vivid visual on my brain
and it's really hard to articulate it.
Got to convert it to language.
I know.
It's so hard.
It's like, it's going from like a feeling
to a visual to language is so stifling sometimes.
I have to convert it from language to a visual,
to a feeling.
Yeah.
I think it's working.
I hope so.
I really like the self-reinforcing of the objects.
I mean, just so I understand,
one way to create a lot of the same kind of object
is make them self-reinforcing.
Yes.
So self-reproduction has this property, right?
Like if a system can make itself,
then it can persist in time, right?
Because all objects decay, they all have a finite lifetime.
So if you're able to make a copy of yourself
before you die, before the second law eats you
or whatever people think happens,
then that structure can persist in time.
So that's a way to sort of emerge out of a random soup,
out of the randomness of soup.
Right, but things that can copy themselves are very rare.
Yeah, fair.
And so what ends up happening is that you get structures
that enable the existence of other things,
and then somehow only for some sets of objects,
you get closed structures that are self-reinforcing
and allow that entire structure to persist.
Right, so the one object A reinforces the existence
of object B, but object A can die.
Yeah.
So you have to close that loop.
Right, so this is the classic idea.
This is just all very unlikely statistically,
but that's sufficiently,
so you're saying there's a chance.
There is a chance.
There's low probability, but once you solve that,
once you close the loop, you can create
a lot of those objects.
And that's what we're trying to figure out,
is what are the causal constraints that close the loop.
So there is this idea that's been in the literature
for a really long time that was originally proposed
by Stuart Kaufman as really critical
to the origin life called autocatalytic sets. So autocatalytic set is exactly this property.
We have A makes B, B makes C, C makes A, and you get a closed system. But the problem with
the theory of autocatalytic sets is incredibly brittle as a theory and it requires a lot
of ad hoc assumptions. Like you have to assume function.
You have to say this thing makes B.
It's not an emergent property, the association between A and B.
And so the way I think about it is much more general.
If you think about these histories that make objects,
it's kind of like the structure of the histories
becomes collapses in such a way that these things are all in
the same sort of causal structure and that causal structure
actually loops back on itself to be able to generate
some of the things that make the higher level structures.
Lee has a beautiful example of this actually in molybdenum.
It's like the first non-organic autocatalytic set.
It's a self-reproducing molybdenum ring.
But it's like molybdenum and basically,
if you look at the molybdenum,
it makes a huge molybdenum ring.
I don't remember exactly how big it is.
It might be like 150 molybdenum atoms or something.
But if you think about the configuration space of that object,
it's exponentially large, how many possible molecules. So why does the entire system collapse on just making that one structure?
If you start from molybdenum atoms that are maybe just a couple of them stuck together.
And so what they see in this system is there's a few intermediate stages.
So there's some random events where the chemistry comes together, makes these structures.
And then once you get to this very large one, it becomes a template for the smaller ones,
and then the whole system just reinforces its own production.
How did Lee find this molybdenum?
If I knew how Lee's brain work,
I think I would understand a little more about the universe.
This is not an algorithmic discovery, it's a...
No, but I think it goes to the deepest roots
of when he started thinking about origins of life.
So I don't know all his history,
but what he's told me is he started out in crystallography.
And there's some things that he would just,
people would just take for granted
about chemical structures
that he was deeply perplexed about.
Just why are these really intricate, really complex structures forming so easily about chemical structures that he was like deeply perplexed about, like just like why
are these like really intricate, really complex structures forming so easily under these conditions.
And he was really interested in life, but he started in that field. So he's just carried
with him these sort of deep insights from these systems that seem like they're totally
not alive and just like these metallic chemistries
into actually thinking about the deep principles of life. So I think he already knew a lot about that chemistry
and he also, you know, assembly theory came from him
thinking about how these systems work.
So he had some intuition about what was going on
with this molybdenum ring.
The molybdenum might be able to be the thing
that makes a ring.
They knew about them for a long time,
but they didn't know that the mechanism
of why that particular structure formed
was autocatalytic feedback.
And so that's what they figured out in this paper.
And I actually think that paper is revealing
some of the mechanism of the origin life transition because really what you see
Like the origin of life is basically like you should have a combinatorial explosion of the space of possible structures
That are too large to exhaust and yet you see it collapse on this
You know really small space of possibilities. that's mutually reinforcing itself to keep existing.
That is the origin of life.
There's some set of structures that result
in this autocatalytic feedback.
Yeah.
And is it, what is it, tiny, tiny, tiny, tiny percent?
I think it's a small space, but chemistry is very large.
So, there might be a lot of them out there,
but we don't know.
And one of them is the thing that probably started
life on Earth.
That's right.
Or many, many starts.
Yes.
And it keeps starting maybe.
Yeah.
I mean, there's also all kinds of other weird properties
that happen around this kind of phase boundary.
So this other project that I have in my lab is focused on the origin
of chirality, which is thinking about – so chirality is this property of molecules that
they can come in mirror image forms, so like chiral literally means hand. So your left
and right hand are what's called non-superimposable because if you try to lay one on the other,
you can't actually lay them directly on top of each other and that's the property being a mirror image.
So there's this sort of perplexing property of the chemistry of life that
no one's been able to really adequately explain that all of the amino acids in
proteins are left-handed and all of the bases in RNA and DNA are right-handed.
And yet the chemistry of these building block
units, amino acids, and nucleobases is the same for left and right-handed. So you
have to have like some kind of symmetry breaking where you go from these
chemistries that seem entirely equivalent to only having one chemistry
take over as the dominant form. And for a long time I had been really, I actually
did my PhD on the origin of chirality.
I was working on it as like a symmetry breaking problem in physics. This is how I got started
in the origin of life. And then I left it for a long time because I thought it was like
one of the most boring problems in the origin of life. But I've come back to it because
I think there's something really deep going on here related to this like combinatorial
explosion of the space of possibilities. But just to get to that point, like this feature of this
handedness has been the main focus, but people take for granted the existence of chiral molecules
at all, that this property of having a handedness, and they just assume that, you know, like it's
just a generic feature of chemistry. But if you actually look at molecules, if you look at chemical space,
which is the space of all possible molecules that people can generate,
and you look at small molecules, things that have less than about 7 to 11 heavy atoms,
so things that are not hydrogen, almost every single molecule in that space is achiral,
doesn't have a chiral center.
So it would be like a spoon.
A spoon doesn't have it, like it's the same as its mirror image.
It's not like a hand that's different than its mirror image.
But if you get to like this threshold boundary above that boundary, almost every single molecule
is chiral.
So you go from a universe where almost nothing has a mirror image form.
There's no mirror image universe of possibilities to this one where every single structure has pretty much
a mirror image version.
And what we've been looking at in my lab is that it seems to be the case that the original
life transition happens around the time when you start accumulating.
You push your molecules to a large enough complexity
that chiral molecules become very likely to form.
And then there's a cascade of molecular recognition
where chiral molecules can recognize each other.
And then you get this sort of autocatalytic feedback
and things self-reinforcing.
So is chirality in itself an interesting feature
or just an accident of complexity? No, it's a super interesting feature. I think chirality breaks symmetry an interesting feature or just an accident?
No, it's a super interesting feature.
I think chirality breaks symmetry in time, not space.
So we think of it as a spatial property, like a left and right hand.
But if I choose the left hand, I'm basically choosing the future of that system for all time,
because I've basically made a choice between the ways that that molecule can now react
with every other object in its chemical universe.
And so you're actually like,
when you have this splitting of making a molecule
that now has another form it could have had
by the same exact atomic composition,
but now it's just a mirror image isometry,
you're basically splitting the universe
of possibilities every time.
Yeah, in two.
In two, but molecules can have more than one chiral center
and that's not the only stereosometry that they can have.
So this is one of the reasons that taxol
fills 1.5 universes of space.
It's all of these spatial permutations
that you do on these objects
that actually makes the space so huge.
So the point of this sort of chiral transition
that I'm pointing out is chirality is actually signature
of being in a complex chemical space.
And the fact that we think it's a really generic feature of chemistry and it's really prevalent
is because most of the chemistry we study on earth is a product already of life. And it also has to
do with this transition and assembly, this transition and possibility spaces, because I
think there's something really fundamental going on at this boundary, that you don't really need to go that far into chemical space to actually see life in terms of
this depth in time, this depth in symmetries of objects, in terms of like chiral symmetries,
or this assembly structure. But getting past this boundary that's not very deep in that space requires life.
It's a really weird property.
And it's really weird that so many abrupt things
happen in chemistry at that same scale.
So would that be the greatest invention ever made on Earth
in its evolutionary history?
So I really like that formulation of it.
Nick Lane has a book called Life Ascending,
where he lists the 10 great inventions of evolution.
The origin of life being first,
and DNA, the hereditary material
that encodes the genetic instructions
for all living organisms.
Then photosynthesis, the process that allows organisms
to convert sunlight into chemical energy,
producing oxygen as a byproduct.
The complex cell, eukaryotic cells,
which contain a nucleus and organelles,
arose from simple bacterial cells.
Sex, sexual reproduction.
Movement, so just the ability to move
under which you have the predation,
the predators and ability of living organs to find food.
I like that movement in there, that's cool.
Yeah, but a movement includes a lot of interesting stuff
in there, like predator-prey dynamic,
which, not to romanticize a nature as metal,
that seems like an important one.
I don't know, it's such a computationally powerful thing
to have a predator and prey.
Well, it's efficient for things to eat,
other things that are already alive,
because they don't have to go all the way back
to the base chemistry.
Well, that, but maybe I just like deadlines,
but it creates an urgency.
You're gonna get eaten.
You gotta live?
Yeah, like survival, it's not just the static
environment you're battling against.
You're like, the dangers against which you're trying to survive are also evolving.
This is just a much faster way to explore the space of possibilities.
I actually think it's a gift that we don't have much time.
Yes.
A sight, the ability to see, so the increasing complexifying of sensory organisms,
consciousness and death,
the concept of programmed cell death.
These are all inventions along the line.
I like invention as a word for them, I think that's good.
Which are the more interesting inventions to you?
What origin of life, because you kind of
are not glorifying the origin of life? Because you kind of are not glorifying
the origin of life itself.
There's a process.
No, I think the origin of life is a continual process.
That's why.
I'm interested in the first transition
and solving that problem,
because I think it's the hardest,
but I think it's happening all the time.
When you look back at the history of Earth,
like what are you impressed happened?
I like sight
as an invention.
Cause I think having sensory perception and trying to comprehend the world
to use anthropocentric terms is like
a really critical feature of life.
And I also, it's interesting the way that sight
has complexified over time, right?
So like, if you think at the
original life, nothing on the planet could see, right? So like for a long time, life had no sight.
And then, you know, like photon receptors were invented. And then when multicellular already
evolved, those cells eventually grew into eyes. And we had the multicellular eye. And
then it's interesting when you get to societies, like human societies, that we invent even
better technologies of seeing like telescopes and microscopes, which allow us to see deeper
into the universe or at smaller scales. So I think that's pretty profound, the way that sight has transformed the ability of
life to literally see the reality in which it's existing in.
I think consciousness is also obviously deeply interesting.
I've gotten kind of obsessed with like octopus.
I don't like, they're just so weird.
And the fact that like they evolved complex nervous systems
kind of independently is like, seems very alien.
Yeah, there's a lot of alien like organisms.
That's another thing I saw in the jungle.
Yeah.
Just things that are like, oh, okay.
They make one of those, huh?
It just feels like there's-
Do you have any examples?
There's a frog that's as thin as a sheet of paper.
And I was like, what?
And it gets birthed through pores.
Oh, I've seen videos of that.
It's so gross when the babies come out.
Did you see that in person, like the babies coming out?
Oh no, no.
I saw the, without the- Have you seen videos of that the baby's coming out. Oh no, no. I saw the, without the.
Have you seen videos of that?
It's so gross.
It's one of the grossest things I've ever seen.
Well, so gross is just the other side of beautiful.
I think.
It's like, oh wow, that's possible.
I guess if I was one of those frogs,
I would think that was the most beautiful event
I'd ever seen.
Although like human childbirth
is not that beautiful either.
Yeah, it's all a matter of perspective.
Well, we come into the world so violently.
It's just amazing.
I mean, the world is a violent place.
Yeah.
So again, it's just another side of the coin.
You know what?
This actually makes me think of one that's not up there,
which I do find really incredibly amazing,
that's not up there, which I do find really incredibly amazing, is the process of the germline cell
in organisms. Basically, every living thing on this planet at some point in its life has to go through a single cell. And this whole issue of development, the developmental program is kind of
crazy. How do you build you out of a single cell?
How does a single cell know how to do that?
Like, you know, pattern formation
of a multicellular organism obviously like evolves with DNA,
but there's a lot of stuff happening there
about when cells take on certain morphologies
and things that people don't understand
like the actual shape formation mechanism.
And a lot of people study that and it's,
and there's a lot of advances being made now in that field.
I think it's pretty shocking though that like
how little we know about that process.
And often it's left off of people's lists.
It's just kind of interesting.
Embryogenesis is fascinating.
Yeah, cause it, you start from just one cell.
Yeah.
And the genes in all the cells are the same, right?
So like the differentiation has to be
something that's like much more about like the actual like,
you know, expression of genes over time
and like how they get switched on and off
and also the physical environment
of like the cell interacting with other cells
and there's just a lot of stuff going on.
Yeah, the computation, the intelligence of that process
might be like the most important thing to understand,
and we just kind of don't really think about it.
We think about the final product.
Maybe the key to understanding the organism
is understanding that process, not the final product.
Probably, yes.
I think most of the things about understanding anything
about what we are are embedded in time.
Well of course you would say that.
I know, so predictable.
It's turning into a deterministic universe.
It always has been, always was like the meme.
Yeah, always was but it won't be in the future.
Well that's, before we talk about the future,
let's talk about the past, the assembly theory.
Can you explain assembly theory to me?
I listened to Lee talk about it for many hours
and I understood nothing, no I'm just kidding.
I just wanted to take another,
you've been already talking about it,
but just, just, just, just,
what from a big picture view
is the assembly theory way of thinking about our world,
about our universe?
Yeah, I think the first thing is,
like the observation that life seems to be the only thing
in the universe that builds complexity
and the way that we see it here.
And complexity is obviously like a loaded term, so I'll just use assembly instead
because I think assembly is more precise.
But the idea that like, you know, all the things on your desk here from your computer
to the pen to, you know, us sitting here don't exist anywhere else in the universe as far as we
know.
They only exist on this planet.
And it took a long evolutionary history to get to us.
Is a real feature that we should take seriously as one that's deeply embedded in the laws
of physics and the structure of the universe that we live in.
Standard physics would say that all of that complexity traces back to the infinitesimal
deviations and the initial state of the universe that there was some order there.
I find that deeply unsatisfactory.
What assembly theory says that's very different is that the universe is basically constructing itself.
And when you get to these commonest tutorial spaces
like chemistry, where the space of possibilities
is too large to exhaust them all,
you can only construct things
along historically contingent paths.
Like you basically have causal chains of events
that happen to allow
other things to come into existence. And that this is the way that complex objects get formed,
is basically on scaffolding on the past history of objects making more complex objects, making
more complex objects. That idea in itself is easy to state and simple, but it has some really radical implications as far as what you think is the nature of the physics that would describe life.
And so what assembly theory does formally is try to measure the boundary in the space
of all things that chemically could exist, for example, like all possible molecules.
Where is the boundary above which we should say these things are too complex to happen outside of an evolutionary chain of
events, outside of selection? And we formalize that with two observables. One of them is the
copy number of the object. So how many of the object did you observe? And the second one is
what's the minimal number of recursive steps to make it. So if you start from elementary building blocks,
like bonds for molecules, and you put them together
and then you take things you've made already
and build up to the object,
what's the shortest number of steps you had to take?
And what Lee's been able to show in the lab with his team
is that for organic chemistry,
it's about 15 steps and then you only see molecules that,
you know, the only molecules that we observe
that are past that threshold are ones that are in life.
And in fact, one of the things I'm trying to do
with this idea of like trying to actually quantify
the origin of life as a transition
and like a phase transition assembly theory
is actually be able to explain why that boundary
is where it is,
because I think that's actually the boundary
that life must cross.
So the idea of going back to this thing
we were talking about before about these structures
that can reinforce their own existence
and move past that boundary,
15 seems to be that boundary in chemical space.
It's not a universal number, it will be different
for different assembly spaces,
but that's what we've experimentally validated so far.
And then-
So literally 15, like the assembly index is 15?
It's 15 or so for the experimental data, yeah.
So that's when you start getting the self-reinforcing.
That's when you have to have that feature
in order to observe molecules
in high abundance in that space.
So copy numbers, the number of exact copies,
that's what you mean by high abundance
and assembly index or the complexity of the object
is how many steps it took to create it, recursive?
Recursive, yeah.
So you can think of objects in assembly theory
as basically recursive stacks
of the construction steps to build them.
So they're like, it's like, you take this step
and then you make this object
and you make it this object and make this object
and then you get up to the final object.
But that object is all of that history
rolled up into the current structure.
What if you took the long way home?
You can't take the long way.
Why not?
The long way doesn't exist.
That's a good song though.
What do you mean the long way doesn't exist?
If I do a random walk from A to B,
I'll eventually, if I start at A,
I'll eventually end up at B,
and that random walk will be much shorter than the short.
If you look at objects,
so we define something we call the assembly universe,
and the assembly universe is ordered in time.
It's actually ordered in the causation,
the number of steps to produce an object.
And so all objects in the universe are in some sense,
exist in a layer that's defined by their assembly index.
And the size of each layer is growing exponentially.
So what you're talking about, if you want to look at the long way of getting to an object, as I'm
increasing the assembly index of an object, I'm moving deeper and deeper into
an exponentially growing space. And it's actually also the case that the sort of
typical path to get to that object is also exponentially growing with respect
to the assembly index. And so if you want to try to make object is also exponentially growing with respect to the assembly index.
And so if you want to try to make a more
and more complex object and you wanna do it
by a typical path, that's actually
an exponentially receding horizon.
And so most objects that come into existence
have to be causally very similar to the things that exist
because they're close by in that space
and they can actually get to it
by an almost shortest path for that object.
Yeah, the almost shortest path is the most likely.
And like by a lot.
By a lot.
Okay, so if you see a high copy number.
Yeah, imagine yourself.
A copy number greater than one.
Yeah, I mean basically we live, the more complex we get,
we live in a space that is growing exponentially large.
And the ways of getting to objects in the space are also growing exponentially large. And the ways of getting to objects in the space
are also growing exponentially large.
And so we're this kind of recursively stacked structure
of all of these objects that are clinging onto each other
for existence and then they grab something else
and are able to bring that thing into existence
because it's kind of similar to them.
But there is a phase transition.
There is a transition.
There is a place where you would say, oh, that's life.
I think it's actually abrupt.
I've never been able to say that in my entire career before.
I've always gone back and forth
about whether the original life was kind of gradual
or abrupt, I think it's very abrupt.
Oh, poetically, chemically, literally.
What snaps?
Okay, that's very beautiful.
It snaps.
Okay, but. We'll be poetic today. But no, I think there's a lot of random exploration Life snaps into existence. Life snaps into existence. Life snaps into existence. Life snaps into existence. Life snaps into existence. It snaps.
We'll be poetic today.
But no, I think there's a lot of random exploration
and then the possibility space just collapses
on the structure really fast
that can reinforce its own existence
because it's basically fighting against non-existence.
Yeah, you tweeted,
the most significant struggle for existence in the evolutionary process
is not among the objects that do exist, but between the ones that do and those that never
have the chance to.
This is where selection does most of its causal work.
The objects that never get a chance to exist.
The struggle between the ones that never get a chance to exist and The struggle between the ones that never get a chance
to exist and the ones that, okay.
What's that line exactly?
I don't know, we can make songs out of all of these.
What are the objects that never get a chance to exist?
What does that mean?
So there was this website, I forgot what it was,
but it's like a neural network
that just generates a human face.
And it's like this person does not exist,
I think that's what it's called, right?
So you can just click on that all day
and you can look at people all day that don't exist.
All of those people exist in that space
of things that don't exist.
Yeah, but there's the real struggle.
Yeah, so the struggle of the quote,
the struggle for existence is,
that goes all the way back to Darwin's writing
about natural selection, right? So like the whole idea of survival of the fittest is everything
struggling to exist, this predator-prey dynamic, and the fittest survive. And so the struggle
for existence is really what selection is all about. But you're, and that's true.
We do see things that do exist, competing to continue to exist.
But each time that, like if you think about this space of possibilities and, you know,
each time the universe, you know, generates a new structure or like an object that exists,
generates a new structure along this causal chain. It's generating something that exists,
that never existed before.
And each time that we make that kind of decision,
we're excluding a huge space possibilities.
And so actually like as this process
of increasing assembly index,
it's not just that like the space that these objects exist in
is exponentially growing,
but there are objects in that space
that are exponentially receding away from us.
So they're becoming exponentially less
and less likely to ever exist.
And so existence excludes a huge number of things.
Just because of the accident of history,
how it ended up.
Yeah, it is in part an accident
because I think some of the structure that gets generated
is driven a bit by randomness.
I think a lot of it, so one of the conceptions that we have in assembly theory is the universe
is random at its base.
You can see this in chemistry, like unconstrained chemical reactions are pretty random.
And then, and also quantum mechanics, you know,
there's lots of places that give evidence for that. And deterministic structures emerge
by things that can causally reinforce themselves and maintain persistence over time. And so
we are some of the most deterministic things in the universe. And so, like, we can generate
very regular structure and we can generate new structure along a particular lineage, but the possibility space
at the sort of tips, like the things we can generate next is really huge. So there's some
stochasticity in what we actually, you know, instantiate as like the next structures that
get built in the biosphere. It's not completely deterministic
because the space of future possibilities
is always larger than the space of things that exist now.
So how many instantiations of life is out there,
do you think?
So how often does this happen?
What we see happen here on Earth,
how often is this process repeated throughout our galaxy,
throughout the universe?
So I said before, like right now,
I think the origin of life is a continuous process on Earth.
Like I think this idea of like combinatorial spaces
that our biosphere generates, not just chemistry,
but other spaces, often cross this threshold
where they then allow themselves to persist
with a particular regular structure over time.
So language is another one where, you know, like the space of, you know, possible configurations
of the 26 letters of the English alphabet is astronomically large, but we use with very high
regularity certain structures. And then we associate meaning to them because of the regularity of,
like, how much we use them, right? So meaning is an emergent property of the causation
and the objects and how often they recur
and what the relationship of the recurrence is
to other objects.
Meaning is the emergent property, okay, got it.
Well, this is why you can play with language
so much, actually.
So words don't really carry meaning,
it's just about how you lace them together.
Yeah, but from where does the meaning emerge?
You don't have a lot of room,
obviously as a speaker of a given language, you don't have
a lot of room with a given word to wiggle, but you do have a certain amount of room to
push the meanings of words.
And I do this all the time and you have to do it with the kind of work that I do because if you want to discover an abstraction, like some
kind of concept that we don't understand yet, it means we don't have the language.
And so the words that we have are inadequate to describe the things.
This is why we're having a hard time talking about assembly theory because it's a newly
emerging idea.
And so I'm constantly playing with words in different ways to try to convey the meaning
that is actually behind the words, but it's hard to do.
So you have to wiggle within the constraints.
Yes, lots of wiggle.
The great orators are just good at wiggling.
Do you wiggle?
I'm not a very good wiggler, no.
This is the problem. This is part of the problem.
No, I like playing with words a lot.
You know, it's very funny because, you know, like, I know you talked about this with Lee,
but like people were so offended by the writing of the paper that came out last fall.
And it was interesting because the ways that we used words
were not the way that people were interacting with the words.
And I think that was part of the mismatch where we were trying to use words in a new way because we were trying to describe something that hadn't been described adequately before, but we had to
use the words that everyone else uses for things that are related. And so it was really interesting
to watch that clash play out in real time for me, being someone that tries to be
so precise with my word usage,
knowing that it's always gonna be vague.
Boy, can I relate.
It's like, what is truth?
Is truth the thing you meant when you wrote the words,
or is truth the thing that people understood
when they read the words?
Oh yeah.
I think that compression mechanism into language
is a really interesting one,
and that's why Twitter is a nice exercise.
You get to write a thing,
and you think a certain thing when you write it,
and then you get to see all these other people
interpret it in all kinds of different ways.
I use it as an experimental platform for that reason.
I wish there was a higher diversity
of interpretation mechanisms applied to tweets,
meaning like all kinds of different people would come to it.
Like some people that see the good in everything
and some people that are ultra cynical,
a bunch of haters and a bunch of lovers and a bunch of.
Maybe they could do better jobs
with presenting material to people.
It's usually based on interest, but I think it would be really nice
if you got 10% of your Twitter feed
was random stuff sampled from other places.
That'd be kind of fun.
True.
I also would love to filter, just like bin,
the response to tweets by like the people
that hate on everything.
Yes.
The people that are.
Oh, that would be fantastic.
The people that are like super positive on everything
and they'll just kinda, I guess normalize their response
because then it'd be cool to see if the people
that are usually positive about everything
are hating on you or like totally don't understand
or completely misunderstood.
Yeah, usually it takes a lot of clicking to find that out.
Yeah, so it'd be better if it was sorted, yeah.
The more clicking you do,
the more damaging it is to the soul.
Yeah, it's like instead of like,
well you could have the blue check,
but you should have like, are you a pessimist, an optimist?
Yeah, there's a lot of colors.
Theotic neutral.
What's your personality?
Yeah, a whole rainbow of checks. Theatic neutral. What's your personal? A whole rainbow of checks.
And then you realize there's more categories
than we can possibly express in colors.
Yeah, of course.
People are complex.
That's our best feature.
I don't know how we got to the wiggling required
given the constraints of language because I think we started about me asking about alien life,
which is how many different times
did the face transition happen elsewhere?
Do you think there's other alien civilizations out there?
This goes into like the, you know,
like are you on the boundary of insane or not?
But you know, when you think about the structure
of the physics of what we are that deeply,
it really changes your conception of things.
And, you know, going to this idea of the universe,
you know, being kind of small in physical space
compared to how big it is in time and like how large we are.
It really makes me question about whether there's any other
structure that's like this giant crystal in time,
this giant causal structure like our biosphere
slash technosphere is anywhere else in the universe.
Why not?
I don't know.
It could be just because this one is gigantic. Doesn not? I don't know.
Just because this one is gigantic doesn't mean there's
other gigantic.
There's no other gigantic.
But I think the universe is expanding.
It's expanding in space.
But in assembly theory, it's also expanding in time.
And actually, that's driving the expansion in space.
And expansion in time is also driving
the expansion in the comb of combinatorial space
of things on our planet.
So that's driving the sort of, you know, pace of technology and all the other things.
So time is driving all of these things, which is a little bit crazy to think that the universe
is just getting bigger because time is getting bigger.
But like, the sort of visual that gets built in my brain about that is like the structure
that we're building on this planet is packing more and more time in this very small volume
of space, right?
Because our planet hasn't changed its physical size in four billion years, but there's like
a ton of causation and recursion and time, whatever word you want to use, information
packed into this. And I think this is also embedded in sort of the virtualization of our technologies
or the abstraction of language and all of these things.
These things that seem really abstract are just really deep in time.
And so what that looks like is you have a planet that becomes increasingly virtualized.
And so it's getting bigger and bigger in time,
but not really expanding out in space.
And the rest of space is kind of moving away from it.
It's again, it's a sort of exponentially receding horizon.
And I'm just not sure how far into this evolutionary process
something gets, if it can ever see
that there's another such structure out there.
What do you mean by virtualized in that context?
Virtual as sort of a play on virtual reality
and like simulation theories.
But virtual also in a sense of,
we talk about virtual particles in particle physics
which they are very critical to doing calculations
about predicting the properties of real particles
but we don't observe them directly.
So what I mean by virtual here is virtual reality for me, things that appear virtual,
appear abstract are just things that are very deep in time in the structure of the things
that we are.
So if you think about you as a four billion year old object,
the things that are part of you,
like your capacity to use language or think abstractly
or have mathematics are just very,
you know, like deep temporal structures.
That's why they look like they're informational
and abstract is because they're like,
they're existing in this temporal part of you,
but not necessarily spatial part.
Just because I have a four billion year old history,
why does that mean I can't hang out with aliens?
There's a couple ideas that are embedded here.
So one of them comes again from Paul.
He wrote this book years ago about,
you know, like the eerie silence and why we're alone.
And he concluded the book with this idea
of quinteligence or something,
but like this idea that like really advanced intelligence would basically just build itself into a quantum computer and it would want to
operate in the vacuum of space because that's the best place to do quantum computation and it would
just like run out all of its computations indefinitely, but it would look completely
dark to the rest of the universe. And I don't think as typical, like I don't think that's
actually like the right physics, but I think something about that idea as I do with all ideas is partially correct.
And Freeman Dyson also had this amazing paper about how long life could persist in a universe
that was exponentially expanding.
And his conception was like if you imagine analog life form, it could run slower and
slower and slower and slower and slower as a function of time. And so it
would be able to run indefinitely even against an exponentially
expanding universe because it would just run exponentially slower. And so I
guess part of what I'm doing in my brain is putting those two things together
along with this idea that we are building, you know, like if you imagine
with our technology we're now building virtual realities,
right, like things we actually call virtual reality,
which required, you know, four billions of years of history
and a whole bunch of data to basically embed them
in a computer architecture.
So now you can put like, you know, an Oculus headset on
and think that you're in this world, right?
And what you really are embedded in
is in a very deep temporal structure.
And so it's huge in time, but it's very small in space. And you can go lots of places
in the virtual space, right? But you're still stuck in like your physical body and like
sitting in the chair. And so, you know, part of it is it might be the case that sufficiently
evolved biospheres kind of virtualize themselves
and they internalize their universe
in their sort of temporal causal structure
and they close themselves off from the rest of the universe.
I just don't know if a deep temporal structure
necessarily means that you're closed off.
No, I don't either.
So that's kind of my fear.
So I'm not sure I'm agreeing with what I say.
I'm just saying like, this is one sort of conclusion I'm just saying like this is one sort of conclusion.
And you know, like in my most sort of like, it's interesting because I don't do psychedelic
drugs.
But when people describe to me like your thing with the faces and stuff and like I have,
you know, had a lot of deep conversations with friends that have done psychedelic drugs
for intellectual reasons and otherwise.
But I'm always like, oh, it sounds like you're just doing theoretical physics.
Like that's what brains do on theoretical physics.
So I live in these like really abstract spaces most of the time.
But there's also this issue of extinction, right?
Like extinction events are basically pinching off an entire like causal structure.
The one of these like, I'm going to call them time crystals.
I don't like know it, but there's like these very large objects in time,
pinching off that whole structure
from the rest of it.
And so it's like, if you imagine that sort of same thing
in the universe, I once thought that sufficiently
advanced technologies would look like black holes.
They would be just completely imperceptible to us.
Yeah.
So there might be lots of aliens out there.
Maybe that's an explanation for all the singularities.
They're all pinched off causal structures
that virtualize their reality and kind of broke off from us.
Black holes in every way, so like, untouchable to us
or unlikely to be detectable by us
with whatever sensory mechanisms we have.
But the other way I think about it is,
there is probably, hopefully life out there.
So like I do work on life detection
efforts in the solar system, and I'm trying to help with the Habitable Worlds Observatory
mission planning right now and working with the biosignatures team for that, to think about
exoplanet biosignatures. So I have some optimism that we might find things. But there are the
challenges that we don't know
the likelihood for life, which is what you were talking about.
So if I get to a more grounded discussion,
what I'm really interested in doing
is trying to solve the origin of life
so we can understand how likely life is out there.
So I think that the problem of discovering alien life and solving the origin of life are deeply coupled and in fact are one and
the same problem. And that the first contact with alien life will actually be in an origin
of life experiment. But that part I'm super interested in. And then there's this other
feature that I think about a lot, which is our own technological phase of development as sort
of like what is this phase in the evolution of life on a planet. If you think about a
biosphere emerging on a planet and evolving over billions of years and evolving into a
technosphere, when a technosphere can move off planet and basically reproduce itself on another planet. Now you have biospheres
reproducing themselves. Basically, they have to go through technology to do that. And so there are
ways of thinking about sort of the nature of intelligent life and how it spreads in that
capacity that I'm also really excited about and thinking about.
And all of those things for me are connected. We have to solve the origin of life
in order for us to get off planet
because we basically have to start life on another planet.
And we also have to solve the origin of life
in order to recognize other alien intelligence.
All of these things are literally the same problem.
Right, understanding the origin of life here on Earth
is a way to understand ourselves.
Understanding ourselves is a way to understand ourselves into,
understanding ourselves as a prerequisite for being able to detect other intelligent civilizations.
I, for one, take it for what it's worth, on Ayahuasca,
one of the things I did is zoom out,
like aggressively, like a spaceship.
And it would always go quickly through the galaxy
and from the galaxy to this representation of the universe.
And at least for me, from that perspective,
it seemed like it was full of alien life.
Not just alien life, but intelligent life.
I like that.
And conscious life.
So like I don't know how to convert it into words.
It's more like a feeling, like you were saying.
A feeling converted to a visual to, converted to words.
So I had a visual with it, but really it was a feeling
that it was just full of this vibrant energy
that I was feeling when I'm looking at the people in my life
and full of gratitude, but that same exact thing
is everywhere in the universe.
Right.
So, yeah. I totally agree with this.
Like, that visual I really love,
and I think we live in a universe
that like generates life and purpose,
and like it's part of the structure of just the world.
And so maybe like this sort of lonely view I have is, I never thought about this way
till you were describing that. I was like, I want to live in that universe. And I'm
like a very optimistic person and I love building visions of reality that are positive. But
I think for me right now in the intellectual process, I have to tunnel through this particular way of thinking
about the loneliness of being separated in time
from everything else, which I think we also all are
because time is what defines us as individuals.
So part of you is drawn to the trauma of being alone.
Deeply into physics.
Yeah, but also part of what I mean is
you have to go through ideas you don't necessarily agree with
to work out what you're trying to understand.
And I'm trying to be inside this structure
so I can really understand it.
And I don't think I've been able to,
I'm so deeply embedded in what we are intellectually
right now that I don't have an ability to see
these other ones
that you're describing, if they're there.
Well, one of the things you kind of described
that you already spoke to,
you call it the great perceptual filter.
Yeah.
So there's the famous great filter,
which is basically the idea that there's some really
powerful moment in every intelligent civilization that
where they destroy themselves. Yeah. That explains why we have not seen aliens and
you're saying that there's something like that in the temporal history of the
creation of complex objects that at a certain point they become an island, an
island too far to reach based on the perceptions.
I hope not, but yeah, I worry about it, yeah.
But that's basically meaning there's something fundamental
about the universe where if the more complex you become,
the harder it will be to perceive other complex creatures.
Yeah, I mean just think about us with microbial life, right?
Like we used to once be cells,
and for most of human history,
we didn't even recognize cellular life was there
until we built a new technology,
microscopes that allowed us to see them.
Right, so, it's kind of weird, right?
Like things that we-
They're close to us.
They're close, they're everywhere.
But also in the history of the development
of complex objects, they're pretty close.
Yeah, super close, super close.
Like, yeah, I mean, everything on this planet is like,
it's like pretty much the same thing.
Like the space of possibilities is so huge.
It's like we're virtually identical.
So how many flavors or kinds of life
do you think are possible?
I'm kind of like trying to imagine
all the little flickering lights in the universe,
like in the way that you were describing
that was kind of cool.
It was so, I mean, it was awesome.
It was exactly that.
It was like lights.
Yeah.
The way you maybe see a city, but a city from like up above,
you see a city with the flickering lights,
but there's a coldness to the city.
Yeah.
There's some, you know, that, you know,
humans are capable of good and evil and you can see like,
there's a complex feeling to the city.
I had no such complex feeling about seeing the lights
of all the galaxies, whatever, the billions of galaxies.
Yeah, this is kind of cool.
I'll answer the question in a second,
but it's just maybe like, this idea of flickering lights
and intelligence is interesting to me because I,
you know, like we have such a human centric view
of alien intelligences that a lot of the work
that I've been doing with my lab is just trying
to take inspiration from non-human life on earth.
And so I have this really talented undergrad student
that's basically building a model
of alien communication based on fireflies.
So one of my colleagues or Peleg, is she's totally brilliant, but she goes out with GoPro
cameras and films in high resolution, all these firefly flickering.
And she has this theory about how their signaling evolved to maximally differentiate the flickering
pattern.
So she has a theory basically that predicts you know like the species should flash like this if this one's flashing like this this other one's gonna do it at a slower rate so that they you know like they can distinguish each other living in the same environment.
I'm so this undergrads building this model where you have like a pulsar background of all these like giant flashing sources in the universe and alien intelligence you know wants signal it's there. So it's flashing like a firefly.
And I just like, I like the idea of thinking
about non-human aliens.
So that was really fun.
The mechanism of the flashing, unfortunately,
is like the diversity of that is very high
and we might not be able to see it.
That's what.
Yeah, well, I think there's some ways
we might be able to differentiate that signal.
I'm still thinking about this part of it.
So one is like, like if you have pulsars
and they all have a certain spectrum
to their pulsing patterns,
and you have this one signal that's in there
that's basically tried to maximally differentiate itself
from all the other sources in the universe,
it might stick out in the distribution,
like there might be ways of actually being able to tell
if it's an anomalous pulsar, basically.
But I don't know if that would really work or not,
so still thinking about it.
You tweeted, if one wants to understand
how truly combinatorially and compositionally complex
our universe is, they only need step
into the world of fashion.
Yeah.
It's bonkers how big the constructable space
of human aesthetics is.
Can you explain?
Can we explore the space of human aesthetics?
Yeah, I don't know.
I've been kind of obsessed with the,
I never know how to pronounce it,
it's a chaparelli.
Like, you know, like they have ears and things.
Like it's such like a weird grotesque aesthetic,
but like it's totally bizarre.
But what I meant, like I have a visceral experience
when I walk into my closet.
I have like a lot of...
How big is your closet?
It's pretty big.
It's like I do assembly theory every morning
when I walk in my closet, because I really like
a very large, combinatorial, diverse palette,
but I never know what I'm gonna build in the morning.
Do you get rid of stuff?
Sometimes.
Or do you have trouble getting rid of stuff?
I have trouble getting rid of some stuff.
It depends on what it is.
If it's vintage, it's hard to get rid of
because it's kind of hard to replace.
It depends on the piece, yeah.
So you have your closet,
is that one of those temporal time crystals that-
Yeah.
They just, you get to visualize the entire history.
It's a physical manifestation of my personality.
Right.
So why is that a good visualization
of the combinatorial and compositionally complex?
I think it's an interesting feature of our species
that we get to express ourselves through what we wear.
Right, like if you think about all those animals
in the jungle you saw, like they're born looking
the way they look, and then they're stuck with it for life.
That's true, I mean, it is one of the loudest,
clearest, most consistent ways we signal to each other.
Yeah.
The clothing we wear.
Yeah.
And it's highly dynamic.
I mean, you can be dynamic if you want to.
Very few people are, there's a certain bravery,
but it's actually more about confidence,
willing to play with style and play with aesthetics.
And I think it's interesting
when you start experimenting with it,
how it changes the fluidity of the social spaces
and the way that you interact with them.
But there's also commitment.
You have to wear the outfit all the time. I know, I know. It's a big commitment. Like you have to wear that outfit all the time.
I know, I know.
That's a big commitment.
Do you feel like that every morning?
No, I wear, that's why.
You're like, this is a life commitment.
So like, all I have is suits and a black shirt and jeans.
Those are the two outfits.
Yeah, well see, this is the thing though, right?
It simplifies your thought process in the morning.
So like I have other ways I do that.
I park in the same exact parking spot when I go to work
on the fourth floor of a parking garage
because no one ever parks on the fourth floor.
So I don't have to remember where I parked my car.
But I really like aesthetics and playing with them.
So I'm willing to spend part of my cognitive energy
every morning trying to figure out
what I wanna be that day.
Did you deliberately think about the outfit
you're wearing today?
Yep.
Was there backup options?
Were you going back and forth between some?
Three or four.
But I really like the look.
Were they drastically different?
Yes.
Okay.
It's okay.
And even this one could have been really different
because it's not just the sort of jacket and the shoes
and the hairstyle, it's the shoes and the hairstyle, it's like the jewelry and the accessories.
So like any outfit is a lot of small decisions.
Well, I think your current outfit
is like a lot of shades of yellow.
There's like a theme.
Yeah. It's nice.
It's really, I'm grateful that you did that.
Thanks. It's like, it's all an art form.
Yeah, yellow's my daughter's favorite color
and I never really thought about yellow much
but she's been obsessed with yellow.
She's seven now and I don't know, I just really love it.
I guess you can pick a color
and just make that the constraint
and just go with it.
I understand the beauty.
I'm playing with yellow a lot lately.
Like this is not even the most yellow
because I have black pants on but I have,
I've worn outfits that have probably
five shades of yellow in them.
Wow.
What do you think beauty is?
We seem to, so underlying this idea of playing
with aesthetics is we find certain things beautiful.
What is it that humans find beautiful?
And why do we need to find things beautiful?
Yeah, you know, it's interesting.
It's not, I'm not, I mean, I am attracted to style
and aesthetics because I think they're beautiful,
but it's much more because I think it's fun to play with.
And so, so I will get to the beauty thing,
but I like, I guess I want to just explain a little bit
about my motivation in this space
because it's really an intellectual thing for me.
And, you know, Stewart Brand has this great infographic about the layers of human society,
and I think it starts with the natural sciences and physics at the bottom, and it goes through
all these layers, and it's economics, and then fashion is at the top, it's the fastest
moving part of human culture and I think I really
Like that because it's so dynamic and so short and it's temporal longevity
Contrasted with like studying the laws of physics which are like, you know
like the deep structure reality that I feel like I like bridging those scales tells me much more about
The structure of the world that I live in. That said, there's certain kinds of fashions.
Like a dude in a black suit with a black tie
seems to be less dynamic.
Yeah.
It seems to persist through time.
Are you embodying this?
Yeah, I think so.
I think it just-
I'd like to see you wear yellow wax.
I don't know. I wouldn't even know what to do with myself. I would freak out. I'd like to see you wear yellow legs.
I wouldn't even know what to do with myself.
I would freak out.
I wouldn't know how to act in the world.
You wouldn't know how to be you.
I know this is amazing though, isn't it?
Amazing, like you have the choice to do it.
But one of my favorite, just on the question of beauty,
one of my favorite fashion designers of all time
is Alexander McQueen.
And he was really phenomenal, but like his early—and
actually I kind of used like what happened to him in the fashion industry as a coping
mechanism with our paper, like the Nature paper in the fall when everyone was saying
it was controversial and how terrible that like, you know, like—but controversial is
good, right? But like when Alexander McQueen, you know, first came out with his fashion
lines, he was mixing horror and beauty.
And people were horrified.
It was so controversial.
It was macabre, he had like,
it looked like there were blood on the models.
And like-
That's beautiful.
Just look at some pictures here.
Yeah, no, I mean, his stuff is amazing.
His first runway line, I think, was called nihilism.
I don't know if you could find it.
I mean, he was really dramatic.
He carried a lot of trauma with him.
There you go.
Yeah.
But he changed the fashion industry.
His stuff became very popular.
That's a good outfit to show off to a party.
Right, right.
But this gets at the question, is that horrific or is it beautiful?
And I think, you know, he ended up committing suicide and actually he left his death note
on the descent of man. So he was a really deep person.
So I mean, great fashion certainly fashion certainly has that depth to it.
Yeah, it sure does.
So I think it's the intellectual pursuit.
This is very highly intellectual and I think it's a lot like how I play with language,
is the same way that I play with fashion or the same way
that I play with ideas in theoretical physics.
There's always this space that you can just push things just enough.
So they look like something someone thinks is familiar,
but they're not familiar.
And yeah, and I think that's really cool.
It seems like beauty doesn't have much function, right?
But it seems to also have a lot of influence
on the way we collaborate with each other.
It has tons of function.
What do you mean it doesn't have function?
I guess sexual selection incorporates beauty somehow,
but why?
Because beauty is a sign of health or something?
I don't even.
Oh, evolutionarily, maybe,
but then beauty becomes a signal of other things, right?
So it's really not like,
and then beauty becomes an adaptive trait,
so it can change with different,
like, you know, maybe some species would think, well, you thought the frog having babies come out of
its back was beautiful and I thought it was grotesque.
There's not a universal definition of what's beautiful.
It is something that is dependent on your history and how you interact with the world.
I guess what I like about beauty, like any other concept, is when you turn it on its head.
So, you know, maybe the traditional conception
of why women wear makeup and they dress certain ways
is because they wanna look beautiful
and pleasing to people.
And I just like to do it,
because it's a confidence thing.
It's about embodying the person that I want to be
and about owning that person.
And then the way that people interact with that person
is very different than if I didn't have the,
like if I wasn't using that attribute as part of,
and obviously that's influenced by the society I live
and like what's aesthetically pleasing things,
but it's interesting to be able to turn that around
and not have it necessarily be about the aesthetics,
but about the power dynamics that the aesthetics create.
But you're saying there's some function to beauty
in that way, in the way you're describing
and the dynamic it creates in the social interaction.
Well, the point is you're saying it's an adaptive trait
for sexual selection or something,
and I'm saying that the adaptation that beauty confers
is far richer than that.
And some of the adaptation is about social hierarchy
and social mobility and just playing social dynamics.
Like why do some people dress goth?
It's because they identify with a community
and a culture associated with that.
And they get, you know, and that's a beautiful aesthetic.
It's a different aesthetic.
Some people don't like it.
So it has the same richness as those language.
Yes.
It's the same kind of.
Yes, and I think too few people think about
the way that they, the aesthetics they build
for themselves in the morning and how they carry it
in the world and the way that other people
interact with that because they put clothes on
and they don't think about clothes as carrying function.
Let's jump from beauty to language.
There's so many ways to explore the topic of language.
You called it, you said that language is,
parts of language or language in itself,
and the mechanism of language is a kind of living life form.
You've tweeted a lot about this in all kinds of poetic ways.
Let's talk about the computation aspect of it.
You tweeted, the world is not a computation,
but computation is our best current language
for understanding the world.
It is important we recognize this
so we can start to see the structure
of our future languages that will allow us
to see deeper than of our future languages that will allow us to see deeper
than computation allows us.
So what's the use of language in helping us understand
and make sense of the world?
I think one thing that I feel like I notice
much more viscerally than I feel like
I hear other people describe is that the representations
in our mind and the way that we use language are not the things like,
actually, I mean, this is an important point going back to what Gödel did, but also this idea of
signs and symbols and all kinds of ways of separating them. There's like the word, right?
And then there's like what the word means about the world, and we often confuse those things.
And what I feel very viscerally, I almost sometimes think
I have some kind of like synesthesia for language
or something, and I just like don't interact with it
like the way that other people do.
But for me, words are objects, and the objects are not
the things that they describe, they have like a different
ontology to them, Like they're physical things and they carry causation and they can create
meaning but they're not what we think they are. And also like the internal representations
in our mind, like the things I'm seeing about this room are probably, you know, like they're
small projection of the things that are actually in this room.
And I think we have such a difficult time moving past
the way that we build representations in the mind
and the way that we structure our language
to realize that those are approximations
to what's out there and they're fluid
and we can play around with them
and we can see deeper structure underneath them
that I think like we're missing a lot.
Yeah, but also the life of the mind is in some ways richer
than the physical reality.
Sure.
What's going on in your mind,
it might be a projection.
Right.
Actually here, but there's also all kinds of other stuff
going on there.
Yeah, for sure.
I love this essay by Poincare about like mathematical
creativity where he talks about this sort of this frothing of all these things,
and then somehow you build theorems on top of it,
and they become concrete.
But I also think about this with language.
It's like there's a lot of stuff happening in your mind,
but you have to compress it in
this few sets of words to try to convey it to someone.
So it's a compactification of the space,
and it's not a very efficient one. I think just recognizing that there's a compactification of the space, and it's not a very efficient one.
And I think just recognizing that there's a lot
that's happening behind language is really important.
I think this is one of the great things
about the existential trauma of large language models,
I think, is the recognition that language
is not the only thing required.
Like there's something underneath it.
Not by everybody.
Can you just speak to the feeling you have
when you think about words?
So is there, like what's the magic of words to you?
Is it like, do you feel, it almost sometimes feels
like you're playing with it.
Yeah, I was just gonna say it's like a playground.
But you're almost like, I was just gonna say it's like a playground.
But you're almost like, I think one of the things
you enjoy, maybe I'm projecting, is deviating,
like using words in ways that not everyone uses them.
Like slightly sort of deviating from the norm.
A little bit just.
I love doing that in everything I do,
but especially with language.
But not so far that it doesn't make sense.
Exactly.
So you're always tethered to reality, to the norm,
but are playing with it,
basically fucking with people's minds a little bit.
And in so doing, creating a different perspective
on the thing that's been previously explored
in a different way.
Yeah, it's literally my favorite thing to do.
Yeah.
Use words as one way to make people think.
Yeah, so I, you know, a lot of my sort of,
like, what happens in my mind
when I'm thinking about ideas
is I've been presented with this information
about how people think about things.
And I try to go around to different communities
and hear the ways that different,
whether it's like, you know,
hanging out with a bunch of artists or philosophers
or scientists thinking about things,
like they all think about it different ways.
And then I just try to figure out like,
how do you take the structure of the way
that we're talking about it and turn it slightly?
So you have all the same pieces
that everybody sees are there,
but the description that you've come up with
seems totally different.
So they can understand that there's,
like they understand the pattern you're describing,
but they never heard the structure underlying it
describe the way that you describe it.
Is there words or terms you remember that
disturbed people the most? Maybe the positive sense of disturbed is assembly theory, I suppose, is one.
Yeah.
I mean, the first couple sentences of that paper disturbed people a lot, and I think
they were really carefully constructed in exactly this kind of way.
What was that?
Let me look it up.
Oh, it was really fun.
But I think it's interesting, because I do, you know,
sometimes I'm very upfront about it.
I say I'm gonna use the same word
in probably six different ways in a lecture, and I will.
You write, scientists have grappled
with reconciling biological evolution
with the immutable laws of the universe defined by physics.
These laws underpin life's origin, evolution and the development of human culture.
Well, he was, I think your love for words runs deeper than these.
Yeah, for sure.
I mean, this is part of the sort of brilliant thing about our collaboration
is, you know, complementary skill sets. So I love playing with the abstract space of
language and it's a really interesting playground when I'm working with Lee because he thinks
that a much deeper level of abstraction than can be expressed by language.
And the ideas we work on are hard to talk about
for that reason.
What do you think about computation as a language?
I think it's a very poor language.
A lot of people think it's a really great one,
but I think it has some nice properties.
But I think the feature of it that is compelling
is this kind of idea of universality
that like you can, If you have a language, you can describe things
in any other language.
For me, one of the people who revealed the expressive power of computation, aside from
Alan Turing, is Stephen Wolfram through all the explorations of cellular automata type of objects that he did in a new kind of science and afterwards.
So what do you get from that?
The kind of computational worlds that are revealed
through even something as simple as cellular automata.
It seems like that's a really nice way to explore languages
that are far outside our human languages and do so rigorously and
understand how those kinds of complex systems can interact with each other, can emerge,
all that kind of stuff.
I don't think that they're outside our human languages.
I think they define the boundary of the space of human languages. They allow us to explore things within that space, which is also fantastic.
But I think there is a set of ideas that takes, and Stephen Wolfram has worked on this quite
a lot and contributed very significantly to it. And I really like some of the stuff that
Stephen's doing with his physics project, but don't agree with a lot of the foundations of it.
I think the space is really fun that he's exploring.
There's this assumption that computation is at the base of reality.
And I kind of see it at the top of reality, not at the base, because I think computation
was built by our biosphere.
It's something that happened after many billion years of evolution. And it doesn't happen in every physical object. It only happens in some of them.
And I think one of the reasons that we feel like the universe is computational is because it's so
easy for us as things that have the theory of computation in our minds.
And actually in some sense,
it might be related to the functioning of our minds
and how we build languages to describe the world
and sets of relations to describe the world.
But it's easy for us to go out into the world
and build computers.
And then we mistake our ability to do that
with assuming that the world is computational.
And I'll give you a really simple example.
This one came from John Conway.
I one time had a conversation with him,
which was really delightful.
He was really fun.
But he was pointing out that if you string lights in a barn,
you can program them to have your favorite
one-dimensional CA, and you might even be able to make them,
you know, do a, like, be capable of universal computation.
Is universal computation a feature of the string lights?
Well, no.
No, it's probably not.
It's a feature of the fact that you, as a programmer,
had a theory that you could embed in's a feature of the fact that you as a programmer had a theory
that you could embed in the physical architecture of the string lights. Now what happens though
is we get confused by this kind of distinction between us as agents in the world that actually
can transfer things that life does onto other physical substrates with what the world is.
And so for example, you'll see people, you know, doing studying the
mathematics of chemical reaction networks and saying, well, chemistry is
turning universal or studying the laws of physics and saying the laws of
physics are turning universal. But anytime that you want to do that, you
always have to prepare an initial state, you have to, you know, you have to
constrain the rule space and then you have to actually be able to demonstrate
the properties of computation,
and all of that requires an agent or a designer
to be able to do that.
But it gives you an intuition.
If you look at a 1D or 2D cellular automata,
it allows you to build an intuition
of how you can have complexity emerge
from very simple beginnings,
very simple initial conditions.
I think that's the intuition
that people have derived from it.
The intuition I get from cellular automata
is that the flat space of an initial condition
in a fixed dynamical law is not rich enough
to describe an open-ended generation process.
And so the way I see cellular automata
is they're embedded slices
in a much larger causal structure.
And if you wanna look at a deterministic slice
of that causal structure, you might be able to extract
a set of consistent rules that you might call
a cellular automata, but you could embed them
as much larger space.
That's not dynamical and is about the causal structure
and relations between all of those computations.
And that would be the space cellular automata live in.
And I think that's the space that Stephen is talking about
when he talks about his Ruliat
and these hypergraphs of all these possible computations.
But I wouldn't take that as my base reality
because I think again, computation itself,
this abstract property computation
is not at the base of reality.
Can we just linger on that Ruliat?
Yeah.
One Ruliat to rule them all.
Yeah.
So what, this is part of a Wolfram Physics project.
It's what he calls the entangled limit of everything
that is computationally possible.
So what's your problem with the Ruliat?
Well, it's interesting.
So, Stephen came to a workshop we had
in the Beyond Center in the fall
and the workshop theme was mathematics, is it evolved or eternal?
And he gave a talk about the Ruliyad, and he was talking about how a lot of the things
that we talk about in the Beyond Center, like does reality have a bottom?
If it has a bottom, what is it?
I need to go to the-
Well, I'll have you know one sometime.
This is great.
Does reality have a bottom?
Yeah. you know, like what's the... I need to go to... Well, I'll have you know one sometime. But this is great.
This reality have a bottom.
Yeah, so we had one that was,
it was called infinite turtles or ground truth.
And it was really just about this issue.
But the thing that was interesting,
I think Steven was trying to make the argument
that, you know, fundamental particles aren't fundamental,
gravitation is not fundamental, these are just
turtles, and computation is fundamental. I remember pointing out to him, I was like,
well, computation is your turtle. I think it's a weird turtle to have.
First of all, isn't it okay to have a turtle?
It's totally fine to have a turtle. Everyone has a turtle. You can't build a theory without a turtle.
Yeah.
It's just, so it depends on the problem
you wanna describe and I actually,
the reason I can't get behind Steven's ontology
is I don't know what question he's trying to answer.
And without a question to answer,
I don't understand why you're building a theory of reality.
And the question you're trying to answer is
What life is.
What life is? Which
another simpler way of phrasing that is how did life originate? Well I started working in the
origin of life and I think what my challenge was there was no one knew what life was and so you
can't really talk about the origination of something if you don't know what it is. And so
the way I would approach it is if you want to understand what life is, then proving
that physics is solving the origin of life.
So there's the theory of what life is, but there's the actual demonstration that that
theory is an accurate description of the phenomena you aim to describe.
So again, they're the same problem.
It's not like I can decouple origin of life from what life is.
It's like that is the problem. It's not like I can decouple origin of life from what life is. It's like that is the problem. And the point I guess I'm making about having a question is no matter
what slice of reality you take, what regularity of nature you're going to try to describe,
there will be an abstraction that unifies that structure of reality, hopefully.
And that will have a fundamental layer to it, right?
Because you have to explain something in terms of something else.
So if I want to explain life, for example, then my fundamental description of nature
has to be something I think that has to do with time being fundamental. But if I wanted to describe, I don't know,
the sort of interactions of matter and light,
I have elementary particles be fundamental.
If I want to describe electricity and magnetism
in the 1800s, I have to have waves be fundamental.
So like you are in quantum mechanics,
like it's a wave function that's fundamental because
that's the sort of explanatory paradigm of your theory.
So I guess I don't know what problem saying computation is fundamental solves.
Doesn't he want to understand how does the basic quantum mechanics and general relativity emerge?
Yeah, but that's-
And how does time-
Right. So I think-
Then that doesn't really answer an important question for us.
Well, I think the issue is general relativity and quantum mechanics are expressed in mathematical
languages. And then computation is a mathematical language. So you're basically saying that maybe
there's a more universal mathematical language for describing theories of physics that we already know. That's
an important question, and I do think that's what Stephen's trying to do and do well. But then the
question becomes, does that formulation of a more universal language for describing the laws of
physics that we know now tell us anything new about the nature of reality?
Or is it a language?
And to you, languages can't be fundamental.
The language itself is never the fundamental thing.
It's whatever it's describing.
So one of the possible titles you were thinking about
originally for the book is the hard problem of life,
sort of reminiscent of the hard problem of consciousness.
So you're saying that assembly theory
is supposed to be answering the question
about what is life.
So let's go to the other hard problems.
You also say that's the easiest of the hard problems
is the hard problem of life.
So what do you think is the nature of intelligence
and consciousness?
We think something like assembly theory
can help us understand that.
I think if assembly theory is an accurate depiction
of the physics of life, it should shed a lot of light on those problems.
And in fact, I sometimes wonder if the problems of consciousness and intelligence are at all
different than the problem of life generally.
And I'm of two minds of it, but I in general try to,
the process of my thinking is trying to regularize everything
into one theory.
So pretty much every interaction I have is like,
oh, how do I fold that into?
And so I'm just building this giant abstraction
that's basically trying to take every piece of data
I've ever gotten in my brain into a theory of what life is.
And consciousness and intelligence are obviously some of the most interesting things that life
has manifest. And so I think they're very telling about some of the deeper features
about the nature of life.
It does seem like they're all flavors of the same thing. But it's interesting to wonder like at which stage
does something that we would recognize as life
in a sort of canonical, silly, human way
and something that we would recognize as intelligence,
at which stage does that emerge?
Like at which assembly index does that emerge
and at which assembly index is it consciousness?
Something that would canonically
recognize as consciousness.
Is this use of flavors the same as you meant
when you were talking about flavors of alien life?
Yeah, sure, yeah.
I mean, it's the same as the flavors of ice cream
and the flavors of fashion.
Yeah, but we were talking about in terms of colors
and very nondescript,
but the way that you just talked about flavors now
was more in the space of consciousness
and intelligence, it was much more specific.
It'd be nice if there was a formal way of expressing.
Quantifying flavors.
Quantifying flavors.
It seems like,
I would order it life, consciousness, intelligence,
probably, as the order in which things emerge
and they're all just the same.
They're the same.
We're using the word life differently here.
I mean, life sort of, when I'm talking about
what is a living versus non-living thing
in a bar with a person, I'm already like
four or five drinks in, that kind of thing.
Just that.
Like we're not being too philosophical,
like here's the thing that moves
and here's the thing that doesn't move.
And, but maybe consciousness precedes that.
It's a weird dance there,
where like, is life precede consciousness
or consciousness precede life?
And I think that understanding of what life is
in the way you're doing will help us disentangle that.
Depending on what you wanna explain,
as I was saying before,
you have to assume something's fundamental.
And so because people can't explain consciousness,
there's a temptation for some people
to wanna take consciousness as fundamental
and assume everything else is derived out of that.
And then you get some people that want to assume consciousness preceded life.
And I don't find either of those views particularly illuminating.
Because I don't want to assume a feminology before I explain a thing.
And so what I've tried really hard to do is not assume that I think life is anything,
except hold on to sort of the patterns and structures that seem to be the sort of consistent
ways that we talk about this thing and then try to build a physics that describes that.
And I think that's a really different approach than saying, you know, consciousness is this
thing, you know, we all feel and experience about things,
I would wanna understand the regularities associated with that and build a deeper structure underneath that
and build into it.
I wouldn't wanna assume that thing
and that I understand that thing,
which is usually how I see people talk about it.
The difference between life and consciousness,
which comes first.
Yeah, so I think if you're thinking about
this sort of thinking about living things
as these giant causal structures
or these objects that are deep in time
or whatever language we end up using to describe it,
it seems to me that consciousness is about,
the fact that we have a conscious experience is because
we are these temporally extended objects.
So consciousness and the abstraction that we have in our minds is actually a manifestation
of all the time that's rolled up in us.
And it's just because we're so huge that we have this very large inner space that we're
experiencing that's not, and it's also separated off from the rest of the world because we're the separate thread in time. And so our consciousness is not exactly shared with
anything else because nothing else occupies the same part of time that we occupy, but I can
understand something about you maybe being conscious because you and I didn't separate
that far in the past in terms of our causal histories.
So in some sense, we can even share experiences
with each other through language
because of that sort of overlap in our structure.
Well, then if consciousness is merely temporal separateness,
then that comes before life.
It's not merely temporal separateness.
It's about the depth in that time.
So it's the reason that my conscious experience
is not the same as yours is because we're separated
in time.
The fact that I have a conscious experience
is because I'm an object that's super deep in time.
So I'm huge in time.
And that means that there's a lot that I am basically
in some sense, a universe onto myself
because my structure is so large relative
to the amount of space that I occupy.
But it feels like that's possible to do
before you get anything like bacteria.
I think there's a horizon,
and I don't know how to articulate this yet.
It's a little bit like the horizon at the origin of life
where the space inside a particular structure
becomes so large that it has some access to a space that's
not, that doesn't feel as physical. It's almost like this idea of counterfactuals.
So I think like the past history of your horizon is just much larger than can be encompassed in
like a small configuration of matter. So you can like pull this stuff into existence.
This property is maybe a continuous property,
but there's something really different about human level physical systems
and human level ability to understand reality.
I really love David Deutsch's conception of universal explainers,
and that's related to's conception of universal explainers and that's
related to the theory of universal computation. And I think there's some transition that
happens there. But maybe to describe that a little bit better, what I can also say is
like what intelligence is in this framework. So you have these objects that are large in time. They were selected to exist by
constraining the possible space of objects to this particular, like all of the matter is funneled
into this particular configuration of object over time. And so these objects arise through
selection. But the more selection that you have embedded in you, the more possible selection you have
on your future.
So selection and evolution, we usually think about in the past sense, where selection happened
in the past.
But objects that are high density configurations of matter that have a lot of selection in
them are also selecting agents in the universe.
So they actually embody the physics of selection and they can select on possible futures.
And I guess what I'm saying with respect to consciousness and the experience we have is
that there's something very deep about that structure and the nature of how we exist in
that structure that has to do with how we're navigating that space and how we generate
that space and how we generate that space
and how we continue to persist in that space.
Is there shortcuts we can take
to artificially engineering living organisms,
artificial life, artificial consciousness,
artificial intelligence?
So maybe just looking pragmatically
at the LLMs we have now,
do you think those can exhibit qualities of life,
qualities of consciousness, qualities of intelligence
in the way we think of intelligence?
I mean, I think they already do,
but not in the way I hear popularly discussed.
So they're obviously signatures of intelligence
and a part of a ecosystem of intelligence systems.
But I don't know that individually,
I would assign all the properties to them
that people have.
It's a little like, so we talked about the history of eyes
before and how eyes scaled up into technological forms.
And language has also had a really interesting history
and got much more interesting, I think,
once we started writing it down and then
inventing books and things.
But every time that we started storing language in a new way,
we were kind of exist accidentally traumatized by it.
So like, you know, the idea of written language was traumatic because it seemed like the dead
were speaking to us even though they were deceased and books were traumatic because,
you know, like suddenly there were lots of copies of this information available to everyone
and it was going to somehow dilute it.
And large language models are kind of interesting because they don't feel as
static, they're very dynamic. But if you think about language in the way I was describing
before as language is this very large in time structure and before it had been something
that was distributed over human brains as a dynamic structure and occasionally we store
components of that very large dynamic structure in books or in written language,
now we can actually store the dynamics of that structure in a physical artifact, which is a
large language model. And so I think about it almost like the evolution of genomes in some sense
where, you know, there might have been like really primitive genes in the first living things and
they didn't store a lot of information or they were like really messy.
And then by the time you get to the eukaryotic cell, you have this really dynamic genetic
architecture that's rewritable, right?
And has all of these different properties.
And I think large language models are kind of like the genetic system for language in
some sense, where it's allowing and a sort of archiving that's highly dynamic.
And I think it's very paradoxical to us because obviously in human history,
we haven't been used to conversing with anything that's not human.
But now we can converse basically with a crystallization of human language in a computer
that's a highly dynamic crystal because it's a crystallization of human language in a computer. That's a highly dynamic crystal
because it's a crystallization in time
of this massive abstract structure
that's evolved over human history
and is now put into a small device.
I think crystallization kind of implies
that a limit on its capabilities.
I think there's not, I mean it very purposefully
because a particular instantiation of a language model
Trained on a particular data set becomes a crystal of the language at that time
It was trained but obviously we're iterating with the technology and evolving it
I guess the question is when you crystallize it when you compress it when you archive it you're archiving
Some slice of the collective intelligence. Yes the human species. That's right.
And the question is, like, how powerful is that?
Right, it's a societal level technology, right?
We've actually put collective intelligence in a box.
Yeah, I mean, how much smarter is the
collective intelligence of humans versus a single human?
And that's the question of AGI versus
human level intelligence. superhuman level intelligence versus human level intelligence.
How much smarter can this thing when done well, when we solve a lot of the complexity,
computation complexities, maybe there's some data complexities and how to really archive
this thing, crystallize this thing really well.
How powerful is this thing gonna be?
What's your thought?
I think, I actually, I don't like the sort of language
we use around that, and I think the language really matters.
So I don't know how to talk about how much smarter
one human is than another, right?
Usually we talk about abilities or particular talent someone has.
And, you know, going back to, you know, David Drake's idea of universal explainers,
like, you know, adopting the view that, you know, we're the first, you know, kinds of structures our biosphere has built
that can understand the rest of reality.
We have this universal comprehension capability.
He makes an argument that basically,
we're the first things that actually are capable of understanding anything.
It doesn't mean an individual understands everything,
but we have that capability.
So there's not a difference between that and what people talk about with AGI.
In some sense, AGI is a universal explainer.
But it might be that a computer is much more efficient
at doing, I don't know, prime factorization or something
than a human is.
But it doesn't mean that it's necessarily smarter
or has a broader reach of the kind of things that
can understand than a human does.
And so I think we really have to think about is it a level shift or is it we're enhancing
certain kinds of capabilities humans have in the same way that we can enhance eyesight
by making telescopes and microscopes?
Are we enhancing capabilities we have into technologies
and the entire global ecosystem is getting more intelligent?
Or is it really that we're building some super machine
in a box that's gonna be smart and kill everybody?
Like, that sounds like a science,
like it's not even a science fiction narrative,
it's a bad science fiction narrative.
I like, I just don't think it's actually accurate
to any of the technologies we're building
or the way that we should be describing them.
It's not even how we should be describing ourselves.
So the benevolent story is,
there's a benevolent system that's able to transform
our economy, our way of life,
by just 10Xing the GDP of culture.
Well, these are human questions, right?
I don't think they're necessarily questions
that we're gonna like outsource to an
artificial intelligence. I think what is happening and will continue to happen is there's a co-evolution
between humans and technology that's happening and we're coexisting in this ecosystem right now
and we're maintaining a lot of the balance and for the balance to shift to the technology would require some very bad human actors,
which is a real risk, or some sort of, I don't know, some sort of dynamic that favors, like,
I just don't know how that plays out without human agency actually trying to put it in
that direction.
It could also be how rapid the rate.
The rapid rate is scary.
So like, I think the things that are terrifying
are the ideas of deep fakes or
all the kinds of issues that become legal issues
about artificial intelligence technologies
and using them to control weapons
or using them for child pornography
or faking out that someone's loved one was kidnapped
or killed and there's all kinds of things
that are super scary in this landscape
and all kinds of new legislation needs to be built
and all kinds of guardrails on the technology to make sure that people don't
abuse it need to be built and that needs to happen.
And I think one function of sort of the artificial intelligence doomsday sort of part of our
culture right now is it's sort of our immune response to knowing that's coming.
And we're over scaring ourselves so we try to act more quickly, which is good.
But I just, you know, it's about the words that we use versus the actual things happening behind
the words. I think one thing that's good is when people are talking about things different ways,
it makes us think about them. And also when things are existentially threatening,
we wanna pay attention to those.
But the ways that they're existentially threatening
and the ways that we're experiencing existential trauma,
I don't think that we're really gonna understand
for another century or two, if ever.
And I certainly think they're not the way
that we're describing them now.
Well, creating existential trauma is one of the things
that makes life fun, I guess.
Yeah, it's just what we do to ourselves.
It gives us really exciting big problems to solve.
Yeah, for sure.
Do you think we will see these AI systems become conscious
or convince us that they're conscious,
and then maybe we'll have relationships with them,
romantic relationships?
Well, I think people are gonna have
romantic relationships with them,
and I also think that some people
would be convinced already that they're conscious.
But I think in order, you know,
what does it take to convince,
convince people that something is conscious.
I think that we actually have to have an idea
of what we're talking about, that it's,
like we have to have a theory that explains
when things are conscious or not, that's testable, right?
And we don't have one right now.
So I think until we have that,
it's always gonna be this sort of gray area
where some people think it hasn't
and some people think it doesn't,
because we don't actually know what we're talking about
that we think it has. So do you think it's possible, and some people think it doesn't, because we don't actually know what we're talking about that we think it has.
So do you think it's possible to get out of the gray area
and really have a formal test for consciousness?
For sure.
And for life, as you were...
For sure.
As we've been talking about for some of you.
Yeah.
Consciousness is a tricky one.
It is a tricky one.
I mean, that's why it's called
the hard problem of consciousness, because it's hard.
And it might even be outside of the purview of science,
which means that we can't understand it
in a scientific way.
There might be other ways of coming to understand it,
but those may not be the ones that we necessarily want
for technological utility or for developing laws
with respect to, because the laws are the things
that are gonna govern the technology.
Well, I think that's actually where
the hard problem of consciousness,
a different hard problem of consciousness,
is that I fear that humans will resist.
That's the last thing they will resist,
is calling something else conscious.
Oh, that's interesting.
I think it depends on the culture though,
because I mean, some cultures already think
like everything's imbued with, you know,
a life essence or kind of conscious.
I don't think those cultures have nuclear weapons.
No, they don't.
They're probably not building
the most advanced technologies.
The cultures that are primed for destroying the other,
constructing a very effective propaganda machines of what the other is,
the group to hate, other cultures that I worry would,
Yeah, I know.
Would be very resistant to label something,
to sort of acknowledge the consciousness laden
in a thing that was created by us humans.
And so what do you think the risks are there
that the conscious things will get angry with us
and fight back?
No, that we would torture and kill conscious beings.
Oh, yeah.
I think we do that quite a lot.
Anyway, without, I mean, I don't,
I mean, it goes back to your,
and I don't know how to feel about this,
but you know, like we talked already
about the predator prey thing that like,
in some sense, you know,
being alive requires eating other things that are alive.
And even if you're a vegetarian or, you know,
like try to have like,
like you're still eating living things, I, yeah.
So maybe part of the story of Earth
will involve a predator prey dynamic
between humans and human creations.
And all of that is part of the type of experience.
But I don't like thinking about them as,
our technologies as a separate species,
because this again goes back to this sort of
levels of selection issue.
And if you think about humans individually alive,
you miss the fact that societies are also alive.
And so I think about it much more in the sense of,
an ecosystem's not the right word,
but we don't have the right words for these things,
of like, and this is why I talk about the technosphere,
it's a system that is both human and technological.
It's not human or technological.
And so this is the part that I think we're really good
for the like, and this is driving in part a lot
of the sort of attitude of like, I'll kill you first
with my nuclear weapons.
We're really good at identifying things as other.
We're not really good at understanding when we're the same or when we're part of
an integrated system that's actually functioning together in some cohesive way.
So even if you look at the division in American politics or something, for example,
it's important that there's multiple sides that are arguing with each other
because that's actually how you resolve society's issues. It's not like a bad feature. I think like some of the sort of extreme positions
and like the way people talk about it are maybe not ideal. But that's how societies solve problems.
What it looks like for an individual is really different than the societal level outcomes and
the fact that like there is, I don't want to call it cognition or computation, I don't know what
you call it, but there is a process playing out in the dynamics of societies that we are
all individual actors in and we're not part of that.
It requires all of us acting individually, but this higher level structure is playing
out some things and things are getting solved for it to be able to maintain itself.
That's the level that our technologies live at.
They don't live at our level.
They live at the societal level and they're deeply integrated with the social organism,
if you want to call it that.
And so I really get upset when people talk about the species of artificial intelligence.
I'm like, you mean we live in an ecosystem of all these kind of intelligent things and
these animating technologies that were,
you know, in some sense, helping to come alive.
We are generating them, but it's not like the biosphere
eliminated all of its past history
when it invented a new species.
All of these things get scaffolded,
and we're also augmenting ourselves at the same time
that we're building technologies.
I don't think we can anticipate
what that system's gonna look like.
So in some fundamental way,
you always wanna be thinking about the planet
as one organism.
The planet is one living thing.
What happens when it becomes multi-planetary?
Is it still just the-
Still the same causal chain.
Same causal chain.
It's like when the first cell split into two.
That's what I was talking about.
When a planet reproduces itself,
the technosphere emerges enough understanding.
It's like this recursive, like the entire history of life is just recursion, right?
So you have an original life event, it evolves for four billion years, at least on our planet.
It evolves a technosphere.
The technologies themselves start to become having this property we call life, which is
the phase we're undergoing now. It solves the origin of itself,
and then it figures out how that process all works,
understands how to make more life,
and then can copy itself onto another planet
so the whole structure can reproduce itself.
And so the origin of life is happening again right now
on this planet in the technosphere
with the way that our planet is undergoing
another transition,
just like at the origin of life when geochemistry transitioned to biology, which is the global,
for me it was a planetary scale transition, it was a multi-scale thing that happened from the scale
of chemistry all the way to planetary cycles. It's happening now all the way from individual humans
to the internet, which is a global technology and all the other things. There's this multi-scale process that's happening
and transitioning us globally,
and it's a dramatic transition.
It's happening really fast.
And we're living in it.
You think this technosphere that we created,
this increasingly complex technosphere
will spread to other planets?
I hope so.
I think so.
You think we'll become a type two Kardashev civilization?
I don't really like the Kardashev scale.
And it goes back to like,
I don't like a lot of the narratives about life
because they're very like, you know,
survival of the fittest, energy consuming, this, that,
and the other thing is very like, I don't know,
sort of old world, you know, like conqueror mentality.
What's the alternative to that?
Exactly.
I mean, I think it does require life
to use new energy sources in order to expand the way it is.
So that part's accurate.
But I think this sort of process of life,
like being the mechanism that the universe
creatively expresses itself, generates novelty,
explores the space of the possible,
is really the thing that's most deeply intrinsic to life.
And so, you know, these sort of energy-consuming scales
of technology, I think, is missing,
the sort of actual feature that's most prominent
about any alien life that we might find,
which is that it's literally our universe, our reality, trying to creatively express
itself and trying to find out what can exist
and trying to make it exist.
See, but past a certain level of complexity,
unfortunately, maybe you can correct me,
but we're built, all complex life on Earth
is built on a foundation of that predator-prairie dynamic.
Yes.
And so, I don't know if we can escape that.
No, we can't, but this is why I'm okay
with having a finite lifetime.
And you know, one of the reasons I'm okay with that,
actually, goes back to this issue of the fact
that we're resource bound.
We live in a, you know, like we have a finite amount
of material, whatever way you wanted to find material.
I think like for me, you know, material is time,
material is information, but we have a finite amount of material.
If time is a generating mechanism,
it's always gonna be finite because the universe is,
it's a resource that's getting generated,
but it has a size,
which means that all the things that could exist
don't exist, and in fact, most of them never will.
So death is a way to make room in the universe
for other things to exist that wouldn't be able
to exist otherwise.
So if the universe over its entire temporal history
wants to maximize the number of things,
wants is a hard word, maximize a hard word,
all these things are approximate,
but wants to maximize the number of things that can exist,
the best way to do it is to make recursively embedded
stacked objects like us that have a lot of structure
and a small volume of space
and to have those things turn over rapidly
so you can create as many of them as possible.
So there for sure is a bunch of those kinds of things
throughout the universe.
Hopefully.
Hopefully our universe is teaming with life.
This is like early on in the conversation
you mentioned that we really don't understand much.
Like there's mystery all around us. Yes.
If you had to like bet money on it, like what percent,
so like say a million years from now,
the story of science and a human understanding understanding that started on
earth is written.
Like what chapter are we on?
Are we like, is this like 1%, 10%, 20%, 50%, 90%?
How much do we understand?
Like the big stuff.
Not like the details of like big important questions
and ideas.
I think we're in our 20s.
20% of the 20s?
No, like age-wise, let's say we're in our 20s,
but the lifespan is gonna keep getting longer.
You can't do that.
I can.
You know why I use that though?
I'll tell you why.
Why my brain went there is because,
anybody that gets an education in physics, you know,
has this sort of trope about how all the great physicists
did their best work in their 20s,
and then you don't do any good work after that.
And I always thought it was kind of funny
because for me, physics is not complete.
It's not nearly complete, but most physicists think that we understand
most of the structure of reality.
And so I think I actually,
I think I put this in the book somewhere,
but like this idea to me that societies
would discover everything while they're young
is very consistent with the way we talk about physics
right now.
But I don't think that's actually
the way that things are gonna go. And
you're finding that people that are making major discoveries are getting older in some sense than
they were, and our lifespan is also increasing. So I think there is something about age and your
ability to learn and how much of the world you can see that's really important over a human lifespan,
but also over the lifespan of societies.
And so I don't know how big the frontier is.
I don't actually think it has a limit.
I don't believe in infinity as a physical thing,
but I think as a receding horizon,
I think because the universe is getting bigger,
you can never know all of it.
Well, I think it's about 1.7%.
1.7, where does that come from?
And it's a finite, I don't know, I just made it up.
That number had to come from somewhere.
I think seven is the thing that people usually pick.
7%.
So I wanted to say 1%, but I thought it would be funnier.
Yeah, I agree.
To add a point, you know, so humor,
inject a little humor in there.
So the seven is for the humor,
one is for how much mystery I think there is out there.
99% mystery, 1% known.
In terms of like really big important questions.
Yeah.
It's like the list, say there's gonna be like 200 chapters,
like the stuff that's gonna remain true.
But you think the book has a finite size.
Yeah, yeah.
And I don't.
I mean, not that I believe in infinities,
but I think the size of the book is growing.
Well, the fact that the size of the book is growing
is one of the chapters in the book.
Oh, there you go.
Ooh, we're being recursive.
I think you have to, you can't have an ever-growing book.
Yes you can.
I mean, you just, I mean, I don't even,
because then-
Well, you couldn't have been asking this
at the origin of life, right?
Because obviously, like, you wouldn't have existed
at the origin of life, but like,
the question of intelligence and artificial general,
like, those questions did not exist then.
And they in part existed because the universe
invented a space for those questions to exist
through evolution.
But I think that question will still stand
a thousand years from now.
It will, but there will be other questions
we can't anticipate now that we'll be asking.
Yeah, and maybe we'll develop the kinds of languages
that we'll be able to ask much better questions.
Right, or like the theory of gravitation, for example.
When we invented that theory,
we only knew about the planets in our solar system, right?
And now, many centuries later,
we know about all these planets around other stars
and black holes and other things
that we could never have anticipated.
So, and then we can ask questions about them.
You know, like we wouldn't have been asking
about singularities and like,
can they really be physical things in the universe
several hundred years ago?
That question couldn't exist.
Yeah, but it's not,
I still think those are chapters in a book.
Like I don't get a sense from that.
So do you think the universe has an end?
If you think it's a book with an end.
I think the number of words required to describe
how the universe works has an end, yes.
Meaning like I don't care if it's infinite or not.
Right.
As long as the explanation is simple and it exists.
Oh I see.
And I think there is a finite explanation
for each aspect of it.
The consciousness, the life.
Yeah.
I mean, very probably there's like some,
the black hole thing is like, what's going on there?
Where's that going?
Like, where are they?
What?
And then, you know, why the Big Bang?
Like what?
It's probably there's just a huge number of universes
and it's like universes inside universes.
I think universes inside universes is maybe possible.
I just think it's,
every time we assume this is all there is,
it turns out there's much more.
The universe is a huge place.
And we mostly talked about the past
and the richness of the past, but the future,
I mean with many worlds interpretation of quantum mechanics.
So.
Oh, I am not a many words person.
You're not.
No, are you?
How many Lexus are there?
Depending on the day.
Well.
Do some of them wear yellow jackets? At the moment the moment the moment you asked the question. There was one
At the moment. I'm answering it. There's no in near infinity apparently
I
mean the future is
The future is bigger than the past. Yes. Yes. Okay. Well, they in the past according to you. It's already gigantic
Yeah, but yeah, I mean, that's consistent with many worlds,
right, because there's this constant branching.
But it doesn't really have a directionality to it.
I don't know, many worlds is weird.
So my interpretation of reality is if you fold it up,
all that bifurcation of many worlds,
and you just fold it into the structure that is you,
and you just said you are all of those many worlds,
and that sort of, your history converged on you,
but you're actually an object that was selected to exist.
And you're self-consistent with the other structures.
So the quantum mechanical reality is not
the one that you live in.
It's this very deterministic classical world.
And you're carving a path through that space,
but I don't think that you're constantly branching
into new spaces.
I think you are that space.
Which, so to you at the bottom, it's deterministic.
I thought you said the universe is just a bunch of animals.
No, it's random at the bottom, right?
But like this randomness that we see at the bottom
of reality that is quantum mechanics,
I think like people have assumed that that is reality.
And what I'm saying is like all those things you see
in many worlds, all those versions of you,
just collect them up and bundle them up.
And like they're all you.
And what has happened is, you know,
like elementary particles don't have,
they don't live in a deterministic universe,
the things that we study in quantum experiments.
They live in this fuzzy random space,
but as that structure collapsed
and started to build structures that were deterministic
and evolved into you,
you are a very deterministic macroscopic object.
And you can look down on that universe
that doesn't have time in it, that random structure.
And you can see that all of these possibilities
look possible, but they're not possible for you
because you're constrained by this
giant causal structural history.
So you can't live in all those universes.
You'd have to go all the way back
to the very beginning of the universe
and retrace everything again to be a different you.
So where's the source of the free will
for the macro object?
It's the fact that you're a deterministic structure
living in a random background.
And also all of that selection bundled in you
allows you to select on possible futures.
So that's where your will comes from.
And there's just always a little bit of randomness
because the universe is getting bigger.
And this idea that the past is in the present
is not large enough yet to contain the future,
the extra structure has to come from somewhere.
And some of that is because outside of those giant causal structures
that are things like us, it's fucking random out there.
And it's scary. And we're all hanging onto each other
because the only way to hang onto each other,
like the only way to exist is to like cling on
to all of these causal structures
that we happen to co-inhabitate existence with
and try to keep reinforcing each other's existence.
All the selection bundled in.
Hold up, enough, but free will's totally consistent
with that.
I don't know what I think about that.
That's complicated to imagine.
Just that little bit of randomness is enough.
Okay.
Well, it's also, it's not just the randomness.
There's two features.
One is randomness helps generate some novelty
and some flexibility, but it's also that like,
because you're the structure that's deep in time,
you have this combinatorial history that's you.
And I think about time and assembly theory,
not as linear time, but as combinatorial time.
So if you have all of this structure
that you're built out of, you, in principle,
your future can be combinations of that structure.
You obviously need to persist yourself as a coherent you.
So you wanna optimize for a future
in that combinatorial space that still includes you,
most of the time for most of us.
And when you make those kinds,
and then that gives you a space to operate in,
and that's your sort of horizon
where your free will can operate.
And your free will can't be instantaneous.
So for like example, like I'm sitting here
talking to you right now, I can't be in the UK
and I can't be in Arizona, but I could plan,
I could execute my free will over time
because free will is a temporal feature of life
to be there tomorrow or the next day if I wanted to.
But what about like the instantaneous decisions
you're making, like to, I don't know,
to put your hand on the table?
I think those were already decided a while ago.
I don't think free will is ever instantaneous.
But on the longer time horizon,
there's some kind of staring going on?
Who's doing the staring?
You are.
And you being this macro object that's encompasses.
Or you being Lex.
Whatever you wanna call it.
There you are saying words to things once again.
I know.
Why does anything exist at all?
You've kind of taken that as a starting point.
Yeah.
It exists.
I think that's the hardest question.
Isn't it just hard questions stack on top of each other?
It is.
Wouldn't it be the same kind of question of what is life?
It is the same.
Well, that's sort of like,
I try to fold all of the questions into that question
because I think that one's really hard.
And I think the nature of existence is really hard.
You think actually like answering what is life
will help us understand existence?
Maybe there's, it's turtles all the way down.
It'll just, understanding the nature of turtles
will help us kind of march down.
Even if we don't have the experimental methodology
of reaching before the Big Bang.
Right, so, well I think there's sort of two questions
embedded here.
I think the one that we can't answer by answering life
is why certain things exist and others don't.
But I think the sort of ultimate question,
the sort of like prime mover question
of why anything exists, we will not be able to answer.
What's outside the universe?
Oh, there's nothing outside the universe.
So I have a very, I am a very,
like I am like the most physicalist that anyone could be.
So like for me, everything exists in our universe.
And it, and like I like to like think it like everything exists here. So even when we talk
about the multiverse, I don't like it. To me, it's not like there's all these other
universes outside of our universe that exists. The multiverse is a concept that exists in
human minds here. And it allows us to have some counterfactual reasoning
to reason about our own cosmology
and therefore it's causal in our biosphere
to understanding the reality that we live in
and building better theories.
But I don't think that the multiverse is something like,
and also math, like I don't think there's a platonic world
that mathematical things live in.
I think mathematical things are here on this planet.
Like I don't think it makes sense to talk about things
that exist outside of the universe.
If you're talking about them,
you're already talking about something
that exists inside the universe
and is part of the universe
and is part of like what the universe is building.
It all originates here.
It all exists here in some people.
I mean, what else would there be?
There could be things you can't possibly understand
outside of all of this that we call the universe.
And you can say that, and that's an interesting philosophy,
but again, this is sort of like pushing on the boundaries
of like the way that we understand things.
I think it's more constructive to say the fact
that I can talk about those things is telling me something
about the structure of where I actually live
and where I exist.
Just because it's more constructive
doesn't mean it's true.
Well, it may not be true.
It may be something that allows me to build better theories
I can test to try to understand something objective.
And in the end, that's a good way to get to the truth.
Exactly.
Even if you realize you were wrong in the past.
Yeah, so there's no such thing as experimental Pletanism.
But if you think math is an object
that emerged in our biosphere,
you can start experimenting with that idea.
And that to me is really interesting.
Like to think about, well, people,
I mean, mathematicians do think about math.
Sometimes it's an experimental science.
But to think about math itself as an object
for study by physicists rather than a tool physicists use to describe reality, it becomes the part of reality they're trying to describe
to me as a deeply interesting inversion.
What to you is most beautiful about this kind of exploration of the physics of life that
you've been doing?
I love the way it makes me feel.
And then you have to try to convert the feelings
into visuals and the visuals into words?
Yeah, so I think I love, yeah,
I love the way it makes me feel to have ideas
that I think are novel.
And I think that the dual side of that
is the painful process of trying to communicate that
with other human beings to test if they have
any kind of reality to them.
And I also love that process.
I love trying to figure out how to explain
really deep abstract things that I don't think
that we understand and trying to understand them
with other people. And I also love think that we understand, and trying to understand them with other people.
I also love the shock value of
this idea we were talking about before of being on the boundary of what we understand.
So people can see what you're seeing,
but they haven't ever saw it that way before.
I love the shock value that people have,
like that immediate moment of recognizing
that there's something beyond the way
that they thought about things before.
And being able to deliver that to people,
I think is one of the biggest joys that I have,
is just like, maybe it's that sense of mystery,
to share that there's something beyond the frontier
of how we understand and we might be able to see it.
And you get to see the humans transformed by the new idea?
Yes. And you get to see the humans transformed by the new idea? Yeah.
Yes.
And I think my greatest wish in life is to somehow contribute to an idea that transforms
the way that we think.
Like I have my problem I want to solve, but like the thing that gives me joy about it
is really changing something. And ideally getting to a deeper understanding
of how the world works and what we are.
Yeah, I would say understanding life at a deep level.
Yeah.
Is probably one of the most exciting problems,
one of the most exciting questions.
So I'm glad you're trying to answer just that
and doing it in style.
It's the only way to do anything.
Thank you so much for this amazing conversation.
Thank you for being you, Sarah.
This was awesome.
Thanks, Lex.
Thanks for listening to this conversation
with Sarah Walker.
To support this podcast,
please check out our sponsors in the description. And now let me leave you with some words from Charles Darwin. Thank you for listening, and hope to see you next time.